INSTRUCTOR’S SOLUTIONS MANUAL to accompany
COST ACCOUNTING A Managerial Emphasis Sixth Canadian Edition Charles T. Horngren Stanford University Srikant M. Datar Stanford University George Foster Stanford University Madhav Rajan Stanford University Christopher Ittner University of Pennsylvania Maureen P. Gowing University of Windsor Steve Janz Southern Alberta Institute of Technology
Toronto Copyright © 2013 Pearson Canada Inc. All rights reserved. This work is protected by Canadian copyright laws and is provided solely for the use of instructors in teaching their courses and assessing student learning. Dissemination or sale of any part of this work (including on the Internet) will destroy the integrity of the work and is not permitted. The copyright holder grants permission to instructors who have adopted Cost Accounting: A Managerial Emphasis, Sixth Canadian Edition, by Horngren, Datar, Foster, Rajan, Ittner, Gowing, and Janz to post this material online only if the use of the website is restricted by access codes to students in the instructor’s class that is using the textbook and provided the reproduced material bears this copyright notice.
Contents Part One Chapter 1: The Accountant’s Vital Role in Decision Making................................1 Chapter 2: An Introduction to Cost Terms and Purposes .....................................19 Chapter 3: Cost-Volume-Profit Analysis .............................................................57 Chapter 4: Job Costing .......................................................................................124 Chapter 5: Activity-Based Costing and Management ........................................174 Part Two Chapter 6: Master Budget and Responsibility Accounting ................................225 Chapter 7: Flexible Budgets, Variances, and Management Control: I ...............281 Chapter 8: Flexible Budgets, Variances, and Management Control: II..............346 Chapter 9: Income Effects of Denominator Level on Inventory Valuation ...................................................................414 Part Three Chapter 10: Quantitative Analyses of Cost Functions........................................480 Chapter 11: Decision Making and Relevant Information...................................520 Chapter 12: Pricing Decisions, Product Profitability Decisions, and Cost Management ...........................................................................572 Chapter 13: Strategy, Balanced Scorecard, and Strategic Profitability Analysis ......................................................................606 Part Four Chapter 14: Period Cost Allocation....................................................................661 Chapter 15: Cost Allocation: Joint Products and Byproducts ............................701 Chapter 16: Revenue and Customer Profitability Analysis................................760 Chapter 17: Process Costing...............................................................................828 Part Five Chapter 18: Spoilage, Rework, and Scrap..........................................................894 Chapter 19: Cost Management: Quality, Time, and the Theory of Constraints ...............................................................942 Chapter 20: Inventory Cost Management Strategies..........................................996 Part Six Chapter 21: Capital Budgeting: Methods of Investment Analysis ...................1033 Chapter 22: Capital Budgeting: A Closer Look ...............................................1077 Part Seven Chapter 23: Transfer Pricing, and Multinational Management Control Systems ......................................................1126 Chapter 24: Multinational Performance Measurement and Compensation......1186
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CHAPTER 1 THE ACCOUNTANT’S VITAL ROLE IN DECISION MAKING
SHORT‐ANSWER QUESTIONS 1‐1 Management accounting measures, analyzes, and reports financial and nonfinancial information to internal managers making internal decisions to improve performance. The reporting and analyses are not restricted by generally accepted accounting principles (GAAP) based on either IFRS or Canadian accounting standards. Financial accounting measures, analyzes, and reports primarily financial information to external parties who own the corporate assets, such as investors, government agencies, and banks. Methods of identification and classification of business transactions, measurement of their economic effect, analyses, and reporting in financial statements must comply with standards set by the Canadian Institute of Chartered Accountants (CICA). The CICA participates in the production of IFRS standards and has the option to amend rather than adopt these standards. Other differences include (1) management accounting emphasizes the future (not the past), and (2) management accounting is designed specifically to influence the behaviour of managers and other employees (rather than primarily reporting economic events).
1‐2
In Canada, financial accounting is constrained by generally accepted accounting principles (GAAP). Companies listed on Stock Exchanges must comply with International Financial Reporting Standards (IFRS). Other companies must comply with CICA standards when reporting to external parties. Management accounting is not restricted to these principles. The result is that management accountants can charge interest on owners’ capital to help judge a division’s performance, even though such a charge is not allowed under GAAP, management accountants can classify, measure, and include the value of internally developed assets and liabilities not recognized under GAAP, management accountants can use measurement methods of the value of assets or liabilities not permitted under GAAP, management accountants can change the method of revenue and expense recognition, which is not permitted under GAAP, and management accountants assess the quality of information provided based on how well it reflects the economic reality of a real business process, not a standard.
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1‐3
Management accountants help formulate strategy by identifying relevant information about the sources of competitive advantage—usually the cost, productivity, or efficiency advantage of their company relative to competitors. Alternatively, management accountants can analyze the benefits to customers and the costs to the company of adding features to further customize more distinctive products or services. These data will assist in setting an appropriate premium price for distinctive value‐ added attributes as determined by the customer.
1‐4
The business functions in the value chain are Research and development—generating and experimenting with ideas related to new products, services, or processes. Design of products, services, and processes—the detailed planning and engineering of products, services, or processes. Production—acquiring, coordinating, and assembling resources to produce a product or deliver a service. Marketing—promoting and selling products or services to customers or prospective customers. Distribution—delivering products or services to customers. Customer service—providing after‐sale support to customers.
1‐5
The “supply chain” is a coordinated flow of goods, services, and information from each initial source of materials and services to the delivery of products to consumers, whether or not the supply activities occur in the purchasing or in other organizations. Cost management is most effective when it integrates and coordinates activities across all suppliers in the supply chain as well as across each business function in the purchasing company’s value chain. Business functions can be restructured to be more cost‐effective.
1‐6
This statement is wrong. Management accountants also analyze revenues from products, services, and customers relative to their costs to assess the profitability of types of products, services, and customers. Management accountants also examine the business environment and report relevant information on the intensity of competition. Cost information is only one part of the relevant internal and external information identified, analyzed, and reported by management accountants.
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Chapter 1
1‐7 Management accountants help a management team identify performance measures that are important to maintain or increase profitability. Important measures include features, quality, and timely delivery as determined by customers. For‐profit companies use these data to evaluate the balance of costs and benefits—both financial and nonfinancial—and provide relative assurance that proposed changes will not impair profitability. Initiatives include TQM, relieving bottleneck constraints, or providing faster customer service.
1‐8
The five‐step decision‐making process is (1) identify the problem and uncertainties, (2) obtain relevant information, (3) predict likely outcomes, (4) decide among alternatives, and (5) implement the decision, evaluate performance, and learn. Often the most important information required to provide certainty around predictions is missing, which is why rigorous and disciplined decision making is important to success.
1‐9
Planning decisions include (a) selecting organization goals, (b) predicting results under various alternative ways of achieving those goals, (c) deciding how to attain the desired goals, and (d) communicating the goals and how to attain them to the entire organization. Good planning decisions indicate how rigorous and disciplined the management team is at making unbiased business decisions in the best interests of improving organizational profit. Control decisions require the assessment of actual compared to planned or predicted outcomes and include (a) identifying performance outcomes and how to measure them, (b) obtaining timely and high‐quality feedback, (c) assessing how to improve actual performance, and (d) acting differently to improve the implementation of planning decisions. Good control decisions indicate how well a management team learns from its actual experience.
1‐10 The three guidelines for management accountants are 1. 2. 3.
Employ a cost‐benefit approach. Recognize behavioural and technical considerations. Identify relevance and understand that decisions require “different costs for different purposes.”
1‐11 Agree. A successful management accountant requires general business skills (such as understanding the strategy of an organization) and people skills (such as motivating other team members) as well as technical skills (such as computer knowledge, calculating costs of products, and supporting planning and control decisions).
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1‐12 The new controller could reply in one or more of the following ways: (a)
(b)
(c)
(d)
Demonstrate to the plant manager how he or she could make better decisions if the plant controller was viewed as a resource rather than a busybody. The plant controller is the best person to show how the plant manager will benefit because his or her time and resources can be saved by bringing the plant controller into the decision‐making process. Demonstrate to the plant manager a good knowledge of the technical aspects of the plant. This approach often requires research on customer preferences, potential for growth in demand, plant‐specific production or service processes, people, and suppliers. It certainly will involve spending time on the plant floor speaking to plant personnel to learn from their practical experience. Show the plant manager examples of the new plant controller’s past successes in working with line managers in other plants. Examples could include: assistance in reducing the plant manager’s time to prepare the budget, assistance in analyzing problem situations and evaluating financial and nonfinancial aspects of different alternatives, and assistance in submitting successful capital budget requests. Seek assistance from the corporate controller to highlight to the plant manager the importance of many tasks undertaken by the new plant controller. This approach is a last resort but may be necessary in some cases.
1‐13 Steps to take when established written policies provide insufficient guidance are (a) (b) (c) (d)
Discuss the problem with the immediate superior (except when it appears that the superior is involved). Clarify relevant ethical issues by confidential discussion with an impartial adviser. Discuss the situation with an adviser from the professional accounting organization you are a member of (CA, CGA, or CMA). Consult your own lawyer about legal obligations and rights arising from ethical conflicts.
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Chapter 1
EXERCISES
1‐14 (10 min.)
Terminology.
1. 2. 3. 4. 5. 6. 7. 8. 9.
timely, reliable technical Control ethical guidelines Management accounting cost‐benefit Strategy Value chain Corporate social responsibility
1‐15 (10 min.) Cost, management, and financial accounting. 1.
2.
Once a transaction has occurred, financial accountants classify the transaction according to CICA standards and GAAP. This information is then communicated to external parties in a standardized way. Management accountants use financial accounting information, knowing the relevance and reliability of these data. The basic financial accounting information can be analyzed and reported by management accountants using a variety of techniques most appropriate to the management decision being made. These analyzes will filter relevant costs and inform an internal decision maker.
All accountants are members of a profession and are bound by professional duty to act with integrity. Their duty is to report estimates of the financial outcomes from doing business, which do not materially misstate the economic value of the company.
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1‐16 (10 min.) Strategy. 1.
2.
Managers assess the internal strengths and weaknesses of their company relative to those in against whom they compete. In addition to competitors managers also gather relevant information about other external parties upon whom the company depends, such as customers, suppliers, financing, the existence of substitute products. The purpose is to evaluate how a management team can control and deploy internal resources to best counter external threats from its environment and profit from external opportunities. By matching the intensity of competition in the environment with the unique competitive strengths of a company, management teams can select the best strategy. Strategy requires managers to examine how the company and its goals fit with the external environment over which the company has no control. Strategic decisions are made for the long‐term guidance and coordination of activities. Operating decisions are made with a focus on internal strengths and weaknesses. Operating decisions are made in the short term to achieve expected performance levels.
1‐17 (15 min.) Value chain and classification of costs, fast food restaurant. 1. 2. 3. 4. 5. 6. 7. 8.
Production Distribution Marketing Marketing Marketing Production Design of products, services or processes Customer service
1‐18 (15 min.) 1. 2. 3. 4. 5. 6. 7. 8.
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Value chain and customer expectations.
Design Marketing Customer service Research and development Marketing Production Marketing Distribution
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Chapter 1
1‐19 (10 min.)
Planning and control decisions.
1. 2. 3. 4. 5.
Planning Control Control Planning Planning
1‐20
(15 min.)
1. 2. 3.
Obtain information. Predict likely future outcomes. Identify the problem and uncertainties.
4. 5. 6.
Implement the decision, evaluate performance, and learn. Predict likely future outcomes(again). Identify and decide among alternatives.
7.
Obtain information.
Five‐step decision‐making role of relevant accounting information.
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(15 min.)
Five‐step decision‐making process, service firm.
1. 2. 3. 4. 5. 6. 7.
Obtain information
Identify the problem and uncertainties Predict likely future outcomes Implement the decision, evaluate performance, and learn Predict likely future outcomes Obtain information Identify and decide among alternatives
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PROBLEMS
1‐22 (20 min.) 1.
Strategic decisions and management accounting.
The strategies the companies are following in each case are: a Low‐price strategy b. Differentiated‐product strategy c. Low‐price strategy d. Differentiated‐product strategy
2.
Examples of information the management accountant can provide for each strategic decision follow. a. Cost to manufacture and sell the smartphone Productivity, efficiency, and cost advantages relative to competition Prices of competitive smart mobile devices Sensitivity of target customers to price and quality The production capacity of Roger Phones relative to its competitors b. Cost to develop, produce, and sell new software Premium price that customers would be willing to pay due to product uniqueness Price of basic software Price of closest competitive software Cash needed to develop, produce, and sell new software c. Cost of producing the “store brand” lip gloss Productivity, efficiency, and cost advantages relative to competition Prices of competitive products Sensitivity of target customers to price and quality How the market for lip gloss is growing d. Cost to produce and sell new line of gourmet bologna Premium price that customers would be willing to pay due to product uniqueness Price of basic meat product Price of closest competitive product
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Chapter 1
1‐23 (15 min.) Planning and control decisions. The plan or budget communicates the financial goals the organization will achieve while control arises from feedback on how well the plan has been achieved and reasons why the plan has not been achieved.
a.
Annual financial statements communicate what was achieved. The annual report is a standardized control report on financial performance. It is feedback on what the organization accomplished. Internal periodic reports of financial performance are control reports. The report of losses suffered from a storm is a financial report that is a control report. Externally the insurer will use the report to estimate the amounts it will reimburse Softmoc according to the insurance contract. Internally the managers will use the report to modify their plan and generate the most appropriate response to an unanticipated event. The actual event will also initiate review of the adequacy of the insurance coverage relative to its cost. These new data will be used in subsequent plans for future insurance coverage and its cost. Weekly reports of the total quantity of particular shoes sold are feedback. They are control reports internally because a comparison can be made with the plan to determine if the plan was achieved and if not, why not. They are control reports for the supplier for the same reasons. Studies of new business development opportunities communicate planned costs and revenue.
b. c.
d.
e.
1‐24 (30 min.)
Accountants’ guidelines and roles in a company.
This problem raises plenty of thought‐provoking questions. There are no easy answers. Generalizing is impossible, based on the unique facts of this case. 1. Is appears that Whisler mistrusts the performance analyses conducted by Berstrom’s staff but the important question is how this arose and how can it be remedied. Whisler and Bergstrom are part of the same management team. Whisler has no confidence in the accountants who seem instrusive and unqualified to identify and measure performance for two stated reasons: (a) the responsibility is Whisler’s, not the accountants’; and (b) Whisler has experienced problems in performance first hand. He understands the complexity of a real situation. Whisler has maintained a day‐to‐day relationship with line personnel in Division C.
1‐24 (cont’d)
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2.
3.
Bergstrom needs to establish trust now, not later that the work is being done by his performance‐analysis staff will reflect the economic reality of Whisler’s performance. It may be that different performance measures will improve their relationship and the benefits to Whisler from using the reports. Then Whisler can concentrate on remedies with confidence they are likely to work. Bergstrom can help Whisler understand that performance measurement and analysis is a support not a line function intended to relieve Whisler of routine tasks. Centralizing performance measurement will help standardize, simplify and predict the likely outcomes of any remedies Whisler implements. Bergstrom can also let Whisler know the benefits of appropriate standardization of performance measures across divisions when strategic decisions must be made Whisler needs reassurance that his job security and remuneration is protected when uncontrollable factors cause performance shortfalls. Two approaches within the existing organization reporting relationships would be: (a) Placing higher priority on having his performance‐analysis staff view the division personnel as important customers and actively seeking out ways to increase customer satisfaction. (b) Encouraging greater use of teams in which division personnel and corporate control personnel are members. Hopefully, mutual respect will increase by this close interaction. A more extreme approach would be to change the organization’s reporting relationships and staff assignments. For example, each division manager could have his or her own performance‐analysis staff member as part of the plant controller’s group. Or, a matrix reporting relationships could be implemented.
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Chapter 1
1‐25 (35 min.) Professional ethics and end‐of‐year actions.
1.
2.
The possible motivations for the snack foods division president wanting to take end‐of‐year actions include: Management incentives. Gourmet Foods may have a division bonus scheme based on one‐year reported division earnings. Efforts to front‐end revenue into the current year or transfer costs into the next year can increase this bonus. Promotion opportunities and job security. Top management of Gourmet Foods likely will view those division managers that deliver high reported earnings growth rates as being the best prospects for promotion. Division managers who deliver “unwelcome surprises” may be viewed as less capable. Retain division autonomy. If top management of Gourmet Foods adopts a “management by exception” approach, divisions that report sharp reductions in their earnings growth rates may attract a sizable increase in top management oversight. Several of the “end‐of‐year actions” clearly are in conflict and should be viewed as unacceptable by Taylor: (b) The fiscal year‐end should be closed on midnight of December 31. “Extending” the close falsely reports next year’s sales as this year’s sales. (c) Altering shipping dates is falsification of the accounting reports. (f) Advertisements run in December should be charged to the current year. The advertising agency is facilitating falsification of the accounting records of Gourmet Foods as well as falsifying its own records. The other “end‐of‐year actions” occur in many organizations and may fall into the “grey” to “acceptable” area. However, much depends on the circumstances surrounding each one: (a) If the independent contractor does not do maintenance work in December, there is no transaction regarding maintenance to record. The responsibility for ensuring packaging equipment is well maintained is that of the plant manager. The division controller probably can do little more than observe the absence of a December maintenance charge. (d) In many organizations sales are heavily concentrated in the final weeks of the fiscal year end. If the double bonus is approved by the division marketing manager, the division controller can do little more than observe the extra bonus paid in December.
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1‐25 (cont’d) (e)
If advertising is reduced in December, the advertising cost in December will be reduced. There is no record falsification here. (g) Much depends on the means of “persuading” carriers to accept the merchandise. For example, if an under‐the‐table payment is involved, it is clearly unethical. If, however, the carrier receives no extra consideration and willingly agrees to accept the assignment, the transaction appears ethical. Each of the (a), (d), (e) and (g) “end‐of‐year actions” may well disadvantage Gourmet Foods in the long‐run. The divisional controller is well advised to raise this issue in meetings with the division president. However, if Gourmet Foods has a rigid set of line/staff distinctions, the division president is the one who bears primary responsibility for justifying division actions to senior corporate officers. 3.
If Taylor believes that Ryan wants her to engage in unethical behaviour, she should first directly raise her concerns with Ryan. If Ryan is unwilling to change his request, Taylor should discuss her concerns with the Corporate Controller of Gourmet Foods. She could also initiate a confidential discussion with a SMAC adviser, other impartial adviser, or her own lawyer. Taylor also may well ask for a transfer from the snack foods division if she perceives Ryan is unwilling to listen to pressure brought by the Corporate Controller, CFO, or even President of Gourmet Foods. In the extreme, she may want to resign if the corporate culture of Gourmet Foods is to reward division managers who take “end‐of‐year actions” that Taylor views as unethical and possibly illegal.
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1‐26 (35 min.) 1.
Chapter 1
Professional ethics and earnings management.
The possible motivations for Harvest Day Corporation’s CEO to “manage” earnings include: Manage the stock price. Harvest Day’s CEO wants to meet the forecasted earnings number of $1.34 per share because the CEO believes that the stock price will drop if actual earnings fall short of the forecast. Job security. The CEO may be concerned that the Board of Directors may have a poor view of him if he delivers “unwelcome surprises.” Depending on how much the stock falls, they may even consider dismissing him. Management incentives. The bonuses of top management and the CEO may be based on earnings. If earnings decrease, smaller or no bonuses may be paid. If top management and the CEO have stock options, the value of these options will be adversely affected if the stock price falls.
2.
Several of the “end‐of‐year actions” clearly are in conflict and should be viewed as unacceptable: (a) Subscriptions cancelled in December should be recorded in December itself and not delayed until January. (c) Subscription revenue received in December in advance for magazines that will be sent out in January is a liability. Showing it as revenue falsely reports next year’s revenue as this year’s revenue. (d) Office supplies purchased in December should be recorded as an expense of the current year and not as an expense of the next year. (e) Booking advertising revenues that relate to January in December falsely reports next year’s revenue as this year’s revenue. The other “end‐of‐year actions” occur in many organizations and may fall into the “grey” to “acceptable” area. However, much depends on the circumstances surrounding each one: (b) If the software on office computers is not updated until January, there is no transaction or expense to record in December. The responsibility for ensuring that the software is updated is that of the chief information technology officer. The controller can do little more than observe the absence of a December software update and question whether this will have an adverse long‐term impact on Harvest Day. (f) If building repairs are not done in December, there is no transaction to record in December. There is no record falsification here. The decision regarding when to do building repairs is made by the operations manager.
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1‐26 (cont’d) (g)
3.
Many companies switch their amortization policy from one method to another. Harvest Day could argue that straight‐line amortization better represents the decrease in the economic value of the asset compared to the declining‐balance method. Straight‐line amortization may also be more in line with what its competitors do. If, however, Harvest Day changes to straight‐line amortization with the sole purpose of reducing expenses to meet its earnings goal, such behaviour would be unacceptable. The standards of ethical behaviour require management accountants to communicate information fairly and objectively, and to carry out duties ethically.
Harvest Day’s controller should directly raise his/her concerns with the CEO. If the CEO refuses to change his request, the Controller should raise these issues with the Audit Committee and the Board of Directors. The Controller could also initiate a confidential discussion with an SMAC adviser, other impartial adviser, or his/her own attorney. In the extreme, the Controller may want to resign if the corporate culture of Harvest Day is to reward executives who take “end of fiscal year actions” that the Controller views as unethical and possibly illegal. It was precisely actions along the lines of (a), (c), (d), and (e) that caused Betty Vinson, an accountant at WorldCom, to be indicted for falsifying WorldCom’s books and misleading investors.
1‐27 (10 min.) 1.
2.
Professional ethics and corporate governance.
Segato’s ethical responsibilities are well summarized in the CMA’s “Code of Professional Ethics” (Exhibit 1‐7 of text). The key area related to Segato’s current dilemma is integrity. Segato should refuse to book the $240,000 of sales until the goods are shipped. Both financial accounting and management accounting principles maintain that sales are not complete until the title is transferred to the buyer. The job of the accountant is to report in a way that reflects the economic reality of what has actually happened. Segato should refuse to follow Maloney’s orders. If Maloney persists, the incident should be reported to the corporate controller. Support for line management should be wholehearted, but it never requires unethical conduct.
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1‐28 (30 min.) 1.
2.
Chapter 1
Professional ethics and corporate governance.
Companies with “codes of conduct” frequently have a “supplier clause” that prohibits their employees from accepting “material” (in some cases, any) gifts from suppliers. The motivations include: Integrity/conflict of interest. Suppose Michaels recommends that a Horizon 1‐2‐3 product subsequently be purchased by Mexa. His recommendation could be because he felt he owed Horizon an obligation as his trip to the Cancun conference was fully paid by Horizon. The appearance of a conflict of interest. Even if the Horizon 1‐2‐3 product is the superior one at that time, other suppliers likely will have a different opinion. They may believe the way to sell products to Mexa is via “fully‐ paid junkets to resorts.” Those not wanting to do business this way may down‐play future business activities with Mexa even though Mexa may gain much from such activities. Some executives view the meeting as “suspect” from the start given the Caribbean location and its “rest and recreation” tone. Pros of attending the user meeting include: Able to interact with other current users as well as possible purchasers and obtain their opinions. Able to influence the future product development plans of Horizon in a way that will benefit Mexa. An example is Horizon’s subsequently developing software modules tailored to food‐product companies. Saves Mexa money. Visiting suppliers and their customers typically costs money whereas Horizon is paying for the Cancun conference. Able to learn more about the software products of Horizon. Cons of attending the user meeting include: The ethical issues raised in requirement 1. Negative morale effects on other Mexa employees who do not get to attend the Cancun conference. These employees may reduce their trust and respect for Michaels’ judgment, arguing he has been on a “supplier‐ paid vacation.”
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1‐28 (cont’d) Conditions on attending which Mexa might impose are: • Sizable part of time in Cancun has to be devoted to business rather than recreation. • Decision on which Mexa executive attends is not made by the person who attends (this reduces the appearance of a conflict of interest). • Person attending (Michaels) does not have final say on purchase decision (this reduces the appearance of a conflict of interest). • Mexa executives only go when a new major purchase is being contemplated (to avoid the conference becoming a regular “vacation”). A conference board publication on corporate ethics asked executives about a comparable situation: • 76% said Mexa and Michaels face an ethical consideration in deciding whether to attend. 71% said Michaels should not attend as the payment of expenses is a “gift” within the meaning of a credible corporate ethics policy. 3.
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Pros of having a written code. The Conference Board outlines the following reasons why companies adopt codes of ethics. The reasons are the following: a. Signals commitment of senior management to ethics. b. Promotes public trust in the credibility of the company and its employees. c. Signals the managerial professionalism of its employees. d. Provides guidance to employees as to how difficult problems are to be handled. If the code is adhered to, employees will avoid many actions that are unethical or appear to be unethical. e. Drafting of the policy (and its redrafting in the light of ambiguities) can assist management in anticipating and preparing for ethical issues not yet encountered. Cons of having a written code include: a. Can give appearance that all issues have been covered. Issues not covered may appear to be “acceptable” even when they are not. b. Can constrain the entrepreneurial activities of employees. Forces people to always “behave by the book.” c. Cost of developing code can be “high” if it consumes a lot of employee time.
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1‐29 (40 min.)
Chapter 1
Global company, ethical challenges.
1.
It is clear that bribes are illegal according to domestic laws. It is not clear from the case whether bribes are illegal in Vartan. However, knowledgeable people in global business would attest to the fact that it is virtually impossible to find any country in the world that specifically sanctions bribery. The major point, however, that deserves discussion is: Should ZenTel engage in any unethical activities even if they are not illegal? It is difficult to make a generalization about all shareholders of the company. It is, however, safe to assume that not all shareholders would want to keep their investment in a company that is engaged in unethical and/or illegal activities. There is historical evidence to substantiate this point: When apartheid laws were in effect in South Africa, many investors divested shares of companies doing business in South Africa. Apart from the ethical issues, it should also be noted that bribery can be very costly in some parts of the world. Bribes may not generate revenues sufficient enough to offset their cost.
2.
Apparently Hank thinks that local culture and common practice are one and the same. This, in fact, is not the case. There are many common practices in developing countries that are against the native culture. Specifically, bribery often leads to decisions that are not made on the basis of the merits of the alternative selected. This results in misallocation of meager resources of the developing country. Misallocation of resources has adverse effects on the economy of a country and the living standard of its population. The negative impact is intensified in developing countries because they can least afford the misallocation of resources. As it applies to local common practice, multinational companies make some small allowances but draw a hard line against paying the $1 million “commission”. In 2010, the UK enacted legislation that requires multinational companies to prevent bribery and similar legislation also came into effect in the United States in January 2011 and in Canada in October of the same years.
3.
ZenTel might have an articulated corporate policy against such payments to get the message across that regardless of laws, the top management would not tolerate any bribery payments made by its employees. A strong and consistent message from the top often has a noticeable effect on the corporate culture and employee behaviour.
1‐29 (cont’d) 4.
If this contract is of great importance to ZenTel’s global strategy, it is likely that this kind of issue will come up again as ZenTel expands into very diverse cultures,
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and the company should tackle it head on and make a policy decision against offering bribes. Steve Cheng should discuss the situation with the top management at ZenTel and re‐affirm his goal to get the Vartan contract by legal means. He could seek the help of the Canadian commercial attaché in Vartan to continue a dialogue with Vartan’s deputy minister of communications. He could propose other creative, legal changes to the ZenTel’s bid, even at the cost of reducing the profitability of the current project. Concessions such as training programs, schools, and other public works projects may be legal, get the attention of the Vartan government, and raise ZenTel’s profile both at home and abroad. In the worst case, if the Vartan government does not agree to any of the creative, legal “extras” that ZenTel can provide in order to win the contract, Cheng should report this to ZenTel’s management and be willing to walk away from the Vartan project.
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CHAPTER 2 AN INTRODUCTION TO COST TERMS AND PURPOSES
SHORT‐ANSWER QUESTIONS 2‐1 A cost object is anything for which a separate measurement of costs is desired. Examples include a product, a service, a project, a customer, a brand category, an activity, a department, and a program. 2‐2 Direct costs of a cost object are related directly to the particular cost object and can be traced to it in an economically feasible way. Indirect costs of a cost object are costs that arise from common costs shared among distinct types of cost objects and cannot be traced to each type of cost object in an economically feasible way. 2‐3 When direct costs are traced to a particular cost object the resources used are unique to the distinct type of cost object and can be accurately assigned to it. When costs of resources shared unequally among distinct types of cost objects are allocated, managers are less certain whether the cost allocation base, a measure of direct resources consumed, accurately measures the benefit or value added to the distinct type of cost object from its share of common resources consumed. Managers prefer to use more accurate costs in their decisions.
2‐4 1. 2. 3. 4.
Factors affecting the classification of a cost as direct or indirect include: the materiality of the cost in question available information‐gathering technology design of operations the type of costing system in use
2‐5
A cost driver is a variable, such as either the level of activity or volume of direct resources used, that causes a change in total cost, measured throughout a specific time. A change in the quantity of a cost driver used results in a change in the level of total costs. For example, the number of tires per vehicle is a driver of the total cost of tires for each vehicle.
2‐6
The relevant range is the range over which the changes in the quantity of the cost driver used has a causal relationship with changes in total cost. Relevant range is important to accurately define cost behaviour as a linear cost function. Linear cost functions are applied when examining cost‐volume‐profit (CVP) relationships as long as the volume levels are within the relevant range.
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2‐7
The usefulness of a unit cost or rate per unit of resource used depends on whether the causal relationship is true, for example with fully variable costs. The rate per unit for variable costs is computed by dividing some total cost of the resource used (the numerator) by a corresponding quantity of units of a resource used (the denominator). But when total cost is fully or partially fixed it is wrong to use a constant rate per unit. There is no direct causal relationship between a fixed cost which is constant, and any quantity of any cost object, either input or output. The fixed cost in the numerator is unchanged but the fixed cost rate will vary as the denominator quantity changes. 2‐8 Manufacturing companies purchase materials and components and convert them into various finished goods, for example pharmaceutical, automotive and textile companies. Merchandising‐sector companies purchase and then sell tangible products without changing their basic form, for example retailing or distribution companies. Service‐sector companies produce and provide services or intangible products to their customers, for example, engineering design, legal advice and audits. 2‐9 Manufacturing companies typically have one or more of the following three types of inventory: 1. Direct materials inventory. Direct materials on site and awaiting use in the production process. 2. Work‐in‐process inventory. Goods partially converted from direct materials to goods available for sale, but not yet finished. Also called work in progress (WIP). 3. Finished goods inventory. Goods completed and available for sale but not yet sold. 2‐10 No. Service sector companies have no inventories and, hence, no inventoriable costs.
2‐11 Overtime premium is the wage rate paid to workers (for both direct labour and indirect labour) in excess of their straight‐time wage rates. Idle time is a sub‐classification of indirect labour that represents wages paid for unproductive time caused by lack of orders, machine breakdowns, material shortages, poor scheduling, and the like.
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Chapter 2
2‐12 Either a product or a service cost is the sum of the costs assigned to it for a specific purpose. Purposes for computing a product cost include: Pricing and product mix decisions, which should include the costs of all value‐ chain functions Contracting with government agencies, which will be defined by a contract and may include only total costs of the production business function in the value chain Preparing GAAP‐compliant financial statements for external reporting which will be defined by a contract and because there is no inventory for the service, will exclude all inventoriable costs 2‐13 Financial accountants classify the actual or historical costs of business transactions during a specific time period in a standardized way. The costs are accumulated for only transactions in a specific classification in general ledger accounts. Management accountants are free to reclassify the reliable costs in general ledger accounts by distinguishing and including only those costs that are relevant to identifying and solving a specific cost‐management problem.
EXERCISES
2‐14 (10 min.) 1. 2. 3. 4. 5. 6. 7. 8.
Terminology.
Conversion costs fixed cost Inventoriable costs Prime costs Period costs variable cost Indirect Relevant cost
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2‐15 (15 min.) 1.
2.
3.
4.
5.
6.
7. 8.
Inventoriable costs versus period costs. Spring water purchased for resale by Sobeys—inventoriable cost of a merchandising company. It becomes part of cost of goods sold when the mineral water is sold. Electricity used at a Toyota assembly plant—inventoriable cost of a manufacturing company. It is part of the manufacturing overhead that is included in the manufacturing cost of a truck finished good. Amortization on Google’s computer equipment—period cost of a service company. Google has no inventory of goods for sale and, hence, no inventoriable cost. Electricity for Sobeys store aisles—period cost of a merchandising company. It is a cost that benefits the current period and is not traceable to goods purchased for resale. Amortization on Toyota’s assembly testing equipment—inventoriable cost of a manufacturing company. It is part of the manufacturing overhead that is included in the manufacturing cost of truck finished good. Salaries of Sobeys marketing personnel—period cost of a merchandising company. It is a cost that is not traceable to goods purchased for resale. It is presumed not to benefit future periods (or at least not to have sufficiently reliable evidence to estimate such future benefits). Water consumed by Google’s engineers—period cost of a service company. Google has no inventory of goods for sale and, hence, no inventoriable cost. Salaries of Google’s marketing personnel—period cost of a service company. Google has no inventory of goods for sale and, hence, no inventoriable cost.
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Chapter 2
2‐16 (15–20 min.) Classification of costs, service sector. Cost object: Each individual focus group Cost variability: With respect to the number of focus groups There may be some debate over classifications of individual items, especially with regard to cost variability. Cost Item D or I V or F A D V B I F C I Va D I F E D V F I F G D V H I Vb a Some students will note that phone call costs are variable when each call has a separate charge. It may be a fixed cost if Consumer Focus has a flat monthly charge for a line, irrespective of the amount of usage. b Gasoline costs are likely to vary with the number of focus groups. However, vehicles likely serve multiple purposes, and detailed records may be required to examine how costs vary with changes in one of the many purposes served. 2‐17 (15‐20 min.) Classification of costs, merchandising sector. Cost object: DVD section of store Cost variability: With respect to changes in the number of DVDs sold There may be some debate over classifications of individual items. Debate about cost variability is more likely. Cost Item D or I V or F A D F B I V C D V D I F E I F F I V or F G I F H D V
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2‐18 (15‐20 min.) Classification of costs, manufacturing sector. Cost object: Type of car assembled (Corolla or Geo Prism) Cost variability: With respect to changes in the number of cars assembled There may be some debate over classifications of individual items. Debate about cost variability is more likely. Cost Item D or I V or F A D V B I F C D F D D F E D V F I V G D V H I F 2‐19 (10 min.) Variable costs, fixed costs, total costs. Plan A: 100 minutes × $0.08 = $8.00 300 minutes × $0.08 = $24.00 500 minutes × $0.08 = $40.00 Plan B: 100 minutes = $16.00 300 minutes = $16.00 500 minutes = $16.00 + $10.00 (200 minutes × $0.05) = $26.00 Plan C: 100 minutes = $20.00 300 minutes = $20.00 500 minutes = $20.00 + $0.80 (20 minutes × $0.04) = $20.80 If Compo plans to make 100 minutes of long‐distance calls each month, she should choose Plan A; for 300 minutes, choose Plan B; for 500 minutes, choose Plan C.
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Chapter 2
2‐20 (10 min.) 1. 2. 3.
Total costs and unit costs.
Total cost, $4,800. Unit cost per person, $4,800 ÷ 500 = $9.60 Total cost, $4,800. Unit cost per person, $4,800 ÷ 2,000 = $2.40 The main lesson of this problem is to alert the student early in the course to the desirability of thinking in terms of total costs rather than unit costs wherever feasible. Changes in the number of cost driver units will affect total variable costs but not total fixed costs. In our example, it would be perilous to use either the $9.60 or the $2.40 unit cost to predict the total cost because the total costs are not affected by the attendance. Instead, the student association should use the $4,800 total cost. Obviously, if the musical group agreed to work for, say $4.80 per person, such a unit variable cost could be used to predict the total cost.
2‐21 (15 min.)
Total and unit costs, decision making.
1.
The variable cost is $1 per flange for materials, and $2 per flange ($20 per hour divided by 10 flanges per hour) for direct manufacturing labour.
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2‐21 (cont’d) .
2.
2–26
The inventoriable (manufacturing) cost per unit for 5,000 flanges is $3 × 5,000 + $20,000 = $35,000. Average (unit) cost = $35,000 ÷ 5,000 units = $7 per unit. This is below Fred’s selling price of $8.25 per flange. However, in order to make a profit, Graham’s Glassworks also needs to cover the period (non‐ manufacturing) costs of $10,000, or $10,000 ÷ 5,000 = $2 per unit. Thus, total costs, both inventoriable (manufacturing) and period (non‐ manufacturing), for the flanges is $7 + $2 = $9. Graham’s Glassworks cannot sell below Fred’s price of $8.25 and still make a profit on the flanges. Alternatively, At Fred’s price of $8.25 per flange: Revenue $8.25 × 5,000 = $41,250 Variable costs $3.00 × 5,000 = 15,000 Fixed costs 30,000 Operating loss $(3,750) Graham’s Glassworks cannot sell below $8.25 per flange and make a profit. At Fred’s price of $8.25 per flange, the company has an operating loss of $3,750. If Graham’s Glassworks produces 10,000 units, the total inventoriable cost will be: $3 × 10,000 + $20,000 = $50,000. Average (unit) inventoriable (manufacturing) cost will be $50,000 ÷ 10,000 units = $5 per flange Unit total cost including both inventoriable and period costs will be ($50,000 + $10,000) ÷ 10,000 = $6 per flange, and Graham’s Glassworks will be able to sell the flanges for less than Fred and still make a profit. Alternatively, At Fred’s price of $8.25 per flange: Revenue $8.25 × 10,000 = $82,500 Variable costs $3.00 × 10,000 = 30,000 Fixed costs 30,000 Operating income $22,500 Copyright © 2013 Pearson Canada Inc.
Chapter 2
2‐21 (cont’d)
Graham’s Glassworks can sell at a price below $8.25 per flange and still make a profit. The company earns operating income of $22,500 at a price of $8.25 per flange. The company will earn operating income as long as the price exceeds $6.00 per flange. The reason the unit cost decreases significantly is that inventoriable (manufacturing) fixed costs and fixed period (nonmanufacturing) costs remain the same regardless of the number of units produced. So, as Graham’s Glassworks produces more units, fixed costs are spread over more units, and cost per unit decreases. This means that if you use unit costs to make decisions about pricing, and which product to produce, you must be aware that the unit cost only applies to a particular level of output.
2‐22 (20 min.) 1.
Computing and interpreting manufacturing unit costs.
(in millions) Supreme Direct materials cost $ 84.00 Direct manuf. labour costs 14.00 Indirect manuf. costs 42.00 Total manuf. costs $140.00 Fixed costs allocated at a rate of $20M $50M (direct mfg. labour) equal to $0.40 per dir. manuf. labour dollar (0.40 $14; 28; 8) 5.60 Variable costs $134.40 Kgs produced (millions) 80 Cost per kg (Total manuf. costs ÷ kgs produced) $1.7500 Variable manuf. cost per kg: (Variable manuf. costs kgs produced) $1.6800
Deluxe $ 54.00 28.00 84.00 $166.00
Regular $ 62.00 8.00 24.00 $ 94.00
Total $200.00 50.00 150.00 $400.00
11.20 $154.80 120
3.20 $ 90.80 100
20.00 $380.00
$1.3833
$0.9400
$1.2900
$0.9080
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2‐22 (cont’d) 2.
(in millions) Supreme Based on total manuf. cost per kg ($1.75 120; $1.3833 160; $0.94 180) $210.00 Correct total manuf. costs based on variable manuf. costs plus fixed costs equal Variable costs ($1.68 120; $201.60 $1.29 160; $0.908 180) Fixed costs Total costs
Deluxe
Regular
Total
$221.33
$169.20
$600.53
$206.40
$163.44
$571.44
20.00 $591.44
The total manufacturing cost per unit in requirement 1 includes $20 million of indirect manufacturing costs that are fixed irrespective of changes in the volume of output per month, while the remaining variable indirect manufacturing costs change with the production volume. Given the kilogram volume changes for June 2012, the use of total manufacturing cost per kg from the past month at a different kg volume level (both in aggregate and at the individual product level) will yield incorrect estimates of total costs of $600.53 million in June 2012 relative to the correct total manufacturing costs of $591.44 million calculated using variable manufacturing cost per kg times units produced plus the fixed costs of $20 million.
2‐23 (15–20 min.) Variable costs and fixed costs. 1.
Variable cost per tonne of beach sand mined Subcontractor $ 80 per tonne Government tax 50 per tonne Total $130 per tonne Fixed costs per month 0 to 100 tonnes of capacity per day 101 to 200 tonnes of capacity per day 201 to 300 tonnes of capacity per day
= $150,000 = $300,000 = $450,000
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2‐23 (cont’d) 2. $450,000 Costs $300,000
$650,000
Tota l Fixed
Tota l Va riable C osts
$975,000
$325,000
2,500
5,000
$150,000
100
7,500
200
300
Tons of Cap acity p er Day
Tons Mine d
The concept of relevant range is potentially relevant for both graphs. However, the question does not place restrictions on the unit variable costs. The relevant range for the total fixed costs is from 0 to 100 tonnes; 101 to 200 tonnes; 201 to 300 tonnes, and so on. Within these ranges, the total fixed costs do not change in total. 3. Tonnes Tonnes Mined Mined per Day per Month (1) (2) = (1) × 25 (a) 180 4,500
Fixed Unit Cost per Tonne (3) = FC ÷ (2) $300,000 ÷ 4,500 = $66.67
(b) 220
$450,000 ÷ 5,500 = $81.82
5,500
Variable Unit Total Unit Cost per Cost per Tonne Tonne (4) (5) = (3) + (4) $130 $196.67 $130
$211.82
The unit cost for 220 tonnes mined per day is $211.82, while for 180 tonnes it is only $196.67. This difference is caused by the fixed cost increment from 101 to 200 tonnes being spread over an increment of 80 tonnes, while the fixed cost increment from 201 to 300 tonnes is spread over an increment of only 20 tonnes.
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2‐24 (20 min.) 1.
2.
3.
Variable costs, fixed costs, relevant range.
Since the production capacity is 4,000 jaw breakers per month, the current annual relevant range of output is 0 to 48,000 jaw breakers (4,000 jaw breakers × 12 months). Current annual fixed manufacturing costs within the relevant range are $1,000 × 12 = $12,000 for rent and other overhead costs, plus $6,000 ÷ 10 = $600 for depreciation, totaling $12,600. The variable costs, the materials, are 10 cents per jaw breaker, or $3,600 ($0.10 per jaw breaker × 3,000 jaw breakers per month × 12 months) for the year. If demand changes from 3,000 to 6,000, Yumball will need a second machine. Assuming Yumball buys a second machine identical to the first machine, it will increase capacity from 4,000 jaw breakers per month to 8,000. The annual relevant range will be between 0 and 96,000 jaw breakers (8,000 jaw breakers × 12 months). Assume the second machine costs $6,000 and is depreciated using straight‐ line depreciation over 10 years and zero residual value, just like the first machine. This will add $600 of depreciation per year. Fixed costs for next year will increase to $13,200. Total fixed costs for next year equal $600 (depreciation on first machine) + $600 (depreciation on second machine) + $12,000 (rent and other fixed overhead costs). The variable cost per jaw breaker next year will be 90% × $0.10 = $0.09. Total variable costs equal $0.09 per jaw breaker × 72,000 jaw breakers = $6,480.
2‐25 (20 min.) 1.
2–30
Unit costs for making decisions
(a) $120,000 ÷ 2,000 = $60.00 per package (b) $120,000 ÷ 6,000 = $20.00 per package (c) $120,000 ÷ 10,000 = $12.00 per package (d) [$120,000 + (10,000 × $9.60)] ÷ 20,000 = $216,000 ÷ 20,000 = $10.80 per package The unit cost to ECG decreases on a per‐unit basis due to the first $120,000 payment being a fixed cost. The $9.60 amount per package beyond 10,000 units is a variable cost. The cost function is:
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Chapter 2
2‐25 (cont’d)
2.
ECG should not use any of the unit costs in requirement 1 when predicting total costs. Up to 10,000 units, the total cost is a fixed amount. Beyond 10,000 units, the total cost is a combination of a fixed amount plus a per‐unit (beyond 10,000 unit) variable amount. The total costs at different volume levels cannot be predicted by using the unit cost at a specific volume level. The total cost should be predicted by combining the total fixed costs and total variable costs rather than by multiplying a unit cost amount by the predicted number of packages sold.
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2‐26 (20 min.) Computing cost of goods manufactured and cost of goods sold. Schedules: Cost of Goods Manufactured and Cost of Goods Sold Schedule of Cost of Goods Manufactured For the Year Ended December 31, 2013 (in thousands) Direct materials used $104,400 Direct manufacturing labour costs 40,800 Indirect manufacturing costs: $ 3,600 Property tax on plant building Plant utilities 20,400 Amortization of plant building 10,800 Amortization of plant equipment 13,200 Plant repairs and maintenance 19,200 Indirect manufacturing labour costs 27,600 Indirect materials used 13,200 Miscellaneous plant overhead 4,800 112,800 Manufacturing costs incurred during 2013 258,000 Add beginning work in process inventory, Jan. 1, 2013 24,000 Total manufacturing costs to account for 282,000 Deduct ending work in process inventory, Dec. 31, 2013 31,200 Cost of goods manufactured $250,800 Schedule of Cost of Goods Sold For the Year Ended December 31, 2013 (in thousands) Beginning finished goods, Jan. 1, 2013 $ 32,400 Cost of goods manufactured (above) 250,800 Cost of goods available for sale 283,200 Ending finished goods, Dec. 31, 2013 40,800 Cost of goods sold $242,400
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2‐27 (20 min.)
Income statement and schedule of cost of goods manufactured
Howell Corporation Income Statement For the Year Ended December 31, 2013 (in millions) Revenue Cost of goods sold: Beginning finished goods, Jan. 1, 2013 Cost of goods manufactured (below) Cost of goods available for sale Ending finished goods, Dec. 31, 2013 Gross margin Marketing, distribution, and customer‐service costs Operating income Howell Corporation Schedule of Cost of Goods Manufactured For the Year Ended December 31, 2013 (in millions) Direct materials costs: Beginning inventory, Jan. 1, 2013 Purchases of direct materials Cost of direct materials available for use Ending inventory, Dec. 31, 2013 Direct materials used Direct manufacturing labour costs Indirect manufacturing costs: Indirect manufacturing labour Plant supplies used Plant utilities Amortization—plant, building, and equipment Plant supervisory salaries Miscellaneous plant overhead Manufacturing costs incurred during 2013 Add beginning work in process inventory, Jan. 1, 2013 Total manufacturing costs to account for Deduct ending work in process, Dec. 31, 2013 Cost of goods manufactured
. $ 84 774 858 66
$1,140 792 348 288 $ 60
$ 18 390 408 24
$384 120 72 12 36 96 6 42
264 768 12 780 6 $774
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2‐28 (20‐25 min.) Computing cost of goods manufactured and cost of goods sold. Schedule of Cost of Goods Manufactured For the Year Ended December 31, 2013 (in thousands) Direct materials used Direct manufacturing labour costs Indirect manufacturing costs: Property tax on plant building $ 4,200 Plant utilities 20,400 14,700 Amortization of plant building Amortization of plant equipment 14,700 Plant repairs and maintenance 19,200 Indirect manufacturing labour costs 27,600 Indirect materials used 12,200 Miscellaneous plant overhead 5,200 Manufacturing costs incurred during 2013 Add beginning work‐in‐process inventory, Jan. 1, 2013 Total manufacturing costs to account for Deduct ending work‐in‐process inventory, Dec. 31, 2013 Cost of goods manufactured Schedule of Cost of Goods Sold For the Year Ended December 31, 2013 (in thousands) Beginning finished goods, Jan. 1, 2013 $ 37,400 Cost of goods manufactured (above) 256,200 Cost of goods available for sale 293,600 Ending finished goods, Dec. 31, 2013 44,800 Cost of goods sold $248,800
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$ 106,800 38,400
118,200 263,400 25,000 288,400 32,200 $256,200
Chapter 2
2‐29 (20 min.) (a)
Computing cost of goods purchased and cost of sales.
Marvin Department Store Schedule of Cost of Goods Purchased For the Year Ended December 31, 2013 (in thousands)
Purchases Add transportation‐in Deduct: Purchase return and allowances $4,000 Purchase discounts 6,000 Cost of goods purchased (b) Marvin Department Store Schedule of Cost Sales For the Year Ended December 31, 2013 (in thousands) Beginning merchandise inventory, Jan. 1, 2013 Cost of goods purchased (above) Cost of goods available for sale Ending merchandise inventory, Dec. 31, 2013 Cost of sales
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$155,000 7,000 162,000
10,000 $152,000
$ 27,000 152,000 179,000 34,000 $145,000
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2‐30 (10–15 min.) Cost drivers and functions. 1. 2.
2–36
Function Representative Cost Driver 1. Accounting Number of transactions processed 2. Human Resources Number of employees 3. Data processing Hours of computer processing unit (CPU) 4. Research and development Number of research scientists 5. Purchasing Number of purchase orders 6. Distribution Number of deliveries made 7. Billing Number of invoices sent
Function Representative Cost Driver 1. Accounting Number of journal entries made 2. Human Resources Salaries and wages of employees 3. Data Processing Number of computer transactions 4. Research and Development Number of new products being developed 5. Purchasing Number of different types of materials purchased 6. Distribution Distance traveled to make deliveries 7. Billing Number of credit sales transactions
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Chapter 2
PROBLEMS
2‐31 (20 min.) 1.
2.
Labour cost, overtime, and idle time.
(a) Total cost of hours worked at regular rates 42 hours × 12 per hour 42 hours × 12 per hour 43 hours × 12 per hour 40 hours × 12 per hour Minus idle time (5.2 hours × $12 per hour) Direct manufacturing labour costs (b) Idle time = 5.2 hours × 12 per hour = (c) Overtime and holiday premium. Week 1: Overtime (42–40) hours × Premium, $6 per hour Week 2: Overtime (42–40) hours × Premium, $6 per hour Week 3: Overtime (43–40) hours × Premium, $6 per hour Week 4: Holiday 8 hours × Premium, $12 per hour Total overtime and holiday premium (d) Total earnings in May Direct manufacturing labour costs Idle time Overtime and holiday premium Total earnings
$ 504.00 504.00 516.00 480.00 2,004.00 62.40 $1,941.60 $62.40
$ 12.00 12.00 18.00 96.00 $138.00 $1,941.60 62.40 138.00 $2,142.00
Idle time caused by equipment breakdowns and scheduling mix‐ups is an indirect cost of the jobs because it is not related to a specific job. Overtime premium caused by the heavy overall volume of work is also an indirect cost because it is not related to a particular job that happened to be worked on during the overtime hours. If, however, the overtime is the result of a demanding “rush job,” the overtime premium is a direct cost of that job.
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2‐32 (30 min.)
Direct costs versus indirect costs
1. Revenue Direct materials Direct manuf. labour Indirect manufacturing Total manuf. costs Gross margin Gross margin percentage 2.
Westec $504 300 48 96
La Electricidad $984 492 120 240
BBC $576 324 72 144
444 $ 60 11.9%
852 $132 13.4%
540 $ 36 6.3%
The BBC job is the only one with overtime charges. The charge is $24 (2 hours × $12 per hour overtime rate). The exclusion of this $24 from direct manufacturing labour costs will also affect indirect manufacturing labour costs allocated (at the 200% rate) to the BBC job. The revised gross margin is:
Revenue Direct materials Direct manuf, labour Indirect manufacturing Total manuf, costs Gross margin Gross margin percentage
BBC $ 576 324 48 96 468 $ 108 18.8%
3.
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The sizable increase in gross margin for BBC is due to $72 of costs being excluded— the $24 of overtime premium plus the $48 of indirect manufacturing costs allocated using the 200% rate. The main pro of charging BBC the $36 per hour labour rate is that this is the actual labour cost. The BBC job was, in fact, done in overtime hours. The main con is that it penalizes the BBC job for a factor unrelated to its manufacture. The job was brought in one week ago, and there was much flexibility when it could be scheduled. It was done in overtime due to the Westec job being a rushed one. Copyright © 2013 Pearson Canada Inc.
Chapter 2
2‐32 (cont’d) A preferable approach is to assign all jobs with no special “rush” requirements the same labour cost per hour. This means that differences in job scheduling will not affect job profitability. Jobs that have a “rush” requirement (“hot‐hot”) are given an extra expediting cost to reflect any additional costs the expedition requires. 4.
The incentive payments would be: 5% of Revenue Westec 0.05 × $504 La Electricidad 0.05 × 984 BBC 0.05 × 576
Incentive $ 25.20 49.20 28.80 $103.20
Incentive 20% of Gross Margin Westec 0.20 × $60 $12.00 La Electricidad 0.20 × 132 26.40 BBC 0.20 × 108* 21.60 $ 60.00 *Assumes that OT is not material, so the 200% indirect cost allocation rate will remain. Alternatively, calculate BBC (0.20 × $36 = $7.20)
EMI prefers jobs that produce high gross margins rather than high gross revenue. The 20% incentive better aligns the sales representative’s incentive with that of EMI. EMI should define how revenue and costs are to be measured so that ambiguities are reduced. The revenue and cost rules should be known in advance. If a rushed job is requested by a customer, the salesperson should know the rush‐job charge so that he or she knows the consequences of accepting the request. A fairer incentive for the salespeople would be 5% of revenue, minus a penalty for any discounts given to the customer in order to gain or win the contract. Too large a percentage of the Gross Margin is attributed in measurement to the performance of the manufacturing and purchasing groups. The salespeople should not be penalized for deficiencies in the other groups.
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2‐33 (30 min.) 1.
2.
Comprehensive problem on unit costs, product costs.
If 2 kilograms of direct materials are used to make each unit of finished product, 100,000 units 2 kg, or 200,000 kg, were used at $0.70 per kilogram of direct materials ($140,000 ÷ 200,000 kg). (The direct material costs of $140,000 are direct materials used, not purchased.) Therefore, the ending inventory of direct materials is 2,000 kg $0.70 = $1,400 Direct materials costs Direct manufacturing labour costs Plant energy costs Indirect manufacturing labour costs Other indirect manufacturing costs Cost of goods manufactured Average unit manufacturing cost: Finished goods inventory in units:
3. 4.
2–40
Manufacturing Costs for 100,000 units Variable Fixed Total $140,000 $ – $140,000 30,000 – 30,000 5,000 – 5,000 10,000 16,000 26,000 8,000 24,000 32,000 $193,000 $40,000 $233,000 $233,000 ÷ 100,000 units = $2.33 per unit $20,970 (given) ÷ $2.33 per unit = 9,000 units
Units sold in 2013 = Beginning inventory + Production – Ending inventory = 0 + 100,000 – 9,000 = 91,000 units Selling price per unit in 2013: $436,800 ÷ 91,000 = $4.80 per unit
Revenue (91,000 units sold $4.80) Cost of units sold: Beginning finished goods, Jan. 1, 2013 Cost of goods manufactured Cost of goods available for sale Ending finished goods, Dec. 31, 2013 Gross margin Operating costs: Marketing, distribution, and customer‐service costs Administrative costs Operating income
$436,800
$ 0 233,000 233,000 20,970
212,030 224,770
162,850 50,000
212,850 $ 11,920
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Chapter 2
2‐33 (cont’d) Note: Although not required, the full set of unit variable costs are:
Direct materials costs Direct manufacturing labour costs Plant energy costs Indirect manufacturing labour costs Other indirect manufacturing costs Marketing, distribution, and customer‐service costs
$1.40
0.30 0.05
= $1.93 per unit manuf’d (100,000)
0.10 0.08 1.35
} per unit sold (91,000)
2‐34 (30 min.) 1.
2.
Budgeted income statement.
Target ending finished goods, Dec. 31, 2014 Forecasted sales for 2014 Total finished goods required in 2014 Beginning finished goods, Jan. 1, 2014 Finished goods production required in 2014 Revenue (122,000 units sold $4.80) Cost of units sold: Beginning finished goods, Jan. 1, 2014 Cost of goods manufactured Cost of goods available for sale Ending finished goods, Dec. 31, 2014 Gross margin Operating costs: Marketing, distn., and customer‐service costs Administrative costs Operating income $ 55,680b
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12,000 units 122,000 units 134,000 units 9,000 units 125,000 units $585,600
$ 20,970b 281,250a 302,220b 27,000c
275,220b 310,380b
204,700b 50,000b
254,700d
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2-34 (cont’d) Supporting Computations a) b) c)
Manufacturing Costs for 125,000 Units Variable Fixed Total b Direct materials costs $175,000 $ – $175,000 b Direct manufacturing labour costs 37,500 – 37,500 Plant energy costs 6,250 – 6,250 Indirect manufacturing labour costs 12,500b 16,000 28,500 Other indirect manufacturing costs 10,000b 24,000 34,000 b Cost of goods manufactured $241,250 $40,000 $281,250 Direct materials costs = 250,000 kg $0.70 per kg = $175,000. The average unit manufacturing costs in 2010 is $281,250 ÷ 125,000 units = $2.25. Finished goods, December 31, 2010 = 12,000 $2.25 = $27,000. d) Variable mktg., distn., and customer‐service costs, 122,000 $1.35 $164,700 Fixed marketing, distribution., and customer‐service costs 40,000 Fixed administrative costs 50,000 $254,700
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Chapter 2
2‐35 (30‐40 min.) Cost of goods manufactured. 1.
2.
Canseco Company Schedule of Cost of Goods Manufactured For the Year Ended December 31, 2013 (in thousands) Direct materials costs: Beginning inventory, Jan. 1, 2013 $22,000 Purchases of direct materials 75,000 Cost of direct materials available for use 97,000 Ending inventory, Dec. 31, 2013 26,000 Direct materials used Direct manufacturing labour costs Indirect manufacturing costs: Indirect manufacturing labour costs $15,000 Plant insurance 9,000 Amortization—plant building and equipment 11,000 Repairs and maintenance—plant 4,000 Manufacturing costs incurred during 2013 Add beginning work in process inventory, Jan. 1, 2013 Total manufacturing costs to account for Deduct ending work in process inventory, Dec. 31, 2013 Cost of goods manufactured
$71,000 25,000
39,000 135,000 21,000 156,000 20,000 $136,000
Canseco Company Income Statement For the Year Ended December 31, 2013 (in thousands)
Revenue Cost of goods sold: Beginning finished goods, Jan. 1, 2013 Cost of goods manufactured (Requirement 1) Cost of goods available for sale Ending finished goods, Dec. 31, 2013 Gross margin Operating costs: Marketing, distribution, and customer‐service General and administrative Operating income
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$300,000
$ 18,000 136,000 154,000 23,000
131,000 $169,000
$ 93,000 29,000
122,000 $ 47,000
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2‐36 (30 min.) 1. 2. 3. 4. 5. 6.
2–44
Flow of inventoriable costs.
Direct materials inventory, Aug. 1, 2013 Direct materials purchased Direct materials available Deduct direct materials used Direct materials inventory, Aug. 31, 2013
(in millions) $ 90 360 450 375 $ 75
Total manufacturing overhead costs Subtract: Variable manufacturing overhead costs Fixed manufacturing overhead costs
$ 480 250 $ 230
Total manufacturing costs Deduct: Direct materials used Manufacturing overhead Direct manufacturing labour costs
$1,600
$375 480
855 $ 745
Work‐in‐Process inventory, Aug. 1, 2013 Total manufacturing costs Deduct cost of goods manufactured (moved into FG) Work‐in‐Process inventory Aug. 31, 2013
$ 200 1,600 1,800 1,650 $ 150
Finished goods inventory Aug. 1, 2013 Cost of goods manufactured (moved from WIP) Goods available for sale
$ 125 1,650 $1,775
Goods available for sale in August (from req. 5) Deduct cost of goods sold Finished goods inventory, Aug. 31, 2013
$1,775 1,700 $ 75
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Chapter 2
2‐37 (25‐30 min.) Income statement and schedule of cost of goods manufactured. Powell Corporation Income Statement For the Year Ended December 31, 2013 (in millions)
Revenue Cost of goods sold: Beginning finished goods, Jan. 1, 2013 Cost of goods manufactured (below) Cost of goods available for sale Ending finished goods, Dec. 31, 2013 Gross margin Marketing, distribution, and customer‐service costs Operating income Powell Corporation Schedule of Cost of Goods Manufactured For the Year Ended December 31, 2013 (in millions) Direct materials costs: Beginning inventory, Jan. 1, 2013 Purchases of direct materials Cost of direct materials available for use Ending inventory, Dec. 31, 2013 Direct materials used Direct manufacturing labour costs Indirect manufacturing costs: Indirect manufacturing labour Plant supplies used Plant utilities Amortization—plant, building, and equipment Plant supervisory salaries Miscellaneous plant overhead Manufacturing costs incurred during 2013 Add beginning work in process inventory, Jan. 1, 2013 Total manufacturing costs to account for Deduct ending work in process, Dec. 31, 2013 Cost of goods manufactured
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$1,140
$ 70 762 832 55
777 363 288 $ 75
$ 15 390 405 20
$385 120
60 12 36 96 6 42
252 757 10 767 5 $762
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
2‐38 (15‐20 min.) Interpretation of statements. 1.
2.
3.
4. 5.
6.
2–46
The schedule of costs of goods manufactured in 2‐37 can become a Schedule of Cost of Goods Manufactured and Sold simply by including the beginning and ending finished goods inventory figures in the supporting schedule, rather than directly in the body of the income statement. Note that the term cost of goods manufactured refers to the cost of goods brought to completion (finished) during the accounting period, whether they were started before or during the current accounting period. Some of the manufacturing costs incurred are held back as costs of the ending work in process; similarly, the costs of the beginning work in process inventory become a part of the cost of goods manufactured for 2013. The sales manager’s salary would be charged as a marketing cost as incurred by both manufacturing and merchandising companies. It is basically an operating cost that appears below the gross margin line on an income statement. In contrast, an assembler’s wages would be assigned to the products worked on. Thus, the wages cost would be charged to Work in Process and would not be expensed until the product is transferred through Finished Goods Inventory to Cost of Goods Sold as the product is sold. The direct–indirect distinction can be resolved only with respect to a particular cost object. For example, in defense contracting, the cost object may be defined as a contract. Then, a plant supervisor’s salary may be charged directly and wholly to that single contract. Direct materials used Amortization
= $385,000,000 ÷ 1,000,000 units = $385 per unit = $ 96,000,000 ÷ 1,000,000 units = $96 per unit
Direct materials unit cost would be unchanged at $385. Amortization unit cost would be $96,000,000 ÷ 1,200,000 = $80 per unit. Total direct materials costs would rise by 20% to $462,000,000 ($385 per unit × 1,200,000 units), whereas total amortization would be unaffected at $96,000,000. Unit costs are averages, and they must be interpreted with caution. The $385 direct materials unit cost is valid for predicting total costs because direct materials is a variable cost; total direct materials costs indeed change as output levels change. However, fixed costs like amortization must be interpreted quite differently from variable costs. A common error in cost analysis is to regard all unit costs as one— as if all the total costs to which they are related are variable costs. Changes in output levels (the denominator) will affect total variable costs, but not total fixed costs. Graphs of the two costs may clarify this point; it is safer to think in terms of total costs rather than in terms of unit costs. Copyright © 2013 Pearson Canada Inc.
Chapter 2
2‐39 1.
(30 min.)
Prime costs version conversion costs.
Prime costs are: purchases of direct materials; direct manufacturing labour. Conversion costs are: plant utilities; indirect manufacturing labour; amortization— plant, building, and equipment; miscellaneous manufacturing overhead; marketing, distribution, and customer service costs; plant supplies used; property taxes on plant
2. Chan Corporation Income Statement For the Year Ended December 31, 2013 (in millions)
Revenue Cost of goods sold: Beginning finished goods, Jan. 1, 2013 Cost of goods manufactured (below) Cost of goods available for sale Ending finished goods, Dec. 31, 2013 Gross margin Marketing, distribution, and customer‐service costs Operating income
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$420.00
$ 48.00 244.80 292.80 14.40
278.40 141.60 108.00 $ 33.60
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2‐39 (cont’d)
2–48
Chan Corporation Schedule of Cost of Goods Manufactured For the Year Ended December 31, 2013 (in millions) Direct material costs: Beginning inventory, Jan. 1, 2013 $ 36.00 Direct materials purchased 96.00 Cost of direct materials available for use 132.00 Ending inventory, Dec. 31, 2013 6.00 Direct materials used Direct manufacturing labour costs Indirect manufacturing costs: Plant supplies used 7.20 Property taxes on plant 1.20 Plant utilities 6.00 Indirect manufacturing labour costs 24.00 Amortization—plant, building, and equipment 10.80 Miscellaneous manufacturing overhead costs 12.00 Manufacturing costs incurred during 2013 Add beginning work in process inventory, Jan. 1, 2013 Total manufacturing costs to account for Deduct ending work in process inventory, Dec. 31, 2013 Cost of goods manufactured (to income statement)
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$126.00 48.00
61.20 235.20 12.00 247.20 2.40 $244.80
Chapter 2
2‐40 Cost classifications and the income statement. 1.
Foxwood Company Income Statement For the Year Ended December 31, 2013
Revenue Cost of goods sold: Beginning finished goods, Jan. 1, 2013 $ 100,000 Cost of goods manufactured (see below) 960,000 Cost of goods available for sale 1,060,000 Ending finished goods, Dec. 31, 2013 150,000 Gross margin Operating costs: Marketing and promotion $ 60,000 Marketing salaries 100,000 Shipping costs 70,000 Customer‐service costs 100,000 Operating income Foxwood Company Schedule of Cost of Goods Manufactured For the Year Ended December 31, 2013 Direct material costs: Beginning inventory, Jan. 1, 2013 $ 40,000 Direct materials purchased during 2013 460,000 Cost of direct materials available for use 500,000 Ending inventory, Dec. 31, 2013 50,000 Direct materials used Direct manufacturing labour costs Indirect manufacturing costs: Sandpaper 2,000 (V) Materials–handling costs 70,000 (V) Lubricants and coolants 5,000 (V) Miscellaneous indirect manufacturing labour 40,000 (V) Plant leasing costs 54,000 (F) Amortization—plant equipment 36,000 (F) Property taxes on plant equipment 4,000 (F) 3,000 (F) Fire and casualty insurance on plant equipment Manufacturing costs incurred during 2013 Add beginning work in process inventory, Jan. 1, 2013 Total manufacturing costs to account for Deduct ending work in process inventory, Dec. 31, 2013 Cost of goods manufactured (to income statement)
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$1,360,000
910,000 $ 450,000
330,000 $ 120,000
$450,000 (V) 300,000 (V)
214,000 964,000 10,000 974,000 14,000 $960,000
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
2‐40 (cont’d) 2.
3.
4.
5.
Direct materials unit cost = Direct materials used ÷ Units produced = $450,000 ÷ 900,000 = $0.50 Plant leasing unit cost = Plant leasing costs ÷ Units produced = $54,000 ÷ 900,000 = $0.06 The direct materials costs are variable, so they would increase in total from $450,000 to $500,000 (1,000,000 x $0.50). However, their unit costs would be unaffected: $500,000 ÷ 1,000,000 units = $0.50. In contrast, the plant leasing costs of $54,000 are fixed, so they would not increase in total. However, if the plant leasing costs were assigned to units produced, the unit costs would decline from $0.060 to $0.054: $54,000 ÷ 1,000,000 = $0.054. The explanation would begin with the answer to requirement 3. As a consultant, you should stress that the unitizing (averaging) of costs that have different behaviour patterns can be misleading. A common error is to assume that a total unit cost, which is often a sum of variable unit costs and fixed unit costs, is an indicator that total costs change in a wholly variable way as the level of production output changes. You must be especially wary about unit fixed costs. Too often, unit fixed costs are erroneously regarded as being indistinguishable from unit variable costs. DML is 33% ($300,000 ÷ $910,000) of total COGS. This is a material amount based on the normal financial accounting guideline that suggests materiality thresholds of 5% to 10%. Because DML is material it should be classified as a prime rather than a conversion cost. Total conversion costs are $214,000; this is less than the DML. To include DML in the conversion cost would distort the relationship between the contribution to costs made by direct and those made by indirect costs. This would misrepresent the material and efficient causes of the cost of each output unit.
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Chapter 2
2‐41 (10 min.) 1. 2. 3.
Inventory decision, opportunity costs.
Unit cost, orders of 20,000 Unit cost, order of 240,000 (0.96 $9.00)
$9.00 $8.64
Alternatives under consideration: (a) Buy 240,000 units at start of year. (b) Buy 20,000 units at start of each month. Average investment in inventory: (a) (240,000 $8.64) ÷ 2 (b) (20,000 $9.00) ÷ 2 Difference in average investment
$1,036,800 90,000 $ 946,800
Opportunity cost of interest forgone from 240,000‐unit purchase at start of year = $946,800 0.10 = $94,680 No. The $94,680 is an opportunity cost rather than an incremental or outlay cost. No actual transaction records the $94,680 as an entry in the accounting system. The following table presents the two alternatives:
Alternative A: Purchase 240,000 spark plugs at beginning of year (1) Annual purchase‐order costs (1 $200; 12 $200) $ 200 Annual purchase (incremental) costs 2,073,600 (240,000 $8.64; 240,000 $9) Annual interest income that could be earned if investment in inventory were invested (opportunity cost) (10% $1,036,800; 10% $90,000) 103,680 $2,177,480 Relevant costs
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Alternative B: Purchase 20,000 spark plugs at beginning of each month (2) $ 2,400 2,160,000 9,000 $2,171,400
Difference (3) = (1) – (2)
$ (2,200) (86,400) 94,680 $ 6,080
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2‐41 (cont’d) Column (3) indicates that purchasing 20,000 spark plugs at the beginning of each month is preferred relative to purchasing 240,000 spark plugs at the beginning of the year because the opportunity cost of holding larger inventory exceeds the lower purchasing and ordering costs. If other incremental benefits of holding lower inventory such as lower insurance, materials handling, storage, obsolescence, and breakage costs were considered, the costs under Alternative A would have been higher, and Alternative B would be preferred even more.
COLLABORATIVE LEARNING CASES 2‐42 (20‐25 min.) Finding unknown balances. Let G = given, I = inferred CASE 1 Step 1: Use gross margin formula Revenue $32,000 G Cost of goods sold A20,700 I Gross margin $11,300 G Step 2: Use schedule of cost of goods manufactured formula Direct materials used $ 8,000 G Direct manufacturing labour costs 3,000 G Indirect manufacturing costs 7,000 G Manufacturing costs incurred 18,000 I Add beginning work in process, Jan. 1, 2013 0 G Total manufacturing costs to account for 18,000 I Deduct ending work in process, Dec. 31, 2013 0 G Cost of goods manufactured $18,000 I Step 3: Use cost of goods sold formula Beginning finished goods inventory, Jan. 1, 2013 $ 4,000 G Cost of goods manufactured 18,000 I Cost of goods available for sale 22,000 I Ending finished goods inventory, Dec. 31, 2013 B 1,300 I Cost of goods sold $20,700 I
CASE 2 $31,800 20,000 C$11,800
$12,000 5,000 D 6,500 23,500 800 24,300 3,000 $21,300
4,000 21,300 25,300 5,300 $20,000
G G I G G I I G I G I G I I G G
For case 1, do steps 1, 2, and 3 in order. For case 2, do steps 1, 3, and then 2.
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Chapter 2
2‐43 (20‐25 min.) Labour‐cost ethics, governance. 1.
2.
3.
No. The direct manufacturing labour costs are not 20% or greater of total manufacturing costs. Direct manufacturing labour costs are $410,000 which are 16.4% of total manufacturing costs, $410,000 ÷ $2,500,000 = 16.4% Buyoung Kim can ask the controller to reclassify at least two of the costs that are currently reported as indirect manufacturing costs to direct manufacturing labour costs. The most logical are the fringe benefits and some of the overtime costs, particularly if it can be argued that some of the overtime was directly caused by jobs. The fringe benefits are logical because they are not only the largest, but can be argued to be a part of normal cost of manufacturing labour. Fringe benefits related to direct manufacturing labour costs together with some of the overtime premium could bring the total direct manufacturing labour cost over the minimum $500,000. Justification for reclassifying vacation and sick time is similar to that of fringe benefits—that it is a normal cost of labour since it is part of and can be traced to the direct manufacturing labourer’s payment. It is harder to justify reclassifying idle time, since it is difficult to identify a specific job that the idle time relates to. Idle time is also the smallest cost item. The controller should not reclassify overhead costs as direct manufacturing labour costs just so the firm can reap tax benefits particularly if the changes would violate the company’s policy of computing direct manufacturing labour costs. The idea of cost classification is to allow internal (and external) decision making by clarifying what each cost item represents. Also, if costs in only the Costa Melon plant are reclassified, it will be harder for XKY to evaluate the Costa Melon plant, when compared to XKY’s other plants. Nevertheless, some of the arguments presented in requirement 2 can be justified and could prompt a reevaluation of XKY’s direct manufacturing labour classifications.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
2‐44 (30 min.) 1.
2–54
Classifying costs for managerial decisions.
The three factors that Diamond should consider in pricing decisions are: Customers. The major customers (“guests” to Diamond) of the Galaxy are business travellers who predominantly stay on a Sunday‐through‐Thursday basis. Diamond should consider these issues: (a) Will some of the $180/$216‐a‐night customers staying Sunday through Thursday transfer their business to Friday or Saturday for reduced rates? If a sizable number of these customers can transfer their business to Friday or Saturday nights, Diamond should be reluctant to make sizable weekend price discounts. (b) Will a new set of customers be attracted to the Galaxy with a reduced weekend rate, people who would not be attracted at the $180/$216‐a‐night rates? (c) How will seasonality affect the business? Will there be more tourists, and therefore less need for a discount, at certain times of the year? The business customers of Galaxy likely will understand cost‐volume‐profit relationships for hotels and not be offended at different rates for different days of the week. “Off‐peak” pricing is an accepted convention in many industries (such as in telecommunications and airlines). Competitors. Many prestige hotels already offer sizable price discounts on weekends. Moreover, cuts of up to 50% are the nominal price discounts. The additional items included in weekend packages (such as breakfast or a bottle of champagne) add to the effective price discount. Costs. The variable costs of servicing each room are only $24 a night per single occupancy and $26.40 a night per double occupancy. Any room rate above these amounts will make a positive contribution to Galaxy’s operating income. It is an accepted convention that weekend rates at Vancouver’s prestige hotels will be lowered on Friday and Saturday nights. Diamond may want to offer moderate price reductions and add other discounted items in the weekend package. The approach may help maintain the policy of treating guests as “royalty.” A Finnish student commented that hotels in Finland provide customers who have a high volume of business in peak periods with complimentary rooms in the off‐peak period.
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Chapter 2
2.
The customers, competitors, and cost factors that apply to setting the rates for Grey Cup weekend include: Customers. The likely customers can be classified as: (a) long‐term Galaxy hotel customers, and (b) other customers. Charging the market rate (even if it is $360 a night) is not likely to alienate other customers. Diamond’s problem lies with long‐term customers. He may want to offer preferred reservations or “normal” weekday ($180/$216‐a‐night) rates to his regular customers on Grey Cup weekend. Competitors. Several four‐star prestige hotels are already advertising $360 a night rates. Thus, Galaxy will not be viewed as the first to adopt an “aggressive price‐gouging” approach. Hotels often increase their rates because of increased demand even when costs do not increase. It is unlikely that the Galaxy chain would be singled out for negative publicity from such a policy, especially if it made an effort to give preferential bookings and rates to its regular customers. Costs. The variable costs of servicing each room are the same as in the answer to requirement 1. 2‐45 (30 min.) Cost analysis, litigation risk; governance. 1. Reasons for Savage not wanting Nash to include the potential litigation costs include: (a) Genuine belief that the product has no risk of future litigation. Note that she asserts “she has total confidence in her medical research team.” (b) Concern that the uncertainties about litigation are sufficiently high to make any numerical estimate “meaningless.” (c) Concern that inclusion of future litigation costs would cause the board of directors to vote against the project. Savage may be “overly committed” to the project and wants to avoid showing information that prompts questions she prefers not be raised. (d) Avoid “smoking gun” memos being included in the project evaluation file. Savage may believe that if subsequent litigation occurs, the plaintiffs will “inappropriately” use a litigation cost line item as “proof” FY “knew the product had health problems” that were known to management at the outset.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
2‐45 (cont’d) 2.
3.
Unit cost to FY Physician price Patient’s price FY’s margin Physician’s margin
No litigation $144.00 172.80 432.00 28.80 259.20
With litigation $276.00 331.20 432.00 55.20 100.80
The selling price would be $828 ($276 × 3) to maintain the triple‐the‐cost target The percentage decrease is: 61.11% [(259.20 – 100.80) / 259.20] Since each treatment is planned to cost patients $432, the new selling price of $331.20 will drop the doctors’ margin to only $100.80 from the planned margin of $259.20. This would probably result in the doctors not having much incentive to promote the product. In fact, it may be quite possible that the doctors may not attempt to prescribe the treatment at such low margin because of their own exposure to liability. Nash has already registered his concern to Savage. The difficulty is that Savage asked Nash to not include the possible litigation in his presentation. If there is no record of this presentation, then Nash may have several concerns. (a) He may be accused at a later stage of not anticipating the costs of litigation. If litigation does occur, some people will try to distance themselves from the problems. It may be to Nash’s advantage to have a record of his early concerns. (Although plaintiffs may make Nash’s life very difficult if they get access to Nash’s files.) Nash may want to keep some record of his presentation to Savage. (b) He may be portrayed as not being a “team player” if he continues his objections. Savage may have to silence his concerns if he decides to stay at FY. (c) He may have difficult ethical objections with Savage’s behaviour. If he thinks she is acting unethically, his main options are to speak to her first (at least one time), speak to her supervisor (probably chairman of the company), or, as a final resort, resign.
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Chapter 3
CHAPTER 3 COST‐VOLUME‐PROFIT ANALYSIS
SHORT‐ANSWER QUESTIONS 3‐1 The assumptions underlying CVP analysis are: 1. 2. 3. 4. 5. 6.
Changes in the sales volume and production volume are identical. The ending balances of inventories are zero. All costs are classified as fixed or variable with no mixed costs. All cost behavior is linear within the relevant volume range. The unit selling price, unit variable costs, fixed costs and sales volume are known. Either the product sold or the product mix remains constant although the volume changes. All revenues and costs can be added and compared without taking into account the time value of money.
3‐2
Operating income is total revenues from operations for the accounting period minus total costs from operations: Operating income = Total revenues from operations – Total costs from operations Net income is operating income plus non‐operating revenues (such as interest revenue) minus non‐operating costs (such as interest cost) minus income taxes.
3‐3
CVP certainly is simple, with its assumption of a single revenue driver, a single cost driver, and linear revenue and cost relationships. Whether these assumptions make it simplistic depends on the decision context. In some cases, these assumptions may be sufficiently accurate for CVP to provide useful insights.
3‐4
An increase in the income tax rate does not affect the breakeven point. Operating income at the breakeven point is zero and thus no income taxes will be paid at this point.
3‐5
Sensitivity analysis is a “what‐if” technique that examines how a result will change if the original predicted data are not achieved or if an underlying assumption changes. The advent of spreadsheet software has greatly increased the ability to explore the effect of alternative assumptions at minimal cost. CVP is one of the most widely used software applications in the management accounting area.
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3‐6
Examples include: • Manufacturing—substituting a robotic machine for hourly wage workers. • Marketing—changing a sales force compensation plan from a percentage of sales dollars to a fixed salary. • Customer service—hiring a subcontractor to do customer repair visits on an annual retainer basis rather than a per visit basis.
3‐7
Examples include: • Manufacturing—subcontracting a component to a supplier on a per unit basis to avoid purchasing a machine with a high fixed amortization cost. • Marketing—changing a sales compensation plan from a fixed salary to a percentage of sales dollars basis. • Customer service—hiring a subcontractor to do customer service on a per visit basis rather than an annual retainer basis.
3‐8
Operating leverage describes the effects that fixed costs have on changes in operating income as changes occur in units sold and hence in contribution margin. Knowing the degree of operating leverage at a given level of sales helps managers calculate the effect of fluctuations in sales on operating incomes.
3‐9
A company with multiple products can compute a breakeven point by assuming there is a constant mix of products at different levels of total revenue.
EXERCISES 3‐10 (10 min.) 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 3-58
Terminology
capital intensive Cost‐volume‐profit analysis breakeven point Operating leverage Risk‐loving contribution margin contribution margin percentage gross margin sales mix Risk aversion margin of safety Copyright © 2013 Pearson Canada Inc.
Chapter 3
3‐11 (15 min.)
CVP analysis computations.
Case a b c d Case a: Case b: Case c:
Variable Costs
Fixed Costs
Total Costs
OI
CM (S)
CM%
$3,000 18,500
$2,290
$250
$2,540
$460
$710
23.67%
7,400
1,300
8,700
9,800
11,100
60.00%
$10,600 9,450
7,420
3,200
10,620
(20)
3,180
30.00%
5,670
2,500
8,170
1,280
3,780
40.00%
Revenues
Revenues ‐ Total Costs = Operating Income $3,000 ‐ Total Costs = $460, Total Costs = $2,540 Total Costs = $2,540 = Variable Costs + Fixed Costs $2,540 = $250 + Variable Costs, Variable Costs = $2,290 CM = Revenues – Variable Costs = $3,000 ‐ $2,290 = $710 CM % = CM/Revenues = $710 ÷ $3,000 = 23.67% Total Costs = Variable Costs + Fixed Costs $8,700 = $7,400 + Fixed Costs, Fixed Costs = $1,300 Revenue ‐ Total Costs = OI Revenue ‐ $8,700 = $9,800, Revenue = $18,500 CM = Revenues ‐ Variable Costs = $18,500 ‐ $7,400 = $11,100 CM % = CM/Revenues = $11,100 ÷ $18,500= 60.00%
CM % = CM/Revenues 30% = CM/$10,600, CM = $3,180 CM = Revenues ‐ Variable Costs $3,180 = $10,600 ‐ Variable Costs, Variable Costs = $7,420 Total Costs = Variable Costs + Fixed Costs Total Costs = $7,420 + $3,200 = $10,620 OI = Revenues ‐ Total Costs = $10,600 ‐ $10,620 = ($20) Case d: Total Costs = Variable Costs + Fixed Costs $8,170 = Variable Costs + $2,500, Variable Costs = $5,670 OI = Revenues ‐ Total Costs = $9,450 ‐ $8,170 = $1,280 CM = Revenues ‐ Variable Costs = $9,450 ‐ $5,670 = $3,780 CM % = CM/Revenues = $3,780 ÷ $9,450= 40.00% Copyright © 2013 Pearson Canada Inc.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
3‐12 (15 min.)
CVP analysis computations.
Case
Unit Selling Price
Unit VC
Units Sold
TCM
Fixed Costs
OI
A B
$70 87
$25
20,000
$900,000
$700,000
$200,000
62
15,000
375,000
250,000
125,000
4,500,000
3,600,000
900,000
1,728,000
1,500,000
228,000
C
250
100
30,000
D
150
a. TCM $900,000 Q TFC b. OI $125,000 TCM TCM $375,000 $25 USP c. OI $900,000 TFC TCM $4,500,000 $150 UVC
3-60
78
24,000
= Q (USP ‐ UVC) = Q ($70 ‐ $25) = 20,000 = TCM ‐ OI = $900,000 ‐ $200,000 = $700,000 = TCM ‐ TFC = TCM ‐ $250,000 = $375,000 = = = =
Q (USP ‐ UVC) 15,000 (USP ‐ $62) (USP ‐ $62) $87
= TCM ‐ TFC = $4,500,000 ‐ TFC = $3,600,000 = = = =
Q (USP ‐ UVC) 30,000 ($250 ‐ UVC) $250 ‐ UVC $100
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Chapter 3
3‐12 (cont’d) d.
OI OI OI
TCM $1,728,000 $72 UVC
3‐13 (10 min.) 1a. 1b.
= TCM ‐ TFC = $1,728,000 ‐ $1,500,000 = $228,000 = = = =
Q (USP ‐ UVC) 24,000 ($150 ‐ UVC) $150 ‐ UVC $78
CVP computations.
Sales ($30 per unit × 200,000 units) Variable costs ($25 per unit × 200,000 units) Contribution margin
$6,000,000 5,000,000 $1,000,000
Contribution margin (from above) Fixed costs Operating income
$1,000,000 800,000 $ 200,000
2a. Sales (from above) $6,000,000 Variable costs ($16 per unit × 200,000 units) 3,200,000 Contribution margin $2,800,000 2b. Contribution margin $2,800,000 Fixed costs 2,400,000 Operating income $ 400,000 3. Operating income is expected to increase by $200,000 if Ms. Schoenen’s proposal is accepted. The management would consider other factors before making the final decision. It is likely that product quality would improve as a result of using state of the art equipment. Due to increased automation, probably many workers will have to be laid off. Patel’s management will have to consider the impact of such an action on employee morale. In addition, the proposal increases the company’s fixed costs dramatically. This will increase the company’s operating leverage and risk.
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3‐14 (10 min.)
CVP analysis, income taxes.
1. Monthly fixed costs = $60,000 + $70,000 + $10,000 = $140,000 Contribution margin per unit = $26,000 ‐ $22,000 ‐ $500 = $3,500
Breakeven units per month =
Monthly fixed costs $140,000 = = 40 cars Contribution margin per unit $3,500 per car
2. Tax rate = 40% Target net income = $63,000
Target operating income =
Target net income $63, 000 $63, 000 $105,000 1 - tax rate (1 0.40) 0.60
Quantity of output units Fixed costs + Target operating income $140, 000 $105, 000 70 cars required to be sold = Contribution margin per unit $3,500
3‐15 (10 min.) 1. 2.
CVP analysis, income taxes
Monthly fixed costs = $28,000 + $45,000 + $5,600 + $1,200 = $79,800 CM per unit = $16,000 ‐ $12,200 = $3,800 Breakeven = Monthly Fixed Costs ÷ UCM = $79,800 ÷ $3,800 = 21 mowers OI = Target Net Income ÷ [1 ‐ tax rate] OI = $42,750 ÷ [1 ‐ 0.25] OI = $57,000 Q =
Fixed Costs + Target OI Unit CM
Q = [$79,800 + $57,000] ÷ $3,800 = 36 mowers
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3‐16 (20 min.)
CVP analysis, income taxes.
1. Variable cost percentage is $3.20 $8.00 = 40% Let R = Revenues needed to obtain target net income $105,000 R ‐ 0.40R ‐ $450,000 = 1 0.30 0.60R = $450,000 + $150,000 R = $600,000 0.60 R = $1,000,000 Proof: Revenues $1,000,000 Variable costs (at 40%) 400,000 Contribution margin 600,000 Fixed costs 450,000 Operating income 150,000 Income taxes (at 30%) 45,000 Net income $ 105,000 2.a. Customers needed to earn net income of $105,000: Total revenues Sales check per customer: $1,000,000 $8 = 125,000 customers b. Customers needed to break even: Contribution margin per customer = $8.00 ‐ $3.20 = $4.80 Breakeven number of customers = Fixed costs Contribution margin per customer = $450,000 $4.80 per customer = 93,750 customers 3. Using the shortcut approach: Unit Change in contribution (1 ‐ Tax rate) Change in net income = number of customers margin = (150,000 ‐ 125,000) $4.80 (1 ‐ 0.30) = $120,000 0.7 = $84,000 New net income = $84,000 + $105,000 = $189,000
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3‐16 (cont’d)
The alternative approach is: Revenues, 150,000 $8.00 Variable costs at 40% Contribution margin Fixed costs Operating income Income tax at 30% Net income
$1,200,000 480,000 720,000 450,000 270,000 81,000 $ 189,000
3‐17 (15 min.) Gross margin and contribution margin. 1.
Ticket sales ($20 500 attendees)
$10,000
Variable cost of dinner ($10a 500 attendees)
$5,000
Variable invitations and paperwork ($1b 500)
$500
Contribution margin
4,500
Fixed cost of dinner
Fixed cost of invitations and paperwork Operating profit (loss) a $5,000/500 attendees = $10/attendee b $500/500 attendees = $1/attendee
6,000 2,500
8,500 $ (4,000)
2. Ticket sales ($20 1,000 attendees)
$20,000
Variable cost of dinner ($10a 1,000 attendees)
$10,000
Variable invitations and paperwork ($1b 1,000)
$1,000
Contribution margin
9,000
Fixed cost of dinner
Fixed cost of invitations and paperwork Operating profit (loss) 3-64
6,000 2,500
8,500 $ 500
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Chapter 3
3‐18 (20 min.) 1. 2. 3.
Scholarships, CVP analysis.
Full course load = 30 credits Tuition fees for full course load = 30 credits x $400 = $12,000 Let the number of scholarships be denoted by Q. Then, $600,000 + $12,000Q = $4,500,000 $12,000Q = $4,500,000 ‐ $600,000 $12,000Q = $3,900,000 Q = 325 scholarships Total budget for next year Then, 600,000 + $12,000Q $12,000Q Q
= = = = =
$4,500,000 (1 ‐ 0.20) = $4,500,000 x 0.80 $3,600,000 $3,600,000 $3,600,000 ‐ $600,000 $3,000,000 ÷ $12,000 = 250 scholarships
Let the scholarship award per student per year be denoted by V. Then,
$600,000 + 325V = $3,600,000 325V = $3,600,000 ‐ $600,000 V = $3,000,000 ÷ 325 = $9,230.77
3‐19 (35–40 min.) CVP analysis, changing revenues and costs. 1a.
SP UVC UCM FC
Q =
FC $22,000 = = 489 tickets (rounded up) UCM $45 per ticket
Q =
FC TOI $22,000 $10,000 $32,000 = = = 712 tickets (rounded up) UCM $45 per ticket $45 per ticket
1b.
= 8% × $1,000 = $80 per ticket = $35 per ticket = $80 ‐ $35 = $45 per ticket = $22,000 a month
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3‐19 (cont’d) 2a.
SP = $80 per ticket VCU = $29 per ticket UCM = $80 ‐ $29 = $51 per ticket FC = $22,000 a month FC $22,000 Q = = = 432 tickets (rounded up) UCM $51 per ticket
FC TOI $22,000 $10,000 $32,000 = = = 628 tickets (rounded up) UCM $51 per ticket $51 per ticket
2b.
Q =
3a.
SP VCU CMU FC
Q =
FC $22,000 = = 1,158 tickets (rounded up) UCM $19 per ticket
Q =
FC TOI $22,000 $10,000 $32,000 = = = 1,685 tickets (rounded up) $19 per ticket $19 per ticket UCM
3b.
= $48 per ticket = $29 per ticket = $48 ‐ $29 = $19 per ticket = $22,000 a month
4a. The $5 delivery fee can be treated as either an extra source of revenue (as done below) or as a cost offset. Either approach increases CMU $5: SP = $53 ($48 + $5) per ticket VCU = $29 per ticket CMU = $53 ‐ $29 = $24 per ticket FC = $22,000 a month FC $22,000 Q = = = 917 tickets (rounded up) CMU $24 per ticket 4b.
Q =
FC TOI $22,000 $10,000 $32,000 = = = 1,334 tickets (rounded up) CMU $24 per ticket $24 per ticket
The $5 delivery fee results in a higher contribution margin, which reduces both the breakeven point and the tickets sold to attain operating income of $10,000.
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Chapter 3
3‐20 (20 min.) 1.
Contribution margin, gross margin and margin of safety.
Mirabel Cosmetics Operating Income Statement, June 2012 Units sold 10,000 Revenues $100,000 Variable costs Variable manufacturing costs $ 55,000 Variable marketing costs 5,000 Total variable costs 60,000 Contribution margin 40,000 Fixed costs Fixed manufacturing costs $ 20,000 Fixed marketing & administration costs 10,000 Total fixed costs 30,000 Operating income $ 10,000 $40,000 $4 per unit 2. Contribution margin per unit = 10,000 units Fixed costs $30, 000 7,500 units Breakeven quantity = Contribution margin per unit $4 per unit Revenues $100, 000 $10 per unit Selling price = Units sold 10,000 units Breakeven revenues = 7,500 units $10 per unit = $75,000 Alternatively, Contribution margin $40, 000 40% Contribution margin percentage = Revenues $100, 000 Fixed costs $30, 000 $75, 000 Breakeven revenues = Contribution margin percentage 0.40 3. Margin of safety = 10,000 units ‐ 7,500 units = 2,500 units
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3‐20 (cont’d) 4.
Units sold Revenues (Units sold Selling price = 8,000 $10) Contribution margin (Revenues CM percentage = $80,000 40%) Fixed costs Operating income Taxes (30% $2,000) Net income
8,000 $80,000 $32,000 30,000 2,000 600 $ 1,400
3‐21 CVP computations. 1.
(a) 5,000,000 ($0.60 ‐ $0.36) ‐ $1,080,000
2. 3. 4. 5. 6.
= $120,000
(a) 1,080,000 ÷ [($0.60 ‐ $0.36) ÷ $0.60] 5,000,000 ($0.60 ‐ $0.408) ‐ $1,080,000
= $2,700,000 = $(120,000)
[5,000,000 (1.1) ($0.60 ‐ $0.36)] ‐ [$1,080,000 (1.1)]
= $132,000
[5,000,000 (1.4) ($0.48 ‐ $0.324)] ‐ [$1,080,000 (0.8)] = $228,000 $1,080,000 (1.1) ÷ ($0.60 ‐ $0.36)
= 4,950,000 units
($1,080,000 + $24,000) ÷ ($0.66 ‐ $0.36)
= 3,680,000 units
3‐22 (15 min.) CVP exercises. 1. Total CM = $3,240,000 48% = $1,555,200 CM = Revenues ‐ Variable Costs $1,555,200 = $3,240,000 ‐ Variable Costs, VC = $1,684,800 Units Sold = $3,240,000 ÷ $36 = 90,000 Per Unit Dollars Revenues @ $36/unit (given) $36.00 $3,240,000 Variable Costs $18.72 $1,684,800 Contribution Margin $17.28 $1,555,200 Fixed Costs (given) $730,000 Budgeted Operating Income $825,200
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% 100% 52% 48%
Chapter 3
3‐22 (cont’d) 2. New Fixed Costs = $730,000 ‐ ($730,000 15%) = $620,500 New unit CM = 42% $36 = $15.12 Per Unit Dollars % Revenues @ $36/unit (given) $36.00 $3,240,000 100% Variable Costs $20.88 $1,879,200 58% Contribution Margin $15.12 $1,360,800 42% Fixed Costs (given) $620,500 Budgeted Operating Income $740,300 3. New Selling Price = $36 1.1 = $39.60 New Volume = 90,000 .95 = 85,500 VC = 85,500 $18.72 = $1,600,560 Per Unit Dollars Revenues $39.60 $3,385,800 Variable Costs $18.72 $1,600,560 Contribution Margin $20.88 $1,785,240 Fixed Costs (given) $730,000 Budgeted Operating Income $1,055,240 4. Increasing the selling price results in the highest budgeted operating income of the alternatives suggested. However, this higher income is based on an assumption that volume will only be reduced by 5% if the price is increased. The company may want to perform additional sensitivity analysis on the volume.
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3‐23 (25 min.) Operating leverage. 1. a.
b.
2.
Let Q denote the quantity of bracelets sold Breakeven point under Option 1 $125Q ‐ $80Q = ($435 3) $45Q = $1,305 Q = 29 bracelets Breakeven point under Option 2 $125Q ‐ $80Q ‐ (0.12 $125Q) = 0 $30Q = 0 Q = 0 All costs are variable and therefore can be avoided. Operating income under Option 1 = $45Q ‐ $1,305 Operating income under Option 2 = $30Q
Find Q such that $45Q ‐ $1,305 = $30Q $15Q = $1,305 Q = 87 87 is the mathematical point of indifference. Option 1: $125(87) ‐ $80(87) ‐ ($435 3) = $2,610 Option 2: $125(87) ‐ $80(87) ‐ $15(87) = $2,610 3. 3.
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a. For Q > 87, say, 88, Option 1 gives operating income = $45 88 ‐ $1,305 = $2,655 better Option 2 gives operating income = $30 88 = $2,640 Rothman will prefer Option 1. b. For Q < 87, say, 86, Option 1 gives operating income = $45 86 ‐ $1,305 = $2,565 Option 2 gives operating income = $30 86 = $2,580 better Rothman will prefer Option 2.
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3‐23 (cont’d) 4.
Degree of operating leverage = CM ÷ Operating Income Under Option 1, the total CM = $45 150 units = $6,750 Operating Income = $6,750 ‐ $1,305 = $5,445 The Degree of Operating Leverage (Opt 1) = $6,750 ÷ $5,445 = 1.24 Under Option 2, the total CM = OI = $30 150 = $4,500 The Degree of Operating Leverage (Opt 2) = $4,500 ÷ $4,500 = 1.00 5. The calculations in requirement 4 indicate that, when sales are 150 units, a percentage change in sales and contribution margin will result in 1.24 times that percentage change in operating income for Option 1, but the same percentage change in operating income for Option 2. The degree of operating leverage at a given level of sales helps managers calculate the effect of fluctuations in sales on operating incomes.
3‐24 (15 min.) Gross margin and contribution margin, making decisions. 1.
Revenues Deduct variable costs: Cost of goods sold Sales commissions Other operating costs Contribution margin
$800,000
$384,000 96,000 32,000
512,000 $288,000
2. 3.
Contribution margin percentage =
$288,000 36.00% $800,000
Incremental revenue (25% $800,000) $200,000 Incremental contribution margin (36% $200,000) 72,000 Incremental fixed costs (advertising) 24,300 Incremental operating income $47,700
If Mr. Saunders increases his advertising, the operating income will increase by $47,700 converting an operating loss of $44,700 to an operating income of $3,000.
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3‐24 (cont’d) Proof (Optional): Variable Other Operating Costs = $32,000 ÷ $800,000 = 4% of sales Revenues (125% $800,000) Cost of goods sold (48% of sales) Gross margin
$1,000,000 480,000 520,000
Operating costs: Store rent $61,200 Salaries and wages 212,000 Sales commissions (12% of sales) 120,000 Amortization of equipment and fixtures 19,200 Other operating costs: Variable (4% of sales) 40,000 Fixed 64,600 Operating income
3‐25 (20 min.)
517,000 $ 3,000
CVP, revenue mix.
1. Men’s Dominator Ladies Luxury Selling Price $750 $640 Variable Cost $475 $390 Sales Commission $25 $21 Unit CM $250 $229 2. Weighted Average CM = (70% $250) + (30% $229) = $175 + $68.70 = $243.70 3. Units required = Fixed Costs + Target OI Weighted Average CM = ($180,000 + $115,000) ÷ $243.70 = 1,210.5 or 1,211 total units Men’s Dominator = 70% 1,211 = 848 units (rounded up) Ladies Luxury = 30% 1,211 = 363 units (rounded down)
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3‐25 (cont’d) Proof: Men’s Dominator Ladies Luxury Unit CM $250 $229 Units Sold 848 363 Total CM $212,000 $83,127 Total CM – Fixed Costs = Operating Income ($212,000 + $83,127) ‐ $180,000 = $115,127 (difference is due to rounding of units)
3‐26 (30 min.) CVP, international cost structure differences. 1a.
Selling Price VC‐Manufacturing VC‐Distribution Total Variable Costs Unit CM Fixed Costs B/E point b/a (units) B/E point in revenues (Units 1b. $47.50) 2. Volume Total CM (Volume UCM) Less Fixed Costs Forecasted OI
India $ 47.50 $ 5.20 $ 21.80 $ 27.00 $ 20.50 $6,400,000 312,196 $14,829,310 1,350,000 $ 27,675,000 $6,400,000 $ 21,275,000
China $ 47.50 $ 9.50 $ 18.40 $ 27.90 $ 19.60 $4,400,000 224,490
Canada $ 47.50 $ 19.30 $ 6.20 $ 25.50 $ 22.00 $10,200,000 463,637
$10,663,275 $22,022,757 1,350,000 1,350,000 $ 26,460,000 $ 29,700,000 $4,400,000 $10,200,000 $ 22,060,000 $ 19,500,000
China has the lowest breakeven point—it has the lowest fixed costs ($4,400,000) and its variable cost per unit ($27.90) is only marginally higher than India. While Canada has a higher per unit CM, the fixed costs are more than double those of China. The higher fixed costs add risk to operating in Canada (leverage).
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3‐26 (cont’d) 3. China’s OI = $19.60 per unit less Fixed Costs of $4,400,000 Canada’s OI = $22.00 per unit less Fixed Costs of $10,200,000 $19.60X ‐ $4,400,000 = $22.00X ‐ $10,200,000 $5,800,000 = $2.40X X = 2,416,666.667 (or 2,416,667) Proof and India’s Operating Income at same sales volume India China Unit CM $ 20.50 $ 19.60 Volume 2,416,666.667 2,416,666.667 Total CM (Volume UCM) $49,541,667 $ 47,366,667 Less Fixed Costs $6,400,000 $4,400,000 Forecasted OI $43,141,667 $ 42,966,667 (Note: India’s forecasted OI is slightly higher at this volume)
3‐27 (25 min.) 1.
2.
Canada $ 22.00 2,416,666.667 $ 53,166,667 $10,200,000 $ 42,966,667
CVP, Not for profit
Contributions Fixed costs Cash available to purchase land Divided by cost per hectare to purchase land Hectares of land SG can purchase
$19,000,000 1,000,000 $18,000,000 ÷3,000 6,000 hectares
Contributions ($19,000,000 ‐ $5,000,000) $14,000,000 Fixed costs 1,000,000 Cash available to purchase land $13,000,000 Divided by cost per hectare ($3,000 ‐ $1,000) ÷2,000 Hectares of land SG can purchase 6,500 hectares
On financial considerations alone, SG should take the subsidy because it can purchase 500 more hectares (6,500 ‐ 6,000). 3-74
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3‐27 (cont’d) 3.
Let the decrease in contributions be $x . Cash available to purchase land = $19,000,000 ‐ $x ‐ $1,000,000 Cost to purchase land = $3,000 ‐ $1,000 = $2,000 To purchase 6,000 hectares, we solve the following equation for x .
19,000,000 x 1,000,000 6,000 2,000 18,000,000 x 6,000 2,000 18,000,000 x 12,000,000 x $6,000,000 SG will be indifferent between taking the government subsidy or not if contributions decrease by $6,000,000.
3‐28 (30 min.)
CVP, revenue mix
Zyrcon
Vegas Pokermatch $59 12 16 28 $31 60% $18.60
1. Alien Predators Revenue $89 Variable Manufacturing Costs 18 Variable Marketing Costs 27 Total Variable Costs 45 Unit CM $44 Sales Mix 40% Weighted CM $17.60 Weighted CM = $17.60 + $18.60 = $36.20 Breakeven in total units = Fixed Costs ÷ Weighted CM = $18,750,000 ÷ $36.20 = 517,956 units 40% of 517,596 = 207,183 units of Alien Predators 60% of 517,596 = 310,773 units of Vegas Pokermatch
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3‐28 (cont’d) Proof: OI = Total CM ‐ Fixed Costs OI = ($44 207,183) + ($31 310,773) ‐ $18,750,000 OI = $9,116,052 + $9,633,963 ‐ $18,750,000 OI = $15 (difference due to rounding of units) 2. Alien Predators Vegas Pokermatch Revenue $89 $59 Variable Manufacturing Costs 18 12 16 Variable Marketing Costs 27 28 Total Variable Costs 45 Unit CM $44 $31 Sales Mix 25% 75% Weighted CM $11.00 $23.25 Weighted CM = $11.00 + $23.25 = $34.25 Breakeven in total units = Fixed Costs ÷ Weighted CM = $18,750,000 ÷ $34.25 = 547,446 units 25% of 547,446 = 136,862 units of Alien Predators 75% o‐f 547,446 = 410,584 units of Vegas Pokermatch Proof: OI = Total CM ‐ Fixed Costs OI = ($44 136,862) + ($31 410,584) ‐ $18,750,000 OI = $6,021,928 + $12,728,104 ‐ $18,750,000 OI = $32 (difference due to rounding of units) 25%/75% Mix 3. 40%/60% Mix Weighted CM $36.20 $34.25 Unit Sales 750,000 750,000 Total CM $27,150,000 $25,687,500 18,750,000 Fixed Costs 18,750,000 OI $8,400,000 $6,937,500
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3‐29 (40 min.) 1.
Alternative cost structures, uncertainty, and sensitivity analysis.
Contribution margin assuming fixed rental arrangement = $50 ‐ $30 = $20 per bouquet Fixed costs = $5,000 Breakeven point = $5,000 ÷ $20 per bouquet = 250 bouquets Contribution margin assuming $10 per arrangement rental agreement = $50 ‐ $30 ‐ $10 = $10 per bouquet Fixed costs = $0 Breakeven point = $0 ÷ $10 per bouquet = 0
2. Let x denote the number of bouquets EB must sell for it to be indifferent between the fixed rent and royalty agreement. To calculate x we solve the following equation. $50 x ‐ $30 x ‐ $5,000 = $50 x ‐ $40 x $20 x ‐ $5,000 = $10 x $10 x = $5,000 x = $5,000 ÷ $10 = 500 bouquets For sales between 0 to 500 bouquets, EB prefers the royalty agreement because in this range, $10 x > $20 x ‐ $5,000. For sales greater than 500 bouquets, EB prefers the fixed rent agreement because in this range, $20 x ‐ $5,000 > $10 x . 3. If we assume the $5 savings in variable costs applies to both options, we solve the following equation for x . $50 x ‐ $25 x ‐ $5,000 = $50 x ‐ $35 x $25 x ‐ $5,000 = $15 x $10 x = $5,000 x = $5,000 ÷ $10 per bouquet = 500 bouquets The answer is the same as in Requirement 2, that is, for sales between 0 to 500 bouquets, EB prefers the royalty agreement because in this range, $15 x > $25 x ‐ $5,000. For sales greater than 500 bouquets, EB prefers the fixed rent agreement because in this range, $25 x ‐ $5,000 > $15 x .
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3‐29 (cont’d) 4.
Fixed rent agreement:
Bouquets Fixed Sold Revenue Costs (1) (3) (2) 200 200 $50=$10,000 $5,000 400 400 $50=$20,000 $5,000 600 600 $50=$30,000 $5,000 800 800 $50=$40,000 $5,000 1,000 1,000 $50=$50,000 $5,000 Expected value of rent agreement
Variable Costs (4) 200 $30=$ 6,000 400 $30=$12,000 600 $30=$18,000 800 $30=$24,000 1,000 $30=$30,000
Operating Income (Loss) (5)=(2)–(3)–(4) $ (1,000) $ 3,000 $ 7,000 $11,000 $15,000
Probability (6)
0.20 0.20 0.20 0.20 0.20
Expected Operating Income (7)=(5) (6) $ ( 200) 600 1,400 2,200 3,000 $7,000
Royalty agreement: Bouquets Variable Sold Revenue Costs (1) (2) (3) 200 200 $50=$10,000 200 $40=$ 8,000 400 400 $50=$20,000 400 $40=$16,000 600 600 $50=$30,000 600 $40=$24,000 800 $40=$32,000 800 800 $50=$40,000 1,000 1,000 $50=$50,000 1,000 $40=$40,000 Expected value of royalty agreement
Operating Expected Operating Income Probability Income (4)=(2)–(3) (5) (6)=(4) (5) $2,000 0.20 $ 400 $4,000 0.20 800 $6,000 0.20 1,200 $8,000 0.20 1,600 $10,000 0.20 2,000 $6,000
EB should choose the fixed rent agreement because the expected value is higher than the royalty agreement. EB will lose money under the fixed rent agreement if EB sells only 200 bouquets but this loss is more than made up for by high operating incomes when sales are high.
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3‐30 (20 min.) 1.
CVP analysis, multiple cost drivers.
350,000 pens sold, order size 100
Costs to buy pens Imprinting Costs Total Variable Costs Revenues Variable Costs Contribution Margin Setups Product Margin Fixed Costs OI Revenues Variable Costs Contribution Margin Setups Product Margin Fixed Costs OI
2.
Per 100 $ 95.00 $ 35.00 $130.00 350,000 $4.50 350,000 $1.30
(350,000/100) $120
350,000 $4.50 350,000 $1.30
(350,000/250) $120
Each Pen $ 0.95 $ 0.35 $ 1.30 $1,575,000 $455,000 $1,120,000 $420,000 $700,000 $275,000 $425,000 $1,575,000 $455,000 $1,120,000 $168,000 $952,000 $275,000 $677,000
350,000 pens sold, order size 250
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3‐30 (cont’d) 3.
Unit Margins, Breakevens & Setups at various order sizes Order Size 50 units/order 100 units/order 250 units/order 500 units/order Setup Costs $120.00 $120.00 $120.00 $120.00 Setup/unit $2.40 $1.20 $0.48 $0.24 VC/Unit $1.30 $1.30 $1.30 $1.30 Subtotal $3.70 $2.50 $1.78 $1.54 Revenues $4.50 $4.50 $4.50 $4.50 Unit Margin $0.80 $2.00 $2.72 $2.96 Fixed Costs $275,000 $275,000 $275,000 $275,000 Breakeven 343,750 units 137,500 units 101,103 units 92,906 units FC/Unit Marg Number of setups 6,875 setups 1,375 setups 404 setups 186 setups at breakeven point The breakeven point is not unique because there are two cost drivers—quantity of pens and number of setups. Various combinations of the two cost drivers can yield zero operating income.
3‐31 (15‐20 min.) Uncertainty, CVP. 1. King pays Couture $3.2 million plus $6.75 (25% of $27.00) for every home purchasing the pay‐per‐view. The expected value of the variable component is: Demand Payment Probability Expected payment (1) (2) = (1) $6.75 (3) (4) = (2) (3) 250,000 $ 1,687,500 0.05 $ 84,375 300,000 2,025,000 0.10 202,500 350,000 2,362,500 0.20 472,500 400,000 2,700,000 0.40 1,080,000 500,000 3,375,000 0.15 506,250 1,000,000 6,750,000 0.10 675,000 $3,020,625 The expected value of King’s payment is $6,220,625 ($3,200,000 fixed fee + $3,020,625).
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3‐31 (cont’d) 2.
USP UVC UCM FC
= = = =
$27.00 $9.00 ($6.75 payment to Couture + $2.25 variable cost) $18.00 $3,200,000 + $1,300,000 = $4,500,000
Q
=
FC = $4,500,000 ÷ $18 = 250,000 UCM
If 250,000 homes purchase the pay‐per‐view, King will break even.
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PROBLEMS 3‐32 (20‐30 min.) Effects on operating income, pricing decision. 1.
Analysis of special order: Sales, 5,000 units $98 Variable costs: $240,000 Direct materials, 5,000 units $48 Direct manufacturing labour, 5,000 units $16 80,000 40,000 Variable manufacturing overhead, 5,000 units $8 Other variable costs, 5,000 units $7 35,000 Sales commission, flat rate 9,500 Total variable costs Contribution margin
$490,000
404,500 $ 85,500
Note that the variable costs, except for commissions, are affected by production volume, not sales dollars. If the order is accepted, operating income increases by $85,500. 4. Whether the general manager is making a correct decision depends on many factors. He is incorrect if the capacity would otherwise be idle and if his objective is to increase operating income in the short run. If the offer is rejected, Teguchi, in effect, is willing to invest $85,500 in immediate gains forgone (an opportunity cost) to preserve the long‐run selling‐price structure. He is correct if he thinks future competition or future price concessions to customers will hurt Teguchi’s operating income by more than $85,500. There is also the possibility that Andrews could become a long‐term customer. In this case, is a price that covers only short‐run variable costs adequate? Would the sales representative be willing to accept the lower flat sales commission (as distinguished from the regular $58,800 = 12% $490,000) on a long term basis?
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3‐33 (20‐30 min.) CVP, executive teaching compensation. 1.
(a)
Advertising in magazines $5,200 Mailing of brochures 2,500 Administrative labour at UKBS 3,700 Charge for UKBS lecture auditorium 1,800 Airfare and accommodation 3,800 Lecture fee 2,750 Total fixed costs $19,750 Meals and drinks $38 Binders and photocopying 37 Unit variable cost $75 Unit contribution margin = Unit revenues – Unit variable costs = $350 ‐ $75 = $275 Breakeven point =
Fixed costs Unit contribu tion m argin
= $19,750 ÷ $275 = 71.82 or 72 attendees
(b) Advertising in magazines Mailing of brochures Administrative labour at UKBS Charge for UKBS lecture auditorium Total fixed costs Unit contribution margin = $275 Breakeven point =
$5,200 2,500 3,700 1,800 $13,200
Fixed costs Unit contribu tion m argin
= $13,200 ÷ $275 = 48 attendees
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3‐33 (cont’d) The breakeven point drops from 72 attendees to 48 attendees—the $6,550 ($3,800 + $2,750) package to Smith requires 24 attendees with a unit contribution margin of $275 to be recouped. In the regular compensation package, Hutchison’s expense allowance and lecture speaking fee of $6,550 is a fixed cost to UKBS. In contrast, with Hutchison’s suggested compensation package, UKBS has no cost item (either fixed or variable) for Hutchison up to its breakeven point. Beyond the breakeven point, Hutchison receives 50% of the operating income from the one‐day program. 2. Operating income to UKBS = $350N ‐ $75N ‐ $13,200 2009 2010 2011 Attendees 60 75 120 Revenues $21,000 $26,250 $42,000 5,625 9,000 VC 4,500 CM 16,500 20,625 33,000 Fixed Costs 13,200 13,200 13,200 OI 3,300 7,425 19,800 Smith’s share (50%) $1,650 $3,712.50 $9,900 3. This question raises a broad set of issues: (a) Hutchison has taken a high level of risk with a compensation plan that only pays him the guaranteed $6,550 under the regular plan. In both 2009 and 2010, he received less than the $6,550 figure. Hutchison could comment to the Dean that if the UKBS finds the risk‐sharing program attractive in periods of low demand, it should be willing to share the revenues in periods of high demand. (b) Hutchison could stress to UKBS how much they both have gained from the one‐ day seminars. UKBS has made an operating income each year. In addition, only some of UKBS’s fixed costs are cash outflows. For example, the $1,800 charge for use of the lecture auditorium is not a cash outflow. If the auditorium would not be otherwise used that day, UKBS may well view the $1,800 amount as quite different from the cash outlay items.
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3‐33 (cont’d) (c) Hutchison could respond to the Dean that the agreement is not really a 50%/50% profit‐sharing plan. It considers only the UKBS costs. Assume Hutchison pays $3,300 for airfare/accommodation. Then, in 2009 he actually lost $1,650 ($1,650 ‐ $3,300) for giving the seminar, while in 2010 he received only $412.50 ($3,712.50 ‐ $3,300). (d) If Hutchison views the Dean as adamant in wanting to change the formula, he could consider negotiating with another university or organization to handle the planning and marketing of the seminar.
3‐34 (20 Min.) 1.
CVP computations with sensitivity analysis
USP = $36.00 (1 ‐ 0.30 margin to bookstore) = $36.00 0.70 = $25.20
UVC = $4.80 variable production and marketing cost 3.78 variable author royalty cost (0.15 $36.00 0.70) $8.58 UCM = $25.20 ‐ $8.58 = $16.62 FC = $600,000 fixed production and marketing cost 3,600,000 up‐front payment to Washington $4,200,000 (a) Breakeven number in units = $4,200,000 ÷ $16.62 = 252,708 copies sold (rounded) (b) Target OI = ($4,200,000 + $2,400,000) ÷ $16.62 = 397,112 copies sold (rounded)
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3‐34 (cont’d) 2. (a) Decreasing the normal bookstore margin to 20% of the listed bookstore price of $36 has the following effects: USP = $36.00 (1 ‐ 0.20) = $36.00 0.80 = $28.80 UVC = $4.80 + $4.32 (0.15 $36.00 0.80) = $9.12 UCM = $28.80 ‐ $9.12 = $19.68 Breakeven number of units = $4,200,000 ÷ $19.68 = 213,415 copies sold (rounded) (b) Increasing the listed bookstore price to $48 while keeping the bookstore margin at 30% has the following effects: USP = $48.00 (1 ‐ 0.30) = $36.00 0.70 = $33.60 UVC = $4.80 + $5.04 (0.15 $48.00 0.70) = $9.84 UCM = $33.60 ‐ $9.84 = $23.76 Breakeven number of units = $4,200,000 ÷ $23.76 = 176,768 copies sold (rounded)
3‐35 (15‐20 min.) CVP analysis, service firm. 1.
Revenue per package $9,200 Variable cost per package 6,340 Contribution margin per package $2,860 Breakeven (units) = Fixed costs ÷ Contribution margin per package = $1,287,000 ÷ $2,860 = 450 package tours
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3‐35 (cont’d) 2.
3.
Contribution margin ratio =
Contribu tion m argin per package = $2,860 ÷ $9,200 Selling price
=31.09% Units needed to achieve target income = (Fixed costs + target OI) ÷ UCM = ($1,287,000 + $214,500) ÷ $2,860 = 525 packages Revenues to earn $214,500 OI = 525 tour packages $9,200= $4,830,000 or Revenue to achieve target income = (Fixed costs + target OI) ÷ CM ratio = ($1,287,000 + $214,500) ÷ .3109 = $4,829,527 (rounding difference) Fixed costs = $1,287,000 + $40,500 = $1,327,500 Breakeven (units) =
Fixed costs Contribu tion m argin per u nit
Contribution margin per unit
= $1,327,500 ÷ 450
= $2,950 per tour package
Desired variable cost per tour package = $9,200 – $2,950 = $6,250 Because the current variable cost per unit is $6,340 the unit variable cost will need to be reduced by $90 to achieve the breakeven point calculated in requirement 1. Alternate Method: If fixed cost increases by $40,500 then total variable costs must be reduced by $40,500 or $40,500/450 or $90 per package tour.
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3‐36 (30 min.)
CVP, target operating income and net income
Cost Item Total Cost Unit Cost Total Variable Costs: Direct Material $600,000 $7.50 Direct Labour 400,000 5.00 Variable Overhead 720,000 9.00 3.25 Variable Selling 260,000 Total Variable Costs $1,980,000 $24.75 Total Fixed Costs Fixed Overhead $400,000 Fixed Selling 250,000 Fixed Administration 150,000 $800,000 1. Selling price to break even (USP ‐ UVC) Q ‐ Fixed Costs = $0 (USP ‐ $24.75) 80,000 ‐ $800,000 = $0 (USP ‐ $24.75) = $800,000 ÷ 80,000 USP ‐ $24.75 = $10 USP = $34.75 2. [USP ‐ $24.75] 60,000 = (0.20USP 60,000) + Fixed Costs 60,000USP ‐ $1,485,000 = 12,000USP + $800,000 48, 000USP = $2,285,000 USP = $47.61 3. Offer should be rejected. The proposed variable cost to purchase of $28 exceeds the variable manufacturing costs of $24.75. The company would lose $3.25 ($28.00 ‐ $24.75) per unit.
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3‐36 (cont’d) 4.
Desired after tax profit Before tax profit Before tax profit Before tax profit (OI)
(USP ‐ $24.75) 80,000 ‐ $800,000 (USP ‐ $24.75) USP ‐ $24.75 USP
3‐37 (30 min.) 1.
= = = =
$350,000 After‐tax profit ÷ (1‐tax rate) $350,000 ÷ (1‐0.30) $500,000
= = = =
$500,000 ($500,000 + $800,000) ÷ 80,000 $16.25 $41.00
CVP, target income, service firm.
Revenue per child Variable costs per child Contribution margin per child
$600 200 $400
Breakeven quantity = Fixed Costs ÷ Contribution margin/child $5,600 = = 14 children $400
2. Target quantity = (Fixed costs + Target operating income) ÷ Contribution margin/child $5,600 $10,400 = 40 children = $400 3. Increase in rent ($3,000 – $2,000) $1,000 Field trips 1,000 Total increase in fixed costs $2,000 Divide by the number of children enrolled ÷40 Increase in fee per child $50 Therefore, the fee per child will increase from $600 to $650.
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3‐37 (cont’d) Alternatively, New contribution margin per child =
$5,600 $2,000 $10,400 = $450 40
New fee per child = Variable costs per child + New contribution margin per child = $200 + $450 = $650
3‐38 (20 min.) 1.
2.
CVP and income taxes.
Revenues – Variable costs ‐ Fixed costs = Target net income ÷ (1 ‐ tax rate) Let X = Net income for 2012 20,000($30.00) ‐ 20,000($16.50) ‐ $162,000 = X ÷ (1‐0.40) $600,000 ‐ $330,000 ‐ $162,000 = X ÷ 0.60 X = $64,800
Let Q = Number of unit to break even $30.00Q ‐ $16.50Q ‐ $162,000 = 0 Q = $162,000 ÷ $ 13.50 = 12,000 units
3.
4.
Let X = Net income for 2013 22,000($30.00) ‐ 22,000($16.50) ‐ ($162,000 + $13,500) = X ÷ (1‐0.40) $297,000 ‐ $175,500 = X ÷ 0.60 X = $72,900
Let Q = Number of units to break even with new fixed costs of $175,500 $30.00Q ‐ $16.50Q ‐ $175,500 = 0 Q = $175,500 ÷ $ 13.50 = 13,000 units Revenues = 13,000($30.00) = $390,000
Alternatively, the computation could be $175,500 divided by the contribution margin percentage of 45% to obtain $390,000.
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3‐38 (cont’d) 5.
6.
Let S = Required sales units to equal 2012 net income $30.00S ‐ $16.50S ‐ $175,500 = $64,800 ÷ 0.60 $13.50S = $283,500 S = 21,000 units Revenues = 21,000 units $30.00 = $630,000
Let A = Amount spent for advertising in 2013 $660,000 ‐ $363,000 ‐ ($162,000 + A) = $72,000 ÷ 0.6 $297,000 ‐ $162,000 ‐ A = $120,000 A = $15,000
3‐39 (20‐25 min.) CVP income taxes, manufacturing decisions. 1. Total Per Unit Sales $1,350,000 $54.00 Variable Costs $742,500 $29.70 CM $607,500 $24.30 Fixed Costs $375,000 Operating Income $232,500 Income Taxes (40%) $93,000 Net Income $139,500 Breakeven point = Fixed Costs ÷ Unit CM = $375,000 ÷ $24.30 = 15,433 units (rounded) Breakeven point ($) = 15,433 $54 = $833,382 or Alternate calculation: CM Percentage = $24.30 ÷ $54.00 = 45% Breakeven point ($) = Fixed Costs ÷ CM% = $375,000 ÷ 0.45 = $833,333 Margin of Safety = Sales ‐ Breakeven Sales = $1,350,000 ‐ $833,333 = $516,667 or = $1,350,000 ‐ $833,382 = $516,618
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3‐39 (cont’d) 2. Operating Income = After Tax Income ÷ (1‐tax rate) = $225,000 ÷ (1‐0.40) = $375,000 Units needed = (Fixed Costs + Target OI) ÷ Unit CM = ($375,000 + $375,000) ÷ $24.30 = 30,865 units (rounded) 3. Change in CM = $9.80 ‐ $7.50 = $2.30 decrease in unit CM New CM = $24.30 ‐ $2.30 = $22.00 Change In Annual Fixed Costs = Increased Amortization Charges = ($25,000 ‐ $0) ÷ 5 = $5,000 New Fixed Costs = $375,000 + $5,000 = $380,000 New Breakeven Point = New Fixed Costs ÷ New Unit CM = $380,000 ÷ $22 = 17,273 units (rounded) Units Needed for Target OI = (New Fixed Costs + Target OI) ÷ New Unit CM = ($380,000 + $232,500) ÷ $22.00 = 27,841 units (rounded) 4. Variable Costs of New Product = $29.70 1.6 = $47.52 New Product Total Old Product Units 30,000 20,000 50,000 Sales $1,620,000 $1,900,000 $3,520,000 VC ($891,000) ($950,400) ($1,841,400) CM $729,000 $949,600 $1,678,600 CM% 45% 49.98% 47.6875%
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3‐39 (cont’d) New Breakeven Point in Sales $ = Fixed Costs ÷ Weighted CM % = $375,000 ÷ 47.6875% = $786,370* Alternate Calculation: Sales mix is 3:2 Weighted Average CM = [3 $24.3] + [2 $47.48] = $72.90 + $94.96 = $167.86 Breakeven Point (packages) = $375,000 ÷ $167.86 = 2,235 packages 2,235 3 = 6,705 units of Old 2,235 2 = 4,470 of New Total Revenues = [6,705 $54] + [4,470 $95] = $362,070 + $424,650 = $786,720* *difference due to rounding of units
3‐40 (20 min.)
CVP, shoe stores.
1. UCM (SP ‐ UVC = $30 ‐ $21) $9.00 a. Breakeven units (FC UCM = $360,000 $9 per unit) 40,000 b. Breakeven revenues (Breakeven units SP = 40,000 units $30 per unit)$1,200,000 2. Pairs sold 35,000 $1,050,000 Revenues, 35,000 $30 Total cost of shoes, 35,000 $19.50 682,500 52,500 Total sales commissions, 35,000 $1.50 Total variable costs 735,000 Contribution margin 315,000 Fixed costs 360,000 Operating income (loss) $ (45,000)
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3‐40 (cont’d) 3. Unit variable data (per pair of shoes) Selling price Cost of shoes Sales commissions Variable cost per unit Annual fixed costs Rent Salaries, $200,000 + $81,000 Advertising Other fixed costs Total fixed costs UCM, $30 ‐ $19.50 a. Breakeven units, $441,000 $10.50 per unit b. Breakeven revenues, 42,000 units $30 per unit 4. Unit variable data (per pair of shoes) Selling price Cost of shoes Sales commissions Variable cost per unit Total fixed costs UCM, $30 ‐ $21.30 a. Break even units = $360,000 $8.70 per unit b. Break even revenues = 41,380 units $30 per unit $1,241,400
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$ 30.00 19.50 0 $ 19.50 $ 60,000 281,000 80,000 20,000 $ 441,000 $ 10.50 42,000 $1,260,000 $ 30.00 19.50 1.80 $ 21.30 $ 360,000 $ 8.70 41,380 (rounded up)
Chapter 3
3‐40 (cont’d)
5. Pairs sold 50,000 $1,500,000 Revenues (50,000 pairs $30 per pair) Total cost of shoes (50,000 pairs $19.50 per pair) $ 975,000 60,000 Sales commissions on first 40,000 pairs (40,000 pairs $1.50 per pair) Sales commissions on additional 10,000 pairs: [10,000 pairs ($1.50 + $0.30 per pair)] 18,000 Total variable costs $1,053,000 Contribution margin $ 447,000 Fixed costs 360,000 Operating income $ 87,000 Alternative approach: Breakeven point in units = 40,000 pairs Store manager receives commission of $0.30 on 10,000 (50,000 ‐ 40,000) pairs. Contribution margin per pair beyond breakeven point of 10,000 pairs = $8.70 ($30 ‐ $21 ‐ $0.30) per pair. Operating income = 10,000 pairs $8.70 contribution margin per pair = $87,000.
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3‐41 (30 min.) CVP, shoe stores (continuation of 3‐40).
Salaries + Commission Plan
No. of CM units sold per Unit CM (1) (2) (3)=(1) (2) 40,000 $9.00 $360,000 42,000 9.00 378,000 44,000 9.00 396,000 46,000 9.00 414,000 48,000 9.00 432,000 50,000 9.00 450,000 52,000 9.00 468,000 54,000 9.00 486,000 56,000 9.00 504,000 58,000 9.00 522,000 60,000 9.00 540,000 62,000 9.00 558,000 64,000 9.00 576,000 66,000 9.00 594,000
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Higher Fixed Salaries Only
Fixed Operating CM Costs Income per Unit CM (4) (5)=(3)–(4) (6) (7)=(1) (6) $360,000 0 $10.50 $420,000 360,000 18,000 10.50 441,000 360,000 36,000 10.50 462,000 360,000 54,000 10.50 483,000 360,000 72,000 10.50 504,000 360,000 90,000 10.50 525,000 360,000 108,000 10.50 546,000 360,000 126,000 10.50 567,000 360,000 144,000 10.50 588,000 360,000 162,000 10.50 609,000 360,000 180,000 10.50 630,000 360,000 198,000 10.50 651,000 360,000 216,000 10.50 672,000 360,000 234,000 10.50 693,000
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Fixed Costs (8) $441,000 441,000 441,000 441,000 441,000 441,000 441,000 441,000 441,000 441,000 441,000 441,000 441,000 441,000
Difference in Operating favour of higher‐ Income fixed‐salary‐only (9)=(7)–(8) (10)=(9)–(5) $ (21,000) $(21,000) 0 (18,000) 21,000 (15,000) 42,000 (12,000) 63,000 (9,000) 84,000 (6,000) 105,000 (3,000) 126,000 0 147,000 3,000 168,000 6,000 189,000 9,000 210,000 12,000 231,000 15,000 252,000 18,000
Chapter 3
3‐41 (cont’d) 1. See preceding table. The new store will have the same operating income under either compensation plan when the volume of sales is 54,000 pairs of shoes. This can also be calculated as the unit sales level at which both compensation plans result in the same total costs:
Let Q = unit sales level at which total costs are same for both plans:
$19.50Q + $360,000 + $81,000 = $21Q + $360,000 $1.50 Q = $81,000 Q = 54,000 pairs
2. When sales volume is above 54,000 pairs, the higher‐fixed‐salaries plan results in lower costs and higher operating incomes than the salary‐plus‐commission plan. So, for an expected volume of 55,000 pairs, the owner would be inclined to choose the higher‐ fixed‐salaries‐only plan. But it is likely that sales volume itself is determined by the nature of the compensation plan. The salary‐plus‐commission plan provides a greater motivation to the salespeople, and it may well be that for the same amount of money paid to salespeople, the salary‐plus‐commission plan generates a higher volume of sales than the fixed‐salary plan. 3.
Let TQ = Target number of units For the salary‐only plan: $30.00TQ ‐ $19.50TQ ‐ $441,000 = $168,000 $10.50TQ = $609,000 TQ = $609,000 ÷ $10.50 TQ = 58,000 units For the salary‐plus‐commission plan: $30.00TQ ‐ $21.00TQ ‐ $360,000 = $168,000 $9.00TQ = $528,000 TQ = $528,000 ÷ $9.00 TQ = 58,667 units (rounded up)
The decision regarding the salary plan depends heavily on predictions of demand. For instance, the salary plan offers the same operating income at 58,000 units as the commission plan offers at 58,667 units.
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3‐41 (cont’d) 4.
WalkRite Shoe Company Operating Income Statement, 2008 Revenues (48,000 pairs $30) + (2,000 pairs $18) Cost of shoes, 50,000 pairs $19.50 Commissions = Revenues 5% = $1,476,000 0.05 Contribution margin Fixed costs Operating income
3‐42 (30 min.)
Uncertainty and expected costs.
1. Monthly Number of Orders 300,000 400,000 500,000 600,000 700,000 Monthly Number of Orders 300,000 400,000 500,000 600,000 700,000 Monthly Number of Orders 300,000 400,000 500,000 600,000 700,000
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$1,476,000 975,000 73,800 427,200 360,000 $ 67,200
Cost of Current System $1,000,000 + $40(300,000) = $13,000,000 $1,000,000 + $40(400,000) = $17,000,000 $1,000,000 + $40(500,000) = $21,000,000 $1,000,000 + $40(600,000) = $25,000,000 $1,000,000 + $40(700,000) = $29,000,000
Cost of Partially Automated System $5,000,000 + $30(300,000) = $14,000,000 $5,000,000 + $30(400,000) = $17,000,000 $5,000,000 + $30(500,000) = $20,000,000 $5,000,000 + $30(600,000) = $23,000,000 $5,000,000 + $30(700,000) = $26,000,000
Cost of Fully Automated System $10,000,000 + $20(300,000) = $16,000,000 $10,000,000 + $20(400,000) = $18,000,000 $10,000,000 + $20(500,000) = $20,000,000 $10,000,000 + $20(600,000) = $22,000,000 $10,000,000 + $20(700,000) = $24,000,000
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3‐42 (cont’d) 2. Current System Expected Cost: $13,000,000 × 0.1 = $ 1,300,000 17,000,000 × 0.25 = 4,250,000 21,000,000 × 0.40 = 8,400,000 25,000,000 × 0.15 = 3,750,000 29,000,000 × 0.10 = 2,900,000 $ 20,600,000 Partially Automated System Expected Cost: $14,000,000 × 0.1 = $ 1 ,400,000 17,000,000 × 0.25 = 4,250,000 20,000,000 × 0.40 = 8,000,000 23,000,000 × 0.15 = 3,450,000 26,000,000 × 0.10 = 2,600,000 $19,700,000 Fully Automated System Expected Cost: $16,000,000 × 0.1 = $ 1,600,000 18,000,000 × 0.25 = 4,500,000 20,000,000 × 0.40 = 8,000,000 22,000,000 × 0.15 = 3,300,000 24,000,000 × 0.10 = 2,400,000 $19,800,000 3. Dawmart should consider the impact of the different systems on its relationship with suppliers. The interface with Dawmart’s system may require that suppliers also update their systems. This could cause some suppliers to raise the cost of their merchandise. It could force other suppliers to drop out of Dawmart’s supply chain because the cost of the system change would be prohibitive. Dawmart may also want to consider other factors such as the reliability of different systems and the effect on employee morale if employees have to be laid off as it automates its systems.
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3‐43 (25 min.) 1.
CVP analysis, decision making.
Unit selling price Variable manufacturing costs per unit Variable marketing and distribution costs per unit Contribution margin per unit Fixed manufacturing costs Fixed marketing and distribution costs Total fixed costs
$148 63 15 $ 70 $ 1,012,000 780,000 $1,792 ,000
Total fixed costs Contribu tion m argin per u nit
Breakeven point in units
=
=
$1,792,000 ÷ $70
=
25,600 units
Breakeven point in revenues = 25,600 units $148 per unit = $3,788,800 2.
Tocchet’s current operating income is as follows:
$8,880,000 Revenues, $148 60,000 Variable costs, $78 60,000 4,680,000 Contribution margin 4,200,000 Fixed costs 1,792,000 Operating income $ 2,408,000 Let the fixed costs be $F. We calculate $F when operating income = $2,408,000 and the selling price is $140. ($140 70,000) ‐ ($78 70,000) – $F = $2,408,000 $9,800,000 ‐ $5,460,000 – $F = $2,408,000 $F = $1,932,000 Hence the maximum increase in fixed costs for which Tocchet will prefer to reduce the selling price is $140,000 ($1,932,000 ‐ $1,792,000).
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3‐43 (cont’d) 3.
Let the selling price be P. We calculate P for which, after increasing fixed manufacturing costs by $150,000 to $1,942,000 and variable manufacturing cost per unit by $3.20 to $66.20, operating income = $2,408,000 60,000P ‐ ($66.20 60,000) ‐ ($15 60,000) ‐ $1,942,000 = $2,408,000 60,000P ‐ $3,972,000 ‐ $900,000 ‐ $1,942,000 = $2,408,000 60,000P = $9,222,000 P = $153.70 Tocchet will consider adding the new features provided the selling price is at least $153.70 per unit. Proof: New CM = $153.70 ‐ $66.20 ‐ $15 = $72.50 OI = (60,000 $72.50) ‐ $1,942,000 = $2,408,000
3‐44 (20–25 min.) Sales mix, two products. 1. Sales of standard and deluxe carriers are in the ratio of 150,000:50,000. So for every 1 unit of deluxe, 3 (150,000 ÷ 50,000) units of standard are sold. Contribution margin of the bundle = 3 $6 + 1 $12 = $18 + $12 = $30 $1, 200,000 Breakeven point in bundles = = 40,000 bundles $30 Breakeven point in units is: Standard 40,000 bundles × 3 units per carrier: bundle 120,000 units Deluxe carrier: 40,000 bundles × 1 unit per bundle 40,000 units Total number of units to breakeven 160,000 units
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3‐44 (cont’d) Alternatively, Let Q = Number of units of Deluxe carrier to break even 3Q = Number of units of Standard carrier to break even Revenues – Variable costs – Fixed costs = Zero operating income $20(3Q) + $30Q ‐ $14(3Q) ‐ $18Q ‐ $1,200,000 = 0 $60Q + $30Q ‐ $42Q ‐ $18Q = $1,200,000 $30Q = $1,200,000 Q = 40,000 units of Deluxe 3Q = 120,000 units of Standard The breakeven point is 120,000 Standard units plus 40,000 Deluxe units, a total of 160,000 units. 2a. Unit contribution margins are: Standard: $20 ‐ $14 = $6; Deluxe: $30 ‐ $18 = $12 If only Standard carriers were sold, the breakeven point would be: $1,200,000 $6 = 200,000 units. 2b. If only Deluxe carriers were sold, the breakeven point would be: $1,200,000 $12 = 100,000 units 3. Operating income = Contribution margin of Standard + Contribution margin of Deluxe - Fixed costs = 180,000($6) + 20,000($12) ‐ $1,200,000 = $1,080,000 + $240,000 ‐ $1,200,000 = $120,000 Sales of standard and deluxe carriers are in the ratio of 180,000: 20,000. So for every 1 unit of deluxe, 9 (180,000 ÷ 20,000) units of standard are sold. Contribution margin of the bundle = 9 $6 + 1 $12 = $54 + $12 = $66 $1, 200,000 = 18,182 bundles (rounded up) Breakeven point in bundles = $66
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3‐44 (cont’d)
Breakeven point in units is: Standard 18,182 bundles × 9 units per carrier: bundle Deluxe carrier: 18,182 bundles × 1 unit per bundle Total number of units to breakeven
163,638 units 18,182 units 181,820 units
Alternatively, Let Q = Number of units of Deluxe product to break even 9Q = Number of units of Standard product to break even $20(9Q) + $30Q ‐ $14(9Q) ‐ $18Q ‐ $1,200,000 = 0 $180Q + $30Q ‐ $126Q ‐ $18Q = $1,200,000 $66Q = $1,200,000 Q = 18,182 units of Deluxe (rounded up) 9Q = 163,638 units of Standard The breakeven point is 163,638 Standard + 18,182 Deluxe, a total of 181,820 units. The major lesson of this problem is that changes in the sales mix change breakeven points and operating incomes. In this example, the budgeted and actual total sales in number of units were identical, but the proportion of the product having the higher contribution margin declined. Operating income suffered, falling from $300,000 to $120,000. Moreover, the breakeven point rose from 160,000 to 181,820 units.
3‐45 (15 min.) 1.
CVP, movie production.
Fixed costs = $22,000,000 (production cost) Unit variable cost = (4% +4% + 8% + 8% + 12%) = 36% of revenues Unit contribution margin = 100% ‐ 36% = 64% of revenues or $0.64 per $1
(a) Breakeven point in revenues =
Fixed costs Unit contribu tion m argin per $1 revenu e
= $22,000,000/$0.64 = $34,375,000 (b) Panther receives 65% of box‐office receipts. Required box‐office receipts = $34,375,000 ÷ 0.65 = $52,884,616 (rounded)
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3‐45 (cont’d) 2.
Revenues, 0.65 $320,000,000 Variable costs, 0.36 $208,000,000 Contribution margin Fixed costs Operating income
$208,000,000 74,880,000 133,120,000 22,000,000 $111,120,000
3‐46 (20 min.) CVP, cost structure differences, movie production (continuation of 3‐ 45). 1.
Contract A Fixed costs for Contract A: Production costs Fixed salary Total fixed costs
$32,000,000 50,000,000 $82,000,000
Unit variable cost = 8% + 8% + 18% = 34% or $0.34 per $1 revenue marketing fee Unit contribution margin = $0.66 per $1 revenue (a) Breakeven point in revenues
=
Fixed costs Unit contribu tion m argin per $1 revenu e
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= =
$82,000,000 ÷ $0.66 $124,242,425 (rounded)
Breakeven point in box office sales = =
$124,242,425 ÷ 0.65 $191,142,192 (rounded)
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Chapter 3
3‐46 (cont’d)
Contract B Fixed costs for Contract B: Production costs Fixed salary Total fixed costs
$32,000,000 8,000,000 $40,000,000
Unit variable cost = $0.18 per $1 revenue fee to Parimont Productions [3%+3%+8%+8%] $0.22 per $1 revenue residual to directors/actors $0.40 per $1 revenue
Unit contribution margin = $0.60 per $1 revenue Breakeven point in revenues = $40,000,000/$0.60 = $66,666,667 (rounded) Breakeven point in box office sales = $66,666,667/0.65 = $102,564,103 (rounded) Difference in Breakeven Points Contract A has a higher fixed cost and a lower variable cost per sales dollar. In contrast, Contract B has a lower fixed cost and a higher variable cost per sales dollar. In Contract B, there is more risk‐sharing between Panther and the actors that lowers the breakeven point, but results in Panther receiving less operating income if the film is a mega‐success. 2. Contract A: Revenues, 0.65 $280,000,000 $182,000,000 61,880,000 Variable costs, 0.34 $182,000,000 Contribution margin 120,120,000 Fixed costs 82,000,000 Operating income $38,120,000 Contract B: $182,000,000 Revenues, 0.65 $280,000,000 Variable costs, 0.4 $182,000,000 72,800,000 Contribution margin 109,200,000 Fixed costs 40,000,000 Operating income $69,200,000
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3‐46 (cont’d) Contract A has a higher breakeven point than Contract B, because it has a higher level of fixed costs and a lower unit contribution margin. This means after breakeven is reached, under Contract A, $0.66 of every additional revenue dollar will contribute to OI, but under Contract B only $0.60 of every additional revenue dollar will contribute to OI. However, the fixed costs for Contract A are significantly higher than for Contract B. At the predicted level of box office receipts, Contract B is the more lucrative contract. The point of indifference (in terms of revenue to Panther) (not required in question) ($1.00R ‐ $0.34R) ‐ $82,000,000 = ($1.00R ‐ $0.40R) ‐ $40,000,000 $0.66R ‐ $0.60R = $42,000,000 R = $700,000,000 It seems highly unlikely the film will gross enough box office receipts to generate $700 million of revenue to Panther. Panther should select Contract B.
3‐47 (30 min.) 1.
3-106
Multi‐product breakeven, decision making.
Unit CM = USP ‐ UVC Breakeven point in 2011 (units)
= $600 ‐ $210 ‐ $60 = $330 = Fixed Costs ÷ Unit CM = $2,574,000 ÷ $330 = 7,800 units
Breakeven point in 2011 (in revenues) = 7,800 units $600 = $4,680,000 in sales revenues
or CM % = UCM ÷ USP = $330 ÷ $600 = 55% Breakeven point in 2011 in revenues = $2,574,000 ÷ 55% = $4,680,000
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Chapter 3
3‐47 (cont’d) 2.
3.
Breakeven point in 2012 (in units) Bonavista expects to sell 2.5 units of Surrey for every 1 unit of Shilo (10,000 ÷ 4,000) Unit Contribution Margin from Surrey = $600 ‐ $270 = $330 Unit Contribution Margin from Shilo = $350 ‐ $180 = $170 The contribution margin for the bundle is ($330 2.5 units) + ($170) = $995 Breakeven point = Fixed Costs ÷ Package CM = $2,574,000 ÷ $995 = 2,587 bundles or packages consisting of 2.5 Surrey and 1 Shilo Surrey 2.5 2,587 = 6,468 Shilo 1 2,587 = 2,587 Total = 9,055 Contribution margin percentage in 2011 = 55% (as calculated above) Contribution margin percentage in 2012 = CM per bundle/Revenue per bundle
CM % in 2012 = $995 ÷ [(2.5 $600) + ($350)] = $995 ÷ $1,850 = 53.78% The breakeven point in 2012 increases because fixed costs are the same in both years but the contribution margin generated by each dollar of sales revenue at the given product mix decreases in 2012 relative to 2011. 4. Despite the breakeven sales revenue being higher, I would advise the president to accept Dover’s offer. The breakeven points per se are irrelevant because I do not expect the company to operate in the region of the breakeven dollars. By accepting the offer, Bonavista can sell all the original Surrey model and sell the Shilo as well without incurring any more fixed costs.
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3‐47 (cont’d) Profits in 2012 with and without Shilo are expected to be as follows: Selling Price
Surrey $600
Shilo $350
Total
Units Total Sales Variable Costs CM Fixed Costs OI
10,000 $6,000,000
4,000 $1,400,000
14,000 $7,400,000
$2,700,000 $3,300,000 $ 2,574,000 $ 726,000
$720,000 $680,000 $ – $ 680,000
$3,420,000 $3,980,000 $2,574,000 $ 1,406,000
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Chapter 3
3‐48 (30 min.)
Choosing between compensation plans, operating leverage.
1. We can recast Marston’s income statement to emphasize contribution margin, and then use it to compute the required CVP parameters. Marston Corporation Income Statement For the Year Ended December 31, 2011 Using Sales Agents Using Own Sales Force Revenues $26,000,000 $26,000,000 Variable Costs Cost of goods sold—variable $11,700,000 $11,700,000 Marketing commissions 4,680,000 16,380,000 2,600,000 14,300,000 Contribution margin $9,620,000 $11,700,000 Fixed Costs Cost of goods sold—fixed 2,870,000 2,870,000 Marketing—fixed 3,420,000 6,290,000 5,500,000 8,370,000 Operating income $3,330,000 $ 3,330,000 Contribution margin percentage ($9,620,000 26,000,000; 37% 45% $11,700,000 $26,000,000) Breakeven revenues ($6,290,000 0.37; $8,370,000 0.45) $17,000,000 $18,600,000 Degree of operating leverage ($9,620,000 $3,330,000; $11,700,000 $3,330,000) 2.89 3.51
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3‐48 (cont’d) 2. The calculations indicate that at sales of $26,000,000, a percentage change in sales and contribution margin will result in 2.89 times that percentage change in operating income if Marston continues to use sales agents and 3.51 times that percentage change in operating income if Marston employs its own sales staff. The higher contribution margin per dollar of sales and higher fixed costs gives Marston more operating leverage, that is, greater benefits (increases in operating income) if revenues increase but greater risks (decreases in operating income) if revenues decrease. Marston also needs to consider the skill levels and incentives under the two alternatives. Sales agents have more incentive compensation and hence may be more motivated to increase sales. On the other hand, Marston’s own sales force may be more knowledgeable and skilled in selling the company’s products. That is, the sales volume itself will be affected by who sells and by the nature of the compensation plan. 3. Variable costs of marketing = 15% of Revenues Fixed marketing costs = $5,500,000 Variable Fixed Operating income = Revenues Variable Fixed marketing marketing manuf. costs manuf. costs costs costs Denote the revenues required to earn $3,330,000 of operating income by R, then: R ‐ 0.45R ‐ $2,870,000 ‐ 0.15R ‐ $5,500,000 = $3,330,000 R ‐ 0.45R ‐ 0.15R = $3,330,000 + $2,870,000 + $5,500,0 0.40R = $11,700,000 R = $11,700,000 0.40 = $29,250,000
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Chapter 3
3‐49 (20‐25 min.) Special‐order decision. 1.
Time spent on manufacturing bottles = 750,000 bottles ÷ 100 bottles per hour = 7,500 hours
So 10,000 ‐ 7,500 = 2,500 hours available for toys. Moulded plastic toy requires: 100,000 units ÷ 40 units per hour = 2,500 hours, so MPC has enough capacity to accept the toys order. Additional income from accepting the order is: $340,000 Revenue $3.40 100,000 Variable costs 2.70 100,000 270,000 Contribution margin 70,000 Fixed costs 24,000 Additional income $ 46,000 So MPC should accept the order since it has enough excess capacity to make the 100,000 toys. 2. Time spent on manufacturing bottles = 850,000 ÷ 100= 8,500 hours So 10,000 ‐ 8,500 = 1,500 hours available for toys. From requirement 1, the moulded plastic toy requires 2,500 hours and generates $46,000 in operating income. So if the toy offer is accepted, 1,000 hours (2,500 hours required ‐ 1,500 hours available) of bottle making will be forgone, equal to 100,000 bottles (100 bottles/hr. 1,000 hrs.): Operating income from accepting $46,000 Forgone contribution margin (100,000 bottles $0.30)* 30,000 Increase in operating income $16,000 So MPC should accept the special order. *CM = $0.55 ‐ $0.25 = $0.30
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3‐49 (cont’d) Without considering the fixed costs for the toy mould, the contribution per machine‐hour of the constrained resource for bottles and the special toy are as follows: Bottles Toys Contribution margin per unit $0.30 $0.70 Multiplied by units made in 1 machine‐hour 100 40 $ 28 Contribution margin per machine‐hour $30 This suggests that MPC should make as many bottles as it can rather than the special toys, because bottles generate a higher contribution margin per machine‐hour. So if MPC used the 1,500 hours available to it for making toys after using the 8,500 hours to make bottles, it would be able to make 1,500 40 = 60,000 toys and earn operating income of: Contribution margin 60,000 $0.70 $42,000 Fixed mould costs 24,000 Increase in operating income $18,000 The contribution margin earned covers the fixed costs of the mould, so MPC should make 850,000 bottles and 60,000 toys. 3. Time spent on manufacturing bottles = 900,000 ÷ 100 = 9,000 hours So 10,000 ‐ 9,000 = 1,000 hours available for toys. So if the toy offer is accepted, then 1,500 hours (2,500 hours required ‐ 1,000 hours available) of bottle capacity will be forgone = 150,000 bottles Contribution from accepting toy offer $ 46,000 (45,000) Forgone profits on bottles 150,000 $0.30 Increase (decrease) in operating income $ 1,000 So accept the special order.
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Chapter 3
3‐50 (25 min.)
CVP, sensitivity analysis.
Contribution margin per corkscrew = $4 ‐ 3 = $1 Fixed costs = $6,000 Units sold = Total sales ÷ Selling price = $40,000 ÷ $4 per corkscrew = 10,000 corkscrews 1. Sales increase 10% $44,000 Sales revenues 10,000 1.10 $4.00 33,000 Variable costs 10,000 1.10 $3.00 Contribution margin 11,000 Fixed costs 6,000 Operating income $ 5,000 2. Increase fixed costs $2,000; Increase sales 50% Sales revenues 10,000 1.50 $4.00 $60,000 Variable costs 10,000 1.50 $3.00 45,000 Contribution margin 15,000 Fixed costs ($6,000 + $2,000) 8,000 Operating income $ 7,000 3. Increase selling price to $5.00; Sales decrease 20% Sales revenues 10,000 0.80 $5.00 $40,000 Variable costs 10,000 0.80 $3.00 24,000 Contribution margin 16,000 Fixed costs 6,000 Operating income $10,000 4. Increase selling price to $6.00; Variable costs increase $1 per corkscrew $60,000 Sales revenues 10,000 $6.00 Variable costs 10,000 $4.00 40,000 Contribution margin 20,000 Fixed costs 6,000 Operating income $14,000 Alternative 4 yields the highest operating income. If TOP is confident that unit sales will not decrease despite increasing the selling price, it should choose alternative 4.
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3‐51 (15‐25 min.) Nonprofit institution. 1.
Let Q = Number of visits Revenues ‐ Variable costs ‐ Fixed costs $850,000 ‐ $16Q ‐ $500,000 $16Q Q
= = = =
0 0 $350,000 21,875 visits
= = = =
0 0 $265,000 16,562 visits
Revenues ‐ Variable costs ‐ Fixed costs $765,000 ‐ $16Q ‐ $500,000 $16Q Q
The reduction in service is more than the 10% reduction in the budget. Without restructuring operations, the quantity of service units must be reduced by 24.29% [(21,875 ‐ 16,562) ÷ 21,875] to stay within the budget. 3. Let V = Variable cost per visit $765,000 ‐ 21,875V ‐ $500,000 = 0 21,875V = $265,000 V = $12.11 ($12.114285)* Percentage drop: ($16 ‐ $12.114285*) ÷ $16 = 24.29% Regarding requirements 2 and 3, note that the decrease in service can be measured by a formula: % reduction in service = (% budget change) ÷ (% variable cost) The variable cost percentage is ($16 21,875) ÷ $850,000 = $350,000 ÷ $850,000 = 41.1765%* % reduction in service = 10% ÷ 41.1765% = 24.29% *The extra decimal places are used to minimize the rounding difference. Most will round to two decimals for the money and to 24%.
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Chapter 3
3‐52 (30 min.) 1.
CVP, nonprofit event planning.
Computation of fixed costs. Rental cost of venue Permits Chamber administration/marketing Entertainment
Hotel $2,700 0 5,000 4,000 $11,700
University $ 7,000 500 5,000 4,000 $16,500
Computation of contribution margin per person: Hotel Selling (ticket) price per person $175 Catering cost per person 110 Contribution margin per person $65
University $175 75 $100
Fixed costs Unit contribu tion m argin
Breakeven point =
Breakeven point for Hotel venue = $11,700 ÷ $65
= 180 tickets
Breakeven point for University venue = $16,500 ÷ $100 = 165 tickets 2. Operating Income Projections with 100 attendees and 250 attendees Hotel Attendees 100 250 Ticket Price $175 $175 Total Revenues $17,500 $43,750 VC @ $110 11,000 27,500 CM 6,500 16,250 11,700 Fixed Costs 11,700 Operating Income $(5,200) $4,550 University Attendees 100 250 Ticket Price $175 $175 Total Revenues $17,500 $43,750 VC @ $75 7,500 18,750 CM 10,000 25,000 Fixed Costs 16,500 16,500 $8,500 Operating Income $(6,500)
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3‐52 (cont’d) The Hotel venue has higher variable costs per person and lower fixed costs. In contrast, the University venue has lower variable costs per person and higher fixed costs. 3. Requirement 2 gives the operating income equation for each venue. Setting these two equations equal and solving for Q gives the level of ticket sales at which the operating incomes for the two venues are equal: $175Q ‐ $110Q ‐ $11,700 = $175Q ‐ $75Q ‐ $16,500 $100Q ‐ $65Q = $16,500 ‐ $11,700 $35Q = $4,800 Q = 137 (rounded) Proof: University Hotel Attendees 137.14286 137.14286 Ticket Price 175 175 Total Revenues 24,000 24,000 10,286 VC @ $110; $75 15,086 CM 8,914 13,714 Fixed Costs 11,700 16,500 Operating Income (2,786) (2,786) Above 137, the University venue will yield higher operating income (or a lower operating loss) than the hotel venue.
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Chapter 3
3‐53 (20‐30 min.) CVP under uncertainty. 1. (a) At a selling price of $120, the unit contribution margin is ($120 ‐ $60) = $60, and it will require the sale of ($240,000 ÷ $60) = 4,000 units to break even. The sales in dollars are $480,000 and there is a 2/3 probability of equaling or exceeding this sales level—that is, that 2/3 of the area under the graph exists between $480,000 and $720,000. (b) At a selling price of $84, the unit contribution margin is ($84 ‐ $60) = $24, and it will require the sale of ($240,000 ÷ $24) = 10,000 units to break even. At the lower price, the sales in dollars are $840,000 and there is a 2/3 probability of equaling or exceeding this sales volume. Therefore, if you seek to maximize the probability of showing an operating income, you are indifferent between the two strategies.
2.
Expected Expected Fixed Selling Variable operating price per unit cost per unit sales costs level income
At a selling price of $120: Expected revenues Expected operating income
= $540,000 ($120 4,500) = [($120 ‐ $60) 4,500] ‐ $240,000 = $30,000
At a selling price of $84: Expected revenues = $900,000 ($84 10,715) Expected operating income = [($84 ‐ $60) 10,715] ‐ $240,000 = $17,160 A selling price of $120 will maximize the expected operating income.
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3‐54 (30 min.)
Governance, CVP analysis.
Revenues – Variable costs Revenues
1.
Contribution margin percentage =
= ($8,000,000 ‐ $4,320,000) ÷ $8,000,000
= $3,680,000 ÷ $8,000,000
= 46%
Breakeven revenues
= Fixed Costs/CM Percentage
2.
= $3,900,000 ÷ .46 = $8,478,261 (rounded)
If variable costs are 48% of revenues, CM percentage equals 52% (100% ‐ 48%).
Breakeven revenues
=
3. 4.
= $3,900,000 ÷ .52 = $7,500,000
Revenues Variable costs (0.48 $8,000,000) Fixed costs Operating income
Fixed costs Contribu tion m argin percentage
$8,000,000 3,840,000 3,900,000 $ 260,000
Incorrect reporting of environmental costs with the goal of continuing operations is unethical. The management accountant could consider the following issues: Competence Clear reports using relevant and reliable information should be prepared. Preparing reports on the basis of incorrect environmental costs in order to make the company’s performance look better than it is violates competence standards. It is unethical for Walton not to report environmental costs in order to make the plant’s performance look good. Integrity The management accountant has a responsibility to avoid actual or apparent conflicts of interest and advise all appropriate parties of any potential conflict. Walton may be tempted to report lower environmental costs to please Bell and Klein and save the jobs of her colleagues. This action, however, violates the responsibility for integrity.
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3‐54 (cont’d) Objectivity The management accountant should require that information should be fairly and objectively communicated and that all relevant information should be disclosed. From a management accountant’s standpoint, underreporting environmental costs to make performance look good would violate the standard of objectivity. Walton should indicate to Bell that estimates of environmental costs and liabilities should be included in the analysis. If Bell still insists on modifying the numbers and reporting lower environmental costs, Walton should raise the matter with one of Bell’s superiors. If, after taking all these steps, there is continued pressure to understate environmental costs, Walton should consider resigning from the company and not engage in unethical behaviour. Walton can also argue the sustainability issue, that is, companies should act with a view to sustainable operations, from all perspectives, environmental, social responsibility, and economic.
3‐55 (20‐25 min.) Governance, CVP, cost analysis. 1.
(a) USP UVC UCM FC Q
= = = = = = =
$68 $28.50 ($19.25 + $9.25) $39.50 $25,000,000 FC ÷ UCM $25,000,000 ÷ $39.50 632,912 monthly treatments (rounded up)
(b) USP UVC UCM FC Q
= $68 = $19.25 = $48.75 = $25,000,000 = FC ÷ UCM = $25,000,000 ÷ $48.75 = 512,821 monthly treatments (rounded up)
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3‐55 (cont’d) 2. Diba believes that the $9.25 per monthly visit should be included in the variable costs per visit. His argument is that a product like “Vital Hair” has a positive probability of attracting product litigation. By excluding any allowance for the possible event, the assumption is that it will be zero. Diba faces an integrity issue. His report to the Executive Committee will understate his expected cost estimates when he takes Kelly’s advice. One possibility Diba should have explored is reporting the $19.25 per treatment variable cost in the breakeven computations as well as including qualifications in the report about possible product litigation costs. 3. Diba likely has been placed in a compromised situation. He may feel Kelly deliberately set him up to avoid the $9.25 amount being reported to the Executive Committee. At a minimum, he should directly confront Kelly with his concerns. If she is unresponsive, he faces a very tough dilemma. His options are: (a) Stay in his current position and be more determined next time to have his concerns registered. (b) Report his concerns to Kelly’s immediate superior. (c) Resign. If he selects (a), it would be useful to show Kelly the Code of Professional Ethics and stress how her behaviour has put him in a difficult ethical situation. 3-120
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Chapter 3
3‐56 (35 min.)
Deciding where to produce.
Selling price Variable cost per unit Manufacturing Marketing and distribution Contribution margin per unit (CMU) Fixed costs per unit Manufacturing Marketing and distribution Operating income per unit CMU of normal production CMU of overtime production ($64 – $3; $48 – $8) 1. Annual fixed costs: P ‐ ($49.00 400 units 240 days) M ‐ ($29.50 320 units 240 days) Breakeven volume: P ‐ ($4,704,000 $64) M ‐ ($2,265,600 $48) 2. Units produced and sold Normal annual volume (units) (400 × 240; 320 × 240) Units over normal volume (overtime) CM from normal production units (normal annual volume CMU normal production) (96,000 × $64; 76,800 × $48) CM from overtime production units (0; 19,200 $40) Total contribution margin Total fixed costs Operating income Total operating income
Peona Modine $150.00 $150.00 $72.00 $88.00 14.00 86.00 14.00 102.00 64.00 48.00 30.00 15.00 19.00 49.00 14.50 29.50 $ 15.00 $ 18.50 $64 $48
61
$4,704,000
40
$2,265,600
73,500 units 96,000
47,200 Units 96,000
96,000 0
76,800 19,200
$6,144,000
$3,686,400
0 6,144,000 4,704,000 $1,440,000
768,000 4,454,400 2,265,600 $2,188,800 $3,628,800
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3‐56 (cont’d) 3. The optimal production plan is to produce 120,000 units at the Peona plant and 72,000 units at the Modine plant. The full capacity of the Peona plant, 120,000 units (400 units × 300 days), should be used because the contribution from these units is higher at all levels of production than is the contribution from units produced at the Modine plant. Contribution margin per plant: Peona, 96,000 × $64 $ 6,144,000 Peona 24,000 × ($64 ‐ $3) 1,464,000 Modine, 72,000 × $48 3,456,000 Total contribution margin 11,064,000 Deduct total fixed costs 6,969,600 Operating income $ 4,094,400 The contribution margin is higher when 120,000 units are produced at the Peona plant and 72,000 units at the Modine plant. As a result, operating income will also be higher in this case since total fixed costs for the division remain unchanged regardless of the quantity produced at each plant.
COLLABORATIVE LEARNING PROBLEM
3‐57 (25 Min.) 1.
(CVP analysis and revenue mix)
Let A = Number of units of A to break even 5A = Number of units of B to break even 4A = Number of units of C to break even
$3.60A + $2.40(5A) + $1.20(4A) ‐ $306,000 = 0 A = 15,000 units of A 5A = 75,000 units of B 4A = 60,000 units of C Total = 150,000 units
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Chapter 3
3‐57 (cont’d) 2.
Contribution margin: A: 20,000 $3.60 = $72,000 B: 100,000 $2.40 = $240,000 C: 80,000 $1.20 = $96,000 $408,000 Operating Income = $408,000 ‐ $306,000 =
3.
$102,000
Contribution margin: A: 20,000 $3.60 = $72,000 B: 80,000 $2.40 = $192,000 C: 100,000 $1.20 = $120,000 $384,000 Operating Income = $384,000 ‐ $306,000 = $78,000 Let A = Number of units of A to break even 4A = Number of units of B to break even 5A = Number of units of C to break even
$3.60A + $2.40(4A) + $1.20(5A) ‐ $306,000 = 0 A = 15,938 units of A 5A = 63,752 units of B 4A = 79,690 units of C Total = 159,380 units
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CHAPTER 4 JOB COSTING
SHORT‐ANSWER QUESTIONS 4‐1 In a job costing system, shared indirect costs of customization are assigned to a distinct unit, batch, or product or service. In a process costing system there is little or no distinction among outputs. The cost of a product or service is obtained by using broad averages to assign costs to masses of similar outputs. 4‐2 Separating manufacturing overhead (MOH) into more than one cost pool may allow for better representation of cost and benefit. Sometimes this type of refinement reveals direct cause and effect relationships between a single MOH cost pool and a single cost driver. Where indirect inputs are shared unequally among distinct types of products, refining a single MOH cost pool into several may improve the accuracy of output accurate costing, pricing and prediction of profitability. 4‐3 An advertising campaign for Pepsi is likely to be very specific to that individual client. Job costing requires that all the specific aspects of each distinct job to be identified. In contrast, the processing of checking account withdrawals is similar for almost all transactions. Here, process costing can be used to compute the cost of each checking account withdrawal. 4‐4 The seven steps in job costing are: (1) identify the job that is the chosen cost object, (2) identify the direct costs of the job, (3) select the cost‐allocation bases to use for allocating indirect costs to the job, (4) identify the indirect costs associated with each cost‐allocation base, (5) compute the rate per unit of each cost‐allocation base used to allocate indirect costs to the job, (6) compute the indirect costs allocated to the job, and (7) compute the total cost of the job by adding all direct and indirect costs assigned to the job. 4‐5 Two major types of organizational elements that managers focus on in companies using job costing are (1) products or services (outputs), and (2) responsibility centres or departments (inputs). 4‐6 Three major source documents used in job‐costing systems are (1) job cost record or job cost sheet, a document that records and accumulates all costs assigned to a specific job, (2) materials requisition record, a document used to charge job cost records and departments for the cost of direct materials used on a specific job, and (3) labour‐time record, a document used to charge job cost records and departments for labour time used on a specific job.
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Chapter 4
4‐7
The main concern with the source documents of job‐cost records is the accuracy of the records. Problems of accuracy include recording either incorrect quantity or dollar amounts, materials recorded on one job being ʺborrowedʺ and used on other jobs, and the wrong job numbers being assigned to materials or labour inputs. 4‐8 Two reasons for using annual budget periods are: a) The numerator reason—the longer the time period, the lesser the influence of seasonal patterns, and b) The denominator reason—the longer the time period, the lesser the effect of variations in output levels on the allocation of fixed costs. 4‐9 Actual costing and normal costing differ in their use of actual or budgeted direct‐ or indirect‐cost rates: Actual Normal Costing Costing Direct‐cost rates Indirect‐cost rates
Actual rates Actual rates
Actual rates Budgeted rates
Both costing methods use the actual quantity of the direct‐cost input and the actual quantity of the cost‐allocation base. 4‐10 A construction firm can use job cost information (a) to determine the profitability of individual jobs, (b) to assist the bidding on future jobs, and (c) to evaluate professionals who are in charge of managing individual jobs. 4‐11 The statement is false. In a normal costing system, Manufacturing Overhead Control account will not, in general, equal the amounts in Manufacturing Overhead Allocated account. The Manufacturing Overhead Control account aggregates the actual overhead costs incurred while Manufacturing Overhead Allocated allocates overhead costs to jobs on the basis of a budgeted rate multiplied by the actual quantity of the cost‐ allocation base. Underallocation or overallocation of indirect (overhead) costs can arise because of: (a) Numerator reason—the actual overhead costs differ from the budgeted overhead costs, and (b) Denominator reason—the actual quantity used of the allocation base differs from the budgeted quantity. 4‐12 Debit entries to Work‐in‐Process Control represent increases in work in process. Examples of debit entries are: (a) direct materials used (credit to Materials Control), (b) direct manufacturing labour billed to job (credit to Wages Payable Control), and (c) manufacturing overhead allocated to job (credit Manufacturing Overhead Allocated).
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4‐13 Alternative ways to make end‐of‐period adjustments for underallocated or overallocated overhead are: a) Adjusted allocation approach: restating all entries for all jobs in the general ledger by using actual cost rates rather than budgeted cost rates. b) Proration based on the total amount of indirect costs allocated (before proration) in the ending balances of work in process, finished goods, and cost of goods sold or on total ending balances (before proration) in work in process, finished goods, and cost of goods sold. c) Year‐end write‐off to Cost of Goods Sold.
4‐14 A service company might use budgeted costs rather than actual costs to compute direct labour rates because it may be difficult to trace some costs to jobs as they are completed.
4‐15 Modern technology such as electronic data interchange (EDI) is helpful to managers because it provides them with quick and accurate product‐cost information that facilitates the management and control of jobs.
EXERCISES
4‐16 (10 min.) 1. 2. 3. 4. 5. 6. 7.
Terminology.
Proration actual cost allocation rate source document opportunity cost Cost tracing cost pool
4‐17 (10 min.) a. b. c. d. e. f. g. h. i. j. k.
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Job order costing, process costing.
Job costing Process costing Job costing Process costing (unless specialty) Job costing Process costing Job costing Job or process (depending on production) Process costing Process costing Job costing
l. m. n. o. p. q. r. s. t. u.
Job costing Process costing Job costing Job costing Job costing Job costing Process costing Job costing Process costing Job costing
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Chapter 4
4‐18 (20 min.)
Actual costing, normal costing, manufacturing overhead.
=
Budgeted manufacturing overhead costs Budgeted direct manufacturing labour costs
=
$2,210,000/$2,600,000
=
85% of Direct Labour Costs or $0.85 per $1 of Direct Labour
Bu d geted m anu factu ring overhead rate
1.
Actu al m anu factu ring
Actu al m anu factu ring overhead rate
=
overhead costs Actu al d irect m anu factu ring labou r costs
2.
=
$2,311,400/$2,540,000
=
91% of Direct Labour Costs or $0.91 per $1 of Direct Labour
Costs of Job 626 under actual and normal costing follow: a. Actual Costing Direct materials $ 38,000 Direct manufacturing labour costs 27,000 Manufacturing overhead costs $27,000 $0.91; $0.85 24,570 Total manufacturing costs of Job 626 $ 89,570
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b. Normal Costing $ 38,000 27,000 22,950 $ 87,950
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4‐18 (cont’d) Total m anu factu ring overhead Actu al m anu factu ring Bu d geted = overhead rate allocated u nd er norm al costing labou r costs
3.
Und erallocated m anu factu ring Actu al m anu factu ring Manu factu ring = – overhead overhead costs overhead allocated
= $2,540,000 0.85 = $2,159,000
= $2,311,400 – $2,159,000 = $152,400 There is no under‐ or overallocated overhead under actual costing because overhead is allocated under actual costing by multiplying actual manufacturing labour costs and the actual manufacturing overhead rate. This, of course, equals the actual manufacturing overhead costs. All actual overhead costs are allocated to products. Hence, there is no under‐ or overallocated overhead.
4.
Actual costing reflects the actual results incurred, while normal costing reflects expectations of the amount the overhead should be. Normal costing can be done in advance and thus can be used in pricing, planning, and cost management decisions.
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Chapter 4
4‐19 (25 min.) 1.
Job costing; actual, normal, and variation from normal costing.
Actual direct‐cost rate for professional labour = $58 per professional labour‐hour Actual indirect‐cost rate = $744,000/15,500 hours = $48 per professional labour‐hour Budgeted direct‐cost rate = $960,000/16,000 hours = $60 per professional labour‐hour Budgeted indirect‐cost rate = $720,000/16,000 hours = $45 per professional labour‐hour
Direct‐Cost Rate
Indirect‐Cost Rate
(a) Actual Costing $58 (Actual rate)
(b) Normal Costing $58 (Actual rate)
(c) Variation of Normal Costing $60 (Budgeted rate)
$48 (Actual rate)
$45 (Budgeted rate)
$45 (Budgeted rate)
2.
Direct Costs Indirect Costs Total Job Costs
(a) Actual Costing $58 120 = $ 6,960 48 120 = 5,760 $12,720
(b) (c) Normal Variation of Costing Normal Costing $58 120 = $ 6,960 $60 120 = $ 7,200 45 120 = 5,400 45 120 = 5,400 $12,360 $12,600
All three costing systems use the actual professional labour time of 120 hours. The budgeted 110 hours for the Pierre Enterprises audit job is not used in job costing. However, Chirac may have used the 110 hour number in bidding for the audit. The actual costing figure of $12,720 exceeds the normal costing figure of $12,360 because the actual indirect‐cost rate ($48) exceeds the budgeted indirect‐ cost rate ($45). The normal costing figure of $12,360 is less than the variation of normal costing (based on budgeted rates for direct costs) figure of $12,600, because the actual direct‐cost rate ($58) is less than the budgeted direct‐cost rate ($60).
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4‐20 (30 min.) 1a.
1b.
Job costing: actual, normal, and variation from normal costing.
Actual costing Direct‐cost rate = Actual professional labour costs ÷ Actual professional labour‐ hours = $1,320,000 ÷ 22,000 hours = $60 per professional hour Indirect‐cost rate = Actual support costs ÷ Actual professional labour‐hours = $2,400,000 ÷ 22,000 hours = $109.09 per professional hour
Normal costing Budgeted professional hours = Budgeted hours per lawyer Number of lawyers = 2,500 8 = 20,000 hours Direct‐cost rate = Actual professional labour costs ÷ Actual professional labour‐ hours = $1,320,000 ÷ 22,000 hours = $60 per professional hour
Indirect‐cost rate = Budgeted support costs ÷ Budgeted professional labour‐ hours = $2,000,000 ÷ 20,000 hours = $100 per professional hour 1c.
Variation from normal costing that uses budgeted rates for direct costs Budgeted direct‐cost rate = $1,100,000 ÷ 20,000 hours = $55 per professional hour Indirect‐cost rate = Budgeted support costs ÷ Budgeted professional labour‐ hours = $2,000,000 ÷ 20,000 hours = $100 per professional hour
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Chapter 4
4‐20 (cont’d) 2.
The costs of Ari Roos’ will under each method follow: a. Actual Costing Direct costs 4,000 hours $60 per hour $240,000 Indirect costs 4,000 hours $109.09 per hour 436,360 Total costs $676,360 b. Normal Costing Direct costs 4,000 hours $60 per hour $240,000 400,000 Indirect costs 4,000 hours $100 per hour Total costs $640,000 c. Variation from normal costing $220,000 Direct costs 4,000 hours $55 per hour Indirect costs 4,000 hours $100 per hour 400,000 Total costs $620,000
4‐21 (20 ‐30 min.) Job costing, normal, and actual costing. 1.
Budgeted indirect‐ = cost rate
Budgeted indirect costs Budgeted direct labour‐ hours
$8,000,000 =
160,000 hours
= $50 per direct labour‐hour
Actual indirect‐ cost rate
=
Actual indirect costs $6,888,000 = Actual direct labour‐hours 164,000 hours
= $42 per direct labour‐hour
These rates differ because both the numerator and the denominator in the two calculations are different—one based on budgeted numbers and the other based on actual numbers.
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4‐21 (cont’d) 2a.
Normal costing Direct costs Direct materials Direct labour Indirect costs Assembly support ($50 900; $50 1,010) Total costs
Laguna Mission Model Model $106,450 $127,604 36,276 41,410 142,726 169,014 45,000 50,500 $187,726 $219,514
2b.
3.
Actual costing Direct costs Direct materials $106,450 $127,604 Direct labour 36,276 41,410 142,726 169,014 Indirect costs Assembly support ($42 900; $42 1,010) 37,800 42,420 Total costs $180,526 $211,434 Normal costing enables Anderson to report a job cost as soon as the job is completed, assuming that both the direct materials and direct labour costs are known at the time of use. Once the 900 direct labour‐hours are known for the Laguna Model (June 2013), Anderson can compute the $187,726 cost figure using normal costing. Anderson can use this information to manage the costs of the Laguna Model job as well as to bid on similar jobs later in the year. In contrast, Anderson has to wait until the December 2013 year end to compute the $180,526 cost of the Laguna Model using actual costing.
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Chapter 4
4‐22 (10‐15 min.) Normal costing, manufacturing overhead 1.
2. 3.
Budgeted Manufacturing Overhead Rate Budgeted Manufacturing Overhead Costs = Budgeted Machine Hours = $1,500,000 ÷ 48,000 = $31.25 per machine‐hour Actual Manufacturing Overhead Costs =$1,605,000 Allocated Manufacturing Overhead Costs = Actual Machine‐Hours Budgeted MOH Rate = 49,200 $31.25 = $1,537,500 Actual MOH Costs – Allocated MOH Costs = Under/Overallocated MOH $1,605,000 ‐ $1,537,500 = $67,500 underallocated Cost of Goods Sold : Cost of Goods Sold before adjustment $2,260,000 Add underallocated overhead 67,500 Adjusted Cost of Goods Sold $2,327,500
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4‐23 (20‐30 min.) Job costing, accounting for manufacturing overhead, budgeted rates. 1.
Budgeted manufacturing overhead divided by allocation base:
$1,800,000 = $36 per machine‐hour 50,000 $3,600,000 Assembly overhead: = 180% of direct manuf. labour costs $2,000,000 $72,000 Machining department, 2,000 hours $36 Assembly department, 180% $15,000 27,000 Total manufacturing overhead allocated to Job 494 $99,000 2. Machining Assembly Actual manufacturing overhead $2,100,000 $ 3,700,000 Manufacturing overhead allocated, 55,000 $36 1,980,000 — 180% $2,200,000 — 3,960,000 Underallocated (Overallocated) $ 120,000 $ (260,000) Machining overhead :
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Chapter 4
4‐24 (20‐25 min.) Job costing, budgeted rates, unit costs. 1.
Budgeted MOH Rate = Budgeted Manufacturing Overhead Costs Budgeted Direct Labour‐Hours = $632,000/32,000 = $19.75 per direct labour‐hour Job X905: Direct Materials $13,200 Direct Labour
$10,120
Overhead Allocated–460 hours @ $19.75 Total
2.
$9,085 $32,405
# of units
500
Unit Cost
$64.81
# of Direct Labour‐Hours on Job X905
= Direct Labour Costs/Hourly Rate = $10,120/$22 = 460 hours
To achieve a margin of 25%, the selling price must be $86.42 (rounded up) USP – Unit Cost = 0.25USP USP – $64.81 = 0.25USP 0.75USP = $64.81 USP = $64.81/0.75 = $86.42 (rounded up)
3.
Under‐ or overallocated overhead = Actual Overhead – Allocated Overhead Under‐ or overallocated overhead = $656,125 – ($19.75 34,100) Under‐ or overallocated overhead = $656,125 ‐ $673,475 Overhead is overallocated by $17,350.
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4‐25 (20 min.) Computing indirect cost rates, services. 1a.
Budgeted Fixed Indirect Costs $ 60,000 60,000 60,000 60,000 $240,000
Budgeted Professional Labour Hours 24,000 12,000 4,800 7,200 48,000
Budgeted Fixed Indirect Cost Rate per Hour $ 2.50 5.00 12.50 8.33 $ 5.00
Budgeted Variable Indirect Cost Rate per Hour $ 12 12 12 12 $ 12
Budgeted Total Indirect Cost Rate per Hour $ 14.50 17.00 24.50 20.33 $ 17.00
Jan.‐March April‐June July‐Sept. Oct.‐Dec. 1b. 2a. All four jobs use 10 hours of professional labour time. The only difference in job costing is the indirect cost rate. The quarterly‐based indirect job cost rates are: Hansen: (10 × $14.50) = $145.00 Kai: (6 × $14.50) + (4 × $17.00) = $155.00 Patera: (4 × $17.00) + (6 × $24.50) = $215.00 Stevens: (5 × $14.50) + (2 × $24.50) + (3 × $20.33) = $182.49 Hansen Kai Patera Stevens Revenue , $78 × 10 $780 $780 $780 $780.00 Direct costs, $36 × 10 360 360 360 360.00 Indirect costs 145 155 215 182.49 Total costs 505 515 575 542.49 Operating income $275 $265 $205 $237.51 2b. Using annual‐based indirect job cost rates, the operating income will be the same for all four customers: Revenue $78 × 10 = $780 Direct costs $36 × 10 = 360 Indirect costs $17 × 10 = 170 Operating income $250
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Chapter 4
4‐25 (cont’d) 3.
All four jobs use 10 hours of professional labour time. Using the quarterly‐based indirect cost rates, there are four different operating incomes as the work done on them is completed in different quarters. In contrast, using the annual indirect cost rate, all four jobs have the same operating income. All these different operating income figures for jobs with the same number of professional labour‐ hours are due to the allocation of fixed indirect costs. Note that basing rates on the quarterly indirect cost rate would unnecessarily distort operating income.
4‐26 (20‐30 min.) Job costing, journal entries. This answer assumes COGS given ($4,020) does not include the write‐off of overallocated manufacturing overhead. 1.
(1) Materials Control Accounts Payable Control (2) Work‐in‐Process Control Materials Control (3) Manufacturing Overhead Control Materials Control (4) Work‐in‐Process Control Manufacturing Overhead Control Wages Payable Control (5) Manufacturing Overhead Control Accumulated Amortization––buildings and manufacturing equipment (6) Manufacturing Overhead Control Miscellaneous accounts (7) Work‐in‐Process Control Manufacturing Overhead Allocated (1.60 $1,300 = $2,080) (8) Finished Goods Control Work‐in‐Process Control (9) Accounts Receivable Control (or Cash) Revenue (10) Cost of Goods Sold Finished Goods Control
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800
550 2,080
800 710 100 2,200 400 550 2,080
4,120 8,000 4,020
4,120 8,000 4,020
710 100 1,300 900 400
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4‐26 (cont’d) (11) Manufacturing Overhead Allocated Manufacturing Overhead Control Cost of Goods Sold
2.
2,080
1,950 130
Materials Control 100 (2) Issues 800 (3) Issues
Bal. 12/31/2012 (1) Purchases Bal. 12/31/2013
90
710 100
Work‐in‐Process Control 60 (8)Goods completed 710 1,300 2,080
Bal. 12/31/2012 (2) Direct materials (4) Direct manuf. labour (7) Manuf. overhead Allocated Bal. 12/31/2013
30
4,120
Bal. 12/31/2012 (8) Goods completed Bal. 12/31/2013
Finished Goods Control 500 (10) Goods sold 4,120 600
4,020
(10) Goods sold
Cost of Goods Sold 4,020 (11) Adjust for overallocation
Bal. 12/31/2013
3,890
130
(3) (4) (5) (6)
Manufacturing Overhead Control Indirect materials 100 (11) To close Indirect manuf. labour 900 Amortization 400 Miscellaneous 550
Bal. 4–138
0
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1,950
Chapter 4
4‐26 (cont’d) Manufacturing Overhead Allocated 2,080 (7) Manuf. overhead 2,080 allocated
(11) To close
Bal.
0
4‐27 (45 min.) 1.
Job costing, journal entries.
Amounts in millions (1) Materials Control Accounts Payable Control (2) Work‐in‐Process Control Materials Control (3) Manufacturing Overhead Control Materials Control (4) Work‐in‐Process Control Wages Payable Control (5) Manufacturing Overhead Control Wages Payable Control (6) Manufacturing Overhead Control Accumulated Amortization (7) Manufacturing Overhead Control Various Liabilities (8) Work‐in‐Process Control Manufacturing Overhead Allocated* (9) Finished Goods Control Work‐in‐Process Control (10a) Cost of Goods Sold Finished Goods Control (10b) Accounts Receivable Control (or Cash) Revenue *Budgeted Manufacturing Overhead Rate = Allocated MOH
238 194 27 123 19 21 9 72.9 374.3 368.4 512
238 194 27 123 19 21 9 72.9 374.3 368.4 512
Budgeted MOH Cost Budgeted Machine Hours
= $73,500,000 ÷ 980,000 = $75.00 per machine‐hour = $75 972,000 = $72,900,000
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4‐27 (cont’d) The posting of entries to T‐accounts is: Materials Control Bal. 6 (2) 194 (1) 238 (3) 27
Bal. Bal. (9) Bal.
23
Finished Goods Control 7.2 (10a) 374.3 13.10
Bal. (2) (4) (8) Bal.
368.4
Work‐in‐Process Control 1.8 (9) 374.3 194.0 123.0 72.9 17.40
(10a) (11)
Cost of Goods Sold 368.4 3.1
(11)
Manufacturing Overhead Allocated 72.9 (8)
(3) (5) (6) (7)
Manufacturing Overhead Control 27 (11) 19 21 9 Accounts Payable Control (1)
76
238
Wages Payable Control (4) (5)
72.9
123 19
Accumulated Amortization (6)
21
Various Liabilities (7)
Accounts Receivable Control (10b) 512 The ending balance of Work‐in‐Process Control is $17.40. 2. (11) Manufacturing Overhead Allocated Cost of Goods Sold Manufacturing Department Overhead Control
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9
Revenue (10b)
72.9 3.1
512
76.0
Chapter 4
4‐28 (20 min.)
Job costing, unit cost, ending work‐in‐process.
1. Budgeted MOH = = = = =
Budgeted Manufacturing Overhead Costs Budgeted Labour Hours Budgeted Annual MOH Budgeted Annual DL Hours $3,780,000 ÷ [35,000 ×12] $3,780,000 ÷ 420,000 $9 per direct labour‐hour
Cost of Job A701: Direct materials $ 80,000 Direct manufacturing labour 287,000 Manufacturing overhead allocated 184,500* Total cost $551,500 *Budgeted rate $9 20,500 direct manufacturing labour‐hours = $184,500
2.
Per‐unit cost
=
3. 4.
= $551,500 ÷ 2,500 = $220.60 per unit
Total cost of the job N u m ber of u nits in the job
Finished Goods Control 551,500 Work‐in‐Process Control 551,500 The work in process consists of Job A702 only: Direct materials Direct manufacturing labour Manufacturing overhead allocated Work in process May 31
$ 92,000 219,000 131,400† $442,400
†Budgeted rate of $9 14,600 direct manufacturing labour‐hours = $131,400
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4‐29 (25 min.)
Job order costing, various cost drivers.
1. Budgeted Manufacturing Overhead Rate (Budgeted MOH Rate) a) Cost driver is direct labour‐hours Budgeted MOH Rate = Budgeted MOH/Budgeted DL Hours Budgeted MOH Rate = $435,000/17,400 = $25 per Direct Labour‐hour b) Cost driver is direct labour cost Budgeted MOH Rate = Budgeted MOH/Budgeted DL Dollars Budgeted MOH Rate = $435,000/(17,400$20.00) Budgeted MOH Rate = $435,000/$348,000 Budgeted MOH Rate = 125% of Direct Labour costs c) Cost driver is machine‐hours Budgeted MOH Rate = Budgeted MOH/Budgeted Machine‐Hours Budgeted MOH Rate = $435,000/72,500 Budgeted MOH Rate = $6 per Machine‐Hour 2. Calculation of Over‐ or Underallocated Manufacturing Overhead Cost Driver Direct Labour‐Hours Direct Labour Cost Machine‐Hours Actual driver used 17,630 $345,548* 73,010 OH Rate $25 per DL Hour 125% of DL Cost $6 per MH Allocated OH $440,750 $431,935 $438,060 Actual OH $434,300 $434,300 $434,300 Over‐ or $6,450 OVER ($2,365) UNDER $3,760 OVER underallocated *$19.60 × 17,630
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Chapter 4
4‐30 (40 min.)
Journal entries, T‐accounts, and source documents.
1. (1) Direct Materials Control 124,000 Accounts Payable Control 124,000 Source Document: Purchase Invoice, Receiving Report Subsidiary Ledger: Direct Materials Record, Accounts Payable (2) Work‐in‐Process Control a 122,000 Direct Materials Control 122,000 Source Document: Material Requisition Records, Job Cost Record Subsidiary Ledger: Direct Materials Record, Work‐in‐Process Inventory, Records by Jobs (3) Work in Process Control 80,000 Manufacturing Overhead Control 54,500 Wages Payable Control 134,500 Source Document: Labour Time Records, Job Cost Records Subsidiary Ledger:, Manufacturing Overhead Records, Employee Labour Records, Work‐in‐Process Inventory Records by Jobs (4) Manufacturing Overhead Control 129,500 Salaries Payable or AP Control 20,000 Accounts Payable Control 9,500 Accumulated Amortization Control 30,000 Rent Payable Control 70,000 Source Document: Amortization Schedule, Rent Schedule, Maintenance wages due, Invoices for miscellaneous factory overhead items Subsidiary Ledger: Manufacturing Overhead Records (5) Work‐in‐Process Control 200,000 Manufacturing Overhead Allocated 200,000 (80,000 $2.50) Source Document: Labour Time Records, Job Cost Record Subsidiary Ledger: Work‐in‐Process Inventory Records by Jobs
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4‐30 (cont’d) (6) Finished Goods Control b 387,000 Work‐in‐Process Control 387,000 Source Document: Job Cost Record, Completed Job Cost Record Subsidiary Ledger: Work‐in‐Process Inventory Records by Jobs, Finished Goods Inventory Records by Jobs 432,000 (7) Cost of Goods Sold c Finished Goods Control 432,000 Source Document: Sales Invoice, Completed Job Cost Record Subsidiary Ledger: Finished Goods Inventory Records by Jobs (8) Manufacturing Overhead Allocated 200,000 Manufacturing Overhead Control 184,000 Cost of Goods Sold 16,000 Source Document: Prior Journal Entries (9) Administrative Expenses 7,000 Marketing Expenses 120,000 Salaries Payable Control 30,000 Accounts Payable Control 90,000 Accumulated Amortization, Office Equipment 7,000 Source Document: Amortization Schedule, Marketing Payroll Request, Invoice for Advertising, Sales Commission Schedule. Subsidiary Ledger: Employee Salary Records, Administration Cost Records, Marketing Cost Records. Materials used = Beginning DM inventory + Purchases ‐ Ending DM inventory = 9,000 + 124,000 ‐ 11,000 = 122,000 bCost of goods manufactured = Beginning WIP inv. + Manufacturing cost ‐ Ending WIP inv. = 6,000 + (122,000 + 80,000 + 200,000) – 21,000 = 387,000 cCost of Goods Sold = Beginning FG inv. + Cost of goods manuf. – Ending FG inv. = 69,000 + 387,000 – 24,000 = 432,000 a
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Chapter 4
4‐30 (cont’d) 2.
T‐accounts
Bal. 1/1/2013 (1) Purchases Bal. 12/31/2013
Direct Materials Control 9,000 (2) Materials used 124,000
122,000
11,000
Bal. 1/1/2013 (2) Direct materials used (3) Direct manuf. labour (5) Manuf. overhead allocated Bal. 12/31/2013
Work‐in‐Process Control 6,000 (6) Cost of goods 122,000 manufactured 80,000 200,000
387,000
21,000
Bal. 1/1/2013 (6) Cost of goods manuf. Bal. 12/31/2013
Finished Goods Control 69,000 (7) Cost of goods sold 387,000
432,000
24,000
(7) Goods sold
Cost of Goods Sold 432,000 (8) Adjust for overallocation
416,000
16,000
Manufacturing Overhead Control (3) Indirect labour 54,500 (8) To close (4) Supplies 20,000 (4) Miscellaneous 9,500 (4) Amortization 30,000 (4) Rent 70,000 Bal.
184,000
0
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4‐30 (cont’d)
(8) To close
Manufacturing Overhead Allocated 200,000 (5) Manuf. overhead allocated
Bal.
200,000 0
4‐31 (10‐15 min.) Accounting for manufacturing overhead. 1. 2.
Budgeted manufacturing overhead rate = $4,180,000/190,000 = $22 per machine‐hour Work‐in‐Process Control 4,224,000 Manufacturing Overhead Allocated 4,224,000 (192,000 machine‐hours $22 = $4,224,000)
3.
$4,224,000 – $4,230,000 = $6,000 underallocated, an insignificant amount.
Manufacturing Overhead Allocated 4,224,000 Cost of Goods Sold 6,000 Manufacturing Overhead Control 4,230,000 4‐32 (30 min.) Proration of overhead. 1. Budgeted manufacturing overhead Budgeted cost manufacturing = overhead rate
Budgeted direct mfg. labour cost
= 2. 4–146
$100,000 $200,000
= 50% of direct manufacturing labour cost
Overhead allocated = 50% × Actual direct manufacturing labour cost = 50% × $220,000 = $110,000 Overallocated plant overhead = Actual plant overhead costs – Allocated plant overhead costs = $106,000 – $110,000 = ‐$4,000 Overallocated plant overhead = ‐$4,000 Copyright © 2013 Pearson Canada Inc.
Chapter 4
4‐32 (cont’d) 3a. All overallocated plant overhead is written off to cost of goods sold. Both work in process (WIP) and finished goods inventory remain unchanged. Proration of $4,000 Dec. 31, 2013 Dec. 31 Balance Overallocated Balance (Before Proration) Manuf. Overhead (After Proration) Account (1) (2) (3) = (1) – (2) $ 0 $ 50,000 WIP $ 50,000 Finished Goods 240,000 0 240,000 Cost of Goods Sold 560,000 4,000 556,000 $4,000 $846,000 Total $850,000 3b. Overallocated plant overhead prorated based on ending balances:
Account WIP Finished Goods Cost of Goods Sold Total
3c.
Dec. 31 Balance (Before Proration) (1) $50,000 240,000 560,000 $850,000
Balance as a Percent of Total (2) = (1) ÷ $850,000 0.0588 0.2824 0.6588 1.0000
Proration of $4,000 Overallocated Manuf. Overhead (3) = (2) $4,000 0.0588 $4,000 =$ 235 0.2824 $4,000 = 1,130 0.6588 $4,000 = 2,635 $4,000
Dec. 31, 2013 Balance (After Proration) (4) = (1) – (3) $49,765 238,870 557,365 $846,000
Overallocated plant overhead prorated based on 2012 overhead in ending balances:
Account WIP Finished Goods Cost of Goods Sold Total
Dec. 31, Balance (Before Proration) (1) $50,000
Allocated MOH in Dec. 31, Balance (2) $10,000a
240,000 560,000 $850,000
30,000b
0.2727
0.2727 × $4,000 =$1,091
70,000c $110,000
0.6364 1.0000
0.6364 $4,000 = $2,545 557,455 $4,000 $846,000
Proration of $4,000 Allocated MOH in Overallocated Dec. 31 Balance Manuf. Overhead as a % of Total (4) = (3) $4,000 (3) = (2) ÷ $110,000 0.0909 0.0909 × $4,000 = $364
Dec. 31, 2013 Balance (After Proration) (5) = (1) – (4) $ 49,636 238,909
Overhead allocated = Direct manuf. labour cost ×50% = $20,000; 60,000; 140,000 × 50%
a,b,c
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4‐32 (cont’d) 4.
Writing off all of the overallocated plant overhead to Cost of Goods Sold (CGS) is usually warranted when CGS is large relative to Work‐in‐Process and Finished Goods Inventory and the overallocated plant overhead is immaterial. Both these conditions apply in this case. ROW should write off the $4,000 overallocated plant overhead to Cost of Goods Sold Account.
4‐33 (25 min.)
Job costing, solving for unknowns.
Summary of unknowns. See Schedule below a. Direct materials purchased $653,000 b. Direct labour $498,750 c. Manufacturing overhead allocated $299,250 d. Cost of Goods Manufactured $1,579,000 e. Cost of Goods Sold $1,556,000 Schedule: Osprey Ltd. Schedule of Cost of Goods Manufactured & Sold for the year ending … Beginning direct materials Given $193,000 Add purchases [$684,000‐$193,000+$162,000] $653,000 Less ending direct materials Given ($162,000) Direct materials used Given $684,000 Direct labour See below $498,750 Manufacturing overhead allocated 60% of direct labour $299,250 Total manufacturing costs incurred $1,482,000 Add beginning work in process Given $204,000 Less ending work in process Given ($107,000) Cost of goods manufactured [$1,482,000+$204,000‐$107,000] $1,579,000 Add beginning finished goods Given $225,000 Less ending finished goods Given ($248,000) Cost of Goods Sold [$1,579,000+$225,000‐$248,000] $1,556,000 Total manufacturing costs incurred = Direct materials + Direct labour + MOH allocated Let X = Direct labour $1,482,000 = $684,000 + X + 0.6X $798,000 = 1.6X X = $498,750 If Direct labour = $498,750, then MOH allocated = 0.60$498,750 = $299,250
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PROBLEMS
4‐34 (25 min.) 1. 2. 3.
Job costing procedures
Taylor: Fixed costs = $82,500 (1,500 MH ÷ 2,000 MH = 0.75; 0.75 $110,000 = $82,500) Operating income = $3,300 ($132,000 ‐ $46,200 ‐ $82,500 = $3,300) Operating margin = 2.5% ($3,300 ÷ $132,000 = 0.025). Kelly: Fixed costs = $27,500 (500 MH ÷ 2,000 MH = 0.25; 0.25 x $110,000 = $27,500) Operating income = $7,700 ($88,000 ‐ $52,800 ‐ $27,500 = $7,700) Operating margin = 8.75% ($7,700 ÷ $88,000 = 0.0875). Broadway should not drop the Kelly Corporation business as the following analysis shows. Loss in revenue from dropping Kelly Savings in costs: Variable costs Fixed costs 20% $110,000 Total savings in costs Effect on operating income
$(88,000) 52,800 22,000 74,800 $(13,200)
Broadway Printers would be worse off by $13,200 if it drops the Kelly Corporation business. If Broadway accepts the additional business from Kelly, it would take an additional 500 hours of machine time. If Broadway accepts all of Kelly’s and Taylor’s business for February, it would require 2,500 hours of machine time (1,500 hours for Taylor and 1,000 hours for Kelly). Broadway only has 2,000 hours of machine capacity. It must therefore choose how much of the Taylor and Kelly business to accept. If Broadway accepts any additional business from Kelly, it must forgo some of Taylor’s business. To maximize operating income, Broadway should maximize contribution margin per unit of the constrained resource. (Fixed costs will remain unchanged at $110,000, whatever business Broadway chooses to accept in February, and is therefore irrelevant.) The contribution margin per unit of the constrained resource for each customer in January is:
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4‐34 (cont’d) Revenue Variable Costs Contribution margin Contribution margin per machine hour:
Taylor Corporation $132,000 46,200 $ 85,800
Kelly Corporation $88,000 52,800 $ 35,200
Taylor = $85,800/1,500 = $57.20 Kelly = $35,200/500 = $70.40 Since the $88,000 of additional Kelly business in February is identical to jobs done in January, it will also have a contribution margin of $70.40 per machine hour, which is greater than the contribution margin of $57.20 per machine hour from Taylor. To maximize operating income, Broadway should first allocate all the capacity needed to take the Kelly Corporation business (1,000 machine hours) and then allocate the remaining 1,000 (2,000 – 1,000) machine hours to Taylor. Broadway’s operating income in February would then be $17,600 as shown below, greater than the $11,000 operating income in January. Contrib. margin per machine hour Machine hours Contribution margin Fixed Costs Operating income
Taylor Corporation $ 57.20
Kelly Corporation $70.40
1,000 $57,200
1,000 $70,400
Total $127,600 110,000 $ 17,600
Alternatively, we could present Broadway’s operating income by taking 2/3 (1,000 ÷ 1,500 machine hours) of Taylor’s January revenue and variable costs, and doubling (1,000 ÷ 500 machine hours) Kelly’s January revenue and variable costs.
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Taylor Corporation $ 88,000 30,800 $57,200
Kelly Corporation $176,000 105,600 $70,400
Revenue Variable Costs Contribution margin Fixed Costs
Total $264,000 136,400 127,600 110,000
Operating income
$ 17,600
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Chapter 4
4‐34 (cont’d) The problem indicated that Broadway could choose to accept as much of the Taylor and Kelly business for February as it wants. However, some students may raise the question that Broadway should think more strategically before deciding what to do. For example, how would Taylor react to Broadway’s inability to satisfy its needs? Will Kelly continue to give Broadway $176,000 of business each month or is the additional $88,000 of business in February a special order? For example, if Kelly’s additional work in February is only a special order and Broadway wants to maintain a long‐term relationship with Taylor, it may in fact prefer to turn down the additional Kelly business. It may feel that the additional $6,600 in operating income in February is not worth jeopardizing Taylor’s long‐ term relationship. Other students may raise the possibility of Broadway accepting all the Taylor and Kelly business for February if it can subcontract some of it to another reliable, high‐quality printer.
4‐35 (2025 min.) Disposition of underallocated or overallocated overhead. 1. 4.
Calculation of Over‐ or Underallocated Manufacturing Overhead Under‐ or Overallocated MOH = Actual MOH – Allocated MOH Under‐ or Overallocated MOH = $337,000 ‐ $302,000 = $35,000 Underallocated Proration Schedule Allocated Calculation % Proration of $35,000 of MOH (Before under allocated Overhead Proration) WIP $52,246 [52,246/302,000 ] 17.3% 0.173 x $35,000 = $6,055 Finished Goods $75,802 [75,802/302,000] 25.1% 0.251 x $35,000 = $8,785 CGS $173,952 [173,952/302,000] 57.6% 0.576 x $35,000 = $20,160 Total $302,000 100.0% $35,000 Journal Entry if written off to CGS: Dr. CGS $35,000 Dr. MOH Allocated $302,000 Cr. MOH Control $337,000 Journal Entry if prorated: Dr. Cost of Goods Sold $20,160 Dr. Work in Process Inventory $6,055 Dr. Finished Goods Inventory $8,785 Dr. MOH Allocated $302,000 Cr. MOH Control $337,000
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4‐35 (cont’d) 3.
For this company, the difference between the two methods may be significant because cost of goods sold only represents 57.6% of the unadjusted balances of the three accounts (Work in Process, Finished Goods and Cost of Goods Sold). As a result, the two methods would result in a difference of $14,840 ($35,000 ‐ $20,160) in reported income (income would be higher under proration). Under proration, $14,840 is recorded in inventories and appears on the Balance Sheet instead of being written off to the Income Statement as an increase to Cost of Goods Sold.
4‐36 (15 min.)
Job costing, law firm.
Bu d geted professional = labou r-hou r d irect-cost rate
1. 2.
= = Bu d geted ind irectcost rate
=
Bu d geted total d irect labou r com pensation Bu d geted total d irect labou r-hou rs
$104,000/1,600 $65 per professional labour‐hour Bu d geted total costs in the ind irect-cost pool Bu d geted total professional labou r-hou rs
= $2,200,000/[25 1,600 hours] = $2,200,000/40,000 = $55 per professional labour‐hour Richardson Punch 3. Direct costs: Professional labour, $65 100; $65 150 $ 6,500 $ 9,750 Indirect costs: Legal support, $55 100; $55 150 5,500 8,250 $12,000 $18,000
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4‐37 (25‐30 min.) Job costing with two direct and two indirect cost categories, law firm. 1. Budgeted compensation/professional Budgeted hours of billable time per professional Budgeted direct‐cost rate
Professional Partner Labour $ 200,000 ÷ 1,600 $125 per hour
2. Budgeted total costs Divided by budgeted quantity of allocation base Budgeted indirect cost rate
Professional Manager Labour $80,000 ÷ 1,600 $50 per hour
General Support $1,800,000 ÷ 40,000 hours $45 per hour
Professional hours = 25 1,600 hours = 40,000 hours Partner hours = 5 1,600 hours = 8,000 hours 3. Richardson Direct costs: Professional partners, $125 60; $125 30 $7,500 Professional manager, $50 40; $50 120 2,000 Direct costs $ 9,500 Indirect costs: General support, $45 100; $45 150 4,500 Admin. support, $50 60; $50 30 3,000 Indirect costs 7,500 Total costs $17,000 4. Single direct ‐ Single indirect (from Problem 4–36) Multiple direct – Multiple indirect (from requirement 3 of Problem 4‐37) Difference
Richardson $12,000 17,000 $ 5,000 undercosted
Administration Support $400,000 ÷ 8,000 hours $50 per hour
Punch
$3,750 6,000
$ 9,750
6,750 1,500 8,250 $18,000 Punch $18,000 18,000 $ 0 no change
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4‐37 (cont’d) The Richardson and Punch jobs differ in their use of resources. The Richardson job has a mix of 60% partners and 40% manager, while Punch has a mix of 20% partners and 80% associates. Thus, the Richardson job is a relatively high user of the more costly partner‐related resources (both direct partner costs and indirect partner secretarial support). The refined‐costing system increases the reported cost in Problem 4‐36 for the Richardson job by 41.7% (from $12,000 to $17,000). 4‐38 (20 min.) Normal costing, overhead allocation, working backwards. 1.
Manufacturing overhead allocated
= $5,175,000
Manufacturing overhead is allocated at 180% of direct manufacturing labour costs.
Manufacturing overhead allocated
manufacturing = 180% Directlabour costs
That is,
manufacturing = 1.8 Directlabour costs
manufacturing Hence, Directlabour costs
$5,175,000
= $5,175,000/1.8 = $2,875,000
2.
Manufacturing Costs Incurred = Direct Materials + Direct Labour + MOH Allocated
$9,732,500 Direct Materials
3.
Note the structure of entries made to the Work‐in‐Process T‐account
= Direct Materials + $2,875,000 + $5,175,000 = $1,682,500
Beginning balance, 1‐1‐2013 Manufacturing costs Ending balance, 12‐31‐2013
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Work in Process xxx Costs of goods manufactured xxx (transferred to finished goods) xxx
xxx
Beg. WIP + Manufacturing Costs – Cost of Goods Manufactured = Ending WIP $236,000 + $9,732,500 ‐ $9,612,200 = Ending WIP Ending WIP = $356,300
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Chapter 4
4‐39 (40 min.)
Disposition of overhead overallocation or underallocation, two indirect cost pools.
1.
Budgeted manufacturing overhead cost rate for the Machining Department
=
Budgeted manufacturing overhead costs in the Machining Department Budgeted machine-hours in the Machining Department
= =
$5,850,000 ÷ 90,000 $65 per machine‐hour
Budgeted manufacturing overhead cost rate for the Assembly Department
=
Budgeted manufacturing overhead costs in the Assembly Department Budgeted direct manufacturing labour-hours in the Assembly Department
= $7,812,000 ÷ 124,000 = $63 per direct manufacturing labour‐hour 2. Machining Department Total actual machine‐hours = 69,000 + 6,900 + 16,100 = 92,000 machine‐hours overhead Manufacturing allocated
= 92,000 $65 = $5,980,000
Over/Underallocated MOH
manufacturing Manufacturing overhead = Actual – overhead costs allocated
= $5,470,000 – $5,980,000
Assembly Department
= $510,000 OVERALLOCATED
Total actual direct manufacturing labour-hours
= 83,200 + 12,800 + 32,000 = 128,000
overhead Manufacturing allocated
= 128,000 $63 = $8,064,000
Over/Underallocated MOH
manufacturing Manufacturing overhead – = Actual overhead costs allocated
= $8,234,000 – $8,064,000
= $170,000 UNDERALLOCATED
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4‐39 (cont’d) 2.
a.
Write‐off to Cost of Goods Sold leads to (i) lower Cost of Goods Sold of $510,000 as a result of overallocation of manufacturing overhead in the Machining Department (ii) higher Cost of Goods Sold of $170,000 as a result of underallocation of manufacturing overhead in the Assembly Department. Hence,
Cost of Goods Sold = $21,600,000 – $510,000 + $170,000 = $21,260,000 b.
Proration based on ending balances (before proration) in Work in Process, Finished Goods, and Cost of Goods Sold.
Account balances in each account after proration follows:
Account (1) Work in Process Finished Goods Cost of Goods Sold
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Account Balance (2) $7,600,000 (23.75%) 2,800,000 (8.75%) 21,600,000 (67.50%) (32,000,000)
Proration of ($510,000) Overallocated Overhead in Machining Dept. (3) 0.2375 ($510,000) =($121,125) 0.0875 ($510,000) = ($44,625) 0.675 ($510,000) =($344,250) ($510,000)
Proration of $170,000 Underallocated Overhead in Assembly Dept. (4) 0.2375 $170,000 = $40,375 0.0875 $170,000 = $14,875 0.675 $170,000 = $114,750 $170,000
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Account Balance (after Proration) (5) = (2) + (3) + (4) $7,519,250 $2,770,250 $21,370,500 $31,660,000
Chapter 4
4‐39 (cont’d)
c.
Proration based on the overhead allocated (before proration) in the ending balances of Cost of Goods Sold, Finished Goods, and Work in Process for each Department follows.
Machining Department
Account (1) Work in process Finished goods Cost of goods sold
Overhead Costs Allocated to Each Account in Machining Department Proration of ($510,000) Using Budgeted Machine‐Hour Rate Overallocated Actual Machine‐hours Overhead (2) (3) $6516,100 = $1,046,500 (17.5%) 0.175 ($510,000) = ($89,250) $656,900 = 448,500 (7.5%) 0.075 ($510,000) = ($38,250) $6569,000 = 4,485,000 (75.0%) 0.75 ($510,000) = ($382,500) $5,980,000 100% ($510,000)
Assembly Department
Account (1) Work in process Finished goods Cost of goods sold
Overhead Costs Allocated to Each Account in Assembly Department Using Budgeted Direct Manuf. Labour‐hour Rate Actual Direct Manuf. Labour‐hours (2) $6332,000 = $2,016,000 (25%) $6312,800 = 806,400 (10%) $6383,200 = 5,241,600 (65%) $8,064,000 (100%)
Proration of $170,000 Underallocated Assembly Overhead (3) 0.25 $170,000 = $42,500 0.10 $170,000 = 17,000 0.65 $170,000 = 110,500 $170,000
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4‐39 (cont’d) Account balances in each account after proration of overallocated Machining Department costs and underallocated Assembly Department costs follow.
Account (1)
Work in process Finished goods Cost of goods sold
3.
Account Balance (before) Proration) (2)
Prorated ($510,000) of Overallocated Machining Department Overhead (calculated earlier) (3)
$7,600,000 2,800,000 21,600,000 $32,000,000
($89,250) (38,250) (382,500) ($510,000)
$ 42,500 17,000 110,500 $170,000
Account Balance (after Proration) (5)=(2)+(3)+(4) $ 7,553,250 2,778,750 21,328,000 $31,660,000
If the purpose is to report the most accurate inventory and cost of goods sold figures, the preferred method is to prorate based on the manufacturing overhead allocated amount in the inventory and cost of goods sold accounts (as in requirement 2c). Note, however, that prorating based on ending balances in Work in Process, Finished Goods, and Cost of Goods Sold (as in requirement 2b) yields a close approximation to the more accurate proration in requirement 2c. Also note that the write‐off to Cost of Goods Sold method (as in requirement 2a) results in a difference of only $68,000 ($21,328,000 ‐ $21,260,000) or less than 1% to the balance of Cost of Goods Sold. Furthermore, the Write Off to Cost of Goods Sold method is simpler than the other methods. Depending on the objectives of the disposal of over/underallocation, a manager may prefer any one of the methods over the other two.
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Prorated $170,000 of Underallocated Assembly Department Overhead (calculated earlier) (4)
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Chapter 4
4‐40 (30‐35 min.) Job costing, normal vs. actual under/over applied overhead. 1.
2.
Actual Manufacturing Overhead: Indirect labour Factory equipment maintenance Factory supplies Factory amortization Factory utilities Insurance on factory Total Manufacturing Overhead Allocated Manufacturing Overhead Under/overallocated manufacturing overhead Under/overallocated manufacturing overhead Underallocated overhead
= = = =
$61,400 $13,300 $4,400 $162,000 $26,000 $22,600 $289,700 63,200 × $4.25 = $268,600 Actual MOH – Allocated MOH $289,700 – $268,600 $21,100
Journal entry to dispose of underallocated overhead Dr. MOH Allocated $268,600 Dr. Cost of Goods Sold $21,100 Cr. MOH Control $289,700
3.
An alternative treatment is to prorate the amount of underallocated overhead among work in process, finished goods, and cost of goods sold. King Ltd. Schedule of Cost of Goods Manufactured for 2013 Beginning Raw Materials Inventory $52,000 Raw Materials Purchases 156,000 Ending Raw Materials Inventory ‐42,500 Raw material used $ 165,500 Direct labour 320,000 Manufacturing Overhead Allocated [63,200×4.25] 268,600 Total manufacturing costs $754,100 Add: Work in process, beg. 34,000 $788,100 Deduct: Work in process, end. 45,000 Cost of goods manufactured (before adjustment) $743,100
4.
5.
Under an actual costing system, the actual amount of manufacturing overhead would appear on the schedule of cost of goods manufactured. ($743,100 + $289,700 – 268,600 = $764,200)
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4‐41 (20 min.) Job costing and governance. 1.
Direct manufacturing costs: Direct materials Direct manufacturing labour Indirect manufacturing costs, 175% $8,400 Total manufacturing costs
$40,000 8,400
$48,400
14,700 $63,100
Aerospace bills the Armed Forces $82,030 ($63,100 130%) for 100 X7 seats or $820.30 ($82,030 ÷ 100) per X7 seat. 2. Direct manufacturing costs: Direct materials $40,000 a Direct manufacturing labour 5,800 $45,800 Indirect manufacturing costs, 175% $5,800 10,150 Total manufacturing costs $55,950 a$8,400 – ($50 16) setup – ($120 15) design $8,400 ‐ $800 ‐ $1,800 Aerospace should have billed the Armed Forces $72,735 ($55,950 130%) for 100 X7 seats or $727.35 ($72,735 ÷ 100) per X7 seat. 3. The problems the letter highlights (assuming it is correct) include: a. Costs included that should be excluded (design costs), b. Costs double‐counted (setup included both as a direct cost and in an indirect cost pool), and c. Possible conflict of interest in Aerospace Comfort purchasing materials from a family‐related company. Steps the Armed Forces could undertake include: (i) Use only contractors with a reputation for ethical behaviour as well as quality products or services. (ii) Issue guidelines detailing acceptable and unacceptable billing practices by contractors. For example, prohibit the use of double‐counting cost allocation methods by contractors. (iii) Issue guidelines detailing acceptable and unacceptable procurement practices by contractors. For example, if a contractor purchases from a family‐related company, require that the contractor obtain quotes from at least two other bidders. (iv) Employ auditors who aggressively monitor the bills submitted by contractors.
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4‐42 (50 min.) Allocation of manufacturing overhead and disposition of overallocation or underallocation. 1.
Bu d geted m anu factu ring overhead costs Budgeted manufacturing = overhead cost rate Direct m anu factu ring labou r costs
= $441,000/$630,000
= $0.70 per direct manufacturing labour dollar
The Work‐in‐Process inventory breakdown at the end of 2013 for Jobs 1768B and 1819C is: Job 1768B Job 1819C Total Direct materials (given) $30,600 $ 56,800 $ 87,400 Direct manufacturing labour (given) 15,000 48,000 63,000 Manufacturing overhead allocated, 70% DML dollars 10,500 33,600 44,100 Total manufacturing costs $56,100 $138,400 $194,500 The finished goods inventory at the end of 2013 is $204,500 (given). A direct manufacturing labour cost of $60,000 implies a budgeted manufacturing overhead costs component of $42,000 ($60,000 × 0.7). Direct materials in finished goods inventory is $102,500 ($204,500 – $60,000 – $42,000). The COGS is $2,200,000 (given). The total direct manufacturing labour of $650,000 implies direct manufacturing labour in COGS of $527,000 ($650,000 – $63,000 in WIP – $60,000 in finished goods). Hence, manufacturing overhead allocated in COGS is 70% $527,000 = $368,900. Direct materials in COGS is $1,304,100 ($2,200,000 – $527,000 – $368,900). The summary account information is: Work in process Finished goods Cost of goods sold Total
Direct Materials $ 87,400 102,500 1,304,100 $1,494 ,000
Direct Manufacturing Manufacturing Overhead Labour Allocated Total $ 63,000 $ 44,100 $ 194,500 60,000 42,000 204,500 527,000 368,900 2,200,000 $650,000 $455,000 $2,599,000
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4‐42 (cont’d) 2. Overallocated
m anu factu ring overhead
=
Manu factu ring overhead Manu factu ring overhead – allocated incu rred
= $455,000* – $406,200 = $48,800 *$650,000 × 0.7 = $455,000
3a. Proration of $48,800 End‐of‐Year End‐of‐Year Overallocated Balance Balance Manuf. (after (before Proration) Overhead Proration) Account (1) (2) (3)=(1)+(2) Work in process $ 194,500 (194.5/2,599 = 7.48%) $(3,652) $190,848 Finished goods 204,500 (204.5/2,599 = 7.87%) (3,840) 200,660 Cost of goods sold 2,200,000 (2,200/2,599 = 84.65%) (41,308) 2,158,692 Total $2,599,000 100.00% $(48,800) $2,550,200 3b. Allocated Proration of End‐of‐Year Overhead $48,800 End‐of‐Year Balance in End‐of‐Year Overallocated Balance (before Balance Manufacturing (after Account Proration) (before Proration) Overhead Proration) Work in process $ 194,500 $ 44,100 (9.69%) $(4,730) $ 189,770 Finished goods 204,500 42,000 (9.23%) (4,505) 199,995 368,900 (81.08%) (39,565) 2,160,435 Cost of goods sold 2,200,000 Total $2,599,000 $455,000 100.0% $(48,800) $2,550,200 4. The COGS amount when the overallocated overhead is immediately written off to COGS is $2,151,200 (see below) compared with $2,158,692 in 3(a) and $2,160,435 in 3(b). Thus, with a lower COGS, there is a higher operating income.
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4‐42 (cont’d) End‐of‐Year Write‐off of End‐of‐Year Balance $48,800 Balance Account (before Proration) Overallocated (after Write‐off) Work in process $ 194,500 $ 0 $ 194,500 Finished goods 204,500 0 204,500 Cost of goods sold 2,200,000 (48,800) 2,151,200 Total $2,599,000 $(48,800) $2,550,200 5. The adjusted allocation rate approach would adjust the cost of Job 1819C for the amount of manufacturing overhead overallocated to it. For 2013, manufacturing overhead is overallocated to each job by 10.73% ($48,800 ÷ $455,000). Hence, the cost of Job 1819C would be decreased by 10.73% manufacturing overhead allocated to 1819C = 10.73% $33,600= $3,604). (Manufacturing overhead allocated $33,600 – $3,604 = $29,996. Cost of Job 1819C would then appear as follows: Direct materials $56,800 Direct manufacturing labour 48,000 Manufacturing overhead allocated 33,600 Adjustment for manufacturing overhead overallocated (3,604) Cost of job after adjustment for overallocation $134,796
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4‐43 (35 min.)
General ledger relationships, underallocation and overallocation.
A summary of the T‐accounts for Northley Company before adjusting for under‐ or overallocation of overhead follows. Beg Purchases End.
Direct Materials Control 32,000 Material used for 431,000 manufacturing 60,000
Work‐in‐Process Control Beg 18,000 Transferred 403,000 Direct to finished materials 403,000 goods Direct manuf. labour 380,000 Manuf. overhead allocated 593,750 End 87,500
1,307,250
Finished Goods Control Cost of Goods Sold 1‐1‐2013 12,250 Cost of Finished Transferred goods 1,280,000 goods 1,280,000 in from 1,307,250 sold sold WIP 12‐31‐2013 39,500 Manufacturing Overhead Control Manufacturing Overhead Allocated Manufac‐ Manufac‐ turing 543,000 turing overhead overhead costs allocated to work in process 593,750
1.
From the credit entry to Direct Materials T‐account, Direct materials issued to manufacturing = $403,000.
2.
Direct manufacturing labour‐hours =
Direct m anu factu ring labou r costs Direct m anu factu ring w age rate per hou r
= $380,000/$16= 23,750 hours
Manu factu ring overhead allocated
=
Direct m anu factu ring Manu factu ring overhead labou r-hou rs rate
= 23,750 hours $25 = $593,750
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4‐43 (cont’d) 3. From the debit entry to Finished Goods T‐account, Cost of jobs completed and transferred from WIP = $1,307,250 4. From Work‐in‐Process T‐account, Ending Work in Process = $18,000 + $403,000 + $380,000 + $593,750 – $1,307,250 = $87,500 5. From the credit entry to Finished Goods Control T‐account, Cost of goods sold (before proration) = $1,280,000 6. Manufacturing Debits to Credit to = – overhead Manufacturing Manufacturing overallocated Overhead Control Overhead Allocated 7.
= $543,000 – $593,750 = $50,750 overallocated
a.
Write‐off to Cost of Goods Sold will decrease (credit) Cost of Goods Sold by $50,750. Hence, Cost of Goods Sold = $1,280,000 – $50,750 = $1,229,250. b. Proration based on ending balances (before proration) in Work in Process, Finished Goods, and Cost of Goods Sold. Account balances in each account after proration follows.
Account (1) Work in Process Finished Goods Cost of Goods Sold Total
Account Balance (2) $87,500 (6.22%) 39,500 (2.81%) 1,280,000 (90.97%) $1,407,000 (100.00%)
Proration of $50,750 Overallocated Manufacturing Overhead (3) 6.22% $50,750 = $3,156 2.81% $50,750 = 1,425 90.97% $50,750 = 46,169 $50,750
Balance (after Proration) (4)=(2) ‐(3) $ 84,344 38,075 1,233,831 $1,356,250
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4‐43 (cont’d) 8. Operating income under the write‐off to Cost of Goods Sold and Proration based on ending balances (before proration) follows: Write‐off to Proration Based on Cost of Goods Sold Ending Balances Revenue $1,664,000 $1,664,000 Cost of goods sold 1,229,250 1,233,831 Gross margin 434,750 430,169 Marketing and distribution costs 199,700 199,700 Operating income $ 235,050 $ 230,469 9. If the purpose is to report the most accurate inventory and cost of goods sold figures, the preferred method is to prorate based on the manufacturing overhead allocated component in the Work in Process, Finished Goods, and Cost of Goods Sold accounts. Proration based on the balances in Work in Process, Finished Goods, and Cost of Goods Sold will equal the proration based on the manufacturing overhead allocated component if the proportions of direct costs to manufacturing overhead costs are constant in the Work in Process, Finished Goods, and Cost of Goods Sold accounts. Even if this is not the case, the proration based on Work in Process, Finished Goods, and Cost of Goods Sold balances will better approximate the results if actual cost rates had been used than the write‐off to Cost of Goods Sold method. However, materiality is always a consideration in how to dispose of under/over allocated manufacturing overhead. In this case, because over 90% of the product has been sold, the overallocated overhead is almost totally adjusted to Cost of Goods Sold under the proration method. The income difference is only $4,581 ($235,050‐$230,469) and as a percentage of sales is insignificant at less than 1% ($4,581/$1,664,000). The main merit of the write‐off to cost of goods sold method is its simplicity. Accuracy and the effect on operating income favour the proration approach when amounts are material. However the simpler approach is preferred when amounts are immaterial.
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4‐44 (35 ‐40 min.) Normal costing, departments. 1.
Manufacturing Overhead Allocation Rate = Budgeted Total MOH Budgeted DL Costs = [$6,450,000 + $1,530,000] [$735,000 + $3,825,000] = $7,980,000 ÷ $4,560,000
= 175% of DL Cost or $1.75 per $1 of DL
Cost of Goods Manufactured: Beginning work in process $0 Direct materials used [$3,350,000 + $2,200,000] $5,550,000 Direct labour [$750,000 + $3,750,000] $4,500,000 Overhead allocated [$4,500,000 × 1.75] $7,875,000 Less ending work in process (see below) ($95,375) $17,829,625 Cost of Goods Manufactured Ending WIP: Job Z438 Job Q917 Total Direct materials $7,000 $10,000 $17,000 Direct labour $1,500 $27,000 $28,500 $47,250 $49,875 MOH @ 175% of DL $2,625 Total $11,125 $84,250 $95,375 2. Under‐ or overallocated overhead = Actual MOH – Allocated MOH Under‐ or overallocated overhead = [$6,390,000 + $1,590,000] – $7,875,000 Under‐ or overallocated overhead = $7,980,000 – $7,875,000 = $105,000 Underallocated
3. Using Departmental Overhead Rates Fabrication Department Budgeted MOH $6,450,000 Budgeted Activity Base 2,580,000 machine‐hours MOH Rate $2.50 per machine‐hour Actual use of cost driver 2,610,000 machine‐hours MOH allocated $6,525,000 Actual MOH incurred $6,390,000 Over‐/(Under‐) allocated $135,000
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Assembly Department $1,530,000 $3,825,000 DL costs $0.40 per $1 DL $3,750,000 DL costs $1,500,000 $1,590,000 ($90,000)
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4‐44 (cont’d) The total manufacturing overhead is $45,000 overallocated ($135,000 – $90,000). The Fabrication Department is automated, therefore machine‐hours would be the appropriate allocation base. The Assembly Department, on the other hand, is labour intensive and therefore Direct Labour cost is an appropriate allocation base. 4‐45 (2025 min.) Disposition of underallocated or overallocated overhead. 1. Budgeted manufacturing overhead rate is $4,800,000 ÷ 80,000 hours = $60 per machine-hour. Manufacturing overhead = Manufacturing overhead – Manufacturing overhead 2. underallocated incurred allocated = $4,900,000 – $4,500,000* = $400,000 *$60 75,000 actual machine‐hours = $4,500,000 a. Write‐off to Cost of Goods Sold Write‐off of $400,000 Account Account Underallocated Balance Balance Manufacturing (After Account (Before Proration) Overhead Proration) (1) (2) (3) (4) = (2) + (3) $ 0 $ 750,000 Work in Process $ 750,000 0 1,250,000 Finished Goods 1,250,000 400,000 8,400,000 Cost of Goods 8,000,000 $10,000,000 $400,000 $10,400,000 Sold Total
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4‐45 (cont’d) b.
Proration based on ending balances (before proration) in Work in Process, Finished Goods, and Cost of Goods Sold.
Account (1) Work in Process Finished Goods Cost of Goods Sold Total
c.
Proration of $400,000 Underallocated Manufacturing Overhead (3)
$ 750,000 (7.5%) 0.075 $400,000 = $30,000 1,250,000 (12.5%) 0.125 $400,000 = 50,000 8,000,000 (80.0%) 0.800 $400,000 = 320,000 $10,000,000 100.0% $400,000
Account Balance (After Proration) (4) = (2) + (3) $ 780,000 1,300,000 8,320,000 $10,400,000
Proration based on the allocated overhead amount (before proration) in the ending balances of Work in Process, Finished Goods, and Cost of Goods Sold. Account (1)
Work in Process Finished Goods Cost of Goods Sold Total
Account Balance (Before Proration) (2)
Account Balance (Before Proration) (2)
Allocated Overhead Included in the Account Balance (Before Proration) (3) (4) a
$ 750,000 $ 240,000 b 1,250,000 660,000 c 8,000,000 3,600,000
Proration of $400,000 Underallocated Manufacturing Overhead (5)
( 5.33%) 0.0533 $400,000 = $ 21,320 (14.67%) 0.1467 $400,000 = 58,680 (80.00%) 0.8000 $400,000 = 320,000
$10,000,000 $4,500,000 100.00%
$400,000
Account Balance (After Proration) (6) = (2) + (5) $ 771,320 1,308,680 8,320,000 $10,400,000
$60 4,000 machine‐hours; b$60 11,000 machine‐hours; c$60 60,000 machine‐hours
a
3.
Alternative (c) is theoretically preferred over (a) and (b). Alternative (c) yields the same ending balances in work in process, finished goods, and cost of goods sold that would have been reported had actual indirect cost rates been used. Chapter 4 also discusses an adjusted allocation rate approach that results in the same ending balances as does alternative (c). This approach operates via a restatement of the indirect costs allocated to all the individual jobs worked on during the year using the actual indirect cost rate.
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COLLABORATIVE LEARNING CASES 4‐46 (35 ‐40 min.) Normal job costing, unit costs. 1. Manufacturing overhead rate = Budgeted MOH Costs Budgeted Direct Labour‐Hours MOH Rate = $180,000/15,000 2. = $12 per DL hour Ending work in process In reviewing the production, the only job that remains in process at the end of the year is Job 817. It had an opening balance (as of December 1) of: Direct materials $2,500 Direct labour $2,400 MOH allocated $1,350 Total $6,250 Beginning Balance $6,250 Direct materials added $700 Direct labour added $1,440 MOH Allocated $960 [80 hours @ $12] Ending balance $9,350 The total balance of ending work in process is $9,350 and relates to one job, Job 817. The unit cost of the job (to date) assuming there are 250 units in the job is $37.40 ($9,350/250). 3. Calculation of the cost of goods manufactured Beginning work in process [$3,200+$6,250+$2,750] $12,200 Direct materials (Dec.) [$500+$700+$1,300+$1,250+$1,500] $5,250 Direct labour (Dec.) [$900+$1,440+$3,060+$3,960+$5,940] $15,300 $12 × [50+80+170+220+330] MOH allocated $10,200 Less ending WIP (see above) ($9,350) COGM $33,600 During the month of December, jobs 815, 822, and 823 were all sold, since only job 824 remains in ending inventory.
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4‐46 (cont’d) Dec. 31 Finished Goods Balance = Job 824 = $1,500 + $5,940 + (330×$12) = $11,400 Dec. 1 Finished Goods + COGM (Dec) – Dec 31 Finished Goods = COGS $0 + $33,600 –$11,400 = $22,200 The selling price is based on 200% of total manufacturing cost. Total Sales = $22,200 × 200% = $44,400 Gross Margin = Sales – Cost of Goods Sold Gross Margin = $44,400 ‐ $22,200 = $22,200 The following chart summarizes the jobs and classifies them into WIP, Finished Goods, and Cost of Goods Sold. Job 815 Job 817 Job 822 Job 823 Job 824 Total WIP, Dec 1 $3,200 $6,250 $2,750 N/A N/A $12,200 DM $500 $700 $1,300 $1,250 $1,500 $5,250 DL $900 $1,440 $3,060 $3,960 $5,940 $15,300 OH Alloc. $600 $960 $2,040 $2,640 $3,960 $10,200 Bal Dec 31 $5,200 $9,350 $9,150 $7,850 $11,400 $42,950 $9,350 WIP N/A N/A N/A N/A $9,350 $11,400 Fin. Good N/A N/A N/A N/A $11,400 $5,200 $9,150 $7,850 COGS N/A N/A $22,200 4. Under‐ or overallocated overhead for the year: Direct labour‐hours worked to December 1 13,750 Additional DL hours worked in December 850 [50+80+170+220+330] Total DL hours worked in the year 14,600 MOH allocated at $12 per DL hour $175,200 Under‐ or overallocated MOH = Actual MOH ‐ Allocated MOH Under‐ or overallocated MOH = $204,800* – $175,200 = $29,600 Underallocated
Manufacturing overhead is underallocated for the year by $29,600. *Should add $2,490+$1,800+$2,200+$1,500+$1,800 = $9,790 in December so that the actual OH for the year would then be $204,800 and the Underallocated amount would be $29,600.
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4‐47 (35 min.) 1.
Job costing, service industry.
Tours in Process (TIP) June 30, 2013 Materials Labour Band (1) (2) As I Lay Dying $ 250 $ 400 Ask Me Later 350 200 Total $600 $600
Overhead (3) = 150% × (2) $ 600 300 $ 900
Total (4) $1,250 850 $2,100
Overhead (3) = 150% × (2) $1,050 1,050 600 $2,700
Total (4) $2,150 2,225 1,275 $5,650
2.
Cost of Completed Tours (CCT) in June 2013 Band Grunge Express Different Strokes Maybe Tomorrow Total
Materials (1) $ 400 475 275 $1,150
Labour (2) $ 700 700 400 $1,800
3. Overhead allocated = 1.50 × 1,400a = $2,100 Underallocated overhead = Actual overhead – Allocated overhead = $2,500 – 2,100 = $400 underallocated a Total labour in June = $100+$300+$400+$200+$400 = $1,400 4a. Underallocated overhead is written off to CCT TIP inventory remains unchanged.
Account TIP CCT
June 30, 2013 Balance (Before Proration) (1) $2,100 5,650 $7,750
Proration of $400 Underallocated Overhead (2) $ 0 400 $400
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June 30, 2013 Balance (After Proration) (3) = (1) + (2) $2,100 6,050 $8,150
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4‐47 (cont’d) 4b.
Underallocated overhead prorated based on ending balances
Account TIP CCT
4c.
June 30 Balance (Before Proration) (1) $2,100 5,650 $7,750
Balance as a Percent of Total (2) = (1) ÷ $7,750 0.271 0.729 1.000
Proration of $400 Underallocated Overhead (3) = (2) $400 0.271 $400 =$108 0.729 $400 = 292 $400
June 30, 2013 Balance (After Proration) (4) = (1) + (3) $2,208 5,942 $8,150
Underallocated overhead prorated based on June overhead in ending balances
Account TIP CCT
June 30 Balance (Before Proration) (1) $2,100 5,650 $7,750
Overhead Overhead Allocated in June Allocated in June Included in June Included in June 30 as a Percent of 30, 2013 Balance Total (2) (3) = (2) ÷ $2,100 a 0.43 $ 900 b 1,200 0.57 $2,100 1.00
Proration of $400 Underallocated Overhead (4) = (3) $400 0.43 $400 =$172 0.57 $400 = 228 $400
June 30 Balance (After Proration) (5) = (1) + (4) $2,272 5,878 $8,150
June labour for As I Lay Dying and Ask Me Later × 150% = ($400 + $200) × 150% = $600 × 150% = $900 bJune labour for Grunge Express, Different Strokes, and Maybe Tomorrow × 150% = ($100 + $300 + $400) × 150% = $800 × $150 = $1,200 a
5.
I would choose the method in 4c because this method results in account balances based on actual overhead allocation rates. The account balances before proration in TIP and CCT are significant and underallocated overhead is material. Furthermore, the ratio of ending balances in TIP and CCT is different from the ratio of overhead allocated to each of these accounts in June.
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CHAPTER 5 ACTIVITY‐BASED COSTING AND MANAGEMENT
SHORT‐ANSWER QUESTIONS
5‐1
Cost smoothing (or traditional costing, broad averaging, peanut‐butter costing”) describes a costing approach that uses one average cost allocation rate for assigning (or spreading, as in spreading peanut butter) the cost of shared resources to distinct types of cost objects when the use among the distinct types of cost objects is unequal. Cost smoothing is appropriate when either the cost objects are similar in sharing consumption of costly indirect resources, or the indirect MOH cost pool is insignificant. Cost smoothing ignores differences in the value‐added provided to different cost objects that is provided by the unequal use of shared resources. The result is inaccurate costing, pricing and predictions. The greater the variations in shared resources consumption the more unreliable and irrelevant the cost data will be to management teams trying to make decisions that will most likely improve profitability.
5‐2
Overcosting may result in competitors entering a market and taking market share for products that a company erroneously believes are low‐margin or even unprofitable. Undercosting may result in companies selling products on which they are in fact losing money, when they erroneously believe them to be profitable.
5‐3
Costing system refinement means making changes to a traditional costing system that reduces the use of one broad average to assign indirect costs of shared resources to cost objects. Reducing the use of one broad average is a refinement that requires increasing the number of indirect MOH cost pools from one to several. Three guidelines for refinement are 1. Classify as many of the total costs as direct costs as is economically feasible. 2. Expand the number of indirect cost pools until each of these pools is more homogenous and less mixed in the resource costs contained in the pool. 3. Use the cause‐and‐effect criterion, when possible, to identify the cost‐driver for each new, homogeneous indirect‐cost pool.
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5‐4
An activity‐based costing (ABC) approach is a refinement to a costing system that defines the cost object as an activity. The same support activity can be done in many business functions in the value chain. The cost of these activities is the activity cost pool or numerator. The activity cost driver is the denominator which when divided into the activity cost pool equals activity cost driver rate. The activity cost driver may be a measure of benefit (such as Purchase Orders completed in a timely way) or a measure of input such as quality control hours consumed. What is essential is that change in the quantity of the activity cost driver explains most of the change in the total value of the activity cost pool.
5‐5
Four levels of a cost hierarchy are (i) Output unit‐level costs: costs of activities performed on each unit of a distinct type of output (ii) Batch‐level costs: costs of activities related to a group of distinct units of homogeneous outputs. A batch may be 1,000 identical units of one distinct type of output that are distinguished from another batch of 1,000 identical units of a different distinct type of output in some meaningful and costly way. (iii) Product‐sustaining or service‐sustaining costs: costs of activities undertaken to support distinct types of products or services regardless of the number of units or batches in which the types of products or services are produced. (iv) Facility‐sustaining costs: costs of intangible (unmeasurable) activities that cannot be traced to distinct types of units, batches, products or services but support the organization as a whole.
5‐6
It is important to classify costs into a cost hierarchy because costs saved at the facilities level can generate savings for all business functions in the value‐chain. By identifying the level at which an activity is shared, the scope of potential savings is also identified. For example a unit‐level cost saving will not affect a facility‐sustaining cost. In practical terms, reducing the cost of a direct material input for a specific type of output, cannot reduce the salary of the Director of IT services.
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5‐7
An ABC system defines activities as the cost objects. The costs of these activities are accumulated throughout the hierarchy to compute the costs of products, and services, and so on. Simple costing systems have one or a few indirect cost pools, that ignore the inaccuracies induced when there are many types of resource costs in one cost pool. ABC systems have multiple indirect cost pools, one for each type of resource used. An ABC approach uses the quantity of activity cost drivers as the allocation base or denominator for each indirect cost pool. A traditional cost system typically uses a quantity of a direct input as the cost allocation base. The ABC approach classifies as many indirect costs as direct costs as possible. This improves the management team’s understanding of cause and effect relationships and the accuracy of costing.
5‐8
Four decisions for which ABC information is useful are 1. pricing and product mix decisions, 2. cost reduction and process improvement decisions, 3. product design decisions, and 4. decisions for planning and managing activities.
5‐9
No. Department indirect‐cost rates are similar to activity‐cost rates if (1) a single activity accounts for a sizable fraction of the department’s costs, or (2) significant costs are incurred because of different activities within a department but each activity has the same cost‐allocation base, or (3) significant costs are incurred because of different activities with different cost‐allocation bases within a department but different products use resources from the different activity areas in the same proportions.
5‐10 “Tell‐tale” signs that indicate when ABC systems are likely to provide the most benefits are as follows: 1. Significant amounts of indirect costs are allocated using only one or two cost pools. 2. All or most indirect costs are identified as output‐unit‐level costs (i.e., few indirect costs are described as batch‐level, product‐sustaining, or facility‐ sustaining costs). 3. Products make diverse demands on shared resources because of differences in volume, process steps, batch size, or complexity. 4. Products that a company is well suited to make and sell show small profits, whereas products that a company is less suited to produce and sell show large profits. 5. Operations staff has significant disagreements with the accounting staff about the costs of manufacturing and marketing products and services.
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5‐11 The main costs and limitations of ABC are the measurements necessary to implement the systems. It is hard for management teams to think about activities instead of jobs as a cost object. It is also hard for management teams to think about the scope of business functions affected by one activity and establish an activity hierarchy. Even basic ABC systems require many calculations to determine costs of products and services. Activity‐cost rates often need to be updated regularly. Very detailed ABC systems are costly to operate and difficult to understand. Sometimes the allocations necessary to calculate activity costs often result in activity‐cost pools and quantities of cost‐drivers being measured with error. When measurement errors are large, activity‐ cost information can be misleading. A common problem is that when accruals are used, the costs in the pool lead the full consumption of the activity. This means the quantity of the activity cost driver is understated relative to the value of the activity cost pool.
5‐12 No, ABC systems are appropriate for service companies such as banks, railroads, hospitals, and accounting firms, as well as for merchandising companies such as retailers and distributors.
5‐13 No. An activity‐based system should be adopted only if its expected benefits exceed its expected costs. It is not always a wise investment. If the jobs, products, or services are alike in the way they use indirect resources of a company, then a simple costing system will suffice.
5‐14 No. Increasing the number of indirect‐cost pools does not guarantee increased accuracy of product or service costs. If the existing cost pool is already homogeneous, increasing the number of cost pools will not increase accuracy. If the existing cost pool is not homogeneous, accuracy will increase only if the increased cost pools themselves increase in homogeneity when compared to the single cost pool.
5‐15 The controller faces a difficult challenge. The benefits of a better accounting system show up in improved decisions by managers. It is important that the controller have the support of these managers when seeking increased investments in accounting systems. Statements by these managers showing how their decisions will be improved by a better accounting system are the controller’s best arguments when seeking increased funding. For example, the new system will result in more accurate product costs which will influence pricing and product mix decisions. The new system can also be used to reduce product costs which will lower selling prices. As a result, the customer will benefit from the new system.
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EXERCISES
5‐16 (10 min.)
Terminology. One common refinement to a traditional or peanut butter costing system is called an activity‐based costing system (ABC). The single MOH cost pool is separated into different activity cost pools distinguished from one another by their measure of benefits provided, or the activity cost driver. Benefits provided unequally to distinct types of outputs provide value‐added to customers, for which customers are willing to pay. This is the basic concept that guides the approach to cost reduction and control called activity‐based management (ABM). The management team identifies and eliminates non‐value added activity and its costs and re‐organizes the value‐added activity to minimize costs. There are four levels of activities in a cost hierarchy. From narrowest to broadest in scope they are output, batch, product (or service), and facility‐sustaining cost. When a management team fails to develop a cost management system that reports faithfully the unequal benefits (and costs) of value‐added activities there is a high risk of mis‐pricing distinct types of outputs. If pricing is cost‐plus then an overcosted output will be priced too high and an undercosted product will be priced too low relative to the economic value‐added. The result is preventable cross‐subsidization of costs of the lower‐priced by the higher‐priced product.
5‐17 (20 min.)
Cost hierarchy.
1. a. Indirect manufacturing labour costs of $1,200,000 support direct manufacturing labour and are output unit‐level costs. Direct manufacturing labour generally increases with output units, and so will the indirect costs to support it. b. Batch‐level costs are costs of activities that are related to a group of units of a product rather than each individual unit of a product. Purchase order‐related costs (including costs of receiving materials and paying suppliers) of $600,000 relate to a group of units of product and are batch‐level costs. c. Cost of indirect materials of $350,000 generally changes with labour‐hours or machine‐hours which are unit‐level costs. Therefore, indirect material costs are output unit‐level costs. d. Setup costs of $700,000 are batch‐level costs because they relate to a group of units of product produced after the machines are set up. e. Costs of designing processes, drawing process charts, and making engineering changes for individual products, $900,000, are product‐sustaining because they relate to the costs of activities undertaken to support individual products regardless of the number of units or batches in which the product is produced.
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5‐17 (cont’d) f. Machine‐related overhead costs (amortization and maintenance) of $1,200,000 are output unit‐level costs because they change with the number of units produced. g. Plant management, plant rent, and insurance costs of $950,000 are facility‐ sustaining costs because the costs of these activities cannot be traced to individual products or services but support the organization as a whole. 2. The complex boom box made in many batches will use significantly more batch‐ level overhead resources compared to the simple boom box that is made in a few batches. In addition, the complex boom box will use more product‐sustaining overhead resources because it is complex. Because each boom box requires the same amount of machine‐hours, both the simple and the complex boom box will be allocated the same amount of overhead costs per boom box if Teledor uses only machine‐hours to allocate overhead costs to boom boxes. As a result, the complex boom box will be undercosted (it consumes a relatively high level of resources but is reported to have a relatively low cost) and the simple boom box will be overcosted (it consumes a relatively low level of resources but is reported to have a relatively high cost). 3. Using the cost hierarchy to calculate activity‐based costs can help Teledor to identify both the costs of individual activities and the cost of activities demanded by individual products. Teledor can use this information to manage its business in several ways: a. Teledor can improve pricing and product mix decisions. Knowing the resources needed to manufacture and sell different types of boom boxes can help Teledor to price the different boom boxes and also identify which boom boxes are more profitable. It can then emphasize its more profitable products. b. Teledor can use information about the costs of different activities to improve processes and reduce costs of the different activities. Teledor could have a target of reducing costs of activities (setups, order processing, etc.) by, say, 3% and constantly seek to eliminate activities and costs (such as engineering changes) that its customers perceive as not adding value. c. Teledor management can identify and evaluate new designs to improve performance by analyzing how product and process designs affect activities and costs. d. Teledor can use its ABC systems and cost hierarchy information to plan and manage activities. What activities should be performed in the period and at what cost?
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5‐18 (20 min.)
Cost hierarchy classification. Requirement 1 Classification Product‐sustaining Batch Unit or Batch* Batch Batch Product or Facility** Facility level
Requirement 2 Cost Drivers Engineering hours # of setups # of units inspected # of parts # of orders Machine‐hours Programmer hours
a Designing new products b Setting up machines c Quality inspection d Moving materials e Receiving raw materials f Performing regular maintenance g Updating inventory software * If all units are inspected this would be a unit‐level activity. If products are sampled, this would likely be a batch‐level activity. **If the production equipment services one product line, it would be product sustaining. If the equipment is general purpose, then it would be facility sustaining.
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5‐19 (15 min.) 1.
Apply the logic of an ABC cost hierarchy.
Rates per unit cost driver. Activity Cost Driver Machining Machine‐hours Setup Production runs Inspection Inspection‐hours Overhead cost per unit: Machining: $6 25,000; 50,000 Set up: $1,440 50; 50 Inspection: $84 1,000; 500 Total manufacturing overhead costs Divide by number of units Manufacturing overhead cost per unit
Rate $450,000 ÷ (25,000 + 50,000) = $6 per machine‐hour $144,000 ÷ (50 + 50) = $1,440 per production run $126,000 ÷ (1,000 + 500) = $84 per inspection‐hour Mathematical $150,000 72,000 84,000 306,000 ÷ 50,000 $ 6.12
Financial $300,000 72,000 42,000 414,000 ÷ 100,000 $ 4.14
Mathematical Manufacturing cost per unit: Direct materials $180,000 ÷ 50,000 $ 3.60 $360,000 ÷ 100,000 Direct manufacturing labour $60,000 ÷ 50,000 1.20 $120,000 ÷ 100,000 Manufacturing overhead (from Requirement 1) 6.12 Manufacturing cost per unit $10.92
Financial
2.
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$3.60 1.20 4.14 $8.94
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5‐20 (20 min.)
Plantwide indirect cost rates.
1.
Actual plantwide variable MOH rate based on machine‐hours: 308,600 ÷ 4,000 = $77.15 per machine‐hour United Holden Leland Motors Motors Vehicle Total Variable manufacturing overhead, allocated based on machine‐hours ($77.15 120; $77.15 2,800; $77.15 1,080) $9,258 $216,020 $83,322 $308,600
2. Department Design Engineering Production
Variable MOH in 2012 $39,000 29,600 240,000
Total Driver Units 390 370 4,000
Design‐related overhead, allocated on CAD‐ design hours (110 $100; 200 $100; 80 $100) Engineering‐related overhead, allocated on engineering hours (70 $80; 60 $80; 240 $80) Production‐related overhead, allocated on machine‐hours (120 $60; 2,800 $60; 1,080 $60) Total
Rate $100 $80 $60 United Motors
per CAD‐design hour per engineering hour per machine‐hour Holden Leland Motors Vehicle Total
$11,000 $ 20,000 $ 8,000 $ 39,000
5,600
4,800
19,200
29,600
7,200 168,000 64,800 240,000 $23,800 $192,800 $92,000 $308,600
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5‐20 (cont’d) 3. a. Department rates (Requirement 2) b. Plantwide rate (Requirement 1) Ratio of (a) ÷ (b)
United Motors $23,800 $ 9,258 2.57
Holden Motors
Leland Vehicle
$192,800
$92,000
$216,020 0.89
$83,322 1.10
The variable manufacturing overhead allocated to United Motors increases by 157% under the department rates, the overhead allocated to Holden decreases by about 11% and the overhead allocated to Leland increases by about 10%. The three contracts differ sizably in the way they use the resources of the three departments. The percentage of total driver units in each department used by the companies is: Cost Department Driver Design CAD‐design Engineering hours Production Engineering hours Machine‐hours
United Motors 28% 19 3
Holden Motors 51% 16 70
Leland Vehicle 21% 65 27
The United Motors contract uses only 3% of total machine‐hours in 2012, yet uses 28% of CAD design‐hours and 19% of engineering hours. The result is that the plantwide rate, based on machine‐hours, will greatly underestimate the cost of resources used on the United Motors contract. This explains the 157% increase in indirect costs assigned to the United Motors contract when department rates are used. In contrast, the Holden Motors contract uses less of design (51%) and engineering (16%) than of machine‐hours (70%). Hence, the use of department rates will report lower indirect costs for Holden Motors than does a plantwide rate.
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5‐20 (cont’d) Holden Motors was probably complaining under the use of the simple system because its contract was being overcosted relative to its consumption of MOH resources. United, on the other hand, was having its contract undercosted and underpriced by the simple system. Assuming that AP is an efficient and competitive supplier, if the new department‐based rates are used to price contracts, United will be unhappy. AP should explain to United how the calculation was done, and point out United’s high use of design and engineering resources relative to production machine‐hours. Discuss ways of reducing the consumption of those resources, if possible, and show willingness to partner with them to do so. If the price increase is going to be steep, perhaps offer to phase in the new prices. 4.
5.
Other than for pricing, AP can also use the information from the department‐ based system to examine and streamline its own operations so that there is maximum value added from all indirect resources. It might set targets over time to reduce both the consumption of each indirect resource and the unit costs of the resources. The department‐based system gives AP more opportunities for targeted cost management. It would not be worthwhile to further refine the cost system into an ABC system if there wasn’t much variation among contracts in the consumption of activities within a department. If, for example, most activities within the design department were, in fact, driven by CAD‐design hours, then the more refined system would be more costly and no more accurate than the department‐based cost system. Even if there were sufficient variation, considering the relative sizes of the 3 department cost pools, it may only be cost‐effective to further analyze the production cost pool, which consumes 78% ($240,000 $308,600) of the manufacturing overhead.
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5‐21 (25 min.) 1.
ABC, product cross‐subsidization.
Current Costing System: Manufacturing Overhead Allocation Rate = Budgeted MOH Costs Direct Labour‐Hours = $1,600,000/100,000 = $16 per DL hour
Unit Costs and Selling Price: Direct Materials Direct Labour Manufacturing Overhead Unit Cost Price (@ 140%)
Table Top Model $28.00 $7.00 $8.00 $43.00 $60.20
2. ABC Costing System: Calculation of Pool Rates: Activity Budgeted Costs Budgeted Activity Materials handling $450,000 400,000 parts Setups $750,000 750 setups General factory $400,000 100,000 DL hours Allocation of overhead costs: Table Top Model Materials Handling: 160,000 parts @ $1.125 $180,000 240,000 parts @ $1.125 Setups: 500 setups @ $1,000 $500,000 250 setups @ $1,000 General Factory Overhead: 20,000 DL hours @$4 $80,000 80,000 DL hours @ $4 Total Overhead Allocated $760,000 # of Units 40,000 Unit Overhead Cost $19.00 Unit Direct Materials Cost $28.00 Unit Direct Labour Cost $7.00 Total Unit Cost (ABC) $54.00 Selling Price (@140%) $75.60
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Floor Model $34.00 $14.00 $16.00 $64.00 $89.60
Pool Rate $1.125 per part $1,000 per setup $4 per DL hour
Floor Model $270,000 $250,000 $320,000 $840,000 80,000 $10.50 $34.00 $14.00 $58.50 $81.90
Chapter 5
5‐21 (cont’d) 3. Comparison Unit Cost – ABC Unit Cost – Current Difference in Cost Percentage Change in Cost Unit Price – ABC Unit Price – Current Difference in Price Percentage Change in Price
Table Top Model $54.00 $43.00 +$11.00 $11/$43 = 25.6% increase $75.60 $60.20 $15.40 $15.4/$60.2 = 25.6% increase
Floor Model $58.50 $64.00 ($5.50) ($5.5)/$64 = 8.6% decrease $81.90 $89.60 ($7.70) ($7.7)/$89.6 = 8.6% decrease
The lower volume product (Table Top Model) is significantly undercosted under the current system. This product currently uses twice as many setups as the higher volume Floor Model. Because it consumes less labour time per unit (0.5 hours per unit versus 1 hour per unit for the Floor Model), under the current costing system it receives proportionately less allocated manufacturing overhead when overhead is allocated based on direct labour‐hours. It may be useful to compare the total allocated manufacturing overhead under the two systems: (refer also to calculations in parts 1 and 2) MOH Allocated – ABC Unit MOH OH – current Number of Units Total MOH Allocated Total Difference Unit Difference
Table Top Model $760,000 $8.00 40,000 $320,000 $440,000 $11.00
Floor Model $840,000 $16.00 80,000 $1,280,000 ($440,000) ($5.50)
ABC systems can be costly to implement; however, in this case it is likely the benefits of the more accurate costing would outweigh the costs.
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5‐22 (15 min.) Explain undercosting and overcosting of services. 1. Support Services Direct Professional Time Rate Number per of Client Hour Hours Total Rate per hour Total (1) (2) (3) (4)=(2)(3) (5) (6)=(4)(5) Winnipeg Dominion Wolfson Ku Anderson
$600 144 96
15 3 22
$9,000 432 2,112
30% 30% 30%
$2,700 130 634
Amount Billed to Client (7)=(4)+(6) $ 11,700 562 2,746 $15,008
Tokyo Enterprises Wolfson $600 2 $1,200 30% $360 Ku 144 8 1,152 30% 346 Anderson 96 30 2,880 30% 864 2. Direct Professional Time Support Services Rate Number per of Client Hour Hours Total Rate per hour Total (1) (2) (3) (4)=(2)(3) (5) (6)=(3)(5) Winnipeg Dominion Wolfson $600 15 Ku 144 3 Anderson 96 22 Tokyo Enterprises Wolfson $600 2 Ku 144 8 Anderson 96 30 Winnipeg Dominion Tokyo Enterprises
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$1,560 1,498 3,744 $6,802
Amount Billed to Client (7)=(4)+(6)
$9,000 432 2,112
$60 60 60
$900 180 1,320
$ 9,900 612 3,432 $13,944
$1,200 1,152 2,880
$60 60 60
$120 480 1,800
$1,320 1,632 4,680 $7,632
Requirement 1 $15,008 6,802 $21,810
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Requirement 2 $13,944 7,632 $21,576
Chapter 5
5‐22 (cont’d) Both clients use 40 hours of professional labour time. However, Winnipeg Dominion uses a higher proportion of Wolfson’s time (15 hours), which is more costly. This attracts the highest support‐services charge when allocated on the basis of direct professional labour costs. 3.
Assume that the Wolfson Group uses a cause‐and‐effect criterion when choosing the allocation base for support services. You could use several pieces of evidence to determine whether professional labour costs or hours is the driver of support‐service costs: a. Interviews with personnel. For example, staff in the major cost categories in support services could be interviewed to determine whether Wolfson requires more support per hour than, say, Anderson. The professional labour costs allocation base implies that an hour of Wolfson’s time requires 6.25 ($600 $96) times more support‐service dollars than does an hour of Anderson’s time. b. Analysis of tasks undertaken for selected clients. For example, if computer‐related costs are a sizable part of support costs, you could determine if there was a systematic relationship between the percentage involvement of professionals with high billing rates on cases and the computer resources consumed for those cases.
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5‐23 (25 min.) Contrast the logic of two cost assignment systems. 1. Total distribution costs (given), $2,636,000 Distribution cost Total distribution costs $2,636,000 per case under = Total cases of specialty = = $13.18 per case 200,000 existing system and regular wine shipped Distribution costs $13.18 120,000; 80,000 2.
a.
b.
$1,581,600
$1,054,400
Regular Per Case Total (2) (1) = (1) ÷ 120,000
Distribution costs of freight $10 120,000 cases $1,200,000 $10 80,000 cases Ordering costs $360 10 orders/year 10 distr. 36,000 $360 20 orders/year 30 distr. Promotion costs $9,600 10 distributors 96,000 $9,600 30 distributors _________ Total costs $1,332,000
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$13.18
Specialty Per Case Total (4) (3) = (3) ÷ 80,000 $13.18
Promotional activity—distributor‐level costs because these costs do not depend on the number of cases shipped or the number of batches in which the cases are shipped. An amount of $9,600 is incurred for each of Niagara’s distributors. Order‐handling costs—batch‐level costs because these costs are incurred each time a customer places an order regardless of the number of cases ordered. These costs total $360 per order. Freight distribution costs—Unit‐level costs because a cost of $10 is incurred on freight for each case shipped.
Regular Per Case Total (2) (1) = (1) ÷ 120,000
Specialty Per Case Total (4) (3) = (3) ÷ 80,000
$10.00
$800,000
$10.00
0.30
216,000
2.70
0.80 ___ $11.10
_ 288,000 $1,304,000
_ 3.60 $16.30
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Chapter 5
5‐23 (cont’d) 3.
The existing costing system uses cases shipped, a unit‐level cost driver, as the only cost allocation base for distribution costs. As a result, the distribution cost per case is the same for specialty and regular wines ($13.18). In fact, specialty wines use distribution resources more intensively than regular wines: (a) Niagara spends $9,600 on promotional activity at each distributor independent of cases sold. Specialty wine distributors sell fewer cases a year than regular wine distributors. As a result the promotional cost per case of wine sold is higher for specialty wines than for regular wines. (b) Niagara’s cost per order is $360 regardless of the number of cases sold in each order. Because specialty wine distributors order fewer cases per order, the ordering costs per case are higher for specialty wines than for regular wines. The existing costing system undercosts distribution costs per case for specialty wines and overcosts distribution costs per case for regular wines. Niagara’s management can use the information from the ABC system to make better pricing and product mix decisions, to reduce costs by eliminating processes and activities that do not add value, to identify and evaluate new designs that reduce the activities demanded by various products, to reduce the costs of doing various activities, and to plan and manage activities.
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5‐24 (25 min.)
Chapter 5
Allocation of costs to activities, unused capacity.
1. Indirect Resources Teachers’ salaries and benefits Principals’ salaries and benefits Facilities cost Office staff salaries and benefits Sports program staff salaries and benefits Indirect Resources Teachers’ salaries and benefits Principals’ salaries and benefits Facilities cost Office staff salaries and benefits Sports program staff salaries and benefits Total No. of students Cost per student Percent of total cost by activity
Percentage of Costs Used by Each Activity Academic Sports Community 2013 Instruction Administration Training Relationships Expenditures 60% 20% 8% 12% $4,000,000 10% 60% 5% 25% 400,000 35% 15% 45% 5% 2,600,000 5% 60% 10% 25% 300,000 35% 10% 45% 10% 500,000 $7,800,000 Actual Resource Cost Used by Each Activity Academic Sports Community 2013 Instruction Administration Training Relationships Expenditures $2,400,000 $ 800,000 $ 320,000 $480,000 $4,000,000 40,000 240,000 20,000 100,000 400,000 910,000 390,000 1,170,000 130,000 2,600,000 15,000 180,000 30,000 75,000 300,000 175,000 50,000 225,000 50,000 500,000 $3,540,000 $1,660,000 $1,765,000 $835,000 $7,800,000 500 500 500 500 500 $7,080 $ 3,320 $3,530 $1,670 $15,600 45% 21% 23% 11% 100%
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5‐24 (cont’d) The overall cost of educating each student is $15,600. Of this, $7,080 (or 45%) is spent on academic instruction and $3,320 (or 21%) is spent on administration. 2.
3.
Cost of ice hockey program = $300,000 Total cost of activities w/o ice hockey program = $7,800,000 – $300,000 = $7,500,000 Per student cost of educational program w/o hockey = $7,500,000 500 = $15,000 Net cost of ice hockey program with $1,000 fee = $300,000 – (30 $1,000) = $270,000 Total cost of activities with ice hockey program fee = $7,500,000 + $270,000 = $7,770,000 Per student cost of educational program with hockey fee = $7,770,000 500 = $15,540
Charging a fee helps a bit but the net cost of the ice hockey program is still high and significantly increases the cost of educating each student.
4. Academic instruction capacity 600 students Cost of academic instruction activity (from requirement 1 calculations) $3,540,000 Cost of academic instruction per student at full $5,900 utilization = $3,540,000 600 Academic instruction resource costs used by current $2,950,000 student population = 500 $5,900 Cost of excess academic instruction capacity = $3,540,000 – $2,950,000 $590,000 Most of the costs at Harmon school are fixed in the short run. So, Smith must try to recruit more students to the school. If, in the long run, it seems like the student population is going to be stable at around 500, he should plan how some of the excess capacity can be cut back so that the fixed school capacity is better utilized; that is, he should work to reduce the cost of excess capacity. One problem with that plan is that “cutting excess academic instruction capacity” may eventually mean reducing the number of sections in each grade and letting teachers go, and if this involves the loss of experienced teachers, that could cause long‐term damage to the school. Unrelated to the excess capacity issue, but with the aim of improving the school’s economics, he should consider doing away with expensive activities like the ice hockey program which raises the cost per student substantially, even after a large fee is charged from students who choose to play the sport.
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Chapter 5
5‐25 (30 min.) 1.
Special order, activity‐based costing.
Medal Plus’s operating income under the alternatives of accepting/rejecting the special order are:
Without With One‐ One‐Time‐ Time‐Only Only Special Special Order Order Difference 9,000 Units 11,500 Units 2,500 Units Sales $1,800,000 $2,220,000 $420,000 Variable costs: 100,000 Direct materials 360,000 460,0001 Direct manufacturing labour 405,000 517,5002 112,500 3 17,500 Batch manufacturing costs 126,000 143,500 Fixed costs: Fixed manufacturing costs 325,000 325,000 — Fixed marketing costs 224,000 224,000 — Total costs 1,440,000 1,670,000 230,000 $ 550,000 $ 190,000 Operating income $ 360,000 1 Unit cost of direct materials = $360,000/9,000 = $40 per medal $40 11,500 = $460,000 2 Unit cost of direct labour = $405,000/9,000 = $45 per medal $45 11,500 = $517,500 3 Batch costs $126,000 + (25 * $700) Alternatively, we could calculate the incremental revenue and the incremental costs of the additional 2,500 units as follows: Incremental revenue $168 2,500 $420,000 Incremental direct material costs 2,500 × $40 = 100,000 Incremental direct manufacturing labour costs 2,500 × $45 = 112,500 Incremental batch manufacturing costs $700 × 25 = 17,500 Total incremental costs 230,000 Total incremental operating income from accepting the special order
$190,000
Medal Plus should accept the one‐time‐only special order if it has no long‐ term implications, because accepting the order increases Medal Plus’s operating income by $190,000. If, however, accepting the special order would cause the regular customers to be dissatisfied or to demand lower prices, then Medal Plus will have to trade off the $190,000 gain from accepting the special order against the operating income it might lose from regular customers.
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5‐25 (cont’d) 2.
Medal Plus has a capacity of 10,000 medals. Therefore, if it accepts the special one‐ time order of 2,500 medals, it can sell only 7,500 medals instead of the 9,000 medals that it currently sells to existing customers. That is, by accepting the special order, Medal Plus must forgo sales of 1,500 medals to its regular customers. Alternatively, Medal Plus can reject the special order and continue to sell 9,000 medals to its regular customers. Medal Plus’s operating income from selling 7,500 medals to regular customers and 2,500 medals under the one‐time special order follows: Sales (7,500 $200) + (2,500 $168) $1,920,000 Direct materials (10,000 * $40) 400,000 Direct manufacturing labour (10,000 * $45) 450,000 Batch manufacturing costs** (150 $700) + (25 $700) 122,500 Fixed manufacturing costs 325,000 Fixed marketing costs 224,000 Total costs 1,521,500 Operating income $ 398,500 **Medal Plus makes regular medals in batch sizes of 50. To produce 7,500 medals requires 150 (7,500 ÷ 50) batches.
Accepting the special order will result in an increase in operating income of $38,500 ($398,500– $360,000). The special order should therefore be accepted. A more direct approach would be to focus on the incremental effects—the benefits of accepting the special order of 2,500 units versus the costs of selling 1,500 fewer units to regular customers. Increase in operating income from the 2,500‐unit special order equals $190,000 (requirement 1). The loss in operating income from selling 1,500 fewer units to regular customers equals: Lost revenue $200 1,500 $(300,000) Savings in direct materials costs $40 1,500 60,000 Savings in direct manufacturing labour costs $45 1,500 67,500 Savings in batch manufacturing costs $700 30 21,000 Operating income lost $ (151,500) Accepting the special order will result in an increase in operating income of $38,500 ($190,000– $151,500). The special order should therefore be accepted. 3.
Medal Plus should not accept the special order. Increase in operating income by selling 2,500 units under the special order (requirement 1) Operating income lost from existing customers ($11 9,000) Net effect on operating income of accepting special order
The special order should therefore be accepted.
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$ 190,000 (99,000) $91,000
Chapter 5
5‐26 (30 min.)
1.
2.
ABC, product cost cross‐subsidization.
Direct costs Direct materials Indirect costs Production support Total costs # of kilograms Cost per kilogram Direct costs Direct materials Packaging Indirect costs Cleaning $0.18 900,000 $0.18 100,000 Cutting $0.30 900,000 $0.20 100,000 Packaging $0.60 900,000 $0.28 100,000 Total costs Kilograms produced Costs per kilogram
$250,000 1,298,000 $1,548,000 1,000,000 $1.548 Retail Potato Cuts
Institutional Potato Cuts
$225,000 238,000
$463,000
$25,000 22,000
162,000
18,000
270,000
20,000
540,000
972,000 $1,435,000 900,000 $1.594
28,000
$47,000
66,000 $113,000 100,000 $1.13
Note: The total costs of $1,548,000 ($1,435,000 + $113,000) are the same as those in requirement #1. This is expected, as the total costs do not change. It is the allocation basis that assigns costs differently. 3. There is much evidence of product‐cost cross‐subsidization. Retail Institutional Current system $1.548 $1.548 ABC system $1.594 $1.130 Assuming the ABC numbers are more accurate, retail is undercosted by approximately 3% ($1.548 ÷ $1.594 = 0.97), while institutional is overcosted by 37% ($1.548 ÷ $1.13 = 1.37).
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5‐26 (cont’d) The current system assumes each product uses all the activity areas in a homogeneous way. This is not the case. Institutional sales use sizably less resources in the cutting area and the packaging area. The percentage of total costs for each cost category are: Retail Institutional Total Direct costs Direct materials 90.0% 10.0% 100.0% Packaging 91.5% 8.5% 100.0 Indirect costs Cleaning 90.0 10.0% 100.0 Cutting 93.1 6.9% 100.0 Packaging 95.1 4.9% 100.0 Units produced 90.0% 10.0% 100.0%
PEI can use the revised cost information for a variety of purposes: a. Pricing/product mix decisions. The sizable drop in the reported cost of institutional potatoes makes it possible that PEI was overpricing potato products in this market. It lost the bid for a large institutional contract with a bid 30% above the winning bid. With its revised product cost dropping from $1.548 to $1.13, PEI could have bid much lower and still made a profit. An increased emphasis on the institutional market appears warranted. b. Product design decisions. ABC provides a road map as to how to reduce the costs of individual products. The relative components of costs are: Retail Institutional Direct costs Direct materials 15.7% 22.1 % Packaging 16.6% 19.5% Indirect costs Cleaning 11.3% 15.9% Cutting 18.8% 17.7% Packaging 37.6% 24.8% 100.0% Total costs 100.0% Packaging‐related costs constitute 54.2% (16.6% +37.6%) of total costs of the retail product line. Design efforts that reduce packaging costs can have a big impact on reducing total unit costs for retail. Retail packaging requires better barrier properties, as the cuts require a longer shelf life than institutional (large quantities) cuts. Retail also has to market the cuts, which requires more expensive packaging design. The biggest problem is the smaller quantity of cuts per package in retail vs. institutional, which means more packages are required for retail. c. Process improvements. Each activity area is now highlighted as a separate cost. The three indirect cost areas are over 50% of total costs for each product, indicating the upside from improvements in the efficiency of processes in these activity areas.
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Chapter 5
5‐27 (15–20 min.) ABC, wholesale, customer profitability.
Chain
1 2 3 4 Gross sales $50,000 $30,000 $100,000 $70,000 Sales returns 10,000 5,000 7,000 6,000 Net sales 40,000 25,000 93,000 64,000 Cost of goods sold (80%) 32,000 20,000 74,400 51,200 5,000 18,600 12,800 Gross margin 8,000 Customer‐related costs: Regular orders $20 × 40; 150; 50; 70 800 3,000 1,000 1,400 Rush orders $100 × 10; 50; 10; 30 1,000 5,000 1,000 3,000 Returned items $10 × 100; 26; 60; 40 1,000 260 600 400 Catalogues and customer support 1,000 1,000 1,000 1,000 Customer related costs 3,800 9,260 3,600 5,800 Contribution (loss) margin $ 4,200 $ (4,260) $ 15,000 $ 7,000 Contribution (loss) margin as (14.2%) 15.0% 10.0% percentage of gross sales 8.4% The analysis indicates that customers’ profitability (loss) contribution varies widely from (14.2%) to 15.0%. Immediate attention to Chain 2 is required which is currently showing a contribution loss. The chain has a disproportionate number of both regular orders and rush orders. Ames should work with the management of Chain 2 to find ways to reduce the number of orders, while maintaining or increasing the sales volume. If this is not possible, Ames should consider dropping Chain 2, if it can save the customer‐related costs. Chain 1 has a disproportionate number of sale returns. The causes of these should be investigated so that the profitability contribution of Chain 1 could be improved.
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5‐28 (30 min.)
ABC, product line costing. 1. Manufacturing overhead activity rates: Activity Budgeted Cost Budgeted Cost Driver Activity Rate Equipment Setups $44,000 80 setups $550/setup Machine Processing $875,000 250,000 machine‐hours $3.50/MH Quality Control $630,000 15,000 inspection hours $42/IH Packaging/Shipping $80,000 200 shipments $400/shipment 2. Unit cost of each model of phone: Family Friend Office Assistant Equipment Setup: 50/30 setups @ $550 $27,500 $16,500 Machine Processing: 30,000/220,000 MH @ $3.50 $105,000 $770,000 Quality Control: 5,000/10,000 IH @ $42 $210,000 $420,000 Packaging/Shipping: $30,000 125/75 shipments @ $400 $50,000 Total allocated overhead $392,500 $1,236,500 Number of units produced 50,000 150,000 Per unit overhead cost $7.85 $8.24 Direct materials $12.14 $28.64 Direct labour $10.86 $10.86 Total unit manufacturing cost $30.85 $47.74 3. Current system using one overhead cost pool and direct labour cost as the activity base: Total budgeted direct labour cost: [50,000 * $10.86] + [150,000 * $10.86] = $2,172,000 Manufacturing overhead rate = Budgeted Manufacturing OH Cost Budgeted Direct Labour Cost = $1,629,000/$2,172,000 = 75% of Direct Labour Cost Family Friend Office Assistant Direct materials $12.14 $28.64 Direct labour $10.86 $10.86 MOH at 75% of direct labour $8.15 $8.15 Total unit manufacturing cost $31.15 $47.65
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5‐28 (cont’d) 4.
Comparison of Results: Total unit cost under ABC Total unit cost – current Difference in dollars
Family Friend $30.85 $31.15 ($0.30)
Office Assistant $47.74 $47.65 $0.09
The $0.30 cost reduction under ABC for the Family Friend model represents approximately a 1% change in the cost ($0.30/$31.15). The nine cent increase in the cost of the Office Assistant model is less than 1% change. In this case, the switch to ABC does not significantly improve product costing and the costs of the ABC system may outweigh the benefits. This would depend on the costs of implementing ABC and how competitive the market place is.
5‐29 (30 min.)
ABC, product costing at banks, cross‐subsidization.
1. Robinson Skerrett Farrel Total Revenue Spread revenue on annual basis (2.5% ; $2,600, $1,200, $40,000) $ 65.00 $ 30.00 $1,000.00 $ 1,095.00 Monthly fee charges ($35; 0, 12, 0) 0.00 420.00 0.00 420.00 Total revenue 65.00 450.00 1,000.00 1,515.00 Costs Deposit/withdrawal with teller $4.00 45; 55; 10 180.00 220.00 40.00 440.00 Deposit/withdrawal with ATM $1.20 12; 24; 18 14.40 28.80 21.60 64.80 Deposit/withdrawal prearranged monthly: $0.80 0; 15; 60 0 12.00 48.00 60.00 Bank cheques written $11.25 10; 5; 4 112.50 56.25 45.00 213.75 Foreign currency drafts $12.50 4; 1; 7 50.00 12.50 87.50 150.00 Inquiries $2.50 12; 20; 11 30.00 50.00 27.50 107.50 379.55 269.60 $1,036.05 Total costs 386.90 Operating income $(321.90) $ 70.45 $730.40 $ 478.95 The assumption that the Robinson and Farrel accounts exceed $2,500 every month and the Skerrett account is less than $2,500 each month means the monthly charges apply only to Skerrett.
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5‐29 (cont’d)
2.
3.
One student with a banking background noted that in this solution 100% of the spread is attributed to the “borrowing side of the bank.” He noted that often the spread is divided between the “borrowing side” and the “lending side” of the bank. Cross‐subsidization across individual Premier Accounts occurs when profits made on some accounts are offset by losses on other accounts. The aggregate profitability on the three customers is $478.95. The Farrel account is highly profitable ($730.40), while the Robinson account is sizably unprofitable. FIB should be very concerned about the cross‐subsidization. Competition likely would “understand” that high‐balance low‐activity type accounts (such as Farrel) are highly profitable. Offering free services to these customers is not likely to retain these accounts if other banks offer higher interest rates. Competition likely will reduce the interest rate spread FIB can earn on the high‐balance low‐ activity accounts they are able to retain. Possible changes FIB could make are: a. Offer higher interest rates on high‐balance accounts to increase FIB’s competitiveness in attracting and retaining these accounts. b. Introduce charges for individual services. The ABC study reports the cost of each service. FIB has to decide if it wants to price each service at cost, below cost, or above cost. If it prices above cost, it may use advertising and other means to encourage additional use of those services by customers. c. Increase the minimum balance for unlimited use of services.
5‐30 (15 ‐ 20 min.) ABC, costs of quality. 1 a. Overhead allocated using current costing system: Direct labour costs 150% = $467,000 150% = $700,500. 1 b. Overhead allocating using ABC: Activity Activity Rate Quantity Allocated Cost Materials inspection $36 per type 50 $1,800 In process testing $6 per unit produced 40,000 $240,000 Final product testing $25 per unit inspected 12,000 $300,000 Testing supplies 30% of DM cost $392,000 $117,600 Total OH allocated $659,400 2. A switch to ABC would result in this job’s cost being reduced by $41,100 ($700,500 – $659,400) or 5.9% reduction in overhead costs assigned ($41,100/$700,500). This is a significant amount and job overcosting could result in lost bids on cost‐plus contracts. A switch to ABC is recommended for this company.
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Chapter 5
PROBLEMS
5‐31 (20‐30 min.) Job costing with single direct‐cost category, single indirect‐cost pool. 1.
2.
Pricing decisions at Wigan Associates are heavily influenced by reported cost numbers. Suppose Wigan is bidding against another firm for a client with a job similar to that of Widnes Coal. If the costing system overstates the costs of these jobs, Wigan may bid too high and fail to land the client. If the costing system understates the costs of these jobs, Wigan may bid low, land the client, and then lose money in handling the case. Widnes Coal Direct professional labour, $70 × 104; $70 × 96 Indirect costs allocated, $105 × 104; $105 × 96 Total costs to be billed
St. Helen’s Glass
Total
$ 7,280
$ 6,720
$14,000
10,920 $18,200
10,080 $16,800
21,000 $35,000
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5‐32 (20–25 min.) Job costing with multiple direct‐cost categories, single indirect‐ cost pool, law firm. 1. 2. 3.
Indirect costs = $7,000 Total professional labour‐hours = 200 hours (104 + 96) = $7,000 ÷ 200 = $35/hour Widnes Coal Direct costs: Direct professional labour, $70 × 104; $70 × 96 $ 7,280 Research support labour 1,600 Computer time 500 Travel and allowances 600 Telephones/faxes 200 Photocopying 250 Total direct costs 10,430 Indirect costs allocated, $35 × 104; $35 × 96 3,640 Total costs to be billed $14,070
St. Helen’s Glass
Total
$ 6,720 $14,000 3,400 5,000 1,300 1,800 4,400 5,000 1,000 1,200 750 1,000 17,570 28,000 3,360 $20,930
7,000 $35,000
Widnes Coal
St. Helen’s Glass
Total
$18,200 14,070
$16,800 20,930
$35,000 35,000
Problem 5‐31 Problem 5‐32
The Problem 5‐32 approach directly traces $14,000 of general support costs to the individual jobs. In Problem 5‐31, these costs are allocated on the basis of direct professional labour‐hours. The averaging assumption implicit in the Problem 5‐ 31 approach appears incorrect—for example, the St. Helen’s Glass job has travel costs more than seven times higher than the Widnes Coal case, despite having lower direct professional labour‐hours.
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5‐33 (30 min.)
Job costing with multiple direct‐cost categories, multiple indirect‐ cost pools, law firm.
Widnes St. Helen’s Coal Glass Total Direct costs: Partner professional labour, $100 × 24; $100 × 56 $ 2,400 $ 5,600 $ 8,000 Associate professional labour, 2,000 6,000 $50 × 80; $50 × 40 4,000 Research support labour 1,600 3,400 5,000 Computer time 500 1,300 1,800 Travel and allowances 600 4,400 5,000 Telephones/faxes 200 1,000 1,200 Photocopying 250 750 1,000 Total direct costs 9,550 18,450 28,000 Indirect costs allocated: Indirect costs for partners, $57.50 × 24; $57.50 × 56 1,380 3,220 4,600 Indirect costs for associates, $20 × 80; $20 × 40 1,600 800 2,400 Total indirect costs 2,980 4,020 7,000 Total costs to be billed $12,530 $22,470 $35,000 Widnes St. Helen’s Comparison Coal Glass Total Single direct cost/ Single indirect cost pool $18,200 $16,800 $35,000 Multiple direct costs/ Single indirect cost pool $14,070 $20,930 $35,000 Multiple direct costs/ Multiple indirect cost pools $12,530 $22,470 $35,000 The higher the percentage of costs directly traced to each case, and the greater the number of homogeneous indirect cost pools linked to the cost drivers of indirect costs, the more accurate the product cost of each individual case.
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5‐33 (cont’d)
The Widnes and St. Helen’s cases differ in how they use “resource areas” of Wigan Associates: Widnes St. Helen’s Coal Glass Partner professional labour 30.0% 70.0% Associate professional labour 66.7 33.3 Research support labour 32.0 68.0 Computer time 27.8 72.2 Travel and allowances 12.0 88.0 Telephones/faxes 16.7 83.3 Photocopying 25.0 75.0 The Widnes Coal case makes relatively low use of the higher‐cost partners but relatively higher use of the lower‐cost associates than does St. Helen’s Glass. As a result, it also uses less of the higher indirect costs required to support partners compared to associates. The Widnes Coal case also makes relatively lower use of the support labour, computer time, travel, phones/faxes, and photocopying resource areas than does the St. Helen’s Glass case.
5‐34 (25 min.) 1.
Contrast the logic of two cost assignment systems.
Output unit‐level costs: 1. Direct‐labour costs, $288,000 2. Equipment‐related costs (rent, maintenance, energy, and so on), $480,000 These costs are output unit‐level costs because they are incurred on each unit of materials tested, that is, for every hour of testing.
Batch‐level costs: 3. Setup costs, $420,000 These costs are batch‐level costs because they are incurred each time a batch of materials is setup for either HT or ST, regardless of the number of hours for which the tests are subsequently run. Service‐sustaining costs: 4. Costs of designing tests, $252,000. These costs are service‐sustaining costs because they are incurred to design the HT and ST tests, regardless of the number of batches tested or the number of hours of test time.
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5‐34 (cont’d) 2.
Heat Testing (HT) Per Hour Total (2) (1) = (1) ÷ 50,000 $ 216,000 $ 4.32
Stress Testing (ST) Per Hour Total (4) (3) = (3) ÷ 30,000 $ 72,000 $ 2.40
Direct labour costs (given) Equipment‐related costs $6 per hour* 50,000 hours 300,000 6.00 $6 per hour* 30,000 hours 180,000 Setup costs $24 per setup‐hour† 13,500 setup‐hours 324,000 6.48 † $24 per setup‐hour 4,000 setup‐hours 96,000 Costs of designing tests $60 per hour** 2,800 hours 168,000 3.36 84,000 $60 per hour** 1,400 hours _________ ___ $20.16 $432,000 Total costs $1,008,000 *$480,000 ÷ (50,000 + 30,000) hours = $6 per test‐hour †$420,000 ÷ (13,500 + 4,000) setup hours = $24 per setup‐hour **$252,000 ÷ (2,800 + 1,400) hours = $60 per hour
6.00
3.20 2.80 $14.40
At a cost per test‐hour of $18, the existing costing system undercosts heat testing ($20.16) and overcosts stress testing ($14.40). The reason is that heat testing uses direct labour, setup, and design resources per hour more intensively than stress testing. Heat tests are more complex, take longer to set up, and are more difficult to design. The existing costing system assumes that testing costs per hour are the same for heat testing and stress testing. 3.
The ABC system better captures the resources needed for heat testing and stress testing because it identifies all the various activities undertaken when performing the tests and recognizes the levels of the cost hierarchy at which costs vary. Halifax’s management can use the information from the ABC system to make better pricing and product mix decisions. For example, it might decide to increase the prices charged for the more costly heat testing and consider reducing prices on the less costly stress testing. Halifax should determine if competitors are underbidding Halifax in stress testing, and causing it to lose business. Halifax can also use ABC information to reduce costs by eliminating processes and activities that do not add value, identifying and evaluating new methods to do testing that reduce the activities needed to do the tests, reducing the costs of doing various activities, and planning and managing activities.
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5‐35 (30 min.) 1.
2.
Use ABC systems for ABM.
The previous costing system reports the following: Baked Milk & Goods Fruit Juice Revenue $68,400 $75,600 Costs Cost of goods sold 45,600 56,400 Store support (30% of COGS) 13,680 16,920 Total costs 59,280 73,320 Operating income $ 9,120 $ 2,280 Operating income ÷ Revenue 13.33% 3.02% The ABC system reports the following: Baked Goods Revenue $68,400 Costs Cost of goods sold 45,600 Ordering 3,600 Delivery 9,408 Shelf‐stocking 4,392 Customer support 3,720 Total costs 66,720 Operating income $ 1,680 Operating income ÷ Revenue 2.46%
Frozen Products $62,400
Total $206,400
42,000 12,600 54,600 $ 7,800
144,000 43,200 187,200 $ 19,200
12.50%
9.30%
Milk & Fruit Juice $75,600
Frozen Products $62,400
Total $206,400
56,400 3,000 3,456 3,984 4,920 71,760 $ 3,840
42,000 1,560 2,688 576 1,896 48,720 $13,680
144,000 8,160 15,552 8,952 10,536 187,200 $ 19,200
5.08%
21.92%
9.30%
These activity costs are based on the following:
Activity Ordering Delivery Shelf‐stocking Customer support
Baked Cost Allocation Rate Goods $120 per purchase order 30 $96 per delivery 98 $24 per hour 183 $0.24 per item sold 15,500
Milk & Fruit Juice 25 36 166 20,500
Frozen Products 13 28 24 7,900
The rankings of products in terms of relative profitability are: 1. 2. 3.
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Previous Costing System Baked goods 13.33% Frozen products 12.50 Milk & fruit juice 3.02
ABC System Frozen products Milk & fruit juice Baked goods
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21.92% 5.08 2.46
Chapter 5
5‐35 (cont’d) The percentage revenue, COGS, and activity costs for each product line are: Revenue COGS Activity areas: Ordering Delivery Shelf‐stocking Customer support
Baked Goods 33.14 31.67
Milk & Fruit Juice 36.63 39.17
Frozen Products 30.23 29.16
Total 100.00 100.00
44.12 60.49 49.06 35.31
36.76 22.22 44.50 46.70
19.12 17.29 6.44 17.99
100.00 100.00 100.00 100.00
3. The baked goods line drops sizably in profitability when the ABC is used. Although it constitutes 31.67% of COGS, it uses a higher percentage of total resources in each activity area, especially the high cost delivery activity area. In contrast, frozen products draws a much lower percentage of total resources used in each activity area than its percentage of total COGS. Hence, under ABC, frozen products is much more profitable. Family Supermarkets may want to explore ways to increase sales of frozen products. It may also want to explore price increases on baked goods. 5‐36 (30‐40 min.) Department and activity‐cost rates, service sector. 1. Overhead costs = $20,610 + $247,320 + $196,180 + $134,350 = $598,460 Budgeted overhead = $598, 460 $1.626 per DL $ rate $368,040 X‐rays Ultrasound CT scan MRI Technician labour $ 61,440 $105,600 $ 96,000 $ 105,000 Amortization 32,240 268,000 439,000 897,500 Materials 22,080 16,500 24,000 31,250 Allocated overhead* 99,901 171,706 156,096 170,730 Total budgeted costs $215,661 $561,806 $715,096 $1,204,480 Budgeted number of ÷4,400 ÷3,000 ÷2,500 procedures ÷3,840 $ 127.68 $ 238.37 $ 481.79 Budgeted cost per service $ 56.16 *Allocated overhead = Budgeted overhead rate × Technician labour costs
Total $ 368,040 1,636,740 93,830 598,433 $2,697,043
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5‐36 (cont’d) 2.
Budgeted Information
X‐rays Number of procedures 3,840 Cleaning minutes per procedure ×5 Total cleaning minutes 19,200 Number of procedures 3,840 Minutes for each procedure ×5 Total procedure minutes 19,200
Activity Administration
Budgeted Cost (1) $ 20,610
Maintenance
$247,320
Sanitation
$196,180
Utilities
$134,350
Technician labour Amortization Materials Allocated activity costs: Administration* Maintenance** Sanitation† Utilities†† Total budgeted cost Budgeted number of procedures Budgeted cost per service
Ultrasound 4,400 ×5 22,000 4,400 ×15 66,000
CT scan 3,000 ×15 45,000 3,000 ×20 60,000
Total 13,740
×35 87,500 2,500 ×45 112,500
173,700 13,740 257,700
Units of Cost Driver Cost Driver Activity Rate (2) (3) (4) = (1) ÷ (3) Total number 13,740 $1.50 per procedure of procedures Total dollars $1,636,740 $0.151105 per dollar of of amortization amortization Total cleaning 173,700 $1.12942 per cleaning minute minutes Total procedure 257,700 $0.52134 per procedure minute minutes X‐rays Ultrasound $61,440 $105,600 32,240 268,000 22,080 16,500 5,760 6,600 4,872 40,496 21,685 24,847 10,010 34,409 $158,087 $496,452 ÷3,840 $ 41.17
÷4,400 $ 112.83
*($1.50×3,840; 4,400; 3,000; 2,500) **($0.151105×$32,240; $268,000; $439,000; $897,500) † ($1.12942×19,200; 22,000; 45,000; 87,500) †† ($0.52134×19,200; 66,000; 60,000; 112,500)
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CT scan MRI Total $ 96,000 $105,000 $ 368,040 439,000 897,500 1,636,740 24,000 31,250 93,830 4,500 3,750 20,610 66,335 135,617 247,320 50,824 98,824 196,180 31,280 58,651 134,350 $711,939 $1,330,592 $2,697,070 ÷3,000 $ 237.31
÷2,500 $ 532.24
Chapter 5
5‐36 (cont’d) 3.
Using the disaggregated activity‐based costing data, managers can see that the MRI actually costs substantially more and x‐rays and ultrasounds substantially less than the traditional system indicated. In particular, the MRI activity generates a lot of maintenance activity and sanitation activity. Managers should examine the use of these two activities to search for ways to reduce the activity consumption and ultimately its cost.
5‐37 (30–40 min.) Activity‐based costing, merchandising. 1.
General Supermarket Chains
Drugstore Chains
Mom‐and‐Pop Single Stores
Total
Revenue $3,708,000 $3,150,000 $1,980,000 $8,838,000 Cost of goods sold 3,600,000 3,000,000 1,800,000 8,400,000 Gross margin $ 108,000 $ 150,000 $ 180,000 $ 438,000 Other operating costs 301,080 Operating income $ 136,920 Gross margin % 2.91% 4.76% 9.09% The gross margin of Pharmacare Inc. was 4.96% ($438,000 ÷ $8,838,000). The operating income margin of Pharmacare Inc. was 1.55% ($136,920 ÷ $8,838,000). 2. The per‐unit cost driver rates are: 1. Customer purchase order processing, $80,000 ÷ 2,000 (140 + 360 + 1,500) orders = $40 per order 2. Line item ordering, $63,840 ÷ 21,280 (1,960 + 4,320 + 15,000) line items = $3 per line item 3. Store delivery, $71,000 ÷ 1,480 (120 + 360 + 1,000) deliveries = $47.973 per delivery 4. Cartons shipped, $76,000 ÷ 76,000 (36,000 + 24,000 + 16,000) cartons = $1 per carton 5. Shelf‐stocking, $10,240 ÷ 640 (360 + 180 + 100) hours = $16 per hour
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5‐37 (cont’d) 3.
The activity‐based costing of each distribution market for August 2013 is: Mom‐and‐ General Pop Supermarket Drugstore Single Stores Total Chains Chains 1. Customer purchase order processing ($40 140; 360; 1,500) $ 5,600 $14,400 $ 60,000 $ 80,000 2. Line item ordering ($3 1,960; 4,320; 15,000) 5,880 12,960 45,000 63 ,840 3. Store delivery ($47.973 120; 360; 1,000) 5,757 17,270 47,973 71,000 4. Cartons shipped ($1 36,000; 24,000; 16,000) 36,000 24,000 16,000 76,000 5. Shelf‐stocking ($16 360; 180; 100) 5,760 2,880 1,600 10,240 $58,997 $71,510 $170,573 $301,080 The revised operating income statement is: General Mom‐and‐Pop Supermarket Drugstore Single Chains Chains Stores Total Revenue $3,708,000 $3,150,000 $1,980,000 $8,838,000 3,000,000 1,800,000 8,400,000 Cost of goods sold 3,600,000 Gross margin 108,000 150,000 180,000 438,000 Operating costs 58,997 71,510 170,573 301,080 $ 78,490 $ 9,427 $ 136,920 Operating income $ 49,003 Operating income margin 1.32% 2.49% 0.48% 1.55%
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5‐37 (cont’d) 4.
The ranking of the three markets are: Using Gross Margin 1. Mom‐and‐Pop Single Stores 9.09% 2. Drugstore Chains 4.76% 3. General Supermarket Chains 2.91%
Using Operating Income 1. Drugstore Chains 2.49% 2. General Supermarket Chains 1.32% 3. Mom‐and‐Pop Single Stores 0.48%
The activity‐based analysis of costs highlights how the Mom‐and‐Pop Single Stores use a larger amount of Pharmacare’s resources per revenue dollar than do the other two markets. The ratio of the operating costs to revenue across the three markets is: General Supermarket Chains Drugstore Chains Mom‐and‐Pop Single Stores
1.59% 2.27% 8.61%
($58,997 ÷ $3,708,000) ($71,510 ÷ $3,150,000) ($170,573 ÷ $1,980,000)
This is a classic illustration of the maxim that “all revenue dollars are not created equal.” The analysis indicates that the Mom‐and‐Pop Single Stores are the least profitable market. Pharmacare should work to increase profits in this market through: (1) a possible surcharge, (2) decreasing the number of orders, (3) offering discounts for quantity purchases, etc. Other issues for Pharmacare to consider include : a. Choosing the appropriate cost drivers for each area. The problem gives a cost driver for each chosen activity area. However, it is likely that over time further refinements in cost drivers would occur. For example, not all store deliveries are equally easy to make, depending on parking availability, accessibility of the storage/shelf space to the delivery point, etc. Similarly, not all cartons are equally easy to deliver—their weight, size, or likely breakage component are factors that can vary across carton types. b. Developing a reliable data base on the chosen cost drivers. For some items, such as the number of orders and the number of line items, this information likely would be available in machine readable form at a high level of accuracy. Unless the delivery personnel have hand‐held computers that they use in a systematic way, estimates of shelf‐stocking time are likely to be unreliable. Advances in information technology likely will reduce problems in this area over time.
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5‐37 (cont’d)
c.
d.
Deciding how to handle costs that may be common across several activities. For example, (3) store delivery and (4) cartons shipped to stores have the common cost of the same trip. Some organizations may treat (3) as the primary activity and attribute only incremental costs to (4). Similarly, (1) order processing and (2) line item ordering may have common costs. Behavioural factors are likely to be a challenge to Flair. He must now tell those salespeople who specialize in Mom‐and‐Pop accounts that they have been less profitable than previously thought.
5‐38 (40‐50 min.) ABC, product cross‐subsidization. 1.
Total indirect costs are $715,800 [$140,000+$48,000+$50,000+$60,000+$35,000+$96,000+$13,800+$148,000+ $50,000+$75,000] Budgeted manufacturing plantwide overhead rate:
Plantwide rate:
= $715,800/[30,000 + 30,000] = $11.93 per direct labour‐hour
To produce 15,000 units of Jordan, the company has budgeted 30,000 hours; therefore, each unit takes 2 hours. To manufacture 5,000 units of Shenandoah, the company has budgeted 30,000 labour‐hours, so each unit requires 6 hours. Jordan Shenandoah Per Unit Cost Direct material $100.00 $200.00 Direct labour @ $20/hour $40.00 $120.00 $71.58 Allocated OH at $11.93/DL hour $23.86 Total $163.86 $391.58
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5‐38 (cont’d) 2. & 3. Students have some discretion in forming cost pools. Certain choices are more obvious than others. Since we have information on orders processed, number of setups, number of requisitions, percentage of units inspected, maintenance hours, and design and support hours, it would make sense to use this information in the creation of cost pools. Therefore it is expected most students would calculate the following rates: Activity Cost Driver Budgeted Cost Activity Base Pool Rate Purchasing materials # of requisitions $50,000 160 [50+110] $312.50 Receiving goods Orders processed $35,000 800 [150+650] $43.75 Setting up # of setups $13,800 115 [15+100] $120.00 $148,000 2,500* $59.20 Inspection Units inspected Design & support Hours $125,000 500 [100+400] $250.00 Maintenance Maintenance hours $140,000 1,400 [450+950] $100.00 * [10% 15,000] + [20% 5,000] = 1,500 + 1,000 = 2,500 This leaves us with 3 activities to classify: Utilities, Factory Rental, and Indirect Materials. A good cost driver for utilities is likely machine‐hours. Since we are told that facility costs (i.e. factory rental) are allocated on the basis of machine‐hours, we can group utilities and factory rental into the same pool. Pool Rate: = [$48,000 + $96,000]/[2,000 + 2,000] = $144,000/4,000 = $36.00 per machine‐hour Indirect materials will likely cause the most variation. Possible drivers may be number of units produced, machine‐hours, or possibly cost of direct materials. The following solutions show two possible classifications: Separate cost pool allocated on the basis of number of units produced Classification with facility costs under the assumption machine‐hours would be the cost driver
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5‐38 (cont’d) Assumption A: Indirect materials allocated on the basis of number of units produced: Indirect materials pool rate: $60,000/[15,000 + 5,000] = $3.00 per unit Allocation of Overhead using ABC: Jordan Shenandoah Purchasing @ $312.50 [50/110] $15,625.00 $34,375.00 Receiving @ $43.75 [150/650] $6,562.50 $28,437.50 Setting up @ $120.00 [15/100] $1,800.00 $12,000.00 Inspection @ $59.20 [ 1,500/1,000] $88,800.00 $59,200.00 Design & support @ $250 [100/400] $25,000.00 $100,000.00 $95,000.00 Maintenance @ $100 [ 450/950] $45,000.00 Subtotal $182,787.50 $329,012.50 Indirect materials @ $3.00 [15,000/5,000] $45,000.00 $15,000.00 $72,000.00 Facility @ $36 [2,000/2,000] $72,000.00 Total allocated overhead $299,787.50 $416,012.50 Number of units produced 15,000 5,000 Per unit cost of overhead $19.986 $83.203 Assumption B: Indirect materials allocated on the basis of machine‐hours. Pool rate = [$48,000 + $96,000 + $60,000]/[2,000 + 2,000] = $204,000/4,000 = $51.00 per machine‐hour Jordan Shenandoah Purchasing @ $312.50 [50/110] $15,625.00 $34,375.00 Receiving @ $43.75 [150/650] $6,562.50 $28,437.50 Setting up @ $120.00 [15/100] $1,800.00 $12,000.00 Inspection @ $59.20 [ 1,500/1,000] $88,800.00 $59,200.00 Design & support @ $250 [100/400] $25,000.00 $100,000.00 $95,000.00 Maintenance @ $100 [ 450/950] $45,000.00 Subtotal $182,787.50 $329,012.50 Facility @ $51 [2,000/2,000] $102,000.00 $102,000.00 Total allocated overhead $284,787.50 $431,012.50 Number of units produced 15,000 5,000 Per unit cost of overhead $18.986 $86.203
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5‐38 (cont’d) 3. & 4. Assumption A: Jordan Shenandoah Per unit cost of overhead – using ABC $19.99 $83.20 Add: Direct materials $100.00 $200.00 Add: Direct labour $40.00 $120.00 Total unit cost – ABC $159.99 $403.20 Unit cost – plantwide rate $163.86 $391.58 Dollar difference (decrease)/increase ($3.87) $11.62 Percentage difference (2.4%) 3.0% Assumption B: Jordan Shenandoah Per unit cost of overhead – using ABC $18.99 $86.20 Add: Direct materials $100.00 $200.00 Add: Direct labour $40.00 $120.00 Total unit cost – ABC $158.99 $406.20 $391.58 Unit cost – plantwide rate $163.86 Dollar difference (decrease)/increase ($4.87) $14.62 Percentage difference (3.0%) 3.7% The activity based costing system does not result in large differences between the costs, but in a competitive market these differences could be important.
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5‐39 (30‐40 min.) Choosing cost drivers, activity‐based costing, activity‐based management. 1.
2.
Direct materials—purses Direct materials—backpacks Direct manufacturing labour—purses Direct manufacturing labour—backpacks Setup Shipping Design
Output unit‐level costs Output unit‐level costs Output unit‐level costs Output unit‐level costs Batch‐level costs Batch‐level costs Product‐sustaining costs
Plant utilities and administration
Facility‐sustaining costs
Direct materials—purses Direct materials—backpacks Direct manufacturing labour—purses Direct manufacturing labour—backpacks Setup Shipping Design Plant utilities and administration
Number of bags Number of bags Number of bags Number of bags Number of batches Number of batches Number of designs Hours of production
Direct material and direct manufacturing labour are costs that can be easily traced to output, which in this case is the number of bags produced. Setup and shipping are both a function of the number of batches produced. Design is related to the number of designs created for each product. Plant utilities and administration result from the general activity level in the plant. Thus, hours of production seems to be an appropriate cost driver.
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5‐39 (cont’d) 3. Direct materials—purses Direct materials—backpacks Direct manufacturing labour—purses Direct manufacturing labour—backpacks Setup Shipping Design Plant utilities and administration
$362,000 ÷ 3,150 purses = $114.92 per purse $427,000 ÷ 6,000 backpacks = $71.17 per backpack $98,000 ÷ 3,150 purses = $31.11 per purse $115,597 ÷ 6,000 backpacks = $19.27 per backpack $64,960 ÷ 203 = $320 per batch $72,065 ÷ 203 = $355 per batch $167,000 ÷ 5 = $33,400 per design $225,000 ÷ 4,160 hours = $54.0865 per hour
4. Backpacks Purses Total Direct materials $427,000 $362,000 $ 789,000 Direct manufacturing labour 115,597 98,000 213,597 Setup ($320×133; 70) 42,560 22,400 64,960 Shipping ($355×133; 70) 47,215 24,850 72,065 Design ($33,400×3; 2) 100,200 66,800 167,000 Plant utilities and administration ($54.0865×1,560; 2,600) 84,375 140,625 225,000 Budgeted total costs $816,947 $714,675 $1,531,622 ÷ Number of bags ÷ 6,000 ÷ 3,150 $ 226.88 Budgeted cost per bag $ 136.16 5. Based on this analysis, over 50% of product cost relates to direct material. Managers should determine whether the material costs can be reduced. Producing in small lots increases the setup and shipping costs. While both are relatively small components of product cost, management may want to evaluate ways to reduce the number of setups and the cost per setup. Of the indirect costs, the product‐ and facility‐sustaining costs are the highest. Management should review the design process for cost savings and examine why it takes so long to produce purses relative to backpacks.
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5‐40 (30 min.) 1.
2.
Make or buy, activity‐based costing, opportunity costs.
Relevant costs under buy alternative: Purchases, 10,000 $12.20 $122,000 Relevant costs under make alternative: Direct materials $60,000 Direct manufacturing labour 30,000 Variable manufacturing overhead 20,000 Inspection, setup, materials handling 2,500 Machine rent 3,500 Total relevant costs under make alternative $116,000 The allocated fixed plant administration and insurance will not change whether Ace makes or buys the chains. Hence these costs are irrelevant to the make/buy decision. The analysis indicates that Ace should not buy the chains from the outside supplier. Relevant costs under the make alternative: Relevant costs (as computed in requirement 1)
$116,000
Relevant costs under the buy alternative: Costs of purchases (10,000 $12.20) $122,000 Additional fixed costs 18,500 Additional contribution margin from using the space where the chains were made to upgrade the bicycles by adding mud flaps and reflector bars, 10,000 ($25 – $20.50) (45,000) $ 95,500 Ace should now buy the chains from the outside vendor and use its own capacity to upgrade its own bicycles.
3.
(a) Since mud flaps and reflectors are added anyway and yield an additional contribution of $45,000, minus additional fixed costs of $18,500, they are irrelevant to the analysis.
(b) Cost of manufacturing chains: Variable costs ($6.00 + $3.00 + $2.00 = $11.00) 6,400 = $70,400 Batch costs, $250/batch 8 batches = 2,000 Machine rent = 3,500 $75,900 Cost of buying chains, $12.20 6,400 $78,080
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5‐40 (cont’d) In this case, Ace should manufacture the chains. Qualitative Analysis – Ace will also want to examine the possible pros and cons of manufacturing vs. purchasing. For example, if Ace purchases the chains, this may free up time and energy for other projects. However, will the quality remain the same if purchased vs. manufactured internally. The quality could be better or worse.
5‐41 (50 min.) 1.
ABC, implementation, governance.
Applewood Electronics should not emphasize the Regal model and phase out the Monarch model. Under activity‐based costing, the Regal model has an operating income percentage of less than 10%, while the Monarch model has an operating income percentage of nearly 38%. Cost driver rates for the various activities identified in the activity‐based costing (ABC) system are as follows:
Activity Soldering
Activity Monarch Regal Cost $1,872,400 1,296,000 214,000
Shipments
$1,480,000
1,500
500
Quality control Purchase orders Machine power Machine setups
$1,749,600
54,000
18,000
$582,400
16,640
4,160
20,800
$61,600
144,000
10,000
154,000
$414,000
360
100
460
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Total Cost Driver 1,510,000 2,000
Activity Rate $1.24/solder point $740/shipment
72,000 $24.30/inspection $28/purchase order $0.40/machine‐ hour $900/setup
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5‐41 (cont’d) Applewood Electronics Calculation of Costs of Each Model under Activity‐Based Costing Direct costs Direct materials ($540 18,000; $1,089 2,000) Direct manufacturing labour ($45 18,000; $126 2,000) Machine costs ($200 18,000; $125 2,000) Total direct costs Indirect costs Soldering ($1.24 1,296,000;214,000) Shipments ($7401,500; 500) Quality control ($24.30 54,000; 18,000) Purchase orders ($28.00 16,640;4,160) Machine power ($0.40 144,000; 10,000) Machine setups ($900 360; 100) Total indirect costs Total costs Profitability analysis Monarch Revenue $30,600,000 Cost of goods sold 19,006,760 Gross margin $11,593,240 Per‐unit calculations: Units sold 18,000 Gross margin per unit $644.07 Selling price $1,700.00 Gross margin percentage 37.89%
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Monarch
Regal
$9,720,000 810,000 3,600,000 14,130,000
$2,178,000 252,000 250,000 2,680,000
1,607,040 1,110,000 1,312,200 465,920 57,600 324,000 4,876,760 $19,006,760
265,360 370,000 437,400 116,480 4,000 90,000 1,283,240 $3,963,240
Regal $4,400,000 3,963,240 $ 436,760
Total $35,000,000 22,970,000 $12,030,000
2,000 $218.38 $2,200.00 9.93%
Chapter 5
5‐41 (cont’d) 2.
3.
Applewood’s existing costing system allocates all manufacturing overhead other than machine costs on the basis of machine‐hours, an output unit‐level cost driver. Consequently, the more machine‐hours per unit that a product needs, the greater is the manufacturing overhead allocated to it. Because Monarch uses 1.6 times the number of machine‐hours per unit compared with Regal, a large amount of manufacturing overhead is allocated to Monarch. The ABC analysis recognizes several batch‐level cost drivers such as purchase orders, shipments, and setups. Regal uses these resources much more intensively than Monarch. The ABC system recognizes Regal’s use of these overhead resources. Consider, for example, purchase order costs. The existing system allocates these costs on the basis of machine‐hours. As a result, each unit of Monarch is allocated 1.6 times (8 machine‐hours to 5 machine‐hours). So using machine‐hours, the purchase order costs of $582,400 would be allocated $544,582 (or $30.25 per unit) to Monarch [($582,400/154,000)*144,000] and $37,818 (or $18.91 per unit) to Regal [($582,400/154,000)*10,000]. The ABC system allocates $465,920 of purchase order costs to Monarch [equal to $25.88 ($465,920 ÷ 18,000) per unit] and $116,480 of purchase order costs to Regal [equal to $58.24 ($116,480÷ 2,000) per unit]. Each unit of Regal uses 2.25 ($58.24 ÷ $25.88) times the purchase order costs of each unit of Monarch. Recognizing Regal’s more intense use of manufacturing overhead results in Regal showing a much lower profitability under the ABC system. By the same token, the ABC analysis shows that Monarch is quite profitable. The existing costing system overcosted Monarch, and so made it appear less profitable. Figueira’s comments about ABC implementation are valid. When designing and implementing ABC systems, managers and management accountants need to trade off the costs of the system against its benefits. Adding more activities makes the system harder to understand and more costly to implement but would probably improve the accuracy of cost information, which, in turn, would help Applewood make better decisions.
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5‐41 (cont’d) 4.
5.
Activity‐based management (ABM) is the use of information from activity‐based costing to make improvements in a firm. For example, a firm could revise product prices on the basis of revised cost information. For the long term, activity‐based costing can assist management in making decisions regarding the viability of product lines, distribution channels, marketing strategies, etc. ABM highlights possible improvements, including reduction or elimination of non‐value‐added activities, selecting lower‐cost activities, sharing activities with other products, and eliminating waste. ABM is an integrated approach that focuses management’s attention on activities with the ultimate aim of continuous improvement. As a whole‐company philosophy, ABM focuses on strategic as well as tactical and operational activities of the company. Incorrect reporting of ABC costs with the goal of retaining both the Monarch and Regal product lines is unethical. In assessing the situation, the management accountant could consider the following: Competence ‐ Clear reports using relevant and reliable information should be prepared. Preparing reports on the basis of incorrect costs in order to retain product lines violates competence standards. It is unethical for Benzo to change the ABC system with the specific goal of reporting different product cost numbers that Figueira favours. Integrity ‐ The management accountant has a responsibility to avoid actual or apparent conflicts of interest and advise all appropriate parties of any potential conflict. Benzo may be tempted to change the product cost numbers to please Figueira, the Division President. This action, however, would violate the responsibility for integrity. Objectivity ‐ The management accountant should require that information should be fairly and objectively communicated and that all relevant information should be disclosed. From a management accountant’s standpoint, adjusting the product cost numbers to make both the Monarch and Regal lines look profitable would violate the standard of objectivity. Benzo should indicate to Figueira that the product cost calculations are, indeed, appropriate. If Figueira still insists on modifying the product cost numbers, Benzo should raise the matter with one of Figueira’s superiors. If, after taking all these steps, there is continued pressure to modify product cost numbers, Benzo should consider resigning from the company, rather than engage in unethical behaviour.
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Chapter 5
COLLABORATIVE LEARNING CASE
5‐42 (40‐60 min.) Using ABC for activity‐based management. 1.
General Mills has identified two segments within the food‐service channel: impulse locations and yogurt shops. The segments differ on three dimensions: The impulse segment, which sells 80% of the total cases in the food‐service channel, orders mostly individual cases (95% of the 1,200,000 impulse segment cases are purchased as individual cases). The shop segment, on the other hand, orders 80% of its needs as full pallets and the rest as individual cases. This results in higher shipping costs to the impulse segment. The shop segment consumes only about 2.6% (90 of 3,450) of the merchandising kits, and the impulse segment consumes the rest. This results in higher merchandising costs to the impulse segment. The shop segment consumes only 1% of the sales time spent on frozen yogurt in the food‐service channel, and the impulse segment consumes the rest. This results in higher selling costs to the impulse segment.
2.
COGS:
Total is $14,250,000 (same for all cases) = $14,250,000 1,500,000 cases = $9.50 per case Impulse: 1,200,000 cases at $9.50 = $11,400,000 Shops: 300,000 cases at $9.50 = $2,850,000
Shipping:
Total of $3,000,000 varies with individual cases ($2.25/case) or pallets ($75 each). Impulse: Pallets = 60,000 75 cases = 800 pallets at $75 = $60,000 Individual cases = 1,140,000 cases at $2.25 = $2,565,000 Total: $2,625,000 Shops: Pallets = 240,000 75 cases = 3,200 pallets at $75=$240,000 Individual cases = 60,000 cases at $2.25 = $135,000 Total: $375,000
Merchandising: $500 per kit Impulse: (3,450 – 90 kits) $500 = 3,360 $500 = $1,680,000 Shops: 90 kits $500 = $45,000
SG&A:
$1,185,000 previously allocated based on sales dollars. After sales diaries analysis, total was adjusted to $3,900,000. Impulse: 99% $3,900,000 = $3,861,000 Shops: 1% $3,900,000 = $39,000
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5‐42 (cont’d) New Net Income Analysis (changed items in bold): Category Impulse Location Yogurt Shops Total Sales in cases 1,200,000 300,000 1,500,000 Sales Revenue $23,880,000 $5,970,000 $29,850,000 Less: Promotions (3,600,000) (900,000) (4,500,000) Net Sales $20,280,000 $5,070,000 $25,350,000 Less: COGS (11,400,000) (2,850,000) (14,250,000) Less: Shipping (2,625,000) (375,000) (3,000,000) Gross Margin $ 6,255,000 $1,845,000 $ 8,100,000 Less: Merchandising (1,680,000) (45,000) (1,725,000) (39,000) (3,900,000) Less: SG&A (3,861,000) Net Income $ 714,000 $1,761,000 $ 2,475,000 Per case: $0.60 $5.87 $1.65 3. The SG&A allocation to each segment using the sales dollar allocation method was too low, inflating net income figures. Recommend allocation based on time (as determined from sales diaries). Marketing costs (price promotions, merchandising, shipping, and SG&A) now total $13,125,000, representing 44% of sales and 530% of net income. This implies that, if marketing support costs can be reduced without reducing sales, profit will increase by 5% for every 1% reduction. Impulse locations have higher marketing support costs, so emphasis on reducing those costs is important—less sales rep time, consolidating the multiple small orders into larger ones, smaller and less costly marketing kits that can be mailed instead of hand‐delivered. Shops have largely been ignored by the sales reps, but there is opportunity to boost these sales. Is it due to sales force lack of training? Either offer training or set up a separate sales force to specialize in this area. Maybe offer incentives to boost shop sales. Start charging for the marketing kits. The price promotions have been costly in this segment, so if they are removed, additional value must be perceived elsewhere, such as more sales force attention, new products, etc. General Mills should recognize that the shops segment has 20% of the sales yet 71% of the net income. Clearly, an opportunity exists to further boost this segment’s performance. In reality, the company shifted its emphasis away from the impulse segment to the shop segment, created a new marketing kit and sales team for shops, and re‐built relationships it had neglected. 5–224
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CHAPTER 6 MASTER BUDGET AND RESPONSIBILITY ACCOUNTING
SHORT‐ANSWER QUESTIONS
6‐1
The budgeting cycle includes the following elements: a. Planning the performance of the organization as a whole as well as of its subunits. The entire management team agrees as to what is expected. b. Providing a frame of reference, a set of specific expectations against which the actual results can be compared. c. Investigating variations from the plans. If necessary, corrective action follows investigation. d. Planning again, considering feedback and changed conditions.
6‐2
A master budget is a single comprehensive income statement that combines information from many individual budgeted statements. The term “master” refers to it being a comprehensive organization‐wide set of budgets that coordinates all financial projections for a set period of time.
6‐3
Plans can and sometimes should be changed if the feedback indicates an assumption used in the budget was wrong. If the feedback indicates the plan was reasonable, then it is necessary to understand the issues preventing the achievement of the planned results and implement an appropriate remedy.
6‐4
Strategy, plans, and budgets are interrelated and affect one another. Strategy is a broad term that usually means selection of overall objectives. Strategic analysis underlies both long‐run and short‐run planning. In turn, these plans lead to the formulation of budgets. Budgets provide feedback to managers about the likely effects of their strategic plans. Managers use this feedback to revise their strategic plans.
6‐5
Yes, budgeted performance is better than past performance for judging managers. Why? Mainly because inefficiencies included in past results can be detected and eliminated in budgeting. Also, new opportunities in the future, which did not exist in the past, may otherwise be ignored if past performance is used.
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6‐6
A company that shares its own internal budget information with other companies can gain multiple benefits. One benefit is better coordination with suppliers, which can reduce the likelihood of supply shortages. Better coordination with customers can result in increased sales as demand by customers is less likely to exceed supply. Better coordination across the whole supply chain can also help a company reduce inventories and thus reduce the costs of holding inventories. Suppliers and customers become “partners in profit.” Here satisfied customers sell the final product to new customers.
6‐7
A rolling budget is a budget or plan that is always available for a specified future period by adding a month, quarter, or year in the future as the month, quarter, or year just ended is dropped. For example, a 12‐month rolling budget for the March 2012 to February 2013 period becomes a 12‐month rolling budget for the April 2012 to March 2013 period the next month, and so on.
6‐8 1. 2. 3. 4. 5. 6. 7. 8. 9.
The steps in preparing an operating budget are: Prepare the revenue budget Prepare the production budget (in units) Prepare the direct materials usage budget and direct materials purchases budget Prepare the direct manufacturing labour budget Prepare the manufacturing overhead budget Prepare the ending inventories budget Prepare the cost of goods sold budget Prepare the nonproduction costs budget Prepare the budgeted income statement
6‐9
The revenue budget is typically the cornerstone for budgeting because production (and hence costs) and inventory levels generally depend on the forecasted level of demand and revenue.
6‐10 Sensitivity analysis adds an extra dimension to budgeting. It enables managers to examine how budgeted amounts change with changes in the underlying assumptions. This helps managers to monitor those assumptions that are most critical to a company attaining its budget and to make timely adjustments to plans when appropriate.
6‐11 Kaizen budgeting is a budgeting approach that explicitly incorporates continuous improvement during the budget period into the resultant budget numbers.
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Chapter 6
6‐12 Non‐output‐based cost drivers can be incorporated into budgeting by the use of activity‐based budgeting (ABB). ABB focuses on the budgeted cost of activities necessary to produce and sell products and services. Non‐output‐based cost drivers, such as the number of part numbers, number of batches, and number of new products, can be used with ABB.
6‐13 The choice of a responsibility centre type guides the variables to be included in the budgeting exercise. For example, if a revenue centre is chosen, the focus will be on variables that assist in forecasting revenue. Factors related to, say, costs of the investment base will be considered only if they assist in forecasting revenue.
6‐14 Equal or across‐the‐board reductions is a strategy that penalizes honest business functions and rewards those that pad the budgets. The strategy produces a perverse incentive, rewarding the overstatement of budgeted costs and the understatement of budgeted revenue.
EXERCISES
6‐15 (10 min.)
Terminology.
A cash cycle, also known as an operating cycle, is the movement of cash arising from business functions to inventories, to receivables, and back to cash when outputs are sold. It is a self‐liquidating cycle where all costs of a corporation are recovered when output is sold. Budgetary slack is the practice of underestimating revenue and overestimating costs to make budget constraints less challenging. Once the corporate budget is produced, all managers make a commitment to reach budget targets. They are responsible for controllable cost that must be at or below the budget constraint during each reporting time period. Some companies produce a rolling budget that adds a reporting time period as one is completed. An investment budget affects the flow in and out of cash either to make the investment or to pay to finance it.
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6‐16 (15 min.) Responsibility and controllability. 1.
2.
3.
4.
5.
(a) Salesman (b) VP of Sales Permit the salesman to offer a reasonable discount to customers, but require that he clear bigger discounts with the VP. Also, base his bonus/performance evaluation not just on revenue generated, but also on margins (or, ability to meet budget). (a) VP of Sales (b) VP of Sales VP of Sales should compare budgeted sales with actuals, and ask for an analysis of all the sales during the quarter. Discuss with salespeople why so many discounts are being offered—are they really needed to close each sale. Are our prices too high (i.e., uncompetitive)? (a) Manager, Shipping department (b) Manager or Director of Operations (including shipping) The shipping department manager must report delays more regularly and request additional capacity in a timely manner. Operations manager should ask for a review of shipping capacity utilization, and consider expanding the department. (a) HR department (b) Production supervisor The production supervisor should devise his or her own educational standards that all new plant employees are held to before they are allowed to work on the plant floor. Offer remedial in‐plant training to those workers who show promise. Be very specific about the types of skills required when using the HR department to hire plant workers. Test the workers periodically for required skills. (a) Production supervisor (b) Production supervisor Get feedback from the workers, analyze it, and act on it. Get extra coaching and training from experienced mentors.
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Chapter 6
6‐16 (cont’d) 6.
(a) Maintenance department (b) Production supervisor First, get the requisite maintenance done on the machines. Make sure that the maintenance department head clearly understands the repercussions of poor maintenance. Discuss and establish maintenance standards that must be met (frequency of maintenance and tolerance limits, for example). Test and keep a log of the maintenance work.
6‐17 (30 min.) Budgeting: direct material usage, manufacturing cost, and gross margin. 1. Direct Material Usage Budget in Quantity and Dollars Physical Units Budget Direct materials required for Blue Rugs (100,000 rugs × 30 skeins and 0.5 gal.) Cost Budget Available from beginning direct materials inventory (under a FIFO cost‐flow assumption) Wool: 349,000 skeins Dye: 5,000 gallons To be purchased this period Wool: (3,000,000 ‐ 349,000) skeins × $2 per skein Dye: (50,000 – 5,000) gal. × $5 per gal. Direct materials to be used this period: (a) + (b)
Material Wool 3,000,0000 skeins
$ 715,450 5,302,000 _________ $6,017,450
Dye
Total
50,000 gal. $ 24,850 225,000 $ 249,850
$6,267,300
2.
Weaving budgeted = $18,852,000 = $3.3664 per DMLH overhead rate 5,600,000 DMLH Dyeing budgeted = $12,809,000 = $28.4644 per MH overhead rate 450,000 MH
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6‐17 (cont’d) 3.
4.
Budgeted Unit Cost of Blue Rug Input per Cost per Unit of Unit of Input Output Total Wool $2 30 skeins $ 60.00 Dye 5 0.5 gal. 2.50 Direct manufacturing labour 15 56 hrs. 840.00 1 128.09 Dyeing overhead 28.4644 4.5 mach‐hrs. Weaving overhead 3.3664 56 DMLH 188.52 Total $1219.11 10.15 machine hour per skein 30 skeins per rug = 4.5 machine‐hrs. per rug. Revenue budget Blue Rugs Blue Rugs
5a.
Units 100,000 95,000
Selling Price $2,000 $2,000
Total Revenue $200,000,000 $190,000,000
Cost of goods sold budget Sales = 100,000 rugs Beginning finished goods inventory Direct materials used Direct manufacturing labour ($840 × 100,000) Dyeing overhead ($128.09 × 100,000) Weaving overhead ($188.52 × 100,000) Cost of goods available for sale Deduct ending finished goods inventory Cost of goods sold
From Schedule Total $ 0 $ 6,267,300 84,000,000 12,809,000 18,852,000
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121,928,300 121,928,300 0 $121,928,300
Chapter 6
6‐17 (cont’d) 5b.
Cost of Goods Sold Budget Sales = 95,000 rugs From Schedule Total Beginning finished goods inventory $ 0 Direct materials used $ 6,267,300 Direct manufacturing labour ($840 × 100,000) 84,000,000 Dyeing overhead ($128.09 × 100,000) 12,809,000 Weaving overhead ($188.52 × 100,000) 18,852,000 121,928,300 Cost of goods available for sale 121,928,300 Deduct ending finished goods inventory ($1,219.11 × 5,000) 6,095,550 Cost of goods sold $115,832,750
6. 100,000 rugs sold $200,000,000
Revenue Less: Cost of goods sold Gross margin
121,928,300 $ 78,071,700
95,000 rugs sold $190,000,000 115,832,750 $ 74,167,250
6‐18 (15 min.) Sales budget, service setting. 1. McGrath & Sons Radon Tests Lead Tests
2013 At 2013 Expected 2014 Volume Selling Prices Change in Volume 11,000 $250 +5% 15,200 $200 ‐10%
Expected 2014 Volume 11,550 13,680
McGrath & Sons Sales Budget For the Year Ended December 31, 2014
Radon Tests Lead Tests
Selling Price $250 $200
Units Sold 11,550 13,680
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Total Revenue $2,887,500 2,736,000 $5,623,500
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6‐18 (cont’d) 2. 2013 Planned 2014 Expected 2014 Expected 2014 McGrath & Sons Volume Selling Prices Change in Volume Volume Radon Tests 11,000 $250 +5% 11,550 ‐5% Lead Tests 15,200 $190 14,440 McGrath & Sons Sales Budget For the Year Ended December 31, 2014 Selling Price Units Sold Total Revenue Radon Tests $250 11,550 $2,887,500 Lead Tests $190 14,440 2,743,600 $5,631,100 Expected revenue at the new 2014 prices are $5,631,100, which are greater than the expected 2013 revenue of $5,623,500 if the prices are unchanged. So, if the goal is to maximize sales revenue and if Jim McGrath’s forecasts are reliable, the company should lower its price for a lead test in 2014.
6‐19 (5 min.)
Sales and production budget.
Budgeted sales in units Add target ending finished goods inventory Total requirements Deduct beginning finished goods inventory Units to be produced
135,000 16,300 151,300 9,700 141,600
6‐20 (5 min.)
Direct materials budget.
Direct materials to be used in production (bottles) Add target ending direct materials inventory (bottles) Total requirements (bottles) Deduct beginning direct materials inventory (bottles) Direct materials to be purchased (bottles)
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2,100,000 55,000 2,155,000 23,700 2,131,300
Chapter 6
6‐21 (10 min.) Budgeting material purchases.
Finished Goods (units) 52,250 29,400 81,650 27,300 54,350
Budgeted sales Add target ending finished goods inventory Total requirements Deduct beginning finished goods inventory Units to be produced Direct materials needed for production (54,350 3) Add target ending direct materials inventory Total requirements Deduct beginning direct materials inventory Direct materials to be purchased
Direct Materials (in litres) 163,050 110,000 273,050 117,350 155,700
6‐22 (30 min.) Sales and production budget. 1.
Selling Price
l‐litre bottles 16‐litre units a520,000 12 months = 6,240,000 b185,000 12 months = 2,220,000 2.
3.
$0.50
Units Sold a 6,240,000
7.00
b 2,220,000
Budgeted unit sales (1‐litre bottles) Add target ending finished goods inventory Total requirements Deduct beginning finished goods inventory Units to be produced Beginning inventory
Total Revenue $ 3,120,000 15,540,000 $18,660,000
6,240,000 976,000 7,216,000 1,275,000 5,941,000
Budgeted Target – Budgeted + = sales ending inventory production = 2,220,000 + 265,000 – 2,090,000 = 395,000 16‐litre units
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6‐23 (15‐20 min.) Budgeting revenue, cost of sales, and gross margin. Franks Budgeted Gross Margin For the Quarter Ending December 31 October November December $14,000 $16,300 $21,100
Total for the Quarter Cash sales $51,400 Credit card sales: $ 9,800 0.96 9,408 $11,200 0.96 10,752 $15,800 0.96 15,168 35,328 Net sales 23,408 27,052 36,268 86,728 Cost of goods sold, at 40% of net sales 9,363 10,821 14,507 34,691 Gross margin $14,045 $16,231 $21,761 $52,037 Some students may think that a 60% gross margin is high. However, this gross margin is before deducting many operating costs such as rent, advertising, and sales commissions.
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Chapter 6
6‐24 (15‐20 min.) Revenue, production, and purchases budget. 1. 2. 3.
985,000 motorcycles 505,000 yen = 497,425,000,000 yen Budgeted sales (units) Add target ending finished goods inventory Total requirements Deduct beginning finished goods inventory Units to be produced
985,000 115,000 1,100,000 152,000 948,000
Direct materials to be used in production, 948,000 2 1,896,000 Add target ending direct materials inventory 28,000 Total requirements 1,924,000 Deduct beginning direct materials inventory 19,000 Direct materials to be purchased 1,905,000 Cost per wheel in yen 21,300 Direct materials purchase cost in yen 40,576,500,000 Note the relatively small inventory of wheels. In Japan, suppliers tend to be located very close to the major manufacturer. Inventories are controlled by just‐in‐ time (JIT) and similar systems. Indeed, some direct materials inventories are almost nonexistent.
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6‐25 (15‐25 min.) Budgets for production and direct manufacturing labour.
All Frame Company Budget for Production and Direct Manufacturing Labour For the Quarter Ended March 31, 2013 January February Budgeted sales (units) 10,000 12,000 12,500 Add target ending finished goods inventory* (units) 16,000 Total requirements (units) 26,000 24,500 Deduct beginning finished goods inventory (units) 16,000 16,000 Units to be produced 10,000 8,500 Direct manufacturing labour‐hours (DMLH) per unit 2.0 2.0 Total hours of direct manufacturing labour time needed 20,000 17,000 Direct manufacturing labour costs: Wages ($10.00 per DMLH) $200,000 $170,000 Pension contributions ($0.50 per DMLH) 10,000 8,500 Workers’ compensation insurance ($0.15 per DMLH) 3,000 2,550 Employee medical insurance ($0.40 per DMLH) 8,000 6,800 Employment insurance (employer’s share) ($10.00 0.075 = $0.75 per DMLH) 15,000 12,750 Total direct manufacturing labour costs $236,000 $200,600
March 8,000 13,500 21,500 12,500 9,000 1.5 13,500
Quarter 30,000 13,500 43,500 16,000 27,500 50,500
$135,000 6,750 2,025 5,400
$505,000 25,250 7,575 20,200
10,125 $159,300
37,875 $595,900
*100% of the first following month’s sales plus 50% of the second following month’s sales.
Note that the employee employment insurance levy of 7.5% is irrelevant. Such taxes are withheld from employees’ wages and paid to the government by the employer on behalf of the employees; therefore, the employee 7.5% amounts are not additional costs to the employer. 6–236
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Chapter 6
6‐26 (30 min.) 1.
2.
Cash flow analysis.
The cash that TabComp Inc. can expect to collect during April 2013 is calculated below: April cash receipts: April cash sales ($400,000 .25) $100,000 April credit card sales ($400,000 .30 .96) 115,200 Collections on account: March ($480,000 .45 .70) 151,200 February ($500,000 .45 .28) 63,000 January (uncollectable–not relevant) 0 Total collections $429,400 a.
The projected number of the MZB‐33 computer hardware units that TabComp Inc. will order on January 25, 2013, is calculated as follows.
March sales Plus: Ending inventorya Total needed Less: Beginning inventoryb Projected purchases in units a0.30 90 unit sales in April b0.30 110 unit sales in March
MZB‐33 Units 110 27 137 33 104
b. Selling price = $2,025,000 675 units, or for March, $330,000 110 units = $3,000 per unit Purchase price per unit, 60% $3,000 $ 1,800 Projected unit purchases x 104 Total MZB‐33 purchases, $1,800 104 $187,200 3.
Monthly cash budgets are prepared by companies such as TabComp Inc. in order to plan for their cash needs. This means identifying when both excess cash and cash shortages may occur. A company needs to know when cash shortages will occur so that prior arrangements can be made with lending institutions in order to have cash available for borrowing when the company needs it. At the same time, a company should be aware of when there will be excess cash available for investment or for repaying loans.
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6‐27 (20‐30 min.) Activity‐based budgeting. 1. Activity Ordering $90 14; 24; 14 Delivery $82 12; 62; 19 Shelf‐stocking $21 16; 172; 94 Customer support $0.18 4,600; 34,200; 10,750 Total budgeted indirect costs Percentage of total indirect costs (subject to rounding) 2.
Cost Soft Fresh Hierarchy Drinks Produce Batch‐ $1,260 $ 2,160 level 984 5,084 Batch‐ level 336 3,612 Output‐ unit‐level 828 6,156 Output‐ unit‐level $3,408 $17,012 13% 63%
Refer to the last row of the table in requirement 1. Fresh produce, which probably represents the smallest portion of COGS, is the product category that consumes the largest share (63%) of the indirect resources. Fresh produce demands the highest level of ordering, delivery, shelf‐stocking, and customer support resources of all three product categories—it has to be ordered, delivered, and stocked in small, perishable batches, and supermarket customers often ask for a lot of guidance on fresh produce items.
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Packaged Food Total $1,260 $ 4,680 1,558 7,626 1,974 5,922 1,935 8,919 $6,727 $27,147 25%
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Chapter 6
6‐27 (cont’d) 3.
An ABB approach recognizes how different products require different mixes of support activities. The relative percentage of how each product area uses the cost driver at each activity area is:
Activity Ordering Delivery Shelf‐stocking Customer support
Cost Hierarchy Batch‐level Batch‐level Output‐unit‐ level Output‐unit‐ level
Soft Fresh Packaged Drinks Produce Food 27% 46% 27% 13 67 20 6 61 33 9 69 22
Total 100% 100 100 100
By recognizing these differences, FS managers are better able to budget for different unit sales levels and different mixes of individual product‐line items sold. Using a single cost driver (such as COGS) assumes homogeneity in the use of indirect costs (support activities) across product lines which does not occur at FS. Other benefits cited by managers include: (1) better identification of resource needs, (2) clearer linking of costs with staff responsibilities, and (3) identification of budgetary slack.
6‐28 (20‐30 min.) Kaizen approach to activity‐based budgeting 1. Activity Ordering Delivery Shelf‐stocking Customer support
Budgeted Cost‐Driver Rates Cost Hierarchy January February March Batch‐level $90.00 $89.82 $89.64 Batch‐level 82.00 81.84 81.67 21.00 Output‐unit‐ 20.96 20.92 level 0.18 0.18 0.179 Output‐unit‐ level
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6‐28 (cont’d) The March 2013 rates can be used to compute the total budgeted cost for each activity area in March 2013:
2.
Cost Soft Fresh Packaged Hierarchy Drinks Produce Food Total Activity Ordering Batch‐level $1,255 $2,151 $89.64 14; 24; 14 $1,255 $4,661 Delivery Batch‐level $81.67 12; 62; 19 5,064 7,596 980 1,552 Output‐unit‐ Shelf‐stocking 3,598 5,899 $20.92 16; 172; 94 level 335 1,966 Customer support Output‐unit‐ level $0.179 4,600; 34,200; 10,750 823 6,122 1,924 8,869 Total $3,393 $16,935 $6,697 $27,025 A kaizen budgeting approach signals management’s commitment to systematic cost reduction. Compare the budgeted costs from Question 6‐27 and 6‐28.
Question 6‐27 Question 6‐28 (Kaizen)
Ordering Delivery $4,680 $7,626 4,661 7,596
Shelf‐ Stocking $5,922 5,899
Customer Support $8,919 8,869
The kaizen budget number will show unfavourable variances for managers whose activities do not meet the required monthly cost reductions. This likely will put more pressure on managers to creatively seek out cost reductions by working “smarter” within FS or by having “better” interactions with suppliers or customers. One limitation of kaizen budgeting, as illustrated in this question, is that it assumes small incremental improvements each month. It is possible that some cost improvements arise from large discontinuous changes in operating processes, supplier networks, or customer interactions. Companies need to highlight the importance of seeking these large discontinuous improvements as well as the small incremental improvements.
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Chapter 6
PROBLEMS
6‐29 (30‐40 min.) Revenue and production budgets. This is a routine budgeting problem. The key to its solution is to compute the correct quantities of finished goods and direct materials. Use the following general formula: Bu d geted Target Bu d geted Beginning prod u ction end ing sales or _ inventory or pu rchases inventory m aterials u sed
1.
Burlington Northern Corporation Revenue Budget For 2014 Widget Thingamajig Projected sales
2.
Units 60,000 40,000
Price $198 300
Total $ 11,880,000 12,000,000 $23,880,000
Burlington Northern Corporation Production Budget (in units) For 2014
Budgeted sales in units Add target finished goods inventories, December 31, 2014 Total requirements Deduct finished goods inventories, January 1, 2014 Units to be produced
Widget 60,000
Thingamajig 40,000
27,000 87,000
11,000 51,000
22,000 65,000
10,000 41,000
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6‐29 (cont’d) 3.
Burlington Northern Corporation Direct Materials Purchases Budget (in quantities) for 2014
Direct materials to be used in production • Widget (budgeted production of 65,000 units times 4 kg of A, 2 kg of B) • Thingamajig (budgeted production of 41,000 units times 5 kg of A, 3 kg of B, 1 unit of C) Total Add target ending inventories, December 31, 2014 Total requirements in quantities Deduct beginning inventories, January 1, 2014 Direct materials to be purchased (quantities) 4.
Widget Thingamajig Total
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Direct Materials B C
260,000
130,000
—
205,000 465,000 36,000 501,000 32,000 469,000
123,000 253,000 32,000 285,000 29,000 256,000
41,000 41,000 7,000 48,000 6,000 42,000
Burlington Northern Corporation Direct Materials Purchases Budget (in dollars) for 2014
Direct material A Direct material B Direct material C Budgeted purchases 5.
A
Budgeted Purchases (Quantities) 469,000 256,000 42,000
Expected Purchase Price per Unit $14 7 5
Total $6,566,000 1,792,000 210,000 $8,568,000
Burlington Northern Corporation Direct Manufacturing Labour Budget for 2014 Direct Budgeted Manufacturing Production Labour‐Hours Total (Units) per Unit Hours 65,000 2 130,000 41,000 3 123,000
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Rate per Hour $15 19
Total $1,950,000 2,337,000 $4,287,000
Chapter 6
6‐29 (cont’d) 6. Burlington Northern Corporation Budgeted Finished Goods Inventory At December 31, 2014 Widget: Direct materials costs: A, 4 kilograms at $14 $56 B, 2 kilograms at $7 14 Direct manufacturing labour costs, 2 hours at $15 Manufacturing overhead costs at $24 per direct manufacturing labour‐hour (2 hours) Budgeted manufacturing costs per unit Finished goods inventory of Widget $148 27,000 units Thingamajig: Direct materials costs: A, 5 kilograms at $14 $70 B, 3 kilograms at $7 21 C, 1 each at $5 5 Direct manufacturing labour costs, 3 hours at $19 Manufacturing overhead costs at $24 per direct manufacturing labour‐hour (3 hours) Budgeted manufacturing costs per unit Finished goods inventory of Thingamajig $225 11,000 units Budgeted finished goods inventory, December 31, 2014
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$70 30 48 $148
$3,996,000
$96 57 72 $225
2,475,000 $6,471,000
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6‐30 (30 min.) Budgeted income statement. Easecom Company Budgeted Income Statement for 2013 (in thousands) Revenue Equipment ($6,000 × 1.06 × 1.10) $6,996 Maintenance contracts ($1,800 × 1.06) 1,908 Total revenue Cost of goods sold ($4,600 × 1.03 × 1.06) Gross margin Operating costs: Marketing costs ($600 + $250) 850 Distribution costs ($150 × 1.06) 159 Customer maintenance costs ($1,000 + $130) 1,130 Administrative costs 900 Total operating costs Operating income
$8,904 5,022 3,882
3,039 $ 843
6‐31 1. 2.
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Comprehensive review of budgeting. Prepare a master operating budget; budge schedules for manufacturer.
Revenue Budget Units sold Unit selling price Budgeted revenue
Executive Line 740 $1,224 $905,760
Production Budget in Units Executive Line Budgeted sales 740 Add budgeted ending f.g. inventory 30 Total requirements 770 Deduct beginning f.g. inventory 20 Budgeted production 750
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Chairperson Line Total 390 $1,920 $748,800 $1,654,560
Chairperson Line 390 15 405 5 400
Chapter 6
6‐31 (cont’d) 3.
Direct Materials Usage Budget (units): Oak Top Executive Line: 1. Budgeted input per f.g. unit 1.5 m2 2. Budgeted production 750 3. Budgeted usage 1,125 Chairperson Line: 4. Budgeted input per f.g. unit — 5. Budgeted production — 6. Budgeted usage — Total direct materials usage (3+6) 1,125 1. Beginning inventory 29.8 2. Unit price (FIFO) $21.60 3. Cost of DM used from beginning inventory $643.68 4. Materials to be used from purchases 1,095.20a 5. Cost of DM in March $24 6. Cost of DM purchased and used in March $26,285 Direct materials used (3+6) $26,928 1125 m2 – 29.8 = 1,095.2 m2 920 m2 – 13.9 = 906.1 m2
Red Oak Oak Top Legs
Red Oak Legs Total
— — —
4 750 3,000
— — —
2.3 m2 400 920
— — —
4 400 1,600
920
3,000
1,600
13.9 $27.60
100 $13.20
40 $20.40
$383.64
$1,320
$816
906.10b $30
2,900c $14.40
1,560d $21.60
$3,163
$27,183 $41,760 $33,696 $128,924 $27,567 $43,080 $34,512 $132,087
3,000 legs – 100 = 2,900 legs 1,600 legs – 40 = 1,560 legs
a
c
b
d
Direct Materials Purchases Budget:
Oak Red Oak Oak Red Oak Top Top Legs Legs Total Budgeted usage 1,125 920 3,000 1,600 Add ending inventory 17.9 18.6 80 44 Total requirements 1,142.90 938.60 3,080 1,644 Deduct beginning inventory 29.8 13.9 100 40 Total DM purchases 1,113.10 924.70 2,980 1,604 Purchase price (March) $ 24.00 $ 30.00 $ 14.40 $ 21.60 Total purchases $26,714.40 $27,741.00 $42,912.00 $34,646.40 $132,013.80
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6‐31 (cont’d) 4.
5.
6.
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Direct Manufacturing Labour Budget Direct Manu. Output Labour‐ Units Hours per Produced Output Unit Executive Line 750 3 Chairperson Line 400 5
Total Hourly Hours Rate 2,250 $36 2,000 $36 4,250
Total $ 81,000 72,000 $153,000
Manufacturing Overhead Budget Variable manufacturing overhead costs (4,250 × $42) $178,500 Fixed manufacturing overhead costs 51,000 Total manufacturing overhead costs $229,500 Total manufacturing overhead cost per hour $229,500 = = $54 per direct manufacturing labour‐hour 4,250 Fixed manufacturing overhead cost per hour $51,000 = = $12 per direct manufacturing labour‐hour 4,250 Computation of unit costs of finished goods: Direct materials Executive Line Chairperson Line Direct materials Oak top ($24 × 1.5; 0) $ 36.00 Red oak top ($30 × 0; 2.3) $ 69.00 Oak legs ($14.40 × 4) 57.60 Red oak legs ($21.60 × 4) 86.40 108.00 180.00 Direct manufacturing labour ($36 × 3; 5) Manufacturing overhead Variable ($42 × 3; 5) 126.00 210.00 Fixed ($12 × 3; 5) 36.00 60.00 Total manufacturing cost per unit $363.60 $605.40
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Chapter 6
6‐31 (cont’d) 7.
Ending Inventory Budget Cost per Unit Direct Materials Oak top $ 24 Red oak top 30 Oak legs 14.40 Red oak legs 21.60 Finished Goods Executive 363.60 Chairperson 605.40 Total Cost of Goods Sold Budget Actual finished goods inventory, March 1, 2013 ($12,576 + $5,820)a Direct materials used Direct manufacturing labour Manufacturing overhead Cost of goods manufactured Cost of goods available for sale Deduct ending finished goods inventory, March 31, 2008 Cost of goods sold a given
Units
Total
17.9 18.6 80 44
$ 429.60 558.00 1,152.00 950.40 $3,090.00
30 15
10,908.00 9,081.00 19,989.00 $23,079.00
$132,087 153,000 229,500
$18,396a
19,989 $512,994
514,587 532,983
Therefore, from #1) Budgeted Revenue = $1,654,560 Less, from #7) Costs of Goods Sold = 512,994 Gross Margin = $1,141,566
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6‐32
Comprehensive review of budgeting. Prepare a master operating budget; budget schedules for manufacturer.
1. Revenues Budget For the Year Ending December 31, 2013 2a.
2b.
Chairs Tables Total
Selling Total Units Price Revenues 172,000 $ 80 $13,760,000 45,000 $900 $40,500,000 $54,260,000
Total budgeted marketing costs = Budgeted variable marketing costs + Budgeted fixed marketing costs = $2,011,200 + $4,500,000 = $6,511,200 $6,511,200 Marketing allocation rate = = 0.12 per sales dollar $54,260,000 Total budgeted distribution costs = Budgeted variable distribution costs + Budgeted fixed distribution costs = $54,000 + $380,000 = $434,000 Chairs: 172,000 units ÷ 500 units per delivery 344 deliveries Tables: 45,000 units ÷ 500 units per delivery 90 deliveries Total 434 deliveries $434,000 Delivery allocation rate = = $1,000 per delivery 434 deliveries
3.
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Production Budget (in Units) For the Year Ending December 31, 2013 Product Chairs Tables Budgeted unit sales 172,000 45,000 Add target ending finished goods inventory 8,500 2,250 Total required units 180,500 47,250 Deduct beginning finished goods inventory 8,000 2,100 Units of finished goods to be produced 172,500 45,150
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Chapter 6
6‐33 1.
Comprehensive budget, fill in schedules, prepare a cash budget
Schedule A: Budgeted Monthly Cash Receipts Item September Total sales $48,000* Credit sales (25%) 12,000* Cash sales (75%) $36,000 Receipts: Cash sales Collections on accounts receivable Total
October November December 4th Quarter $57,600* $72,000* $96,000* $225,600 14,400* 18,000 24,000 56,400 $43,200 $54,000 $72,000 169,200 $43,200*
$54,000
$72,000
12,000* $55,200*
14,400 $68,400
18,000 $90,000
*Given
2.
Schedule B: Budgeted Monthly Cash Disbursements for Purchases Item Purchases Deduct 2% cash discount Disbursements
*Given
October November December 4th Quarter $50,400* $67,200 $30,240 $147,840 1,008* 1,344 605 2,957 $49,392* $65,856 $29,635 $144,883
Note that purchases are 0.7 of next month’s sales, as gross margin averages 30% of sales (given).
3.
Schedule C: Budgeted Monthly Cash Disbursements for Operating Costs Item October November December 4th Quarter Salaries and wages (15% of sales) $ 8,640* $10,800 $14,400 $33,840 Rent (5% of sales) 2,880* 3,600 4,800 11,280 Other cash operating costs (4% of sales) 2,304* 2,880 3,840 9,024 Total $13,824* $17,280 $23,040 $54,144
*Given
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6‐33 (cont’d) 4.
Schedule D: Budgeted Total Monthly Cash Disbursements Item October November December 4th Quarter Purchases $49,392* $65,856 $29,635 $144,883 Cash operating costs 13,824* 17,280 23,040 54,144 Light fixtures 720* 480* — 1,200 Total $63,936* $83,616 $52,675 $200,227
*Given
5.
Item Receipts Disbursements Net cash increase Net cash decrease
*Given
6.
Schedule F: Financing Required Item Beginning cash balance Net cash increase Net cash decrease Cash position before borrowing (a) Minimum cash balance required Excess (Deficiency) Borrowing required (b) Interest payments (c) Borrowing repaid(d) Ending cash balance [(a) + (b) − (c) − (d)]
*Given
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Schedule E: Budgeted Cash Receipts and Disbursements October November December 4th Quarter $55,200* $68,400 $90,000 $213,600 63,936* 83,616 52,675 200,227 $37,325 $ 13,373 ($8,736)* ($15,216)
October November December 4th Quarter $14,400* $ 9,664* $10,448 $14,400 37,325 13,373 8,736* 15,216 _______ _______ 5,664*
(5,552)
47,773
27,773
9,600* (3,936)* 4,000* _______
9,600 (15,152) 16,000 _______
9,600 38,173 660 20,000
9,600 18,173 20,000 660 20,000
$ 9,664*
$10,448
$27,113
$27,113
(c) Interest computation: $4,000 @ 18% for 3 months = $180 $16,000 @ 18% for 2 months = 480 Total interest expense = $660
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Chapter 6
6‐33 (cont’d) 7.
8.
Short‐term, self‐liquidating financing is best. The schedules clearly demonstrate the mechanics of a “self‐liquidating” loan. The need for such a loan arises because of the seasonal nature of many businesses. When sales soar, the payroll and suppliers must be paid in cash. The basic source of cash is proceeds from sales. However, the credit extended to customers creates a lag between the sale and the collection of cash. When the cash is collected, it in turn may be used to repay the loan. The amount of the loan and the timing of the repayment are heavily dependent on the credit terms that pertain to both the purchasing and selling functions of the business. Somewhat strangely, in seasonal businesses the squeeze on cash is often heaviest in the months of peak sales and is lightest in the months of low sales.
Newport Stationery Store Budgeted Income Statement For the Quarter Ending December 31 Revenues—Schedule A Cost of goods sold (70% of sales) Gross margin 67,680 Operating costs Salaries and wages—Schedule C $33,840 Rent—Schedule C 11,280 Other cash operating costs—Schedule C 9,024 Amortization ($1,200 × 3 months) 3,600 Operating income 9,936 Deduct interest expense Schedule F Add purchase discounts—schedule B Net income (before taxes) *Note: Ending inventory and proof of cost of goods sold: Inventory, September 30 $ 76,320 Add purchases—schedule B 147,840 Deduct inventory, December 31: Basic inventory 36,000 December purchases—Schedule B 30,240 Cost of goods sold
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$ 225,600 157,920*
57,744 (660) 2,957 $ 12,233
$224,160
66,240 $157,920
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6‐33 (cont’d) Newport Stationery Store Budgeted Balance Sheet December 31 9.
Assets: Current assets: Cash—Schedule F Accounts receivable December credit sales—Schedule A Inventory (see Note above) Total current assets Equipment and fixtures: Equipment—net ($120,000 – $3,600 amortization) Fixtures—Schedule D Total Liabilities and Owners’ Equity: Liabilities Owners’ equity Total * Owners’ equity, September 30: $14,400 + $76,320 + $12,000 + $120,000 (Given) $222,720 Net income, quarter ended December 31 12,233 Owners’ equity, December 31 $234,953
$27,113
24,000 66,240 117,353
$116,400 1,200
117,600 $234,953
None $234,953* $234,953
All of the transactions have been simplified—for example, no bad debts are considered. Also, many businesses face wide fluctuation of cash flows within a month. For example, perhaps customer receipts lag and are bunched together near the end of a month and disbursements are due evenly throughout the month or are bunched near the beginning of the month. Cash requirements would then need to be evaluated on a weekly and perhaps daily basis rather than on a monthly basis. Consider also that borrowing and payment are not necessarily always done on the first and last day of each moth.
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Chapter 6
6‐34
Prepare a cash budget.
Itami Wholesale Co. Statement of Budgeted Cash Receipts and Disbursements For the Months of December 2013, and January 2014
December 2013 January 2014 Cash balance, beginning $ 12,000 $ 2,580 Add receipts: Collections of receivables (schedule 1) 283,080 342,960 Total cash available for needs (a) 295,080 345,540 Deduct disbursements: For merchandise purchases (schedule 2) 220,500 170,100 For variable costs (schedule 3) 60,000 30,000 For fixed costs (schedule 3) 12,000 12,000 Total disbursements (b) 292,500 212,100 Cash balance, end of month [(a) – (b)] $ 2,580 $133,440 Enough cash should be available for repayment of the note on January 31, 2014. Schedule 1: Collections of Receivables Collections in October November December $17,280[a] 60,000[b] 205,800[c] January 24,000[d] [a] 0.08 × $216,000 [d] 0.08 × $300,000
December
Total
72,000[e] 246,960[f]
$283,080 $342,960
[b] 0.20 × $300,000 [c] 0.70 × $300,000 × 0.98 [e] 0.20 × $360,000 [f] 0.70 × $360,000 × 0.98
Schedule 2: Payments for Merchandise November Target ending inventory (in units) 1,250[b] Add units sold (Sales ÷ $120) 2,500 Total requirements 3,750 Deduct beginning inventory (in units) 1,125[d] Purchases (in units) 2,625 Purchases in dollars (units × $84) $220,500
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December 875[a] 3,000 3,875 1,250 2,625
January 800[c] 1,500 2,300 875 1,425
$220,500
$119,700
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6‐34 (cont’d)
Cash disbursements: For previous month’s purchases at 50% For current month’s purchases at 50%
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December
January
$110,250 110,250 $220,500
$110,250 59,850 $170,100
[a] 500 units + 0.25($180,000 ÷ $120) [b] $105,000 ÷ $84 [c] 500 units + 0.25($144,000 ÷ $120) [d] 500 units + 0.25($300,000 ÷ $120)
Also: [b] Ending Inventory Nov. = 500 units + 0.25 (360,000 ÷ 120) = 1,250 Schedule 3: Marketing. Distribution, and Customer Service Costs Total annual fixed costs, $180,000, minus $36,000 amortization Monthly fixed cost requiring cash outlay Variable cost ratio to sales =
$480,000 – $180,000 $1,800,000
December variable costs: 1/6 × $360,000 sales = $60,000 January variable costs: 1/6 × $180,000 sales = $30,000
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= 1/6 (= 0.167)
$144,000 $ 12,000
Chapter 6
6‐35 (30 min.) Activity‐based budgeting. 1. Revenue Budget For the Quarter Ending March 31 Units 20,000 Selling price $120 Total revenue $2,400,000 2. Direct Material Usage Budget in Quantity and Dollars For the Quarter Ending March 31 Physical units budget Direct materials required (20,000 units 10 g) 200,000 g Cost budget To be purchased this period $800,000 (200,000 g $4 per g) Direct materials to be used this period $800,000 3. Direct Manufacturing Labour Costs Budget For the Quarter Ending March 31 Output units produced 20,000 Direct manufacturing labour‐hours per unit 2 Total direct manufacturing labour‐hours 40,000 $15 Hourly wage rate Total direct manufacturing labour costs $600,000
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6‐35 (cont’d) 4. Manufacturing Overhead Costs Budget For the Quarter Ending March 31 Machine setup overhead (400 setup‐hours $80 per hour) $32,0001 Operations overhead (40,000 hours $1.60 per hour) 64,000 Total manufacturing overhead costs $96,000
(20,000 units/100units) = 200 batches. Each batch requires 2 setup hours, so 200 batches 2 setup‐ hours per batch = 400 setup‐hours 1
5. Budgeted Unit Cost For the Quarter Ending March 31 Cost per Unit of Input per Input Unit of Output Direct material $ 4 10 g Direct manufacturing labour 15 2 DMLH Machine setup overhead 80 0.02 setup‐hours1 Operations overhead 1.60 2 DMLH Total cost per gizmo
Total $40.00 30.00 1.60 3.20 $74.80
Setup‐hours per gizmo = 400 setup‐hours ÷ 20,000 gizmos = 0.02 setup‐hours per gizmo.
1
Alternatively, Budgeted Unit Cost For the Quarter Ending March 31 Total (1) Direct material costs (requirement 2) $ 800,000 Direct manufacturing labour costs (requirement 3) 600,000 Machine setup overhead costs (requirement 4) 32,000 Operations overhead costs (requirement 4) 64,000 Total costs $1,496,000
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Per unit (2) = (1) ÷ 20,000 $40.00 30.00 1.60 3.20 $74.80
Chapter 6
6‐35 (cont’d) 6. Cost of Goods Sold Budget For the Quarter Ending March 31
Beginning finished goods inventory, Jan. 1 Direct materials used Direct manufacturing labour Manufacturing overhead Cost of goods manufactured Cost of goods available for sale Deduct: Ending finished goods inventory, Mar. 311 Cost of goods sold
Total $800,000 600,000 96,000
$ 72,000 1,496,000 1,568,000 72,000 $1,496,000
Under LIFO cost flow assumption, the 1,000 gizmos in beginning finished goods inventory that remain in inventory on March 31 continue to be valued at $72,000.
1
7. Budgeted Gross Margin For the Quarter Ending March 31 Revenue $2,400,000 Cost of goods sold 1,496,000 Gross margin $ 904,000
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6‐35 (cont’d) 8.
Direct material Direct manufacturing labour Machine setup overhead Operations overhead
1st Quarter Quantity (1) 10 oz 2 DMLH 0.02 setup‐hours 2 DMLH
Proposed Decrease (2) 1% 1% 3% 1%
2nd Quarter 3rd Quarter Revised Revised Quantity Quantity (3) = (1)×(100% ─ (4) = (3)×(100% ─ (2)) (2)) 9.9 g 9.8 g 1.98 DMLH 1.96 DMLH 0.0194 setup‐hours 0.01882 setup‐hours 1.98 DMLH 1.96 DMLH
Budgeted Unit Cost For the Quarters Ending June 30 and Sept. 30 nd Budgeted 3rd Quarter Cost per 2 Quarter Input per Unit Cost Input per Unit of Input Unit of Output June 30 Unit of Output Direct material $ 4 9.9 g $39.60 9.8 g Direct manufacturing labour 15 1.98 DMLH 29.70 1.96 DMLH Machine setup overhead 80 0.0194 setup hrs. 1.55 0.0188 setup‐hrs Operations overhead 1.60 1.98 DMLH 3.17 1.96 DMLH Total $74.02
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Budgeted Unit Cost Sept. 30 $39.20 29.40 1.50 3.14 $73.24
Chapter 6
6‐35 (cont’d) Budgeted Gross Margin For the Quarters Ending June 30 Revenue $2,400,000 Cost of goods sold ($74.02; $73.24 × 20,000) 1,480,400 Gross margin $ 919,600 9.
Sept. 30 $2,400,000 1,464,800 $ 935,200
Reduction in materials can be accomplished by reducing waste and scrap. Reduction in direct labour and setup time can be accomplished by improving the efficiency of operations and decreasing down time. Employees who make the gizmos may have suggestions for ways to do their jobs more efficiently. For instance, employees may recommend process changes that reduce idle time, setup time, and scrap. To motivate workers to improve efficiency, many companies have set up programs that share productivity gains with the workers. Korna must be careful that productivity improvements and cost reductions do not in any way compromise product quality.
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6‐36 (60 min.) 1.
Comprehensive problem with ABC costing.
Revenue Budget For the Month of April Selling Units Price Total Revenue Cat‐allac 500 $160 $ 80,000 Dog‐eriffic 300 250 75,000 Total $155,000
2.
Production Budget For the Month of April
Product Cat‐allac Dog‐eriffic Budgeted unit sales 500 300 Add target ending finished goods inventory 35 15 Total required units 535 315 Deduct beginning finished goods inventory 15 30 Units of finished goods to be produced 520 285 3a.
Direct Material Usage Budget in Quantity and Dollars For the Month of April Material Plastic Metal Total Physical Units Budget Direct materials required for Cat‐allac (520 units × 4 kgs. and 0.5 kg.) 2,080 kgs. 260 kgs. 285 kgs. Dog‐errific (285 units × 6 kgs. and 1 kg.) 1,710 kgs. Total quantity of direct material to be used 3,790 kgs. 545 kgs.
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Chapter 6
6‐36 (cont’d) Cost Budget Available from beginning direct materials inventory (under a FIFO cost‐flow assumption) Plastic: 250 kgs. × $3.80 per kg. $ 950 Metal: 60 kgs. × $3 per kg. $ 180 To be purchased this period Plastic: (3,790 – 250) kgs. $4 per kg. 14,160 __ ____ 1,455 Metal: (545 – 60) kgs. $3 per kg. Direct materials to be used this period $15,110 $ 1,635 $16,745 Direct Material Purchases Budget For the Month of April Material Plastic Metal Total Physical Units Budget To be used in production (requirement 3) 3,790 kgs. 545 kgs. Add target ending inventory 380 kgs. 55 kgs. Total requirements 4,170 kgs. 600 kgs. Deduct beginning inventory 250 kgs. 60 kgs. Purchases to be made 3,920 kgs. 540 kgs. Cost Budget Plastic: 3,920 kgs. $4 $15,680 Metal: 540 kgs. $3 ______ $ 1,620 $ 1,620 $ 17,300 Purchases $15,680
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6‐36 (cont’d) 4. Direct Manufacturing Labour Costs Budget For the Month of April Output Units Hourly Produced DMLH Total Wage (requirement 2) per Unit Hours Rate Cat‐allac 520 3 1,560 $10 Dog‐errific 285 5 1,425 10 Total 5.
Total $15,600 14,250 $29,850
Machine Setup Overhead Units to be produced Units per batch Number of batches Setup time per batch Total setup time
Cat‐allac 520 ÷ 20 26 1.5 hrs. 39 hrs.
Dog‐errific 285 ÷15 19 1.75 hrs. 33.25 hrs.
Total 72.25 hrs.
Budgeted machine setup costs
= $100 per setup hour 72.25 hours = $7,225
Processing Overhead Budgeted machine‐hours (MH) = (10 MH per unit × 520 units) + (18 MH per unit × 285 units) = 5,200 MH + 5,130 MH = 10,330 MH Budgeted processing costs = $5 per MH × 10,330 MH = $51,650
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Inspection Overhead Budgeted inspection hours = (0.5 26 batches) + (0.6 19 batches) = 13 + 11.4 = 24.4 inspection hrs. Budgeted inspection costs = $16 per inspection hr. 24.4 inspection hours = $390.40
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Chapter 6
Manufacturing Overhead Budget For the Month of April Machine setup costs $ 7,225 Processing costs 51,650 Inspection costs 390 Total costs $59,265 6. Unit Costs of Ending Finished Goods Inventory April 30 Product Cat‐allac Dog‐errific Cost per Input per Input per Unit of Unit of Unit of Input Output Total Output Total Plastic $ 4 4 kgs. $ 16.00 6 kgs. $ 24.00 Metal 3 0.5 kgs. 1.50 1 kg. 3.00 Direct manufacturing labour 10 3 hrs. 30.00 5 hrs. 50.00 1 1 Machine setup 100 0.075 hrs. 7.50 0.1167 hr 11.67 Processing 5 10 MH 50.00 18 MH 90.00 2 2 0.40 0.04 hr. 0.64 Inspection 16 0.025 hr Total $105.40 $179.31 39 setup hours ÷ 520 units = 0.075 hours per unit; 33.25 setup hours ÷ 285 units = 0.1167 hours per unit 2 13 inspection hours ÷ 520 units = 0.025 hours per unit; 11.4 inspection hours ÷ 285 units = 0.04 hours per unit 1
Direct Materials Plastic Metals Finished goods Cat‐allac Dog‐errific Total ending inventory
Ending Inventories Budget April 30 Quantity Cost per Unit 380 $4 55 3 35 $105.40 15 179.31
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Total $1,520 165 $3,689 2,690
$1,685 6,379 $8,064
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6‐36 (cont’d) 7. Cost of Goods Sold Budget For the Month of April Beginning finished goods inventory, April, 1 ($1,500 + $5,580) Direct materials used (requirement 3) $16,745 Direct manufacturing labour (requirement 4) 29,850 Manufacturing overhead (requirement 5) 59,265 Cost of goods manufactured Cost of goods available for sale Deduct: Ending finished goods inventory, April 30 (reqmt. 6) Cost of goods sold 8. Nonmanufacturing Costs Budget For the Month of April Salaries ($36,000 ÷ 2 1.05) $18,900 Other fixed costs ($36,000 ÷ 2) 18,000 Sales commissions ($155,000 1%) 1,550 Total nonmanufacturing costs $38,450 9. Budgeted Income Statement For the Month of April Revenue $155,000 Cost of goods sold 106,561 Gross margin 48,439 Operating (nonmanufacturing) costs 38,450 Operating income $ 9,989
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$ 7,080 105,860 112,940 6,379 $106,561
Chapter 6
6‐37 (25 min.) Cash budget. Cash Budget April 30 Cash balance, April 1 Add receipts Cash sales ($155,000 × 10%) Credit card sales ($155,000 × 90% × 97%) Total cash available for needs (x) Deduct cash disbursements Direct materials ($8,500 + ($17,300 × 50%)) Direct manufacturing labour Manufacturing overhead ($59,265 – $20,000 depreciation) Nonmanufacturing salaries Sales commissions Other nonmanufacturing fixed costs ($18,000 – $10,000 deprn) Machinery purchase Income taxes Total disbursements (y) Financing Repayment of loan 1 Interest at 12% ($2,000 12% ) 12 Total effects of financing (z) Ending cash balance, April 30 (x) ─ (y) ─ (z)
$ 5,360 15,500 135,315 $156,175 $ 17,150 29,850 39,265 18,900 1,550 8,000 13,700 5,000 $133,415 $ 2,000 20 $ 2,020 $ 20,740
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6‐38 (15 min.) Responsibility and controllability. The time lost in the plant should be charged to the purchasing department. Certainly, the plant manager could not be asked to underwrite a loss which is due to failure of delivery over which he had no supervision. Although the purchasing agent may feel that he has done everything he possibly could, he must realize that, in the whole organization, he is the one who is in the best position to evaluate the situation. He receives an assignment. He may accept it or reject it. But if he accepts, he must perform. If he fails, the damage is evaluated. Everybody makes mistakes. The important point is to avoid making too many mistakes and also to understand fully that the extensive control reflected in “responsibility accounting” is the necessary balance to the great freedom of action that individual executives are given. Discussions of this problem have again and again revealed a tendency among students (and among accountants and managers) to “fix the blame”—as if the variances arising from a responsibility accounting system should pinpoint misbehaviour and provide answers. The point is that no accounting system or variances can provide answers. However, variances can lead to questions. In this case, in deciding where the penalty should be assigned, the student might inquire who should be asked—not who should be blamed. Classroom discussions have also raised the following diverse points: (a) Is the railway company liable? Yes, and they have liability insurance. (b) Costs of idle time are usually routinely charged to the production department. Should the information system be fine‐tuned to reallocate such costs to the purchasing department? Both purchasing and the plant manager answer to either a business manager or an operations manager. The buck stops here. Some companies have the purchasing department answer directly to the plant manager, which would be a probable result of the above mistake. Give accountability to the plant manager as his/her authority warrants it. (c) How will the purchasing managers behave in the future regarding willingness to take risks? The text emphasizes the following: Beware of overemphasis on controllability. For example, a time‐honoured theme of management is that responsibility should not be given without accompanying authority. Such a guide is a useful first step, but responsibility accounting is more far‐reaching. The basic focus should be on information or knowledge, not on control. The key question is: “Who is the best informed?” Put another way, “Who is the person who can tell us the most about the specific item, regardless of ability to exert personal control?”
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6‐39 (15 min.) Budgeting and governance. 1. 2.
3.
The standards proposed by Wert are not challenging. In fact, he set the target at the level his department currently achieves. DM 2.95 lbs. 100 units = 295 lbs. DL 19.2 min. 100 units = 1,920 min ÷ 60 = 32 hrs. MT 9.9 min. 100 units = 990 min. ÷ 60 = 16.5 hrs. Wert probably chose these standards so that his department would be able to make the goal and receive any resulting reward. With a little effort, his department can likely beat these goals. As discussed in the chapter, benchmarking might be used to highlight the easy targets set by Wert. Perhaps the organization has multiple plant locations that could be used as comparisons. Alternatively, management could use industry averages. Also, management should work with Wert to better understand his department and encourage him to set more realistic targets. Finally, the reward structure should be designed to encourage increasing productivity, not beating the budget.
6‐40 1. 2.
Prepare a master operating budget.
Schedule 1: Revenue Budget for the Year Ended December 31, 2013 Units Snowboards 1,200
Selling Price Total Revenues $540 $648,000
Schedule 2: Production Budget (in Units) for the Year Ended December 31, 2013 Snowboards Budgeted unit sales (Schedule 1) 1,200 Add target ending finished goods inventory 200 Total requirements 1,400 Deduct beginning finished goods inventory 100 Units to be produced 1,300
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6‐40 (cont’d) 3.
4.
Schedule 3A: Direct Materials Usage Budget for the Year Ended December 31, 2013 Wood Fibreglass Physical Budget To be used in production (Wood: 1,300 × 5.00 b.f. Fibreglass: 1,300 × 6.00 yards) 6,500 7,800 6,500 7,800 Cost Budget (uses FIFO) Available from beginning inventory (Wood: 2,000 b.f. × $34.00 68,000 Fibreglass: 1,000 yards × 5.80) 5,800 To be used from purchases this period (Wood: (6,500 – 2,000) × $36.00 $162,000 Fibreglass: (7,800 – 1,000) × $6.00) ________ $40,800 Total cost of direct materials to be used $230,000 $46,600 Schedule 3B: Direct Materials Purchases Budget for the Year Ended December 31, 2013 Wood Fibreglass Physical Budget Production usage (from Schedule 3A) 6,500 7,800 Add target ending inventory 1,500 2,000 Total requirements 8,000 9,800 Deduct beginning inventory 2,000 1,000 Purchases 6,000 8,800 Cost Budget (Wood: 6,000 × $36.00 $216,000 Fibreglass: 8,800 × $6.00) ________ $52,800 $52,800 $216,000 Note: All units of measurement are standard in this industry. Schedule 4: Direct Manufacturing Labour Budget for the Year Ended December 31, 2013 Cost Labour Driver DML Hours per Total Category Units Driver Unit Hours Manufacturing Labour 1,300 5.00 6,500
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Total
$276,600
Total
$268,800
Wage Rate
Total
$25.00
$162,500
Chapter 6
6‐40 (cont’d) 5. 6.
Schedule 5: Manufacturing Overhead Budget for the Year Ended December 31, 2013 At Budgeted Level of 6,500 Direct Manufacturing Labour‐Hours Variable manufacturing overhead costs ($8.40 × 6,500) $ 54,600 Fixed manufacturing overhead costs 78,000 Total manufacturing overhead costs $132,600 Budgeted manufacturing overhead rate:
$132,600 = $20.40 per DML hour 6,500
7. Budgeted manufacturing overhead cost per output unit: 8.
Schedule 6A: Computation of Unit Costs of Finished Goods Inventory at End of 2013 Direct materials Wood Fibreglass Direct manufacturing labour Total manufacturing overhead Total cost per unit
$132,600 = $102.00 per output unit 1,300
Cost per Unit of Inputa
Inputsb
Total
$36.00 6.00 25.00
5.00 6.00 5.00
$180.00 36.00 125.00 102.00 $443.00
Units
Cost per Unit
Total
1,500 2,000
$36.00 6.00
$ 54,000 12,000
200
443.00
88,600 $154,600
Cost is per board‐foot, yard, or hour. Inputs is the amount of input per board.
a
b
9.
Schedule 6B: Ending Inventory Budget December 31, 2013 Direct materials Wood Fibreglass Finished goods Snowboards Total Ending Inventory
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6‐40 (cont’d) 10. 11.
Budgeted Income Statement for Slopes, Inc. for the Year Ended December 31, 2013 Revenue Schedule 1 Costs Cost of goods sold Schedule 7 Gross margin Operating costs Marketing costs ($300 × 36) $ 10,800 Other costs* 36,000 Operating income
*Fixed nonmanufacturing costs
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Schedule 7: Cost‐of‐Goods‐Sold Budget for the Year Ended December 31, 2013 Beginning finished goods inventory January 1, 2013 Direct materials used Direct manufacturing labour Manufacturing overhead Cost of goods manufactured Cost of goods available for sale Deduct ending finished goods inventory, December 31, 2013 Cost of goods sold
From Schedule
Total
Given 3A 4 5
$276,600 162,500 132,600
$ 44,976
6B
88,600 $528,076
$648,000
528,076 119,924
46,800 $ 73,124
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571,700 616,676
Chapter 6
6‐41
Responsibility versus controllability; fixing responsibility.
Note that the lost contribution margin of $1,200 is rarely accounted for in ordinary accounting systems. If measured at all, it would appear as an underachieved budgeted contribution margin; that is, actual would be less than budgeted by $1,200. The essence of this case is to demonstrate the limitations of responsibility accounting and the futility of a “blame‐setting” theme in implementing responsibility accounting. The responsibility lies with the authority, the city manager. She was not specific in delegating responsibility. If her authority is required to break a stalemate, then her people must know to take the stalemate to her. The repair shop manager was negligent in not doing this. The theory of responsibility accounting is straightforward—link each cost ultimately to one person in the organization who has the most day‐to‐day influence over its total amount. Repair and maintenance costs provide one of the most difficult illustrations of implementing the theory. The total cost of the repair job, by itself, is the responsibility of the repair shop manager. The manager has the most influence over the total amount incurred at the instant of repair. However, in the eyes of many observers, the department is only an intermediate cost objective because it services other departments. Most students will probably maintain that the utility department should bear the $3,120 cost because its failure to maintain specified clearances led to this incident. Some students will feel that the sanitation department should bear the extra costs above the $2,400 original proposal. Decisions regarding these disputes are inherently contextual, so students should be properly uneasy about choosing a course of action for the controller. The controller has dealt with all parties before and will interact with them again and again, so he must measure the effects of his present decision against a whole series of decisions about the running of the control system. The key is to prevent a similar occurrence in this or other areas. Given these precautions, the controller might avoid the issue of “fixing blame” by not charging any department (or by charging the controller’s department). All the managers seem to have partial responsibility. It would be reasonable to split the $3,120 cost between them evenly to avoid singling one manager out from the others, yet still penalize each one for making an error. The lost $1,200 revenue need not be split. The controller should learn from this incident and take action to: 1. Pinpoint responsibility for preventive maintenance of utility lines in the future. Decide how future costs should be allocated to provide the best set of coordinated goals and incentives. 2. Have a meeting of all department heads involved to improve mutual understanding of responsibilities.
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COLLABORATIVE LEARNING CASES Comprehensive budgeting problem; activity‐based costing, 6‐42 (60 min.) operating and financial budgets. 1a. Revenue Budget For the Month of June Large Giant Total
Units Selling Price Total Revenue 3,000 $3 $ 9,000 1,800 4 7,200 $16,200
1b. Production Budget For the Month of June Budgeted unit sales Add: target ending finished goods inventory Total required units Deduct: beginning finished goods inventory Units of finished goods to be produced
Product Large Giant 3,000 1,800 300 180 3,300 1,980 200 150 3,100 1,830
1c. Direct Material Usage Budget in Quantity and Dollars For the Month of June Material Sugar Sticks Physical Units Budget Direct materials required for Large (3,100 units × 0.25 lb.; 1 stick) 775 lbs. 3,100 1,830 Giant (1,830 units × 0.50 lb.; 1 stick) 915 lbs. 4,930 Total quantity of direct materials to be used 1,690 lbs. Cost Budget Available from beginning direct materials inventory (under a FIFO cost‐flow assumption) $ 64 $ 105 To be purchased this period Sugar: (1,690 lbs. – 125 lbs.) × $0.50 per lb. 783 Sticks: (4,930 – 350) × $0.30 per stick ____ 1,374 $1,479 Direct materials to be used this period $847
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Total $2,326
Chapter 6
6‐42 (cont’d) Direct Materials Purchases Budget For the Month of June Material Sugar Sticks Physical Units Budget To be used in production 1,690 lbs. 4,930 480 Add: Target ending direct material inventory 240 lbs. Total requirements 1,930 lbs. 5,410 Deduct: beginning direct material inventory 125 lbs. 350 5,060 Purchases to be made 1,805 lbs. Cost Budget Sugar: (1,805 lbs. × $0.50 per lb.) $903 Sticks: (5,060 × $0.30 per stick) ____ $1,518 Total $903 $1,518
Total $2,421
1d.
Large Giant Total 1e.
Direct Manufacturing Labour Costs Budget For the Month of June Output Units Direct Manufacturing Total Hourly Wage Produced Labour‐Hours per Unit Hours Rate 3,100 0.20 620 $8 1,830 0.25 457.5 8 1,077.5
Total $4,960 3,660 $8,620
Manufacturing Overhead Costs Budget For the Month of June Machine setup (Large 310 batches1 0.08 hrs./batch + Giant 183 batches2 0.09 hrs./batch) $20/hour Processing (1,077.5 DMLH $1.70) Total
Total $ 825 1,832 $2,657
1 2
Large: 3,100 units ÷ 10 units per batch = 310 Giant: 1,830 units ÷ 10 units per batch = 183
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6‐42 (cont’d) 1f. Unit Costs of Ending Finished Goods Inventory For the Month of June Large Giant Input per Input per Unit of Unit of Cost per Unit of Input Output Total Output Total Sugar $ 0.50 0.25 lb $0.125 0.50 lb. $ 0.25 Sticks 0.30 1 0.30 1 0.30 Direct manufacturing labour 8.00 0.2 hr. 1.60 0.25 hr. 2.00 Machine setup 20.00 0.008 hr. 1 0.16 0.009 hr1 0.18 Processing 1.70 0.2 hr 0.34 0.25 hr 0.425 Total $2.525 $3.155
0.08 hour per setup ÷ 10 units per batch = 0.008 hr. per unit; 0.09 hour per setup ÷ 10 units per batch = 0.009 hr. per unit. 1
Direct Materials Sugar Sticks Finished goods Large Giant Total ending inventory
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Ending Inventories Budget June Quantity Cost per unit 240 lbs. $0.50 480 sticks 0.30 300 $2.525 180 3.155
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Total $120 144 $757 568
$ 264 1,325
$1,589
Chapter 6
6‐42 (cont’d) 1g. Cost of Goods Sold Budget For the Month of June Beginning finished goods inventory, June 1 ($500 + $474) Direct materials used (requirement c) $2,326 Direct manufacturing labour (requirement d) 8,620 Manufacturing overhead (requirement e) 2,657 Cost of goods manufactured Cost of goods available for sale Deduct ending finished goods inventory, June 30 (requirement f) Cost of goods sold 1h. Nonmanufacturing Costs Budget For the Month of June Total Marketing and general administration $1,620 10% 16,200
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$ 974 13,603 14,577 1,325 $13,252
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6‐42 (cont’d) 2. Cash Budget June 30 Cash balance, June 30 Add receipts Collections from May accounts receivable Collections from June accounts receivable ($16,200 80% 50%) Collections from June cash sales ($16,200 20%) Total collection from customers Total cash available for needs (x) Deduct cash disbursements Direct material purchases in May Direct material purchases in June ( $2,421 70%) Direct manufacturing labour Manufacturing overhead ( $2,657 60% because 40% is depreciation) Nonmanufacturing costs ( $1,620 70% because 30% is depreciation) Taxes Total disbursements (y) Financing Interest at 12% ($20,000 12% 1 ÷ 12) (z) Ending cash balance, June 30 (x) ─ (y) ─ (z)
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$ 587 4,704 6,480 3,240 14,424 $15,011 $ 696 1,695 8,620
1,594
1,134 500 $14,239 $ 200 $ 572
Chapter 6
6‐42 (cont’d) 3. Budgeted Income Statement For the Month of June Revenue Cost of goods sold Gross margin Operating (nonmanufacturing) costs $1,620 Bad debt expense ($16,200 80% 1%) 130 Interest expense (for June) 200 Net income
$16,200 13,252 2,948 1,950 $ 998
Budgeted Balance Sheet June 30 Assets Cash Accounts receivable ($16,200 80% 50%) $ 6,480 Less: allowance for doubtful accounts 130 Inventories Direct materials $ 264 Finished goods 1,325 Fixed assets $190,000 Less: accumulated depreciation 57,308 ($55,759 + 2,657 40% + 1,620 30%) Total assets Liabilities and Equity Accounts payable ($2,421 30%) Interest payable Long‐term debt Common stock Retained earnings ($109,279 + $998) Total liabilities and equity
$ 572 6,350 1,589 132,692 $141,203 $ 726 200 20,000 10,000 110,277 $141,203
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6‐43 (60 min.)
University department, budget revision options.
This exercise illustrates the difficulty of budgeting issues in universities. There are multiple stakeholders—student‐athletes, student non‐athletes, coaches, sports administrators, university faculty, university administrators, and alumni. Actions that benefit one type of stakeholder can “gore the ox” of other stakeholders. The general options that groups could examine are outlined below. Increasing Revenue There are at least two approaches to “increase” revenue: (a) Increase revenue from outside sources. For example, sell more tickets to football, basketball, etc. This is heavily driven by success. Medley’s concerns about academic standards likely will constrain Gemst’s flexibility to recruit any athlete he believes to be a major star. Some universities have been innovative in terms of increasing cable television revenue from coverage of university sporting games. Gemst could propose direct fundraising for the athletics department. This could run into problems with Medley, as she may require all fundraising to be coordinated at the University level. (b) Increase the “revenue” attributed to the athletics department. Gemst could argue that a successful athletics program has many positive externalities for Pacific University, many of which increase P.U. revenue. • Alumni are more likely to give money and other contributions when they are stimulated by being on campus to watch a nationally ranked team or viewing a successful P.U. team on television. Many universities use tickets to athletic events and invitations to related social functions as a thank‐you to major donors. • Athletics officials (especially nationally prominent coaches) are expected to assist Medley and her senior officers in promoting P.U. to potential donors, parents of future students, etc. For example, the coach of a number‐one‐ranked football team may attend over 50 dinners/functions a year on behalf of the university. Some of these dinners are “one‐on‐one” with potential large donors. • Merchandising revenue sold to alumni and other supporters is likely to increase when P.U.’s athletics teams achieve national success. These include sweaters, towels, and rings. The current budgeting process gives zero recognition to these externalities, which may well exceed the projected $3.612 million deficit.
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6‐43 (cont’d) Decreasing Costs Gemst can always cut costs to meet any level Medley may impose. However, the ways to achieve any substantial reduction will be relatively painful. (a) Reduce scholarships (either number or amount) to students. This can take time to achieve bottom‐line reductions as existing students may have three more years of scholarship remaining. Unless Gemst cuts existing scholarships, he is restricted to cutting back on scholarships to new students. This option will be very painful. One consequence will be lower‐quality levels of student athletes which will have implications for the sporting competitiveness of P.U. The option of cutting back on already committed existing scholarships would be traumatic (but it has occurred). Gemst could undertake across‐the‐board cuts or target the reductions to some sports. For example, sports that do not draw sizable crowds may be candidates for reduction. One difficulty here is that Gemst is faced with both reducing total costs and increasing the relative percentage of scholarships to women. The scholarship breakdown is: Men’s Women’s Program Program Total Football 37 — 37 Basketball 21 11 32 Swimming 6 4 10 Other 4 2 6 Total 68 17 85 The largest percentage of scholarships are for the two highly successful programs— men’s football (37/85 = 44%) and men’s basketball (21/85 = 25%). There is little room for cutbacks in the second tier sports at P.U. (b) Reduce sports sponsored by the athletics department. Cut out support for all but a few targeted sporting programs. This will cause morale problems for students in these sporting programs (such as rugby, soccer, and volleyball). (c) Reduce salaries and other costs of the athletics department. The salary for Bill Madden is an obvious target for Gemst’s cost reduction. However, Madden may have a multi‐year contract that leaves P.U. little room for cost reduction. Moreover, if cost reduction is attempted, Madden may leave, which could have negative general effects on morale and university finances. Gemst could approach alumni or sponsors to cover Madden’s salary and other costs. This would address Medley’s budget balance concerns but not her concern as to the level of Madden’s salary vis‐à‐vis leading academics.
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6‐43 (cont’d) Cost reductions could be achieved by reducing the number of assistant coaches and the number of support officials. The effect of these reductions on student morale and P.U. athletic achievements is difficult to measure. Gender Issues Based on dollar expenditures and scholarships, Medley has evidence to support her concerns. The men’s programs get the “lion’s share” of the expenditures and student scholarships. Men’s Women’s Program Program Costs $13.248 million $3.36 million Full student scholarships 68 17 Gemst could respond by noting that the men’s programs have a lower deficit based on revenue minus assigned costs (in millions): Men’s Women’s Program Program Revenue $12.42 $ 0.936 Assigned costs 13.248 3.36 Contribution $(0.828) $(2.424) This lower deficit reflects, in part, the large revenue‐drawing capacity of their successful men’s football and athletics departments. Medley’s demands for a balanced budget, more gender equality, and higher academic standards leaves Gemst in an unenviable position.
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CHAPTER 7 FLEXIBLE BUDGETS, VARIANCES, AND MANAGEMENT CONTROL: I SHORT‐ANSWER QUESTIONS
7‐1 Static budget variance can mislead those assessing actual against pro forma performance indicators. The key issue is that when production and sales volume exceed pro forma amounts, an unfavourable cost variance analysis is an inevitable result of what is usually considered good news. Managers may waste valuable time investigating routine‐cost behaviour. 7‐2 Management by exception is the practice of concentrating on areas not operating as anticipated and giving less attention to areas operating as anticipated. Variance analysis helps managers identify areas not operating as anticipated. The larger the variance, the more likely an area is not operating as anticipated. 7‐3 A favourable variance—denoted F—is a variance that increases operating income relative to the budgeted amount. An unfavourable variance—denoted U—is a variance that decreases operating income relative to the budgeted amount. 7‐4 The key difference is the output level used to set the budget. A static budget is based on the level of output planned at the start of the budget period. A flexible budget is developed using budgeted revenues or cost amounts based on the level of output actually achieved in the budget period. The actual level of output is not known until the end of the budget period. Flexible budgets give managers more insight into the causes of variances than static budgets. 7‐5 The steps in developing a flexible budget are: Step 1: Determine the budgeted selling price per unit, the budgeted variable costs per unit, and the budgeted fixed costs. Step 2: Determine the actual quantity of the revenue driver. Step 3: Determine the flexible budget for revenue based on the budgeted unit revenue and the actual quantity of the revenue driver. Step 4: Determine the actual quantity of the cost driver(s). Step 5: Determine the flexible budget for costs based on the budgeted unit variable costs and fixed costs and the actual quantity of the cost driver(s). 7‐6 Four reasons for using standard costs are: (i) cost management, (ii) pricing decisions, (iii) budgetary planning and control, and (iv) financial statement preparation.
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7‐7
Possible causes of a favourable materials price variance are: • purchasing officer negotiated more skillfully than was planned in the budget, • purchasing manager bought in larger lot sizes than budgeted, thus obtaining quantity discounts, • materials prices decreased unexpectedly due to, say, industry oversupply, • budgeted purchase prices were set without careful analysis of the market, and • purchasing manager purchased lower quality materials.
7‐8
Direct materials price variances are often computed at the time of purchase while direct materials efficiency variances are often computed at the time of usage. Purchasing managers are typically responsible for price variances, while production managers are typically responsible for usage variances.
7‐9 Some possible reasons for an unfavourable direct manufacturing labour efficiency variance are: • the hiring and use of underskilled workers, • inefficient scheduling of work so that the workforce was not optimally occupied, • poor maintenance of machines resulting in a high proportion of non‐value‐ added labour, • unrealistic time standards. Each of these factors would result in actual direct manufacturing labour‐hours being higher than indicated by the standard work rate. 7‐10 A process where the inputs are nonsubstitutable leaves workers no discretion as to the components to use. A process where the inputs are substitutable means there is discretion about the exact number and type of inputs or about the weighting of inputs. 7‐11 The direct materials efficiency variance is a Level 3 variance. Further insight into this variance can be gained by moving to a Level 4 analysis where the effect of mix and yield changes are quantified. The mix variance captures the effect of a change in the relative percentage use of each input relative to that budgeted. The yield variance captures the effect of a change in the number of inputs required to obtain a given output relative to that budgeted.
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7‐12 Variance analysis, by providing information about actual performance relative to standards, can form the basis of continuous operational improvement. The underlying causes of unfavourable variances are identified, and corrective action taken where possible. Favourable variances can also provide information if the organization can identify why a favourable variance occurred. Steps can often be taken to replicate those conditions more often. As the easier changes are made, and perhaps some standards tightened, the harder issues will be revealed for the organization to act on—this is continuous improvement. 7‐13 An individual business function, such as production, is interdependent with other business functions. Factors outside of production can explain why variances arise in the production area. For example: purchasing of lower quality materials that creates excess waste poor design of products or processes can lead to a sizable number of defects, and marketing personnel making promises for delivery times that require a large number of rush orders that create production‐scheduling difficulties. 7‐14 The plant supervisor likely has good grounds for complaint if the plant accountant puts excessive emphasis on using variances to pin blame. The key value of variances is to help understand why actual results differ from budgeted amounts and then to use that knowledge to promote learning and continuous improvement.
EXERCISES
7‐15
Terminology.
The question is whether or not the actual results met expectations, exceeded expectations or failed to meet expectations and a variance analysis will respond to this question. A variance is the result of subtracting the budgeted or predicted outcome from the actual outcome. A favourable (F) variance means the effect of the variance is to increase operating income. An unfavourable (U) variance means the effect of the variance is to decrease operating income. A static budget variance simply fails to reflect the routine effect of changes in quantity produced and sold on the revenue and the variable costs. A flexible budget does reflect the routine changes to be expected when the quantity produced and sold fluctuates from what was predicted. The flexible budget permits more fineness in the report of non‐routine variances and management by exception. The flexible budget variance plus the sales volume variance equals the static budget variance.
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7‐15 (cont’d) When quantities of direct materials purchased and used differs from budget the variance can be the result of either a rate variance (input price variance) arising in an unexpected difference in the cost/unit or an efficiency variance arising from an unexpected difference in the quantity of the input used, or a combination of both. When a direct materials input mix has substitutable inputs the direct materials mix and the direct materials yield variance both become important. These elements of a level 4 analysis permit the managers to assess how changes from what was expected affected the yield. 7‐16 (20–30 min.) Flexible budget. Variance Analysis for Brabham Enterprises for August 2013
Units (tires) sold
Actual Results (1)
Flexible‐Budget Variances (2) = (1) – (3)
g
0
a
$ 5,600 F
$308,000 207,200
2,800
Revenues
$313,600
Variable costs Contribution margin
229,600
d
22,400 U
84,000
16,800 U
Fixed costs Operating income
g
2,800
200 U b
e
100,800 g
Static Budget (5) g
3,000 c
$22,000 U
$330,000
14,800 F
222,000
7,200 U
108,000
f
g
50,000
4,000 F
54,000
0
54,000
$ 34,000
$12,800 U
$ 46,800
$ 7,200 U
$ 54,000
$12,800 U
$ 7,200 U
Total flexible‐budget variance Total sales‐volume variance $20,000 U Total static‐budget variance $112 × 2,800 = $313,600
b
$110 × 3,000 = $330,000
d
$74 × 2,800 = $207,200
f
a c
Flexible Budget (3)
Sales‐ Volume Variances (4) = (3) – (5)
e
$110 × 2,800 = $308,000 Given. Unit variable cost = $229,600 ÷ 2,800 = $82 per tire
$74 × 3,000 = $222,000
Given
g
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Chapter 7
7‐16 (cont’d) 2.
The key information items are: Units Unit selling price Unit variable cost Fixed costs
Actual 2,800 $ 112 $ 82 $50,000
Budgeted 3,000 $ 110 $ 74 $54,000
The total static‐budget variance in operating income is $20,000 U. There is both an unfavourable total flexible‐budget variance ($12,800) and an unfavourable sales‐volume variance ($7,200). The unfavourable sales‐volume variance arises solely because actual units manufactured and sold were 200 less than the budgeted 3,000 units. The unfavourable flexible‐budget variance of $12,800 in operating income is due primarily to the $8 increase in unit variable costs. This increase in unit variable costs is only partially offset by the $2 increase in unit selling price and the $4,000 decrease in fixed costs.
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7‐17 (15 min.) Flexible budget. The existing performance report is a Level 1 analysis, based on a static budget. It makes no adjustment for changes in output levels. The budgeted output level is 10,000 units–– direct materials of $400,000 in the static budget ÷ budgeted direct materials cost per attaché case of $40. The following is a Level 2 analysis that presents a flexible‐budget variance and a sales‐volume variance of each direct cost category. Variance Analysis for Connor Company
Output units Direct materials Direct manufacturing labour Direct marketing labour Total direct costs
Actual Results (1) 8,800 $364,000 78,000 110,000 $552,000
Flexible‐ Budget Flexible Sales‐Volume Variances Budget Variances (2) = (1) – (3) (3) (4) = (3) – (5) 0 8,800 1,200 U $352,000 $12,000 U $48,000 F 70,400 7,600 U 9,600 F 105,600 4,400 U 14,400 F $528,000 $24,000 U $72,000 F $24,000 U $72,000 F Flexible‐budget variance Sales‐volume variance $48,000 F Static‐budget variance
Static Budget (5) 10,000 $400,000 80,000 120,000 $600,000
The Level 1 analysis shows total direct costs have a $48,000 favourable variance. However, the Level 2 analysis reveals that this favourable variance is due to the reduction in output of 1,200 units from the budgeted 10,000 units. Once this reduction in output is taken into account (via a flexible budget), the flexible‐budget variance shows each direct cost category to have an unfavourable variance indicating less efficient use of each direct cost item than was budgeted, or the use of more costly direct cost items than was budgeted, or both.
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7‐17 (cont’d) Each direct cost category has an actual unit variable cost that exceeds its budgeted unit cost: Actual Budgeted Units 8,800 10,000 Direct materials $ 41.36 $ 40.00 Direct manufacturing labour $ 8.86 $ 8.00 Direct marketing labour $ 12.50 $ 12.00 Analysis of price and efficiency variances for each cost category could assist in further the identifying causes of these more aggregated (Level 2) variances. 7‐18 (15 min.) Materials and manufacturing‐labour variances. Flexible Budget Actual Costs (Budgeted Input Incurred Actual Input Qty. Allowed for (Actual Input Qty. Qty. Actual Output × Actual Price) × Budgeted Price × Budgeted Price) Direct $200,000 $214,000 $225,000 Materials $14,000 F $11,000 F Price variance Efficiency variance $25,000 F Flexible‐budget variance Direct $90,000 $86,000 $80,000 Mfg. Labour $4,000 U $6,000 U Price variance Efficiency variance $10,000 U Flexible‐budget variance
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7‐19 (25 min.) 1.
Price and efficiency variances.
The key information items are: Output units (scones) Input units Cost per input unit
Actual 60,800 17,000 $0.99
Budgeted 60,000 16,000 $1.11
Peterson budgets to obtain 3.75 (60,000 ÷ 16,000) pumpkin scones from each kilogram of pumpkin. The flexible‐budget variance is $1,167 F. Flexible‐ Sales‐ Actual Budget Flexible Volume Static Results Variance Budget Variance Budget (1) (2)=(1)–(3) (3) (4)=(3)–(5) (5) Pumpkin costs 16,830a $1,167 F $17,997b $237 U $17,760c
17,000 $0.99 = $16,830 60,800 ÷ 3.75 $1.11 = $17,997 c60,000 ÷ 3.75 $1.11 = $17,760 a
b
2.
Actual Costs Incurred (Actual Input Actual Price $16,830a
Price variance
Flexible Budget (Budgeted Input Allowed for Actual Actual Input Output Achieved Budgeted Price Budgeted Price) $18,870b $17,997c $2,040 F $873 U Efficiency variance $1,167 F
Flexible‐budget variance 17,000 $0.99 = $16,830 b17,000 $1.11 = $18,870 (no inventory involved) c60,800 ÷ 3.75 $1.11 = $17,997 a
3.
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The favourable flexible‐budget variance of $1,167 has two offsetting components: (a) favourable price variance of $2,040—reflects the $0.99 actual purchase cost being lower than the $1.11 budgeted purchase cost per kilogram. (b) unfavourable efficiency variance of $873—reflects the actual materials yield of 3.58 scones per kilogram of pumpkin (60,800 ÷ 17,000 = 3.58) being less than the budgeted yield of 3.75 (60,000 ÷ 16,000 = 3.75) Overall, one explanation is that Peterson purchased lower‐quality pumpkins at a lower cost per kilogram.
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Chapter 7
7‐20 (30‐40 min.) Flexible‐budget and sales‐volume variances. 1. and 2. Performance Report for Marron, Inc., June 2013
Actual (1) Units (pounds) 525,000 Revenue $3,360,000 Variable mfg. costs 1,890,000 Contribution margin $1,470,000
Flexible Sales Static Budget Volume Budget Flexible Static Variances Budget Variances Budget Variance (2) = (1) – (3) (3) (4) = (3) – (5) (5) (6) = (1) – (5) ‐ 525,000 25,000 F 500,000 25,000 F a $ 52,500 U $3,412,500 $162,500 F $3,250,000 $110,000 F 52,500 U 1,837,500b 87,500 U 1,750,000 140,000 U $105,000 U $1,575,000 $ 75,000 F $1,500,000 $ 30,000 U $105,000 U $ 75,000 F Flexible‐budget variance Sales‐volume variance
Static Budget Variance as % of Static Budget (7) = (6) (5) 5.0% 3.4% 8.0% 2.0%
$30,000 U Static‐budget variance
Budgeted selling price = $3,250,000 500,000 lbs = $6.50 per lb. Flexible‐budget revenues = $6.50 per lb. 525,000 lbs. = $3,412,500 b Budgeted variable mfg. cost per unit = $1,750,000 500,000 lbs. = $3.50 Flexible‐budget variable mfg. costs = $3.50 per lb. 525,000 lbs. = $1,837,500 a
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7‐20 (cont’d) 3. 4.
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The selling price variance, caused solely by the difference in actual and budgeted selling price, is the flexible‐budget variance in revenue = $52,500 U. The flexible‐budget variances show that for the actual sales volume of 525,000 pounds, selling prices were lower and costs per pound were higher. The favourable sales volume variance in revenue (because more pounds of ice cream were sold than budgeted) helped offset the unfavourable variable cost variance and shored up the results in June 2013. Levine should be more concerned because the small static‐budget variance in contribution margin of $30,000 U is actually made up of a favourable sales‐volume variance in contribution margin of $75,000, an unfavourable selling‐price variance of $52,500 and an unfavourable variable manufacturing costs variance of $52,500. Levine should analyze why each of these variances occurred and the relationships among them. Could the efficiency of variable manufacturing costs be improved? Did the sales volume increase because of a decrease in selling price or because of growth in the overall market? Analysis of these questions would help Levine decide what actions he should take.
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Chapter 7
7‐21 (25 min.) Comprehensive variance analysis. 1.
Variance Analysis for Sol Electronics for the second quarter of 2013
Units Selling price Sales Variable costs Direct materials Direct manuf. labour Other variable costs Total variable costs Contribution margin Fixed costs Operating income
Second‐ Flexible Quarter Flexible Budget for Sales 2013 Budget Second Volume Static Actuals Variance Quarter Variance Budget (1) (2) = (1) – (3) (3) (4) = (3) – (5) (5) 4,800 800 F 4,000 4,800 0 $ 71.50 $ 70.00 $ 70.00 $343,200 $7,200 F $336,000 $56,000 F $280,000 a 57,600 2,592 F 60,192 10,032 U 50,160 30,240
1,440
U
28,800 b
4,800 U
24,000
47,280
720
F
48,000 c
8,000 U
40,000
135,120
1,872
F
136,992
22,832 U
114,160
208,080 68,400 $139,680
9,072 400 $8,672
F U F
199,008 68,000 $131,008
33,168 F 0 $33,168 F
165,840 68,000 $97,840
4,800 units 2.2 kg per unit $5.70 per kg = $60,192 4,800 units 0.5 hrs. per unit $12 per hr. = $28,800 c 4,800 units $10 per unit = $48,000 a
b
Second‐ Quarter 2013 Actuals $57,600
Price Variance $2,880 U
Actual Input Flexible Qty. Budget for Budgeted Efficiency Second Price Variance Quarter a $54,720 $5,472 F $60,192
Direct materials Direct manuf. labour (DML) 30,240 4,320 U 25,920 b a 4,800 units 2 kg per unit $5.70 per kg = $54,720 b 4,800 units 0.45 DMLH per unit $12 per DMLH = $25,920
2,880
F 28,800
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7‐21 (cont’d) 2.
3.
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The following details, revealed in the variance analysis, should be used to rebut the union if it focuses on the favourable operating income variance: Most of the static budget operating income variance of $41,840F ($139,680 – $97,840) comes from a favourable sales volume variance, which only arose because Sol sold more units than planned. Of the $8,672 F flexible‐budget variance in operating income, most of it comes from the $7,200F flexible‐budget variance in sales. The net flexible‐budget variance in total variable costs of $1,872 F is small, and it arises from direct materials and other variable costs, not from labour. Direct manufacturing labour flexible‐budget variance is $1,440 U. The direct manufacturing labour price variance, $4,320U, which is large and unfavourable, is indeed partially offset by direct manufacturing labour’s favourable efficiency variance—but the efficiency variance is driven by the fact that Sol is using new, more expensive materials. Shaw may have to “prove” this to the union, which will insist that it’s because workers are working smarter. Even if workers are working smarter, the favourable direct manufacturing labour efficiency variance of $2,880 does not fully offset the unfavourable direct manufacturing labour price variance of $4,320. Changing the standards may make them more realistic, making it easier to negotiate with the union. But the union will resist any tightening of labour standards, and it may be too early (is one quarter’s experience sufficient?); a change of standards at this point may be viewed as opportunistic by the union. Perhaps a continuous improvement program to change the standards will be more palatable to the union and will achieve the same result over a somewhat longer period of time.
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Chapter 7
7‐22 (30 min.)
1.
Flexible‐budget preparation and analysis.
Variance Analysis for Bank Management Printers Inc. for September 2013 Level 1 Analysis Actual Results (1) 12,000 a $252,000 d 84,000 168,000 150,000 $ 18,000
Units sold Revenue Variable costs Contribution margin Fixed costs Operating income 2.
Static Budget (3) 15,000 c $300,000 f 120,000 180,000 145,000 $ 35,000
$17,000 U
Total static‐budget variance Level 2 Analysis
Units sold
Actual Results (1) 12,000
Revenue
$252,000
Variable costs Contribution margin Fixed costs Operating income
Static‐ Budget Variances (2) = (1) – (3) 3,000 U $ 48,000 U 36,000 F 12,000 U 5,000 U $ 17,000 U
a
b
$60,000 U
$300,000
e
$12,000 F $240,000
c
84,000
d
12,000 F
96,000
24,000 F
120,000
168,000 150,000
24,000 F 5,000 U
144,000 145,000
36,000 U 0
180,000 145,000
f
$19,000 F $ (1,000) $36,000 U $ 35,000 $19,000 F $36,000 U Total flexible‐budget Total sales‐volume variance variance $17,000 U Total static‐budget variance
$ 18,000
Flexible‐ Sales Budget Flexible Volume Static Variances Budget Variances Budget (2) = (1) – (3) (3) (4) = (3) – (5) (5) 0 12,000 3,000 U 15,000
12,000 × $21 = $252,000 d 12,000 × $7 = $84,000 b e 12,000 × $20 = $240,000 12,000 × $8 = $96,000 c f 15,000 × $20 = $300,000 15,000 × $8 = $120,000 a
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7‐22 (cont’d) 3.
Level 2 analysis breaks down the static‐budget variance into a flexible‐budget variance and a sales‐volume variance. The primary reason for the static‐budget variance being unfavourable ($17,000 U) is the reduction in unit volume from the budgeted 15,000 to an actual 12,000. One explanation for this reduction is the increase in selling price from a budgeted $20 to an actual $21. Operating management was able to reduce variable costs by $12,000 relative to the flexible budget. This reduction could be a sign of efficient management. Alternatively, it could be due to using lower‐quality materials (which in turn adversely affected unit volume).
7‐23 (30 min.)
Flexible budget, working backward.
1. Actual Results (1) Units sold 130,000 Revenue $715,000 Variable costs 515,000 Contribution margin 200,000 Fixed costs 140,000 Operating income $ 60,000
Flexible‐ Budget Variances (2)=(1)–(3) 0 $260,000 F 255,000 U 5,000 F 20,000 U $15,000 U
Flexible Budget (3) 130,000 $455,000a 260,000b 195,000 120,000 $ 75,000
$15,000 U
Sales‐ Volume Variances (4)=(3)–(5) 10,000 F $35,000 F 20,000 U 15,000 F 0 $15,000 F
$15,000 F
Total flexible‐budget varianceTotal sales‐volume variance $0 Total static‐budget variance 130,000 $3.50 = $455,000 130,000 $2.00 = $260,000
a
b
2.
Actual selling price: Budgeted selling price: Actual variable cost per unit: Budgeted variable cost per unit:
$715,000 ÷ 130,000 420,000 ÷ 120,000 515,000 ÷ 130,000 240,000 ÷ 120,000
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Static Budget (5) 120,000 $420,000 240,000 180,000 120,000 $ 60,000
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= $5.50 = 3.50 = 3.96 = 2.00
Chapter 7
7‐23 (cont’d) 3.
A nil total static‐budget variance is due to offsetting total flexible‐budget and total sales‐volume variances. In this case, these two variances exactly offset each other:
Total flexible‐budget variance Total sales‐volume variance
$15,000 Unfavourable $15,000 Favourable
A closer look at the variance components reveals some major deviations from plan. Actual variable costs increased from $2.00 to $3.96, causing an unfavourable flexible‐budget variable cost variance of $255,000. Such an increase could be a result of, for example, a jump in material prices. Clarkson Company was able to pass most of the increase in costs (fixed and variable) on to their customers— average selling price went up about 57%, bringing about an offsetting favourable flexible‐budget variance in the amount of $15,000. An increase in the actual number of units sold also contributed to more favourable results. Although such an increase in quantity in the face of a price increase may appear counterintuitive, customers may have forecast higher future platinum prices and therefore decided to stock up. The most important lesson learned here is that a superficial examination of summary level data (Levels 0 and 1) may be insufficient. It is imperative to scrutinize data at a more detailed level (Level 2). Had Clarkson not been able to pass costs on to customers, losses would have been considerable.
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7‐24 (35 min.) 1.
Material cost variances, use of variances for performance evaluation Materials Variances Actual Costs Flexible Budget Incurred (Budgeted Input Qty. (Actual Input Allowed Qty. × Actual Actual Input Qty. for Actual Output Price) × Budgeted Price) × Budgeted Price Purchases Usage a (500 × 8 × $20) Direct (6,000 × $18 ) (6,000 × $20) (5,000 × $20) $108,000 $120,000 $100,000 (4,000 × $20) Materials $80,000
$12,000 F
$20,000 U
Price variance Efficiency variance a $108,000 ÷ 6,000 = $18 2. The favourable price variance is due to the $2 difference ($20 ‐ $18) between the standard price based on the previous suppliers and the actual price paid through the on‐line marketplace. The unfavourable efficiency variance could be due to several factors including inexperienced workers and machine malfunctions. But the likely cause here is that the lower‐priced titanium was lower quality or less refined, which led to more waste. The labour efficiency variance could be affected if the lower quality titanium caused the workers to use more time. 3. Switching suppliers was not a good idea. The $12,000 savings in the cost of titanium was outweighed by the $20,000 extra material usage. In addition, the $20,000U efficiency variance does not recognize the total impact of the lower quality titanium because, of the 6,000 pounds purchased, only 5,000 pounds were used. If the quantity of materials used in production is relatively the same, Better Bikes could expect the remaining 1,000 kgs to produce 100 more units. At standard, 100 more units should take 100 × 8 = 800 kg. There could be an additional unfavourable efficiency variance of (1,000 $20) (100 × 8 × $20) $20,000 $16,000 $4,000U
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7‐24 (cont’d) 4.
5.
6.
The purchasing manager’s performance evaluation should not be based solely on the price variance. The short‐run reduction in purchase costs was more than offset by higher usage rates. His evaluation should be based on the total costs of the company as a whole. In addition, the production manager’s performance evaluation should not be based solely on the efficiency variances. In this case, the production manager was not responsible for the purchase of the lower‐quality titanium, which led to the unfavourable efficiency scores. In general, it is important for Stanley to understand that not all favourable material price variances are “good news,” because of the negative effects that can arise in the production process from the purchase of inferior inputs. They can lead to unfavourable efficiency variances for both materials and labour. Stanley should also that understand efficiency variances may arise for many different reasons and she needs to know these reasons before evaluating performance. Variances should be used to help Better Bikes understand what led to the current set of financial results, as well as how to perform better in the future. They are a way to facilitate the continuous improvement efforts of the company. Rather than focusing solely on the price of titanium, Scott can balance price and quality in future purchase decisions. Future problems can arise in the supply chain. Scott may need to go back to the previous suppliers. But Better Bikes’ relationship with them may have been damaged and they may now be selling all their available titanium to other manufacturers. Lower quality bicycles could also affect Better Bikes’ reputation with the distributors, the bike shops and customers, leading to higher warranty claims and customer dissatisfaction, and decreased sales in the future.
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7‐25 (30 min.) Materials and manufacturing labour variances, standard costs.
1.
Direct Materials Actual Costs Incurred (Actual Input Qty. × Actual Price) (3,700 sq. m × $5.10) $18,870
Actual Input Qty. × Budgeted Price (3,700 sq. m × $5.00) $18,500
Flexible Budget (Budgeted Input Qty. Allowed for Actual Output × Budgeted Price) (2,000 × 2 × $5.00) (4,000 sq. m × $5.00) $20,000
$370 U $1,500 F Price variance Efficiency variance $1,130 F Flexible‐budget variance The unfavourable materials price variance may be unrelated to the favourable materials efficiency variance. For example, (a) the purchasing officer may be less skillful than assumed in the budget, or (b) there was an unexpected increase in materials price per square metre due to reduced competition. Similarly, the favourable materials efficiency variance may be unrelated to the unfavourable materials price variance. For example, (a) the production manager may have been able to employ higher‐skilled workers, or (b) the budgeted materials standards were set too loosely. It is also possible that the two variances are interrelated. The higher materials input price may be due to higher quality materials being purchased. Less material was used than budgeted due to the higher quality of the materials.
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7‐25 (cont’d) Direct Manufacturing Labour Flexible Budget (Budgeted Input Actual Costs Qty. Allowed for Incurred Actual Input Qty. Actual Output (Actual Input Qty. × Budgeted Price × Budgeted Price) × Actual Price) (2,000 × 0.5 × $10.00) (900 hrs. × $9.80) (900 hrs. × $10.00) (1,000 hrs. × $10.00) $8,820 $9,000 $10,000 $180 F $1,000 F Price variance Efficiency variance $1,180 F Flexible‐budget variance The favourable labour price variance may be due to, say, (a) a reduction in labour rates due to a recession, or (b) the standard being set without detailed analysis of labour compensation. The favourable labour efficiency variance may be due to, say, (a) more efficient workers being employed, (b) a redesign in the plant enabling labour to be more productive, or (c) the use of higher quality materials. 2. Flexible Budget (Budgeted Input Qty. Allowed Actual Costs for Incurred Actual Output (Actual Input Qty. Actual Input Qty. × Budgeted Control × Actual Price) × Budgeted Price Price) Point Purchasing (6,000 sq. m × $5.10) (6,000 sq. m × $5.00) $30,600 $30,000 $600 U Price variance Production (3,700 sq. m × $5.00) (2,000 × 2 × $5.00) $18,500 $20,000 $1,500 F Efficiency variance
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Direct manufacturing labour variances are the same as in requirement 1. 7‐26 (30 min.) Journal entries and T‐accounts. For requirement 1 from Exercise 7‐25: a. Direct Materials Control 18,500 Direct Materials Price Variance 370 Accounts Payable Control 18,870 To record purchase of direct materials. b. Work‐in‐Process Control 20,000 Direct Materials Efficiency Variance 1,500 Direct Materials Control 18,500 To record direct materials used. c. Work‐in‐Process Control 10,000 180 Direct Manufacturing Labour Price Variance Direct Manufacturing Labour Efficiency Variance 1,000 Wages Payable Control 8,820 To record liability for and allocation of direct labour costs. Direct Direct Materials Direct Materials Materials Control Price Variance Efficiency Variance (a) 18,500 (b) 18,500 (a) 370 (b) 1,500 Work‐in‐Process Direct Manufacturing Direct Manuf. Labour Control Labour Price Variance Efficiency Variance (b) 20,000 (c) 180 (c) 1,000 (c) 10,000 Wages Payable Control Accounts Payable Control (c) 8,820 (a) 18,870
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7‐26 (cont’d) For requirement 2 from Exercise 7‐25: The following journal entries pertain to the measurement of price and efficiency variances when 6,000 sq. m of direct materials are purchased: a1. Direct Materials Control 30,000 Direct Materials Price Variance 600 Accounts Payable Control 30,600 To record direct materials purchased. a2. Work‐in‐Process Control 20,000 Direct Materials Control 18,500 Direct Materials Efficiency Variance 1,500 To record direct materials used. Direct Direct Materials Materials Control Price Variance (a1) 30,000 (a2) 18,500 (a1) 600 Accounts Payable Control Work‐in‐Process Control (a1) 30,600 (a2) 20,000 Direct Materials Efficiency Variance (a2) 1,500 The T‐account entries related to direct manufacturing labour are the same as in requirement 1. The difference between standard costing and normal costing for direct cost items is: Standard Costs Normal Costs Direct Costs Standard price(s) Actual price(s) × Standard input × Actual input allowed for actual outputs achieved These journal entries differ from the normal costing entries because Work‐in‐ Process Control is no longer carried at “actual” costs. Furthermore, Direct Materials Control is carried at standard unit prices rather than actual unit prices. Finally, variances
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appear for direct materials and direct manufacturing labour under standard costing but not under normal costing. 7‐27 (25 min.) Flexible budget. A more detailed analysis underscores the fact that the world of variances may be divided into three general parts: price, efficiency, and what is labelled here as a sales‐ volume variance. Failure to pinpoint these three categories muddies the analytical task. The clearer analysis follows (in dollars): Actual Costs Flexible Budget Incurred (Budgeted Input (Actual Qty. Allowed for Input Qty. Actual Output Static × Actual Actual Input Qty. × Budgeted Price × Budgeted Price) Budget Price) Direct Materials $18,870 $18,500 $20,000 $25,000 (a) $370 U (b) $1,500 F (c) $5,000 F Direct Manuf. Labour $8,820 $9,000 $10,000 $12,500 (a) $180 F (b) $1,000 F (c) $2,500 F (a) Price variance (b) Efficiency variance (c) Sales‐volume variance The sales‐volume variances are favourable here in the sense that less cost would be expected solely because the output level is less than budgeted. However, this is an example of how variances must be interpreted cautiously. Managers may be incensed at the failure to reach scheduled production (it may mean fewer sales) even though the 2,000 units were turned out with supreme efficiency. Sometimes this phenomenon is called being efficient but ineffective, where effectiveness is defined as the ability to reach original targets and efficiency is the optimal relationship of inputs to any given outputs. Note that a target can be reached in an efficient or inefficient way; similarly, as this problem illustrates, a target can be missed but the given output can be attained efficiently.
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7‐28 (20‐25 min.) Direct materials efficiency, mix, and yield variances. 1 and 2. Actual total quantity of all inputs used and actual input mix percentages for each input are as follows: Chemical Actual Quantity Actual Mix Percentage Echol 24,080 24,080 ÷ 86,000 = 0.28 Protex 15,480 15,480 ÷ 86,000 = 0.18 Benz 36,120 36,120 ÷ 86,000 = 0.42 CT‐40 10,320 10,320 ÷ 86,000 = 0.12 Total 86,000 1.00 Budgeted total quantity of all inputs allowed and budgeted input mix percentages for each input are as follows: Chemical Budget Quantity Budget Mix Percentage Echol 25,200 25,200 ÷ 84,000 = 0.30 Protex 16,800 16,800 ÷ 84,000 = 0.20 Benz 33,600 33,600 ÷ 84,000 = 0.40 CT‐40 8,400 8,400 ÷ 84,000 = 0.10 Total 84,000 1.00 Total direct materials efficiency variance can also be computed as: Direct m aterials Actu al Bu d geted inpu ts allow ed Bu d geted efficiency variance prices inpu ts for actu al ou tpu ts achieved for each inpu t Echol = (24,080 – 25,200) $0.22 Protex = (15,480 – 16,800) $0.47 Benz = (36,120 – 33,600) $0.17 CT‐40 = (10,320 – 8,400) $0.32 Total direct materials efficiency variance
= $246 F = 620 F = 428 U = 614 U $176 U
The total direct materials yield variance can also be computed as the sum of the direct materials yield variances for each input:
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7‐28 (cont’d) Direct
Bu d geted Bu d geted Bu d geted total qu antity Actu al total d irect m aterials price of m aterials qu antity of all of all d irect m aterials inpu t m ix d irect m aterials yield variance d irect m aterials inpu ts allow ed for percentage inpu ts for each inpu t inpu ts u sed actu al ou tpu t achieved Echol = (86,000 – 84,000) 0.30 $0.22 = 2,000 0.30 $0.22 = $132 U Protex = (86,000 – 84,000) 0.20 $0.47 = 2,000 0.20 $0.47 = 188 U Benz = (86,000 – 84,000) 0.40 $0.17 = 2,000 0.40 $0.17 = 136 U CT‐40 = (86,000 – 84,000) 0.10 $0.32 = 2,000 0.10 $0.32 = 64 U Total direct materials yield variance $520 U The total direct materials mix variance can also be computed as the sum of the direct materials mix variances for each input: Direct Actu al Bu d geted Actu al Bu d geted m aterials d irect m aterials d irect m aterials qu antity of all price of inpu t m ix m ix variance inpu t m ix d irect m aterials d irect m aterials for each inpu t percentage inpu ts u sed inpu ts percentage Echol = (0.28 – 0.30) 86,000 $0.22 = –0.02 86,000 $0.22 = $378 F Protex = (0.18 – 0.20) 86,000 $0.47 = –0.02 86,000 $0.47 = 808 F Benz = (0.42 – 0.40) 86,000 $0.17 = 0.02 86,000 $0.17 = 292 U CT‐40 = (0.12 – 0.10) 86,000 $0.32 = 0.02 86,000 $0.32 = 550 U Total direct materials mix variance $344 F 3. Energy Products used a larger total quantity of direct materials inputs than budgeted, and so showed an unfavourable yield variance. The mix variance was favourable because the actual mix contained more of the cheapest input, Benz, and less of the most costly input, Protex, than the budgeted mix. The favourable mix variance offset some, but not all, of the unfavourable yield variance—the overall efficiency variance was unfavourable. Energy Products will find it profitable to shift to the cheaper mix only if the yield from this cheaper mix can be improved. Energy Products must also consider the effect on output quality of using the cheaper mix, and the potential consequences for future revenues.
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Chapter 7
SOLUTION EXHIBIT 7‐28 Columnar Presentation of Direct Materials Efficiency, Yield, and Mix Variances for The Energy Products Company for August 2013 Flexible Budget: Budgeted Total Quantity of Actual Total Quantity Actual Total Quantity All Inputs Allowed for of All Inputs Used of All Inputs Used Actual Output Achieved Actual Input Mix Budgeted Input Mix Budgeted Input Mix Budgeted Price Budgeted Price Budgeted Price (1) (2) (3) Echol Protex Benz CT‐40
86,000 0.28 $0.22 = $5,298 86,000 0.18 $0.47 = 7,276 86,000 0.42 $0.17 = 6,140 86,000 0.12 $0.32 = 3,302 $22,016
86,000 0.30 $0.22= $5,676 84,000 0.30 $0.22 = $5,544 86,000 0.20 $0.47 = 8,084 84,000 0.20 $0.47 = 7,896 86,000 0.40 $0.17 =5,848 84,000 0.40 $0.17 = 5,712 86,000 0.10 $0.32 = 2,752 84,000 0.10 $0.32 = 2,688 $22,360 $21,840
$344 F
$520 U
Total mix variance
Total yield variance
$176 U
Total efficiency variance F = favourable effect on operating income; U = unfavourable effect on operating income
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7‐29 (35 min.) Direct materials rate, efficiency, mix, and yield variances. 1.
Solution Exhibit 7‐29A presents the total rate variance ($3,100F), the total efficiency variance ($2,760U), and the total flexible‐budget variance ($340F). Total direct materials rate variance can also be computed as: Direct m aterials Actu al Bu d geted Actu al price variance Price Price Inpu ts for each inpu t Tolman = ($0.30 – $0.32) 62,000 = $1,240 F Golden Delicious = ($0.28 – $0.28) 155,000 = 0 Ribston = ($0.22 – $0.24) 93,000 = 1,860 F Total direct materials rate variance $3,100 F Total direct materials efficiency variance can also be computed as:
Direct m aterials
Actu al Bu d geted inpu ts allow ed Bu d geted efficiency variance Prices Inpu ts for actu al ou tpu ts achieved for each inpu t Tolman = (62,000 – 45,000) $0.32 = 5,440 U Golden Delicious = (155,000 – 180,000) $0.28 = 7,000 F Ribston = (93,000 – 75,000) $0.24 = 4,320 U Total direct materials efficiency variance $2,760 U SOLUTION EXHIBIT 7‐29A Columnar Presentation of Direct Materials Price and Efficiency Variances for Greenwood Inc. for November 2013 Flexible Budget: Actual Costs (Budgeted Inputs Incurred Allowed for Actual (Actual Inputs Actual Input Outputs Achieved Actual Prices) Budgeted Prices Budgeted Prices) (1) (2) (3) Tolman 62,000 $0.30 = $18,600 Golden Delicious 155,000 $0.28 = 43,400 Ribston 93,000 $0.22 = 20,460 $82,460
62,000 $0.32 = $19,840 155,000 $0.28 = 43,400 93,000 $0.24 = 22,320 $85,560
45,000 $0.32 = $14,400 180,000 $0.28 = 50,400 75,000 $0.24 = 18,000 $82,800
$3,100 F $2,760 U Total rate variance Total efficiency variance $340 F Total flexible‐budget variance F = favourable effect on operating income; U = unfavourable effect on operating income
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7‐29 (cont’d) 2. Solution Exhibit 7‐29B presents the total direct materials yield and mix variances for Greenwood Inc. for November 2013. The total direct materials yield variance can also be computed as the sum of the direct materials yield variances for each input: Bu d g e te d to ta l A ctu a l to ta l q u a n t it y o f a ll q u a n t it y o f a ll d ir e ct m a t e r ia ls y ie ld v a r ia n ce i n p u t s a l l o w e d fo r d ir e ct m a t e r ia ls fo r e a c h in p u t s u s e d a ctu a l o u tp u t in p u t a ch ie v e d D ir e ct m a te r ia ls
Bu d g e te d Bu d g e te d d ir e ct p r ice o f d ir e ct m a te r ia ls in p u t m ix m a t e r ia ls p e r ce n ta g e in p u t s
Tolman = (310,000 – 300,000) 0.15 $0.32 = 10,000 0.15 $0.32 Golden Delicious = (310,000 – 300,000) 0.60 $0.28 = 10,000 0.60 $0.28 Ribston = (310,000 – 300,000) 0.25 $0.24 = 10,000 0.25 $0.24 Total direct materials yield variance
= = =
$ 480 U 1,680 U 600 U $2,760 U
The total direct materials mix variance can also be computed as the sum of the direct materials mix variances for each input: Direct Bu d geted Actu al total Bu d geted Actu al m aterials d irect qu antity of price of d irect m aterials m ix variance m aterials all d irect d irect inpu t m ix for each inpu t m ix m aterials m aterials percentage inpu t percentage inpu ts u se d inpu ts Tolman = (0.20 – 0.15) 310,000 $0.32 = 0.05 310,000 $0.32 Golden Delicious = (0.50 – 0.60) 310,000 x $0.28 = –0.10 310,000 $0.28 Ribston = (0.30 – 0.25) 310,000 $0.24 = 0.05 310,000 $0.24 Total direct materials mix variance =
3.
= $4,960 U = 8,680 F = 3,720 U $ 0 U
Greenwood paid less for Tolman and Ribston apples and, so, had a favourable direct materials rate variance of $3,100. It also had an unfavourable efficiency variance of $2,760. Greenwood would need to evaluate if these were unrelated events or if the lower price resulted from the purchase of apples of poorer quality that affected efficiency. The net effect in this case from a cost standpoint was favourable—the savings in price being greater than the loss in efficiency. Of course, if the apple jelly and applesauce are of poorer quality, Greenwood must also evaluate the potential effects on current and future revenues that have not been considered in the variances described in requirements 1 and 2.
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7‐29 (cont’d) The unfavourable efficiency variance is entirely attributable to an unfavourable yield. The actual mix does deviate from the budgeted mix but at the budgeted prices; the greater quantity of Tolman and Ribston apples used in the actual mix exactly offsets the fewer Golden Delicious apples used. Again, management should evaluate the reasons for the unfavourable yield variance. Is it due to poor quality Tolman and Ribston apples (recall from requirement 1 that these apples were acquired at a price lower than the standard price)? Is it due to the change in mix (recall that the mix used is different from the budgeted mix, even though the mix variance is $0)? Isolating the reasons can lead management to take the necessary corrective actions. SOLUTION EXHIBIT 7‐29B Columnar Presentation of Direct Materials, Yield, and Mix Variances for Greenwood Inc. for November 2013 Flexible Budget: Budgeted Total Quantity of Actual Total Quantity Actual Total Quantity All Inputs Allowed for of All Inputs Used of All Inputs Used Actual Output Achieved Actual Input Mix Budgeted Input Mix Budgeted Input Mix Budgeted Prices Budgeted Prices Budgeted Prices (1) (2) (3) Tolman 310,000 0.20a $0.32 = $19,840 310,000 0.15d $0.32 = $14,880 300,000 0.15d $0.32 = $14,400 Golden Delicious 310,000 0.50b $0.28 = 43,400 310,000 0.60e $0.28 = 52,080 300,000 0.60e $0.28 = 50,400 Ribston 310,000 0.30c $0.24 = 22,320 310,000 0.25f $0.24 = 18,600 300,000 0.25f $0.24 = 18,000 $85,560 $85,560 $82,800
0 $2,760 U Total mix variance Total yield variance $2,760 U Total efficiency variance F = favourable effect on operating income; U = unfavourable effect on operating income a 62,000 ÷ 310,000 d 45,000 ÷ 300,000 b 155,000 ÷ 310,000 e 180,000 ÷ 300,000 c 93,000 ÷ 310,000 f 75,000 ÷ 300,000
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PROBLEMS
7‐30 (30 min.) Variance analysis, non‐manufacturing setting. 1.
Lightning Car Detailing Income Statement Variances For the Month Ended June 30, 2013
Cars Detailed
Budget 200
Actual 225
Revenue
$ 30,000 $ 39,375
1,500 5,600
2,250 6,000
750 U 400 U
Total variable costs
7,100
8,250
1,150 U
Contribution margin
22,900
31,125
8,225 F
9,500
9,500
Operating income
$ 13,400 $ 21,625
0 $ 8,225 F
$ 9,375 F
Variable costs: Costs of supplies Labour
Fixed costs
2.
Static Budget Variance 25 F
To compute flexible budget variances for revenues and the variable costs, first calculate the budgeted cost or revenue per car, and then multiply that by the actual number of cars detailed. Subtract the actual revenue or cost, and the result is the flexible budget variance. FBV(Revenue) = Actual revenue – (Actual number of cars (Budgeted revenue/Budgeted number of cars)) = $39,375 – (225 ($30,000/200)) = $39,375 – $33,750 = $5,625 Favourable
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7‐30 (cont’d)
FBV(Supplies) = Actual supplies expense – (Actual number of cars (Budgeted cost of supplies/Budgeted number of cars)) = $2,250 – (225 ($1,500/200)) = $2,250 – $1,687.50 = $562.50 Unfavourable FBV(Labour) = Actual labour expense – (Actual number of cars (Budgeted cost of labour/Budgeted number of cars)) = $6,000 – (225 ($5,600/200)) = $6,000 – $6,300 = $300 Favourable The flexible budget variance for fixed costs is the same as the static budget variance, and equals $0 in this case. Therefore, the overall flexible budget variance in income is given by aggregating the variances computed earlier, adjusting for whether they are favourable or unfavourable. This yields: FBV(Operating Income) = $5,625F (‐) $562.50U (+) $300F = $5,362.50F In addition to understanding the variances computed above, Stevie should attempt to keep track of the number of cars worked on by each employee, as well as the number of hours actually spent on each car. In addition, Stevie should look at the prices charged for detailing, in relation to the hours spent on each job.
3.
4.
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This is a problem of two equations and two unknowns. The two equations relate to the number of cars detailed and the labour costs (the wages paid to the employees). X = number of cars detailed by long‐term employee Y = number of cars detailed by both short‐term employees (combined) Actual: X + Y = 225 Budget: X + Y = 200 40X + 20Y = 5,600 40X + 20Y = 6,000 Substitution: Substitution: 40X + 20(200‐X) = 5,600 40X + 20(225‐X) = 6,000 20X = 1600 20X = 1500 X = 80 X = 75 Y = 120 Y = 150
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Chapter 7
7‐30 (cont’d)
5.
Therefore the long‐term employee is budgeted to detail 80 cars, and the new employees are budgeted to detail 60 cars each. Actually, the long‐term employee details 75 cars (and grosses $3,000 for the month), and the other two wash 75 each and gross $1,500 apiece. The two short‐term employees are budgeted to earn gross wages of $18,000 per year: 150 ÷ 2 × 2 hrs × $10 = $1,500 × 12 months = $18,000 (if June is typical, and less if it is a high‐volume month). If this is a part‐time job for them, then that is fine. If it is full‐time, and they only get paid for what they wash, the excess capacity may be causing motivation problems. Stevie needs to determine a better way to compensate employees to encourage retention. This should increase customer satisfaction, and potentially revenue, because longer‐term employees do a more thorough job. In addition, rather than paying the same wage per car, Stevie might consider setting quality standards and improvement goals for all of the employees.
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7‐31 (30‐40 min.) Direct‐materials variances, long‐term agreement with supplier. 1. Month (1) January February March April May
Average Total Actual Actual Direct Total Actual Direct Materials Quantity of Materials Purchase Direct Usage in Price per Materials in Dollars Kilogram of Kilograms (2) Metal (4) = (2) ÷ ( 3) (3) $290,880 343,872 530,712 474,317 304,128
$144 144 151.2 153.6 144
2,020 2,388 3,510 3,088 2,112
Number of Machining Systems Produced (5) 10 12 18 16 11
Actual Direct Materials Input in Kilograms per Machining System (6) = (4) ÷ (5) 202 199 195 193 192
Materials Price Variance Actual Costs Incurred: Budgeted Direct Actual Input Price per Actual Input Materials Month Actual Actual Input Unit of Input Budgeted Price (1) Price (3) (4) Price Variance (2) (5) = (3) (4) (6) = (2) – (5) January $290,880 2,020 $144 $290,880 $ 0 February 343,872 2,388 144 343,872 0 March 530,712 3,510 144 505,440 25,272 U April 474,317 3,088 144 444,672 29,645 U May 304,128 2,112 144 304,128 0 Materials Efficiency Variance Flexible Budget Actual Budgeted Budgeted (Budgeted Direct Input Input per Actual Price per Input Materials Budgeted Unit of Output Unit of Allowed for Efficiency Month Price Output Achieved Input Actual Output Variance (1) (2) (3) (4) (5) Achieved (7) = (2) – Budgeted (6) Price) (6) = (3) (4) (5) January $290,880 198 10 $144 $285,120 $ 5,760 February 343,872 198 12 144 342,144 U March 505,440 198 18 144 513,216 1,728 U April 444,672 198 16 144 456,192 7,776 F May 304,128 198 11 144 313,632 11,520 F 9,504 F
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7‐31 (cont’d) 2.
The unfavourable materials price variances in March and April imply that Metalmoulder paid more than $144 per kilogram above the 2,400 kilogram contract amount.
Month (1) March April
Total Actual Costs Incurred (2) $530,712 474,317
Contract Amount for 2,400 kg: 2,400 $144 (3) $345,600 345,600
Cost for Purchases Above 2,400 kg (4) = (2) – (3) $185,112 128,717
Quantity of Purchases Above 2,400 kg (5) 1,110 688
Actual Price per Kilogram of Purchases Above 2,400 kg (6) = (4) ÷ (5) $166.77 187.09
The percentage price increases for the additional purchases above 2,400 kilograms are: March April
Actual Price $166.77 187.09
Standard Price $144 144
% Increase 15.8 29.9
With a long‐term agreement that has a fixed purchase‐price clause for a set minimum quantity, no price variance will arise when the purchase amount is below the minimum quantity (assuming the budgeted price per unit is the contract price per unit). A price variance will occur only when the purchased amount exceeds the set minimum quantity. A price variance signals that the purchased amount exceeds this set minimum quantity (2,400 kilograms per month). It is likely that the supplier will charge a higher price (above $144) for purchases above the 2,400 base. If a lower price were charged, the purchaser might apply pressure to renegotiate the contract purchase price for the base amount. If the purchasing officer is able to negotiate only a small price increase for additional purchases above the base amount, the purchasing performance may well be “favourable” despite the materials price variance being labelled “unfavourable.” Metalmoulder may see the advantage of a long‐term contract in factors other than purchase price (for example, a higher quality of materials, a lower required level of inventories because of more frequent deliveries, and a guaranteed availability of materials). In general, the existence of a long‐term agreement reduces the importance of materials price variances when evaluating the month‐to‐month performance of a purchasing officer.
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7‐32 (30 min.) Variance procedures; price and efficiency variances, journal entries. 1.
Direct materials and direct manufacturing labour are analyzed in turn: Actual Costs Incurred (Actual Input Qty. × Actual Price)
Actual Input Qty. × Budgeted Price
Flexible Budget (Budgeted Input Qty. Allowed for Actual Output × Budgeted Price)
Purchases Usage (100,000 × $4.65a) (100,000 × $4.50) (98,055 × $4.50) (9,850 × 10 × $4.50) Direct Materials $465,000 $450,000 $441,248 $443,250 $15,000 U $2,002 F Price variance Efficiency variance (9,850 × 0.5 × $30) or Direct b (4,900 × $30) (4,925 × $30) Manufacturing (4,900 × $31.5 ) $154,350 $147,000 $147,750 Labour $7,350 U $750 F Price variance Efficiency variance a
$465,000 ÷ 100,000 = $4.65 $154,350 ÷ 4,900 = $31.5
b
2.
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Direct Materials Control Direct Materials Price Variance Accounts Payable or Cash Control
450,000 15,000
465,000
Work‐in‐Process Control Direct Materials Control Direct Materials Efficiency Variance
443,250
441,248 2,002
Work‐in‐Process Control 147,750 Direct Manuf. Labour Price Variance 7,350 Wages Payable Control Direct Manuf. Labour Efficiency Variance
154,350 750
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Chapter 7
7‐32 (cont’d) 3.
4.
Some students’ comments will be immersed in conjecture about higher prices for materials, better quality materials, higher grade labour, better efficiency in use of materials, and so forth. A possibility is that approximately the same labour force, paid somewhat more, is taking slightly less time with better materials and causing less waste and spoilage. A key point in this problem is that all of these efficiency variances are likely to be insignificant. They are so small as to be nearly meaningless. Fluctuations about standards are bound to occur in a random fashion. Practically, from a control viewpoint, a standard is a band or range of acceptable performance rather than a single‐figure measure. The purchasing point is where responsibility for price variances is found most often. The production point is where responsibility for efficiency variances is found most often. The Monroe Corporation may calculate variances at different points in time to tie in with these different responsibility areas.
7‐33 (20‐30 min.) Direct materials and manufacturing labour variances, solving unknowns. All given items are designated by an asterisk. Flexible Budget (Budgeted Input Actual Costs Qty. Allowed for Incurred Actual Input Qty. Actual Output (Actual Input Qty. × Budgeted Price × Budgeted Price) × Actual Price) Direct Manufacturing (1,900 × $21) (1,900 × $20*) (4,000* × 0.5* × $20*) Labour $39,900 $38,000 $40,000 $1,900 U* $2,000 F* Price variance Efficiency variance Direct Materials
(13,000 × $5.25) $68,250*
Purchases (13,000 × $5*) $65,000
Usage (12,500 × $5*) $62,500
$3,250 U* Price variance
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(4,000* × 3* × $5*) $60,000
$2,500 U* Efficiency variance
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7‐33 (cont’d) 1. 2.
4,000 units × 0.5 hours/unit = 2,000 hours Flexible budget – Efficiency variance = $40,000 – $2,000 = $38,000 Actual DMLH = $38,000 ÷ Budgeted price of $20/hour = 1,900 hours
3.
$38,000 + Price variance, $1,900 = $39,900, the actual direct manuf. labour cost Actual rate = Actual cost ÷ Actual hours = $39,900 ÷ 1,900 hours = $21/hour
4. 5.
Standard qty. of direct materials = 4,000 units × 3 kg/unit = 12,000 kg
Flexible budget + Dir. matls. effcy. var. = $60,000 + $2,500 = $62,500 Actual quantity of dir. matls. used = $62,500 ÷ Budgeted price per kg = $62,500 ÷ $5/lb = 12,500 kg
6.
Actual cost of direct materials, $68,250 – Price variance, $3,250 = $65,000 Actual qty. of direct materials purchased = $65,000 ÷ Budgeted price, $5/kg = 13,000 kg 7. Actual direct materials price = $68,250 ÷ 13,000 kg = $5.25 per kg 7‐34 (30 min.) Direct manufacturing labour and direct materials variances, missing data. 1. Flexible Budget (Budgeted Input Actual Costs Qty. Allowed for Incurred (Actual Actual Input Qty. Actual Output Input Qty. × Actual Price) × Budgeted Price × Budgeted Price) $384,000b $360,000c Direct mfg. labour $368,000a $16,000 F $24,000 U Price variance Efficiency variance $8,000 U Flexible‐budget variance a Given (or 32,000 hours × $11.50/hour) b 32,000 hours × $12/hour = $384,000 c 6,000 units × 5 hours/unit × $12/hour = $360,000
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7‐34 (cont’d) 2.
Unfavourable direct materials efficiency variance of $12,500 indicates that more pounds of direct materials were actually used than the budgeted quantity allowed for actual output. $12,500 efficiency variance = $2 per pound budgeted price = 6,250 pounds
Budgeted pounds allowed for the output achieved = 6,000 × 20 = 120,000 pounds Actual pounds of direct materials used = 120,000 + 6,250 = 126,250 pounds
$292,500 150,000 = $1.95 per pound
3. Actual price paid per pound = 4.
Actual Costs Incurred (Actual Input × Actual Price) $292,500a
Actual Input × Budgeted Price $300,000b
$7,500 F Price variance
a
Given 150,000 pounds × $2/pound = $300,000
b
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7‐35 (20 min.) Direct materials and manufacturing labour variances, journal entries. 1.
Direct Materials:
Flexible Budget Actual Costs (Budgeted Input Incurred Qty. Allowed for (Actual Input Actual Input Qty. Actual Output Qty. × Budgeted Price × Budgeted Price) × Actual Price) Wool (given) 2,633.50 $3.00 230 12 $3.00 $8,295.50 $7,900.50 $8,280.00 $395 U $379.50 F Price variance Efficiency variance $15.50 U Flexible‐budget variance
Direct Manufacturing Labour: Flexible Budget Actual Costs (Budgeted Input Incurred Qty. Allowed for (Actual Input Qty. Actual Input Qty. Actual Output × Actual Price) × Budgeted Price × Budgeted Price) (given) 836 $10.50 230 3.5 $10.50 $7,814.50 $8,778.00 $8,452.50 $963.50 F $325.50 U Price variance Efficiency variance $638 F Flexible‐budget variance
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7‐35 (cont’d) 2.
3.
Direct Materials Price Variance (time of purchase = time of use): Direct Materials Control 7,900.50 Direct Materials Price Variance 395.00 Accounts Payable Control or Cash 8,295.50 Direct Materials Efficiency Variance: Work‐in‐Process Control 8,280.00 Direct Materials Efficiency Variance 379.50 Direct Materials Control 7,900.50 Direct Manufacturing Labour Variances: Work‐in‐Process Control 8,452.50 Direct Mfg. Labour Efficiency Variance 325.50 Direct Mfg. Labour Price Variance 963.50 Wages Payable or Cash 7,814.50 Plausible explanations for the above variances include: Shayna paid a little bit extra for the wool, but the wool was thicker and allowed the workers to use less of it. Shayna used more inexperienced workers in April than she usually does. This resulted in payment of lower wages per hour, but the new workers were more inefficient and took more hours than normal. Overall, the lower wage rates resulted in Shayna’s total wage bill being significantly lower than expected.
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7‐36 (30 min.) Comprehensive variance analysis. 1.
(a) Aunt Mollyʹs Old Fashioned Cookies unit selling prices and unit costs of inputs: Actual selling price = = Budgeting selling price = =
$4,266,000 ÷ 450,000 kg $9.48 $3,840,000 ÷ 400,000 kg $9.60
Selling‐price variance = Actual
selling price
Budgeted Actual selling price units sold
= ($9.48 – $9.60) 450,000 kg = $54,000 U
(b) to (e) The actual and budgeted unit costs are: Direct materials Cookie mix Milk chocolate Almonds Direct labour Mixing Baking
Actual
Budgeted
$0.384 $3.84 $9.60
$0.384 $2.88 $9.60
$17.28 $21.60
$17.28 $21.60
The actual output achieved is 450,000 kilograms of chocolate nut supreme. $129,600 ÷ (450,000 ÷ 60 minutes) = $17.28 $288,000 ÷ (800,000 ÷ 60 minutes) = $21.60
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7‐36 (cont’d) The direct cost price and efficiency variances are:
Actual Costs Incurred Actual (Actual Input Input Actual Price Budgeted Price) Variance Prices (1) (2)=(1)–(3) (3) Direct materials Cookie mix $ 111,360 $ 0 $111,360a Milk chocolate $ 621,005 155,251 U 465,754b Almonds $ 285,000 0 285,000c $1,017,365 $155,251 U $862,114 Direct labour costs Mixing $129,600 $ 0 $129,600d Baking $288,000 0 288,000e $417,600 $ 0 $417,600 $0.384 290,000 kg = $111,360 b$2.88 161,720 kg = $465,754 c$9.60 29,688 kg = $285,000 d$17.28 (450,000 ÷ 60) = $129,600 e$21.60 (800,000 ÷ 60) = $288,000 a
Flex. Budget (Budgeted Input Allowed for Actual Output Efficiency Achieved Variance Budgeted Price) (4)=(3)–(5) (5) $ 3,360 U 60,754 U 15,000 U $79,114 U
$108,000h 405,000i 270,000j $783,000
$ 0 $129,600k 36,000 F 324,000l $36,000 F $453,600
$0.384/kg 281,250* kg = $108,000 $2.88/kg 140,625* kg = $405,000 j$9.60/kg 28,125* kg = $270,000 k$17.28 (1/60) 450,000 = $129,600 l$21.60 (2/60) 450,000 = $324,000 h i
*Cookie mix: 0.625 kg mix 450,000 kg total = 281,250 kg kg total
Milk chocolate: 0.3125 kg choc. 450,000 kg total = 140,625 kg kg total
Almonds: 0.0625 kg almonds 450,000 kg total = 28,125 kg
kg total
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7‐36 (cont’d) 2. (a) Selling price variance. This may arise from a proactive decision to reduce price to expand market share or from a reaction to a price reduction by a competitor. It could also arise from unplanned price discounting by salespeople. (b) Material price variance. The $0.96 increase in the price per kilogram of milk chocolate could arise from uncontrollable market factors or from poor contract negotiations by Aunt Molly’s. (c) Material efficiency variance. For all three material inputs, usage is greater than budgeted. Possible reasons include lower quality inputs, use of lower quality workers, and the mixing and baking equipment not being maintained in a fully operational mode. (d) Labour price variance. The zero variance is consistent with workers being on long‐term contracts that are not renegotiated on a month‐by‐month basis. (e) Labour efficiency variance. The favourable efficiency variance for baking could be due to workers eliminating non‐valued‐added steps in production. 7‐37 (60 min.) Comprehensive variance analysis, responsibility issues. 1a. Actual selling price = $82.00 Budgeted selling price = $80.00 Actual sales volume = 7,275 units Selling price variance = (Actual sales price Budgeted sales price) × Actual sales volume = ($82 $80) × 7,275 = $14,550 Favourable 1b. Development of Flexible Budget Budgeted Unit Actual Flexible Budget Amounts Volume Amount Revenues $80.00 7,275 $582,000 Variable costs a DMFrames $2.20/g × 3.00 g 6.60 7,275 48,015 b DMLenses $3.10/g × 6.00 g 18.60 7,275 135,315 Direct manuf. $15.00/hr. × 1.20 c labour hrs. 18.00 7,275 130,950 Total variable manufacturing costs 314,280 Fixed manufacturing costs 112,500 Total manufacturing costs 426,780 Gross margin a$49,500 ÷ 7,500 units; b$139,500 ÷ 7,500 units; c$135,000 ÷ 7,500 units
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$155,220
Chapter 7
7‐37 (cont’d)
Units sold Revenues Variable costs DMFrames DMLenses Direct manuf. labour Total variable costs Fixed manuf. costs Total costs Gross margin
Actual Results (1) 7,275 $596,550 55,872 150,738 145,355
Flexible‐ Budget Variances (2)=(1)‐(3)
7,857 U 15,423 U 14,405 U
Flexible Budget (3) 7,275 $582,000 48,015 135,315 130,950
1,485 F 4,185 F 4,050F
Static Budget (5) 7,500 $600,000 49,500 139,500 135,000
351,965
37,685 U
314,280
9,720 F
324,000
108,398 460,363 $ 136,187
4,102 F 33,583 U $19,033 U
112,500 426,780 $155,220
0 9,720 F $ 8,280 U
112,500 436,500 $163,500
$ 14,550 F
Sales ‐ Volume Variance (4)=(3)‐(5) $ 18,000 U
Level 2 $19,033 U $ 8,280 U Flexible‐budget variance Sales‐volume variance Level 1 $27,313 U Static‐budget variance 1c. Price and Efficiency Variances DMFramesActual grams used = 3.20 per unit × 7,275 units = 23,280 g Price per gram = $55,872 23,280 = $2.40 DMLensesActual grams used = 7.00 per unit × 7,275 units = 50,925 g Price per gram = $150,738 50,925 = $2.96 Direct LabourActual labour hours = $145,355 14.80 = 9,821.3 hours Labour hours per unit = 9,821.3 7,275 units = 1.35 hours per unit
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7‐37 (cont’d)
Direct Materials: Frames
Actual Costs Incurred (Actual Input Qty. × Actual Price) (1) (7,275 × 3.2 × $2.40) $55,872
Actual Input Qty. × Budgeted Price (2) (7,275 × 3.2 × $2.20) $51,216
$4,656 U Price variance
Flexible Budget (Budgeted Input Qty. Allowed for Actual Output × Budgeted Price) (3) (7,275 × 3.00 × $2.20) $48,015
$3,201 U Efficiency variance
Direct Materials: Lenses
(7,275 × 7.0 × $2.96) $150,738
Direct Manuf. Labour
2.
$7,130 F Price variance
(7,275 × 1.35 × $14.80) $145,355
(7,275 × 7.0 × $3.10) $157,868
$1,964 F Price variance
$22,553 U Efficiency variance
(7,275 × 1.35 × $15.00) $147,319
(7,275 × 1.20 × $15.00) $130,950
$16,369 U Efficiency variance
Possible explanations for the price variances are: (a) Unexpected outcomes from purchasing and labour negotiations during the year. (b) Higher quality of frames and/or lower quality of lenses purchased. (c) Standards set incorrectly at the start of the year. Possible explanations for the uniformly unfavourable efficiency variances are: (a) Substantially higher usage of lenses due to poor quality lenses purchased at lower price. (b) Lesser trained workers hired at lower rates result in higher materials usage (for both frames and lenses), as well as lower levels of labour efficiency. (c) Standards set incorrectly at the start of the year.
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(7,275 × 6.00 × $3.10) $135,315
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7‐38 (60 min.) Comprehensive variance analysis review. 1.
Actual Results Units sold Selling price per unit Revenue Direct materials purchased and used: Total direct materials cost Direct materials per unit Direct manufacturing labour: Total direct manufacturing labour costs (5,000 $18) Manufacturing labour‐hours of input (1,400,000 280) Labour productivity per hour Actual manufacturing rate per hour Direct marketing labour: Total direct marketing costs (1,400,000 $0.36) Direct marketing cost per unit
1,400,000 $4.86 $6,804,000 $1,316,000 $0.94
$90,000 5,000 280 $18.00
$504,000 $0.36
Fixed costs ($1,080,000 – $33,000)
$1,047,000
Static Budgeted Amounts Units sold Selling price per unit Revenue
1,660,500 $4.80 $7,970,400
Direct materials purchased and used: Direct materials per unit Total direct materials costs
$1.02 $1,693,710
Direct manufacturing labour: Direct manufacturing rate per hour Labour productivity per hour Manufacturing labour‐hours of input (1,660,500 300) Total direct manufacturing labour cost Direct marketing labour Direct marketing cost per unit Total direct marketing cost Fixed costs
$18.00 300 5,535 $99,630
$0.36 $597,780 $1,080,000
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7‐38 (cont’d)
2.
Revenue Variable costs Direct materials Direct manufacturing labour Direct marketing labour Total variable costs Contribution margin Fixed costs Operating income Actual operating income Static‐budget operating income Total static‐budget variance
3, 4, and 5. Actual Results Units sold 1,400,000 Revenue $6,804,000 Variable costs Direct materials 1,316,000 Direct manuf. labour 90,000 Direct marketing labour 504,000 Total variable costs 1,910,000 Contribution margin 4,894,000 Fixed costs 1,047,000 Operating income $3,847,000
Actual Results $6,804,000
Static‐ Budgeted Amount $7,970,400
1,316,000 90,000 504,000 1,910,000 4,894,000 1,047,000 $3,847,000
1,693,710 99,630 597,780 2,391,120 5,579,280 1,080,000 $4,499,280
$3,847,000 4,499,280 $ 652,280 U
Flexible‐ Budget Flexible Variances Budget — 1,400,000
Sales‐ Volume Static Variances Budget — 1,660,500
$ 84,000 F $6,720,000 $1,250,400 U $7,970,400 112,000 F 1,428,000 265,710 F 1,693,710 6,000 U 84,000 a 15,630 F 99,630 0 U 504,000 93,780 F 597,780 106,000 F 2,016,000 375,120 F 2,391,120 190,000 F 4,704,000 875,280 U 5,579,280 33,000 F 1,080,000 0 1,080,000 $223,000 F $3,624,000 $ 875,280 U $4,499,280 $223,000 F
$875,280 U
Total flexible‐budget varianceTotal sales‐volume variance $652,280 U Total static‐budget variance
(1,400,000 300) hrs $18/hr = $84,000
a
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7‐38 (cont’d) 6, 7, and 8. Material Variances: Flexible Budget Actual Costs (Budgeted Input Incurred Allowed for Actual (Actual Input Actual Input Output Actual Price) Budgeted Price Budgeted Price) (1,400,000 $0.94) (1,400,000 $1.02) (1,400,000 $1.02) $1,316,000 $1,428,000 $1,428,000 $112,000 F $0
Price variance
Efficiency variance
$112,000 F
Flexible‐budget variance Manufacturing Labour Variances: Flexible Budget Actual Costs (Budgeted Input Incurred Allowed for Actual (Actual Input Actual Input Output Actual Price) Budgeted Price Budgeted Price) (5,000 $18.00) (5,000 $18.00) (4,667** x $18.00) $90,000 $90,000 $84,000 $0 $6,000 U
Price variance
Efficiency variance
$6,000 U
Flexible‐budget variance **1,400,000÷ 300 = 4,667 rounded
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7‐38 (cont’d) Marketing Labour Variances: Flexible Budget Actual Costs (Budgeted Input Incurred Allowed for Actual (Actual Input Actual Input Output Actual Price) Budgeted Price Budgeted Price) (1,400,000 $0.36) (1,400,000 $0.36) (1,400,000 $0.36) $504,000 $504,000 $504,000 $0 $0
Price variance
Efficiency variance $0
Flexible‐budget variance Total price variances = $112,000 F Total efficiency variances = $6,000 U The unfavourable efficiency variance arises because of the decline in productivity from the budgeted 300 drives per hour to the actual 280 drives per hour. 7‐39 (35 min.) Materials variances: price, efficiency, mix, and yield. 1. Oak ($6 × 8 b.f.) $ 48 Pine ($2 × 12 b.f.) 24 Cost per dresser $ 72 Number of ×3,000 units dressers Total budgeted $216,000 cost
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7‐39 (cont’d) 2.
Solution Exhibit 7‐39A presents the total price variance ($5,246 F), the total efficiency variance ($1,280 F), and the total flexible‐budget variance ($6,526 F). Total direct materials price variance can also be computed as: Direct materials quantity Actual Budgeted × Actual price variance = of input price of input price of input for each input Oak = ($6.10 – $6.00) × 23,180 = $2,318 U Pine = ($1.80 – $2.00) × 37,820 = $7,564 F Total direct materials price variance $5,246 F
Total direct materials efficiency variance can also be computed as: Direct materials Budgeted efficiency variance = Actual quantity Budgeted quantity of input × price of input of input allowed for actual output for each input Oak = (23,180 – 24,000) × $6.00 = $4,920 F Pine = (37,820 – 36,000) × $2.00 = $3,640 U Total direct materials efficiency variance $1,280 F
SOLUTION EXHIBIT 7‐39A Columnar Presentation of Direct Materials Price and Efficiency Variances for PDS Manufacturing Flexible Budget (Budgeted Input Quantity Actual Costs Incurred Allowed for Actual (Actual Input Quantity Actual Input Quantity Output × Actual Price) × Budgeted Price × Budgeted Price) (1) (2) (3) Oak Pine
23,180 × $6.10 = $141,398 37,820 × $1.80 = 68,076 $209,474
23,180 × $6.00 = $139,080 37,820 × $2.00 = 75,640 $214,720
$5,246 F
24,000 × $6.00 = $144,000 36,000 × $2.00 = 72,000 $216,000
$1,280 F
Total price variance Total efficiency variance $6,526 F Total flexible‐budget variance
F = favourable effect on operating income; U = unfavourable effect on operating income
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7‐39 (cont’d) 3.
Actual Quantity Actual of Input Mix Oak 23,180 b.f. 38% Pine 37,820 b.f. 62% Total 61,000 b.f. 100%
Budgeted Quantity of Input for Actual Output 8 b.f. × 3,000 units = 24,000 b.f. 12 b.f. × 3,000 units = 36,000 b.f. 60,000 b.f.
Budgeted Mix 40% 60% 100%
4. Solution Exhibit 7‐39B presents the total direct materials yield and mix variances for PDS Manufacturing. The total direct materials yield variance can also be computed as the sum of the direct materials yield variances for each input: Direct materials = yield variance for each input
Budgeted Budgeted Actual total Budgeted total quantity direct materials price of quantity of all of all direct materials inputs × × direct materials input mix direct materials allowed for actual output inputs used inputs percentage
Oak = (61,000 – 60,000) × 0.40 × $6.00 = 1,000 × 0.40 × $6.00 = $2,400 U Pine = (61,000 – 60,000) × 0.60 × $2.00 = 1,000 × 0.60 × $2.00 = 1,200 U Total direct materials yield variance $3,600 U The total direct materials mix variance can also be computed as the sum of the direct materials mix variances for each input: Direct Actual total Budgeted Actual Budgeted materials quantity of all price of direct materials direct materials = × × mix variance input mix input mix direct materials direct materials for each input percentage inputs used inputs percentage
Oak = (0.38 – 0.40) × 61,000 × $6.00 = 0.02 × 61,000 × $6.00 = $7,320 F Pine = (0.62 – 0.60) × 61,000 × $2.00 = – 0.02 × 61,000 × $2.00 = 2,440 U Total direct materials mix variance $4,880 F The sum of the direct materials mix variance and the direct materials yield variance equals the direct materials efficiency variance. The favourable mix variance arises from using more of the cheaper pine (and less oak) than the budgeted mix. The yield variance indicates that the dressers required more total inputs (61,000 b.f.) than expected (60,000 b.f.) for the production of 3,000 dressers. Both variances are relatively small and probably within tolerable limits. PDS should investigate whether substituting the cheaper pine for the more expensive oak caused the unfavourable yield variance. It should also be careful that using more of the cheaper pine does not reduce the quality of the dresser or how customers perceive it.
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Solution Exhibit 7‐39B Columnar Presentation of Direct Materials Yield and Mix Variances for PDS Manufacturing Flexible Budget: Budgeted Total Quantity Actual Total Quantity Actual Total Quantity of All Inputs Allowed for of All Inputs Used of All Inputs Used Actual Output × × Actual Input Mix × Budgeted Input Mix Budgeted Input Mix × Budgeted Price × Budgeted Price × Budgeted Price (1) (2) (3) Oak 61,000 × 0.38 × $6.00 = $139,080 Pine 61,000 × 0.62 × $2.00 = 75,640 $214,720
61,000 × 0.40 × $6.00 = $146,400 60,000 × 0.40 × $6.00 = $144,000 61,000 × 0.60 × $2.00 = 73,200 60,000 × 0.60 × $2.00 = 72,000 $219,600 $216,000
4,880 F
$3,600 U
Total mix variance Total yield variance $1,280 F
Total efficiency variance F = favourable effect on operating income; U = unfavourable effect on operating income.
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7‐40 (50 min.) Product input mix and yield variance. 1.
The direct materials standard to produce 80 kilograms of tropical fruit salad are: 50 kilograms of pineapple; 30 kilograms of watermelon; 20 kilograms of strawberries. Therefore, budgeted input allowed for each kilogram of tropical fruit salad: Pineapples: 50 kilograms ÷ 80 kilograms = 0.625 kilograms Watermelons: 30 kilograms ÷ 80 kilograms = 0.375 kilograms Strawberries: 20 kilograms ÷ 80 kilograms = 0.250 kilograms All fruit: 1.250 kilograms Budgeted input allowed for 54,000 kilograms of tropical fruit salad: Pineapples: 54,000 0.625 = 33,750 kilograms Watermelons: 54,000 0.375 = 20,250 kilograms Strawberries: 54,000 0.25 = 13,500 kilograms All fruit: 67,500 kilograms Solution Exhibit 7‐40A presents the total direct materials price and efficiency variances for Tropical Fruit Inc. for October.
The total direct materials price variances can also be computed as:
Direct m aterials
Actu al Bu d geted Actu al price variance price inpu ts price for each inpu t
Pineapples = (0.95 – $1.05) 36,400 Watermelons = (0.65 – $0.55) 18,200 Strawberries = (0.75 – $0.80) 15,400 Total direct materials price variance
= = = =
$3,640 F 1,820 U 770 F $2,590 F
The direct materials efficiency variances can also be computed as:
Direct m aterials
Actu al inpu ts Bu d geted inpu ts allow ed Bu d geted efficiency variance price u sed for actu al ou tpu t for each inpu t Pineapples = (36,400 – 33,750) $1.05 Watermelons = (18,200 – 20,250) $0.55 Strawberries = (15,400 – 13,500) $0.80 Total direct materials efficiency variance
= = = =
$2,782.50 U 1,127.50 F 1,520.00 U $3,175.00 U
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SOLUTION EXHIBIT 7‐40A Columnar Presentation of Direct Materials Price and Efficiency Variances for Tropical Fruits Actual Costs Incurred: Actual Input Actual Input Actual Price Budgeted Price (1) (2) Pineapple Watermelons Strawberries All Inputs
36,400 $0.95 = $34,580 18,200 $0.65 = 11,830 15,400 $0.75 = 11,550 $57,960
36,400 $1.05 = $38,220 18,200 $0.55 = 10,010 15,400 $0.80 = 12,320 $60,550
Flexible Budget: Budgeted Input Allowed for Actual Outputs Budgeted Price (3) 33,750 $1.05 = $35,437.50 20,250 $0.55 = 11,137.50 13,500 $0.80 = 10,800.00 $57,375.00
$2,590 F $3,175 U Total price variance Total efficiency variance $585 U Total flexible‐budget variance F = favourable effect on operating income; U = unfavourable effect on operating income. 2. Solution Exhibit 7‐40B presents the total direct materials yield and mix variances for Tropical Fruits Inc. for October. The total direct materials yield variance can also be computed as the sum of the direct materials yield variances for each input. Budgeted total quantity Bud geted Budgeted Actual total materials quantity of all of all direct materials direct materials price of direct materials yield variance inputs allowed for input mix direct percentage materials input for each input actual output inputs used Direct
Pineapple: = (70,000 – 67,500) 0.5 $1.05 = 2,500 0.5 $1.05 Watermelon: = (70,000 – 67,500) 0.3 $0.55 = 2,500 0.3 $0.55 Strawberries: = (70,000 – 67,500) 0.2 $0.80 = 2,500 0.2 $0.80 Total direct materials yield variance
= = =
$1,312.50 U 412.50 U 400.00 U $2,125.00 U
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7‐40 (cont’d) The total direct materials mix variance can also be computed as the sum of the direct materials mix variances for each input: Actu al Bu d geted Bu d geted m aterials qu antity of all d irect m aterials d irect m aterials price of m ix variance d irect m aterials inpu t m ix inpu t m ix d irect m aterials for each inpu t inpu ts u sed percentage percentage inpu t Direct
Actu al total
Pineapple = 70,000 (0.52 – 0.50) $1.05 = 70,000 0.02 $1.05 = $1,470 U Watermelon = 70,000 (0.26 – 0.30) $0.55 = 70,000 –0.04 $0.55 = 1,540 F Strawberries = 70,000 (0.22 – 0.20) $0.80 = 70,000 0.02 $0.80 = 1,120 U Total direct materials mix variance $1,050 U 3. Tropical Fruits has traded off a favourable material price variance of $2,590 against an unfavourable material efficiency variance of $3,175. Tropical Fruits should investigate if the favourable price variances on pineapples and strawberries were obtained by compromising quality. Both the yield and the mix variances are unfavourable. Tropical Fruits could have used larger quantities of all fruits to produce the given output because of lower quality of pineapples and strawberries. The total direct materials mix variance is unfavourable because the actual mix of direct materials inputs had a greater proportion of the more costly inputs (pineapples and strawberries) than the budgeted mix. 4. Direct materials yield and direct materials mix variances are especially informative when management can substitute among the individual material inputs. Such substitution is possible in the processing of individual fruits into tropical fruit salad.
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SOLUTION EXHIBIT 7‐40B Columnar Presentation of Direct Materials Yield and Mix Variances for Tropical Fruits Flexible Budget: Budgeted Total Quantity of Actual Total Quantity Actual Total Quantity All Inputs Allowed for of All Inputs Used of All Inputs Used Actual Output Actual Input Mix Budgeted Input Mix Budgeted Input Mix Budgeted Price Budgeted Price Budgeted Price (1) (2) (3) Pineapple (70,000 0.52a) $1.05 = $38,220 Watermelon (70,000 0.26c) $0.55 = 10,010 Strawberries (70,000 0.22e) $0.80 = 12,320 All Inputs $60,550
(70,000 0.5b) $1.05 = $36,750 (67,500 0.5) $1.05 = $35,437.50 (70,000 0.3d) $0.55 = 11,550 (67,500 0.3) $0.55 = 11,137.50 (70,000 0.2f) $0.80 = 11,200 (67,500 0.2) $0.80 = 10,800.00 $59,500 $57,375.00
$1,050 U $2,125 U Total mix variance Total yield variance $3,175 U Total efficiency variance F = favourable effect on operating income; U = unfavourable effect on operating income. Actual Input Mix: aPineapple = 36,400 ÷ 70,000 = 52% cWatermelon = 18,200 ÷ 70,000 = 26% eStrawberries = 15,400 ÷ 70,000 = 22% Budgeted Input Mix: bPineapple = 50 ÷ 100 = 50% dWatermelon = 30 ÷ 100 = 30% fStrawberries = 20 ÷ 100 = 20%
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7‐41 (30‐40 min.) Possible causes for price and efficiency variances. 1.
Variances
Actual Costs (Budgeted Input Incurred Qty. Allowed for (Actual Input Qty. Actual Input Qty. Actual Output × Actual Price) × Budgeted Price × Budgeted Price) Direct (60,000,000 × $0.035) (360,000 × 150g × $0.035) Materials $2,125,000 $2,100,000 $1,890,000 $25,000 U $210,000 U Price variance Efficiency variance Direct Manufacturing (22,040 × $29.30) (12,000a × $29.30) Labour $664,940 $645,772 $351,600 $19,168 U $294,172 U Price variance Efficiency variance a
0.5 bottle per minute equates to 30 bottles per hour; 360,000/30 = 12,000 hours
2.
Materials and labour efficiency variances account for the most significant portion of the total variance. Poor quality of materials and the resulting extra labour time working required to work with poor quality materials are one possible reason for the unfavourable efficiency variances.
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7‐42 (20 min.) Variance analysis with activity‐based costing and batch‐level direct costs 1. Flexible budget variances for batch activities Actual Costs Incurred (Actual Input Qty. Actual Input Qty. × Actual Price) × Budgeted Price 15, 000 15, 000 Setup $ $
75
$16,800
Quality Inspection
Flexible Budget (Budgeted Input Qty. Allowed for Actual Output × Budgeted Price) 15, 000 $ 75 100 $15,050 $12,900 $1,750 U $2,150 U Price variance Efficiency variance $3,900 U
Actual Costs Incurred (Actual Input Qty. Actual Input Qty. × Actual Price) × Budgeted Price 15, 000 $ 100
15, 000 $ 100
Flexible Budget (Budgeted Input Qty. Allowed for Actual Output × Budgeted Price) 15, 000 $ 120
$20,925 $23,625 $21,875 $2,700 F $1,750 U Price variance Efficiency variance
$950 F
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7‐42 (cont’d) 2.
Re: Explanation of Variances Below I explain the implications of the variances that I calculated. I would enjoy meeting with you to discuss whether we are following the most efficient policies, given these calculations. Please let me know if there is any way to improve my work or my presentation to you. 1. Our batch sizes for both setups and quality inspection were smaller than planned. Even though we were able to reduce the setup and quality inspection time needed for each batch (because of the smaller batch sizes), these gains were more than offset by the increased number of batches. Overall, we ended up substantially below the level of efficiency at which we wished to operate. 2. The hourly wage for the setup workers went over budget due to the tight labour market in our area for such employees. However, we saved a considerable amount of money because we were able to negotiate reduced wage rates for the quality inspection labour after the expiration of their previous contract. Overall, given our output level of 15,000 eels, we had a moderately favourable variance for quality inspection costs, and a significant unfavourable variance on setups, for the reasons outlined above.
7‐43
Variance procedures; flexible‐budget preparation, service sector
1.
Budgeted selling price (revenue per loan application) 1/2% × budgeted average loan amount = 1/2% × $240,000 = $1,200 Budgeted variable costs per output unit are: Professional labour (6 × $48) $288 Loan filing fees 120 Credit worthiness checks 144 Courier mailings 60 Budgeted variable costs $612 Budgeted fixed costs = $37,200 per month.
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7‐43 (cont’d) The static budget for the 90‐loan applicant level (and the flexible budget for the 120‐loan application level in Requirement 2) are: Requirement 1 Requirement 2 90 Loan 120 Loan Applications Applications Budgeted revenue (90, 120 × $1,200) $108,000 $144,000 Budgeted variable costs (90, 120 × $612) 55,080 73,440 Contribution margin 52,920 70,560 Fixed costs 37,200 37,200 Operating income $ 15,720 $ 33,360 2.
The actual results are: Revenue (120 × 1/2% × $268,800) $161,280 Variable costs: Professional labour (120 × 7.2 × $50.40) $ 43,546 Loan filing fees (120 × $120) 14,400 Creditworthiness checks (120 × $150) 18,000 Courier mailings (120 × $64.80) 7,776 83,722 Contribution margin 77,558 Fixed costs 40,200 Operating income $ 37,358 These actual results can be analyzed in a Level 2 variance analysis. Level 2 Analysis Actual Results (1) Units sold 120 Revenue $161,280 Variable costs 83,722 Contribution margin 77,558 Fixed costs 40,200 Operating income $ 37,358
Flexible‐ Budget Variances (2)=(1)–(3) 0 $17,280 F 10,282 U 6,998 F 3,000 U $ 3,998 F
Sales‐ Flexible Volume Static Budget Variances Budget (3) (4)=(3)–(5) (5) 120 30 F 90 $144,000 $36,000 F $108,000 73,440 18,360 U 55,080 70,560 17,640 F 52,920 37,200 0 37,200 $ 33,360 $17,640 F $15,720
$3,998 F
$17,640 F
Total flexible‐budget variance
Total sales‐volume variance
Total static‐budget variance
$21,638 F
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7‐43 (cont’d) Note that the $21,638 favourable static‐budget variance is largely the result of an increase in loan applications from a budgeted 90 to an actual 120. In addition, the average size of a loan increased from a budgeted $240,000 to $268,800 which explains the flexible‐budget variance of $17,280 F for revenues (0.5% × $28,800 × 120 = $17,280). One possible explanation is a rapid decrease in interest rates leading to an increase in demand for loan refinancing.
7‐44 1.
2.
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Benchmarking, hospital cost comparisons.
Detailed cost studies of the kind developed by Market Insights can provide insight into one critical area of Horn’s performance that is, cost management. Horn apparently believes in an “ask no questions” approach in relation to cost management. When an institution is running large deficits, this approach is totally unacceptable. (Even if surpluses were occurring, an “ask no questions” approach is not appropriate.) Horn is correct in noting that in many areas of hospital administration, it is not possible to have well‐defined relationships between inputs and outputs. He is also correct in observing that “good output” is difficult to define. However, neither point means that he cannot learn from a study that shows the cost management skills of other hospitals doing similar operations to PUH. The main inference is that PUH has well‐above‐average cost levels. At the aggregate hospital level, its cost structure is 20% above the average cost. Even more disconcerting, it is over 70% more costly than hospitals E, C and J. PUH is above average cost for five of the six diagnostic groups listed. Even more disconcerting is the magnitude of the difference between PUH and the 25th percentile for five of the six diagnostic groups: Angina, chest pain Asthma, bronchitis Skin disorders, cellulitis Renal failure & dialysis Diabetes Gastroenteritis
Ratio of PUH to 25th Percentile 1.33 1.48 1.48 1.81 1.81 0.75
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7‐44 (cont’d) 3.
4.
5.
Leung could use the MI benchmark cost report as an attention‐directing mechanism. It provides some quantitative data to use with PUH managers when discussing cost management. The onus could be put on PUH managers to explain why their cost structure is so far above average. Leung might also consider using the MI reports in subsequent performance evaluation of PUH managers. Targets could be set for the managers to reduce (say) the gap between PUH and the 25th percentile. The report could also be used to determine why gastroenteritis is so cost efficient, and possibly help to identify if any best practices that area could be used in the less‐efficient departments. Horn might make the following criticisms of the MI benchmark cost reports: (a) The reports focus only on cost—they are “a cost accountant’s view of the world.” (b) The reports rely on data hospitals submit to various regulatory bodies. These reports likely serve different purposes and hence may not be appropriate to use for cost comparisons. (c) Cost accounting systems of hospitals are of highly variable quality. Horn probably would argue “garbage‐in garbage‐out” applies to this data. Other factors include: (a) The perceived (and actual) quality of service provided to patients. (b) The success rate of operations. (c) The morale of the doctors, nurses, and other staff. Being a university hospital, other factors would also likely be important, including: (d) The teaching ability of doctors at the hospital. (e) The research record of doctors at the hospital.
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COLLABORATIVE LEARNING CASES
7‐45 (30‐40 min.) Procurement costs, variance analysis, governance. 1.
Purchase price variances can be computed for each country.
Purchase price Actual price Budgeted price Actual quantity of input variance of input of input
Hergonia = ($15.60* – $14.00) 250,000 = $400,000 U *$3,900,000 ÷ 250,000 = $15.60
On a per‐unit basis, there is a $12.43(1) payment to the shoe manufacturer and a $3.17(2) payment for “other costs.” $3,108,000 ÷ 250,000 $792,000 ÷ 250,000
(1) (2)
= $12.43 = $3.17
Tanista = ($13.67* – $14.00) 900,000 = $297,000 F
*$12,300,000 ÷ 900,000 = $13.67
On a per‐unit basis, there is an $11.26(3) payment to the shoe manufacturer and a $2.40(4) payment for “other costs.” (3) $10,136,000 900,000 = $11.26 (4) $2,164,000(5) 900,000 = $2.40 (5) $12,300,000 – 10,136,000 = $2,164,000
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7‐45 (cont’d) 2.
Daley and Mullins face many ethical issues: (a) Reliability of cost information to be presented to the board of directors. There are minimal or questionable receipts for $792,000 in Hergonia and $2,164,000 in Tanista. (b) Potential existence of kickback payments in both Hergonia and Tanista. (c) Employment of young children (many of them under 15 years).
3.
Should Daley and Mullins be forthright and present all their concerns on (a), (b), and (c)? Both Daley and Mullins face the dilemma that any discussion of (a), (b), or (c) will raise questions about their own behaviour at the time the acquisitions were made. Board members may ask “When did you first know about (a), (b), and (c)?” and “If it is only recently, why did you not undertake examination of these issues at the time you supported the acquisitions?” Mullins has very high standards of ethical conduct to meet. She should not make presentations to the Board based on information she has strong doubts about. If she decides to make the presentation, all her concerns and caveats should be presented. She should require detailed documentation for all payments. No future payments should be made without adequate documentation. Investigation of kickback allegations should be made, however difficult that may be. Mullins should be able to show she made a good‐faith effort to ensure kickback payments are not an ongoing practice in Hergonia or Tanista.
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7‐46 (30 min.)
Price and efficiency variances, problems in standard‐setting, benchmarking.
1. Budgeted direct materials input per shirt = 600 rolls ÷ 6,000 shirts = 0.10 roll of cloth Budgeted direct manufacturing labour‐hours per shirt = 1,500 hours ÷ 6,000 shirts = 0.25 hours Budgeted direct materials cost = $30,000 ÷ 600 = $50 per roll Budgeted direct manufacturing labour cost per hour = $27,000 ÷ 1,500 = $18 per hour Actual output achieved = 6,732 shirts
Flexible Budget Actual Costs (Budgeted Input Incurred Qty. Allowed for (Actual Input Qty. Actual Input Qty. Actual Output × Actual Price) × Budgeted Price × Budgeted Price) Direct (612 × $50) (6,732 × 0.10 × $50) Materials $30,294 $30,600 $33,660 $306 F $3,060 F Price variance Efficiency variance Direct Manufacturing (1,530 × $18) (6,732 × 0.25 × $18) Labour $27,693 $27,540 $30,294 $153 U $2,754 F Price variance Efficiency variance 2. Actions employees may have taken include: (a) Adding steps that are not necessary in working on a shirt. (b) Taking more time on each step than is necessary. (c) Creating problem situations so that the budgeted amount of average downtime will be overstated. (d) Creating defects in shirts so that the budgeted amount of average rework will be overstated. Employees may take these actions for several possible reasons. (a) They may be paid on a piece‐rate basis with incentives for production levels above budget. (b) They may want to create a relaxed work atmosphere, and a less demanding standard can reduce stress. (c) They have a “them vs. us” mentality rather than a partnership perspective.
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7‐46 (cont’d) (d)
They may want to gain all the benefits that ensue from superior performance (job security, wage rate increases) without putting in the extra effort required.
This behaviour is unethical if it is deliberately designed to undermine the credibility of the standards used at New Fashions. If Jorgenson does nothing about standard costs, his behaviour will violate a number of standards of ethical conduct for practitioners of management accounting. In particular, he would violate the (a) standards of competence, by not performing professional duties in accordance with relevant standards; (b) standards of integrity, by passively subverting the attainment of the organization’s objective to control costs; and (c) standards of credibility, by not communicating information fairly and not disclosing all relevant cost information.
3.
4.
Jorgenson should discuss the situation with Fenton and point out that the standards are lax and that this practice is unethical. If Fenton does not agree to change, Jorgenson should escalate the issue up the hierarchy in order to effect change. If organizational change is not forthcoming, Jorgenson should be prepared to resign rather than compromise his professional ethics.
5.
Main pros of using Benchmarking Clearing House information to compute variances are: (a) Highlights to New Fashions in a direct way how it may or may not be cost‐competitive. (b) Provides a “reality check” to many internal positions about efficiency or effectiveness.
Main cons are: (a) New Fashions may not be comparable to companies in the database. (b) Cost data about other companies may not be reliable. (c) Cost of Benchmarking Clearing House reports.
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CHAPTER 8 FLEXIBLE BUDGETS, OVERHEAD COST VARIANCES, AND MANAGEMENT CONTROL: II
SHORT‐ANSWER QUESTIONS 8‐1
Effective planning of variable overhead costs involves: 1. Planning to undertake only those variable overhead activities that add value for customers using the product or service, and 2. Planning to use the drivers of costs in those activities in the most efficient way.
8‐2
At the start of an accounting period, a larger percentage of fixed overhead costs are locked‐in than is the case with variable overhead costs. When planning fixed overhead costs, a company must choose the appropriate level of capacity or investment that will benefit the company over a long time. This is a strategic decision.
8‐3
The key differences are how direct costs are traced to a cost object and how indirect costs are allocated to a cost object: Actual Costing Standard Costing Direct costs Actual prices × Standard prices × Standard inputs Actual inputs used allowed for actual output Indirect costs Actual indirect rate Standard indirect cost‐allocation rate × × Actual inputs used Standard quantity of cost‐allocation base allowed for actual output
8‐4
8‐5
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Steps in developing a budgeted variable‐overhead cost rate: 1. Choose the period to be used for the budget, 2. Select the cost‐allocation bases to use in allocating variable overhead costs to the output produced, 3. Identify the variable overhead costs associated with each cost‐allocation base, and 4. Compute the rate per unit of each cost‐allocation base used to allocate variable overhead costs to output produced. Two factors affecting the rate variance for variable manufacturing overhead are: • Price inflation or deflation of individual items included in variable overhead. • Usage of individual items included in variable overhead. Copyright © 2013 Pearson Canada Inc.
8‐6
Chapter 8
Reasons for a $30,000 favourable variable‐overhead efficiency variance: • Workers more skillful in using machines than budgeted. • Production scheduler was able to schedule jobs better than budgeted, resulting in lower‐than‐budgeted machine‐hours. • Machines operated with fewer slowdowns than budgeted. • Machine time standards set with padding built in by machine‐workers.
8‐7
A direct materials efficiency variance indicates whether more or less direct materials were used than was budgeted for the actual output achieved. A variable manufacturing overhead efficiency variance indicates whether more or less of the chosen allocation base was used than was budgeted for the actual output achieved.
8‐8
Steps in developing a budgeted fixed‐overhead rate are 1. Choose the period to use for the budget, 2. Select the cost‐allocation base to use in allocating fixed overhead costs to output produced, 3. Identify the fixed‐overhead costs associated with each cost‐allocation base, and 4. Compute the rate per unit of each cost‐allocation base used to allocate fixed overhead costs to output produced.
8‐9
The relationship for fixed‐manufacturing overhead variances is: Flexible-budget variance
Efficiency variance
Rate variance (never a variance) There is never an efficiency variance for fixed overhead because managers cannot be more or less efficient in dealing with an amount that is fixed regardless of the output level. The result is that the flexible‐budget variance amount is the same as the rate variance for fixed‐manufacturing overhead.
8‐10 For planning and control purposes, fixed overhead costs are a lump sum amount that is not controlled on a per‐unit basis. In contrast, for inventory costing purposes, fixed overhead costs are allocated to products on a per‐unit basis.
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8‐11 An important caveat is what change in selling price might have been necessary to attain the level of sales assumed in the denominator of the fixed manufacturing overhead rate. For example, the entry of a new low‐price competitor may have reduced demand below the denominator level if the budgeted selling price was maintained. An unfavourable production‐volume variance may be small relative to the selling‐price variance had prices been dropped to attain the denominator level of unit sales.
8‐12 A strong case can be made for writing off an unfavourable production‐volume variance to cost of goods sold. The alternative is prorating it among inventories and cost of goods sold, but this would “penalize” the units produced (and in inventory) for the cost of unused capacity, i.e., for the units not produced. But, if we take the view that the denominator level is a “soft” number—i.e., it is only an estimate, and it is never expected to be reached exactly, then it makes more sense to prorate the production volume variance—whether favourable or not—among the inventory stock and cost of goods sold. Prorating a favourable variance is also more conservative: it results in a lower operating income than if the favourable variance had all been written off to cost of goods sold. Finally, prorating also dampens the efficacy of any steps taken by company management to manage operating income through manipulation of the production volume variance. In sum, a production‐volume variance need not always be written off to cost of goods sold.
8‐13 The four variances are:
Variable manufacturing overhead costs rate variance efficiency variance Fixed manufacturing overhead costs rate variance production‐volume variance
8‐14 Interdependencies among the variances could arise for the rate and efficiency variances. For example, if the chosen allocation base for the variable overhead efficiency variance is only one of several cost drivers, the variable overhead rate variance will include the effect of the other cost drivers. As a second example, interdependencies can be induced when there are misclassifications of costs as fixed when they are variable, and vice versa.
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EXERCISES
8‐15 (10 min.)
Terminology.
Interpretation of variances strategically means management teams must place their internal performance relative to their competitors and to what their customers value. Decisions about capacity incur capacity costs of ownership and maintenance for the long term. To the customer, however, the cost of unused capacity is a non‐ value‐added cost for which they will not pay. This cost arises because the quantity produced is less than the capacity available. The cost is fixed therefore the burden assigned to each actual unit produced is higher than it should be. This unfavourable outcome is a denominator‐level variance. It is also referred to as the production volume variance and is an underallocation of capacity costs that will persist until consumer demand, actual production and available capacity intersect. But fixed costs also include contractual costs such as salaries and regulatory costs of taxes. These costs can change unexpectedly and will result in a fixed overhead rate variance. Equipment also requires maintenance which, along with custodial and security costs are required and shared resources that benefit all outputs. When the actual measure of benefit provided exceeds the budget what arises is an unfavourable variable overhead efficiency variance. When the actual cost per unit of benefit provided exceeds budget there arises an unfavourable variable overhead rate variance. Both are underallocations of variable overhead cost 8‐16 (20 min.) Variable manufacturing overhead, variance analysis. 1. Variable Manufacturing Overhead Variance Analysis for Esquire Clothing for June 2013 Actual Costs Incurred Actual Input Qty. Actual Input Qty. × Actual Rate × Budgeted Rate (1) (2)
(4,536 × $11.50) $52,164
(4,536 × $12) $54,432
Flexible Budget: Budgeted Input Qty. Allowed for Actual Output × Budgeted Rate (3) (4 × 1,080 × $12) $51,840
$2,268 F Rate variance
$2,592 U Efficiency variance
$324 U Flexible-budget variance
Allocated: Budgeted Input Qty. Allowed for Actual Output × Budgeted Rate (4) (4 × 1,080 × $12) $51,840
Never a variance
Never a variance
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8‐16 (cont’d) 2.
Esquire had a favourable rate variance of $2,268 because the actual variable overhead rate was $11.50 per direct manufacturing labour‐hour versus $12 budgeted. It had an unfavourable efficiency variance of $2,592 U because each suit averaged 4.2 labour‐hours (4,536 hours ÷ 1,080 suits) versus 4.0 budgeted labour‐hours.
8‐17 (20 min.) Fixed manufacturing overhead variance analysis. 1 & 2.
Budgeted fixed overhead $62,400 rate per unit of = 1,040 4 allocation base $62,400 = 4,160 = $15 per hour
Fixed Manufacturing Overhead Variance Analysis for Esquire Clothing for June 2013 Allocated: Flexible Budget: Same Budgeted Same Budgeted Budgeted Input Lump Sum Lump Sum Qty. (as in Static Budget) (as in Static Budget) Allowed for Actual Actual Costs Regardless of Regardless of Output Incurred Output Level Output Level × Budgeted Rate (4) (1) (2) (3) (4 × 1,080 × $15) $63,916 $62,400 $62,400 $64,800 $1,516 U $2,400 F
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Rate variance
Never a variance Production‐volume variance
$1,516 U Flexible‐budget variance
$2,400 F Production‐volume variance
The fixed manufacturing overhead rate variance and the fixed manufacturing flexible budget variance are the same––$1,516 U. Esquire spent $1,516 above the $62,400 budgeted amount for June 2013.
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Chapter 8
8‐17 (cont’d) The production‐volume variance is $2,400 F. This arises because Esquire utilized its capacity more intensively than budgeted (the actual production of 1,080 suits exceeds the budgeted 1,040 suits). This results in overallocated fixed manufacturing overhead of $2,400 (4 × 40 × $15). Esquire would want to understand the reasons for a favourable production‐volume variance. Is the market growing? Is Esquire gaining market share? Will Esquire need to add capacity?
8‐18 (30 min.) Variable manufacturing overhead variance analysis. 1. Denominator level = ((3,840,000/100) × 2 hours) = 76,800 hours Flexible 2. Actual Budget Results Amounts 1. Output units (baguettes) 3,360,000 3,360,000 2. Direct manufacturing labour‐hours 50,400 67,200a 3. Labour‐hours per output unit (2 1) 0.015 0.020 4. Variable manuf. overhead (MOH) costs $326,400 $268,800 5. Variable MOH per labour‐hour (4 2) $6.476 $4 6. Variable MOH per output unit (4 1) $0.097 $0.080 a ((3,360,000/100) 2) = 67,200 hours Variable Manufacturing Overhead Variance Analysis for French Bread Company for 2013 Flexible Budget: Allocated: Budgeted Input Qty. Budgeted Input Qty. Actual Costs Allowed for Allowed for Incurred Actual Output Actual Output Actual Input Qty. Actual Input Qty. × Budgeted Rate × Budgeted Rate × Budgeted Rate × Actual Rate (2) (3) (4) (1) (50,400 × $6.476) (50,400 × $4) (67,200 × $4) (67,200 × $4) $326,400 $201,600 $268,800 $268,800 $124,800U $67,200 F Rate variance Never a variance Efficiency variance $57,600U Flexible-budget variance Never a variance
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8‐18 (cont’d) 3.
Rate variance of $124,800U. It is unfavourable because variable manufacturing overhead was higher than planned. A possible explanation could be an increase in energy rates relative to the rate per standard labour‐hour assumed in the flexible budget. Efficiency variance of $67,200F. It is favourable because the actual number of direct manufacturing labour‐hours required was lower than the number of hours in the flexible budget. Labour was more efficient in producing the baguettes than management had anticipated in the budget. This could occur because of improved morale in the company, which could result from an increase in wages or an improvement in the compensation scheme. Flexible‐budget variance of $57,600U. It is unfavourable because the favourable efficiency variance was not large enough to compensate for the large unfavourable rate variance.
8‐19 (30 min.) Fixed manufacturing overhead variance analysis. 1.
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Budgeted standard direct manufacturing labour used = 0.02 per baguette Budgeted output = 3,840,000 baguettes Budgeted standard direct manufacturing labour‐hours = 3,840,000 × 0.02 = 76,800 hours Budgeted fixed manufacturing overhead costs = 76,800 × $4.00 per hour = $307,200 Actual output = 3,360,000 baguettes Allocated fixed manufacturing overhead = 3,360,000 × 0.02 × $4 = $268,800
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Chapter 8
8‐19 (cont’d) Fixed Manufacturing Overhead Variance Analysis for French Bread Company for 2013 Flexible Budget: Same Budgeted Same Budgeted Allocated: Lump Sum Lump Sum Budgeted Input Qty. (as in Static Budget) (as in Static Budget) Allowed for Actual Costs Regardless of Regardless of Actual Output Incurred Output Level Output Level × Budgeted Rate (1) (2) (3) (4) (3,360,000 × 0.02 × $4) $272,000 $307,200 $307,200 $268,800 $38,400 U $35,200 F Production-volume Rate variance Never a variance variance
$35,200 F Flexible-budget variance
$38,400 U Production-volume variance
$3,200 U Underallocated fixed overhead (Total fixed overhead variance)
2. The fixed manufacturing overhead is underallocated by $3,200. 3. The production‐volume variance of $38,400U captures the difference between the budgeted 3,840,0000 baguettes and the lower actual 3,360,000 baguettes produced— the fixed cost capacity not used. The rate variance of $35,200 favourable means that the actual aggregate of fixed costs ($272,000) is less than the budget amount ($307,200). For example, monthly leasing rates for baguette‐making machines may have increased above those in the budget for 2013.
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8‐20 (30–40 min.) Manufacturing overhead, variance analysis. 1.
The summary information is:
The Solutions Corporation (June 2013) Outputs units (number of assembled units) Hours of assembly time Assembly hours per unit Variable mfg. overhead cost per hour of assembly time Variable mfg. overhead costs Fixed mfg. overhead costs Fixed mfg. overhead costs per hour of assembly time a 200 units 2 assembly hours per unit = 400 hours
Actual 216 411 1.90b
Flexible Static Budget Budget 216 200 c 432 400a 2.00 2.00
$ 30.20d $12,420 $20,560
$ 30.00 $12,960e $19,200
$ 50.02g
411 hours 216 units = 1.90 assembly hours per unit
b
216 units 2 assembly hours per unit = 432 hours
c
$12,420 411 assembly hours = $30.22 per assembly hour
d
432 assembly hours $30 per assembly hour = $12,960
e
400 assembly hours $30 per assembly hour = $12,000
f
$20,560 411 assembly hours = $50 per assembly hour
g
$19,200 400 assembly hours = $48 per assembly hour
h
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$ 30.00 $12,000f $19,200 $ 48.00h
Chapter 8
8‐20 (cont’d)
Flexible Budget: Allocated: Budgeted Input Budgeted Input Qty. Allowed Qty. Allowed Actual Costs Actual Input Qty. Budgeted Budgeted Incurred Budgeted Rate for Actual Output Rate for Actual Output Rate Variable $30.00 432 $30.00 432 $30.00 411 assy. per assy. per assy. Manufacturing hrs. hr. assy. hrs. hr. assy. hrs. per assy. hr. Overhead $12,420 $12,330 $12,960 $12,960 $90 U $630 F Rate variance Efficiency variance Never a variance
$540 F Flexible‐budget variance
Never a variance $540 F Overallocated variable overhead
Flexible Budget: Budgeted Input Allocated: Static Budget Lump Sum Static Budget Lump Sum Allowed Budgeted Regardless of Output Incurred Level Regardless of Output Level for Actual Output Rate 432 $48.00 assy. hrs. assy. hr. $20,560 $19,200 $19,200 $20,736 $1,360 U $1,536 F Rate Variance Never a Variance Production‐volume Variance $1,360 U $1,536 F Flexible‐budget variance Production‐volume variance
Actual Costs
Fixed Manufacturing Overhead
$176 F
Overallocated fixed overhead
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8‐20 (cont’d) The summary analysis is:
Rate Variance $90 U
Efficiency Variance $630 F
Variable Manufacturing Overhead Fixed Manufacturing $1,360 U Never a variance Overhead 2. Variable Manufacturing Costs and Variances
Production‐Volume Variance Never a variance
12,420
$1,536 F
a. Variable Manufacturing Overhead Control Accounts Payable Control and various other accounts 12,420 To record actual variable manufacturing overhead costs incurred. b. Work‐in‐Process Control 12,960 Variable Manufacturing Overhead Allocated 12,960 To record variable manufacturing overhead allocated. c. Variable Manufacturing Overhead Allocated 12,960 Variable Manufacturing Overhead Rate Variance 90 Variable Manufacturing Overhead Control 12,420 Variable Manufacturing Overhead Efficiency Variance 630 To isolate variances for the accounting period. d. Variable Manufacturing Overhead Efficiency Variance 630 Variable Manufacturing Overhead Rate Variance 90 Cost of Goods Sold 540 To write off variable manufacturing overhead variances to cost of goods sold.
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Chapter 8
8‐20 (cont’d) Fixed Manufacturing Costs and Variances a. Fixed Manufacturing Overhead Control 20,560 Salaries Payable, Acc. Depreciation, various other accounts 20,560 To record actual fixed manufacturing overhead costs incurred. b. Work‐in‐Process Control 20,736 Fixed Manufacturing Overhead Allocated 20,736 To record fixed manufacturing overhead allocated. c. Fixed Manufacturing Overhead Allocated 20,736 Fixed Manufacturing Overhead Rate Variance 1,360 Fixed Manufacturing Overhead Production‐Volume Variance 1,536 Fixed Manufacturing Overhead Control 20,560 To isolate variances for the accounting period. d. Fixed Manufacturing Overhead Production‐Volume Variance 1,536 Fixed Manufacturing Overhead Rate Variance 1,360 Cost of Goods Sold 176 To write off fixed manufacturing overhead variances to cost of goods sold. 3. Planning and control of variable manufacturing overhead costs has both a long‐ run and a short‐run focus. It involves Solutions planning to undertake only value‐added overhead activities (a long‐run view) and then managing the cost drivers of those activities in the most efficient way (a short‐run view). Planning and control of fixed manufacturing overhead costs at Solutions have primarily a long‐run focus. It involves undertaking only value‐added fixed‐overhead activities for a budgeted level of output. Solutions makes most of the key decisions that determine the level of fixed‐overhead costs at the start of the accounting period.
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8‐21 (1015 min.) Four‐variance analysis, fill in the blanks. Variable Fixed 1. Rate variance $4,200 U $3,000 U 2. Efficiency variance 4,500 U NEVER 3. Production‐volume variance NEVER 600 U 4. Flexible‐budget variance 8,700 U 3,000 U 5. Underallocated (overallocated) MOH 8,700 U 3,600 U These relationships could be presented in the same way as in Exhibit 8‐4. Flexible Budget: Allocated: Budgeted Input Budgeted Input Qty. Qty. Actual Input Allowed for Allowed for Actual Costs Qty. Actual Output Actual Output Incurred × Budgeted Rate × Budgeted Rate × Budgeted Rate (1) (2) (3) (4) Variable $35,700 $31,500 $27,000 $27,000 MOH $4,200 U $4,500 U Never a variance Rate variance Efficiency variance $8,700 U Never a variance Flexible-budget variance $8,700 U Underallocated variable overhead (Total variable overhead variance)
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8‐21 (cont’d)
Fixed MOH
Same Budgeted Lump Sum (as in Static Budget) Regardless of Actual Costs Output Level Incurred (2) (1) $18,000 $15,000
Flexible Budget: Same Budgeted Lump Sum (as in Static Budget) Regardless of Output Level (3) $15,000
Allocated: Budgeted Input Qty. Allowed for Actual Output × Budgeted Rate (4) $14,400
$3,000 U $600 U Rate variance Never a variance Production-volume variance $600 U $3,000 U Production-volume variance Flexible-budget variance $3,600 U Underallocated fixed overhead (Total fixed overhead variance) An overview of the four overhead variances is: Production‐ Four‐Variance Rate Efficiency Volume Analysis Variance Variance Variance Variable Overhead $4,200 U $4,500 U Never a variance FixedOverhead $3,000 U Never a variance $600 U
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8‐22 (20–30 min.) Straightforward four‐variance overhead analysis. 1.
The budget for fixed manufacturing overhead is 4,000 units × 6 machine‐hours × $15 machine‐hours/unit = $360,000. An overview of the four‐variance analysis is: Four‐Variance Analysis Variable Manufacturing Overhead Fixed Manufacturing Overhead
Rate Variance $17,800 U $13,000 U
Efficiency Production‐ Variance Volume Variance $16,000 U Never a Variance Never a Variance $36,000 F
Solution Exhibit 8‐22 has details of these variances. A detailed comparison of actual and flexible budgeted amounts is:
Output units (auto parts)
Actual 4,400
Flexible Budget 4,400
Allocation base (machine‐hours)
28,400
26,400
Allocation base per output unit
6.45
b
a
6.00 c
Variable MOH
$245,000
Variable MOH per hour
$8.63
$8.00
Fixed MOH
$373,000
$360,000
Fixed MOH per hour
$13.13
d
f
$211,200 e
–
4,400 units × 6.00 machine‐hours/unit = 26,400 machine‐hours 28,400 ÷ 4,400 = 6.45 machine‐hours per unit c 4,400 units × 6.00 machine‐hours per unit × $8.00 per machine‐hour = $211,200 d $245,000 ÷ 28,400 = $8.63 e 4,000 units × 6.00 machine‐hours per unit × $15 per machine‐hour = $360,000 f $373,000 ÷ 28,400 = $13.13 a
b
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Chapter 8
Solution Exhibit 8‐22 Flexible Budget: Budgeted Input Allocated: Allowed for Budgeted Input Actual Input Actual Output Allowed for Actual Costs × Budgeted × Budgeted Actual Output Incurred Rate Rate × Budgeted Rate (1) (2) (3) (4) Variable (28,400 × $8) (4,400 × 6 × $8) (4,400 × 6 × $8) MOH $245,000 $227,200 $211,200 $211,200 $17,800 U $16,000 U Rate variance Efficiency variance Never a variance $33,800 U Flexible-budget variance Never a variance $33,800 U Underallocated variable overhead (Total variable overhead variance) Flexible Budget: Same Budgeted Same Budgeted Lump Sum Lump Sum Allocated: (as in Static (as in Static Budgeted Input Budget) Budget) Allowed for Regardless of Regardless of Actual Output Actual Costs Incurred Output Level Output Level × Budgeted Rate (1) (2) (3) (4) Fixed (4,000 × 6 × $15) (4,000 × 6 × $15) (4,400 × 6 × $15) MOH $373,000 $360,000 $360,000 $396,000 $13,000 U $36,000 F Production-volume Rate variance Never a variance variance $36,000 F $13,000 U Production-volume Flexible-budget variance variance $23,000 F Overallocated fixed overhead (Total fixed overhead variance) Copyright © 2013 Pearson Canada Inc.
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8‐22 (cont’d) 2. 3.
4.
8–362
Variable Manufacturing Overhead Control Accounts Payable Control and other accounts
245,000
245,000
Work‐in‐Process Control Variable Manufacturing Overhead Allocated
211,200
211,200
Variable Manufacturing Overhead Allocated Variable Manufacturing Overhead Rate Variance Variable Manufacturing Overhead Efficiency Variance Variable Manufacturing Overhead Control
211,200 17,800 16,000
245,000
Fixed Manufacturing Overhead Control Wages Payable Control, Accumulated Depreciation Work‐in‐Process Control Fixed Manufacturing Overhead Allocated
373,000 Control, etc.
373,000
396,000
396,000
Fixed Manufacturing Overhead Allocated 396,000 Fixed Manufacturing Overhead Rate Variance 13,000 Fixed Manufacturing Overhead Production‐Volume Variance Fixed Manufacturing Overhead Control
36,000 373,000
Individual fixed manufacturing overhead items are not usually affected very much by day‐to‐day control. Instead, they are controlled periodically through planning decisions and budgeting procedures that may sometimes have horizons covering six months or a year (for example, management salaries) and sometimes covering many years (for example, long‐term leases and depreciation on plant and equipment). The fixed overhead rate variance is caused by the actual realization of fixed costs differing from the budgeted amounts. Some fixed costs are known because they are contractually specified, such as rent or insurance, although if the rental or insurance contract expires during the year, the fixed amount can change. Other fixed costs are estimated, such as the cost of managerial salaries which may depend on bonuses and other payments not known at the beginning of the period. In this example, the rate variance is unfavourable, so actual FOH is greater than the budgeted amount of FOH. The fixed overhead production volume variance is caused by production being over or under expected capacity. You may be under capacity when demand drops from expected levels, or if there are problems with production. Over capacity is usually driven by favourable demand shocks or a desire to increase inventories. The fact that there is a favourable volume variance indicates that production exceeded the expected level of output (4,400 units actual relative to a denominator level of 4,000 output units).
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Chapter 8
8‐23 (3040 min.) Straightforward coverage of manufacturing overhead, standard cost system. Solution Exhibit 8‐23 shows the computations. Summary details are:
1.
Output units Allocation base (machine‐hours)
Actual 49,200 15,960
Allocation base per output unit Variable MOH
0.324b $186,120
Variable MOH per hour
$11.662 $481,200
Fixed MOH Fixed MOH per hour
d
e
$30.15
Flexible Budget 49,200 a
14,760 0.30 c
$212,544 $14.40 $468,000 –
d $186,120 ÷ 15,960 = $11.662 49,200 × 0.30 = 14,760 b 15,960 ÷ 49,200 = 0.324 e $481,200 ÷ 15,960 = $30.15 c 14,760 × $14.40 = $212,544 An overview of the four‐variance analysis is: Four‐Variance Rate Efficiency Production Analysis Variance Variance Volume Variance Variable Manufacturing $43,704 F $17,280 U Never a variance Overhead Fixed Manufacturing $13,200 U Never a $25,200 U Overhead variance 2. Variable Manufacturing Overhead Control 186,120 Accounts Payable Control and other accounts 186,120 Work‐in‐Process Control 212,544 Variable Manufacturing Overhead Allocated 212,544 Variable Manufacturing Overhead Allocated 212,544 a
Variable Manufacturing Overhead Efficiency Variance Variable Manufacturing Overhead Rate Variance Variable Manufacturing Overhead Control
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17,280
43,704 186,120
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8‐23 (cont’d) 3.
4.
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Fixed Manufacturing Overhead Control Wages Payable Control, Accumulated Depreciation Control, etc.
481,200
481,200
Work‐in‐Process Control Fixed Manufacturing Overhead Allocated
442,800
442,800
Fixed Manufacturing Overhead Allocated 442,800 Fixed Manufacturing Overhead Rate Variance 13,200 Fixed Manufacturing Overhead Production‐Volume Variance 25,200 Fixed Manufacturing Overhead Control
481,200
The control of variable manufacturing overhead requires the identification of the cost drivers for such items as energy, supplies, and repairs. Control often entails monitoring nonfinancial measures that affect each cost item, one by one. Examples are kilowatt‐hours used, quantities of lubricants used, and repair parts and hours used. The most convincing way to discover why overhead performance did not agree with a budget is to investigate possible causes, line item by line item. The variable overhead rate variance is favourable. This means the actual rate applied to the manufacturing costs is lower than the budgeted rate. Since variable overhead consists of several different costs, this could be for a variety of reasons, such as the utility rates being lower than estimated or the indirect materials costs per unit of denominator activity being less than estimated. The variable overhead efficiency variance is unfavourable, which implies that the estimated denominator activity was too low. Since the denominator activity is machine hours, this could be the result of inefficient use of machines, poorly scheduled production runs, or machines that need maintenance and thus are not working at the expected level of efficiency.
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Chapter 8
Solution Exhibit 8‐23
Variable Manufacturing Overhead
Fixed Manufacturing Overhead
Actual Input × Budgeted Rate (2)
Flexible Budget: Budgeted Input Allocated: Allowed for Budgeted Input Actual Output Allowed for × Budgeted Rate Actual Output (3) × Budgeted Rate (4)
(15,960 × $14.40) $229,824
(14,760 × $14.40) $212,544
$43,704 F Rate variance
(14,760 × $14.40) $212,544
$17,280 U Efficiency variance Never a variance
$26,424 F Flexible-budget variance
Actual Costs Incurred (1) $186,120
Never a variance
$26,424 F Underallocated variable overhead (Total variable overhead variance) Same Budgeted Flexible Budget: Lump Sum Same Budgeted Allocated: (as in Static Lump Sum Budgeted Input Budget) (as in Static Budget) Allowed for Actual Costs Regardless of Regardless of Actual Output Incurred Output Level Output Level × Budgeted Rate (1) (2) (3) (4) (14,760 × $30) $481,200 $468,000 $468,000 $442,800 $13,200 U Rate variance
Never a variance
$13,200 U Flexible-budget variance
$25,200 U Production-volume variance $25,200 U Production-volume variance
$38,400 U Underallocated fixed overhead (Total fixed overhead variance)
Fixed manufacturing overhead $468,000 = = $30 per machine‐hour. budgeted rate 15,600 machine - hours
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8‐24 (20–25 min.) Overhead variances, service sector. 1. Meals on Wheels (May 2013) Output units (number of deliveries) Hours per delivery Hours of delivery time Variable overhead costs per delivery hour Variable overhead (VOH) costs Fixed overhead costs Fixed overhead cost per hour
Actual Results 8,800 0.65a 5,720 $1.80c $10,296 $38,600
Flexible Budget 8,800 0.70 6,160b $1.50 $9,240d $35,000
Static Budget 10,000 0.70 7,000b $1.50 $10,500d $35,000 $5.00e
5,720 hours 8,800 deliveries = 0.65 hours per delivery hrs. per delivery number of deliveries = 0.70 10,000 = 7,000 hours c $10,296 VOH costs 5,720 delivery hours = $1.80 per delivery hour d Delivery hours VOH cost per delivery hour = 7,000 $1.50 = $10,500 e Static budget delivery hours = 10,000 units 0.70 hours/unit = 7,000 hours; Fixed overhead rate = Fixed overhead costs Static budget delivery hours = $35,000 7,000 hours = $5 per hour a
b
VARIABLE OVERHEAD
Actual Costs Incurred
Actual Input Qty. Budgeted Rate 5,720 hrs $1.50 per hr. $8,580
$10,296 $1,716 U Rate variance
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Flexible Budget: Budgeted Input Qty. Allowed for Actual Output Budgeted Rate 6,160 hrs $1.50 per hr. $9,240
$660 F Efficiency variance
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8‐24 (cont’d) 2.
Actual Costs Incurred
$38,600 3.
$3,600 U Rate variance
FIXED OVERHEAD Flexible Budget: Same Budgeted Lump Sum (as in Static Budget) Regardless of Output Level
$35,000
Allocated: Budgeted Input Qty. Allowed for Actual Output Budgeted Rate 8,800 units 0.70 hrs./unit $5/hr. 6,160 hrs. $5/hr. $30,800
$4,200 U Production‐volume variance
The rate variances for variable and fixed overhead are both unfavourable. This means that MOW had increases over budget in either or both the cost of individual items (such as telephone calls and gasoline) in the overhead cost pools, or the usage of these individual items per unit of the allocation base (delivery time). The favourable efficiency variance for variable overhead costs results from more efficient use of the cost allocation base––each delivery takes 0.65 hours versus a budgeted 0.70 hours. MOW can best manage its fixed overhead costs by long‐term planning of capacity rather than day‐to‐day decisions. This involves planning to undertake only value‐added fixed‐overhead activities and then determining the appropriate level for those activities. Most fixed overhead costs are committed well before they are incurred. In contrast, for variable overhead, a mix of long‐run planning and daily monitoring of the use of individual items is required to manage costs efficiently. MOW should plan to undertake only value‐added variable‐overhead activities (a long‐run focus) and then manage the cost drivers of those activities in the most efficient way (a short‐run focus). There is no production‐volume variance for variable overhead costs. The unfavourable production‐volume variance for fixed overhead costs arises because MOW has unused fixed overhead resources that it may seek to reduce in the long run.
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8‐25 (4050 min.) Total overhead, three‐variance analysis. 1.
This problem has two major purposes: (a) to give experience with data allocated on a total overhead basis instead of on separate variable and fixed bases and (b) to reinforce distinctions between actual hours of input, budgeted (standard) hours allowed for actual output, and denominator level. An analysis of direct manufacturing labour will provide the data for actual hours of input and standard hours allowed. One approach is to plug the known figures (designated by asterisks) into the analytical framework and solve for the unknowns. The direct manufacturing labour efficiency variance can be computed by subtracting $3,856 from $5,776. The complete picture is as follows: Flexible Budget: Budgeted Input Allowed for Actual Costs Actual Input Actual Output Incurred × Budgeted Rate × Budgeted Rate * (4,820 hrs. × $16.80) (4,820hrs. × $16.00 ) (4,700 hrs. × $16.00*) $80,976* $77,120 $75,200 $3,856 U* Price variance
$1,920 U Efficiency variance
$5,776 U* Flexible-budget variance
Given Direct Labour calculations Actual input × Budgeted rate = Actual costs – Price variance = $80,976 – $3,856 = $77,120 Actual input = $77,120 ÷ Budgeted rate = $77,120 ÷ $16 = 4,820 hours Budgeted input × Budgeted rate = $77,120 – Efficiency variance = $77,120 – $1,920 = $75,200 Budgeted input = $75,200 ÷ Budgeted rate = $75,200 ÷ 16 = 4,700 hours Production Overhead Variable overhead rate = $25,600* ÷ 3,200* hrs. = $8.00 per standard labour‐hour Budgeted fixed = $79,040* – (4,000* × $8.00) = $47,040 fixed overhead overhead costs If total overhead is allocated at 120% of direct labour‐cost, the single overhead rate must be 120% of $16.00, or $19.20 per hour. Therefore, the fixed overhead component of the rate must be $19.20 – $8.00, or $11.20 per direct labour‐hour. *
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8‐25 (cont’d) Let D = denominator level in input units Budgeted fixed Budgeted fixed overhead costs overhead rate = Denominator level in input units per input unit $11.20 = $47,040 ÷ D D = 4,200 direct labour‐hours A summary three‐variance analysis for October follows: Flexible Budget: Allocated: Budgeted Input Budgeted Input Actual Allowed for Allowed for Actual Inputs Actual Output Actual Output Costs × Budgeted Rate × Budgeted Rate × Budgeted Rate Incurred ($47,040 + (4,820 × $8.00) $47,040 + ($8 × 4,700) (4,700 hrs. × $19.20) $99,600* $85,600 $84,640 $90,240 $14,000 U $5,600 F* $960 U Rate variance variance Production-volume variance Efficiency $14,960 U $5,600 F*
Flexible-budget variance
Production-volume variance
Known figure An overview of the three‐variance analysis using the block format in the text is: Three‐Variance Rate Efficiency Production Analysis Variance Variance Volume Variance $14,000 U $960U $5,600 F Total Overhead 2. The control of variable manufacturing overhead requires the identification of the cost drivers for such items as energy, supplies, equipment, and maintenance. Control often entails monitoring nonfinancial measures that affect each cost item, one by one. Examples are kilowatts used, quantities of lubricants used, and equipment parts and hours used. The most convincing way to discover why overhead performance did not agree with a budget is to investigate possible causes, line item by line item. Individual fixed manufacturing overhead items are not usually affected very much by day‐to‐day control. Instead, they are controlled periodically through planning decisions and budgeting that may sometimes have horizons covering six months or a year (for example, management salaries) and sometimes covering many years (for example, long‐term leases and depreciation on plant and equipment). *
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8‐26 (30 min.) Overhead variances, missing information. 1.
In the columnar presentation of variable overhead variance analysis, all numbers shown in bold are calculated from the given information, in the order (a) ‐ (e).
VARIABLE MANUFACTURING OVERHEAD Flexible Budget: Budgeted Input Qty. Actual Costs Actual Input Qty. Allowed for Budgeted Incurred Actual Output Rate Budgeted Rate (b) (a) (c) $6.00 14,850 15,000 $6.00 mach. per mach. per mach. hrs. hr. mach. hrs. hr. $89,625 $90,000 $89,100 $375 F $900 U (d) Rate variance Efficiency variance
$525 U (e) Flexible‐budget variance a. 15,000 machine‐hours $6 per machine‐hour = $90,000 b. Actual VMOH = $90,000 – $375F (VOH rate variance) = $89,625 c. 14,850 machine‐hours $6 per machine‐hour = $89,100 d. VOH efficiency variance = $90,000 – $89,100 = $900U e. VOH flexible budget variance = $900U – $375F = $525U Allocated variable overhead will be the same as the flexible budget variable overhead of $89,100. The actual variable overhead cost is $89,625. Therefore, variable overhead is underallocated by $525.
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8‐26 (cont’d) 2.
In the columnar presentation of fixed overhead variance analysis, all numbers shown in bold are calculated from the given information, in the order (a) – (e).
FIXED MANUFACTURING OVERHEAD Flexible Budget: Allocated: Static Budget Lump Sum Budgeted Input Actual Costs Regardless of Output Qty. Allowed for Budgeted Incurred Level Actual Output Rate (a) (b) 14,850 $1.60* (c) mach. hrs. mach. hr. $30,375 $28,800 $23,760 $1,575 U $5,040 U (d) Rate variance Production‐volume variance $1,575 U (e) Flexible‐budget variance a. Actual FOH costs = $120,000 total overhead costs – $89,625 VOH costs = $30,375 b. Static budget FOH lump sum = $30,375 – $1,575 rate variance = $28,800 c. *FOH allocation rate = $28,800 FOH static‐budget lump sum 18,000 static‐budget machine‐ hours = $1.60 per machine‐hour Allocated FOH = 14,850 machine‐hours $1.60 per machine‐hour = $23,760 d. PVV = $28,800 – $23,760 = $5,040U e. FOH flexible budget variance = FOH rate variance = $1,575 U Allocated fixed overhead is $23,760. The actual fixed overhead cost is $30,375. Therefore, fixed overhead is underallocated by $6,615.
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8‐27 (15 min.) Identifying favourable and unfavourable variances.
Scenario Production output is 5% more than budgeted, and actual fixed manufacturing overhead costs are 6% more than budgeted Production output is 10% more than budgeted; actual machine hours are 5% less than budgeted Production output is 8% less than budgeted
VOH Rate Variance Cannot be determined: no information on actual versus budgeted VOH rates
FOH Rate Variance Unfavourable: actual fixed costs are more than budgeted fixed costs
FOH Production‐ Volume Variance Favourable: output is more than budgeted causing FOH costs to be overallocated
Cannot be determined: no information on actual versus budgeted VOH rates
Favourable: actual machine‐ hours less than flexible‐budget machine‐hours
Cannot be determined: no information on actual versus budgeted FOH costs
Favourable: output is more than budgeted causing FOH costs to be overallocated
Cannot be determined: no information on actual versus budgeted VOH rates
Cannot be determined: no information on actual machine‐ hours versus flexible‐budget machine‐hours Unfavourable: more machine‐ hours used relative to flexible budget
Cannot be determined: no information on actual versus budgeted FOH costs
Unfavourable: output less than budgeted will cause FOH costs to be underallocated
Cannot be determined: no information on actual versus budgeted FOH costs
Cannot be determined: no information on flexible‐budget machine‐hours relative to static‐ budget machine‐ hours Cannot be determined: no information on actual output relative to budgeted output
Actual machine hours are 15% greater than flexible‐budget machine hours
Cannot be determined: no information on actual versus budgeted VOH rates
Relative to the flexible budget, actual machine hours are 10% greater and actual variable manufacturing overhead costs are 15% greater
Unfavourable: actual VOH rate greater than budgeted VOH rate
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VOH Efficiency Variance Cannot be determined: no information on actual versus flexible‐budget machine‐hours
Unfavourable: actual machine‐ hours greater than flexible‐ budget machine‐ hours
Cannot be determined: no information on actual versus budgeted FOH costs
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Chapter 8
8‐28 (35 min.) Flexible‐budget variances, review of Chapters 7 and 8. 1.
Solution Exhibit 8‐28 contains a columnar presentation of the variances for Doorknob Design Company (DDC) for April 2013.
SOLUTION EXHIBIT 8‐28 Flexible Budget: Budgeted Input Qty. Allowed for Actual Output × Budgeted Price (47,500 $20.0) $950,000
Actual Costs Incurred: Actual Input Qty. Actual Input Qty. Budgeted Price Usage × Actual Rate Purchases Direct (50,000 $22.0) (50,000 $20.0) (45,000 $20.0) Materials $1,100,000 $1,000,000 $900,000 $100,000 U $50,000 F
a. Price variance
Direct Manufacturing Labour
b. Efficiency variance
$650,000 $50,000 U
(20,000 $30.0) (23,750 $30.0) $600,000 $712,500 $112,500 F
c. Price variance
d. Efficiency variance
Allocated: Flexible Budget: (Budgeted Input Budgeted Input Qty. Qty. Actual Allowed for Allowed for Costs Actual Input Qty. Actual Output Actual Output Incurred Budgeted Rate Budgeted Rate Budgeted Rate) Variable Manufacturing (45,000 $10.0) (47,500 $10.0) (47,500 $10.0) Overhead $400,000 $450,000 $475,000 $475,000 $50,000 F $25,000 F e. Rate variance f. Efficiency variance Never a variance
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8‐28 (cont’d) Fixed (47,500 $5.0) Manufacturing $350,000 $250,000* $250,000 $237,500 Overhead $100,000 U $12,500 U h. Rate variance Never a variance g. Production‐volume variance *Denominator level in kg.: 100,000 x .5 = 50,000 kg. Budgeted Fixed Overhead: 50,000 x $5/kg = $250,000 2. The direct materials price variance indicates that DDC paid more for brass than they had planned. If this is because they purchased a higher quality of brass, it may explain why they used less brass than expected (leading to a favourable material efficiency variance). In turn, since variable manufacturing overhead is assigned based on pounds of materials used, this directly led to the favourable variable overhead efficiency variance. The purchase of a better quality of brass may also explain why it took less labour time to produce the doorknobs than expected (the favourable direct labour efficiency variance). Finally, the unfavourable direct labour price variance could imply that the workers who were hired were more experienced than expected, which could also be related to the positive direct material and direct labour efficiency variances.
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PROBLEMS 8‐29 (30 min.) Comprehensive variance analysis. 1.
2.
3.
4.
5.
6.
Budgeted number of machine‐hours planned can be calculated by multiplying the number of units planned (budgeted) by the number of machine‐hours allocated per unit: 888 units 2 machine‐hours per unit = 1,776 machine‐hours. Budgeted fixed MOH costs per machine‐hour can be computed by dividing the flexible budget amount for fixed MOH (which is the same as the static budget) by the number of machine‐hours planned (calculated in (a.)): $348,096 ÷ 1,776 machine‐hours = $196.00 per machine‐hour Budgeted variable MOH costs per machine‐hour are calculated as budgeted variable MOH costs divided by the budgeted number of machine‐hours planned: $71,040 ÷ 1,776 machine‐hours = $40.00 per machine‐hour. Budgeted number of machine‐hours allowed for actual output achieved can be calculated by dividing the flexible‐budget amount for variable MOH by budgeted variable MOH costs per machine‐hour: $76,800 ÷ $40.00 per machine‐hour= 1,920 machine‐hours allowed The actual number of output units is the budgeted number of machine‐hours allowed for actual output achieved divided by the planned allocation rate of machine hours per unit: 1,920 machine‐hours ÷ 2 machine‐hours per unit = 960 units. The actual number of machine‐hours used per output unit is the actual number of machine hours used (given) divided by the actual number of units manufactured: 1,824 machine‐hours ÷ 960 units = 1.9 machine‐hours used per output unit.
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8‐30 (60 min.) Journal entries. 1. Key information underlying the computation of variances is: Actual Results 960 1,824 1.90
Flexible‐Budget Amount 960 1,920 2.00 $76,800 $40.00 $80.00 $348,096 $181.30 $362.60
1. Output units (food processors) 2. Machine‐hours 3. Machine‐hours per output unit 4. Variable MOH costs $76,608 5. Variable MOH costs per machine‐ hour (Row 4 ÷ Row 2) $42.00 6. Variable MOH costs per unit (Row 4 ÷ Row 1) $79.80 7. Fixed MOH costs $350,208 8. Fixed MOH costs per machine‐ hour (Row 7 ÷ Row 2) $192.00 9. Fixed MOH costs per unit (7 ÷ 1) $364.80 Solution Exhibit 8‐30 shows the computation of the variances. Journal entries for variable MOH, year ended December 31, 2013: Variable MOH Control 76,608 Accounts Payable Control and Other Accounts Work‐in‐Process Control 76,800 Variable MOH Allocated Variable MOH Allocated 76,800 Variable MOH Rate Variance 3,648 Variable MOH Control Variable MOH Efficiency Variance
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Static‐ Budget Amount 888 1,776 2.00 $71,040 $40.00 $80.00 $348,096 $196.00 $392.00
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76,608
76,800
76,608 3,840
Chapter 8
8‐30 (cont’d) Journal entries for fixed MOH, year ended December 31, 2013: Fixed MOH Control 350,208 Wages Payable, Accumulated Depreciation, etc. 350,208 Work‐in‐Process Control 376,320 Fixed MOH Allocated 376,320 Fixed MOH Allocated 376,320 Fixed MOH Rate Variance 2,112 Fixed MOH Control 350,208 Fixed MOH Production‐Volume Variance 28,224 2. Adjustment of COGS Variable MOH Efficiency Variance 3,840 Fixed MOH Production‐Volume Variance 28,224 Variable MOH Rate Variance 3,648 Fixed MOH Rate Variance 2,112 Cost of Goods Sold 26,304 SOLUTION EXHIBIT 8‐30 Variable Manufacturing Overhead Allocated: Flexible Budget: Budgeted Input Budgeted Input Qty. Qty. Allowed for Allowed for Actual Input Qty. Actual Output Actual Output Actual Costs Incurred × Budgeted Rate × Budgeted Rate × Budgeted Rate (2) (3) (4) (1) (1,824 $42) (1,824 $40) (1,920 $40) (1,920 $40) $76,608 $72,960 $76,800 $76,800 $3,648 U $3,840 F Rate variance Never a variance Efficiency variance
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8‐30 (cont’d) Fixed Manufacturing Overhead Flexible Budget: Same Budgeted Lump Sum (as in Static Budget) Regardless of Output Level (3) $348,096
Same Budgeted Lump Sum (as in Static Budget) Actual Costs Regardless Of Incurred Output Level (1) (2) $350,208 $348,096 $2,112U Rate variance Never a variance 8‐31 (3040 min.) Graphs and overhead variances. 1. Variable Manufacturing Overhead Costs Total Variable Manuf. Overhead Costs $18,000,000
$28,224 F Production-volume variance
Graph for planning and control and inventory costing purposes at $9 per machine-hour
$9,000,000
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Allocated: Budgeted Input Qty. Allowed for Actual Output × Budgeted Rate (4) (1,920 × $196) $376,320
1,000,000 Machine-Hours
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Chapter 8
8‐31 (cont’d) Fixed Manufacturing Overhead Costs Total Fixed Manuf. Overhead Costs $18,000,000
Graph for planning and control purpose Graph for inventory costing purpose ($18 per machine-hour)
$9,000,000
1,000,000 Machine-Hours * Budgeted fixed manufacturing Budgeted fixed manufacturing overhead = overhead rate per hour Denominator level = $18,000,000/ 1,000,000 machine hours = $18 per machine‐hour 2. (a) Variable Manufacturing Overhead Variance Analysis for Fresh, Inc. for 2013 Allocated: Flexible Budget: Budgeted Input Budgeted Input Qty. Qty. Allowed for Allowed for Actual Input Qty. Actual Output Actual Costs Actual Output Incurred × Budgeted Rate × Budgeted Rate × Budgeted Rate (1) (2) (3) (4) (950,000 $9) (875,000 $9) (875,000 $9) $9,025,000 $8,550,000 $7,875,000 $7,875,000 $475,000 U $675,000 U Rate variance Efficiency variance Never a variance $1,150,000 U Flexible-budget variance Never a variance $1,150000 U
Underallocated variable overhead (Total variable overhead variance)
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8‐31 (cont’d)
(b) Fixed Manufacturing Overhead Variance Analysis for Fresh, Inc. for 2013
Actual Costs Incurred (1)
Same Budgeted Lump Sum (as in Static Budget) Regardless of Output Level (2)
Flexible Budget: Same Budgeted Lump Sum (as in Static Budget) Regardless of Output Level (3)
$18,050,000
$18,000,000
$18,000,000
$50,000 U Rate variance
Never a variance
Allocated: Budgeted Input Qty. Allowed for Actual Output × Budgeted Rate (4) (875,000 × $18) $15,750,000
$2,250,000 U* Production-volume variance
$50,000 U Flexible-budget variance
$2,250,000 U* Production-volume variance
$2,300,000 U Underallocated fixed overhead (Total fixed overhead variance)
Alternative computation: 1,000,000 denominator hrs. – 875,000 budgeted hrs. allowed = 125,000 hrs. 125,000 $18 = $2,250,000 U 3. The underallocated manufacturing overhead was: variable, $1,150,000 and fixed, $2,300,000. The flexible‐budget variance and underallocated overhead are always the same amount for variable manufacturing overhead, because the flexible‐ budget amount of variable manufacturing overhead and the allocated amount of variable manufacturing overhead coincide. In contrast, the budgeted and allocated amounts for fixed manufacturing overhead only coincide when the budgeted input of the allocation base for the actual output level achieved exactly equals the denominator level.
*
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8‐31 (cont’d) 4.
The choice of the denominator level will affect inventory costs. The new fixed manufacturing overhead rate would be $18,000,000 ÷ 750,000 = $24 per machine‐ hour. In turn, the allocated amount of fixed manufacturing overhead and the production‐volume variance would change as seen below:
Actual $18,050,000
Budget $18,000,000
Allocated 875,000 × $24 = $21,000,000
$50,000 U $3,000,000 F* Flexible‐budget variance Prodn. volume variance $2,950,000 F Total fixed overhead variance *Alternate computation: (750,000 – 875,000) × $24 = $3,000,000 F The major point of this requirement is that inventory costs (and, hence, income determination) can be heavily affected by the choice of the denominator level used for setting the fixed manufacturing overhead rate.
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8‐32 (30 min.) Fixed overhead variance. Known figures denoted by an * Flexible Budget: Allocated: Budgeted Input Budgeted Input Qty. Qty. Actual Input Allowed for Allowed for Actual Costs Qty. Actual Output Actual Output Incurred × Budgeted Rate × Budgeted Rate × Budgeted Rate Case A: Variable Manufacturing (1,325 × $15) (1,250* × $15) (1,250* × $15) Overhead $15,000* $19,875 $18,750* $18,750* $1,125 U $4,875* F Rate variance Efficiency variance Never a variance Fixed a Manufacturing (Lump sum) (Lump sum) (1,250 × $20 ) Overhead $26,500* $25,000* $25,000* $25,000* $1,500 U $0 Rate variance Never a variance Production-volume variance Total budgeted manufacturing overhead = $18,750 + $25,000 = $43,750 Case B: Variable (1,625 $8.50*) (1,625* $8.50*) (1,625* $8.50*) Manufacturing Overhead $13,813 $13,813 $13,813 $13,813 $0* $0 Rate variance Never a variance Efficiency variance Fixed (Lump sum) (Lump sum) (1,625* $10) Manufacturing b b Overhead $16,750 $17,500 $17,500 $16,250 $750 F* $1,250 U* Rate variance Never a variance Production-volume variance Denominator level = Budgeted FMOH costs ÷ Budgeted FMOH rate = $17,500 ÷ $10 = 1,750 hours
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8‐32 (cont’d) Actual Costs Incurred Case C: Variable Manufacturing Overhead Fixed Manufacturing Overhead
$15,500
Flexible Budget: Budgeted Input Allocated: Qty. Budgeted Input Allowed for Qty. Actual Input Actual Output Allowed for Qty. × Budgeted Actual Output × Budgeted Rate Rate × Budgeted Rate (2,925 $5.00*) $14,625
$875 U* Rate variance
$30,000*
(2,875 $5.00*) (2,875 $5.00*) c
$14,375
$250 U* Efficiency variance
$27,500*
c
$14,375
Never a variance
$27,500*
d
$28,750
$2,500 U $1,250 F* Rate variance Never a variance Production-volume variance Total budgeted manufacturing overhead = $14,375 + $27,500 = $41,875
Budgeted FMOH rate = Budgeted FMOH costs ÷ Denominator level = $25,000 ÷ 1,250 = $20 Budgeted b Budgeted Budgeted = + fixed manuf. overhead variable manuf. overhead total overhead $31,313* = BFMOH + (1,625 $8.50) BFMOH = $17,500 a
c
Budgeted hours allowed for actual output achieved must be derived from the output level variance before this figure can be derived, or, since the fixed manufacturing overhead rate is $27,500 ÷ 2,750 = $10, and the allocated amount is $28,750, the budgeted hours allowed for the actual output achieved must be 2,875 ($28,750 $10).
d
2,875 ($27,500* ÷ 2,750*) = $28,750
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8‐33 (1525 min.) Flexible budgets, four‐variance analysis. 1.
Budgeted hours allowed Budgeted DLH = per unit of output Budgeted actual output 3,600,000 = = 5 hours per unit 720,000 Budgeted DLH allowed for May output = 66,000 units 5 hrs./unit = 330,000 hrs. Allocated total MOH = 330,000 Total MOH rate per hour = 330,000 $1.20 = $396,000
2, 3, 4, 5. See Solution Exhibit 8‐33 Variable manuf. overhead rate per DLH = $0.25 + $0.34 = $0.59 Fixed manuf. overhead rate per DLH = $0.18 + $0.15 + $0.28 = $0.61 Fixed manuf. overhead budget for May = ($648,000 + $540,000 + $1,008,000) ÷ 12 = $2,196,000 ÷ 12 = $183,000 or, Fixed manuf. overhead budget for May = $54,000 + $45,000 + $84,000 = $183,000 Using the format of Exhibit 8‐5 for variable manufacturing overhead and then fixed manufacturing overhead: Actual variable manuf. overhead: $75,000 + $111,000 = $186,000 Actual fixed manuf. overhead: $51,000 + $54,000 + $84,000 = $189,000 An overview of the four‐variance analysis using the block format of the text is: Production‐ Four‐Variance Rate Efficiency Volume Analysis Variance Variance Variance Variable Manufacturing $150 U $8,850 F Never a Overhead variance Fixed Manufacturing $6,000 U Never a $18,300 F Overhead variance 8–384
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Chapter 8
Solution Exhibit 8‐33 Variable Manufacturing Overhead Allocated: Flexible Budget: Budgeted Input Budgeted Input Qty. Qty. Allowed for Allowed for Actual Costs Actual Input Qty. Actual Output Actual Output Incurred × Budgeted Rate × Budgeted Rate × Budgeted Rate (1) (2) (3) (4) (315,000 $0.59) (330,000 $0.59) (330,000 $0.59) $186,000 $185,850 $194,700 $194,700 $150 U $8,850 F Never a variance Rate variance Efficiency variance Fixed Manufacturing Overhead Flexible Budget: Same Budgeted Same Budgeted Allocated: Lump Sum Lump Sum Budgeted Input (as in Static Budget) (as in Static Budget) Allowed for Actual Costs Regardless of Regardless of Actual Output Output Level Output Level × Budgeted Rate Incurred (2) (3) (4) (1) (330,000 $0.61) $189,000 $183,000 $183,000 $201,300 $6,000 U $18,300 F Rate variance Never a variance Production-volume variance Alternate computation of the production volume variance: Budgeted hours Budgeted Denominator fixed = allowed for actual – output achieved hours overhead rate 3, 600, 000 = 330,000 × $ 0.61 12 = (330,000 – 300,000) × $0.61 = $18,300 F
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8‐34 (20 min.) Variable overhead variance. 1.
Direct Manufacturing Labour variance analysis for Sarah Beth’s Art Supply Company Flexible Budget: Budgeted Input Qty. Allowed for Actual Actual Costs Actual Input Qty. Output Budgeted Rate Incurred Budgeted Price 13,000 × 0.75 × 20.2 13,000 × 0.75 × 20 13,000 × 0.5 × 20.0 $196,950 $195,000 $130,000 $1,950 U $65,000 U Price variance Efficiency variance
2.
Variable Manufacturing Overhead variance analysis for Sarah Beth’s Art Supply Company Flexible Budget: Budgeted Input Qty. Allowed for Actual Output Actual Costs Actual Input Qty. Budgeted Rate Incurred Budgeted Rate 13,000 × 0.75 × 9.75 13,000 × 0.75 × 10.0 13,000 × 0.5 × 10.0 $95,062.5 $97,500 $65,000 $2,437.5 F $32,500 U Rate variance Efficiency variance
3.
4.
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The favourable rate variance for variable manufacturing overhead suggests that less costly items were used, which could have a negative impact on labour efficiency. But note that the workers were paid a higher rate than budgeted, which, if it indicates the hiring of more qualified employees, should lead to favourable labour efficiency variances. Moreover, the price variance and the rate variance are both very small, approximately 1% and 2.5% respectively, while the efficiency variances are very large, each equaling 50% of expected costs. It is clear therefore that the efficiency variances are related to factors other than the cost of the labour or overhead. If the variable overhead consisted only of costs that were related to direct manufacturing labour, then Sarah is correct ‐ both the labour efficiency variance and the variable overhead efficiency variance would reflect real cost overruns due to the inefficient use of labour. However, a portion of variable overhead may be a function of factors other than direct labour (e.g., the costs of energy or the usage of indirect materials). In this case, allocating variable overhead using direct labour as the only base will inflate the effect of inefficient labour usage on the variable overhead efficiency variance. The real effect on firm profitability will be lower, and will likely be captured in a favourable rate variance for variable overhead.
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Chapter 8
8‐35 (30 min.) Causes of indirect variances
1. 2.
Variable Overhead Variance Analysis for Heather’s Horse Spa for August 2013 Actual Variable Overhead $7,500
Actual input × Budgeted rate (950 × 38 × $0.2) $7,220
$280 U Rate variance
Budgeted input allowed for Actual output × Budgeted rate (900 × 38 × $0.2) $6,840
$380 U Efficiency variance
Fixed Overhead Variance Analysis for Heather’s Horse Spa for August 2013 Actual Static Budget Fixed Overhead Fixed Overhead (900 x 40 x $1.5) $50,000 $54,000
$4,000 F Rate variance
Budgeted input allowed for Actual output × Budgeted Rate (900 × 38 × $1.5) 51,300
$2,700 U Production‐volume variance
3. The variable overhead rate variance arises from the fact that the cost of horse feed, shampoo, ribbons and other supplies was higher, per weighted average horse‐guest week, than expected ($7,500/(950×38)lbs = $0.208 per lb > $0.2 per lb). Unlike the material and labour price variances, which only reflect the prices paid, the rate variance could have both a cost and usage component. HHS would have a negative rate variance if they paid more for feed than expected or if the horses ate more feed than expected. 4. The $380 unfavourable variable overhead efficiency variance reflects the fact that the average weight of a horse was higher than expected. HHS expected horses to weigh an average of 900 lbs but during August, the horses weighed an average of 950 lbs. Larger horses are expected to consume more variable overhead, such as horse feed and shampoo, hence the unfavourable nature of the variance. 5. Fixed overhead is fixed with respect to horse weight. This does not mean that it can be forecasted with 100% accuracy. For example, salaries or actual costs for advertising may have been higher than expected, leading to the $4,000 unfavourable variance.
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8‐35 (cont’d) 6. The production‐volume variance of $2,700 exists because the fixed overhead rate was based on the forecasted number of horse guest‐weeks, 40, while the fixed overhead was applied using the actual number of horse guest‐weeks, 38. The overestimation of the number of horse guests in August would lead to an under‐ absorption of fixed overhead, resulting in the unfavourable production‐volume variance. If the estimate was too far off from the actual number of horses, HHS might potentially not charge enough to cover their costs.
8‐36 (20 min.) Activity‐based costing, batch‐level variance analysis 1.
Static budget number of crates = Budgeted pairs shipped / Budgeted pairs per crate
= 240,000/12 = 20,000 crates
2.
Flexible budget number of crates = Actual pairs shipped / Budgeted pairs per crate
= 180,000/12 = 15,000 crates
3.
Actual number of crates shipped = Actual pairs shipped / Actual pairs per box
= 180,000/10 = 18,000 crates
4.
Static budget number of hours = Static budget number of crates × budgeted hours per box
5.
= 20,000 × 1.2 = 24,000 hours
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Fixed overhead rate = Static budget fixed overhead / static budget number of hours
= 60,000/24,000 = $2.50 per hour Variable Overhead Variance Analysis for Rica’s Fleet Feet Inc. for 2013
Actual Variable Overhead (18,000 × 1.1 × $21) $415,800
Actual hours Budgeted hours allowed for ×Budgeted rate Actual output × Budgeted rate (18,000 × 1.1 × $20) (15,000 × 1.2 × $20) $396,000 $360,000
$19,800 U Rate variance
$36,000 U Efficiency variance
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Chapter 8
8‐36 (cont’d)
6.
Fixed Overhead Variance Analysis for Rica’s Fleet Feet Inc. for 2013 Actual Static Budget Fixed Overhead Fixed Overhead $55,000 $60,000
$5,000 F Rate variance
Budgeted hours allowed for Actual output × Budgeted Rate (15,000 × 1.2 ×$2.5) $45,000
$15,000 U Production volume variance
8‐37 (30 min.) Activity‐based costing, batch‐level variance analysis 1. Static budget number of setups = Budgeted books produced/ Budgeted books per setup = 200,000 ÷ 500 = 400 setups 2. Flexible budget number of setups = Actual books produced / Budgeted books per setup = 216,000 ÷ 500 = 432 setups 3. Actual number of setups = Actual books produced / Actual books per setup = 216,000/480 = 450 setups 4. Static budget number of hours = Static budget # of setups × Budgeted hours per setup = 400 × 6 = 2,400 hours Fixed overhead rate = Static budget fixed overhead / Static budget number of hours = 72,000/2,400 = $30 per hour 5. Budgeted variable overhead cost of a setup = Budgeted variable cost per setup‐hour × Budgeted number of setup‐hours = $100 × 6 = $600.
Budgeted total overhead cost of a setup
= Budgeted variable overhead cost + Fixed overhead rate × Budgeted number of setup-hours
= $600 + ($30 × 6) = $780. So, the charge of $700 covers the budgeted incremental (i.e., variable overhead) cost of a setup, but not the budgeted full cost.
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8‐37 (cont’d) 6.
Variable Setup Overhead Variance Analysis for Jo Nathan Publishing Company for 2013
Actual Variable Overhead (450 × 6.5 × $90) $263,250
7. 8.
$33,300U Efficiency variance
Actual Static Budget Fixed Overhead Fixed Overhead $79,000 $72,000
$7,000 U Rate variance
Standard hours × Budgeted Rate (432 × 6.0 × $30) $77,760
$5,760 F Production‐volume variance
Rejecting an order may have implications for future orders (i.e., professors would be reluctant to order books from this publisher again). Jo Nathan should consider factors such as prior history with the customer and potential future sales. If a book is relatively new, Jo Nathan might consider running a full batch and holding the extra books in case of a second special order or just hold the extra books until next semester. If the special order comes at heavy volume times, Jo should look at the opportunity cost of filling it, i.e., accepting the order may interfere with or delay the printing of other books.
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$29,250F Rate variance
Standard hours × Standard rate (432 × 6.0 × $100) $259,200
Fixed Setup Overhead Variance Analysis for Jo Nathan Publishing Company for 2013
Actual hours × Budgeted rate (450 × 6.5 × $100) $292,500
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Chapter 8
8‐38 (35 min.) Production‐volume variance analysis and sales‐volume variance. 1. and 2.
Fixed Overhead Variance Analysis for Dawn Floral Creations, Inc. for February Actual Fixed Static Budget Standard Hours Overhead Fixed Overhead × Budgeted Rate (600 × 1.5 × $6*) $9,200 $9,000 $5,400 $200 U $3,600 U Rate variance Production‐volume variance * fixed overhead rate = (budgeted fixed overhead)/(budgeted DL hours at capacity) = $9,000/(1000 x 1.5 hours) = $9,000/1,500 hours = $6/hour 3. An unfavourable production‐volume variance measures the cost of unused capacity. Production at capacity would result in a production‐volume variance of 0 since the fixed overhead rate is based upon expected hours at capacity production. However, the existence of an unfavourable volume variance does not necessarily imply that management is doing a poor job or incurring unnecessary costs. Using the suggestions in the problem, two reasons can be identified. a. For most products, demand varies from month to month while commitment to the factors that determine capacity, e.g. size of workshop or supervisory staff, tends to remain relatively constant. If Dawn wants to meet demand in high demand months, it will have excess capacity in low demand months. In addition, forecasts of future demand contain uncertainty due to unknown future factors. Having some excess capacity would allow Dawn to produce enough to cover peak demand as well as slack to deal with unexpected demand surges in non‐peak months. b. Basic economics provides a demand curve that shows a tradeoff between price charged and quantity demanded. Potentially, Dawn could have a lower net revenue if they produce at capacity and sell at a lower price than if they sell at a higher price at some level below capacity. In addition, the unfavourable production‐volume variance may not represent a feasible cost savings associated with lower capacity. Even if Dawn could shift to lower fixed costs by lowering capacity, the fixed cost may behave as a step function. If so, fixed costs would decrease in fixed amounts associated with a range of production capacity, not a specific production volume. The production‐ volume variance would only accurately identify potential cost savings if the fixed cost function is continuous, not discrete.
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8‐38 (cont’d) 4.
The static‐budget operating income for February is: Revenue $55 × 1,000 Variable costs $25 × 1,000 Fixed overhead costs Static‐budget operating income
$55,000 25,000 9,000 $ 21,000
The flexible‐budget operating income for February is: Revenue $55 × 600 Variable costs $25 × 600 Fixed overhead costs Flexible‐budget operating income
$33,000 15,000 9,000 $ 9,000
The sales‐volume variance represents the difference between the static‐budget operating income and the flexible‐budget operating income:
Static‐budget operating income Flexible‐budget operating income Sales‐volume variance
$21,000 9,000 $12,000 U
Equivalently, the sales‐volume variance captures the fact that when Dawn sells 600 units instead of the budgeted 1,000, only the revenue and the variable costs are affected. Fixed costs remain unchanged. Therefore, the shortfall in profit is equal to the budgeted contribution margin per unit times the shortfall in output relative to budget.
Budgeted Difference in quantity of Sales‐volume Budgeted = – variable cost × units sold relative to the variance selling price per unit static budget = ($55 – $25) × 400 = $30 × 400 = $12,000 U In contrast, we computed in requirement 2 that the production‐volume variance was $3,600U. This captures only the portion of the budgeted fixed overhead expected to be unabsorbed because of the 400‐unit shortfall. To compare it to the sales‐volume variance, consider the following:
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8‐38 (cont’d)
Budgeted selling price Budgeted variable cost per unit Budgeted fixed cost per unit ($9,000 ÷ 1,000) Budgeted cost per unit Budgeted profit per unit
$55 $25 9
34 $ 21
Operating income based on budgeted profit per unit $21 per unit × 600 units
$12,600
The $3,600 U production‐volume variance explains the difference between operating income based on the budgeted profit per unit and the flexible‐budget operating income:
Operating income based on budgeted profit per unit $12,600 Production‐volume variance 3,600 U Flexible‐budget operating income $ 9,000 Since the sales‐volume variance represents the difference between the static‐ and flexible‐budget operating incomes, the difference between the sales‐volume and production‐volume variances, which is referred to as the operating‐income volume variance is:
Operating‐income volume variance = Sales‐volume variance – Production‐volume variance = Static‐budget operating income ‐ Operating income based on budgeted profit per unit = $21,000 U – $12,600 U = $8,400 U. The operating‐income volume variance explains the difference between the static‐ budget operating income and the budgeted operating income for the units actually sold. The static‐budget operating income is $21,000 and the budgeted operating income for 600 units would have been $12,600 ($21 operating income per unit 600 units). The difference, $8,400 U, is the operating‐income volume variance, i.e., the 400 unit drop in actual volume relative to budgeted volume would have caused an expected drop of $8,400 in operating income, at the budgeted operating income of $21 per unit. The operating‐income volume variance assumes that $50,000 in fixed cost ($9 per unit 400 units) would be saved if production and sales volumes decreased by 400 units.
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8‐39 (3040 min.) Comprehensive review of Chapters 7 and 8, working backward from given variances. 1. a. b. c. d. e. f. 2.
Solution Exhibit 8‐39 outlines the Chapter 7 and 8 framework underlying this solution. Pounds of direct materials purchased = $176,000 ÷ $1.10 = 160,000 pounds Pounds of excess direct materials used = $69,000 ÷ $11.50 = 6,000 pounds Variable manufacturing overhead rate variance = $10,350 – $18,000 = $7,650 F Standard direct manufacturing labour rate = $800,000 ÷ 40,000 hours = $20 per hour Actual direct manufacturing labour rate = $20 + $0.50 = $20.50 Actual direct manufacturing labour‐hours = $522,750 ÷ $20.50 = 25,500 hours Standard variable manufacturing overhead rate = $480,000 ÷ 40,000 = $12 per DML‐hour Variable manuf. overhead efficiency variance of $18,000 ÷ $12 = 1,500 excess hours Actual hours – Excess hours = Standard hours allowed for units produced 25,500 – 1,500 = 24,000 hours Budgeted fixed manufacturing overhead rate = $640,000 ÷ 40,000 hours = $16 per DML‐hour Fixed manufacturing overhead allocated = $16 24,000 hours = $384,000 Production‐volume variance = $640,000 – $384,000 = $256,000 U The control of variable manufacturing overhead requires the identification of the cost drivers for such items as energy, supplies, and repairs. Control often entails monitoring nonfinancial measures that affect each cost item, one by one. Examples are kilowatts used, quantities of lubricants used, and repair parts and hours used. The most convincing way to discover why overhead performance did not agree with a budget is to investigate possible causes, line item by line item. Individual fixed overhead items are not usually affected very much by day‐to‐day control. Instead, they are controlled periodically through planning decisions and budgeting procedures that may sometimes have planning horizons covering six months or a year (for example, management salaries) and sometimes covering many years (for example, long‐term leases and depreciation on plant and equipment).
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Chapter 8
Solution Exhibit 8‐39 Flexible Budget: Actual Costs Budgeted Input Incurred Qty. (Actual Input Actual Input Qty. Allowed for Qty. Budgeted Rate Actual Output Actual Rate) Purchases Usage Budgeted Rate Direct 160,000 $10.40 160,000 $11.50 96,000 $11.50 3 30,000 $11.50 Materials $1,664,000 $1,840,000 $1,104,000 $1,035,000 $69,000 U $176,000 F Efficiency variance Price variance 0.85 30,000 $20.50 Direct 0.85 30,000 $20 0.80 30,000 $20 Manuf. $522,750 $510,000 $480,000 Labour $12,750 U $30,000 U Price variance Efficiency variance $42,750 U Flexible-budget variance Flexible Budget: Allocated: Budgeted Input Budgeted Input Actual Costs Qty. Qty. Incurred Actual Input Allowed for Allowed for Actual Input Qty. Qty. Actual Output Actual Output Actual Rate Budgeted Rate Budgeted Rate Budgeted Rate Variable 0.85 30,000 0.85 30,000 0.80 30,000 $12 0.80 30,000 $12 MOH $11.70 $12 $288,000 $288,000 $298,350 $306,000 $7,650 F $18,000 U Rate variance Efficiency Never a variance $10,350 U Never a variance Flexible-budget variance
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8‐39 (cont’d)
Fixed MOH
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Actual Costs Incurred (1)
Same Budgeted Lump Sum (as in Static Budget) Regardless of Output Level (2)
$597,460
$640,000
$42,540 F Rate variance volume
Flexible Budget: Same Budgeted Lump Sum (as in Static Budget) Regardless of Output Level (3)
Allocated: Budgeted Input Qty. Allowed for Actual Output × Budgeted Rate (4)
0.80 × 50,000 × $16 0.80 x 30,000 × $16 $640,000 $384,000 $256,000 U
Never a variance
$42,540 F Flexible-budget variance
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$256,000 U Production volume variance
Chapter 8
8‐40 (3050 min.) Review of Chapters 7 and 8, three‐variance analysis. 1.
Total standard production costs are based on 7,800 units of output. Direct materials, 7,800 $15.00 7,800 3 lbs. $5.00 (or 23,400 lbs. $5.00) $ 117,000 Direct manufacturing labour, 7,800 $75.00 7,800 5 hrs. $15.00 (or 39,000 hrs. $15.00) 585,000 Manufacturing overhead: Variable, 7,800 $30.00 (or 39,000 hrs. $6.00) 234,000 Fixed, 7,800 $40.00 (or 39,000 hrs. $8.00) 312,000 Total $1,248,000 The following is for later use: Fixed manufacturing overhead, a lump‐sum budget $320,000* Budgeted fixed manufacturing overhead *Fixed manufacturing overhead rate = Denominator level
2.
$8.00 =
Budget 40,000 hours
Budget = 40,000 hours $8.00 = $320000
Solution Exhibit 8‐40 presents a columnar presentation of the variances. An overview of the 3‐variance analysis using the block format of the text is:
Three‐Variance Analysis Total Manufacturing Overhead
Rate Variance $39,400 U
Efficiency Variance $6,600 U
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Production Volume Variance $8,000 U
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Solution Exhibit 8‐40 Flexible Budget: Budgeted Input Qty. Allowed for Actual Output × Budgeted Price (23,400 $5.00) $117,000
Actual Costs Incurred: Actual Input Qty. Budgeted Price Actual Input Qty. × Actual Rate Purchases Usage Direct (25,000 $5.20) (25,000 $5.00) (23,100 $5.00) Materials $130,000 $125,000 $115,500 $5,000 U $1,500 F a. Price variance b. Efficiency variance Direct (40,100 $15.00) (39,000 $15.00) Manuf. (40,100 $14.60) Labour $585,460 $601,500 $585,000 $16,040 F $16,500 U d. Efficiency variance c. Price variance Allocated: Flexible Budget: (Budgeted Input Budgeted Input Qty. Qty. Actual Allowed for Allowed for Costs Actual Input Qty. Actual Output Actual Output Incurred Budgeted Rate Budgeted Rate Budgeted Rate) Variable Manuf. (40,100 $6.00) (39,000 $6.00) (39,000 $6.00) Overhead (not $240,600 $234,000 $234,000 given) $6,600 U Efficiency variance Never a variance Fixed Manuf. (39,000 $8.00) Overhead (not given) $320,000 $320,000 $312,000 * $8,000 U Never a variance Prodn. volume variance
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Chapter 8
8‐40 (cont’d) Total Manuf. Overhead
(given) $600,000
($240,600 + $320,000) $560,600
($234,000 + $320,000) $554,000
($234,000 + $312,000) $546,000
$39,400 U $6,600 U $8,000 U e. Rate variance f. Efficiency variance g. Prodn. volume variance *Denominator level in hours 40,000 Production volume in standard hours allowed 39,000 Production‐volume variance 1,000 hours × $8.00 = $8,000 U 8‐41 (20 min.) Nonfinancial and non‐manufacturing variances 1. Variance Analysis of Inspection Hours for Daisy Canine Products for May
2.
Actual Hours For Inspections 210 hours
Actual Pounds Standard Pounds Inspected Inspected/Budgeted for Actual Output /Budgeted Pounds per hour Pounds per hour 200,000lbs/1,000 lbs per hour (2,250,000 x .1)/1,000 lbs per hour 200 hours 225 hours
10 hours U 25 hours F Efficiency Variance Quantity Variance
Variance Analysis of Pounds Failing Inspection for Daisy Canine Products for May Actual Pounds Failing Inspections 3,500 lbs
Actual pounds Standard Pounds Inspected Inspected × Budgete for Actual Output × Budgeted Inspection Failure Rate Inspection Failure Rate (200,000lbs x .02) (2,250,000 x .1 x .02) 4,000 lbs 4,500 lbs
500 lbs F Efficiency Variance
500 lbs F Quantity Variance
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8‐42 (20 min.) Nonfinancial performance measures 1.
2. 3.
The cost of the ball bearings would be indirect materials if it is either not possible to trace the costs to individual products, or if the cost is so small relative to other costs that it is impractical to do so. Since Department B makes a fairly constant number of finished products (400 units) each day, it would be easy to trace the cost of bearings to the wheels completed daily. However, the fact that Rollie measures ball bearings by weight and discards leftover bearings at the end of each day suggests that they are a relatively inexpensive item and not worth the effort to restock or track in inventory. As such, it could be argued that ball bearings should be classified as overhead (e.g., indirect materials). Nonfinancial performance measures for Department B might include: Number or proportion of wheels sent back for rework and/or amount or proportion of time spent on rework; Number of wheels thrown away, ratio of wheels thrown away to wheels reworked, and/or ratio of bad to good wheels; Amount of down time for broken machines during the day; Weight of ball bearings discarded, or ratio of weights used and discarded. If the number of wheels thrown away is significant relative to the number of reworked wheels, then it is not efficient to rework them and so Rollie should re‐ examine the rework process or even just throw away all the bad wheels without rework. If the amount of rework is significant then the original process is not turning out quality goods in a timely manner. Rollie might slow down the process in Department B so it takes a little longer to make each good wheel, but the number of good wheels will be higher and may even save time overall if rework time drops considerably. They might also need to service the machines more often than just after the total daily production run, in which case they will trade off intentional down time for more efficient processing. If the amount of unintentional down time is significant they might bring in the mechanics during the day to fix a machine that goes down during a production run. Finally, Rollie might consider determining a better measure of ball bearings to requisition each day so that fewer are discarded, and might also keep any leftover ball bearings for use the next day.
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Chapter 8
8‐43 (45 min.) Overhead variances, governance. 1.
a.
Total budgeted overhead Budgeted variable overhead ($10 budgeted rate per machine‐hour × 2,500,000 budgeted machine‐hours) Budgeted fixed overhead
$31,250,000
25,000,000 $ 6,250,000
b. Budgeted cost per machine‐hour $6,250,000 budgeted amount = $2.50 per machine-hour Budgeted fixed OH rate 2,500,000 budgeted machine-hours c. Fixed overhead rate variance = Actual costs incurred – Budgeted amount. Because fixed overhead rate variance is unfavourable, the amount of actual costs is higher than the budgeted amount. Actual cost = $6,250,000 + $1,500,000 = $7,750,000 d. Production‐volume variance = Fixed overhead allocated using budgeted Budgeted fixed overhead – input allowed for actual output units produced = $6,250,000 – ($2.50 per machine‐hour × 2 machine‐hours per unit* × 1,245,000 units) = $6,250,000 – $6,225,000 = $25,000 U * Budgeted variable overhead per unit = $20 Budgeted variable overhead rate = $10 per machine‐hour Therefore, budgeted machine hours allowed per unit = $20/$10 = 2 machine‐hours 2. Variable overhead rate variance: Actual quantity Actual variable Budgeted variable of variable overhead overhead cost – overhead cost × cost-allocation base per unit of cost per unit of used for actual output allocation base cost-allocation base
$25,200,000 budget amount $10 per machine-hour 2, 400, 000 machine-hours 2,400,000 actual machine-hours = ($10.50 – $10) × 2,400,000 = $1,200,000 U
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8‐43 (cont’d) Variable overhead efficiency variance: Actual units of Budgeted units of Budgeted variable overhead variable overhead variable cost‐allocation – cost‐allocation base × overhead base used for allowed for rate actual output actual output = (2,400,000 – (2 × 1,245,000)) × $10 = (2,400,000 – 2,490,000) × $10 = $900,000 F 3. By manipulating, Remich has created a sizable unfavourable fixed overhead rate variance or, at least, has increased its magnitude. Jack Remich’s action is clearly unethical. Variances draw attention to the areas that need management attention. If the top management relies on Remich, due to his expertise, to interpret and explain the reasons for the unfavourable variance, it is likely that his report will be biased and misleading to the top management. The top management may erroneously conclude that Monroe is not able to manage his fixed overhead costs effectively. Another probable adverse outcome of Remich’s actions will be that Monroe will have even less confidence in the usefulness of accounting reports. This, of course, defeats the purpose of preparing the reports. In summary, Remich’s unethical actions will waste top management’s time and may lead to wrong decisions.
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8‐44
ABC overhead variances.
1. a. Units of SFA produced and sold b. Batch size c. Number of batches (a ÷ b) d. Testing‐hours per batch
Static‐Budget Amounts 21,000 500 42 5.5
Actual Amounts 22,000 550 40 5.4
e. Total testing‐hours (c × d)
231
216
f. Variable overhead cost per testing‐hour
$48
$50.40
$11,088
$10,886
g. Variable testing overhead costs (e × f)
$32,650 $32,659 h. Total fixed testing overhead costs i. Fixed overhead cost per testing hour (h ÷ e) $141 $151 The flexible budget is based on the budgeted number of testing‐hours for the actual output achieved, 22,000 units ÷ 500 units per batch = 44 batches. Computation of variable testing overhead cost variances follows: Allocated: (Budgeted Input Allowed for Actual Costs Actual Input Actual Output × Budgeted Rate × Budgeted Rate)
Incurred
(40 × 5.4 × $50.40)
(40 × 5.4 × $48)
(44 × 5.5 × $48)
$10,886
$10,368
$11,616
$518 U $1,248 F Spending variance Efficiency variance The unfavourable spending variance is due to the actual variable overhead cost per testing‐hour increasing from the budgeted $48 per hour to the actual rate of $50.40 per hour. The favourable efficiency variance is due to the actual output of 22,000 units (1) requiring fewer batches, 40, than the budgeted amount of 42 and (2) each batch taking less time, 5.4 hours, than the budgeted time of 5.5 hours.
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8‐44 (cont’d) 2.
Computation of the fixed testing overhead cost variances follows: Same Budgeted Allocated Lump Sum (Budgeted Input (as in Static Budget) Allowed for Actual Costs Regardless of Actual Output
Incurred
Output Level
× Budgeted Rate)
(44 × 5.5 × $141)
$32,659 $32,650 $34,122 $9 U $1,472 F Spending variance Production‐volume variance The fixed testing overhead cost spending variance is $9 U because the amount of actual costs was slightly higher than the budgeted amount of $32,650. The production‐volume variance is $1,472 F because the actual number of SFA produced and sold required less costs than budgeted.
8‐45 1.
8–404
ABC overhead variances. The flexible budget is flexed on the number of technical‐support hours, which has the budgeted relationship with output units of one hour of technical support for every 5,000 minutes of airtime sold (or every minute of airtime sold has a budgeted 0.0002 minutes of technical service). Key data items for the month ended August 31, 2010, are: Flexible Static Actual Budget Budget Results Amount Amount 1. Output units (minutes) 7,350,000 7,350,000 6,850,000 2. Technical support hours 1,500 1,470 1,370** 3. Technical support hours per minute 0.000204 0.0002 0.0002 4. Variable technical service activity area costs $37,800* $42,336 $39,456* 5. Variable technical service activity area $28.80 $28.80a costs per technical service hour (4/2) $25.20a 6. Variable technical service activity area costs per minute (4/1) $0.00514 $0.00576 $0.00576 7. Fixed technical service activity area costs $81,000 $83,844 $83,844 8. Fixed technical service activity area costs per technical support hour (7/2) $54.00 $57.04 $61.20 9. Fixed technical service activity area costs per minute (7/1) $0.0110 $0.0114 $0.0122
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Chapter 8
8‐45 (cont’d) Variable technical service activity area costs per technical support hour is calculated by dividing the total variable technical service activity area costs by the number of technical support hours. Actual: $37,800/1,500 = $25.20 Budgeted: $39,456/1,370 = $28.80 a
*Given **The budgeted denominator of 1,370 is calculated as budgeted airtime sold (6,850,000) divided by 5,000.
2.
Allocated fixed technical service activity area overhead is calculated by multiplying the budgeted input allowed for actual output achieved (given as 1,470 technical service hours) by the budgeted rate for fixed overhead. The budgeted rate for fixed overhead is calculated by dividing the budgeted amount for fixed technical service activity area costs (given as $83,844) by the budgeted number of technical service hours (1,370): $83,844/1,370 = $61.20 Allocated fixed technical service activity area overhead is therefore: 1,470 × $61.20 = $89,964
3.
Variable overhead analysis: Actual Costs Actual Inputs
× Budgeted Rate × Budgeted Rate × Budgeted Rate
Incurred
Flexible Budget: Allocated: Budgeted Input Budgeted Input Allowed for Allowed for Actual Actual Output Output Achieved
(1)
(2)
(3)
(4)
(1,500 × $25.20)
(1,500 × $28.80)
(1,470 × $28.80)
(1,470 × $28.80)
$37,800
$43,200
$42,336
$42,336
$5,400 F
$864 U
Spending variance
Efficiency variance
Sales‐volume variance (Never a variance)
$4,536 F Flexible‐budget variance
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8‐45 (cont’d) The favourable spending variance of $5,400 can be attributed to the lower variable costs incurred in the technical service activity area ($25.20 versus $28.80). The unfavourable efficiency variance ($864) is due to the larger number of technical service hours used compared with the number of hours that would have been allowed per plan for the actual number of minutes sold. Since the favourable spending variance is greater than the unfavourable efficiency variance, the flexible‐budget variance, in the amount of $4,536, is favourable. 4.
Fixed overhead analysis: Flexible Budget: Same Lump Sum Same Lump Sum Allocated: (as in Static Budget) (as in Static Budget) Budgeted Input Regardless of Regardless of Allowed for Actual Costs Budgeted Output Budgeted Output Actual Output
Incurred
Level
(1) $81,000
(2) $83,844
$2,844 F Spending variance
× Budgeted Rate
Level (3) $83,844
(4) $89,964*
$6,120 F Efficiency variance Production‐volume variance (Never a variance)
$2,844 F
Flexible‐budget variance
$8,964 F
Flexible‐budget variance
$6,120 F
Production‐volume variance
*1,470 × $61.20 CellOne management overallocated fixed overhead by $8,964.
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Chapter 8
8‐46 1.
Integrate and reconcile all overhead variances.
Budgeted number of machine‐hours planned can be calculated by multiplying the number of units planned (budgeted) by the number of machine‐hours allocated per unit: 17,760 × 2.00 = 35,520 machine‐hours
2.
3.
4.
5.
6.
7.
Budgeted fixed MOH costs per machine‐hour can be computed by dividing the flexible budget amount for fixed MOH (which is the same as the static budget) by the number of machine‐hours planned (calculated in (1.)): $8,354,304 ÷ 35,520 = $235.20 per machine‐hour Budgeted variable MOH costs per machine‐hour are calculated as budgeted variable MOH costs divided by the budgeted number of machine‐hours planned: $1,704,960 ÷ 35,520 = $48.00 per machine‐hour Budgeted number of machine‐hours allowed for actual output achieved can be calculated by dividing the flexible‐budget amount for variable MOH by budgeted variable MOH costs per machine‐hour: $1,843,200 ÷ $48.00 = 38,400 machine‐hours allowed The actual number of output units is the budgeted number of machine‐hours allowed for actual output achieved divided by the planned allocation rate of machine‐hours per unit: 38,400 ÷ 2.00 = 19,200 output units The actual number of machine‐hours used per panel is the actual number of machine hours used (given) divided by the actual number of units manufactured: 36,480 ÷ 19,200 = 1.9 machine‐hours used per panel The allocated amount for fixed MOH is the budgeted input allowed for actual output achieved (4.) multiplied by the budgeted fixed MOH costs per machine‐ hour (2): 38,400 × $235.20 = $9,031,680
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8‐47
Integrate and reconcile all overhead variances.
Key information underlying the computation of variances is: Flexible Actual Budget Results Amount 1. Output units (panels) 19,200 19,200 2. Machine‐hours 36,480 38,400 3. Machine‐hours per panel 1.90 2.00 4. Variable MOH costs $1,838,592 $1,843,200 5. Variable MOH costs per machine‐hour (4/2) $50.40 $48.00 6. Variable MOH costs per unit (4/1) $95.76 $96.00 7. Fixed MOH costs $8,404,992 $8,354,304 8. Fixed MOH costs per machine‐hour (7/2) $230.40 $217.56 9. Fixed MOH costs per unit (7/1) $437.76 $435.12 Solution Exhibit 8‐47 has the computation of the variances. SOLUTION EXHIBIT 8‐47 Variable MOH Actual Costs Actual Inputs
8–408
Incurred
Static Budget Amount 17,760 35,520 2.00 $1,704,960 $48.00 $96.00 $8,354,304 $235.20 $470.40
Allocated Flexible Budget: Budgeted Input (Budgeted Input Allowed for Allowed for Actual Actual Output Output
× Budgeted Rate × Budgeted Rate × Budgeted Rate)
(1)
(2)
(3)
(4)
(36,480 × $50.40)
(36,480 × $48)
(38,400 × $48)
(38,400 × $48)
$1,838,592 $1,751,040 $1,843,200 $87,552 U $92,160 F
$1,843,200
Spending variance Efficiency variance Sales‐volume variance (Never a variance)
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Chapter 8
8‐47 (cont’d)
Fixed MOH Flexible Budget: Same Lump Sum Same Lump Sum Allocated (as in Static Budget) (as in Static Budget) (Budgeted Input Regardless of Regardless of Allowed for Actual Costs Budgeted Output Budgeted Output Actual Output
Incurred
Level
Level
× Budgeted Rate)
(1)
(2)
(3)
(4)
(38,400 × $235.20)
$8,404,992 $8,354,304 $50,688 U
Spending variance
1.
$8,354,304 $9,031,680 $677,376 F
Efficiency variance Production‐volume variance (Never a variance)
Journal entries for variable MOH, year ended December 31, 2010: Variable MOH Control 1,838,592 Accounts Payable Control and Other Accounts 1,838,592 Work‐in‐Process Control 1,843,200 Variable MOH Allocated 1,843,200 Variable MOH Allocated 1,843,200 Variable MOH Spending Variance (U) 87,552 Variable MOH Control 1,838,592 Variable MOH Efficiency Variance (F) 92,160 Journal Entries for fixed MOH, year ended December 31, 2010: Fixed MOH Control 8,404,992 Wages Payable, Accumulated Amortization, etc. 8,404,992 Work‐in‐Process Control 9,031,680 Fixed MOH Allocated 9,031,680 Fixed MOH Allocated 9,031,680 Fixed MOH Spending Variance (U) 50,688 Fixed MOH Control 8,404,992 Fixed MOH Production‐Volume Variance (F) 677,376
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8‐47 (cont’d) 2.
Adjustment of COGS Cost of Goods Sold Variable MOH Efficiency Variance (F) Fixed MOH Production‐Volume Variance (F) Variable MOH Spending Variance (U) Fixed MOH Spending Variance (U) 1 677,376 + 92,160 – [87,552 + 50,688] = 631,296
92,160 677,376
631,2961
87,552 50,688
8‐48 (30 min.) 1.
Overhead analysis.
Variable overhead analysis. Allocated: (Budgeted Input Allowed for Actual Costs Actual Input Actual Output Incurred Budgeted Rate Budgeted Rate) (30,000 $360) (35,000 $360) $11,520,000 $10,800,000 $12,600,000 $720,000 U $1,800,000 F
Rate variance
Efficiency variance
2.
Bu d geted fixed overhead cost rate
=
Bu d geted total costs in fixed overhead cost pool Bu d geted total qu antity of m achine-hou rs
=
5, 940, 000 33, 000
= $180 per machine‐hour
8–410
Fixed overhead analysis: Same Budgeted Allocated: Lump Sum (Budgeted Input (as in Static Budget) Allowed for Actual Costs Regardless of Actual Output Incurred Output Level Budgeted Rate) ($180 35,000) $5,400,000 $5,940,000 $6,300,000 $540,000 F $360,000 F Rate variance
Prodn.‐volume variance
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Chapter 8
COLLABORATIVE LEARNING CASES
8‐49 (30 min.) Overhead variances, four‐variance analysis. Solution Exhibit 8‐49 shows the summary results: 1. Favourable VOH efficiency = (Budgeted hours allowed – Actual hours) $12 $2,400* = (1,800* – A) $12* $2,400 = $21,600 – $12A $12A = $19,200 A = 1,600 2. Budgeted total MOH = Budgeted fixed MOH + Budgeted variable MOH $27,000* = B.F. MOH + (1,800* $12*) Budgeted fixed MOH = $5,400 3. Answer (2) + $1,080, or: Fixed MOH overhead allocated = Budgeted fixed MOH + Favourable production‐volume variance = $5,400 + $1,080* = $6,480 4. Answer (3) ÷ 1,800 hours = Fixed MOH rate $6,480 ÷ 1,800* = $3.60 5.
Bu d geted Bu d geted Denom inator Favou rable prod u ction fixed = hou rs level MOH volu m e variance allow ed hou rs rate
$1,080* $1,080 –$5,400 D
= = = =
(1,800* – D) $3.6 $6,480 – $3.60D –$3.60D 1,500 hours
Alternatively,
Bu d geted Fixed MOH Rate
=
$3.60D =
Bud geted Fixed MOH Denom inator level $5, 400 D
D = 1,500 hours
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SOLUTION EXHIBIT 8‐49 Flexible Budget: Actual Costs (Budgeted Input Incurred Allowed for Actual (Actual Input Actual Input Output Achieved Actual Rate) Budgeted Rate Budgeted Rate) Variable Overhead (1,600 $13.50) (1,600 $12*) (1,800* $12*) $21,600 $19,200 $21,600 $2,400 U* $2,400 F*
Rate variance
Actual Costs Incurred Fixed Overhead $5,160
Same Lump Sum Regardless of Output Level
Same Lump Sum Regardless of Output Level
Allocated: (Budgeted Input Allowed for Actual Output Achieved Budgeted Rate)
$5,400
$5,400
($1,800* $3.60) $6,480
$240 F*
Rate variance
Efficiency variance
Efficiency variance Production‐volume variance (Never a variance)
*Given
8–412
$1,080 F*
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Chapter 8
8‐50 (20 min.) Standard setting, benchmarking, governance. 1.
2.
Padding of standard costs and standard amounts for billing operations can arise from: (a) Deliberately taking longer time to process the bills when standards are being set. (b) Deliberately not taking advantage of information technology in the standard‐ setting period and then exploiting that technology later on. (c) Creating problems in billing for which solutions have already been worked out and using those solutions only in the non‐standard‐setting period. (d) Not purchasing items in the most economic way during the standard‐setting period. Reasons for padding include: (a) Individual performance evaluation—individuals who wish to look “good” for bonuses, promotion, etc. purposes. (b) Department performance evaluation—departments wish to retain autonomy, which is more likely with favourable variances. (c) Defying authority and control systems—some individuals have an inherent opposition to “standards” and “controls.” Stone can operate at several levels: (a) Best practice observation—MEG’s report should be a catalyst to General’s examining what other hospitals in the survey are doing and then using this best practice internally. MEG may be hired to facilitate field visits to other more efficient hospitals. (b) Operations—make flowcharts of how billing occurs at General and eliminate all unnecessary steps. (c) Incentive systems—provide economic and other incentives to General employees to implement efficiency and effectiveness improvements. The emphasis here should be on accuracy and timeliness of billing as well as the cost of billing. (d) Corporate culture—Stone should emphasize that “padding” and the deliberate misrepresentation it entails are unacceptable. This could be done via in‐house programs on ethics and culture or by making “examples” of those found deliberately undermining a culture of honesty and teamwork for General.
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CHAPTER 9 INCOME EFFECT OF DENOMINATOR LEVEL ON INVENTORY VALUATION
SHORT‐ANSWER QUESTIONS
9‐1
No. Differences in operating income between variable costing and absorption costing are due to accounting for fixed manufacturing costs. Under variable costing only variable manufacturing costs are included as inventoriable costs. Under absorption costing both variable and fixed manufacturing costs are included as inventoriable costs. Fixed marketing and distribution costs are not accounted for differently under variable costing and absorption costing.
9‐2
The term direct costing is a misnomer for variable costing for two reasons: a. Variable costing does not include all direct costs as inventoriable costs. Only variable direct manufacturing costs are included. Any fixed direct manufacturing costs, and any direct nonmanufacturing costs (either variable or fixed), are excluded from inventoriable costs. b. Variable costing includes as inventoriable costs not only direct manufacturing costs but also some indirect costs (variable indirect manufacturing costs).
9‐3
No. The difference between absorption costing and variable costs is due to accounting for fixed manufacturing costs. As service or merchandising companies have no fixed manufacturing costs, these companies do not make choices between absorption costing and variable costing.
9‐4
The main issue between variable costing and absorption costing is the proper timing of the release of fixed manufacturing costs as costs of the period: a. at the time of incurrence, or b. at the time the finished units to which the fixed overhead relates are sold. Variable costing uses (a) and absorption costing uses (b).
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9‐5
No. A company that makes a variable‐cost/fixed‐cost distinction is not forced to use any specific costing method. The Stassen Company example in the text of Chapter 9 makes a variable‐cost/fixed‐cost distinction. As illustrated, it can use variable costing, absorption costing, or throughput costing. A company that does not make a variable‐cost/fixed‐cost distinction cannot use variable costing or throughput costing. However, it is not forced to adopt absorption costing. For internal reporting, it could, for example, classify all costs as costs of the period in which they are incurred.
9‐6
Variable costing does not view fixed costs as unimportant or irrelevant, but it maintains that the distinction between behaviours of different costs is crucial for certain decisions. The planning and management of fixed costs is critical, irrespective of what inventory costing method is used.
9‐7
Under absorption costing, heavy reductions of inventory during the accounting period might combine with low production and a large production volume variance. This combination could result in lower operating income even if the unit sales level rises.
9‐8
(a)
(b)
The factors that affect the breakeven point under variable costing are: 1. Fixed (manufacturing and operating) costs. 2. Contribution margin per unit. The factors that affect the breakeven point under absorption costing are: 1. Fixed (manufacturing and operating) costs. 2. Contribution margin per unit. 3. Production level in units in excess of breakeven sales in units. 4. Denominator level chosen to set the fixed manufacturing cost rate.
9‐9 Examples of dysfunctional decisions managers may make to increase reported operating income include: a. Plant managers may switch production to those orders that absorb the highest amount of manufacturing overhead, irrespective of the demand by customers. b. Plant managers may accept a particular order to increase production even though another plant in the same company is better suited to handle that order. c. Plant managers may defer maintenance beyond the current period to free up more time for production.
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9‐10 Approaches used to reduce the negative aspects associated with using absorption costing include: a. Change the accounting system: Adopt either variable or throughput costing, both of which reduce the incentives of managers to produce for inventory. Adopt an inventory holding charge for managers who tie up funds in inventory. b. Extend the time period used to evaluate performance. By evaluating performance over a longer time period (say, 3 to 5 years), the incentive to take short‐run actions that reduce long‐term income is lessened. c. Include nonfinancial as well as financial variables in the measures used to evaluate performance.
9‐11 The downward demand spiral is the continuing reduction in demand for a company’s product that occurs when the prices of competitors’ products are not met and (as demand drops further), higher and higher unit costs result in more and more reluctance to meet competitors’ prices. Pricing decisions need to consider competitors and customers as well as costs.
9‐12 No. It depends on how a company handles the production‐volume variance in the end‐of‐period financial statements. For example, if the adjusted allocation‐rate approach is used, each denominator‐level capacity concept will give the same financial statement numbers at year‐end.
9‐13 The denominator‐level concepts of theoretical and practical capacity emphasize what a plant can supply. The denominator‐level concepts of normal utilization and master budget utilization emphasize what customers demand for products produced by a plant.
9‐14 No. The costs of having too much capacity/too little capacity involve revenue opportunities potentially forgone as well as costs of money tied up in plant assets.
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EXERCISES
9‐15 (10 min.)
Terminology.
When the full costs of production are included this is called absorption costing, but it is sometimes more appropriate to use either variable costing or to include only direct materials called throughput or supervariable costing. The two types of demand capacity that can be used in the denominator to calculate a unitized fixed cost rate are long‐term demand normal capacity or short‐term demand called master budget capacity. The only acceptable measure for CRA is master budget capacity, while the only GAAP compliant measure to value inventory and COGS is normal capacity. The two supply side measures that may be used in the denominator to calculate a unitized fixed cost rate are long‐term measures. The first is unrealistic and excludes any allowance for off limits idle capacity. It is a 24/7/365 measure called theoretical capacity. The second includes allowance for scheduled maintenance and but not for non‐productive idle capacity, It is called practical capacity.
9‐16 (30 min.) Variable and absorption costing; explaining operating‐income differences. 1.
Key inputs for income statement computations are Beginning inventory Production Goods available for sale Units sold Ending inventory
April 0 500 500 350 150
May 150 400 550 520 30
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9‐16 (cont’d) The budgeted fixed cost per unit and budgeted total manufacturing cost per unit under absorption costing are (a) (b) (c)=(a)÷(b) (d) (e)=(c)+(d)
(a)
Budgeted fixed manufacturing costs Budgeted production Budgeted fixed manufacturing cost per unit Budgeted variable manufacturing cost per unit Budgeted total manufacturing cost per unit
April
May
$2,000,000 500 $4,000 $10,000 $14,000
$2,000,000 500 $4,000 $10,000 $14,000
Variable costing April 2013
a
Revenue Variable costs Beginning inventory Variable manufacturing costsb Cost of goods available for sale Deduct ending inventoryc Variable cost of goods sold
May 2013
$ 0 5,000,000 5,000,000 (1,500,000) 3,500,000
$8,400,000
$12,480,000 $1,500,000 4,000,000 5,500,000 (300,000) 5,200,000
1,050,000 2,000,000 600,000
4,550,000 3,850,000 2,600,000 $1,250,000
1,560,000 2,000,000 600,000
d
Variable operating costs Total variable costs Contribution margin Fixed costs Fixed manufacturing costs Fixed operating costs Total fixed costs Operating income
a $24,000 × 350; $24,000 × 520
c $10,000 × 150; $10,000 × 30
b $10,000 × 500; $10,000 × 400
d $3,000 × 350; $3,000 × 520
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6,760,000 5,720,000 2,600,000 $3,120,000
Chapter 9
9‐16 (cont’d) (b)
Absorption costing
April 2013 May 2013 a Revenue $8,400,000 $12,480,000 Cost of goods sold Beginning inventory $ 0 $2,100,000 5,000,000 4,000,000 Variable manufacturing costsb c Allocated fixed manufacturing costs 2,000,000 1,600,000 Cost of goods available for sale 7,000,000 7,700,000 (2,100,000) (420,000) Deduct ending inventoryd Adjustment for prod.‐vol. variancee 0 400,000 U 7,680,000 Cost of goods sold 4,900,000 Gross margin 3,500,000 4,800,000 Operating costs 1,050,000 1,560,000 Variable operating costsf 600,000 Fixed operating costs 600,000 Total operating costs 1,650,000 2,160,000 Operating income $1,850,000 $ 2,640,000 a $24,000 × 350; $24,000 × 520 d $14,000 × 150; $14,000 × 30 b $10,000 × 500; $10,000 × 400 e $2,000,000 – $2,000,000; $2,000,000 – $1,600,000 c $4,000 × 500; $4,000 × 400 f $3,000 × 350; $3,000 × 520
2.
Absorption-costing Variable-costing Fixed manufacturing costs Fixed manufacturing costs – operating income = in ending inventory – in beginning inventory operating income
April: $1,850,000 – $1,250,000 = ($4,000 × 150) – ($0) $600,000 = $600,000 May: $2,640,000 – $3,120,000 = ($4,000 × 30) – ($4,000 × 150) – $480,000 = $120,000 – $600,000 – $480,000 = – $480,000 The difference between absorption and variable costing is due solely to moving fixed manufacturing costs into inventories as inventories increase (as in April) and out of inventories as they decrease (as in May).
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9‐17 (20 min.) Throughput costing. April 2013 May 2013 1. a Revenue $8,400,000 $12,480,000 Direct material cost of goods sold Beginning inventory $ 0 Direct materials in goods $1,005,000 3,350,000 2,680,000 manufacturedb 3,350,000 3,685,000 Cost of goods available for sale c (1,005,000) (201,000) Deduct ending inventory Total direct material cost of goods sold 2,345,000 3,484,000 Throughput contribution 6,055,000 8,996,000 Other costs d e 3,320,000 Manufacturing costs 3,650,000 2,160,000g Other operating costs 1,650,000f 5,480,000 Total other costs 5,300,000 Operating income $ 755,000 $ 3,516,000 a $24,000 × 350; $24,000 × 520 e ($3,300 × 400) + $2,000,000 b $6,700 × 500; $6,700 × 400 f ($3,000 × 350) + $600,000 c $6,700 × 150; $6,700 × 30 g ($3,000 × 520) + $600,000 d ($3,300 × 500) + $2,000,000
2.
Operating income under: Absorption costing Variable costing Throughput costing
April $1,850,000 1,250,000 755,000
May $2,640,000 3,120,000 3,516,000
In April, throughput costing has the lowest operating income, whereas in May throughput costing has the highest operating income. Throughput costing puts greater emphasis on sales as the source of operating income than does either absorption or variable costing. 3.
Throughput costing puts a penalty on production without a corresponding sale in the same period. Costs other than direct materials that are variable with respect to production are expensed in the period of incurrence, whereas under variable costing they would be capitalized. As a result, throughput costing provides less incentive to produce for inventory than either variable costing or absorption costing.
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Chapter 9
9‐18 (40 min.) Variable and absorption costing, explaining operating‐income differences. The following solution is based on budgeted monthly production of 1,000 units. 1. Key inputs for income statement computations are: January February March 300 300 Beginning inventory 0 Production 1,000 800 1,250 Goods available for sale 1,000 1,100 1,550 Units sold 700 800 1,500 300 300 50 Ending inventory The budgeted fixed manufacturing cost per unit and budgeted total manufacturing cost per unit under absorption costing are: (a) (b) (c)=(a)÷(b) (d) (e)=(c)+(d)
Budgeted fixed manufacturing costs Budgeted production Budgeted fixed manufacturing cost per unit Budgeted variable manufacturing cost per unit Budgeted total manufacturing cost per unit
January $400,000 1,000 $400 $900 $1,300
February $400,000 1,000 $400 $900 $1,300
March $400,000 1,000 $400 $900 $1,300
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9‐18 (cont’d) (a)
Variable Costing Revenuea Variable costs Beginning inventoryb Variable manufacturing costsc Cost of goods available for sale Deduct ending inventoryd Variable cost of goods sold Variable operating costse Total variable costs
Contribution margin Fixed costs Fixed manufacturing costs Fixed operating costs Total fixed costs Operating income a $$3,000× 700; $3,000× 800; $× 1,500
January 2013 $2,100,000 $ 0
February 2013 $2,400,000 $270,000
March 2013 $4,500,000 $ 270,000
720,000
1,125,000
900,000 (270,000) 630,000 420,000
1,050,000
990,000 (270,000) 720,000 480,000
1,200,000
1,395,000 (45,000) 1,350,000 900,000
400,000 140,000
1,050,000 540,000 $ 510,000
400,000 140,000
1,200,000 540,000 $ 660,000
400,000 140,000
900,000
b $? × 0; $900 × 300; $900 × 300 c $900 × 1,000; $900 × 800; $900 × 1,250 d $900 × 300; $900 × 300; $900 × 50 e $600 × 700; $600 × 800; $600 × 1,500
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2,250,000 2,250,000
540,000 $ 1,710,000
Chapter 9
9‐18 (cont’d) (b) Absorption Costing Revenuea Cost of goods sold Beginning inventoryb Variable manufacturing costsc Allocated fixed manufacturing costsd Cost of goods available for sale Deduct ending inventorye Adjustment for prod. vol. var.f Cost of goods sold Gross margin Operating costs Variable operating costsg Fixed operating costs Total operating costs
January 2013 $2,100,000 $ 0 900,000
720,000
1,125,000
400,000
320,000
500,000
1,300,000 (390,000)
1,430,000 (390,000)
2,015,000 (65,000)
0
910,000 1,190,000
420,000 140,000
Operating income a $3,000× 700; $3,000 × 800; $3,000 × 1,500 c $900 × 1,000; $900 × 800; $900 × 1,250 e $1,300 × 300; $1,300 × 300; $1,300 × 50 g $600 × 700; $600 × 800; $600 × 1,500
February 2013 March 2013 $2,400,000 $4,500,000 $ 390,000 $ 390,000
560,000 $ 630,000
80,000 U 480,000 140,000
1,120,000 1,280,000
(100,000) F
1,850,000 2,650,000
900,000 140,000 620,000 $ 660,000
1,040,000 $ 1,610,000
$?× 0; $1,300 × 300; $1,300 × 300 $400 × 1,000; $400 × 800; $400 × 1,250 f $400,000 – $400,000; $400,000 – $320,000; $400,000 – $500,000 b d
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9‐18 (cont’d) 2.
Fixed manufacturing Fixed manufacturing Absorption‐costing – Variable costing = – costs in costs in operating income operating income ending inventory beginning inventory January: $630,000 – $510,000 = ($400 × 300) – $0 $120,000 = $120,000 February: $660,000 – $660,000 = ($400 × 300) – ($400 × 300) $0 = $0 March: $1,610,000 – $1,710,000 = ($400 × 50) – ($400 × 300) – $100,000 = – $100,000 The difference between absorption and variable costing is due solely to moving fixed manufacturing costs into inventories as inventories increase (as in January) and out of inventories as they decrease (as in March).
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Chapter 9
9‐19 (20–30 min.) Throughput costing. 1. Revenuea Direct material cost of goods sold Beginning inventoryb Direct materials in goods manufacturedc Cost of goods available for sale Deduct ending inventoryd Total direct material cost of goods sold Throughput contribution Other costs Manufacturinge Operatingf Total other costs Operating income
January $2,100,000 $ 0 500,000 500,000 (150,000) 350,000 1,750,000 800,000 560,000 1,360,000 $ 390,000
February $2,400,000 $150,000 400,000 550,000 (150,000) 400,000 2,000,000 720,000 620,000 1,340,000 $ 660,000
March $4,500,000 $ 150,000 625,000 775,000 (25,000) 750,000 3,750,000 900,000 1,040,000 1,940,000 $1,810,000
b $? × 0; $500 × 300; $500 × 300 $3,000 × 700; $3,000 × 800; $3,000 × 1,500 c $500 × 1,000; $500 × 800; $500 × 1,250 d $500 × 300; $500 × 300; $500 ×50 e ($400 × 1,000) + $400,000; ($400 × 800) + $400,000; ($400 × 1,250) + $400,000 f ($600 × 700) + $140,000; ($600 × 800) + $140,000; ($600 × 1,500) + $140,000 a
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9‐19 (cont’d) 2.
Operating income under:
Absorption costing Variable costing Throughput costing
January $510,000 630,000 390,000
February $660,000 660,000 660,000
March $1,710,000 1,610,000 1,810,000
Throughput costing puts greater emphasis on sales as the source of operating income than does absorption or variable costing. 3.
Throughput costing puts a penalty on producing without a corresponding sale in the same period. Costs other than direct materials that are variable with respect to production are expensed when incurred, whereas under variable costing they would be capitalized as an inventoriable cost.
9‐20 (10 min.)
Absorption and variable costing.
The answers are 1(a) and 2(c). Computations: 1. Absorption Costing: Revenuea Cost of goods sold: Variable manufacturing costsb Allocated fixed manufacturing costsc Gross margin Operating costs: Variable operatingd Fixed operating Operating income
$2,400,000 360,000 1,200,000 400,000
$4,800,000 2,760,000 2,040,000 1,600,000 $ 440,000
$40 × 120,000 $20 × 120,000 c Fixed manufacturing rate = $600,000 ÷ 200,000 = $3 per output unit Fixed manufacturing costs = $3 × 120,000 d $10 × 120,000 a
b
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Chapter 9
9‐20 (cont’d) 2.
Variable Costing: Revenuea Variable costs: Variable manufacturing cost of goods soldb Variable operating costsc Contribution margin Fixed costs: Fixed manufacturing costs Fixed operating costs Operating income a $40 × 120,000 b $20 × 120,000 c $10 × 120,000
$2,400,000 1,200,000 600,000 400,000
$4,800,000 3,600,000 1,200,000 1,000,000 $ 200,000
9‐21 (20–30 min.) Comparison of actual costing methods. The numbers are simplified to ease computations. This problem avoids standard costing and its complications. 1. Variable‐costing income statements:
2012 Sales 1,000 units Production 1,400 units $3,000 $ 0 700 700 (200) 500 1,000 1,500 1,500 700 400 1,100 $ 400
2013 Sales 1,200 units Production 1,000 units $3,600 $ 200 500 700 (100) 600 1,200 1,800 1,800 700 400 1,100 $ 700
Revenue ($3 per unit) Variable costs: Beginning inventory Variable cost of goods manufactured Cost of goods available for sale Deduct ending inventorya Variable cost of goods sold Variable operating costs Variable costs Contribution margin Fixed costs Fixed manufacturing costs Fixed operating costs Total fixed costs Operating income a Unit inventoriable costs: Year 1: $700 ÷ 1,400 = $0.50 per unit; $0.50 × (1,400 – 1,000) Year 2: $500 ÷ 1,000 = $0.50 per unit; $0.50 × (400 + 1,000 – 1,200)
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9‐21 (cont’d) 2. Absorption‐costing income statements: 2012 2013 Sales 1,000 units Sales 1,200 units Production 1,400 units Production 1,000 units Revenue ($3 per unit) $3,000 $3,600 Cost of goods sold: Beginning inventory $ 0 $ 400 Variable manufacturing costs 700 500 Fixed manufacturing costsa 700 700 Cost of goods available for sale 1,400 1,600 b Deduct ending inventory (400) (240) Cost of goods sold 1,000 1,360 Gross margin 2,000 2,240 Operating costs: 1,000 Variable operating costs 1,200 Fixed operating costs 400 400 Total operating costs 1,400 1,600 $ 600 $ 640 Operating income a Fixed manufacturing cost rate: Year 1: $700 ÷ 1,400 = $0.50 per unit Year 2: $700 ÷ 1,000 = $0.70 per unit b Unit inventoriable costs: Year 1: $1,400 ÷ 1,400 = $1.00 per unit; $1.00 × (1400 – 1000) Year 2: $1,200 ÷ 1,000 = $1.20 per unit $1.20 × (400 + 1,000 – 1,200)
3.
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2012
2013
Variable Costing: Operating income $400 $700 Ending inventory 200 100 Absorption Costing: Operating income $600 $640 Ending inventory 400 240 Fixed manuf. overhead • in beginning inventory 0 200 • in ending inventory 200 140 Fixed Absorption Variable Fixed costing – costing = manuf. costs – manuf. costs operating operating in ending in beginning income inventory income inventory
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Chapter 9
9‐21 (cont’d)
Year 1: $600 – $400 $200 Year 2: $640 – $700 –$60
$0.50 × 400 – $0 $200 ($0.70 × 200) – ($0.50 × 400) –$60
The difference in reported operating income is due to the amount of fixed manufacturing overhead in the beginning and ending inventories. In Year 1, absorption costing has a higher operating income of $200 due to ending inventory having $200 more in fixed manufacturing overhead than does beginning inventory. In Year 2, variable costing has a higher operating income of $60 due to ending inventory under absorption costing having $60 less in fixed manufacturing overhead than does beginning inventory.
4.
a.
b.
= = = =
Absorption costing is more likely to lead to inventory build‐ups than variable costing. Under absorption costing, operating income in a given accounting period is increased by inventory buildup, because some fixed manufacturing costs are accounted for as an asset (inventory) instead of as a cost of the period of production. Although variable costing will counteract undesirable inventory build‐ ups, other measures can be used without abandoning absorption costing. Examples include: (1) careful budgeting and inventory planning, (2) incorporating a carrying charge for inventory, (3) changing the period used to evaluate performance to be long‐term, (4) including nonfinancial variables that measure inventory levels in performance evaluations.
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9‐22 (40 min) Absorption versus variable costing. 1. The variable manufacturing cost per unit is $55 + $45 + $120 = $220. 2013 Variable‐Costing Based Operating Income Statement $10,752,000 Revenue (8,960 $1,200 per unit) Variable costs Beginning inventory $ 0 Variable manufacturing costs (10,000 units $220 per unit) 2,200,000 Cost of goods available for sale 2,200,000 a Deduct: Ending inventory (1,040 units $220 per unit) (228,800) Variable cost of goods sold 1,971,200 Variable marketing costs (8,960 units $75 per unit) 672,000 Total variable costs 2,643,200 Contribution margin 8,108,800 Fixed costs Fixed manufacturing costs 1,471,680 Fixed R&D 981,120 Fixed marketing 3,124,480 Total fixed costs 5,577,280 Operating income $2,531,520 a Beginning Inventory 0 + Production 10,000 – Sales 8,960 = Ending Inventory 1,040 units
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9‐22 (cont’d) 2.
2013 Absorption‐Costing Based Operating Income Statement Revenue (8,960 units $1,200 per unit) Cost of goods sold Beginning inventory $ 0 2,200,000 Variable manufacturing costs (10,000 units $220 per unit) Allocated fixed manufacturing costs (10,000 units $165 per unit) 1,650,000 Cost of goods available for sale 3,850,000 (400,400) Deduct ending inventory (1,040 units ($220 + $165) per unit) Deduct favourable production volume variance (178,320)a F Cost of goods sold Gross margin Operating costs 672,000 Variable marketing costs (8,960 units $75 per unit) Fixed R&D 981,120 Fixed marketing 3,124,480 Total operating costs Operating income a PVV = Allocated $1,650,000 ($165 10,000) – Actual $1,471,680 = $178,320
3.
$10,752,000 3,271,280 7,480,720 4,777,600 $2,703,120
2013 operating income under absorption costing is greater than the operating income under variable costing because in 2013 inventories increased by 1,040 units, and under absorption costing fixed overhead remained in the ending inventory, and resulted in a lower cost of goods sold (relative to variable costing). As shown below, the difference in the two operating incomes is exactly the same as the difference in the fixed manufacturing costs included in ending vs. beginning inventory (under absorption costing).
Operating income under absorption costing Operating income under variable costing Difference in operating income under absorption vs. variable costing Under absorption costing: Fixed mfg. costs in ending inventory (1,040 units $165 per unit) Fixed mfg. costs in beginning inventory (0 units $165 per unit)
$2,703,120 2,531,520 $ 171,600
$ 171,600 0 Change in fixed mfg. costs between ending and beginning inventory $ 171,600
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9‐22 (cont’d) 4.
Relative to the obvious alternative of using contribution margin (from variable costing), the absorption‐costing based gross margin has some pros and cons as a performance measure for Electron’s supervisors. It takes into account both variable costs and fixed costs—costs that the supervisors should be able to control in the long‐run—and therefore it is a more complete measure than contribution margin which ignores fixed costs (and may cause the supervisors to pay less attention to fixed costs). The downside of using absorption‐costing‐ based gross margin is the supervisor’s temptation to use inventory levels to control the gross margin—in particular, to shore up a sagging gross margin by building up inventories. This can be offset by specifying, or limiting, the inventory build‐up that can occur, charging the supervisor a carrying cost for holding inventory, and using nonfinancial performance measures such as the ratio of ending to beginning inventory.
9‐23 (10 min.) Capacity management, denominator‐level capacity concepts. 1. a, b 2. a 3. d 4. c, d 5. c 6. d 7. a 8. b (or a) 9. b 10. c, d 11. a, b
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Chapter 9
9‐24 (40 min) Variable versus absorption costing. 1. Income Statement for the Zwatch Company, Variable Costing for the Year Ended December 31, 2013 Revenue: $22 × 345,400 Variable costs Beginning inventory: $5.10 × 85,000 Variable manufacturing costs: $5.10 × 294,900 Cost of goods available for sale Deduct ending inventory: $5.10 × 34,500 Variable cost of goods sold Variable operating costs: $1.10 × 345,400 Adjustment for variances Total variable costs Contribution margin Fixed costs Fixed manufacturing overhead costs Fixed operating costs Total fixed costs Operating income
$ 433,500 1,503,990
$7,598,800
1,937,490 (175,950) 1,761,540 379,940 0 1,440,000 1,080,000
2,141,480 5,457,320 2,520,000 $2,937,320
Absorption Costing Data: Fixed manufacturing overhead allocation rate = Fixed manufacturing overhead/Denominator level machine‐hours = $1,440,000 6,000 = $240 per machine‐hour Fixed manufacturing overhead allocation rate per unit = Fixed manufacturing overhead allocation rate/standard production rate = $240 50 = $4.80 per unit
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9‐24 (cont’d) Income Statement for the Zwatch Company, Absorption Costing for the Year Ended December 31, 2013 Revenue: $22 × 345,400 $7,598,800 Cost of goods sold Beginning inventory ($5.10 + $4.80) × 85,000 $ 841,500 Variable manuf. costs: $5.10 × 294,900 1,503,990 Allocated fixed manuf. costs: $4.80 × 294,900 1,415,520 Cost of goods available for sale $3,761,010 Deduct ending inventory: ($5.10 + $4.80) × 34,500 (341,550) a 24,480 U Adjust for manuf. variances ($4.80 × 5,100) Cost of goods sold 3,443,940 Gross margin 4,154,860 Operating costs Variable operating costs: $1.10 × 345,400 $ 379,940 Fixed operating costs 1,080,000 Total operating costs 1,459,940 Operating income $2,694,920 a Production volume variance = [(6,000 hours × 50) – 294,900] × $4.80 = (300,000 – 294,900) × $4.80 = $24,480 2. Zwatch’s operating margins as a percentage of revenue are Under variable costing: Revenue $7,598,800 Operating income 2,937,320 Operating income as percentage of revenues 38.7% Under absorption costing: Revenues $7,598,800 2,694,920 Operating income Operating income as percentage of revenues 35.5%
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Chapter 9
9‐24 (cont’d) 3. 4.
Operating income using variable costing is about 9% higher than operating income calculated using absorption costing. Variable costing operating income – Absorption costing operating income = $2,937,320 – $2,694,920 = $242,400 Fixed manufacturing costs in beginning inventory under absorption costing – Fixed manufacturing costs in ending inventory under absorption costing = ($4.80 × 85,000) – ($4.80 × 34,500) = $242,400 The factors the CFO should consider include (a) Effect on managerial behaviour. (b) Effect on external users of financial statements.
I would recommend absorption costing because it considers all the manufacturing resources (whether variable or fixed) used to produce units of output. Absorption costing has many critics. However, the dysfunctional aspects associated with absorption costing can be reduced by Careful budgeting and inventory planning. Adding a capital charge to reduce the incentives to build up inventory. Monitoring nonfinancial performance measures.
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PROBLEMS
9‐25 (20 min.) Downward demand spiral. 1. and 2. Competitive Original Situation Practical capacity (units) 7,500 7,500 Budgeted capacity (units) 7,500 6,000 Variable manufacturing cost per unit $100 $100 Fixed manufacturing costs $2,250,000 $2,250,000 Markup percentage 100% 100% Manufacturing cost per unit Variable $100 $100 Fixed (fixed mfg costs budgeted capacity) ($2,250,000 7,500; $2,250,000 6,000) 300 375 Full manufacturing cost per unit $400 $475 Selling Price (200% of full manuf. cost per unit) $800 $950 3. We can see that when the budgeted production is used as the denominator level and this level changes with anticipated demand, then the full manufacturing cost per unit and therefore the selling price can be quite sensitive to the denominator level. In this case, the denominator level has fallen by 20% [(7,500 – 6,000) 7,500] and the allocated fixed cost has increased by 25% [($375 – $300) 300], resulting in an 18.75% [($950 – $800) $800] increase in selling price. If Network’s market is becoming more competitive because of foreign entrants, raising the selling price could further drive away customers, lower the budgeted capacity and raise the fixed cost per unit, that is, lead to a downward spiral. If Network’s production plant was built for a practical capacity of 7,500 units, a denominator level of 7,500 units should be used, and the cost of excess capacity should not be charged to the units produced and sold. This will focus managerial attention on the unused capacity. If the competitive trends continue, Network will need to cut back its installed capacity to stay competitive.
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9‐25 (cont’d) 4.
Suppose Network sells x units each year. Its total cost to manufacture the x units would be $100x + $2,250,000. Its total cost to purchase x units would be $400x + $450,000. Therefore, Network should manufacture in‐house, if $100x + $2,250,000 < $400x + $450,000; i.e., if x > 6,000 units. In‐house, the cost structure is a low variable cost, high fixed cost structure, and only worth pursuing for high volumes. The source‐outside cost structure is a high variable cost, low fixed cost structure, and only worth pursuing for small volumes. Currently, demand is exactly at 6,000 units. Network should conduct some research to forecast future demand patterns. If it seems likely that demand is going to fall below 6,000, it may be better to shut down its production capacity and outsource all of its needed units. This may also allow the management to examine and pursue other business options, as its current business gets increasingly competitive.
9‐26 (35 min.)
Absorption costing and production volume variance ‐‐ alternative capacity bases
1.
Inventoriable cost per unit = Variable production cost + Fixed manufacturing overhead/Capacity
Capacity Type Theoretical Practical Normal Master Budget
Capacity Level 800,000 500,000 250,000 200,000
Fixed Mfg. Overhead $1,000,000 $1,000,000 $1,000,000 $1,000,000
Fixed Mfg. Variable Overhead Production Inventoriable Rate Cost Cost Per Unit $1.25 $2.50 $3.75 $2.00 $2.50 $4.50 $4.00 $2.50 $6.50 $5.00 $2.50 $7.50
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9‐26 (cont’d) 2.
ELF’s actual production level is 220,000 bulbs. We can compute the production‐ volume variance as: Budgeted Fixed MOH – (Fixed MOH Rate × Actual Production Level)
Capacity Level 800,000 500,000 250,000 200,000
Fixed Mfg. Overhead $1,000,000 $1,000,000 $1,000,000 $1,000,000
Fixed Mfg. Fixed Overhead Mfg. Rate × Actual Overhead Rate Production $1.25 $ 275,000 $2.00 $ 440,000 $4.00 $ 880,000 $5.00 $1,100,000
Production Volume Variance $725,000 U $560,000 U $120,000 U $100,000 F
Capacity Type Theoretical Practical Normal Master Budget 3. Operating Income for ELF given production of 220,000 bulbs and sales of 200,000 bulbs @ $9 apiece: Revenue Less: Cost of goods sold a Production‐volume variance Gross margin Variable selling b Fixed selling Operating income
Theoretical $1,800,000 750,000 725,000 U 325,000 50,000 250,000 $ 25,000
Practical $1,800,000 900,000 560,000 U 340,000 50,000 250,000 $ 40,000
a
200,000 × 3.75, × 4.50, × 6.50, × 7.50 200,000 × 0.25
b
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Normal
Master Budget $1,800,000 $1,800,000 1,300,000 1,500,000 120,000 U (100,000)F 380,000 400,000 50,000 50,000 250,000 250,000 $ 80,000 $ 100,000
Chapter 9
9‐27 (35 min.) Operating income effects of denominator‐level choice and disposal of production‐volume variance (continuation of 9‐26) 1.
Since no beginning inventories exist, if ELF sells all 220,000 bulbs manufactured, its operating income will be the same under all four capacity options. Calculations are provided below:
Theoretical Practical Revenue $1,980,000 $1,980,000 a Less: Cost of goods sold 825,000 990,000 Production volume variance 725,000 U 560,000 U Gross margin 430,000 430,000 b 55,000 55,000 Variable selling 250,000 Fixed selling 250,000 $ 125,000 Operating income $ 125,000
Normal Master Budget $1,980,000 $1,980,000 1,430,000 1,650,000 120,000 U (100,000) F 430,000 430,000 55,000 55,000 250,000 250,000 $ 125,000 $ 125,000
a
220,000 × 3.75, × 4.50, × 6.50, × 7.50 200,000 × 0.25
b
2.
If the manager of ELF produces and sells 220,000 bulbs, then all capacity levels will result in the same operating income of $125,000 (see requirement 1 above). If the manager of ELF is able to sell only 200,000 of the bulbs produced and if the production‐volume variance is closed to cost of goods sold, then the operating income is given as in requirement 3 of 9‐26. Both sets of numbers are reproduced below. Master Theoretical Practical Normal Budget Income with sales of 220,000 bulbs $125,000 $125,000 $125,000 $125,000 Income with sales of 200,000 bulbs 25,000 40,000 80,000 100,000 Decrease in income when there is over production $100,000 $ 85,000 $ 45,000 $ 25,000 Comparing these results, it is clear that for a given level of overproduction relative to sales, the manager’s performance will appear better if he/she uses as the denominator a level that is lower. In this example, setting the denominator to equal the master budget (the lowest of the four capacity levels here), minimizes the loss to the manager from being unable to sell the entire production quantity of 220,000 bulbs.
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9‐28 (60 min.) Throughput. 1. Unit fixed m anu factu ring overhead cost
Unit manufacturing costs a) Absorption costing:
=
$10, 000 2, 000
= $5 per unit produced
Variable direct manuf. costs per unit Variable indirect manuf. costs per unit Fixed manuf. costs per unit Total manuf. cost per unit
2012 $48.70 15.00 5.00 $68.70
2013 $48.70 15.00 5.00 $68.70
2012 $48.70 15.00 $63.70
2013 $48.70 15.00 $63.70
2012 $28.00
2013 28.00
2012 900 2,000 2,900 1,500 1,400
2013 1,400 400 1,800 1,700 100
b) Variable costing: Variable direct manuf. costs per unit Variable indirect manuf. costs per unit Total variable manuf. cost per unit c) Throughput costing:
Variable direct materials per unit Unit data for 2012 and 2013 are: Beginning inventory Production Goods available for sale Sales Ending inventory
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Chapter 9
9‐28 (cont’d) (a) Absorption costing Revenue Cost of goods sold Beginning inventoryb Variable manuf. costsc Fixed manuf. costsd Cost of goods available for sale Ending inventorye Cost of goods sold (at std. cost) Adjustment for variances—variable Adjustment for variances—fixedf Total cost of goods sold Gross margin Variable marketing costsg Fixed marketing costs Total marketing costs Operating income a
2012 $180,000
2013 $204,000
61,830 127,400 10,000 199,230 96,180 103,050 1,000 U 0 104,050 75,950 1,500 3,000 4,500 $ 71,450
96,180 25,480 2,000 123,660 6,870 116,790 1,000 U 8,000 U 125,790 78,210 1,700 3,000 4,700 $ 73,510
$120 1,500; $120 1,700 $68.70 900; $68.70 1,400 c$63.70 2,000; $63.70 400 d$5 2,000; $5 400 e$68.70 1,400; $68.70 100 fProduction‐volume variance = 2006: (2,000 – 2,000) 5; 2007: (2,000 – 400) $5 g$1 1,500; $1 1,700 a
b
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9‐28 (cont’d) (b) Variable costing Revenue Variable costs Beginning inventoryb Variable cost of goods manufacturedc Cost of goods available for sale Ending inventoryd Variable manuf. COGSs Variable marketing costse Variable costs (at standard costs) Adjustment for variances Total variable costs Contribution margin Fixed costs Fixed manufacturing overhead costs Fixed marketing costs Fixed costs (at standard costs) Adjustment for variances Total fixed costs Operating income a
$120 1,500; $120 1,700 $63.70 900; $63.70 1,400 c$63.70 2,000; $63.70 400 d$63.70 l,400; $63.70 100 e$1 1,500; $1 1,700 a
b
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2012 $180,000
2013 $204,000
57,330 127,400 184,730 89,180 95,550 1,500 97,050 1,000 U 98,050 81,950
89,180 25,480 114,660 6,370 108,290 1,700 109,990 1,000 U 110,990 93,010
10,000 3,000 13,000 0 13,000 $ 68,950
10,000 3,000 13,000 0 13,000 $ 80,010
Chapter 9
9‐28 (cont’d) (c) Throughput costing Revenue Variable direct materials costs Beginning inventoryb Direct materials in goods manuf.c Cost of goods available for sale Ending inventoryd Direct materials costs (at std.) Adjustment for direct materials variances Total variable direct materials costs Throughput contribution Other costs Manufacturing Marketing Adjustment for variances Total other costs Operating income a
2012 $180,000
2013 $204,000
25,200 56,000 81,200 39,200 42,000 0 42,000 138,000
39,200 11,200 50,400 2,800 47,600 0 47,600 156,400
81,400e 4,500g 1,000 U 86,900 $ 51,100
24,280f 4,700h 1,000 U 29,980 $126,420
$120 1,500; $120 1,700 b$28 900; $28 1,400 c$28 2,000; $28 400 d$28 1,400; $28 100 1 $48.70 – $28.00 = $20.70 a
2.
[($20.701+$15) 2,000] + $10,000 = $81,400 f[($20.701+$15) 400] + $10,000 = $24,280 g[($1 1,500) +$3,000] = $4,500 h[($1 1,700) + $3,000] = $4,700 e
Absorption costing makes operating income a function of both sales levels and production levels. This can create an incentive for managers to manipulate production levels to increase their operating income in a period when this is not in Byrd Company’s best interest. It is not always the case that managers will manipulate production to increase inventory levels. They would also consider differences across periods in the fixed manufacturing overhead rates. Variable costing highlights the effect of changes in units sold on operating income. It thus reduces the incentives for using production variations to “manage” operating income for manager performance evaluation purposes.
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9‐28 (cont’d) 3.
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Pros of Throughput Costing (a) Extreme form of variable costing. There is even less incentive to build for inventory than under variable costing. Indeed, managers who produce but do not sell the output in the same period, will see operating income decline because of variable costs other than direct materials being expensed to that period. Hence there is a disincentive for inventory buildup. (b) Very simple to operate. (c) Avoids disputes between absorption costing and variable costing over, say, whether a manufacturing cost item is variable indirect or fixed indirect. Throughput costing reduces incentives of managers to play games with respect to cost classifications. Cons of Throughput Costing (a) Procuring for inventory is not universally a negative. In industries where there is high uncertainty about demand and huge economies of scale in production, having some inventory may be economically appropriate. Throughput costing does not reinforce the economics of such situations. (b) Can lead to large swings over time in operating income that managers may not feel represent their underlying performance. (c) Some managers have maintained that when inventory is reported at only direct materials costs there is an incentive to reduce selling prices at the end of the year to get large increases in reported operating income for that period. This may not be in the company’s best interest. This effect is marked for industries with a low direct materials cost to total manufacturing cost ratio. (d) Can create need to run “dual” systems because of throughput costing being unacceptable for financial reporting or taxation.
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Chapter 9
9‐29 (25 min.) Denominator‐level choices, changes in inventory levels, effect on operating income. 1. Normal Theoretical Practical Utilization Capacity Capacity Capacity Denominator level in units 144,000 120,000 96,000 Budgeted fixed manuf. costs $1,440,000 $1,440,000 $1,440,000 Budgeted fixed manuf. cost allocated per unit $ 10.00 $ 12.00 $ 15.00 Production in units 104,000 104,000 104,000 Allocated fixed manuf. costs (production in units budgeted fixed manuf. cost allocated per unit) $1,040,000 $1,248,000 $1,560,000 Production volume variance (Budgeted fixed manuf. $ 400,000 U $ 192,000 U $ 120,000 F costs – allocated fixed manuf. costs)a
aPVV is unfavourable if budgeted fixed manuf. costs are greater than allocated fixed costs 2. Units sold Budgeted fixed mfg. cost allocated per unit Budgeted var. mfg. cost per unit Budgeted cost per unit of inventory or production
Theoretical Capacity 112,000 $10 $ 3 $13
Practical Capacity 112,000 $12 $ 3 $15
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Normal Utilization Capacity 112,000 $15 $ 3 $18
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9‐29 (cont’d) ABSORPTION‐COSTING BASED INCOME STATEMENTS Revenue ($30 selling price per unit units sold) Cost of goods sold Beginning inventory (10,000 units budgeted cost per unit of inventory) Variable manufacturing costs (104,000 units $3 per unit) Allocated fixed manufacturing overhead (104,000 units budgeted fixed mfg. cost allocated per unit) Cost of goods available for sale Deduct ending inventory (2,000b units budgeted cost per unit of inventory) Adjustment for production‐volume variance Total cost of goods sold Gross margin Operating costs Operating income
$3,360,000
$3,360,000
$3,360,000
130,000
150,000
180,000
312,000
312,000
312,000
1,040,000 1,482,000
1,248,000 1,710,000
1,560,000 2,052,000
(26,000) 400,000 U 1,856,000 1,504,000 400,000 $1,104,000
(30,000) (36,000) 192,000 U (120,000) F 1,872,000 1,896,000 1,488,000 1,464,000 400,000 400,000 $1,088,000 $1,064,000
Ending inventory = Beginning inventory + production – sales = 10,000 + 104,000 – 112,000 = 2,000 units 2,000 × $13; 2,000 × $15; 2,000 × $18 3. Koshu’s 2013 beginning inventory was 10,000 units; its ending inventory was 2,000 units. So, during 2013, there was a drop of 8,000 units in inventory levels (matching the 8,000 more units sold than produced). The smaller the denominator level, the larger is the budgeted fixed cost allocated to each unit of production, and, when those units are sold (all the current production is sold, and then some), the larger is the cost of each unit sold, and the smaller is the operating income. Normal utilization capacity is the smallest capacity of the three, hence in this year, when production was less than sales, the absorption‐ costing based operating income is the smallest when normal capacity utilization is used as the denominator level. b
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Chapter 9
9‐29 (cont’d) 4. Reconciliation Theoretical Capacity Operating Income – $16,000 Practical Capacity Operating Income Decrease in inventory level during 2013 8,000 Fixed mfg cost allocated per unit under practical capacity – fixed mfg. cost allocated per unit under theoretical capacity ($12 – $10) $2 Additional allocated fixed cost included in COGS $16,000 under practical capacity = 8,000 units $2 per unit = More fixed manufacturing costs are included in inventory under practical capacity, so, when inventory level decreases (as it did in 2013), more fixed manufacturing costs are included in COGS under practical capacity than under theoretical capacity, resulting in a lower operating income.
9‐30 (40 min.) Variable and absorption costing, sales, and operating‐income changes. 1.
Headsmart’s annual fixed manufacturing costs are $1,200,000. It allocates $24 of fixed manufacturing costs to each unit produced. Therefore, it must be using $1,200,000 $24 = 50,000 units (annually) as the denominator level to allocate fixed manufacturing costs to the units produced. We can see from Headsmart’s income statements that it disposes off any production volume variance against cost of goods sold. In 2012, 60,000 units were produced instead of the budgeted 50,000 units. This resulted in a favourable production volume variance of $240,000 F ((60,000 – 50,000) units $24 per unit), which, when written off against cost of goods sold, increased gross margin by that amount.
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9‐30 (cont’d) The breakeven calculation, same for each year, is shown below: Calculation of breakeven volume Selling price ($2,100,000 50,000; $2,100,000 50,000; $2,520,000 60,000) Variable cost per unit (all manufacturing) Contribution margin per unit Total fixed costs (fixed mfg. costs + fixed selling & admin. costs) Breakeven quantity = Total fixed costs contribution margin per unit
2011
2012
$42 14 $28
2013
$42 14 $28
$42 14 $28
$1,400,000 $1,400,000 $1,400,000 50,000
50,000
50,000
2011 50,000 $2,100,000
2012 50,000 $2,100,000 0 840,000 (140,000) 700,000 $1,400,000 $1,200,000 200,000 $ 0
2013 60,000 $2,520,000
3. Variable Costing Sales (units) Revenue Variable cost of goods sold Beginning inventory $14 0; 0; 10,000 Variable manuf. costs $14 50,000; 60,000; 50,000 Deduct ending inventory $14 0; 10,000; 0 Variable cost of goods sold Contribution margin Fixed manufacturing costs Fixed selling and administrative expenses Operating income
Explaining variable costing operating income Contribution margin ($28 contribution margin per unit sales units) Total fixed costs Operating income
0 700,000 0 700,000 $1,400,000 $1,200,000 200,000 $ 0
$1,400,000 1,400,000 $ 0
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$1,400,000 1,400,000 $ 0
140,000 700,000 0 840,000 $1,680,000 $1,200,000 200,000 $ 280,000
$1,680,000 1,400,000 $ 280,000
Chapter 9
9‐30 (cont’d) 4. Reconciliation of absorption/variable costing operating incomes (1) Absorption costing operating income (ACOI) (2) Variable costing operating income (VCOI) (3) Difference (ACOI – VCOI) (4) Fixed mfg. costs in ending inventory under absorption costing (ending inventory in units $24 per unit) (5) Fixed mfg. costs in beginning inventory under absorption costing (beginning inventory in units $24 per unit) (6) Difference = (4) – (5)
2011 $0 0 $0
2012 $240,000 0 $240,000
$0
$240,000
0 $0
0 $240,000
2013 $ 40,000 280,000 $(240,000) $ 0
240,000 $(240,000)
In the table above, row (3) shows the difference between the operating income under absorption costing and the operating income under variable costing, for each of the three years. In 2011, the difference is $0; in 2012, absorption costing income is greater by $240,000; and in 2013, it is less by $240,000. Row (6) above shows the difference between the fixed costs in ending inventory and the fixed costs in beginning inventory under absorption costing, which is $0 in 2011, $240,000 in 2012 and ‐$240,000 in 2013. Row (3) and row (6) explain and reconcile the operating income differences between absorption costing and variable costing. Stuart Weil is surprised at the non‐zero, positive net income (reported under absorption costing) in 2012, when sales were at the ‘breakeven volume’ of 50,000; further, he is concerned about the drop in operating income in 2013, when, in fact, sales increased to 60,000 units. In 2012, starting with zero inventories, 60,000 units were produced, 50,000 were sold, i.e., at the end of the year, 10,000 units remained in inventory. These 10,000 units had each absorbed $24 of fixed costs (total of $240,000), which would remain as assets on Headsmart’s balance sheet until they were sold. Cost of goods sold, representing only the costs of the 50,000 units sold in 2012, was accordingly reduced by $240,000, the production volume variance, resulting in a positive operating income even though sales were at breakeven levels. The following year, in 2013, production was 50,000 units, sales were 60,000 units i.e., all of the fixed costs that were included in 2012 ending inventory, flowed through COGS in 2013. Contribution margin in 2013 was $1,680,000 (60,000 units $28), but, in absorption costing, COGS also contains the allocated fixed manufacturing costs of the units sold, which were $1,440,000 (60,000 units $24), resulting in an operating income of $40,000 = 1,680,000 – $1,440,000 – $200,000 (fixed sales and
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9‐30 (cont’d)
admin.) Hence the drop in operating income under absorption costing, even though sales were greater than the computed breakeven volume: inventory levels decreased sufficiently in 2013 to cause 2013’s operating income to be lower than 2012 operating income. Note that beginning and ending with zero inventories during the 2011– 2013 period, under both costing methods, Headsmart’s total operating income was $280,000.
9‐31 (25 min.) Denominator‐level problem. 1. Budgeted fixed manufacturing overhead costs rates: Budgeted Fixed Budgeted Fixed Denominator Manufacturing Budgeted Manufacturing Level Capacity Overhead per Capacity Overhead Cost Concept Period Level Rate Theoretical $ 4,000,000 2,880 $ 1,388.89 Practical 4,000,000 1,920 2,083.33 Normal 4,000,000 1,200 3,333.33 Master‐budget 4,000,000 1,500 2,666,67 The rates are different because of varying denominator‐level concepts. Theoretical and practical capacity levels are driven by supply‐side concepts, i.e., “how much can I produce?” Normal and master‐budget capacity levels are driven by demand‐side concepts, i.e., “how much can I sell?” (or “how much should I produce?”) 2. The variances that arise from use of the theoretical or practical level concepts will signal that there is a divergence between the supply of capacity and the demand for capacity. This is useful input to managers. As a general rule, however, it is important not to place undue reliance on the production volume variance as a measure of the economic costs of unused capacity.
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9‐31 (cont’d) 3.
Under a cost‐based pricing system, the choice of a master‐budget level denominator will lead to high prices when demand is low (more fixed costs allocated to the individual product level), further eroding demand; conversely, it will lead to low prices when demand is high, forgoing profits. This has been referred to as the downward demand spiral—the continuing reduction in demand that occurs when the prices of competitors are not met and demand drops, resulting in even higher unit costs and even more reluctance to meet the prices of competitors. The positive aspects of the master‐budget denominator level are that it is based on demand for the product and indicates the price at which all costs per unit would be recovered to enable the company to make a profit. Master‐budget denominator level is also a good benchmark against which to evaluate performance.
9‐32 (30 min.) Cost allocation, downward demand spiral. SOLUTION EXHIBIT 9‐32
Budgeted fixed costs Denominator level Budgeted fixed cost per meal Budgeted fixed costs Denominator level ($1,533,000 1,022,000; $1,533,000 1,460,000; $1,533,000 876,000) Budgeted variable cost per meal Total budgeted cost per meal 1.
2012 2013 Master Practical Master Budget Capacity Budget (1) (2) (3) $1,533,000 $1,533,000 $1,533,000 1,022,000 1,460,000 876,000
$ 1.50 4.50 $ 6.00
$ 1.05 4.50 $ 5.55
$ 1.75 4.50 $ 6.25
The 2012 budgeted fixed costs are $1,533,000. Deliman budgets for 1,022,000 meals in 2012, and this is used as the denominator level to calculate the fixed cost per meal. $1,533,000 1,022,000 = $1.50 fixed cost per meal. (see column (1) in Solution Exhibit 9‐32).
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9‐32 (cont’d) 2.
3.
In 2013, 3 hospitals have dropped out of the purchasing group and the master budget is 876,000 meals. If this is used as the denominator level, fixed cost per meal = $1,533,000 876,000 = $1.75 per meal, and the total budgeted cost per meal would be $6.25 (see column (3) in Solution Exhibit 9‐32). If the hospitals have already been complaining about quality and cost and are allowed to purchase from outside, they will not accept this higher price. More hospitals may begin to purchase meals from outside the system, leading to a downward demand spiral, possibly putting Deliman out of business. The basic problem is that Deliman has excess capacity and the associated excess fixed costs. If Smith uses the practical capacity of 1,460,000 meals as the denominator level, the fixed cost per meal will be $1.05 (see column (2) in Solution Exhibit 9‐32), and the total budgeted cost per meal would be $5.55, probably a more acceptable price to the customers (it may even draw back the three hospitals that have chosen to buy outside). This denominator level will also isolate the cost of unused capacity and not allocate it to the meals produced. To make the $5.55 price per meal profitable in the long run, Smith will have to find ways to either use the extra capacity or reduce Deliman’s practical capacity and the related fixed costs.
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9‐33 (30 min.) Effects of differing production levels on absorption costing income: Metrics to minimize inventory buildups. 1.
10,000 12,000 16,000 books books books Revenue $1,000,000 $1,000,000 $1,000,000 Cost of goods sold 720,000a 720,000 720,000 Production‐volume variance 0b ( 24,000)c (72,000)d Net cost of goods sold 720,000 696,000 648,000 Gross Margin $ 280,000 $ 304,000 $ 352,000 a cost per unit = ($60 + $120,000/10,000 books) = $72 per book CGS = $72 10,000 = $720,000 b volume variance = Budgeted fixed cost – fixed overhead rate production $120,000 – $12 10,000 books = $0 c volume variance = Budgeted fixed cost – fixed overhead rate production $120,000 – $12 12,000 books = $24,000 d volume variance = Budgeted fixed cost – fixed overhead rate production $120,000 – $12 16,000 books = $72,000 2. 10,000 12,000 16,000 books books books Beginning inventory 0 0 0 16,000 books + Production 10,000 books 12,000 books 10,000 12,000 16,000 ─ Books sold 10,000 10,000 10,000 Ending inventory 0 books 2,000 books 6,000 books × $72 Cost per book × $72 × $72 Cost of Ending Inventory $0 $144,000 $432,000
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9‐33 (cont’d) 3a.
10,000 books
12,000 books
16,000 books
Gross margin $280,000 $304,000 $352,000 (43,200) Less 10% Ending inventory 0 (14,400) $289,600 $308,800 Adjusted gross margin $280,000
While adjusting for ending inventory does to some degree mitigate the increase in inventory associated with excess production, it may be difficult to mechanically compensate for all of the increased income. In addition, it does nothing to hold the manager responsible for the poor decisions from the organization’s standpoint. 3b.
10,000 books
12,000 books
1) Inventory change: End inventory ─ begin inventory 0 2,000 books 2) Excess production (%) Production ÷ sales 10000 ÷ 10,000 12000 ÷ 10000 1.0 1.2
16,000 books 6,000 books
16000 ÷10000 1.6
A ratio of ending inventory to beginning inventory, as suggested in the book, is not possible since beginning inventory was 0, so we substituted change in inventory level. For these nonfinancial measures to be useful they must be incorporated into the reward function of the manager.
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9‐34
(40 min.) Variable costing and absorption costing, The All‐Fixed Company.
This problem always generates active classroom discussion. 1. The treatment of fixed manufacturing overhead in absorption costing is affected primarily by what denominator level is selected as a base for allocating fixed manufacturing costs to units produced. In this case, is 10,000 tons per year, 20,000 tons, or some other denominator level the most appropriate base? We usually place the following possibilities on the board or overhead projector and then ask the students to indicate by vote how many used one denominator level versus another. Incidentally, discussion tends to move more clearly if variable‐costing income statements are discussed first, because there is little disagreement as to computations under variable costing. a. Variable‐Costing Income Statement: 2012 2013 Together Revenue (and contribution $300,000 $300,000 $600,000 margin) Fixed costs: Manufacturing costs $280,000 Operating costs 40,000 320,000 320,000 640,000 Operating income $ (20,000) $ (20,000) $ (40,000)
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9‐34 (cont’d) b. Absorption‐Costing Income Statement: The ambiguity about the 10,000‐ or 20,000‐unit denominator level is intentional. IF YOU WISH, THE AMBIGUITY MAY BE AVOIDED BY GIVING THE STUDENTS A SPECIFIC DENOMINATOR LEVEL IN ADVANCE. Alternative 1. Use 20,000 units as a denominator; fixed manufacturing overhead per unit is $280,000 20,000 = $14. 2012 2013 Together Revenue $300,000 $ 300,000 $600,000 Cost of goods sold * Beginning inventory 0 140,000 0 Allocated fixed manufacturing costs at 280,000 — 280,000 $14 Deduct ending inventory (140,000) — — Adjustment for production‐volume 0 280,000 U 280,000 U variance 420,000 560,000 Cost of goods sold 140,000 Gross margin 160,000 (120,000) 40,000 40,000 80,000 Operating costs 40,000 Operating income $120,000 $(160,000) $ (40,000)
*
Inventory carried forward from 2012 and sold in 2013.
Alternative 2. Use 10,000 units as a denominator; fixed manufacturing overhead per unit is $280,000 10,000 = $28. 2012 Revenue $300,000 Cost of goods sold Beginning inventory 0 Allocated fixed manufacturing costs at $28 560,000 Deduct ending inventory (280,000) Adjustment for production‐volume variance (280,000) F Cost of goods sold 0 Gross margin 300,000 Operating costs 40,000 Operating income $260,000 *Inventory carried forward from 2012 and sold in 2013.
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2013 $300,000 280,000* — — 280,000 U 560,000 (260,000) 40,000 $(300,000)
Together $600,000 0 560,000 — 0 560,000 40,000 80,000 $ (40,000)
Chapter 9
9‐34 (cont’d) Note that operating income under variable costing follows sales and is not affected by inventory changes. Note also that students will understand the variable‐costing presentation much more easily than the alternatives presented under absorption costing. Breakeven point $320,000 Fixed costs under variable = 2. = Contributi on margin per ton $30 costing = 10,667 (rounded) tons per year or 21,334 for two years. If the company could sell 667 more tons per year at $30 each, it could get the extra $20,000 contribution margin needed to break even. Most students will say that the breakeven point is 10,667 tons per year under both absorption costing and variable costing. The logical question to ask a student who answers 10,667 tons for variable costing is: “What operating income do you show for 2008 under absorption costing?” If a student answers $120,000 (alternative 1 above), or $260,000 (alternative 2 above), ask: “But you say your breakeven point is 10,667 tons. How can you show an operating income on only 10,000 tons sold during 2012?” The answer to the above dilemma lies in the fact that operating income is affected by both sales and production under absorption costing. Given that sales would be 10,000 tons in 2012, solve for the production level that will provide a breakeven level of zero operating income. Using the formula in the chapter, sales of 10,000 units, and a fixed manufacturing overhead rate of $14 (based on $280,000 ÷ 20,000 units denominator level = $14): Let P = Production level Target Fixed manuf. Breakeven Units Total fixed operating overhead sales in produced Breakeven costs income rate units sales = Unit contribution margin in units $320‚000 $0 $14(10‚000 P) 10,000 tonnes = $30 $300,000 = $320,000 + $140,000 – $14P $14P = $160,000 P = 11,429 units (rounded)
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9‐34 (cont’d) Proof: Gross margin, 10,000 × ($30 – $14) $160,000 Production‐volume variance, (20,000 – 11,429) × $14 $119,994 Marketing and administrative costs 40,000 159,994 Operating income (due to rounding) $ 6 Given that production would be 20,000 tons in 2012, solve for the breakeven unit sales level. Using the formula in the chapter and a fixed manufacturing overhead rate of $14 (based on a denominator level of 20,000 units): Let N = Breakeven sales in units Target Fixed manuf. Units Total fixed operating overhead N produced costs income rate N = Unit contribution margin $320,000 + $0 + $14(N 20,000) N = $30 $30N = $320,000 + $14N – $280,000 $16N = $40,000 N = 2,500 units Proof: Gross margin, 2,500 × ($30 – $14) $40,000 Production‐volume variance $ 0 40,000 Marketing and administrative costs 40,000 Operating income $ 0 We find it helpful to put the following comparisons on the board: Variable costing breakeven = f(sales) = 10,667 tons Absorption costing breakeven = f(sales and production) = f(10,000 and 11,429) = f(2,500 and 20,000)
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9‐34 (cont’d) 3. 4.
Absorption costing inventory cost: Either $140,000 or $280,000 at the end of 2012 and zero at the end of 2013. Variable costing: Zero at all times. This is a major criticism of variable costing and focuses on the issue of the definition of an asset. Operating income is affected by both production and sales under absorption costing. Hence, most managers would prefer absorption costing because their performance in any given reporting period, at least in the short run, is influenced by how much production is scheduled near the end of a period.
9‐35 1. 2.
Variable and absorption costing, and breakeven points.
Production = Sales + Ending Inventory – Beginning Inventory = 242,400 + 24,800 – 32,600 = 234,600 Breakeven point in cases: a. Variable Costing: Total Fixed Costs + Target Operating Income Q = Contribution Margin per Unit ($4,504,320 + $7,882,560) + $0 Q = $112.80 – ($19.20 + $12.00 + $7.20 + $16.80 + $2.40) $12,386,880 Q = $55.20 Q = 224,400 cases
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9‐35 (cont’d) b.
Absorption Costing: Total Fixed Breakeven Target Fixed Units Q = + + Manuf. Cost × Sales in Units – Produced Cost OI Rate Contribution Margin per Unit
Q = Q = Q = 3.
$12,386,880 + [$19.201 (Q – 234,600)] $55.20 $12,386,880 + $19.20Q – 4,504,320 $55.20 $7,882,560 + $19.20Q $55.20
55.20Q – 19.20Q = $7,882,560 36Q = $7,882,560 Q = 218,960 cases
1
$4,504,320 ÷ 234,600 cases = $19.20
If grape prices increase by 25%, the cost of grapes per case will increase from $19.20 in 2013 to $24 in 2014. This will decrease the unit contribution margin from $55.20 in 2013 to $50.40 in 2014.
a.
b.
Variable Costing: $12,386,880 Q = $50.40 = 245,772 cases (rounded up) Absorption Costing: $7,882,560 + $19.20Q Q = $50.40 $50.40Q = $7,882,560 + $19.20Q $31.20Q = $7,882,560 Q = 252,647 cases (rounded up)
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9‐35 (cont’d) 4.
Variable Costing: OI 2014 = $242,400 – 224,400) ×CM = (18,000) × (Revenue – Variable Costs) = (18.000) × ($55.20 = $993,600 Variable costing: $993,600 × 110% = $1,092,960 OI Variable costing: Required OI = $1,092,960 in 2014 Breakeven = 245,772 cases (from question 3a.) 1) OI = $1,092,960 2) CM = $50.40 Required Sales = (BE + 1) ÷ 2 = (245,772 + 1,092,960) ÷ 50.40 = 247,772 + 21,686 = 267,458 cases (rounded up) Absorption Costing: $12,386,880 + $1,092,960 + $19.20 (Q – 234,600) Q = $50.40 31.20Q = 8,975.520 Q = 287,677 (rounded)
9‐36 (30–35 min.) Comparison of variable costing and absorption costing. 1.
Since production volume variance is unfavourable, the budgeted fixed manufacturing overhead must be larger than the fixed manufacturing overhead allocated.
Production ‐ volume = variance
Budgeted fixed Fixed manufacturing – manufacturing overhead overhead allocated
$400,000
=
$1,200,000 – Allocated
Allocated
=
$800,000, which is 67% of $1,200,000
If 67% of the budgeted fixed costs were allocated, the plant must have been operating at 67% of denominator level in 2013.
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9‐36 (cont’d) 2.
The problem provides the beginning and ending inventory balances under both, variable and absorption costing. Under variable costing, all fixed costs are written off as period costs, i.e., they are not inventoried. Under absorption costing, inventories include variable and fixed costs. Therefore the difference between inventory under absorption costing and inventory under variable costing is the amount of fixed costs included in the inventory.
Inventories: December 31, 2012 December 31, 2013 3.
Fixed Manuf. Absorption Variable Overhead Costing Costing in Inventory $1,720,000 $1,200,000 $520,000 206,000 66,000 140,000
Note that the answer to (3) is independent of (1). The difference in operating income of $380,000 ($1,520,000 – $1,140,000) is explained by the release of $380,000 of fixed manufacturing costs when the inventories were decreased during 2013: Fixed Manuf. Absorption Variable Overhead Costing Costing in Inventory Inventories: December 31, 2012 $1,720,000 $1,200,000 $520,000 December 31, 2013 206,000 66,000 140,000 Release of fixed manuf. costs $380,000 The above schedule in this requirement is a formal presentation of the equation:
Absorpting Variable costing – costing = operating operating income income
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Fixed Fixed manuf. costs in – manuf. costs in beginning ending inventory inventory
($1,140,000 – $1,520,000) = ($140,000 – $520,000) – $380,000 = – $380,000 Alternatively, the presence of fixed manufacturing overhead costs in each income statement can be analyzed:
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Chapter 9
9‐36 (cont’d) Absorption costing, Fixed manuf. costs in cost of goods sold ($5,860,000 − $4,680,000) $1,180,000 Production‐volume variance 400,000 1,580,000 Variable costing, fixed manuf. costs charged to expense (1,200,000) Difference in operating income explained $ 380,000 4.
Under absorption costing, operating income is a function of both sales and production (i.e., change in inventory levels). During 2013 Hinkle experienced a severe decline in inventory levels: sales were probably higher than anticipated, production was probably lower than planned (at 67% of denominator level), resulting in much of the 2013 beginning inventory passing through cost of goods sold in 2013. This means that under absorption costing, large amounts of inventoried fixed costs have flowed through 2013 cost of goods sold, resulting in a smaller operating income than in 2012, despite an increase in sales volume.
9‐37 (40 min.) Variable costing versus absorption costing. 1.
Absorption Costing: Mavis Company Income Statement For the Year Ended December 31, 2013 Revenue (540,000 × $5.00) $2,700,000 Cost of goods sold: a $ 111,000 Beginning inventory (30,000 × $3.70 ) Variable manufacturing costs (550,000 × $3.00) 1,650,000 Allocated fixed manufacturing costs (550,000 × $0.70) 385,000 Cost of goods available for sale 2,146,000 Deduct ending inventory (40,000 × $3.70) (148,000) Add adjustment for prod.‐vol. variance (50,000b × $0.70) 35,000 U Cost of goods sold 2,033,,000 Gross margin 667,000 Operating costs: Variable operating costs (540,000 × $1) 540,000 Fixed operating costs 120,000 Total operating costs 660,000 Operating income $ 7,000
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9‐37 (cont’d) a $3.00 + ($7.00 ÷ 10) = $3.00 + $0.70 = $3.70 b [(10 units per mach. hr. × 60,000 mach. hrs.) – 550,000 units)] = 50,000 units
2.
unfavourable Variable Costing: Mavis Company Income Statement For the Year Ended December 31, 2013 Revenue Variable cost of goods sold: Beginning inventory (30,000 × $3.00) Variable manufacturing costs (550,000 × $3.00) Cost of goods available for sale Deduct ending inventory (40,000 × $3.00) Variable cost of goods sold Variable operating costs Contribution margin Fixed costs: Fixed manufacturing overhead costs Fixed operating costs Total fixed costs Operating income
$2,700,000
$ 90,000 1,650,000 1,740,000 (120,000)
1,620,000 540,000 540,000
420,000 120,000
540,000 $ 0
3.
The difference in operating income between the two costing methods is:
Fixed Absorption‐ Variable‐ Fixed costing – costing = manuf. costs – manuf. costs operating operating in ending in beginning income inventory income inventory
$7,000 – $0 = [(40,000 × $0.70) – (30,000 × $0.70)] $7,000 = $28,000 – $21,000 $7,000 = $7,000 The absorption‐costing operating income exceeds the variable costing figure by $7,000 because of the increase of $7,000 during 2009 of the amount of fixed manufacturing costs in ending inventory vis‐a‐vis beginning inventory.
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9‐37 (cont’d) 4. Total fixed manufacturing costs
Actual and budget line $420,000 $385,000
Unfavorable production-volume variance
productionvolume variance } Favorable
{
55,000
Allocated line @ $7.00
60,000
Machine-hours
5.
Absorption costing is more likely to lead to buildups of inventory than does variable costing. Absorption costing enables managers to increase reported operating income by building up inventory which reduces the amount of fixed manufacturing overhead included in the current period’s cost of goods sold. Ways to reduce this incentive include (a) Careful budgeting and inventory planning. (b) Change the accounting system to variable costing or throughput costing. (c) Incorporate a carrying charge for carrying inventory. (d) Use a longer time period to evaluate performance than a quarter or a year. (e) Include nonfinancial as well as financial measures when evaluating management performance.
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9‐38 (30‐35 min.) 1.
Effects of denominator.
Normal capacity utilization. Givens denoted*
Actual Costs Incurred (1) $52,000
a
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Same Budgeted Lump Sum (as in Static Budget) Regardless of Output Level (2) $48,000*
$4,000 U* Rate variance
Flexible Budget: Same Budgeted Lump Sum (as in Static Budget) Regardless of Output Level (3) $48,000*
Allocated: Budgeted Input Allowed for Actual Output × Budgeted Rate (4) a
28,000 hrs.* × $2.00 = $56,000 $8,000 F* Never a variance Prodn. volume variance
Production Fixed overhead allocated Budgeted volume = fixed – using budgeted input allowed for variance actual output achieved overhead – $8,000 = ($48,000 – X) X = $56,000
Budgeted fixed manufacturing = $56,000 ÷ 28,000 machine‐hours overhead rate per unit = $2 per machine‐hour Denominator level = $48,000 ÷ $2 per machine‐hour = 24,000 machine‐hours
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Chapter 9
9‐38 (cont’d) 2.
Practical capacity. Givens denoted* Actual Costs Incurred (1) $52,000
3.
Same Lump Sum (as in Static Budget) Regardless of Budgeted Output Level (2) $48,000*
$4,000 U* Rate variance
Flexible Budget: Same Lump Sum (as in Static Budget) Regardless of Budgeted Output Level (3) $48,000*
Allocated: Budgeted Input Allowed for Actual Output × Budgeted Rate (4) a
28,000* × $1.20 = $33,600 $14,400 U* Never a variance Prodn. volume variance
Fixed overhead allocated Budgeted Production‐volume fixed = – using budgeted input allowed for variance actual output achieved overhead $14,400 = ($48,000 – X) X = $33,600 a Budgeted manufacturing = $33,600 ÷ 28,000 machine‐hours overhead rate per unit = $1.20 per machine‐hour Denominator level = $48,000 ÷ $1.20 per machine‐hour = 40,000 machine‐hours To maximize operating income, the executive vice president would favour using normal capacity utilization rather than practical capacity. Why? Because normal capacity utilization is a smaller base than practical capacity, resulting in any year‐end inventory having a higher unit cost. Thus, less fixed manufacturing overhead would become a 2013 expense as part of the production‐volume variance if normal capacity utilization were used as the denominator level.
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9‐39 (20 min.) Cost allocation, responsibility accounting, ethics. 1.
(See Solution Exhibit 9‐32). If Deliman uses its master budget capacity utilization to allocate fixed costs in 2013, it would allocate 806,840 $1.75 = $1,411,970. Budgeted fixed costs are $1,533,000. Therefore, the production volume variance = $1,533,000 – $1,411,970 = $121,030 U. An unfavourable production volume variance will reduce operating income by this amount. (Note: in this business, there are no inventories. All variances are written off to cost of goods sold).
2.
Hospitals are charged a budgeted variable cost rate and allocated budgeted fixed costs. By overestimating budgeted meal counts, the denominator‐level is larger, hence the amount charged to individual hospitals is lower. Consider 2013 where the budgeted fixed cost rate is computed as follows:
$1,533,000/876,000 meals = $1.75 per meal If in fact, the hospital administrators had better estimated and revealed their true demand (say, 806,800 meals), the allocated fixed cost per meal would have been
$1,533,000/806,800 meals = $1.90 per meal, 8.6% higher than the $1.75 per meal. Hence, by deliberately overstating budgeted meal count, hospitals are able to reduce the price charged by Deliman for each meal. In this scheme, Deliman bears the downside risk of demand overestimates.
3.
Evidence that could be collected include: (a) Budgeted meal‐count estimates and actual meal‐count figures each year for each hospital controller. Over an extended time period, there should be a sizable number of both underestimates and overestimates. Controllers could be ranked on both their percentage of overestimation and the frequency of their overestimation. (b) Look at the underlying demand estimates by patients at individual hospitals. Each hospital controller has other factors (such as hiring of nurses) that give insight into their expectations of future meal‐count demands. If these factors are inconsistent with the meal‐count demand figures provided to the central food‐catering facility, explanations should be sought.
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9‐39 (cont’d) 4.
(a)
(b)
(c)
Highlight the importance of a corporate culture of honesty and openness. Deli One could institute a Code of Ethics that highlights the upside of individual hospitals providing honest estimates of demand (and the penalties for those who do not). Have individual hospitals contract in advance for their budgeted meal count. Unused amounts would be charged to each hospital at the end of the accounting period. This approach puts a penalty on hospital administrators who overestimate demand. Use an incentive scheme that has an explicit component for meal‐count forecasting accuracy. Each meal‐count “forecasting error” would reduce the bonus by $0.05. Thus, if a hospital bids for 292,000 meals and actually uses 200,000 meals, its bonus would be reduced by $0.05 × (292,000 – 200,000) = $4,600.
9‐40 (55 min.) Variable and absorption costing and breakeven points 1a. 2013 Variable‐Costing Based Operating Income Statement Revenues (800 cat trees x $300 per tree) Variable costs Beginning inventory Variable manufacturing costs (1,000 trees $75 per tree.) Cost of goods available for sale Deduct: Ending inventory (200 trees $75 per tree) Variable cost of goods sold Variable shipping costs (800 trees $25 per tree) Total variable costs Contribution margin Fixed costs Fixed manufacturing costs Fixed selling and administrative Total fixed costs Operating income
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$ 0 75,000 75,000 (15,000) 60,000 20,000 100,000 50,000
$240,000 80,000 160,000 150,000 $ 10,000
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9‐40 (cont’d) 1b. 2013Absorption‐Costing Based Operating Income Statement Revenues (800 cat trees x $300 per tree) Cost of goods sold Beginning inventory $ 0 Variable manufacturing costs (1,000 trees. $75 per tree) 75,000 Allocated fixed manufacturing costs (1,000 trees $100* per tree) 100,000 Cost of goods available for sale 175,000 (35,000) Deduct ending inventory (200 trees ($75 + $100) per tree) Cost of goods sold Gross margin Operating costs 20,000 Variable marketing costs (800 trees $25 per pkg.) Fixed selling and administrative 50,000 Total operating costs Operating income *Fixed manufacturing rate = Fixed manufacturing cost/production = $100,000/1000 trees = $100 per tree 2. Breakeven point in units: a. Variable Costing: Total Fixed Costs Target Operating Income QT = Contributi on Margin Per Unit ($100,000 $50,000) $0 QT = $300 ($75 $25) QT QT
$150,000 $200 = 750 cat trees =
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$240,000 140,000 100,000 70,000 $ 30,000
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9‐40 (cont’d)
b. QT
Absorption costing: Fixed manufacturing cost rate = $100,000 ÷ 1,000 = $100 per cat tree Total Fixed Target Fixed Manuf. Breakeven Units Cost Rate Cost OI Sales in Units Produced = Contribution Margin Per Unit
QT
=
$150,000 $100 (QT 1,000) $200
QT
=
$150, 000 $100 QT $100,000 $200
3.
$200 QT $100 QT = $150,000 – $100,000 $100 QT = $50,000 QT = 500 cat trees Breakeven point in units: a. Variable Costing:
QT
=
Total Fixed Costs Target Operating Income Contributi on Margin Per Unit
=
($100,000 $50,000) $0 $300 ($100 $25)
=
$150,000 $175
QT QT QT
= 857.14 cat trees
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9‐40 (cont’d) b.
QT
Absorption costing: Fixed manufacturing cost rate = $100,000 ÷ 1,000 = $100 per cat tree
QT
=
$150,000 $100 (QT 1,000) $175
QT
=
$150, 000 $100 QT $100,000 $175
$175 QT $100 QT = $150,000 – $100,000 $75 QT = $50,000 QT = 666.66 cat trees
4.
Units needed to achieve target operating income: a. Variable Costing: QT
=
Total Fixed Costs Target Operating Income Contributi on Margin Per Unit
=
($100,000 $50,000) $10,000 $300 ($75 $25)
=
$160,000 $200
QT QT QT
= 800 cat trees
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Total Fixed Target Fixed Manuf. Breakeven Units Cost Rate Cost OI Sales in Units Produced = Contribution Margin Per Unit
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Chapter 9
9‐40 (cont’d)
b.
QT
Absorption costing: Fixed manufacturing cost rate = $100,000 ÷ 1,000 = $100 per cat tree
QT
=
$150,000 $30,000 $100 (QT 1,000) $200
QT
=
$180, 000 $100 QT $100,000 $200
Total Fixed Target Fixed Manuf. Breakeven Units Cost Rate Cost OI Sales in Units Produced = Contribution Margin Per Unit
$200 QT $100 QT = $180,000 – $100,000 $100 QT = $80,000 QT = 800 cat trees
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COLLABORATIVE LEARNING CASES
9‐41 (50 min.) Absorption, variable, and throughput costing 1.
Variable Costing Revenuea Variable costs Beginning inventoryb Variable manufacturing costsc Cost of goods available for sale Deduct ending inventoryd Variable cost of goods sold Variable selling costse Total variable costs Contribution margin Fixed costs Fixed manufacturing costs Fixed administrative costs Total fixed costs Operating income
April 2013 $300,000 $ 0 77,500 77,500 0 77,500 7,500 85,000 215,000 105,000 35,000 140,000 $ 75,000
May 2013 $300,000 $ 0 108,500 108,500 (31,000) 77,500 7,500 85,000 215,000 105,000 35,000 140,000 $ 75,000
a $6 × 50,000 b ? × 0; $1.55 × 0; $1.55 × 20,000 c $1.55 × 50,000; $1.55 × 70,000; $1.55 × 30,000 d $1.55 × 0; $1.55 × 20,000; $1.55 × 0 e $.15 × 50,000
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June 2013 $300,000 $ 31,000 46,500 77,500 0 77,500 7,500 85,000 215,000 105,000 35,000 140,000 $ 75,000
Chapter 9
9‐41 (cont’d) 2. Absorption Costing Revenuea Cost of goods sold Beginning inventoryb Variable manufacturing costsc Allocated fixed manufacturing costsd Cost of goods available for sale Deduct ending inventorye Adjustment for prod. vol. var.f Cost of goods sold Gross margin Operating costs Variable selling costsg Fixed administrative costs Total operating costs Operating income a $6 × 50,000
April 2013 $300,000 $ 0 77,500 105,000 182,500 0 0 182,500 117,500 7,500 35,000 42,500 $ 75,000
May 2013 June 2013 $300,000 $300,000 $ 0 $ 61,000 108,500 46,500 105,000 105,000 213,500 212,500 (61,000) 0 30,000 U 0 152,500 212,500 147,500 87,500 7,500 35,000
42,500 $105,000
7,500 35,000
42,500 $ 45,000
$?× 0; $3.65× 0; $3.05 × 20,000 $1.55 × 50,000; $1.55 × 70,000; $1.55 × 30,000 d ($105,000/50,000)×50,000; ($105,000/70,000) ×70,000; (105,000/30,000)×30,000 e $3.65 × 0; $3.05 × 20,000; $5.05 × 0 f $105,000 – $105,000; $105,000 – $105,000; $105,000 – $105,000 g $.15 × 50,000 b c
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9‐41 (cont’d) 3.
Throughput costing Revenuea Direct material cost of goods sold Beginning inventoryb Direct materials in goods manufacturedc Cost of goods available for sale Deduct ending inventoryd Total direct material cost of goods sold
April 2013 $300,000 $ 0 40,000 40,000 0 40,000
May 2013 June 2013 $300,000 $300,000 $ 0 $ 16,000 56,000 24,000 56,000 40,000 (16,000) 0 40,000 40,000
Throughput contribution Other costs Manufacturinge Operatingf Total other costs Operating income
142,500 42,500
157,500 42,500
260,000 185,000 $ 75,000
$6 × 50,000 b $?× 0; $0.80× 0; $0.80 × 20,000 c $0.80 × 50,000; $0.80 × 70,000; $0.80 × 30,000 d $0.80 × 0; $0.80 × 20,000; $0.80 × 0 e ($0.75 × 50,000) + $105,000; ($0.75× 70,000) + $105,000; ($0.75 × 30,000) + $105,000 f ($0.15 × 50,000) + $35,000 a
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260,000
200,000 $ 60,000
127,500 42,500
260,000
170,000 $ 90,000
Chapter 9
9‐41 (cont’d) 4.
The benefit of using throughput costing is that net income is reduced if managers produce more units than they can sell. By treating all costs, except direct material costs, as period costs, the income statement expenses not only the cost of goods sold but also the direct labour and variable overhead costs associated with units in ending inventory. So reported income is reduced by the cost of unnecessary production. For performance evaluation purposes, variable costing is superior to absorption costing because it prevents managers from increasing income by just increasing production. In the same way, throughput costing may be considered superior to variable costing because not only is management not rewarded for producing more than can be sold, they are penalized for excess production. In this example, income is highest when management produced less than demand and therefore reduced inventory that already existed.
9‐42
Capacity‐level (denominator) choices.
1. Denominator‐ Level Capacity Theoretical Capacity Practical Capacity Normal Capacity Master‐budget Capacity Jan – Jun 2012 Jul – Dec 2012
Budgeted Fixed Manufacturing Overhead Per Period $50,000,000 $50,000,000 $50,000,000 $25,000,000 $25,000,000
Budgeted Denominator Level 5,256,000 3,500,000 2,800,000 1,120,000 1,680,000
Budgeted Fixed Manufacturing Overhead Cost Rate $ 9.51 $ 14.29 $ 17.86 $ 22.32 $ 14.88
The differences arise for several reasons: a. The theoretical and practical capacity concepts emphasize supply factors, while normal capacity utilization and master‐budget capacity utilization emphasize demand factors. b. The two separate six‐month rates for the master‐budget capacity utilization concept differ because of seasonal differences in budgeted production.
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9‐42 (cont’d) 2. Theoretical capacity—based on the production of output at maximum efficiency for 100% of the time. Practical capacity—reduces theoretical capacity for unavoidable operating interruptions such as scheduled maintenance time, shutdowns for holidays and other days, and so on. For each of the three determinants of capacity in Lucky Lager’s plant, practical capacity is less than theoretical capacity: Capacity Barrels per Working Working Type Hour Hrs./Day Days/Year Capacity Theoretical 600 24 365 5,256,000 Practical 500 20 350 3,500,000 3. The smaller the denominator, the higher will be the amount of overhead costs capitalized for inventory units. Thus, if the plant manager wishes to be able to “adjust” plant operating income by building inventory, master‐budget capacity utilization or possibly normal capacity utilization would be preferred. 4. Inventoriable cost per unit = Variable production cost + Fixed manufacturing overhead/Capacity Fixed Mfg. Variable Capacity Capacity Fixed Mfg. Overhead Production Inventoriable Type Level Overhead Rate Cost Cost Per Unit Theoretical 5,256,000 $50,000,000 $9.51 $51.40 $60.91 Practical 3,500,000 $50,000,000 $14.29 $51.40 $65.69 Normal 2,800,000 $50,000,000 $17.86 $51.40 $69.26 Lucky Lager’s actual production level is 2,600,000 barrels. We can compute the production‐volume variance as:
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9‐42 (cont’d) Production Volume Variance = Budgeted Fixed Mfg. Overhead – (Fixed Mfg. Overhead Rate × Actual Production Level)
Fixed Mfg. Overhead Fixed Mfg. Rate × Overhead Actual Rate Production $9.51 $ 24,726,000 $14.29 $ 37,154,000 $17.86 $ 46,436,000
Production Volume Variance $25,274,000 U $12,846,000 U $ 3,564,000 U
Capacity Capacity Fixed Mfg. Type Level Overhead Theoretical 5,256,000 $50,000,000 Practical 3,500,000 $50,000,000 Normal 2,800,000 $50,000,000 Operating Income for Lucky Lager given production of 2,600,000 barrels and sales of 2,400,000 barrels @ $82 apiece: Theoretical Practical Normal Revenue $196,800,000 $196,800,000 $196,800,000 a Less: Cost of goods sold 146,184,000 157,656,000 166,224,000 Production‐volume variance 25,274,000U 12,846,000U 3,564,000 U Rate variance 1,241,600F 1,241,600F 1,241,600F Gross margin 24,100,400 25,056,400 25,770,400 b Variable selling 0 0 0 Fixed selling 0 0 0 $25,056,000 $25,770,400 Operating income $24,100,400 a2,400,000 × 60.91, × 65.69, × 69.26 b None, internal transfer. 5. Based on the calculations above, theoretical would be preferred, as normal has a higher dollar‐value level of inventory left thus increasing tax burden. 6. CRA requires consistency in use of method; master‐budget capacity.
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CHAPTER 10 QUANTITATIVE ANALYSES OF COST FUNCTIONS
SHORT‐ANSWER QUESTIONS
10‐1 The two assumptions are 1. 2.
Changes in the level of a single direct input used or an activity (the cost driver) explain the changes in the related total costs. Cost behaviour is estimated by a continuous, linear cost function within the relevant range. Within the relevant range, the graph of data pairs of total quantity used and total MOH cost can be joined and will form a straight line.
10‐2 Three alternative linear cost functions are 1.
2.
3.
Variable cost function––a cost function in which total costs change in proportion to the changes in the level of activity or resources consumed within the relevant range. Fixed cost function––a cost function in which total costs do not change with changes in the level of activity, inputs consumed or outputs produced in the relevant range of production. Mixed cost function––a cost function that has both variable and fixed costs accumulated from using many different types of resources. Total costs change but cannot be fully explained by changes in the level of a single activity or quantity of single direct input used.
10‐3 The first step is to identify the dependent variable (Y) throughout some time period and then develop a correlation with one or more likely independent variables (X) throughout the same time period in preparation for developing a predictive model. Together the values form an (X,Y) pair of actual data points that have actually occurred. These are called time‐series data.
10‐4 No. High correlation merely indicates that changes in (X) correspond to changes in the (Y) data. It does not matter how high this correlation is, no inference can ever be made about a cause and effect relationship. Even a strong or high correlation can be a coincidence. The management team must consider how well the correlation reflects what actually happens in a production process. This is economic plausibility. Without any economic plausibility, any predictions of future cost (y) will be just a guess and therefore irrelevant to any management decision making. Should the management team mistakenly use just the results without thinking about their economic plausibility any predictions made will be unreliable.
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10‐5 A discontinuous linear cost function will either have different slopes throughout the relevant range, or will be a series of horizontal lines with zero slope throughout the relevant range. Some types of analyses that can be done to improve cost control include the industrial engineering method, conference method, account analysis method, and quantitative analyses (high‐low, ordinary least squares linear regression).
10‐6 Four approaches to estimating a cost function are 1. 2. 3. 4.
Industrial engineering method. Conference method. Account analysis method. Quantitative analysis of current or past cost relationships.
10‐7 The conference method estimates cost functions on the basis of analysis and opinions about costs and their drivers gathered from various departments of a company (purchasing, process engineering, manufacturing, employee relations, etc.). Advantages of the conference method include 1. The speed with which cost estimates can be developed. 2. The pooling of knowledge from experts across functional areas. 3. The improved credibility of the cost function to all personnel.
10‐8 The cost driver (X) is the predictor variable and when using the high‐low method you base the observations on the high and low values of (X). The cost pool is the outcome variable (Y). The reason is that based on economic plausibility, changes in the predictor variable are supposed to explain changes in the outcome variable, not the reverse.
10‐9 The goal of an OLS linear regression is to select the best cost driver from all the existing data available in a traditional costing system, which will most reliably predict the values of the MOH cost pool.
10‐10 Three criteria important when choosing among alternative cost functions are 1. 2. 3.
Economic plausibility. Goodness of fit (the explanatory power measured as r2). Confidence level (either 95% or 99%).
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10‐11 The goodness of fit is mathematically calculated as a straight line that minimizes the sum of the differences squared between the actual data points (X,Y) and the corresponding predicted data points on the linear regression line (X, y). The smaller this sum is, the higher will be the proportion of changes in y explained by corresponding changes in X. The proportion is reported by the coefficient of determination, measured by r2 in decimal form such as 0.32 . This means that 32% of the changes in predicted y can be explained by corresponding actual, historical changes in X. All other things equal the cost driver with the higher r2 will be the better choice.
10‐12 This is not true. Some of the predictor variables may report the effect of predictable changes in the business environment on the changes in the MOH cost pool. Examples include temperature, seasonal demand, foreign currency exchange rates and inflation.
10‐13 Frequently encountered problems when collecting cost data on variables included in a cost function are 1. The time period used to measure the outcome variable (MOH cost pool) is not properly matched with the time period used to measure the predictor variable (cost driver(s)). 2. Fixed costs are allocated as if they were variable. 3. Data are either not available for all observations or are not uniformly reliable. 4. Extreme values of either X or Y occur due to random events, unlikely to recur. 5. A homogeneous relationship between the individual cost items in the dependent variable cost pool and the cost driver(s) does not exist. 6. The relationship between the cost and the cost driver is not stationary over time. 7. Inflation has occurred in a dependent variable, a cost driver, or both.
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EXERCISES
10‐14 (10 min.)
Terminology.
There are several methods of quantitative analysis that a management team can use to predict the value of a single overhead cost pool in a traditional costing system. The methods are: account analysis method, conference method, high‐low method, industrial engineering method, ordinary least squares (OLS) simple linear regression method. There are different criteria to consider when choosing a method of analysis which are: affordability, understandability, data availability and quality, explanatory power, and economic plausibility. The relationship between cost of unequally shared resources used in production, and their benefit to distinct types of cost objects must be economically plausible.. The change in quantity of resources used must be a good measure of change in benefit. The relationship must be a linear cost function if OLS simple linear regression analysis is to be used. Ideally, the OLS will be based on at least 25 data points observed and reported in the past as a timeseries. If insufficient data are available then the other methods of analysis will help the management team predict the value of the indirect cost pool. When true, the orderly change in the quantity of resource used will explain a large proportion of the change in the indirect cost pool. This is called explanatory power. A high explanatory power indicates a high correlation between the change in the measure of benefit or the predictor variable, X, and the change in the predicted indirect cost pool or outcome variable, y. You can observe this in the goodness of fit between the predicted (X,y) line and the actual data points (X,Y)from which the prediction was made. The measure of goodness of fit is called r2. Other important statistics that assess the reliability of the predicted regression line are the t‐stat and P value. While the OLS is a very rigorous analysis and can predict future values at a specific confidence level, it is not appropriate for all situations.
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10‐15 (10 min.) Estimating a cost function.
1.
Slope coefficient =
Difference in costs Difference in machine‐hours $5, 400 $4,000 = 10,000 6,000 $1, 400 = $0.35 per machine‐hour = 4, 000
2.
Constant = Total cost – (Slope coefficient Quantity of cost driver) = $5,400 – ($0.35 10,000) = $1,900 = $4,000 – ($0.35 6,000) = $1,900
The cost function based on the two observations is Maintenance costs = $1,900 + $0.35 Machine‐hours The cost function in requirement 1 is an estimate of how costs behave within the relevant range, not at cost levels outside the relevant range. If there are no months with zero machine‐hours represented in the maintenance account, data in that account cannot be used to estimate the fixed costs at the zero machine‐ hours level. Rather, the constant component of the cost function provides the best available starting point for a straight line that approximates how a cost behaves within the relevant range.
10‐16 (20 min.) Discontinuous linear cost functions. 1. 2. 3. 4.
5. 6. 7. 8. 9.
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K B G J
I L F K C
Note that A is incorrect because, although the cost per pound eventually equals a constant at $9.20, the total dollars of cost increases linearly from that point onward. The total costs will be the same regardless of the volume level. This is a classic step‐cost function.
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Chapter 10
10‐17
(15 min.) Account analysis method.
1. Variable costs: Car wash labour $260,000 Soap, cloth, and supplies 42,000 Water 38,000 Electric power to move conveyor belt 72,000 Total variable costs $412,000 Fixed costs: Depreciation $ 64,000 Salaries 46,000 Total fixed costs $110,000 Some costs are classified as variable because the total costs in these categories change in proportion to the number of cars washed in Lorenzo’s operation. Some costs are classified as fixed because the total costs in these categories do not vary with the number of cars washed. If the conveyor belt moves regardless of the number of cars on it, the electricity costs to power the conveyor belt would be a fixed cost. $412,000 = $5.15 per car 2. Variable costs per car = 80,000 Total costs estimated for 90,000 cars = $110,000 + ($5.15 × 90,000) = $573,500
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10‐18 (30 min.) Account analysis method. 1.
Manufacturing cost classification for 2012: Account
Direct materials Direct manufacturing labour Power Supervision labour Materials‐handling labour Maintenance labour Amortization Rent, property taxes, admin. Total
Total Costs (1) $300,000 225,000 37,500 56,250 60,000 75,000 95,000 100,000 $948,750
% of Total Costs That is Variable Fixed Variable Costs Costs (2) (3) = (1) (2) (4) = (1) – (3) 100% 100 100 20 50 40 0 0
$300,000 225,000 37,500 11,250 30,000 30,000 0 0 $633,750
$ 0 0 0 45,000 30,000 45,000 95,000 100,000 $315,000
Variable Cost per Unit (5) = (3) ÷ 75,000
$4.00 3.00 0.50 0.15 0.40 0.40 0 0 $8.45
Total manufacturing cost for 2012 = $948,750 Variable costs in 2013: Account
Unit Variable Cost per Unit for 2012 (6)
$4.00 Direct materials 3.00 Direct manufacturing labour 0.50 Power Supervision labour 0.15 Materials‐handling labour 0.40 Maintenance labour 0.40 Amortization 0 Rent, property taxes, admin. 0 Total
$8.45
Increase in Variable Cost per Unit Total Variable Costs Percentage Variable Cost for 2013 Increase per Unit for 2013 (7) (8) = (6) (7) (9) = (6) + (8) (10) = (9) 80,000 5% 10 0 0 0 0 0 0
$0.20 0.30 0 0 0 0 0 0 $0.50
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$4.20 3.30 0.50 0.15 0.40 0.40 0 0
$336,000 264,000 40,000 12,000 32,000 32,000 0 0
$8.95
$716,000
Chapter 10
10‐18 (cont’d) Fixed and total costs in 2013: Account Direct materials Direct manufacturing labour Power Supervision labour Materials‐handling labour Maintenance labour Amortization Rent, property taxes, admin. Total
Dollar Increase in Fixed Costs Variable Fixed Costs Percentage Fixed Costs for 2010 Costs for for 2009 Increase (13) = (14) = 2010 (11) (12) (11) (12) (11) + (13) (15) $ 0 0 0 45,000 30,000 45,000 95,000 100,000 $315,000
0% 0 0 0 0 0 5 7
$ 0 0 0 0 0 0 4,750 7,000 $11,750
$ 0 0 0 45,000 30,000 45,000 99,750 107,000 $326,750
$336,000 264,000 40,000 12,000 32,000 32,000 0 0 $716,000
Total Costs (16) = (14) + (15) $ 336,000 264,000 40,000 57,000 62,000 77,000 99,750 107,000 $1,042,750
Total manufacturing costs for 2013 = $1,042,750 2. Total cost per unit, 2012 = $948,750 = $12.65 3.
Total cost per unit, 2013
75,000 $1,042,750 = 80,000
= $13.03
Cost classification into variable and fixed costs is based on qualitative, rather than quantitative, analysis. How good the classifications are depends on the knowledge of individual managers who classify the costs. Gower may want to undertake quantitative analysis of costs, using regression analysis on time‐series or cross‐sectional data to better estimate the fixed and variable components of costs. Better knowledge of fixed and variable costs will help Gower to better price its products, to know when it is getting a positive contribution margin, and to better manage costs.
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10‐19 (30–40 min.) Linear cost approximation. 1.
2.
Difference in cost $529,000 $400,000 = $43.00 = Difference in labor‐hours 7,000 4,000
Slope coefficient (b) =
Constant (a) = $529,000 – ($43.00 × 7,000) = $228,000 Cost function = $228,000 + $43.00 professional labour‐hours The linear cost function is plotted in Solution Exhibit 10‐19 No, the constant component of the cost function does not represent the fixed overhead cost of the Calgary Group. The relevant range of professional labour‐ hours is from 3,000 to 8,000. The constant component provides the best available starting point for a straight line that approximates how a cost behaves within the 3,000 to 8,000 relevant range. A comparison at various levels of professional labour‐hours follows. The linear cost function is based on the formula of $228,000 per month plus $43.00 per professional labour‐hour. Total overhead cost behaviour:
Month 1
Month 2
Professional labour‐hours Actual total overhead costs Linear approximation Actual minus linear approximation
3,000 $340,000 357,000 $(17,000)
4,000 $400,000 400,000 $ 0
Month 3
Month 4
Month 5
Month 6
5,000 6,000 $435,000 $477,000 443,000 486,000 $ (8,000) $ (9,000)
7,000 $529,000 529,000 $ 0
8,000 $587,000 572,000 $ 15,000
The data are shown in Solution Exhibit 10‐19. The linear cost function overstates costs by $8,000 at the 5,000‐hour level and understates costs by $15,000 at the 8,000‐hour level. 3. Contribution before deducting incremental overhead Incremental overhead Contribution after incremental overhead The total contribution margin actually forgone is $3,000. 10–488
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Based on Actual $38,000 35,000 $ 3,000
Based on Linear Cost Function $38,000 43,000 $ (5,000)
Chapter 10
SOLUTION EXHIBIT 10‐19 Linear Cost Function Plot of Professional Labour‐Hours on Total Overhead Costs for Calgary Consulting Group
Total Overhead Costs
$700,000 600,000 500,000 400,000 300,000 200,000 100,000 0 0
1,000 2,000 3,000 4,000 5,000 6,000 7,000
8,000 9,000
Professional Labour-Hours
10‐20 (20 min.) Cost‐volume‐profit and regression analysis. 1a. 1b.
Total manufacturing costs Number of bicycle frames $900,000 = $30 per frame = 30,000 This cost is greater than the $28.50 per frame that Ryan has quoted. Average cost of manufacturing
=
Garvin cannot take the average manufacturing cost in 2012 of $30 per frame and multiply it by 36,000 bicycle frames to determine the total cost of manufacturing 36,000 bicycle frames. The reason is that some of the $900,000 (or equivalently the $30 cost per frame) are fixed costs and some are variable costs. Without distinguishing fixed from variable costs, Garvin cannot determine the cost of manufacturing 36,000 frames. For example, if all costs are fixed, the manufacturing costs of 36,000 frames will continue to be $900,000. If, however, all costs are variable, the cost of manufacturing 36,000 frames would be $30 36,000 = $1,080,000. If some costs are fixed and some are variable, the cost of manufacturing 36,000 frames will be somewhere between $900,000 and $1,080,000.
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10‐20 (cont’d) Some students could argue that another reason for not being able to determine the cost of manufacturing 36,000 bicycle frames is that not all costs are output unit‐level costs. If some costs are, for example, batch‐level costs, more information would be needed on the number of batches in which the 36,000 bicycle frames would be produced, in order to determine the cost of manufacturing 36,000 bicycle frames. 2.
3.
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Expected cost to make = $432,000 + $15 36,000 36,000 bicycle frames = $432,000 + $540,000 = $972,000 Purchasing bicycle frames from Ryan will cost $28.50 36,000 = $1,026,000. Hence, it will cost Garvin $1,026,000 $972,000 = $54,000 more to purchase the frames from Ryan rather than manufacture them in‐house. Garvin would need to consider several factors before being confident that the equation in requirement 2 accurately predicts the cost of manufacturing bicycle frames. a. Is the relationship between total manufacturing costs and quantity of bicycle frames economically plausible? For example, is the quantity of bicycles made the only cost driver or are there other cost‐drivers (for example batch‐level costs of setups, production orders, or material handling) that affect manufacturing costs? b. How good is the goodness of fit? That is, how well does the estimated line fit the data? c. Is the relationship between the number of bicycle frames produced and total manufacturing costs linear? d. Does the slope of the regression line indicate that a strong relationship exists between manufacturing costs and the number of bicycle frames produced? e. Are there any data problems such as, for example, errors in measuring costs, trends in prices of materials, labour, or overheads that might affect variable or fixed costs over time, extreme values of observations, or a nonstationary relationship over time between total manufacturing costs and the quantity of bicycles produced? f. How is inflation expected to affect costs? g. Will Ryan supply high‐quality bicycle frames on time?
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Chapter 10
10‐21 (25 min.) OLS simple linear regression analysis in Excel; regression analysis, service company 1. On the left is the chart of the predicted (y), the linear regression line. On the right is the summary of relevant statistics extracted and reformatted from the Excel report. Labour Hours and Overhead Cost Regression Line $120,000 $100,000 $80,000 $60,000 $40,000
Regression Statistics Labour Hours Std Error
t-Stat
R Square 0.7322 Observations 12.0 df 11.0 Intercept a $ 31,886.03 9,098.884 Slope b $ 9.45 1.8076 Confidence 95.0% Critical Value df = 11 2.202
3.5044 0.0057 5.2290 0.0004 95.0% 2.202
P-value
Y
$20,000
Predicted Y
$0 -
2.
2,000 4,000 6,000 X = Labour Hours
8,000
The RSquare (r2) indicated that a change in labour hours will explain approximately 73% of a change in the total overhead cost pool. This is higher than the benchmark of 30% explanatory power. The t‐Stat indicates whether or not the intercept a value is random or not and in this case 3.5044 > 2.202 at df = 11 and confidence level of 95%. The value of 2.202 is read from Exhibit 10‐6 in the list of critical values in Appendix. Bob can be confident 95/100 times that the unexplained portion of change in the overhead cost pool is approximately $31,886. The P‐value of 0.0057 tells Bob that 57/1,000 times the actual unexplained value will not be within a reasonable range of $31,886. Similarly for the rate of change Bob can expect in the overhead cost pool when labour hours change by 1 unit is approximately b = $9.45/hour. Again the t‐Stat of 5.2290 > 2.202 at df = 11 and confidence level of 95%. the P‐value is only 4/1,000 that an observed rate of change will be beyond a reasonable range of $9.45.
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10‐21 (cont’d) 3.
Using the data provided in the regression output, the predicted range of values within which any future observed value of a and b should fall is calculated as: Range: a (critical value * (standard error of a÷√n) and: b (critical value * (standard error of b÷√n)
The results of these calculations are: RANGE OF COEFFICIENT VALUES Cost Driver Labour Hours 95.0% √n= 3.317 df = 11 Coefficients Critical Value Standard Error High Low $31,886.03 2.202 9,098.884 $37,863.93 $24,908.12 Intercept a $ 9.45 2.202 1.808 $ 10.64 $ 8.26 Slope b
The highest estimated value of intercept a is approximately $37,864 and lowest is $25,908. The highest estimated value of slope b is approximately $10.64 and lowest is $8.26. 4. Mr. Ladouceur’s figures, 200 people Using linear regression, 200 people
Total Variable a Total Cost $6,083.48 $6,083.48 $2,079.47 31,886.03 33,965.50
To earn a positive contribution margin, the minimum bid for a 200‐person cocktail party would be any amount greater than $6,084. This amount is calculated by multiplying the variable cost per person of $30.42 by the 200 people. At a price above the variable costs of $6,084, Mr. Ladouceur will be earning a contribution margin toward coverage of his fixed costs.
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10‐21 (cont’d) Of course, Mr. Ladouceur will consider other factors in developing his bid including (a) an analysis of the competition––vigorous competition will limit Ladouceur’s ability to obtain a higher price (b) a determination of whether or not his bid will set a precedent for lower prices––overall, the prices Mr. Ladouceur charges should generate enough contribution to cover fixed costs and earn a reasonable profit, and (c) a judgment of how representative past historical data (used in the regression analysis) is about future costs. Using the data Mr. Ladouceur will overbid using the linear regression and will not obtain the job. He is better off to use his own estimate of costs based on his own data. There must be another cost driver that better specifies how overhead costs change systematically. The intercept value of a is not a fixed cost. It is the estimated dollar value of cost change that is not explained by a change in labour hours. 5.
6.
Mr. Ladouceur is making a mistake when he assumes that the value of a is a fixed cost. The MOH cost pool is heterogeneous. Some of the costs are fixed but some are variable. Of the variable costs not all are driven by labour hours, although Mr. Ladouceur has chosen this as his cost driver. Mr. Ladouceur only has 12 data points and the minimum he should have to derive a reliable systematic relationship is 31 data points. Mr. Ladouceur should not use the specification derived from the linear regression. The chart of the residuals shows that the error terms e are not randomly scattered around the mean (the horizontal line). After the initial increase from January to February, there is a steady downward drift to the values. The residuals also appear to have a wave form. This is further evidence that a reliable cost driver has not yet been specified.
Residuals
Y - y = e Residual Plot 20000 10000 0 -10000 -20000 -30000 -40000
2,000
4,000
6,000
8,000
Labour Hours
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10‐22 (30 min)
Regression analysis, activity‐based costing, choosing cost drivers
The data set, charts and summary of statistics is presented from the OLS Simple Linear Regression:
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Chapter 10
10‐22 (cont’d) 1.
Based on the linear regression graphs it appears there is an economically plausible, systematic linear relationship for both cost functions. There is even scatter of blue (actual) historical data points around the red line joining the predicted data points. The scatter does seem closer for X = Q units moved than for X = Q shipments. The predicted costs fit the first set of data better than the second. This is confirmed by the RSquare (r2) for the first cost driver which is approximately 0.84 while for the second is only 0.55. This means the change in units moved can explain 84% of the corresponding change in the distribution cost pool But the change in shipments can only explain 55% of the corresponding change in the distribution cost pool value.. Looking at the Residual graphs it appears that the error terms are not related to one another. The intercept coefficient value when X = 0 units moved is $5,188 approximately and the 0 value of X is within the relevant range. But this value is not statistically significant because the t‐stat is smaller than the critical value of 2.201 at d.f. = 11 and a 95% confidence level. This means Jill must accept $5,188 is most likely a random value. The probability this decision is wrong is also relatively high, approximately 23%. The same is true of the intercept coefficient value for the second cost driver. One fact that could explain the result for the cost driver Q = shipments is that X = 0 is not in the relevant range of actual observed historical values. The t‐stat is smaller than the critical value of 2.201 and there is a similar probability of approximately 24% (or 24 times in 100) that Jillʹs decision to accept the $9,073 value is random is wrong. Based on these statistics, neither cost driver reports the unexplained amount of change in the cost pool with any certainty. The slope coefficient value, however, is statistically significant for the first cost driver (the t‐stat is far greater than the critical value of 2.201) but it is not for the second cost driver. If Jill accepts that for every single unit change in Q of units shipped she will observe approximately $0.07 change in the distribution cost pool there is almost no probability she will be wrong. She will observe this rate of change 95 times out of 100 observations in future. This is not true for the second cost driver. The rate of change of approximately $89 per 1 unit change in shipments is most likely a random value. The probability that Jillʹs decision on this is wrong is extremely small, only about 6 in 1,000. Based on this analysis, assuming there are no other alternatives, Jill is best to choose the cost driver, Q = units shipped, although there very big limitations to this choice.
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10‐22 (cont’d) By accepting either cost driver as an explanation of changes in the indirect cost pool value, any predictions will have a large potential variance. Jill knows this by comparing the standard error of the estimated value of the intercept for Q = units moved. The error is almost as large as the coefficient value and this is also true for the intercept value for Q = shipments. Using these results in the cost function will not provide Jill with reliable estimates of future values of the distribution cost pool. But Jill has gained information too. She now knows by controlling the units moved she can control the value of the cost pool but by controlling the number of shipments she cannot control the value of the cost pool. 2. If Ms Goldstein persists then the calculation of the distribution costs is a simple matter of replacing the coefficients and X values with actual numbers. y = $5,188 + $0.53*40,000 = $26,388 for the cost driver Q = units moved y = $9,073 + $89 * 220 = $28,653 for the cost driver Q = shipments. 3. Inspecting the original data, when 37,000 units were moved the distribution cost was $26,400 and when 43,000 units were moved the distribution cost was $24,000. Although itʹs dangerous to speculate based on only two data points this is the best information I have to try and predict the cost pool differences if I use shipments instead of units. At the cost of $24,000 Jillʹs 210 shipments also moved 43,000 units and at a cost of $28,800 Jillʹs 225 shipments moved 54,000 units. Again this is not ideal but I would predict a higher distribution cost based on shipments than if I used units. My data points suggest that as units moved increase, cost decreases but as shipments increase, costs increase. 4. Jill needs more data without doubt 12 data points is too few but she also needs to audit these data to ensure they are clean (reliable and accurate). In order to provide a reliable justification to choose one cost driver over another, the data set must be representative of an average productivity for Jillʹs company. This cannot be assured with such a small number of observations. Jill can also choose to gather data on other potential cost drivers for distribution costs, or to add a second cost driver to her specification of this cost function and run a multiple linear regression. If she makes this choice then she must be certain that the second cost driver is independent of the first. In this case the number of shipments is most likely dependent on the number of units moved therefore is not a good candidate as a second cost driver because it is simply a second measurement of the same activity.
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PROBLEMS
10‐23 (25 min.) OLS and high‐low method. The Excel results of the OLS simple linear regression follow: SUMMARY OUTPUT Regression Statistics Multiple R 0.805645917 R Square 0.649065343 Adjusted R Square 0.634443066 Standard Error 16960.32863 Observations 26 ANOVA df Regression Residual Total
1 24 25
SS MS F Significance F 12768560221 1.28E+10 44.38879984 6.84301E‐07 6903665933 2.88E+08 19672226154
Coefficients Standard Error t Stat P‐value 439285.256 28757.1465 15.27569 7.29758E‐14 ‐1.817453317 0.272788817 ‐6.66249 6.84301E‐07
Intercept MH
Lower 95% Upper 95% Lower 95.0% Upper 95.0% 379933.4231 498637.0889 379933.4231 498637.0889 ‐2.380461761 ‐1.254444873 ‐2.380461761 ‐1.254444873
MH Line Fit Plot
RESIDUAL OUTPUT
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26
Predicted Cost 275714.4575 239365.3911 257539.9243 221190.8579 284801.724 248452.6577 266627.1909 230278.1245 266627.1909 230278.1245 248452.6577 212103.5914 275714.4575 235730.4845 261174.8309 217555.9513 277531.9108 244817.7511 272079.5508 224825.7646 268444.6442 233913.0312 252087.5643 211194.8647 280258.0907 236639.2111
Residuals 6285.542546 ‐17365.39111 6460.075717 18809.14206 3198.275961 ‐44452.6577 ‐8627.190868 3721.875474 15372.80913 ‐2278.124526 21547.3423 3896.408645 7785.542546 ‐13930.48448 5825.169083 17444.04869 9968.089229 ‐37317.75106 ‐14279.55082 8574.235426 15855.35581 ‐12913.03116 11412.43567 12905.1353 ‐758.0907465 ‐17139.21114
300,000 250,000
Cost
Observation
350,000
200,000 150,000
Cost
100,000
Predicted Cost
50,000 0 0
50,000
100,000
150,000
MH
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10‐23 (cont’d) 1a.
Mechanically replacing the values of a and b with the regression estimates the predicted value of y = $439,285 + $(1.82 * 100,000) = $257,285 But Ken should not just plug in the numbers. Ken needs to inspect the graphs and reflect on the meaning of this cost function. The slope of the regression line in red traces a downward slope through the blue dots that are the actual data points that have been observed in the past. The value of the slope coefficient of $(1.82) is significant and negative. The probability that accepting this coefficient value as non‐random is wrong is virtually zero. The same can be said of the coefficient value of the intercept. It is statistically significant and the probability of being wrong in accepting this is not a random number is virtually zero. This indicates that the systematic change is such that the more DMH used, the less is the maintenance cost in a specific time period. It is difficult to explain how this could be economically plausible. The reasonable expectation would be at best that the maintenance costs are fixed within the relevant range of practical capacity. There is a problem with the scatter of the blue dots because they form a clear sloped pattern through the regression line. Ken should suspect one of 3 problems with his specification a) the systematic relationship is non‐linear b) the systematic relationship is not continuous c) there is another variable that is systematically affecting the cost pool value in addition to DMH. Inspecting the original quarterly data set suggests the DMH quantity and the maintenance costs systematically increase from quarter 1 to quarter 4, then return to quarter 1 levels. Ken should investigate this as a potential explanatory variable.
1b.
1c .
The high and low points of machine hours, the predictor variable, are 125,500 and 85,000 with respective maintenance costs of $224,100 and $288,000. These points create a function that is not economically plausible. Neither cost function is sensible as a description of the systematic relationship, if any, between consuming DMH and the value of the Maintenance Cost Pool. Reflecting on pattern in the historical data, it appears routine maintenance occurs the first of every four quarters, irrespective of the DMH consumed during that quarter.
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10‐23 (cont’d) 2a.
Lack of economic plausibility cannot be remedied by changing the timing of the proposed relationship between DMH used and the indirect costs contributing to the maintenance cost pool. Nevertheless using the lagged DMH regressed on Maintenance cost: y = $33,551 + 2.05 * 100,000 DMH = $238,551. The statistics offer confirmatory evidence that this is a more reasonable estimate of a systematic relationship than the first estimation of the cost function. The explanatory power of the lagged DMH is almost 87% compared to 65% for the unlagged DMH. The unexplained portion of change, the intercept value at X=0 is far smaller, however, there is still an issue because X=0 is beyond the relevant range of DMH consumption. Even though the t‐Stat and P‐value suggest Ken would be correct in a decision to use this regression estimate of a, he still must understand how this relationship arises. The slope value has changed sign but again, Ken needs to know why this would happen simply by lagging DMH by one quarter before he accepts this as a good reflection of cost behaviour in the Maintenance cost pool. The actual interpolated critical value at df = 24 and a confidence interval of 95% will be slightly different from 2.060 but not enough to change the conclusion that the values of a and b are not random.
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10‐23 (cont’d)
2b.
10–500
Lagging the predictor variable eliminates the inverse relationship between DMH and the value of the indirect cost pool. Y = $204,000 + $2.40*100,000 DMH = $444,000 using the low value of the intercept value. But Ken cannot simply take this at face value because it is higher than the highest cost on the High‐Low graph. While the value of X = 100,000 is well within the relevant range of practical capacity, the estimate cost has never been experienced in almost 9 years of quarterly observed data (26 * 4)/12 8.7 years).
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Chapter 10
10‐23 (cont’d) 2c.
Using the lagged cost driver DMH provides a better cost function that depicts the linear relationship between DMH and the value of the indirect cost pool. Notice, however, it does not explain why this cost behaviour exists. While the scatter of blue dots indicating actual lagged values of X,Y are close to the red linear regression line plotted through the predicted values (X,y) Ken still does not know why. Until this is determined, the economic plausibility of the systematic change remains in doubt. The High‐Low method provides poor estimates in both instances. In the first example the estimate of the size of the cost pool is negative, which is impossible. In the second example it is almost double most of the observed values of the cost pool over the past 25 quarters, which is also impossible.
10‐24 (25 min.)
OLS simple linear regression analysis
The basic data used in 1a. are:
The chart of OLS regression line and the summary of relevant statistics from the Excel results are:
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10‐24 (cont’d)
1a.
1b.
1c.
Actual revenue from long standing customers is $5,000 × 10 months = $50,000. Total revenue of $720,000 less $50,000 fixed equals $670,000 variable. Variable revenue per advertising dollar = $670,000/$28,200 = $23.76. Therefore, Y = $5,000 + (23.76*$1,900) = $50,144 The high and low points of the revenue driver, advertising dollars, are $1,200 and $4,800 with corresponding revenues of $66,000 and $96,000. This results in Y = $56,016 + (8.33 * $1,900) = $71,843 Y = 47,402 + (8.723 * $1,900) = $63,976
2. The reported standard error of the estimate for a = The calculation of the range is: Cost Driver DMH
Intercept a Slope b
$ $
$ 6,939.131 and slope b
95.0% df = 9 √n = 3.000 Critical Value Standard Error High 47,401.87 2.262 6,939.1312 $ 52,633.97 8.7227 2.262 2.2993 $ 10.46
= $
2.299
Low $ 42,169.76 $ 6.99
$ 72,501.14 when the high values of the coefficients are substituted in the equation y = a + b X $ 55,449.01 when the low values of the coefficients are substituted in the equation y = a + b X The highest favourable or unfavourable variance from the predicted $ 63,975.08 = $ 8,526.07 . As a percentage of the estimated value this is large = 13.33% . The managers also need to note that X = $0 advertising is not is not within the relevant range of X. At X = $1,900 y =
3.
10–502
Clean data is reliable data. The more reliable the input data, the better the partnersʹ decisions will be. Reliability in an OLS simple linear regression requires far more than 10 data points. To clean up this data the first thing the partners should do is collect more data points. They could consider using weekly instead of monthly data but then need to carefully assess the report on the residuals to assure there is no autocorrelation and no serial correlation in this time series data.
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Chapter 10
10‐24 (cont’d) With so few data points , there is a relatively large standard error for the values of a and b. This means there will be a wide range within which the observed future value of y when X = $1,900 could fall. While the explanatory power is reasonable at about 64.3% this only refers to the explained portion of change in revenue. There remains unexplained revenue of approximately $42,170 or 78% of the actual revenue in September and 44% of actual revenue in October. One reason is because the intercept value of y is supposed to be estimated at the data point when X = 0 and this value is not within the relevant range of X. The rate of change in Revenue is estimated at approximately $2.26 for every $1.00 of advertising expense. But the t‐stat is not significant at the 95% confidence level. This means the partners cannot say with any confidence that by increasing advertising expense $1 they will increase revenue $2.26 .The plot of the residuals indicates no serial or autocorrelation in the error terms of this time‐series. 4.
Based on the interpretation of the statistics output from the linear regression, no, I would not recommend using these results in their present form to predict revenue from advertising expense.
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10‐25 (30–40 min.) OLS linear regression Regression Statistics Degrees C Std Error t-Stat P-value RSquare 0.017029265 Observations 19 df 18 Intercept a $ 943.84316 2440.03187 0.386816 0.70369 Slope b $ 47.12590 86.8375498 0.54269 0.59439 Confidence 95.00% 95.00% Critical Value of df = 18 2.101 2.101
Profit y , OLS Linear Regression Line $5,000 Profit $ y
$4,000 $3,000 $2,000 $1,000 $Y
-
10.0
Predicted Y
20.0 30.0 X = Degrees C
40.0
Y - y = e Residual Plot
e =Residuals
3000 2000 1000 0 -1000 -2000
10.0
20.0
30.0
40.0
Original Data Set: Observations 1993 1994 1995 1996 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011
X = Degrees C 22.6 24.3 25.5 28.1 29.3 31.0 30.1 26.9 31.0 28.3 29.1 29.8 31.2 28.6 24.5 27.9 26.5 28.2 29.1
Profit Y $ 1,219 1,568 1,731 1,395 1,421 1,320 2,101 1,795 2,300 2,152 2,487 2,104 3,307 3,502 3,862 4,200 1,800 2,265 2,475
1. 2.
3.
4.
10–504
The equation of the linear‐regression line defines a positive relationship such that as temperature increases, net income increases. The RSquare (r2 ) = 0.017 means that change in temperature can only explain slightly more than 1% of the change in net income, well below the threshold value of 0.30 or 30%. The critical value of t for d.f. = 18 and a confidence level of 95% is 2.101 compared to the calculated t‐value of 0.387 for a and 0.543 for b. The P‐ value for a is 0.704 and for b is 0.594. The calculated t for both coefficients is below the critical value of t which means that it is likely these two values are accidental and not the result of any systematic relationship between the predictor and outcome variables. The two statistics suggest the values of a and b are unreliable. The P‐values mean if the values of a and b are accepted as not random the probability of being wrong is about 70% and 59% respectively. Be tactful, however, the objective evidence from this OLS linear regression indicates change in temperature has no power at all to explain year‐to‐year changes in the net income. The appropriate recommendation is to stop adjusting the budget on the basis of anticipated average summer temperature.
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Chapter 10
10‐26 (20 min.) Specification of a linear cost function There is a clear pattern in the residuals. This means that the error term e, is not caused by random events. In this time series data set there is an increasing funnel shape. There is clearly non‐constant variance because the greater the value of X, the greater are the residual values. These residuals illustrate heteroskedasticity. The graph of the residuals also illustrates that the estimate of y is highly negative for some values of X in order for Y‐y = e to be negative. This is not economically plausible because indirect cost pools contain a variety of fixed and variable costs. It implies that for some non‐zero values of X this company would actually save money if they produced and sold those quantities, and that is nonsense. One of the values of a or b in the OLS simple linear regression estimate of y = a + bX + e is completely unreliable. Mr. Goretsky knows that an unreliable coefficient value could occur because X = 0 is not within the relevant range of this time series data. This means that estimating (0, y), the intercept value of y (or a) when X = 0 will be unreliable. The estimate is actually no better than a random guess about how much of the change in the cost pool is unexplained by change in the cost driver. The standard error of this estimate will be very large; the t‐Stat will not be significant; and the P‐value or probability that any range around the estimate of y will not reflect economically plausible future values of (X, Y) is very high. A large standard error for the estimate of a is probably what is causing the large estimated negative values y and hence the negative values of Y ‐ y. Mr. Goretsky must re‐ evaluate his data set and respecify his cost function.
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COLLABORATIVE LEARNING CASES
10‐27 (25 min.) Account analysis, high‐low method, alternative regression functions. 1.
M&S Java use the account analysis method, based on their close understanding of actual cost behaviour for the month. The fixed cost was actually $572. The total variable cost was $3,017 ($3,589 ‐ $572) for a unit variable cost of $1.8987 per kg of coffee beans consumed ($3,017 ÷ 1,589). The unitized fixed cost rate would be $0.3599 ($572 ÷ 1,589). The rounded forecast daily cost of consuming 65 kg of coffee beans: Y = a + bX = $22.88 + ($1.90 *65 kg) = $146.38
This value would change if the monthly total kg of coffee beans changed because the fixed costs of $572 would be divided by either a higher or lower number of kg of coffee beans consumed. If M&S Java observe an actual value of $160 as they did in day 8 last month, they would begin conclude they had a large unfavourable variance. M&S Java would take action to reduce indirect costs. M&S Java would be unlikely to examine their consumption of coffee beans because this is only a direct cost driver of the direct materials cost pool. Rather M&S Java must investigate the cost drivers of other costs in the indirect cost pool, perhaps the cost of utilities, which arise from grinding the beans and making carafes of coffee. This emphasises the difference in an investigation of indirect cost pool unfavourable variances in contrast to a direct cost pool investigation. The indirect cost pool is heterogeneous and none of the costs comprising it can be traced to the consumption of coffee beans. These indirect costs, however, would not have arisen unless M&S Java had consumed coffee beans and sold cups of coffee. Using the regression values of y = a + bX the same calculation with an intercept a of $13.32 and a slope b of $2.041 would result in a rounded forecast cost of $145.97 per day if 65 kg of coffee
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10‐27 (cont’d) 2.
3. The following calculations for range are based on the results of the analysis. a (critical value * (standard error of a÷√n) b (critical value * (standard error of b÷√n)
Total budgeted costs day‐by‐day of the indirect cost pool are calculated using the values of the intercept and slope provided for kilos of coffee beans. The final column to the right is the point estimate of the future cost pool values with no error term included (y = a + bX). The High and Low columns include the predicted error in the calculation of the y = a + bX range of values around a and b: y = a + bX + e Copyright © 2013 Pearson Canada Inc.
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10‐27 (cont’d)
M&S Java can be sure, if they choose kilos of coffee beans used, then 95/100 months that the actual value of the indirect cost pool will fall within the range of rounded values of $3,740 and $3,438. The predicted point estimate for the total indirect cost pool, with no error is $3,589, all other things equal, the largest forecast unfavourable or favourable variance in future months would be $151. The three different methods, M&S Java result in three different forecast daily costs when 65 kg of coffee beans are used. Based on the account analysis method the rounded daily indirect cost forecast is $146 on the high‐low method, $164 and on the regression analysis method, $146 which raises the question of which choice is best? Assuming clean data is
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10‐27 (cont’d) available, the regression analysis method will be unbiased and quantitatively justifiable. It is as simple as inputting data according to the Excel program instructions. This approach accurately reflects the economic substance of the complexity of the decision about which among alternatives is the better cost driver for heterogeneous, indirect cost pools and why. The results can also be used to calculate a range within which a budgeted future value of indirect cost pools will fall with a specific confidence level and probability that the forecast will be wrong. Managers can use the results to predict the range within which variances will likely occur. Overall with the availability of the program, what remains is the genuine management task of interpreting the results in an unbiased and knowledgeable way. 4.
M&S Java are going to have to trade of the strengths and weaknesses of the two cost drivers. The strengths of using kilos of coffee beans include a higher explanatory power, lower dollar value of the amount of the indirect cost pool unexplained by a change in kilos consumed, and a very strong t‐ Stat and P‐value for the slope. Changes in consumption of kilos of coffee beans explain (rounded) 92.3% of any change in the indirect cost pool. For the intercept value, however, the t‐Stat of 1.8272 <2.060, the critical value. This means that the unexplained portion reported of $13.32 is no better than a random guess or it could even be zero at 25 df and a confidence level of 95%. This tells M&S Java there is no real way of knowing how much of a change in the indirect cost pool is unexplained by a change in consumption of kilos of coffee. The probability that an actual future value of the indirect cost pool would fall outside the range estimated by using the linear regression values is quite high, 8/100 or 0.08. Usually the threshold is P< 0.01. For the alternative the corresponding probability is only 1/1,000. The strengths of using cups (supplies rather than direct material) is that the rounded t‐Stat for the intercept of 3.70 >2.201 the critical value at df = 25 and confidence level of 95%. M&S Java can be confident the unexplained value is neither random nor zero 95/100 times they inspect their future monthly results. The P‐value indicates that future actually observed values would fail to fall with the range forecast using the linear regression results only 1/1,000 times.
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10‐27 (cont’d) The weakness of using cups as the cost driver, however, is that its explanatory power is only 80.7% compared to the 92.8% for kilos of coffee beans. Using cups leaves approximately $38 of any change in the total cost pool unexplained by a change in number of cups consumed. The average monthly cost was approximately $138 ($3,589 ÷ 26) therefore using cups leaves about 28% of the change unexplained. But we know this is the case 95/100 times whereas we know nothing about the unexplained portion of change should we choose kg of coffee beans. M&S Java then examine the graphs of the line fit plots and residuals. Inspection tells them that a linear relationship does reflect the actual systematic relationship between changes in the each cost driver and the indirect cost pool. The slope of the line for kilos of coffee is $2.04 per kilo while the slope for cups is $0.27 per cup. Practically, if M&S could reduce its use of coffee beans by 1 kilo, it should be able to predict a $2.04 decrease in the indirect cost pool. For cups, however, the predicted decrease would only be $0.27 for every reduction of 1 cup. The problem here is that each serving requires a cup. Reducing cups implies reduced servings and therefore reduced revenue. Unless there is undue waste of empty cups being thrown away this would be an impractical cost control measure. Balancing off the practicality of cost control against the statistical evidence, M&S Java determine the evidence implies choosing cups but practicality implies choosing kilos of coffee. Controlling kilos of coffee will likely mean better scheduling of brewing new pots to reduce spoilage. M&S Java owners agree they will not reduce kilos of coffee used by adding more water to less ground coffee beans. They decide to use the kilos of coffee beans as their cost driver for the indirect cost pool.
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10‐28 1a. 1b. 2.
3.
Evaluating alternative simple regression models, not‐for‐profit.
Solution Exhibit 10‐28A plots the relationship between number of academic programs and overhead costs. Solution Exhibit 10‐28B plots the relationship between number of enrolled students and overhead costs. Solution Exhibit 10‐28C compares the two simple regression models estimated by Hanks. Both regression models appear to perform well when estimating overhead costs. Cost function 1, using the number of academic programs as the independent variable, appears to perform slightly better than cost function 2, which uses number of enrolled students as the independent variable. Cost function 1 has a high r2 and goodness of fit, a high t‐value, indicating a significant relationship between number of academic programs and overhead costs, and meets all the specification assumptions for ordinary least‐squares regression. Cost function 2 has a lower r2 than cost function 1 and exhibits positive autocorrelation among the residuals as indicated by a low Durbin‐ Watson statistic. The analysis indicates that overhead costs are related to the number of academic programs and the number of enrolled students. If Eastern has pressures to reduce and control overhead costs, it may need to look hard at closing down some of its academic programs and reducing its intake of students. Reducing the number of enrolled students may cut down on overhead costs, but it also cuts down on revenues (tuition payments), hurts the reputation of the school, and reduces its alumni base, which is a future source of funds. For these reasons, Eastern may prefer to downsize its academic programs, particularly those programs that attract few students. Of course, Eastern should continue to reduce costs by improving the efficiency of the delivery of its programs.
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SOLUTION EXHIBIT 10‐28A Plot of Number of Academic Programs versus Overhead Costs (in thousands)
SOLUTION EXHIBIT 10‐28B
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SOLUTION EXHIBIT 10‐28C Comparison of Alternative Cost Functions for Overhead Costs Estimated with Simple Regression for Eastern University Criterion Cost Function 1: Cost Function 2: Number of Number of Academic Programs as Enrolled Students as Independent Variable Independent Variable A positive relationship 1. Economic plausibility A positive relationship between overhead costs between overhead costs and number of academic and number of enrolled programs is economically students is economically plausible at Eastern plausible at Eastern University. University. 2. Goodness of fit r2 = 0.72, Adj. R2 = 0.693 r2 = 0.55, Adj. R2 = 0.509 Excellent goodness of fit Good goodness of fit but not as good as for number of academic programs 3. Significance of t‐value of 5.08 is significant. t‐value of 3.52 is significant. independent variable(s) d.f. = 11, (critical = 2.20 at d.f. = 11, (critical = 2.20 at 95% C.L.) 95% C.L.) Plot of the data indicates 4. Specification analysis of Plot of the data indicates estimation assumptions that assumptions of that assumptions of linearity, constant variance, linearity, constant variance, independence of residuals, and normality of residuals and normality of residuals hold, but inferences drawn hold, but inferences drawn from only 12 observations from only 12 observations are not reliable; the Durbin‐ are not reliable; Durbin Watson statistic = 0.82 Watson statistic = 2.07 indicates that indicates that independence of residuals independence of residuals does not hold. holds.
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10‐29 1.
2.
3.
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Evaluating multiple regression models, not‐for‐profit It is economically plausible that the correct form of the model of overhead costs includes both number of academic programs and number of enrolled students as cost drivers. The findings in Collaborative Learning Case 10‐28 indicate that each of the independent variables affects overhead costs. (Each regression has a significant r2 and t‐value on the independent variable.) Hanks could choose to divide overhead costs into two cost pools, (i) those overhead costs that are more closely related to number of academic programs and (ii) those overhead costs more closely related to number of enrolled students, and rerun the simple regression analysis on each overhead cost pool. Alternatively, Hanks could run a multiple regression analysis with total overhead costs as the dependent variable and the number of academic programs and number of enrolled students as the two independent variables.
Solution Exhibit 10‐29 evaluates the multiple regression model using the format of Exhibit 10‐14. Hanks should use the multiple regression model rather than the two simple regression models of Collaborative Learning Case 10‐28. The multiple regression model appears economically plausible and the regression model performs very well when estimating overhead costs. It has an excellent goodness of fit, significant t‐values on both independent variables, and meets all the specification assumptions for ordinary least squares regression. The adjusted R2 value = 0.766 is higher than the Collaborative Learning Case 10‐28 simple linear regression models R2 values. There is some correlation between the two independent variables, but multicollinearity does not appear to be a problem here. The significance of both independent variables (despite some correlation between them) suggests that each variable is a driver of overhead cost. Of course, as the chapter describes, even if the independent variables exhibited multicollinearity, Hanks should still prefer to use the multiple regression model over the simple regression models of Collaborative Learning Case 10‐28. Omitting any one of the variables will cause the estimated coefficient of the independent variable included in the model to be biased away from its true value. The Durbin‐Watson statistic = 1.91, so serial correlation in the residuals is not apparent. Caution: The sample size of 12 is small. Possible uses for the multiple regression results include: a. Planning and budgeting at Eastern University. The regression analysis indicates the variables (number of academic programs and number of enrolled students) that help predict changes in overhead costs.
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10‐29 (cont’d) b.
c.
Cost control and performance evaluation. Hanks could compare actual performance with budgeted or expected numbers and seek ways to improve the efficiency of the university operations, and evaluate the performance of managers responsible for controlling overhead costs. Cost management. If cost pressures increase, the University could save costs by closing down academic programs that have few students enrolled.
SOLUTION EXHIBIT 10‐29 Evaluation of Cost Function for Overhead Costs Estimated with Multiple Regression for Eastern University Criterion Number of Academic Programs and Number of Enrolled Students as Independent Variables 1. Economic Plausibility A positive relationship between overhead costs and number of academic programs and number of enrolled students is economically plausible at Eastern University. 2. Goodness of Fit r2 = 0.81, Adjusted R2 = 0.766 Excellent goodness of fit 3. Significance of Independent t‐values of 3.46 on number of academic programs and Variable(s) 2.02 on number of enrolled students are both significant, at 99% and 90% C.L.s respectively. MLR d.f. = n − k = 12 − 2 = 10 degrees of freedom At 95% C.L. t‐critical = 2.23 Therefore t‐stat of 2.02 for # of students enrolled is only statistically significant at 90% C.L. t‐ critical re 90% C.L. = 1.81 with 10 d.f. 4. Specification Analysis of The assumptions of linearity, constant variance, and Estimation normality of residuals hold, but inferences drawn Assumptions from only 12 observations are not reliable; the Durbin‐Watson statistic = 1.91 indicates that independence of residuals holds.
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10‐29 (cont’d)
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10‐29 (cont’d)
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CHAPTER 11 DECISION MAKING AND RELEVANT INFORMATION SHORT‐ANSWER QUESTIONS 11‐1 The five steps in the decision process outlined in Exhibit 11‐1 of the text are 1. Identify the problem and uncertainties 2. Obtain information 3. Make predictions about the future 4. Make decisions by choosing among alternatives 5. Implement the decision, evaluate performance, and learn An example of interdependencies include absenteeism/low employee morale and increased labour costs.
11‐2 Relevant costs are expected future costs that differ among the alternative courses of action being considered. Historical costs are irrelevant because they are past costs and, therefore, cannot differ among alternative future courses of action.
11‐3 Quantitative factors are outcomes that are measured in numerical terms. Some quantitative factors are financial––that is, they can be easily expressed in monetary terms. Direct materials is an example of a quantitative financial factor. Qualitative factors are outcomes that are difficult to measure accurately in numerical terms. An example is employee morale.
11‐4 Two potential problems that should be avoided in relevant cost analysis are
(i)
(ii)
Do not assume all variable costs are relevant and all fixed costs are irrelevant. Do not use unit‐cost data directly. It can mislead decision makers because a. it may include irrelevant costs, and b. comparisons of unit costs computed at different output levels lead to erroneous conclusions
11‐5 Opportunity cost is the contribution to income that is forgone (rejected) by not using a limited resource in its next‐best alternative use.
11‐6 No. Some variable costs may not differ among the alternatives under consideration and, hence, will be irrelevant. Some fixed costs may differ among the alternatives and, hence, will be relevant. 11‐520
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11‐7 No. Managers should aim to get the highest contribution margin per unit of the constraining (that is, scarce, limiting, or critical) factor. The constraining factor is what restricts or limits the production or sale of a given product (for example, availability of machine‐hours).
11‐8 No. When deciding on the quantity of inventory to buy, managers must consider both the purchase cost per unit and the opportunity cost of funds invested in the inventory. For example, the purchase cost per unit may be low when the quantity of inventory purchased is large, but the benefit of the lower cost may be more than offset by the high opportunity cost of the funds invested in acquiring and holding inventory.
11‐9 No. For example, if the revenues that will be lost exceed the costs that will be saved, the branch or business segment should not be shut down. Shutting down will only increase the loss. Allocated costs are always irrelevant to the shut‐down decision.
11‐10 Cost written off as depreciation is irrelevant when it pertains to costs for equipment already purchased. But the purchase cost of new equipment to be acquired in the future that will later be written off as depreciation is relevant.
11‐11 No. Managers tend to favour the alternative that makes their performance look best, so they focus on the measures used in the performance‐evaluation model. If the performance‐evaluation model does not emphasize maximizing operating income or minimizing costs, managers will most likely not choose the alternative that maximizes operating income or minimizes costs.
11‐12 No. Relevant costs are defined as those expected future costs that differ among alternative courses of action being considered. Thus, future costs that do not differ among the alternatives are irrelevant to deciding which alternative to choose.
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EXERCISES
11‐13 (10 min.)
Terminology.
A full absorption cost refers to all manufacturing costs including all MOH whereas full product costs refers to all period or non‐manufacturing costs as well as all manufacturing costs to bring the product to point of sale. The opportunity cost is the value lost because a different alternative was not chosen. The incremental revenue and incremental cost are the unique inflows and outflows arising from a specific alternative, should it be chosen. Similarly an outlay cost arises from implementation of a specific alternative. In comparison a differential cost is the savings or added costs that arise when comparing alternatives to the current state. At some point the choice must be made and frequently a management team can suffer paralysis by analysis because they seek more and more information. There are some costs that are always irrelevant and one category is sunk costs that have already been spent and cannot be recovered by making a different decision. One way to select an alternative is to use an optimization technique called linear programming. Optimization under specific constraints on resources may target either in cost minimization or profit maximization. The technical name to calculate what will be optimized is the objective function. 11‐14 (20 min.) Disposal of assets. 1. This is an unfortunate situation, yet the $88,000 costs are irrelevant regarding the decision to remachine or scrap. The only relevant factors are the future revenues and future costs. By ignoring the accumulated costs and deciding on the basis of expected future costs, operating income will be maximized (or losses minimized). The difference in favour of remachining is $3,300: (a) (b) Remachine Scrap Future revenues $38,500 $2,200 Deduct future costs 33,000 — Operating income $ 5,500 $2,200 Difference in favour of remachining $3,300
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11‐14 (cont’d) 2.
This too is an unfortunate situation. But the $110,000 original cost is irrelevant to this decision. The difference in favour of rebuilding is $7,700:
New truck Deduct current disposal price of existing truck Rebuild existing truck Difference in favour of rebuilding
(a) Replace $112,200
(b) Rebuild —
11,000 — $101,200
— $93,500 $93,500 $7,700
Note here that the current disposal price of $11,000 is relevant, but the original cost (or book value, if the truck were not brand new) is irrelevant. 11‐15 (10 min.) Inventory decision, opportunity costs. 1. Unit cost, orders of 20,000 $9.00 Unit cost, order of 240,000 (0.96 $9.00) $8.64 Alternatives under consideration: (a) Buy 240,000 units at start of year. (b) Buy 20,000 units at start of each month. Average investment in inventory: (a) (240,000 $8.64) ÷ 2 $1, 036,800 (b) ( 20,000 $9.00) ÷ 2 90,000 Difference in average investment $ 946,800 Opportunity cost of interest forgone from 240,000‐unit purchase at start of year = $946,800 0.10 = $94,680 2. No. The $94,680 is an opportunity cost rather than an incremental or outlay cost. No actual transaction records the $94,680 as an entry in the accounting system.
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11‐15 (cont’d) 3.
The following table presents the two alternatives: Alternative A: Alternative B: Purchase Purchase 240,000 20,000 spark plugs at spark plugs beginning of at beginning year of each month Difference (1) (2) (3) = (1) – (2)
Annual purchase‐order costs $ 200 (1 $200; 12 $200) $ 2,400 $ (2,200) 2,073,600 2,160,000 (86,400) Annual purchase (incremental) costs (240,000 $8.64; 240,000 $9) Annual interest income that could be earned if investment in inventory were invested (opportunity cost) (10% $1,036,800; 10% $90,000) 103,680 9,000 94,680 Relevant costs $2,177,480 $2,171,400 $ 6,080 Column (3) indicates that purchasing 20,000 spark plugs at the beginning of each month is preferred relative to purchasing 240,000 spark plugs at the beginning of the year because the opportunity cost of holding larger inventory exceeds the lower purchasing and ordering costs. If other incremental benefits of holding lower inventory such as lower insurance, materials handling, storage, obsolescence, and breakage costs were considered, the costs under Alternative A would have been higher, and Alternative B would be preferred even more.
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11‐16 (20 min.) Relevant and irrelevant costs. 1. Relevant costs Variable costs Avoidable fixed costs Purchase price Unit relevant cost
Make $180 20 ____ $200
Buy $210 $210
Dalton Computers should reject Peach’s offer. The $30 of fixed costs are irrelevant because they will be incurred regardless of this decision. When comparing relevant costs between the choices, Peach’s offer price is higher than the cost to continue to produce. 2. Cash operating costs (4 years) Current disposal value of old machine Cost of new machine Total relevant costs
Keep Replace Difference $80,000 $48,000 $32,000 (2,500) 2,500 ______ 8,000 (8,000) $80,000 $53,500 $26,500
AP Manufacturing should replace the old machine. The cost savings are far greater than the cost to purchase the new machine.
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11‐17 (10 min.) The careening personal computer. Considered alone, book value is irrelevant as a measure of loss when equipment is destroyed. The measure of the loss is replacement cost or some computation of the present value of future services lost because of equipment loss or damage. In the specific case described, the following observations may be apt: 1.
2.
11–526
A fully amortized item probably is relatively old. Chances are that the loss from this equipment is less than the loss for a partially amortized item because the replacement cost of an old item would be far less than that for a nearly new item. The loss of an old item, assuming replacement is necessary, automatically accelerates the timing of replacement. Thus, if the old item were to be junked and replaced tomorrow, no economic loss would be evident. However, if the old item were supposed to last five more years, replacement is accelerated five years. The best practical measure of such a loss probably would be the cost of comparable used equipment that had five years of remaining useful life. The fact that the computer was fully amortized also means the accounting reports will not be affected by the accident. If accounting reports are used to evaluate the office manager’s performance, the manager will prefer any accidents to be on fully amortized units.
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Chapter 11
11‐18 (2530 min.) Closing and opening stores. 1.
2.
Solution Exhibit 11‐18, Column 1, presents the relevant loss in revenues and the relevant savings in costs from closing the Surrey store. Lopez is correct that Sanchez Corporation’s operating income would increase by $7,000 if it closes down the Surrey store. Closing down the Surrey store results in a loss of revenues of $860,000 but cost savings of $867,000 (from cost of goods sold, rent, labour, utilities, and corporate costs). Note that by closing down the Surrey store, Sanchez Corporation will save none of the equipment‐related costs because this is a past cost. Also note that the relevant corporate overhead costs are the actual corporate overhead costs $44,000 that Sanchez expects to save by closing the Surrey store. The corporate overhead of $40,000 allocated to the Surrey store is irrelevant to the analysis. Solution Exhibit 11‐18, Column 2, presents the relevant revenues and relevant costs of opening another store like the Surrey store. Lopez is correct that opening such a store would increase Sanchez Corporation’s operating income by $11,000. Incremental revenues of $860,000 exceed the incremental costs of $849,000 (from higher cost of goods sold, rent, labour, utilities, and some additional corporate costs). Note that the cost of equipment written off as depreciation is relevant because it is an expected future cost that Sanchez will incur only if it opens the new store. Also note that the relevant corporate overhead costs are the $4,000 of actual corporate overhead costs that Sanchez expects to incur as a result of opening the new store. Sanchez may, in fact, allocate more than $4,000 of corporate overhead to the new store but this allocation is irrelevant to the analysis. The key reason that Sanchez’s operating income increases either if it closes down the Surrey store or if it opens another store like it is the behaviour of corporate overhead costs. By closing down the Surrey store, Sanchez can significantly reduce corporate overhead costs presumably by reducing the corporate staff that oversees the Surrey operation. On the other hand, adding another store like Surrey does not increase actual corporate costs by much, presumably because the existing corporate staff will be able to oversee the new store as well.
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SOLUTION EXHIBIT 11‐18 Relevant‐Revenue and Relevant‐Cost Analysis of Closing Surrey Store and Opening Another Store Like It. Incremental (Loss in Revenues) Revenues and and Savings in (Incremental Costs) Costs from Closing of Opening New Store Surrey Store Like Surrey Store (1) (2) Revenue Cost of goods sold Lease rent Labour costs Depreciation of equipment Utilities (electricity, heating) Corporate overhead costs Total costs Effect on operating income (loss)
$(860,000) 660,000 75,000 42,000 0 46,000 44,000 867,000 $ 7,000
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$ 860,000 (660,000) (75,000) (42,000) (22,000) (46,000) (4,000) (849,000) $ 11,000
Chapter 11
11‐19 (30–40 min.) Relevance of equipment costs. 1a. Statements of Cash Receipts and Disbursements Keep Buy New Machine Each Four Each Four Year Years Year Years Year 1 2, 3, 4 Together Year 1 2, 3, 4 Together Receipts from operations: Revenues $150,000 $150,000 $600,000 $150,000 $150,000 $600,000 Deduct disbursements: Other operating costs (110,000) (110,000) (440,000) (110,000) (110,000) (440,000) Operation of machine (15,000) (15,000) (60,000) (9,000) (9,000) (36,000) Purchase of “old” machine (20,000)* (20,000) (20,000) (20,000) Purchase of “new” equipment (24,000) (24,000) Cash inflow from sale of old equipment 8,000 8,000 $ 5,000 $ 25,000 $ 80,000 $ (5,000) $ 31,000 $ 88,000 Net cash inflow
*Some students ignore this item because it is the same for each alternative. However, note that a statement for the entire year has been requested. Obviously, the $20,000 would affect Year 1 only under both the “keep” and “buy” alternatives. The difference is $8,000 for four years taken together. In particular, note that the $20,000 book value can be omitted from the comparison. Merely cross out the entire line; although the column totals are affected, the net difference is still $8,000.
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11‐19 (cont’d) 1b. Again, the difference is $8,000: Income Statements Revenues Costs (excluding disposal): Other operating costs Depreciation Operating costs of machine Total costs (excluding disposal) Loss on disposal: Book value (“cost”) Proceeds (“revenue”) Loss on disposal Total costs Operating income
Keep Each Four Year Years 1, 2, 3, 4 Together $150,000 $600,000 110,000 440,000 5,000 20,000 15,000 60,000 130,000 520,000 130,000 520,000 $ 20,000 $ 80,000
Buy New Machine Each Four Years Year Together Year 1 2, 3, 4 $150,000 $150,000 $600,000 110,000 110,000 440,000 6,000 6,000 24,000 9,000 9,000 36,000 125,000 125,000 500,000 20,000 20,000* (8,000) (8,000) 12,000 12,000 137,000 512,000 125,000 $ 13,000 $ 25,000 $ 88,000
As in part (1), the $20,000 book value may be omitted from the comparison without changing the $8,000 difference. This adjustment would mean excluding the depreciation item of $5,000 per year (a cumulative effect of $20,000) under the “keep” alternative and excluding the book value item of $20,000 in the loss on disposal computation under the “buy” alternative. 1c. The $20,000 purchase cost of the old equipment, the revenues, and the other operating costs are irrelevant because their amounts are common to both alternatives. *
2.
The net difference would be unaffected. Any number may be substituted for the original $20,000 figure without changing the final answer. Of course, the net cash outflows under both alternatives would be high. The Auto Wash manager really blundered. However, keeping the old equipment will increase the cost of the blunder to the cumulative tune of $8,000 over the next four years.
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11‐19 (cont’d) 3.
Book value is irrelevant in decisions about the replacement of equipment, because it is a past (historical) cost. All past costs are down the drain. Nothing can change what has already been spent or what has already happened. The $20,000 has been spent. How it is subsequently accounted for is irrelevant. The analysis in requirement (1) clearly shows that we may completely ignore the $20,000 and still have a correct analysis. The only relevant items are those expected future items that will differ among alternatives. Despite the economic analysis shown here, many managers would keep the old machine rather than replace it. Why? Because, in many organizations, the income statements of part (2) would be a principal means of evaluating performance. Note that the first‐year operating income would be higher under the “keep” alternative. The conventional accrual accounting model might motivate managers toward maximizing their first‐year reported operating income at the expense of long‐run cumulative betterment for the organization as a whole. This criticism is often made of the accrual accounting model. That is, the action favoured by the “correct” or “best” economic decision model may not be taken because the performance‐evaluation model is either inconsistent with the decision model or because the focus is on only the short‐run part of the performance‐evaluation model. There is yet another potential conflict between the decision model and the performance evaluation model. Replacing the machine so soon after it is purchased may reflect badly on the manager’s capabilities and performance. Why didn’t the manager search and find the new machine before buying the old machine? Replacing the old machine one day later at a loss may make the manager appear incompetent to his or her superiors. If the manager’s bosses have no knowledge of the better machine, the manager may prefer to keep the existing machine rather than alert his or her bosses about the better machine.
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11‐20 (30 min.) Product mix, constrained resource. 1.
Nealy Tersa Pelta Total
Units (1) 1,800 4,500 39,000
Machine Hrs Per Unit (2) = Var. Mach. Cost/Unit ÷ $200/Hour $600 ÷ $200 = 3 $500 ÷ $200 = 2.5 $200 ÷ $200 = 1
Machine Hrs Demanded (3) = (1) × (2) 5,400 11,250 39,000 55,650
2. Selling price Variable costs: Direct materials Variable machining Sales commissions (5%, 5%, 10%) Total variable costs Contribution margin per unit 3.
Nealy $3,000 750 600
Tersa $2,100 500 500
Pelta $800 100 200
150 1,500 $1,500
105 1,105 $ 995
80 380 $420
Total machine hours needed to satisfy demand exceed the machine hours available (55,650 needed > 50,000 available). Consequently Marion Taylor needs to evaluate these products based on the contribution margin per machine hour. Nealy Tersa Pelta Unit contribution margin $1,500 $995 $420 Machine‐hours (MH) per unit ÷3 MH ÷2.5 MH ÷1 MH Unit contribution margin per MH $ 500 $398 $420
Based on this analysis, Marion Taylor should produce to meet the demand for products with the highest unit contribution margin per machine hour, first Nealy, then Pelta, and finally Tersa. The optimal product mix will be as follows: Nealy Pelta Tersa Total
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1,800 units = 5,400 MH 39,000 units = 39,000 MH 2,240 (5,600 MH ÷ 2.5 MH/unit) units = 5,600 MH (50,000 ─ 5,400 ─ 39,000) 50,000 MH
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11‐20 (cont’d) 4.
The optimal product mix in Part 3 satisfies the demand for Nealy and Pelta and leaves only 2,260 units (4,500 ─ 2,240) of Tersa unfilled. These remaining units of Tersa require 5,650 machine hours (2,260 units 2.5 MH per unit). The maximum price Marion Taylor is willing to pay for extra machine hours is $398, which is the unit contribution per machine hour for additional units of Tersa. That is, total cost per machine‐hour for these units will be $398 + $200 (variable cost per machine‐hour) = $598 per machine‐hour.
11‐21 (10 min.) Sell or process further. Xylon should process the Aardyn further and turn it into Anardyn. The incremental costs of processing further are: $6,945 (given) The incremental revenues of processing further are: Revenues if processed further ($2.38 × 9,600) $22,848 Revenues if sold at splitoff point 15,360 Incremental revenues 7,488 Net benefit $ 543
11‐22 (30 min.) Special order, activity‐based costing. 1.
Award Plus’ operating income under the alternatives of accepting/rejecting the special order are: Without With One‐ One‐Time Time Only Only Special Special Order Order Difference 7,500 Units 10,000 Units 2,500 Units
Revenue Variable costs:
$1,125,000
$1,375,000
262,500
350,000
Direct materials Direct manufacturing labour Batch manufacturing costs Fixed costs: Fixed manufacturing costs Fixed marketing costs Total costs Operating income 1
$262,500 7,500
10,000
2
$300,000 7,500
300,000
$250,000
1
87,500
2
100,000
3
400,000
75,000
87,500
12,500
275,000 175,000 1,087,500 $ 37,500
275,000 175,000 1,287,500 $ 87,500
–– –– 200,000 $ 50,000
10,000
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3
$75,000 + (25 $500)
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11‐22 (cont’d) Alternatively, we could calculate the incremental revenue and the incremental costs of the additional 2,500 units as follows: Incremental revenue $100 2,500 $250,000 $262,500 Incremental direct manufacturing costs 2,500 87,500 7,500 $300,000 Incremental direct manufacturing costs 2,500 100,000 7,500 Incremental batch manufacturing costs $500 25 12,500 Total incremental costs 200,000 Total incremental operating income from accepting the special order $ 50,000
2.
Award Plus should accept the one‐time‐only special order if it has no long‐term implications because accepting the order increases Award Plus’ operating income by $50,000. If, however, accepting the special order would cause the regular customers to be dissatisfied or to demand lower prices, then Award Plus will have to trade off the $50,000 gain from accepting the special order against the operating income it might lose from regular customers. Award Plus has a capacity of 9,000 medals. Therefore, if it accepts the special one‐time order of 2,500 medals, it can sell only 6,500 medals instead of the 7,500 medals that it currently sells to existing customers. That is, by accepting the special order, Award Plus must forgo sales of 1,000 medals to its regular customers. Alternatively, Award Plus can reject the special order and continue to sell 7,500 medals to its regular customers. Award Plus’ operating income from selling 6,500 medals to regular customers and 2,500 medals under one‐time special order follow:
Revenues (6,500 $150) + (2,500 $100)
$1,225,000
1
1
Direct materials (6,500 $35 ) + (2,500 $35 ) 2
315,000 2
Direct manufacturing labour (6,500 $40 ) +(2,500 $40 ) 3
Batch manufacturing costs (130 $500) + (25 $500) Fixed manufacturing costs Fixed marketing costs Total costs Operating income
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360,000 77,500 275,000 175,000 1,202,500 $ 22,500
Chapter 11
11‐22 (cont’d) 1
$35 =
$262,500 7,500
2
$40 =
$300,000 7,500
3
Award Plus makes regular medals in batch sizes of 50. To produce 6,500 medals requires 130 (6,500 ÷ 50) batches. Accepting the special order will result in a decrease in operating income of $15,000 ($37,500 – $22,500). The special order should, therefore, be rejected. A more direct approach would be to focus on the incremental effects––the benefits of accepting the special order of 2,500 units versus the costs of selling 1,000 fewer units to regular customers. Increase in operating income from the 2,500‐unit special order equals $50,000 (requirement 1). The loss in operating income from selling 1,000 fewer units to regular customers equals: Lost revenue, $150 1,000 Savings in direct materials costs, $35 1,000 Savings in direct manufacturing labour costs, $40 1,000 Savings in batch manufacturing costs, $500 20 Operating income lost
$(150,000) 35,000 40,000 10,000 $ (65,000)
Accepting the special order will result in a decrease in operating income of $15,000 ($50,000 – $65,000). The special order should, therefore, be rejected. 3. Award Plus should not accept the special order. Increase in operating income by selling 2,500 units under the special order (requirement 1) $ 50,000 Operating income lost from existing customers ($10 7,500) (75,000) Net effect on operating income of accepting special order $(25,000) The special order should, therefore, be rejected.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
11‐23 (30 min.) Make versus buy, activity‐based costing. 1.
The expected manufacturing cost per unit of CMCBs in 2013 is as follows:
Total Manufacturing Manufacturing Costs of CMCB Cost per Unit (1) (2) = (1) ÷ 10,000 $170 Direct materials, $170 10,000 $1,700,000 45 Direct manufacturing labour, $45 10,000 450,000 Variable batch manufacturing costs, $1,500 80 12 120,000 Fixed manufacturing costs 32 Avoidable fixed manufacturing costs 320,000 80 Unavoidable fixed manufacturing costs 800,000 $3,390,000 $339 Total manufacturing costs 2. The following table identifies the incremental costs in 2013 if Svenson (a) made CMCBs and (b) purchased CMCBs from Minton. Total Per‐Unit Incremental Costs Incremental Costs Incremental Items Make Buy Make Buy Cost of purchasing CMCBs from $3,000,000 $300 Minton $170 Direct materials $1,700,000 45 Direct manufacturing labour 450,000 12 Variable batch manufacturing costs 120,000 32 Avoidable fixed manufacturing costs 320,000 $2,590,000 $3,000,000 $259 $300 Total incremental costs $410,000 Difference in favour of making $41 Note that the opportunity cost of using capacity to make CMCBs is zero since Svenson would keep this capacity idle if it purchases CMCBs from Minton. Svenson should continue to manufacture the CMCBs internally since the incremental costs to manufacture are $259 per unit compared to the $300 per unit that Minton has quoted. Note that the unavoidable fixed manufacturing costs of $800,000 ($80 per unit) will continue to be incurred whether Svenson makes or buys CMCBs. These are not incremental costs under either the make or the buy alternative and hence, are irrelevant.
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Chapter 11
11‐23 (cont’d) 3.
Svenson should continue to make CMCBs. The simplest way to analyze this problem is to recognize that Svenson would prefer to keep any excess capacity idle rather than use it to make CB3s. Why? Because expected incremental future revenues from CB3s, $2,000,000, are less than expected incremental future costs, $2,150,000. If Svenson keeps its capacity idle, we know from requirement 2 that it should make CMCBs rather than buy them. An important point to note is that, because Svenson forgoes no contribution by not being able to make and sell CB3s, the opportunity cost of using its facilities to make CMCBs is zero. It is, therefore, not forgoing any profits by using the capacity to manufacture CMCBs. If it does not manufacture CMCBs, rather than lose money on CB3s, Svenson will keep capacity idle. A longer and more detailed approach is to use the total alternatives or opportunity cost analyses shown in Exhibit 11‐6 of the chapter. Choices for Svenson Buy CMCBs Make CMCBs Buy CMCBs and Do Not and Make and Do Not Make CB3s Make CB3s CB3s Relevant Items TOTAL‐ALTERNATIVES APPROACH TO MAKE‐OR‐BUY DECISIONS Total incremental costs of making/buying CMCBs (from $3,000,000 $3,000,000 requirement 2) $2,590,000 Excess of future costs over future revenues from CB3s 0 0 150,000 Total relevant costs $2,590,000 $3,000,000 $3,150,000 Svenson will minimize manufacturing costs by making CMCBs. OPPORTUNITY‐COST APPROACH TO MAKE‐OR‐BUY DECISIONS Total incremental costs of making/buying CMCBs (from requirement 2) $2,590,000 $3,000,000 $3,000,000 Opportunity cost: profit contribution forgone because * * capacity will not be used to 0 0 0 make CB3s $3,000,000 $3,000,000 Total relevant costs $2,590,000 *Opportunity cost is 0 because Svenson does not give up anything by not making CB3s. Svenson is best off leaving the capacity idle (rather than manufacturing and selling CB3s).
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11‐24 (25 min.) Product mix, constrained resource. 1. Selling price Variable costs: Direct materials (DM) Labour and other costs Total variable costs Contribution margin Kilograms of DM per unit1 Contribution margin per lb.
A110 $84
B382 $ 56 15 27 42 $ 14 ÷5 kg $2.80 per kg
24 28 52 $32 ÷8 kg $ 4 per kg
C657 $70 9 40 49 $21 ÷ 3 kg $ 7 per kg
1
A110:
B382: C657:
Direct material cost per unit Cost per kg of Bistide Direct material cost per unit Cost per kg of Bistide Direct material cost per unit Cost per kg of Bistide
= = =
$24 = 8 kg per unit $3 $15 = 5 kg per unit $3 $9 = 3 kg per unit $3
First, satisfy minimum requirements. Minimum units Times kilograms per unit Kilograms needed to produce minimum units
A110 B382 200 200 ×8 kg per unit ×5 kg per unit 1,600 kg
1,000 kg
C657 200 ×3 kg per unit 600 kg
Total
3,200 kg
The remaining 1,800 kilograms (5,000 ─ 3,200) should be devoted to C657 because it has the highest contribution margin per kilogram of direct material. Since each unit of C657 requires 3 kilograms of Bistide, the remaining 1,800 kilograms can be used to produce another 600 units of C657. The following combination yields the highest contribution margin given the 5,000 kilograms constraint on availability of Bistide. A110: 200 units B382: 200 units C657: 800 units (200 minimum + 600 extra)
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Chapter 11
11‐24 (cont’d) 2.
The demand for Westford’s products exceeds the materials available. Assuming that fixed costs are covered by the original product mix, Westford should be willing to pay upto an additional $7 per kilogram (the contribution margin per kilogram of C657) for another 1,000 kilograms of Bistide. That is, Westford should be willing to pay $3 + $7 = $10 per kilogram of Bistide1. This cost assumes that sufficient demand exists to sell another 333 units (1000 kilograms ÷ 3 kilograms per unit) of C657. If not, then the maximum price falls to an additional $4 per kilogram (the contribution margin per kilogram of A110) so that Westford can produce up to 125 more units of A110 (1,000 kilograms ÷ 8 kilograms per unit). In this case, Westford would be willing to pay $3 + $4 = $7 per kilogram. If there is insufficient demand to sell another 125 units of A110, then the maximum price Westford would be willing to pay falls to an additional $2.80 per kilogram (the contribution margin per kilogram of B382). Westford would be willing to pay $2.80 + $3 = $5.80 per kilogram of Bistide.
An alternative calculation focuses on column 3 for C657 of the table in requirement 1. Selling price $70 Variable labour and other costs (excluding direct 40 materials) Contribution margin $30 Divided by kilograms of direct material per unit ÷3 kg Direct material cost per kilogram that Westford can pay without contribution margin becoming negative $10
1
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11‐25 (10 min.) Selection of most profitable product. Only Model 14 should be produced. The key to this problem is the relationship of manufacturing overhead to product. Note that it takes twice as long to produce Model 9; machine‐hours for Model 9 are twice that for Model 14. Management should choose the product mix that maximizes operating income for a given production capacity (the scarce resource in this situation). In this case, Model 14 will yield a $20.90 contribution to fixed costs per unit of machine time, and Model 9 will yield $19.80: Model 9 Model 14 Selling price per unit $110.00 $77.00 Variable costs per unit 90.20 66.55 Contribution margin per unit $ 19.80 $ 10.45 Relative output (units of product) per machine‐hour × 1 × 2 Contribution margin per unit of machine time $ 19.80 $20.90
PROBLEMS
11‐26 (60 min.) Multiple choice, comprehensive problem on relevant costs. You may wish to assign only some of the parts. Manufacturing costs: Direct materials $1.00 Direct manufacturing labour 1.20 Variable manufac. indirect costs 0.80 Fixed manufac. indirect costs 0.50 Marketing costs: Variable $1.50 Fixed 0.90 1. (b) $3.50 Manufacturing Costs Variable $3.00 Fixed 0.50 Total $3.50
11–540
Total
Per Unit Fixed
Variable
$3.50
$0.50
$3.00
2.40 $5.90
0.90 $1.40
1.50 $4.50
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Chapter 11
11‐26 (cont’d) 2. (e)
None of the above. Decrease in operating income is $16,800.
Old Differential New 240,000 $6.00 $1,440,000 + $ 91,200* 264,000 $5.80 $1,531,200
Revenue Variable costs Manufacturing 240,000 $3.00 720,000 + 72,000 Marketing and other 240,000 $1.50 360,000 + 36,000 Variable costs 1,080,000 + 108,000 Contribution margin 360,000 – 16,800 Fixed costs Manufacturing $0.50 20,000 12 mos. = 120,000 –– –– Marketing and other $0.90 240,000 216,000 Fixed costs 336,000 — Operating income $ 24,000 – $ 16,800
264,000 $3.00 792,000 264,000 $1.50 396,000 1,188,000 343,200 120,000 216,000 336,000 $ 7,200
*Incremental revenue: $5.80 24,000 $139,200 Deduct price reduction $0.20 240,000 48,000 $ 91,200 3. (c) $3,500 If this order were not landed, fixed manufacturing overhead would be underallocated by $2,500, $0.50 per unit 5,000 units. Therefore, taking the order increases operating income by $1,000 plus $2,500, or $3,500. Another way to present the same idea follows: Revenues will increase by (5,000 $3.50 = $17,500) + $1,000 $18,500 Costs will increase by 5,000 $3.00 (15,000) – Fixed overhead will not change Change in operating income $ 3,500 Note that this answer to (3) assumes that variable marketing costs are not influenced by this contract. These 5,000 units do not displace any regular sales.
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11‐26 (cont’d) 4. (a)
$4,000 less ($7,500 – $3,500) Government Contract As above $3,500
Regular Channels Sales, 5,000 $6.00 $30,000 Increase in costs: Variable costs only: Manufacturing, 5,000 $3.00 $15,000 Marketing, 5,000 $1.50 7,500 22,500 Fixed costs are not affected Change in operating income $ 7,500
5. (b) $4.15 Differential costs: Variable: Manufacturing $3.00 Shipping 0.75 $3.75 10,000 Fixed: $4,000 ÷ 10,000 0.40 10,000 $4.15 10,000 Selling price to break even is $4.15 per unit.
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$37,500 4,000 $41,500
Chapter 11
11‐27
Multiple choice, comprehensive problem on relevant costs.
6. (e) $1.50, the variable marketing costs. The other costs are past costs and therefore, are irrelevant. 7. (e) None of these. The correct answer is $3.55. This part always gives students trouble. The short‐cut solution below is followed by a longer solution that is helpful to students. Short‐cut solution: The highest price to be paid would be measured by those costs that could be avoided by halting production and subcontracting: Variable manufacturing costs $3.00 Fixed manufacturing costs saved $60,000 ÷ 240,000 0.25 Marketing costs (0.20 $1.50) 0.30 Total costs $3.55 Longer but clearer solution: Comparative Annual Income Statement Present Difference Proposed $ – $1,440,000 Revenues $1,440,000 Variable costs: +132,000 Manufacturing, 240,000 $3.00 720,000 852,000* – 72,000 Marketing and other, 240,000 $1.50 360,000 288,000 Variable costs 1,080,000 1,140,000 360,000 300,000 Contribution margin Fixed costs: 120,000 – 60,000 60,000 Manufacturing 216,000 216,000 Marketing and other Total fixed costs 336,000 276,000 Operating income $ 24,000 $ 0 $ 24,000 *This solution is obtained by filling in the above schedule with all the known figures and working “from the bottom up” and “from the top down” to the unknown purchase figure. Maximum variable costs that can be incurred, $1,140,000 – $288,000 = maximum purchase costs, or $852,000. Divide $852,000 by 240,000 units, which yields a maximum purchase price of $3.55.
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11‐28 (20–25 min.) Relevant costs, contribution margin, product emphasis. 1.
Cola $18.80 14.20 $ 4.60
Lemonade $20.00 16.10 $ 3.90
Punch $27.10 20.70 $ 6.40
Natural Orange Juice $39.20 30.20 $ 9.00
Selling price Deduct variable cost per case Contribution margin per case 2. The argument fails to recognize that shelf space is the constraining factor. There are only 12 feet of front shelf space to be devoted to drinks. Sexton should aim to get the highest daily contribution margin per foot of front shelf space: Natural Orange Cola Lemonade Punch Juice Contribution margin per case $ 4.60 $ 3.90 $ 6.40 $ 9.00 Sales (number of cases) per foot of shelf space per day 25 24 4 5 Daily contribution per foot $93.60 $25.60 $45.00 of front shelf space $115.00 3. The allocation that maximizes the daily contribution from soft drink sales is: Daily Contribution Feet of per Foot of Total Contribution Shelf Space Front Shelf Space Margin per Day Cola 6 $115.00 $ 690.00 Lemonade 4 93.60 374.40 Natural Orange Juice 1 45.00 45.00 Punch 1 25.60 25.60 $1,135.00 The maximum of six feet of front shelf space will be devoted to Cola because it has the highest contribution margin per unit of the constraining factor. Four feet of front shelf space will be devoted to Lemonade, which has the second highest contribution margin per unit of the constraining factor. No more shelf space can be devoted to Lemonade since each of the remaining two products, Natural Orange Juice and Punch (that have the second lowest and lowest contribution margins per unit of the constraining factor) must each be given at least one foot of front shelf space.
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Chapter 11
11‐29 (20 min.) Opportunity costs. 1.
The opportunity cost to Wolverine of producing the 2,000 units of Orangebo is the contribution margin lost on the 2,000 units of Rosebo that would have to be forgone, as computed below:
Selling price Variable costs per unit: Direct materials Direct manufacturing labour Variable manufacturing overhead Variable marketing costs Contribution margin per unit Contribution margin for 2,000 units
$ 2 3 2 4
$20
11 $ 9 $ 18,000
The opportunity cost is $18,000. Opportunity cost is the maximum contribution to operating income that is forgone (rejected) by not using a limited resource in its next‐best alternative use.
2.
Contribution margin from manufacturing 2,000 units of Orangebo and purchasing 2,000 units of Rosebo from Buckeye is $16,000, as follows:
Selling price Variable costs per unit: Purchase costs Direct materials Direct manufacturing labour Variable manufacturing costs Variable marketing overhead Variable costs per unit Contribution margin per unit Contribution margin from selling 2,000 units of Orangebo and 2,000 units of Rosebo
Manufacture Orangebo
Purchase Rosebo
Total
$15 – 2 3 2 2 9 $ 6 $12,000
$20 14 4 18 $ 2 $4,000
$16,000
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
11‐29 (cont’d) As calculated in requirement 1, Wolverine’s contribution margin from continuing to manufacture 2,000 units of Rosebo is $18,000. Accepting the Miami Company and Buckeye offer will cost Wolverine $2,000 ($16,000 – $18,000). Hence, Wolverine should refuse the Miami Company and Buckeye Corporation’s offers. 3.
The minimum price would be $9, the sum of the incremental costs as computed in requirement 2. This follows because, if Wolverine has surplus capacity, the opportunity cost = $0. For the short‐run decision of whether to accept Orangebo’s offer, fixed costs of Wolverine are irrelevant. Only the incremental costs need to be covered for it to be worthwhile for Wolverine to accept the Orangebo offer.
11‐30 (30 min.) 1.
Optimal production plan, computer manufacturer.
Let X = Units of printers and Y = Units of desktop computers
Objective: Maximize total contribution margin of $240X + $120Y Constraints: For production line 1: 7.2X + 4.8Y 28.8 equation 1) For production line 2: 12X 24 equation 2) Sales of X and Y: Y – X >= 0 equation 3) Negative production impossible: X >= 0 equation 4) Y >= 0 equation 5) 2. Solution Exhibit 11‐30 presents a graphical summary of the relationships. The sales‐ mix constraint here is somewhat unusual. The X – Y = 0 line is the one going upward at a 45 ' angle from the origin. Using the trial‐and‐error method: Using equations 1) and 2): 7.2X + 4.8Y = 28.8 12X = 24 Multiply equation 2 by 0.6 and subtract from equation 1: 7.2X + 4.8Y = 28.8 7.2X + 0Y = 14.4 4.8Y = 14.4 Y = 3 Substitute Y=3 into equation 1 to find X: 7.2X + 4.8(3) = 28.8 X = 2 11–546
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Chapter 11
11‐30 (cont’d)
Using equations 3) and 2): Y – X = 0 12X = 24
Multiply equation 1 by 12 and subtract from equation 2: 12Y ‐ 12X = 0 0Y +12X = 24 12Y = 24 Y = 2 Substitute Y= 2 into equation 1: (2) – X = 0 X = 2
Using equations 1) and 4): 7.2X + 4.8Y = 28.8 X = 0 Multiply equation 2 by 7.2 and subtract from equation 1: 7.2X + 4.8Y = 28.8 7.2X + 0Y = 0 4.8Y = 28.8 Y = 6 Substitute Y = 6 into equation 1: 7.2X + 4.8(6) = 28.8 X = 0 Using equations 1) and 5): 7.2X + 4.8Y = 28.8 Y = 0
Multiply equation 2 by 4.8 and subtract from equation 1: 7.2X + 4.8Y = 28.8 4.8Y = 0 7.2X = 28.8 X = 4
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
11‐30 (cont’d)
Substitute X = 4 into equation 1: 7.2(4) + 4.8Y = 28.8 Y = 0 Using equations 4) and 5): X = 0 Y = 0 The 4 corners of the area of feasible solutions are: (0,0), (2,2), (2,3), and (0,6) Trial 1 2 3 4
Corner (X,Y) (0; 0) (2; 2) (2; 3)* (0; 6)
Total Contribution Margin $240(0) + $120(0) = $ 0 240(2) + 120(2) = 720 240(2) + 120(3) = 840 240(0) + 120(6) = 720
*The optimal solution that maximizes operating income is 2 printers and 3 computers. SOLUTION EXHIBIT 11‐30 Graphic Solution to Find Optimal Mix, Information Technology, Inc.
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Chapter 11
11‐31 (30–40 min.) Optimal product mix. 1.
2.
Let D represent the batches of Della’s Delight made and sold. Let B represent the batches of Bonny’s Bourbon made and sold. The contribution margin per batch of Della’s Delight is $300. The contribution margin per batch of Bonny’s Bourbon is $250. The LP formulation for the decision is: Maximize $300D + $250 B Subject to 30D + 15B 660 (Mixing Department constraint) 15B 270 (Filling Department constraint) 10D + 15B 300 (Baking Department constraint) Solution Exhibit 11‐31 presents a graphical summary of the relationships. The optimal corner is the point (18, 8) i.e., 18 batches of Della’s Delights and 8 of Bonny’s Bourbons.
SOLUTION EXHIBIT 11‐31 Graphic Solution to Find Optimal Mix, Della Simpson, Inc. Della Simpson Production Model 50
45
(0,44) Mixing Dept. Constraint
B (batches of Bonny's Bourbons)
40
35
Equal Contribution Margin Lines
30
Optimal Corner (18,8) 25
20
Filling Dept. Constraint
(3,18) 0, 18 (0,18)
15
10
Feasible Region 5
Baking Dept. Constraint
0 0
5
10
15
20
(22,0)
25
30
35
40
D (batches of Della's Delight)
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
11‐31 (cont’d)
We next calculate the optimal production mix using the trial‐and‐error method. The corner point where the Mixing Dept. and Baking Dept. constraints intersect can be calculated as (18, 8) by solving: 30D + 15B = 660 (1) Mixing Dept. constraint 10D + 15B = 300 (2) Baking Dept. constraint Subtracting (2) from (1), we have 20D = 360 or D = 18 Substituting in (2) (10 18) + 15B = 300 that is, 15B = 300 180 = 120 or B = 8 The corner point where the Filling and Baking Department constraints intersect can be calculated as (3,18) by substituting B = 18 (Filling Department constraint) into the Baking Department constraint: 10 D + (15 18) = 300 10 D = 300 270 = 30 D = 3 The feasible region, defined by 5 corner points, is shaded in Solution Exhibit 11‐ 40. We next use the trial‐and‐error method to check the contribution margins at each of the five corner points of the area of feasible solutions.
Trial 1 2 3 4 5
Corner (D,B) (0,0) (22,0) (18,8) (3,18) (0,18)
Total Contribution Margin ($300 0) + ($250 0) = $0 ($300 22) + ($250 0) = $6,600 ($300 18) + ($250 8) = $7,400 ($300 3) + ($250 18) = $5,400 ($300 0) + ($250 18) = $4,500
The optimal solution that maximizes contribution margin and operating income is 18 batches of Della’s Delights and 8 batches of Bonny’s Bourbons.
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Chapter 11
11‐31 (cont’d) SOLVER: Linear Program in Excel Contribution Margin Maximization The goal is to select the product mix to maximize total contribution margin on cookies. Therefore, total contribution margin is the objective function. Total contribution margin will be equal to the number of batches of each cookie produced, multiplied by the contribution margin (CM) per batch. The Excel function is SUMPRODUCT Objective Function
0
The data in the purple cells of the Contribution Margin Array are given but what Solver will provide is the output in the blue cells,Q Batches produced. Contribution Margin Array Product CM per Batch Quantity Produced Della's Delight 300 0 Bonnie's Burbon 250 You also must provide the data for minutes used in each of 3 activities as the Product Composition Array. There are 2 rows and 3 columns in this array of data. Another term is 2 x 3 matrix (rows always first then columns). these data are from the first table p. xxx of the text without the final row.
Product Composition Array Mixing
Filling
Della's Delight Bonnie's Burbon
Baking
30 15
0 15
10 15
The last row in the table in the text has been reported separately in a different format. There is a limit or constraint on the minutes available per day. The values in the purple cells must be greater than the values filled into the blue cells in the CM array, multiplied by the purple cells filled into the Product Composition Array. This is what the symbol in the line above Supply limit means. Total Minutes Used Minutes Total
Mixing
Filling 0
660
0 <=
<=
<=
Supply Limit
Baking
0
270
300
We are trying to determine how many batches of each cookie to produce (blue cells). Within the Contribution Margin Array, the blue cells are a 2 x 1 matrix of their own. In addition within the Product Compositon Array, each process can be thought of as a matrix, yielding three 2 x 1 arrays. Because we now have arrays of the same dimensions, we can multiply them, which will give us the total number of minutes used in each process (green cells). For example, B36 =SUMPRODUCT(C17:C18, B26:B27). This function can be used to determine the total minutes used in the Fillilng and Baking processes as well.
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11‐31 (cont’d) SOLVER: Using Solver Step 1: Set the target cell which is the green cell beside the Objective Function B10 Step 2: Click Max because you are maximizing the contribution Margin. Step 3: In the "By Changing Cells" box, click the empty blue cell C17 and drag to C18. Step 4: Identify the constraints using the data in the Total Minutes Used matrix. Click "Add" beside the Subject to Constraints box. Click on the first cell, B36 and highlight to D36 then the ≤ symbol in Solver. Finally click on the Supply limit cell B38 and highlight to D38, click. If there are more constraints move to Add and enter the other constraints. Continue until you have entered all the constraints.
Step 5: When you finish adding constraints, move the cursor to the target cell B10 next to the Objective Function. Step 6: Move the cursor to Solve in the dialogue box and click on OK. All the empty cells will fill in. Objective Function 7400 Product D B Total Material Used Material
Units Produced
Contribution 300 250
Mixing
18 8
Filling
Total
660
120
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660
<=
Product Composition Matrix Mixing Product 1 Product 2
300
<=
<=
Supply Limit
Baking
270
Filling 30 15
300
Baking 0 15
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Chapter 11
11‐31 (cont’d)
The solution reports the value of the maximized contribution margin in the green highlighted target cell beside the objective function. Contribution margin will be $7,400. In the blue cells is reported the quantity of each type of cookine required to obtain this total contribution margin. When 18 batches of Della's Delights and 8 batches of Bonnie's Burbon are produced, contribution margin will be maximized.
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11‐32 (30‐40 min.) Opportunity costs, book value. 1.
Easyspread 2.0 has a higher relevant operating income than Easyspread 1.0. Based on this analysis, Easyspread 2.0 should be introduced immediately:
Relevant revenue Relevant costs: Manuals, diskettes Total relevant costs Relevant operating income
Easyspread 1.0 $165
$ 0 0 $165
Easyspread 2.0 $203.50 $ 27.50 27.50 $176.00
Reasons for other cost items being irrelevant are: Easyspread 1.0 • Manuals, diskettes—already incurred • Development costs—already incurred • Marketing and administration—fixed costs of period Easyspread 2.0 • Development costs—already incurred • Marketing and administration—fixed costs of period Note that total marketing and administration costs will not change whether Easyspread 2.0 is introduced on July 1, 2014, or on October 1, 2014. An alternative way to show that Easyspread 2.0 should be introduced immediately is: Total Per Unit (1) (2)=(1)÷60,000 Incremental revenues from July to September 2014 by introducing Easyspread 2.0 $203.50 immediately on July 1, 2014 $12,210,000a Incremental costs of manuals and diskettes in July–September 2014 if Easyspread 2.0 is introduced on July 1, 2014 1,650,000b 27.50 Incremental increase in operating income 10,560,000 176.00 Opportunity cost of selling Easyspread 2.0 is the lost revenue from not selling the existing stock of 60,000 units of Easyspread 1.0 (Recall that there are no further costs to be incurred to sell Easyspread 1.0.) 9,900,000c 165.00 Net relevant benefit $ 660,000 $ 11.00 a$12,210,000 = $203.50 60,000 b$1,650,000 = $27.50 60,000 c$9,900,000 = $165 60,000
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Chapter 11
11‐32 (cont’d) 2.
Other factors to be considered: a. Customer satisfaction. If 2.0 is significantly better than 1.0 for its customers, a customer‐driven organization would immediately introduce it unless other factors offset this bias towards “do what is best for the customer.” b. Quality level of Easyspread 2.0. It is critical for new software products to be fully debugged. Easyspread 2.0 must be error‐free. Consider an immediate release only if 2.0 passes all quality tests and can be fully supported by the salesforce. c. Importance of being perceived to be a market leader. Being first in the market with a new product can give Basil Software a “first‐mover advantage,” e.g., capturing an initial large share of the market that, in itself, causes future potential customers to lean towards purchasing Easyspread 2.0. Moreover, by introducing 2.0 earlier, Basil can get quick feedback from users about ways to further refine the software while its competitors are still working on their own first versions. Finally, by locking in early customers, you may increase the likelihood of these customers also buying future upgrades of Easyspread 2.0. d. Morale of developers. These are key people at Basil Software. Delaying introduction of a new product can hurt their morale, especially if a competitor then pre‐empts Basil from being viewed as a market leader. e. Development of business relationships with distributors. There are pros and cons here. The pro is that with 2.0 they will have a new product that will generate many sales at a higher selling price. Moreover, if rumors arise about 2.0 being planned, sales of 1.0 may plummet as people hold off buying until the new product is introduced. A possible con is that distributors may be stuck with unsold versions of 1.0. Will Basil be willing to take these units back as a credit against supplying 2.0? f. Alternative ways of disposing of Easyspread 1.0. One student suggested Basil donate all 60,000 Easyspread 1.0 packages to public schools and claim a tax deduction. Another student suggested there may be costs of disposing of Easyspread 1.0 (e.g., shredding the packages). g. Incentive compensation scheme at Basil Software. How will the writeoff (if any) on Easyspread 1.0 packages affect the compensation plan? Management at Basil may not view the costs of Easyspread 1.0 as a sunk cost if their bonus will be affected by a writeoff on Easyspread 1.0.
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11‐33 (20 min.) Choosing customers. If Broadway accepts the additional business from Kelly, it would take an additional 500 machine‐hours. If Broadway accepts all of Kelly’s and Taylor’s business for February, it would require 2,500 machine‐hours (1,500 hours for Taylor and 1,000 hours for Kelly). Broadway has only 2,000 hours of machine capacity. It must, therefore, choose how much of the Taylor or Kelly business to accept. To maximize operating income, Broadway should maximize contribution margin per unit of the constrained resource. (Fixed costs will remain unchanged at $100,000 regardless of the business Broadway chooses to accept in February, and is, therefore, irrelevant.) The contribution margin per unit of the constrained resource for each customer in January is: Taylor Kelly Corporation Corporation $32,000 $78,000 Contribution margin per machine‐hour = $52 = $64 1,500 500 Since the $80,000 of additional Kelly business in February is identical to jobs done in January, it will also have a contribution margin of $64 per machine‐hour, which is greater than the contribution margin of $52 per machine‐hour from Taylor. To maximize operating income, Broadway should first allocate all the capacity needed to take the Kelly Corporation business (1,000 machine‐hours) and then allocate the remaining 1,000 (2,000 – 1,000) machine‐hours to Taylor. Taylor Kelly Corporation Corporation Total Contribution margin per machine‐hour $52 $64 Machine‐hours to be worked 1,000 1,000 Contribution margin $52,000 $64,000 $116,000 Fixed costs 100,000 Operating income $ 16,000
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11‐34 (30 min.) Contribution approach, relevant costs. 1. 2.
3.
$ 500 (40) $ 460 × 200 $ 92,000 4,000 $ 88,000
If fare is $ 480.00 Commission at 8% of $480 (38.40) Net cash per ticket 441.60 Food and beverage cost per ticket 20.00 Contribution margin per passenger $ 421.60 Total contribution margin from passengers per flight ($421.60 × 212) $89,379.20 All other costs are irrelevant. On the basis of quantitative factors alone, Air Pacific should decrease its fare to $480 because reducing the fare gives Air Pacific a higher contribution margin from passengers ($89,379.20 versus $88,000). In evaluating whether Air Pacific should charter its plane to Travel International, we compare the charter alternative to the solution in requirement 2 because requirement 2 is preferred to requirement 1. Under requirement 2, contribution from passengers $89,379.20 Deduct fuel costs 14,000.00 Total contribution per flight $75,379.20 Air Pacific gets $74,500 per flight from chartering the plane to Travel International. On the basis of quantitative financial factors, Air Pacific is better off not chartering the plane and, instead, lowering its own fares.
Average one‐way fare per passenger Commission at 8% of $500 Net cash to Air Pacific per ticket Average number of passengers per flight Revenues per flight ($460 × 200) Food and beverage cost per flight ($20 × 200) Total contribution margin from passengers per flight
Other qualitative factors that Air Pacific should consider in coming to a decision are a. The lower risk from chartering its plane relative to the uncertainties regarding the number of passengers it might get on its scheduled flights. b. The stability of the relationship between Air Pacific and Travel International. If this is not a long‐term arrangement, Air Pacific may lose current market share and not benefit from sustained charter revenues.
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11‐35 (20 min.) 1.
Reduce conflict.
On the basis of Gray’s information, Pastel should buy RG1 from York Corporation rather than make it in‐house. The relevant costs and benefits analysis is as follows:
Incremental costs of purchasing 40,000 units of RG1, $23.10 40,000 Cost savings: Direct materials costs Direct manufacturing labour costs Manufacturing overhead costs Total cost savings Net benefit of outsourcing 2.
3.
$660,000 220,000 263,450
$(924,000)
1,143,450 $ 219,450
We need to determine the quantity of purchases from York Corporation at which the cost of purchasing equals the cost savings of $1,143,450. This quantity is $1,143,450 ÷ $23.10 = 49,500. If Pastel’s yield improves to 49,500 or greater (that is, scrap levels fall to 500 units or less), then continuing to manufacture in‐house will be preferred to purchasing from York. For example, if yields were 49,750, the cost savings from outsourcing would still be $1,143,450, but the incremental costs of purchasing 49,750 units from York Corporation would be $1,149,225 ($23.10 49,750), which exceeds the cost savings. In assessing the situation, a management accountant should consider the following: Clear reports using relevant and reliable information should be prepared. It is unethical for Berry to suggest that Gray change the cost numbers for the make alternative and for Gray to change the numbers in order to favour the make alternative. The management accountant has a responsibility to avoid actual or apparent conflicts of interest and to advise all appropriate parties of any potential conflict. Berry’s motivation for wanting Gray to reduce costs of the make alternative was to help his friends even though this may not be in the best interests of the company. In this regard, both Berry’s and Gray’s behaviours (if Gray agrees to reduce the cost of the make alternative) could be viewed as unethical. Gray should indicate to Berry that the costs derived under the make alternative are correct and consistent with the yield and quality experienced at the plant. If Berry still insists on making the changes and reducing the costs of manufacturing RG1 in‐‐ house, Gray should raise the matter with Berry’s superior, after informing Berry of his plans. If, after taking all these steps, there is continued pressure to understate the costs, Gray should consider resigning from the company, instead of engaging in unethical behaviour.
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11‐36 (30 min.) 1.
Equipment upgrade versus replacement.
Based on the analysis in the table below, TechMech will be better off by $180,000 over three years if it replaces the current equipment.
Over 3 years
Comparing Relevant Costs of Upgrade and Upgrade Replace Replace Alternatives (1) (2) Cash operating costs $140; $80 per desk 6,000 desks per yr. 3 yrs. $2,520,000 $1,440,000 Current disposal price (600,000) One time capital costs, written off periodically as 2,700,000 4,200,000 depreciation Total relevant costs $5,220,000 $5,040,000
Difference in favour of Replace (3) = (1) – (2) $1,080,000 600,000 (1,500,000) $ 180,000
Note that the book value of the current machine ($900,000) would either be written off as depreciation over three years under the upgrade option, or, all at once in the current year under the replace option. Its net effect would be the same in both alternatives: to increase costs by $900,000 over three years, hence it is irrelevant in this analysis. 2.
Suppose the capital expenditure to replace the equipment is $X. From requirement 1, column (2), substituting for the one‐time capital cost of replacement, the relevant cost of replacing is $1,440,000 – $600,000 + $X. From column (1), the relevant cost of upgrading is $5,220,000. We want to find X such that $1,440,000 – $600,000 + $X < $5,220,000 (i.e., TechMech will favour replacing) Solving the above inequality gives us X < $5,220,000 – $840,000 = $4,380,000. TechMech would prefer to replace, rather than upgrade, if the replacement cost of the new equipment does not exceed $4,380,000. Note that this result can also be obtained by taking the original replacement cost of $4,200,000 and adding to it the $180,000 difference in favour of replacement calculated in requirement 1.
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11‐36 (cont’d) 3.
Suppose the units produced and sold over 3 years equal y. Using data from requirement 1, column (1), the relevant cost of upgrade would be $140y + $2,700,000, and from column (2), the relevant cost of replacing the equipment would be $80y – $600,000 + $4,200,000. TechMech would want to upgrade if $140y + $2,700,000 < $80y – $600,000 + $4,200,000 $60y < $900,000 y < $900,000 $60 = 15,000 units or upgrade when y < 15,000 units (or 5,000 per year for 3 years) and replace when y > 15,000 units over 3 years. When production and sales volume is low (less than 5,000 per year), the higher operating costs under the upgrade option are more than offset by the savings in capital costs from upgrading. When production and sales volume is high, the higher capital costs of replacement are more than offset by the savings in operating costs in the replace option.
4.
Operating income for the first year under the upgrade and replace alternatives are shown below: Year 1 Upgrade Replace (1) (2) Revenues (6,000 $500) $3,000,000 $3,000,000 Cash operating costs $140; $80 per desk 6,000 desks per year 840,000 480,000 a Depreciation ($900,000 + $2,700,000) 3; $4,200,000 3 1,200,000 1,400,000 Loss on disposal of old equipment (0; $900,000 – $600,000) 0 300,000 Total costs 2,040,000 2,180,000 Operating Income $ 960,000 $ 820,000 aThe book value of the current production equipment is $1,500,000 3 5 = $900,000; it has a remaining useful life of 3 years.
First‐year operating income is higher by $140,000 under the upgrade alternative, and Dan Doria, with his one‐year horizon and operating income‐based bonus, will choose the upgrade alternative, even though, as seen in requirement 1, the replace alternative is better in the long run for TechMech. This exercise illustrates the possible conflict between the decision model and the performance evaluation model.
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11‐37 (40 min.) Optimal product mix. In order to maximize OmniSport’s profitability, OmniSport should manufacture 12,000 snowboard bindings, manufacture 1,000 pairs of skates, and purchase 6,000 pairs of skates from Colcott Inc. This combination of manufactured and purchased goods maximizes the contribution per available machine‐hour, which is the limiting resource, as shown below. Because snowboards have a higher contribution per machine‐hour than skates, OmniSport should manufacture the maximum number of snowboards. Because the contribution per manufactured pair of skates is higher than the contribution from a purchased pair of skates, total contribution will be maximized by using the remaining manufacturing capacity to produce skates and then purchasing the remaining required skates. This optimal combination is calculated as presented below.
Manufactured Purchased Manufactured Snowboard Skates Skates Bindings 1,000 pairs 12,000 6,000 pairs Per Per Per Unit Total Unit Total Unit Total Total $117.60 $705,600 $117.60 $117,600 $72.00 $864,000 $1,687,200
Selling price Variable costs Direct materials 90.00 540,000 9.60 9,600 24.00 288,000 837,600 Machine operating costs — — 14.40 14,400 7.60 91,200 105,600 1 — 28.80 28,800 2.40 28,800 57,600 Manufacturing overhead costs — Selling & administrative costs 4.802 28,800 18.00 18,000 9.603 115,200 162,000 Variable costs 94.80 568,800 70.80 70,800 43.60 523,200 1,162,800 Contribution margin $ 22.80 $136,800 $46.80 $46,800 $28.40 $340,800 $524,400 Fixed costs Manufacturing overhead 36,000 Marketing & administrative costs 72,000 Fixed costs 108,000 Operating income $ 416,400 Machine‐hours per unit — 1.5 0.5 Contribution per machine‐hour ($46.80 ÷ 1.5; $28.40 ÷ 0.5) — $31.20 $56.80 1) Total fixed overhead = 5,000 pairs of skates x $21.60 = $108,000 Fixed marketing & administrative costs = $108,000 ‐ $36,000 = $72,000 Fixed manufacturing allocation rate = $36,000/7,500 mh = $4.80/mh Snowboard binding variable manufacturing overhead rate = $7.20 ‐ $4.80 = $2.40 2) $12.00 $7.20 = $4.80 3) $16.80 $7.20 = $9.60
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11‐37 (cont’d)
OmniSport Contribution Analysis Total Machine‐ Machine‐ Total Hours Hours Machine‐ Product per Used Hour Unit Contribution Quantity Unit (3)= Balance Contribution (6)= (1) (2) (1)(2) (4) (5) (1)(5) Machine‐hours available 7,500 Snowboard bindings 12,000 0.5 6,000 1,500 $28.40 $340,800 Skates (pairs)—manufacture 1,000 1.5 1,500 — 46.80 46,800 Skates (pairs)—purchase 6,000 — — — 22.80 136,800 Total contribution 524,400 Less original contribution (5,000 pairs of skates $46.80 per pair) (234,000) Improvement in contribution $290,400
11‐38 (20 min.) Special order. 1. Revenue from special order ($25 10,000 bats) Variable manufacturing costs ($161 10,000 bats) Increase in operating income if Ripkin order accepted
1 Direct
$250,000 (160,000) $ 90,000
materials + Direct manufacturing labor + Variable manufacturing overhead = $12 $1 $3 $16
Louisville should accept Ripkin’s special order because it increases operating income by $90,000. Since no variable selling costs will be incurred on this order, this cost is irrelevant. Similarly, fixed costs are irrelevant because they will be incurred regardless of the decision. 2a. 1 Direct
Revenue from special order ($25 10,000 bats) Variable manufacturing costs ($16 10,000 bats) Contribution margin foregone ([$32─$181] 10,000 bats) Decrease in operating income if Ripkin order accepted
$250,000 (160,000) (140,000) $ (50,000)
matls. + Direct manuf. labor + Variable manuf. overhead + Variable selling exp. = $12 $1 $3 $2 $18
Based strictly on financial considerations, Louisville should reject Ripkin’s special order because it results in a $50,000 reduction in operating income.
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11‐38 (cont’d)
2b.
2c.
Louisville will be indifferent between the special order and continuing to sell to regular customers if the special order price is $30. At this price, Louisville recoups the variable manufacturing costs of $160,000 and the contribution margin given up from regular customers of $140,000 ([$160,000 + $140,000] ÷ 10,000 units = $30). Looked at a different way, Louisville expects the full price of $32 less the $2 saved on variable selling costs. Louisville may be willing to accept a loss on this special order if the possibility of future long‐term sales seem likely. However, Louisville should also consider the effect on customer relationships by refusing sales from existing customers. Also, Louisville cannot afford to adopt the special order price long‐term or with other customers who may ask for price concessions.
11‐39 (30–40 min.) Product mix. 1.
R3 HP6 Selling price Variable manufacturing cost per unit Variable marketing cost per unit Total variable costs per unit Contribution margin per unit
$121 72 18 90 $ 31
$180 120 42 162 $ 18
Contribution margin per hour of the constrained resource (the regular machine)
$31 / 1 = $31 $18 / 0.5 = $36
Total contribution margin from selling only R3 or only HP6 R3: $31 50,000; HP6: $36 50,000 Less Lease costs of high‐precision machine to produce and sell HP6 Net relevant benefit
$1,550,000
$1,800,000
$1,550,000
300,000 $1,500,000
Even though HP6 has the higher contribution margin per unit of the constrained resource, the fact that Pendleton must incur additional costs of $300,000 to achieve this higher contribution margin means that Pendleton is better off using its entire 50,000‐hour capacity on the regular machine to produce and sell 50,000 units (50,000 hours 1 hour per unit) of R3. The additional contribution from
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11‐39 (cont’d)
selling HP6 rather than R3 is $50,000 ($1,550,000 $1,500,000), which is not enough to cover the additional costs of leasing the high‐precision machine. Note that, because all other overhead costs are fixed and cannot be changed, they are irrelevant for the decision. 2.
If capacity of the regular machines is increased by 15,000 machine‐hours to 65,000 machine‐hours (50,000 originally + 15,000 new), the net relevant benefit from producing R3 and HP6 is as follows: R3 HP6 Total contribution margin from selling only R3 or only HP6 R3: $31 65,000; HP6: $36 65,000 $2,015,000 Less Lease costs of high‐precision machine that would be incurred if HP6 is produced and sold Less Cost of increasing capacity by 15,000 hours on regular machine 180,000 Net relevant benefit $1,835,000
$2,340,000 300,000 180,000 $1,860,000
Investing in the additional capacity increases Pendleton’s operating income by $310,000 ($1,860,000 calculated in requirement 2 minus $1,550,000 calculated in requirement 1), so Pendleton should add 15,000 hours to the regular machine. With the extra capacity available to it, Pendleton should use its entire capacity to produce HP6. Using all 65,000 hours of capacity to produce HP6 rather than to produce R3 generates additional contribution margin of $325,000 ($2,340,000 $2,015,000) which is more than the additional cost of $300,000 to lease the high‐ precision machine. Pendleton should therefore produce and sell 130,000 units of HP6 (65,000 hours 0.5 hours per unit of HP6) and zero units of R3. 3. Selling price Variable manufacturing costs per unit Variable marketing costs per unit Total variable costs per unit Contribution margin per unit
Contribution margin per hour of the constrained resource (the regular machine)
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R3
HP6
S3
$121 72 18 90 $ 31
$180 120 42 162 $ 18
$120 72 15 87 $ 33
$31 / 1 = $31 $18 / 0.5 = $36 $33 / 1 = $33
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Chapter 11
11‐39 (cont’d)
The contribution margin per machine hour is $3 higher for HP6 than S3. The additional contribution margin will cover the $300,000 fixed lease cost for HP6 at 100,000 machine hours. ($300,000/$3). At less than this level S3 is more profitable.The first step is to compare the operating profits that Pendleton could earn if it accepted the Carter Corporation offer for 20,000 units with the operating profits Pendleton is currently earning. To produce the 20,000 units of S3 requested by Carter Corporation, Pendleton would require 20,000 hours on the regular machine resulting in contribution margin of $33 20,000 = $660,000. Pendleton now has 45,000 hours available on the regular machine to produce R3 or HP6.
Total contribution margin from selling only R3 or only HP6 R3: $31 45,000; HP6: $36 45,000 Less Lease costs of high‐precision machine to produce and sell HP 6 Net relevant benefit
R3
HP6
$1,395,000
$1,620,000
$1,395,000
300,000 $1,320,000
Pendleton should use all the 45,000 hours of available capacity to produce 45,000 units of R3. Thus, the product mix that maximizes operating income is 20,000 units of S3, 45,000 units of R3, and zero units of HP6. This optimal mix results in a contribution margin of $2,055,000 ($660,000 from S3 and $1,395,000 from R3).
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11‐40 (30–40 min.) Relevance, short‐term. 1.
The variable costs required to manufacture 150,000 starter assemblies are
Direct materials Direct manufacturing labour Variable manufacturing overhead Total variable costs
$220,000 165,000 110,000 $495,000
The variable costs per unit are $495,000 ÷ 150,000 = $3.30 per unit. Let X = number of starter assemblies required in the next 12 months. The data can be presented in both “all data” and “relevant data” formats:
All Data Alternative Alternative 1: Make 2: Buy – $ 3.3X $150,000 150,000 – 100,000 80,000 40,000 – 80,000 4X – $370,000 $230,000 + $ 3.3X + $ 4X
Relevant Data Alternative Alternative 1: Make 2: Buy $ 3.3X – – – 100,000 – 40,000 $80,000 80,000 – – 4X $220,000 $80,000 + $ 3.3X + $ 4X
Variable manufacturing costs Fixed general manufacturing overhead Fixed overhead, avoidable Division 2 manager’s salary Division 3 manager’s salary Purchase cost, if bought from Tidnish Electronics Total The number of units at which the costs of make and buy are equivalent is All data analysis: $370,000 + $3.3X = $230,000 + $4X X = 200,000 or Relevant data analysis: $220,000 + $3.3X = $80,000 + $4X X = 200,000
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11‐40 (cont’d)
Assuming cost minimization is the objective, then • If production is expected to be less than 200,000 units, it is preferable to buy units from Tidnish. • If production is expected to exceed 200,000 units, it is preferable to manufacture internally (make) the units. • If production is expected to be 200,000 units, Oxford should be indifferent between buying units from Tidnish and manufacturing (making) the units internally. 2.
The information on the storage cost, which is avoidable if self‐manufacture is discontinued, is relevant; these storage charges represent current outlays that are avoidable if self‐manufacture is discontinued. Assume these $50,000 charges are represented as an opportunity cost of the make alternative. The costs of internal manufacture that incorporate this $50,000 opportunity cost are $420,000 + $3.3X All data analysis: Relevant data analysis: $270,000 + $3.3X
The number of units at which the costs of make and buy are equivalent is
All data analysis: $420,000 + $3.3X = $230,000 + $4X X = 271,429 Relevant data analysis: $270,000 + $3.3X = $80,000 + $4X X = 271,429 If production is expected to be less than 271,429, it is preferable to buy units from Tidnish. If production is expected to exceed 271,429, it is preferable to manufacture the units internally.
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COLLABORATIVE LEARNING CASES
11‐41 (30 min.) Make versus buy, governance. 1. Direct materials per unit = $195,000 30,000 = 6.50 Direct manufacturing labour per unit = $120,000 30,000 = $4 Variable manufacturing overhead for 30,000 units = 40% of $225,000 = $90,000 Variable manufacturing overhead as a percentage of direct manufacturing labour = $90,000 $120,000 = 75% Fixed manufacturing overhead = 60% of $225,000 = $135,000 SOLUTION EXHIBIT 11‐41A Manuf. Costs for 32,000 Manuf. Costs for Units with 30,000 Porter Estimates Units (1) (2) Purchasing costs ($17.30/unit 32,000 units) Direct materials ($6.50/unit 30,000; 32,000 units) $195,000 $208,000 128,000 Direct manufacturing labour ($4/unit 30,000; 32,000 units) 120,000 Plant space rental (or penalty to terminate) 84,000 84,000 Equipment leasing (or penalty to terminate) 36,000 36,000 Variable overhead (75% of direct manufacturing labour) 90,000 96,000 135,000 Fixed manufacturing overhead 135,000 Total manufacturing or purchasing costs $660,000 $687,000
Purchase Costs for 32,000 Units with Porter Estimates (3) $553,600 10,000 5,000 135,000 $703,600
On the basis of Porter’s estimates, Solution Exhibit 11‐41A suggests that in 2014, the cost to purchase 32,000 units of MTR‐2000 will be $703,600, which is greater than the estimated $687,000 costs to manufacture MTR‐2000 in‐house. Based solely on these financial results, the 32,000 units of MTR‐2000 for 2014 should be manufactured in‐house.
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11‐41 (cont’d)
SOLUTION EXHIBIT 11‐41B
Purchasing costs ($17.30/unit 32,000 units) Direct materials ($208,000 1.08) Direct manufacturing labour ($128,000 1.05) Plant space rental (or penalty to terminate) Equipment leasing (or penalty to terminate) Variable overhead (75% of direct mfg. labour) Fixed manufacturing overhead Total manufacturing or purchasing costs
2.
Manufacturing Costs for 32,000 Units w/ Hardt Estimates (4) $224,640 134,400 84,000 36,000 100,800 135,000 $714,840
Purchase Costs for 32,000 Units w/ Hardt Estimates (5) $553,600 10,000 3,000 135,000 $701,600
Based solely on the financial results shown in Solution Exhibit 11‐41B, Hardt’s estimates suggest that the 32,000 units of MTR‐2000 should be purchased from Marley. The total cost from Marley would be $701,600, or $13,240 less than if the units were made by Paibec. At least four other factors that Paibec Corporation should consider before agreeing to purchase MTR‐2000 from Marley Company include the following: In future years, Paibec will not incur the rental and lease contract termination costs on its annual contacts that it will incur in 2014. This will make the purchase option even more attractive, in a financial sense. But then, Marley’s own longevity, its ability to provide the required units of MTR‐2000, and its demanded price should be considered, since terminating the contracts may make the make‐versus‐buy decision a long‐term one for Paibec. The quality of the Marley component should be equal to, or better than, the quality of the internally made component. Otherwise, the quality of the final product might be compromised and Paibec’s reputation affected. Marley’s reliability as an on‐time supplier is important, since late deliveries could hamper Paibec’s production schedule and delivery dates for the final product. Layoffs may result if the component is outsourced to Marley. This could impact Paibec’s other employees and cause labour problems or affect the company’s position in the community. In addition, there may be labour termination costs, which have not been factored into the analysis.
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11‐41 (cont’d) 3.
Referring to “Standards of Ethical Conduct for Management Accountants,” Lynn Hardt would consider the request of John Porter to be unethical for the following reasons. Competence Prepare complete and clear reports and recommendations after appropriate analysis of relevant and reliable information. Adjusting cost numbers violates the competence standard. Integrity Refrain from either actively or passively subverting the attainment of the organization’s legitimate and ethical objectives. Paibec has a legitimate objective of trying to obtain the component at the lowest cost possible, regardless of whether it is manufactured internally or outsourced to Marley. Communicate unfavourable as well as favourable information and professional judgments or opinions. Hardt needs to communicate the proper and accurate results of the analysis, regardless of whether or not it favours internal production. Refrain from engaging in or supporting any activity that would discredit the profession. Falsifying the analysis would discredit Hardt and the profession. Credibility Communicate information fairly and objectively. Hardt needs to perform an objective make‐versus‐buy analysis and communicate the results fairly. Disclose fully all relevant information that could reasonably be expected to influence an intended user’s understanding of the reports, comments, and recommendations presented. Hardt needs to fully disclose the analysis and the expected cost increases. Confidentiality Not affected by this decision.
Hardt should indicate to Porter that the costs she has derived under the make alternative are correct. If Porter still insists on making the changes to lower the costs of making MTR‐2000 internally, Hardt should raise the matter with Porter’s superior, after informing Porter of her plans. If, after taking all these steps, there is a continued pressure to understate the costs, Hardt should consider resigning from the company, rather than engage in unethical conduct.
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11‐42 (30‐40 min.) 1.
2.
Relevance, short‐term.
Hernandez Corporation has already purchased the 10,000 kilograms of the special cement that it needs, so it will incur no incremental costs. Alternatively stated, the costs of materials are past (sunk) costs. If Hernandez obtained Contract No. 2 a month from now, it would cost $25,000 in substitute material (10,000 kilograms $2.50 per kilogram). There is, therefore, a cost (lost benefit) of $25,000 by using the special cement on Contract No. 1 now. Alternatively, Hernandez could sell the special cement immediately for $16,000. The opportunity cost that Hernandez should use is the benefit it would get in the next‐best alternative should it not use the cement in Contract No. 1. The greater of these two benefits is using the cement in Contract No. 2. The opportunity cost is $25,000. The relevant cost that Gomez should use when bidding on Contract No. 1 is: Incremental cost Plus opportunity cost Relevant cost
$ 0 25,000 $25,000
As in Question 1, the incremental costs of acquiring the special cement for use on Contract No. 1 are zero because Hernandez has already purchased the material. If Hernandez does not land Contract No. 2, the opportunity cost of using the special cement for Contract No. 1 is $15,000 (10,000 kilograms $1.50 per kilogram), the amount Hernandez would get if it sold the special cement one month from now. Gomez assesses a probability of 0.7 that the special cement will be used on Contract No. 2 and a probability of 0.3 that the special cement will be sold. The expected benefit of holding the special cement and not using it on Contract No. 1 is: = (0.7 $25,000*) + (0.3 $15,000**) = $17,500 + $4,500 = $22,000 * relevant cost if special cement is used in Contract No. 2 (see requirement 1) ** relevant cost if special cement is sold one month from now Alternatively, the special cement can be sold right away and fetch $16,000. The opportunity cost is the greater of these two benefits and hence equals $22,000. When bidding on the Contract, Gomez should use:
3.
Incremental cost Plus opportunity cost Relevant cost
$ 0 22,000 $22,000
In this case, the benefit of selling the cement now is $23,000, while the benefit of using the cement in Contract No. 2 is $25,000. The opportunity cost of using the cement in Contract No. 1 is the lesser of these two numbers, $23,000. Incremental cost $ 0 Plus opportunity cost 23,000 Relevant cost $23,000
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CHAPTER 12 PRICING DECISIONS, PRODUCT PROFITABILITY DECISIONS, AND COST MANAGEMENT
SHORT‐ANSWER QUESTIONS
12‐1 The three major influences on pricing decisions are: (a) (b) (c)
Customers Competitors Costs
12‐2 There are many circumstances when a company might price below full cost, but the key issue is capacity. When a company has idle capacity, pricing to cover outlay costs (normally variable costs but may include relevant fixed costs) will contribute to fixed cost coverage and will be considered by the firm. This could apply in decisions to accept or reject special orders, but could also apply to pricing of existing products. With idle capacity the company might consider pricing a new or struggling product below full cost to penetrate the market and gain market share. The company might also price below full cost to be in line with market‐based pricing. It will then work to achieve cost reductions. 12‐3 Two examples of pricing decisions with a short‐run focus: (a) Pricing for a one‐time‐only special order with no long‐term implications. (b) Adjusting product mix and volume in a competitive market. 12‐4 Activity‐based costing helps managers in pricing decisions in two ways. (a) It gives managers more accurate product‐cost information for making pricing decisions. (b) It helps managers to manage costs during value engineering by identifying the cost impact of eliminating, reducing, or changing various activities. 12‐5 Two alternative approaches for long‐run pricing decisions are: (a) Market‐based pricing, an important form of which is target pricing. The market‐based approach asks, “Given what our customers want and how our competitors will react to what we do, what price should we charge?” (b) Cost‐based pricing which asks, “What does it cost us to make this product, and hence what price should we charge that will recoup our costs and produce a desired profit?” 12‐6 Product life cycle means different things to different stakeholders. To the seller it means a cradle to grave total cost of the product or service, which may include recycling, reclamation and reuse of product components. To the buyer it means all costs of ownership, operations, maintenance and disposal of a product. 12–572
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12‐7 Collusive pricing is the practice among competitors of negotiating a price above the competitive price, at which all will sell their product or service. It is illegal because it lessens or unduly restrains competition. Predatory pricing arises when one manufacturer sells output at less than the total variable cost of the product repeatedly, with the intent of obstructing or eliminating competition. Both are illegal under the Competition Act of Canada. 12‐8 Life‐cycle budgeting is an estimate of the revenue and costs attributable to each product from its initial R&D to its final customer servicing and support. 12‐9 No. It is important to distinguish between when costs are locked in (through design decisions) and when costs are incurred, because it is difficult to alter or reduce costs that have already been locked in. 12‐10 Three benefits of using a product life‐cycle reporting format are: 1. The full set of revenues and costs associated with each product becomes more visible. 2. Differences among products in the percentage of total costs committed at early stages in the life cycle are highlighted. 3. Interrelationships among business function cost categories are highlighted. 12‐11 Cost‐plus pricing methods vary depending on the bases used to calculate prices. Examples are (a) variable manufacturing costs, (b) manufacturing function costs, (c) variable product costs, and (d) full product costs. 12‐12 Two examples where the difference in the incremental or outlay costs of two products or services is much smaller than the differences in their prices follow: 1. The difference in prices charged for a telephone call, hotel room, or car rental during busy versus slack periods is often much greater than the difference in costs to provide these services. 2. The difference in incremental or outlay costs for an airplane seat sold to a passenger travelling on business or a passenger travelling for pleasure is roughly the same. However, airline companies routinely charge business travellers—those who are likely to start and complete their travel during the same week excluding the weekend—a much higher price than pleasure travellers, who generally stay at their destinations over at least one weekend.
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EXERCISES 12‐13 (10 min.) Terminology. Target pricing is a policy well suited to a highly competitive environment where many substitutes are available and may provide customers with the same valuable attributes at lower cost. Target cost per unit is set after the price and target margin are determined. This target margin may be in percent or dollars at either the gross or operating margin level. In a highly competitive environment customer life‐cycle pricing refers to the total cost of ownership of a product including purchase, operating costs, maintenance, and disposal. In comparison life‐cycle pricing refers to the total cost to the seller of the product from cradle to grave. The invested capital refers in this chapter to total assets. The target return on investment is the target operating income divided by the invested capital. Price discrimination is illegal because the manufacturerʹs intent is to obstruct or destroy competition. In contrast peak load pricing is the practice of charging the highest rate to provide a service when demand for the service is highest. It is common practice and not illegal. Value engineering is the evaluation by a top management team of any innovations and modifications to any business function that customers would value most highly. In comparison, value analysis is a process to retain both quality and all attributes that customers value while reducing costs. 12‐14 (15 min.) Non‐cost factors. 1. No. We would expect the incremental or outlay costs of providing telephone services to be no different in peak versus off‐peak hours. Most costs of maintaining and operating the telephone network are fixed costs that are the same in peak and off‐peak periods. In fact, the unit cost per telephone call is likely to be higher during off‐peak hours when fewer calls are made. Yet the prices charged for telephone calls during peak periods are higher than the prices charged for off‐peak evenings, nights, and weekends. 2. Charging higher prices for peak period calls is an example of price discrimination. Price discrimination occurs because calls made between 8 AM and 6 PM are generally made by businesses who are relatively more price insensitive—they must make telephone calls to conduct their regular day‐to‐day business activities. Charging a higher price for peak‐period calls maximizes the telephone company’s operating income. Charging higher prices during business hours is also an example of peak‐load pricing. Because the number of telephone calls that can be put through at any one time is limited, the telephone company raises prices to levels that the market will bear when demand is high. It is interesting that the prices of telephone calls do not vary much with the distances over which the calls are placed. Technological advances such as fibre
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optic cables have made costly devices such as repeaters and amplifiers, that were formerly needed to ensure high‐quality sound reproduction over long distances, unnecessary. The cost of laying cables has also decreased. The cost of a phone call does not vary much with distance.
12‐15 (2025 min.) Cost‐plus, target pricing, working backward. 1.
Investment Return on investment Operating income (20% $2,400,000) Operating income per unit of RF17 ($480,000 20,000) Full cost per unit of RF17 Selling price ($300 + $24) Markup percentage on full cost ($24 $300) With a 50% markup on variable costs,
2.
$2,400,000 20% $480,000 $24 $300 $324 8%
Selling price of RF17 = Variable cost per unit of RF17 1.50, so: Variable cost per unit of RF17 = $324/1.5 = $216 Fixed cost per unit = $300 – $216 = Total fixed costs = $84 per unit 20,000 units = At a price of $348, sales = 20,000 units 0.90 Revenues ($348 18,000) Variable costs ($216 18,000) Contribution margin ($132 18,000) Fixed costs Operating income
$84 $1,680,000 18,000 $6,264,000 3,888,000 2,376,000 1,680,000 $ 696,000
If Waterbuy increases the selling price of RF17 to $348, its operating income will be $696,000. This would be more than the $480,000 operating income Waterbury earns by selling 20,000 units at a price of $324, so, if its forecast is accurate, and based on financial considerations alone, Waterbury should increase the selling price to $348. 3.
Target investment in 2014 Target return on investment Target operating income in 2014, 20% $2,100,000 Anticipated revenues in 2014, $315 20,000 Less target operating income in 2014
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$2,100,000 20% $420,000 $6,300,000 420,000
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Target full costs in 2014 5,880,000 Less: total target fixed costs 1,680,000 Total target variable costs in 2014 $4,200,000 Target variable cost per unit in 2014, $4,200,000 20,000 = $210
12‐16 (20 min.) Cost‐plus target return on investment pricing. 1. 2.
Target operating income = target return on investment invested capital Target operating income (25% of $1,000,000) $250,000 Total fixed costs 358,000 Target contribution margin $608,000 Target contribution per room‐night, ($608,000 ÷ 16,000) $38 Add variable costs per room‐night 4 Price to be charged per room‐night $42
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Proof Total room revenue ($42 16,000 room‐nights) $672,000 Total costs: Variable costs ($4 16,000) $ 64,000 Fixed costs 358,000 Total costs 422,000 Operating income $250,000 The full cost of a room = variable cost per room + fixed cost per room The full cost of a room = $4 + ($358,000 ÷ 16,000) = $4 + $22.375 = $26.375 Markup per room = Rental price per room – Full cost of a room = $42 – $26.375 = $15.625 Markup percentage as a fraction of full cost = $15.625 ÷ $26.375 = 59.24% If price is reduced by 10%, the number of rooms Beck could rent would increase by 10%. The new price per room would be 90% of $42 $37.80 The number of rooms Beck expects to rent is 110% of 16,000 17,600 The contribution margin per room would be $37.80 – $4 $33.80 Contribution margin ($33.80 17,600) $594,880 Because the contribution margin of $594,880 at the reduced price of $37.80 is less than the contribution margin of $608,000 at a price of $42, Beck should not reduce the price of the rooms. Note that the fixed costs of $358,000 will be the same under the $42 and the $37.80 price alternatives and hence, are irrelevant to the analysis.
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12‐17 (15‐20 min.) Short‐run pricing, capacity constraints. 1.
Per kilogram of hard cheese: Milk (10 litres $1.50 per litre) Direct manufacturing labour Variable manufacturing overhead Fixed manufacturing cost allocated Total manufacturing cost
$15 5 3 6 $29
If Manitoba Dairy can get all the Holstein milk it needs, and has sufficient production capacity, then, the minimum price per kilo it should charge for the hard cheese is the variable cost per kilo = $15+5+3 = $23 per kilo. 2.
If milk is in short supply, then each kilo of hard cheese displaces 2.5 kilos of soft cheese (10 litres of milk per kilo of hard cheese versus 4 litres of milk per kilo of soft cheese). Then, for the hard cheese, the minimum price Manitoba should charge is the variable cost per kilo of hard cheese plus the contribution margin from 2.5 kilos of soft cheese, or, $23 + (2.5 $8 per kilo) = $43 per kilo That is, if milk is in short supply, Manitoba should not agree to produce any hard cheese unless the buyer is willing to pay at least $43 per kilo.
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12‐18 (20 min.) Target costs, effect of product‐design changes on product costs. 1. and 2. Manufacturing costs of HJ6 in 2012 and 2013 are as follows: 2012 Per Unit Total (2) = (1) (1) ÷ 3,500 Direct materials, $1,200 × 3,500; $1,100 × 4,000 $4,200,000 $1,200 Batch‐level costs, $8,000 × 70; $7,500 × 80 560,000 160 Manuf. operations costs, $55 × 21,000; $50 × 22,000 1,155,000 330 Engineering change costs, $12,000 × 14; $10,000 × 10 168,000 48 Total $6,083,000 $1,738
3.
2013 Per Unit Total (4) = (3) (3) ÷ 4,000 $4,400,000 $1,100 600,000 150 1,100,000
275
100,000 $6,200,000
25 $1,550
Target manufacturing cost per unit of HJ6 in 2013
Manufacturing cost × 90% per unit in 2012 = $1,738 × 0.90 = $1,564.20 =
Actual manufacturing cost per unit of HJ6 in 2013 was $1,550. Hence, Medical Instruments did achieve its target manufacturing cost per unit of $1,564.20 4.
To reduce the manufacturing cost per unit in 2013, Medical Instruments reduced the cost per unit in each of the four cost categories—direct materials costs, batch‐ level costs, manufacturing operations costs, and engineering change costs. It also reduced machine‐hours and number of engineering changes made—the quantities of the cost drivers. In 2012, Medical Instruments used 6 machine‐hours per unit of HJ6 (21,000 machine‐hours 3,500 units). In 2013, Medical Instruments used 5.5 machine‐hours per unit of HJ6 (22,000 machine‐hours 4,000 units). Medical Instruments reduced engineering changes from 14 in 2012 to 10 in 2013. Medical Instruments achieved these gains through value engineering activities that retained only those product features that customers wanted while eliminating non‐value‐added activities and costs.
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12‐19 (25–30 min.) Value‐added, non‐value‐added costs. 1. Category Value‐added costs Non‐value‐added costs
Grey area
Examples a. Materials and labour for regular repairs b. Rework costs c. Expediting costs caused by work delays g. Breakdown maintenance of equipment Total d. Materials handling costs e. Materials procurement and inspection costs f. Preventive maintenance of equipment Total
$ 800,000 $ 75,000 60,000 55,000 $190,000 $ 50,000 35,000 15,000 $100,000
Classifications of value‐added, non‐value‐added, and grey area costs are often not clear‐cut. Other classifications of some of the cost categories are also plausible. For example, some students may include materials handling, materials procurement, and inspection costs and preventive maintenance as value‐added costs (costs that customers perceive as adding value and as being necessary for good repair service) rather than as in the grey area. Preventive maintenance, for instance, might be regarded as value‐added because it helps prevent non‐value‐ adding breakdown maintenance. 2.
Total costs in the grey area are $100,000. Of this, we assume 65%, or $65,000, are value‐added and 35%, or $35,000, are non‐value‐added.
Total value‐added costs: $800,000 + $65,000 Total non‐value‐added costs: $190,000 + $35,000 Total costs
$ 865,000 225,000 $1,090,000
Non‐value‐added costs are $225,000 ÷ $1,090,000 = 20.64% of total costs. Value‐added costs are $865,000 ÷ $1,090,000 = 79.36% of total costs.
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12‐19 (cont’d) 3. Program (a) Quality improvement programs to • reduce rework costs by 75% (0.75 $75,000) • reduce expediting costs by 75% (0.75 $60,000) • reduce materials and labour costs by 5% (0.05 $800,000) Total effect (b) Working with suppliers to • reduce materials procurement and inspection costs by 20% (0.20 $35,000) • reduce materials handling costs by 25% (0.25 $50,000) Total effect Transferring 65% of grey area costs (0.65 $19,500 = $12,675) as value‐added and 35% (0.35 $19,500 = $6,825) as non‐value‐added Effect on value‐added and non‐value‐added costs (c) Maintenance programs to • increase preventive maintenance costs by 50% (0.50 $15,000) • decrease breakdown maintenance costs by 40% (0.40 $55,000) Total effect Transferring 65% of grey area costs (0.65 $7,500 = $4,875) as value‐added and 35% (0.35 $7,500 = $2,625) as non‐value‐added Effect on value‐added and non‐value‐added costs Total effect of all programs Value‐added and non‐value‐added costs calculated in requirement 2 Expected value‐added and non‐value‐added costs as a result of implementing these programs
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Effect on Costs Classified as Value‐ Non‐value‐ Grey Added Added Area –$56,250 – 45,000 –$ 40,000 –$ 40,000 –$101,250 –$7,000 –12,500 –19,500 –$ 12,675 – $ 6,825 + 19,500 –$ 12,675 – $6,825 $ 0 +$7,500 – $22,000 – 22,000 + $7,500 + 2,625 – 7,500 +$ 4,875 +$ 4,875 – $19,375 $ 0 – $ 47,800 –$127,450 865,000 225,000 $ 97,550 $817,200
Chapter 12
12‐19 (cont’d) If these programs are implemented in 2013, total costs would decrease from $1,090,000 (requirement 2) to $817,200 + $97,550 = $914,750, and the percentage of non‐value‐added costs would decrease from 20.64% (requirement 2) to $97,550 ÷ 914,750 = 10.66%. These are significant improvements in Marino’s performance.
12‐20
Life‐cycle product costing.
1.
Variable cost per unit = Production cost per unit + Marketing and distribution cost per unit = $50 + $10 = $60 Total fixed costs over life of Yew = $6,590,000 + $1,450,000 + $19,560,000 + 5,242,000 + $2,900,000 = $35,742,000
BEP in units =
Fixed costs $35,742,000 = 714,840 units Selling price Variable cost per unit $110 $60
2a. Revenue ($110 1,500,000 units) Variable costs ($60 1,500,000 units) Fixed costs Operating income
$165,000,000 90,000,000 35,742,000 $ 39,258,000
Revenue Year 2 ($240 100,000 units) Years 3 & 4 ($110 1,200,000 units) Total revenue Variable costs ($60 1,300,000 units) Fixed costs Operating income
$ 24,000,000 132,000,000 156,000,000 78,000,000 35,742,000 $ 42,258,000
2b.
Over the product’s life‐cycle, Option B results in an overall higher operating income of $3,000,000. 3.
Before selecting its pricing strategy, Intentical managers should evaluate whether the same pricing policy will be adopted globally. Different markets may need different pricing. For example, special taxes on imports may mean higher prices in foreign markets. Intentical’s pricing strategy must be sensitive to changing customer preferences and reactions of competitors.
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12‐21 (25–30 min.) Target prices, target costs, activity‐based costing. 1.
Snappy’s operating income in 2012 is as follows:
Revenue ($4 250,000) Purchase cost of tiles ($3 250,000) Ordering costs ($50 500) Receiving and storage ($30 4,000) Shipping ($40 1,500) Total costs Operating income 2.
Total for 250,000 Tiles (1) $1,000,000 750,000 25,000 120,000 60,000 955,000 $ 45,000
Per Unit (2) = (1) ÷ 250,000 $4.00 3.00 0.10 0.48 0.24 3.82 $0.18
Price to retailers in 2013 is 95% of 2012 price = 0.95 $4 = $3.80; cost per tile in 2013 is 96% of 2012 cost = 0.96 $3 = $2.88.
Snappy’s operating income in 2013 is as follows: Total for 250,000 Tiles (1) Revenue ($3.80 250,000) $ 950,000 Purchase cost of tiles ($2.88 250,000) 720,000 Ordering costs ($50 500) 25,000 Receiving and storage ($30 4,000) 120,000 Shipping ($40 1,500) 60,000 925,000 Total costs $ 25,000 Operating income
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Per Unit (2) = (1) ÷ 250,000 $3.80 2.88 0.10 0.48 0.24 3.70 $0.10
Chapter 12
12‐21 (cont’d) 3.
Snappy’s operating income in 2013, if it makes changes in ordering and material handling, will be as follows: Total for 250,000 Tiles Per Unit (1) (2) = (1) ÷ 250,000 Revenue ($3.80 250,000) $950,000 $3.80 Purchase cost of tiles ($2.88 250,000) 720,000 2.88 Ordering costs ($25 200) 5,000 0.02 Receiving and storage ($28 3,125) 87,500 0.35 Shipping ($40 1,500) 60,000 0.24 872,500 3.49 Total costs Operating income $ 77,500 $0.31
Through better cost management, Snappy will be able to achieve its target operating income of $0.30 per tile despite the fact that its revenue per tile has decreased by $0.20 ($4.00 – $3.80), while its purchase cost per tile has decreased by only $0.12 ($3.00 – $2.88).
12‐22 (20‐25 min.)
Product costs, activity‐based costing systems.
This problem illustrates how both product designers and manufacturing personnel can play key roles in a company manufacturing competitively priced products. The following table presents the manufacturing cost per unit for different cost categories for P‐41 and P‐ 63. Cost Categories P‐41 P‐63 Direct manufacturing product costs Direct materials $489.00 $350.52 Indirect manufacturing product costs Materials handling (85 $1.44; 46 $1.44) 122.40 66.24 Assembly management (3.2 $48; 1.9 $48) 153.60 91.20 Machine insertion of parts (49 $0.84; 31 $0.84) 41.16 26.04 Manual insertion of parts (36 $2.52; 15 $2.52) 90.72 37.80 Quality testing (1.4 $30; 1.1 $30) 42.00 33.00 Total indirect manufacturing product costs $449.88 $254.28 Total manufacturing product costs $938.88 $604.80
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12‐23 (20–30 min.) Relevant‐cost approach to short‐run pricing decisions. 1.
2.
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Analysis of special order: Sales, 3,000 units $75 $225,000 Variable costs: Direct materials, 3,000 units $35 $105,000 Direct manufacturing labour, 3,000 units $10 30,000 Variable manufacturing overhead, 3,000 units $6 18,000 Other variable costs, 3,000 units $5 15,000 Sales commission 8,000 Total variable costs 176,000 Contribution margin $ 49,000 Note that the variable costs, except for commissions, are affected by production volume, not sales dollars. If the special order is accepted, operating income would be $800,000 + $49,000 = $8,049,000. Whether McMahon’s decision to quote full price is correct depends on many factors. He is incorrect if the capacity would otherwise be idle and if his objective is to increase operating income in the short run. If the offer is rejected, Montreal, in effect, is willing to invest $49,000 in immediate gains forgone (an opportunity cost) to preserve the long‐run selling‐price structure. McMahon is correct if he thinks future competition or future price concessions to customers will hurt Montreal’s operating income by more than $49,000. There is also the possibility that Dorval; could become a long‐term customer. In this case, is a price that covers only short‐run variable costs adequate? Would Marcotte be willing to accept a $8,000 sales commission (as distinguished from her regular $33,750 = 15% $225,000) for every Dorval order of this size if Dorval becomes a long‐term customer?
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12‐24 (25–30 min.) Target rate of return on investment, activity‐based costing. 1. Operating Income Statement, April 2012 Revenue (12,000 DVDs $22 per DVD) Materials (12,000 DVDs $15 per DVD) Gross margin Ordering (40 vendors $250 per vendor) Cataloging (20 new titles $100 per title) Delivery and support (400 deliveries $15 per delivery) Billing and collection (300 customers $50 per customer) Operating Income Rate of return on investment ($51,000 $300,000 ) 2.
$264,000 180,000 84,000 10,000 2,000 6,000 15,000 $ 51,000 17.00%
The table below shows that if the selling price of game DVDs falls to $18 and the cost of each DVD falls to $12, monthly gross margin falls to $72,000 (from $84,000 in April), and this results in a return on investment of 13%, which is below EA’s target rate of return on investment of 15%. EA will have to cut costs to earn its target rate of return on investment.
Operating Income Statement, May 2012 Revenue (12,000 DVDs $18 per DVD) Materials (12,000 DVDs $12 per DVD) Gross margin Ordering (40 vendors $250 per vendor) Cataloging (20 new titles $100 per title) Delivery and support (400 deliveries $15 per delivery) Billing and collection (300 customers $50 per customer) Operating Income Rate of return on investment ($39,000 $300,000 )
$216,000 144,000 72,000 10,000 2,000 6,000 15,000 $ 39,000 13.00%
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12‐24 (cont’d) 3.
After EA’s workforce has implemented process improvements, its monthly support costs are $31,500, as shown below.
Monthly support costs after process improvements, May 2012 $ 6,000 Ordering (30 vendors $200 per vendor) Cataloging (15 new titles $100 per title) 1,500 Delivery and support (450 deliveries $20 per delivery) 9,000 15,000 Billing and collection (300 customers $50 per customer) Total monthly support costs $31,500 EA now earns $6 ($18 – $12) gross margin per DVD. Suppose it needs to sell X game DVDs to earn at least its 15% target rate of return on investment of $300,000. Then X needs to be such that: $6 X – $31,500 >= $300,000 15% = $45,000 $6 X >= $76,500 X >= $76,500 $6 = 12,750 game DVDs i.e., EA must now sell at least 12,750 game disks per month to earn its target rate of return on investment of 15%.
12‐25 (20–30 min.) Relevant‐cost approach to pricing decisions, special order. 1.
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Relevant revenue, $4.00 1,000 Relevant costs Direct materials, $1.60 1,000 $1,600 Direct manufacturing labour, $0.90 1,000 900 Variable manufacturing overhead, $0.70 1,000 700 Variable selling costs, 0.05 $4,000 200 Total relevant costs Increase in operating income
$4,000
3,400 $ 600
This calculation assumes that: a. The monthly fixed manufacturing overhead of $150,000 and $65,000 of monthly fixed marketing costs will be unchanged by acceptance of the 1,000 unit order. b. The price charged and the volumes sold to other customers are not affected by the special order. Chapter 12 uses the phrase “one‐time‐only special order” to describe this special case.
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12‐25 (cont’d) 2.
3.
The president’s reasoning is defective on at least two counts: a. The inclusion of irrelevant costs––assuming the monthly fixed manufacturing overhead of $150,000 will be unchanged; it is irrelevant to the decision. b. The exclusion of relevant costs––variable selling costs (5% of the selling price) are excluded. Key issues are: a. Will the existing customer base demand price reductions? If this 1,000‐ DVD order is not independent of other sales, cutting the price from $5.00 to $4.00 can have a large negative effect on total revenue. b. Is the 1,000‐DVD order a one‐time‐only order, or is there the possibility of sales in subsequent months? The fact that the customer is not in Dill Company’s “normal marketing channels” does not necessarily mean it is a one‐time‐only order. Indeed, the sale could well open a new marketing channel. Dill Company should be reluctant to consider only short‐run variable costs for pricing long‐run business.
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12‐26 (2530 min.) Target operating income, value‐added costs, service company. 1.
The classification of total costs in 2012 into value‐added, non‐value‐added, or in the grey area in between follows:
Value Added (1) Doing calculations and preparing drawings 75% × $400,000 $300,000 Checking calculations and drawings 4% × $400,000 Correcting errors found in drawings 7% × $400,000 Making changes in response to client requests 6% × $400,000 24,000 Correcting errors to meet government building code, 8% × $400,000 Total professional labour costs 324,000 Administrative and support costs at 40% ($160,000 ÷ $400,000) of professional labour costs 129,600 Travel 18,000 Total $471,600
Grey Area (2) $16,000
Non‐value‐ Total added (4) = (3) (1)+(2)+(3)
$300,000
16,000
$28,000
28,000
24,000
16,000
32,000 60,000
32,000 400,000
6,400 $22,400
24,000 — $84,000
160,000 18,000 $578,000
Doing calculations and responding to client requests for changes are value‐ added costs because customers perceive these costs as necessary for the service of preparing architectural drawings. Costs incurred on correcting errors in drawings and making changes because they were inconsistent with building codes are non‐value‐added costs. Customers do not perceive these costs as necessary and would be unwilling to pay for them. Carasco should seek to eliminate these costs by making sure that all associates are well‐informed regarding building code requirements and by training associates to improve the quality of their drawings. Checking calculations and drawings is in the grey area (some, but not all, checking may be needed). There is room for disagreement on these classifications. For example, checking calculations may be regarded as value added.
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12‐26 (cont’d) 2. 3.
Reduction in professional labour‐hours by a. Correcting errors in drawings (7% × 8,000) 560 hours b. Correcting errors to conform to building code (8% × 8,000) 640 hours Total 1,200 hours Cost savings in professional labour costs (1,200 hours × $50) $ 60,000 Cost savings in variable administrative and support costs (40% × $60,000) 24,000 Total cost savings $ 84,000 Current operating income in 2013 $102,000 Add cost savings from eliminating errors 84,000 Operating income in 2013 if errors eliminated $186,000 Currently 85% × 8,000 hours = 6,800 hours are billed to clients generating revenue of $680,000. The remaining 15% of professional labour‐hours (15% × 8,000 = 1,200 hours) is lost in making corrections. Carasco bills clients at the rate of $680,000 ÷ 6,800 = $100 per professional labour‐hour. If the 1,200 professional labour‐hours currently not being billed to clients were billed to clients, Carasco’s revenue would increase by 1,200 hours × $100 = $120,000 from $680,000 to $800,000.
Costs remain unchanged Professional labour costs Administrative and support (40% × $400,000) Travel Total costs Carasco’s operating income would be Revenue Total costs Operating income
$400,000 160,000 18,000 $578,000
$800,000 578,000 $222,000
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PROBLEMS
12‐27 (20 min.) Cost‐plus, time and materials. 1.
The different markup rates used by Mazzoli for direct materials and direct labour may represent the approximate overheads (plus a profit margin) associated with each: for example, direct materials would incur ordering and handling overhead, and direct labour would incur overheads such as benefits, insurance, etc., and these may be approximately 50% and 100% of costs. These markups could also be driven by industry practice and competitive factors.
2.
As shown in the table below, Bariess will tell White that she will have to pay $270 get the clutch plate repaired and $390 to get it replaced. COST Labour Materials Total Cost Repair option (3.5 hrs. $30 per hr.; $40) $105 $ 40 $145 Replace option (1.5 hrs. $30 per hr.; $200) 45 200 245 PRICE (100% markup on labour cost; 50% markup on materials) Labour Materials Total Price Repair option ($105 2; $40 1.5) $210 $ 60 $270 Replace option ($45 2; $200 1.5) 90 300 390
3.
If the repair and replace options are equally safe and effective, White will choose to get the clutch plate repaired for $270 (rather than spend $390 on a replacement plate).
4.
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Mazzoli Brothers will earn a greater contribution toward overhead in the replace option ($145 = $390 – $245) than in the repair option ($125 = $270 – $145). If we assume that Mazzoli Brothers earns a constant profit margin on each job, it will earn a larger profit by replacing the clutch plate on Johanna White’s car for $390 than by repairing it for $270. Therefore, Bariess will recommend the replace option to White, which is not the one she would prefer. Recognizing this conflict, Bariess may even present only the replace option to Johanna White, or suggest that the repair option will result in a less‐than‐safe car. Of course, he runs the risk of White walking away and thinking of other options (at which point, he could present the repair option as a compromise). The problem is that Bariess has superior information about the repairs needed but his incentives may cause him to not reveal his information and instead use it to his advantage. It is only the seller’s desire to build a reputation, to have a long‐term relationship with the customer, and to have the customer recommend the seller to other potential buyers of the service that encourages an honest discussion of the options.
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12‐28 (25 min.) Cost‐plus, target pricing, working backward. 1.
In the following table, work backwards from operating income to calculate the selling price Selling price $ 9.45 (plug) Less: Variable cost per unit 2.50 Unit contribution margin $ 6.95 Number of units produced and sold ×500,000 units Contribution margin $3,475,000 Less: Fixed costs 3,250,000 Operating income $ 225,000
a) Total sales revenue = $9.45 500,000 units = $4,725,000 b) Selling price = $9.45 (from above)
Alternatively, Operating income $ 225,000 Add fixed costs 3,250,000 Contribution margin 3,475,000 Add variable costs ($2.50 × 500,000 units) 1,250,000 Sales revenue $4,725,000 Sales revenue $4,725,000 Selling price = $9.45 Units sold 500,000 Operating income $225,000 c) Rate of return on investment = = 9% Total investment in assets 2,500,000 d) Markup % on full cost Total cost = ($2.50 500,000 units) + $3,250,000 = $4,500,000 $4,500,000 Unit cost = = $9 500,000 units $9.45 $9 = 5% Markup % = $9 $4,725,000 $4,500,000 Or = 5% $4,500,000
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12‐28 (cont’d) 2. 3.
New fixed costs New variable costs New total costs New total sales (5% markup) New selling price Alternatively, New unit cost New selling price
= $3,250,000 ─ $250,000 = $3,000,000 = $2.50 ─ $0.50 = $2 = ($2 500,000 units) + $3,000,000 = $4,000,000 = $4,000,000 1.05 = $4,200,000 = $4,200,000 ÷ 500,000 units = $8.40 = $4,000,000 ÷ 500,000 units = $8 = $8 1.05 = $8.40
New units sold = $500,000 × 90% = $450,000 units Budgeted Operating Income For the year ending December 31 Revenue ($8.40 450,000 units) Variable costs ($2.00 450,000 units) Contribution margin Fixed costs Operating income (loss)
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$3,780,000 900,000 2,880,000 3,000,000 $ (120,000)
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12‐29 (40–45 min.) Target prices, target costs, value engineering, cost incurrence, locked‐in costs, activity‐based costing. 1. Direct materials costs Direct manufacturing labour costs Machining costs Testing costs Rework costs Ordering costs Engineering costs Total manufacturing costs
Old CE100 $182,000 28,000 31,500 35,000 14,000 3,360 21,140 $315,000
Cost Change $2.20 7,000 = $15,400 less $0.50 7,000 = $3,500 less Unchanged because capacity same (20% 2.5 7,000) $2 = $7,000 (See Note 1) (See Note 2) Unchanged because capacity same
New CE100 $166,600 24,500 31,500 28,000 5,600 2,100 21,140 $279,440
Note 1: 10% of old CE100s are reworked. That is, 700 (10% of 7,000) CE100s made are reworked. Rework costs = $20 per unit reworked 700 = $14,000. If rework falls to 4% of New CE100s manufactured, 280 (4% of 7,000) New CE100s manufactured will require rework. Rework costs = $20 per unit 280 = $5,600. Note 2 : Ordering costs for New CE100 = 2 orders/month 50 components $21/order = $2,100 Unit manufacturing costs of New CE100 = $279,440 ÷ 7,000 = $39.92 2. Total manufacturing cost reductions based on new design = $315,000 – $279,440 = $35,560 Reduction in unit manufacturing costs based on new design = $35,560 ÷ 7,000 = $5.08 per unit. The reduction in unit manufacturing costs based on the new design can also be calculated as: Unit cost of old design, $45 ($315,000 ÷ 7,000 units) – Unit cost of new design, $39.92 = $5.08
Therefore, the target cost reduction of $6 per unit is not achieved by the redesign.
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12‐29 (cont’d) 3.
Changes in design have a considerably larger impact on costs per unit relative to improvements in manufacturing efficiency ($5.08 versus $1.50). One explanation is that many costs are locked in once the design of the radio‐cassette is completed. Improvements in manufacturing efficiency cannot reduce many of these costs. Design choices can influence many direct and overhead cost categories, for example, by reducing direct materials requirements, by reducing defects requiring rework, and by designing in fewer components that translate into fewer orders placed and lower ordering costs.
12‐30 (30 min.) 1. 2.
Relevant‐cost approach to pricing decisions.
Revenue (1,000 crates at $100 per crate) $100,000 Variable costs: Manufacturing $40,000 Marketing 14,000 Total variable costs 54,000 Contribution margin 46,000 Fixed costs: Manufacturing $20,000 Marketing 16,000 Total fixed costs 36,000 Operating income $ 10,000 Normal markup percentage: $46,000 ÷ $54,000 = 85.19% of total variable costs. Only the manufacturing‐cost category is relevant to considering this special order; no additional marketing costs will be incurred. The relevant manufacturing costs for the 200‐crate special order are: Variable manufacturing cost per unit $40 200 crates $ 8,000 Special packaging 2,000 Relevant manufacturing costs $10,000
Any price above $50 per crate ($10,000 ÷ 200) will make a positive contribution to operating income. Therefore, based on financial considerations, Stardom should accept the 200‐crate special order at $55 per crate that will generate revenue of $11,000 ($55 200) and relevant (incremental) costs of $10,000.
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12‐30 (cont’d)
3.
The reasoning based on a comparison of $55 per crate price with the $60 per crate absorption cost ignores monthly cost‐volume‐profit relationships. The $60 per crate absorption cost includes a $20 per crate cost component that is irrelevant to the special order. The relevant range for the fixed manufacturing costs is from 500 to 1,500 crates per month; the special order will increase production from 1,000 to 1,200 crates per month. Furthermore, the special order requires no incremental marketing costs. If the new customer is likely to remain in business, Stardom should consider whether a strictly short‐run focus is appropriate. For example, what is the likelihood of demand from other customers increasing over time? If Stardom accepts the 200‐crate special offer for more than one month, it may preclude accepting other customers at prices exceeding $55 per crate. Moreover, the existing customers may learn about Stardom’s willingness to set a price based on variable cost plus a small contribution margin. The longer the time frame over which Stardom keeps selling 200 crates of canned peaches at $55 a crate, the more likely it is that existing customers will approach Stardom for their own special price reductions. If the new customer wants the contract to extend over a longer time period, Stardom should negotiate a higher price.
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12‐31
Cost‐plus and market‐based pricing.
1. 2.
$1, 262, 460 $11.91 per testing hour 106,000 testing hours Billing rate = $11.91 1.45 = $17.27
Single rate =
$ 491,840 = $4.64 per test‐hour 106,000 test-hours $402,620 Setup and facility costs = = $503.275 per setup hour 800 setup hours $368,000 = $36.80 per MH Utilities = 10,000 MH
Labour and supervision =
3. HTT Labour and supervision (60%, 40%) $295,104 Setup and facility cost (25%, 75%) 100,655 Utilities (50%, 50%) 184,000 Total cost $579,759 1 Number of testing hours (TH) ÷63,600 TH Cost per testing hour $ 9.12 per TH Markup ×1.45 Billing rate per testing hour $ 13.22 per TH
ACT $196,736 301,965 184,000 $682,701 ÷42,400 TH $ 16.10 per TH ×1.45 $ 23.35 per TH
Total $ 491,840 402,620 368,000 $1,262,460
106,000 testing hours 60% = 63,600 TH; 106,000 testing hours 40% = 42,400 TH The billing rates based on the activity‐based cost structure make more sense. These billing rates reflect the ways the testing procedures consume the firm’s resources. 4. To stay competitive, Best Test needs to be more efficient in arctic testing. Roughly 301,965 44% ) occurs in setups and facility 44% of arctic testing’s total cost ( 682,701 costs. Perhaps the setup activity can be redesigned to achieve cost savings. 1
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12‐32 (25 min.) Cost‐plus and market‐based pricing. 1.
St. John’s Temps’ full cost per hour of supplying contract labour is Variable costs $12 Fixed costs ($240,000 ÷ 80,000 hours) 3 Full cost per hour $15 Price per hour at full cost plus 20% = $15 1.20 = $18 per hour.
2.
Contribution margins for different prices and demand realizations are as follows:
Contribution Variable Cost Margin per Demand in Total Price per Hour per Hour Hour Hours Contribution (1) (2) (3) = (1) – (2) (4) (5) = (3) × (4) $16 $12 $4 120,000 $480,000 17 12 5 100,000 500,000 18 12 6 80,000 480,000 19 12 7 70,000 490,000 20 12 8 60,000 480,000 Fixed costs will remain the same regardless of the demand realizations. Fixed costs are, therefore, irrelevant since they do not differ among the alternatives. The table above indicates that St. John’s Temps can maximize contribution margin ($500,000) and operating income by charging a price of $17 per hour. 3. The cost‐plus approach to pricing in requirement 1 does not explicitly consider the effect of prices on demand. The approach in requirement 2 models the interaction between price and demand and determines the optimal level of profitability using concepts of relevant costs. The two different approaches lead to two different prices in requirements 1 and 2. As the chapter describes, pricing decisions should consider both demand or market considerations and supply or cost factors. The approach in requirement 2 is the more balanced approach. In most cases, of course, managers use the cost‐plus method of requirement 1 as only a starting point. They then modify the cost‐plus price on the basis of market considerations—anticipated customer reaction to alternative price levels and the prices charged by competitors for similar products.
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12‐33 (35 min.) 1.
Pricing of a special order.
Fane Industries has a maximum capacity of 350,000 units. The production flow is as follows: Beginning inventory 5,000 Maximum production 350,000 Goods available 355,000 Special order needs 50,000 Available for regular customers 305,000 Required for regular customers 325,000 Lost sales 20,000 6,000 Less recovery of lost sales in future months (30%) Total lost sales 14,000 Sales to regular customers earn a contribution margin of $23 compared to the $9 contribution margin earned on the special order: Regular Sales Special Order Selling price $70.00 $52.00 Variable manufacturing costs $35.00 $35.00 Variable selling costs $12.00 $8.00 Contribution margin $23.00 $9.00
If the special order is accepted: The company will lose: 14,000 units @ CM of $23/unit or $322,000 And the company will gain: 50,000 units @ CM of $9/unit or $450,000 The order should be accepted for a net benefit of $128,000 ($450,000 – $322,000). 2.
The minimum price that should be accepted is based on incremental outlay cost plus the opportunity cost: The outlay cost is $35 + $8 = $43 The opportunity cost in total is $322,000 (from above) This cost expressed on a per unit basis is $322,000/50,000 = $6.44 The minimum price for the order is $43.00 + $6.44 = $49.44 Proof: Total CM on special order with selling price of $49.44 = ($49.44 – $35.00 – $8.00) * 50,000 = $322,000
3. Factors to consider in pricing special orders: • What will be the response of existing customers? • What will be the response of the competition? • What impact is there on employees and production (maintenance schedules)? • Will this customer order in the future? • How accurate is the estimate of the recovery of lost sales?
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12‐34 (25–30 min.) Life‐cycle costing. 1. Projected Life Cycle Income Statement Revenue [$500 (16,000 + 4,800)] Variable costs: Production [$225 (16,000 + 4,800)] Distribution [($20 16,000) + ($22 4,800)] Contribution margin Fixed costs: Design costs Production ($9,000 48 mos.) Marketing [($3,000 32 mos.) + ($1,000 16 mos.)] Distribution [($2,000 32 mos.) + ($1,000 16 mos.)] Life cycle operating income
$10,400,000 4,680,000 425,600 5,294,400 700,000 432,000 112,000 80,000 $ 3,970,400
Average profit per desk =
$3,970, 400 $190.88 (16,000 4,800)
2. Projected Life Cycle Income Statement Revenue ($400 16,000) Variable costs: Production ($225 16,000) Distribution ($20 16,000) Contribution margin Fixed costs: Design costs Production ($9,000 32 mos.) Marketing ($3,000 32 mos.) Distribution ($2,000 32 mos.) Life cycle operating income
$6,400,000 3,600,000 320,000 2,480,000 700,000 288,000 96,000 64,000 $1,332,000
The new desk design is still profitable even if FFM drops the product after only 32 months of production. However, the operating income per unit falls to only $83.25 ($1,332,000 / 16,000 desks) per desk.
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12‐34 (cont’d) 3. Life cycle operating income (requirement 2) Additional fixed production costs ($9,000 16 mos.) Revised life cycle operating income
$1,332,000 144,000 $1,188,000
No, the answer does not change even if FFM continues to incur the fixed production costs for the full 48 months. The revised operating income for the new executive desk becomes $1,188,000, which translates into $74.25 $1,188,000 ( ) operating income per desk. 16,000 desks
12‐35 (30 min.) Airline pricing, considerations other than cost in pricing. 1.
If the fare is $500, a. Snowbound Air would expect to have 200 business and 100 pleasure travellers. b. Variable costs per passenger would be $80. c. Contribution margin per passenger = $500 – $80 = $420. If the fare is $2,000, a. Snowbound Air would expect to have 190 business and 20 pleasure travellers. b. Variable costs per passenger would be $180. c. Contribution margin per passenger = $2,000 – $180 = $1,820. Contribution margin from business travellers at prices of $500 and $2,000, respectively, follow: At a price of $500: $420 × 200 passengers = $ 84,000 At a price of $2,000: $1,820 × 190 passengers = $345,800 Snowbound Air would maximize contribution margin and operating income by charging business travellers a fare of $2,000. Contribution margin from pleasure travellers at prices of $500 and $2,000, respectively, follow: At a price of $500: $420 × 100 passengers = $42,000 At a price of $2,000: $1,820 × 20 passengers = $36,400
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12‐35 (cont’d) Snowbound Air would maximize contribution margin and operating income by charging pleasure travellers a fare of $500. Air Americo would maximize contribution margin and operating income by a price differentiation strategy, where business travellers are charged $2,000 and pleasure travellers $500. In deciding between the alternative prices, all other costs such as fuel costs, allocated annual lease costs, allocated ground services costs, and allocated flight crew salaries are irrelevant. Why? Because these costs will not change whatever price Snowbound Air chooses to charge. 2.
3.
The elasticity of demand of the two classes of passengers drives the different demands of the travellers. Business travellers are relatively price insensitive because they must get to their destination during the week (exclusive of weekends) and their fares are paid by their companies. A 300% increase in fares from $500 to $2,000 will deter only 5% of the business passengers from flying with Snowbound Air. In contrast, a similar fare increase will lead to an 80% drop in pleasure travellers who are paying for their own travels, unlike business travellers, and who may have alternative vacation plans they could pursue instead. Since business travellers often want to return within the same week, while pleasure travellers often stay over weekends, a requirement that a Saturday night stay is needed to qualify for the $500 discount fare would discriminate between the passenger categories. This price discrimination is legal because airlines are service companies rather than manufacturing companies and because these practices do not, nor are they intended to, destroy competition.
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12‐36 (25 min.) Governance and pricing. 1. 2.
Baker prices at full product costs plus a mark‐up of 10% = $80,000 + 10% of $80,000 = $80,000 + $8,000 = $88,000
The incremental costs of the order are as follows: Direct materials $40,000 Direct manufacturing labour 10,000 30% of overhead costs (30% × $30,000) 9,000 Incremental costs $59,000 Any bid above $59,000 will generate a positive contribution margin for Baker. Baker may prefer to use full product costs because it regards the new ball‐ bearings order as a long‐term business relationship rather than a special order. For long‐run pricing decisions, managers prefer to use full product costs because it indicates the bare minimum costs they need to recover to continue in business rather than shut down. For a business to be profitable in the long run, it needs to recover both its variable and its fixed product costs. Using only variable costs may tempt the manager to engage in excessive long‐run price cutting as long as prices give a positive contribution margin. Using full product costs for pricing thereby prompts price stability.
3.
Not using full product costs (including an allocation of fixed overhead) to price the order, particularly if it is in direct contradiction of company policy, may be unethical. In assessing the situation, the specific “Standards of Ethical Conduct for Management Accountants,” described in Chapter 1 (p. 16), that the management accountant should consider are listed below.
Competence Clear reports using relevant and reliable information should be prepared. Reports prepared on the basis of excluding certain fixed costs that should be included would violate the management accountant’s responsibility for competence. It is unethical for Lazarus to suggest that Decker change the cost numbers that were prepared for the bearings order and for Decker to change the numbers in order to make Lazarus’s performance look good.
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12‐36 (cont’d) Integrity The management accountant has a responsibility to avoid actual or apparent conflicts of interest and advise all appropriate parties of any potential conflict. Lazarus’s motivation for wanting Decker to reduce costs was precisely to earn a larger bonus. This action could be viewed as violating the standard for integrity. The Standards of Ethical Conduct require the management accountant to communicate favourable as well as unfavourable information. In this regard, both Lazarus’s and Decker’s behaviour (if Decker agrees to reduce the cost of the order) could be viewed as unethical. Credibility The Standards of Ethical Conduct for Management Accountants require that information should be fairly and objectively communicated and that all relevant information should be disclosed. From a management accountant’s standpoint, reducing fixed overhead costs in deciding on the price to bid are clearly violating both of these precepts. For the reasons cited above, the behaviour described by Lazarus and Decker (if he goes along with Lazarus’s wishes) is unethical. Decker should indicate to Lazarus that the costs were correctly computed and that determining prices on the basis of full product costs plus a mark‐up of 10% are required by company policy. If Lazarus still insists on making the changes and reducing the costs of the order, Decker should raise the matter with Lazarus’s superior. If, after taking all these steps, there is continued pressure to understate the costs, Decker should consider resigning from the company, rather than engaging in unethical behaviour.
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COLLABORATIVE LEARNING CASE 12‐37 (40‐50 min.) Target prices, target costs, value engineering. 1.
Activity‐based allocation of overhead costs:
Tvez Premia Cost Cost Units of Allocation Units of Allocation Cost Drivers (2) = (1) Cost Drivers (4) = (3) (1) Rate/Hour (3) Rate/Hour Machine setup costs: $ 45,000 (125b 18hrs) $ 67,500 $30/setup hr. (100a 15hrs) Testing costs: $2.40/testing hr. (50,000 2.5hrs) 300,000 (25,000 5 hrs) 300,000 Engineering costs 200,000 280,000 Total ABC overhead allocation $545,000 $647,500
50,000 units/500 units per batch = 100 batches b 25,000 units/200 units per batch = 125 batches Activity‐based full‐product costs of Tvez and Premia are as follows: Tvez Direct materials costs $1,020,000 Direct manufacturing labour costs 360,000 Direct machine costs 180,000 Machine setup costs 45,000 Testing costs 300,000 Engineering costs 200,000 Total manufacturing and full product costs $2,105,000 Number of units 50,000 Full product cost per unit $42.10 a
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Premia $ 720,000 240,000 120,000 67,500 300,000 280,000 $1,727,500 25,000 $69.10
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12‐37 (cont’d) 2. Markup on full product cost per unit of Tvez = 3.
4.
Selling price – Fu ll prod u ct cost Fu ll prod u ct cost
= ($52.50 – $42.10)/$52.50 = 20%
The target price for New Tvez is $48.00. Suppose the target cost per unit of New Tvez is $X. Then $X(1.20) = $48.00 = $48.00/1.20 = $40.00 Activity‐based costs of New Tvez are as follows: Direct materials ($20.40 – $2.50) 50,000 units Direct manufacturing labour ($7.20 – $0.70) 50,000 units Direct machining* (fixed) Machine setup costs (7 hours 100 setups $30 per setup hour) Testing costs (2.5 hours – 0.5 hours) 50,000 $2.40 Engineering costs (same as for Tvez) Manufacturing and full product costs Number of units Manufacturing and full product costs per unit
$ 895,000 325,000 180,000 21,000 240,000 200,000 $1,861,000 50,000 $ 37.22
*Machining costs are long‐run fixed costs and so will not change even though it requires 20 fewer minutes to make each unit of New Tvez. The New Tvez design will reduce the manufacturing costs per unit by $4.88 ($42.10 – $37.22). The $37.22 cost is less than the target cost of $40.00 5. 6.
$37.22 × 1.20 = $44.66 Avery should charge the target price of $48.00 to maintain its market of 50,000 units. If it uses the cost‐plus price of $52.50, Avery risks losing some of its market share for New Tvez. Avery should strive to further reduce costs and achieve its target cost, either by changing the design to reduce cost drivers more, or by reducing the costs per unit of the cost driver.
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CHAPTER 13 STRATEGY, BALANCED SCORECARD, AND PROFITABILITY ANALYSIS
SHORT‐ANSWER QUESTIONS
13‐1 Strategy specifies how an organization matches its own capabilities with the opportunities in the marketplace to accomplish its objectives.
13‐2 The five key forces to consider in industry analysis are: (a) competitors, (b) potential entrants into the market, (c) equivalent products, (d) bargaining power of customers, and (e) bargaining power of input suppliers.
13‐3 Two generic strategies are (1) value leadership (product differentiation), an organization’s ability to offer products or services perceived by its customers to be superior and unique relative to the products or services of its competitors and (2) cost leadership, an organization’s ability to achieve lower costs relative to competitors through productivity and efficiency improvements, elimination of waste, and tight cost control.
13‐4 A customer preference map describes how different competitors perform across various product attributes desired by customers, such as price, quality, customer service and product features.
13‐5 Reengineering is the fundamental rethinking and redesign of business processes to achieve improvements in critical measures of performance such as cost, quality, service, speed, and customer satisfaction.
13‐6 The four key perspectives in the balanced scorecard are: (1) Financial perspective—this perspective evaluates the profitability of the strategy, (2) Customer perspective—this perspective identifies the targeted customer and market segments and measures the company’s success in these segments, (3) Internal business process perspective—this perspective focuses on internal operations that further both the customer perspective by creating value for customers and the financial perspective by increasing shareholder value, and (4) Learning and growth perspective—this perspective identifies the capabilities the organization must excel at to achieve superior internal processes that create value for customers and shareholders.
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13‐7 A strategy map represents more detailed and specific cause‐and‐effect relationships across various scorecard measures. It describes specific links across the measures.
13‐8 A good balanced scorecard design has several features: 1. 2.
3.
4. 5.
It tells the story of a company’s strategy by articulating a sequence of cause‐and‐ effect relationships. It helps to communicate the strategy to all members of the organization by translating the strategy into a coherent and linked set of understandable and measurable operational targets. It places strong emphasis on financial objectives and measures in for‐profit companies. Nonfinancial measures are regarded as part of a program to achieve future financial performance. It limits the number of measures to only those that are critical to the implementation of strategy. It highlights suboptimal tradeoffs that managers may make when they fail to consider operational and financial measures together.
13‐9 Pitfalls to avoid when implementing a balanced scorecard are: 1. 2. 3. 4. 5. 6.
Don’t assume the cause‐and‐effect linkages are precise; they are merely hypotheses. An organization must gather evidence of these linkages over time. Don’t seek improvements across all of the measures all of the time. Don’t use only objective measures in the balanced scorecard. Don’t fail to consider both costs and benefits of different initiatives before including these initiatives in the balanced scorecard. Don’t ignore nonfinancial measures when evaluating managers and employees. Don’t use too many measures.
13‐10 Three key components in doing a strategic analysis of operating income are: 1.
2.
3.
The growth component which measures the change in operating income attributable solely to the change in quantity of output sold from one year to the next. The price‐recovery component which measures the change in operating income attributable solely to changes in the prices of inputs and outputs from one year to the next. The productivity component which measures the change in costs attributable to a change in the quantity and mix of inputs used in the current year relative to the quantity and mix of inputs that would have been used in the previous year to produce current year output. Copyright © 2013 Pearson Canada Inc.
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13‐11 A stakeholder might not have a financial interest in what the corporation accomplishes. A shareholder has a financial interest.
13‐12 Engineered costs result from a cause‐and‐effect relationship between the cost driver, output, and the (direct or indirect) resources used to produce that output. Discretionary costs arise from periodic (usually annual) decisions regarding the maximum amount to be incurred. There is no measurable cause‐and‐effect relationship between output and resources used.
13‐13 Downsizing (also called rightsizing) is an integrated approach configuring processes, products, and people to match costs to the activities that need to be performed for operating effectively and efficiently in the present and future. Downsizing is an attempt to eliminate unused capacity.
13‐14 No. Total factor productivity (TFP) and partial productivity measures work best together because the strengths of one offset weaknesses in the other. TFP measures are comprehensive, consider all inputs together, and explicitly consider economic substitution among inputs. Physical partial productivity measures are easier to calculate and understand and, as in the case of labour productivity, relate directly to employees’ tasks. Partial productivity measures are also easier to compare across different plants and different time periods.
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EXERCISES
13‐15 (10 min.)
Terminology. Any management team must understand how it created value for its customers and decide how to accomplish this goal better than all its competitors. This is a decision about strategy. For exciting new products and products with no substitutes, consumers are willing to pay a premium price. Focusing on inventing and commercializing products with unique attributes is a value leadership (or product differentiation) strategy. For most mass produced products sold by many competitors, consumers readily find substitutes. Cost leadership is the alternative strategy that improves profitability and ROI through economies of scale and economies of scope. Usually this means the management team will work on increasing the quantity of output using the same capacity. The fixed cost per unit produced will decrease and if price is fixed then profit will increase. Often cost leadership (or reduction) is achieved by reengineering the production process. Growth can also be achieved by producing similar but not identical products and this is organic revenue growth that provides economies of scope. This type of growth can also be achieved through merger and acquisition or growth through adjacencies. Implementing strategy successfully depends in part on correct identification of the distinctive competence of a company. This is also called the companyʹs core competence. Competitive advantage is identified by a resource or set of resources available to a company that enable it to execute its business activities more profitably than other competitors. Management teams must align the choice of strategy with the competitive advantage to implement a strategy well. The resource or set of resources that provide competitive advantage are called key success factors (KSF) To obtain feedback on how successful the implementation of strategy is, a balanced scorecard (BSC).is often used. The BSC is the foundation of more technologically intensive enterprise risk management (ERM) systems. The BSC and ERM require refined cost reporting systems. The BSC measures success from four perspectives, customer perspective, internal process perspective learning/growth perspective and of course financial perspective The BSC approach provides a more detailed basis upon which to evaluate the success of implementation of strategy.
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13‐16 (15 min.) Balanced scorecard. 1.
2.
La Flamme’s 2013 strategy is a cost leadership strategy. La Flamme plans to grow by producing high‐quality boxes at a low cost delivered to customers in a timely manner. La Flamme’s boxes are not differentiated, and there are many other manufacturers who produce similar boxes. To succeed, La Flamme must produce high‐quality boxes at lower costs relative to competitors through productivity and efficiency improvements. Solution Exhibit 13‐16A shows the customer preference map for corrugated boxes for La Flamme and Portage on price, timeliness, quality and design.
SOLUTION EXHIBIT 13‐16A Customer Preference Map for Corrugated Boxes
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13‐16 (cont’d) 3.
Measures that we would expect to see on a La Flamme’s balanced scorecard for 2013 are Financial Perspective (1) Operating income from productivity gain, (2) operating income from growth, (3) cost reductions in key areas. These measures evaluate whether La Flamme has successfully reduced costs and generated growth through cost leadership. Customer Perspective (1) Market share in corrugated boxes market, (2) new customers, (3) customer satisfaction index. The logic is that improvements in these customer measures are leading indicators of whether La Flamme’s cost leadership strategy is succeeding with its customers and helping it to achieve superior financial performance. Internal Business Process Perspective (1) Productivity, (2) order delivery time, (3) on‐time delivery, (4) number of major process improvements. Improvements in these measures are key drivers of achieving cost leadership and are expected to lead to more satisfied customers and in turn to superior financial performance Learning and Growth Perspective (1) Percentage of employees trained in process and quality management, (2) employee satisfaction. Improvements in these measures aim to improve La Flamme’s ability to achieve cost leadership and have a cause‐and‐effect relationship with improvements in internal business processes, which in turn lead to customer satisfaction and financial performance. Solution Exhibit 13‐16B presents the strategy for La Flamme for 2013.
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SOLUTION EXHIBIT 13‐16B Strategy Map for La Flamme for 2013 FINANCIAL PERSPECTIVE
CUSTOMER PERSEPCTIVE
Operating income from productivity gain
Cost reduction in key areas
Number of new customers
Customer satisfaction
Productivity
INTERNALBUSINESSPROCESS PERSEPCTIVE
LEARNING-ANDGROWTH PERSEPCTIVE
Operating income from growth
Market share in corrugated boxes market
Quality
Number of major improvements in manufacturing process
On-time delivery
Employeesatisfaction ratings
Percentage of employees trained in process and quality management
13‐17 (20 min.) Analysis of growth, price‐recovery, and productivity components. 1.
2.
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La Flamme’s operating income gain is consistent with the cost leadership strategy identified in requirement 1 of Exercise 13‐16. The increase in operating income in 2014 was driven by the $140,000 gain in productivity in 2014. La Flamme took advantage of its productivity gain to reduce the prices of its boxes and to fuel growth. It increased market share by growing even though the total market size was unchanged. The productivity component measures the change in costs attributable to a change in the quantity and mix of inputs used in a year relative to the quantity and mix of inputs that would have been used in a previous year to produce the current year output. It measures the amount by which operating income increases and costs decrease through the productive use of input quantities. When comparing productivities across years, the productivity calculations use current year input prices in all calculations. Hence, the productivity component is unaffected by input price changes. Copyright © 2013 Pearson Canada Inc.
Chapter 13
13‐17 (cont’d) The productivity component represents savings in both variable costs and fixed costs. With respect to variable costs, such as direct materials, productivity improvements immediately translate into cost savings. In the case of fixed costs, such as fixed manufacturing conversion costs, productivity gains result only if management takes actions to reduce unused capacity. For example, reengineering manufacturing processes will decrease the capacity needed to produce a given level of output, but it will lead to a productivity gain only if management reduces the unused capacity by, say, selling off the excess capacity.
13‐18 (15 min.) Strategy, balanced scorecard. 1.
Meredith Corporation follows a value leadership (product differentiation) strategy in 2013. Meredith’s D4H machine is distinct from its competitors and generally regarded as superior to competitors’ products. To succeed, Meredith must continue to differentiate its product and charge a premium price.
2.
Balanced scorecard measures for 2013 follow: Financial Perspective (1) Increase in operating income from charging higher margins, (2) price premium earned on products. These measures indicate whether Meredith has been able to charge premium prices and achieve operating income increases through value leadership. Customer Perspective (1) Market share in high‐end special‐purpose textile machines, (2) customer satisfaction, (3) new customers. Meredith’s strategy should result in improvements in these customer measures that help evaluate whether Meredith’s value leadership strategy is succeeding with its customers. These measures are leading indicators of superior financial performance. Internal Business Process Perspective (1) Manufacturing quality, (2) new product features added, (3) order delivery time. Improvements in these measures are expected to result in more distinctive products delivered to its customers and in turn superior financial performance.
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13‐18 (cont’d) Learning and Growth Perspective (1) Development time for designing new machines, (2) improvements in manufacturing processes, (3) employee education and skill levels, (4) employee satisfaction. Improvements in these measures are likely to improve Meredith’s capabilities to produce distinctive products that have a cause‐and‐effect relationship with improvements in internal business processes, which in turn lead to customer satisfaction and financial performance.
13‐19 (30 min.) Strategic analysis of operating income. Operating income for each year is as follows:
1.
Revenue ($40,000 200; $42,000 210) Costs Direct materials costs ($8 300,000; $8.50 310,000) Manufacturing conversion costs ($8,000 250; 8,100 250) Selling & customer service costs ($10,000 100; $9,900 95) Design costs ($100,000 12; $101,000 12) Total costs Operating income Change in operating income
2012 $8,000,000
2,400,000 2,635,000 2,000,000 2,025,000 1,000,000 940,500 1,212,000 1,200,000 6,812,500 6,600,000 $1,400,000 $2,007,500 $607,500 F
2.
The Growth Component Revenue effect of growth
=
Actual units of output sold in 2013
–
Actual units of output sold in × 2012
Selling price in 2012
= (210 200) $40,000 = $400,000 F Cost effect of growth for variable costs
=
Units required to produce 2013 output in 2012
–
Actual units of inputs used to product 2012 output
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×
2013 $8,820,000
Input price in 2012
Chapter 13
13‐19 (cont’d)
Cost effect of growth for fixed costs
=
Actual units of capacity in 2012 if adequate to produce 2013 output in 2012 OR If 2012 capacity is inadequate to produce 2013 output in 2012, units of capacity required to produce 2013 output in 2012
–
Actual units of capacity in 2012
×
Price per unit of capacity in 2012
Direct materials costs that would be required in 2013 to produce 210 units instead of the 200 units produced in 2012, assuming the 2012 input‐output relationship 300,000 210). Manufacturing continued into 2013, equal 315,000 kilograms ( 200 conversion costs and selling and customer‐service costs will not change since adequate capacity exists in 2012 to support year 2013 output and customers. R&D costs are discretionary costs and would not change in 2012 if Meredith had to produce and sell the higher 2013 volume in 2013.
The cost effects of growth component are:
Direct materials costs (315,000 300,000) $8 = Manufacturing conversion costs (250 250) $8,000 = Selling & customer‐service costs (100 100) $10,000 = Design costs (12‐12) $100,000 =
$120,000 U 0 0 0
Cost effect of growth
$120,000 U
In summary, the net increase in operating income as a result of the growth component equals: Revenue effect of growth $400,000 F Cost effect of growth 120,000 U Change in operating income due to growth $280,000 F
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13‐19 (cont’d) The Price‐Recovery Component Revenue effect of price recovery
=
Selling price – in 2013
Selling price in 2012
×
Actual units of output sold in 2013
= ($42,000 $40,000) 210 = $420,000 F Cost effect of price recovery for variable costs
=
Input price in 2013
–
Input price in 2012
×
Units of input required to produce 2013 output in 2012
Cost effect of price recovery for fixed costs
Price per unit = of capacity in 2013
–
Price per unit of capacity in × 2012
Actual units of capacity in 2012 if adequate to produce 2013 output in 2012 OR If 2012 capacity is inadequate to produce 2013 output in 2012, units of capacity required to produce 2013 output in 2012
Direct materials costs ($8.50 $8) 315,000 = $157,500 U Manufacturing conversion costs ($8,100 $8,000) 250 = 25,000 U Selling & customer‐service costs ($9,900 $10,000) 100 = 10,000 F Design costs ($101,000 $100,000) 12 = 12,000 U Cost effect of price‐recovery $184,500 U In summary, the net increase in operating income as a result of the price‐ recovery component equals:
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Revenue effect of price‐recovery Cost effect of price‐recovery Change in operating income due to price‐recovery
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$420,000 F 184,500 U $235,500 F
Chapter 13
13‐19 (cont’d) The Productivity Component Cost effect of productivity for variable costs
=
Actual units of input used to produce 2013 output
–
Units of input required to produce 2013 output in 2012
×
Input price in 2013
Cost effect of productivity for fixed costs
The productivity component of cost changes are: Direct materials costs (310,000 315,000) $8.50 Manufacturing conversion costs (250 250) $8,100 Selling & customer‐service costs (95 100) $9,900 Design costs (12 12) $101,000 Change in operating income due to productivity
Price per unit of capacity in 2013
= = = =
$42,500 F 0 49,500 F 0 $92,000 F
The change in operating income between 2012 and 2013 can be analyzed as follows:
Revenues Costs Operating income
=
Actual units of capacity in 2013
Actual units of capacity in 2012 if adequate to produce 2013 output in 2012 OR × – If 2012 capacity is inadequate to produce 2013 output in 2012, units of capacity required to produce 2013 output in 2012
Income Statement Amounts in 2012 (1) $8,000,000 6,600,000 $1,400,000
Revenue and Revenue and Cost Effect Cost Effects Cost Effects of of of Growth Price‐Recovery Productivity Component Component Component in 2013 in 2013 in 2013 (2) (3) (4) $400,000 F $420,000 F 120,000 U 184,500 U $92,000 F $280,000 F $235,500 F $92,000 F
Income Statement Amounts in 2013 (5) = (1) + (2) + (3) + (4) $8,820,000 6,812,500 $2,007,500
$607,500 F Change in operating income
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13‐19 (cont’d) 3.
The analysis of operating income indicates that a significant amount of the increase in operating income resulted from Meredith’s value leadership strategy. The company was able to continue to charge a premium price while growing sales. Meredith was also able to earn additional operating income by improving its productivity.
13‐20 (20 min.)
Analysis of growth, price‐recovery, and productivity components.
Effect of the industry market‐size factor on operating income Of the 10‐unit increase in sales from 200 to 210 units, 3% or 6 (3% 200) units are due to growth in market size, and 4 (10 – 6) units are due to an increase in market share. The change in Meredith’s operating income from the industry market‐size factor rather than from specific strategic actions is: 6 $280,000 (the growth component in Exercise 13‐19) $168,000 F 10 Effect of value leadership (product differentiation) on operating income The change in operating income due to: Increase in the selling price of D4H (revenue effect of price recovery) $420,000 F Increase in price of inputs (cost effect of price recovery) 184,500 U Growth in market share due to value leadership 4 $280,000 (the growth component in Exercise 13‐19) 112,000 F 10 Change in operating income due to value leadership $347,500 F Effect of cost leadership on operating income The change in operating income from cost leadership is: Productivity component $ 92,000 F The change in operating income between 2012 and 2013 can be summarized as follows: Change due to industry market‐size $168,000 F Change due to value leadership $347,500 F Change due to cost leadership 92,000 F Change in operating income $607,500 F Meredith has been successful in implementing its value leadership strategy. More than 57% ($347,500 $607,500) of the increase in operating income during 2013 was due to value leadership, i.e., the distinctiveness of its machines. It was able to raise the prices of its machines faster than the costs of its inputs and still grow market share. Meredith’s operating income increase in 2013 was also helped by a growth in the overall market and some productivity improvements. 13–618
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13‐21 (15 min.) Identifying and managing unused capacity. 1.
The amount and cost of unused capacity at the beginning of year 2013 based on year 2013 production follows:
Manufacturing, 250 – 210; (250 – 210) $8,100 Selling and customer service, 100 – 80; (100 – 80) $9,900 Design
Amount of Unused Capacity 40 20 Discretionary cost, so cannot determine unused capacity*
Cost of Unused Capacity $324,000 198,000 Discretionary cost so cannot be calculated*
The absence of a cause‐and‐effect relationship makes identifying unused capacity for discretionary costs difficult. Management cannot determine the R&D resources used for the actual output produced to compare R&D capacity against. *
2.
3.
Meredith can reduce manufacturing capacity from 250 units to 220 (250 30) units. Meredith will save 30 $8,100 = $243,000. This is the maximum amount of costs Meredith can save in 2013. It cannot reduce capacity further (by another 30 units to 190 units) because it would then not have enough capacity to manufacture 210 units in 2013 (units that contribute significantly to operating income). Meredith may choose not to downsize because it projects sales increases that would lead to a greater demand for and utilization of capacity. Meredith may have also decided not to downsize because downsizing requires a significant reduction in capacity. For example, Meredith may have chosen to downsize some more manufacturing capacity if it could do so in increments of say, 10, rather than 30, units. Also, Meredith may be focused on value leadership, which is key to its strategy, rather than on cost reduction. Not reducing significant capacity also helps to boost and maintain employee morale.
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13‐22 (20‐30 min.)
Balanced scorecard.
Perspectives • Financial
Strategic Objectives
Performance Measures • Earnings per share • Increase shareholder • Net income value • Return on assets • Increase profit generated • Return on sales by each salesperson • Return on equity • Product cost per unit • Customer cost per unit • Profit per salesperson • Customer • Acquire new customers • Number of new • Retain customers customers • Develop profitable • Percentage of customers customers retained • Customer profitability • Internal Business Process • Improve manufacturing • Percentage of defective quality product units • Introduce new products • Percentage of error‐free • Minimize invoice error invoices rate • Percentage of on‐time • On‐time delivery by deliveries by suppliers suppliers • Number of patents • Increase proprietary • Percentage of processes products with real‐time feedback • Increase information system capabilities • Learning and Growth • Enhance employee skills • Average job‐related training hours per employee • Employee turnover rate
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13‐23 (15 min.) Strategy, balanced scorecard, service company. 1.
2.
Snyder Corporation’s strategy in 2013 is cost leadership. Snyder’s consulting services for implementing sales management software is not distinct from its competitors. The market for these services is very competitive. To succeed, Snyder must deliver quality service at low cost. Improving productivity while maintaining quality is key. Balanced Scorecard measures for 2013 follow: Financial Perspective (1) Increase operating income from productivity gains and growth, (2) revenue per employee, (3) cost reductions in key areas, for example, software implementation and overhead costs. These measures indicate whether Snyder has been able to reduce costs and achieve operating income increases through cost leadership. Customer Perspective (1) Market share, (2) new customers, (3) customer responsiveness, (4) customer satisfaction. Snyder’s strategy should result in improvements in these customer measures that help evaluate whether Snyder’s cost leadership strategy is succeeding with its customers. These measures are leading indicators of superior financial performance. Internal Business Process Perspective (1) Time to complete customer jobs, (2) time lost due to errors, (3) quality of job (is system running smoothly after job is completed?) Improvements in these measures are key drivers of achieving cost leadership and are expected to lead to more satisfied customers, lower costs, and superior financial performance. Learning and Growth Perspective (1) Time required to analyze and design implementation steps, (2) time taken to perform key steps implementing the software, (3) skill levels of employees, (4) hours of employee training, (5) employee satisfaction and motivation. Improvements in these measures are likely to improve Snyder’s ability to achieve cost leadership and have a cause‐and‐effect relationship with improvements in internal business processes, customer satisfaction, and financial performance. Copyright © 2013 Pearson Canada Inc.
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13‐24 (30 min.) Strategic analysis of operating income. 1. Operating income for each year is as follows: Revenue ($50,000 60; $48,200 70) Costs Software implementation labour costs ($60 30,000; $63 32,000) Software implementation support costs ($4,000 90; $4,100 90) Software development costs ($125,000 3; $130,000 3) Total costs Operating income Change in operating income 2. The Growth Component Revenue effect of growth
=
Actual units of output sold in 2013
–
Actual units of output sold in × 2012
2012 $3,000,000
2013 $3,374,000
1,800,000
2,016,000
360,000
369,000
390,000 375,000 2,535,000 2,775,000 $ 465,000 $ 599,000 $134,000 F
Selling price in 2012
= (70 – 60) $50,000 = $500,000 F Cost effect of growth for variable costs
Actual units of inputs used to product 2012 output
=
Units required to produce 2013 output in 2012
=
Actual units of capacity in 2012 if adequate to produce 2013 output in 2012 OR If 2012 capacity is inadequate to produce 2013 output in 2012, units of capacity required to produce 2013 output in 2012
–
×
Input price in 2012
Cost effect of growth for fixed costs
–
Actual units of capacity in 2012
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×
Price per unit of capacity in 2012
Chapter 13
13‐24 (cont’d) Software implementation labour costs that would be required in 2013 to produce 70 units instead of the 60 units produced in 2012, assuming the 2012 input‐output 30,000 relationship continued into 2013, equal 35,000 ( 70) labour‐hours. 60 Software implementation support costs would not change since adequate capacity exists in 2012 to support year 2013 output and customers. Software development costs are discretionary costs not directly related to output and, hence, would not change in 2012 even if Snyder had to produce and sell the higher year 2013 output in 2012. The cost effects of growth component are Software implementation labour costs (35,000 – 30,000) $60 = $300,000 U Software implementation support costs (90 – 90) $4,000 = 0 Software development costs (3 – 3) $125,000 = 0 Cost effect of growth $300,000 U In summary, the net increase in operating income as a result of the growth component equals: Revenue effect of growth $500,000 F Cost effect of growth 300,000 U Change in operating income due to growth $200,000 F The Price‐Recovery Component Revenue effect of price recovery
=
Selling price – in 2013
Selling price in 2012
×
Actual units of output sold in 2013
= ($48,200 – $50,000) 70 = $126,000 U
Cost effect of price recovery for variable costs
=
Input price in 2013
–
Input price in 2012
×
Units of input required to produce 2013 output in 2012
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13‐24 (cont’d)
Cost effect of price recovery for fixed costs
Price per unit = of capacity in 2013
Price per unit of capacity in × 2012
–
Actual units of capacity in 2012 if adequate to produce 2013 output in 2012 OR If 2012 capacity is inadequate to produce 2013 output in 2012, units of capacity required to produce 2013 output in 2012
Software implementation labour costs ($63 – $60) 35,000 = $105,000 U Software implementation support costs ($4,100 – $4,000) 90 = 9,000 U Software development costs ($130,000 – $125,000) 3 = 15,000 U Cost effect of price recovery $129,000 U In summary, the net decrease in operating income as a result of the price‐ recovery component equals: Revenue effect of price‐recovery $126,000 U Cost effect of price‐recovery 129,000 U Change in operating income due to price recovery $255,000 U The Productivity Component Cost effect of productivity for variable costs
Cost effect of productivity for fixed costs
=
=
Actual units of input used to produce 2013 output
Actual units of capacity in 2013
–
Units of input required to produce 2013 output in 2012
Input price in 2013
Actual units of capacity in 2012 if adequate to produce 2013 output in 2012 OR × – If 2012 capacity is inadequate to produce 2013 output in 2012, units of capacity required to produce 2013 output in 2012
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Price per unit of capacity in 2013
Chapter 13
13‐24 (cont’d) The productivity component of cost changes are: Software implementation labour costs (32,000 – 35,000) $63 = $189,000 F Software implementation support costs (90 – 90) $4,100 = 0 Software development costs (3 – 3) $130,000 = 0 Change in operating income due to productivity $189,000 F The change in operating income between 2012 and 2013 can be analyzed as follows:
Revenue
Income Statement Amounts in 2011 (1) $3,000,000
Costs
2,535,000
300,000 U
129,000 U
$189,000 F
2,775,000
Operating income
$ 465,000
$200,000 F
$255,000 U
$189,000 F
$ 599,000
3.
Revenue and Revenue and Cost Effect Income Cost Effects Cost Effects of of Statement of Growth Price‐Recovery Productivity Amounts Component Component Component in 2012 in 2012 in 2011 in 2012 (5) = (2) (3) (4) (1) + (2) + (3) + (4) $500,000 F $126,000 U $3,374,000
$134,000 F Change in operating income
The analysis of operating income indicates that a significant amount of the increase in operating income resulted from Snyder’s productivity improvements in 2013. The company had to reduce selling prices while labour costs were increasing but it was able to increase operating income by improving its productivity. The productivity gains also allowed Snyder to be competitive and grow the business. The unfavourable price recovery component indicates that Snyder could not pass on increases in labour‐related wages via price increases to its customers, very likely because its product was not differentiated from competitors’ offerings.
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13‐25 (25 min.) Analysis of growth, price‐recovery, and productivity components. Effect of industry‐market‐size factor on operating income Of the 10‐unit increase in sales from 60 to 70 units, 5% or 3 units (5% 60) are due to growth in market size, and 7 (10 3) units are due to an increase in market share. The change in Snyder’s operating income from the industry market‐size factor rather than from specific strategic actions is: 3 $200,000 (the growth component in Exercise 13‐24) $ 60,000 F 10 Effect of value leadership (product differentiation) on operating income Of the $1,800 decrease in selling price, 1% or $500 (1% $50,000) is due to a general decline in prices, and the remaining decrease of $1,300 ($1,800 $500) is due to a strategic decision by Snyder’s management to implement its cost leadership strategy of lowering prices to stimulate demand. The change in operating income due to a decline in selling price (other than the strategic reduction in price included in the cost leadership component) $500 70 units $ 35,000 U Increase in prices of inputs (cost effect of price recovery) 129,000 U Change in operating income due to value leadership $164,000 U Effect of cost leadership on operating income Productivity component $189,000 F Effect of strategic decision to reduce selling price, $1,300 70 91,000 U Growth in market share due to productivity improvement and strategic decision to reduce selling price 7 $200,000 (the growth component in Exercise 13‐24) 140,000 F 10 Change in operating income due to cost leadership $238,000 F The change in operating income between 2012 and 2013 can then be summarized as Change due to industry‐market‐size $ 60,000 F Change due to value leadership 164,000 U Change due to cost leadership 238,000 F Change in operating income $134,000 F Snyder has been very successful in implementing its cost leadership strategy. Due to a lack of value leadership, Snyder was unable to pass along increases in labour costs by increasing the selling price—in fact, the selling price declined by $1,800 per work unit. However, Snyder was able to take advantage of its productivity gains to reduce price, gain market share, and increase operating income. 13–626
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Chapter 13
13‐26 (20 min.) Identifying and managing unused capacity. 1.
The amount and cost of unused capacity at the beginning of year 2013 based on work performed in year 2013 follows:
Amount of Unused Capacity Software implementation support, 90 70; (90 70) $4,100 20 Software development Discretionary cost, so cannot determine unused capacity*
Cost of Unused Capacity $82,000 Discretionary cost, so cannot be calculated*
*The absence of a cause‐and‐effect relationship makes identifying unused capacity for discretionary costs difficult. Management cannot determine the software development resources used for the actual output produced to compare against software development capacity. 2.
3.
Snyder can reduce software implementation support capacity from 90 units to 70 (90 20) units. Snyder will save 20 $4,100 = $82,000. This is the maximum amount of costs Snyder can save by downsizing in 2012. It cannot reduce capacity further (by another 15 units to 60 units) because it would then not have enough capacity to perform 70 units of work in 2013 (work that contributes significantly to operating income). Snyder may choose not to downsize because it projects sales increases that would lead to greater demand for and utilization of capacity. Snyder may have also decided not to downsize because downsizing requires significant reduction in capacity. For example, Snyder may have chosen to downsize additional software implementation support capacity if it could do so in, say, increments of 5, rather than 15 units. Not reducing significant capacity by laying off employees boosts employee morale and keeps employees more motivated and productive.
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13‐27 (45 min.) Strategy, balanced scorecard, merchandising operation. 1.
2.
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Oceano & Sons follows a value leadership (product differentiation strategy). Oceano’s designs are “trendsetting,” its T‐shirts are distinctive, and it aims to make its T‐shirts a “must have” for each and every teenager. These are all clear signs of a value leadership strategy, and, to succeed, Oceano must continue to innovate and be able to charge a premium price for its product. Possible key elements of Oceano’s balance scorecard, given its value leadership strategy: Financial Perspective (1) Increase in operating income from charging higher margins, (2) price premium earned on products. These measures will indicate whether Oceano has been able to charge premium prices and achieve operating income increases through value leadership. Customer Perspective (1) Market share in distinctive, name‐brand T‐shirts, (2) customer satisfaction, (3) new customers, (4) number of mentions of Oceano’s T‐shirts in the leading fashion magazines Oceano’s strategy should result in improvements in these customer measures that help evaluate whether Oceano’s value leadership strategy is succeeding with its customers. These measures are, in turn, leading indicators of superior financial performance. Internal Business Process Perspective (1) Quality of silk‐screening (number of colours, use of glitter, durability of the design), (2) frequency of new designs, (3) time between concept and delivery of design Improvements in these measures are expected to result in more distinctive and trendsetting designs delivered to its customers and in turn, superior financial performance. Learning and Growth Perspective (1) Ability to attract and retain talented designers (2) improvements in silk‐ screening processes, (3) continuous education and skill levels of marketing and sales staff, (4) employee satisfaction. Improvements in these measures are expected to improve Oceano’s capabilities to produce distinctive designs that have a cause‐and‐effect relationship with improvements in internal business processes, which in turn lead to customer satisfaction and financial performance. Copyright © 2013 Pearson Canada Inc.
13‐28 1.
Chapter 13
Strategic analysis of operating income.
Operating Income Statement 2012 2013 $4,950,000 $6,414,200
Revenue ($25 198,000; $26 246,700) Costs T‐shirts purchased ($10 200,000; $8.50 250,000) Administrative costs Design costs Total costs Operating income Change in operating income 2.
The Growth Component Revenue effect of growth
2,000,000 2,125,000 1,200,000 1,162,500 250,000 275,000 3,450,000 3,562,500 $1,500,000 $2,851,700 $1,351,700 F
=
Actual units of output sold in 2013
Actual units of – output sold in × 2012
Selling price in 2012
= (246,700 198,000) $25 = $1,217,500 F
Cost effect of growth for variable costs
Actual units of inputs used to product 2012 output
=
Units required to produce 2013 output in 2012
=
Actual units of capacity in 2012 if adequate to produce 2013 output in 2012 OR If 2012 capacity is inadequate to produce 2013 output in 2012, units of capacity required to produce 2013 output in 2012
–
×
Input price in 2012
Cost effect of growth for fixed costs
–
Actual units of capacity in 2012
×
Price per unit of capacity in 2012
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13‐28 (cont’d) Direct materials (purchased T‐shirts) costs that would be required in 2013 to sell 246,700 T‐shirts instead of the 198,000 sold in 2012, assuming the 2012 input‐output relationship 246,700 200,000). continued into 2013, equal 249,192 purchased T‐shirts ( 198,000 Administrative costs will not change since adequate capacity exists in 2012 to support year 2013 output and customers. Design capacity is discretionary and adequate to support output in year 2013. The cost effects of growth component are Direct materials costs (249,192 200,000) $10 = $491,920 U Administrative costs (4,000 – 4,000) $300 = 0 Design costs (5 – 5) $50,000 = 0
Cost effect of growth
$491,920 U
In summary, the net increase in operating income as a result of the growth component equals: Revenue effect of growth $1,217,500 F Cost effect of growth 491,920 U Change in operating income due to growth $ 725,580 F The Price‐Recovery Component Revenue effect of price recovery
=
Selling price – in 2013
Selling price in 2012
×
Actual units of output sold in 2013
= ($26 $25) 246,700 = $246,700 F
Cost effect of price recovery for variable costs
=
Input price in 2013
–
Input price in 2012
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Units of input required to produce 2013 output in 2012
Chapter 13
13‐28 (cont’d)
Cost effect of price recovery for fixed costs
Price per unit = of capacity in 2013
Price per unit of capacity in × 2012
–
Actual units of capacity in 2012 if adequate to produce 2013 output in 2012 OR If 2012 capacity is inadequate to produce 2013 output in 2012, units of capacity required to produce 2013 output in 2012
Direct materials costs ($8.50 $10) 249,192 = $373,788 F Administrative costs ($310 $300) 4,000 = 40,000 U 5 = 25,000 U Design costs ($55,000 $50,000) Total cost effect of price‐recovery component $308,788 F In summary, the net increase in operating income as a result of the price‐recovery component equals: Revenue effect of price‐recovery $246,700 F Cost effect of price‐recovery 308,788 F Change in operating income due to price‐recovery $555,488 F The Productivity Component Cost effect of productivity for variable costs
Cost effect of productivity for fixed costs
=
=
Actual units of input used to produce 2013 output
Actual units of capacity in 2013
–
Units of input required to produce 2013 output in 2012
×
Input price in 2013
Actual units of capacity in 2012 if adequate to produce 2013 output in 2012 OR × – If 2012 capacity is inadequate to produce 2013 output in 2012, units of capacity required to produce 2013 output in 2012
Price per unit of capacity in 2013
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
13‐28 (cont’d) The productivity component of cost changes are Direct materials costs (250,000 249,192) $8.50 = $ 6,868 U Administrative costs (4,000 3,750) $310 = 77,500 F 0 Design costs (5 5) $55,000 = Change in operating income due to productivity $70,632 F The change in operating income between 2012 and 2013 can be analyzed as follows: Income Revenue and Revenue and Cost Effect Statement Cost Effects Cost Effects of of Amounts of Growth Price‐Recovery Productivity in 2013 in 2013 in 2013 in 2013 (5) = (2) (3) (4) (1) + (2) + (3) + (4) $1,217,500 F $246,700 F $6,414,200
Revenue
Income Statement Amounts in 2012 (1) $4,950,000
Costs
3,450,000
491,920 U
308,788 F
$70,632 F
3,562,500
Operating income
$1,500,000
$ 725,580 F
$555,488 F
$70,632 F
$2,851,700
3.
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$1,351,700 F Change in operating income
The analysis of operating income indicates that growth, price‐recovery, and productivity all resulted in favourable changes in operating income in 2013. Further, a significant amount of the increase in operating income resulted from Oceano’s value leadership strategy. The company was able to continue to charge a premium price while growing sales. It was also able to earn additional operating income by improving its productivity.
Copyright © 2013 Pearson Canada Inc.
Chapter 13
PROBLEMS
13‐29 (30 min.) Balanced scorecard, non‐profit, governance. 1.
SHARP is a non‐profit organization dedicated to the rescue and protection of domestic animals. It operates several animal shelters in the Sunset Heights area (including animal adoption services), rescues injured or abused domestic animals, and educates volunteers, pet owners, and potential pet owners on animal guardianship. It offers a variety of programs and therefore scorecard measures should reflect the various programs. Applying balanced scorecard concepts to this organization is different from applying balanced scorecards to traditional profit organizations, not only because of the absence of profit, but also because the “customers” of the organization may be defined as the animals, as well as members of society. Strategic objectives may include: i. Improve the level of service or care to animals in custody ii. Increase the animal adoption rate iii. Reduce the number of animals requiring services iv. Increase the number of volunteers v. Improve transparency and visibility of financial reporting vi. Improve accountability for donations vii. Increase the number of workshops in the community viii. Improve financial position ix. Improve the visibility of the organization x. Increase funds raised The following lists potential measures to be included on the scorecard. A scorecard would likely focus on 2 to 4 measures within each perspective.
Financial Perspective (1) Increase funding from donations or sponsorship as measured by dollars raised, (2) number of donors, (3) number of new donors, (4) average donation (in dollars), (5) operating costs by program. If SHARP raises restricted donations, then it may want to track operating costs of the restricted fund relative to restricted funds raised. The measures directly relate to strategic objectives v, vi, viii and x and indirectly relate to i.
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13‐29 (cont’d) Learning and Growth Perspective (1) Hours of employee training, or percentage of employees trained, (2) employee satisfaction and motivation (as measured by survey), (3) hours of volunteer training, or percentage of volunteers trained, (4) number (or hours) of workshops provided, (5) number of hits on the organization’s website. Volunteer measures are important since SHARP requires volunteers to deliver its programs. These measures relate directly to strategic objectives i and iv.
Customer Perspective “Customers” may include the animals serviced or the general public. (1) Number of workshops provided, (2) number of animals rescued, (3) number of lost animals found, (4) number or percentage of animals adopted, (5) size (m2) of recreation area for animals in care, (6) adoption rate These measures directly relate to strategic objectives i, ii, iii, vii.
Internal Business Process Perspective (1) Response time, (2) capacity measures (number or percentage of cages occupied), (3) number of animals in care, (4) average time to adoption. These measures directly relate to strategic objectives i, ii, and viii. 2. Corporate governance issues. Students with knowledge of not‐for‐profit accounting can address restricted funds and encumbrance issues. The general issues in this case are: • Organization’s inability to respond to board of directors’ request for information • Accountability to donors • Failure to operate with a balanced budget To address these issues, SHARP must ensure it has an information system that records donations, including any donations that are earmarked for specific purposes. It must also improve its accounting system to track direct costs of individual programs. It may wish to consider allocating common costs to programs if a cause‐ and‐effect relationship can be established. Reporting and review of results must be made on an ongoing basis (such as weekly or monthly). The organization must be aware of its available funds and its service levels. If funding is running out, it must have mechanisms in place to review its various services and service levels and prioritize the services it can provide. Alternatively, it may trigger a need for additional fundraising or sponsorship activities.
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Copyright © 2013 Pearson Canada Inc.
13‐30 (30 min.) 1.
Chapter 13
Balanced scorecard and strategy.
Solution Exhibit 13‐30A shows the customer preference map for ZP98‐type electronic components for Dransfield Company and Yorunt Manufacturing on price, delivery time, and quality.
SOLUTION EXHIBIT 13‐30A Customer Preference Map for ZP98‐type Electronic Components
2.
3.
Dransfield currently follows a cost leadership strategy, which is reflected in its lower price compared to Yorunt Manufacturing. The electronic component ZP98 is similar to products offered by competitors. In the internal‐business‐process perspective, Dransfield needs to set targets for decreasing the percentage of defective products sold and then identify measures that would be leading indicators of achieving this goal. For example, in the learning and growth perspective, Dransfield may want to measure the percentage of employees trained in quality management and the percentage of manufacturing processes with real‐time feedback. The logic is that improvements in these measures will drive quality improvements and so reduce the percentage of defective products sold. To achieve its goals, items that Dransfield could include under each perspective of the balanced scorecard follows:
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13‐30 (cont’d) Financial Perspective
Operating income from productivity and quality improvement Operating income from growth Revenue growth Customer Perspective Market share in electronic components Number of additional customers Customer‐satisfaction ratings Internal‐Business‐ Percentage of defective products sold Process Perspective Order delivery time On‐time delivery Number of major improvements in manufacturing process Learning‐and‐Growth Employee‐satisfaction ratings Percentage of employees trained in quality management Perspective Percentage of line workers empowered to manage processes Percentage of manufacturing processes with real‐time feedback 4. Solution Exhibit 13‐30B presents Dransfield’s strategy map explaining cause‐and‐ effect relationships in its balanced scorecard.
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Chapter 13
SOLUTION EXHIBIT 13‐30B Strategy Map for Dransfield Company for 2013 FINANCIAL PERSPECTIVE
CUSTOMER PERSEPCTIVE
INTERNALBUSINESSPROCESS PERSEPCTIVE
Operating income from productivity and quality improvement
Customer-satisfaction ratings
Percentage of defective products sold
Revenue growth
Operating income from growth
Number of additional customers
Market share in electronic components segment
Orderdelivery time
On-time delivery
Number of major improvements in manufacturing processes
LEARNING AND GROWTH PERSEPCTIVE
Employeesatisfaction ratings
Percentage of employees trained in quality management
Percentage of manufacturing processes with real-time feedback
Percentage of line workers empowered to manage processes
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
13‐31 (25‐30 min.) Strategic analysis of operating income. 1. Operating income for each year is as follows: Revenue ($44 5,000; $50 6,250) Less: Sales returns ($44 500; $50 225) Net revenue Costs Direct materials costs ($10 2,500; $10 3,125) Conversion costs Selling & customer service costs Advertising costs Total costs Operating income Change in operating income 2. The Growth Component Revenue effect of growth
=
Actual units of output sold in 2013
–
Actual units of output sold in × 2012
2012 $220,000 22,000 198,000
2013 $312,500 11,250 301,250
25,000 31,250 128,000 184,000 4,000 4,180 24,000 20,000 177,000 243,430 $ 21,000 $ 57,820 $36,820 F
Selling price in 2012
= (6,025 4,500) $44 = $67,100 F
Cost effect of growth for variable costs
=
Units required to produce 2013 output in 2012
–
Actual units of inputs used to product 2012 output
×
Input price in 2012
Cost effect of growth for fixed costs
=
Actual units of capacity in 2012 if adequate to produce 2013 output in 2012 OR If 2012 capacity is inadequate to produce 2013 output in 2012, units of capacity required to produce 2013 output in 2012
–
Actual units of capacity in 2012
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Copyright © 2013 Pearson Canada Inc.
×
Price per unit of capacity in 2012
Chapter 13
13‐31 (cont’d) Direct materials costs that would be required in 2013 to produce 6,025 units instead of the 4,500 units produced in 2012 assuming the 2013 input‐output relationship continued 2,500 6,025 into 2012, equal 3,347.22 pounds ( ). Conversion costs and selling and 4,500 customer‐service costs will not change since adequate capacity exists in 2012 to support year 2013 output and customers. Advertising costs are discretionary costs and would not change in 2012 if Dransfield had to produce and sell the higher 2013 volume in 2012. The cost effects of growth component are:
Direct materials costs Conversion costs Selling & cust.‐serv. costs Advertising costs
Cost effect of growth
$10 = (3,347 2,500) (8,000 8,000) $16 = (60 60) $66.67 = (1‐1) $20,000 =
$ 8,470 U 0 0 0 $ 8,470 U
In summary, the net increase in operating income as a result of the growth component equals: Revenue effect of growth $67,100 F Cost effect of growth 8,470 U Change in operating income due to growth $58,630 F The Price‐Recovery Component Revenue effect of price recovery
=
Selling price – in 2013
Selling price in 2012
×
Actual units of output sold in 2013
= ($50 $44) 6,025 = $36,150 F Cost effect of price recovery for variable costs
=
Input price in 2013
–
Input price in 2012
×
Units of input required to produce 2013 output in 2012
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13‐31 (cont’d)
Cost effect of price recovery for fixed costs
Price per unit = of capacity in 2013
Price per unit of capacity in × 2012
–
Actual units of capacity in 2012 if adequate to produce 2013 output in 2012 OR If 2012 capacity is inadequate to produce 2013 output in 2012, units of capacity required to produce 2013 output in 2012
$ 0 Direct materials costs ($10 $10) 3,347 = Conversion costs ($23 $16) 8,000 = 56,000 U Selling & customer‐service costs ($69.67 $66.67) 60 = 180 U Advertising costs ($24,000 $20,000) 1 = 4,000 U Cost effect of price‐recovery $60,180 U In summary, the net increase in operating income as a result of the price‐recovery component equals: Revenue effect of price‐recovery $36,150 F Cost effect of price‐recovery 60,180 U Change in operating income due to price‐recovery $24,030 U The Productivity Component Cost effect of productivity for variable costs
Cost effect of productivity for fixed costs
=
=
Actual units of input used to produce 2013 output
Actual units of capacity in 2013
–
Units of input required to produce 2013 output in 2012
Input price in 2013
Actual units of capacity in 2012 if adequate to produce 2013 output in 2012 OR × – If 2012 capacity is inadequate to produce 2013 output in 2012, units of capacity required to produce 2013 output in 2012
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×
Copyright © 2013 Pearson Canada Inc.
Price per unit of capacity in 2013
Chapter 13
13‐31 (cont’d) The productivity component of cost changes are Direct materials costs (3,125 3,347) $10 = $2,220 F $23 = 0 Conversion costs (8,000 8,000) Selling & customer‐service costs (60 60) $69.67 = 0 0 Advertising costs (1 1) $24,000 = Change in operating income due to productivity $2,220 F The change in operating income between 2012 and 2013 can be analyzed as follows:
Revenue
Income Statement Amounts in 2012 (1) $198,000
Revenue and Revenue and Cost Effect Income Cost Effects Cost Effects of of Statement of Growth Price‐Recovery Productivity Amounts Component Component Component in 2013 in 2013 in 2013 in 2013 (5) = (2) (3) (4) (1) + (2) + (3) + (4) $301,250 $67,100 F $36,150 F
Costs
177,000
8,470 U
60,180 U
$2,220 F
243,430
Operating income
$ 21,000
$58,630 F
$24,030 U
$2,220 F
$57,820
3.
$36,820 F Change in operating income
The analysis of operating income indicates that a significant amount of the increase in operating income resulted from Dransfield’s cost leadership strategy. The company was able to improve quality and grow sales. The price recovery component indicates that selling prices increased in line with the market but Dransfield’s costs increased even faster, particularly the price of conversion cost capacity, as Dransfield focused on improving quality. The benefit of this improved quality came in the form of higher sales that more than offset the spending on quality.
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13‐32 (20 min.)
Analysis of growth, price‐recovery, and productivity components.
Effect of the industry‐market‐size factor on operating income Of the 1,525 increase in sales from 4,500 to 6,025 units, 8% or 360 (8% 4,500) units are due to growth in market size, and 1,165 (1,525 360) units are due to an increase in market share. The change in Dransfield’s operating income from the industry‐market size factor rather than from specific strategic actions is: 360 $58,630 (the growth component in Exercise 13‐31) $13,840 F 1,525 Effect of value leadership ( product differentiation) on operating income The change in operating income due to: Increase in the selling price of ZP98 (revenue effect of price recovery) $36,150 F Increase in price of inputs (cost effect of price recovery) 60,180 U Change in operating income due to value leadership $24,030 U Effect of cost leadership on operating income The change in operating income from cost leadership is: Productivity component $ 2,220 F Growth in market share due to cost leadership 1,165 44,790 F $58,630 (the growth component in Exercise 13‐31) 1,525 Change in operating income due to cost leadership $47,010 F The change in operating income between 2011 and 2012 can be summarized as follows: Change due to industry market‐size $13,840 F Change due to value leadership 24,030 U Change due to cost leadership 47,010 F Change in operating income $36,820 F A thoughtful student might argue that the $24,030 U price‐recovery variance could also be thought of as part of the productivity variance. Why? Because a large component of this cost is from conversion costs incurred to improve quality which is more closely associated with productivity and process improvement rather than product development and value leadership. Under this assumption, the change in operating income between 2012 and 2013 can be summarized as follows: 13–642
Copyright © 2013 Pearson Canada Inc.
Chapter 13
13‐32 (cont’d)
Change due to market industry size Change due to value leadership Change due to cost leadership ($47,010 ─ $24,030) Change in operating income
$13,840 F 0 22,980 F $36,820 F
Dransfield has been successful in implementing its cost leadership strategy. The increase in operating income during 2013 was due to quality improvements and sales growth. Dransfield’s operating income increase in 2013 was also helped by a growth in the overall market size.
13‐33 (20 min.) Identifying and managing unused capacity. 1.
The amount and cost of unused capacity at the beginning of the year for 2013 production follows:
Manufacturing, 8,000 6,250; (8,000 – 6,250) $23 Selling and customer service, 60 – 60; (60– 60) $4,180 Advertising
2.
Amount of Unused Capacity 1,750 0 Discretionary cost, so cannot determine unused capacity*
Cost of Unused Capacity $40,250 $ 0 Discretionary cost, so cannot be calculated*
*The absence of a cause‐and‐effect relationship makes identifying unused capacity for discretionary costs difficult. Management cannot determine the advertising resources used for the actual output produced to compare advertising capacity against. Reasons for Downsizing: 1. Currently Dransfield only operates at 78% of capacity (6,250 units ÷ 8,000 units). Downsizing will allow the company to match resources available with resources consumed and eliminate management time and effort in managing unused capacity. 2. Downsizing should lead to cost savings and increased efficiency that result in higher operating income.
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13‐33 (cont’d)
3a.
Reasons against Downsizing: 1. Downsizing may require layoffs, which can hurt employee morale and loyalty. 2. Dransfield may want to maintain some unused capacity for future growth. Misclassification of the cost will not affect overall operating income because the cost will still be included in the calculation of operating income, only as advertising instead of sales and customer service. For financial accounting purposes, it will still be part of selling and administration (period) costs.
3b. This cost will not affect the growth component since the growth component is calculated using cost data from 2012. Misclassification of the cost will have no effect on the sales and customer service component of the cost effect of price recovery because adequate capacity exists in 2012 to produce 2013 output. It will increase the advertising component of the cost effect of price recovery. Misclassification of this cost will increase the productivity component because the capacity amount for selling and customer‐service cost will be understated. There will be no effect on advertising because advertising capacity had not changed. The net effect of this misclassification is to decrease the price‐recovery component by increasing the cost effect of price‐recovery for advertising and to increase the productivity component by an equal amount by understating the selling and customer‐service capacity. 3c. The misclassification will make the performance of the ZP98 manager look better than it is because selling and customer‐service costs that the manager is evaluated on will appear lower. The higher advertising cost does not affect the manager’s performance evaluation because advertising costs are excluded from the manager’s performance evaluation measure. The manager’s cost classification actions are unethical because the sole purpose of the misclassification of customer‐service costs as advertising costs is to make the manager’s performance look better than it is. Like many other corporations, Dransfield’s code of conduct, values and culture need to clearly proscribe such behaviour.
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13‐34 1.
2.
(20 min.)
Chapter 13
Balanced scorecard.
Caltex’s strategy is to focus on “service‐oriented customers” who are willing to pay a higher price for services. Even though gasoline is largely a commodity product, Caltex wants to differentiate itself through the service it provides at its retailing stations. Does the scorecard represent Caltex’s strategy? By and large it does. The focus of the scorecard is on measures of process improvement, quality, market share, and financial success from value leadership and charging higher prices for customer service. There are some deficiencies that the subsequent assignment questions raise but, abstracting from these concerns for the moment, the scorecard does focus on implementing a value leadership strategy. Having concluded that the scorecard has been reasonably well designed, how has Caltex performed relative to its strategy in 2013? It appears from the scorecard that Caltex was successful in implementing its strategy in 2013. It achieved all targets in the financial, internal business, and learning and growth perspectives. The only target it missed was the market share target in the customer perspective. At this stage, students may raise some questions about whether this is a good scorecard measure. Requirement 3 gets at this issue in more detail. The bottom line is that measuring “market share in the overall gasoline market” rather than in the “service‐oriented customer” market segment is not a good scorecard measure, so not achieving this target may not be as big an issue as it may seem at first. Yes, Caltex should include some measure of employee satisfaction and employee training in the learning and growth perspective. Caltex’s differentiation strategy and ability to charge a premium price is based on customer service. The key to good, fast, and friendly customer service is well trained and satisfied employees. Untrained and dissatisfied employees will have poor interactions with customers and cause the strategy to fail. Hence, training and employee satisfaction are very important to Caltex for implementing its strategy. These measures are leading indicators of whether Caltex will be able to successfully implement its strategy and should be measured on the balanced scorecard.
Copyright © 2013 Pearson Canada Inc.
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13‐34 (cont’d) 3.
4.
5.
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Caltex’s strategy is to focus on the 60% of gasoline consumers who are service‐ oriented, not on the 40% price‐shopper segment. To evaluate if it has been successful in implementing its strategy, Caltex needs to measure its market share in its targeted market segment, “service‐oriented customer,” not its market share in the overall market. Given Caltex’s strategy, it should not be concerned if its market share in the price‐shopper segment declines. In fact, charging premium prices will probably cause its market share in this segment to decline. Caltex should replace “market share in overall gasoline market” with “market share in the service‐oriented customer segment” in its balanced scorecard customer measure. Caltex may also want to consider putting a customer satisfaction measure on the scorecard. This measure should capture an overall evaluation of customer reactions to the facility, the convenience store, employee interactions, and quick turnaround. The customer satisfaction measure would serve as a leading indicator of market share in the service‐oriented customer segment. Although there is a cause‐and‐effect link between internal business process measures and customer measures on the current scorecard, Caltex should add more measures to tighten this linkage. In particular, the current scorecard measures focus exclusively on refinery operations and not on gas station operations. Caltex should add measures of gas station performance such as cleanliness of the facility, turnaround time at the gas pumps, the shopping experience at the convenience store, and the service provided by employees. Many companies do random audits of their facilities to evaluate how well their branches and retail outlets are performing. These measures would serve as leading indicators of customer satisfaction and market share in Caltex’s targeted segments. Caltex is correct in not measuring changes in operating income from productivity improvements on its scorecard under the financial perspective. Caltex’s strategy is to grow by charging premium prices for customer service. The scorecard measures focus on Caltex’s success in implementing this strategy. Productivity gains per se are not critical to Caltex’s strategy and therefore, should not be measured on the scorecard.
Copyright © 2013 Pearson Canada Inc.
Chapter 13
13‐35 (20 min.) Engineered and discretionary overhead costs, unused capacity, customer help‐desk. 1.
2.
Brightstar’s customer help‐desk costs are indirect, engineered costs. Over time, there is a clear cause‐and‐effect relationship between the output (number of subscribers or customers) and customer help‐desk representatives needed and customer help‐desk costs. The more homes serviced, the greater the number of customer‐service calls expected, and the greater the number of customer help‐desk representatives needed. a.
Assume customer help‐desk costs are engineered costs. (1) Available customer help‐desk capacity 8 hours per day 250 days 8 representatives (2) Customer help‐desk services actually used 1 72,000 calls hour per call 6 (3) = (1) – (2) Hours of unused customer help‐desk capacity (4) Cost per hour, $48,000 ÷ 2,000 hours (8 hours/day 250 days) (5) = (3) (4) Cost of unused customer help‐desk capacity in 2012
16,000 hours 12,000 hours 4,000 hours $24.00 per hour $96,000
b. Assume customer help‐desk costs are discretionary costs. In this case, cost of unused capacity in 2012 cannot be determined. The absence of a cause‐and‐ effect relationship between homes serviced and customer‐service calls means that Brightstar cannot determine the customer help‐desk resources used and, hence, the amount of unused capacity.
3.
Customer calls received in 2012/Total subscribers in 2009 = 72,000/900,000 = 8% Applying this 8% to the 1,020,000 subscribers in 2010 means that Brightstar received 81,600 (8% 1,020,000) calls in 2013.
a.
Assume customer help‐desk costs are engineered costs. (1) Available customer help‐desk capacity as in 2012 (2) Customer help‐desk services actually used 81,600 calls
1 6
hour per call
(3) = (1) – (2) Hours of unused customer help‐desk capacity (4) Cost per hour (5) = (3) (4) Cost of unused customer help‐desk capacity in 2013
16,000 hours 13,600 hours 2,400 hours $ 24.00 per hour $57,600
b. Assume customer help‐desk costs are discretionary costs.
For the reasons described in 2b, cost of unused capacity in 2013 cannot be determined.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
13‐36 (30 min.) Balanced scorecard. 1.
2.
3.
13–648
The market for colour laser printers is competitive. Lee’s strategy is to produce and sell high quality laser printers at a low cost. The key to achieving higher quality is reducing defects in its manufacturing operations. The key to managing costs is dealing with the high fixed costs of Lee’s automated manufacturing facility. To reduce costs per unit, Lee would have to either produce more units or eliminate excess capacity. The scorecard correctly measures and evaluates Lee’s broad strategy of growth through productivity gains and cost leadership. There are some deficiencies, of course, that subsequent assignment questions will consider. It appears from the scorecard that Lee was not successful in implementing its strategy in 2013. Although it achieved targeted performance in the learning and growth and internal business process perspectives, it significantly missed its targets in the customer and financial perspectives. Lee has not had the success it targeted in the market and has not been able to reduce fixed costs. Lee’s scorecard does not provide any explanation of why the target market share was not met in 2013. Was it due to poor quality? Higher prices? Poor post‐sales service? Inadequate supply of products? Poor distribution? Aggressive competitors? The scorecard is not helpful for understanding the reasons underlying the poor market share. Lee may want to include some measures in the customer perspective (and internal business process perspective) that get at these issues. These measures would then serve as leading indicators (based on cause‐and‐effect relationships) for lower market share. For example, Lee should measure customer satisfaction with its printers on various dimensions of product features, quality, price, service, and availability. It should measure how well its printers match up against other colour laser printers on the market. This is critical information for Lee to successfully implement its strategy. Lee should include a measure of employee satisfaction to the learning and growth perspective and a measure of new product development to the internal business process perspective. The focus of its current scorecard measures is on processes and not on people and innovation. Copyright © 2013 Pearson Canada Inc.
Chapter 13
13‐36 (cont’d) Lee considers training and empowering workers as important for implementing its high‐quality, low‐cost strategy. Therefore employee training and employee satisfaction should appear in the learning and growth perspective of the scorecard. Lee can then evaluate if improving employee‐related measures results in improved internal‐business process measures, market share and financial performance. Adding new product development measures to internal business processes is also important. As Lee reduces defects, Lee’s costs will not automatically decrease because many of Lee’s costs are fixed. Instead, Lee will have more capacity available to it. The key question is how Lee will obtain value from this capacity. One important way is to use the capacity to produce and sell new models of its products. Of course if this strategy is to work, Lee must develop new products at the same time that it is improving quality. Hence, the scorecard should contain some measure to monitor progress in new product development. Improving quality without developing and selling new products (or downsizing) will result in weak financial performance. 4.
Improving quality and significantly downsizing to eliminate unused capacity is difficult. Recall that the key to improving quality at Lee Corporation is training and empowering workers. As quality improvements occur, capacity will be freed up, but because costs are fixed, quality improvements will not automatically lead to lower costs. To reduce costs, Lee’s management must take actions such as selling equipment and laying off employees. But how can management lay off the very employees whose hard work and skills led to improved quality? If it did lay off employees now, will the remaining employees ever work hard to improve quality in the future? For these reasons, Lee’s management should first focus on using the newly available capacity to sell more product. If it cannot do so and must downsize, management should try to downsize in a way that would not hurt employee morale, such as through retirements and voluntary severance.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
13‐37 (20 min.) Partial productivity measurement. 1.
Guble Company’s partial productivity ratios in 2013 are as follows:
Direct materials partial productivity
=
Quantity of output produced in 2013 Yards of direct materials used in 2013
2,650,000 = 1,669,500
Quantity of output produced in 2013 Units of manuf. capacity in 2013
= 2,650,000 2,800,000
=
1.59 wallets per yard
Conversion costs partial productivity
=
0.95 wallets = per unit of capacity
To compare partial productivities in 2013 with partial productivities in 2012, we first calculate the inputs that would have been used in 2012 to produce year 2013’s 2,650,000 units of output assuming the year 2012 relationship between inputs and outputs. Direct materials = = Manufacturing capacity =
1,875,000 yards (2008) 2,650,000 output units in 2013 2,500,000 output units in 2012 1,875,000 yards 1.06 = 1,987,500 yards 3,000,000 units of capacity, because manufacturing capacity is fixed, and adequate capacity existed in 2012 to produce year 2013 output.
Partial productivity calculations for 2012 based on year 2013 output (to make the partial productivities comparable across the two years): Direct materials partial productivity Conversion costs partial productivity
Quantity of output produced in 2013 = Yards of direct materials that would have been used in 2012 to produce year 2013 output Quantity of output produced in 2013 = Units of manuf. capacity that would have been used in 2012 to produce year 2013 output
2,650,000 = 1,987,500
=
1.33 units per yard
2,650,000 = 3,000,000
=
0.883 units per unit of capacity
The calculations indicate that Guble improved the partial productivity of direct materials and conversion costs between 2012 and 2013 via efficiency improvements and by reducing unused manufacturing capacity. 13–650
Copyright © 2013 Pearson Canada Inc.
Chapter 13
13‐37 (cont’d) 2.
Guble Company management can use the partial productivity measures to set targets for the next year. Partial productivity measures can easily be compared over multiple periods. For example, they may specify bonus payments if partial productivity of direct materials increases to 1.75 units of output per yard and if partial productivity of conversion costs improves to 1 unit of output per unit of capacity. A major advantage of partial productivity measures is that they focus on a single input; hence, they are simple to calculate and easy to understand at the operations level. Managers and operators can also examine these numbers to understand the reasons underlying productivity changes from one period to the next—better training of workers, lower labour turnover, better incentives, or improved methods. Management can then implement and sustain these factors in the future.
13‐38 (25 min.) Total factor productivity. 1.
Total factor productivity for 2013 using 2013 prices
2.
=
Quantity of output produced in 2013 Costs of inputs used in 2013 based on 2013 prices
2,650,000
=
=
= 0.1725 units of output per dollar of input
(1,669,500 $4)+(8, 680, 000) 2, 650, 000 2,650,000 $6, 678, 000 $8,680,00 $15,358,000
By itself, the 2013 TFP of 0.1725 units per dollar of input is not particularly helpful. We need something to compare the 2013 TFP against. We use, as a benchmark, TFP calculated using the inputs that Guble would have used in 2012 to produce 2,650,000 units of output calculated in requirement 1 at 2013 prices. Using the current year’s (2013) prices in both calculations controls for input price differences and focuses the analysis on the adjustments the manager made in the quantities of inputs in response to changes in prices.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
13‐38 (cont’d) 2013 price of capacity
=
Cost of capacity in 2013 Capacity in 2013
=
$8,680,000 2,800,000 units
= $3.10 per unit of capacity
Benchmark TFP
=
Quantity of output produced in 2013 Costs of inputs that would have been used in 2012 to produce 2013 output at year 2013 input prices
2,650,000
=
=
=
= 0.1536 units of output per dollar of input
(1,987,500 $4)+(3,000,000 $3.10) 2,650,000 $7,950,000 + $9,300,000 2,650,000 $17,250,000
Using year 2013 prices, total factor productivity increased 12.3% [(0.1725 0.1536) 0.1536] from 2012 to 2013. 3.
Total factor productivity increased because Guble produced more output per dollar of input in 2013 relative to 2012, measured in both years using 2013 prices. The change in partial productivity of direct materials and conversion costs tells us that Guble used less materials and capacity in 2013 relative to output, than in 2012. A major advantage of TFP over partial productivity measures is that TFP combines the productivity of all inputs and so measures gains from using fewer physical inputs and substitution among inputs. Partial productivities cannot be combined to indicate the overall effect on cost as a result of these individual improvements. The TFP measure allows managers to evaluate the change in overall productivity by simultaneously combining all inputs to measure gains from using fewer physical inputs as well as substitution among inputs.
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13‐39 (35 min.) Downsizing. 1.
The downsizing plan would not be acceptable as the required subsidy is more than 20% of the current subsidy: $25,231 compared to $20,992, calculated as follows:
Under downsizing plan Annual revenue: [(160 sandwiches $5.10) + $340 beverages/desserts] 260 days Cost of supplies: $300,560 52% Cost of downsizing plan: Wages and fringe benefits ($94,000 1.25) Utilities and equipment maintenance Annual cost of supplies (from above or $300,560 52%) Total costs Annual revenue Mayfair downsizing plan subsidy
$ 117,500 52,000 156,291 325,791 300,560 $ 25,231
Under current cafeteria plan Annual revenues: ($720 + $405 + $300)*260 [(100 entrees $7.20) + (90 salads/sandwiches $4.50) + $300 beverages/dessert] 260 days Cost of supplies (62% $370,500)
$370,500 $229,710
$300,560 $156,291
Computation of subsidy limitation Current operation: Wages and fringe benefits [$155,000 + (25% $155,000)] Utilities and equipment maintenance Cost of supplies (from above or $370,500 62%) Total costs Annual revenue Mayfair current operations subsidy Mayfair Corporation’s subsidy limitation 20% of current subsidy (20% $104,960)
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$193,750 52,000 229,710 475,460 370,500 $104,960
$ 20,992
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13‐39 (cont’d) 2. The Wilco Foods proposal is more advantageous to Mayfair Corporation than the downsizing plan and the current operations. The subsidy at the projected volume is $11,128. The calculations follow: Wilco Daily Revenue: 70 entrees @ $7.80 = $546 98 sandwiches/salads @ $5.50 = $539 Other = $370 Total daily revenue = $1,455 Breakeven Sales: CM Ratio = 100% ‐ 75% = 25% Fixed costs = $1,300 * 12 = $15,600/year Breakeven sales = $15,600/25% = $62,400
Revenue to Mayfair: Wilco revenue $1,455 * 260 days Less: Breakeven sales Revenues in excess of breakeven sales Revenues payable to Mayfair ($315,900 0.08) Plus: Rent Total payments to Mayfair
Cost to Mayfair: Fixed costs (utilities and equipment maintenance) Mayfair’s Wilco Foods proposal subsidy
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$378,300 62,400 $315,900 $ 25,272 15,600 40,872
52,000 $ 11,128
Chapter 13
COLLABORATE LEARNING CASES
13‐40 (35 min.) Strategic analysis of operating income. 1.
Halsey is following a value leadership (product differentiation) strategy. Halsey offers a wide selection of clothes and excellent customer service. Halsey’s strategy is to distinguish itself from its competitors and to charge a premium price.
2. Operating income for each year is as follows: 2012 2013 Revenue ($60 40,000; $59 40,000) $2,400,000 $2,360,000 Costs Costs of goods sold ($40 40,000; $41 40,000) 1,600,000 1,640,000 Selling & customer service costs ($7 51,000); $6.90 43,000) 357,000 296,700 Purchasing & admin. costs ($250 980; $240 850) 245,000 204,000 Total costs 2,202,000 2,140,700 Operating income $ 198,000 $ 219,300 Change in operating income $21,300 F 3. The Growth Component Revenue effect of growth
=
Actual units of output sold in 2013
–
Actual units of output sold in × 2012
Selling price in 2012
= (40,000 40,000) $60 = $0 Cost effect of growth for variable costs
Actual units of inputs used to product 2012 output
=
Units required to produce 2013 output in 2012
=
Actual units of capacity in 2012 if adequate to produce 2013 output in 2012 OR If 2012 capacity is inadequate to produce 2013 output in 2012, units of capacity required to produce 2013 output in 2012
–
×
Input price in 2012
Cost effect of growth for fixed costs
–
Actual units of capacity in 2012
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×
Price per unit of capacity in 2012
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13‐40 (cont’d) Pieces of clothing that would be required to be purchased in 2013 would be the same as that required in 2012 because output is the same between 2012 and 2013. Purchasing and administrative costs and selling and customer‐service costs will not change since adequate capacity exists in 2012 to support year 2013 output and customers.
The cost effects of growth component are: Costs of goods sold (40,000 40,000) Selling & customer‐service costs (51,000 51,000) Purch. & admin. costs (980 980) Cost effect of growth
$40 = $7 = $250 =
$0 0 0 $0
In summary, the net effect on operating income as a result of the growth component equals: Revenue effect of growth Cost effect of growth Change in operating income due to growth The Price‐Recovery Component Revenue effect of price recovery
=
Selling price – in 2013
Selling price in 2012
×
$0 0 $0
Actual units of output sold in 2013
= ($59 $60) 40,000 = $40,000 U
Cost effect of price recovery for variable costs
=
Input price in 2013
–
Input price in 2012
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×
Units of input required to produce 2013 output in 2012
Chapter 13
13‐40 (cont’d)
Cost effect of price recovery for fixed costs
Price per unit = of capacity in 2013
Price per unit of capacity in × 2012
–
Actual units of capacity in 2012 if adequate to produce 2013 output in 2012 OR If 2012 capacity is inadequate to produce 2013 output in 2012, units of capacity required to produce 2013 output in 2012
Costs of goods sold ($41 $40) 40,000 = Selling & cust.‐serv. costs ($6.90 $7) 51,000 = Purchas. & admin. costs ($240 $250) 980 = Cost effect of price‐recovery
$40,000 U 5,100 F 9,800 F $25,100 U
In summary, the net decrease in operating income as a result of the price‐ recovery component equals:
Revenue effect of price‐recovery Cost effect of price‐recovery Change in operating income due to price‐recovery
$40,000 U 25,100 U $65,100 U
The Productivity Component Cost effect of productivity for variable costs
Cost effect of productivity for fixed costs
=
=
Actual units of input used to produce 2013 output
Actual units of capacity in 2013
–
Units of input required to produce 2013 output in 2012
×
Input price in 2013
Actual units of capacity in 2012 if adequate to produce 2013 output in 2012 OR × – If 2012 capacity is inadequate to produce 2013 output in 2012, units of capacity required to produce 2013 output in 2012
Price per unit of capacity in 2013
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13‐40 (cont’d) The productivity component of cost changes are: Costs of goods sold (40,000 40,000) $41 = 0 Selling & customer‐service costs (43,000 51,000) $6.90 = $55,200 F = 31,200 F Purchasing & admin. costs (850 980) $240 Change in operating income due to productivity $86,400 F The change in operating income between 2012 and 2013 can be analyzed as follows: Revenue and Revenue and Cost Effect Income Cost Effects Cost Effects of of Statement of Growth Price‐Recovery Productivity Amounts Component Component Component in 2013 in 2013 in 2013 in 2013 (5) = (2) (3) (4) (1) + (2) + (3) + (4) $0 $40,000 U $2,360,000
Revenue
Income Statement Amounts in 2012 (1) $2,400,000
Costs
2,202,000
0
25,100 U
$ 86,400 F
2,140,700
Operating income
$ 198,000
$0
$65,100 U
$ 86,400 F
$ 219,300
4.
$21,300 F Change in operating income
The analysis of operating income indicates that a significant amount of the increase in operating income resulted from productivity gains rather than value leadership. The company was unable to charge a premium price for its clothes. Thus, the strategic analysis of operating income indicates that Halsey has not been successful at implementing its premium price, value leadership strategy, despite the fact that operating income increased by more than 10% between 2012 and 2013. Halsey could not pass on increases in purchase costs to its customers via higher prices. Halsey must either reconsider its value leadership strategy or focus managers on increasing margins and growing market share by offering better product variety and superb customer service.
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Chapter 13
13‐41 (20‐30 min.)
Balanced scorecard, sustainability. Note to instructors: this question is intended to be open‐ended. 1. Okanagan Orchard Products has a stated objective to be the number one distributor of its product lines within Canada. It has also identified quality, efficiency, and innovation as key factors in its success. While there are many possible balanced scorecards that could be created, it is important that students’ answers reflect these key factors. It is also important to note that Okanagan distributes its products to food retailers. It operates in a B2B environment; however, the food retailers are not the company’s ultimate customers. Therefore while it is important to create distributor relationships, the company cannot overlook the final customer. Strategic objectives may include: i. Improve manufacturing quality (quality). ii. Improve yields and manufacturing processes (efficiency). iii. Introduce new products (innovation). iv. Be number one in Canada. Financial Perspective (1) Increase operating income from productivity gains and growth, (2) revenues per distributor. [primary strategic objective iv] Customer Perspective (1) Market share, (2) customer satisfaction, (3) Number and/or percentage of food retailers carrying Okanagan Orchard products. [strategic objectives iv, i, and iii] Further to the comments above, it is important for Okanagan to evaluate its success with distributors as well as with the final consumer. Internal Business Process Perspective (1) Yields (fruit inputs to final product outputs), (2) percentage of good units (in kilograms or number of jars, etc.), (3) process time. [strategic objective ii] Improvements in these measures are key drivers of achieving cost leadership and are expected to lead to more satisfied customers, lower costs, and superior financial performance. Learning and Growth Perspective (1) Hours of employee training, or percentage of employees trained, (2) employee satisfaction and motivation (as measured by survey), (3) number of new products introduced to the market (for example new flavours, sugar‐reduced offerings etc.) [all strategic objectives emphasized]. Employee measures are important since Okanagan has identified problems in managing turnover. Employees are important for efficiency and for innovation.
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13‐41 (cont’d) 2.
3.
Sustainability Measures This question was left intentionally vague regarding whether or not Okanagan grows the fruit or merely processes the fruit into jams/jellies. If Okanagan is also a grower, then a whole host of sustainability measures become important. Okanagan must consider the sustainability of the land, and look at crop rotations, soil nutrients, etc. Also the issue of insect control and the use of pesticides and their impact are important from a sustainability perspective. However, if we assume that Okanagan processes the fruit, then a key measure would be a Waste/Input Ratio. The Dow Jones Sustainability Index is another consideration. Employee turnover issues can be addressed through training at both the individual and management levels and through improved communication. Staff not only need to be trained for current positions, but also trained for future growth and advancement. Supervisory or management staff need to clarify the links between performance and reward (particularly non‐monetary rewards such as recognition and opportunities for advancement)1. If employees can see a future in the organization, they may be more inclined to stay with the organization, particularly when it offers competitive wages. In addition to employee and supervisory training, the company could implement additional communication mechanisms, such as employee suggestion boxes. It could introduce measures designed to enhance organizational culture, such as employee events (casual Fridays, Tuesday lunch‐time speakers, etc.). From a sustainability perspective, some of these events could be tied to external events or causes (e.g., a corporate team participating in the Terry Fox Run for the Cure, or in a Bike Tour for MS (multiple sclerosis)). Many such initiatives have minimal costs and would have long‐run benefits through the reduction of employee turnover related costs.
Most students studying cost accounting at this level have had an introductory course in organizational behaviour. The human resources aspect of this question allows students to integrate their knowledge of motivational theory with management/cost accounting. Students could refer to Expectations Theory and concepts of leadership, including leadership styles and roles (e.g. task versus consideration). 1
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CHAPTER 14 PERIOD COST APPLICATION
SHORT‐ANSWER QUESTIONS
14‐1 Disagree. Cost accounting data plays a key role in many management planning and control decisions. The division president will be able to make better operating and strategy decisions by being involved in key decisions about cost pools and cost allocation bases. 14‐2 The dual‐rate method provides information to division managers about cost behaviour. Knowing how fixed costs and variable costs behave differently is useful in decision making. 14‐3 The four purposes of cost allocation are: 1. To provide information for economic decisions. 2. To motivate managers and employees. 3. To justify costs or compute reimbursement. 4. To measure income and assets for meeting external reporting and legal regulatory obligations. 14‐4 Criteria used to justify cost allocation decisions include: 1. Cause and effect. 2. Benefits received. 3. Fairness or equity. 4. Ability to bear. Either the cause‐and‐effect criterion or the benefits received criterion is the dominant one when the purpose of the allocation is related to the economic decision purpose or the motivation purpose. 14‐5 The first consideration is to select the method that best reflects the economic facts of production. The second is affordability. The management team’s decisions will always improve with higher quality information but the cost of obtaining that information may be too high relative to the benefit received. 14‐6 Cost‐benefit considerations can affect costing choices in several ways: (a) Classifying some immaterial costs as indirect when they could, at high cost, be traced to products, services or customers as direct costs. (b) Using a small number of indirect cost pools when, at high cost, an increased number of indirect cost pools would provide more homogeneous cost pools. (c) Using allocation bases that are readily available (or can be collected at low cost) when, at high cost, more appropriate cost allocation bases could be developed.
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14‐7 Three decisions managers face when designing the cost allocation component of an accounting system are: i. Which cost items should be included in the indirect cost pools? ii. How many indirect cost pools should be used? iii. Which allocation base should be used for each indirect cost pool? 14‐8 Examples of bases used to allocate corporate cost pools to operating divisions are: Corporate Cost Pools Possible Allocation Bases Corporate executive dept. Sales; assets employed; operating income Treasury department Sales; assets employed; estimated time or usage Legal department Estimated time or usage; sales; assets employed Marketing department Sales; number of sales personnel Payroll department Number of employees; payroll dollars Human resources Number of employees; payroll dollars; number of new department hires 14‐9 The use of budgeted indirect cost allocation rates rather than actual indirect rates has several attractive features to the manager of a user department: a. the user knows the costs in advance and can factor them into ongoing operating choices, b. the cost allocated to a particular user department does not depend on the amount of resources used by other user departments, and c. inefficiencies at the department providing the service do not affect the costs allocated to the user department. 14‐10 Disagree. Allocating costs on “the basis of estimated long‐run use by user department managers” means department managers can lower their cost allocations by deliberately underestimating their long‐run use. 14‐11 The three methods differ in how they recognize reciprocal services among support departments: a. The direct allocation method ignores any services rendered by one support department to another; it allocates each support department’s total costs directly to the operating departments. b. The step‐down allocation method allows for partial recognition of support rendered by support departments to other support departments. c. The reciprocal allocation method allocates costs by explicitly recognizing the mutual services rendered among support departments.
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Chapter 14
14‐12 The reciprocal method is theoretically the most defensible method because it explicitly recognizes the mutual services rendered among all departments, irrespective of whether those departments are operating or support departments. 14‐13 The incremental common cost allocation method first allocates the common costs to the primary user; the incremental party is allocated the incremental component of the common cost arising because there are two users and not just the primary user. The stand‐ alone common cost allocation method allocates the common cost on the basis of each user’s percentage of the total of the individual stand‐alone costs. 14‐14 One key method to avoid disputes is to clearly define the basis for support cost allocation.
EXERCISES
14‐15 (10 min.)
Terminology.
Target pricing is a policy well suited to a highly competitive environment where the corporation is a price taker because customers set the price. Depending on the proportion of fixed costs in the pool, the management team must choose between a dual‐rate or a single‐rate cost pool. Cost leadership is an appropriate policy and the reciprocal method most accurately reflects cost flows from support divisions back and forth among one another and to core operating divisions. To implement the reciprocal method the support cost pools must be arithmetically adjusted to create artificial costs pool, which are then the basis for all cost allocation. The sequential method is an improvement over the direct method of applying support costs, but only reports the flow of support departments to one another in one direction. The support divisions are first ranked on some basis from highest to lowest flow of either costs or resources step down from the largest to smallest support division. Then the adjusted support cost pools are allocated to core divisions. A common cost arises when two or more users share benefits from consuming a corporate resource. There are two ways to recognize proportional cost and benefit. The standalone cost allocation method defines each cost object as if it was the only output. The incremental cost allocation method ranks those who share in benefits from incurring the total common cost pool from high to low. The highest ranked is the primary party bears most of the total shared cost. The remaining incremental parties share the difference between the total common cost pool minus the costs allocated to the primary party. Disputes over the primary party often arise.
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14‐16 (15‐20 min.) Criteria of cost allocation decisions. 1.
Direct costs = $2.30 Indirect costs = $10.62– $2.30 = $8.32
Overhead rate =
2.
The answers here are less than clear‐cut in some cases.
$8.32 = 361.7% $2.30
Overhead Cost Item Processing of paperwork for purchase Supplies room management fee Operating room and patient room handling charge Administrative hospital costs Research‐related recoupment Malpractice insurance costs Costing of treating uninsured patients Profit component 3.
Allocation Criteria Cause and effect Benefits received Cause and effect Benefits received Ability to bear Ability to bear or benefits received Ability to bear None. This is not a cost.
Note: In the U.S. for‐profit health‐care system, individuals purchase their own insurance for medical procedures or pay privately in the same way Canadians pay for dental care. Assuming that Meltzer’s insurance company is responsible for paying the $4,800 bill, Meltzer probably can only express outrage at the amount of the bill. The point of this question is to note that even if Meltzer objects strongly to one or more overhead items, it is his insurance company that likely has the greater incentive to challenge the bill. Individual patients have very little power in the medical arena. In contrast, insurance companies have considerable power and may decide that certain costs are not reimbursable—for example, the costs of treating uninsured patients.
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Chapter 14
14‐17 (20 min.) Single‐rate versus dual‐rate methods, support division. Bases available (kilowatt hours): Practical capacity Expected monthly usage
1a.
Cambridge 20,000 9,000
Burlington 12,000 7,000
Brantford 8,000 6,000
Total 50,000 30,000
Single‐rate method based on practical capacity: Total costs in pool = $6,000 + $9,000 = $15,000 Practical capacity = 50,000 kilowatt hours Allocation rate = $15,000 ÷ 50,000 = $0.30 per hour of capacity
Practical capacity in hours Costs allocated at $0.30 per hour
1b.
Mississauga 10,000 8,000
Mississauga 10,000 $3,000
Cambridge 20,000 $6,000
Burlington 12,000 $3,600
Brantford 8,000 $2,400
Total 50,000 $15,000
Single‐rate method based on expected monthly usage: Total costs in pool = $6,000 + $9,000 = $15,000 Expected usage = 30,000 kilowatt hours Allocation rate = $15,000 ÷ 30,000 = $0.50 per hour of expected usage
Mississauga Cambridge Burlington Brantford Expected monthly usage in hours 8,000 9,000 7,000 6,000 Costs allocated at $0.50 per hour $4,000 $4,500 $3,500 $3,000
2.
Variable‐Cost Pool: Total costs in pool Expected usage Allocation rate Fixed‐Cost Pool: Total costs in pool Practical capacity Allocation rate
Total 30,000 $15,000
= = =
$6,000 30,000 kilowatt hours $6,000 ÷ 30,000 = $0.20 per hour of expected usage
= = =
$9,000 50,000 kilowatt hours $9,000 ÷ 50,000 = $0.18 per hour of capacity
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14‐17 (cont’d) Mississauga
Variable‐cost pool $0.20 × 8,000; 9,000; 7,000, 6,000 Fixed‐cost pool $0.18 × 10,000; 20,000; 12,000, 8,000 Total
$1,600 1,800 $3,400
Cambridge Burlington Brantford Total
$1,800 3,600 $5,400
$1,400 2,160 $3,560
$1,200 1,440 $2,640
$ 6,000 9,000 $15,000
The dual‐rate method permits a more refined allocation of the power department costs; it permits the use of different allocation bases for different cost pools. The fixed costs result from decisions most likely associated with the practical capacity level. The variable costs result from decisions most likely associated with monthly usage.
14‐18 (20–25 min.) Single‐rate method, budgeted versus actual costs and quantities. 1a. 1b. 1c.
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Budgeted indirect costs = $115,000/50 trips = $2,300 per round‐trip Budgeted trips Indirect costs allocated to Dark C. Division = $2,300 per round‐trip 30 budgeted round trips = $69,000 Indirect costs allocated to Milk C. Division = $2,300 per round‐trip 20 budgeted round trips = $46,000 Budgeted rate = $2,300 per round‐trip Indirect costs allocated to Dark C. Division = $2,300 per round‐trip 30 actual round trips = $69,000 Indirect costs allocated to Milk C. Division = $2,300 per round‐trip 15 actual round trips = $34,500
Budgeted rate =
Actual indirect costs = $96,750/ 45 trips = $2,150 per round‐trip Actual trips Indirect costs allocated to Dark C. Division = $2,150 per round‐trip 30 actual round trips = $64,500 Indirect costs allocated to Milk C. Division = $2,150 per round‐trip 15 actual round trips = $32,250 Actual rate =
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Chapter 14
14‐18 (cont’d) 2.
When budgeted rates/budgeted quantities are used, the Dark Chocolate and Milk Chocolate Divisions know at the start of 2013 that they will be charged a total of $69,000 and $46,000 respectively for transportation. In effect, the fleet resource becomes a fixed cost for each division. Then, each may be motivated to over‐use the trucking fleet, knowing that their 2013 transportation costs will not change. When budgeted rates/actual quantities are used, the Dark Chocolate and Milk Chocolate Divisions know at the start of 2013 that they will be charged a rate of $2,300 per round trip, i.e., they know the price per unit of this resource. This enables them to make operating decisions knowing the rate they will have to pay for transportation. Each can still control its total transportation costs by minimizing the number of round trips it uses. Assuming that the budgeted rate was based on honest estimates of their annual usage, this method will also provide an estimate of the excess trucking capacity (the portion of fleet costs not charged to either division). In contrast, when actual costs/actual quantities are used, the two divisions must wait until year‐end to know their transportation charges. The use of actual costs/actual quantities makes the costs allocated to one division a function of the actual demand of other users. In 2013, the actual usage was 45 trips, which is 5 trips below the 50 trips budgeted. The Dark Chocolate Division used all the 30 trips it had budgeted. The Milk Chocolate Division used only 15 of the 20 trips budgeted. When costs are allocated based on actual costs and actual quantities, the same fixed costs are spread over fewer trips resulting in a higher rate than if the Milk Chocolate Division had used its budgeted 20 trips. As a result, the Dark Chocolate Division bears a proportionately higher share of the fixed costs. Using actual costs/actual rates also means then any efficiencies or inefficiencies of the trucking fleet get passed along to the user divisions. In general, this will have the effect of making the truck fleet less careful about its costs, although in 2013, it appears to have managed its costs well, leading to a lower actual cost per roundtrip relative to the budgeted cost per round trip. For the reasons stated above, of the three single‐rate methods suggested in this problem, the budgeted rate and actual quantity may be the best one to use. (The management of Chocolat, Inc. would have to ensure that the managers of the Dark Chocolate and Milk Chocolate divisions do not systematically overestimate their budgeted use of the fleet division in an effort to drive down the budgeted rate).
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14‐19 (20 min.) Dual‐rate method, budgeted versus actual costs, and practical capacity versus actual quantities. 1. 2.
Charges with dual rate method. Variable indirect cost rate = $1,500 per trip Fixed indirect cost rate = $40,000 budgeted costs/ 50 round trips budgeted
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= $800 per trip Dark Chocolate Division Variable indirect costs, $1,500 × 30 Fixed indirect costs, $800 × 30 Milk Chocolate Division Variable indirect costs, $1,500 × 15 Fixed indirect costs, $800 × 20
$45,000 24,000 $69,000
$22,500 16,000 $38,500
The dual rate changes how the fixed indirect cost component is treated. By using budgeted trips made, the Dark Chocolate Division is unaffected by changes from its own budgeted usage or that of other divisions. When budgeted rates and actual trips are used for allocation (see requirement 1b. of Problem 14‐18), the Dark Chocolate Division is assigned the same $24,000 for fixed costs as under the dual‐rate method because it made the same number of trips as budgeted. However, note that the Milk Chocolate Division is allocated $16,000 in fixed trucking costs under the dual‐rate system, compared to $800 15 actual trips = $12,000 when actual trips are used for allocation. As such, the Dark Chocolate Division is not made to appear disproportionately more expensive than the Milk Chocolate Division simply because the latter did not make the number of trips it budgeted at the start of the year.
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Chapter 14
14‐20 (30 min.) Support department cost allocation, direct and step‐down methods. 1. a. Direct method costs Alloc. of AS costs (40/75, 35/75) Alloc. of IS costs (30/90, 60/90) b. Step‐down (AS first) costs Alloc. of AS costs (0.25, 0.40, 0.35) Alloc. of IS costs (30/90, 60/90) c. Step‐down (IS first) costs Alloc. of IS costs (0.10, 0.30, 0.60) Alloc. of AS costs (40/75, 35/75) 2. Direct method Step‐down (AS first) Step‐down (IS first)
AS IS $600,000 $2,400,000 (600,000)
GOVT
CORP
$ 320,000
$ 280,000
(2,400,000) 800,000 0 $1,120,000 $ 0 $ $600,000 $2,400,000
1,600,000 $1,880,000
(600,000)
150,000 $ 240,000
$ 210,000
(2,550,000) 850,000 $ 0 $ 0 $1,090,000 $600,000 $2,400,000
1,700,000 $1,910,000
240,000 (2,400,000) (840,000) $ 0 $
0
$ 720,000
$1,440,000
448,000 $1,168,000
392,000 $1,832,000
GOVT $1,120,000 1,090,000 1,168,000
CORP $1,880,000 1,910,000 1,832,000
The direct method ignores any services to other support departments. The step‐ down method partially recognizes services to other support departments. The information systems support group (with total budget of $2,400,000) provides 10% of its services to the AS group. The AS support group (with total budget of $600,000) provides 25% of its services to the information systems support group. When the AS group is allocated first, a total of $2,550,000 is then assigned out from the IS group. Given CORP’s disproportionate (2:1) usage of the services of IS, this method then results in the highest overall allocation of costs to CORP. By contrast, GOVT’s usage of the AS group exceeds that of CORP (by a ratio of 8:7), and so GOVT is assigned relatively more in support costs when AS costs are assigned second, after they have already been incremented by the AS share of IS costs as well.
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14‐20 (cont’d) 3.
Three criteria that could determine the sequence in the step‐down method are: a. Allocate support departments on a ranking of the percentage of their total services provided to other support departments. 1. Administrative Services 25% 2. Information Systems 10% b. Allocate support departments on a ranking of the total dollar amount in the support departments. 1. Information Systems $2,400,000 2. Administrative Services $ 600,000 c. Allocate support departments on a ranking of the dollar amounts of service provided to other support departments 1. Information Systems (0.10 $2,400,000) = $240,000 2. Administrative Services (0.25 $600,000) = $150,000
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The approach in (a) above typically better approximates the theoretically preferred reciprocal method. It results in a higher percentage of support‐ department costs provided to other support departments being incorporated into the step‐down process than does (b) or (c), above.
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Chapter 14
14‐21 (50 min.) Support‐department cost allocation, reciprocal method. 1a.
Support Departments AS I S $600,000 $2,400,000 (861,538) 215,385 261,538 (2,615,385) $ 0 $ 0
Operating Departments Govt. Corp. $ 344,615 $ 301,538 784,616 1,569,231 $1,129,231 $1,870,769
Costs Alloc. of AS costs (0.25, 0.40, 0.35) Alloc. of IS costs (0.10, 0.30, 0.60) Reciprocal Method Computation AS = $600,000 + 0.10 IS IS = $2,400,000 + 0.25AS IS = $2,400,000 + 0.25 ($600,000 + 0.10 IS) = $2,400,000 + $150,000 + 0.025 IS 0.975IS = $2,550,000 IS = $2,550,000 ÷ 0.975 = $2,615,385 AS = $600,000 + 0.10 ($2,615,385) = $600,000 + $261,538 = $861,538
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14‐21 (cont’d) 1b.
Support Departments AS I S Costs $600,000 $2,400,000 st 1 Allocation of AS (0.25, 0.40, 0.35) (600,000) 150,000 2,550,000 st 1 Allocation of IS (0.10, 0.30, 0.60) 255,000 (2,550,000) nd 2 Allocation of AS (0.25, 0.40, 0.35) (255,000) 63,750 nd 2 Allocation of IS (0.10, 0.30, 0.60) 6,375 (63,750) 3rd Allocation of AS (0.25, 0.40, 0.35) (6,375) 1,594 rd 3 Allocation of IS (0.10, 0.30, 0.60) 160 (1,594) 4th Allocation of AS (0.25, 0.40, 0.35) (160) 40 4th Allocation of IS (0.10, 0.30, 0.60) 4 (40) th 5 Allocation of AS (0.25, 0.40, 0.35) (4) 1 th 5 Allocation of IS (1) (0.10, 0.30, 0.60) 0 Total allocation $ 0 $ 0
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Operating Departments Govt. Corp. $ 240,000 $ 210,000 765,000 1,530,000 102,000 89,250 19,125 38,250 2,550 2,231 478 956 64 56 12 24 2 1 0 1 $1,129,231 $1,870,769
Chapter 14
14‐21 (cont’d) 2. Govt. Consulting Corp. Consulting a. Direct $1,120,000 $1,880,000 b. Step‐Down (AS first) 1,090,000 1,910,000 c. Step‐Down (IS first) 1,168,000 1,832,000 d. Reciprocal (linear equations) 1,129,231 1,870,769 e. Reciprocal (repeated iterations) 1,129,231 1,870,769 The four methods differ in the level of support department cost allocation across support departments. The level of reciprocal service by support departments is material. Administrative Services supplies 25% of its services to Information Systems. Information Systems supplies 10% of its services to Administrative Services. The Information Department has a budget of $2,400,000 that is 400% higher than Administrative Services. The reciprocal method recognizes all the interactions and is thus the most accurate. This is especially clear from looking at the repeated iterations calculations.
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14‐22 (45 min.) Allocating costs of support departments; step‐down and direct methods.
1. Step‐down Method: (1) Building & grounds at $0.10/sq.m. ($10,000 ÷ 100,000) (2) Personnel at $6/employee ($1,200 ÷ 200) (3) General plant administration at $1/labour‐hour ($27,000 ÷ 27,000) (4) Cafeteria at $20/empoloyee ($3,100 ÷ 155) (5) Storeroom at $1.50/requisition ($4,500 ÷ 3,000) (6) Costs allocated to operating depts. (7) Divide (6) by dir. manuf. labour‐hrs. (8) Overhead rate per direct manuf. labour‐hour 2. Direct method: (1) Building & grounds, 30,000/80,000; 50,000/80,000 (2) Personnel, 50/150; 100/150 (3) General plant administration, 8,000/25,000; 17,000/25,000 (4) Cafeteria, 50/150; 100/150 (5) Storeroom: 2,000/3,000; 1,000/3,000 (6) Costs allocated to operating depts. (7) Divide (6) by direct manufacturing labour‐hours (8) Overhead rate per direct manufacturing labour‐hour
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Building & Grounds $ 10,000
Personnel $ 1,000
$(10,000)
Cafeteria Operating Loss $ 1,640
General Plant Admin. $ 26,090
Storeroom $ 2,670
Machining $34,700
200
700
400
700
3,000
5,000
$(1,200)
210
60 1,000
30 1,000
300 8,000
600 17,000
$(3,100)
100
1,000
2,000
$(4,500)
3,000 $50,000 ÷ 5,000
1,500 $75,000 ÷15,000
$ 10 $34,700 3,750 333 8,349 547
$ 5 $48,900 6,250 667 17,741 1,093
1,780 $49,459 ÷ 5,000 $ 9.892
890 $75,541 ÷15,000 $ 5.036
$1,000
$1,640
$2,670
$10,000 (10,000)
Assembly $48,900
$(27,000)
$26,090
(1,000) (26,090)
(1,640)
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(2,670)
Chapter 14
14‐22 (cont’d) 3. 4.
Comparison of Methods: Step‐down method: Direct method:
18 × $10 2 × $ 5 3 × $10 17 × $ 5 18 × $9.892 2 × $5.036 3 × $9.892 17 × $5.036
$180 10 $ 30 85 $178.06 10.07 $ 29.68 85.61
$190.00
115.00
$188.13 115.29
The manager of Machining Department would prefer the direct method. The direct method results in a lower amount of support departments’ costs being allocated to the Machining Department than the step‐down method. This is clear from a comparison of the overhead rate, per direct manufacturing labour‐hour, for the Machining Department under the two methods.
14‐23 1.
Job 88: Job 89: Job 88: Job 89:
Fixed cost allocation
i) Allocation using actual usage. Actual Percentage of Restaurant Usage Total Usage A 1,500 0.357 B 1,400 0.333 0.310 C 1,300 Total 4,200 ii) Allocation using planned usage. Percentage of Planned Total Planned Restaurant Usage Usage A 1,600 0.400 B 1,300 0.325 C 1,100 0.275 Total 4,000
Allocation % × 10,000 $ 3,570 3,330 3,100 $10,000
Allocation % × 10,000 $ 4,000 3,250 2,750 $10,000
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iii) Allocation using practical capacity. Percentage of Total Practical Practical Restaurant Capacity Capacity A 2,000 0.400 B 1,500 0.300 C 1,500 0.300 Total 5,000
Allocation % × 10,000 $ 4,000 3,000 3,000 $10,000
2.
If the practical capacity refers to the number of parking spots that are earmarked or reserved for each of the restaurants, then it would appear to be the most appropriate basis for allocating the $10,000 common cost. This ratio is a stable benchmark and does not fluctuate based on variations in either the actual or planned monthly usage of spots for each of the restaurants, which is an issue with each of the other two methods. Moreover, the practical capacity taken by each restaurant presumably reflects the restaurant’s expectation of the long‐run usage of the parking facility by its patrons. The cost of any unused capacity then highlights the extent to which these expectations are not met, and might lead to the restaurant settling for a smaller parking facility in the future. Of course, if it is ever the case that the expected or actual usage for any restaurant exceeds the practical capacity that it has “booked,” it would need to suitably compensate the other restaurants for the portion of their parking capacity it has appropriated.
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14‐24 (40 min.) Direct and step‐down allocation. 1. Costs Incurred Alloc. of HR costs (42/70, 28/70) Alloc. of Info. Syst. costs (1,920/3,520, 1,600/3,520)
2.
Operating Support Departments Departments HR Info. Corporate Consumer Systems $72,700 $234,400 $ 998,270 $489,860 (72,700) 43,620 29,080 127,855 106,545 ____ (234,400) $ 0 $ 0 $1,169,745 $625,485
Total $1,795,230
_________ $1,795,230
Rank on percentage of services rendered to other support departments. Step 1: HR provides 23.077% of its services to information systems: 21 21 = = 23.077% 42 28 21 91 This 23.077% of $72,700 HR department costs is $16,777. Step 2: Information systems provides 8.333% of its services to HR: 320 320 = = 8.333% 1,920 1,600 320 3,840
This 8.333% of $234,400 information systems department costs is $19,533. Operating Departments Support Departments HR Info. Systems Corporate Consumer Total Costs Incurred $72,700 $234,400 $ 998,270 $489,860 $1,795,230 Alloc. of HR costs 16,777 33,554 22,369 (21/91, 42/91, 28/91) (72,700) 251,177 $ 0 Alloc. of Info. Syst. costs 114,171 (1,920/3,520, 1,600/3,520) (251,177) 137,006 $626,400 $1,795,230 $ 0 $1,168,830
3.
An alternative ranking is based on the dollar amount of services rendered to other support departments. Using numbers from requirement 2, this approach would use the following sequence: Step 1: Allocate Information Systems first ($19533 provided to HR). Step 2: Allocate HR second ($16777 provided to Information Systems).
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14‐25 (30 min.) Reciprocal cost allocation (continuation of 14‐24). 1.
The reciprocal allocation method explicitly includes the mutual services provided among all support departments. Interdepartmental relationships are fully incorporated into the support department cost allocations.
2. HR = $72,700 + .08333IS IS = $234,400 + .23077HR HR = $72,700 + [.08333($234,400 + .23077HR)] = $72,700 + [$19,532.55 + 0.01923HR] 0.98077HR = $92,232.55 HR = $92,232.55 0.98077 = $94,041 IS = $234,400 + (0.23077 $94,041) = $256,102 Costs Incurred Alloc. of HR costs (21/91, 42/91, 28/91) Alloc. of Info. Syst. costs (320/3,840, 1,920/3,840, 1,600/3,840)
Support Depts. Info. Systems HR $72,700 $234,400 (94,041)
21,341 $ 0
Operating Depts.
Corporate Consumer $ 998,270 $489,860 21,702 43,404 28,935 (256,102) 128,051 106,710 $ 0 $1,169,725 $625,505
Total $1,795,230
$1,795,230
Solution Exhibit 14‐25 presents the reciprocal method using repeated iterations.
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SOLUTION EXHIBIT 14‐25 Reciprocal Method of Allocating Support Department Costs for September 2013 at E‐books Using Repeated Iterations Support Departments Operating Departments Human Information Corporate Consumer Resources Systems Sales Sales Total Budgeted manufacturing overhead costs before any interdepartmental cost allocation $72,700 $234,400 $ 998,270 $489,860 $1,795,230 st 1 Allocation of HR a (21/91, 42/91, 28/91) (72,700) 16,777 33,554 22,369 1st Allocation of Information Systems 20,931 (251,177) 125,589 104,657 (320/3,840, 1,920/3,840, 1,600/3,840)b nd 2 Allocation of HR (20,931) 4,830 9,661 6,440 (21/91, 42/91, 28/91)a 2nd Allocation of Information Systems (320/3,840, 1,920/3,840, 1,600/3,840)b 402 (4,830) 2,415 2,013 rd 3 Allocation of HR (402) 93 185 124 (21/91, 42/91, 28/91)a rd 3 Allocation of Information Systems 8 (93) 46 39 (320/3,840, 1,920/3,840, 1,600/3,840)b th 4 Allocation of HR (21/91, 42/91, 28/91)a (8) 2 4 2 th 4 Allocation of Information Systems: 0 (2) 1 1 ________ (320/3,840, 1,920/3,840, 1,600/3,840)b Total budgeted manufacturing $ 0 $1,169,725 $625,505 $1,795,230 overhead of operating departments $ 0 Total accounts allocated and reallocated (the numbers in parentheses in first two columns) HR $72,700 + $20,931 + $402 + $8 = $94,041 Information Systems $251,177 + $4,830 + $93 + $2 = $256,102 aBase is (21 + 42 + 28) or 91 employees bBase is (320 + 1,920 + 1,600) or 3,840 minutes
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14‐25 (cont’d) 3.
The reciprocal method is more accurate than the direct and step‐down methods when there are reciprocal relationships among support departments. A summary of the alternatives is: Corporate Sales Consumer Sales Direct method $1,169,745 $625,485 Step‐down method (HR 1,168,830 626,400 first) Reciprocal method 1,169,725 625,505
The reciprocal method is the preferred method, although for September 2014 the numbers do not appear materially different across the alternatives.
PROBLEMS 14‐26 (20 min.) Single‐rate, dual‐rate, and practical capacity allocation. Budgeted number of gifts wrapped = 6,750 Budgeted fixed costs = $6,750 Fixed cost per gift based on budgeted volume = $6,750 ÷ 6,750 = $1.00 Average budgeted variable cost per gift = 0.50 Total cost per gift wrapped $1.50 1a. Allocation based on budgeted usage of gift‐wrapping services: Women’s Face Wash (2,475 × $1.50) $ 3,712.50 Men’s Face Wash (825 × $1.50) 1,237.50 Fragrances (1,800 × $1.50) 2,700.00 Body Wash (450 × $1.50) 675.00 Hair Products (1,200 × $1.50) 1,800.00 Total $10,125.00
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14‐26 (cont’d) 1b.
1c. 2.
Allocation based on actual usage of gift‐wrapping services: Women’s Face Wash (2,100 × $1.50) Men’s Face Wash (750 × $1.50) Fragrances (1,575 × $1.50) Body Wash (525 × $1.50) Hair Products (1,050 × $1.50) Total
$3,150.00 1,125.00 2,362.50 787.50 1,575.00 $9,000.00
Practical gift‐wrapping capacity = 7,500 Budgeted fixed costs = $6,750 Fixed cost per gift based on practical capacity = $6,750 ÷ 7,500 = $0.90 Average budgeted variable cost per gift = 0.50 Total cost per gift wrapped $1.40 Allocation based on actual usage of gift‐wrapping services: Women’s Face Wash (2,100 × $1.40) $2,940 Men’s Face Wash (750 × $1.40) 1,050 Fragrances (1,575 × $1.40) 2,205 Body Wash (525 × $1.40) 735 Hair Products (1,050 × $1.40) 1,470 Total $8,400
Budgeted fixed costs Practical capacity = $6,750 ÷ 7,500 gifts = $0.90 per gift Fixed costs allocated on budgeted usage.
Budgeted rate for fixed costs =
Rate for variable costs = $0.50 per item Variable costs based on actual usage. Allocation:
Department Women’s Face Wash Men’s Face Wash Fragrances Body Wash Hair Products Total
Variable Costs 2,100 × $0.50 =$1,050.00 750 × $0.50 = 375.00 1,575 × $0.50 = 787.50 525 × $0.50 = 262.50 1,050 × $0.50 = 525.00 $3,000.00
Fixed Costs 2,475 × $0.90 = $2,227.50 825 × $0.90 = 742.50 1,800 × $0.90 = 1,620.00 450 × $0.90 = 405.00 1,200 × $0.90 = 1,080.00 $6,075.00
Total $3,277.50 1,117.50 2,407.50 667.50 1,605.00 $9,075.00
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14‐26 (cont’d) 3.
The dual‐rate method has two major advantages over the single‐rate method: a. Fixed costs and variable costs can be allocated differently—fixed costs based on rates calculated using practical capacity and budgeted usage and variable costs based on budgeted rates and actual usage. b. Fixed costs are allocated proportionately to the departments causing the incurrence of those costs based on the capacity of each department. c. The costs allocated to a department are not affected by the usage by other departments. Note: If capacity costs are the result of a long‐term decision by top management, it may be desirable to allocate to each department the cost of capacity used based on actual usage. The users are then not allocated the costs of unused capacity.
14‐27 (15 min.) Allocating costs to divisions. 1. Allocations based on square metres. 1. Square metres 2. % square metres (130,000; 90,000; 80,000; 100,000 ÷ 400,000) 3. Allocated HQ cost (Row 2 × $14,255,000)
Refrigerator 130,000
32.5% $4,632,875
Stove 90,000
Microwave Dishwasher Oven 80,000 100,000
22.5% $3,207,375
20% $2,851,000
25% $3,563,750
Total 400,000
100% $14,255,000
Microwave Refrigerator Stove Dishwasher Oven Segment margin $5,200,000 $8,400,000 $5,300,000 $3,560,000 Less: Headquarters costs 4,632,875 3,207,375 2,851,000 3,563,750 Division margin $ 567,125 $5,192,625 $2,449,000 $ (3,750) (0.06)% Division margin ÷ Revenue 5.2% 27.6% 21.3%
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Total $22,460,000 14,255,000 $ 8,205,000 17.1%
Chapter 14
14‐27 (cont’d) Allocations based on segment margin. Refrigerator
1. Segment margin 2. % segment margin $5,200,000; $8,400,000; $5,300,000; $3,560,000 ÷ $22,460,000 3. Allocated headquarters cost (Row 2 × $14,255,000)
$5,200,000
23.15% $3,300,033
Stove $8,400,000
Dishwasher
Microwave Oven
$5,300,000
$3,560,000
37.40% $5,331,370
23.60% $3,364,180
15.85% $2,259,417
Total $22,460,000
100% $14,255,000
Refrigerator
Stove
Dishwasher
Microwave Oven
Segment margin
$5,200,000
$8,400,000
$5,300,000
$3,560,000
$22,460,000
Less: Headquarters costs
3,300,033
5,331,370
3,364,180
2,259,417
14,255,000
Division margin
$1,899,967
$3,068,630
$1,935,820
$1,300,583
$ 8,205,000
Division margin ÷ Revenue
2.
3.
17.4%
16.3%
16.8%
19.2%
Total
17.1%
I prefer the allocation based on segment margins because a cause‐and‐effect relationship may exist between headquarters costs and division segment margin— headquarters staff are likely to spend more time on divisions that have more revenue and segment margins. Segment margins can also be justified on the ability‐to‐bear principle—divisions with higher margins can bear more of the headquarters costs. The physical size of the divisions probably has no cause‐and‐effect relationship with headquarters costs. None of the divisions should be dropped, since all four have positive segment margins before considering the headquarters’ cost allocation. As seen by these two options, the allocation of headquarters costs is arbitrary and should not serve as the basis for closing a division.
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14‐28 (40–60 min.) Support‐department cost allocations; single‐division cost pools; direct, step‐down, and reciprocal methods. All the following computations are in dollars. 1. Direct method: To X To Y A 250/400 $100,000 = $62,500 150/400 $100,000 = $37,500 B 100/500 $ 40,000 = 8,000 400/500 $ 40,000 = 32,000 Total $70,500 $69,500 Step‐down method, allocating A first: A B X Y Costs to be allocated $100,000 $40,000 — — Allocate A: (100; 250; 150 ÷ 500) (100,000) 20,000 $50,000 $30,000 (60,000) 12,000 48,000 Allocate B: (100; 400 ÷ 500) — Total $ 0 $ 0 $62,000 $78,000 Step‐down method, allocating B first: A B X Y Costs to be allocated $100,000 $ 40,000 — — Allocate B: (500; 100; 400 ÷ 1,000) 20,000 (40,000) $ 4,000 $16,000 Allocate A: (250/400, 150/400) (120,000) — 75,000 45,000 Total $ 0 $ 0 $79,000 $61,000 Note that these methods produce significantly different results, so the choice of method may frequently make a difference in the budgeted department overhead rates. Reciprocal method: Stage 1: Let A = total costs of materials‐handling department B = total costs of power‐generating department (1) A = $100,000 + 0.5B (2) B = $ 40,000 + 0.2A Stage 2: Substituting in (1): A = $100,000 + 0.5($40,000 + 0.2A) A = $100,000 + $20,000 + 0.1A 0.9A = $120,000 A = $133,333
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14‐28 (cont’d) Substituting in (2): B = $40,000 + 0.2($133,333) B = $66,666 Stage 3: A B X Y Original amounts $100,000 $40,000 — — Allocation of A (133,333) 26,666(20%) $66,667(50%) $40,000(30%) Allocation of B 33,333(50%) (66,666) 6,667(10%) 26,666(40%) $ 0 $73,334 $66,666 Totals accounted for $ 0 SOLUTION EXHIBIT 14‐28 Reciprocal Method of Allocating Support Department Costs for Manes Company Using Repeated Iterations.
Operating Departments X Y
Support Departments A B
Budgeted manufacturing overhead costs before any interdepartmental cost allocations $100,000 st a 1 Allocation of Dept. A: (2/10, 5/10, 3/10) (100,000) st b 30,000 1 Allocation of Dept. B (5/10, 1/10, 4/10) nd a 2 Allocation of Dept A: (2/10, 5/10, 3/10) (30,000) 3,000 2nd Allocation of Dept B: (5/10, 1/10, 4/10)b rd a (3,000) 3 Allocation of Dept A: (2/10, 5/10, 3/10) rd b 3 Allocation of Dept B: (5/10, 1/10, 4/10) 300 (300) 4th Allocation of Dept A: (2/10, 5/10, 3/10)a 30 4th Allocation of Dept B: (5/10, 1/10, 4/10)b th 5 Allocation of Dept A: (2/10, 5/10, 3/10) (30) 3 5th Allocation of Dept B: (5/10, 1/10, 4/10) th (3) 6 Allocation of Dept A: (2/10, 5/10, 3/10) Total budgeted manufacturing overhead of operating departments $ 0
$40,000 $20,000 (60,000) 6,000 (6,000) 600 (600) 60 (60) 6 (6) 0 $ 0
$50,000 6,000 15,000 600 1,500 60 150 6 15 1 2
$30,000 24,000 9,000 2,400 900 240 90 24 9 2 1
$73,334
$66,666
Total accounts allocated and reallocated (the numbers in parentheses in first two columns) Dept A; Materials Handling: $100,000 + $30,000 + $3,000 + $300 + $30 + $3 = $133,333 Dept B; Power Generation: $60,000 + $6,000 + $600 + $60 + $6 = $66,666 aBase is (100 + 250 +150) or 500 labour‐hours; 100 ÷ 500 = 2/10, 250 ÷ 500 = 5/10, 150 ÷ 500 = 3/10. bBase is (500 + 100 + 400) or 1,000 kWh ; 500 ÷ 1,000 = 5/10, 100 ÷ 1,000 = 1/10, 400 ÷ 1,000 = 4/10.
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14‐28 (cont’d) Comparison of methods: Method of Allocation X Y Direct method $70,500 $69,500 Step‐down: A first 62,000 78,000 Step‐down: B first 79,000 61,000 Reciprocal method 73,334 66,666 Note that in this case the direct method produces answers that are the closest to the “correct” answers (that is, those from the reciprocal method), step‐down allocating B first is next, and step‐down allocating A first is least accurate. 2. At first glance, it appears that the cost of power is $40 per unit plus the material handling costs. If so, Manes would be better off by purchasing from the power company. However, the decision should be influenced by the effects of the interdependencies and the fixed costs. Note that the power needs would be less (students frequently miss this) if they were purchased from the outside: Outside Power Units Needed X 100 Y 400 A (500 units minus 20% of 500 units, because there is no need to service the nonexistent power department) 400 Total units 900 Total costs, 900 $40 = $36,000 In contrast, the total costs that would be saved by not producing the power inside would depend on the effects of the decision on various costs:
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14‐28 (cont’d) Variable indirect labour and indirect material costs Supervision in power department Materials handling, 20% of $70,000* Probable minimum cost savings Possible additional savings: a. Can any supervision in materials handling be saved because of overseeing less volume? Minimum savings is probably zero; the maximum is probably 20% of $10,000 or $2,000. b. Is any depreciation a truly variable, wear‐and‐tear type of cost? Total savings by not producing 1,000 units of power
Avoidable Costs of 1,000 Units of Power Produced Inside $10,000 10,000 14,000 $34,000 ? ? ______ $34,000 + ?
* Materials handling costs are higher because the power department uses 20% of materials handling. Therefore, materials‐handling costs will decrease by 20%. In the short run (at least until a capital investment in equipment is necessary), the data suggest continuing to produce internally because the costs eliminated would probably be less than the comparable purchase costs.
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14‐29 (25 min.) Common costs. 1. 2.
3.
Stand‐alone cost‐allocation method. (900 $40) Wright, Inc. = (1,500 $32) (900 $40) (600 $40) $36, 000 = $48, 000 = $28,800 ($36, 000 $24, 000) (600 $40) Brown, Inc. = (1,500 $32) (900 $40) (600 $40) $24, 000 = $48, 000 = $19,200 ($36, 000 $24, 000) With Wright, Inc. as the primary party: Party Costs Allocated Wright $36,000 Brown 12,000 ($48,000 – $36,000) Total $48,000 With Brown, Inc. as the primary party: Party Costs Allocated Brown $24,000 Wright 24,000 ($48,000 – $24,000) Total $48,000
Cumulative Costs Allocated $24,000 $48,000
The results of the four cost‐allocation methods are shown below. Stand‐alone method Incremental (Wright primary) Incremental (Brown primary) Shapley value
Wright, Inc. $28,800 36,000 24,000 30,000
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Cumulative Costs Allocated $36,000 $48,000
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Brown, Inc. $19,200 12,000 24,000 18,000
Chapter 14
14‐29 (cont’d)
The allocations are very sensitive to the method used. The stand‐alone method is simple and fair since it allocates the common cost of the dyeing machine in proportion to the individual costs of leasing the machine. The Shapley values are also fair. They result in very similar allocations and any one of them can be chosen. In this case, the stand‐alone method is likely more acceptable. If they used the incremental cost‐allocation method, Wright, Inc. and Brown, Inc. would probably have disputes over who is the primary party because the primary party gets allocated all of the primary party’s costs.
14‐30 (60 min.) 1.
Support cost allocation to support and operations.
Solution Exhibit 14‐30 presents the costs allocated to each assembly department under the four service department cost allocation methods. The linear equations underlying the complete reciprocated costs reported in Solution Exhibit 14‐30 are:
Fixed Cost Pool: ES = $2,800 + 0.20IS IS = $8,100 + 0.10ES ES = $2,800 + 0.20($8,100 + 0.10ES) ES = $4,420 + 0.02ES 0.98ES = $4,420 ES = $4,420 ÷ 0.98 = $4,510 IS = $8,100 + 0.10($4,510) = $8,551 Variable Cost Pool: ES = $8,500 +0.25IS IS = $3,750 + 0.15ES ES = $8,500 + 0.25 ($3,750 + 0.15ES) ES = $9,437.50 + 0.0375ES 0.9625ES = $9,437.50 ES = $9,437.50 ÷ 0.9625 = $9,805 IS = $3,750 + 0.15($9,805) = $3,750 + $1,471 = $5,221
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14‐30 (cont’d) A summary of the costs allocated under each method is: Home Security Systems a. Direct Method: $4,282 Fixed cost pool 3,750 Variable cost pool $8,032 b. Step‐down (Information first): $4,394 Fixed cost pool 3,893 Variable cost pool $8,287 c. Step‐down (Engineering first): $4,262 Fixed cost pool 3,555 Variable cost pool $7,817 d. Reciprocal Method: $4,369 Fixed cost pool 3,724 Variable cost pool $8,093
Business Security Systems $ 6,618 8,500 $15,118 $ 6,506 8,357 $14,863 $ 6,638 8,695 $15,333 $ 6,531 8,526 $15,057
2.
Support department costs allocated per unit:
a. b. c. d. 3.
Direct method Step‐down (Information first) Step‐down (Engineering first) Reciprocal method
Home Security Systems $1.01 $1.04 $0.98 $1.02
Business Security Systems $4.03 $3.96 $4.09 $4.02
Factors that might explain the very limited adoption of the reciprocal method include: a. Managers find the reciprocal method difficult to understand, especially where there are many support departments. b. The final cost allocations yielded by using the reciprocal method differ little in some cases from those yielded by using the direct or step‐down methods. As illustrated in requirement 2, the differences among the four methods in this problem appear small. c. It is costly to maintain records of the use of the support departments by other support departments.
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SOLUTION EXHIBIT 14‐30 (in thousands)
a.
Direct Method Fixed Cost Pool: Eng. Support (4/9, 5/9) Info. Support (3/8, 5/8) Variable Cost Pool: Eng. Support (30/85, 55/85) Info. Support (15/75, 60/75)
b.
Step‐down (Information first) Fixed Cost Pool: Info. Support (.2, .3, .5) Eng. Support (4/9, 5/9) Variable Cost Pool: Info. Support (.25, .15, .60) Eng. Support (30/85, 55/85) Step‐down (Engineering first) Fixed Cost Pool: Eng. Support (.1, .4, .5) Info. Support (3/8, 5/8) Variable Cost Pool: Eng. Support (.15, .30, .55) Info. Support (15/75, 60/75) Reciprocal Method Fixed Cost Pool: Eng. Support (.1, .4, .5) Info. Support (.2, .3, .5) Variable Cost Pool: Eng. Support (.15, .30, .55) Info. Support (.25, .15, .60)
c.
d.
Engineering Support $2,800 (2,800) 000000 0 $8,500 (8,500) 000000 0 $2,800 1,620 (4,420) 0 $8,500 938 (9,438) 0 $2,800 (2,800) 0 $8,500 (8,500) — 0 $2,800 (4,510) 1,710 0 $8,500 (9,805) 1,305 0
Information Systems Support $8,100 (8,100) 0 $3,750 — (3,750) 0 $8,100 (8,100) — 0 $3,750 (3,750) — 0 $8,100 280 (8,380) 0 $3,750 1,275 (5,025) 0 $8,100 451 (8,551) 0 $3,750 1,471 (5,221) 0
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Home Security Systems $1,244 3,038 $4,282 $3,000 750 $3,750 $2,430 1,964 $4,394 $ 562 3,331 $3,893 $1,120 3,142 $4,262 2,550 1,005 $3,555 $1,804 2,565 $4,369 $2,941 783 $3,724
Business Security Systems $1,556 5,062 $6,618 $5,500 3,000 $8,500 $4,050 2,456 $6,506 $2,250 6,107 $8,357 $1,400 5,238 $6,638 $4,675 4,020 $8,695 $2,255 4,276 $6,531 $5,393 3,133 $8,526
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14‐31 (40 min.) Support cost allocation processes. Because corporate policy encourages line managers to seek legal counsel on pertinent issues from the Legal Department, any step in the direction of reducing costs of legal department services would be consistent with the corporate policy. Currently a user department is charged a standard fee of $400 per hour based on actual usage. It is possible that some managers may not be motivated to seek the legal counsel they need due to the high allocated cost of the service. It is also possible that those managers whose departments are currently experiencing budgetary cost overruns may be disinclined to make use of the service; it would save them from the Legal Department’s cost allocation. However, it could potentially result in much costlier penalties for Environ later if the corporation inadvertently engaged in some activities that violated one or more laws. It is quite likely that the line managers would seek legal counsel, whenever there were any pertinent legal issues, if the service were free. Making the service of the Legal Department free, however, might induce some managers to make excessive use of the service. To avoid any potential abuse, Environ may want to adjust the rate downward considerably, perhaps at a level lower than what it would cost if outside legal services were sought, but not eliminate it altogether. As long as the managers know that their respective departments would be charged for using the service, they would be disinclined to make use of it unnecessarily. However, they would be motivated to use it when necessary because it would be considered a “good value” if the standard hourly rate was low enough.
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Chapter 14
14‐32
Cost allocation to divisions. 1. Bread Segment margin $6,400,000 Allocated headquarters costs ($5,100,000 ÷ 3) 1,700,000 Operating income $4,700,000 2. Segment margin Allocated headquarters costs, Human resources1 (50%; 12.5%; 37.5% × $1,900,000) Accounting department2 (53.9%; 11.6%; 34.5% × $1,400,000) Rent and depreciation3 (50%; 20%; 30% × $1,200,000)
1 3
Other ( $600,000 )
Cake $1,300,000
Doughnuts Total $6,150,000 $13,850,000
1,700,000 $ (400,000)
1,700,000 $4,450,000
5,100,000 $ 8,750,000
Bread $6,400,000
Cake $1,300,000
Doughnuts Total $6,150,000 $13,850,000
950,000
237,500
712,500
1,900,000
754,600
162,400
483,000
1,400,000
600,000
240,000
360,000
1,200,000
200,000
200,000
200,000
600,000
Total 2,504,600 839,900 1,755,500 5,100,000 $ 460,100 $4,394,500 $ 8,750,000 Operating income $3,895,400 1HR costs: 400 ÷ 800 = 50%; 100 ÷ 800 = 12.5%; 300 ÷ 800 = 37.5% 2Accounting: $20,900,000 ÷ $38,800,000 = 53.9%; $4,500,000 ÷ $38,800,000 = 11.6%; $13,400,000 ÷ $38,800,000 = 34.5% 3 Rent and depreciation: 10,000 ÷ 20,000 = 50%; 4,000 ÷ 20,000 = 20%; 6,000 ÷ 20,000 = 30%
3.
A cause‐and‐effect relationship may exist between Human Resources costs and the number of employees at each division. Rent and depreciation costs may be related to square metres, except that very expensive machines may require few square metres, which is inconsistent with this choice of allocation base. The Accounting Department costs are probably related to the revenue earned by each division—higher revenue mean more transactions and more accounting. Other overhead costs are allocated arbitrarily. The manager suggesting the new allocation bases probably works in the Cake Division. Under the old scheme, the Cake Division shows an operating loss after allocating headquarters costs because it is smaller, yet was charged an equal amount (a third) of headquarters costs. The new allocation scheme shows an operating profit in the Cake Division, even after allocating headquarters costs. The ABC method is a better way to allocate headquarters costs because it uses cost allocation bases that, by and large, represent cause‐and‐effect relationships between various categories of headquarters costs and the demands that different divisions place on these costs.
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14‐33 1.
Matrix algebra.
2.
3.
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Chapter 14
Matrix algebra.
1.
2.
3.
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14‐35 (30 min.) Support cost allocation processes. 1.
Problems with the monthly allocation report include: a. The single‐rate method used does not distinguish between fixed and variable costs. b. Actual costs and actual quantities are used. This results in managers not knowing cost rates until year‐end. c. Monthly time periods are used to determine cost rates. The use of a monthly time period can result in highly variable cost rates depending on seasonality, days in a month, demand surges and so on.
2.
Budgeted variable cost (based on normal usage): $8, 000, 000 $0.08 per kwh 100, 000, 000
Monthly Allocation Report November 2014 Allocations of Variable Costs (based on budgeted rate × actual usage)* To Department A: 60,000,000 $0.08 $4,800,000 To Department B: 20,000,000 $0.08 1,600,000 $6,400,000 *There will be $1,600,000 of unallocated variable costs for November 2013 Allocation of Fixed Costs (Based on budgeted usage budgeted amount) To Department A: 60% $30,500,000 $18,300,000 12,200,000 To Department B: 40% $30,500,000 $30,500,000 Department A Variable costs $ 4,800,000 Fixed costs 18,300,000 $23,100,000 Department B Variable costs $ 1,600,000 Fixed costs 12,200,000 $13,800,000
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Chapter 14
14‐35 (cont’d) 3.
Under Lamb’s allocation report, the production manager has both risk‐exposure and uncertainty concerns: • Risk‐exposure—Changes in the demand for energy by Department A affect the costs Lamb will report for Department B. Increases in demand by A will reduce B’s cost per kwh and vice versa. Department B’s production manager may seek to curtail production in periods when Departments A’s production declines. This could create an ever‐diminishing cycle of production. Alternatively, Department B may subcontract outside to avoid a higher energy rate, even if it is not in Bulldog’s best interest to subcontract. • Uncertainty—When actual costs are used, managers cannot plan costs with certainty. Managers typically have less ability to bear uncertainty than do companies. The result is that managers may reject alternatives that are good risks from Bulldog’s perspectives but not attractive risks for themselves.
14‐36 (35 min.)
Common cost allocation and contracts. 1. Miller = 1,000 × $1.00 × ($1,360*) ($1,000 × $1.00) + (700 × $1.00) = $1,000 × $1,360 = $800 $1,000 + $700 * (1,700 × $0.80) = $1,360 Jackson = 700 × $1.00 × ($1,360) (700 × $1.00) + ($1,000 × $1.00) × $1,360 = $560 = $700 $700 + $1,000
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14‐36 (cont’d) 2. Costs Remaining Party Costs Allocated to be Allocated Miller (primary) $1,000 $360 ($1,360 – $1,000) Jackson (incremental) $ 360 $ 0 If Jackson is the primary party, the allocation would be Costs Remaining Party Costs Allocated to be Allocated Jackson (primary) $700 $660 ($1,360 – $700) Miller (incremental) $660 $ 0 3. Use the stand‐alone cost allocation method since it is fairer than the incremental one. Using this approach, Miller is allocated $800 and Jackson is allocated $560 out of the total costs of $1,360. If they used the incremental cost‐allocation method, Miller and Jackson would probably have disputes over who is the primary party because the primary party gets allocated all costs first.
COLLABORATIVE LEARNING CASE
14‐37 (20–25 min.) Revenue allocation, bundled products. 1a.
The stand‐alone revenue (using unit selling prices) of the three components of the $1,000 package are:
Lodging
Recreation
Food
Lodging $400.00 × 2 = $ 800 Recreation $187.50 × 2 = 375 Food $100.00 × 2 = 200 $1,375 $800 $1,000 0.582 $1,000 $582 $1,375 $375 $1,000 0.273 $1,000 $273 $1,375 $200 $1,000 0.145 $1,000 $145 $1,375
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14‐37 (cont’d) b.
Product Recreation Lodging Food
2.
Revenue Allocated $ 375 625 ($1,000 – $375) 0 $1,000
Cumulative Revenue Allocated $ 375 $1,000 $1,000
The pros of the stand‐alone‐revenue‐allocation method include the following: a. Each item in the bundle receives a positive weight, which means the resulting allocations are more likely to be accepted by all parties than a method allocating zero revenue to one or more products. b. It uses market‐based evidence (unit selling prices) to decide the revenue allocations—unit prices are one indicator of benefits received . c. It is simple to implement. The cons of the stand‐alone revenue‐allocation method include: a. It ignores the relative importance of the individual components in attracting consumers to purchase the bundle. b. It ignores the opportunity cost of the individual components in the bundle. The golf course operates at 100% capacity. Getaway participants must reserve a golf booking one week in advance, or else they are not guaranteed playing time. A getaway participant who does not use the golf option may not displace anyone. Thus, under the stand‐alone method, the golf course may be paid twice—once from the non‐getaway person who does play and second from an allocation of the $1,000 package amount for the getaway person who does not play (either did not want to play or wanted to play but made a booking too late, or failed to show). c. The weight can be artificially inflated by individual product managers setting “high” list unit prices and then being willing to frequently discount these prices. The use of actual unit prices or actual revenue per product in the stand‐alone formula will reduce this problem. d. The weights may change frequently if unit prices are constantly changing. This is not so much a criticism as a reflection that the marketplace may be highly competitive.
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14‐37 (cont’d) The pros of the incremental method include: a. It has the potential to reflect that some products in the bundle are more highly valued than others. Not all products in the bundle have a similar “write‐down” from unit list prices. Ensuring this “potential pro” becomes an “actual pro” requires that the choice of the primary product be guided by reliable evidence on consumer preferences. This is not an easy task. b. Once the sequence is chosen, it is straightforward to implement. The cons of the incremental method include: a. Obtaining the rankings can be highly contentious and place managers in a “no‐win” acrimonious debate. The revenue allocations can be sensitive to the chosen rankings. b. Some products will have zero revenue assigned to them. Consider the Food division. It would incur the costs for the two dinners but receive no revenue.
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CHAPTER 15 COST ALLOCATION: JOINT PRODUCTS AND BYPRODUCTS
SHORT‐ANSWER QUESTIONS
15‐1 Exhibit 15‐2 presents thirteen examples from four different general industries. These include: Industry Separable Products at the Splitoff Point Agriculture: • Lamb • Lamb cuts, tripe, hides, bones, fat • Turkey • Breasts, wings, thighs, poultry meal, etc. Extractive: • Petroleum • Crude oil, natural gas, raw LPG 15‐2 A joint cost is a cost of a production process that yields multiple products simultaneously. A separable cost is a cost incurred beyond the splitoff point that is assignable to each of the specific products identified at the splitoff point. 15‐3 The distinction between a joint product and a byproduct is based on relative sales value. A joint product is a product that has a relatively high sales value. A byproduct is a product that has low sales value compared to the sales value of the joint (or main) products. 15‐4 A product is any output that has a positive sales value (or an output that enables an organization to avoid incurring costs). In some joint cost settings, outputs can occur that do not have a positive sales value. The offshore processing of hydrocarbons yields water that is recycled back into the ocean while yielding oil and gas. The processing of mineral ore to yield gold and silver also yields dirt as an output, which is recycled back into the ground. 15‐5 The chapter lists the following seven reasons for allocating joint costs: 1. Inventory cost and cost‐of‐goods‐sold computations for external financial statements and reports for income tax authorities. 2. Inventory cost and cost‐of‐goods‐sold computations for internal financial reporting. 3. Cost reimbursement under contracts when only a portion of a business’s products or services is sold or delivered to a single customer. 4. Customer profitability analysis where individual customers purchase varying combinations of joint products or byproducts as well as other products of the company. 5. Insurance settlement computations. 6. Rate regulation when one or more of the jointly produced products or services are subject to price regulation. 7. Contract litigation in which costs of joint products are key inputs.
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15‐6 The joint production process yields individual products that are either sold this period or held as inventory to be sold in subsequent periods. Hence the joint costs need to be allocated between total production rather than just those sold this period. 15‐7 This situation can occur when a production process yields separable outputs at the splitoff point that do not have selling prices available until further processing. The result is that selling prices are not available at the splitoff point to use the sales value at splitoff method. Examples include processing in integrated pulp and paper companies and in petro‐chemical operations. 15‐8 Both methods use market selling‐price data in allocating joint costs, but they differ in which sales‐price data they use. The sales value at splitoff method allocates joint costs on the basis of each product’s relative sales value at the splitoff point. The estimated net realizable value method allocates joint costs on the basis of the relative estimated net realizable value (expected final sales value in the ordinary course of business minus the expected separable costs of production and marketing). 15‐9 Limitations of the physical measure method of joint cost allocation include: a. The physical weights used for allocating joint costs may have no relationship to the revenue‐producing power of the individual products. b. The joint products may not have a common physical denominator—for example, one may be a liquid while another a solid with no readily available conversion factor. 15‐10 The estimated NRV method can be simplified by assuming (a) a standard set of post‐splitoff point processing steps and (b) a standard set of selling prices. The use of (a) and (b) achieves the same benefits that the use of standard costs does in costing systems. 15‐11 The constant gross‐margin percentage NRV method takes account of the post‐ splitoff point “profit” contribution earned on individual products, in addition to the joint costs, when making cost assignments to joint products. 15‐12 No. Management teams should select the method that best reflects the economic facts of the production process. Teams also need to do a careful cost/benefit analysis to ensure the method they select is affordable for the benefits received. When a product is an inherent result of a joint process, the decision to process further should not be influenced by either the size of the total joint costs or the portion of the joint costs assigned to particular products. Joint costs are irrelevant for these decisions. The only relevant items for these decisions are the incremental revenue and the incremental costs beyond the splitoff point.
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15‐13 No. The only relevant items are incremental revenues and incremental costs when making decisions about selling products at the splitoff point or processing them further. Separable costs are not always identical to incremental costs. Separable costs are costs incurred beyond the splitoff point that are assignable to individual products. Some separable costs may not be incremental costs in a specific setting (e.g., allocated manufacturing overhead that includes amortization). 15‐14 Two methods to account for byproducts are: a. Production method—recognizes byproducts in the financial statements at the time production is completed. b. Sales method—delays recognition of byproducts until the time of sale.
EXERCISES
15‐15 (10 min.)
Terminology.
Companies provide value‐added to their customers through the sale of more than one product. A product is any output or service that can be sold for a price that recovers the total costs to bring the product to the customer plus some reasonable profit. Some products yield both a main product with the highest sales price, a by product that requires little if any further processing but is sold for a far lower price, and scrap which is usually unused direct materials recovered and sold for almost nothing. Two or more products of sold at a high price are called joint products. The costs of producing more than one product can be common or joint costs plus separable costs to complete each product. The splitoff point determines what pool comprises the joint costs that must be allocated on a reasonable basis. The allocation methods are physical measure, sales value at splitoff, estimated net realizable value, and constant gross margin percentage. The task of the management team is to select the method of joint cost allocation that best represents what actually happened in the physical production process.
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15‐16 (20‐30 min.) Joint cost allocation, insurance settlement. 1. a. Sales value at splitoff method: Wholesale Kg Selling Sales Weighting: of Price Value Sales Value Product per kg at Splitoff at Splitoff Breasts 100 $0.55 $55.00 0.675 Wings 20 0.20 4.00 0.049 Thighs 0.35 14.00 0.172 40 Bones 80 0.10 8.00 0.098 Feathers 10 0.05 0.50 0.006 250 $81.50 1.000
Joint Costs Allocated $33.75 2.45 8.60 4.90 0.30 $50.00
Allocated Costs per kg 0.3375 0.1225 0.2150 0.0613 0.0300
Costs of Destroyed Product Breasts: $0.3375 per kilogram 40 kilograms = $13.50 Wings: $0.1225 per kilogram 15 kilograms = 1.84 $15.34 b. Physical measure method:
Breasts Wings Thighs Bones Feathers
Kg of Product 100 20 40 80 10 250
Weighting: Physical Measures 0.400 0.080 0.160 0.320 0.040 1.000
Joint Costs Allocated $20.00 4.00 8.00 16.00 2.00 $50.00
Costs of Destroyed Product Breast: $0.20 per kilogram 40 kilograms = Wings: $0.20 per kilogram 15 kilograms =
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$ 8 3 $11
Allocated Costs per kg $0.200 0.200 0.200 0.200 0.200
Chapter 15
15‐16 (cont’d) Note: Although not required, it is useful to highlight the individual product profitability figures: Sales Value at Physical Splitoff Method Measures Method Sales Joint Costs Gross Joint Costs Gross Product Value Allocated Income Allocated Income Breasts $55.00 $33.75 $21.25 $20.00 $35.00 Wings 4.00 2.45 1.55 4.00 0.00 Thighs 14.00 8.60 5.40 8.00 6.00 Bones 8.00 4.90 3.10 16.00 (8.00) Feathers 0.50 0.30 0.20 2.00 (1.50) 2. The sales‐value at splitoff method captures the benefits‐received criterion of cost allocation and is the preferred method. The costs of processing a chicken are allocated to products in proportion to the ability to contribute revenue. Quality Chicken’s decision to process chicken is heavily influenced by the revenues from breasts and thighs. The bones provide relatively few benefits to Quality Chicken despite their high physical volume. The physical measures method shows profits on breasts and thighs and losses on bones and feathers. Given that Quality Chicken has to jointly process all the chicken products, it is non‐intuitive to single out individual products that are being processed simultaneously as making losses while the overall operations make a profit. Quality Chicken is processing chicken mainly for breasts and thighs and not for wings, bones, and feathers, while the physical measure method allocates a disproportionate amount of costs to wings, bones, and feathers.
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15‐17 (10 min.) Joint products and byproducts. 1. Ending inventory: Breasts 15 $0.3375 = $5.0625 Wings 4 0.1225 = 0.4900 Thighs 6 0.2150 = 1.2900 Bones 5 0.0613 = 0.3065 Feathers 2 0.0300 = 0.0600 $7.2090 2. Net Realizable Values of Joint products Byproducts Byproducts: Breasts Wings Wings $ 4.00 Thighs Bones Bones 8.00 Feathers Feathers 0.50 $12.50 Joint costs to be allocated: Joint costs – Net realizable values of byproducts = $50 – $12.50 = $37.50
Breast Thighs
Kg Wholesale of Selling Price Product per kg 100 $0.55 40 0.35
Sales Weighting: Value Sales Value at Splitoff at Splitoff $55 55 ÷ 69 14 14 ÷ 69 $ 69
Joint Allocated Costs Costs Per Allocated kg $29.89 $0.2989 7.61 0.1903 $37.50
Ending inventory: Breasts 15 $0.2989 Thighs 6 0.1903
$4.4835 1.1418 $5.6253
3. Treating all products as joint products does not require judgments as to whether a product is a joint product or a byproduct. Joint costs are allocated in a consistent manner to all products for the purpose of costing and inventory valuation. In contrast, the approach in requirement 2 lowers the joint cost by the amount of byproduct net realizable values and results in inventory values being shown for only two of the five products, the ones (perhaps arbitrarily) designated as being joint products.
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15‐18 (40‐60 min.) Usefulness of joint cost allocation. 1. a. Sales value at splitoff method: Chocolate‐ Powder Liquor Base Sales value at splitoff, 200a × $25.20*; 300b $31.20 $5,040 Weighting Allocation of joint costs, 0.35 $12,000; 0.65 $12,000
Milk‐ Chocolate Liquor Base $9,360
$5, 040 0.35 $14, 400
$9,360 0.65 $14,400
$4,200
$7,800
b(3,400/340) 30 (2,000/200) 20 * [=] per container 0 [=] kg/20 containers [=] containers 02 [=] kg/30 containers b. Physical‐measure method: Chocolate‐ Milk‐ Powder Chocolate Liquor Base Liquor Base 200 (10 20) 4‐litre containers 300 (10 30) 4‐litre containers 200 4‐litre 300 4‐litre containers containers
Total $14,400
$12,000
a
Weighting Allocation of joint costs, 0.40 $12,000; 0.60 $12,000
200 0.40 500
300 0.60 500
$4,800
$7,200
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Total 500 4‐litre containers
$12,000
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15‐18 (cont’d) c.
Estimated net realizable value method: Chocolate‐ Milk‐ Powder Chocolate Liquor Base Liquor Base Expected sales value of production, 2,000 $4.80; 3,400 $6.00 $9,600 $20,400 Deduct expected separable cost of further processing 5,100* 10,500* Estimated net realizable value at splitoff point $4,500 $ 9,900 Weighting Allocation of joint costs, 0.3125 $12,000; 0.6875 $12,000
$4, 500 0.3125 $14, 400
$3,750
Total
$30,000 15,600 $14,400
$9, 900 0.6875 $14, 400
$8,250
$12,000
* Given
d. Constant gross‐margin percentage NRV method: Step 1: Total final sales value of production, (2,000 $4.80) + (3,400 $6.00) $30,000 Deduct joint and separable costs, ($12,000 + $5,100 + $10,500) 27,600 Gross margin $ 2,400 Gross‐margin percentage ($2,400 ÷ $30,000) 8% Step 2: Chocolate‐ Milk‐ Powder Chocolate Liquor Base Liquor Base Total Expected final sales value of production (2,000 $4.80); (3,400 $6.00) $9,600 $20,400 $30,000 Deduct gross margin, using overall gross‐margin percentage of sales (8%) 768 1,632 2,400 Cost of goods sold 8,832 18,768 27,600 15–708
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Chapter 15
15‐18 (cont’d)
Step 3: Deduct separable cost of further processing 5,100 Joint costs allocated $3,732 2. Chocolate‐ Powder Liquor Base a. Sales $9,600 Joint costs 4,200 Separable costs 5,100 Total costs 9,300 Gross margin $ 300 Gross margin percentage 3.125% b. Sales $9,600 Joint costs 4,800 Separable costs 5,100 Total costs 9,900 Gross margin $ (300) Gross‐margin percentage (3.125)% c. Sales $9,600 Joint costs 3,750 Separable costs 5,100 Total costs 8,850 Gross margin $ 750 Gross‐margin percentage 7.812% d. Sales $9,600 Joint costs 3,732 Separable costs 5,100 Total costs 8,832 Gross margin $ 768 Gross‐margin percentage 8%
10,500 $8,268
Milk‐ Chocolate Liquor Base $20,400 7,800 10,500 18,300 $ 2,100
15,600 $12,000
Total $30,000 12,000 15,600 27,600 $ 2,400
10.294%
8%
$20,400 7,200 10,500 17,700 $ 2,700
$30,000 12,000 15,600 27,600 $ 2,400
13.235%
8%
$20,400 8,250 10,500 18,750 $ 1,650
$30,000 12,000 15,600 27,600 $ 2,400
8.088%
8%
$20,400 8,268 10,500 18,768 $ 1,632
$30,000 12,000 15,600 27,600 $ 2,400
8%
8%
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15‐18 (cont’d) 3.
Further processing of chocolate‐powder liquor base into chocolate powder: $4,560 Incremental revenue, $9,600 – $5,0401 Incremental costs 5,100 Incremental operating income from further processing $ (540) Further processing of milk‐chocolate liquor base into milk chocolate: Incremental revenue, $20,400 – $9,3602 $11,040 Incremental costs 10,500 Incremental operating income from further processing $ 540 Roundtree Chocolates could increase operating income by $540 (to $2,940) if chocolate‐powder liquor base is sold at the splitoff point and if milk‐chocolate liquor base is further processed into milk chocolate. 1 Sales value at splitoff = $5,040 (chocolate‐powder liquor) 2 Sales value at splitoff = $9,360 (milk chocolate liquor)
15‐19 (40 min.) Irrelevance of joint costs. A diagram of the situation is in Solution Exhibit 15‐19. 1. Methanol Physical measure of total production (litres) 10,000 10, 000 0.25 40, 000
Weighting
Joint costs allocated, M, 0.25 $144,000; T, 0.75 $144,000
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$36,000
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Turpentine 30,000
Total 40,000
30, 000 0.75 40, 000
$108,000
$144,000
Chapter 15
15‐19 (cont’d) 2. Methanol
Final sales value of total production, M, 10,000 $6.30; T, 30,000 $4.20 Deduct separable costs to complete and sell, M, 10,000 $0.90; T, 30,000 $0.60 Net realizable value at splitoff point
Weighting
3.
Joint costs allocated, M, 1/3 $144,000; T, 2/3 $144,000
Turpentine
Total
$63,000
$126,000
$189,000
9,000
18,000
27,000
$54,000
$108,000
$162,000
$54, 000 1 162, 000 3
$108, 000 2 162, 000 3
$48,000
$96,000
$144,000
a. Physical‐measure (litres) method: Methanol $63,000
Revenues Cost of goods sold: Joint costs (25%; 75% × $144,000) 36,000 Separable costs 9,000 Total costs 45,000 Gross margin $18,000
Turpentine $126,000
Total $189,000
108,000 18,000 126,000 $ 0
144,000 27,000 171,000 $ 18,000
Turpentine $126,000
Total $189,000
96,000 18,000 114,000 $ 12,000
144,000 27,000 171,000 $ 18,000
b. Estimated net realizable value method:
Revenues Cost of goods sold: Joint costs Separable costs Total costs Gross margin
Methanol $63,000 48,000 9,000 57,000 $ 6,000
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15‐19 (cont’d) 4. Lab Ethanol Final sales value of total production, Lab ethanol, 10,000 $18.00; T, 30,000 $4.20 Deduct separable costs to complete and sell, Lab ethanol, 10,000 $3.60* + (0.20 $180,000); T, 30,000 $0.60 Net realizable value at splitoff point
Weighting Joint costs allocated, Lab ethanol, 0.5 $144,000; T, 0.5 $144,000
Turpentine
Total
$180,000
$126,000
$306,000
72,000 $108,000
18,000 $108,000
90,000 $216,000
$108, 000 0.50 $216, 000
$108, 000 0.50 $216, 000
$ 72,000
$ 72,000
$144,000
* $2.70 + $0.90
An incremental approach demonstrates that the company should use the new process: Incremental revenue, ($18.00 – $6.30) 10,000 Incremental costs: Added processing, $2.70 10,000 Taxes, (0.20 $18.00) 10,000 Incremental operating income from further processing
$117,000
$27,000 36,000
63,000
$ 54,000
Proof:
Total sales of both products Joint costs Separable costs Cost of goods sold New gross margin Old gross margin Difference in gross margin
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$306,000 144,000 90,000 234,000 72,000 18,000 $ 54,000
Chapter 15
SOLUTION EXHIBIT 15‐19
15‐20 (20 min.) Joint cost allocation: sell immediately or process further. 1.
a. Sales value at splitoff method:
Sales value of total production at splitoff, 500lbs × $1; 100 gallons × $4 Weighting, $500; $400 $900 Joint costs allocated, 0.556; 0.444 $500 b. Net realizable value method: Final sales value of total production, 600lbs × $2; 400qts × $1.25 Deduct separable costs Net realizable value Weighting, $900; $300 $1,200 Joint costs allocated, 0.75; 0.25 $500
Cookies/ Soymeal
Soyola/ Soy Oil
Total
$500 0.556
$400 0.444
$900
$278
$222
$500
Cookies
Soyola
$1,200 300 $ 900 0.75 $ 375
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$500 200 $300 0.25 $125
Total $1,700 500 $1,200 $ 500
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15‐20 (cont’d) 2. Revenue if sold at splitoff Process further NRV Profit (Loss) from processing further
Cookies/Soy Meal $500a 900 c $400
Soyola/Soy Oil $ 400 b 300 d $(100)
500 lbs × $1 = $500 100 gal × $4 = $400 c 600 lbs × $2 – $300 = $900 d 400 qts × $1.25 – $200 = $300 ISP should process the soy meal into cookies because it increases profit by $400 (900‐500). However, they should sell the soy oil as is, without processing it into the form of Soyola, because profit will be $100 (400‐300) higher if they do. Since the total joint cost is the same under both allocation methods, it is not a relevant cost to the decision to sell at splitoff or process further. a
b
15‐21 (10 min.) Net realizable value method. A diagram of the situation is in Solution Exhibit 15‐21. Corn Syrup Final sales value of total production, $625,000 12,500 $50; 6,250 $25 Deduct separable costs 375,000 Net realizable value at splitoff point $250,000 Weighting, $250,000; $62,500 $312,500 0.8 Joint costs allocated, 0.8; 0.2 $325,000 $260,000
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Corn Starch $156,250 93,750 $ 62,500 0.2 $ 65,000
Total $781,250 468,750 $312,500 $325,000
Chapter 15
SOLUTION EXHIBIT 15‐21 (all numbers are in thousands) Separable Costs Joint Costs
Processing $375,000
Corn Syrup: 12,500 cases at $50 per case
Processing $93,750
Corn Starch: 6,250 cases at $25 per case
Processing $325000
Splitoff Point
15‐22 (30 min.) Joint cost allocation, sales value, physical measure, NRV methods. 1.
a.
PANEL A: Allocation of Joint Costs Using Sales Value at Splitoff Method Sales value of total production at splitoff point (10,000 tonnes $10 per tonne; 20,000 $15 per tonne) Weighting ($100,000; $300,000 ÷ $400,000) Joint costs allocated (25; 0.75 $240,000) PANEL B: Product‐Line Income Statement for June 2013 Revenues (12,000 tonnes $18 per tonne; 24,000 $25 per tonne) Deduct joint costs allocated (from Panel A) Deduct separable costs Gross margin Gross margin percentage
Special B/ Special S/ Beef Shrimp Ramen Ramen Total $100,000 $300,000 $400,000 0.25 0.75 $60,000 $180,000 $240,000 Special B Special S Total $216,000 $600,000 $816,000 60,000 180,000 240,000 168,000 216,000 48,000 $108,000 $252,000 $360,000 50% 42% 44%
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15‐22 (cont’d) 1. b. PANEL A: Allocation of Joint Costs Using Physical‐ Measure Method Physical measure of total production (tonnes) Weighting (10,000 tonnes; 20,000 tonnes ÷ 30,000 tonnes) Joint costs allocated (0.33 $240,000; 0.67 $240,000) PANEL B: Product‐Line Income Statement for June 2013 Revenues (12,000 tonnes $18 per tonne; 24,000 $25 per tonne) Deduct joint costs allocated (from Panel A) Deduct separable costs Gross margin Gross margin percentage
Special B/ Beef Ramen 10,000 33% $79,200
Special S/ Shrimp Ramen 20,000 67% $160,800
Total 30,000 $240,000
Special B Special S Total $216,000 $600,000 $816,000 79,200 160,800 240,000 168,000 216,000 48,000 $ 88,800 $271,200 $360,000 41% 45% 44%
1. c. PANEL A: Allocation of Joint Costs Using Net Realizable Value Method Special B Special S Total Final sales value of total production during accounting period (12,000 tonnes $18 per tonne; 24,000 tonnes $25 per tonne) $216,000 $600,000 $816,000 Deduct separable costs 48,000 168,000 216,000 Net realizable value at splitoff point $168,000 $432,000 $600,000 Weighting ($168,000; $432,000 ÷ $600,000) 28% 72% $67,200 $172,800 $240,000 Joint costs allocated (0.28; 0.72 $240,000) PANEL B: Product‐Line Income Statement for June 2013 Special B Special S Total Revenues (12,000 tonnes $18 per tonne; 24,000 tonnes $25 per tonne) $216,000 $600,000 $816,000 Deduct joint costs allocated (from Panel A) 67,200 172,800 240,000 Deduct separable costs 48,000 168,000 216,000 Gross margin $100,800 $259,200 $360,000 Gross margin percentage 46.7% 43.2% 44.1%
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Chapter 15
15‐22 (cont’d) 2.
Sherrie Dong probably performed the analysis shown below to arrive at the net loss of $2,228 from marketing the stock:
PANEL A: Allocation of Joint Costs Using Sales Value at Splitoff Sales value of total production at splitoff point (10,000 tonnes $10 per tonne; 20,000 $15 per tonne; 4,000 $5 per tonne) Weighting ($100,000; $300,000; $20,000 ÷ $420,000) Joint costs allocated (0.238095; 0.714286; 0.047619 $240,000) PANEL B: Product‐Line Income Statement for June 2009 Revenues (12,000 tonnes $18 per tonne; 24,000 $25 per tonne; 4,000 $5 per tonne) Separable processing costs Joint costs allocated (from Panel A) Gross margin Deduct marketing costs Operating income
Special B/ Beef Ramen
Special S/ Shrimp Ramen Stock
$100,000
$300,000
23.8095%
71.4286%
$20,000 4.7619%
$57,143
$171,429
$11,428
Special B Special S $216,000 48,000 57,143 $110,857
$600,000 168,000 171,429 $260,571
Stock $20,000 0 11,428 8,572 10,800 $ (2,228)
Total $420,000 100% $240,000
Total $836,000 216,000 240,000 380,000 10,800 $369,200
In this (misleading) analysis, the $240,000 of joint costs are re‐allocated between Special B, Special S, and the stock. Irrespective of the method of allocation, this analysis is wrong. Joint costs are always irrelevant in a process‐further decision. Only incremental costs and revenues past the splitoff point are relevant. In this case, the correct analysis is much simpler: the incremental revenues from selling the stock are $20,000, and the incremental costs are the marketing costs of $10,800. So, Instant Foods should sell the stock—this will increase its operating income by $9,200 ($20,000 – $10,800).
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15‐23 (30 min.)
Joint cost allocation, process further.
Joint Costs = $1800
ICR8 (Non-Saleable)
Processing $175
Crude Oil 150 bbls × $18 / bbl = $2700
ING4 (Non-Saleable)
Processing $105
NGL 50 bbls × $15 / bbl = $750
XGE3 (Non-Saleable)
Processing $210
Gas 800 eqvt bbls × $1.30 / eqvt bbl = $1040
Splitoff Point
1a. Physical Measure Method: 1. Physical measure of total prodn. 2. Weighting (150; 50; 800 ÷ 1,000) 3. Joint costs allocated (weights $1,800) 1b. NRV Method 1. Final sales value of total production 2. Deduct separable costs 3. NRV at splitoff 4. Weighting (2,525; 645; 830 ÷ 4,000) 5. Joint costs allocated (weights $1,800)
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Crude Oil NGL Gas 150 50 800 0.15 0.05 0.80 $270 $90 $1,440
Total 1,000 1.00 $1,800
Crude Oil $2,700 175 $2,525 0.63125 $1,136.25
Total $4,490 490 $4,000 $1,800
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NGL $750 105 $645 0.16125 $290.25
Gas $1,040 210 $ 830 0.20750 $373.50
Chapter 15
15‐23 (cont’d) 2. The operating income amounts for each product using each method is: a. Physical Measure Method Crude Oil NGL Gas Revenues $2,700 $750 $1,040 Cost of goods sold Joint costs 270 90 1,440 Separable costs 175 105 210 Total cost of goods sold 445 195 1,650 Gross margin $2,255 $555 $ (610) b. NRV Method Crude Oil NGL Gas Revenues $2,700.00 $750.00 $1,040.00 Cost of goods sold Joint costs 1,136.25 290.25 373.50 Separable costs 175.00 105.00 210.00 Total cost of goods sold 1,311.25 395.25 583.50 Gross margin $1,388.75 $354.75 $ 456.50 3.
4.
Total $4,490 1,800 490 2,290 $2,200
Total $4,490.00 1,800.00 490.00 2,290.00 $2,200.00
Neither method should be used for product emphasis decisions. It is inappropriate to use joint cost‐allocated data to make decisions regarding dropping individual products, or pushing individual products, as they are joint by definition. Product‐ emphasis decisions should be made based on relevant revenues and relevant costs. Each method can lead to product emphasis decisions that do not lead to maximization of operating income. Since crude oil is the only product subject to taxation, it is clearly in Sinclair’s best interest to use the NRV method since it leads to a lower profit for crude oil and, consequently, a smaller tax burden. A letter to the taxation authorities could stress the conceptual superiority of the NRV method. Chapter 15 argues that, using a benefits‐received cost allocation criterion, market‐based joint cost allocation methods are preferable to physical‐measure methods. A meaningful common denominator (revenues) is available when the sales value at splitoff point method or NRV method is used. The physical‐measures method requires nonhomogeneous products (liquids and gases) to be converted to a common denominator.
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15‐24 (40 min.) Alternative methods of joint cost allocation, ending inventories. Total production for the year was: Ending Total Sold Inventories Production X 120 180 300 Y 340 60 400 Z 475 25 500 A diagram of the situation is in Solution Exhibit 15‐24. 1. a. Net realizable value (NRV) method: X Y Z Total Final sales value of total production, $350,000 $1,200,000 300 $1,500; 400 $1,000; 500 $700 $450,000 $400,000 Deduct separable costs –– –– 200,000 200,000 Net realizable value at splitoff point $450,000 $400,000 $150,000 $1,000,000 Weighting, $450; $400; $150 $1,000 0.45 0.40 0.15 Joint costs allocated, 0.45, 0.40, 0.15 $400,000 $180,000 $160,000 $ 60,000 $ 400,000 Ending Inventory Percentages: X Y Z Ending inventory 180 60 25 Total production 300 400 500 Ending inventory percentage 60% 15% 5%
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Chapter 15
15‐24 (cont’d) Income Statement X Y Z Total Revenues, $332,500 $852,500 120 $1,500; 340 $1,000; 475 $700 $180,000 $340,000 Cost of goods sold: Joint costs allocated 180,000 160,000 60,000 400,000 Separable costs –– –– 200,000 200,000 Production costs 180,000 160,000 260,000 600,000 Deduct ending inventory, 60%; 15%; 5% of production costs 108,000 24,000 13,000 145,000 247,000 455,000 Cost of goods sold 72,000 136,000 Gross margin $108,000 $204,000 $ 85,500 $397,500 Gross‐margin percentage 60% 60% 25.71% b. Constant gross‐margin percentage NRV method: Step 1: Final sales value of prodn., (300 $1,500) + (400 $1,000) + (500 $700) $1,200,000 Deduct joint and separable costs, $400,000 + $200,000 600,000 Gross margin $ 600,000 Gross‐margin percentage, $600,000 ÷ $1,200,000 50% Step 2: X Y Z Total Final sales value of total production, 300 $1,500; 400 $1,000; 500 $700 $450,000 $400,000 $350,000 $1,200,000 Deduct gross margin, using overall 200,000 175,000 600,000 gross‐margin percentage of sales, 50% 225,000 Total production costs 225,000 200,000 175,000 600,000 Step 3: Deduct separable costs — — 200,000 200,000 Joint costs allocated $225,000 $200,000 $(25,000) $ 400,000
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15‐24 (cont’d) The negative joint cost allocation to Product Z illustrates one “unusual” feature of the constant gross‐margin percentage NRV method: some products may receive negative cost allocations so that all individual products have the same gross‐margin percentage. Income Statement Revenues, 120 $1,500; 340 $1,000; 475 $700 Cost of goods sold: Joint costs allocated Separable costs Production costs Deduct ending inventory, 60%; 15%; 5% of production costs Cost of goods sold Gross margin Gross‐margin percentage Summary a. NRV method: Inventories on balance sheet Cost of goods sold on income statement b. Constant gross‐margin percentage NRV method Inventories on balance sheet Cost of goods sold on income statement
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X
Y
$180,000
$340,000
$332,500 $852,500
225,000 ‐ 225,000
200,000 ‐ 200,000
(25,000) 200,000 175,000
135,000 90,000 $ 90,000 50%
30,000 170,000 $170,000 50%
8,750 173,750 166,250 426,250 $166,250 $426,250 50% 50%
X
Y
$108,000 72,000
$ 24,000 136,000
$ 13,000 $145,000 247,000 455,000 $600,000
$135,000 90,000
$ 30,000 170,000
$ 8,750 $173,750 166,250 426,250 $600,000
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Z
Z
Total
400,000 200,000 600,000
Total
Chapter 15
15‐24 (cont’d) 2. Gross‐margin percentages: NRV method Constant gross‐margin percentage NRV SOLUTION EXHIBIT 15‐24
X 60% 50%
Y 60% 50%
Z 25.71% 50.00%
Separable Costs
Joint Costs
Product X: 300 tons at $1,500 per tonne Joint Processing Costs $400,000
Product Y: 400 tons at $1,000 per tonne
Processing $200000 Splitoff Point
Product Z: 500 tonnes at $700 per tonne
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15‐25 (40 min.) 1.
Process further or sell, byproduct.
The analysis shown below indicates that it would be more profitable for Newcastle Mining Company to continue to sell bulk raw coal without further processing. This analysis ignores any value related to coal fines. It also assumes that the costs of loading and shipping the bulk raw coal on river barges will be the same whether Newcastle sells the bulk raw coal directly or processes it further.
Incremental sales revenues: Sales revenue after further processing (9,400,000a tonnes $36) Sales revenue from bulk raw coal (10,000,000 tonnes $27) Incremental sales revenue Incremental costs: Direct labour Supervisory personnel Heavy equipment costs ($25,000 12 months) Sizing and cleaning (10,000,000 tonnes $3.50) Outbound rail freight (9,400,000 tonnes 60 tonnes) $240 per car Incremental costs Incremental gain (loss)
$338,400,000 270,000,000 68,400,000 800,000 200,000 300,000 35,000,000 37,600,000 73,900,000 $ (5,500,000)
10,000,000 tonnes (1– 0.06)
a
2.
3.
The cost of producing the raw coal is irrelevant to the decision to process further or not. As we see from requirement 1, the cost of producing raw coal does not enter any of the calculations related to either the incremental revenues or the incremental costs of further processing. The answer would the same as in requirement 1: do not process further. The analysis shown below indicates that the potential revenue from the coal fines byproduct would result in additional revenue, ranging between $4,950,000 and $9,900,000, depending on the market price of the fines.
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Chapter 15
15‐25 (cont’d)
Coal fines = 75% of 6% of raw bulk tonnage = 0.75 (10,000,000 .06) = 450,000 tonnes Potential incremental income from preparing and selling the coal fines: Minimum Maximum Incremental income per tonne $11 ($15 – $4) $22 ($24 – $2) (Market price – Incremental costs) Incremental income ($11; $22 450,000) $4,950,000 $9,900,000
The incremental loss from sizing and cleaning the raw coal is $5,500,000, as calculated in requirement 1. Analysis indicates that relative to selling bulk raw coal, the effect of further processing and selling coal fines is only slightly negative at the minimum incremental gain ($4,950,000 – $5,500,000 = – $550,000) and very beneficial at the maximum incremental gain ($9,900,000 – $5,500,000 = $4,400,000). NMC will benefit from further processing and selling the coal fines as long as its incremental income per tonne of coal fines is at least $12.22 ($5,500,000 450,000 tonnes). Hence, further processing is preferred. Note that other than the financial implications, some factors that should be considered in evaluating a sell‐or‐process‐further decision include: Stability of the current customer market for raw coal and how it compares to the market for sized and cleaned coal. Storage space needed for the coal fines until they are sold and the handling costs of coal fines. Reliability of cost (e.g., rail freight rates) and revenue estimates, and the risk of depending on these estimates. Timing of the revenue stream from coal fines and impact on the need for liquidity. Possible environmental problems, i.e., dumping of waste and smoke from unprocessed coal.
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15‐26 (30 min.)
Accounting for a main product and a byproduct.
1.
Revenues Main product Byproduct Total revenues Cost of goods sold Total manufacturing costs Deduct value of byproduct production Net manufacturing costs Deduct main product inventory Cost of goods sold Gross margin
32,000 $20.00 8,000 $5.00 c (8,000/40,000) × $440,000 = $88,000
b
Production Method
Sales Method
$640,000 —__ 640,000
$640,000 28,000d 668,000
480,000 40,000b 440,000 88,000c 352,000 $288,000
480,000 0 480,000 96,000e 384,000 $284,000
a
5,600 $5.00 (8,000/40,000) × $480,000 = $96,000
d e
2.
Main Product Byproduct
Production Method $88,000 12,000a
Sales Method $96,000 0
a Ending inventory shown at unrealized selling price. BI + Production – Sales = EI 0 + 8,000 – 5,600 = 2,400 kilograms Ending inventory = 2,400 kilograms $5 per kilogram = $12,000
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Chapter 15
15‐27 (35‐45 min.) Joint costs and byproducts. 1.
Computing byproduct deduction to joint costs: Revenues from C, 20,000 $3 Deduct: Gross margin, 10% of revenues Marketing costs, 25% of revenues Peanut Butter Department separable costs Net realizable value (less gross margin) of C Joint costs Deduct byproduct contribution Net joint costs to be allocated
$ 60,000 6,000 15,000 10,000 $ 29,000 $160,000 29,000 $131,000
Deduct Net Unit Final Separable Realizable Allocation of Sales Sales Processing Value at $131,000 Quantity Price Value Cost Splitoff Weighting Joint Costs A 10,000 $10 $100,000 $20,000 $ 80,000 40% $ 52,400 120,000 60% 78,600 B 60,000 2 120,000 –– $20,000 $200,000 $131,000 Totals $220,000 Add Separable Joint Costs Processing Allocation Costs Total Costs Units Unit Cost A $ 52,400 $20,000 $ 72,400 10,000 $7.24 B 78,600 –– 78,600 60,000 1.31 $20,000 $151,000 70,000 Totals $131,000
Unit cost for C: $1.45 ($29,000 ÷ 20,000) + $0.50 ($10,000 ÷ 20,000) = $1.95, or $3.00 – $0.30 (10% $3) – $0.75 (25% $3) = $1.95.
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15‐27 (cont’d) 2.
If all three products are treated as joint products:
A B C Totals
Unit Sales Quantity Price 10,000 $10 60,000 2 20,000 3
Final Sales Value $100,000 120,000 60,000 $280,000
Deduct Net Separable Realizable Processing Value at Cost Splitoff $20,000 $ 80,000 120,000 ─ 25,000* 35,000 $45,000 $235,000
Allocation of $160,000 Weighting Joint Costs 80 ÷ 235 $ 54,468 120 ÷ 235 81,702 35 ÷ 235 23,830 $160,000
* $10,000 separable processing costs + $15,000 marketing costs = $25,000 Add Separable Joint Costs Processing Allocation Costs Total Costs Units A $ 54,468 $20,000 $ 74,468 10,000 B 81,702 –– 81,702 60,000 25,000 48,830 20,000 C 23,830 $45,000 $205,000 90,000 Totals $160,000
Unit Cost $7.45 1.36 2.44
Call the attention of students to the different unit “costs” resulting from the two assumptions about the relative importance of Product C. The point is that costs of individual products depend heavily on which assumptions are made and which accounting methods and techniques are used.
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Chapter 15
15‐28 (20 min.) Byproduct, disposal costs, governance. 1.
2.
The comparative analysis prepared by the cost accountant is flawed. In the process further alternative, he has erroneously included the $300,000 allocated joint costs. Allocated joint costs are irrelevant because they are not incremental costs of the alternative being considered. If the joint costs allocated are taken out, it becomes clear that financially it would be to the advantage of the company to process further the product as it would increase the operating income by $180,000 [$600,000 – ($360,000 + $60,000)]. Furthermore, the dumping alternative does not consider potential future costs that may arise from environmental liabilities. It appears that there would be no legal ramifications if the company decided to dump the hazardous product into the Gulf. The country either may have no laws against such dumping, or even if they exist, they are not enforced in accordance with the government policy. A more important consideration, however, is the ethical implications. To knowingly dump a hazardous material into the Gulf would certainly result in water pollution. This is an unacceptable action from a societal standpoint. It is important to remember that an act that does not violate any laws is not necessarily an ethical act. Ethical considerations go beyond legal considerations. In different parts of the world, legal systems are imperfect and not comprehensive. It is the responsibility of top management to take a broader, societal view when making decisions. In other words, a business should take its social responsibility seriously, by making it an integral part of the decision‐making process. In the long run it is in the best interest of all stakeholders as well as the business itself.
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15‐29 (30 min.) Joint cost allocation, process further or sell. A diagram of the situation is in Solution Exhibit 15‐29. 1. a. Sales value at splitoff method:
Studs (Building) Decorative Pieces Posts Totals
Monthly Unit Output 75,000 5,000 20,000
Selling Price Per Unit $ 8 60
Sales Value of Total Prodn. at Splitoff $ 600,000 300,000
20
400,000 $1,300,000
Weighting 46.1539% 23.0769
Joint Costs Allocated $ 461,539 230,769
30.7692 100.0000%
307,692 $1,000,000
Weighting
b. Physical measure method:
Physical Measure of Total Prodn.
Studs (Building) Decorative Pieces Posts Totals
75,000 5,000
75.00% 5.00
Joint Costs Allocated $ 750,000 50,000
20,000 100,000
20.00 100.00%
200,000 $1,000,000
Net Realizable Value at Splitoff $ 600,000
c. Net realizable value method:
Studs (Building) Decorative Pieces Posts Totals
Monthly Units of Total Prodn. 75,000 4,500a 20,000
Fully Processed Selling Price per Unit $ 8 100 20
350,000b 400,000 $1,350,000
Weighting 44.4445%
Joint Costs Allocated $ 444,445
25.9259 29.6296 100.0000%
259,259 296,296 $1,000,000
5,000 monthly units of output – 10% normal spoilage = 4,500 good units. 4,500 good units $100 = $450,000 – Further processing costs of $100,000 = $350,000
a
b
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Chapter 15
15‐29 (cont’d) 2.
Presented below is an analysis for Sonimad Sawmill, Inc., comparing the processing of decorative pieces further versus selling the rough‐cut product immediately at splitoff: Units Dollars Monthly unit output 5,000 Less: Normal further processing shrinkage 500 Units available for sale 4,500 $450,000 Final sales value (4,500 units $100 per unit) Less: Sales value at splitoff 300,000 Incremental revenue 150,000 Less: Further processing costs 100,000 Additional contribution from further $ 50,000 processing
3. Assuming Sonimad Sawmill, Inc. announces that in six months it will sell the rough‐ cut product at splitoff due to increasing competitive pressure, behaviour that may be demonstrated by the skilled labour in the planing and sizing process include the following: • lower quality, • reduced motivation and morale, and • job insecurity, leading to nonproductive employee time looking for jobs elsewhere. Management actions that could improve this behaviour include the following: • Improve communication by giving the workers a more comprehensive explanation as to the reason for the change so they can better understand the situation and bring out a plan for future operation of the rest of the plant. • Offer incentive bonuses to maintain quality and production and align rewards with goals. • Provide job relocation and internal job transfers.
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SOLUTION EXHIBIT 15‐29 Joint Costs $1,000,000
Separable Costs
Studs $8 per unit
Processing
Raw Decorative Pieces $60 per unit
Posts $20 per unit Splitoff Point
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Processing $100000
Decorative Pieces $100 per unit
Chapter 15
PROBLEMS
15‐30 (30 min.) Accounting for byproducts.
1. Byproduct Accounting Method A B When byproducts are recognized At Production At Sale in the general ledger Where byproduct revenues Reduction of cost Revenue item appear in income statement Revenues: Main product: Rainbow Dew, $192,000 $192,000 8,000 $24.00 Byproduct: Resi‐Dew, 1,400 $2.40 — 3,360 192,000 195,360 Cost of goods sold: Total manufacturing costs 144,000 144,000 Deduct byproduct sales value, 3,360 — 2,000 $2.40 Net manufacturing costs 140,640 144,000 Deduct main product inventory, 2,000/10,000 net manufacturing costs 28,128 28,800 Cost of goods sold 112,512 115,200 Gross margin $ 79,488 $ 80,160 Gross margin percentage 41.40% 41.03% 2. Inventoriable costs (Sept. 30): $28,800 Main product—Rainbow Dew $28,128 0 Byproduct—Resi‐Dew 1,440a a 600 $2.40 = $1,440 Under method B there is no inventoriable cost shown for the byproduct (Resi‐Dew), as byproducts are not recognized in the general ledger until sales are made. This problem is based on an example in C. Cheatham and M. Green, “Teaching Accounting for Byproducts,” Management Accounting News & Views (1988), pp. 14‐15. 3. Method A results in a better matching of costs with revenues than does Method B.
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15‐31 (40 min.) Alternative methods of joint cost allocation, product‐mix decisions. A diagram of the situation is in Solution Exhibit 15‐31. 1. Computation of joint cost allocation proportions: a. Sales Value of Total Production Allocation of $100,000 at Splitoff Weighting Joint Costs A $ 50,000 50 ÷ 200 = 0.25 $ 25,000 B 30,000 30 ÷ 200 = 0.15 15,000 C 50,000 50 ÷ 200 = 0.25 25,000 D 70,000 70 ÷ 200 = 0.35 35,000 $200,000 1.00 $100,000 b. Physical Measure Allocation of $100,000 of Total Production Weighting Joint Costs A 300,000 litres 300 ÷ 500 = 0.60 $ 60,000 B 100,000 litres 100 ÷ 500 = 0.20 20,000 C 50,000 litres 50 ÷ 500 = 0.10 10,000 D 50,000 litres 50 ÷ 500 = 0.10 10,000 500,000 litres 1.00 $100,000 c. Final Sales Net Value of Realizable Allocation of Total Separable Value at $100,000 Production Costs Splitoff Weighting Joint Costs Super A $300,000 $200,000 $100,000 100 ÷ 200 = 0.50 $ 50,000 Super B 100,000 80,000 20,000 20 ÷ 200 = 0.10 10,000 C 50,000 – 50,000 50 ÷ 200 = 0.25 25,000 Super D 120,000 90,000 30,000 30 ÷ 200 = 0.15 15,000 $200,000 1.00 $100,000
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15‐31 (cont’d) Computation of gross‐margin percentages: a. Sales value at splitoff method: Super A Super B C Super D Total Revenues $300,000 $100,000 $50,000 $120,000 $570,000 Joint costs 25,000 15,000 25,000 35,000 100,000 0 90,000 370,000 Separable costs 200,000 80,000 Total cost of goods sold 225,000 95,000 25,000 125,000 470,000 Gross margin $ 75,000 $ 5,000 $25,000 $ (5,000) $100,000 Gross‐margin percentage 25% 5% 50% (4.17%) 17.54% b. Physical‐measure method: Super A Super B C Super D Total Revenues $300,000 $100,000 $50,000 $120,000 $570,000 Joint costs 60,000 20,000 10,000 10,000 100,000 Separable costs 200,000 80,000 0 90,000 370,000 Total cost of goods sold 260,000 100,000 10,000 100,000 470,000 Gross margin $ 40,000 $ 0 $40,000 $ 20,000 $100,000 Gross‐margin 13.33% 0% 80% 16.67% 17.54% percentage c. Net realizable value method: C Super D Total Super A Super B Revenues $300,000 $100,000 $50,000 $120,000 $570,000 Joint costs 50,000 10,000 25,000 15,000 100,000 Separable costs 200,000 80,000 0 90,000 370,000 Total cost of goods sold 250,000 90,000 25,000 105,000 470,000 Gross margin $ 50,000 $ 10,000 $25,000 $ 15,000 $100,000 10% 50% 12.5% 17.54% Gross‐margin 16.67% percentage
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15‐31 (cont’d) Summary of gross‐margin percentages: Joint cost Allocation Method Super A Super B C Super D Sales value at splitoff 25.00% 5% 50% (4.17)% Physical measure 13.33% 0% 80% 16.67% Net realizable value 16.67% 10% 50% 12.50% 2. Further Processing of A into Super A: Incremental revenue, $300,000 – $50,000 $250,000 Incremental costs 200,000 Incremental operating income from further processing $ 50,000 Further processing of B into Super B: Incremental revenue, $100,000 – $30,000 $ 70,000 Incremental costs 80,000 Incremental operating loss from further processing $ (10,000) Further Processing of D into Super D: Incremental revenue, $120,000 – $70,000 $ 50,000 Incremental costs 90,000 Incremental operating loss from further processing $ (40,000) Operating income can be increased by $50,000 if both B and D are sold at their splitoff point rather than processed further into Super B and Super D.
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SOLUTION EXHIBIT 15‐31
Revenues at Splitoff and Separable Costs
Joint Costs
gallons A, 300000 litres Revenue = $50000 B, 100000 litres gallons Revenue = $30000 Processing $100000
Processing $200000
Super A $300000
Processing $80000
Super B $100000
Processing $90000
Super D $120000
C, 50000 litres gallons Revenue = $50000 D, 50000 litres gallons Revenue = $70000
Splitoff Point
15‐32 (25 min.) Joint cost allocation, relevant costs (R. Capettini, adapted). 1.
2.
The “four‐day progressive product trimming” ignores the fundamental point that the $360 cost to buy the pig is a joint cost. A pig is purchased as a whole. The butcher’s challenge is to maximize the total revenues minus incremental costs (assumed zero) from the sale of all products. At each stage, the decision made ignores the general rule that product emphasis decisions should consider relevant revenues and relevant costs. Allocated joint costs are not relevant. For example, the Day 2 decision to drop bacon ignores the fact that the $360 joint cost has been paid to acquire the whole pig. The $172.80 of revenues are relevant inflows. This same position also holds for the Day 3 and Day 4 decisions. The revenue amounts are the figures to use in the sales value at splitoff method: Product Pork chops Ham Bacon
Revenue $144.00 180.00 172.80 $496.80
Joint Costs Weighting Allocated 0.2899 $104.36 0.3623 130.43 0.3478 125.21 1.0000 $360.00
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15‐32 (cont’d) 3.
No. The decision to sell or not sell individual products should consider relevant revenues and relevant costs. In the butcher’s context, the relevant costs would be the additional time and other incidentals to take each pig part and make it a salable product. The relevant revenues would be the difference between the selling price at the consumer level for the pig parts and what the butcher may receive for the whole pig.
15‐33 (25 min.) 1.
Accounting for a byproduct.
Byproduct recognized at time of production: Joint cost = $1,500 Joint cost to be charged to main product = Joint Cost – NRV of Byproduct = $1,500 (50 kg × $1.20) = $1,440 $1440 = $3.60 per container Inventoriable cost of main product = 400 containers Inventoriable cost of byproduct = NRV = $1.20 per kilogram Gross Margin Calculation under Production Method Revenues Main product: Water (600/2 containers × $8) $2,400 Byproduct: Sea Salt 0 2,400 Cost of goods sold Main product: Water (300 containers × $3.60) 1,080 Gross margin $1,320 Gross‐margin percentage ($1,320 ÷ $2,400) 55.00% Inventoriable costs (end of period): Main product: Water (100 containers × $3.60) = $360 Byproduct: Sea Salt (10 kilograms × $1.20) = $12
2. Byproduct recognized at time of sale: Joint cost to be charged to main product = Total joint cost = $1,500 $1500 Inventoriable cost of main product = = $3.75 per container 400 containers Inventoriable cost of byproduct = $0
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15‐33 (cont’d)
3.
Gross Margin Calculation under Sales Method Revenues Main product: Water (600/2 containers × $8) Byproduct: Sea Salt (40 kilograms × $1.20) Cost of goods sold Main product: Water (300 containers × $3.75) Gross margin Gross‐margin percentage ($1,323 ÷ $2,448)
$2,400 48 2,448 1,125 $1,323 54.04%
Inventoriable costs (end of period): Main product: Water (100 containers × $3.75) = $375 Byproduct: Sea Salt (10 kilograms × $0) = $0
The production method recognizes the byproduct cost as inventory in the period it is produced. This method sets the cost of the byproduct inventory equal to its net realizable value. When the byproduct is sold, inventory is reduced without being expensed through the income statement. The sales method associates all of the production cost with the main product. Under this method, the byproduct has no inventoriable cost and is recognized only when it is sold.
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15‐34 (40 min.) Joint cost allocation. 1. Joint Costs $20,000
Separable Costs
Butter
Processing $0.50 per pound
Spreadable Butter
Milk Processing
Buttermilk
Processing $0.25 per pint
Buttermilk
SPLITOFF POINT
a. Physical‐measure method: Physical measure of total production (10,000 lbs × 2; 20,000 qts × 4) Weighting, 20,000; 80,000 100,000 Joint costs allocated, 0.20; 0.80 × $20,000
Butter 20,000 cups 0.20 $4,000
Buttermilk Total 80,000 cups 100,000 cups 0.80 $16,000
$20,000
b. Sales value at splitoff method: Butter Buttermilk Sales value of total production at splitoff, 10,000 × $2; 20,000 × $1.5 $20,000 $30,000 Weighting, $20,000; $30,000 $50,000 0.40 0.60 Joint costs allocated, 0.40; 0.60 $20,000 $ 8,000 $12,000
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Total $50,000
$20,000
Chapter 15
15‐34 (cont’d) c. Net realizable value method: Butter Buttermilk Total Final sales value of total production, 20,000 $2.50; 20,000 $1.50 $50,000 $30,000 $80,000 0 5,000 Deduct separable costs 5,000 Net realizable value $45,000 $30,000 $75,000 Weighting, $45,000; $30,000 $75,000 0.60 0.40 Joint costs allocated, 0.60; 0.40 $20,000 $12,000 $ 8,000 $20,000 d. Constant gross‐margin percentage NRV method: Step 1: Final sales value of total production, $80,000 Deduct joint and separable costs, ($20,000 + $5,000) 25,000 Gross margin $55,000 Gross‐margin percentage ($55,000 ÷ $80,000) 68.75% Step 2: Butter Buttermilk Total Final sales value of total production (see 1c.) $50,000 $30,000 $80,000 Deduct gross margin, using overall 20,625 55,000 gross‐margin percentage of sales 34,375 (68.75%) Total production costs 15,625 9,375 25,000 Step 3: Deduct separable costs 5,000 0 5,000 $ 9,375 $20,000 Joint costs allocated $10,625
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15‐34 (cont’d) 2. Advantages and disadvantages:
3.
Physical‐Measure Advantage: Low information needs. Only knowledge of joint cost and physical distribution is needed. Disadvantage: Allocation is unrelated to the revenue‐generating ability of products. Sales Value at Splitoff Advantage: Considers market value of products as basis for allocating joint cost. Relative sales value serves as a proxy for relative benefit received by each product from the joint cost. Disadvantage: Uses selling price at the time of splitoff even if product is not sold by the firm in that form. Selling price may not exist for product at splitoff. Net Realizable Value Advantages: Allocates joint costs using ultimate net value of each product; applicable when the option to process further exists. Disadvantages: High information needs. Makes assumptions about expected outcomes of future processing decisions. Constant Gross‐Margin percentage method Advantage: Since it is necessary to produce all joint products, they all look equally profitable. Disadvantages: High information needs. All products are not necessarily equally profitable; method may lead to negative cost allocations so that unprofitable products are subsidized by profitable ones. When selling prices for all products exist at splitoff, the sales value at splitoff method is the preferred technique. It is a relatively simple technique that depends on a common basis for cost allocation: revenues. It is better than the physical measure method because it considers the relative market values of the products generated by the joint cost when seeking to allocate it (which is a surrogate for the benefits received by each product from the joint cost). Further, the sales value at splitoff method has advantages over the NRV method and the constant gross margin percentage method because it does not penalize managers by charging more for developing profitable products using the output at splitoff, and it requires no assumptions about future processing activities and selling prices.
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15‐35 (10 min.)
Further‐processing decision. 1 & 2. The decision about which combination of products to produce is not affected by the method of joint cost allocation. For both the sales value at splitoff and physical measure methods, the relevant comparisons are as shown below: Revenue if sold at splitoff Process further NRV Profit (Loss) from processing further
Butter $20,000 a 45,000 c $25,000
Buttermilk $30,000 b 26,000 d $(4,000)
10,000 lbs × $2 = $20,000 20,000 qts × $1.5 = $30,000 c 20,000 tubs × $2.5 – 10,000lbs × $.5 = $45,000 d 40,000 pints × $.9 – 40,000 pints × $.25 = $26,000 a
b
To maximize profits, Elsie should process butter further into spreadable butter. However, Elsie should sell the buttermilk at the splitoff point in quart containers. The extra cost to convert to pint containers ($0.25 per pint × 2 pints per quart = $0.50 per quart) exceeds the increase in selling price ($0.90 per pint × 2 pints per quart = $1.80 per quart – $1.50 original price = $0.30 per quart) and leads to a loss of $4,000. 3.
The decision to sell a product at splitoff or to process it further should have nothing to do with the allocation method chosen. For each product, you need to compare the revenue from selling the product at splitoff to the NRV from processing the product further. Other things being equal, management should choose the higher alternative. The total joint cost is the same regardless of the alternative chosen and is therefore irrelevant to the decision.
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15‐36 (20 min.) 1.
Joint cost allocation with a byproduct.
Sales value at splitoff method: Byproduct recognized at time of production method Joint cost to be charged to joint products = Joint cost – NRV of Byproduct = $10,000 – (1,000 tonnes × 20% × 0.25 vats) × $60 = $10,000 – (50 vats × $60) = $ 7,000
Grade A Coal
Sales value of coal at splitoff, 1,000 tonnes × 0.4 × $100; 1,000 tonnes × 0.4 × $60 Weighting, $40,000; $24,000 $64,000 Joint costs allocated, 0.625; 0.375 × $7,000
$40,000 0.625 $ 4,375
Grade B Coal
Total
$24,000 $64,000 0.375 $ 2,625 $ 7,000
$21,375 $57,000 Gross margin (Sales revenue ─ Allocated cost) $35,625 2. Sales value at splitoff method: Byproduct recognized at time of sale method Joint cost to be charged to joint products = Total joint cost = $10,000 Grade A Grade B Total Coal Coal Sales value of coal splitoff, 1,000 tonnes × .4 × $100; 1,000 tonnes × .4 × $60 $40,000 $24,000 $64,000 Weighting, $40,000; $24,000 $64,000 0.625 0.375 Joint costs allocated, 0.625; 0.375 × $10,000 $ 6,250 $ 3,750 $10,000 Gross margin (Sales revenue ─ Allocated cost) $33,750 $20,250 $54,000 Since the entire production is sold during the period, the overall gross margin is the same under the production and sales methods. In particular, under the sales method, the $3,000 received from the sale of the coal tar is added to the overall revenues, so that Cumberland’s overall gross margin is $57,000, as in the production method.
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15‐36 (cont’d) 3.
The production method of accounting for the byproduct is only appropriate if Cumberland is positive they can sell the byproduct and positive of the selling price. Moreover, Cumberland should view the byproduct’s contribution to the firm as material enough to find it worthwhile to record and track any inventory that may arise. The sales method is appropriate if either the disposition of the byproduct is unsure or the selling price is unknown, or if the amounts involved are so negligible as to make it economically infeasible for Cumberland to keep track of byproduct inventories.
15‐37 (15 min.) Byproduct‐costing journal entries. 1.
Byproduct—production method journal entries
i) At time of production: Work‐in‐Process Inventory 10,000 Accounts Payable, etc. For byproduct: Finished Goods Inv – Coal tar 3,000 Work‐in‐Process Inventory For joint products Finished Goods Inv – Grade A 4,375 Finished Goods Inv – Grade B 2,625 Work‐in‐Process Inventory ii) At time of sale: For byproduct Cash or A/R 3,000 Finished Goods Inv – Coal Tar
For joint products Cash or A/R 64,000 Sales Revenue – Grade A Sales Revenue – Grade B
Cost of goods sold ‐ Grade A Cost of goods sold ‐ Grade B Finished Goods Inv – Grade A Finished Goods Inv – Grade B
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10,000
3,000
7,000
3,000
40,000 24,000
4,375 2,625 4,375 2,625
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15‐37 (cont’d) 2.
Byproduct—sales method journal entries i) At time of production: Work‐in‐Process Inventory 10,000 Accounts Payable, etc. For byproduct: No entry For Joint Products Finished Goods Inv – Grade A 6,250 Finished Goods Inv – Grade B 3,750 Work‐in‐Process Inventory ii) At time of sale For byproduct Cash or A/R 3,000 Sales Revenue – Coal Tar
3,000
For joint products Cash or A/R 64,000 Sales Revenue – Grade A Sales Revenue – Grade B
40,000 24,000
Cost of goods sold ‐ Grade A Cost of goods sold ‐ Grade B Finished Goods Inv – Grade A Finished Goods Inv – Grade B
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10,000
10,000
6,250 3,750 6,250 3,750
Chapter 15
15‐38 (30 min.) Accounting for a byproduct. 1.
Byproduct recognized at time of production: Joint cost = ($300 × 50) + $10,000 = $25,000 Joint cost charged to main product = Joint cost – NRV of byproduct = $25,000 – (6 scarves × 50 bolts × $25) = $25,000 – (300 scarves × $25) = $17,500 $17,500 Inventoriable cost of main product = = $11.67 per blouse 1,500 blouses Inventoriable cost of byproduct = NRV = $25 per scarf Gross Margin Calculation under Production Method Revenues Main product: Blouses (1,200 blouses × $90) $108,000 Byproduct: Scarves 0 108,000 Cost of goods sold Main product: Blouses (1,200 blouses × $11.67) 14,000 Gross margin $ 94,000 Gross‐margin percentage ($94,000 ÷ $108,000) 87.04% Inventoriable costs (end of period): Main product: Blouses (300 blouses × $11.67) = $3,500 Byproduct: Scarves (40 scarves × $25) = $1,000
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15‐38 (cont’d) 2.
Byproduct recognized at time of sale: Joint cost to be charged to main product = Total joint cost = $25,000 $25,000 = $16.67 per blouse Inventoriable cost of main product = 1,500 blouses Inventoriable cost of byproduct = $0 Gross Margin Calculation under Sales Method Revenues Main product: Blouses (1,200 blouses × $90) $108,000 Byproduct: Scarves (260 scarves × $25) 6,500 114,500 Cost of goods sold Main product: Blouses (1,200 blouses × $16.67) 20,000 Gross margin $ 94,500 Gross‐margin percentage ($94,500 ÷ $114,500) 82.53% Inventoriable costs (end of period): Main product: Blouses (300 blouses × $16.67) = $5,000 Byproduct: Scarves (40 scarves × $0) = $0 3. a. Byproduct—production method journal entries i) At time of production: Work‐in‐Process Inventory 25,000 Accounts Payable, etc. 25,000 For byproduct: Finished Goods Inv – Scarves 7,500 Work‐in‐Process Inventory 7,500 For main product Finished Goods Inv – Blouses 17,500 Work‐in‐Process Inventory 17,500
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15‐38 (cont’d)
ii) At time of sale: For byproduct Cash or A/R 6,500 Finished Goods Inv – Scarves
For main product Cash or A/R Sales Revenue – Blouses
108,000
Cost of goods sold – Blouses Finished Goods Inv – Blouses
108,000
14,000 14,000
b. Byproduct—sales method journal entries i) At time of production: Work‐in‐Process Inventory 25,000 Accounts Payable, etc. For byproduct: No entry For main product Finished Goods Inv – Blouses 25,000 Work‐in‐Process Inventory ii) At time of sale: For byproduct Cash or A/R 6,500 Sales Revenue – Scarves
6,500
25,000
25,000
6,500
For joint product Cash or A/R 108,000 Sales Revenue – Blouses 108,000 Cost of goods sold ‐ Blouses 20,000 Finished Goods Inv – Blouses 20,000
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15‐39 (30 min.) 1.
Estimated net realizable value method, byproducts.
A diagram of the situation is in Solution Exhibit 15‐39. a.
For the month of November 2010, Princess Corporation’s output was: • apple slices 89,100 • applesauce 81,000 • apple juice 67,500* • animal feed 27,000
These amounts were calculated as follows: Total Product Input Proportion Kilograms Slices 270,000 kg 0.33 89,100 Sauce 270,000 0.30 81,000 Juice 270,000 0.27 72,900 Feed 270,000 0.10 27,000 1.00 270,000
Kilograms Lost — — 5,400 — 5,400
Net Kilograms 89,100 81,000 67,500* 27,000 264,600
*Net kilograms: = 72,900 – (0.08 net kilograms) 1.08 net kilograms = 72,900 Net kilograms = 67,500
b. The estimated net realizable value for each of the three main products is calculated below: Estimated Net Net Separable Realizable Product Kilograms Price Revenue Costs Value Slices 89,100 $0.96 $ 85,536 $13,536 $ 72,000 Sauce 81,000 0.66 53,460 10,260 43,200 Juice 67,500 0.48 32,400 3,600 28,800 $171,396 $27,396 $144,000
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15‐39 (cont’d) c. and d. The estimated net realizable value of the byproduct is deducted from the production costs prior to allocation to the joint products, as presented below: Allocation of Cutting Department Costs to Joint Products and Byproducts Net realizable value (NRV) of byproduct = Byproduct revenue – Separable costs = $0.12 (270,000 10%) – $840 = $3,240 – $840 = $2,400 Costs to be allocated = Joint costs – NRV of byproduct = $72,000 – $2,400 = $69,600 Separable Joint Gross Product Revenue Costs Costs Margin 1 Slices $ 85,536 $13,536 $34,800 $37,200 Sauce 53,460 10,260 20,8802 22,320 3 Juice 32,400 3,600 13,920 14,880 $171,396 $27,396 $69,600 $74,400 1) Slices 72K/144K $69,600 = $34,800 2) Sauce 43.2K/144K $69,600 = $20,880 3) Juice 28.8K/144K $69,600 = $13,920 2. The gross‐margin dollar information by main product is determined by the arbitrary allocation of joint production costs. As a result, these cost figures and the resulting gross‐margin information are of little significance for planning and control purposes. The allocation is made only for purposes of inventory costing and income determination.
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15‐39 (cont’d) SOLUTION EXHIBIT 15‐39
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15‐40 (20‐30 min.) Joint‐product/byproduct distinctions, governance. 1.
The 2013 method gives Princess managers relatively little discretion vis‐à‐vis the pre‐2013 method. The 2013 method recognizes all four products in the accounting system at the time of production. The pre‐2013 method recognizes only two products (apple slices and applesauce) at the time of production. Consider the data in the question. The $72,000 of joint costs would be allocated as follows (using the $72,000 and $43,200 estimated NRV amounts): Apple Slices:
$72, 000 $72, 000 $45, 000 $115, 200
Applesauce:
$43, 200 $72, 000 $27, 000 $115, 200
The gross margin on each product is: Apple Slices:
($85, 536 $45, 000 $13, 536) 31.57% $85, 536
Applesauce:
($53, 460 $27, 000 $10, 260) 30.30% $53, 460
The gross margins on the two “byproducts” are: Apple Juice:
$32, 400 $3, 600 88.89% $32, 400
Animal Feed:
$3, 240 $840 74.07% $3, 240
With the pre‐2013 method, managers have flexibility as to when to sell the apple juice and the animal feed. Both can be kept in cold storage until needed. If there is a need for a large “dose” of gross margin at year end to meet the target ratio, high gross margins from apple juice or animal feed can be drawn on to help achieve the target. 2.
The controller could examine the sales patterns of apple juice and animal feed at year end. Do managers who have ratios from existing sales below the target sell apple juice and animal feed inventories to achieve the target ratio? Do managers who have ratios above the target put apple juice and animal feed production into inventory so as to provide a “cushion” for subsequent years? One piece of evidence here would be physical inventory holding patterns on a monthly basis. If there were a different pattern of inventory holding for the two byproducts than for the two joint products, there would be grounds for further investigating whether managers are abusing the bonus system.
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15‐40 (cont’d) 3.
Using the estimated net realizable value method with all products treated as a joint product would reduce “gaming” behaviour by managers with respect to bonus payments. The estimated net realizable value of all four products ($72,000 + $43,200 + $28,800 + $2,400 = $146,400) would be used to allocate the $72,000 joint cost:
Slices:
$72,000 $72,000 $146, 400
= $35,410
Sauce:
$43, 200 $72,000 $146, 400
= $21,246
Juice:
$28,800 $72,000 $146, 400
= $14,164
Feed:
$2, 400 $72,000 $146, 400
= $ 1,180
$72,000
A second method that could be used in conjunction with that discussed above is to have an inventory‐holding charge. If managers build up inventory, they would be penalized. This would reduce incentives to use inventory to manipulate reported income to meet target ratios.
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COLLABORATIVE LEARNING CASES
15‐41 Usefulness of joint cost allocation. 1.
2.
3.
4.
Two reasons are relevant. The first is that the OPOs are being reimbursed on a contracted basis that specifies allowable costs, some of which are allocated. Some proportion of the allocated costs are joint costs. The OPOs can only justify claiming those costs which are identified using the contracted joint costing method. The second is litigation—the government will use the courts if necessary to recover the lost $47 million from the OPOs. The standardization of joint costing methods and the specification of the allowable joint costs will enable each party to defend its actions. The splitoff point is the event beyond which costs become separately identifiable. If a donor had chosen to donate both a kidney and part of a liver, then the incision by the surgeon would be the splitoff point. Costs incurred for procedures subsequent to the incision (e.g., disposable supplies, labour, fees for the organ removal, storage, transportation etc.) for the kidney donation service would be splitoff from those incurred for the liver donation service. Different surgical techniques, preservatives, and processes are required for each organ recovered. The use of the operating room and the anaesthetic would be joint costs as well as any antibiotic medications to prevent post‐surgical infection and the hospital days in recovery. Joint cost allocation is relevant information when decision‐makers are assessing the rates at which hospitals and surgeons will be reimbursed for the recovery process. The governments do not want to pay twice for the same activities and joint cost allocation is a technique to ensure this does not happen.
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15‐42 (60 min.) 1.
a.
Joint cost allocation.
The Net Realizable Value Method allocates joint costs on the basis of the relative net realizable value (final sales value minus the separable costs of production and marketing). Joint costs would be allocated as follows:
Deluxe Standard Module Module Total Final sales value of total production $25,000 $ 8,500 $33,500 Deduct separable costs 1,500 1,000 2,500 $ 7,500 $31,000 Net realizable value at splitoff point $23,500 Weighting ($23,500; $7,500 ÷ $31,000) 0.7581 0.2419 Joint costs allocated (0.7581; 0.2419 × $24,000) $18,194 $ 5,806 $24,000 Total production costs ($18,194 + $1,500; $5,806 + $1,000) $19,694 $ 6,806 $26,500 Production costs per unit ($19,694; $6,806 ÷ 500 units) $ 39.39 $ 13.61 b. The constant gross‐margin percentage NRV method allocates joint costs in such a way that the overall gross‐margin percentage is identical for all individual products as follows: Step 1 Final sales value of total production: (Deluxe, $25,000; Standard, $8,500) $33,500 Deduct joint and separable costs (Joint, $24,000 + Separable Deluxe, $1,500 + Separable Standard, $1,000) Gross margin Gross‐margin percentage ($7,000 ÷ $33,500) Step 2 Deluxe Module Final sales value of total production $25,000 Deduct gross margin using overall gross margin percentage (20.8955%) 5,224 Total production costs 19,776
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26,500 $ 7,000 20.8955%
Standard Module $8,500
Total $33,500
1,776 6,724
7,000 26,500
Chapter 15
15‐42 (cont’d) Step 3 Deduct separable costs Joint costs allocated Production costs per unit ($19,776; $6,724 ÷ 500 units)
1,500 $18,276
1,000 $5,724
$ 39.55
$13.45
2,500 $24,000
c.
The physical measure method allocates joint costs on the basis of the relative proportions of total production at the splitoff point, using a common physical measure such as the number of bits produced for each type of module. Allocation on the basis of the number of bits produced for each type of module follows:
Deluxe Standard Module/ Module/ Chips Chips Total Physical measure of total production (bits) 500,000 250,000 750,000 Weighting (500,000; 250,000 ÷ 750,000) 0.6667 0.3333 Joint costs allocated (0.6667; 0.3333 × $24,000) $16,000 $ 8,000 $24,000 Total production costs ($16,000 + $1,500; $8,000 + $1,000) $17,500 $ 9,000 $26,500 Production costs per unit ($17,500; $9,000 ÷ 500 units) $ 35.00 $18.00 Each of the methods for allocating joint costs has weaknesses. Because the costs are joint in nature, managers cannot use the cause‐and‐effect criterion in making this choice. Managers cannot be sure what causes the joint costs attributable to individual products. The net realizable value (NRV) method (or sales value at splitoff method) is widely used when selling price data are available. The NRV method provides a meaningful common denominator to compute the weighting factors. It allocates costs on the ability‐to‐pay principle. It is probably preferred to the constant gross‐margin percentage method which also uses sales values to allocate costs to products. That’s because the constant gross‐margin percentage method makes the further tenuous assumption that all products have the same ratio of cost to sales value.
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15‐42 (cont’d) The physical measure method bears little relationship to the revenue‐producing power of the individual products. Several physical measures could be used, such as the number of chips and the number of good bits. In each case, the physical measure only relates to one aspect of the chip that contributes to its value. The value of the module as determined by the marketplace is a function of multiple physical features. Another key question is whether the physical measure chosen portrays the amount of joint resources used by each product. It is possible that the resources required by each type of module depend on the number of good bits produced during chip manufacturing. But this cause‐and‐ effect relationship is hard to establish. MMC should use the NRV method. But the choice of method should have no effect on their current control and measurement systems. 2.
The correct approach in deciding whether to process further and make DRAM modules from the standard modules is to compare the incremental revenue with the incremental costs:
Incremental revenue from making DRAMs ($26 × 400) – ($17 × 500) Incremental costs of DRAMs, further processing Incremental operating income from converting standard modules into DRAMs
$1,900 1,600 $ 300
A total income computation of each alternative follows:
Alternative 1: Sell Deluxe and Standard
Total revenues ($25,000 + $8,500) $33,500 Total costs 26,500 Operating income $ 7,000
Alternative 2: Sell Deluxe and DRAM
Difference
($25,000 + $10,400) $35,400 ($26,500 + $1,600) 28,100 $ 7,300
$1,900 1,600 $ 300
It is profitable to extend processing and to incur additional costs on the standard module to convert it into a DRAM module as long as the incremental revenue exceeds incremental costs. The amount of joint costs incurred up to splitoff ($24,000)—and how these joint costs are allocated to each of the products— are irrelevant to the decision of whether to process further and make DRAM modules. That’s because the joint costs of $24,000 remain the same whether or not further processing is done on the standard modules.
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15‐42 (cont’d) Joint cost allocations using the physical measure method (on the basis of the number of bits) may mislead MMC, if MMC uses unit‐cost data to guide the choice between selling standard modules versus selling DRAM modules. In requirement 2, allocating joint costs on the basis of the number of good bits yielded a cost of $16,000 for the Deluxe modules and $8,000 for the Standard modules. A product‐line income statement for selling Deluxe modules and DRAM modules would appear as follows: Revenues Cost of goods sold Joint costs allocated Separable costs Total cost of goods sold Gross margin
Deluxe Module $25,000 16,000 1,500 17,500 $ 7,500
DRAM Module $10,400 8,000 2,600* 10,600 $ (200)
*Separable costs of $1,000 to manufacture the Standard module and further separable costs of $1,600 to manufacture the DRAM module. This product‐line income statement would erroneously imply that MMC would suffer a loss by selling DRAM modules, and as a result, it would suggest that MMC should not process further to make and sell DRAM modules. This occurs because of the way the joint costs are allocated to the two products. As mentioned earlier, the joint cost allocation is irrelevant to the decision. On the basis of the incremental revenues and incremental costs, MMC should process the Standard modules into DRAM modules.
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CHAPTER 16 REVENUE AND CUSTOMER PROFITABILITY ANALYSIS
SHORT‐ANSWER QUESTIONS
16‐1 Companies increasingly are selling packages of products or services for a single price. Revenue allocation is required when managers in charge of developing or marketing individual products in a bundle are evaluated using product‐specific revenue.
16‐2 The stand‐alone revenue‐allocation method uses product‐specific information on the products in the bundle as weights for allocating the bundled revenue to the individual products. The incremental revenue allocation method ranks individual products in a bundle according to criteria determined by management—such as the product in the bundle with the most sales—and then uses this ranking to allocate bundled revenue to the individual products. The first‐ranked product is the primary product in the bundle. The second‐ranked product is the first incremental product, the third‐ranked product is the second incremental product, and so on.
16‐3 Managers typically will argue that their individual product is the prime reason why consumers buy a bundle of products. Evidence on this argument could come from the sales of the products when sold as individual products. Other pieces of evidence include surveys of users of each product and surveys of people who purchase the bundle of products.
16‐4 A dispute over allocation of revenue of a bundled product could be resolved by (a) having an agreement that outlines the preferred method in the case of a dispute, or (b) having a third party (such as the company president or an independent arbitrator) make a decision.
16‐5 Using the levels approach introduced in Chapter 7, the sales‐volume variance is a Level 2 variance. By sequencing through Level 3 (sales‐mix and sales‐quantity variances) and then Level 4 (market‐size and market‐share variances), managers can gain insight into the causes of a specific sales‐volume variance caused by changes in the mix and quantity of the products sold as well as changes in market size and market share.
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16‐6 The total sales‐mix variance arises from differences in the budgeted contribution margin of the actual and budgeted sales mix. The composite unit concept enables the effect of individual product changes to be summarized in a single intuitive number by using weights based on the mix of individual units in the actual and budgeted mix of products sold.
16‐7 A favourable sales‐quantity variance arises because the actual units of all products sold exceed the budgeted units of all products sold.
16‐8 The sales‐quantity variance can be decomposed into (a) a market‐size variance (because the actual total market size in units is different from the budgeted market size in units), and (b) a market share variance (because the actual market share of a company is different from the budgeted market share of a company). Both variances use the budgeted average contribution margin per unit.
16‐9 Some companies believe that reliable information on total market size is not available and therefore they choose not to compute market‐size and market‐share variances.
16‐10 Customer profitability analysis highlights to managers how individual customers differentially contribute to total profitability. It helps managers to see whether customers who contribute sizably to total profitability are receiving a comparable level of attention from the organization. 16‐11 No. Government‐funded social services receive revenue based on revenue allocation methods. One example is the social welfare programs provided from casino revenue by the First Nations to its own people.
16‐12 No. A customer‐profitability profile highlights differences in current periodʹs profitability across customers. Dropping customers should be the last resort. An unprofitable customer in one period may be highly profitable in subsequent future periods. Moreover, costs assigned to individual customers need not be purely variable with respect to short‐run elimination of sales to those customers. Thus, when customers are dropped, costs assigned to those customers may not disappear in the short run.
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16‐13 Five categories in a customer cost hierarchy are identified in the chapter. The examples given relate to the Spring Distribution Company used in the chapter: Customer output‐unit‐level costs—costs of activities to sell each unit (case) to a customer. An example is product‐handling costs of each case sold. Customer batch‐level costs—costs of activities that are related to a group of units (cases) sold to a customer. Examples are costs incurred to process orders or to make deliveries. Customer‐sustaining costs—costs of activities to support individual customers, regardless of the number of units or batches of product delivered to the customer. Examples are costs of visits to customers or costs of displays at customer sites. Distribution‐channel costs—costs of activities related to a particular distribution channel rather than to each unit of product, each batch of product, or specific customers. An example is the salary of the manager of Spring’s retail distribution channel. Corporate‐sustaining costs—costs of activities that cannot be traced to individual customers or distribution channels. Examples are top management and general administration costs.
16‐14 Companies that separately record (a) the list price and (b) the discount have sufficient information to subsequently examine the level of discounting by each individual customer and by each individual salesperson.
EXERCISES
16‐15 (10‐15 min.) Terminology. To satisfy their customersʹ value proposition and benefit from economies of scale companies often create customized product bundles from individual products. This is also called a composite unit. The decision the management team needs to make is how to allocate the bundled revenue to each component of the bundle. There are two methods, standalone and incremental revenue allocation. In combination with ABC systems, the management team can examine detailed variance reports of sales‐mix, sales‐quantity, market‐share and market‐size variance. This informs the team how well they are implementing their strategy. The team can also use the customer as cost object in an ABC system and conduct a customer profitability analysis to determine whether to drop or add customers, stores, branches to improve profit. 16–762
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16‐16 (10‐15 min.) Allocation of common costs. 1.
a.
Stand‐alone method (costs are in thousands):
Separate Cost $2,100 1,400 3,500 $7,000
Joint Percentage Cost $2,100 ÷ $7,000=0.3 $5,000 $1,400 ÷ $7,000=0.2 5,000 $3,500 ÷ $7,000=0.5 5,000
City Allocation St. Anne $1,500 St. Teresa 1,000 2,500 St. Steven $5,000 1. b. Incremental method (cities ranked in order of most waste to least waste): Allocated Cost Cost Remaining to Allocate St. Steven $3,500 $1,500 ($5,000 ─ $3,500) St. Anne 1,500 0 ($1,500 ─ $1,500) St. Teresa 0 0 2. In this situation, the stand‐alone method is the better method because the weights it uses for allocation are based on the cost for each user as a separate entity. The citizens of St. Steven would not consider the incremental method fair because they would be subsidizing the other cities (especially St. Teresa). St. Anne is indifferent across the two methods; its citizens save $600,000 over the stand‐alone cost in either case. While the citizens of St. Teresa would clearly prefer the incremental allocation method and might seek to justify it because they generate the least amount of waste, they should understand that citizens of the other cities would believe it is not fair.
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16‐17 (20 min.) Revenue allocation. 1.
a.
Stand‐alone method for the BegM + RCC package Separate Revenue $ 60 40 $100
Joint Percentage Revenue $60 ÷ $100=0.6 $90 $40 ÷ $100=0.4 90
DVD Allocation BegM $54 RCC 36 $90 1. b. Incremental method Allocated Revenue Revenue Remaining i) (BegM first) To Allocate BegM $60 $30 ($90 ─ $60) RCC 30 Allocated Revenue Revenue Remaining ii) (RCC first) To Allocate RCC $40 $50 ($90 ─ $40) BegM 50 1. c. Shapley method (assuming each DVD is demanded in equal proportion) i) BegM ($60 + $50) ÷ 2 = $55 ii) RCC ($30 + $40) ÷ 2 = $35 2. a. Stand‐alone method for the ConM + RCC package Separate Joint Revenue DVD Percentage Revenue Allocation ConM $50 $50 ÷ $90=0.556 $72 $40 $40 ÷ $90=0.444 72 32 RCC 40 $90 $72
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16‐17 (cont’d) i)
b.
Incremental method
ConM RCC
Allocated Revenue Revenue Remaining (ConM first) To Allocate $50 $22 ($72 ─ $50) 22
RCC ConM
Allocated Revenue Revenue Remaining (RCC first) To Allocate $40 $32 ($72 ─ $40) 32
ii)
3.
c.
Shapley method. (assuming each DVD is demanded in equal proportion)
i) BegM ii) RCC
(50+32) ÷ 2 = 41 (22+40) ÷ 2 = 31
For each DVD package, the stand‐alone method and the Shapley method give approximately the same allocation to each DVD. These methods are fair if the demand for the DVDs are approximately equal. The stand‐alone method might be slightly preferable here since it is simpler and easier to explain. The incremental method would be appropriate if one DVD has a higher level of demand than the other DVD. In this situation, the dominant DVD would be sold anyway so it should receive its stand‐alone revenue, and the other DVD should receive the remainder.
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16‐18 (30–40 min.) Variance analysis, multiple products. 1.
Sales‐volume Actual sales Budgeted contribution = Budgeted sales margin per ticket quantity in units quantity in units variance
Lower‐tier tickets = (3,300 – 4,000) $20 = $14,000 U Upper‐tier tickets = (7,700 – 6,000) $ 5 = 8,500 F All tickets $ 5,500 U
2.
Budgeted average contribution margin per unit =
(4,000 $20) (6,000 $5) 10,000
=
$80,000 $30,000 $110,000 = 10,000 10,000
=
$11 per unit (seat sold)
Sales‐mix percentages: Budgeted Actual 3,300 4,000 = 0.40 = 0.30 Lower‐tier 10,000 11,000 6,000 7,700 = 0.60 = 0.70 Upper‐tier 11,000 10,000
Solution Exhibit 16‐18 presents the sales‐volume, sales‐quantity, and sales‐mix variances for lower‐tier tickets, upper‐tier tickets, and in total for Penguins in 2013
The sales‐quantity variances can also be computed as: Budgeted Budgeted Sales‐quantity Actual units Budgeted units = of all tickets of all tickets sales - mix cont. margin variance percentage sold sold per ticket The sales‐quantity variances are: Lower‐tier tickets = (11,000 – 10,000) × 0.40 × $20 = $ 8,000 F Upper‐tier tickets = (11,000 – 10,000) × 0.60 × $ 5 = 3,000 F All tickets $11,000 F
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16‐18 (cont’d)
3.
The sales‐mix variance can also be computed as: Budgeted Budgeted Sales‐mix Actual units Actual = of all tickets × sales-mix sales-mix contribution margin variance percentage percentage per ticket sold The sales‐mix variances are Lower‐tier tickets = 11,000 × (0.30 – 0.40) × $20 Upper‐tier tickets = 11,000 × (0.70 – 0.60) × $ 5 All tickets
= $22,000 U = 5,500 F $16,500 U
The Penguins increased average attendance by 10% per game. However, there was a sizable shift from lower‐tier seats (budgeted contribution margin of $20 per seat) to the upper‐tier seats (budgeted contribution margin of $5 per seat). The net result: the actual contribution margin was $5,500 below the budgeted contribution margin.
SOLUTION EXHIBIT 16‐18 Columnar Presentation of Sales‐Volume, Sales‐Quantity and Sales‐Mix Variances for Downtown Penguins Flexible Budget: Static Budget: Actual Units of Actual Units of Budgeted Units of All Products Sold All Products Sold All Products Sold × Actual Sales Mix × Budgeted Sales Mix × Budgeted Sales Mix × Budgeted × Budgeted × Budgeted Contribution Contribution Margin Contribution Margin per Unit per Unit Margin per Unit (1) (2) (3) Panel A: a b b Lower‐tier (11,000 × 0.40 ) × $20 (10,000 × 0.40 ) × $20 (11,000 × 0.30 ) × $20
3,300 × $20 4,400 × $20 4,000 × $20 $66,000 $88,000 $80,000 $22,000U $8,000 F Sales‐mix variance Sales‐quantity variance $14,000 U Sales‐volume variance
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16‐18 (cont’d) Panel B: Upper‐tier
c
d
d
(11,000 × 0.70 ) × $5 (11,000 × 0.60 ) × $5 (10,000 × 0.60 ) × $5 7,700 × $5 6,600 × $5 6,000 × $5 $38,500 $33,000 $30,000 $5,500 F $3,000 F Sales‐mix variance Sales‐quantity variance $8,500 F Sales‐volume variance
e f g Panel C: $104,500 $121,000 $110,000 All Tickets $16,500 U $11,000 F (Sum of Total sales‐mix varianceTotal sales‐quantity variance Lower‐tier and $5,500 U Upper‐tier Total sales‐volume variance tickets) F = favourable effect on operating income; U = unfavourable effect on operating income. Budgeted Sales Mix: Actual Sales Mix: a c
Lower‐tier = 3,300 ÷ 11,000 = 30%
b
Lower‐tier = 4,000 ÷ 10,000 = 40%
d
e
f
g
Upper‐tier = 7,700 ÷ 11,000 = 70% $66,000 + $38,500 = $104,500
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Upper‐tier = 6,000 ÷ 10,000 = 60% $88,000 + $33,000 = $121,000 $80,000 + $30,000 = $110,000
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Chapter 16
16‐19 (30 min.) Variance analysis, working backward. 1. and 2. Solution Exhibit 16‐19 presents the sales‐volume, sales‐quantity, and sales‐mix variances for the Plain and Chic wine glasses and in total for Jinwa Corporation in June 2013 The steps to fill in the numbers in Solution Exhibit 16‐19 follow: Step 1 Consider the static budget column (Column 3): Static budget total contribution margin $5,600 Budgeted units of all glasses to be sold 2,000 Budgeted contribution margin per unit of Plain $2 Budgeted contribution margin per unit of Chic $6 Suppose that the budgeted sales‐mix percentage of Plain is y. Then the budgeted sales‐mix percentage of Chic is (1 – y). Therefore, (2,000y $2) + (2,000 (1 – y) $6) = $5,600 $4000y + $12,000 – $12,000y = $5,600 $8,000y = $6,400 y = 0.8 or 80% 1 – y = 20% Jinwa’s budgeted sales mix is 80% of Plain and 20% of Chic. We can then fill in all the numbers in Column 3. Step 2 Next, consider Column 2 of Solution Exhibit 16‐19. The total is $4,200 (the static budget total contribution margin of $5,600 – the total sales‐quantity variance of $1,400 U which was given in the problem). We need to find the actual units sold of all glasses, which we denote by q. From Column 2, we know that (q 0.8 $2) + (q 0.2 $6) = $4,200 $1.6q + $1.2q = $4,200 $2.8q = $4,200 q = 1,500 units So, the total quantity of all glasses sold is 1,500 units. This computation allows us to fill in all the numbers in Column 2.
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Step 3 Next, consider Column 1 of Solution Exhibit 16‐19. We know actual units sold of all glasses (1,500 units), the actual sales‐mix percentage (given in the problem information as Plain, 60%; Chic, 40%), and the budgeted unit contribution margin of each product (Plain, $2; Chic, $6). We can therefore determine all the numbers in Column 1. Solution Exhibit 16‐19 displays the following sales‐quantity, sales‐mix, and sales‐ volume variances: Sales‐Volume Variance Plain $1,400 U Chic 1,200 F All Glasses $ 200 U Sales‐Quantity Variances Sales‐Mix Variances Plain $ 600 U Plain $ 800 U Chic 1,800 F Chic 600 U All Glasses $1,200 F All Glasses $1,400 U 3. Jinwa Corporation shows an unfavourable sales‐quantity variance because it sold fewer wine glasses in total than was budgeted. This unfavourable sales‐quantity variance is partially offset by a favourable sales‐mix variance because the actual mix of wine glasses sold has shifted in favour of the higher contribution margin Chic wine glasses. The problem illustrates how failure to achieve the budgeted market penetration can have negative effects on operating income.
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SOLUTION EXHIBIT 16‐19 Columnar Presentation of Sales‐Volume, Sales‐Quantity, and Sales‐Mix Variances for Jinwa Corporation Flexible Budget: Static Budget: Actual Units Actual Units Budgeted Units of All Glasses Sold of All Glasses Sold of All Glasses Sold Actual Sales Mix Budgeted Sales Mix Budgeted Sales Mix Budgeted Budgeted Budgeted Contribution Contribution Contribution Margin per Unit Margin per Unit Margin per Unit Panel A: (1,500 0.6) $2 (1,500 0.8) $2 (2,000 0.8) $2 Plain 900 $2 1,200 $2 1,600 $2 $1,800 $2,400 $3,200 $600 U $800 U Sales‐mix variance Sales‐quantity variance $1,400 U Sales‐volume variance (1,500 0.2) $6 (2,000 0.2) $6 Panel B: (1,500 0.4) $6 600 $6 300 $6 400 $6 Chic $3,600 $1,800 $2,400 $1,800 F $600 U Sales‐mix variance Sales‐quantity variance $1,200 F Sales‐volume variance Panel C: $5,400 $4,200 $5,600 All Glasses $1,200 F $1,400 U Total sales‐mix varianceTotal sales‐quantity variance $200 U Total sales‐volume variance F = favourable effect on operating income; U = unfavourable effect on operating income.
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16‐20 (60 min.) Variance analysis, multiple products. 1.
Budget for 2013
Selling Price (1) Kola $6.00 Limor 4.00 Orlem 7.00 Total Actual for 2013 Variable Selling Price (1) Kola $6.20 Limor 4.25 Orlem 6.80 Total
Variable Contrib. Cost Margin Units per Unit per Unit Sold (2) (3) = (1) – (2) (4) $4.00 $2.00 400,000 2.80 1.20 600,000 4.50 2.50 1,500,000 2,500,000 Contrib. Cost Margin Units per Unit per Unit Sold (2) (3) = (1) – (2) (4) $4.50 $1.70 480,000 2.75 1.50 900,000 4.60 2.20 1,620,000 3,000,000
Sales Mix (5) 16% 24 60 100% Sales Mix (5) 16% 30 54 100%
Contribution Margin (6) = (3) × (4) $ 800,000 720,000 3,750,000 $5,270,000
Contribution Margin (6) = (3) × (4) $ 816,000 1,350,000 3,564,000 $5,730,000
Solution Exhibit 16‐20 presents the sales‐volume, sales‐quantity, and sales‐mix variances for each product and in total for 2013. Budgeted Budgeted Actual Sales-volume quantity of quantity of contribution margin variance units sold units sold per unit Kola = ( 480,000 – 400,000) × $2.00 = $160,000 F Limor = ( 900,000 – 600,000) × $1.20 = 360,000 F Orlem = (1,620,000 – 1,500,000) × $2.50 = 300,000 F Total $820,000 F 16–772
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16‐20 (cont’d)
Budgeted Budgeted Actual units Budgeted units Sales-quantity of all products of all products sales-mix contribution margin variance percentage per unit sold sold
Kola = (3,000,000 – 2,500,000) × 0.16 × $2.00 = $ 160,000 F Limor = (3,000,000 – 2,500,000) × 0.24 × $1.20 = 144,000 F Orlem = (3,000,000 – 2,500,000) × 0.60 × $2.50 = 750,000 F Total $1,054,000 F
Actual units Actual Budgeted Budgeted Sales-mix variance = of all products × sales‐mix – sales‐mix × contrib. margin sold percentage percentage per unit
Kola = 3,000,000 × (0.16 – 0.16) × $2.00 = $ 0 Limor = 3,000,000 × (0.30– 0.24) × $1.20 = 216,000 F Orlem = 3,000,000 × (0.54 – 0.60) × $2.50 = 450,000 U Total $234,000 U 2. The breakdown of the favourable sales‐volume variance of $820,000 shows that the biggest contributor is the 500,000 unit increase in sales resulting in a favourable sales‐quantity variance of $1,054,000. There is a partially offsetting unfavourable sales‐mix variance of $234,000 in contribution margin.
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SOLUTION EXHIBIT 16‐20 Sales‐Mix and Sales‐Quantity Variance Analysis of Soda King for 2013 Flexible Budget: Static Budget: Actual Units of Actual Units of Budgeted Units of All Products Sold All Products Sold All Products Sold Actual Sales Mix Budgeted Sales Mix Budgeted Sales Mix Budgeted Contribution Budgeted Contribution Budgeted Contribution Margin Per Unit Margin Per Unit Margin Per Unit Kola 3,000,000 0.16 $2 = $ 960,000 3,000,000 0.16 $2 = $ 960,000 2,500,000 0.16 $2 = $ 800,000 Limor 3,000,000 0.30 $1.20 = 1,080,000 3,000,000 0.24 $1.20 = 864,000 2,500,000 0.24 $1.20 = 720,000 2,500,000 0.60 $2.50 = 3,750,000 Orlem 3,000,000 0.54 $2.50 = 4,050,000 3,000,000 0.60 $2.50 = 4,500,000 $6,090,000 $6,324,000 $5,270,000 $234,000 U $1,054,000 F Sales‐mix variance Sales‐quantity variance $820,000 F Sales‐volume variance
F = favourable effect on operating income; U= unfavourable effect on operating income
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16‐21 (20 min.) Market‐share and market‐size variances. Actual Budgeted Western region 24 million 25 million Soda King 3 million 2.5 million Market share 12.5% 10% Average budgeted contribution margin per unit = $2.108 ($5,270,000 ÷ 2,500,000) Solution Exhibit 16‐21 presents the sales‐quantity variance, market‐size variance, and market‐share variance for 2012. Actual Market Actual – = market size × share market share variance
Budgeted × market share
Budgeted contribution margin per composite share unit for budgeted mix
= 24,000,000 × (0.125 – 0.10) × $2.108 = 24,000,000 × .025 × $2.108 = $1,264,800 F
Market = size
Actual market variance
–
Budgeted × market size
Budgeted × market share
Budgeted contribution margin per composite unit for budgeted mix
= (24,000,000 – 25,000,000) × 0.10 × $2.108 = – 1,000,000 × 0.10 × $2.108 = 210,800 U
The market share variance is favourable because the actual 12.5% market share was higher than the budgeted 10% market share. The market size variance is unfavourable because the market size decreased 4% [(25,000,000 – 24,000,000) ÷ 25,000,000]. While the overall total market size declined (from 25 million to 24 million), the increase in market share meant a favourable sales‐quantity variance. Sales‐Quantity Variance $1,054,000 F Market‐share variance Market‐size variance $1,264,800 F $210,800 U
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SOLUTION EXHIBIT 16‐21 Market‐Share and Market‐Size Variance Analysis of Soda King for 2013
Actual Market Size Actual Market Share Budgeted Average Contribution Margin Per Unit 24,000,000 0.125a $2.108b $6,324,000
Static Budget: Actual Market Size Budgeted Market Size Budgeted Market Share Budgeted Market Share Budgeted Average Budgeted Average Contribution Margin Contribution Margin Per Unit Per Unit c b c b 24,000,000 0.10 $2.108 25,000,000 0.10 $2.108 $5,059,200 $5,270,000
$1,264,800 F
$210,800 U
Market‐share variance
Market‐size variance
$1,054,000 F
Sales‐quantity variance
F = favourable effect on operating income; U = unfavourable effect on operating income aActual market share: 3,000,000 units ÷ 24,000,000 units = 0.125, or 12.5% bBudgeted average contribution margin per unit $5,270,000 ÷ 2,500,000 units = $2.108 per unit cBudgeted market share: 2,500,000 units ÷ 25,000,000 units = 0.10, or 10%
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Chapter 16
16‐22 (2030 min.)
Customer profitability, service company.
1. Avery Okie Wizard Grainger Duran Revenue $260,000 $200,000 $322,000 $122,000 $212,000 Technician and equipment cost 182,000 175,000 225,000 107,000 178,000 Gross margin 78,000 25,000 97,000 15,000 34,000 Service call handling ($75 150; 240; 40; 120; 180) 11,250 18,000 3,000 9,000 13,500 Web‐based parts ordering 9,600 16,800 4,800 12,000 12,000 ($80 120; 210; 60; 150; 150) Billing/Collection ($50 30; 90; 90; 60; 120) 1,500 4,500 4,500 3,000 6,000 Database maintenance ($10 150; 240; 40; 120; 180) 1,500 2,400 400 1,200 1,800 Customer‐level operating income $ 54,150 $ (16,700) $ 84,300 $(10,200) $ 700 2. Customers Ranked on Customer‐Level Operating Income Customer Code Wizard Avery Duran Grainger Okie
Customer‐Level Operating Income (1) $ 84,300 54,150 700 (10,200) (16,700) $112,250
Cumulative Customer‐Level Operating Income Customer‐Level Cumulative as a % of Total Customer Operating Income Customer‐Level Customer‐Level Revenue as a % of Revenue Operating Income Operating Income (2) (3) = (1) (2) (4) (5) = (4) $112,250 $ 322,000 26.18% $ 84,300 75% 260,000 20.83% 138,450 123% 212,000 0.33% 139,150 124% 122,000 ‐8.36% 128,950 115% 200,000 ‐8.35% 112,250 100% $1,116,000
The above table and the graph on the next page present the summary results. Wizard, the most profitable customer, provides 75% of total operating income. The three best customers provide 124% of IS’s operating income, and the other two, by incurring losses for IS, erode the extra 24% of operating income down to IS’s operating income.
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16‐22 (cont’d)
Customer-Level Operating Income
Customer-Level Operating Income $100,000 $84,300 $80,000 $60,000 $54,150 Wizard $40,000 Avery $20,000 Duran Grainger Okie $700 $0 $(10,200) -$20,000 $(16,700) -$40,000 Customers 3. The options that Instant Service should consider include: a. Increase the attention paid to Wizard and Avery. These are “key customers,” and every effort has to be made to ensure they retain IS. IS may well want to suggest a minor price reduction to signal how important it is in their view to provide a cost‐effective service to these customers. b. Seek ways of reducing the costs or increasing the revenue of the problem accounts––Okie and Grainger. For example, are the copying machines at those customer locations outdated and in need of repair? If yes, an increased charge may be appropriate. Can IS provide better on‐site guidelines to users about ways to reduce breakdowns? c. As a last resort, IS may want to consider dropping particular accounts. For example, if Grainger (or Okie) will not agree to a fee increase but has machines continually breaking down, IS may well decide that it is time not to bid on any more work for that customer. But care must then be taken to otherwise use or get rid of the excess fixed capacity created by “firing” unprofitable customers.
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Chapter 16
16‐23 (2025 min.) Customer profitability, distribution. 1.
The activity‐based costing for each customer is: Charlesville Pharmacy 1. Order processing, $40 × 13; $40 × 10 $ 520 2. Line‐item ordering, $3 × (13 × 9; 10 × 18) 351 3. Store deliveries, $50 × 7; $50 ×10 350 4. Carton deliveries, $1 × (7 × 22; 10 × 20) 154 5. Shelf‐stocking, $16 × (7 × 0; 10 × 0.5) 0 Operating costs $1,375 The operating income of each customer is: Charlesville Pharmacy Revenue $2,400 × 7; $1,800 × 10 $16,800 Cost of goods sold, $2,100 × 7; $1,650 × 10 14,700 Gross margin 2,100 Operating costs 1,375 Operating income $ 725
Chapelville Pharmacy $ 400 540 500 200 80 $1,720
Chapelville Pharmacy $18,000 16,500 1,500 1,720 $ (220)
Chapelville Pharmacy has a lower gross margin percentage than Charlesville (8.33% vs. 12.50%) and consumes more resources to obtain this lower margin.
Ways Figure Four could use this information include: a. Pay increased attention to the top 20% of the customers. This could entail asking them for ways to improve service. Alternatively, you may want to highlight to your own personnel the importance of these customers; e.g., it could entail stressing to delivery people the importance of never missing delivery dates for these customers.
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16‐23 (cont’d) b.
Work out ways internally at Figure Four to reduce the rate per cost driver; e.g., reduce the cost per order by having better order placement linkages with customers. This cost reduction by Figure Four will improve the profitability of all customers. c. Work with customers so that their behaviour reduces the total “system‐ wide” costs. At a minimum, this approach could entail having customers make fewer orders and fewer line items. This latter point is controversial with students; the rationale is that a reduction in the number of line items (diversity of products) carried by Ma and Pa stores may reduce the diversity of products Figure Four carries. There are several options here: Simple verbal persuasion by showing customers cost drivers at Figure Four. Explicitly pricing out activities like cartons delivered and shelf‐ stocking so that customers pay for the costs they cause. Restricting options available to certain customers, e.g., customers with low revenue could be restricted to one free delivery per week. An even more extreme example is working with customers so that deliveries are easier to make and shelf‐stocking can be done faster. d. Offer salespeople bonuses based on the operating income of each customer rather than the gross margin of each customer. Some students will argue that the bottom 40% of the customers should be dropped. This action should be only a last resort after all other avenues have been explored. Moreover, an unprofitable customer today may well be a profitable customer tomorrow, and it is myopic to focus on only a 1‐month customer‐profitability analysis to classify a customer as unprofitable.
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Chapter 16
PROBLEMS
16‐24 (15‐20 min.) Customer profitability, responsibility for environmental cleanup, 1.
2.
governance. Customer‐profitability analysis examines how individual customers differ in their profitability. The revenue and costs of each customer can be estimated with varying degrees of accuracy. Revenue of IF typically would be known at the time of sale. Many costs also would be known, e.g., the cost of materials used to manufacture the fluids sold to each customer. A major area of uncertainty is future costs associated with obligations arising from the sale. There are several issues here: (a) Uncertainty as to the existence and extent of legal liability. Each customer has primary responsibility to dispose of its own toxic waste. Papandopolis needs to determine the extent of IFL’s liability. It would be necessary to seek legal guidance on this issue. (b) Uncertainty as to when the liability will occur. The further in the future, the lower the amount of the liability (assuming discounting for the time value of money occurs.) (c) Uncertainty as to the amount of the liability given that the liability exists and the date of the liability can be identified. Papandopolis faces major difficulties here—see the answer to requirement 2. Many companies argue that uncertainties related to (a), (b), and (c) make the inclusion of “hard‐dollar estimates meaningless.” However, at a minimum, a contingent liability should be recognized and included in the internal customer‐ profitability reports. Papandopolis’ controller may believe that if estimates of future possible legal exposure are sufficiently uncertain they should not be recorded. His concern about “smoking guns” may have a very genuine basis—that is, if litigation arises, third parties may misrepresent Papandopolis’ concerns to the detriment of IFL. Any written comments that she makes may surface 5 or 10 years later and be interpreted as “widespread knowledge” within IF that they have responsibility for large amounts of environmental clean‐up. Given this background, Papandopolis still has the responsibility to prepare a report in an objective and competent way. Moreover, she has visited 10 customer sites and has details as to their toxic‐waste‐handling procedures. If Acme goes bankrupt and has no liability insurance, one of the “deep pockets” available to meet toxic‐waste‐handling costs is likely to be IFL. At a minimum, she should report the likely bankruptcy and the existence of IFL’s contingent liability for toxic‐waste clean‐ up in her report. Whether she quantifies this contingent liability is a more difficult question. Papandopolis has limited information available to make a meaningful quantification. She is not an employee of Acme Metal and has no information about Acme’s liability insurance. Moreover, she does not know what other parties (such as other suppliers) are also jointly liable to pay Acme’s clean‐up costs. The appropriate course appears to be to highlight the contingent liability but not to attempt to quantify it.
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16‐25 (30‐40 min.) Revenue allocation, bundled products. 1.
Royalties on individual sales SuperAbs ($42 27,000 0.15)
2.
$170,100
SuperArms ($37 53,000 0.25)
490,250
SuperLegs ($27 20,000 0.18)
97,200
(a) Stand‐alone revenue allocation method. SuperAbs + SuperArms $32.96a 18,000 0.15 $29.04b 18,000 0.25 SuperAbs + SuperLegs $32.87c 6,000 0.15 $21.13d 6,000 0.18 SuperArms + SuperLegs $25.44e 11,000 0.25 $18.56f 11,000 0.18 SuperAbs + SuperArms + SuperLegs $26.55g 22,000 0.15 $23.39h 22,000 0.25 $17.06i 22,000 0.18
SuperAbs SuperArms SuperLegs $88,992
$130,680
29,583
$22,820
69,960
36,749
87,615 $206,190
128,645 $329,285
67,558 $127,127
(42/(42 + 37)) $62 (37/(42 + 37)) $62 c(42/(42 + 27)) $54 d(27/(42 + 27)) $54 e(37/(37 + 27)) $44 f(27/(37 + 27)) $44 g(42/(42 + 37 + 27)) $67 h(37/(42 + 37 + 27)) $67 i(27/(42 + 37 + 27)) $67 a
b
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= $32.96 = 29.04 = 32.87 = 21.13 = 25.44 = 18.56 = 26.55 = 23.39 = 17.06
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Chapter 16
16‐25 (cont’d) (b) Incremental revenue allocation method SuperAbs SuperArms SuperLegs SuperAbs + SuperArms $25a 18,000 0.15 $67,500 $37a 18,000 0.25 $166,500 SuperAbs + SuperLegs $42 6,000 0.15 37,800 $12 6,000 0.18 $12,960 SuperArms + SuperLegs $37 11,000 0.25 101,750 $ 7 11,000 0.18 13,860 SuperAbs + SuperArms + SuperLegs $30 22,000 0.15 99,000 $37 22,000 0.25 203,500 $ 0 22,000 0.18 0 $204,300 $471,750 $26,820 a. b. c. d. 3.
SuperArms SuperAbs SuperAbs SuperLegs SuperArms SuperLegs SuperArms SuperAbs SuperLegs
$37 $25 ($62 – $37) $42 $12 ($54 – $42) $37 $7 ($44 – $37) $37 $30 ($67 – $37) $0
The pros of the stand‐alone revenue allocation method include: (a) Each item in the bundle receives a positive weight, which means the resulting allocations are more likely to be accepted by all parties than a method allocating zero revenue to one or more products. (b) Uses market‐based evidence (unit selling prices) to decide the revenue allocations—unit prices are one indicator of benefits received. (c) Simple to implement.
The cons of the stand‐alone revenue allocation method include: (a) Ignores the relative importance of the individual components in attracting consumers to purchase the bundle.
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16‐25 (cont’d) (b) Ignores the opportunity cost of the individual components in the bundle. If there was a shortage of (say) SuperArms DVDs, the manager of SuperArms is better off by selling the DVD on its own. The pros of the incremental method include: (a) It has the potential to reflect that some products in the bundle are more highly valued than others. Not all products in the bundle have a similar “write‐down” from unit list prices. Ensuring this “potential pro” becomes an “actual pro” requires that the choice of the primary product be guided by reliable evidence on consumer preferences. This is not an easy task. (b) Once the sequence is chosen, it is straightforward to implement. The cons of the incremental method include: (a) Obtaining the rankings can be highly contentious and place managers in a “no‐ win” acrimonious debate. The revenue allocations can be highly sensitive to the chosen rankings. (b) Some products will have zero revenue assigned to them. The SuperLegs DVD in the three‐DVD package illustrates this con. 4.
(a) Rank on consumer preferences. (b) Rank on total stand‐alone revenue of products included in the bundle. (c) Rank on age of the products where the newest product receives the first (primary) rank. The assumption here is that older products are likely to be already purchased and what the new bundled package provides is an updated version of these older products as opposed to a new separate product.
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Chapter 16
16‐26 (40 min.) Customer profitability, distribution. 1.
P $29,952
a
Revenue at list prices
Customer Q R S $126,000 $875,520 $457,920
T $56,160
0
2,100
72,960
15,264
5,616
29,952 24,960 4,992
123,900 105,000 18,900
802,560 729,600 72,960
442,656 381,600 61,056
50,544 46,800 3,744
1,500
2,500
3,000
2,500
3,000
160
240
480
160
240
Delivery vehicles
280
240
360
640
1,600
g
1,040
4,375
30,400
15,900
1,950
0
0
0
0
300
2,980 $ 2,012
7,355 $ 11,545
34,240 $ 38,720
b
Discount Revenue (at actual prices) c
Cost of goods sold Gross margin Customer‐level operating costs d
Order taking e
Customer visits f
Product handling h
Expedited runs Total Customer‐level operating income
19,200 7,090 $ 41,856 $ (3,346)
a
$14.40 2,080; 8,750; 60,800; 31,800; 3,900
($14.40 – $14.40) 50,000; ($14.40 – $14.16) 8,750; ($14.40 – $13.20) 60,800; ($14.40 – $13.92) 31,800; ($14.40 – $12.96) 3,900 b
c
$12 2,080; 8,750; 60,800, 31,800; 3,900 $100 15; 25; 30; 25; 30
d
$80 2; 3; 6; 2; 3
e f
$2 (10 14); (30 4); (60 3); (40 8); (20 40) $0.50 2,080; 8,750; 60,800; 31,800; 3,900
g
$300 0; 0; 0; 0; 1
h
Customer S is the most profitable customer, despite having only 52% (31,800 60,800) of the unit volume of Customer R. A major explanation is that Customer R receives a $1.20 discount per case while Customer S receives only a $0.48 discount per case. Customer T is unprofitable, while the smaller customer P is profitable. Customer T receives a $1.44 discount per case, makes more frequent orders, requires more customer visits, and requires more delivery miles than Customer P.
16‐26 (cont’d)
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2.
Separate reporting of both the list selling price and the actual selling price enables Spring Distribution to examine which customers receive different discounts and how salespeople may differ in the discounts they grant. There is a size pattern in the discounts across the five customers, except for Customer T, larger volume customers get larger discounts: Discount per case Sales Volume R (60,800 cases) $1.20 S (31,800 cases) $0.48 Q (8,750 cases) $0.24 T (3,900 cases) $1.44 P (2,080 cases) $0.00
The reasons for the $1.44 discount for T should be explored. 3.
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Dropping customers should be the last resort taken by Spring Distribution. Factors to consider include the following: a. What is the expected future profitability of each customer? Are the currently unprofitable (T) or low‐profit (P) customers likely to be highly profitable in the future? b. Are there externalities from having some customers, even if they are unprofitable in the short run? For example, some customers have a marquee‐value that is “in effect” advertising that benefits the business. c. What costs are avoidable if one or more customers are dropped? d. Can the relationship with the “problem” customers be restructured so that there is a “win‐win” situation? For example, could Customer T get by with fewer deliveries per month?
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Chapter 16
16‐27 (60 min.) Variance analysis, sales‐mix, and sales‐quantity variances. 1.
Actual Contribution Margins Actual Sales Volume in Units 11,000 44,000 55,000 110,000
Actual Actual Actual Variable Contribution Actual Actual Selling Cost per Margin per Contribution Contribution Product Price Unit Unit Dollars Percent Palm Pro $349 $178 $171 $ 1,881,000 16% Palm CE 285 92 193 8,492,000 71% 1,595,000 13% PalmKid 102 73 29 $11,968,000 100% The actual average contribution margin per unit is $108.80 ($11,968,000 110,000 units).
Budgeted Contribution Margins Budgeted Budgeted Budgeted Budgeted Variable Contribution Sales Budgeted Selling Cost per Margin per Volume in Contribution Product Price Unit Unit Units Dollars Palm Pro $379 $182 $197 12,500 $ 2,462,500 Palm CE 269 98 171 37,500 6,412,500 4,200,000 Palm Kid 149 65 84 50,000
Budgeted Contribution Percent 19% 49% 32%
100,000 $13,075,000 100% The budgeted average contribution margin per unit is $130.75 ($13,075,000 100,000 units). 2. Actual Sales Mix Actual Sales Volume Actual Product in Units Sales Mix Palm Pro 11,000 10.0% (11,000 ÷ 110,000) Palm CE 44,000 40.0% (44,000 ÷ 110,000) Palm Kid 55,000 50.0% (55,000 ÷ 110,000) 110,000 100.0%
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16‐27 (cont’d)
Product Palm Pro Palm CE Palm Kid 3.
Budgeted Sales Mix Budgeted Sales Volume in Budgeted Units Sales Mix 12,500 12.5% (12,500 ÷ 100,000) 37,500 37.5% (37,500 ÷ 100,000) 50.0% (50,000 ÷ 100,000) 50,000 100,000 100.0%
Sales‐volume variance: Budgeted Budgeted Actual = quantity of quantity of contribution margin units sold units sold per unit
PalmPro (11,000 12,500) × $197 $ 295,500 U PalmCE (44,000 37,500) × $171 1,111,500 F PalmKid (55,000 50,000) × $ 84 420,000 F Total sales‐volume variance $1,236,000 F Sales‐mix variance: Actual units Budgeted Budgeted Actual = of all × sales mix sales mix × contrib. margin products sold percentage percentage per unit $541,750 U PalmPro = 110,000 × (0.10 0.125) × $197 PalmCE = 110,000 × (0.40 0.375) × $171 470,250 F PalmKid = 110,000 × (0.50 0.50) × $ 84 0 F Total sales‐mix variance $ 71,500 U Sales‐quantity variance: Budgeted Budgeted units Budgeted Actual units × sales mix × contrib. margin = of all of all products sold products sold percentage per unit $ 246,250 F PalmPro (110,000 100,000) × 0.125 × $197 PalmCE (110,000 100,000) × 0.375 × $171 641,250 F 420,000 F PalmKid (110,000 100,000) × 0.500 × $ 84 Total sales‐quantity variance $1,307,500 F 16–788
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Chapter 16
16‐27 (cont’d) Solution Exhibit 16‐27 presents the sales‐volume variance, the sales‐mix variance, and the sales‐quantity variance for Palm Pro, Palm CE, and PalmKid and in total for the third quarter 2013. SOLUTION EXHIBIT 16‐27 Sales‐Mix and Sales‐Quantity Variance Analysis of Aussie Infonautics for the Third Quarter 2013.
Flexible Budget: Actual Units of All Products Sold Actual Sales Mix Budgeted Contribution Margin Per Unit
Actual Units of All Products Sold Budgeted Sales Mix Budgeted Contribution Margin Per Unit
Static Budget: Budgeted Units of All Products Sold Budgeted Sales Mix Budgeted Contribution Margin Per Unit
Palm Pro 110,000 0.10 $197 =$ 2,167,000 110,000 0.125 $197 =$ 2,708,750 100,000 0.125 $197 =$ 2,462,500 PalmCE 110,000 0.40 $171 = 7,524,000 110,000 0.375 $171 = 7,053,750 100,000 0.375 $171 = 6,412,500 PalmKid 110,000 0.50 $ 84 = 4,620,000 110,000 0.50 $ 84 = 4,620,000 100,000 0.50 $ 84 = 4,200,000 $14,311,000 $14,382,500 $13,075,000
$71,500 U
$1,307,500 F
Sales‐mix variance
Sales‐quantity variance
$1,236,000 F Sales‐volume variance
F = favourable effect on operating income; U= unfavourable effect on operating income
4.
The following factors help us understand the differences between actual and budgeted amounts: The difference in actual versus budgeted contribution margins was $1,107,000 unfavourable ($11,968,000 $13,075,000). However, the contribution margin from the PalmCE exceeded budget by $2,079,500 ($8,492,000 $6,412,500) while the contributions from the PalmPro and the PalmKid were lower than expected and offset this gain. This is attributable to lower unit sales in the case of PalmPro and lower contribution margins in the case of PalmKid. In percentage terms, the PalmCE accounted for 71% of actual contribution margin versus a planned 49% contribution margin. However, the PalmPro accounted for 16% versus planned 19% and the PalmKid accounted for only 13% versus a planned 32%.
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16‐27 (cont’d)
In unit terms (rather than in contribution terms), the PalmKid accounted for 50% of the sales mix as planned. However, the PalmPro accounted for only 10% versus a budgeted 12.5% and the PalmCE accounted for 40% versus a planned 37.5%. Variance analysis for the PalmPro shows an unfavourable sales‐mix variance outweighing a favourable sales‐quantity variance and producing an unfavourable sales‐volume variance. The drop in sales‐mix share was far larger than the gain from an overall greater quantity sold. The PalmCE gained both from an increase in share of the sales mix as well as from the increase in the overall number of units sold. The PalmKid maintained sales‐mix share at 50%––as a result, the sales‐mix variance is zero. However, PalmKid sales gained from the overall increase in units sold. Overall, there was a favourable total sales‐volume variance. However, the large drop in PalmKid’s contribution margin per unit combined with a decrease in the actual number of PalmPro units sold as well as a drop in the actual contribution margin per unit below budget, led to the total contribution margin being much lower than budgeted.
Other factors could be discussed here––for example, it seems that the PalmKid did not achieve much success with a three digit price point––selling price was budgeted at $149 but dropped to $102. At the same time, variable costs increased. This could have been due to a marketing push that did not succeed.
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Chapter 16
16‐28
(20 min.) Market‐share and market‐size variances.
1. Worldwide Aussie Info. Market share
Actual Budgeted 500,000 400,000 110,000 100,000 22% 25%
Average contribution margin per unit: Actual = $108.80 ($11,968,000 110,000) Budgeted = $130.75 ($13,075,000 100,000)
Budgeted Actual Budgeted contribution margin market market per composite unit share share for budgeted mix = 500,000 (0.22 – 0.25) $130.75 = 500,000 (–0.03) $130.75 = $1,961,250 U
Actual Market-share market size = variance in units
Market-size variance
=
Budgeted Actual market size market size in units in units
Budgeted Budgeted contribution margin market per composite unit share for budgeted mix
= (500,000 – 400,000) 0.25 $130.75 = 100,000 0.25 $130.75 = $3,268,750 F
Solution Exhibit 16‐28 presents the market‐share variance, the market‐size variance, and the sales‐quantity variance for the third quarter 2013.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
SOLUTION EXHIBIT 16‐28 Market‐Share and Market‐Size Variance Analysis of Aussie Infonautics for the Third Quarter 2013.
Actual Market Size Actual Market Share Budgeted Average Contribution Margin Per Unit 500,000 0.22a $130.75b $14,382,500
Static Budget: Actual Market Size Budgeted Market Size Budgeted Market Share Budgeted Market Share Budgeted Average Budgeted Average Contribution Margin Contribution Margin Per Unit Per Unit 500,000 0.25c $130.75 b 400,000 0.25c $130.75b $16,343,750 $13,075,000
$1,961,250 U
$3,268,750 F
Market‐share variance
Market‐size variance
$1,307,500 F
Sales‐quantity variance
F = favourable effect on operating income; U = unfavourable effect on operating income
Actual market share: 110,000 units ÷ 500,000 units = 0.22, or 22% bBudgeted average contribution margin per unit $13,075,000 ÷ 100,000 units = $130.75 per unit cBudgeted market share: 100,000 units ÷ 400,000 units = 0.25, or 25% 2. While the market share declined (from 25% to 22%), the overall increase in the total market size meant a favourable sales‐quantity variance: Sales‐Quantity Variance $1,307,500 F a
Market‐Share Variance $1,961,250 U
Market Size Variance $3,268,750 F
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Chapter 16
16‐28 (cont’d) 3.
The required actual market size is the budgeted market size, i.e., 400,000 units. This can easily be seen by setting up the following equation:
Budgeted Budgeted Budgeted Actual Market - size market size market size market contribution margin variance per composite unit in units in units share for budgeted mix = (M – 400,000) × 0.25 × $130.75
When M = 400,000, the market‐size variance is $0. Actual Market‐Share Calculation Again, the answer is the budgeted market share, 25%. By definition, this will hold irrespective of the actual market size. This can be seen by setting up the appropriate equation: Budgeted Actual Actual Budgeted contribution margin Market-share market size = market market per composite unit variance share share in units for budgeted mix = Actual market size × (M – 25%) × $130.75 When M = 25%, the market‐share variance is $0.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
16‐29 (40 min.) Variance analysis, multiple products. 1, 2, and 3. Solution Exhibit 16‐29 presents the sales‐volume, sales‐quantity, and sales‐ mix variances for each type of cookie and in total for Debbie’s Delight, Inc., in August 2013. The sales‐volume variances can also be computed as Sales-volume = Actual quantity Budgeted quantity × Budgeted contribution margin per pound of pounds sold of pounds sold variance The sales‐volume variances are Chocolate chip = (57,600 – 45,000) $2.00 = $25,200 F Oatmeal raisin = (18,000 – 25,000) $2.30 = 16,100 U Coconut = (9,600 – 10,000) $2.60 = 1,040 U White chocolate = (13,200 – 5,000) $3.00 = 24,600 F Macadamia nut = (21,600 – 15,000) $3.10 = 20,460 F All cookies $53,120 F The sales‐quantity variance can also be computed as Budgeted Budgeted Actual pounds Budgeted pounds Sales-volume = of all cookies of all cookies sales-mix contribution variance percentage margin per pound sold sold The sales‐quantity variances are Chocolate chip = (120,000 – 100,000) 0.45 $2.00 = $18,000 F Oatmeal raisin = (120,000 – 100,000) 0.25 $2.30 = 11,500 F 5,200 F Coconut = (120,000 – 100,000) 0.10 $2.60 = White chocolate = (120,000 – 100,000) 0.05 $3.00 = 3,000 F Macadamia nut = (120,000 – 100,000) 0.15 $3.10 = 9,300 F All cookies $47,000 F The sales‐mix variance can also be computed as: Actual pounds Budgeted Sales-quantity = Actual sales- Budgeted sales- of all cookies contribution mix percentage mix percentage variance sold margin per pound
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Chapter 16
16‐29 (cont’d) The sales‐mix variances are: = $ 7,200 F Chocolate chip = (0.48 – 0.45) 120,000 $2.00 Oatmeal raisin = (0.15 – 0.25) 120,000 $2.30 = 27,600 U = 6,240 U Coconut = (0.08 – 0.10) 120,000 $2.60 White chocolate = (0.11 – 0.05) 120,000 $3.00 = 21,600 F Macadamia nut = (0.18 – 0.15) 120,000 $3.10 = 11,160 F All cookies $ 6,120 F A summary of the variances is: Sales‐Volume Variance Chocolate chip $25,200 F Oatmeal raisin 16,100 U Coconut 1,040 U White chocolate 24,600 F Macadamia nut 20,460 F All cookies $53,120 F Sales‐Quantity Variance Sales‐Mix Variance Chocolate chip $ 7,200 F Chocolate chip $18,000 F Oatmeal raisin 27,600 U Oatmeal raisin 11,500 F Coconut 6,240 U Coconut 5,200 F White chocolate 21,600 F White chocolate 3,000 F Macadamia nut 11,160 F Macadamia nut 9,300 F All cookies $ 6,120 F All cookies $47,000 F 4. Debbie’s Delight shows a favourable sales‐quantity variance because it sold more cookies in total than was budgeted. Together with the higher quantities, Debbie’s also sold more of the high‐contribution margin white chocolate and macadamia nut cookies relative to the budgeted mix––as a result, Debbie’s also showed a favourable total sales‐mix variance.
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SOLUTION EXHIBIT 16‐29 Columnar Presentation of Sales‐Volume, Sales‐Quantity, and Sales‐Mix Variances for Debbie’s Delight, Inc. Flexible Budget: Static Budget: Actual Pounds of Actual Pounds of Budgeted Pounds of All Cookies Sold All Cookies Sold All Cookies Sold × Actual Sales Mix × Budgeted Sales Mix × Budgeted Sales Mix × Budgeted × Budgeted × Budgeted Contribution Margin Contribution Margin Contribution Margin per Pound per Pound per Pound (1) (2) (3) Panel A: Chocolate a b b Chip (120,000 × 0.48 ) × $2 (120,000 × 0.45 ) × $2 (100,000 × 0.45 ) × $2 57,600 × $2 54,000 × $2 45,000 × $2 $115,200 $108,000 $90,000 $7,200 F $18,000 F Sales-mix variance Sales-quantity variance $25,200 F Sales-volume variance Panel B: c d d Oatmeal Raisin (120,000 × 0.15 ) × (120,000 × 0.25 ) × (100,000 × 0.25 ) × $2.30
16–796
$2.30 18,000 × $2.30 $41,400
$2.30 30,000 × $2.30 $69,000
$27,600 U Sales-mix variance
25,000 × $2.30 $57,500
$11,500 F Sales-quantity variance
$16,100 U Sales-volume variance
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Chapter 16
16‐29 (cont’d)
Panel C: (120,000 × 0.08 ) × (120,000 × 0.10 ) × f $2.60 $2.60 Coconut (100,000 × 0.10 ) × $2.60 9,600 × $2.60 12,000 × $2.60 10,000 × $2.60 $24,960 $31,200 $26,000 $6,240 U $5,200 F Sales-mix variance Sales-quantity variance $1,040 U Sales-volume variance F = favourable effect on operating income; U = unfavourable effect on operating income. e
Actual Sales Mix: a c
Chocolate Chip = 57,600 ÷ 120,000 = 48%
Coconut
Panel D: White Chocolate
Budgeted Sales Mix:
Oatmeal Raisin = 18,000 ÷ 120,000 = 15%
e
f
= 9,600 ÷ 120,000 = 8%
b
d
Oatmeal Raisin = 25,000 ÷ 100,000 = 25%
f
= 10,000 ÷ 100,000 = 10%
Chocolate Chip = 45,000 ÷ 100,000 = 45% Coconut
Flexible Budget: Actual Pounds of All Cookies Sold × Actual Sales Mix × Budgeted Contribution Margin per Pound (1)
Actual Pounds of All Cookies Sold × Budgeted Sales Mix × Budgeted Contribution Margin per Pound (2)
Static Budget: Budgeted Pounds of All Cookies Sold × Budgeted Sales Mix × Budgeted Contribution Margin per Pound (3)
(120,000 × 0.11g) × $3.00 13,200 × $3.00 $39,600
(120,000 × 0.05h) × $3.00 6,000 × $3.00 $18,000
(100,000 × 0.05h) × $3.00 5,000 × $3.00
$21,600 F Sales-mix variance
$15,000
$3,000 F Sales-quantity variance
$24,600 F Sales-volume variance
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
16‐29 (cont’d) Panel E: Macadamia Nut
j
(120,000 × 0.18 ) × $3.10 21,600 × $3.10 $66,960
k
(120,000 × 0.15 ) × $3.10 18,000 × $3.10 $55,800
k
(100,000 × 0.15 ) × $3.10 15,000 × $3.10 $46,500
$9,300 F Sales-quantity variance
$11,160 F Sales-mix variance
$20,460 F Sales-volume variance
Panel F: All Cookies
l
m
$288,120
$282,000
$6,120 F Total sales-mix variance
n $235,000
$47,000 F Total sales-quantity variance
$53,120 F Total sales-volume variance
F = favourable effect on operating income; U = unfavourable effect on operating income. Actual Sales Mix:
Budgeted Sales Mix:
g
White Chocolate = 13,200 ÷ 120,000 = 11%
j
Macadamia Nut = 21,600 ÷ 120,000 = 18%
l
$115,200 + $41,400 + $24,960 + $39,600 + $66,960 = $288,120
h
m
White Chocolate = 5,000 ÷ 100,000 = 5%
k
Macadamia Nut = 15,000 ÷ 100,000 = 15%
$108,000 + $69,000 + $31,200 + $18,000 + $55,800 = $282,000 n$90,000 + $57,500 + $26,000 + $15,000 + $46,500 = $235,000
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Chapter 16
16‐30 (15 min.) Market‐share and market‐size variances.
Chicago Market Debbieʹs Market share
Actual 960,000 120,000 0.125
Budgeted 1,000,000 100,000 0.100
The budgeted average contribution margin per unit (also called budgeted contribution margin per composite unit for budgeted mix) is $2.35: Budgeted Budgeted Budgeted Contribution Sales Contribution Margin Margin per Volume Pound in Pounds $2.00 45,000 Chocolate chip $ 90,000 Oatmeal raisin 2.30 25,000 57,500 Coconut 2.60 10,000 26,000 3.00 5,000 White 15,000 chocolate 3.10 15,000 46,500 Macadamia nut 100,000 $235,000 All cookies $235,000 = = $2.35 100,000 Budgeted Budgeted Budgeted Market‐size Actual average variance in = market size – market size × market × contrib. margin in units share contribution margin in units per unit = (960,000 – 1,000,000) × 0.100 × $2.35 = $9,400 U Budgeted Market‐share Actual Actual Budgeted average variance in = market size × market – market × contrib. margin contribution margin in units share share per unit = 960,000 × (0.125 – 0.100) × $2.35 = $56,400 F
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16‐30 (cont’d) By increasing its actual market share from the 10% budgeted to the actual 12.50%, Debbie’s Delight has a favourable market‐share variance of $56,400. There is a smaller offsetting unfavourable market‐size variance of $9,400 due to the 40,000 unit decline in the Chicago market (from 1,000,000 budgeted to an actual of 960,000). Solution Exhibit 16‐30 presents the sales‐quantity, market‐share, and market‐size variances for Debbie’s Delight, Inc., in August 2013. SOLUTION EXHIBIT 16‐30 Market‐Share and Market‐Size Variance Analysis of Debbie’s Delight for August 2013 Static Budget: Actual Market Size Actual Market Size Budgeted Market Size Actual Market Share Budgeted Market Share Budgeted Market Share Budgeted Average Budgeted Average Budgeted Average Contribution Margin Contribution Margin Contribution Margin Per Unit Per Unit Per Unit a b c b 960,000 0.125 $2.35 960,000 0.10 $2.35 1,000,000 0.10c $2.35b $282,000 $225,600 $235,000
$56,400 F
$9,400 U
Market‐share variance
Market‐size variance
$47,000 F
Sales‐quantity variance
F = favourable effect on operating income; U = unfavourable effect on operating income
Actual market share: 120,000 units ÷ 960,000 units = 0.125, or 12.5% Budgeted average contribution margin per unit: $235,000 ÷ 1,000,000 units = $2.35 per unit cBudgeted market share: 100,000 units ÷ 1,000,000 units = 0.10, or 10% a
b
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Chapter 16
16‐30 (cont’d) An overview of Problems 16‐29 and 16‐30 is: Sales-Volume Variance $53,120 F Sales-Mix Variance Sales-Quantity Variance $6,120 F $47,000 F Market-Share Variance Market-Size Variance $56,400 F $9,400 U 16‐31 (20 min.) Relevance, quantitative and qualitative. The future outlay of operating costs will be $400 million regardless of which base is closed, since there will be an additional $100 million in costs at Halifax if Vancouver is closed. Further one of the bases will remain open permanently, while the other will be shut down. The only relevant revenue and cost comparisons are: (a) $500 million from sale of the Vancouver base. Note that the historical cost of building the Vancouver base ($100 million) is irrelevant. Note also that future increases in the value of the land at the Vancouver base are also irrelevant. One of the bases must be kept open, so, if it is decided that the Vancouver base is to be kept open, National Defence will not be able to sell this land at a future date. (b) $60 million in savings in fixed income note if the Halifax base is closed. Again, the historical cost of building the Halifax base ($150 million) is irrelevant. The relevant costs and benefits analysis favours closing the Vancouver base despite the objections raised by the British Columbia delegation. The net benefit equals $440 ($500 – $60) million.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
16‐32 (40 min.) Customer loyalty clubs and profitability analysis. 1. Gold Program Revenue 2,673 20 ($200 0.90) 2,673 30 ($200 0.80) 2,673 10 ($200 0.70) Total revenue Variable Costs Hotel variable costs, 2,673 60 $65 Wine Costs 2,673 50 $5 2,673 10 $20 Restaurant costs 2,673 20 $10 2,673 30 $15 2,673 10 $20 Total variable costs Contribution margin Silver Program Revenue 9,174 20 ($200 0.90) 9,174 15 ($200 0.80) Total revenue Variable Costs Hotel variable costs, 9,174 35 $65 Wine costs, 9,174 35 $5 Restaurant Costs 9,174 20 $10 9,174 15 $15 Total variable costs Contribution margin Bronze Program Revenue, 88,330 10 ($200 0.90) Variable costs Hotel variable costs, 88,330 10 $65 Wine costs 88,330 10 $5 Restaurant costs 88,330 10 $10 Total variable costs Contribution margin 16–802
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$ 9,622,800 12,830,400 3,742,200 26,195,400 10,424,700 668,250 534,600 534,600 1,202,850 534,600 13,899,600 $12,295,800
$33,026,400 22,017,600 55,044,000 20,870,850 1,605,450 1,834,800 2,064,150 26,375,250 $28,668,750 $158,994,000 57,414,500 4,416,500 8,833,000 70,664,000 $ 88,330,000
Chapter 16
16‐32 (cont’d) No Program Revenue, 240,900 1 $200 Variable costs, 240,900 1 $65 Contribution margin
$48,180,000 15,658,500 $32,521,500
Loyalty Total Variable Contribution Contrib. Margin/ Program Revenue Costs Margin Total Revenue Gold $ 26,195,400 $ 13,899,600 $ 12,295,800 46.94% Silver 55,044,000 26,375,250 28,668,750 52.08 Bronze 158,994,000 70,664,000 88,330,000 55.56 No program 48,180,000 15,658,500 32,521,500 67.50 Total $288,413,400 $126,597,350 $161,816,050 The no‐program group of customers has the highest contribution margin per revenue dollar. However, it comprises only 16.71% ($48,180,000 ÷ $288,413,000) of total revenue. The gold program has the lowest contribution margin per revenue dollar. However, it is misleading to evaluate each program in isolation. A key aim of loyalty programs is to promote a high frequency of return business. The contribution margin to total revenue ratio of each program in isolation does not address this issue. 2. Revenue $288,413,400 Variable costs 126,597,350 Contribution margin 161,816,050 Fixed costs 140,580,000 Operating income $ 21,236,050 3. Number of room nights 160,380 Gold, 2,673 60 Silver, 9,174 35 321,090 Bronze, 88,330 10 883,300 No program, 240,900 1 240,900 1,605,670 $288, 413, 400 Average room rate per night: $179.62 1, 605, 670 Average variable cost per night:
$126, 597, 350 $78.84 1, 605, 670
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
16‐32 (cont’d) 4.
Sherriton Hotels has fixed costs of $140,580,000. A key challenge is to attract a high number of repeat business customers. Loyalty programs aim to have customers return to Sherriton multiple times. Their aim is increasing the revenue beyond what they would be without the program. It is to be expected that the higher the level of nights stayed, the greater the inducements necessary to keep attracting the customer to return. However, given the low level of variable costs to room rates, there is a considerable cushion available for Sherriton to offer high inducements for frequent stayers. Sherriton could adopt a net present value analysis of customers who are in the different loyalty clubs. It would be informative for Sherriton to have information on how much of each customer’s total lodging industry expenditures it captures. It may well want to give higher levels of inducements to frequent stayers if the current program attracts only, say, 30% of each of its frequent customers’ total business in cities where it has lodging properties available.
16‐33 (30 min.) Customer profitability, customer‐cost hierarchy. 1. All amounts in thousands of U.S. dollars Wholesale Retail North America South America Big Sam World Wholesaler Wholesaler Stereo Market Revenue at list prices $420,000 $580,000 $130,000 $100,000 Price discounts 30,000 40,000 7,000 500 Revenue (at actual prices) 390,000 540,000 123,000 99,500 455,000 118,000 90,000 Cost of goods sold 325,000 Gross margin 65,000 85,000 5,000 9,500 Customer‐level operating costs Delivery 450 650 200 125 Order processing 800 1,000 200 130 5,500 2,300 1,350 Sales visit 5,600 Total cust.‐level optg.costs 6,850 7,150 2,700 1,605 Customer‐level operating income $ 58,150 $ 77,850 $ 2,300 $ 7,895
16–804
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Chapter 16
16‐33 (cont’d) 2.
Revenue (at actual prices) Customer‐level costs Customer‐level operating income Distribution‐channel costs Distribution‐channel‐ level operating income Corporate‐sustaining costs Operating income
Total $1,152,500 1,006,305
Customer Distribution Channels (All amounts in thousands of dollars) Wholesale Customers Retail Customers North South America America Big Sam World Total Wholesaler Wholesaler Total Stereo Market $930,000 $390,000 $540,000 $222,500 $123,000 $99,500 794,000 331,850 462,150 212,305 120,700 91,605
146,195 45,000
136,000 38,000
$ 58,150
$77,850
10,195 7,000
101,195 65,000 $ 36,195
$98,000
$ 3,195
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$ 2,300
$ 7,895
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
16‐33 (cont’d.) 3.
16–806
If corporate costs are allocated to the channels, the retail channel will show an operating loss of $10,805,000 ($3,195,000 – $14,000,000), and the wholesale channel will show an operating profit of $47,000,000 ($98,000,000 – $51,000,000). The overall operating profit, of course, is still $36,195,000, as in requirement 2. There is, however, no cause‐and‐effect or benefits‐received relationship between corporate costs and any allocation base, i.e., the allocation of $51,000,000 to the wholesale channel and of $14,000,000 to the retail channel is arbitrary and not useful for decision‐making. Therefore, the management of Ramish Electronics should not base any performance evaluations or investment/disinvestment decisions based on these channel‐level operating income numbers. They may want to take corporate costs into account, however, when making pricing decisions.
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Chapter 16
16‐34
Customer profitability in a manufacturing firm.
1. Calculation of customer profitability by customer: Customer A B C Revenue at list price $100 × 5,000; 2,400; 1,200; 4,000; 8,000 $500,000 $240,000 $120,000 Price discount 10% × $500,000; 0; 10% × $120,000; 0; 10% × $400,000 50,000 0 12,000 Revenue (actual price) 450,000 240,000 108,000 Cost of goods sold 400,000 192,000 96,000 $80 × 5,000; 2,400, 1,200; 4,000; 8,000 Gross margin 50,000 48,000 12,000 Customer‐level costs: Order taking 3,800 4,560 18,240 $380 × 10; 12; 48; 16; 12 Product handling 5,000 2,400 1,440 $10 × 500; 240; 144; 400; 812 Warehousing 715 880 0 $55 × 13; 16; 0; 12; 120 Rush order processing $520 × 0; 2; 0; 0; 5 0 1,040 0 Exchange and repair $40 × 0; 30; 5; 20; 95 0 1,200 200 Total customer‐level costs 9,515 10,080 19,880 Customer‐level operating income $ 40,485 $ 37,920 $ (7,880)
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D
E
$400,000 $800,000 0 400,000
40,000 760,000
320,000 640,000 80,000 120,000
6,080
4,560
4,000
8,120
660
6,600
0
2,600
800 3,800 11,540 25,680 $ 68,460 $ 94,320
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
16‐34 (cont’d) Customer ranking
Customer‐ Level Operating Customer Income Code (1)
Customer Revenue (2)
Cumulative Customer‐Level Cumulative Customer‐Level Operating Customer‐ Operating Income Income Level as a % of Total Divided by Operating Customer‐Level Revenue Income Operating Income (3) = (1) ÷ (2) (4) (5) = (4) ÷ $233,305 $ 94,320
40.4%
E
$ 94,320
$ 760,000
12.4%
D
68,460
400,000
17.1%
$162,780
69.8%
A
40,485
450,000
9.0%
$203,265
87.1%
B
37,920
240,000
15.8%
$241,185
103.4%
C
(7,880)
108,000
‐7.3%
$233,305
100.0%
$1,958,000
Total $233,305
2.
16–808
Customer C is Bizzan’s only unprofitable customer. All other customers are profitable in line with revenue, except customer A which has more revenue than D but less operating income. If Customer C were not being given price discounts, C would be profitable. The salesperson is giving discounts on orders, even though the size of the order is small. It is costing Bizzan money to process many small orders as opposed to a few large orders. To turn Customer C into a profitable customer, Bizzan needs to encourage Customer C to place fewer, larger orders and offer a price discount only if Customer C changes behaviour, rather than as a reward for repeat business. Customer A has many rush orders in proportion to total number of orders. Bizzan should work with Customer A to find a production schedule that would meet its needs without having to rush the order. Customer E has high warehousing needs that are costly to Bizzan. Bizzan should work with Customer E to align its production schedule to Customer E’s needs. The exchange and repair rate for customers with rush orders is higher than for other customers. Bizzan should explore whether rushing an order reduces attention to quality. Either reducing the number of rush orders (which would also save Bizzan money) or working toward increasing the quality of rush orders would help to reduce these costs. The three most profitable customers (E, D, and A) generate 87% of the customer‐level operating income. These customers are valued customers and should receive the highest level of customer service.
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Chapter 16
16‐35
(30 min.) Customer profitability.
1. Customer‐level costs Customer orders ($40 × 2; 7; 1; 5; 20; 3) Customer fittings ($25 × 1; 2; 0; 0; 4; 1) Rush order costs ($100 × 0; 0; 1; 1; 3; 0) Returns for repair ($30 × 0; 1; 0; 1; 5; 1) Total customer‐level costs Revenue Cost of product Gross profit Customer‐level costs Customer‐level operating income
01 $ 80 25 0 0 $105 $600 420 180 105 $ 75
02 $ 280 50 0 30 $ 360 $4,200 2,940 1,260 360 $ 900
Customer 03 04 $ 40 $ 200 0 0 100 100 0 30 $140 $ 330 $300 $2,500 210 1,750 90 750 140 330 $(50) $ 420
05 $ 800 100 300 150 $1,350 $4,900 3,430 1,470 1,350 $ 120
06 $120 25 0 30 $175 $700 490 210 175 $ 35
The table indicates there are profitable and unprofitable customers. The ranking of customers from most to least profitable is: Customer‐ Level Operating Customer Customer Income Revenue Number (1) (2) 02 $ 900 $ 4,200 04 420 2,500 05 120 4,900 01 75 600 06 35 700 300 03 (50) $13,200 $1,500
Customer‐Level Cumulative Cumulative Customer‐ Operating Customer‐ Income Level Level Operating Income Divided by Operating as a % of Total Customer Income Revenue Income (3) = (1) ÷ (2) (4) (5) = (4) ÷ $1,500 21.4% $ 900 60.0% 16.8% $1,320 88.0% 2.4% $1,440 96.0% 12.5% $1,515 101.0% 5% $1,550 103.3% ‐16.7% $1,500 100.0%
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
16‐35 (cont’d)
Customer 03 is unprofitable and of the rest, customer 06 has the lowest operating income. Customer 05 has a very low operating income to revenue percentage. Customer 3 is unprofitable because it has very low revenue and requires a rush order. Customer 5 has a low operating income percentage because it places many orders, several rush orders, and requires a large number of customer return visits for repairs in the 30‐day period after the sale. Ring Delights could make these customers more profitable by charging extra for rush orders, charging a small fee for repairs, increasing the selling price, or requiring a minimum total revenue for free post‐sales service. Whatever decision it takes, Ring Delights must also consider the effect the decision might have on sales. 16‐36 (20 min.) Opening a store (CMA adapted). 1. First the expected market size must be determined: (600,000 * 55%) + (450,000 * 45%) = 330,000 +202,500 = 532,500 units If Voltaire opens location A: Total fixed costs = $38,000 + $90,000 = $128,000 Expected sales = 532,500 * 30% = 159,750 units Expected contribution = 159,750 * ($4.00 ‐ $2.60) = $223,650 Expected operating income = $223,650 – $128,000 = $95,650 If Voltaire opens location B: Total fixed costs = $12,000 + $54,000 = $66,000 Expected sales = 532,500 * 22% = 117,150 units Expected contribution = 117,150 * ($4.00 ‐ $2.60) = $164,010 Expected operating income = $164,010– $66,000 = $98,010 Therefore, Voltaire should open location B as its expected operating income is $2,360 ($98,010 ‐ $95,650) higher.
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Chapter 16
16‐36 (cont’d) 2.
Location A potential outcomes: CM – fixed costs = operating income [(600,000 * 30%) * ($4.00 ‐ $2.60)] – $128,000 = $252,000 – $128,000 = $124,000 or [(450,000 * 30%) * ($4.00 ‐ $2.60)] – $128,000 = $189,000 – $128,000 = $61,000 Location B potential outcomes: CM – fixed costs = operating income [(600,000 * 22%) * ($4.00 ‐ $2.60)] – $66,000 = $184,800 – $66,000 = $118,800 or [(450,000 * 22%) * ($4.00 ‐ $2.60)] – $66,000 = $138,600 – $66,000 = $72,600 This question is best solved with a decision table: Market Size = 600,000 P = 55% 1. Location A $124,000 2. Location B $118,800
Market Size = 450,000 P = 45% $61,000 $72,600
With perfect information, Voltaire would choose to open location A if he knew the market size would be 600,000 and he would open location B if he knew the market size would be 450,000. The expected value of this decision (the decision made with the perfect information) would be: ($124,000 * 55%) + ($72,600 * 45%) = $68,200 + $32,670 = $100,870 Without the perfect information, Voltaire would open location B; this option has an expected outcome of $98,010 (as per requirement #1).
Voltaire therefore would be willing to pay up to $2,860 ($100,870 – $98,010) to know with certainty the market size, as this represents his potential increase to income that the perfect information provides.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
16‐37 (40 min.) Customer profitability and governance 1.
Customer‐level operating income based on expected cost of orders: Customers
IHoG GRU GM Revenue at list price $40 × 200; 540; 300; 100; 400; 1,000 $8,000 $21,600 $12,000 Price discounts 0 1,080 0 GRU: 5% × $21,600; Gmart: 5% × $40,000 Revenue (actual price) Cost of good sold $30 × 200; 540; 300; 100; 400; 1,000 Gross margin Customer‐level operating Order taking $28 × 4; 12; 6; 4; 16; 20 Product handling $1 × 200; 540; 300; 100; 400; 1,000 Delivery $1 × 80; 120; 72; 28; 304; 100 Expedited delivery $300 × 0; 4; 0; 0; 1; 3 Sales commissions $20 × 4; 12; 6; 4; 16; 20) Total customer‐level operating costs Customer‐level operating income
GG
Gmart
$4,000 $16,000 $40,000 0
0
2,000
8,000
20,520
12,000
4,000
16,000
38,000
6,000 2,000
16,200 4,320
9,000 3,000
3,000 12,000 1,000 4,000
30,000 8,000
112
336
168
112
448
560
200
540
300
100
400
1,000
80
120
72
28
304
100
0
1,200
0
0
300
900
80 320 320 1,772 $ 680 $ 2,228
400 2,960 $ 5,040
80 472 $1,528
240 120 2,436 660 $ 1,884 $ 2,340
16–812
GC
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Chapter 16
16‐37 (cont’d) 2.
Customer level operating income based on actual order costs: Customer
IHoG GRU GM Revenue at list price $40 × 200; 540; 300; 100; 400; 1,000 $8,000 $21,600 $12,000 Price discounts 0 GRU: 5% × $21,600; Gmart: 5% × $40,000 0 1,080 8,000 20,520 12,000 Revenue (actual price) Cost of good sold $30 × 200; 540; 300; 100; 400; 1,000 6,000 16,200 9,000 2,000 4,320 3,000 Gross margin Customer‐level operating Order taking $12 × 4; $28 × 12; $12 × 6; $12 × 4; $12 × 16; $12 × 20 48 336 72 Product handling $1 × 200; 540; 300; 100; 400; 1,000 200 540 300 Delivery 80 120 72 $1 × 80; 120; 72; 28; 304; 100 Expedited delivery 0 1,200 0 $300 × 0; 4; 0; 0; 1; 3 Sales commissions 80 240 120 $20 × 4; 12; 6; 4; 16; 20 Total customer‐level operating costs 408 2,436 564 Customer‐level operating income $1,592 $ 1,884 $ 2,436
GC
GG
Gmart
$4,000 $16,000 $40,000 0 4,000
0 16,000
2,000 38,000
3,000 12,000 1,000 4,000
30,000 8,000
48
192
240
100
400
1,000
28
304
100
0
300
900
80 320 256 1,516 $ 744 $ 2,484
400 2,640 $ 5,360
Comparing the answers in requirements 1 and 2, it appears that operating income is higher than expected, so the management of Glat Corporation would be very pleased with the performance of the salespeople for reducing order costs. Except for GRU, all of the customers are more profitable than originally reported.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
16‐37 (cont’d) 3.
Customer‐level operating
Customer
IHoG GRU GM GC GG Gmart Revenue at list price $8,000 $21,600 $12,000 $4,000 $16,000 $40,000 $40 × 200; 540; 300; 100; 400; 1,000 Price discounts 0 1,080 0 0 0 2,000 GRU: 5% × $21,600; Gmart: 5% × $40,000 Revenue (actual price) 8,000 20,520 12,000 4,000 16,000 38,000 Cost of good sold 6,000 16,200 9,000 3,000 12,000 30,000 $30 × 200; 540; 300; 100; 400; 1,000 Gross margin 2,000 4,320 3,000 1,000 4,000 8,000 Customer‐level operating costs: Order taking $28 × 2; 12; 2; 2; 4; 10 56 336 56 56 112 280 Product handling 200 540 300 100 400 1,000 $1 × 200; 540; 300; 100; 400; 1,000 Delivery 80 120 72 28 304 100 $1 × 80; 120; 72; 28; 304; 100 Expedited delivery 0 1,200 0 0 300 900 $300 × 0; 4; 0; 0; 1; 3 Sales commissions 40 240 40 40 80 200 $20 × 2; 12; 2; 2; 4; 10 Total customer‐level operating costs 376 2,436 468 224 1,196 2,480 Customer‐level operating income $1,624 $ 1,884 $ 2,532 $ 776 $ 2,804 $ 5,520
4.
16–814
The behaviour of the salespeople is costing Glat Corporation $640 in profit (the difference between the incomes in requirements 2 and 3.) Although management thinks the salespeople are saving money based on the budgeted order costs, in reality they are costing the firm money by increasing the costs of orders ($936 in requirement 2 versus $896 in requirement 3) and at the same time increasing their sales commissions ($1,240 in requirement 2 versus $640 in requirement 3). This is not ethical. Glat Corporation needs to change the structure of the sales commission, possibly linking commissions to the overall units sold rather than on number of orders. They could also base commissions on total revenue, which will discourage salespeople from offering discounts unless they are needed to close the sale. A negative consequence of greater reluctance to offer discounts is that salespeople will not seek larger orders but instead focus on smaller orders that do not require discounts to be offered. This behaviour will, in turn, increase order‐taking costs. Copyright © 2013 Pearson Canada Inc.
Chapter 16
16‐38 (25 min.)
Closing down divisions.
1. Sales Variable costs of goods sold ($490,000 0.85; $390,000 0.96) Variable S,G, & A ($140,000 0.64; $120,000 0.78) Total variable costs Contribution margin
Division A $550,000
Division D $460,000
416,500
374,400
89,600 506,100 $ 43,900
93,600 468,000 $(8,000)
Division A
Division D
$ 73,500
$15,600
50,400 $123,900
26,400 $42,000
2.
Fixed costs of goods sold ($490,000 – $416,500; $390,000 – $374,400) Fixed S,G, & A ($140,000 – $89,600; $120,000 – $93,600) Total fixed costs Fixed costs savings if shut down ($123,900 0.50; $42,000 0.50)
$21,000 Division A’s contribution margin of $43,900 does not cover its avoidable fixed costs of $61,950. In other words, the fixed costs that can be avoided of $61,950 are greater than its contribution margin of $43,900. By closing Division A, the remaining divisions will need to generate sufficient profits to cover the entire $61,950 unavoidable fixed costs of Division A. $61,950
Division D earns a negative contribution margin, which means its revenue is less than its variable costs. Division D also generates $21,000 of avoidable fixed costs. Based strictly on financial considerations, Division D should be closed because the company will save $29,000 ($21,000 + $8,000).
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16‐39 (20‐25 min.) Revenue allocation for bundled products. 1.
(a) The stand‐alone revenue (using unit selling prices) of the three components of the $770 package are:
Lodging Recreation Food
– – –
$352 2 $165 2 $ 88 2
$ 704 330 176 $1,210
Lodging:
$704 $770 0.58 $770 $447 $1, 210
Recreation
$330 $770 0.27 $770 $208 $1, 210
$176 $770 0.15 $770 $115 $1, 210 $770 Food
(b) 2.
Product Recreation Lodging Food
Revenue Allocated $330 440 0 $770
Revenue Remaining to Be Allocated to Other Products $770 – $330 $440 – $440
The pros of the stand‐alone revenue allocation method include: (a) Each item in the bundle receives a positive weight, which means the resulting allocations are more likely to be accepted by all parties than a method allocating zero revenue to one or more products. (b) Uses market‐based evidence (unit selling prices) to decide the revenue allocations—unit prices are one indicator of benefits received. (c) Simple to implement.
The cons of the stand‐alone revenue allocation method include: (a) Ignores the relative importance of the individual components in attracting consumers to purchase the bundle.
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Chapter 16
16‐39 (cont’d) (b) Ignores the opportunity cost of the individual components in the bundle. The golf course operates at 100% capacity. Getaway participants must reserve a golf booking one week in advance or else they are not guaranteed playing time. A getaway participant who does not use the golf option may not displace anyone. Thus, under the stand‐alone method the golf course may be paid twice—once from the non‐getaway person who does play and second from an allocation of the $770 package amount for the getaway person who does not play (either did not want to play or wanted to play but made a booking too late). Note: Some criticisms of the (a) and (b) method are criticisms of the use of listed unit selling prices in these methods rather than of the methods themselves. For example: (a) the weight can be artificially inflated by individual product managers setting “high” list unit prices and then being willing to frequently discount these prices. The use of actual unit prices or actual revenue per product in the stand‐alone formula will reduce this problem. (b) the weights may change frequently if unit prices are constantly changing. This is not so much a criticism as a reflection that the market place may be highly competitive. The pros of the incremental method include: (a) It has the potential to reflect that some products in the bundle are more highly valued than others. Not all products in the bundle have a similar “write‐down” from unit list prices. Ensuring this “potential pro” becomes an “actual pro” requires that the choice of the primary product be guided by reliable evidence on consumer preferences. This is not an easy task. (b) Once the sequence is chosen, it is straightforward to implement. The cons of the incremental method include: (a) Obtaining the rankings can be highly contentious and place managers in a “no‐ win” acrimonious debate. The revenue allocations can be highly sensitive to the chosen rankings. (b) Some products will have zero revenue assigned to them. Consider the Food division. It would incur the costs for the two dinners but receive no revenue.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
16‐40 (50‐60 min.) Revenue allocation for bundled products. 1.
a) Stand‐alone revenue in 2013: Fraîche ($110 20,000) Désarmer ($88 37,500) Innocence ($275 20,000)
$2,200,000 3,300,000 5,500,000
The weights for Fraîche + Désarmer suite: Fraîche:
$2,200,000 $165 $66 $2,200,000 + $3,300,000
Désarmer:
$3,300,000 $165 $99 $2,200,000 + $3,300,000
The weights for Fraîche + Innocence suite: Fraîche:
$2,200,000 $308 $88 $2,200,000 + $5,500,000
Innocence:
$5,500,000 $308 $220 $2,200,000 + $5,500,000
b) Fraîche + Désarmer suite: Product Désarmer Fraîche Total revenue allocated Fraîche + Innocence suite: Product Innocence Fraîche Total revenue allocated
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Revenue Allocated $ 88 77 $165
Revenue Remaining to be Allocated $77 ($165 – $88) 0
Revenue Allocated $275 33 $308
Revenue Remaining to be Allocated $33 ($308 – $275) 0
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Chapter 16
16‐40 (cont’d) 2.
Each product will be considered as a primary product and first incremental product. An average revenue is the final revenue allocation to the product. This approach is illustrated below. Fraîche + Désarmer suite: Fraîche Allocation as the primary product Allocation as the incremental product ($165 – $88) Total Allocation ($187 ÷ 2) Désarmer Allocation as the primary product Allocation as the incremental product ($165 – $110) Total Allocation ($143 + 2)
$ 110 77 $ 187 $93.50 $ 88 55 $ 143 $71.50
According to this approach, Fraîche’s revenue allocation is $93.50 and Désarmer’s revenue allocation is $71.50 out of the total suite revenue of $165. Fraîche + Innocence suite: Fraîche Allocation as the primary product Allocation as the incremental product ($308 – $275) Total Allocation ($143 ÷ 2)
$ 110 33 $ 143 $71.50
Allocation as the primary product Allocation as the incremental product ($308 – $110) Total Allocation ($473 ÷ 2)
$ 275 198 $ 473 $236.50
Innocence
Fraîche is allocated $71.50 revenue and Innocence is allocated $236.50 revenue out of the total suite revenue of $308. An alternative approach is to take into account both the price and the units sold, that is, total revenue from each product when calculating the weights. On a stand‐alone basis, the price of Fraîche plus Désarmer is $110 + $88 = $198. On a stand‐alone basis the revenue is Fraîche Désarmer Total
$2,200,000 3,300,000 $5,500,000
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16‐40(cont’d) So Fraîche accounts for 40% ($2,200,000 ÷ $5,500,000) and Désarmer 60% ($3,300,000 ÷ 5,500,000) of total revenue from Fraîche and Désarmer. Applying these percentages to the total stand‐alone price of $198, we get revenue‐ weighted prices of $198 40% = $79.20 for Fraîche and $198 60% = $118.80 for Désarmer. Using these revenue‐weighted prices and considering each product as the primary product and then the incremental product: Fraîche and Désarmer suite: Fraîche Allocation as the primary product $ 79.20 Allocation as the incremental product ($165 – $118.80) 46.20 Total $125.40 Allocation ($125.40 ÷ 2) $ 62.70 Désarmer Allocation as the primary product $118.80 Allocation as the incremental product ($165 – $79.20) 85.80 Total $204.60 Allocation ($204.60 ÷ 2) $102.30 On a stand‐alone basis, the price of Fraîche + Innocence is $110 + $275 = $385. On a stand‐alone basis, the revenue is Fraîche $2,200,000 Innocence $5,500,000 Total $7,700,000 So Fraîche accounts for 2/7 ($2,200,000 ÷ $7,700,000) and Innocence 5/7 ($5,500,000 ÷ $7,700,000) of total revenue from Fraîche and Innocence. Applying these percentages to the total stand‐alone price of $385, we get revenue‐ weighted prices of $385 2/7 = $110 for Fraîche and $385 5/7 = $275 for Innocence. Using these revenue‐weighted prices and considering each product as the primary product and then the incremental product: Fraîche and Innocence suite: Fraîche Allocation as the primary product $ 110 Allocation as the incremental product ($308 – $275) 33 Total $ 143 Allocation ($143 ÷ 2) $71.50 Innocence Allocation as the primary product $ 275 Allocation as the incremental product ($308 – $110) $ 198 Total $ 473 Allocation ($473 ÷ 2) $236.50 16–820
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Chapter 16
16‐40 (cont’d) A summary of the price allocations for the bundled products under different methods follows. Shapley Incremental Value Incremental With Shapley Based on Stand‐alone With Désarmer/ Value Revenue‐ Revenue Fraîche Innocence Based on Weighted Allocation Primary Primary Price Price (1) (2) (3) (4) (5) Fraîche $ 66 $110 $ 77 $ 93.50 $ 62.70 55 88 71.50 102.30 Désarmer 99 Total $165 $165 $165 $ 165.00 $ 165.00 Fraîche $ 88 $110 $ 33 $ 71.50 $ 71.50 Innocence 220 198 275 236.50 236.50 Total $308 $308 $308 $ 308.00 $ 308.00 Note that the Shapley value calculations based on price and revenue‐weighted prices are the same for Fraîche and Innocence because the same number of units of each of these products is sold (20,000 units). In general, the Shapley value calculations based on revenue‐weighted prices gives the most fair allocation of prices to each product in the bundle because it considers not only the prices of each product sold but also the units. Thus, if one of the products in the bundle sells very few units, it gets very few revenue allocated to it even if it sells for a high price. The table above also indicates that the stand‐ alone revenue allocation method closely approximates the Shapley value calculations based on revenue‐weighted prices. Note that columns 2 and 4 in the above table allocate more revenue with Fraîche‐Désarmer bundle to Fraîche because Fraîche sells for a higher price ($110 versus $88). But the allocations in these columns ignore the important fact that Fraîche sells far fewer units than Désarmer (20,000 versus 37,500).
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
16‐41 (25‐30 min.) Closing and opening stores. 1.
2.
16–822
Solution Exhibit 16‐41, Column 1, presents the relevant loss in revenue and the relevant savings in costs from closing the Surrey store. Lopez is correct that Sundry Corporation’s operating income would increase by $7,000 if it closes down the Surrey store. Closing down the Surrey store results in a loss of revenue of $860,000 but cost savings of $867,000 (from cost of goods sold, rent, labour, utilities, and corporate costs). Note that by closing down the Surrey store, Sundry Corporation will save none of the equipment‐related costs because this is a past cost. Also note that the relevant corporate overhead costs are the actual corporate overhead costs of $44,000 that Sundry expects to save by closing the Surrey store. The corporate overhead of $40,000 allocated to the Surrey store is irrelevant to the analysis. Solution Exhibit 16‐41, Column 2, presents the relevant revenue and relevant costs of opening another store like the Surrey store. Lopez is correct that opening such a store would increase Sundry Corporation’s operating income by $11,000. Incremental revenue of $860,000 exceed the incremental costs of $849,000 (from higher cost of goods sold, rent, labour, utilities, and some additional corporate costs). Note that the cost of equipment written off as amortization is relevant because it is an expected future cost that Sundry will incur only if it opens the new store. Also note that the relevant corporate overhead costs are the $4,000 of actual corporate overhead costs that Sundry expects to incur as a result of opening the new store. Sundry may, in fact, allocate more than $4,000 of corporate overhead to the new store but this allocation is irrelevant to the analysis. The key reason that Sundry’s operating income increases either if it closes down the Surrey store or if it opens another store like it is the behaviour of corporate overhead costs. By closing down the Surrey store, Sundry can significantly reduce corporate overhead costs presumably by reducing the corporate staff that oversees the Surrey operation. On the other hand, adding another store like Surrey does not increase actual corporate costs by much, presumably because the existing corporate staff will be able to oversee the new store as well.
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Chapter 16
SOLUTION EXHIBIT 16‐41 Relevant‐Revenue and Relevant‐Cost Analysis of Closing Surrey Store and Opening Another Store Like It. Incremental Revenue and (Loss in Revenue) Savings in (Incremental Costs) Costs from Closing of Opening New Store Surrey Store Like Surrey Store (1) (2) Revenue $(860,000) $ 860,000 Cost of goods sold 660,000 (660,000) Lease rent 75,000 (75,000) Labour costs 42,000 (42,000) Amortization of equipment 0 (22,000) Utilities (electricity, heating) 46,000 (46,000) (4,000) Corporate overhead costs 44,000 Total costs 867,000 (849,000) Effect on operating income (loss) $ 7,000 $ 11,000
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16‐42 (30 min.)
Cost allocation and decision making.
1. 1. Division revenue 2. % revenue $7,800,000; $8,500,000; $6,200,000; $5,500,000 ÷ $28,000,000 3. Segment margin 4. Allocated headquarter costs (Row 2 × $5,600,000) 5. Operating margin after allocating headquarter costs 6. Direct costs 7. % of direct costs $5,300,000; $4,100,000; $4,300,000; $4,600,000 ÷ $18,300,000 8. Segment margin 9. Allocated headquarter costs (Row 7 × $5,600,000) 10. Operating margin after allocating headquarter costs 11. Segment margin 12. %Segment margin $2,500,000; $4,400,000; $1,900,000; $900,000 ÷ $9,700,000 13. Segment margin 14. Allocated headquarter costs (Row 12 × $5,600,000) 15. Operating income after allocating headquarter costs 16. Number of employees 17. % Employees 2,000; 4,000; 1,500; 500 ÷ 8,000
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Ontario $7,800,000
Alberta $8,500,000
Yukon $6,200,000
27.8571% 30.3571% 22.14285% $2,500,000 $4,400,000 $1,900,000
Saskatchewan $5,500,000
Total $28,000,000
19.64285% $ 900,000
100% $ 9,700,000
1,560,000
1,700,000
1,240,000
1,100,000
5,600,000
$ 940,000 $5,300,000
$2,700,000 $4,100,000
$ 660,000 $4,300,000
$(200,000) $4,600,000
$ 4,100,000 $18,300,000
28.96174% 22.40437% 23.49726% $2,500,000 $4,400,000 $1,900,000
25.13661% $ 900,000
100% $9,700,000
1,254,645
1,407,650
5,600,000
1,621,858
$ 878,142 $2,500,000
$3,145,355 $4,400,000
1,315,847
$ 584,153 $1,900,000
25.77319% 45.36082% 19.58762% $2,500,000 $4,400,000 $1,900,000
$ (507,650) $ 900,000
$4,100,000 $9,700,000
9.27835% $ 900,000
100% $9,700,000
1,443,299
2,540,206
1,096,907
519,588
5,600,000
$1,056,701 2,000
$1,859,794 4,000
$ 803,093 1,500
$ 380,412 500
$4,100,000 8,000
25%
50%
18.75%
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6.25%
100%
Chapter 16
16‐42 (cont’d) 18. Segment margin 19. Allocated headquarter costs (Row 17 × $5,600,000) 20. Operating income
2. 3.
4.
$2,500,000
$4,400,000
$1,900,000
$ 900,000
$9,700,000
1,400,000 $1,100,000
2,800,000 $1,600,000
1,050,000 $ 850,000
350,000 $ 550,000
5,600,000 $4,100,000
The Saskatchewan Division manager will prefer the number of employees allocation base because it results in the highest operating margin for the division. The Ontario Division and the Yukon Division receive roughly the same percentage allocation of headquarter costs regardless of the allocation base used (Ontario range = 25%‐29%; Yukon range = 18.75%‐23.5%). However, the Alberta Division and the Saskatchewan Division vary widely (Alberta range = 22.4%‐ 50%; Saskatchewan range = 6.25%‐ 25.1%). All four methods are reasonable options, but none clearly meets the cause‐and‐effect criterion for selecting the allocation base. If larger divisions tend to consume more of headquarter’s resources, then using division revenue or number of employees seem to be the best choices. Without compelling reason to change, Greenbold should stay with the division revenue as the allocation base. Another alternative is to use segment margin as the allocation base on the grounds that segment margin represents the ability of different divisions to bear corporate overhead costs. If Greenbold elects to use direct costs as the allocation base, the Saskatchewan Division will appear to have a $507,650 operating loss. Even so, the Saskatchewan Division generates a $900,000 segment margin before allocating the cost of the corporate headquarters. As seen in the analysis in requirement 1, different allocation bases yield different operating incomes for the Saskatchewan Division, with the direct cost allocation base being the lowest. The Saskatchewan Division should not be closed because 1) the choice of allocation base is not based on a cause‐and‐effect relation (i.e., it is arbitrary), and 2) the division earns positive segment margin which contributes to covering the cost of the corporate headquarters. The Saskatchewan Division should only be closed if closing it will save more than $507,650 in corporate headquarter costs – a highly unlikely scenario.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
16‐43 (30 min.) 1.
Revenue allocation, bundled products.
The weights in the stand‐alone method are based on the stand‐alone selling prices of the DVDs in the bundled package. The following table details these weights, which are then used to allocate the revenue of each bundled package to the three individual DVDs.
2.
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An alternative approach to allocating the bundled product revenue is the incremental revenue‐allocation method. Here the individual DVDs in the bundle are ranked in order of importance, and the revenue is allocated to each product using stand‐alone selling prices until all the bundled revenue has been fully allocated. Use of this approach would likely create some friction among the three business speakers. It would be in each speaker’s interest to claim to be the primary speaker driving sales of the bundle. The actual 2013 units‐sold figures would enable Business Horizons to give a market‐success‐based ranking of individual business speakers if it used the incremental revenue‐allocation method.
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Chapter 16
COLLABORATIVE LEARNING CASE
16‐44 1.
2.
Relevance of variance analyses.
The yield trend analysis over eight years is an example of a linear regression (Chapter 10). If you input the data on weather (the predictor variable) and yield (the outcome variable) into Excel’s regression function you would be able to determine how much of the change in yield is explained by changes in the weather. A good r2 would probably be in excess of 50% and knowing this would help you decide if you would purchase at the spring price. If the regression result is above 50% then you know roughly how to model future yield under different assumptions about weather. You are, of course, most interested in what the yield is likely to be given what you expect the local weather conditions to be in the Okanagan Valley. You know the cost of unused capacity and this is your opportunity cost. If the strike price with the Okanagan producer is lower than the opportunity cost and the expected yield will fill your unused capacity, you would be willing to contract. If, however, your assumptions about the weather in the Okanagan lead to a yield that will not fill your unused capacity you will be unlikely to contract at the specified strike price. Knowing the probable yield this year from both your leased harvest and the purchased grapes will help you estimate your productive efficiency and effectiveness. Even the most efficient producer, however, must sell the output to generate a profit. If your estimate of normal (long‐term demand) capacity is too high relative to your practical capacity, you will lose market share to your competitors and to retain share you will need to make a decision about whether or not you can remain competitive without increasing your capacity. On the other hand if your practical capacity is too high relative to normal capacity you may not generate sufficient revenue in the short‐run to realize the longer term profit when this gap closes. Understanding the market size, expected rate of growth, and your market share is important and relevant to your long‐term profitability. Understanding what causes unfavourable variances, especially in market share, will help you and your management team direct attention to discovering what causes the variance and changing activities to control the causes if possible.
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CHAPTER 17 PROCESS COSTING
SHORT‐ANSWER QUESTIONS
17‐1 Industries using process costing in their manufacturing area include chemical processing, oil refining, pharmaceuticals, plastics, brick and tile manufacturing, semiconductor chips, beverages, and breakfast cereals.
17‐2 Process costing systems separate costs into cost categories according to the timing of when costs are introduced into the process. Often, only two cost classifications, direct materials and conversion costs, are necessary. Direct materials are frequently added at one point in time, often the start or the end of the process, and all conversion costs are added at about the same time, but in a pattern different from direct materials costs.
17‐3 Equivalent units is a derived amount of output units that takes the quantity of each input (factor of production) in units completed or in incomplete units in work in process, and converts the quantity of input into the amount of completed output units that could be made with that quantity of input. Each equivalent unit is comprised of the physical quantities of direct materials or conversion costs inputs necessary to produce output of one fully completed unit. Equivalent unit measures are necessary since all physical units are not completed to the same extent at the same time.
17‐4 Two conditions under which computing equivalent units will make a material difference are when significant amounts of work in process exist, and when labour and conversion costs are input throughout the process.
17‐5 The weighted‐average process‐costing method calculates the equivalent‐unit cost of all the work done to date (regardless of the accounting period in which it was done), assigns this cost to equivalent units completed and transferred out of the process, and to equivalent units in ending work‐in‐process inventory.
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17‐6 FIFO computations are distinctive because they assign the cost of the previous accounting period’s equivalent units in beginning work‐in‐process inventory to the first units completed and transferred out of the process and they assign the cost of equivalent units worked on during the current period first to complete beginning inventory, next to start and complete new units, and finally to units in ending work‐in‐ process inventory. In contrast, the weighted‐average method costs units completed and transferred out and in ending work in process at the same average cost.
17‐7 The journal entries in process costing are basically similar to those made in job‐ costing systems. The main difference is that, in process costing, there is often more than one work‐in‐process account––one for each process.
17‐8 Standard‐cost procedures are particularly appropriate to process‐costing systems where there are various combinations of materials and operations used to make a wide variety of similar products as in the textiles, paints, and ceramics industries. Standard‐ cost procedures also avoid the intricacies involved in detailed tracking with weighted‐ average or FIFO methods when there are frequent price variations over time.
17‐9 There are two reasons why the accountant should distinguish between transferred‐in costs and additional direct materials costs for a particular department: (a) All direct materials may not be added at the beginning of the department process. (b) The control methods and responsibilities may be different for transferred‐ in items and materials added in the department.
17‐10 No. Transferred‐in costs or previous department costs are costs incurred in a previous department that have been charged to a subsequent department. These costs may be costs incurred in that previous department during this accounting period or a preceding accounting period.
17‐11 Materials are only one cost item. Other items (often included in a conversion costs pool) include labour, energy, and maintenance. If the costs of these items vary over time, this variability can cause a difference in cost of goods sold and inventory amounts when the weighted‐average or FIFO methods are used. A second factor is the amount of inventory on hand at the beginning or end of an accounting period. The smaller the amount of production held in beginning or ending inventory relative to the total number of units transferred out, the smaller the effect on operating income, cost of goods sold, or inventory amounts from the use of weighted‐ average or FIFO methods.
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Chapter 17
EXERCISES
17‐12 (10 min.)
Terminology. In process costing, the cost object is the entire production process. The method is used for mass‐produced items that are identical. That is why a weighted average can be used to calculate the ratio of work‐in‐process to finished goods. A common denominator must be found because a physical unit 100% converted has cost more to produce than one that is only 50% converted and remains in work‐in‐process inventory. The benefits of the conversion process are unequally shared between the items in each type of inventory. The average conversion rate is calculated using a denominator called an equivalent unit (EU) There are three methods to assign conversion costs to finished goods and work‐in process. The choice of method should be made by the management team such that the method is economically plausible. The method reflects the facts of the economic outcome of the production process in a specified time period. The three methods are first‐in, first‐out (FIFO) method, the weighted‐average process‐costing method, and the standard costing method.
17‐13 (25 min.) Equivalent units, zero beginning inventory. 1. 2a.
Direct materials cost per unit ($750,000 ÷ 10,000) Conversion cost per unit ($798,000 ÷ 10,000) Assembly Department cost per unit
$ 75.00 79.80 $154.80
Solution Exhibit 17‐13A calculates the equivalent units of direct materials and conversion costs in the Assembly Department of Nihon, Inc. in February 2012. Solution Exhibit 17‐13B computes equivalent unit costs. 2b. Direct materials cost per unit $ 75 Conversion cost per unit 84 Assembly Department cost per unit $159 3. The difference in the Assembly Department cost per unit calculated in requirements 1 and 2 arises because the costs incurred in January and February are the same but fewer equivalent units of work are done in February relative to January. In January, all 10,000 units introduced are fully completed resulting in 10,000 equivalent units of work done with respect to direct materials and conversion costs. In February, of the 10,000 units introduced, 10,000 equivalent units of work is done with respect to direct materials but only 9,500 equivalent units of work is done with respect to conversion costs. The Assembly Department cost per unit is, therefore, higher.
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SOLUTION EXHIBIT 17‐13A Steps 1 and 2: Summarize Output in Physical Units and Compute Output in Equivalent Units; Assembly Department of A&A Company Ltd. for February 2012 (Step 2) (Step 1) Equivalent Units Physical Direct Conversion Flow of Production Units Materials Costs Work in process, beginning (given) 0 Started during current period (given) 10,000 To account for 10,000 Completed and transferred out during current period 9,000 9,000 9,000 Work in process, ending* (given) 1,000 1,000 100%; 1,000 50% 1,000 500 Accounted for 10,000 Work done in current period 10,000 9,500 *Degree of completion in this department: direct materials, 100%; conversion costs, 50%.
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Chapter 17
SOLUTION EXHIBIT 17‐13B Compute Cost per Equivalent Unit, Assembly Department of A&A Company Ltd. for February 2012.
(Step 3) Costs added during February Divide by equivalent units of work done in current period (Solution Exhibit 17‐l3A) Cost per equivalent unit
Total Production Costs $1,548,000
Direct Materials $750,000 10,000 $ 75
Conversion Costs $798,000 9,500 $ 84
17‐14 (20 min.) Journal entries. 1.
2.
3.
Work in Process––Assembly 750,000 Accounts Payable 750,000 To record $750,000 of direct materials purchased and used in production during February 2012 Work in Process––Assembly 798,000 Various accounts 798,000 To record $798,000 of conversion costs for February 2012; examples include energy, manufacturing supplies, all manufacturing labour, and plant depreciation Work in Process––Testing 1,431,000 Work in Process––Assembly 1,431,000 To record 9,000 units completed and transferred from Assembly to Testing during February 2012 at $159 9,000 units = $1,431,000 Postings to the Work in Process––Assembly account follow. Work in Process –– Assembly Department Beginning inventory, Feb. 1 0 3. Transferred out to 1. Direct materials 750,000 Work in Process––Testing 1,431,000 2. Conversion costs 798,000 Ending inventory, Feb. 28 117,000
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
17‐15 (25 min.) Zero beginning inventory, materials introduced in middle of process. 1. 2.
Solution Exhibit 17‐15A shows equivalent units of work done in the current period of Chemical P, 50,000; Chemical Q, 35,000; Conversion costs, 45,000. Solution Exhibit 17‐15B summarizes the total Mixing Department costs for July 2012, calculates cost per equivalent unit of work done in the current period for Chemical P, Chemical Q, and Conversion costs, and assigns these costs to units completed (and transferred out) and to units in ending work in process.
SOLUTION EXHIBIT 17‐15A Steps 1 and 2: Summarize Output in Physical Units and Compute Output in Equivalent Units; Mixing Department of Roary Chemicals for July 2012. (Step 1) (Step 2) Equivalent Units Physical Conversion Flow of Production Units Chemical P Chemical Q Costs Work in process, beginning (given) 0 Started during current period (given)50,000 To account for 50,000 Completed and transferred out during current period 35,000 35,000 35,000 35,000 Work in process, ending* (given) 15,000 15,000 100%; 15,000 0%; 15,000 66 2/3% 15,000 0 10,000 Accounted for 50,000 Work done in current period only 50,000 35,000 45,000 *Degree of completion in this department: Chemical P, 100%; Chemical Q, 0%; conversion costs, 66 2/3%.
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SOLUTION EXHIBIT 17‐15B Steps 3, 4, and 5: Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed and to Units in Ending Work in Process; Mixing Department of Roary Chemicals for July 2012.
Total Production Conversion Costs Chemical P Chemical Q Costs $250,000 $70,000 $135,000 $455,000 $455,000 $250,000 $70,000 $135,000 $250,000 $70,000 $135,000
(Step 3) Costs added during July Total costs to account for (Step 4) Costs added in current period Divide by equivalent units of work done in current period (Solution Exhibit 17‐l8A) Cost per equivalent unit (Step 5) Assignment of costs: Completed and transferred out (35,000 units) Work in process, ending (15,000 units) Total costs accounted for
35,000 45,000 $ 2 $ 3 (35,000* $5) + (35,000* $2) + (35,000* $350,000 $3) 50,000 $ 5
105,000 (15,000† $5) + (0† $2) + (10,000† $3) $455,000 $250,000 + $70,000 + $135,000
*Equivalent units completed and transferred out from Solution Exhibit 17‐15A, Step 2. †Equivalent units in ending work in process from Solution Exhibit 17‐15A, Step 2.
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17‐16
(25 min.) Weighted‐average method, assigning costs.
1. & 2. Solution Exhibit 17‐16A shows equivalent units of work done to date for Bio Doc Corporation for direct materials and conversion costs. Solution Exhibit 17‐16B summarizes total costs to account for, calculates the cost per equivalent unit of work done to date for direct materials and conversion costs, and assigns these costs to units completed and transferred out and to units in ending work‐ in‐process inventory. SOLUTION EXHIBIT 17‐16A Steps 1 and 2: Summarize Output in Physical Units and Compute Output in Equivalent Units; Weighted‐Average Method of Process Costing, Bio Doc Corporation for July 2012.
(Step 2) (Step 1) Equivalent Units Physical Direct Conversion Flow of Production Units Materials Costs Work in process, beginning (given) 12,500 Started during current period (given) 50,000 To account for 62,500 Completed and transferred out during current period 42,500 42,500 42,500 Work in process, ending* (given) 20,000 20,000 100%; 20,000 50% 20,000 10,000 Accounted for 62,500 52,500 Work done to date 62,500 *Degree of completion: direct materials, 100%; conversion costs, 50%.
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SOLUTION EXHIBIT 17‐16B Steps 3, 4, and 5: Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed and to Units in Ending Work in Process; Weighted‐Average Method of Process Costing, Bio Doc Corporation for July 2012.
(Step 3) Work in process, beginning (given) Costs added in current period (given) Total costs to account for (Step 4) Costs incurred to date Divide by equivalent units of work done to date (Solution Exhibit 17‐16A) Cost per equivalent unit of work done to date (Step 5) Assignment of costs: Completed and transferred out (42,500 units) Work in process, ending (20,000 units) Total costs accounted for
Total Production Costs $162,500 813 ,750 $976,250
Direct Materials $ 75,000 350,000
Conversion Costs $ 87,500 463,750
$425,000 $425,000 62,500
$551,250 $551,250 52,500
$ 6.80 $735,250 241,000 $976,250
$ 10.50
(42,500* $6.80) + (42,500* $10.50) (20,000† $6.80) + (10,000† $10.50) $425,000 + $551,250
*Equivalent units completed and transferred out (given). †Equivalent units in ending work in process (given).
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
17‐17 (30 min.) FIFO method, assigning costs. 1. & 2. Solution Exhibit 17‐17A calculates the equivalent units of work done in the current period. Solution Exhibit 17‐17B summarizes total costs to account for, calculates the cost per equivalent unit of work done in the current period for direct materials and conversion costs, and assigns these costs to units completed and transferred out and to units in ending work‐in‐process inventory. SOLUTION EXHIBIT 17‐17A Steps 1 and 2: Summarize Output in Physical Units and Compute Output in Equivalent Units; FIFO Method of Process Costing, Bio Doc Corporation for July 2012. (Step 2) (Step 1) Equivalent Units Physical Direct Conversion Flow of Production Units Materials Costs (work done before current Work in process, beginning (given) 12,500 period) Started during current period (given) 50,000 62,500 To account for Completed and transferred out during current 12,500 period: § 0 3,750 From beginning work in process 12,500 (100% 100%); 12,500 (100% – 70%) 30,000† Started and completed 30,000 30,000 30,000 100%, 30,000 100% 20,000 Work in process, ending* (given) 20,000 10,000 20,000 100%; 20,000 50% Accounted for 62,500 43,750 Work done in current period only 50,000
Degree of completion in this department: direct materials, 100%; conversion costs, 70%. †42,500 physical units completed and transferred out minus 12,500 physical units completed and transferred out from beginning work‐in‐process inventory. *Degree of completion in this department: direct materials, 100%; conversion costs, 50%. §
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SOLUTION EXHIBIT 17‐17B Steps 3, 4, and 5: Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed and to Units in Ending Work in Process; FIFO Method of Process Costing, Bio Doc Corporation for July 2012.
(Step 3) Work in process, beginning (given) Costs added in current period (given)
Total Production Costs $162,500 813,750
Total costs to account for
$976,250
(Step 4) Costs added in current period Divide by equivalent units of work done in current period (Solution Exhibit 17‐17A) Cost per equivalent unit of work done in current period (Step 5) Assignment of costs: Completed and transferred out (42,500 units): Work in process, beginning (12,500 units) Cost added to beginning work in process in current period Total from beginning inventory Started and completed (30,000 units) Total costs of units completed and transferred out Work in process, ending (20,000 units) Total costs accounted for
Direct Materials $ 75,000 350,000
Conversion Costs $ 87,500 463,750
$425,000
$551,250
$350,000
$463,750
50,000 $ 7
43,750 $ 10.60
$162,500 39,750 202,250 528,000 730,250 246,000 $976,250
$75,000 + $87,500 (0* $7) + (3,750* $10.60) (30,000 $7) + (30,000† $10.60) # (20,000 $7) + (10,000# $10.60) $425,000 + $551,250 †
*Equivalent units used to complete beginning work in process from Solution Exhibit 17‐17A, Step 2. †Equivalent units started and completed from Solution Exhibit 17‐17A, Step 2. #Equivalent units in ending work in process from Solution Exhibit 17‐17A, Step 2.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
17‐18 (30 min.) Standard‐costing method, assigning costs. 1. The calculations of equivalent units for direct materials and conversion costs are identical to the calculations of equivalent units under the FIFO method. Solution Exhibit 17‐17A shows the equivalent unit calculations for standard costing and computes the equivalent units of work done in July 2012. Solution Exhibit 17‐18 uses the standard costs (direct materials, $6.60; conversion costs, $10.40) to summarize total costs to account for, and to assign these costs to units completed and transferred out and to units in ending work‐in‐process inventory. 2. Solution Exhibit 17‐18 shows the direct materials and conversion costs variances for Direct materials $20,000 U Conversion costs $8,750 U SOLUTION EXHIBIT 17‐18 Steps 3, 4, and 5: Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed and to Units in Ending Work in Process; Standard Costing Method of Process Costing, Bio Doc Corporation for July 2012. Total Conversion Direct Production Costs Materials Costs (Step 3) Work in process, beginning (given) $173,500 (12,500 $6.60) + (8,750 $10.40) Costs added in current period at standard costs 785,000 (50,000 $6.60) + (43,750 $10.40) Total costs to account for $958,500 $412,500 + $546,000 (Step 4) Standard cost per equivalent unit (given) $ 10.40 $ 6.60 (Step 5) Assignment of costs at standard costs: Completed and transferred out (42,500 units): $173,500 (12,500 $6.60) + (8,750 $10.40) Work in process, beginning (12,500 units) 39,000 (0* $6.60) + (3,750* $10.40) Costs added to beg. work in process in current period 212,500 Total from beginning inventory Started and completed (30,000 units) 510,000 (30,000† $6.60) + (30,000† $10.40) Total costs of units transferred out 722,500 Work in process, ending (20,000 units) 236,000 (20,000# $6.60) + (10,000# $10.40) Total costs accounted for $958,500 $412,500 + $546,000 Summary of variances for current performance: $330,000 Costs added in current period at standard costs (see Step $455,000 350,000 3 above) 463,750 Actual costs incurred (given) $ 20,000 U $ 8,750 U Variance *Equivalent units to complete beginning work in process from Solution Exhibit 17‐18A, Step 2. †Equivalent units started and completed from Solution Exhibit 17‐18A, Step 2. #Equivalent units in ending work in process from Solution Exhibit 17‐18A, Step 2.
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Chapter 17
17‐19 (15 min.) Weighted‐average method, equivalent units and unit costs. Under the weighted‐average method, equivalent units are calculated as the equivalent units of work done to date. Solution Exhibit 17‐19 shows equivalent units of work done to date for the Satellite Assembly Division for direct materials and conversion costs. SOLUTION EXHIBIT 17‐19 Steps 1 and 2: Summarize Output in Physical Units and Compute Equivalent Units Weighted‐Average Method of Process Costing, Satellite Assembly Division for May 2012 (Step 1) (Step 2) Physical Equivalent Units Units Direct Conversion Flow of Production (given) Materials Costs Work in process beginning 8 Started during current period 55 To account for 63 Completed and transferred out during current period 51 51.0 51.0 Work in process, ending* (12 60%; 12 30%) 12 7.2 3.6 Accounted for 63 ____ Work done to date 58.2 54.6 *Degree of completion in this department: direct materials, 60%; conversion costs, 30%. Costs per equivalent unit: $5, 426, 960 $35, 420, 000 $40, 846, 960 DM 58.2 58.2
$701, 837.80/ equ ivalent u nit
CV
$1, 001, 440 $15, 312, 000 $16, 313, 440 54.6 54.6
$298, 780.95/ equ ivalent u nit
Copyright © 2013 Pearson Canada Inc.
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17‐20 (20 min.) Weighted‐average method, assigning costs. Solution Exhibit 17‐20 calculates cost per equivalent unit of work done to date in the Assembly Division, summarizes total costs to account for, and assigns costs to units completed and to units in ending work‐in‐process inventory. SOLUTION EXHIBIT 17‐20 Steps 3, 4, and 5: Compute Equivalent Unit Costs, Summarize Total Costs to Account for, and Assign Costs to Units Completed and to Units in Ending Work in Process Weighted‐Average Method of Process Costing, Satellite Assembly Division for May 2012
Total Production Direct Conversion Costs Materials Costs (Step 3) Work in process, beginning (given) $ 6,428,400 $ 5,426,960 $ 1,001,440 35,420,000 15,312,000 Costs added in current period (given) 50,732,000 Costs incurred to date $40,846,960 $16,313,440 Divide by equivalent units of work ÷ 54.60 done to date (Solution Exhibit 17‐19) ÷ 58.20 Cost per equivalent unit of work done to date $ 701,837.80 $298,780.95 (Step 4) Total costs to account for $57,160,400 (Step 5) Assignment of costs: Completed and transferred out (51 units) $51,031,556 (51* $701,837.80) + (51* $298,780.95) Work in process, ending (12 units) Direct materials 5,053,232 7.2† $701,837.80 3.6† $298,780.95 Conversion costs 1,075,612 Total work in process 6,128,844 Total costs accounted for $57,160,400 *Equivalent units completed and transferred out from Solution Exhibit 17‐19, Step 2. †Equivalent units in work in process, ending from Solution Exhibit 17‐19 Step 2.
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Chapter 17
17‐21 (15 min.) FIFO method, equivalent units and unit costs. 1.
Under the FIFO method, equivalent units are calculated as the equivalent units of work done in the current period only. Solution Exhibit 17‐21 shows equivalent units of work done in May 2012 in the Assembly Division for direct materials and conversion costs.
SOLUTION EXHIBIT 17‐21 Steps 1 and 2: Summarize Output in Physical Units and Compute Equivalent Units FIFO Method of Process Costing, Satellite Assembly Division of for May 2012 (Step 2) (Step 1) Equivalent Units Physical Direct Conversion Flow of Production Units Materials Costs Work in process, beginning (given) 8 (work done before current period) Started during current period (given) 55 To account for 63 (work done before current period) Completed and transferred out during current period: From beginning work in process§ 8 8 (100% – 90%); 8 (100% – 40%) 0.8 4.8 † Started and completed 43 43 100%, 43 100% 43.0 43.0 Work in process, ending* (given) 12 12 60%; 12 30% 7.2 3.6 Accounted for 63 51.4 Work done in current period only 51.0
Degree of completion in this department: direct materials, 90%; conversion costs, 40%. 51 physical units completed and transferred out minus 8 physical units completed and transferred out from beginning work‐in‐process inventory. *Degree of completion in this department: direct materials, 60%; conversion costs, 30%. 2. Direct material costs, added May $35,420,000 Equivalent units 51 Cost per equivalent unit $694,510 Conversion costs, May $15,312,000 Equivalent units 51.4 Cost per equivalent units $297,899 § †
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
17‐22 (20 min.) FIFO method, assigning costs. Solution Exhibit 17‐22 calculates cost per equivalent unit of work done in May 2012 in the Assembly Division, summarizes total costs to account for, and assigns costs to units completed, and to units in ending work‐in‐process inventory. SOLUTION EXHIBIT 17‐22 Steps 3, 4, and 5: Compute Equivalent Unit Costs, Summarize Total Costs to Account For, and Assign Costs to Units Completed and to Units in EndingWork in Process FIFO Method of Process Costing, Satellite Assembly Division for May 2012
Total Production Direct Conversion Costs Materials Costs Work in process, beginning ($5,426,960 + $1,001,440)$ 6,428,400(costs of work done before current period) (Step 3) Costs added in current period (given) 50,732,000 $35,420,000 $15,312,000 Divide by equivalent units of work done in current period (Solution Exhibit 17‐21) ÷ 51 ÷ 51.4 Cost per equivalent unit of work done in $ 297,899 current period __________ $ 694,510 (Step 4) Total costs to account for $57,160,400 (Step 5) Assignment of costs: Completed and transferred out (51 units): Work in process, beginning (8 units) $ 6,428,400 Direct materials added in current period 555,608 0.8* $694,510 4.8 $297,899 Conversion costs added in current period 1,429,915 Total from beginning inventory 8,413,923 Started and completed (43 units) 42,673,587(43† $694,510) + 43† $297,899) Total costs of units completed & transf. out 51,087,510 Work in process, ending (12 units) Direct materials 5,000,472.00 7.2# $694,510 Conversion costs 1,072,436.40 3.6# $297,899 Total work in process, ending 6,072,908.40 Total costs accounted for $57,160,400 [rounded down]
*Equivalent units used to complete beginning work in process from Solution Exhibit 17‐ 21, Step 2. †Equivalent units started and completed from Solution Exhibit 17‐21, Step 2. #Equivalent units in work in process, ending from Solution Exhibit 17‐21, Step 2.
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17‐23 (25‐30 min.) Standard‐costing method, assigning costs. 1.
2. 3.
The calculations of equivalent units for direct materials and conversion costs are identical to the calculations of equivalent units under the FIFO method. Solution Exhibit 17‐19 shows the equivalent unit calculations under standard costing given by the equivalent units of work done in May 2012 in the Assembly Division. Solution Exhibit 17‐23 summarizes the total costs to account for, and assigns these costs to units completed and transferred out, and to units in ending work in process. Solution Exhibit 17‐23 shows the direct materials and conversion cost variances for Direct materials Conversion costs
$280,000 F $108,000 F
SOLUTION EXHIBIT 17‐23 Steps 3, 4, and 5: Compute Equivalent Unit Costs, Summarize Total Costs to Account For, and Assign Costs to Units Completed and to Units in Ending Work in Process Use of Standard Costs in Process Costing, Satellite Assembly Division of for May 2012 Total Production Direct Conversion Costs Materials Costs (Step 3) Standard cost per equivalent unit (given) $ 700,000 $ 300,000 Work in process, beginning (given) Direct materials, 7.2* $700,000; Conversion costs, 3.2* $300,000 $6,000,000 Costs added in current period at standard costs Direct materials, 51 $700,000; $35,700,000 $15,420,000 Conversion costs, 51.4 $300,000 51,120,000 (Step 4) Costs to account for $57,120,000 (Step 5) Assignment of costs at standard costs: Completed and transferred out (51 units): Work in process, beginning (8 units) $ 6,000,000 Direct materials added in current period 560,000 0.8* $700,000 Conversion costs added in current period 1,440,000 4.8* $300,000 Total from beginning inventory 8,000,000 Started and completed (43 units) 43,000,00043† $700,000 + 43† $300,000 Total costs of units transferred out 51,000,000
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17‐23 (cont’d) Work in process, ending (12 units) Direct materials 5,040,000 7.2# $700,000 3.6# $300,000 Conversion costs 1,080,000 Total work in process, ending 6,120,000 Total costs accounted for $57,120,000 Summary of variances for current performance: Costs added in current period at standard prices (see above) $35,700,000 $15,420,000 15,312,000 Actual costs incurred (given) 35,420,000 $ 108,000 F Variance $ 280,000 F
*Equivalent units to complete beginning work in process from Solution Exhibit 17‐21, Step 2. †Equivalent units started and completed from Solution Exhibit 17‐21, Step 2. #Equivalent units in work in process, ending from Solution Exhibit 17‐21, Step 2. *Degree of completion: direct material 90%; conversion costs 40% (8 0.90 = 7.2) ; (8 0.40 = 3.2)
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Chapter 17
17‐24 (35–40 min.) Transferred‐in costs, weighted‐average method. 1, 2. & 3. Solution Exhibit 17‐24A calculates the equivalent units of work done to date. Solution Exhibit 17‐24B summarizes total costs to account for, calculates the cost per equivalent unit of work done to date for transferred‐in costs, direct materials, and conversion costs, and assigns these costs to units completed and transferred out and to units in ending work‐in‐process inventory. SOLUTION EXHIBIT 17‐24A Steps 1 and 2: Summarize Output in Physical Units and Compute Output in Equivalent Units Weighted‐Average Method of Process Costing; Finishing Department of Asaya Clothing for June 2012 (Step 1) Physical Flow of Production Units Work in process, beginning (given) 75 Transferred in during current period (given) 135 To account for 210 Completed and transferred out during current period 150 Work in process, ending* (given) 60 60 100%; 60 0%; 60 75% Accounted for 210 Work done to date
(Step 2) Equivalent Units Transferred‐ Direct Conversion in Costs Materials Costs
150
150
150
60 210
0 150
45 195
*Degree of completion in this department: transferred‐in costs, 100%; direct materials, 0%; conversion costs, 75%.
Copyright © 2013 Pearson Canada Inc.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
SOLUTION EXHIBIT 17‐24B Steps 3, 4, and 5: Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed and to Units in Ending Work in Process; Weighted‐Average Method of Process Costing, Finishing Department of Asaya Clothing for June 2012. Total Production Transferred‐in Direct Conversion Costs Costs Materials Costs (Step 3) Work in process, beginning (given) $105,000 $ 75,000 $ 0 $ 30,000 Costs added in current period (given) 258,000 142,500 37,500 78,000 Total costs to account for $363,000 $ 217,500 $37,500 $108,000 (Step 4) Costs incurred to date $ 217,500 $37,500 $108,000 Divide by equivalent units of work done to date (Solution Exhibit 17‐24A) ÷ 210 ÷ 150 ÷ 195 Cost per equivalent unit of work done to date $1,035.71 $ 250 $ 553.85 (Step 5) Assignment of costs: a a Completed and transferred out (150 units) $275,934 (150 $1,035.71) + (150 $250) + (150a $553.85) Work in process, ending (60 units): 87,066 (60b $1,035.71) + (0b $250) + (45b $553.85) Total costs accounted for $363,000 $ 217,500 + $37,500 + $108,000 a Equivalent units completed and transferred out from Sol. Exhibit 17‐24, step 2. b Equivalent units in ending work in process from Sol. Exhibit 17‐24A, step 2.
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Chapter 17
17‐25 (35–40 min.) Transferred‐in costs, FIFO method. Solution Exhibit 17‐25A calculates the equivalent units of work done in the current period (for transferred‐in costs, direct‐ materials, and conversion costs) to complete beginning work‐in‐process inventory, to start and complete new units, and to produce ending work in process. Solution Exhibit 17‐25B summarizes total costs to account for, calculates the cost per equivalent unit of work done in the current period for transferred‐in costs, direct materials, and conversion costs, and assigns these costs to units completed and transferred out and to units in ending work‐in‐process inventory. SOLUTION EXHIBIT 17‐25A Steps 1 and 2: Summarize Output in Physical Units and Compute Output in Equivalent Units FIFO Method of Process Costing; Finishing Department of Asaya Clothing for June 2012 (Step 1) (Step 2) Equivalent Units Physical Transferred‐in Direct Conversion Units Costs Materials Costs Flow of Production Work in process, beginning (given) 75 (work done before current period) Transferred‐in during current period (given) 135 To account for 210 Completed and transferred out during current period: 75 From beginning work in processa [75 (100% – 100%); 75 (100% – 0%); 75 (100% – 60%)] 0 75 30 b Started and completed 75 100%; 75 100%; 75 100%) 75 75 75 (75 60 Work in process, endingc (given) ___ 60 0 45 (60 100%; 60 0%; 60 75%) ___ ___ ___ Accounted for 210 150 150 Work done in current period only 135 aDegree of completion in this department: Transferred‐in costs, 100%; direct materials, 0%; conversion costs, 60%. b150 physical units completed and transferred out minus 75 physical units completed and transferred out from beginning work‐in‐process inventory. cDegree of completion in this department: transferred‐in costs, 100%; direct materials, 0%; conversion costs, 75%.
Copyright © 2013 Pearson Canada Inc.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
SOLUTION EXHIBIT 17‐25B Steps 3, 4, and 5: Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed and to Units in Ending Work in Process; FIFO Method of Process Costing, Finishing Department of Asaya Clothing for June 2012. Total Transferred‐in Production Costs Costs Direct Materials Conversion Costs (Step 3) Work in process, beginning (given) $ 90,000 $ 60,000 $ 0 $ 30,000 130,800 37,500 78,000 Costs added in current period (given) 246,300 $190,800 $37,500 $108,000 Total costs to account for $336,300 (Step 4) Costs added in current period $130,800 $37,500 $ 78,000 Divide by equivalent units of work done in current period ÷ 150 ÷ 150 (Solution Exhibit 17‐22A) ÷ 135 Cost per equivalent unit of work done in current $ 250 $ 520 period $ 968.89 (Step 5) Assignment of costs: Completed and transferred out (150 units) Work in process, beginning (75 units) $ 90,000 $ 60,000 $ 0 $ 30,000 Costs added to beginning work in process in 34,350 (0a $968.89) + (75a $250) + (30 a $520) current period Total from beginning inventory 124,350 b b b (75 $968.89) + (75 $250) + (75 $520) Started and completed (75 units) 130,416 Total costs of units completed and transferred out 254,766 c c c (60 $968.89) + (0 $250) + (45 $520) Work in process, ending (60 units): 81,534 Total costs accounted for $336,300 $190,800 + $37,500 + $108,000 a Equivalent units used to complete beginning work in process from Solution Exhibit 17‐28A, step 2. b Equivalent units started and completed from Solution Exhibit 17‐22A, step 2. c Equivalent units in ending work in process from Solution Exhibit 17‐22A, step 2.
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Chapter 17
17‐26 (15 min.) Weighted‐average method, equivalent units. Under the weighted‐average method, equivalent units are calculated as the equivalent units of work done to date. Solution Exhibit 17‐26 shows equivalent units of work done to date for the Assembly Division of Fenton Watches, Inc., for direct materials and conversion costs. SOLUTION EXHIBIT 17‐26 Steps 1 and 2: Summarize Output in Physical Units and Compute Output in Equivalent Units; Weighted‐Average Method of Process Costing, Assembly Division of Fenton Watches, Inc., for May 2012 (Step 2) (Step 1) Equivalent Units Physical Direct Conversion Flow of Production Units Materials Costs Work in process beginning (given) 80 Started during current period (given) 500 To account for 580 Completed and transferred out during current period 460 460 460 72 36 Work in process, ending* (120 60%; 120 30%) 120 ___ ___ Accounted for 580 Work done to date 532 496
*Degree of completion in this department: direct materials, 60%; conversion costs, 30%.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
17‐27 (20 min.) Weighted‐average method, assigning costs. Solution Exhibit 17‐27 summarizes total costs to account for, calculates cost per equivalent unit of work done to date in the Assembly Division of Fenton Watches, Inc., and assigns costs to units completed and to units in ending work‐in‐process inventory. SOLUTION EXHIBIT 17‐27 Steps 3, 4, and 5: Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed and to Units in Ending Work in Process; Weighted‐Average Method of Process Costing, Assembly Division of Fenton Watches, Inc., for May 2012 Total Conversion Direct Production Costs Materials Costs (Step 3) Work in process, beginning (given) $ 584,400 $ 493,360 $ 91,040 Costs added in current period (given) 4,612,000 3,220,000 1,392,000 Total costs to account for $5,196,400 $3,713,360 $1,483,040 (Step 4) Costs incurred to date $3,713,360 $1,483,040 Divide by equivalent units of work done to date (Solution Exhibit 17‐26) 532 496 Cost per equivalent unit of work done to $ 6,980 $ 2,990 date (Step 5) Assignment of costs: Completed and transferred out (460 units) $4,586,200 (460* $6,980) + (460* $2,990) Work in process, ending (120 units) 610,200 (72† $6,980) + (36† $2,990) Total costs accounted for $5,196,400 $3,713,360 + $1,483,040 *Equivalent units completed and transferred out from Solution Exhibit 17‐26, Step 2. † Equivalent units in work in process, ending from Solution Exhibit 17‐26, Step 2.
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Chapter 17
17‐28 (15 min.) FIFO method, equivalent units. Under the FIFO method, equivalent units are calculated as the equivalent units of work done in the current period only. Solution Exhibit 17‐26 shows equivalent units of work done in May 2012 in the Assembly Division of Fenton Watches, Inc., for direct materials and conversion costs. SOLUTION EXHIBIT 17‐28 Steps 1 and 2: Summarize Output in Physical Units and Compute Output in Equivalent Units; FIFO Method of Process Costing, Assembly Division of Fenton Watches, Inc., for May 2012
(Step 2) (Step 1) Equivalent Units Physical Direct Conversion Units Materials Costs 80 (work done before current 500 period) 580 80 8 48 † 380 380 380 120 ___ 72 36 580 464 460
Flow of Production Work in process, beginning (given) Started during current period (given) To account for Completed and transferred out during current period: From beginning work in process§ 80 (100% 90%); 80 (100% 40%) Started and completed 380 100%, 380 100% Work in process, ending* (given) 120 60%; 120 30% Accounted for Work done in current period only §Degree of completion in this department: direct materials, 90%; conversion costs, 40%. †460 physical units completed and transferred out minus 80 physical units completed and transferred out from beginning work‐in‐process inventory. *Degree of completion in this department: direct materials, 60%; conversion costs, 30%.
Copyright © 2013 Pearson Canada Inc.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
17‐29 (20 min.) FIFO method, assigning costs. Solution Exhibit 17‐29 summarizes total costs to account for, calculates cost per equivalent unit of work done in May 2012 in the Assembly Division of Fenton Watches, Ltd., and assigns total costs to units completed and to units in ending work‐in‐process inventory. SOLUTION EXHIBIT 17‐29 Steps 3, 4, and 5: Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed and to Units in Ending Work in Process; FIFO Method of Process Costing, Assembly Division of Fenton Watches, Ltd.., for May 2012 Total Production Direct Conversion Costs Materials Costs (Step 3) Work in process, beginning (given) $ 584,400 $ 493,360 $ 91,040 Costs added in current period (given) 4,612,000 3,220,000 1,392,000 $3,713,360 $1,483,040 Total costs to account for $5,196,400 (Step 4) Costs added in current period $3,220,000 $1,392,000 Divide by equivalent units of work done in 460 464 current period (Solution Exhibit 17‐29) Cost per equiv. unit of work done in current $ 7,000 $ 3,000 period (Step 5) Assignment of costs: Completed and transferred out (460 units): Work in process, beginning (80 units) $ 584,400 $493,360 + $91,040 Costs added to beginning work in process in current period 200,000 (8* $7,000) + (48* $3,000) Total from beginning inventory 784,400 † † Started and completed (380 units) 3,800,000 (380 $7,000) + (380 $3,000) Total costs of units completed and 4,584,400 transferred out 612,000 (72# $7,000) + (36# $3,000) Work in process, ending (120 units) $5,196,400 $3,713,360 + $1,483,040 Total costs accounted for *Equivalent units used to complete beginning work in process from Solution Exhibit 17‐29, Step 2. †Equivalent units started and completed from Solution Exhibit 17‐29, Step 2. #Equivalent units in work in process, ending from Solution Exhibit 17‐29, Step 2.
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Copyright © 2013 Pearson Canada Inc.
Chapter 17
17‐30 (20‐25 min.) Standard‐costing method, assigning costs. 1. SOLUTION EXHIBIT 17‐30A Steps 1 and 2: Summarize Output in Physical Units and Compute Output in Equivalent Units; Standard Costing Method of Process Costing for Bucky’s Boxes for July 2012
(Step 2) (Step 1) Equivalent Units Physical Direct Conversion Units Materials Costs 185,000 (work done before current period) 465,000 650,000 185,000 0 138,750 327,000† 327,000 327,000 138,000 _______ 138,000 110,400 650,000 _______ _______ 576,150 465,000
Flow of Production Work in process, beginning (given) Started during current period (given) To account for Completed and transferred out during current period: From beginning work in process§ 185,000 (100% 100%); 185,000 (100% – 25%) Started and completed 327,000 100%, 327,000 100% Work in process, ending* (given) 138,000 100%; 138,000 80% Accounted for Work done in current period only §Degree of completion in this department: direct materials, 100%; conversion costs, 25%. †512,000 physical units completed and transferred out minus 185,000 physical units completed and transferred out from beginning work‐in‐process inventory. *Degree of completion in this department: direct materials, 100%; conversion costs, 80%.
Copyright © 2013 Pearson Canada Inc.
17‐855
Instructor’s Solutions Manual for Cost Accounting, 6Ce
2. SOLUTION EXHIBIT 17‐30B Steps 3, 4, and 5: Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed and to Units in Ending Work in Process; Standard Costing Method of Process Costing for Bucky’s Boxes for July 2012
Total Production Costs (Step 3) Work in process, beginning (given) $ 337,625 Costs added in current period at standard costs 1,814,415 Total costs to account for $2,152,040 (Step 4) Standard cost per equivalent unit (given) (Step 5) Assignment of costs at standard costs: Completed and transferred out (512,000 units): $ 337,625 Work in process, beginning (185,000 units) 291,375 Costs added to beg. work in process in current period 629,000 Total from beginning inventory Started and completed (327,000 units) 1,111,800 Total costs of units transferred out 1,740,800 Work in process, ending (138,000 units) 411,240 Total costs accounted for $2,152,040 Summary of variances for current performance: Costs added in current period at standard costs (see Step 3 above) Actual costs incurred (given) Variance
Conversion Direct Costs Materials $240,500 + $ 97,125 (465,000 $1.30) + (576,150 $2.10) $845,000 + $1,307,040 $ 1.30
$ 2.10
$240,500 + $97,125 (0* $1.30) + (138,750* $2.10) (327,000† $1.30) + (327,000† $2.10) (138,000# $1.30) + (110,400# $2.10) $845,000 + $1,307,040 $604,500 $1,209,915 607,500 1,207,415 $ 3,000 U $ 2,500 F
*Equivalent units to complete beginning work in process from Solution Exhibit 17‐30A, Step 2. †Equivalent units started and completed from Solution Exhibit 17‐30A, Step 2. #Equivalent units in ending work in process from Solution Exhibit 17‐30A, Step 2.
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Copyright © 2013 Pearson Canada Inc.
Chapter 17
PROBLEMS 17‐31 (25 min.) Weighted‐average method. 1.
Since direct materials are added at the beginning of the assembly process, the units in this department must be 100% complete with respect to direct materials. Solution Exhibit 17‐31A shows equivalent units of work done to date:
Direct materials Conversion costs
25,000 equivalent units 24,250 equivalent units
SOLUTION EXHIBIT 17‐31A Steps 1 and 2: Summarize Output in Physical Units and Compute Output in Equivalent Units; Weighted‐Average Method of Process Costing, Assembly Department of Larsen Company, for October 2012. (Step 1) (Step 2) Equivalent Units Physical Direct Conversion Flow of Production Units Materials Costs Work in process, beginning (given) 5,000 Started during current period (given) 20,000 To account for 25,000 Completed and transferred out during current period 22,500 22,500 22,500 Work in process, ending* (given) 2,500 2,500 100%; 2,500 70% 2,500 1,750 Accounted for 25,000 24,250 Work done to date 25,000 *Degree of completion in this department: direct materials, 100%; conversion costs, 70%.
Copyright © 2013 Pearson Canada Inc.
17‐857
Instructor’s Solutions Manual for Cost Accounting, 6Ce
17‐31 (cont’d) 2. & 3. Solution Exhibit 17‐31B summarizes the total Assembly Department costs for October 2012, calculates cost per equivalent unit of work done to date, and assigns these costs to units completed (and transferred out) and to units in ending work in process using the weighted‐average method. SOLUTION EXHIBIT 17‐31B Steps 3, 4, and 5: Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed and to Units in Ending Work in Process; Weighted‐ Average Method of Process Costing, Assembly Department of Larsen Company, for October 2012
Total Production Costs (Step 3) Work in process, beginning (given) $1,652,750 Costs added in current period (given) 6,837,500 Total costs to account for $8,490,250 (Step 4) Costs incurred to date Divide by equivalent units of work done to date (Solution Exhibit 17‐31A) Cost per equivalent unit of work done to date (Step 5) Assignment of costs: $7,717,500 Completed and transferred out (22,500 units) Work in process, ending (2,500 units) 772,750 Total costs accounted for $8,490,250
Direct Materials $1,250,000 4,500,000 $5,750,000 $5,750,000 25,000 $ 230
Conversion Costs $ 402,750 2,337,500 $2,740,250 $2,740,250 24,250 $ 113
(22,500* $230) + (22,500* $113) (2,500† $230) + (1,750† $113) $5,750,000 + $2,740,000
Equivalent units completed and transferred out from Solution Exhibit 17‐31A, Step 2. †Equivalent units in work in process, ending from Solution Exhibit 17‐31A, Step 2. *
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Copyright © 2013 Pearson Canada Inc.
Chapter 17
17‐32 (10 min.) Journal entries. 1. 2. 3.
Work in Process––Assembly Department Accounts Payable Direct materials purchased and used in production in October.
4,500,000
4,500,000
Work in Process––Assembly Department Various accounts Conversion costs incurred in October.
2,337,500
2,337,500
Work in Process––Testing Department 7,717,500 Work in Process––Assembly Department 7,717,500 Cost of goods completed and transferred out in October from the Assembly Department to the Testing Department.
Work in Process––Assembly Department Beginning inventory, October 1 1,652,750 3. Transferred out to 1. Direct materials 4,500,000 Work in Process–Testing 2. Conversion costs 2,337,500 Ending Inventory, October 31 772,750
Copyright © 2013 Pearson Canada Inc.
7,717,500
17‐859
Instructor’s Solutions Manual for Cost Accounting, 6Ce
17‐33 (20 min.) FIFO method. 1.
2.
3.
The equivalent units of work done in the current period in the Assembly Department in October 2012 for direct materials and conversion costs are shown in Solution Exhibit 17‐33A. The cost per equivalent unit of work done in the current period in the Assembly Department in October 2012 for direct materials and conversion costs is calculated in Solution Exhibit 17‐32B. Solution Exhibit 17‐32B summarizes the total Assembly Department costs for October 2012, and assigns these costs to units completed (and transferred out) and units in ending work in process under the FIFO method. The cost per equivalent unit of beginning inventory and of work done in the current period differ:
Direct materials Conversion costs Total cost per unit
Beginning Inventory $250.00 ($1,250,000 5,000 equiv. units) 134.25 ($ 402,750 3,000 equiv. units) $384.25
Work Done in Current Period $225.00 110.00 $335.00
Direct Materials $230* $225**
Conversion Costs $113* $110**
Cost per equivalent unit (weighted‐average) Cost per equivalent unit (FIFO) *from Solution Exhibit 17‐31B **from Solution Exhibit 17‐32B The cost per equivalent unit differs between the two methods because each method uses different costs as the numerator of the calculation. FIFO uses only the costs added during the current period whereas weighted‐average uses the costs from the beginning work‐in‐process as well as costs added during the current period. Both methods also use different equivalent units in the denominator. The following table summarizes the costs assigned to units completed and those still in process under the weighted‐average and FIFO process‐costing methods for our example.
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Chapter 17
17‐33 (cont’d)
Cost of units completed and transferred out Work in process, ending Total costs accounted for
Weighted Average (Solution Exhibit 17‐31B) $7,717,500 772,750 $8,490,250
FIFO (Solution Exhibit 17‐33B) Difference $7,735,250 + $17,750 755,000 $17,750 $8,490,250
The FIFO ending inventory is lower than the weighted‐average ending inventory by $17,750. This is because FIFO assumes that all the higher‐cost prior‐period units in work in process are the first to be completed and transferred out while ending work in process consists of only the lower‐cost current‐period units. The weighted‐average method, however, smoothes out cost per equivalent unit by assuming that more of the lower‐cost units are completed and transferred out, while some of the higher‐cost units in beginning work in process are placed in ending work in process. So, in this case, the weighted‐average method results in a lower cost of units completed and transferred out and a higher ending work‐in‐process inventory relative to the FIFO method. SOLUTION EXHIBIT 17‐33A Steps 1 and 2: Summarize Output in Physical Units and Compute Output in Equivalent Units; FIFO Method of Process Costing, Assembly Department of Larsen Company for October 2012 (Step 1) (Step 2) Equivalent Units Physical Direct Conversion Flow of Production Units Materials Costs Work in process, beginning (given) 5,000 (work done before current period) Started during current period (given) 20,000 To account for 25,000 Completed and transferred out during current period: § From beginning work in process 5,000 (100% 100%); 5,000 (100% 60%) 5,000 0 2,000 Started and completed 17,500 17,500 17,500 100%, 17,500 100% 17,500† Work in process, ending* (given) 2,500 2,500 100%; 2,500 70% _____ 2,500 1,750 ______ Accounted for 25,000 Work done in current period only 20,000 21,250 §Degree of completion in this department: direct materials, 100%; conversion costs, 60%. †22,500 physical units completed and transferred out minus 5,000 physical units completed and transferred out from beginning work‐in‐process inventory. *Degree of completion in this department: direct materials, 100%; conversion costs, 70%.
Copyright © 2013 Pearson Canada Inc.
17‐861
Instructor’s Solutions Manual for Cost Accounting, 6Ce
SOLUTION EXHIBIT 17‐33B Steps 3, 4, and 5: Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed and to Units in Ending Work in Process; FIFO Method of Process Costing, Assembly Department of Larsen Company for October 2012
Total Production Costs $1,652,750 6,837,500 $8,490,250
Direct Materials $1,250,000 4,500,000 $5,750,000 $4,500,000 20,000 $ 225
Conversion Costs $ 402,750 2,337,500 $2,740,250 $2,337,500 21,250 $ 110
(Step 3) Work in process, beginning (given) Costs added in current period (given) Total costs to account for (Step 4) Costs added in current period Divide by equivalent units of work done in current period (Solution Exhibit 17‐33A) Cost per equivalent unit of work done in current period (Step 5) Assignment of costs: Completed and transferred out (22,500 units): Work in process, beginning (5,000 units) $1,652,750 $1,250,000 + $ 402,750 Costs added to beg. work in process in current 220,000 (0* $225) + (2,000* $110) period 1,872,750 Total from beginning inventory Started and completed (17,500 units) 5,862,500 (17,500† $225) + (17,500† $110) Total costs of units completed & transferred out 7,735,250 Work in process, ending (2,500 units) 755,000 (2,500# $225) + (1,750# $110) Total costs accounted for $8,490,250 $5,750,000 + $2,740,250 *Equivalent units used to complete beginning work in process from Solution Exhibit 17‐33A, Step 2. †Equivalent units started and completed from Solution Exhibit 17‐33A, Step 2. #Equivalent units in ending work in process from Solution Exhibit 17‐33A, Step 2.
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Copyright © 2013 Pearson Canada Inc.
Chapter 17
17‐34 (30 min.) Transferred‐in costs, weighted‐average method. 1.
2.
3.
4.
Transferred‐in costs are 100% complete, and direct materials are 0% complete in both beginning and ending work‐in‐process inventory. The reason is that transferred‐in costs are always 100% complete as soon as they are transferred in from the Assembly Department to the Testing Department. Direct materials in beginning or ending work in process for the Testing Department are 0% complete because direct materials are added only when the testing process is 90% complete and the units in beginning and ending work in process are only 70% and 60% complete, respectively. Solution Exhibit 17‐34A computes the equivalent units of work done to date in the Testing Department for transferred‐in costs, direct materials, and conversion costs. Solution Exhibit 17‐34B summarizes total Testing Department costs for October 2012, calculates the cost per equivalent unit of work done to date in the Testing Department for transferred‐in costs, direct materials, and conversion costs, and assigns these costs to units completed and transferred out and to units in ending work in process using the weighted‐average method. Journal entries: a. Work in Process––Testing Department Work in Process––Assembly Department Cost of goods completed and transferred out during October from the Assembly Department to the Testing Department b. Finished Goods Work in Process––Testing Department Cost of goods completed and transferred out during October from the Testing Department to Finished Goods inventory
Copyright © 2013 Pearson Canada Inc.
7,717,500
7,717,500
23,459,600 23,459,600
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
SOLUTION EXHIBIT 17‐34A Steps 1 and 2: Summarize Output in Physical Units and Compute Output in Equivalent Units; Weighted‐Average Method of Process Costing, Testing Department of Larsen Company for October 2012 (Step 1) (Step 2) Equivalent Units Physical Transferred‐ Direct Conversio Flow of Production Units in Materials n Costs Costs Work in process, beginning (given) 7,500 Transferred in during current period (given) 22,500 To account for 30,000 Completed and transferred out during current period 26,300 26,300 26,300 26,300 Work in process, ending* (given) 3,700 3,700 100%; 3,700 0%; 3,700 60% 3,700 0 2,220 Accounted for 30,000 Work done to date 30,000 26,300 28,520 *Degree of completion in this department: transferred‐in costs, 100%; direct materials, 0%; conversion costs, 60%.
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Chapter 17
SOLUTION EXHIBIT 17‐34B Steps 3, 4, and 5: Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed and to Units in Ending Work in Process; Weighted‐Average Method of Process Costing, Testing Department of Larsen Company for October 2012 Total Production Transferred Direct Conversion Costs ‐in Costs Materials Costs (Step 3) Work in process, beginning (given) $ 3,767,960 $ 2,932,500 $ 0 $ 835,460 Costs added in current period (given) 21,378,100 7,717,500 9,704,700 3,955,900 Total costs to account for $25,146,060 $10,650,000 $9,704,700 $4,791,360 (Step 4) Costs incurred to date $10,650,000 $9,704,700 $4,791,360 Divide by equivalent units of work done to date (Solution Exhibit 17‐34A) 30,000 26,300 28,520 Equivalent unit costs of work done to date $ 355 $ 369 $ 168 (Step 5) Assignment of costs: Completed and transferred out (26,300 (26,300* $355) + (26,300* $369) + (26,300* $168) units) $23,459,600 Work in process, ending (3,700 units) 1,686,460 (3,700† $355) + (0† $369) + (2,220† $168) Total costs accounted for $25,146,060 $10,650,000 + $9,704,700 + $4,791,360 *Equivalent units completed and transferred out from Solution Exhibit 17‐34A, Step 2. †Equivalent units in ending work in process from Solution Exhibit 17‐34A, Step 2.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
17‐35 (30 min.) Transferred‐in costs, FIFO method (continuation of 17‐34). 1.
2.
3.
4.
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As explained in Problem 17‐33, requirement 1, transferred‐in costs are 100% complete and direct materials are 0% complete in both beginning and ending work‐in‐process inventory. The equivalent units of work done in October 2012 in the Testing Department for transferred‐in costs, direct materials, and conversion costs are calculated in Solution Exhibit 17‐35A. Solution Exhibit 17‐35B summarizes total Testing Department costs for October 2012, calculates the cost per equivalent unit of work done in October 2012 in the Testing Department for transferred‐in costs, direct materials, and conversion costs, and assigns these costs to units completed and transferred out and to units in ending work in process using the FIFO method. Journal entries: a. Work in Process––Testing Department Work in Process––Assembly Department Cost of goods completed and transferred out during October from the Assembly Dept. to the Testing Dept. b. Finished Goods Work in Process––Testing Department Cost of goods completed and transferred out during October from the Testing Department to Finished Goods inventory.
Copyright © 2013 Pearson Canada Inc.
7,735,250
7,735,250
23,463,787
23,463,787
Chapter 17
SOLUTION EXHIBIT 17‐35A Steps 1 and 2: Summarize Output in Physical Units and Compute Output in Equivalent Units; FIFO Method of Process Costing, Testing Department of Larsen Company for October 2012. (Step 2) (Step 1) Equivalent Units Physical Transferred Direct Conversion Flow of Production Units in Costs Materials Costs (work done before current period) Work in process, beginning (given) 7,500 Transferred‐in during current period 22,500 30,000 (given) To account for Completed and transferred out during current period: From beginning work in process§ 7,500 7,500 (100% 100%); 7,500 (100% 0%); 0 7,500 2,250 7,500 (100% 70%) † 18,800 Started and completed 18,800 100%; 18,800 100%; 18,800 18,800 100% 18,800 18,800 Work in process, ending* (given) 3,700 3,700 100%; 3,700 0%; 3,700 60% ______ 3,700 0 2,220 Accounted for 30,000 _____ ______ Work done in current period only 22,500 26,300 23,270 § Degree of completion in this department: Transferred‐in costs, 100%; direct materials, 0%; conversion costs, 70%. †26,300 physical units completed and transferred out minus 7,500 physical units completed and transferred out from beginning work‐in‐process inventory. *Degree of completion in this department: transferred‐in costs, 100%; direct materials, 0%; conversion costs, 60%.
Copyright © 2013 Pearson Canada Inc.
17‐867
Instructor’s Solutions Manual for Cost Accounting, 6Ce
SOLUTION EXHIBIT 17‐35B Steps 3, 4, and 5: Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed and to Units in Ending Work in Process; FIFO Method of Process Costing, Testing Department of Larsen Company for October 2012
(Step 3) Work in process, beginning (given) Costs added in current period (given) Total costs to account for (Step 4) Costs added in current period Divide by equivalent units of work done in current period (Solution Exhibit 17‐35A) Cost per equiv. unit of work done in current period (Step 5) Assignment of costs: Completed and transferred out (26,300 units): Work in process, beginning (7,500 units) Costs added to beg. work in process in current period Total from beginning inventory Started and completed (18,800 units) Total costs of units completed & transferred out Work in process, ending (3,700 units) Total costs accounted for (rounded)
Total Production Costs $ 3,717,335 21,395,850 $25,113,185
Transferred‐in Costs $ 2,881,875 7,735,250 $10,617,125 $ 7,735,250 22,500 $ 343.79
Direct Materials $ 0 9,704,700 $9,704,700 $9,704,700 26,300 $ 369.00
$ 3,717,335 3,150,000
$2,881,875 + $0 + $835,460 (0* $343.79) + (7,500* $369.00) + (2,250* $170.00)
6,867,335 16,596,452 23,463,787 1,649,423 $25,113,210
(18,800† $343.79)+(18,800† $369.00)+(18,800† $170.00) (3,700# $343.79) + (0# $369.00) + (2,220# $170.00) $10,617,150 + $9,704,700 + $4,791,360
*Equivalent units used to complete beginning work in process from Solution Exhibit 17‐35A, Step 2. †Equivalent units started and completed from Solution Exhibit 17‐35A, Step 2. #Equivalent units in ending work in process from Solution Exhibit 17‐35A, Step 2.
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Conversion Costs $ 835,460 3,955,900 $4,791,360 $3,955,900 23,270 $ 170.00
Copyright © 2013 Pearson Canada Inc.
Chapter 17
17‐36 (25 min.) Weighted‐average method. Solution Exhibit 17‐36A shows equivalent units of work done to date of: Direct materials 625 equivalent units Conversion costs 525 equivalent units Note that direct materials are added when the Assembly Department process is 10% complete. Both the beginning and ending work in process are more than 10% complete and hence are 100% complete with respect to direct materials. Solution Exhibit 17‐36B summarizes the total Assembly Department costs for April 2009, calculates cost per equivalent unit of work done to date for direct materials and conversion costs, and assigns these costs to units completed (and transferred out), and to units in ending work in process using the weighted‐average method. SOLUTION EXHIBIT 17‐36A Steps 1 and 2: Summarize Output in Physical Units and Compute Output in Equivalent Units; Weighted‐Average Method of Process Costing, Assembly Department of Porter Handcraft for April 2012 (Step 1) (Step 2) Equivalent Units Physical Direct Conversion Flow of Production Units Materials Costs Work in process, beginning (given) 75 Started during current period (given) 550 To account for 625 Completed and transferred out during current period 500 500 500 125 Work in process, ending* (given) 125 100%; 125 20% 125 25 Accounted for 625 __ Work done to date 625 525 *Degree of completion in this department: direct materials, 100%; conversion costs, 20%.
Copyright © 2013 Pearson Canada Inc.
17‐869
Instructor’s Solutions Manual for Cost Accounting, 6Ce
SOLUTION EXHIBIT 17‐36B Steps 3, 4, and 5: Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed and to Units in Ending Work in Process; Weighted‐Average Method of Process Costing, Assembly Department of Porter, April 2012 Total Production Direct Conversion Costs Materials Costs (Step 3) Work in process, beginning (given) $ 1,910 $ 1,775 $ 135 Costs added in current period (given) 28,490 17,600 10,890 $19,375 $11,025 Total costs to account for $30,400 (Step 4) Costs incurred to date $19,375 $11,025 Divide by equivalent units of work done to 625 525 date (Solution Exhibit 17‐36A) Cost per equivalent unit of work done to $ 31 $ 21 date (Step 5) Assignment of costs: Completed and transferred out (500 $26,000 units) (500* $31) + (500* $21) Work in process, ending (125 units) 4,400 (125† $31) + (25† $21) Total costs accounted for $30,400 $19,375 + $11,025 *Equivalent units completed and transferred out from Solution Exhibit 17‐36A, Step 2. †Equivalent units in ending work in process from Solution Exhibit 17‐36A, Step 2.
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Chapter 17
17‐37 (5–10 min.) Journal entries. 1. 2. 3.
Work in Process–– Assembly Department Accounts Payable To record direct materials purchased and used in production during April
17,600
Work in Process–– Assembly Department Various Accounts To record Assembly Department conversion costs for April
10,890
10,890
Work in Process––Finishing Department Work in Process–– Assembly Department To record cost of goods completed and transferred out in April from the Assembly Department to the Finishing Department
26,000
26,000
17,600
Work in Process –– Assembly Department Beginning inventory, April 1 1,910 3. Transferred out to 1. Direct materials 17,600 Work in Process––Finishing 2. Conversion costs 10,890 Ending inventory, April 30 4,400
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26,000
17‐871
Instructor’s Solutions Manual for Cost Accounting, 6Ce
17‐38 (20 min.) FIFO method. The equivalent units of work done in April 2012 in the Assembly Department for direct materials and conversion costs are shown in Solution Exhibit 17‐38A. Solution Exhibit 17‐38B summarizes the total Assembly Department costs for April 2012, calculates the cost per equivalent unit of work done in April 2012 in the Assembly Department for direct materials and conversion costs, and assigns these costs to units completed (and transferred out) and to units in ending work in process under the FIFO method. The equivalent units of work done in beginning inventory is: direct materials, 75 100% = 75; and conversion costs 75 40% = 30. The cost per equivalent unit of beginning inventory and of work done in the current period are: Work Done in Current Period Beginning (Calculated Under Inventory FIFO Method) Direct materials $23.67 ($1,775 75) $32 $4.50 ($135 30) Conversion costs $22 The following table summarizes the costs assigned to units completed and those still in process under the weighted‐average and FIFO process‐costing methods for our example. Weighted Average FIFO (Solution (Solution Exhibit 17‐36B) Exhibit 17‐38B) Difference $25,850 –$150 Cost of units completed and $26,000 transferred out 4,400 4,550 +$150 $30,400 $30,400 Work in process, ending Total costs accounted for The FIFO ending inventory is higher than the weighted‐average ending inventory by $150. This is because FIFO assumes that all the lower‐cost prior‐period units in work in process are the first to be completed and transferred out while ending work in process consists of only the higher‐cost current‐period units. The weighted‐average method, however, smoothes out cost per equivalent unit by assuming that more of the higher‐cost units are completed and transferred out, while some of the lower‐cost units in beginning work in process are placed in ending work in process. Hence, in this case, the weighted‐average method results in a higher cost of units completed and transferred out and a lower ending work‐in‐process inventory relative to the FIFO method.
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Copyright © 2013 Pearson Canada Inc.
Chapter 17
SOLUTION EXHIBIT 17‐38A Steps 1 and 2: Summarize Output in Physical Units and Compute Output in Equivalent Units; FIFO Method of Process Costing, Assembly Department of Porter Handcraft for April 2012 (Step 2) (Step 1) Equivalent Units Physical Direct Conversion Flow of Production Units Materials Costs Work in process, beginning (given) 75 (work done before current Started during current period (given) 550 period) 625 To account for Completed and transferred out during current period: 75 § From beginning work in process 0 45 75 (100% 100%); 75 (100% 40%) Started and completed 425† 425 425 425 100%; 425 100% Work in process, ending* (given) 125 125 100%; 125 20% 125 25 Accounted for 625 Work done in current period only 550 495
Degree of completion in this department: direct materials, 100%; conversion costs, 40%. 500 physical units completed and transferred out minus 75 physical units completed and transferred out from beginning work‐in‐process inventory. *Degree of completion in this department: direct materials, 100%; conversion costs, 20%. § †
Copyright © 2013 Pearson Canada Inc.
17‐873
Instructor’s Solutions Manual for Cost Accounting, 6Ce
SOLUTION EXHIBIT 17‐38B Steps 3, 4, and 5: Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed and to Units in Ending Work in Process; FIFO Method of Process Costing, Assembly Department of Porter Handcraft for April 2012 Total Production Direct Conversion Costs Materials Costs (Step 3) Work in process, beginning $ 1,910 $ 135 (given) $ 1,775 Costs added in current period (given) 28,490 17,600 10,890 Total costs to account for $30,400 $19,375 $11,025 (Step 4) Costs added in current period $17,600 $10,890 Divide by equivalent units of work 495 done in current period (Exhibit 17‐38A) 550 Cost per equivalent unit of work done in current $ 22 period $ 32 (Step 5) Assignment of costs: Completed and transferred out (500 units): Work in process, beginning (75 $ 1,910 $1,775 + $135 units) Costs added to begin work in 990 (0* $32) + (45* $22) process in current period Total from beginning inventory 2,900 † Started and completed (425 units) 22,950 (425 $32) + (425† $22) Total costs of units completed 25,850 & transferred out 4,550 (125# $32) + (25# $22) $30,400 $19,375 + $11,025 Work in process, ending (125 units) Total costs accounted for *Equivalent units used to complete beginning work in process from Solution Exhibit 17‐ 38A, Step 2. †Equivalent units started and completed from Solution Exhibit 17‐38A, Step 2. #Equivalent units in ending work in process from Solution Exhibit 17‐38A, Step 2.
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Chapter 17
17‐39 (30 min.) Transferred‐in costs, weighted average. 1.
2.
Solution Exhibit 17‐39A computes the equivalent units of work done to date in the Binding Department for transferred‐in costs, direct materials, and conversion costs. Solution Exhibit 17‐39B summarizes total Binding Department costs for April 2012, calculates the cost per equivalent unit of work done to date in the Binding Department for transferred‐in costs, direct materials, and conversion costs, and assigns these costs to units completed and transferred out and to units in ending work in process using the weighted‐average method. Journal entries: a. Work in Process–– Binding Department 144,000 Work in Process––Printing Department 144,000 Cost of goods completed and transferred out during April from the Printing Department to the Binding Department b. Finished Goods 249,012 Work in Process–– Binding Department 249,012 Cost of goods completed and transferred out during April from the Binding Department to Finished Goods inventory
SOLUTION EXHIBIT 17‐39A Steps 1 and 2: Summarize Output in Physical Units and Compute Output in Equivalent Units; Weighted‐Average Method of Process Costing, Binding Department of Publish, Inc. for April 2012.
(Step 1)
(Step 2) Equivalent Units Physical Transferred‐in Direct Conversion Units Costs Materials Costs 900
Flow of Production Work in process, beginning (given) Transferred‐in during current period (given) 2,700 To account for 3,600 Completed and transferred out during current period: 3,000 3,000 3,000 3,000 a 600 Work in process, ending (given) 600 0 360 (600 100%; 600 0%; 600 60%) _____ Accounted for 3,600 3,000 3,360 Work done to date 3,600 aDegree of completion in this department: transferred‐in costs, 100%; direct materials, 0%; conversion costs, 60%.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
SOLUTION EXHIBIT 17‐39B Steps 3, 4, and 5: Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed and to Units in Ending Work in Process; Weighted‐Average Method of Process Costing, Binding Department of Publish, Inc. for April 2012
Total Production Costs
Transferred‐in Costs
Direct Materials
Conversion Costs
(Step 3) Work in process, beginning (given) $ 47,775 $ 32,775 $ 0 $15,000 Costs added in current period (given) 239,700 144,000 26,700 69,000 Total costs to account for $287,475 $176,775 $26,700 $84,000 (Step 4) Costs incurred to date $176,775 $26,700 $84,000 Divide by equivalent units of work done to date ÷ 3,000 ÷ 3,360 (Solution Exhibit 17‐38A) ÷ 3,600 $ 8.90 $ 25 Cost per equivalent unit of work done to date $ 49.104 (Step 5) Assignment of costs: Completed and transferred out (3,000 units) $249,012 (3,000a × $49.104) + (3,000a × $8.90) + (3,000a × $25) Work in process, ending (600 units): 38,463 (600b × $49.104) + (0b × $8.90) + (360b × $25) $176,775 + $26,700 + $84,000 Total costs accounted for $287,475 a Equivalent units completed and transferred out from Sol. Exhibit 17‐39A, step 2. b Equivalent units in ending work in process from Sol. Exhibit 17‐39A, step 2.
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17‐40 1.
2.
Chapter 17
Transferred‐in costs, FIFO costing.
Solution Exhibit 17‐40A calculates the equivalent units of work done in April 2012 in the Binding Department for transferred‐in costs, direct materials, and conversion costs. Solution Exhibit 17‐40B summarizes total Binding Department costs for April 2012, calculates the cost per equivalent unit of work done in April 2012 in the Binding Department for transferred‐in costs, direct materials, and conversion costs, and assigns these costs to units completed and transferred out and to units in ending work in process using the FIFO method. Journal entries: a. Work in Process–– Binding Department Work in Process––Printing Department Cost of goods completed and transferred out during April from the Printing Department to the Binding Department.
141,750
141,750
240,525
240,525
b.
Finished Goods Work in Process–– Binding Department Cost of goods completed and transferred out during April from the Binding Department to Finished Goods inventory.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
17‐40 (cont’d)
The equivalent units of work done in beginning inventory is: Transferred‐in costs, 900 100% = 900; direct materials, 900 0% = 0; and conversion costs, 900 40% = 360. The cost per equivalent unit of beginning inventory and of work done in the current period are: Beginning Work Done in Inventory Current Period Transferred‐in costs (weighted $36.42 ($32,775 900) $53.33 ($144,000 2,700) average) $30.95 ($27,855 900) $52.50 ($141,750 2,700) — $ 8.90 Transferred‐in costs (FIFO) Direct materials $41.67 ($15,000 360) $23.00 Conversion costs The following table summarizes the costs assigned to units completed and those still in process under the weighted‐average and FIFO process‐costing methods for the Binding Department. Weighted Average FIFO (Solution (Solution Exhibit 17‐ Exhibit 17‐40B) Difference 40B) Cost of units completed and transferred $249,012 $240,525 –$8,487 out 38,463 39,780 +$1,317 $287,475 $280,305 Work in process, ending Total costs accounted for The FIFO ending inventory is higher than the weighted‐average ending inventory by $1,317. This is because FIFO assumes that all the lower‐cost prior‐period units in work in process (resulting from the lower transferred‐in costs in beginning inventory) are the first to be completed and transferred out while ending work in process consists of only the higher‐cost current‐period units. The weighted‐average method, however, smoothes out cost per equivalent unit by assuming that more of the higher‐cost units are completed and transferred out, while some of the lower‐cost units in beginning work in process are placed in ending work in process. Hence, in this case, the weighted‐average method results in a higher cost of units completed and transferred out and a lower ending work‐in‐process inventory relative to FIFO. Note that the difference in cost of units completed and transferred out (–$8,487) does not fully offset the difference in ending work‐in‐process inventory (+$1,317). This is because the FIFO and weighted‐ average methods result in different values for transferred‐in costs with respect to both beginning inventory and costs transferred in during the period.
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Chapter 17
SOLUTION EXHIBIT 17‐40A Steps 1 and 2: Summarize Output in Physical Units and Compute Output in Equivalent Units; FIFO Method of Process Costing, Binding Department of Publish, Inc. for April 2012. (Step 1) (Step 2) Equivalent Units Physical Transferred‐in Direct Conversion Flow of Production Units Costs Materials Costs Work in process, beginning (given) 900 (work done before current period) Transferred‐in during current period (given) 2,700 To account for 3,600 Completed and transferred out during current period: From beginning work in processa 900 [900 (100% – 100%); 900 (100% – 0%); 900 (100% – 40%)] 0 900 540 b Started and completed 2,100 (2,100 100%; 2,100 100%; 2,100 100%) 2,100 2,100 2,100 c Work in process, ending (given) 600 (600 100%; 600 x 0%; 600 60%) ____ 600 0 360 Accounted for 3,600 ____ ____ ____ Work done in current period only 2,700 3,000 3,000 a Degree of completion in this department: Transferred‐in costs, 100%; direct materials, 0%; conversion costs, 40%. b 3,000 physical units completed and transferred out minus 900 physical units completed and transferred out from beginning work‐in‐process inventory. c Degree of completion in this department: transferred‐in costs, 100%; direct materials, 0%; conversion costs, 60%.
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SOLUTION EXHIBIT 17‐40B Steps 3, 4, and 5: Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed and to Units in Ending Work in Process; FIFO Method of Process Costing, Binding Department of Publish, Inc. for April 2012.
(Step 3) (Step 4)
Total Production Costs $ 42,855 237,450 $280,305
Transferred‐in Costs $ 27,855 141,750 $169,605 $141,750
Direct Materials $ 0 26,700 $26,700 $26,700
Conversion Costs $15,000 69,000 $84,000 $69,000
Work in process, beginning (given) Costs added in current period (given) Total costs to account for Costs added in current period Divide by equivalent units of work done in current ÷ 3,000 ÷ 3,000 period (Sol. Exhibit 17‐39A) ÷ 2,700 $ 8.90 $ 23.00 Cost per equivalent unit of work done in current period $ 52.50 (Step 5) Assignment of costs: Completed and transferred out (3,000 units) Work in process, beginning (900 units) $ 42,855 $27,855 + $0 + $15,000 Costs added to beginning work in process in current period 20,430 (0a × $52.50) + (900a × $8.90) + (540a × $23) Total from beginning inventory 63,285 b b b Started and completed (2,100 units) 177,240 (2,100 × $52.50) + (2,100 × $8.90) + (2,100 × $23) Total costs of units completed and transferred out 240,525 c c c Work in process, ending (600 units): 39,780 (600 × $52.50) + (0 × $8.90) + (360 × $23) Total costs accounted for $280,305 $169,605 + $26,700 + $84,000 a Equivalent units used to complete beginning work in process from Solution Exhibit 17‐40A, step 2. b Equivalent units started and completed from Solution Exhibit 17‐40A, step 2. c Equivalent units in ending work in process from Solution Exhibit 17‐40A, step 2.
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Chapter 17
17‐41 (45 min.) Transferred‐in costs, weighted‐average and FIFO methods. 1.
2.
Solution Exhibit 17‐41A computes the equivalent units of work done to date in the Drying and Packaging Department for transferred‐in costs, direct materials, and conversion costs. Solution Exhibit 17‐41B summarizes total Drying and Packaging Department costs for week 37, calculates the cost per equivalent unit of work done to date in the Drying and Packaging Department for transferred‐in costs, direct materials, and conversion costs, and assigns these costs to units completed and transferred out and to units in ending work in process using the weighted‐average method. Solution Exhibit 17‐41C computes the equivalent units of work done in week 37 in the Drying and Packaging Department for transferred‐in costs, direct materials, and conversion costs. Solution Exhibit 17‐41D summarizes total Drying and Packaging Department costs for week 37, calculates the cost per equivalent unit of work done in week 37 in the Drying and Packaging Department for transferred‐in costs, direct materials, and conversion costs, and assigns these costs to units completed and transferred out and to units in ending work in process using the FIFO method.
SOLUTION EXHIBIT 17‐41A Steps 1 and 2: Summarize Output in Physical Units and Compute Output in Equivalent Units; Weighted‐Average Method of Process Costing, Drying and Packaging Department of Frito‐Lay Inc. for Week 37. (Step 1) (Step 2) Equivalent Units Physical Transferred‐ Direct Conversion Flow of Production Units in Costs Materials Costs Work in process, beginning (given) 1,250 Transferred in during current period (given) 5,000 To account for 6,250 Completed and transferred out during current period 5,250 5,250 5,250 5,250 Work in process, ending* (given) 1,000 1,000 0 400 1,000 100%; 1,000 0%; 1,000 40% Accounted for 6,250 5,250 5,650 Work done to date 6,250 *Degree of completion in this department: transferred‐in costs, 100%; direct materials, 0%; conversion costs, 40%.
Copyright © 2013 Pearson Canada Inc.
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SOLUTION EXHIBIT 17‐41B Steps 3, 4, and 5: Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed and to Units in Ending Work in Process; Weighted‐Average Method of Process Costing, Drying and Packaging Department of Frito‐Lay Inc. for Week 37. Total Production Transferred Direct Conversion Costs ‐in Costs Materials Costs (Step 3) Work in process, beginning (given) $ 38,060 $ 29,000 $ 0 $ 9,060 Costs added in current period (given) 159,600 96,000 25,200 38,400 Total costs to account for $197,660 $125,000 $25,200 $47,460 (Step 4) Costs incurred to date $125,000 $25,200 $47,460 Divide by equivalent units of work done 6,250 5,250 5,650 to date (Solution Exhibit 17‐40A) Equivalent unit costs of work done to date $ 20 $ 4.80 $ 8.40 (Step 5) Assignment of costs: Completed and transferred out (5,250 units) (5,250* $20) + (5,250* $4.80) + (5,250* $174,300 $8.40) Work in process, ending (1,000 units) (1,000† $20) + (0† $4.80) + (400† $8.40) 23,360 Total costs accounted for $197,660 $125,000 + $25,200 + $47,460 *Equivalent units completed and transferred out from Solution Exhibit 17‐41A, Step 2. †Equivalent units in ending work in process from Solution Exhibit 17‐41A, Step 2.
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Chapter 17
SOLUTION EXHIBIT 17‐41C Steps 1 and 2: Summarize Output in Physical Units and Compute Output in Equivalent Units; FIFO Method of Process Costing, Drying and Packaging Department of Frito‐Lay Inc. for Week 37. Flow of Production Work in process, beginning (given) Transferred‐in during current period (given) To account for Completed and transferred out during current period: From beginning work in process§ 1,250 (100% 100%); 1,250 (100% 0%); 1,250 (100% 80%) Started and completed 4,000 100%; 4,000 100%; 4,000 100% Work in process, ending* (given) 1,000 100%; 1,000 0%; 1,000 40% Accounted for Work done in current period only
(Step 2) (Step 1) Equivalent Units Physical Transferred‐ Direct Conversion Units in Costs Materials Costs (work done before current period) 1,250 5,000 6,250 1,250 0 1,250 250 4,000† 4,000 4,000 4,000 1,000 1,000 0 400 6,250 5,250 4,650 5,000
Degree of completion in this department: Transferred‐in costs, 100%; direct materials, 0%; conversion costs, 80%. †5,250 physical units completed and transferred out minus 1,250 physical units completed and transferred out from beginning work‐in‐process inventory. *Degree of completion in this department: transferred‐in costs, 100%; direct materials, 0%; conversion costs, 40%. §
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SOLUTION EXHIBIT 17‐41D Steps 3, 4, and 5: Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed and to Units in Ending Work in Process; FIFO Method of Process Costing, Drying and Packaging Department of Frito‐Lay Inc. for Week 37 Total Direct Conversion Production Transferred Costs ‐in Costs Materials Costs (Step 3) Work in process, beginning (given) $ 37,980 $ 28,920 $ 0 $ 9,060 Costs added in current period (given) 157,600 94,000 25,200 38,400 $122,920 $25,200 $47,460 Total costs to account for $195,580 (Step 4) Costs added in current period $ 94,000 $25,200 $38,400 Divide by equivalent units of work done in current 5,250 4,650 period (Solution Exhibit 17‐40C) 5,000 Cost per equivalent unit of work done in current period $ 18.80 $ 4.80 $ 8.258 (Step 5) Assignment of costs: Completed and transferred out (5,250 units): Work in process, beginning (1,250 units) $ 37,980 $28,920 + $0 + $9,060 Costs added to beg. work in process in current 8,065 (0* $18.80) + (1,250* $4.80) + (250* $8.258) period Total from beginning inventory 46,045 Started and completed (4,000 units) 127,432 (4,000† $18.80) + (4,000† $4.80) + (4,000† $8.258) 173,477 Total costs of units completed & transferred out 22,103 (1,000# $18.80) + (0# $4.80) + (400# $8.258) Work in process, ending (1,000 units) $195,580 $122,920 + $25,200 $47,460 Total costs accounted for *Equivalent units used to complete beginning work in process from Solution Exhibit 17‐41C, Step 2. †Equivalent units started and completed from Solution Exhibit 17‐41C, Step 2. #Equivalent units in ending work in process from Solution Exhibit 17‐41C, Step 2.
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Chapter 17
17‐42 (30‐35 min.) Standard costing with beginning and ending work in process. 1.
Solution Exhibit 17‐42A computes the equivalent units of work done in November 2012 by Paquita’s Pearls Company for direct materials and conversion costs.
2. and 3. Solution Exhibit 17‐42B summarizes total costs of the Paquita’s Pearls Company for November 30, 2012 and, using the standard cost per equivalent unit for direct materials and conversion costs, assigns these costs to units completed and transferred out and to units in ending work in process. The exhibit also summarizes the cost variances for direct materials and conversion costs for November 2012. SOLUTION EXHIBIT 17‐42A Steps 1 and 2: Summarize Output in Physical Units and Compute Output in Equivalent Units; Standard Costing Method of Process Costing, Paquita’s Pearls Company for the month ended November 30, 2012. (Step 2) (Step 1) Equivalent Units Physical Direct Conversion Flow of Production Units Materials Costs Work in process, beginning (given) 25,000 (work done before current Started during current period (given) 126,250 period) 151,250 To account for Completed and transferred out during current period: 25,000 § From beginning work in process 0 6,250 25,000 (100% 100%); 25,000 (100% – 75%) 100,000† Started and completed 100,000 100%, 100,000 100% 100,000 100,000 26,250 Work in process, ending* (given) _______ 26,250 13,125 26,250 100%; 26,250 50% Accounted for 151,250 _______ _______ Work done in current period only 126,250 119,375 §Degree of completion in this department: direct materials, 100%; conversion costs, 75%. †125,000 physical units completed and transferred out minus 25,000 physical units completed and transferred out from beginning work‐in‐process inventory. *Degree of completion in this department: direct materials, 100%; conversion costs, 50%.
Copyright © 2013 Pearson Canada Inc.
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SOLUTION EXHIBIT 17‐42B Steps 3, 4, and 5: Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed and to Units in Ending Work in Process; Standard‐Costing Method of Process Costing, Paquita’s Pearls Company for the month ended November 30, 2012. Total Production Costs (Step 3) Work in process, beginning (given) $ 250,000 Costs added in current period at standard costs 1,509,375 Total costs to account for $1,759,375 (Step 4) Standard cost per equivalent unit (given) (Step 5) Assignment of costs at standard costs: Completed and transferred out (125,000 units): $ 250,000 Work in process, beginning (25,000 units) 62,500 Costs added to beg. work in process in current period 312,500 Total from beginning inventory Started and completed (100,000 units) 1,250,000 Total costs of units transferred out 1,562,500 Work in process, ending (26,250 units) 196,875 Total costs accounted for $1,759,375 Summary of variances for current performance: Costs added in current period at standard costs (see Step 3 above) Actual costs incurred (given) Variance
Conversion Direct Costs Materials $ 62,500 + $ 187,500 (126,250 2.50) + (119,375 $10.00) $378,125 + $1,381,250 $ 2.50
$ 10.00
$62,500 + $187,500 (0* $2.50) + (6,250* $10.00) (100,000† $2.50) + (100,000† $10.00) (26,250# $2.50) + (13,125# $10.00) $378,125 + $1,381,250 $315,625 $1,193,750 327,500 1,207,415 $ 11,875 U $ 13,665 U
*Equivalent units to complete beginning work in process from Solution Exhibit 17‐42A, Step 2. †Equivalent units started and completed from Solution Exhibit 17‐42A, Step 2. #Equivalent units in ending work in process from Solution Exhibit 17‐42A, Step 2.
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Chapter 17
17‐43 (15 min.) Operation costing. Costs of Work Order 815 and Work Order 831 are as follows: Work Order 815 Number of units (pairs) 1,000 Direct materials costs $30,000 Conversion costs: Cutting (1,000 $11; 5,000 $11) 11,000 Sewing (1,000 $16; 5,000 $16) 16,000 Lining (1,000 $9; 0 $9) 9,000 Packing (1,000 $3; 5,000 $3) 3,000 Total costs $69,000 $69, 000 Total cost per unit $69 1, 000
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Work Order 831 5,000 $50,000 55,000 80,000 0 15,000 $200,000 $200, 000 $40 5, 000
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17‐44 (15‐30 min.) Operation costing, equivalent units. 1.
Materials and conversion costs of each operation, the total units produced, and the material and conversion cost per unit for the month of May are as follows:
Units produced Materials costs Materials cost per unit Conversion costs* Conversion cost per unit
Extrusion 18,000 $192,000 10.67 392,000 21.78
Form 12,500 $44,000 3.52 132,000 10.56
Trim 6,000 $15,000 2.50 69,000 11.50
Finish 2,500 $12,000 4.80 42,000 16.80
*Direct manufacturing labour and manufacturing overhead. The unit cost and total costs in May for each product are as follows: Plastic Standard Deluxe Cost Elements Sheets Model Model Extrusion materials (EM) $10.67 $10.67 $10.67 Form materials (FM) — 3.52 3.52 Trim materials (TM) — — 2.50 Finish materials — — — Extrusion conversion (EC) 21.78 21.78 21.78 Form conversion (FC) — 10.56 10.56 Trim conversion (TC) — — 11.50 Finish conversion — — — Total unit cost $ 32.45 $ 46.53 $ 60.53 Multiply by units produced 5,500 6,500 3,500 Total product costs $178,475 $302,445 $211,855
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Executive Model $10.67 3.52 2.50 4.80 21.78 10.56 11.50 16.80 $ 82.13 2,500 $205,325
Chapter 17
17‐44 (cont’d) 2.
Entering trim operation: 2,000 Deluxe units 1,500 Deluxe units 2,500 Executive units Total equivalent units
Equivalent Units Materials Conversion Costs Percent Percent Complete Quantity Complete Quantity 100 100 100
2,000 1,500 2,500 6,000
100 60 100
2,000 900 2,500 5,400
Conversion cost per equivalent unit in trim operation: ($30,000 + $39,000) ÷ 5,400 units = $12.78 per unit Materials cost per equivalent unit in trim operation (as before) $15,000 ÷ 6,000 units = $2.50 per unit Deluxe model work‐in‐process costs at the trim operation Extrusion material (100% complete when transferred in) Extrusion conversion (100% complete when transferred in) Form material (100% complete when transferred in) Form conversion (100% complete when transferred in) Trim material (100% complete) Trim conversion (60% complete) Work‐in‐process costs
Unit Cost
Equivalent Units
Total Costs
$10.67
1,500
$16,005
21.78
1,500
32,670
3.52
1,500
5,280
10.56 2.50 12.78 $61.81
1,500 1,500 900
15,840 3,750 11,502 $85,047
Copyright © 2013 Pearson Canada Inc.
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COLLABORATIVE LEARNING CASES
17‐45 (20‐25 min.) Equivalent unit computations, benchmarking, governance. 1.
2.
3.
The reported monthly cost per equivalent unit of either direct materials or conversion costs is lower when the plant manager overestimates the percentage of completion of ending work in process; the overestimate increases the denominator and thus decreases the cost per equivalent whole unit. By reporting a lower cost per equivalent unit, the plant manager increases the likelihood of being in the top three ranked plants for the benchmarking comparisons. A plant manager can manipulate the monthly estimate of percentage of completion by understating the number of steps yet to be undertaken before a suit becomes a finished good. There are several options available: a. Major shows the letters to the line executive to whom the plant managers report in a hard‐line way (say, the corporate manager of manufacturing). This approach is appropriate if the letters allege it is the plant managers who are manipulating the percentage of completion estimates. b. Major herself shows the letters to the plant managers. This approach runs the danger of the plant managers ignoring or reacting negatively to someone to whom they do not report in a line‐mode questioning their behaviour. Much will depend here on how Major raises the issue. Unsigned letters need not have much credibility unless they contain specific details. c. Major discusses the letters with the appropriate plant controllers without including the plant manager in the discussion. While the plant controller has responsibility for preparing the accounting reports from the plant, the plant controller in most cases reports hard‐line to the plant manager. If this reporting relationship exists, Major may create a conflict of interest situation for the plant controller. Only if the plant controller reports hard‐line to the corporate controller and dotted‐line to the plant manager should Major show the letters to the plant controller without simultaneously showing them to the plant manager. The plant controller’s ethical responsibilities to Major and to Leisure Suits should be the same. These include: • The plant controller is expected to have the competence to make equivalent unit computations. This competence does not always extend to making estimates of the percentage of completion of a product. In Leisure Suits’ case, however, the products are probably easy to understand and observe. Hence, a plant controller could obtain reasonably reliable evidence on percentage of completion at a specific plant. • The plant controller should not allow the possibility of the division being written‐ up favourably in the company newsletter to influence the way equivalent unit costs are computed.
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17‐45 (cont’d)
4. Major could seek evidence on possible manipulations as follows: a. Have plant controllers report detailed breakdowns on the stages of production and then conduct end‐of‐month audits to verify the actual stages completed for ending work in process. b. Examine trends over time in ending work in process. Divisions that report low amounts of ending work in process relative to total production are not likely to be able to greatly affect equivalent cost amounts by manipulating percentage of completion estimates. Divisions that show sizable quantities of total production in ending work in process are more likely to be able to manipulate equivalent cost computations by manipulating percentage of completion estimates.
17‐46 (25‐30 min.) Operation costing 1.
To obtain the overhead rates, divide the budgeted cost of each operation by the pairs of shoes that are expected to go through that operation.
Operation 1 Operation 2 Operation 3 Operation 4 Operation 5 Operation 6
Budgeted Conversion Cost $145,125 58,050 4,275 67,725 13,500 2,025
Conversion Cost per Pair of Shoes $4.50 1.80 1.90 2.10 0.45 0.90
Budgeted Pairs of Shoes 32,250 32,250 2,250 32,250 30,000 2,250
2.
Shoe type: Quantity: Direct Materials Operation 1 Operation 2 Operation 3 Operation 4 Operation 5 Operation 6 Total
Work Order 10399 Basic 1,000 $13,000 4,500 1,800 0 2,100 450 0 $21,850
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Work Order 10400 Elaborate 150 $4,200 675 270 285 315 0 135 $5,880
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17‐46 (cont’d) The direct materials costs per unit vary based on the type of shoe ($390,000 ÷ 30,000 = $13 for the Basic, and $63,000 ÷ 2,250 = $28 for the Elaborate). Conversion costs are charged using the rates computed in part (1), taking into account the specific operations that each type of shoe actually goes through. 3.
Work order 10399 (Basic shoes):
Total cost $21,850 Divided by number of pairs of shoes: ÷ 1,000 Cost per pair of plain shoes: $ 21.85
Work order 10400 (Elaborate shoes):
Total cost: $5,880 Divided by number of pairs of shoes: ÷ 150 Cost per pair of fancy shoes: $39.20
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CHAPTER 18 SPOILAGE, REWORK, AND SCRAP
SHORT‐ANSWER QUESTIONS
18‐1 Managers have found that improved quality and intolerance for high spoilage have lowered overall costs and increased sales.
18‐2 Spoilage—units of production that do not meet the standards required by customers for good units and that are discarded or sold at reduced prices. Rework—units of production that do not meet the specifications required by customers but which are subsequently repaired and sold as good finished units. Scrap—residual material that results from manufacturing a product. It has low total sales value compared to the total sales value of the product.
18‐3 Normal spoilage is spoilage inherent in a particular production process that arises even under efficient operating conditions. Management decides the spoilage rate it considers normal depending on the production process.
18‐4 Abnormal spoilage is spoilage that is not inherent in a particular production process and would not arise under efficient operating conditions. Costs of abnormal spoilage are “lost costs,” measures of inefficiency that should be written off directly as losses in the current accounting period.
18‐5 Management effort can affect the spoilage rate. Many companies are relentlessly reducing their rates of normal spoilage, spurred on by competitors who, likewise, are continuously reducing costs.
18‐6 Normal spoilage typically is expressed as a percentage of good units passing the inspection point. Given actual spoiled units, we infer abnormal spoilage as follows: Abnormal spoilage = Actual spoilage – Normal spoilage.
18‐7 Accounting for spoiled goods deals with cost assignment, rather than with cost incurrence, because the existence of spoiled goods does not involve any additional cost beyond the amount already incurred.
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18‐8 Yes. Normal spoilage rates should be computed from the good output or from the normal input, not the total input. Normal spoilage is a given percentage of a certain output base. This base should never include abnormal spoilage, which is included in total input. Abnormal spoilage does not vary in direct proportion to units produced, and to include it would cause the normal spoilage count to fluctuate irregularly and not vary in direct proportion to the output base.
18‐9 Yes, the point of inspection is the key to the assignment of spoilage costs. Normal spoilage costs do not attach solely to units transferred out. Thus, if units in ending work in process have passed inspection, they should have normal spoilage costs added to them.
18‐10 No. If abnormal spoilage is detected at a different point in the production cycle than normal spoilage, then unit costs would differ. If, however normal and abnormal spoilage are detected at the same point in the production cycle, their unit costs would be the same.
18‐11 No. Spoilage may be considered a normal characteristic of a given production cycle. The costs of normal spoilage caused by a random malfunction of a machine would be charged as a part of the manufacturing overhead allocated to all jobs. Normal spoilage attributable to a specific job is charged to that job.
18‐12 No. Unless there are special reasons for charging normal rework to jobs that contained the bad units, the costs of extra materials, labour, and so on are usually charged to manufacturing overhead and allocated to all jobs.
18‐13 Yes. Abnormal rework is a loss just like abnormal spoilage. By charging it to manufacturing overhead, the abnormal rework costs are spread over other jobs and also included in inventory to the extent a job is not complete. Abnormal rework is rework over and above what is expected during a period, and is recognized as a loss for that period.
18‐14 A company is justified in inventorying scrap when its estimated net realizable value is significant and the time between storing it and selling or reusing it is quite long.
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EXERCISES 18‐15 (10 min.)
Terminology.
There is no perfect machine, nor is there a perfect manufacturing process. That is why each process has at least one inspection point to assess the output quality and send the units back for rework and ultimately on for sale, or scrap them. Costs of reworked units are non‐value added for the customer who will therefore, not pay them. The company bears this cost. The difference between abnormal spoilage and normal spoilage is in accounting for the costs. Normal spoilage is predictable but unavoidable therefore GAAP allows this cost in cost of goods manufactured. Abnormal spoilage is avoidable but unpredictable and GAAP requires this cost be expensed. These costs did not produce an asset from which future revenue will be recovered therefore are not part of cost of goods manufactured.
18‐16 (5–10 min.) Normal and abnormal spoilage in units. 1. Total spoiled units 12,000 Normal spoilage in units, 5% 132,000 6,600 Abnormal spoilage in units 5,400 2. Abnormal spoilage, 5,400 $10 $ 54,000 Normal spoilage, 6,600 $10 66,000 Potential savings, 12,000 $10 $120,000 Regardless of the targeted normal spoilage, abnormal spoilage is non‐recurring and avoidable. The targeted normal spoilage rate is subject to change. Many companies have reduced their spoilage to almost zero, which would realize all potential savings. Of course, zero spoilage usually means higher‐quality products, more customer satisfaction, more employee satisfaction, and various beneficial effects on nonmanufacturing (for example, purchasing) costs of direct materials.
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18‐17 (20 min.) Weighted‐average method, spoilage, equivalent units. Solution Exhibit 18‐17 calculates equivalent units of work done to date for direct materials and conversion costs. SOLUTION EXHIBIT 18‐17 Summarize Output in Physical Units and Compute Output in Equivalent Units; Weighted‐Average Method of Process Costing with Spoilage, Grey Manufacturing Company for November 2013. (Step 1) (Step 2) Equivalent Units Physical Direct Conversion Flow of Production Units Materials Costs Work in process, beginning (given) 1,000 a Started during current period 10,150 To account for 11,150 Good units completed and transferred out 9,000 during current period: 9,000 9,000 Normal spoilage* 100 100 100 100%; 100 100% 100 50 Abnormal spoilage† 50 50 50 100%; 50 100% 2,000 Work in process, ending‡ (given) 600 2,000 2,000 100%; 2,000 30% Accounted for 11,150 11,150 9,750 Work done to date a From below, 11,150 total units are accounted for. Therefore, units started during current period must be = 11,150 – 1,000 = 10,150. *Degree of completion of normal spoilage in this department: direct materials, 100%; conversion costs, 100%. †Degree of completion of abnormal spoilage in this department: direct materials, 100%; conversion costs, 100%. ‡Degree of completion in this department: direct materials, 100%; conversion costs, 30%.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
18‐18 (2025 min.) Weighted‐average method, assigning costs. Solution Exhibit 18‐18 summarizes total costs to account for, calculates the costs per equivalent unit for direct materials and conversion costs, and assigns total costs to units completed and transferred out (including normal spoilage), to abnormal spoilage, and to units in ending work in process. SOLUTION EXHIBIT 18‐18 Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed, to Spoiled Units, and to Units in Ending Work in Process; Weighted‐Average Method of Process Costing, Grey Manufacturing Company, November 2013
Total Production Costs (Step 3) Work in process, beginning (given) $ 2,533 Costs added in current period (given) 39,930 Total costs to account for $42,463 (Step 4) Costs incurred to date Divided by equivalent units of work done to date Cost per equivalent unit (Step 5) Assignment of costs Good units completed and transferred out (9,000 units) $37,620 Costs before adding normal spoilage 418 Normal spoilage (100 units) (A) Total cost of good units completed & 38,038 transf. out 209 (B) Abnormal spoilage (50 units) 4,216 (C) Work in process, ending (2,000 units) $42,463 (A)+(B)+(C) Total costs accounted for
Direct Materials $ 1,423 12,180 $13,603 $13,603 11,150 $ 1.22
Conversion Costs $ 1,110 27,750 $28,860 $28,860 9,750 $ 2.96
(9,000# $1.22) + (9,000# $2.96) (100# $1.22) + (100# $2.96) (50# $1.22) + (50# $2.96) (2,000# $1.22) + (600# $2.96) $13,603 + $28,860
#
Equivalent units of direct materials and conversion costs calculated in Step 2 in Solution Exhibit 18‐17.
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Chapter 18
18‐19 (15 min.) FIFO method, spoilage, equivalent units. Solution Exhibit 18‐19 calculates equivalent units of work done in the current period for direct materials and conversion costs. SOLUTION EXHIBIT 18‐19 Summarize Output in Physical Units and Compute Output in Equivalent Units; First‐in, First‐out (FIFO) Method of Process Costing with Spoilage, Grey Manufacturing Company for November 2013. (Step 2) (Step 1) Equivalent Units Physical Direct Conversion Flow of Production Units Materials Costs Work in process, beginning (given) 1,000 a Started during current period 10,150 11,150 To account for Good units completed and transferred out during 1,000 current period: || From beginning work in process 500 0 1,000 (100% 100%); 1,000 (100% 50%) 8,000# Started and completed 8,000 8,000 100 8,000 100%; 8,000 100% Normal spoilage* 100 100 50 100 100%; 100 100% † Abnormal spoilage 50 50 50 100%; 50 100% 2,000 Work in process, ending‡ ____ 600 2,000 2,000 100%; 2,000 30% 11,150 Accounted for 10,150 9,250 Work done in current period only a From below, 11,150 total units are accounted for. Therefore, units started during current period must be 11,150 – 1,000 = 10,150. ||Degree of completion in this department: direct materials, 100%; conversion costs, 50%. #9,000 physical units completed and transferred out minus 1,000 physical units completed and transferred out from beginning work‐in‐process inventory. *Degree of completion of normal spoilage in this department: direct materials, 100%; conversion costs, 100%. †Degree of completion of abnormal spoilage in this department: direct materials, 100%; conversion costs, 100%. ‡Degree of completion in this department: direct materials, 100%; conversion costs, 30%.
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18‐20 (2025 min.) FIFO method, assigning costs. Solution Exhibit 18‐20 summarizes total costs to account for, calculates the costs per equivalent unit for direct materials and conversion costs, and assigns total costs to units completed and transferred out (including normal spoilage), to abnormal spoilage, and to units in ending work in process. SOLUTION EXHIBIT 18‐20 Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed, to Spoiled Units, and to Units in Ending Work in Process; FIFO Method of Process Costing, Grey Manufacturing Company, November 2013
Total Production Costs (Step 3) Work in process, beginning (given) $ 2,533 Costs added in current period (given) 39,930 Total costs to account for $42,463 (Step 4) Costs added in current period Divided by equivalent units of work done in current period Cost per equivalent unit (Step 5) Assignment of costs: Good units completed and transferred out (9,000 units) $ 2,533 Work in process, beginning (1,000 units) 1,500 Costs added to beg. work in process in current period Total from beginning inventory before normal 4,033 spoilage 33,600 Started and completed before normal spoilage (8,000 420 units) 38,053 Normal spoilage (100 units) 210 (A) Total costs of good units completed and 4,200 transferred out $42,463 (B) Abnormal spoilage (50 units) (C) Work in process, ending (2,000 units) (A)+(B)+(C) Total costs accounted for
Direct Materials $ 1,423 12,180 $13,603 $12,180 10,150 $ 1.20
Conversion Costs $ 1,110 27,750 $28,860 $27,750 9,250 $ 3
$1,423 + $1,110 (0a $1.20) + (500a $3) (8,000a $1.20) + (8,000a $3) (100a $1.20) + (100a $3) (50a $1.20) + (50a $3) (2,000a $1.20) + (600a $3) $13,603 + $28,860
Equivalent units of direct materials and conversion costs calculated in Step 2 in Solution Exhibit 18‐19.
a
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Copyright © 2013 Pearson Canada Inc.
Chapter 18
18‐21 (35 min.) Weighted‐average method, spoilage. 1.
Solution Exhibit 18‐21A calculates equivalent units of work done in the current period for direct materials and conversion costs.
SOLUTION EXHIBIT 18‐21A Summarize Output in Physical Units and Compute Output in Equivalent Units; Weighted‐Average Method of Process Costing with Spoilage, Appleton Company for August 2013. (Step 1) (Step 2) Equivalent Units Physical Direct Conversion Flow of Production Units Materials Costs Work in process, beginning (given) 2,000 Started during current period (given) 10,000 To account for 12,000 Good units completed and tsfd. out during current period: 9,000 9,000 9,000 a 900 Normal spoilage (900 100%; 900 100%) 900 900 b Abnormal spoilage 300 (300 100%; 300 100%) 300 300 c Work in process, ending (given) 1,800 (1,800 100%; 1,800 75%) ______ 1,800 1,350 ______ Accounted for 12,000 ______ Work done to date 12,000 11,550 aNormal spoilage is 10% of good units transferred out: 10% × 9,000 = 900 units. Degree of completion of normal spoilage in this department: direct materials, 100%; conversion costs, 100%. bTotal spoilage = Beg. units + Units started ‐ Good units transferred out – Ending units = 2,000 + 10,000 ‐ 9,000 ‐ 1,800 = 1,200; Abnormal spoilage = Total spoilage – Normal spoilage = 1,200 – 900 = 300 units. Degree of completion of abnormal spoilage in this department: direct materials, 100%; conversion costs, 100%. cDegree of completion in this department: direct materials, 100%; conversion costs, 75%.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
18‐21 (cont’d) 2.
Solution Exhibit 18‐21B summarizes total costs to account for, calculates the costs per equivalent unit for direct materials and conversion costs, and assigns total costs to units completed and transferred out (including normal spoilage), to abnormal spoilage, and to units in ending work in process, using the weighted‐ average method.
SOLUTION EXHIBIT 18‐21B Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed, to Spoiled Units, and to Units in Ending Work in Process; Weighted‐Average Method of Process Costing, Appleton Company, August 2013.
(Step 3)
Work in process, beginning (given) Costs added in current period (given)
(Step 4)
Total costs to account for Costs incurred to date Divide by equivalent units of work done to date Cost per equivalent unit Assignment of costs Good units completed and transferred out (9,000 units)
(Step 5) (A) (B)
Costs before adding normal spoilage Normal spoilage (900 units) Total costs of good units completed and transferred out Abnormal spoilage (300 units)
Total Production Costs $ 28,600 174,300 $202,900
Direct Materials $17,700 81,300 $99,000 $99,000 12,000 $ 8.250
Conversion Costs $ 10,900 93,000 $103,900 $103,900 ÷11,550 $ 8.9957
(9,000d $8.25) + (9,000 d $8.9957) $155,211 d 15,521 (900 $8.25) + (900d $8.9957)
170,732 d 5,174 (300 $8.25) + (300d $8.9957) (1,800d $8.25) + (1,350d $8.9957) (C) Work in process, ending (1,800 units): 26,994 (A) + (B) + (C) Total costs accounted for $202,900 $99,000 + $103,900 dEquivalent units of direct materials and conversion costs calculated in step 2 of Solution Exhibit 18‐21A.
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Chapter 18
18‐22 (10 min.) Standard‐costing method, spoilage, and journal entries. Spoilage represents the amount of resources that go into the process, but do not result in finished product. A simple way to account for spoilage in process costing is to calculate the amount of direct material that was spoiled. The journal entry to record the spoilage incurred in Aaron’s production process is: Manufacturing overhead control (normal spoilage) 250 Work‐in‐process inventory (cost of spoiled sheet metal) 250
18‐23 (15 min.) Recognition of loss from spoilage. 1. 2. 3.
The unit cost of making the 10,000 units is: $209,000 ÷ 10,000 units = $20.90 per unit The total cost of the 500 spoiled units is: $20.90 × 500 units = $10,450 The increase in the per‐unit cost of goods sold as a result of the normal spoilage is: $10,450 ÷ 9,500 good units = $1.10 Unit cost of goods sold for units remaining after the spoilage = $20.90 + $1.10 = $22.00. (Another way to calculate this is $209,000 ÷ 9,500 units = $22.00 per unit.)
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
18‐24 (25 min.) Weighted‐average method, spoilage. 1.
Solution Exhibit 18‐24, Panel A, calculates the equivalent units of work done to date for each cost category in September 2013.
2.
Solution Exhibit 18‐24, Panel B, summarizes total costs to account for, calculates the costs per equivalent unit for each cost category, and assigns total costs to units completed (including normal spoilage), to abnormal spoilage, and to units in ending work in process using the weighted‐average method.
SOLUTION EXHIBIT 18‐24 Weighted‐Average Method of Process Costing with Spoilage; Chipcity, September 2013. PANEL A: Steps 1 and 2—Summarize Output in Physical Units and Compute Output in Equivalent Units (Step 1) (Step 2) Equivalent Units Physical Direct Conversion Flow of Production Units Materials Costs 600 Work in process, beginning (given) 2,550 Started during current period (given) 3,150 To account for Good units completed and transferred out 2,100 2,100 2,100 during current period: 315 Normal spoilage* 315 315 315 100%; 315 100% 285 Abnormal spoilage† 285 100%; 285 100% 285 285 Work in process, ending‡ (given) 450 450 100%; 450 40% 180 450 3,150 Accounted for 3,150 2,880 Work done to date *Normal spoilage is 15% of good units transferred out: 15% 2,100 = 315 units. Degree of completion of normal spoilage in this department: direct materials, 100%; conversion costs, 100%. †Total spoilage = 600 + 2,550 – 2,100 – 450 = 600 units; Abnormal spoilage = Total spoilage Normal spoilage = 600 315 = 285 units. Degree of completion of abnormal spoilage in this department: direct materials, 100%; conversion costs, 100%. ‡Degree of completion in this department: direct materials, 100%; conversion costs, 40%.
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Chapter 18
SOLUTION EXHIBIT 18‐24 PANEL B: Steps 3, 4, and 5— Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed, to Spoiled Units, and to Units in Ending Work in Process Total Conversion Direct Production Costs Materials Costs (Step 3) Work in process, beginning (given) $111,300 $ 96,000 $ 15,300 Costs added in current period (given) 797,400 567,000 230,400 Total costs to account for $908,700 $663,000 $245,700 (Step 4) Costs incurred to date $663,000 $245,700 Divided by equivalent units of work done 3,150 2,880 to date $210.476 $85.3125 Cost per equivalent unit (Step 5) Assignment of costs Good units completed and transferred out (2,100 units) $621,156 (2,100#$210.476) + (2,100#$85.3125) Costs before adding normal spoilage 93,173 (315# $210.476) + (315# $85.3125) Normal spoilage (315 units) (A) Total cost of good units completed and transferred out 714,329 (B) Abnormal spoilage (285 units) 84,300 (285# $210.476) + (285# $85.3125) (C) Work‐in‐process, ending (450 units) 110,071 (450# $210.476) + (180# $85.3125) (A)+(B)+(C) Total costs accounted for $908,700 $663,000 $245,700 # Equivalent units of direct materials and conversion costs calculated in Step 2 in Panel A.
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18‐25 (25 min.) FIFO method, spoilage. 1.
Solution Exhibit 18‐25, Panel A, calculates the equivalent units of work done in the current period for each cost category in September 2013.
2.
Solution Exhibit 18‐25, Panel B, summarizes the total Chip Department costs for September 2013, calculates the costs per equivalent unit for each cost category, and assigns total costs to units completed and transferred out (including normal spoilage), to abnormal spoilage, and to units in ending work in process under the FIFO method.
SOLUTION EXHIBIT 18‐25 First‐in, First‐out (FIFO) Method of Process Costing with Spoilage; Chipcity, September 2013. PANEL A: Steps 1 and 2—Summarize Output in Physical Units and Compute Output in Equivalent Units (Step 2) (Step 1) Equivalent Units Physical Direct Conversion Flow of Production Units Materials Costs Work in process, beginning (given) 600 Started during current period (given) 2,550 3,150 To account for Good units completed and transferred out during current period: || 600 From beginning work in process 600 (100% 100%); 600 (100% 30%) 0 420 Started and completed 1,500# 1,500 100%; 1,500 100% 1,500 1,500 315 Normal spoilage* 315 100%; 315 100% 315 315 † Abnormal spoilage 285 285 100%; 285 100% 285 285 Work in process, ending‡ 450 450 100%; 450 40% 450 180 Accounted for 3,150 Work done in current period only 2,550 2,700 ||Degree of completion in this department: direct materials, 100%; conversion costs, 30%. #2,100 physical units completed and transferred out minus 600 physical units completed and transferred out from beginning work in process inventory.
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18‐25 (cont’d) *Normal spoilage is 15% of good units transferred out: 15% 2,100 = 315 units. Degree of completion of normal spoilage in this department: direct materials, 100%; conversion costs, 100%. †Abnormal spoilage = Actual spoilage Normal spoilage = 600 315 = 285 units. Degree of completion of abnormal spoilage in this department: direct materials, 100%; conversion costs, 100%. ‡Degree of completion in this department: direct materials, 100%; conversion costs, 40%.
SOLUTION EXHIBIT 18‐25 PANEL B: Steps 3, 4 and 5— Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed, to Spoiled Units, and to Units in Ending Work in Process Total Conversion Direct Production Costs Materials Costs (Step 3) Work in process, beginning (given) $111,300 $ 96,000 $ 15,300 Costs added in current period (given) 797,400 567,000 230,400 Total costs to account for $908,700 $663,000 $245,700 (Step 4) Costs added in current period $567,000 $230,400 Divided by equivalent units of work done in 2,550 2,700 current period $222.353 $ 85.333 Cost per equivalent unit (Step 5) Assignment of costs: Good units completed and transferred out (2,100 units) $111,300 Work in process, beginning (600 units) 35,840 Costs added to beg. work in process in current period $96,000 + $15,300 Total from beginning inventory before 147,140 (0§ $222.353) + (420§ $85.333) normal spoilage Started and completed before normal 461,529 spoilage 96,921 (1,500 units) (1,500§ $222.353)+(1,500§$85.333) Normal spoilage (315 units) 705,590 (315§ $222.353) + (315§ $85.333) (A) Total costs of good units completed and 87,691 transferred out 115,419 (B) Abnormal spoilage (285 units) (285§ $222.353) + (285§ $85.333) (C) Work in process, ending (450 units) (450§ $222.353) + (180§ $85.333) (A)+(B)+(C) Total costs accounted for $908,700 $663,000 + $245,700 Equivalent units of direct materials and conversion costs calculated in Step 2 in Panel A.
§
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
18‐26 (30 min.) Standard‐costing method, spoilage. 1.
2.
Solution Exhibit 18‐25, Panel A, shows the computation of the equivalent units of work done in September 2013 for direct materials (2,550 units) and conversion costs (2,700 units). (This computation is the same for FIFO and standard‐costing.) The direct materials cost per equivalent unit of beginning work in process and of work done in September 2013 is the standard cost of $200 given in the problem. The conversion cost per equivalent unit of beginning work in process and of work done in September 2013 is the standard cost of $75 given in the problem. Solution Exhibit 18‐26 summarizes the total costs to account for, and assigns these costs to units completed (including normal spoilage), to abnormal spoilage, and to units in ending work in process using the standard costing method.
SOLUTION EXHIBIT 18‐26 Standard Costing Method of Process Costing with Spoilage; Chipcity, September 2013. Steps 3, 4, and 5—Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed, to Spoiled Units, and to Units in Ending Work in Process Total Conversion Direct Production Costs Materials Costs (Step 3) Work in process, beginning* $133,500 (600 $200) (180 $75) Costs added in current period at standard prices 712,500 (2,550 $200) (2,700 $75) Costs to account for $846,000 $630,000 $216,000 (Step 4) Standard costs per equivalent unit (given) $ 275 $ 200 $ 75 (Step 5) Assignment of costs at standard costs: Good units completed and transferred out (2,100 units) $133,500 Work in process, beginning (600 units)* (600 $200) + (180 $75) 31,500 Costs added to beg. work in process in current (0§ $200) + (420§ $75) period Total from beginning inventory before normal 165,000 spoilage Started and completed before normal spoilage 412,500 (1,500§ $200) + (1,500§ $75) (1,500 units) 86,625 (315§ $200) + (315§ $75) Normal spoilage (315 units) (A) Total costs of good units completed and 664,125 transferred out 78,375 (B) Abnormal spoilage (285 units) 103,500 (285§ $200) + (285§ $75) (C) Work in process, ending (450 units) $846,000 (450§ $200) + (180§ $75) (A)+(B)+(C) Total costs accounted for $630,000 + $216,000
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18‐26 (cont’d) *Work in process, beginning has 600 equivalent units (600 physical units 100%) of direct materials and 180 equivalent units (600 physical units 30%) of conversion costs. §Equivalent units of direct materials and conversion costs calculated in Step 2 in Solution Exhibit 18‐25, Panel A.
18‐27 (20–30 min.) Spoilage and job costing. 1.
Cash Loss from Abnormal Spoilage Work‐in‐Process Control Loss = ($6.00 200) – $200 = $1,000
200 1,000
1,200
Remaining cases cost = $6.00 per case. The cost of these cases is unaffected by the loss from abnormal spoilage.
2. a. Cash 400 Work‐in‐Process Control 400 The cost of the remaining good cases = [($6.00 2,500) – $400] = $14,600 The unit cost of a good case now becomes $14,600 2,300 = $6.3478 b. Cash 400 Manufacturing Department Overhead Control 800 Work‐in‐Process Control 1,200 The unit cost of a good case remains at $6.00. c. The unit costs in 2a and 2b are different because in 2a the normal spoilage cost is charged as a cost of the job which has exacting job specifications. In 2b however, normal spoilage is due to the production process, not the particular attributes of this specific job. These costs are, therefore, charged as part of manufacturing overhead and the manufacturing overhead cost of $1 per case already includes a provision for normal spoilage.
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18‐27 (cont’d) 3.
a.
Work‐in‐Process Control Materials Control, Wages Payable Control, Manufacturing Overhead Allocated
200
The cost of the good cases = [($6.00 2,500) + $200] = $15,200 The unit cost of a good case is $15,200 2,500 = $6.08
b. Manufacturing Department Overhead Control 200 Materials Control, Wages Payable Control, Manufacturing Overhead Allocated 200 The unit cost of a good case = $6.00 per case c. The unit costs in 3a and 3b are different because in 3a the normal rework cost is charged as a cost of the job which has exacting job specifications. In 3b however, normal rework is due to the production process, not the particular attributes of this specific job. These costs are, therefore, charged as part of manufacturing overhead and the manufacturing overhead cost of $1 per case already includes a provision for this normal rework.
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200
Copyright © 2013 Pearson Canada Inc.
Chapter 18
18‐28 (15 min.) Reworked units, costs of rework. 1.
The two alternative approaches to account for the materials costs of reworked units are: a. To charge the costs of rework to the current period as a separate expense item as abnormal rework. This approach would highlight to Grey Goods the costs of the supplier problem. b. To charge the costs of the rework to manufacturing overhead as normal rework.
2.
3.
The $50 tumbler cost is the cost of the actual tumblers included in the washing machines. The $44 tumbler units from the first supplier were eventually never used in any washing machine, and that supplier is now bankrupt. The units have now been disposed of at zero disposal value. The total costs of rework due to the defective tumbler units include the following: a. the labour and other conversion costs spent on substituting the new tumbler units; b. the costs of any extra negotiations to obtain the replacement tumbler units; c. any higher price the existing supplier may have charged to do a rush order for the replacement tumbler units; and d. ordering costs for the replacement tumbler units.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
18‐29 (25 min.) Scrap, job‐order costing. 1.
Journal entry to record scrap generated by a specific job and accounted for at the time scrap is sold is: Cash or Accounts Receivable Work‐in‐Process Control To recognize asset from sale of scrap. A memo posting is also made to the specific job record.
2.
490
490
Scrap common to various jobs and accounted for at the time of its sale can be accounted for in two ways: a.
Regard scrap sales as a separate line item of revenue (the method generally used when the dollar amount of scrap is immaterial):
Cash or Accounts Receivable Sale of Scrap To recognize revenue from sale of scrap. b.
4,000
Regard scrap sales as offsets against manufacturing overhead (the method generally used when the dollar amount of scrap is material):
Cash or Accounts Receivable Manufacturing Department Overhead Control To record cash raised from sale of scrap.
4,000
4,000
4,000
3.
Journal entry to record scrap common to various jobs at the time scrap is returned to storeroom: Materials Control 4,000 Manufacturing Department Overhead Control 4,000 To record value of scrap returned to storeroom.
When the scrap is reused as direct material on a subsequent job, the journal entry is: Work‐in‐Process Control 4,000 Materials Control 4,000 To record reuse of scrap on a job. Explanations of journal entries are provided here but are not required.
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PROBLEMS
18‐30 (30 min.) Weighted‐average method, spoilage. Solution Exhibit 18‐30 summarizes total costs to account for, calculates the equivalent units of work done to date for each cost category, and assigns total costs to units completed (including normal spoilage), to abnormal spoilage, and to units in ending work in process using the weighted‐average method. SOLUTION EXHIBIT 18‐30 Weighted‐Average Method of Process Costing with Spoilage; Cleaning Department of the Red Deer Company for May. PANEL A: Steps 1 and 2—Summarize Output in Physical Units and Compute Output in Equivalent Units
(Step 1) Physical Units 2,500 22,500 25,000 18,500 1,850 650 4,000 25,000
(Step 2) Equivalent Units Direct Conversion Materials Costs 18,500 18,500 1,850 1,850 650 650 4,000 1,000 25,000 22,000
Flow of Production Work in process, beginning (given) Started during current period (given) To account for Good units completed and transferred out during current period: Normal spoilage* 1,850 100%; 1,850 100% Abnormal spoilage† 650 100%; 650 100% Work in process, ending‡ (given) 4,000 100%; 4,000 25% Accounted for Work done to date *Normal spoilage is 10% of good units transferred out: 10% 18,500 = 1,850 units. Degree of completion of normal spoilage in this department: direct materials, 100%; conversion costs, 100%. †Total spoilage = 2,500 + 22,500 – 18,500 – 4,000 = 2,500 units; Abnormal spoilage = 2,500 – 1,850 = 650 units. Degree of completion of abnormal spoilage in this department: direct materials, 100%; conversion costs, 100%. ‡Degree of completion in this department: direct materials, 100%; conversion costs, 25%.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
SOLUTION EXHIBIT 18‐30 PANEL B: Steps 3, 4, and 5— Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed, to Spoiled Units, and to Units in Ending Work in Process Total Conversion Direct Production Costs Materials Costs (Step 3) Work in process, beginning (given) $ 4,500 $ 2,500 $ 2,000 42,500 22,500 20,000 Costs added in current period (given) Total costs to account for $47,000 $25,000 $22,000 (Step 4) Costs incurred to date $25,000 $22,000 Divided by equivalent units of work done to 25,000 22,000 date $ 1 $ 1 Cost per equivalent unit (Step 5) Assignment of costs Good units completed and transferred out (18,500 units) Costs before adding normal spoilage $37,000 (18,500# $1) + (18,500# Normal spoilage (1,850 units) 3,700 (1,850# $1) + $1) (1,850# $1) (A) Total costs of good units completed and transferred out 40,700 (B) Abnormal spoilage (650 units) 1,300 (650# $1) + # $1) + (650# $1) (4,000 (C) Work in process, ending (4,000 units) 5,000 (A)+(B)+(C) Total costs accounted for $47,000 $25,000 + (1,000# $1) $22,000 #
Equivalent units of direct materials and conversion costs calculated in Step 2 in Panel A above.
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Copyright © 2013 Pearson Canada Inc.
Chapter 18
18‐31 (25 min.) FIFO method, spoilage. For the Cleaning Department, Solution Exhibit 18‐31 summarizes the total costs for May, calculates the equivalent units of work done in the current period for direct materials and conversion costs, and assigns total costs to units completed and transferred out (including normal spoilage), to abnormal spoilage, and to units in ending work in process under the FIFO method. SOLUTION EXHIBIT 18‐31 First‐in, First‐out (FIFO) Method of Process Costing with Spoilage; Cleaning Department of the Red Deer Company for May. PANEL A: Steps 1 and 2—Summarize Output in Physical Units and Compute Output in Equivalent Units (Step 2) (Step 1) Equivalent Units Physical Direct Conversion Flow of Production Units Materials Costs Work in process, beginning (given) 2,500 Started during current period (given) 22,500 To account for 25,000 Good units completed and transferred out during current period: || 2,500 From beginning work in process 2,500 (100% 100%); 2,500 (100% 80%) 0 500 # Started and completed 16,000 16,000 100%; 16,000 100% 16,000 16,000 Normal spoilage* 1,850 1,850 100%; 1,850% 100% 1,850 1,850 650 Abnormal spoilage† 650 100%; 650 100% 650 650 ‡ 4,000 Work in process, ending 4,000 100%; 4,000 25% _____ 4,000 1,000 _____ _____ Accounted for 25,000 20,000 Work done in current period only 22,500 || Degree of completion in this department: direct materials, 100%; conversion costs, 80%. #18,500 physical units completed and transferred out minus 2,500 physical units completed and transferred out from beginning work‐in‐process inventory. *Normal spoilage is 10% of good units transferred out: 10% 18,500 = 1,850 units. Degree of completion of normal spoilage in this department: direct materials, 100%; conversion costs, 100%.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
18‐31 (cont’d)
Total spoilage = 2,500 + 22,500 – 18,500 – 4,000 = 2,500 units Abnormal spoilage = 2,500 – 1,850 = 650 units. Degree of completion of abnormal spoilage in this department: direct materials, 100%; conversion costs, 100%. ‡Degree of completion in this department: direct materials, 100%; conversion costs, 25%. †
SOLUTION EXHIBIT 18‐31 PANEL B: Steps 3, 4, and 5— Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed, to Spoiled Units, and to Units in Ending Work in Process Total Conversion Direct Production Costs Materials Costs (Step 3) Work in process, beginning (given) $ 4,500 $ 2,500 $ 2,000 Costs added in current period (given) 42,500 22,500 20,000 Total costs to account for $47,000 $25,000 $22,000 (Step 4) Costs added in current period $22,500 $20,000 Divided by equivalent units of work done in current 22,500 20,000 period $ 1 $ 1 Cost per equivalent unit (Step 5) Assignment of costs: Good units completed and transferred out (18,500 units) $ 4,500 $2,500 + $2,000 Work in process, beginning (2,500 units) 500 (0§ $1) + (500§ $1) Costs added to beg. work in process in current period 5,000 Total from beginning inventory before normal 32,000 (16,000§ $1) + (16,000§ $1) spoilage 3,700 (1,850§ $1) + (1,850§ $1) Started and completed before normal spoilage 40,700 (16,000 units) 1,300 (650§ $1) + (650§ $1) Normal spoilage (1,850 units) 5,000 (4,000§ $1) + (1,000§ $1) (A) Total costs of good units completed and $47,000 $25,000 + $22,000 transferred out (B) Abnormal spoilage (650 units) (C) Work in process, ending (4,000 units) (A)+(B)+(C) Total costs accounted for §Equivalent units of direct materials and conversion costs calculated in Step 2 in Panel A.
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Copyright © 2013 Pearson Canada Inc.
Chapter 18
18‐32 (35 min.) Weighted‐average method, Packaging department. For the Packaging Department, Solution Exhibit 18‐32 summarizes total costs to account for, calculates the equivalent units of work done to date for each cost category, and assigns costs to units completed (including normal spoilage), to abnormal spoilage, and to units in ending work in process using the weighted‐average method. SOLUTION EXHIBIT 18‐32 Weighted‐Average Method of Process Costing with Spoilage; Packaging Department of the Red Deer Company for May. PANEL A: Steps 1 and 2—Summarize Output in Physical Units and Compute Output in Equivalent Units (Step 1) (Step 2) Equivalent Units Physical Transferred‐ Direct Conversion Flow of Production Units in Costs Materials Costs Work in process, beginning (given) 7,500 Started during current period (given) 18,500 To account for 26,000 Good units completed and transferred 15,000 15,000 15,000 15,000 out 750 during current period: 750 750 750 Normal spoilage* 250 750 100%; 750 100%; 750 100% 250 250 250 Abnormal spoilage† 250 100%; 250 100%, 250 100% 10,000 ‡ Work in process, ending (given) 0 2,500 10,000 10,000 100%; 10,0000%; 10,00025% 26,000 ______ _____ 26,000 Accounted for 16,000 18,500 Work done to date *Normal spoilage is 5% of good units transferred out: 5% 15,000 = 750 units. Degree of completion of normal spoilage in this department: transferred‐in costs, 100%; direct materials, 100%; conversion costs, 100%. †Total spoilage =7,500 + 18,500 – 15,000 – 10,000 = 1,000 units. Abnormal spoilage = 1,000 – 750 = 250 units. Degree of completion of abnormal spoilage in this department: transferred‐in costs, 100%; direct materials, 100%; conversion costs, 100%. ‡
Degree of completion in this department: transferred‐in costs, 100%; direct materials, 0%; conversion costs, 25%.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
SOLUTION EXHIBIT 18‐32 PANEL B: Steps 3, 4, and 5— Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed, to Spoiled Units, and to Units in Ending Work in Process
(Step 3)
Work in process, beginning (given) Costs added in current period (given) Total costs to account for (Step 4) Costs incurred to date Divided by equivalent units of work done to date Cost per equivalent unit (Step 5) Assignment of costs Good units completed and transferred out (15,000 units) Costs before adding normal spoilage Normal spoilage (750 units) (A) Total cost of good units completed and transferred out (B) Abnormal spoilage (250 units) (C) Work in process, ending (10,000 units) (A)+(B)+(C)Total costs accounted for
Total Production Transferred‐ in costs Costs $16,125 $22,250 40,700* 54,675 $76,925 $56,825 56,825 26,000 $2.1856
Direct Materials $ 0 1,600 $1,600 1,600 16,000 $ 0.10
Conversion Costs $ 6,125 12,375 $18,500 18,500 18,500 $ 1
15,000# ($2.1856 + $0.10 + $1) $49,284 750# ($2.1856 + $0.10 + $1) 2,464 51,748 250# ($2.1856 + $0.10 + $1) 821 24,356 (10,000# $2.1856)+(0# $0.10)+(2,500# $1) $76,925 $56,825 + $1,600 + $18,500
*Total costs of good units completed and transferred out in Panel B (Step 5) of Solution Exhibit 18‐30. #Equivalent units of direct materials and conversion costs calculated in Step 2 in Panel A above.
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Copyright © 2013 Pearson Canada Inc.
Chapter 18
18‐33 (25 min.) FIFO method, Packaging Department (continuation of 18‐31). Solution Exhibit 18‐33 summarizes the total Packaging Department costs for May, shows the equivalent units of work done in the Packaging Department in the current period for transferred‐in costs, direct materials, and conversion costs, and assigns total costs to units completed and transferred out (including normal spoilage), to abnormal spoilage, and to units in ending work‐in‐process under the FIFO method. SOLUTION EXHIBIT 18‐33 First‐in, First‐out (FIFO) Method of Process Costing with Spoilage; Packaging Department of the Red Deer Company for May. PANEL A: Steps 1 and 2—Summarize Output in Physical Units and Compute Output in Equivalent Units (Step 2) (Step 1) Equivalent Units Physical Transferred Direct Conversion Flow of Production Units in Costs Materials Costs Work in process, beginning (given) 7,500 Started during current period (given) 18,500 To account for 26,000 Good units completed and transferred out during current period: 7,500 From beginning work in process|| 7,500 (100% 100%); 7,500 7,500 1,500 0 # (100% 0%); 7,500 (100% 80%) 7,500 Started and completed 7,500 7,500 7,500 7,500 100%; 7,500 100%; 7,500 750 100% 750 750 750 Normal spoilage* 250 750 100%; 750% 100%; 750 100% 250 250 250 Abnormal spoilage† 10,000 250 100%; 250 100%; 250 100% 0 2,500 10,000 Work in process, ending‡ 26,000 10,000 100%; 10,000 0%; 10,000 25% 18,500 16,000 12,500 Accounted for Work done in current period only ||Degree of completion in this department: transferred‐in costs, 100%; direct materials, 0%; conversion costs, 80%. #15,000 physical units completed and transferred out minus 7,500 physical units completed and transferred out from beginning work‐in‐process inventory.
Copyright © 2013 Pearson Canada Inc.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
18‐33 (cont’d) *Normal spoilage is 5% of good units transferred out: 5% 15,000 = 750 units. Degree of completion of normal spoilage in this department: transferred‐in costs, 100%; direct materials, 100%; conversion costs, 100%. †Total spoilage = 7,500 + 18,500 – 15,000 – 10,000 = 1,000 units. Abnormal spoilage = 1,000 – 750 = 250 units. Degree of completion of abnormal spoilage in this department: transferred‐in costs, 100%; direct materials, 100%; conversion costs, 100%. ‡Degree of completion in this department: transferred‐in costs, 100%; direct materials, 0%; conversion costs, 25%.
SOLUTION EXHIBIT 18‐33 PANEL B: Steps 3, 4, and 5— Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed, to Spoiled Units, and to Units in Ending Work in Process Total Conversion Direct Production Transferred‐ Costs Materials in Costs Costs (Step 3) Work in process, beginning (given) $22,250 $16,125 Costs added in current period (given) $ 0 $ 6,125 40,700* 54,675 Total costs to account for 1,600 12,375 (Step 4) Costs added in current period $76,925 $56,825 $1,600 $18,500 Divided by equivalent units of work done in current period $40,700 $1,600 $12,375 Cost per equivalent unit 18,500 ÷16,000 12,500 (Step 5) Assignment of costs: $ 2.20 $ 0.10 $ 0.99 Good units completed and transferred out (15,000 units) $22,250 $16,125 + $0 + $6,125 Work in process, beginning (7,500 units) Costs added to beg. work in process (0 $2.20) + (7,500§ 0.10)+(1,500§$0.99) in current period 2,235 Total from beginning inventory before normal spoilage 24,485 Started and completed before normal § ($2.20 + $0.10 + $0.99) 7,500 spoilage (7,500 units) 24,675 Normal spoilage (750 units) 2,467 750§ ($2.20 + $0.10 + $0.99) (A) Total costs of good units completed and transferred out 51,627 § (B) Abnormal spoilage (250 units) 823 250 ($2.20 + $0.10 + $0.99) (10,000§$2.20)+(0§$0.10)+(2,500§$0.99) (C) Work in process, ending (10,000 units) 24,475 (A)+(B)+(C) Total costs accounted for $76,925 $56,825 + $1,600 + $18,500 *Total costs of good units completed and transferred out in Step 5 Panel B of Solution Exhibit 18‐31. Equivalent units of direct materials and conversion costs calculated in Step 2 in Panel A.
§
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Copyright © 2013 Pearson Canada Inc.
Chapter 18
18‐34 (2025 min.) Job‐costing spoilage and scrap. 1. 2.
a. Materials Control Manufacturing Overhead Control Work‐in‐Process Control (975 + 600 + 300 = 1,875) b. Accounts Receivable or Cash Work‐in‐Process Control
800 1,075
1,875
1,995
1,995
a. The clause does not specify whether the 1% calculation is to be based on the input cost ($40,400 + $22,600 + $11,300) or the cost of the good output before the ʺ1% normal spoilageʺ is added. b. If the inputs are used to determine the 1%: $40,400 + $22,600 + $11,300 = $74,300 1% of $74,300 = $743. Then, the entry to leave the $743 ʺnormal spoilageʺ cost on the job, remove the salvageable material, and charge manufacturing overhead would be:
Materials Control Manufacturing Overhead Control Work‐in‐Process Control ($1,075 spoilage minus $743 = $332 spoilage cost that is taken out of the job; $800 salvage value plus $332 = $1,132; or $1,875 minus $743 = $1,132)
800 332
1,132
If the outputs are used to determine the 1%: $40,400 – $975 = $39,425 22,600 – 600 = 22,000 11,300 – 300 = 11,000 $74,300 $72,425
Then, $72,425 1% = $724.25 or $724, rounded. The journal entry would be: Materials Control Manufacturing Overhead Control Work‐in‐Process Control
800 351
1,151
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
18‐35 (25 min.)
Weighted‐average method, spoilage 1. Physical Equivalent units PHYSICAL FLOW UNITS MATERIALS CONVERSION Beginning WIP 400 Started into production 1,700 To account for 2,100 Completed & transferred out 1,400 1,400 1,400 Normal spoilage (15%)* 210 210 210 Abnormal spoilage* 190 190 190 Ending WIP 300 300 (100%) 120 (40%) ______ ______ Accounted for 2,100 Work done to date (1) 2,100 1,920 * Normal spoilage is 15% of good units produced or 1,400 x 15% = 210. The number of units of abnormal spoilage is equal to 2,100 total units to account for – 1,400 good units – 210 normal spoilage – 300 in ending WIP = 190. Note that spoilage is identified at the end of the process and units are complete as to both materials and conversion costs. 2. COST RECONCILIATION Beginning WIP $ 89,040 $ 76,800 $ 12,240 Added this period 637,539 453,600 184,320 Costs to account for $726,920 Cost of work done to date (2) $530,400 $196,560 Cost per equivalent unit (2)/(1) $ 252.571 $ 102.375 3. Cost assignment $ 353,600 $ 143,325 Completed & transferred out** $ 496,925 Normal spoilage** 74,539 53,040 21,499 Total cost of good units 571,464 67,440 47,989 19,451 Abnormal spoilage** ** Ending WIP 88,056 75,771 12,285 Costs accounted for $726,960 $530,400 $196,560 ** Cost of goods completed and transferred out, normal spoilage, abnormal spoilage, and ending work‐in‐process inventory are equal to the appropriate equivalent unit amount for each component multiplied by the cost per equivalent unit for that component. For example: 1,400 x $102.375 = $143,325. Note that we add across the individual component costs to determine the total cost of each line in the table.
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Copyright © 2013 Pearson Canada Inc.
Chapter 18
18‐36 (25 min.) FIFO method. Physical Equivalent units PHYSICAL FLOW UNITS MATERIALS CONVERSION Beginning WIP 400 400 (100%) 120 (30%) Started into production 1,700 To account for 2,100 Current period only Completion of beginning WIP 400 0 280 (70%) Started and completed 1,000 1,000 1,000 * Normal spoilage 210 210 210 * Abnormal spoilage 190 190 190 300 (100%) 120 (40%) Ending WIP 300 Accounted for 2,100 ______ ______ Work done in current period (1) 1,700 1,800 * Normal spoilage is 15% of good units produced or 1,400 x 15% = 210. The number of units of abnormal spoilage is equal to 2,100 total units to account for – 1,400 good units completed – 210 normal spoilage – 300 in ending WIP = 190. Note that spoilage is identified at the end of the process and units are complete as to both materials and conversion costs. COST RECONCILIATION Beginning WIP** $ 89,040 Added this period (2) 637,920 $453,600 $184,320 Costs to account for $726,960 Cost per equivalent unit this period (2)/(1) $266.824 $102.40 ** $76,800 + $12,240 = $89,040
Cost assignment Beginning WIP $ 89,040 Completion of beginning WIP***28,672 Started and completed*** 369,224 *** Normal spoilage 77,537 Total cost of good units 564,473 *** Abnormal spoilage 70,152 *** 92,335 Ending WIP Costs this period Costs accounted for $726,960
0 266,824 56,033
28,672 102,400 21,504
50,696 80,047 $ 453,600
19,456 12,288 $ 184,320
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
18‐36 (cont’d)
Costs to complete beginning WIP, started and completed, normal spoilage, abnormal spoilage, and ending work‐in‐process inventory are equal to the appropriate equivalent unit amount for each component multiplied by the cost per equivalent unit for that component. For example: 280 x $102.40 = $28,672. Note that we add across the individual component costs to determine the total cost of each line in the table. 18‐37 (30 min.) Standard‐costing method, spoilage. Physical Equivalent units PHYSICAL FLOW UNITS MATERIALS CONVERSION Beginning WIP 400 400 (100%) 120 (30%) Started into production 1,700 To account for 2,100 Current period only Completion of beginning WIP 400 0 280 (70%) Started and completed 1,000 1,000 1,000 * Normal spoilage 210 210 210 * Abnormal spoilage 190 190 190 Ending WIP 300 300 (100%) 120 (40%) Accounting for 2,100 Work done in current period (1) 1,700 1,800 * Normal spoilage is 15% of good units produced or 1,400 x 15% = 210. The number of units of abnormal spoilage is equal to 2,100 total units to account for – 1,400 good units – 210 normal spoilage – 300 in ending WIP = 190. Note that spoilage is identified at the end of the process and units are complete as to both materials and conversion costs. Cost per equivalent unit (given) $ 246 $ 96 COST RECONCILIATION $ 109,920 $ 98,400 $ 11,520 Beginning WIP* * Added this period 591,000 $418,200 $172,800 $700,920 Costs to account for ***
At standard cost *
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Copyright © 2013 Pearson Canada Inc.
Chapter 18
18‐37 (cont’d) Cost assignment Beginning WIP $109,920 0 26,880 Completion of beginning WIP**26,880 Started and completed** 342,000 $ 246,400 $ 96,000 Normal spoilage** 71,820 51,660 20,160 Total cost of good units 550,620 Abnormal spoilage** 64,980 46,740 18,240 Ending WIP** 85,320 73,800 11,520 $418,200 $172,800 Costs accounted for $700,920 ** Cost of goods completed and transferred out, normal spoilage, abnormal spoilage, and ending work‐in‐process inventory are equal to the appropriate equivalent unit amount for each component multiplied by the cost per equivalent unit for that component. For example: 1,400 x $246 = $344,400. Note that we add across the individual component costs to determine the total cost of each line in the table.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
18‐38
(2025 min.)
Physical units, inspection at various stages of completion.
Inspection Inspection Inspection at 15% at 40% at 100% Work in process, beginning (20%)* 14,000 14,000 14,000 120,000 120,000 Started during March 120,000 To account for 134,000 134,000 134,000 Good units completed and 113,000a 113,000a 113,000a transferred out 6,600b 7,440c 6,780d Normal spoilage Abnormal spoilage (10,000 – 3,400 2,560 3,220 11,000 11,000 normal spoilage) 11,000 134,000 134,000 134,000 Work in process, ending (70%)* Accounted for *Degree of completion for conversion costs of the forging process at the dates of the work‐in‐process inventories a14,000 beginning inventory +120,000 –10,000 spoiled – 11,000 ending inventory = 113,000. b6% (120,000 units started – 10,000 units spoiled) = 6% 110,000 = 6,600; beginning work‐in‐process inventory is excluded because it was already 20% complete at March 1 and past the inspection point. c6% (134,000 units – 10,000 ) = 6% 124,000 = 7,440, because all units passed the 40% completion inspection point in March. d6% 113,000 = 6,780, because 113,000 units are fully completed and inspected during March.
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Copyright © 2013 Pearson Canada Inc.
Chapter 18
18‐39 (2535 min.) Weighted‐average method, inspection at 80% completion. The computation and allocation of spoilage is the most difficult part of this problem. The units in the ending inventory have passed inspection. Therefore, of the 100,000 units to account for (12,500 beginning + 87,500 started), 12,500 must have been spoiled in May [100,000 – (62,500 completed + 25,000 ending inventory)]. Normal spoilage is 8,750 [0.10 (62,500 + 25,000)]. The 3,750 remainder is abnormal spoilage (12,500 – 8,750). Solution Exhibit 18‐39, Panel A, calculates the equivalent units of work done for each cost category. We comment on several points in this calculation: Ending work in process includes an element of normal spoilage since all the ending WIP have passed the point of inspection––inspection occurs when production is 80% complete, while the units in ending WIP are 95% complete. Spoilage includes no direct materials units because spoiled units are detected and removed from the finishing activity when inspection occurs at the time production is 80% complete. Direct materials are added only later when production is 90% complete. Direct materials units are included for ending work in process, which is 95% complete, but not for beginning work in process, which is 25% complete. The reason is that direct materials are added when production is 90% complete. The ending work in process, therefore, contains direct materials units; the beginning work in process does not. Solution Exhibit 18‐39, Panel B, summarizes total costs to account for, computes the costs per equivalent unit for each cost category, and assigns costs to units completed (including normal spoilage), to abnormal spoilage, and to units in ending work in process using the weighted‐average method. The cost of ending work in process includes the assignment of normal spoilage costs since these units have passed the point of inspection. The costs assigned to each cost category are as follows: Cost of good units completed and transferred out (including normal spoilage costs on good units) $2,346,687 Abnormal spoilage 84,638 Cost of ending work in process (including normal spoilage costs on ending work in process) 917,675 Total costs assigned and accounted for $3,349,000
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
SOLUTION EXHIBIT 18‐39 Weighted‐Average Method of Process Costing with Spoilage; Finishing Department of the Ottawa Manufacturing Company for August. PANEL A: Steps 1 and 2—Summarize Output in Physical Units and Compute Output in Equivalent Units (Step 1) (Step 2) Equivalent Units Physical Transferred Direct Conversion Flow of Production Units ‐ Materials Costs in Costs Work in process, beginning (given) 12,500 Started during current period (given) 87,500 100,000 To account for Good units completed and transferred out 62,500 during current period: 62,500 62,500 62,500 6,250 Normal spoilage on good units* 6,250 100%; 6,250 0%; 6,250 80% 0 5,000 6,250 25,000 Work in process, ending‡ (given) 25,000 100%; 25,000 100%; 25,000 25,000 23,750 25,000 95% 2,500 Normal spoilage on ending WIP** 0 2,000 2,500 2,500 100%; 2,500 0%; 2,500 80% 3,750 † Abnormal spoilage 0 3,000 3,750 3,750 100%; 3,750 0%; 3,750 80% 100,000 100,000 87,500 96,250 Accounted for Work done to date *Normal spoilage is 10% of good units that pass inspection: 10% 62,500 = 6,250 units. Degree of completion of normal spoilage in this department: transferred‐in costs, 100%; direct materials, 0%; conversion costs, 80%. ‡Degree of completion in this department: transferred‐in costs, 100%; direct materials, 100%; conversion costs, 95%. **Normal spoilage is 10% of the good units in ending WIP that have passed the inspection point, 10% 25,000 = 2,500 units. Degree of completion of normal spoilage in this department: transferred‐in costs, 100%; direct materials, 0%; conversion costs, 80%. †Abnormal spoilage = Actual spoilage Normal spoilage = 12,500 8,750 = 3,750 units. Degree of completion of abnormal spoilage in this department: transferred‐in costs, 100%; direct materials, 0%; conversion costs, 80%.
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Copyright © 2013 Pearson Canada Inc.
Chapter 18
SOLUTION EXHIBIT 18‐39 PANEL B: Steps 3, 4, and 5— Summarize Total Costs to Account For, Compute Cost per Equivalent Unit, and Assign Total Costs to Units Completed, to Spoiled Units, and to Units in Ending Work in Process
Total Production Costs
Transferred‐ Direct Conversion in Costs Materials Costs (Step 3) Work in process, beginning (given) $ 156,125 $103,625 $ $ 52,500 809,375 3,192,875 819,000 1,564,500 Costs added in current period (given) $819,000 $1,617,000 $3,349,000 $913,000 Total costs to account for (Step 4) Costs incurred to date $913,000 $819,000 $1,617,000 100,000 87,500 96,250 Divided by equivalent units of work done to date $ 9.13 $ 9.36 $ 16.80 Cost per equivalent unit (Step 5) Assignment of costs Good units completed and transferred out (62,500 units) 62,500# ($9.13 + $9.36 + $16.80) Costs before adding normal spoilage $2,205,625 Normal spoilage (6,250 units) 141,063 (6,250# $9.13) + (0# $9.36) + (5,000# $16.80) (A) Total costs of good units completed 2,346,688 and transferred out 84,638 (3,750# $9.13) + (0# $9.36) + (3,000# $16.80) (B) Abnormal spoilage (3,750 units) Work in process, ending (25,000 units) 861,250 (25,000# $9.13) + (25,000# $9.36) + (23,750# $16.80) WIP ending, before normal spoilage 56,425 (2,500# $9.13) + (0# $9.36) + (2,000# $16.80) Normal spoilage on ending WIP 917,675 (C) Total costs of ending WIP $3,349,000 $913,000 + $819,000 + $1,617,000 (A)+(B)+(C) Total costs accounted for
Equivalent units of transferred‐in costs, direct materials, and conversion costs calculated in Step 2 in Panel A. #
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
18‐40 (15 min.) Spoilage in job costing 1. Normal spoilage rate= Units of normal spoilage ÷ Total good units completed = 5 ÷ 35 = 14.3%. 2. a) Journal entry for spoilage related to a specific job: Materials Control (spoiled goods at current disposal value) 5 × $200 1,000 Work‐in‐Process Control (Job #10) 1,000 Note: The costs incurred on the bad units (5 × $1,000) are already part of the balance in WIP. The cost of the 35 good units is (35 × 1,000) + (5 × $800) = $39,000 b) Journal entry for spoilage common to all jobs: Materials Control (spoiled goods at current disposal value) 5 × $200 1,000 Manufacturing Overhead Control (normal spoilage) 4,000 Work‐in‐Process Control (Job #10) 5,000 Note: In developing the predetermined O/H rate, the budgeted manufacturing overhead would include expected normal spoilage costs. c) Journal entry for abnormal spoilage: Materials Control (spoiled goods at current disposal value) 5 × $200 1,000 Loss from Abnormal Spoilage 5 × $800 4,000 Work‐in‐Process Control (job #10) 5,000 Note: If the spoilage is abnormal, the net loss is highlighted and always charged to an abnormal loss account.
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Copyright © 2013 Pearson Canada Inc.
Chapter 18
18‐41 (10 min.) Rework in job costing, journal entry. a) Journal entry for rework related to a specific job: Work‐in‐Process Control (Job #10) Various Accounts (To charge rework costs to the job) b) Journal entry for rework common to all jobs: Manufacturing Overhead Control (rework costs) Various Accounts c) Journal entry for abnormal rework: Loss from Abnormal Rework Various Accounts
18‐42
1,800
1,800
1,800 1,800
1,800 1,800
(10 min.) Scrap at time of sale or at time of production, journal entries.
a) Journal entry for recognizing immaterial scrap at time of sale: Cash or Accounts Receivable 300 Scrap Revenues 300 (To record other revenue sale of scrap) b) Journal entry for recognizing material scrap related to a specific job at time of sale: Cash or Accounts Receivable 300 Work‐in‐Process Control (Job #10) 300 c) Journal entry for recognizing material scrap common to all jobs at time of sale: Cash or Accounts Receivable 300 Manufacturing Overhead Control 300 d) Journal entry for recognizing material scrap as inventory at time of production and recording at net realizable value: Materials Control 300 Work‐in‐Process Control (Job #10) 300 Cash or Accounts Receivable 300 Materials Control 300 (When later sold)
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
18‐43 (30 min.) Job costing, rework. 1.
Work‐in‐Process Control (CS1 chips) ($110 80) Materials Control ($60 80) Wages Payable ($12 80) Manufacturing Overhead Allocated ($38 80) Total costs assigned to 80 spoiled units of CS1 chips before considering rework costs.
8,800
4,800 960 3,040
Manufacturing Department Overhead Control (rework) Materials Control ($12 50) Wages Payable ($9 50) Manufacturing Overhead Allocated ($15 50) Normal rework on 50 units, but not attributable specifically to the CS1 chip batches or jobs.
1,800
600 450 750
Loss from Abnormal Rework ($36 30) Materials Control ($12 30) Wages Payable ($9 30) Manufacturing Overhead Allocated ($15 30) Total costs of abnormal rework on 30 units (Abnormal rework = Actual rework – Normal rework = 80 – 50 = 30 units) of CS1 chips.
1,080
360 270 450
Work‐in‐Process Control (CS1 chips) 1,200 Work‐in‐Process Control (CS2 chips) 600 Manufacturing Department Overhead Allocated (rework) (Allocating manufacturing department rework costs to CS1 and CS2 in the proportion 1,000:500 since each calculator requires the same number of machine‐hours.) 2.
Total rework costs for CS1 chips in August 2013 are as follows: Normal rework costs allocated to CS1 Abnormal rework costs for CS1 Total rework costs
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Copyright © 2013 Pearson Canada Inc.
$1,200 1,080 $2,280
1,800
Chapter 18
18‐43 (cont’d) We emphasize two points: a. Only $1,200 of the normal rework costs are allocated to CS1 even though the normal rework costs of the 50 CS1 calculators reworked equal $1,800. The reason is that the normal rework costs are not specifically attributable to CS1. For example, the machines happened to malfunction when CS1 was being made, but the rework was not caused by the specific requirements of CS1. If it were, then all $1,800 would be charged to CS1. b. Abnormal rework costs of $1,080 are linked to CS1 in the management control system even though for financial reporting purposes the abnormal rework costs are written off to the income statement. 18‐44 (40 min.) Job costing, spoilage, governance. 1. Analysis of the 5,000 units rejected by Richmond Company for Job No. R1192‐122 yields the following breakdown between normal and abnormal spoilage. Units Normal spoilage* 3,000 Abnormal spoilage: Design defect 900 Other [5,000 – (3,000 + 900)] 1,100 Total units rejected 5,000 *Normal spoilage = 0.025 of normal input When output equals 117,000 units, Normal input = 117,000 ÷ (1 – 0.025) = 120,000 units Normal spoilage = 120,000 0.025 = 3,000 units
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18‐44 (cont’d) 2.
The journal entries required to properly account for Job No. R1192–122 are presented below and use an average cost per unit of $68.40 ($8,344,800 ÷ 122,000).
Materials control (or A/R or cash)1 $34,440 129,000 Abnormal loss2 WIP control3 Cash4 To account for 5,000 units rejected. Finished good inventory5 $8,182,800 WIP control To transfer 117,000 units to finished goods inventory.
$162,000 1,440
$8,182,800
Units for sale 4,100 units sold at $8.40 each.
1
Loss from abnormal spoilage: 2,000 units at $68.40 $136,800 Disposal cost 1,440 Cost recovery (1,100 $8.40) (9,240) $129,000 3WIP control: 900 defective units at $68.40 $ 61,560 1,100 other rejected units at $68.40 75,240 3,000 normal units at $8.40 25,200 $162,000 4Additional cost to dispose of 900 units rejected because of design defect. 2
Less $8,344,800 Total manufacturing costs 162,000 WIP control 8,182,800 5
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18‐44 (cont’d) 3. a. If all spoilage were considered normal, the journal entries to account for Job No. R1192–122 would be as follows: Materials Control (or A/R or cash) $34,440 Finished Goods Inventory 8,311,800 WIP Control $8,344,800 Cash 1,440 To transfer 117,000 good units to finished goods inventory and to recognize the salvage value of 4,100 units of spoiled units (4,100 $8.40 = $34,440) and the disposal cost of $1,440 of the other 900 spoiled units. All remaining WIP costs are treated as normal costs of production and charged to finished goods. By considering all spoilage as normal, Richmond will show no abnormal loss but instead will add $129,000 to the finished‐goods inventory. Hence, showing all spoilage as normal will increase Richmond’s operating income by $129,000 in the short term since abnormal spoilage is expensed immediately to the income statement. 3b. Incorrect reporting of spoilage as normal instead of abnormal with the goal of increasing operating income is unethical. In assessing the situation, the management accountant should consider the following: • Spoilage should be accounted for using relevant and reliable information. Accounting for spoilage incorrectly to make the company’s operating performance look better than it is violates competence standards. It is unethical for Rutherford to suggest that Perez change abnormal spoilage to normal spoilage in order to make operating performance look good. • The management accountant has a responsibility to avoid actual or apparent conflicts of interest and advise all appropriate parties of any potential conflict. Rutherford’s motivation for wanting Perez to revise the quality figures could well have been motivated by Rutherford’s desire to please senior management. In this regard, both Rutherford’s and Perez’s behaviour (if Drummond agrees to modify the spoilage classification) could be viewed as unethical. • The management accountant should require that information be fairly and objectively communicated and that all relevant information should be disclosed. From a management accountant’s standpoint, showing abnormal spoilage as normal spoilage to make operating performance look good would be unethical. Perez should indicate to Rutherford that the classification of normal and abnormal spoilage established by Richmond Company is, indeed, appropriate. If Rutherford still insists on modifying the spoilage classification for this job to report higher operating income figures, Perez should raise the matter with one of Rutherford’s superiors. If, after taking all these steps, there is continued pressure to overstate operating income, Perez should consider resigning from the company, and not engage in unethical behaviour.
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18‐45 (2025 min.) Physical units, inspection at various stages of completion. Inspection Inspection Inspection at 15% at 40% at 100% Work in process, beginning (20%)* 16,000 16,000 16,000 129,000 129,000 Started during March 129,000 To account for 145,000 145,000 145,000 a a a Good units completed and 120,000 120,000 120,000 b c d transferred out 8,190 9,310 8,400 Normal spoilage 2,690 3,600 Abnormal spoilage (10,000 – 3,810 13,000 13,000 normal spoilage) 13,000 145,000 145,000 145,000 Work in process, ending (70%)* Accounted for *Degree of completion for conversion costs of the forging process at the dates of the work‐in‐process inventories a16,000 beginning inventory +129,000 –12,000 spoiled – 13,000 ending inventory = 120,000. b7% (129,000 units started – 12,000 units spoiled) = 7% 117,000 = 8,190; beginning work‐in‐process inventory is excluded because it was already 20% complete at March 1 and past the inspection point. c7% (145,000 units – 12,000 ) = 6% 133,000 = 9,310, because all units passed the 40% completion inspection point in March. d7% 120,000 = 8,400, because 120,000 units are fully completed and inspected during March.
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18‐46 (30 min.) 1. 2. 3.
Job costing, scrap.
Materials Control Materials‐Related Manufacturing Overhead Control (To record scrap common to all jobs at the time it is returned to the storeroom)
$8,400
$8,400
Cash or Accounts Receivable Materials Control (To record sale of scrap from the storeroom)
$8,400
$8,400
A summary of the manufacturing costs for HM3 and JB4 before considering the value of scrap are as follows:
HM3 JB4 Total Costs Cost Cost per Total per Total Unit Costs Unit Costs (1) (2)=(1) 20,000 (3) (4)=(3) 10,000 (5)=(2)+(4) Direct materials $12.00 $240,000 $18.00 $180,000 $420,000 Direct manufacturing labour 3.60 72,000 4.80 48,000 120,000 Materials‐related manufacturing overhead (20% of direct materials)2.40 48,000 3.60 36,000 84,000 Other manufacturing overhead (200% of direct manufacturing labour) 7.20 144,000 9.60 96,000 240,000 Total $25.20 $504,000 $36.00 $360,000 $864,000 The value of scrap generated during March of $8,400 will reduce materials‐related manufacturing overhead costs by $8,400 from $84,000 to $75,600. Materials‐related manufacturing overhead will then be allocated at 18% of direct materials costs ($75,600 ÷ $420,000 = 0.18).
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18‐46 (cont’d) The revised manufacturing cost per unit would then be:
HM3 JB4 Total Costs Cost Cost per Total per Total Unit Costs Unit Costs (1) (2)=(1) 20,000 (3) (4)=(3) 10,000 (5)=(2)+(4) $12.00 $240,000 $18.00 $180,000 $420,000 3.60 72,000 4.80 48,000 120,000
Direct materials Direct manufacturing labour Materials‐related manufacturing overhead (18% of direct materials)2.16 Other manufacturing overhead (200% of direct manufacturing labour) 7.20 Total $24.96
43,200
3.24
32,400
75,600
144,000 $499,200
9.60 $35.64
96,000 $356,400
240,000 $855,600
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Chapter 18
COLLABORATIVE LEARNING CASE
18‐47 (35 min.) FIFO method, spoilage, working backward. 1.
Equivalent units of work done in the current period can be calculated using Step 2 as follows: Direct Conversion Materials Costs Costs added in January $1,776,000 $1,130,400 Divided by costs per equivalent unit of work done in January ÷ $24 ÷ $14.40 Equivalent units of work done in January 74,000 78,500 2. Solution Exhibit 18‐49, Panel A, shows the equivalent units of work done (a) to complete beginning work‐in‐process inventory, (b) to start and complete new units, (c) for normal spoilage, (d) for abnormal spoilage and (e) work in process inventory. 3. The physical units of ending work in process can be calculated by taking total physical units to account for, 84,000 (beginning work in process, 10,000 plus units started 74,000) and subtracting good units completed and transferred out, 61,000; normal spoilage, 6,710; and abnormal spoilage, 1,290, to obtain 15,000 physical units in ending work in process. The percentage of completion of ending work in process for each cost category can then be calculated as follows: Direct Conversion Materials Costs Equivalent units of ending work in process (requirement 2) 15,000 12,000 Divided by physical units of ending work in process ÷15,000 ÷15,000 Percentage of completion of ending work in process 100% 80% 4. Solution Exhibit 18‐49, Panel B summarizes total costs to account for, and assigns these costs to units completed and transferred out (including normal spoilage), to abnormal spoilage, and to units in ending work in process.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
18‐47 (cont’d) SOLUTION EXHIBIT 18‐47 First‐in, First‐out (FIFO) Method of Process Costing with Spoilage Cooking Department of Spicer Inc. for January PANEL A: Steps 1 and 2—Summarize Output in Physical Units and Compute Equivalent Units (Step 2) (Step 1) Equivalent Units Physical Direct Conversion Flow of Production Units Materials Costs Work in process, beginning (given) 10,000 Started during current period (given) 74,000 To account for 84,000 Good units completed and transferred out during current period: From beginning work in process* 10,000 10,000 (100% – 100%); 10,000 (100% – 25%) 0 7,500 # Started and completed 51,000 51,000 100%; 51,000 100% 51,000 51,000 Normal spoilage** 6,710 6,710 100%; 6,710% 100% 6,710 6,710 † Abnormal spoilage 1,290 1,290 100%; 1,290 100% 1,290 1,290 ‡ 15,000 Work in process, ending 15,000 100%; 15,000 80% 15,000 12,000 Accounted for 84,000 Work done in current period only 74,000 78,500
*Degree of completion in this department: direct materials, 100%; conversion costs, 25%. #61,000 physical units completed and transferred out minus 10,000 physical units completed and transferred out from beginning work‐in‐process inventory. **Normal spoilage is 11% of good units transferred out: 11% 61,000 = 6,710 units. Degree of completion of normal spoilage in this department: direct materials, 100%; conversion costs, 100%. †Abnormal spoilage = Actual spoilage – Normal spoilage = 8,000 – 6,710 = 1,290 units. Degree of completion of abnormal spoilage in this department: direct materials, 100%; conversion costs, 100%. ‡Degree of completion in this department: direct materials, 100%; conversion costs, 80%. 18‐940
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18‐47 (cont’d) PANEL B: Steps 3, 4, and 5—Compute Equivalent Unit Costs, Summarize Total Costs to Account For, and Assign Costs to Units Completed, to Spoilage Units, and to Units in Ending Work in Process
Total Production
(Step 3) (Step 4) (Step 5) (A) (B) (C) (A)+(B)+(C)
Costs Work in process, beginning (given: $264,000 + $36,000) $ 300,000 Costs added in current period (given) 2,906,400 Divided by equivalent units of work done in current period Equivalent unit costs of work done in current period $3,206,400 Total costs to account for Assignment of costs: Good units completed and transferred out (61,000 units) Work in process, beginning (10,000 units) $300,000 Direct materials added in current period 0 Conversion costs added in current period 108,000 Total from beginning inventory before normal spoilage 408,000 Started and completed before normal spoilage (51,000 units) 1,958,400 Normal spoilage (6,710 units) 257,664 Total cost of good units transferred out 2,216,064 Abnormal spoilage (1,290 units) 49,536 Work in process, ending (15,000 units) Direct materials 360,000 Conversion costs 172,800 Total work in process, ending 532,800 Total costs accounted for $3,206,400
Direct
Conversion
Materials
Costs
$1,776,000
$1,130,400
÷ 74,000 $ 24
÷ 78,500 $ 14.40
0§ $24
7,500§ $14.40
51,000§ $24 + 51,000§ $14.40 6,710§ $24 + 6,710§ $14.40 1,290§ $24 + 1,290 $14.40 15,000§ $24
12,000§ $14.40
Equivalent units of direct materials and conversion costs calculated in Step 2 in Panel A.
§
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CHAPTER 19 COST MANAGEMENT: QUALITY, TIME, AND THE THEORY OF CONSTRAINTS
SHORT‐ANSWER QUESTIONS
19‐1 Quality costs (including the opportunity cost of lost sales because of poor quality) can be as much as 10% to 20% of sales revenue of many organizations. Quality‐ improvement programs can result in substantial cost savings and higher revenue and market share from increased customer satisfaction.
19‐2 Quality of design refers to how closely the characteristics of a product or service meet the needs and wants of customers. Conformance quality refers to the performance of a product or service relative to its design and product specifications.
19‐3 Exhibit 19‐3 of the text lists the following six line items in the prevention costs category: design engineering; process engineering; supplier evaluations; preventive equipment maintenance; quality training; and testing of new materials.
19‐4 An internal failure cost differs from an external failure cost on the basis of when the nonconforming product is detected. An internal failure is detected before a product is shipped to a customer, whereas an external failure is detected after a product is shipped to a customer.
19‐5 No, companies should emphasize financial as well as nonfinancial measures of quality, such as yield and defect rates. Nonfinancial measures are not directly linked to bottom‐line performance but they indicate and direct attention to the specific areas that need improvement to improve the bottom line. Tracking nonfinancial measures over time directly reveals whether these areas have, in fact, improved over time. Nonfinancial measures are easy to quantify and easy to understand.
19‐6 Nonfinancial measures of customer satisfaction include number of customer complaints and on‐time delivery rate.
19‐7 No. There is a trade‐off between customer‐response time and on‐time performance. Simply scheduling longer customer‐response time makes achieving on‐ time performance easier. Companies should, however, attempt to reduce uncertainty of arrival of orders, manage bottlenecks, reduce setup and processing time, and run
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smaller batches. This would have the effect of reducing both customer‐response time and improving on‐time performance.
19‐8 Two reasons why lines, queues, and delays occur is (1) uncertainty about when customers will order products or services––uncertainty causes a number of orders to be received at the same time, causing delays, and (2) limited capacity and bottlenecks––a bottleneck is an operation where the work to be performed approaches or exceeds the available capacity.
19‐9 No. Adding a product when capacity is constrained and the timing of customer orders is uncertain causes delays in delivering all existing products. If the revenue losses from delays in delivering existing products and the increase in carrying costs of the existing products exceed the positive contribution earned by the product that was added, then it is not worthwhile to make and sell the new product, despite its positive contribution margin. The chapter describes the negative effects (negative externalities) that one product can have on others when products share common manufacturing facilities. 19‐10 The three main measures used in the theory of constraints are: 1. Throughput contribution equal to sales revenues minus direct materials costs. 2. Investments (inventory) equal to the sum of materials costs of direct materials inventory, work in process inventory, finished goods inventory, research and development costs, and costs of equipment and buildings. 3. Other operating costs equal to all operating costs (other than direct materials) incurred to earn throughput contribution. 19‐11 The four key steps in managing bottleneck resources are: Step 1: Recognize that the bottleneck operation determines throughput contribution. Step 2: Search for and find the bottleneck. Step 3: Keep the bottleneck busy and subordinate all nonbottleneck operations to the bottleneck operation. Step 4: Increase bottleneck efficiency and capacity.
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19‐12 If a company has adopted a cost leadership strategy, the learning curve demonstrates the importance of human experience. The more often people follow the same process the fewer mistakes with accompanying non‐value added costs are incurred. The result is a lower cost of goods sold, all other things equal. When considering a long‐term capacity expansion the effects of the learning curve will contribute to reduced working capital expense over time. If a company has adopted a value‐leadership strategy the learning curve is equally important to demonstrating the effect of good recruitment, training and retention of experienced people who actually manufacture the output or provide the service error‐free.
EXERCISES
19‐13 (10 min.)
Terminology.
The cost of quality failure include those of appraisal, prevention, design, internal failure, and external failure. The costs may arise from poor quality of design and the output will fail to meet customer expectations. They may also arise from poor conformance quality or failure during production to conform to design specifications. The total cost of quality (COQ) failure in the customerʹs hand are not merely financial but can be non‐financial, including fatalities. A high quality process quality management system will track all four COQ types to detect and prevent quality failures. Successful quality control can be measured using a BSC. From the perspective of customers, market share and size can increase. From the learning and growth perspective, analysis and tracking of the both the learning and experience curves improves the reliability of predictions of orderly cost decreases. Both the incremental unit time learning and cumulative average time learning models will improve the management and control of quality. From the perspective of internal business control, quality can be tracked using a control chart, Pareto diagrams and cause‐effect or fishbone diagrams.
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19‐14 (20 min.) Learning curve, cumulative average‐time learning model. The direct manufacturing labour‐hours (DMLH) required to produce the first 2, 4, and 8 units given the assumption of a cumulative average‐time learning curve of 90%, is as follows: 90% Learning Curve Cumulative Cumulative Cumulative Number Average Time Total Time: per Unit (y): Labour Labour‐ of Units (X) Hours Hours (1) (2) (3) = (1) (2) 1 3,000 3,000 2 2,700 = (3,000 0.90) 5,400 3 2,539 7,616 9,720 4 2,430 = (2,700 0.90) 5 2,349 11,745 6 2,285 13,710 7 2,232 15,624 8 2,187 = (2,430 0.90) 17,496 Alternatively, to compute the values in column (2) we could use the formula y = aXb where a = 3,000, X = 2, 4, or 8, and b = – 0.152004, which gives when X = 2, y = 3,000 2– 0.152004 = 2,700 when X = 4, y = 3,000 4– 0.152004 = 2,430 when X = 8, y = 3,000 8– 0.152004 = 2,187 Variable Costs of Producing 2 Units 4 Units 8 Units Direct materials $80,000 2; 4; 8 $160,000 $320,000 $ 640,000 Direct manufacturing labour $25 5,400; 9,720; 17,496 135,000 243,000 437,400 Variable manufacturing overhead $15 5,400; 9,720; 17,496 81,000 145,800 262,440 Total variable costs $376,000 $708,800 $1,339,840
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19‐15 (20 min.) Learning curve, incremental unit‐time learning model. 1.
The direct manufacturing labour‐hours (DMLH) required to produce the first 2, 3, and 4 units, given the assumption of an incremental unit‐time learning curve of 90%, is as follows:
Cumulative Number of Units (X) (1) 1 2 3 4
90% Learning Curve Individual Unit Time for Xth Unit (y): Labour Hours (2) 3,000 2,700 = (3,000 0.90) 2,539 2,430 = (2,700 0.90)
Cumulative Total Time: Labour‐Hours (3) 3,000 5,700 8,239 10,669
Values in column (2) are calculated using the formula y = aXb where a = 3,000, X = 2, 3, or 4, and b = – 0.152004, which gives when X = 2, y = 3,000 2– 0.152004 = 2,700 when X = 3, y = 3,000 3– 0.152004 = 2,539 when X = 4, y = 3,000 4– 0.152004 = 2,430 Variable Costs of Producing 2 Units 3 Units 4 Units Direct materials $80,000 2; 3; 4 $160,000 $240,000 $ 320,000 Direct manufacturing labour 142,500 $25 5,700; 8,239; 10,669 205,975 266,725 Variable manufacturing overhead $15 5,700; 8,239; 10,669 85,500 123,585 160,035 $388,000 $569,560 $746,760 Total variable costs Variable Costs of 2. Producing 2 Units 4 Units Incremental unit‐time learning model (from requirement 1) Cumulative average‐time learning model (from Exercise 19‐14) Difference
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$388,000 376,000 $ 12,000
$746,760 708,800 $ 37,960
Chapter 19
19‐15 (cont’d) Total variable costs for manufacturing 2 and 4 units are lower under the cumulative average‐time learning curve relative to the incremental unit‐time learning curve. Direct manufacturing labour‐hours required to make additional units decline more slowly in the incremental unit‐time learning curve relative to the cumulative average‐time learning curve when the same 90% factor is used for both curves. The reason is that, in the incremental unit‐time learning curve, as the number of units double only the last unit produced has a cost of 90% of the initial cost. In the cumulative average‐time learning model, doubling the number of units causes the average cost of all the additional units produced (not just the last unit) to be 90% of the initial cost.
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19‐16 (30 min.) Costs of quality. 1.
The ratios of each COQ category to revenue and to total quality costs for each period are as follows: Costen, Inc.: Semi‐annual Costs of Quality Report (in thousands)
6/30/2011 12/31/2011 6/30/2012 12/31/2012 % of Total % of Total % of Total % of Total Quality Quality % of Quality % of Quality % of % of Costs Costs Actual Revenue Costs Actual Revenue Costs Actual Revenue Actual Revenue (2) = (3) = (5) = (6) = (8) = (9) = (11) = (12) = (1) (1) ÷ $8,240(1) ÷ $2,040 (4) (4) ÷ $9,080(4) ÷ $2,159 (7) (7) ÷ $9,300(7) ÷ $1,605 (10) (10) ÷ $9,020(10) ÷ $1,271 Prevention costs Machine maintenance $ 440 $ 440 $ 390 $ 330 Supplier training 20 100 50 40 Design reviews 50 214 210 200 Total prevention costs 510 6.2% 25.0% 754 8.3% 34.9% 650 7.0% 40.5% 570 6.3% 44.9% Appraisal costs Incoming inspection 108 123 90 63 Final testing 332 332 293 203 Total appraisal costs 440 5.3% 21.6% 455 5.0% 21.1% 383 4.1% 23.9% 266 3.0% 20.9% Internal failure costs Rework 231 202 165 112 Scrap 124 116 71 67 Total internal failure costs 355 4.3% 17.4% 318 3.5% 14.7% 236 2.5% 14.7% 179 2.0% 14.1% External failure costs Warranty repairs 165 85 72 68 Customer returns 570 547 264 188 Total external failure costs 735 8.9% 36.0% 632 7.0% 29.3% 336 3.6% 20.9% 256 2.8% 20.1% Total quality costs $2,040 24.7% 100.0% $2,159 23.8% 100.0% $1,605 17.2% 100.0% $1,271 14.1% 100.0% Total production and revenue $8,240 $9,080 $9,300 $9,020
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2.
3.
From an analysis of the Cost of Quality Report, it would appear that Costen, Inc.’s program has been successful because: Total quality costs as a percentage of total revenue have declined from 24.7% to 14.1%. External failure costs, those costs signaling customer dissatisfaction, have declined from 8.9% of total revenue to 2.8% of total revenue and from 36% of all quality costs to 20.1% of all quality costs. These declines in warranty repairs and customer returns should translate into increased revenue in the future. Internal failure costs as a percentage of revenue have been halved from 4.3% to 2%. Appraisal costs have decreased from 5.3% to 3% of revenue. Preventing defects from occurring in the first place is reducing the demand for final testing. Quality costs have shifted to the area of prevention where problems are solved before production starts: total prevention costs (maintenance, supplier training, and design reviews) have risen from 25% to 44.9% of total quality costs. The $60,000 increase in these costs is more than offset by decreases in other quality costs. Because of improved designs, quality training, and additional pre‐production inspections, scrap and rework costs have almost been halved while increasing sales by 9.5%. Production does not have to spend an inordinate amount of time with customer service since they are now making the product right the first time and warranty repairs and customer returns have decreased. To estimate the opportunity cost of not implementing the quality program and to help her make her case, Jessica Tolmy could have assumed that: Sales and market share would continue to decline if the quality program was not implemented and then calculated the loss in revenue and contribution margin. The company would have to compete on price rather than quality and calculated the impact of having to lower product prices. Opportunity costs are not recorded in accounting systems because they represent the results of what might have happened if the company had not improved quality. Nevertheless, opportunity costs of poor quality can be significant. It is important for Costen to take these costs into account when making decisions about quality.
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19‐17 (20 min.) Costs of quality analysis. 1. Appraisal cost = Inspection cost = $5 × 100,000 car seats = $500,000 2. Internal failure cost = Rework cost = 5% × 100,000 × $1 = 5,000 × $1 = $5,000 3. Out of pocket external failure cost = Shipping cost + Repair cost = 2% × 100,000 × ($10 + $1) = 2,000 × $11 = $22,000 4. Opportunity cost of external failure = Lost future sales = (2% × 100,000) × 20% × $500 = 400 car seats × $500 = $200,000 5. Total cost of quality control = $500,000 + 5,000 + 22,000 + 200,000 = $727,000 6. Quality control costs under the alternative inspection technique: Appraisal cost = $1.50 × 100,000 = $150,000 Internal failure cost = 2.5% × 100,000 × $1 = $2,500 Out of pocket external failure cost = 4.5% × 100,000 × ($10 + 1) = 4,500 × $11 = $49,500 Opportunity cost of external failure = 4,500 car seats × 20% × $500 = 900 car seats × $500 = $450,000 Total cost of quality control = $150,000 + 2,500 + 49,500 + 450,000 = $652,000 7. In addition to the lower costs under the alternative inspection plan, Safe Rider should consider a number of other factors: a. There could easily be serious reputation effects if the percentage of external failures increases by 225% (from 2% to 4.5%). This rise in external failures may lead to costs greater than $500 per failure due to lost sales. b. Higher external failure rates may increase the probability of lawsuits. c. Government intervention is a concern, with the chances of government regulation increasing with the number of external failures.
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19‐18 (15 min.) Cost of quality analysis, ethical considerations. 1. Cost of improving quality of plastic = $25 × 100,000 = $2,500,000 2. Total cost of lawsuits = 2 × $750,000 = $1,500,000 3. While economically this may seem like a good decision, qualitative factors should be more important than quantitative factors when it comes to protecting customers from harm and injury. If a product can cause a customer serious harm and injury, an ethical and moral company should take steps to prevent that harm and injury. The company’s code of ethics should guide this decision. 4. In addition to ethical considerations, the company should consider the societal cost of this decision, reputation effects if word of these problems leaks out at a later date, and governmental intervention and regulation.
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19‐19 (25 min.)
Nonfinancial measures of quality and time.
1. 2012 2013 100 400 Percentage of defective = 5% = 4% 2,000 10,000 units shipped 150 250 Customer complaints as a = 7.5% = 2.5% 2,000 10,000 percentage of units shipped Percentage of units 120 700 = 6% = 7% reworked during 2,000 10,000 production Manufacturing lead time as 15 16 = 50% = 57% a percentage of total time 30 28 from order to delivery 2. Quality has by and large improved. The percentage of defects has decreased by 1% and the number of customer complaints has decreased by 5%. The former indicates an increase in the quality of the cell phones being produced. The latter has positive implications for future sales. However, the percentage of units reworked has also increased. WCP should look into the reason for the increase. One possible explanation is the five‐fold increase in production that may have resulted in a higher percentage of errors. WCP should do a root‐cause analysis to identify reasons for the additional rework. Finally, the average time from order placement to order delivery has decreased. So customers are receiving their orders on a timelier basis. But manufacturing lead time is a higher fraction of customer lead time. WCP should seek ways to reduce manufacturing lead time. For example, process improvements could reduce both rework and manufacturing lead time. Any reduction in manufacturing lead time would help to further reduce customer response time. 3. Manufacturing lead time = wait time + manufacturing time. Producing 10,000 cell phones in 2013 may have required more waiting time for each order than the waiting time from producing 2,000 cell phones in 2012. Manufacturing lead time may have increased as more time was spent on making products with fewer defects and reducing rework activities. Customer response time = receipt time + manufacturing lead time + delivery time. Manufacturing lead time is a subset of customer response time. Lower customer response time times is due to order processing efficiency and/or delivery efficiency and not manufacturing lead time.
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19‐20 (25 min.) Quality improvement, relevant costs, and relevant revenue. 1.
Relevant costs over the next year of choosing the new lens = $55 20,000 copiers = $1,100,000 Relevant Benefits over the Next Year of Choosing the New Lens Costs of quality items Savings in rework costs $1,030,000 $80 12,875 rework hours Savings in customer‐support costs 36,000 $40 900 customer‐support‐hours Savings in transportation costs for parts $360 200 fewer loads 72,000 Savings in warranty repair costs $90 7,000 repair‐hours 630,000 Opportunity costs Contribution margin from increased sales 1,800,000 Cost savings and additional contribution margin $3,568,000
Because the expected relevant benefits of $3,568,000 exceed the expected relevant costs of the new lens of $1,100,000, Photon should introduce the new lens. Note that the opportunity cost benefits in the form of higher contribution margin from increased sales is an important component for justifying the investment in the new lens. 2.
The incremental cost of the new lens of $1,100,000 is less than the incremental savings in rework and repair costs of $1,768,000 ($1,030,000 + $36,000 + $72,000 + $630,000). Thus, it is beneficial for TechnoPrint to invest in the new lens even without making any additional sales.
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19‐21 (20 min.) Nonfinancial quality measures, on‐time delivery. 1.
The data seem to support the concerns expressed by Checker’s headquarters. Store 2 has the lowest percentage of late deliveries and the highest customer satisfaction scores. On the other hand, Store 4 has the highest percentage of late deliveries and the lowest customer satisfaction score. Both Stores 1 and 3 fall between the two extremes and have similar customer satisfaction scores.
2. Percentage of Average Overall Late Deliveries Satisfaction (X) (Y) Highest observation of late delivery percentage 25 2 Lowest observation of late delivery percentage 5 4 Difference 20 – 2 Average overall satisfaction = a + b × Percentage of late deliveries 2 Slope coefficient (b) = 0.10 20 Using high observation, Constant (a) = 2 + (0.10 × 25) = 4.5 Using low observation, Constant (a) = 4 + (0.10 ×5) = 4.5 Average overall satisfaction = 4.5 – 0.10 × Percentage of late deliveries If the percentage of late deliveries increases from 5% to 7%, Average overall satisfaction = 4.5 – 0.10 × 7 = 3.8 3.
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Checkers must estimate the profit implications of lost customer satisfaction due to failure to meet guaranteed delivery times. In addition, the company needs information about the value customers place on the delivery guarantee. Customers may choose to order from Checkers because of the guarantee. Because failure to meet the guarantee represents a cost, Checkers needs to compare this expected cost to the additional sales and profits attributable to the guarantee. Moreover, the delivery guarantee should motivate employees to strive for on‐time delivery. After all, store profits on which store managers bonuses are based will be lower because of the $5 discount if pizzas are not delivered on time. Store managers who view the guarantee as a “win‐win” situation should also be educated on the long‐term effects that late deliveries have on the company if overall customer satisfaction declines. One possibility is to modify the bonus scheme so that on‐time delivery is explicitly weighted in the bonus calculation.
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Chapter 19
19‐22 (30 min.) 1.
Waiting time, service industry.
If SMU’s advisors expect to see 300 students each day and it takes an average of 12 minutes to advise each student, then the average time that a student will wait can be calculated using the following formula:
2 Average number Time taken to of students per day advise a student Wait time = Maximum amount Average number Time taken to 2 advise a student of time available of students per day
= =
300 12
2
2 10 advisors 10 hours 60 minutes 300 12
43,200 = 9 minutes 2 6,000 3,600
2.
At 400 students seen a day, 2 Average number Time taken to of students per day advise a student Wait time = Maximum amount Average amount Time taken to 2 of time available of students per day advise a student
400 12 = 2 10 advisors 10 hours 60 minutes 400 12 2
= 3.
57,600 = 24 minutes 2 6,000 4,800
If the average time to advise a student is reduced to 10 minutes, then the average wait time would be 2 Average number Time taken to of students per day advise a student = Maximum amount Average amount Time taken to 2 of time available of students per day advise a student
400 10 = 2 10 advisors 10 hours 60 minutes 400 10 2
=
40,000 = 10 minutes 2 6,000 4,000
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19‐23 (25 min.) Waiting time, cost considerations, and customer satisfaction. 1. i) If SMU hires two more advisors then the average wait time will be:
2 Average number Time taken to of students per day advise a student = Maximum amount Average amount Time taken to 2 of time available of students per day advise a student
400 12 = 2 12 advisors 10 hours 60 minutes 400 12 2
=
57,600 = 12 minutes 2 7, 200 4,800
ii) If SMU has its current employees work 6 days a week and has them advise 350 students a day then the average wait time will be: 2 Average number Time taken to of students per day advise a student = Maximum amount 2 Average amount Time taken to of time available advise a student of students per day
350 12 = 2 10 advisors 10 hours 60 minutes 350 12 2
=
50,400
2 6,000 4, 200
= 14 minutes
2. i) Cost if SMU hires 2 extra advisors for the registration period: Advisor salary cost = 12 advisors ×10 days × $100 = $12,000 ii) Cost if SMU has its 10 advisors work 6 days a week for the registration period: Advisor salary cost = (10 advisors × 10 days × $100) + (10 advisors × 2 days × $150) = $13,000 Alternative (i) is less costly for SMU. 19–956
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19‐23 (cont’d) 3.
Hiring two extra advisors has a shorter waiting time and a lower cost than extending the workweek to 6 days during the registration period. However, the quality of the advising may not be as high. The temporary advisors may not be as familiar with the requirements of the university. They may also be unaware of how to work within the system (i.e., they may not be aware of alternatives that may be available to help students).
19‐24 (15 min.) Manufacturing cycle time, manufacturing cycle efficiency. 1.
Manufacturing cycle efficiency (MCE) is defined as follows: MCE = Value‐added manufacturing time ÷ Total manufacturing time So MCE in Torrance Manufacturing is: MCE = 4 days of processing time ÷ 22 days total manufacturing time = 0.18 2. Manufacturing cycle time = Total time from receipt of an order by production until its completion. Manufacturing cycle time = (8 + 6 + 2 + 4 + 2) days = 22 days
19‐25 (25 min.) Theory of constraints, throughput contribution, relevant costs. 1.
Finishing is a bottleneck operation. Therefore, producing 1,000 more units will generate additional throughput contribution and operating income. Increase in throughput contribution ($72 – $32) 1,000 Incremental costs of the jigs and tools Net benefit of investing in jigs and tools
$40,000 30,000 $10,000
Mayfield should invest in the modern jigs and tools because the benefit of higher throughput contribution of $40,000 exceeds the cost of $30,000. 2.
The Machining Department has excess capacity and is not a bottleneck operation. Increasing its capacity further will not increase throughput contribution. There is, therefore, no benefit from spending $5,000 to increase the Machining Departmentʹs capacity by 10,000 units. Mayfield should not implement the change to do setups faster.
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19‐25 (cont’d) 3.
Finishing is a bottleneck operation. Therefore, getting an outside contractor to produce 12,000 units will increase throughput contribution. Increase in throughput contribution ($72 – $32) 12,000 Incremental contracting costs $10 12,000 Net benefit of contracting 12,000 units of finishing
$480,000 120,000 $360,000
Mayfield should contract with an outside contractor to do 12,000 units of finishing at $10 per unit because the benefit of higher throughput contribution of $480,000 exceeds the cost of $120,000. The fact that the cost of $10 per unit is double Mayfieldʹs finishing cost of $5 per unit is irrelevant. 4.
Operating costs in the Machining Department of $640,000, or $8 per unit, are fixed costs. Mayfield will not save any of these costs by subcontracting machining of 4,000 units to Hunt Corporation. Total costs will be greater by $16,000 ($4 per unit 4,000 units) under the subcontracting alternative. Machining more filing cabinets will not increase throughput contribution, which is constrained by the finishing capacity. Mayfield should not accept Huntʹs offer. The fact that Huntʹs costs of machining per unit are half of what it costs Mayfield in‐house is irrelevant.
19‐26 (15 min.) Theory of constraints, throughput contribution, quality. 1.
Cost of defective unit at machining operation which is not a bottleneck operation is the loss in direct materials (variable costs) of $32 per unit. Producing 2,000 units of defectives does not result in loss of throughput contribution. Despite the defective production, machining can produce and transfer 80,000 units to finishing. Therefore, cost of 2,000 defective units at the machining operation is $32 2,000 = $64,000.
2.
A defective unit produced at the bottleneck finishing operation costs Mayfield materials costs plus the opportunity cost of lost throughput contribution. Bottleneck capacity not wasted in producing defective units could be used to generate additional sales and throughput contribution. Cost of 2,000 defective units at the finishing operation is: Loss of direct materials $32 2,000 Forgone throughput contribution ($72 – $32) 2,000 Total cost of 2,000 defective units
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$ 64,000 80,000 $144,000
Chapter 19
19‐26 (cont’d) Alternatively, the cost of 2,000 defective units at the finishing operation can be calculated as the lost revenue of $72 2,000 = $144,000. This line of reasoning takes the position that direct materials costs of $32 2,000 = $64,000 and all fixed operating costs in the machining and finishing operations would be incurred anyway whether a defective or good unit is produced. The cost of producing a defective unit is the revenue lost of $144,000.
PROBLEMS 19‐27 (30 min.) Quality improvement, relevant costs, and relevant revenue. One way to present the alternatives is via a decision tree, as shown below. Make T971 Implement new design
Do not make T971
Do not implement new design
The idea is to first evaluate the best action that Thomas should take if it implements the new design (that is, make or not make T971). Thomas can then compare the best mix of products to produce if it implements the new design against the status quo of not implementing the new design. 1. Thomas has capacity constraints. Demand for V262 valves (370,000 valves) exceeds production capacity of 330,000 valves (3 valves per hour 110,000 machine‐hours). Since capacity is constrained, Thomas will choose to sell the product that maximizes contribution margin per machine‐hour (the constrained resource). Contribution margin per = $8 per valve 3 valves per hour = $24 machine-hour for V262 margin per Contribution machine-hour for T971 = $10 per valve 2 valves per hour = $20. Thomas should reject Jackson Corporation’s offer and continue to manufacture only V262 valves.
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19‐27 (cont’d) 2.
Now compare the alternatives of (a) not implementing the new design versus (b) implementing the new design. By implementing the new design, Thomas will save 10,000 machine‐hours of rework time. This time can then be used to make and sell 30,000 (3 valves per hour 10,000 hours) additional V262 valves. The relevant costs and benefits of implementing the new design follow:
The relevant costs of implementing the new design Relevant benefits: (a) (b)
Savings in rework costs ($3 per V262 valve 30,000 valves) Additional contribution margin from selling another 30,000 V262 valves (3 valves per hour 10,000 hours) because capacity previously used for rework is freed up ($8 per valve 30,000 units) a
Net relevant benefit
$(315,000)
90,000
240,000 $ 15,000
Note that the fixed rework costs of equipment rent and allocated overhead are irrelevant, because these costs will be incurred whether Thomas implements or does not implement the new design. a
3.
Thomas should implement the new design since the relevant benefits exceed the relevant costs by $15,000. Thomas Corporation should also consider other benefits of improving quality. For example, the process of quality improvement will help Thomasʹs managers and workers gain expertise about the product and the manufacturing process that may lead to further cost reductions in the future. Improving quality within the plant is also likely to translate into delivering better quality products to customers. The increased reputation and customer goodwill may well lead to higher future revenue through greater unit sales and higher sales prices.
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Chapter 19
19‐28 (30 min.) Quality improvement, relevant costs, and relevant revenue. 1.
By implementing the new method, Tan would incur additional direct materials costs on all the 200,000 units started at the moulding operation. $800,000 Additional direct materials costs = $4 per lamp 200,000 lamps The relevant benefits of adding the new material are: Increased revenue from selling 30,000 more lamps $40 per lamp 30,000 lamps $1,200,000 Note that Tan Corporation continues to incur the same total variable costs of direct materials, direct manufacturing labour, setup labour and materials handling labour, and the same fixed costs of equipment, rent, and allocated overhead that it is currently incurring, even when it improves quality. Since these costs do not differ among the alternatives of adding the new material or not adding the new material, they are excluded from the analysis. The relevant benefit of adding the new material is the extra revenue that Tan would get from producing 30,000 good lamps. An alternative approach to analyzing the problem is to focus on scrap costs and the benefits of reducing scrap. The relevant benefits of adding the new material are: a. Cost savings from eliminating scrap: Variable cost per lamp, $19a 30,000 lamps $ 570,000 b. Additional contribution margin from selling another 30,000 lamps because 30,000 lamps will no longer be scrapped: Unit contribution margin $21b 30,000 lamps 630,000 Total benefits to Tan of adding new material to improve quality $1,200,000 a Note that only the variable scrap costs of $19 per lamp (direct materials, $16 per lamp; direct manufacturing labour, setup labour, and materials handling labour, $3 per lamp) are relevant because improving quality will save these costs. Fixed scrap costs of equipment, rent, and other allocated overhead are irrelevant because these costs will be incurred whether Tan Corporation adds or does not add the new material. b Contribution margin per unit
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19‐28 (cont’d) Selling price Variable costs: Direct materials costs per lamp $16.00 Moulding department variable manufacturing costs per lamp (direct manufacturing labour, setup labour, and materials handling labour) 3.00 Variable costs Unit contribution margin
2.
$40.00
(19.00) $21.00
On the basis of quantitative considerations alone, Tan should use the new material. Relevant benefits of $1,200,000 exceed the relevant costs of $800,000 by $400,000. Other nonfinancial and qualitative factors that Tan should consider in making a decision include the effects of quality improvement on: a. gaining manufacturing expertise that could lead to further cost reductions in the future; b. enhanced reputation and increased customer goodwill which could lead to higher future revenue through greater unit sales and higher sales prices; and c. higher employee morale as a result of higher quality.
19‐29 (30–40 min.) Statistical quality control, airline operations. 1.
The + 2 rule will trigger a decision to investigate when the round‐trip fuel usage is outside the control limit: Mean + 2 = 200 + 2 = 200 + (2 20) or 160 to 240 litre‐units Any fuel usage less than 160 litre‐units or greater than 240 litre‐units will trigger a decision to investigate. The only plane to be outside the specified + 2 fuel usage control limit is the Spirit of Manchester on flights #5 (242 litre‐units), #7 (249 litre‐units), and #10 (244 litre‐units).
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Chapter 19
19‐29 (cont’d) 2.
3.
Solution Exhibit 19‐29 presents the SQC charts for each of the three 747s. The Spirit of Birmingham has no observation outside the + 2 control limits. However, there was an increase in fuel use in each of the last nine round‐ trip flights. The probability of nine consecutive increases from an in‐control process is very low, and this is a trend that should be investigated. The Spirit of Glasgow appears in control regarding fuel usage. The Spirit of Manchester has three observations outside the + 2 control limits. Moreover, the mean of the fuel usage for the last six flights is 238 litre‐ units compared to a mean of 208 litre‐units for the first four flights. There is a rising trend, and some observations are already greater than the acceptable upper limits for fuel consumption. This should be investigated. The advantage of using dollar fuel costs as the unit of analysis in an SQC chart is that it focuses on a variable of overriding concern to top managers (operating costs). However, the disadvantages of using dollar fuel costs are: a. Split responsibilities. Operations managers may not control the purchase of fuel, and may want to exclude from their performance measures any variation stemming from factors outside their control. b. Offsetting factors may mask important underlying trends when the quantity used and the price paid are combined in a single observation. For example, decreasing litre usage may be offset by increasing fuel costs. Both of these individual patterns are important in budgeting for an airline. c. The distribution of fuel usage in litres may be different from the distribution of fuel prices per litre. More reliable estimates of the and parameters might be obtained by focusing separately on the individual usage and price distributions.
Note: The above disadvantages are most marked if actual fuel prices are used. The use of standard fuel prices can reduce many of these disadvantages.
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SOLUTION EXHIBIT 19‐29 Plots of Round‐Trip Fuel Usage for Jetrans Airlines
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Chapter 19
19‐30 (30–40 min.) Compensation linked with profitability, waiting time, and quality measures. 1. Philadelphia Add: Profitability 1% of operating income Add: Average waiting time $50,000 if < 15 minutes Deduct: Patient satisfaction $50,000 if < 70 Total: Bonus paid Baltimore Add: Profitability 1% of operating income Add: Average waiting time $50,000 if < 15 minutes Deduct: Patient satisfaction $50,000 if < 70 Total: Bonus paid
Jan.‐June $106,500 50,000 0 $156,500 $90,000 0 (50,000) $40,000
July‐Dec. $106,000 0 0 $106,000 $ 9,500 50,000 0 $59,500
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19‐30 (cont’d) 2.
Operating income as a measure of profitability
Operating income captures revenue and cost‐related factors. However, there is no recognition of investment differences between the two groups. If one group is substantially bigger than the other, differences in size alone give the president of the larger group the opportunity to earn a bigger bonus. An alternative approach would be to use return on investment (perhaps relative to the budgeted ROI). 15 minute benchmark as a measure of patient response time This measure reflects the ability of Mid‐Atlantic Healthcare to meet a benchmark for patient response time. Several concerns arise with this specific measure: a. It is a yes‐or‐no cut‐off. A 16 minute waiting time earns no bonus, but neither does a two hour wait. Moreover, no extra bonus is paid for additional waiting time reductions below 15 minutes. An alternative is to have the bonus that increases with greater waiting time improvements. b. It can be manipulated. Doctors might quickly make initial contact with a patient to meet the benchmark, but then leave the patient sitting in the examination room for a more detailed examination or procedure to take place. c. It reflects performance relative only to the initial waiting time. It does not consider other time‐related issues such as the wait for an appointment or the time needed to fill out forms. Problems in (b) and (c) can be overcome by measuring total patient response time (such as how long it takes from the time a patient makes an appointment to the time the actual appointment is concluded), in addition to average waiting time to meet the doctor. Patient satisfaction as a measure of quality This measure represents a common method for assessing quality. However, there are several concerns with its use: a. Patient satisfaction is likely to be influenced by a number of factors that are outside the groups’ control, such as how sick the patients are when coming in or the extent to which they follow doctors’ orders. 19–966
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19‐30 (cont’d) b. It is influenced by the questions asked in the survey and the survey methodology. As a result, is likely to be “noisy” or very sensitive to assumptions. c. Patient satisfaction is not the same as patient health outcomes, an important measure of healthcare quality. A combination of measures may work well as a composite measure of quality.
3. Most companies use both financial and nonfinancial measures to evaluate performance, sometimes presented in a single report such as a balanced scorecard. Using multiple measures of performance enables top management to evaluate whether lower‐level managers have improved one area at the expense of others. For example, did the better average waiting time (and patient satisfaction) between July and December in the Baltimore group result from significantly higher expenditures that contributed to the dramatic reduction in operating income? An important issue is the relative importance to place on the different measures. If waiting time is not used for performance evaluation, managers will concentrate on increasing operating income and give less attention to waiting time, even if waiting time has a significant influence on whether customers choose Mid‐Atlantic Healthcare or another healthcare provider when given the choice. However, the president of the Baltimore group received a larger bonus in the second half of the year due in part to lower average waiting time, even though operating profits dropped by nearly 90%. Companies must understand the relative importance of different financial and nonfinancial objectives when using multiple measures for performance evaluation.
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19‐31 (25–30 min.) Waiting times, manufacturing lead times. 1.
Average waiting time for an order of Z39 2
=
Annual average number Manufacturing time of orders of Z39 × per order of Z39 2 ×
Annual machine – capacity
[50 × (80)2]
=
= 2 × [5,000 – (50 × 80)]
Average manufacturing
lead time for Z39
Annual average number Manufacturing time of orders of Z39 × per order of Z39
(50 × 6,400)
320,000 = 160 hours per order = 2 × (5,000 – 4,000) (2 × 1,000)
=
Average order waiting Order manufacturing time + for Z39 time for Z39
= 160 hours + 80 hours = 240 hours per order
2.
Average waiting time for Z39 and Y28
Annual average number of orders of Z39 Annual machine
2 ×
capacity
×
Manufacturing time per order of Z39
Annual average –
number of orders of Z39
2
+
Annual average number of orders of Y28
Manufacturing ×
time per order of
–
Z39
number of orders of Y28
= [(50 × 6,400) + (25 × 400)] [50 × (80)2 ] + [25 × (20) 2] 2 × [5,000 – (50 × 80) – (25 × 20)] 2 × [5,000 – 4,000 – 500]
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Manufacturing time per
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2
order of Y28
Annual average
330,000 = 330 hours 1,000 Average manufacturing = Average order + Order manufacturing waiting time lead time for Z39 time for Z39 = 330 hours + 80 hours = 410 hours Average order Order manufacturing Average manufacturing = waiting time + lead time for Y28 time for Y28 = 330 hours + 20 hours = 350 hours
×
×
Manufacturing time per order of Y28
= (320,000 + 10,000) 2 × 500
Chapter 19
19‐32 (60 min.) Waiting times, relevant revenue, and relevant costs. 1. The direct approach is to look at incremental revenue and incremental costs. Selling price per order of Y28, which has an average manufacturing lead time of 350 hours $ 8,000 Variable cost per order 5,000 Additional contribution per order of Y28 3,000 Multiply by expected number of orders × 25 Increase in expected contribution from Y28 $75,000 Expected loss in revenue and increase in costs from introducing Y28 Expected Loss in Expected Increase in Expected Loss in Revenue from Carrying Costs from Revenue Plus Increasing Average Increasing Average Expected Increases Manufacturing Lead Manufacturing Lead in Carrying Costs of Product Times for All Products Times for All Products Introducing Y28 (2) (3) (4) = (2) + (3) (1) Z39 $25,000.00a $6,375.00b $31,375.00 c Y28 – 2,187.50 2,187.50 Total $25,000.00 $8,562.50 $33,562.50 a 50 orders × ($27,000 – $26,500) b (410 hours – 240 hours) × $0.75 × 50 orders c (350 hours – 0) × $0.25 × 25 Increase in expected contribution from Y28 of $75,000 is greater than increase in expected costs of $33,562.50 by $41,437.50. Therefore, SRG should introduce Y28.
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19‐32 (cont’d) Alternative calculations of incremental revenue and incremental costs of introducing Y28: Alternative 2: Alternative 1: Do Not Introduce Y28 Introduce Y28 (1) (2) a $1,350,000.00b Expected revenue $1,525,000.00 750,000.00d Expected variable costs 875,000.00c 9,000.00f Expected inv. carrying costs 17,562.50e Expected total costs 892,562.50 759,000.00 Expected revenue minus $ 591,000.00 expected costs $ 632,437.50 a (50 × $26,500) + (25 × $8,000) b 50 × $27,000 c (50 × $15,000) + (25 × $5,000) d 50 × $15,000 e (50 × $0.75 × 410) + (25 × $0.25 × 350) f 50 × $0.75 × 240
2.
Selling price per order of Y28, which has an average manufacturing lead time of more than 320 hours Variable cost per order Additional contribution per order of Y28 Multiply by expected number of orders Increase in expected contribution from Y28
Relevant Revenue and Relevant Costs (3) = (1) – (2) $175,000.00 125,000.00 8,562.50 133,562.50 $ 41,437.50
$ 6,000 5,000 $ 1,000 × 25 $25,000
Expected loss in revenue and increase in costs from introducing Y28:
Expected Loss in Expected Increase in Revenue from Carrying Costs from Increasing Average Increasing Average Manufacturing Lead Manufacturing Lead Product Times for All Products Times for All Products (1) (2) (3) a Z39 $25,000.00 $6,375.00b Y28 – 2,187.50c $8,562.50 Total $25,000.00 a 50 orders × ($27,000 – $26,500) b (410 hours – 240 hours) × $0.75 × 50 orders c (350 hours – 0) × $0.25 × 25
Expected Loss in Revenue Plus Expected Increases in Carrying Costs of Introducing Y28 (4) = (2) + (3) $31,375.00 2,187.50 $33,562.50
Increase in expected contribution from Y28 of $25,000 is less than increase in expected costs of $33,562.50 by $8,562.50. Therefore, SRG should not introduce Y28.
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Chapter 19
19‐33 (4045 min.) Manufacturing lead times, relevant revenue, and relevant costs. 1a. Average waiting time for an order of B7 if Brandt manufactures only B7 2 Average number Manufacturing of orders of B7 time for B7 = Annual machine Average number Manufacturing 2 capacity time for B7 of orders of B7 (125 1,600) [125 (40) 2 ] 200,000 = = = = 100 hours ( 2 1,000) 2 [6,000 (125 40)] 2 (6,000 5,000) 1b.
Average manufacturing = Average order waiting + Order manufacturing time lead time for B7 time for B7 for B7
= 100 hours + 40 hours = 140 hours Average waiting time for an order of B7 and A3 if Brandt manufactures both B7 and A3. 2 2 Average number Manufacturing Average number Manufacturing of orders of B7 time for B7 of orders of A3 time for A3 Average number Manufacturing Average number Manufacturing 2 Annual machine capacity time for B7 of orders of A3 time for A3 of orders of B7
[125 (40) 2 ] [10 (50) 2 ] = 2 [6,000 (125 40) (10 50)] =
[(125 1,600) (10 2,500)] (200,000 25,000) = 2 [6,000 5,000 500] 2 500
=
225,000 = 225 hours 1,000
Average manufacturing lead time for B7
=
Average order waiting Order manufacturing + time for B7 time
Average manufacturing lead time for A3
= 225 hours + 40 hours = 265 hours
= 225 hours + 50 hours = 275 hours
=
Average order waiting Order manufacturing + time for A3 time
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19‐33 (cont’d) 2.
The direct approach is to look at incremental revenue and incremental costs of manufacturing and selling A3.
Selling price per order for A3, which has average operating throughput time of 275 hours $12,960 Variable cost per order 9,000 Additional contribution per order from A3 3,960 Multiply by expected number of orders 10 Increase in expected contribution from A3 $39,600 Expected loss in revenue and increase in costs from introducing A3: Expected Loss in Expected Increase in Expected Loss in Revenue from Carrying Costs from Revenue Plus Increasing Average Increasing Average Expected Increases Manufacturing Lead Manufacturing Lead in Carrying Costs Product Times for All Products Times for All Products of Introducing A3 (1) (2) (3) (4) = (2) + (3) B7 $75,000.00a $7,812.50b $82,812.50 c – 1,237.50 1,237.50 A3 Total $75,000.00 $9,050.00 $84,050.00 a125 orders ($15,000 $14,400) b(265 hours – 140 hours) $0.50 125 orders c(275 hours – 0) $0.45 10 orders Increase in expected contribution from A3 of $39,600 is less than increase in expected costs of $84,050 by $44,450. Therefore, Brandt should not introduce A3; instead, it should sell only B7.
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19‐33 (cont’d) Alternative calculations of incremental revenue and incremental costs of introducing A3 follow. Alternative 2: Alternative 1: Do Not Relevant Revenue Introduce A3 Introduce A3 and Relevant (1) (2) Costs (3) = (1) – (2) a b Expected revenue $1,929,600 $1,875,000 $54,600 c d Expected variable costs 1,340,000 1,250,000 90,000 e f 8,750 9,050 Expected inventory carrying costs 17,800 Expected total costs 1,357,800 1,258,750 99,050 $ 616,250 $(44,450) Expected revenue minus expected $ 571,800 costs a(125 $14,400) + (10 $12,960) b125 $15,000 c(125 $10,000) + (10 $9,000) d125 $10,000 e(125 $0.50 265) + (10 $0.45 275) f125 $0.50 140 3. Delays occur in the processing of B7 and A3 because of (a) uncertainty about how many orders Brandt will actually receive (Brandt expects to receive 125 orders of B7 and 10 orders of A3), and (b) uncertainty about the actual dates when Brandt will receive the orders. The uncertainty (randomness) about the quantity and timing of customer orders means that Brandt may receive customer orders while another order is still being processed. Orders received while the machine is actually processing another order must wait in queue for the machine to be free. As average capacity utilization of the machine increases, there is less slack and a greater chance that a machine will be busy when another order arrives. Delays can be reduced if the uncertainties facing the firm can be reduced, perhaps by negotiating fixed schedules with customers in advance. Brandt should explore these alternatives before deciding on whether to manufacture and sell A3. A3 may be a strategically important product for Brandt in the future. For example, it may help Brandt to develop a customer relationship with Airbus Industries that could be helpful in the future. Even though manufacturing A3 is costly in the short run, it may be beneficial to Brandt in the long term. If Brandt could reduce manufacturing time for A3 (and B7), it could find it profitable to manufacture both harnesses. Brandt may also want to try to negotiate a higher price for A3 that would make manufacturing both B7 and A3 profitable.
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19‐34 (20 min.) Theory of constraints, throughput contribution, relevant costs. 1.
2.
It will cost Cabano $50 per unit to reduce manufacturing time. But manufacturing is not a bottleneck operation; installation is. Therefore, manufacturing more equipment will not increase sales and throughput contribution. Cabano Industries should not implement the new manufacturing method. Additional relevant costs of new direct materials, $2,000 320 units, $640,000 Increase in throughput contribution, $25,000 20 units, $500,000 The additional incremental costs exceed the benefits from higher throughput contribution by $140,000, so Cabano Industries should not implement the new design.
Alternatively, compare throughput contribution under each alternative. $7,500,000 Current throughput contribution is $25,000 300 With the modification, throughput contribution is $23,000 320 $7,360,000 The current throughput contribution is greater than the throughput contribution resulting from the proposed change in direct materials. Therefore, Cabano Industries should not implement the new design.
3.
Increase in throughput contribution, $25,000 10 units Increase in relevant costs
$250,000 $ 50,000
The additional throughput contribution exceeds incremental costs by $200,000, so Cabano Industries should implement the new installation technique. 4.
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Motivating installation workers to increase productivity is worthwhile because installation is a bottleneck operation, and any increase in productivity at the bottleneck will increase throughput contribution. On the other hand, motivating workers in the manufacturing department to increase productivity is not worthwhile. Manufacturing is not a bottleneck operation, so any increase in output will result only in extra inventory of equipment. Cabano Industries should encourage manufacturing to produce only as much equipment as the installation department needs, not to produce as much as it can. Under these circumstances, it would not be a good idea to evaluate and compensate manufacturing workers on the basis of their productivity.
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Chapter 19
19‐35 (30–40 min.) Theory of constraints, throughput contribution, quality, relevant costs. 1.
Direct materials costs to produce 390,000 tablets, $156,000 $156,000 Direct materials costs per tablet = = $0.40 per tablet 390,000 Selling price per tablet = $1.00 Unit throughput contribution = Selling price – Unit direct materials costs = $1.00 – $0.40 = $0.60 per tablet Tablet‐making is a bottleneck operation. Therefore, producing 19,500 more tablets will generate additional operating income.
2.
3.
Unit throughput Additional operating Additional operating income = – contribution costs per tablet per contractor‐made tablet = $0.60 – $0.12 = $0.48 Increase in operating income, $0.48 19,500 = $9,360. Therefore, Aardee should accept the outside contractorʹs offer. Operating costs for the mixing department are a fixed cost. Contracting out the mixing activity will not reduce mixing department costs but will cost an additional $0.07 per gram of mixture. Mixing more direct materials will have no effect on throughput contribution, since tablet making is the bottleneck operation. Therefore, Aardee should reject the companyʹs offer. The benefit of improved quality is $10,000. Aardee is using the same quantity of direct materials as before, so it incurs no extra direct materials costs. The 10,000 extra tablets produced generate additional revenue of $10,000 ($1 10,000 tablets) a month. The modification costs $7,000 per month, which results in a net gain of $3,000. Aardee should implement the new method.
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19‐35 (cont’d) 4. 5.
19–976
Cost per gram of mixture =
$156,000 = $0.78 per gram 200,000
Cost of 10,000 grams of mixture = $0.78 10,000 = $7,800 Benefit from better mixing quality $7,800 per month Cost of improving the mixing operation $9,000 per month Since the costs exceed the benefits by $1,200 per month, Aardee should not adopt the proposed quality improvement plan. Compare the answers to requirements 3 and 4. The benefit of improving quality at the mixing operation is the savings in materials costs. The benefit of improving quality of the tablet‐ making department (the bottleneck operation) is the savings in materials costs plus the additional throughput contribution from higher sales equal to the total revenue that result from relieving the bottleneck constraint.
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Chapter 19
19‐36 (30–35 min.) Governance and quality. 1. Revenue
2012 $10,000,000 Percentage of Revenue Cost (2) = (1) ÷ Costs of Quality (1) $10,000,000 Prevention costs 2.0% Design engineering $200,000 Appraisal costs 90,000 Inspection of production 210,000 Product testing 300,000 3.0% Total appraisal costs Internal failure costs 2.3% Scrap 230,000 External failure costs 2.6% 260,000 Warranty liability $990,000 9.9% Total costs of quality The total costs of quality are less than 10% of revenue. 2. Students can probably discuss both sides of this argument. Evans is obviously concerned because he expected the customer complaints calculation to be based on the number of customers who actually complained, not on Williams’s survey. However, Williams’s approach has the advantage of being thorough and systematic. Having done the survey, it would be unethical for Williams to now modify her analysis and incorrectly report the costs of quality and various nonfinancial measures of quality. In assessing the situation, the specific “Standards of Ethical Conduct for Management Accountants” (described in Exhibit 1‐7) that Lindsey Williams should consider are listed below.
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19‐36 (cont’d) Competence Clear reports using relevant and reliable information should be prepared. Preparing reports on the basis of incorrect numbers violates competence standards. Integrity Integrity requires that Williams report the numbers she collected. The standards of ethical conduct require the management accountant to communicate favourable as well as unfavourable information. Williams also has a responsibility to avoid actual or apparent conflicts of interest and advise all appropriate parties of any potential conflict. If Williams revises the customer complaints numbers, her action could be interpreted as being motivated by her desire to please her bosses. This would violate the responsibility for integrity. Credibility The management accountantʹs standards of ethical conduct require that information should be fairly and objectively communicated and that all relevant information should be disclosed. From a management accountantʹs standpoint, adjusting the customer complaints numbers to make performance look good would violate the standard of objectivity. Williams should indicate to Roche that the costs of quality and nonfinancial measures of quality presented in the reports are, indeed, appropriate. She could propose that she add another line item indicating the number of unsolicited complaints she received, that is, complaints she received independent of the survey. She should not, however, change the numbers she obtained in the survey. If Roche still insists on modifying the customer complaints numbers, Williams should raise the matter with one of Roche’s superiors, other than Evans, who has a vested interest in this dispute. If, after taking all these steps, there is continued pressure to change survey results, Williams should consider resigning from the company and not engage in unethical behaviour.
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Chapter 19
19‐37 (30‐35 min.) Theory of constraints, contribution margin, sensitivity analysis. 1.
Assuming only one type of doll is produced, the maximum production in each department given their resource constraints is:
Chatty Chelsey
Moulding Department 30,000 kg = 20,000 1.5 kg
Assembly Department 8,400 hours = 25,200 1/3 hours
Contribution Margin
$35 – (1.5 × $10) – (1/3 × $12) = $16 8,400 hours Talking Tanya $45 – (2 × $10) – (½ × 30,000 kg = 16,800 = 15,000 1/2hours $12) 2 kg = $19 For both types of dolls, the constraining resource is the availability of material since this constraint causes the lowest maximum production. If only Chatty Chelsey is produced, LTT can produce 20,000 dolls with a contribution margin of 20,000 × $16 = $320,000 If only Talking Tanya is produced, LTT can produce 15,000 dolls with a contribution margin of 15,000 × $19 = $285,000. LTT should produce Chatty Chelseys. 2. As shown in Requirement 1, available material in the Moulding department is the limiting constraint. If LTT sells two Chatty Chelseys for each Talking Tanya, then the maximum number of Talking Tanya dolls the Moulding Department can produce (where the number of Talking Tanya dolls is denoted as T) is: (T × 2 kg) + ([2 × T] × 1.5 kg) = 30,000 kg 2T + 3T = 30,000 5T = 30,000 T = 6,000 The Moulding Department can produce 6,000 Talking Tanya dolls, and 2 × 6,000 (or 12,000) Chatty Chelsey dolls.
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19‐37 (cont’d) Since LTT can only produce 6,000 Talking Tanyas and 12,000 Chatty Chelseys before it runs out of ingredients, the maximum contribution margin (CM) is: CM = (12,000 × $16) + (6,000 × $19) = $306,000 3. With 10 more pounds of materials, LTT would produce more dolls. Using the same technique as in Requirement 2, the increase in production is: (T × 2 kg) + ([2 × T] × 1.5 kg) =10 kg 2T + 3T = 10 T = 2 LTT would produce 2 extra Talking Tanya dolls and 4 extra Chatty Chelsey dolls. Contribution margin would increase by (4 × $16) + (2 × $19) = $102 4. With 10 more labour hours, production would not change. The limiting constraint is pounds of material, not labour hours. LTT already has more labour hours available than it needs.
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Chapter 19
19‐38 (25 min.) Quality improvement, Pareto diagram, cause‐and‐effect diagram. 1. 2.
3.
Examples of failures in accounts receivable management include the following: a. uncollectible amounts or bad debts; and b. delays in receiving payments. Prevention activities that could reduce failures in accounts receivable management include the following: a. credit checks on customers by salespersons based on company credit policy; b. shipping the correct copier to the customer; c. supporting installation of the copier and answering customer questions; c. sending the correct invoice, in the correct amount, and to the correct address, promptly; d. following up to see if the machine is functioning smoothly; and e. offering cash discounts to encourage early payment of receivables. A Pareto diagram for the problem of delays in receiving customer payments follows:
Number of times problem (failure) observed
SOLUTION EXHIBIT 19‐38A Pareto Diagram for Failures in Accounts Receivables at Murray Corporation
700
Delays in sending invoices
600 500
Improper installation
400 300 200
Invoice sent to incorrect address Incorrect copier shipped
100
Machine Customer not in functioning smoothly financial difficulties
Type of problem (failure)
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19‐38 (cont’d) A cause‐and‐effect or fishbone diagram for the problem of delays in sending invoices may appear as follows: SOLUTION EXHIBIT 19‐38B Cause‐and‐Effect Diagram For Problem of Delays in Sending Invoices at Murray Corporation Methods and Human Factor Design Factor Delivery documents New receivables not received clerk Wrong account Machine improperly debited installed not Invoices Computer error printed in invoice Wrong copier Computer not working shipped or backed up Machine-related Methods and Factors Components
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Chapter 19
19‐39 (30 min.) BSC analysis of quality. 1.
The ratio of each COQ category to revenues for each period is as follows: Semi‐annual Costs of Quality Report Bergen, Inc. (in thousands)
6/30/2012 12/31/2012 6/30/2013 12/31/2013 % of Rev. % of Rev. % of Rev. % of Rev. (2) = (4) = (6) = (8) = (1) (1)÷4,944 (3) (3)÷5,448 (5) (5)÷5,580 (7) (7)÷5,412
Prevention costs Machine maintenance$ 258 $ 258 Training suppliers 6 54 Design reviews 24 122 288 5.8% 434 Appraisal costs Incoming inspection 54 64 Final testing 192 192 246 5.0% 256 Internal failure costs Rework 144 127 Scrap 82 77 226 4.6% 204 External failure costs Warranty repairs 83 37 Customer returns 314 301 397 8.0% 338 Total quality costs $1,157 23.4% $1,232 Total production and $5,448 revenues $4,944
$ 228 24 120 8.0% 372
$ 192 18 114 6.7% 324
6.0%
4.7%
43 168 211
3.8%
26 113 139
2.6%
3.7%
106 50 156
2.8%
74 48 122
2.2%
30 28 139 96 6.2% 169 3.0% 124 2.3% 22.6% $ 908 16.3% $ 709 13.1% $5,580
$5,412
From an analysis of the Cost of Quality Report, it would appear that Bergen Inc.’s program has been successful since • Total quality costs as a percentage of total revenues have declined from 23.4% to 13.1%. • External failure costs, those costs signalling customer dissatisfaction have declined from 8% of total revenues to 2.3%. These declines in warranty repairs and customer returns should translate into increased revenues in the future. • Internal failure costs have been reduced from 4.6% to 2.2% of revenues. • Appraisal costs have decreased from 5.0% to 2.6%. Preventing defects from occurring in the first place is reducing the demand for final testing.
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19‐39 (cont’d) • Quality costs have shifted to the area of prevention where problems are solved before production starts. Maintenance, training, and design reviews have increased from 5.8% of total revenues to 6% and from 24.9% of total quality costs ($288 ÷ $1,157) to 45.7% ($324 ÷ $709). The $36,000 increase in these costs is more than offset by decreases in other quality costs. Because of improved designs, quality training, and additional pre‐production inspections, scrap and rework costs have declined. Production does not have to spend an inordinate amount of time with customer service since they are now making the product right the first time and warranty repairs and customer returns have decreased. 2.
To measure the opportunity cost of not implementing the quality program, Bergen Inc. could assume that
• Sales and market share would continue to decline if the quality program had not been implemented and then calculate the loss in revenue and contribution margin. • The company would have to compete on price rather than quality and calculate the impact of having to lower product prices. Opportunity costs are not recorded in accounting systems because they represent the results of what might have happened if Bergen had not improved quality. Nevertheless, opportunity costs of poor quality can be significant. It is important for Bergen to take these costs into account when making decisions about quality.
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Chapter 19
19‐40 (30‐40 min.) BSC analysis of quality. 1. and 2.
Sales, Costs of Quality and Costs of Quality as a Percentage of Sales for Olivia
Sales = $2,400 10,000 units = $24,000,000 Percentage of Sales Cost (2) = (1) ÷ Costs of Quality (1) $24,000,000 Prevention costs Design engineering ($90 6,000 hours) $ 540,000 2.25% Appraisal costs Testing and inspection ($48 1 hour 10,000 units) 480,000 2.00% Internal failure costs Rework ($600 5% 10,000 units) 300,000 1.25% External failure costs Repair ($720 4% 10,000 units) 288,000 1.20% Total costs of quality $1,608,000 6.70% Sales, Costs of Quality and Costs of Quality as a Percentage of Sales for Solta Sales: $1,800 5,000 units = $9,000,000 Percentage of Sales Cost (2) = (1) ÷ Costs of Quality (1) $9,000,000 Prevention costs Design engineering ($90 1,000 hours) $ 90,000 1.00% Appraisal costs Testing and inspection ($48 0.5 5,000 units) 120,000 1.33% Internal failure costs Rework ($480 10% 5,000 units) 240,000 2.67% External failure costs Repair ($540 8% 5,000 units) 216,000 2.40% Estimated forgone contribution margin 252,000 2.80% on lost sales [($1,800 – $960) 300] Total external failure costs 468,000 5.20% Total costs of quality $918,000 10.20%
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19‐40 (cont’d) Costs of quality as a percentage of sales are significantly different for Solta (10.20%) as compared with Olivia (6.70%). Ontario spends very little on prevention and appraisal activities for Solta, and incurs high costs of internal and external failures. Ontario follows a different strategy with respect to Olivia, spending a greater percentage of sales on prevention and appraisal activities. The result: fewer internal and external failure costs and lower overall costs of quality as a percentage of sales than with Solta. 3. Examples of nonfinancial quality measures that Ontario Industries could monitor as part of a total‐quality‐control effort are (a) Outgoing quality yield for each product. (b) Returned refrigerator percentage for each product. (c) On‐time delivery. (d) Employee turnover.
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Chapter 19
19‐41 (20 min.) Financial and nonfinancial analysis of quality. 1. and 2. Sales
2013 $12,500,000 Percentage of Sales Cost (2)=(1) ÷ (1) $12,500,000
2012 $10,000,000 Percentage of Sales Cost (4)=(3) ÷ (3) $10,000,000
Costs of Quality Prevention costs Design engineering Preventive maintenance Training Supplier evaluations Total prevention costs
$ 240,000 90,000 120,000 50,000 500,000
4.0%
$ 100,000 35,000 45,000 20,000 200,000
2.0%
Appraisal costs Line inspection Product testing equipment Incoming materials inspection Product testing labour Total appraisal costs
85,000 50,000 40,000 75,000 250,000
2.0%
110,000 50,000 20,000 220,000 400,000
4.0%
Internal failure costs Scrap Rework Breakdown maintenance Total internal failure costs
175,000 135,000 40,000 350,000
2.8%
250,000 160,000 90,000 500,000
5.0%
External failure costs Returned goods 145,000 Customer support 30,000 Product liability claims 100,000 Warranty repair 200,000 Total external failure costs 475,000 Total costs of quality $1,575,000
3.8% 12.6%
60,000 40,000 200,000 300,000 600,000 $1,700,000
6.0% 17.0%
Between 2012 and 2013 Hartono’s costs of quality have declined from 17% of sales to 12.6% of sales. The analysis of individual costs of quality categories indicates that Hartono began allocating more resources to prevention activities—design engineering, preventive maintenance, training and supplier evaluations in 2013 than in 2012. As a result, appraisal costs declined from 4% of sales to 2%, costs of internal failure fell from 5% of sales to 2.8%, and external failure costs decreased from 6% of sales to 3.8%.
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19‐41 (cont’d) 3.
Examples of nonfinancial quality measures that Hartono Corporation could monitor are (a) Number of defective grinders shipped to customers as a percentage of total units of grinders shipped. (b) Ratio of good output to total output at each production process. (c) Employee turnover.
19‐42 (30‐40 min.) Financial and nonfinancial analysis of quality. 1. Jan.–March April–June Kitchener Add: Profitability 2% of operating income $19,200 $20,400 Add: On‐time delivery $10,000 if above 98% 12,000 12,000 Deduct: Quality 50% of cost of sales (10,800) (15,600) returns $20,400 $16,800 Total: Bonus paid Napanee Add: Profitability 2% of operating income $38,400 $36,000 Add: On‐time delivery 0 $10,000 if above 98% 0 Deduct: Quality 50% of cost of sales (21,000) (20,400) returns $17,400 $15,600 Total: Bonus paid
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July–Sept. $16,800 0 (6,000) $10,800
Oct.–Dec. $21,600 0 (15,000) $ 6,600
$43,200 0 (16,800) $26,400
$45,600 12,000 (13,200) $44,400
Chapter 19
19‐42 (cont’d) 2.
Operating income as a measure of profitability Operating income does capture revenue and cost‐related factors. However, there is no recognition of investment differences between the two plants. Napanee sales are approximately double that of Kitchener This difference gives the Napanee plant manager the opportunity to earn a larger bonus due to investment size alone. An alternative approach would be to use return on investment (perhaps relative to the budgeted ROI). 98% on‐time benchmark as a measure of on‐time delivery performance This measure does reflect the ability of Pacific‐Dunlop to meet a benchmark for on‐ time delivery. Several concerns arise with this specific measure: (a) It is a yes‐or‐no cut‐off. A 10% on‐time performance earns no bonus, but neither does a 97.9% on‐time performance. Moreover, no extra bonus is paid for performance above 98.0%. An alternative is to have the bonus be a percentage of the on‐time delivery percentage. (b) It can be manipulated by management. The Pacific‐Dunlop plant manager may quote conservative delivery dates to salespeople in an effort to “guarantee” that the 98% target is achieved. (c) It reflects performance only relative to scheduled delivery date. It does not consider how quickly Pacific‐Dunlop can respond to customer orders. 50% of cost of sales returns as a measure of quality
This measure does incorporate one cost that arises with defective goods. However, there are several concerns with its use: (a) Not all sales returns are due to defective work by the plant manager. Some returns are due to tampering by the customer. Other returns arise from breakage during delivery and installation. (b) It does not systematically incorporate customer opinion about quality. Not all customers return defective goods. (c) It ignores important categories of the cost of defective goods. For example, dissatisfied customers may decline to make any subsequent purchases.
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19‐42 (cont’d) 3.
4.
Most companies use both financial and nonfinancial measures to evaluate performance, sometimes presented in a single report called a balanced scorecard. Using multiple measures of performance enables top management to evaluate whether lower‐level managers have improved one area at the expense of others. For example, did the on‐time delivery performance of the Kitchener plant manager decrease in the October‐December period relative to the April‐June period because the manager emphasized shipment of high‐margin products to increase operating income? If on‐time delivery were dropped as a performance evaluation measure, managers will concentrate on increasing operating income and decreasing sales returns but will give less attention to on‐time delivery. Consider the following situation. Suppose a manager must choose between (1) delivering a high‐margin order that will add to operating income while delaying a number of other orders and adversely affecting on‐time performance or (2) delaying the high‐margin order and sacrificing some operating income to achieve better on‐time performance. What action will the manager take? If on‐time performance is excluded as a performance evaluation measure, the manager will almost certainly choose (1). Only if on‐time performance is included in the manager’s performance evaluation will the manager consider choosing option (2).
19‐43 (20‐25 min.) Customer‐response time, on‐time delivery. 1. Pizzas delivered in 30 minutes or less Pizzas delivered in between 31 and 45 minutes Pizzas delivered in between 46 and 60 minutes Pizzas delivered in between 61 and 75 minutes
January– June 2012 120, 000 25% 480, 000 240, 000 50% 480, 000 96, 000 20% 480, 000 24, 000 5% 480, 000
January– December 2012 180, 000 30%
100%
Total
600, 000 312, 000 52% 600, 000 84, 000 14% 600, 000 24, 000 4% 600, 000
100%
Yes, customer‐response time has improved from January–June 2012 to July– December 2012. The percentage of pizzas delivered in less than 30 minutes increased by 5%, and pizzas delivered in less than or equal to 45 minutes increased by 7% [82% (30% + 52%) in July–December minus 75% (25% + 50%) in January–June]. In turn, pizzas delivered in greater than 45 minutes decreased by 7% [25% (20% + 5%) in January–June minus 18% (14% + 4%) in July–December].
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Chapter 19
19‐43 (cont’d) 2.
3.
In the January–June 2012 period, Pizzafest should quote a customer‐response time of (a) 45 minutes to achieve on‐time delivery performance of 75% (75% of all pizzas were delivered within this time frame) and (b) 60 minutes to achieve on‐time delivery performance of 95% (95% of all pizzas were delivered within this time frame). Yes. In the July–December 2012 period, Pizzafest would achieve on‐time delivery performance of (a) 82% (greater than its target performance level of 75%) if it had quoted a customer‐response time of 45 minutes and (b) 96% (greater than its target performance level of 95%) if it had quoted a customer‐response time of 60 minutes.
COLLABORATIVE LEARNING CASES
19‐44 (45–50 min.) Quality improvement, theory of constraints. 1.
2.
Consider the incremental revenue and incremental costs to Wellesley Corporation of purchasing additional grey cloth from outside suppliers. Incremental revenue, $1,250 × (5,000 rolls × 0.90) Incremental costs: Cost of grey cloth, $900 × 5,000 rolls $4,500,000 Direct materials variable costs at printing operation, $100 × 5,000 rolls 500,000 Incremental costs Excess of incremental revenue over incremental costs
$5,625,000
5,000,000 $ 625,000
Note that, because the printing department has surplus capacity equal to 5,500 (15,000 – 9,500) rolls per month, purchasing grey cloth from outside entails zero opportunity costs. Yes, the Printing Department should buy the grey cloth from the outside supplier. By producing a defective roll in the Weaving Department, Wellesley Corporation is worse off by the entire amount of revenue forgone of $1,250 per roll. Note that, since the weaving operation is a constraint, any rolls received by the Printing Department that are defective and disposed of at zero net disposal value result in lost revenue to the firm. An alternative approach to analyzing the problem is to focus on the costs of defective units and the benefits of reducing defective units.
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19‐44 (cont’d)
The relevant costs of defective units in the Printing Department are: a. Direct materials variable costs in the Weaving Department $ 500 b. Direct materials variable costs in the Printing Department 100 c. Contribution margin forgone from not selling one roll $1,250 – $500 – $100 650 Amount by which Wellesley Corporation is worse off as a result of a defective unit in the Printing Department $1,250 Note that only the variable costs of defective units of $600 per roll (direct materials in the Weaving Department, $500 per roll: direct materials in the Printing Department, $100 per roll) are relevant because improving quality will save these costs. Fixed costs of producing defective units, attributable to other operating costs, are irrelevant because these costs will be incurred whether Wellesley Corporation reduces defective units in the Printing Department or not. Wellesley Corporation should make the proposed modifications in the Printing Department because the incremental benefits exceed the incremental costs by $125,000 per month:
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Incremental benefits of reducing defective units in the Printing Department by 4% (from 10% to 6%) 4% × 9,500 rolls × $1,250 per roll (computed above) $475,000 Incremental costs of the modification 350,000 Excess of incremental benefits over incremental costs $125,000
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Chapter 19
19‐44 (cont’d) 3.
To determine how much Wellesley Corporation is worse off by producing a defective roll in the Weaving Department, consider the payoff to Wellesley from not having a defective roll produced in the Weaving Department. The good roll produced in the Weaving Department will be sent for further processing in the Printing Department. The relevant costs and benefits of printing and selling this roll follow: Additional direct materials variable costs incurred in the Printing Department $ (100) Expected revenue from selling the finished product, $1,250 × 0.9 (since 10% of the Printing Department output will be defective and will earn zero revenue) 1,125 Net expected benefit of producing a good roll in the Weaving Department $1,025 By producing a defective roll in the Weaving Department, Wellesley Corporation is worse off by $1,025 per roll. Note that, since the weaving operation is a constraint, any rolls that are defective will result in lost revenue to the firm. An alternative approach to analyzing the problem is to focus on the costs and benefits of reducing defective units. The relevant costs of defective units in the Weaving Department are: a. Direct materials variable costs in the Weaving Department $ 500 b. Expected unit contribution margin forgone from 525 not selling one roll, ($1,250 × 0.9) – $500 – $100 Amount by which Wellesley Corporation is worse off as a result of producing a defective unit in the Weaving Department $1,025 Note that only the variable scrap costs of $500 per roll (direct materials in the Weaving Department) are relevant because improving quality will save these costs. All fixed costs of producing defective units attributable to other operating costs are irrelevant because these costs will be incurred whether Wellesley Corporation reduces defective units in the Weaving Department or not. Wellesley Corporation should make the improvements proposed by the design engineering team because the incremental benefits exceed the incremental costs by $30,000 per month:
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19‐44 (cont’d)
Incremental benefits of reducing defective units in the Weaving Department by 2% (from 5% to 3%) 2% × 10,000 rolls × $1,025 per roll (computed above) $205,000 Incremental costs of improvements 175,000 Excess of incremental benefits over incremental costs $ 30,000
19‐45 (10 min.) Curvilinear cost functions. 1.
2.
3.
4.
Comparing the calculated values of t for the coefficients a, and b, you note that the critical value for d.f. = 25 and a confidence level of 95% of 2.060 is higher than the calculated t value of 1.006 for the intercept coefficient a but lower than the calculated t value for the slope coefficient b of 3.865. You can be confident there is only a very small chance, about 7 in 10,000, or .0007, that the slope is a random value—but there is an unacceptably high probability of over 3 in 10 that the value of the intercept is a random value. Specification analysis or checking that the linear relationship specified between (X,Y) reports on the economic facts of production must be the first step BEFORE doing any analyses. The real relationship may not be linear, the residuals may not be normally distributed, and the residuals may not display a uniform or constant variance. The next step is to examine the residuals. The plot of the residuals provides further evidence that the relationship has not been fully specified by the linear equation. An imaginary line joining the points indicates a systematic, curved line. There are also far more positive differences between Y and y and of larger size, than there are negative differences which are of smaller size. The next step is to try plotting a different relationship, perhaps a curvilinear relationship between the increase in production and in cost. From Chapter 10 the measure of value‐added is usually a quantity of common direct input consumed. The input measure is considered to be an affordable and economically plausible way to allocate the unequal benefits of unequal sharing of the common input. This is the predictor variable. The outcome variable is usually the value of a cost pool. From the results of plotting the Actual Values of the Quarterly MOH cost pool with a trendline, two things are apparent. First there are two small quarterly values followed by two much larger values. This suggests there is another explanatory variable and seasonality in demand (and production) may be the second explanatory variable.
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Chapter 19
19‐45 (cont’d)
Second, and perhaps more importantly the trendline indicates a curvilinear relationship, not a linear relationship among the predictor variables and the outcome variable. The multiple linear regression analysis will not help the team if this is true. It suggests that there are economies of scale at work to reduce costs despite the increase in production. This reinforces that a multiple linear regression analysis is inappropriate. Third by specifying a curvilinear function the R2 is almost unchanged. Sales clearly has some explanatory power but is inadequate on its own to make a reliable prediction of future MOH costs.
5. The trendline of actual average cost per unit reinforces that the change in average cost per unit is increasing at a faster rate as sales increase. This may arise because the company is outsourcing production that is beyond the relevant range of the company’s capacity. In the short term this may be appropriate but over the longer term it could indicate inappropriate scheduling of production to meet peak periods.
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CHAPTER 20 INVENTORY COST MANAGEMENT STRATEGIES
SHORT‐ANSWER QUESTIONS
20‐1 Cost of goods sold (in retail organizations) or direct materials costs (in organizations with a manufacturing function) as a percentage of sales frequently exceeds net income as a percentage of sales by many orders of magnitude. In the Kroger grocery store example cited in the text, cost of goods sold to sales is 73.7%, and net income to sales is 0.6%. Thus, a 10% reduction in the ratio of cost of goods sold to sales (73.7 to 66.3%) without any other changes can result in a 1233% increase in net income to sales (0.6% to 8.0%).
20‐2 Five cost categories important in managing goods for sale in a retail organization are the following: 1. purchasing costs; 2. ordering costs; 3. carrying costs; 4. stockout costs; and 5. quality costs
20‐3 Five assumptions made when using the simplest version of the EOQ model are: 1. 2. 3. 4. 5.
The same quantity is ordered at each reorder point. Demand, ordering costs, carrying costs, and the purchase‐order lead time are certain. Purchasing cost per unit is unaffected by the quantity ordered. No stockouts occur. Costs of quality are considered only to the extent that these costs affect ordering costs or carrying costs.
20‐4 Costs included in the carrying costs of inventory are incremental costs for such items as insurance, rent, obsolescence, spoilage, and breakage plus the opportunity cost of capital (or required return on investment).
20‐5 Examples of opportunity costs relevant to the EOQ decision model but typically not recorded in accounting systems are the following: 1. the return forgone by investing capital in inventory; 2. lost contribution margin on existing sales when a stockout occurs; and 3. lost contribution margin on potential future sales that will not be made to disgruntled customers.
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Chapter 20
20‐6 The steps in computing the costs of a prediction error when using the EOQ decision model are: Step 1: Compute the monetary outcome from the best action that could be taken, given the actual amount of the cost input. Step 2: Compute the monetary outcome from the best action based on the incorrect amount of the predicted cost input. Step 3: Compute the difference between the monetary outcomes from Steps 1 and 2.
20‐7 Goal congruence issues arise when there is an inconsistency between the EOQ decision model and the model used for evaluating the performance of the person implementing the model. For example, if opportunity costs are ignored in performance evaluation, the manager may be induced to purchase in a quantity larger than the EOQ model indicates is optimal.
20‐8 Just‐in‐time (JIT) purchasing is the purchase of materials (or goods) so that they are delivered just as needed for production (or sales). Benefits include lower inventory holdings (reduced warehouse space required and less money tied up in inventory) and less risk of inventory obsolescence and spoilage.
20‐9 Factors causing reductions in the cost to place purchase orders of materials are:
Companies are establishing long‐run purchasing agreements that define price and quality terms over an extended period. Companies are using electronic links, such as the Internet, to place purchase orders. Companies are increasing the use of purchase‐order cards.
20‐10 Supply‐chain analysis describes the flow of goods, services, and information from the initial sources of materials and services to the delivery of products to consumers, regardless of whether those activities occur in the same organization or in other organizations. Sharing of information across companies enables a reduction in inventory levels at all stages, fewer stockouts at the retail level, reduced manufacture of product not subsequently demanded by retailers, and a reduction in expedited manufacturing orders.
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Instructor’s Solutions Manual, Cost Accounting, 6Ce
20‐11 Obstacles to companies adopting a supply‐chain approach include: • Communication obstacles—the unwillingness of some parties to share information. • Trust obstacles—includes the concern that all parties will not meet their agreed‐upon commitments. • Information system obstacles—includes problems due to the information systems of different parties not being technically compatible. • Limited resources—includes problems due to the people and financial resources given to support a supply‐chain initiative not being adequate.
20‐12 Just‐in‐time (JIT) production is a “demand‐pull” manufacturing system that has the following features: Organize production in manufacturing cells, Hire and retain workers who are multi‐skilled, Aggressively pursue total quality management (TQM) to eliminate defects, Place emphasis on reducing both setup time and manufacturing lead time, and Carefully select suppliers who are capable of delivering quality materials in a timely manner.
20‐13 Traditional normal and standard costing systems use sequential tracking, in which journal entries are recorded in the same order as actual purchases and progress in production, typically at four different trigger points in the process. Backflush costing omits recording some of the journal entries relating to the cycle from purchase of direct materials to sale of finished goods, i.e., it has fewer trigger points at which journal entries are made. When journal entries for one or more stages in the cycle are omitted, the journal entries for a subsequent stage use normal or standard costs to work backward to “flush out” the costs in the cycle for which journal entries were not made.
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Chapter 20
20‐14 Versions of backflush costing differ in the number and placement of trigger points at which journal entries are made in the accounting system: Number of Journal Entry Location in Cycle Where Trigger Points Journal Entries Made Version 1 3 Stage A. Purchase of direct materials Stage C. Completion of good finished units of product Stage D. Sale of finished goods Version 2 2 Stage A. Purchase of direct materials Stage D. Sale of finished goods Version 3 2 Stage C. Completion of good finished units of product Stage D. Sale of finished goods
EXERCISES 20‐15
(10 min.) Terminology.
Supply‐chain strategy decisions determine inventory management activities. Managing inventory involves the identification of three relevant costs, purchasing costs, ordering costs, and carrying costs. One strategy of just‐in‐time(JIT) purchasing will match to a production decision to undertake just‐in‐time (JIT) or lean production. This JIT purchasing strategy will minimize purchasing costs of inventory and reduce or eliminate both shrinkage and carrying costs but may increase ordering costs. The goal of the management team is to minimize the overall combination of costs associated with inventory management. Any inventory management model requires careful analysis to identify the reorder point, the economic order quantity, and the trigger points. The management team requires high quality information database of the type found in Enterprise Resource Planning (ERP) systems. ERP systems are demand pull systems. Implementing a good demand pull system requires a highly co‐ordinated information flow that supports lean production. Lean production (JIT) can eliminate inventory and therefore the backflush costing method is appropriate. With no WIP or materials inventories, the need for sequential or synchronous tracking of costs of production through the inventories is no longer necessary. Instead trigger points are identified such as materials purchase and completion of unspoiled finished goods. Costs transfer at only these two trigger points from the Direct Materials to the Finished Goods inventory.
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Instructor’s Solutions Manual, Cost Accounting, 6Ce
20‐16 (20 min.) Economic order quantity for retailer. 1.
D = 10,000, P = $200, C = $7 2 DP 2 10,000 $200 EOQ = 755.93 756 jerseys C 7
2.
Number of orders per year =
10,000 D = = 13.22 14 orders EOQ 756
10,000 D = = 27.40 jerseys per day Number of working days 365 Purchase lead time = 7 days Reorder point = 27.40 7 = 191.80 192 jerseys
Demand each 3. working day =
20‐17 (20 min.) Economic order quantity, effect of parameter changes. 1.
D = 10,000, P = $30, C = $7 2 DP 2 10,000 $30 EOQ = 292.77 jerseys 293 jerseys C 7
The sizable reduction in ordering cost (from $200 to $30 per purchase order) has reduced the EOQ from 756 to 293. 2.
The AT proposal has both upsides and downsides. The upside is potentially higher sales. FB customers may purchase more online than if they have to physically visit a store. FB would also have lower administrative costs and lower inventory holding costs with the proposal. The downside is that AT could capture FB’s customers. Repeat customers to the AT web site need not be classified as FB customers. FB would have to establish enforceable rules to make sure it captures ongoing revenue from customers it directs to the AP web site. There is insufficient information to determine whether FB should accept AT’s proposal. Much depends on whether FB views AT as a credible, “honest” partner.
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Chapter 20
20‐18 (15 min.) EOQ for a retailer. 1.
D = 20,000, P = $160, C = 20% $8 = $1.60
EOQ =
2DP 2 20‚000 $160 = = 2,000 yards C $1.60
2.
Number of orders per year:
20‚000 D = = 10 orders 2‚000 EOQ
3.
D Number of working days 20‚000 = 250 = 80 yards per day = 400 yards per week Purchasing lead time = 2 weeks Reorder point = 400 yards per week 2 weeks = 800 yards Demand each working day =
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Instructor’s Solutions Manual, Cost Accounting, 6Ce
20‐19 (20 min.) EOQ for manufacturer. 1.
Relevant carrying costs per part per year: Required annual return on investment 15% $60 = Relevant insurance, materials handling, breakage, etc. costs per year Relevant carrying costs per part per year
$ 9 6 $15
With D = 18,000; P = $150; C = $15, EOQ for manufacturer is: 2DP 2 18,000 $150 = = 600 units C $15
2. 3.
4.
D Total relevant ordering costs = Q P
18,000 $150 = 600 = $4,500 where Q = 600 units, the EOQ.
At the EOQ, total relevant ordering costs and total relevant carrying costs will be exactly equal. Therefore, total relevant carrying costs at the EOQ = $4,500 (from requirement 2). We can also confirm this with direct calculation: Q Total relevant carrying costs = C 2 600 = $15 2 = $4,500 where Q = 600 units, the EOQ. Purchase order lead time is half a month. Monthly demand is 18,000 units ÷ 12 months = 1,500 units per month. 1 Demand in half a month is 1,500 units or 750 units. 2 Lakeland should reorder when the inventory of rotor blades falls to 750 units.
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Chapter 20
20‐20 (20 min.) Sensitivity of EOQ to changes in relevant ordering and carrying costs. 1.
A straightforward approach to the requirement is to construct the following table for EOQ at relevant carrying and ordering costs. Annual demand is 10,000 units. The formula for the EOQ model is:
2DP C D = demand in units for a specified period of time P = relevant ordering costs per purchase order C = relevant carrying costs of one unit in stock for the time period used for D (one year in this problem.
EOQ =
where
Relevant Carrying Costs per Unit per Year
Relevant Ordering Costs per Purchase Order $300 $200
$10
2 10,000 $300 $10
= 775
2 10,000 $200 $10
= 632
15
2 10,000 $300 = 632 $15
2 10,000 $200 = 516 $15
2 10,000 $300
2 10,000 $200
2.
20
$20
= 548
$20
= 447
For a given demand level, as relevant carrying costs increase, EOQ becomes smaller. For a given demand level, as relevant order costs increase, EOQ increases.
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Instructor’s Solutions Manual, Cost Accounting, 6Ce
20‐21 (15 min.)
Inventory management and the balanced scorecard. 1. The incremental increase in operating profits from employee cross‐training (ignoring the cost of the training) is: Increased revenue from higher customer satisfaction ($5,000,000 × 2% × 5) $500,000 Reduced inventory‐related costs 100,000 Incremental increase in operating profits (ignoring training costs) $600,000 2. At a cost of $600,000, DSC will be indifferent between current expenditures and increasing employee cross‐training by 5%. Consequently, the most DSC would be willing to pay for this cross‐training is the $600,000 benefit received. 3. Besides increasing short‐term operating profits, additional employee cross‐ training can improve employee satisfaction because their jobs can have more variety, potentially leading to unanticipated productivity improvements and lower employee turnover. Multi‐skilled employees can also understand the production process better and can suggest potential improvements. Each of these may lead to additional cost reductions.
20‐22 (20 min.) JIT production, relevant benefits, relevant costs. 1. 2.
20–1004
Solution Exhibit 20‐22 presents the annual net benefit of $315,000 to Champion Hardware Company of implementing a JIT production system. Other nonfinancial and qualitative factors that Champion should consider in deciding whether it should implement a JIT system include: a. The possibility of developing and implementing a detailed system for integrating the sequential operations of the manufacturing process. Direct materials must arrive when needed for each subassembly so that the production process functions smoothly. b. The ability to design products that use standardized parts and reduce manufacturing time. c. The ease of obtaining reliable vendors who can deliver quality direct materials on time with minimum lead time. d. Willingness of suppliers to deliver smaller and more frequent orders. e. The confidence of being able to deliver quality products on time. Failure to do so would result in customer dissatisfaction. f. The skill levels of workers to perform multiple tasks such as minor repairs, maintenance, quality testing and inspection.
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Chapter 20
SOLUTION EXHIBIT 20‐22 Annual Relevant Costs of Current Production System and JIT Production System for Champion Hardware Company Relevant Relevant Costs under Costs under Current JIT Production Production Relevant Items System System Annual tooling costs – $100,000 Required return on investment: $150,000 15% per year $1,000,000 of average inventory per year 15% per year $200,000a of average inventory per year 30,000 Insurance, space, materials handling, and setup costs 300,000 225,000b Rework costs 200,000 140,000c Incremental revenue from higher selling prices – (160,000)d Total net incremental costs $650,000 $335,000 Annual difference in favour of JIT production $315,000 a $1,000,000 (1 – 80%) = $200,000 b c
$300,000 (1 – 0.25) = $225,000
$200,000 (1 – 0.30) = $140,000
d
$4 × 40,000 units = $160,000
3.
Personal observation by production line workers and managers is more effective in JIT plants than in traditional plants. A JIT plant’s production process layout is streamlined. Operations are not obscured by piles of inventory or rework. As a result, such plants are easier to evaluate by personal observation than cluttered plants where the flow of production is not logically laid out. Besides personal observation, nonfinancial performance measures are the dominant methods of control. Nonfinancial performance measures provide most timely and easy to understand measures of plant performance. Examples of nonfinancial performance measures of time, inventory, and quality include: Manufacturing lead time Units produced per hour Machine setup time ÷ manufacturing time Number of defective units ÷ number of units completed
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Instructor’s Solutions Manual, Cost Accounting, 6Ce
20‐22 (cont’d) In addition to personal observation and nonfinancial performance measures, financial performance measures are also used. Examples of financial performance measures include: Cost of rework Ordering costs Stockout costs Inventory turnover (cost of goods sold average inventory) The success of a JIT system depends on the speed of information flows from customers to manufacturers to suppliers. The Enterprise Resource Planning (ERP) system has a single database, and gives lower‐level managers, workers, customers, and suppliers access to operating information. This benefit, accompanied by tight coordination across business functions, enables the ERP system to rapidly transmit information in response to changes in supply and demand so that manufacturing and distribution plans may be revised accordingly.
20‐23 (30 min.) Backflush costing and JIT production. 1. (a) Purchases of direct materials (b) Incur conversion costs (c) Completion of finished goods
Inventory: Materials and In‐Process Control Accounts Payable Control Conversion Costs Control Various Accounts Finished Goods Controla
(d) Sale of finished goods a26,800 × ($102 + $28) = $3,484,000 b26,400 × ($102 + $28) = $3,432,000
Inventory: Materials and In‐Process Control Conversion Costs Allocated b 3,432,000 Cost of Goods Sold Finished Goods Control
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2,754,000 2,754,000 723,600 723,600 3,484,000
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2,733,600 750,400
3,432,000
Chapter 20
20‐23 (cont’d) 2.
Inventory:
Materials and In-Process Control
Direct Materials
(a) 2,754,000
(c) 2,733,600
Finished Goods Control (c) 3,484,000 (d) 3,432,000
Cost of Goods Sold (d) 3,432,000
Bal. 52,000
Bal. 20,400
Conversion Costs Allocated (c) 750,400
Conversion Costs
Conversion Costs Control (b) 723,600
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Instructor’s Solutions Manual, Cost Accounting, 6Ce
20‐23 (cont’d) 3.
Under an ideal JIT production system, there could be zero inventories at the end of each day. Entry (c) would be $3,432,000 finished goods production, not $3,484,000. Also, there would be no inventory of direct materials instead of $2,754,000 – $2,733,600 = $20,400.
20‐24 (20 min.) Backflush costing, two trigger points, materials purchase and sale. 1. (a) Purchases of direct materials (b) Incur conversion costs (c) Completion of finished goods (d) Sale of finished goods (e) Underallocated or overallocated conversion costs
20–1008
Inventory Control Accounts Payable Control Conversion Costs Control Various Accounts No entry
2,754,000
723,600
2,754,000 723,600
Cost of Goods Sold 3,432,000 Inventory Control Conversion Costs Allocated Conversion Costs Allocated 739,200 Costs of Goods Sold Conversion Costs Control
2,692,800 739,200 15,600 723,600
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Chapter 20
20‐24 (cont’d) 2. Direct Materials
Inventory Control (a) 2,754,000
(d) 2,692,800
Cost of Goods Sold (d) 3,432,000
(e) 15,600
Bal. 61,200
Conversion Costs Allocated (e) 739,200 (d) 739,200
Conversion Costs
Conversion Costs Control (b) 723,600
(e) 723,600
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Instructor’s Solutions Manual, Cost Accounting, 6Ce
20‐25 (20 min.) Backflush costing, two trigger points, completion of production and sale. 1. (a) Purchases of direct materials (b) Incur conversion costs (c) Completion of finished goods
No Entry Conversion Costs Control Various Accounts Finished Goods Control
(d) Sale of finished goods (e) Underallocated or Overallocated conversion Costs
20–1010
723,600 3,484,000
723,600
Accounts Payable Control Conversion Costs Allocated Cost of Goods Sold 3,432,000 Finished Goods Control Conversion Costs Allocated 750,400 Costs of Goods Sold Conversion Costs Control
2,733,600 750,400
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3,432,000 26,800 723,600
Chapter 20
20‐25 (cont’d) 2.
Direct Materials
Finished Goods Control (c) 3,484,000
(d) 3,432,000
Cost of Goods Sold (d) 3,432,000
(e) 26,800
Bal. 52,000
Conversion Costs Allocated (e) 750,400 (c) 750,400
Conversion Costs
Conversion Costs Control (b) 723,600
(e) 723,600
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Instructor’s Solutions Manual, Cost Accounting, 6Ce
PROBLEMS
20‐26 (30 min.) Effect of different order quantities on ordering costs and carrying costs, EOQ. 1.
1 234,000 $ 81.00 $ 11.70 900 260.00 $21,060 $ 5,265
2 234,000 $ 81.00 $ 11.70 1,500 156.00 $12,636 $ 8,775
Scenario 3 234,000 $ 81.00 $ 11.70 1,800 130.00 $10,530 $10,530
$26,325
$21,411
$21,060
Demand (units) (D) Cost per purchase order (P) Annual carrying cost per package (C) Order quantity per purchase order (units) (Q) Number of purchase orders per year (D Q) Annual ordering costs (D Q) P Annual carrying costs (QC 2) Total relevant costs of ordering and carrying inventory
4 234,000 $ 81.00 $ 11.70 2,100 111.43 $ 9,026 $12,285
5 234,000 $ 81.00 $ 11.70 2,700 86.67 $ 7,020 $15,795
$21,311
$22,815
The economic order quantity is 1,800 packages. It is the order quantity at which carrying costs equal ordering costs and total relevant ordering and carrying costs are minimized. We can also confirm this from direct calculation. Using D = 234,000; P = $81 and C = $11.70 2 234,000 $81 EOQ = = 1,800 packages $11.70 It is interesting to note that Koala Blue faces a situation where total relevant ordering and carrying costs do not vary very much when order quantity ranges from 1,500 packages to 2,700 packages. 2. When the ordering cost per purchase order is reduced to $49: 2 234,000 $49 = 1,400 packages EOQ = $11.70 The EOQ drops from 1,800 packages to 1,400 packages when Koala Blue’s ordering cost per purchase order decreases from $81 to $49. D 234,000 $49 = $8,190 And the new relevant costs of ordering inventory = P = Q 1,400 1,400 Q and the new relevant costs or carrying inventory = C = $11.70 = $8,190 2 2 The total new costs of ordering and carrying inventory = $8,190 2 = $16,380
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Chapter 20
20‐26 (cont’d) 3.
As summarized below, the new Mona Lisa web‐based ordering system, by lowering the EOQ to 1,400 packages, will lower the carrying and ordering costs by $4,680. Koala Blue will spend $2,000 to train its purchasing assistants on the new system. Overall, Koala Blue will still save $2,680 in the first year alone.
Total relevant costs at EOQ (from Requirement 2) Annual cost benefit over old system ($21,060 – $16,380) Training costs Net benefit in first year alone
$16,380 $ 4,680 2,000 $ 2,680
20‐27 (30 min.) EOQ, uncertainty, safety stock, reorder point. 1. 2.
2 DP 2 120,000 $250 C $2.40 = 5,000 pairs of shoes
EOQ
Weekly demand = Monthly demand ÷ 4 = 10,000 ÷ 4 = 2,500 pairs of shoes per week Purchasing lead time = 1 week Reorder point = 2,500 pairs of shoes per week × 1 week = 2,500 pairs of shoes 3. Safety stock = 20% ×10,000 = 2,000 pairs of shoes Reorder point = Weekly demand + Safety stock = 2,500 + 2,000 = 4,500 pairs of shoes EOQ = 5,000 pairs of shoes (since neither annual demand, ordering cost, nor carrying cost have changed, the EOQ will not change). 4. Without Safety Stock With Safety Stock D 120, 000 120, 000 Total relevant a. = P $250 = $6,000 $250 = $6,000 ordering costs 5, 000 5, 000 Q 5, 000 5, 000 Total relevant Q $2.40 = $6,000 ( 2,000) $2.40 =$10,800 b. = ( Safety Stock) C ordering costs 2 2 2 c. Total Relevant Cost (a + b)
$12,000
$16,800
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Instructor’s Solutions Manual, Cost Accounting, 6Ce
20‐28 (25 min.) MRP and ERP. 1. Under a MRP system: Annual cost of producing and carrying J‐Pods in inventory = Variable production cost + Setup cost + Carrying cost = $50 × 48,000 + ($50,000 × 12 months) + [$20 × (4,000 ÷ 2)] = $2,400,000 + 600,000 + 40,000 = $3,040,000 2. Using an EOQ model to determine batch size:
EOQ
2 DP 2 48,000 $50,000 C $20
= 15,492 J‐Pods per batch Production of 48,000 per year divided by a batch size of 15,492 would imply J‐ Pods would be produce 3.1 batches per year. Rounding this up to the nearest whole number yields 4 batches per year. Annual Cost of producing and carrying J‐Pods in inventory = Variable production cost + Setup cost + Carrying cost = $50 × 48,000 + ($50,000 × 4) + [$20 × (15,492 ÷ 2)] = $2,400,000 + 200,000 + 154,920 = $2,754,920 3. Under a JIT system Annual Cost of producing and carrying J‐Pods in inventory = Variable production cost + Setup cost + Carrying cost = $50 × 48,000 + ($5,000 × 96 a) + [$20 × (500 ÷ 2)] = $2,400,000 + 480,000 + 5,000 = $2,885,000 a production of 48,000 per year divided by a batch size of 500 would imply 96 setups per year.
4. The EOQ system resulted in the lowest costs, despite the fact that carrying costs were lower for the JIT model. However, the EOQ model, in this case, limits production to only once every four months. This would not allow managers to react quickly to changing market demand or economic conditions. The JIT model provides management with much more flexibility. JIT systems might also lead managers to improve processes, reduce costs and increase quality.
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Chapter 20
20‐29 (30 min.) Effect of management evaluation criteria on EOQ model.
2 DP 2 500,000 $800 C $50 = 4,000 computers
1. EOQ
2. Number of orders per year =
D 500,000 = 125 orders EOQ 4,000
500,000 Total relevant = D ordering costs Q P = 4,000 $800 = $100,000 4,000 Total relevant Q C $50 = $100,000 = = carrying costs 2 2 Total relevant cost = $100,000 + $100,000 = $200,000 3. EOQ
2 DP 2 500,000 $800 C $30
= 5,164 computers 500,000 Total relevant = D P $800 = = $77,459 ordering costs Q 5,164 Q 5,164 Total relevant = carrying costs 2 C = 2 $50 = $129,100 Total relevant cost = $77,459 + 129,100 = $206,559 Thus, the EOQ quantity and total relevant costs are higher if the company ignores holding costs when evaluating managers, but only by about 3%. The square root in the EOQ model reduces the sensitivity of the ordering decision to errors in parameter estimates. 4. Since managers will choose to order 5,164 computers instead of 4,000, the cost to the company will be $6, 559 ($206,559 ‐ $200,000) higher than it would be if managers were evaluated based upon all carrying costs. Computers 4 U probably does not include the opportunity costs of carrying inventory because it is not tracked by the financial accounting system. The company could change the evaluation model to include a cost of investment in inventory. Even though this would involve an additional calculation, it would encourage managers to make optimal decisions.
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Instructor’s Solutions Manual, Cost Accounting, 6Ce
20‐30 (25 min.) Effect of EOQ ordering on supplier costs. 1. i) Set up cost = Cost per setup × annual setups Alternative A: $1,000 ×50 setups = $50,000 Alternative B: $1,000 × 250 setups = $250,000 ii) Carrying Cost = Average inventory level × carrying cost Alternative A: 10,000 ÷ 2 × $50 = $250,000 Alternative B: Assumed to be $0 (because computers are shipped on the day they are produced) iii) Total relevant cost Alternative A: $50,000 + $250,000 = $300,000 Alternative B: $250,000 + $0 = $250,000
Costs would be lower if IMBest produced computers every day. 2. Let C = carrying costs per unit Alternative A: Total cost = $50,000 + (10,000 ÷ 2) × C Alternative B: Total cost = $250,000 + $0
20–1016
Equating these costs, $50,000 + $5,000C = $250,000 $5,000C = $200,000 C = $40 If carrying costs fall below $40 per unit, IMBest would be better off producing the computers once a week.
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Chapter 20
20‐31 (30 min.) JIT purchasing, relevant benefits, relevant costs. 1. 2.
Solution Exhibit 20‐31 presents the $37,500 cash savings that would result if Margro Corporation adopted the just‐in‐time inventory system in 2013. Conditions that should exist in order for a company to successfully adopt just‐in‐ time purchasing include the following: • Top management must be committed and provide the necessary leadership support to ensure a company‐wide, coordinated effort. • A detailed system for integrating the sequential operations of the manufacturing process needs to be developed and implemented. Direct materials must arrive when needed for each subassembly so that the production process functions smoothly. • Accurate sales forecasts must be available for effective finished goods planning and production scheduling. • Products should be designed to maximize use of standardized parts to reduce manufacturing time and costs. • Reliable vendors who can deliver quality direct materials on time with minimum lead time must be obtained.
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Instructor’s Solutions Manual, Cost Accounting, 6Ce
SOLUTION EXHIBIT 20‐31 Annual Relevant Costs of Current Purchasing Policy and JIT Purchasing Policy for Margro Corporation Relevant Relevant Costs under Costs under Current JIT Purchasing Purchasing Policy Policy Required return on investment 20% per year $600,000 of average inventory per year $120,000 $ 0 20% per year $0 inventory per year Annual insurance and property tax costs 14,000 0 Warehouse rent 60,000 (13,500)a Overtime costs No overtime 0 Overtime premium 40,000 Stockout costs No stockouts 0 b $6.50 contribution margin per unit 20,000 units 130,000 Total incremental costs $194,000 $156,500 Difference in favour of JIT purchasing $37,500 a$(13,500) = Warehouse rental revenue, [(75% 12,000) $1.50]. bCalculation of unit contribution margin Selling price ($10,800,000 ÷ 900,000 units) $12.00 Variable costs per unit : Variable manufacturing cost per unit ($4,050,000 ÷ 900,000 units) $4.50 Variable marketing and distribution cost per unit ($900,000 ÷ 900,000 units) 1.00 Total variable costs per unit 5.50 Contribution margin per unit $ 6.50 Note that the incremental costs of $40,000 in overtime premiums to make the additional 15,000 units are less than the contribution margin from losing these sales equal to $97,500 ($6.50 15,000). Margro would rather incur overtime than lose 15,000 units of sales.
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Chapter 20
20‐32 (25 min.) Supply‐chain effects on total relevant inventory costs. 1.
The relevant costs of purchasing from Maji and Induk are:
Cost Category Maji Induk Purchase costs 10,000 boards × $93 per board $930,000 10,000 boards × $90 per board 900,000 Ordering costs 50 orders × $10 per order 500 50 orders × $8 per order 400 Inspection costs 10,000 boards × 5% × $5 per board 2,500 10,000 boards × 25% × $5 per board 12,500 Required annual return on investment 930 100 boards × $93 per board × 10% 100 boards × $90 per board × 10% 900 Stockout costs 100 boards × $5 per board 500 300 boards × $8 per board 2,400 Return costs 50 boards × $25 per board 1,250 500 boards × $25 per board 12,500 Other carrying costs 100 boards × $2.50 per board per year 250 100 boards × $2.50 per board per year ________ 250 $928,950 Total Cost $935,930 2. While Induk will save Cow Spot $6,980 ($935,930 − $928,950), Cow Spot may still choose to use Maji for the following reasons: a. The savings are less than 1% of the total cost of the mother boards. b. With ten times the number of returns, Induk will probably have a negative effect on Cow Spot’s reputation. c. With Induk’s higher stockouts, Cow Spot’s reputation for availability and on time delivery will be effected. d. The increased number of inspections may necessitate the hiring of additional personnel and the need for additional factory space and equipment.
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Instructor’s Solutions Manual, Cost Accounting, 6Ce
20‐33 (20 min.) Blackflush costing and JIT production. 1. (a) Purchases of direct materials (b) Incur conversion costs (c) Completion of finished goods
550000
Inventory: Materials and In‐Process Control Accounts Payable Control Conversion Costs Control Various Accounts Finished Goods Controla
550000 440000 440000 945000 525000
Inventory: Materials & In‐Process Control Conversion Costs Allocated (d) Sale of finished goods Cost of Goods Soldb Finished Goods Control a 21000 × $45 ($25 + $20) = $945000 b 20000 × $45 = $900000 2. Direct Materials
Inventory Materials and In-Process Control ( a ) 5 50 ,00 0 (c ) 525,000 Bal . 2 5,0 00
Conversion Costs
Finished Goods Control (c)
945,000 (d)
Ba l. 45,000
Conversion Costs Allocated (c ) 420,000 Conversion Costs Control (b ) 4 40 ,0 00
20–1020
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900,000
420000 900000 900000
Cost of Goods Sold (d )
9 00,000
Chapter 20
20‐34 (20 min.) Backflush, two trigger points, materials purchase and sale. 1. (a) Purchases of direct materials Inventory Control 550,000 Accounts Payable Control 550,000 (b) Incur conversion costs Conversion Costs Control 440,000 Various Accounts (such as Accounts Payable Control and Wages Payable Control) 440,000 (c) Completion of finished goods No entry (d) Sale of finished goods Cost of Goods Sold 900,000 500,000 Inventory Control Conversion Costs Allocated 400,000 (e) Underallocated Conversion Costs Allocated 400,000 or overallocated Cost of Goods Sold 40,000 conversion costs Conversion Costs Control 440,000 2. Inventory Control Direct Materials
(a) 550000
(d) 500000
Cost of Goods Sold (d) 900000
Bal.50000
Conversion Costs Allocated (e) 400000
(d) 400000
Conversion Costs
(e) 40000 Conversion Costs Control (b) 440000
(e) 440000
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20‐1021
Instructor’s Solutions Manual, Cost Accounting, 6Ce
20‐35 (20 min.) Backflush, two trigger points, completion of production and sale. 1. (a) Purchase of direct materials (b) Incur conversion costs (c) Completion of finished goods (d) Sale of finished goods (e) Underallocated or overallocated conversion costs 2.
No entry Conversion Costs Control 440,000 Various Accounts (such as Accounts Payable Control and Wages Payable Control) 440,000 Finished Goods Control 945,000 Accounts Payable Control 525,000 Conversion Costs Allocated 420,000 Cost of Goods Sold Finished Goods Control
900,000 900,000
Conversion Costs Allocated Cost of Goods Sold Conversion Costs Control
420,000 20,000 440,000
Finished Goods Control D ir ect M a t e ri a l s
(c) 945,000 (d ) 900,000
Cost of Goods Sold (d ) 9 00 ,0 00
Bal. 45,000
C o n v er s io n Costs Alloca ted (e ) 4 20 ,0 00 (c) 420,000 Co n v ers i o n Co s t s
(e ) 20 ,0 00 Co n v er si o n C osts Control (b ) 4 40 ,0 00 (e ) 440,000
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Chapter 20
20‐36 (20 min.) Lean accounting. 1.
2.
The cost object in lean accounting is the value stream, not the individual product. FSD has identified two distinct value streams: Mechanical Devices and Electronic Devices. All direct costs are traced to the value streams. However, not all plant‐ level overhead costs are allocated to the value streams when computing operating income. Value streams are only charged for the percentage of space they actually use, only 85% of the $120,000 occupancy costs are charged to the two value streams. The remaining 15%, or $18,000, is not used to compute value stream profits, nor are other plant‐level overhead costs. Operating income under lean accounting are the following (in thousands of dollars):
Sales ($700 + $500; $900 + $450) Costs Direct material purchased ($190 + $125; $250 + $90) Direct manufacturing labour ($150 + $75; $200 + $60) Equipment costs ($90 + $125; $200 + $100) Product‐line overhead ($110 + $60; $125 + $50) Occupancy costs ($120,000 × 40%) ($120,000 × 45%) Value stream operating income
Mechanical Devices $1,200
Electronic Devices $1,350
315
340
225
260
215
300
170
175 54 $ 221
48 $ 227
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20‐1023
Instructor’s Solutions Manual, Cost Accounting, 6Ce
20‐36 (cont’d) In addition to the differences discussed in Requirement 1, FSD’s lean accounting system treats all direct material costs as expenses in the period they are purchased. The following factors explain the differences between traditional operating income and lean accounting income for the two value streams: Mechanical Electronic Devices Devices Traditional operating income ($100 + $105; $45 + $140) $205 $185 Additional cost of direct materials ($315 − $300; $340 − $325) (15) (15) Decrease in allocated plant‐level overhead ($85 − $48; $105 − $54) 37 51 Value stream operating income $227 $221
20‐37 (20‐30 min.) EOQ conflicts. 1.
EOQ =
2DP C
D = 2,000; P = $48; C = $4.80 + (10% $60) = $10.80
2(2, 000)$48 133.333 tires 133 tires $10.80 DP QC where Q can be any quantity, including the EOQ TRC = Q 2
EOQ =
=
2,000 48 133.3 $10.80 $720 $720 $1, 440. 133.3 2
If students used an EOQ of 133 tires (order quantities rounded to the nearest whole number), TRC =
2,000 $48 133 $10.80 $721.80 $718.20 $1, 440.00. 133 2
Sum of annual relevant ordering and carrying costs equal $1,440. 2.
The prediction error affects C, which is now: C
= $4.80+ (10% $36) = $8.40
D = 2,000, P = $48, C = $8.40 EOQ = 20–1024
2(2, 000)$48 151.186 tires 151 tires $8.40 Copyright © 2013 Pearson Canada Inc.
Chapter 20
20‐37 (cont’d)
The cost of the prediction error can be calculated using a three‐step procedure: Step 1: Compute the monetary outcome from the best action that could have been taken, given the actual amount of the cost input. TRC =
=
DP QC Q 2 2,000 $48 151.186 $8.40 151.186 2
= $634.98 + $634.98 = $1,269.96 Step 2: Compute the monetary outcome from the best action based on the incorrect amount of the predicted cost input. TRC =
=
DP QC Q 2 2,000 $48 133.333 $8.40 133.333 2
= $720.00 + $560.00 = $1,280.00 Step 3: Compute the difference between the monetary outcomes from Step 1 and Step 2: Monetary Outcome Step 1 $1,269.96 Step 2 1,280.00 Difference $ (10.04) The cost of the prediction error is $10.04. Note: The $24 prediction error for the purchase price of the heavy‐duty tires is irrelevant in computing purchase costs under the two alternatives because the same purchase costs will be incurred whatever the order size. Some students may prefer to round off the EOQs to 133 tires and 151 tires respectively. The calculations under each step in this case follows: Step 1: TRC = Step2:
TRC =
2, 000 $48 151 8.40 $635.76 $634.20 $1, 269.96 151 2
2, 000 $48 133 $8.40 $721.80 $558.60 $1, 280.40 133 2
Step 3: Difference = $1,269.96 – $1,280.40 = $10.04
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20‐1025
Instructor’s Solutions Manual, Cost Accounting, 6Ce
20‐38 (20‐25 min.) Backflush costing. 1. (a) Purchases of raw Inventory: Raw and In‐Process Control $6,360,000 materials Accounts Payable Control $6,360,000 (b) Incur conversion Conversion Costs Control $3,696,000 costs Various Accounts $3,696,000 (c) Completion of Finished Goods Control $9,840,0001) finished goods Inventory: Raw and In‐Process Control $6,240,0002) Conversion Costs allocated 3,600,0003) (d) Sale of finished Cost of Goods Sold $9,446,4004) goods Finished Goods Control $9,446,4004) 1) 200,000 units × ($31.20 + $18) = $9,840,000 2) 200,000 units × $31.20 = $6,240,000 3) 200,000 units × $18 = $3,600,000 4) 192,000 units × ($31.20 + $18) = $9,446,400 2.
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Chapter 20
20‐39 (25 min.) Supplier evaluation and relevant costs of qualify and timely deliveries. Solution Exhibit 20‐39 presents the $1,450 annual relevant costs difference in favour of purchasing from Quality Sports. Copeland should buy the footballs from Quality Sports. SOLUTION EXHIBIT 20‐39 Annual Relevant Costs of Purchasing from Big Red and Quality Sports Relevant Costs of Purchasing From Relevant Item Big Red Quality Sports Purchasing costs $60 per unit 12,000 units per year $720,000 $61.20 per unit 12,000 units per year $734,400 Inspection costs $0.02 per unit 12,000 units 240 No inspection necessary 0 Opportunity carrying costs, required return on investment, 15% per year $60 cost per unit 100 units of average inventory per year; 900 15% per year $61.20 cost per unit 100 units of average inventory per year 918 Other carrying costs (insurance, material handling, and so on) $4 per unit 100 units of average inventory per year 400 $4.50 per unit 100 units of average inventory per year 450 Stockout costs $24 per unit 350 units per year 8,400 720 $12 per unit 60 units per year Customer returns costs $30 per unit 300 units 9,000 $30 per unit 25 units 750 Total annual relevant costs $738,940 $737,238 Annual difference in favour of Quality Sports
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$1,702
20‐1027
Instructor’s Solutions Manual, Cost Accounting, 6Ce
20‐40 (20 min.) Supply‐chain analysis, company viewpoints. 1.
2.
The major benefits to adopting a supply‐chain approach include: a. Overall reduction in inventory levels across the supply chain: • “receiving better information has allowed us to forecast and reduce inventory levels ...” • “The inventory levels are lower ... by not overstocking the warehouses” b. Fewer stockouts at the retail level. c. Reduced manufacturing of items not subsequently demanded by retailers: • “You only produce what you need” • “We have less waste by not overstocking the warehouses” d. Lower manufacturing costs due to better production scheduling and fewer expedited orders: • “We can fine tune our production scheduling” These benefits can both increase revenues (fewer stockouts) and decrease costs (lower manufacturing costs, lower holding costs, and lower distribution costs). Key obstacles to a manufacturer adopting a supply‐chain approach are: a. Communication obstacles—includes the unwillingness of some parties to share information. b. Trust obstacles—includes the concern that all parties will not meet their agreed‐ upon commitments. c. Information system obstacles—includes problems due to the information systems of different parties not being technically compatible. d. Limited resources—includes problems due to the people and financial resources given to support a supply‐chain initiative not being adequate.
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Chapter 20
20‐41 (30 min.) Backflush costing, income manipulation, governance. 1.
2.
3.
Factors SVC should consider in deciding whether to adopt a version of backflush costing include: a. Effects on decision making by managers. There is a loss of information with backflushing. Supporters of backflushing maintain, however, that non‐financial information and observation of production provide sufficient inputs to monitor production and management costs at the shop‐floor level. b. Costs of maintaining sequential tracking vis‐à‐vis backflush costing. c. Materiality of the differences. If the production lead time is short (say, less than one day) and inventory levels are minimal (as one would anticipate with JIT), the differences between sequential tracking and backflush may be minimal. d. Opportunity for managers to manipulate reported numbers. Strong’s concerns certainly warrant consideration. Much depends on the corporate culture at SVC. If the culture is that quarterly or monthly reported numbers are pivotal to evaluations, and that managers “push the accounting system to facilitate meeting the numbers,” Strong should raise these issues with Honig. Adopting an accounting system with an obvious opportunity for manipulation (backflush with sale as the trigger point) may well send managers the wrong message. Strong’s concerns, however, are not by themselves sufficient to cause SVC to not adopt backflush costing. The factors mentioned in requirement 1 may well be compelling enough to support adoption of backflush costing. Honig has alternative ways to address Strong’s quite legitimate concerns—see requirement 3. Ways to motivate managers to not “artificially change” reported income include: a. Adopting long‐term measures that reduce the importance of short‐run financial targets. b. Increasing the weight on non‐accounting‐based variables—e.g., more use of stock options or customer‐satisfaction measures. c. Penalize heavily (the “stick approach”) managers who are found out to have “artificially changed” reported income. This can include withdrawal of bonuses or even termination of employment.
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20‐1029
Instructor’s Solutions Manual, Cost Accounting, 6Ce
20‐42 (20‐30 min.) Purchase‐order size for retailer, EOQ, just‐in‐time purchasing. 1.
EOQ =
2DP C
(a) D = 7,200; P = $36; C = $1.20
EOQ =
2(7,200) ($36) 432,000 657.3 cases @658 cases $1.20
(b) D = 7,200; P = $36; C = $1.80
EOQ =
2(7, 200) ($36) 288,000 536.7 cases 537 cases $1.80
(c) D = 7,200; P = $6; C = $1.80 2.
EOQ =
2(7, 200) ($6) 48,000 219.1 cases 220 cases $1.80
A just‐in‐time purchasing policy involves the purchase of goods such that their delivery immediately precedes their demand. Given the purchase order sizes calculated in requirement 1, the number of purchase orders placed each month is (D ÷ EOQ):
D 7, 200 = 11 orders per month or 1 every 2.7 days EOQ 658 D 7, 200 (b) = 14 orders per month or 1 every 2.15 days EOQ 537 D 7, 200 = 33 orders per month or 1.1 every day (c) EOQ 220
(a)
An increase in C and a decrease in P led to increases in the optimal frequency of orders. The 24‐Hour Mart has increased the frequency of delivery from every third day (1a: P = $36; C = $1.20) to a delivery every day (1c: P = $6; C = $1.80). There is a reduction of 219 cases in the average inventory level: (658 – 220) ÷ 2 = 219.
20–1030
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Chapter 20
COLLABORATIVE LEARNING CASE
20‐43 (35–40 min.) Backflushing. 1.
2.
Glendale has successfully implemented JIT in its production operations and, as a result, minimized work‐in‐process inventory. However, it still has a fair amount of raw material and finished goods inventory. Glendale should, therefore, adopt a backflush costing system with two trigger points, as follows: a. Direct materials purchases charged to Inventory: Materials and In‐Process Control. b. Completion of finished goods recorded as Finished Goods Control. The backflush approach described closely approximates the costs computed using sequential tracking. There is no work in process so there is no need for a Work in Process inventory account. Further, by maintaining a Materials and In‐Process Inventory Control and Finished Goods Control account, Glendale can keep track of and control the inventories of direct materials and finished goods in its plant. a. Glendale should adopt a backflush costing system with trigger points at completion of finished goods and at the sale of finished goods. This would approximate the sequential tracking approach since the question assumes Glendale has no direct materials or work‐in‐process inventories. There is, therefore, no need for these inventory accounts. b. A backflush costing system with two trigger points—when purchases of direct materials are made (debited to Inventory Control), and when Finished Goods are sold—would approximate sequential tracking, since the question assumes Glendale has no work‐in‐process or finished goods inventories. c. A backflush costing system with a single trigger point when finished goods are sold would approximate sequential tracking, since the question assumes Glendale has no direct material, work‐in‐process, or finished goods inventories. This is a further simplification of the examples in the text. The principle here is that backflushing of costs should be triggered at the finished goods inventory stage if Glendale plans to hold finished goods inventory. If Glendale plans to hold no finished goods inventory, backflushing can be postponed until the finished goods are sold. In other words, the trigger points for backflushing relate to the points where inventory is being accumulated. As a result, backflushing matches the sequential tracking approach and also maintains a record for the monitoring and control of the inventory.
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Instructor’s Solutions Manual, Cost Accounting, 6Ce
20‐43 (cont’d) 3.
Some comments on the quotation follow: a. The backflush system is a standard costing system, not an actual costing system. b. If standard costing is used, an up‐to‐date, realistic set of standard costs is always desirable––as long as the set meets the cost‐benefit test of updating. c. The operating environments of “the present JIT era” have induced many companies toward more simplicity (backflush) and to abandon the typical standard costing system (sequential tracking). d. Backflush is probably closer to being a periodic system than a perpetual system. However, a periodic system may be cost‐effective, particularly where physical inventories are relatively low or stable. e. The textbook points out that, to be attractive, backflush costing should generate the same financial measurements as sequential tracking––and at a lower accounting cost. f. The choice of a product costing system is highly contextual. Its characteristics should be heavily affected by its costs, the preferences of operating managers, and the underlying operating processes. Sweeping generalizations about any cost accounting system or technique are unjustified.
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CHAPTER 21 CAPITAL BUDGETING: METHODS OF INVESTMENT ANALYSIS
21‐1 No. Capital budgeting focuses on an individual investment project throughout its life, recognizing the time value of money. The life of a project is often longer than a year. Accrual accounting focuses on a particular accounting period, often a year, with an emphasis on income determination. 21‐2 The six parts in the capital budgeting decision process are: 1. An identification stage to distinguish the types of capital expenditure projects that will accomplish strategic goals for the organization. 2. A stage to establish assumptions that are common for exploring several potential capital expenditure investments that will achieve organization objectives. 3. An information‐acquisition stage to consider the predicted costs and consequences of alternative capital investments through an analysis of the present value of future cash inflows and outflows and relevant qualitative factors. 4. A selection stage to decide on the projects to execute, timing of implementation, and performance criteria. 5. A financing stage to obtain project financing. 6. An implementation and control stage to put the projects in motion and monitor their performance throughout the investment life.
21‐3 In essence, the discounted cash‐flow method calculates the expected cash inflows and outflows of a project as if they occurred at a single point in time so that they can be aggregated (added, subtracted, etc.) in an appropriate way. This enables comparison with cash flows from other projects that might occur over different time periods.
21‐4 No. Only quantitative outcomes are formally analyzed in capital budgeting decisions. Many effects of capital budgeting decisions, however, are difficult to quantify in financial terms. These nonfinancial or qualitative factors (for example, the number of accidents in a manufacturing plant or employee morale) are important to consider in making capital budgeting decisions.
21‐5 Sensitivity analysis can be incorporated into DCF analysis by examining how the DCF of each project changes with changes in the inputs used. These could include changes in revenue assumptions, cost assumptions, tax rate assumptions, and discount rates.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
21‐6 The payback method measures the time it will take to recoup, in the form of expected future net cash inflows, the net initial investment in a project. The payback method is simple and easy to understand. It is a handy method when screening many proposals and particularly when predicted cash flows in later years are highly uncertain. The main weaknesses of the payback method are its neglect of the time value of money and of the cash flows after the payback period.
21‐7 The accrual accounting rate‐of‐return (AARR) method divides an accrual accounting measure of average annual income of a project by an accrual accounting measure of investment. The strengths of the accrual accounting rate of return method are that it is simple, easy to understand, and considers profitability. Its weaknesses are that it ignores the time value of money and does not consider the cash flows for a project.
21‐8 No. The discounted cash‐flow techniques implicitly consider depreciation in rate of return computations; the compound interest tables automatically allow for recovery of investment. The net initial investment of an asset is usually regarded as a lump‐sum outflow at time zero. Where taxes are included in the DCF analysis, depreciation costs are included in the computation of the taxable income number that is used to compute the tax payment cash flow.
21‐9 A point of agreement is that an exclusive attachment to the mechanisms of any single method examining only quantitative data is likely to result in overlooking important aspects of a decision. Two points of disagreement are (1) DCF can incorporate those strategic considerations that can be expressed in financial terms, and (2) “Practical considerations of strategy” not expressed in financial terms can be incorporated into decisions after DCF analysis. 21‐10 No. If managers are evaluated on the accrual accounting rate of return, they may not use the NPV method for capital‐budgeting decisions. Instead, managers will choose investments that maximize the accrual accounting rate of return.
21‐11 All overhead costs are not relevant in NPV analysis. Overhead costs are relevant only if the capital investment results in a change in total overhead cash flows. Overhead costs are not relevant if total overhead cash flows remain the same but the overhead allocated to the particular capital investment changes.
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Chapter 21
21‐12 Capital investment projects typically have five major categories of cash flows: 1. Initial investment in machine and working capital: outflows made for purchasing plant, equipment, and machines that occur in the early periods of the project’s life and include cash outflows for transporting and installing the item. Investments in plant, equipment, machines and sales promotions for product lines are invariably accompanied by incremental investments in working capital. These investments take the form of current assets, such as receivables and inventories, minus current liabilities, such as accounts payable. Working capital investments are similar to machine investments. In each case, available cash is tied up. 2. Cash flow from current disposal of the old machine: any cash received from disposal of the old machine is a relevant cash inflow. 3. Recurring operating cash flows: these inflows may result from producing and selling additional goods or services or from operating cost savings. 4. Cash flow from terminal disposal of machine and recovery of working capital: the disposal of the investment at the date of termination of a project generally increases cash inflow in the year of disposal. The initial investment in working capital is usually fully recouped when the project is terminated. At that time, inventories and receivables necessary to support the project are no longer needed. 5. Income tax impacts on cash flows: to be discussed in Chapter 22. 21‐13 Four critical success factors that managers focus on when controlling job projects are (a) scope, (b) quality, (c) time schedule, and (d) costs.
21‐14 The Division Y manager should consider why the Division X project was accepted and the Division Y project rejected by the president. Possible explanations are: a. The president considers qualitative factors not incorporated into the IRR computation and this leads to the acceptance of the X project and rejection of the Y project. b. The president believes that Division Y has a history of overstating cash inflows and understating cash outflows. c. The president has a preference for the manager of Division X over the manager of Division Y—this is a corporate politics issue. Factor a. means qualitative factors should be emphasized more in proposals. Factor b. means Division Y needs to document whether its past projections have been relatively accurate. Factor c. means the manager of Division Y has to play the corporate politics game better.
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EXERCISES
21‐15 (10 min.)
Terminology.
The goal of capital budgeting is to provide capacity in a planned and orderly manner that will match the predicted demand growth of the company and achieve a targeted rate of return (ROR) on these investments. The determination of the ROR links closely to the operating income or profit on sales (chapter 12). That is why investments (investment programs, projects) affect the balance sheet, the income statement and the statement of cash flow. Capital budgeting requires a careful analysis the amount and timing of cash outflows and cash inflows. There are four methods from which a management team can choose, net present value (NPV), internal rate of return(IRR), payback, and accrual accounting rate of return (or return on investment (ROI)) . The first two methods require the calculation of discounted cash flow. The NPV method requires that the management team determine what its required rate of return must be (also called the discount rate, hurdle rate or opportunity cost of capital). This discount rate is the return the team could expect from investing in a different project of similar risk. In contrast the IRR (sometimes called the adjusted rate of return) is fully determined by cash inflow and outflow. It is the rate at which the discounted net cash flow is zero. The payback method is based on nominal, not discounted cash flow. It is simply the total investment divided by cash inflow to determine the time it takes to recover the cost of the investment. The AARR is calculated by dividing the increase in an accrual , expected average operating income, by the cost of the initial investment.
21‐16 Exercises in compound interest, no income taxes. The answers to these exercises are printed after the last problem, at the end of the chapter.
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Chapter 21
21‐17 (22–25 min.) Capital budget methods, no income taxes. 1a. 1b. 1c.
The table for the present value of annuities (Appendix A, Table 4) shows: 5 periods at 12% = 3.605 Net present value = $60,000 (3.605) – $160,000
Payback period
= $216,300 – $160,000 = $56,300 = $160,000 ÷ $60,000 = 2.67 years
Internal rate of return: $160,000 = Present value of annuity of $60,000 at R% for 5 years, or what factor (F) in the table of present values of an annuity (Appendix A, Table 4) will satisfy the following equation. $160,000 = $60,000F $160,000 = 2.667 F = $60,000
On the 5‐year line in the table for the present value of annuities (Appendix A, Table 4), find the column closest to 2.667; it is between a rate of return of 24% and 26%. Interpolation is necessary: Present Value Factors 24% 2.745 2.745 IRR rate –– 2.667 –– 26% 2.635 Difference 0.110 0.078 0.078 Internal rate of return = 24% + (2%) 0.110 = 24% + (0.7091) (2%) = 25.42%
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
21‐17 (cont’d) 1d.
Accrual accounting rate of return based on net initial investment: Net initial investment = $160,000 Estimated useful life = 5 years Annual straight‐line depreciation = $160,000 ÷ 5 = $32,000 Accrual accounting = Increase in expected average annual operating income rate of return Net initial investment $60,000 $32,000 $28,000 = = = 17.5% $160,000 $160,000
Note how the accrual accounting rate of return, whichever way calculated, can produce results that differ markedly from the internal rate of return. 2.
Other than the NPV, rate of return and the payback period on the new computer system, factors that Guelph should consider are: Issues related to the financing the project, and the availability of capital to pay for the system. The effect of the system on employee morale, particularly those displaced by the system. Salesperson expertise and real‐time help from experienced employees is key to the success of a hardware store. The benefits of the new system for customers (faster checkout, fewer errors). The upheaval of installing a new computer system. Its useful life is estimated to be 5 years. This means that Guelph could face this upheaval again in 5 years. Also ensure that the costs of training and other “hidden” start‐up costs are included in the estimated $160,000 cost of the new computer system.
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21‐18 (15 min.) 1.
Chapter 21
New assets: comparison of approaches in capital budgeting.
Payback period in years: Buy 2 Small Machines: $200,000 / ($70,000 – $10,000) = 3.33 years Buy 1 Large Machine: $250,000 / ($70,000 – $15,000) = 4.54 years
2. Present value and 3. Net present value Buy 2 small machines Buy 1 large machine Present value of annuities 4 periods at 5% = 3.5460 5 periods at 5% =4.3295 (Appendix A, Table 4) Present value = ($70,000 – $10,000) x 3.5460 = ($70,000 – $15,000) x 4.3295 = $212,760 = $238,120 Net Present value = $200,000 – $212,760 = $250,000 – $238,120 = $12,760 = ($11,880) 4. The IRR of buying 2 small machines is more than 5% because the NPV is positive. But the IRR of buying 1 large machine is less than 5% because the NPV is negative. 5. Only the project of buying 2 small machines can be accepted given the projected cash flows.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
21‐19 (20 min.) 1.
New equipment purchase.
The cash inflow per year is $31,250. a. Solution Exhibit 21‐19a shows the NPV computation. NPV= $32,656 An alternative approach: Present value of 5‐year annuity of $31,250 at 12% $31,250 3.605 $ 112,656 Present value of cash outlays, $80,000 1.000 80,000 Net present value $ 32,656
EXHIBIT 21‐19a
Present Value Discount Factors At 12%
Total Present Value
1a. Initial equipment investment $(80,000) 1.000 1b. Initial working capital investment 0 1.000 2a. Annual cash flow from operations (excl. depr.)
Sketch of Relevant Cash Flows 0 1 2 3
4
5
$(80,000) $0 $31,25 0
Year 1 Year 2 Year 3
27,906 24,906 22,250
0.893 0.797 0.712
Year 4 Year 5 3 a. Terminal disposal of equipment 3 b. Recovery of working capital Net present value if new equipment is purchased
19,875 17,719
0.636 0.567
0
0.567
$0
0 $ 32,656
0.567
$0
$31,250 $31,250 $31,25 0 $31,250
b. c.
Payback = $80,000 ÷ $31,250 = 2.56 years Let F = Present value factor for an annuity of $1 for 5 years in Appendix B, Table 4
F = $80,000 ÷ $31,250 = 2.56
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Chapter 21
21‐19 (cont’d) The internal rate of return can be calculated by interpolation: 26% IRR 28% Difference
Present Value Factors for Annuity of $1 for 5 years 2.635 2.635 2.560 2.532 0.103 0.075
0.075 Internal rate of return = 26% + (2%) = 27.46%. 0.103 2.
3.
Both the net present value and internal rate of return methods use the discounted cash flow approach in which all expected future cash inflows and outflows of a project are measured as if they occurred at a single point in time. The net present value approach computes the surplus generated by the project in today’s dollars, while the internal rate of return attempts to measure its effective return on investment earned by the project. The payback method, by contrast, considers nominal cash flows (without discounting) and measures the time at which the project’s expected future cash inflows recoup the net initial investment in a project. The payback method thus ignores the profitability of the project’s entire stream of future cash flows. The adjustment in discount rate made by the controller in headquarters will only change the net present value, while IRR and payback period will remain the same. Present value of 5‐year annuity of $31,250 at 20% $31,250 2.991 Present value of cash outlays, $80,000 1.000 Net present value
$ 93,469 80,000 $ 13,469
The project will be approved by Innovation Inc. because its NPV is positive at a 20% required rate of return. The same conclusion can be achieved if the required rate of return (20%) is compared with the internal rate of return of the project (27.46%)
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21‐20 (25 min.) Capital budgeting with uneven cash flows, no income taxes. 1. Present value of savings in cash operating costs: $10,000 × 0.862 $ 8,620 8,000 × 0.743 5,944 6,000 × 0.641 3,846 5,000 × 0.552 2,760 Present value of savings in cash operating costs 21,170 Net initial investment (23,000) Net present value $( 1,830) 2. Payback period: Cumulative Initial Investment Yet to Be Year Cash Savings Cash Savings Recovered at End of Year 0 – – $23,000 1 $10,000 $10,000 13,000 2 8,000 18,000 5,000 3 6,000 24,000 – $5,000 Payback period = 2 years + = 2.83 years $6,000 3. From requirement 1, the net present value is negative with a 16% required rate of return. Therefore, the internal rate of return must be less than 16%. Year (1) 1 2 3 4
P.V. Cash Factor Savings at 14% (2) (3) $10,000 0.877 8,000 0.769 6,000 0.675 5,000 0.592
P.V. at 14% (4) = (2) × (3) $ 8,770 6,152 4,050 2,960 $21,932
P.V. Factor at 12% (5) 0.893 0.797 0.712 0.636
P.V. at 12% (6) = (2) × (5) $ 8,930 6,376 4,272 3,180 $22,758
P.V. Factor at 10% (7) 0.909 0.826 0.751 0.683
Net present value at 14% = $21,932 – $23,000 = $(1,068) Net present value at 12% = $22,758 – $23,000 = $(242) Net present value at 10% = $23,619 – $23,000 = $619
=
= 10% + (0.719) (2%) = 11.44%
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10% +
619 (2%) 619 242
Internal rate of return
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P.V. at 10% (8) = (2) × (7) $ 9,090 6,608 4,506 3,415 $23,619
Chapter 21
21‐20 (cont’d) 4. Accrual accounting rate of return based on net initial investment: $29,000 Average annual savings in cash operating costs = = $7,250 4 years $23,000 Annual straight‐line depreciation = = $5,750 4 years $7,250 $5,750 Accrual accounting rate of return = $23,000 $1,500 = 6.52% = $23,000
21‐21 (30 min.) Comparison of projects, no income taxes. 1. Total Present Value Plan I $ (375,000) (3,526,725) $(3,901,725) Plan II $(1,500,000) (1,339,500) (1,195,500) $(4,035,000) Plan III $ (150,000) (1,339,500) (1,195,500) (1,068,000) $(3,753,000)
Present Value Discount Factors at 12%
Year
0
1
2
$(4,425,000)
3
1.000 0.797
$ (375,000)
1.000 0.893 0.797
$(1,500,000) $(1,500,000) $(1,500,000)
1.000 0.893 0.797 0.712
$ (150,000) $(1,500,000) $(1,500,000) $(1,500,000)
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21‐21 (cont’d) 2. Plan III has the lowest net present value cost. Plan III is the preferred one on financial criteria. 3. Factors to consider, in addition to NPV, are: a. Financial factors including: Competing demands for cash. Availability of financing for project. b. Nonfinancial factors including: Risk of building contractor not remaining solvent. Plan II exposes New Bio most if the contractor becomes bankrupt before completion because it requires more of the cash to be paid earlier. Ability to have leverage over the contractor if quality problems arise or delays in construction occur. Plans I and III give New Bio more negotiation strength by being able to withhold sizable payment amounts if, say, quality problems arise in Year 1. Investment alternatives available. If New Bio has capital constraints, the new building project will have to compete with other projects for the limited capital available.
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Chapter 21
21‐22 (30 min.) Payback and NPV methods, no income taxes. 1a. Payback measures the time it will take to recoup, in the form of expected future cash flows, the net initial investment in a project. Payback emphasizes the early recovery of cash as a key aspect of project ranking. Some managers argue that this emphasis on early recovery of cash is appropriate if there is a high level of uncertainty about future cash flows. Projects with shorter paybacks give the organization more flexibility because funds for other projects become available sooner. Strengths Easy to understand One way to capture uncertainty about expected cash flows in later years of a project (although sensitivity analysis is a more systematic way) Weaknesses Fails to incorporate the time value of money Does not consider a project’s cash flows after the payback period 1b. Project A Outflow, $3,000,000 Inflow, $1,000,000 (Year 1) + $1,000,000 (Year 2) + $1,000,000 (Year 3) + $1,000,000 (Year 4) Payback = 3 years Project B Outflow, $1,500,000 Inflow, $400,000 (Year 1) + $900,000 (Year 2) + $800,000 (Year 3) ($1,500,000 $400,000 $900,000) = 2.25 years Payback = 2 years + $800,000
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21‐22 (cont’d) Project C Outflow, $4,000,000 Inflow, $2,000,000 (Year 1) + $2,000,000 (Year 2) + $200,000 (Year 3) + $100,000 (Year 4) Payback = 2 years Payback Period 1. Project C 2 years 2. Project B 2.25 years 3. Project A 3 years If payback period is the deciding factor, Andrews will choose Project C (payback period = 2 years; investment = $4,000,000) and Project B (payback period = 2.25 years; investment = $1,500,000), for a total capital investment of $5,500,000. Assuming that each of the projects is an all‐or‐nothing investment, Andrews will have $500,000 left over in the capital budget, not enough to make the $3,000,000 investment in Project A. 2. Solution Exhibit 21‐22 shows the following ranking: NPV 1. Project B $ 207,800 2. Project A $ 169,000 3. Project C $(311,500) 3. Using NPV rankings, Projects B and A, which require a total investment of $3,000,000 + $1,500,000 = $4,500,000, which is less than the $6,000,000 capital budget, should be funded. This does not match the rankings based on payback period because Projects B and A have substantial cash flows after the payback period, cash flows that the payback period ignores. Nonfinancial qualitative factors should also be considered. For example, are there differential worker safety issues across the projects? Are there differences in the extent of learning that can benefit other projects? Are there differences in the customer relationships established with different projects that can benefit Andrews Construction in future projects?
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Chapter 21
SOLUTION EXHIBIT 21‐22
Total Present Value
Present Value Discount Factors at 10%
PROJECT A Net initial invest. Annual cash inflow Net present value PROJECT B Net initial invest. Annual cash inflow Net present value PROJECT C Net initial invest. Annual cash inflow Net present value
$(3,000,000) 909,000 826,000 751,000 683,000 $ 169,000 $(1,500,000) 363,600 743,400 600,800 $ 207,800 $(4,000,000) 1,818,000 1,652,000 150,200 68,300 $ (311,500)
0
1.000 0.909 0.826 0.751 0.683 1.000 0.909 0.826 0.751 1.000 0.909 0.826 0.751 0.683
$(3,000,000) $(1,500,000) $(4,000,000)
Sketch of Relevant Cash Flows 1 2 3 $1,000,000 $1,000,000 $1,000,000 $ 400,000 $ 900,000 $ 800,000 $2,000,000 $2,000,000 $ 200,000
4 $1,000,000 $ 100,000
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21‐23 (22–30 min.) DCF, accrual accounting rate of return, working capital, evaluation of performance, no income taxes. 1. Present value of annuity of savings in cash operating costs ($31,250 per year for 8 years at 14%): $31,250 4.639 Present value of $37,500 terminal disposal price of machine at end of year 8: $37,500 0.351 Present value of $10,000 recovery of working capital at end of year 8: $10,000 0.351 Gross present value Deduct net initial investment: Centrifuge machine, initial investment $137,500 Additional working capital investment 10,000 Net present value 2. Use a trial‐and‐error approach. First, try a 16% discount rate: $135,750 $31,250 4.344 ($37,500 + $10,000) 0.305 14,488 Gross present value 150,238 Deduct net initial investment (147,500) Net present value $ 2,738 Second, try an 18% discount rate: $127,438 $31,250 4.078 12,635 ($37,500 + $10,000) .266 Gross present value 140,073 Deduct net initial investment (147,500) Net present value $ (7,427) By interpolation: $2,738 Internal rate of return = 16% + × 2% $2,738 $7, 427
21–1048
= 16% + (0.2693 2%) = 16.54%
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$144,969 13,163 3,510 161,642
147,500 $ 14,142
Chapter 21
21‐23 (cont’d) 3. Accrual accounting rate of return based on net initial investment: Net initial investment = $137,500 + $10,000 = $147,500 Annual depreciation ($137,500 – $37,500) ÷ 8 years = $12,500 $31,250 $12,500 Accrual accounting rate of return = = 12.71%. $147,500 4. If your decision is based on the DCF model, the purchase would be made because the net present value is positive, and the 16.54% internal rate of return exceeds the 14% required rate of return. However, you may believe that your performance may actually be measured using accrual accounting. This approach would show a 12.71% return on the initial investment, which is below the required rate. Your reluctance to make a “buy” decision would be quite natural unless you are assured of reasonable consistency between the decision model and the performance evaluation method. 21‐24 (20‐30 min.) Net present value, internal rate of return, sensitivity analysis. 1. b.
a. The table for the present value of annuities (Appendix A, Table 4) shows: 5 periods at 12% = 3.6048 Net present value
= =
$8,000 (3.605) – $25,000 $28,840 – $25,000 = $3,840
Internal rate of return: $25,000 = Present value of annuity of $8,000 at X% for 5 years, or what factor (F) in the table of present values of an annuity (Appendix A, Table 4) will satisfy the following equation. $25,000 = $8,000F F
$25,000 = 3.125 $8,000
On the five‐year line in the table for the present value of annuities (Appendix A, Table 4), find the column closest to 3.125; 3.125 is between a rate of return of 18% and 20%.
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21‐24 (cont’d) Interpolation is necessary: Present Value Factors 18% 3.127 IRR rate 20% 2.991 Difference Internal rate of return 2.
3.127 — — 0.136
3.125 0.002
0.002 = 18% + (2%) 0.136 = 18% + (0.015) (2%) = 18.03%
Let the minimum annual cash savings be $X. Then we want $X (3.605) = $25,000 $25,000 X = $6,935 3.605
Muskoka Landscaping would want annual cash savings of at least $6,935 for the net present value of the investment to equal zero. This amount of cash savings would justify the investment in financial terms. 3. When the manager is uncertain about future cash flows, the manager would want to do sensitivity analysis, a form of which is described in requirement 2. Calculating the minimum cash flows necessary to make the project desirable gives the manager a feel for whether the investment is worthwhile or not. If the manager were quite certain about the future cash‐operating cost savings, the approaches in requirement 1 would be preferred.
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Chapter 21
21‐25 (21‐30 min.) DCF, accrual accounting rate of return, working capital, evaluation of performance. 1. a. Present value of annuity of savings in cash operating costs ($15,000 per year for 8 years at 14%): $15,000 4.6389 Present value of $12,000 terminal disposal price of machine at 14% and at end of year 8: $12,000 0.3506 Present value of $5,000 recovery of working capital at 14% and at end of year 8: $5,000 0.3506 Gross present value Deduct net initial investment: Special‐purpose machine, initial investment $60,000 Additional working capital investment 5,000 Net present value 1 b. Use a trial and error approach. First, try a 20% discount rate: $15,000 3.837 $57,555 ($12,000 + $5,000) 0.2326 3,954 Gross present value 61,509 Deduce net initial investment (65,000) Net present value $ (3,491) Second, try an 18% discount rate: $15,000 4.078 $61,170 ($12,000 + $5,000) 0.266 4,522 Gross present value 65,692 Deduct net initial investment (65,000) Net present value $ 692 By interpolation: Internal rate of return $692 = 18% + (2%) $692 $3,491 = 18% + (0.165) (2%) = 18.33%
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$69,583 4,207 1,753 75,543
65,000 $ 10,543
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21‐25 (cont’d) 2. Accrual accounting rate of return based on net initial investment: Net initial investment = $60,000 + $5,000 = $65,000 Annual amortization [$65,000 – ($12,000 + 5,000)] ÷ 8 years = $6,000
$15,000 $6,000 Accrual accounting rate of return = 13.85% $65,000
3. If your decision is based on the DCF model, the purchase would be made because the net present value is positive, and the 18.33% internal rate of return exceeds the 14% required rate of return. However, you may believe that your performance may actually be measured using accrual accounting. This approach would show a 13.85% return on the initial investment, which is slightly below the required 14% rate. Your reluctance to make a “buy” decision may be natural, unless you are assured of reasonable consistency between the decision model and the performance evaluation method. 21‐26 (30 min.) Equipment replacement, net present value, relevant costs, payback. 1. The cash outflows and inflows for the two alternatives are: Keep Old 53ʹ Truck Buy New 53ʹ Truck Year Cash Outflows Cash Inflows Cash Outflows Cash Inflows 0 $ 0 $ 0 $67,200 $31,200 1 42,000 0 30,000 0 2 42,000 0 30,000 0 3 42,000 0 30,000 0 4 48,000 7,200 30,000 9,600
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Chapter 21
21‐26 (cont’d) Computations for the net present value of each alternative are: PV Keep Old 53ʹ Truck Buy New 53ʹ Truck Discount PV of Net PV of Net Factor at Net Cash Cash Net Cash Cash 12% Year Outflows Outflows Outflows Outflows 0 1.000 $ 0 $ 0 $36,000 $36,000 1 0.893 42,000 37,506 30,000 26,790 2 0.797 42,000 33,474 30,000 23,910 3 0.712 42,000 29,904 30,000 21,360 4 0.636 40,800 25,949 20,400 12,974 $126,833 $121,034 Edgeley Inc. should purchase the new 53ʹ truck. The net present value difference in favour of purchase is $5,799 ($126,833 – $121,034). The amortization on either of the trucks is irrelevant. Another approach to determine the NPV of buying a new 53ʹ truck follows. This End of Year approach considers only the differential cash flows of purchasing the new truck. 1. Initial investment in new tru ck $(67,200) 1.000 $(67,200) d isposal Present 2. Current Value price of old truck 31,200 1.000 $31,200 3. Savings in 10,716 0.893 $12,000 Total of $1 Sketch of Relevant Cash Flows recurring 9,564 0.797 $12,000 Present Discounted 0 1 2 $12,0003 4 5 operating cash 8,544 0.712 Value at 12% 0.636 $20,400 flows 12,974 $5,798 End of Year 2. The net initial investment for the new truck is $36,000. The difference in cash outflows between the two alternatives is: Cash Investment Difference in Cumulative Yet to Be Recovered Year Cash Savings Cash Savings at End of Year 0 — — $36,000 1 $12,000 $12,000 24,000 2 12,000 24,000 12,000 3 12,000 36,000 — 4 20,400 56,400 — Payback period = 3 years
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21‐27 (20‐30 min.) NPV and customer profitability. 1.
The operating income per customer in each year is calculated as follows:
Year 1 Sales Net margin 10% Other identifiable costs Operating income of each customer
High Low Volume Volume $5,000 $18,000 $ 500 $ 1,800 $ 0 ($ 1,143) $ 500 $ 657
High Year 2 and beyond Low Volume Volume Sales $5,000 $18,000 Net margin 10% $ 500 $ 1,800 Other identifiable costs $ 0 $ 1,143 Operating income of each customer $ 500 $ 657 2. To determine the value of each kind of customer an assumption is needed: required rate of return. If the average net margin is 10%, then it is reasonable to assume that minimum is required. However, to provide for contingencies, it is normal that the required rate of return is slightly higher than the average return, so in this case it is also reasonable to assume a discount rate of 12%.
Low‐Volume Customer Present Total Value Cash Present Discount Flow Value Factors s At 10% Initial Investment $ 0.00 1.000 $ 0 Cash inflows (at year end): Year 1 $454.50 0.909 $500 Year 2 $413.00 0.826 $500 Year 3 $375.50 0.751 $500 Year 4 $341.50 0.683 $500 Year 5 Year 6 Year 7 Net present value $1,584.50
High‐Volume Customer Present Total Value Cash Present Discount Flows Value Factors At 10% ($8,000) 1.000 ($8,000) $1,636.20 0.909 $1,800 $1,486.80 0.826 $1,800 $1,351.80 0.751 $1,800 $1,229.40 0.683 $1,800 $1,117.80 0.621 $1,800 $1,015.20 0.564 $1,800 $ 923.40 0.513 $1,800 $ 760.60
3. From the NPV calculations in 2. it is clear that low‐volume customers are more profitable. However, if the initial investment of high‐volume customers can be slightly reduced, they will be more profitable.
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Chapter 21
PROBLEMS
21‐28 (30 min.)
Comparison of projects, no income taxes.
1. Total Present Value
Present Value Discount Factors at 10%
Year 0
1
2
3
Plan I $(240,000) 1.000 $(240,000) (2,973,600) 0.826 $(3,600,000) $(3,213,600) Plan II $(1,200,000) 1.000 $(1,200,000) (1,090,800) 0.909 $(1,200,000) (991,200) 0.826 $(1,200,000) $(3,282,000) Plan III $(120,000) 1.000 $(120,000) (1,090,800) 0.909 $(1,200,000) (991,200) 0.826 $(1,200,000) (901,200) 0.751 $(1,200,000) $(3,103,200) 2. Plan III has the lowest net present cost. Subject to financing being available, Plan III is the preferred one on financial criteria. 3. Factors to consider, in addition to NPV, are: a. Financial factors including: • Competing demands for cash. • Availability of financing for project. b. Nonfinancial factors including: • Risk of building contractor not remaining solvent. Plan II exposes Fox Valley most if Vukacek becomes bankrupt before completion. • Ability to have leverage over Vukacek if quality problems arise or delays in construction occur. Plans I and III give Fox more negotiation strength by being able to withhold sizable amounts if, say, quality problems arise in Year 1. • Investment alternatives available. If Fox Valley has capital constraints, the new building project will have to compete with other projects for the limited capital available.
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21‐29 (20 min.) DCF, sensitivity analysis, no income taxes. 1. Revenues, $25 × 1,000,000 $25,000,000 Variable cash costs, $10 × 1,000,000 10,000,000 Cash contribution margin 15,000,000 Fixed cash costs 5,000,000 Cash inflow from operations $10,000,000 Net present value: Cash inflow from operations: $10,000,000 × 3.433 $34,330,000 Cash outflow for initial investment (30,000,000) Net present value $ 4,330,000 2a. 5% reduction in selling prices: Revenues, $23.75 × 1,000,000 $23,750,000 Variable cash costs, $10 × 1,000,000 10,000,000 Cash contribution margin 13,750,000 Fixed cash costs 5,000,000 Cash inflow from operations $ 8,750,000 Net present value: Cash inflow from operations: $8,750,000 × 3.433 $30,038,750 Cash outflow for initial investment (30,000,000) Net present value $ 38,750 b. 5% increase in the variable cost per unit: Revenues, $25 × 1,000,000 $25,000,000 Variable cash costs, $10.50 × 1,000,000 10,500,000 Cash contribution margin 14,500,000 Fixed cash costs 5,000,000 Cash inflow from operations $ 9,500,000 Net present value: Cash inflow from operations: $9,500,000 × 3.433 $32,613,500 Cash outflow for initial investment (30,000,000) Net present value $ 2,613,500 3. Sensitivity analysis enables management to see those assumptions for which input variations have sizable impact on NPV. Extra resources could be devoted to getting more informed estimates of those inputs with the greatest impact on NPV. Sensitivity analysis also enables management to have contingency plans in place if assumptions are not met. For example, if a 5% reduction in selling price is viewed as occurring with 0.40 probability, management may wish to line up bank loan facilities.
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Chapter 21
21‐30 (45 min.) NPV, IRR and sensitivity analysis. 1.
Net present value of project: Cash inflows Cash outflows Net cash flows
Period 0 $(42,000) $(42,000)
Periods 1 ‐ 10 $23,000 (16,000)
Annual net cash inflows Present value factor for annuity, 10 periods, 6% Present value of net cash inflows Initial investment Net present value
$ 7,000 × 7.36 $51,520 (42,000) $ 9,520
To find IRR, first divide the initial investment by the net annual cash inflow: $42,000 ÷ $7,000 = 6.0. The 6.0 represents the present value factor for a ten‐period project with the given cash flows, so look in Table 4, Appendix B for the present value of an annuity in arrears to find the factor closest to 6.0 along the ten period row. You should find that it is between 10% and 12%. The internal rate of return can be calculated by interpolation: Present Value Factors for Annuity of $1 for 10 years 10% 6.145 6.145 IRR 6.000 12% 5.650 __ 0.145 Difference 0.495 0.145 Internal rate of return = 10% + (2%) = 10.6%. 0.495 Note: You can use a calculator or excel to find the IRR, and you will get an answer of approximately 10.56%.
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21‐30 (cont’d) 2.
If revenues are 10% higher, the new net present value will be: Period 0 Periods 1 ‐ 10 Cash inflows $25,300 Cash outflows $(42,000) (16,000) $ 9,300 Net cash inflows $(42,000)
Annual net cash inflows Present value factor for annuity, 10 periods, 6% Present value of net cash inflows Initial investment Net present value
$ 9,300 × 7.36 $68,448 (42,000) $26,448
And the IRR will be: $42,000 ÷ $9,300 = present value factor of 4.516, yielding a return of 17.87% via interpolation (see below), or using a calculator, a return of 17.86%. Present Value Factors for Annuity of $1 for 10 years 16% 4.833 4.833 IRR 4.516 18% 4.494 __ Difference 0.339 0.317 0.317 Internal rate of return = 16% + (2%) = 17.87%. 0.339 If revenues are 10% lower, the new net present value will be: Period 0 Periods 1 – 10 Cash inflows $20,700 Cash outflows $(42,000) (16,000) Net cash inflows $(42,000) $ 4,700 Annual net cash inflows $ 4,700 Present value factor for annuity, 10 periods, 6% × 7.36 Present value of net cash inflows $ 34,592 Initial investment (42,000) Net present value $ (7,408)
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Chapter 21
21‐30 (cont’d) And the IRR will be: $42,000 ÷ $4,700 = present value factor of 8.936, yielding a return of 2.11% using interpolation (see calculations below) or, using a calculator, a return of 2.099%. Present Value Factors for Annuity of $1 for 10 years 2% 8.983 8.983 IRR 8.936 __ 4% 8.111 Difference 0.872 0.047 0.047 Internal rate of return = 2% + (2%) = 2.11%. 0.872 3. If both revenues and costs are higher, the new net present value will be: Period 0 Periods 1 –10 Cash inflows $25,300 Cash outflows $(42,000) (17,120) Net cash inflows $(42,000) $ 8,180 Annual net cash inflows $ 8,180 Present value factor for annuity, 10 periods, 6% × 7.36 Present value of net cash inflows $60,205 Initial investment (42,000) Net present value $18,205 And the IRR will be: $42,000 ÷ $8,180 = present value factor of 5.134, yielding a return of 14.43% via interpolation, or using a calculator, a return of 14.406%. Present Value Factors for Annuity of $1 for 10 years 14% 5.216 5.216 IRR 5.134 __ 16% 4.833 0.082 Difference 0.383 0.082 Internal rate of return = 14% + (2%) = 14.43%. 0.383
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21‐30 (cont’d) If both revenues and costs are lower, the new net present value will be: Period 0 Periods 1 ‐ 10 Cash inflows $20,700 Cash outflows $(42,000) (14,400) Net cash inflows $(42,000) $ 6,300 Annual net cash inflows $ 6,300 Present value factor for annuity, 10 periods, 6% × 7.36 Present value of net cash inflows $46,368 Initial investment (42,000) $ 4,368 Net present value To compute the IRR, note that the present value factor is $42,000 ÷ $6,300 = present value factor of 6.667, yielding a return of 8.15% from interpolation or, using a calculator, a return of 8.144%. Present Value Factors for Annuity of $1 for 10 years 8% 6.710 6.710 IRR 6.667 10% 6.145 __ Difference 0.565 0.043 0.043 Internal rate of return = 8% + (2%) = 8.15%. 0.565 4. To find the NPV with a different rate of return, use the same cash flows but with a different discount rate, this time for ten periods at 8%. Annual net cash inflows $ 7,000 Present value factor for annuity, 10 periods, 8% × 6.71 Present value of net cash inflows $46,970 Initial investment (42,000) Net present value $ 4,970 The NPV is positive, so they should accept this project. Of course, this result is to be expected since in requirement 1, the IRR was determined to be 10.6%. Therefore, for any discount rate less than 10.6%, the NPV of the stream of cash flows will be positive.
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21‐31 (30 min.)
Chapter 21
Relevant costs, outsourcing, capital budgeting.
1. Relevant operating cash outflows and operating cash savings each year if Part No. 789 is outsourced: 2014 to 2013 2017 Operating cash outflows for purchasing Part No. 789 $(60,000) $(60,000) Relevant operating cash savings from outsourcing Part No. 789: Direct materials 26,400 26,400 Direct manufacturing labour 13,200 13,200 Variable overhead 8,400 8,400 Product and process engineering — 4,800 Rent 1,200 1,200 Total relevant operating cash savings 49,200 54,000 Net relevant operating cash outflows if Part No. 789 is purchased from Gabriella $ (10,800) ($6,000) NPV of cash inflows and outflows if Part No. 789 is purchased from outside (in thousands): Present 2012 2013 2014 2015 2016 2017 Total Value of $1 Sketch of Relevant Cash Flows Present Discounted Value at 12% End of Year 1. Disposal price of machine$18.000
1.000
2. Recurring operating cash flows Net present value
0.893 0.797 0.712 0.636 0.567
$(9.644) (4.782) (4.272) (3.816) (3.402) $(7.916)
$18 $(10.80) $(6)
$(6)
$(6)
$(6)
The decision to purchase Part No. 789 from Gabriella has a negative NPV of $7,916. Strubel should continue to make Part No. 789 in‐house based on quantitative, financial considerations.
Note the following: (a) Equipment amortization is a noncash cost and hence irrelevant for the NPV analysis. (b) Product and process engineering is irrelevant for 2012, since $4,800 in costs will be incurred in 2012 whether Part No. 789 is outsourced or manufactured in‐house. But product and process engineering is relevant from 2013 to 2016. These cash costs will be saved if Strubel decides to outsource Part No. 789.
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21‐31 (cont’d) (c) The allocated rent costs of $2,400 are irrelevant for NPV analysis, but the $1,200 rent saved for outside storage if Strubel outsources Part No. 789 is a relevant cash saving under the “outsourcing” alternative. (d) Allocation of general plant overhead costs of $6,000 is irrelevant since these costs will not change in total whether Part No. 789 is outsourced or manufactured in‐house. 2. Sensitivity analysis with respect to the quantity of Part No. 789 required seems desirable. • If demand for Part No. 789 decreases, Gabriella is willing to supply a lower quantity at the same price of $60 per part. If Strubel continued to manufacture Part No. 789, the costs it would incur may not decrease quite as fast with lower quantities of production because of fixed costs. Furthermore, the net cash outflows of outsourcing calculated in requirement 1 will be smaller if lower quantities of Part No. 789 are demanded. For example, if only 900 units per year are required, the net relevant cash outflows if Part No. 789 is purchased from Gabriella will be less by $6,000 in years 2 through 5. Note that cash inflow from selling the machine is still $18,000. This would make outsourcing Part No. 789 more attractive. • If, on the other hand, Strubel’s demand for Part No. 789 increases, Strubel will continue to prefer manufacturing the part in‐house. 3. Other nonfinancial and qualitative factors that Lin should consider before making a decision are: (a) Whether Gabriella will deliver Part No. 789 according to the agreed‐upon delivery schedule. (b) Whether Gabriella will produce Part No. 789 according to the desired quality standards. (c) Whether Gabriella will be in a position to accommodate modifications in Part No. 789 if Strubel’s requirements change. (d) Whether Gabriella will continue in business for the next five years and continue to make Part No. 789 based on Strubel’s demands.
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Chapter 21
21‐31 (cont’d) 4. Compute the effects of relevant items on operating income under the alternatives of outsourcing versus making Part No. 789 in‐house. Increase (Decrease) in Strubel’s Operating Income in 2012 (in thousands) Cost of Making Part No. 789 in‐house Direct materials $26,400 Direct manufacturing labour 13,200 Variable manufacturing overhead 8,400 Amortization on machine 12,000 Relevant costs for operating income calculations if Part No. 789 is manufactured in‐house $60,000 Cost of outsourcing Part No. 789 Purchase costs of Part No. 789 $60,000 Savings in rent (1,200) a Loss on sale of machine 42,000 Relevant costs to consider for operating income computations if Part No. 789 is outsourced $100,800
Proceeds from sale of machine $18,000 Deduct book value of machine ($72,000 – $12,000) 60,000 Loss on sale of machine $42,000 Lin will maximize reported operating income in 2013 by manufacturing Part No. 789 in‐‐ house (relevant costs of $60,000 by manufacturing in‐house versus $100,800 by outsourcing). In this case, there is no conflict between the conclusions Lin will reach based on NPV and on operating income analysis. Note the following: (a) Machine amortization is relevant for operating income computations. This cost will only be incurred if Strubel continues to manufacture Part No. 789. (b) Product and process engineering costs, allocated rent, and allocated general plant overhead costs are irrelevant because these costs will continue to be incurred in total whether Part No. 789 is outsourced or manufactured in‐house. The savings in rent of $1,200 will only occur if Part No. 789 is outsourced. These savings are relevant and are therefore included in the calculation of operating income under the “outsource Part No. 789” alternative. a
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21‐32 (40 min.)
NPV and customer profitability, no income taxes.
1. Homebuilders 2012 2013 2014 2015 2016 2017 Revenues (5%)* $54,000 $56,700 $59,535 $62,512 $65,637 $68,919 COGS (4%)* 26,400 27,456 28,554 29,696 30,884 32,120 12,480 12,979 13,498 14,038 14,600 Op. Costs (4%)* 12,000 Total costs 38,400 39,936 41,533 43,194 44,922 46,720 Cash flow from operations $15,600 $16,764 $18,002 $19,318 $20,715 $22,199 Kitchen $515,775 $593,141 $682,112 $784,429 Revenues (15%)* $390,000 $448,500 COGS (4%)* 216,000 224,640 233,626 242,971 252,689 262,797 Op. Costs (4%)* 90,000 93,600 97,344 101,238 105,287 109,499 Total costs 306,000 318,240 330,970 344,209 357,976 372,296 Cash flow from operations $84,000 $130,260 $184,805 $248,932 $324,136 $412,133 Subdivision Revenues (8%)* $1,032,000 $1,114,560 $1,203,725 $1,300,023 $1,404,025 $1,516,346 COGS (4%)* 660,000 686,400 713,856 742,410 772,107 802,991 Op. Costs (4%)* 282,000 293,280 305,011 317,212 329,900 343,096 Total costs 942,000 979,680 1,018,867 1,059,622 1,102,007 1,146,087 Cash flow from operations $ 90,000 $134,880 $ 184,858 $ 240,401 $ 302,018 $ 370,259 *Annual increases given in question. 2. Homebuilders Kitchen Subdivision Cash Flow Cash Flow Cash Flow P.V. Factor from Present from Present from Present Year for 10% Operations Value Operations Value Operations Value 2013 0.909 $16,764 $15,238 $130,260 $118,406 $134,880 $122,606 2014 0.826 18,002 14,870 184,805 152,649 184,858 152,693 2015 0.751 19,318 14,508 248,932 186,948 240,401 180,541 2016 0.683 20,715 14,148 324,136 221,385 302,018 206,278 2017 0.621 22,199 13,786 412,133 255,935 370,259 229,931 $935,323 $892,049 $72,550
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Chapter 21
21‐32 (cont’d) Customer NPVs over next 5 years (2013 to 2017): Homebuilders $ 72,550 Kitchen Constructors 935,323 Subdivision Erectors 892,049 3. Assume the 20% discount is given at the end of 2012 2012 2013 2014 2015 2016 2017 a b b b Revenues (5%) $390,000 $312,000 $327,600 $343,980 $361,179 $379,238b Total costs (4%) 306,000 318,240 330,970 344,208 357,976 372,296 Cash flow from $ (228) $ 3,203 $ 6,942 operations $ 84,000 $ (6,240) $ (3,370) a20% price discount b5% annual increase Net present value: PV Factor Cash Flow Present Year at 10% from Operations Value 2010 0.909 $(6,240) $(5,672) 2011 0.826 (3,370) (2,784) 2012 0.751 (228) (171) 2014 0.683 3,203 2,188 2014 0.621 6,942 4,311 $(2,128) 4. The 20% discount and reduced subsequent annual revenue reduces the NPV from $892,049 to ($2,128). This is a drop of $894,177 in NPV. The year ended is 2012; therefore, 2013 is the startup and the first 5% increase in revenue will occur in 2014 (after the 20% discount). In year 1 (2013), 100% of revenue will be obtained; in year 2 (2014) 105% of revenue, and so on. Christen should consider whether the price discount demanded by Kitchen needs to be met in full to keep the account. The implication of meeting the full demand is that the account is minimally profitable at best. An equally serious concern is whether Christen’s other two customers will demand comparable price discounts if Kitchen’s full demands are met. The consequence would be very large reductions in the NPVs of all its customers. Christen should also consider the reliability of the growth estimates used in computing the NPVs. Are the predicted differences in revenue growth rates based on reliable information? Many revenue growth estimates by salespeople turn out to be overestimates or occur over a longer time period than initially predicted.
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21‐33 (30 min.) Payback, even and uneven cash flows.
1. Annual revenue $140,000 Annual costs Fixed $96,000 Variable 14,000 110,000 Net annual cash inflow $ 30,000 Payback period = Investment net cash inflows = $159,000 ÷ $30,000 = 5.30 years
2. Revenue Cash Fixed Cash Variable Net Cash Inflows Cumulative Year (1) Costs (2) Costs (3) (4) = (1) − (2) − (3) Amounts 1 $ 90,000 $96,000 $ 9,000 $(15,000) $(15,000) 2 115,000 96,000 11,500 7,500 (7,500) 3 130,000 96,000 13,000 21,000 13,500 4 155,000 96,000 15,500 43,500 57,000 5 170,000 96,000 17,000 57,000 114,000 6 180,000 96,000 18,000 66,000 180,000 7 140,000 96,000 14,000 30,000 210,000 8 125,000 96,000 12,500 16,500 226,500 9 80,000 96,000 8,000 (24,000) 202,500 The cumulative amount exceeds the initial $159,000 investment for the first time at the end of year 6. So, payback happens in year 6. Using linear interpolation, a more precise measure is that payback happens at: $159,000 - $114,000 5 years + 5.68 years. $66,000
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Chapter 21
21‐34 (30–35 min.) NPV and AARR, goal‐congruence issues. 1. Annual cash flow from operations $100,000 Amortization: $320,000 ÷ 6 = $53,333 per year, but this is irrelevant because it has no impact on cash flows beyond moment 0. 0 Initial investment $(320,000) Initial working capital investment (5,000) Cash flow from operations (exl. deprcn.) Times discount factor at 16% × 1.000 Present value $ 368,400 Net present value $ 45,450
1
$100,000 × 0.862 $86,200
Time Period 2 3
4
5
6
5,000
$100,000 $100,000 $100,000 $100,000 $105,000 × 0.743 $74,300
Alternative solution using the annuity tables: PV Factor at i+16%, n+6
× 0.641 $64,100
× 0.552 $55,200
Net Cash Inflow
× 0.476 $47,600
× 0.410 $43,050
Total Present Value
Net present value: Present value of annuity of equal annual after‐tax cash flows from operations 3.685 ×$100,000 per year + (5,000 × .410)= $370,550 Net initial investment (325,000) Net present value $45,550 Note: There is a difference of $100 between the two solutions due to rounding in the tables.
2. Accrual accounting rate of return (AARR): The accrual accounting rate of return takes the annual accrual net income and divides by the initial investment to get a return. Incremental net operating income excluding amortization $100,000 Less: amortization expense ($320,000 ÷ 6) 53,333 Income before tax 46,667 AARR = $46,667 ÷ $325,000 = 14.36%.
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21‐34 (cont’d) 3. Nate will not accept the project if he is being evaluated on the basis of accrual accounting rate of return, because the project does not meet the 16% threshold above which Nate earns a bonus. However, Nate should accept the project if he wants to act in the firm’s best interest because the NPV is positive, implying that, based on the cash flows generated, the project exceeds the firm’s required 16% rate of return. Thus, Nate will turn down an acceptable long‐run project to avoid a poor evaluation based on the measure used to evaluate his performance. To remedy this, the firm could evaluate Nate instead on a project‐by‐project basis by looking at how well he achieves the cash flows forecasted when he chose to accept the project.
21‐35 (40‐45 min.) Recognizing cash flows for capital investment projects, NPV. 1. Net initial investment Initial equipment investment Initial working‐capital investment Net initial investment Cash flow from operations Annual after‐tax cash flow from operations (excl. deprn. effects) Cash revenues Material cash costs 1 Direct labour cash costs $3,600,000 4 Increase in cash overhead costs Annual cash flow from operations with new equipment Deduct income‐tax payments (0.30 × $760,000) Annual after‐tax cash flow from operations Income‐tax cash savings from annual depreciation deductions (0.30×$460,000)1 Total cash flow from operations (after‐tax) Cash flow from terminal disposal of investment Cash flow from terminal disposal of machine (net of tax of $0) Cash flow from terminal disposal of working capital (net of tax of $0) After‐tax cash flow from terminal disposal of investment
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$(5,000,000) (45,000) $(5,045,000)
$3,750,000 (1,700,000) (900,000) (390,000) (760,000) (228,000) $532,000
138,000 $670,000
$400,000 45,000 $445,000
Chapter 21
21‐35 (cont’d)
$5,000,000 $400,000 $460,000 10 Cash flows not relevant to the capital budgeting problem ‐The revenues and investment in the furniture parts division are not relevant to the project ‐The costs of the furniture parts division are not relevant except as the basis for estimation of labour costs for the project ‐The CFO salary is irrelevant since it is not affected by the project These three amounts can be combined to determine the NPV at a 12% discount rate: Present value of net initial investment, $(5,045,000) × 1.000 $(5,045,000) Present value of 10‐year annuity of annual after‐tax cash flow from operations ($670,000 × 5.650) 3,785,500 Present value of after‐tax cash flow from terminal disposal of investment ($445,000 × 0.322) 143,290 Net present value $(1,116,210) Since the net present value is negative, this is clearly not a good investment for a firm that requires a 12% rate of return. Met‐All should not expand into bicycle parts. 21‐36 (35 min.) Recognizing cash flows for capital investment projects. 1. Partitioning relevant cash flows into categories: (1) Net initial investment cash flows: • The $98,000 cost of the new Flab‐Buster 3000. • The disposal value of the old machine, $5,000, is a cash inflow . (2) Cash flow savings from operations: • The 30% savings in utilities cost per year of $4,320 (30% × $1,200 per month × 12 months) results in cash inflow from operations of $4,320. • The savings of half the maintenance costs per year of $5,000 (50% × $10,000) results in a cash inflow from operations of $5,000. (3) Cash flows from terminal disposal of investment: • The $10,000 salvage value of Flab‐Buster 3000 minus the $0 salvage value of the old Fit‐O‐Matic is a terminal cash flow at the end of Year 10. (4) Data not relevant to the capital budgeting decision: • The $10 charge for customers, since it would not change whether or not Ludmilla got the new machine. • The $78,000 cost of the machine Ludmilla does not intend to buy. 1
Depreciation deductions =
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21‐36 (cont’d)
• The $50,000 original cost, nor the $46,000 in accumulated amortization of the Fit‐O‐Matic machine. • The annual amortization.
2. Net present value of the investment: Net initial investment: Initial investment in Flab‐Buster 3000 $(98,000) Current disposal value of Fit‐O‐Matic 5,000 Net initial investment $(93,000) Annual cash flow from operations: Savings in utilities costs $ 4,320 Savings in maintenance costs 5,000 Annual cash flow from operations $ 9,320 Cash flow from terminal disposal of machines $ 10,000 These three amounts can be combined to determine the NPV at an 8% discount rate. Present value of net initial investment, $(93,000) × 1.000 $(93,000) PV of 10‐year annuity of cash flow from operations $9,320 × 6.710 62,537 PV of cash flow from terminal disposal of machines $10,000 × 0.463 4,630 Net present value $(25,833) At the required rate of return of 8%, the net present value of the investment in the Flab‐ Buster 3000 is substantially negative. Ludmilla should therefore not make the investment.
21‐37 (25 min.)
Defensive and offensive strategies in capital budgeting.
1. Project: Increase capacity to serve new markets Initial investment $600,000 + $50,000 Years 1 to 9 $400,000 Cash inflow Present value 5.328 $2,131,200 Year 10 Working capital $50,000 Disposal value $60,000 Cash inflow $400,000 Present value 0.322 $164,220 Net present value $1,645,420
21–1070
Project: Upgrade customer service Initial investment $345,000 + $150,000 Years 1 to 4 $80,000 + Cash inflow $40,000 Present value 3.037 $364,440 Year 5 Working capital $150,000 Cash inflow $80,000 + $40,000 Present value 0.567 $153,090 $22,530
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Chapter 21
21‐37 (cont’d) 2. Deciding based only on NPV, the Bakery should execute immediately the project proposed by the production manager. 3. Capital investment decisions that are strategic in nature require managers to consider a broad range of factors that may be difficult to estimate. The proposal of the production manager is a typical offensive strategy in capital budgeting, while the sales and marketing manager proposal is a defensive strategy in capital budgeting. A defensive strategy does not necessarily have to yield a positive NPV; sometimes it is acceptable that it breaks even while maintaining the company at a competitive level with the rest of the players in the industry. In this problem, the Bakery can do both projects but not at the same time, so when prioritizing, managers must evaluate their position in the industry and see if their direct competitors have the same technology for flexible planning of routes or not, because if everybody but Kleinburg has the technology, then the sales and marketing manager project must be done first; otherwise, it can wait until next year.
COLLABORATIVE LEARNING CASE
21‐38 (45 min.) Net present value, Internal Rate of Return, Sensitivity Analysis. 1. Given the annual operating cash outflows of $160,000 and the payment of 10% of revenues (10% × $260,000 = $26,000), the net cash inflows for each period are as follows: Period 0 1 ‐ 12 Cash inflows $260,000 Cash outflows $(500,000) (186,000) Net cash $ 74,000 inflows $(500,000) The NPV of the investment is: Annual net cash inflows $ 74,000 Present value factor for annuity, 12 periods, × 7.536 8% Present value of net cash inflows $557,664 Initial investment (500,000) Net present value $ 57,664
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21‐38 (cont’d) And the IRR will be: $500,000 ÷ $74,000 = present value factor of 6.76, yielding a return just over 10% from the table, or using a calculator, a return of 10.17%. 2. For revenues of $240,000, the cash flows and NPV computation are given below. Period 0 1 ‐ 12 Cash inflows $240,000 Cash outflows $(500,000) (184,000) Net cash inflows $ 56,000 $(500,000) Annual net cash inflows $ 56,000 Present value factor for annuity, 12 periods, × 7.536 8% Present value of net cash inflows $422,016 Initial investment (500,000) Net present value $ (77,984) And the IRR will be: $500,000 ÷ $56,000 = present value factor of 8.93, yielding a return between 4% and 6% from the table, or using a calculator, a return of 4.87%. For revenues of $220,000: Period 0 1 ‐ 12 Cash inflows $220,000 Cash outflows $(500,000) (182,000) Net cash inflows $(500,000) $ 38,000 Annual net cash inflows $ 38,000 Present value factor for annuity, 12 periods, 8% × 7.536 Present value of net cash inflows $ 286,368 Initial investment (500,000) Net present value $(213,632) 21–1072
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Chapter 21
21‐38 (cont’d) And the IRR will be: $500,000 ÷ $38,000 = present value factor of 13.16, yielding a return of less than 2% from the table or −1.35% using a calculator. 3. For revenues of $240,000, lower costs of $150,000, and payments of only 6% of revenues equal to $14,400: Period 0 1 ‐ 12 Cash inflows $240,000 Cash outflows $(500,000) (164,400) Net cash inflows $(500,000) $ 75,600 Annual net cash inflows $ 75,600 Present value factor for annuity, 12 periods, 8% × 7.536 Present value of net cash inflows $569,722 Initial investment (500,000) Net present value $ 69,722 And the IRR will be: 500,000 ÷ 75,600 = present value factor of 6.61, yielding a return between 10% and 12% from the table, or using a calculator, a return of 10.61%. For revenues of $220,000, lower costs of $150,000, and payments of only 6% of revenues equal to 13,200: Period 0 1 ‐ 12 Cash inflows $220,000 Cash outflows $(500,000) (163,200) Net cash inflows $ 56,800 $(500,000) Annual net cash inflows $ 56,800 Present value factor for annuity, 12 periods, 8% × 7.536 Present value of net cash inflows $428,045 Initial investment (500,000) Net present value $ (71,955)
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21‐38 (cont’d) And the IRR will be: 500,000 ÷ 56,800 = present value factor of 8.80, yielding a return between 4% and 6% from the table, or using a calculator, a return of 5.12%. 4. Under the scenario of higher costs, Francesca will only be well off making the investment if she can reach the sales revenue goal of $260,000. Otherwise she will earn less than her desired return of 8%. In fact, her return at the lower revenue scenarios will be below 6%, her cost of capital (see the IRR calculations). If Francesca is able to lower the operating costs to $150,000 and pay out a smaller share of her revenues, the project will be profitable unless she only reaches the revenue level of $220,000; in that case, she will fall short not only of her desired return, but also her cost of capital of 6%. In summary, unless Francesca is either fairly certain to reach the $260,000 revenue level or fairly certain to lower her costs, it is advised that she not make the investment. It is not necessary to redo the NPV with different interest rates if you already calculated the IRR, since the IRR will not change with changes in desired rate of return. All you need to do is compare the IRR of the project to different desired returns if you are changing the required rate of return and not the cash flows themselves.
21‐39 (45 min.) Relevant costs, capital budgeting, strategic decision. 1. The proposal of Oh‐Mart increases the net income of Wilcox Microwaves by $142,500. Wilcox (current year) ‘Top Line’ Selling price 120 90 Materials 30 40 Labour 20 20 10 Variable overhead (only 50% is variable) 10 Unit contribution margin 60 20 Units to sell 75,000 24,000 Total contribution margin $ 4,500,000 $480,000 Cannibalization 5,000 units (300,000) Fixed costs* (1,000,000) Cost of funds to maintain inventory (1) (37,500) Net income $ 3,500,000 Net effect on income of the proposal $ 142,500
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Chapter 21
21‐39 (cont’d)
$20 labour × 100% = $20 overhead × 50% = $10 fixed/variable $10 fixed × 100,000 units denominator level = $1,000,000
The net production required is of 94,000 units; however, if the cannibalization does not happen, Wilcox will be operating at almost full capacity of 99,000 units. Determination of the costs of funding the extra inventory required by this proposal: Materials 4,000 units at $40 each 160,000 Work in process 1,000 units at 100% of materials at $40 40,000 1,000 units at 50% of labour and variable overhead 15,000 Finished goods 500 units at $70 each 35,000 Increase in working capital (inventory) 250,000 Annual cost of financing the extra inventories (15%) $37,500 2. The solution can use any discount rate, but the minimum should be around the 15% that is the cost of financing the working capital for this project. A rough and simple calculation of the value of the total contract could be done by discounting free cash flows of $142,500 per year (assuming that the cash flows occurred at the end of each year). We can use a rate of discount of 14%. Year Net annual cash flow Discount factor at 14% Discounted at 14% 1 142,500 0.877 124,972.50 2 142,500 0.769 109,582.50 3 142,500 0.675 96,187.50 4 142,500 0.592 84,360.00 5 142,500 0.519 73,957.50 Total value of the contract $489,060.00 Note: there is no initial investment required because the cost of financing the increase of working capital is included in the cash flow of $142,500.
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21‐39 (cont’d) 3. On the basis of the net present value criterion, Wilcox Microwaves should accept the offer because it has a present value of $489,060. It would be pertinent for Wilcox managers to perform some sensitivity analysis; particularly, what happens if the cannibalization is larger and what happens if the costs are higher than expected. 4. To estimate the strategic consequences several qualitative analyses can be done. SWOT analysis: Strengths: current perception of quality, premium price, and distribution channels. Weaknesses: very vulnerable position, only one product. Opportunities: go to other products (broaden the array of electronic appliances). Threats: persistent reduced sales in the whole industry.
Industry analysis: High rivalry in the industry (arrival of cheap brands from Asia). Substitutes: normal and traditional ovens. Threats of new entrants: it is a product easy to manufacture and sell. Suppliers: not a critical element (low bargaining power). Customers: big discount chains and supermarkets with a lot of bargaining power and small retailers with less power. Accepting this offer implies a new strategic positioning for Wilcox. Wilcox was set up for large production runs, but the situation of the market (demand growth less than expected) drove the company to work below capacity. So, is the Oh Mart offer the best way to increase capacity? If Wilcox focuses 100% of its production in products similar to ‘Top Line’ we would have: Marginal contribution $20 instead of $60. The breakeven point would be 54,500 units, more than 50% of the capacity of each shift (54,500 microwaves are needed to cover fixed overhead costs). Wilcox should significantly cut the fixed costs in the short term to be able to maintain the ROA and ROE if deciding to move all the production to low contribution margin microwaves. In summary, what seems to be a very good business opportunity in a stagnant industry, if framed as a one‐time only contract, might represent a disaster from the strategic perspective.
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CHAPTER 22 CAPITAL BUDGETING: A CLOSER LOOK
SHORT‐ANSWER QUESTIONS
22‐1 The three types of cash flows impacted by income taxes are: 1.
2. 3.
Operating cash flows—any increase or decrease in annual operating cash flows must be adjusted so that they represent the after‐tax increase or decrease in operating cash flows. Investment cash flows—represents the expenditure on capital equipment. It must be adjusted for the tax shield created by capital cost allowance. Cash flows from trade‐ins and disposals of assets—we need not be concerned with the net tax book value of the asset (UCC). Our concern is with the UCC of the entire pool of assets, and the effect the trade‐in or disposal will have on the tax shield created by CCA.
22‐2 Yes. To apply a consistent set of regulations and to provide for implementation of government initiatives, the federal government has implemented its own system of capital cost allowance (CCA). The Income Tax Act (ITA) does not permit a company to deduct amortization expense in determining taxable income but rather a company is allowed to deduct CCA. Therefore, the accounting amortization method will have no effect on taxes payable. 22‐3 The chapter describes five categories of cash flows considered in capital‐ budgeting analyses: 1. Initial equipment investment. 2. After‐tax cash flow from current disposal of old equipment. 3. Recurring after‐tax operating cash flows. 4. Income tax cash savings from CCA deductions. 5. After‐tax cash flow from terminal disposal of new equipment. 22‐4 The total project approach calculates the present value of all cash outflows and inflows associated with each alternative. The incremental approach analyzes only the differences in those cash outflows and inflows that differ between alternatives. 22‐5 Yes. Accounting amortization is a noncash item and thus is not an input into a discounted cash flow analysis.
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22‐6 Income taxes can affect the cash inflows or outflows in a motor vehicle replacement decision as follows: a. Tax is payable on gain or loss on disposal of the existing motor vehicle, b. Tax is payable on any change in the operating costs of the new vehicle vis‐à‐vis the existing vehicle, and c. Tax is payable on gain or loss on the sale of the new vehicle at the project termination date. d. Additional capital cost allowance deductions for the new vehicle result in tax cash savings.
22‐7 Most CCA classes use the declining‐balance method. However, occasionally the straight‐line method is used in which the CCA is the same for each year, except for the first and last years which have one‐half of the CCA due to the half‐year rule. Another exception occurs where the CCA rate is varied year by year. For example, when it was implemented class 39 allowed for 40% in year 1 (subject to half‐year rule), 35% in year 2, 30% in year 3 and 25% in the remaining years.
22‐8 These two rates of return differ in their elements: Real‐rate of return Nominal rate of return 1. Risk‐free element 1. Risk‐free element 2. Business‐risk element 2. Business‐risk element 3. Inflation element The inflation element is the premium above the real rate of return that is demanded for the anticipated decline in the general purchasing power of the monetary unit. The nominal rate of return and the real rate of return are related as follows: a) Nominal rate (i) – Inflation rate (g) = Real rate (r) of Return The above is a good approximation especially when the term r g is small. Real rates are the nominal rates adjusted for inflation. (1 i) = (1 r)(1 g) = 1 r + g rg i = r + g + rg b) Nominal rate = [(1 + Real rate)(1 + Inflation rate)] – 1 22‐9 A cellular telephone company manager responsible for retaining customers needs to consider the expected future revenues and the expected future costs of “different investments” to retain customers. One such investment could be a special price discount. An alternative investment is offering loyalty club benefits to long‐time customers.
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Chapter 22
22‐10 The chapter outlines five approaches used to recognize risk in capital budgeting: 1. 2. 3. 4. 5.
Varying the required payback time. Adjusting the required rate of return. Adjusting the estimated future cash flows. Sensitivity (“what‐if”) analysis. Estimating the probability distribution of future cash inflows and outflows for each project.
22‐11 Yes. Projects with different levels of risk should have different required rates of return. The higher the risk, the higher the required rate of return. 22‐12 No. Discounted cash‐flow analysis applies to both profit‐seeking and not‐for‐ profit organizations. Not‐for‐profit organizations must also decide which long‐term assets will accomplish various tasks at the least cost. Not‐for‐profit organizations incur an opportunity cost of funds.
22‐13 NPV and IRR will not always rank projects identically. Different rankings occur when projects have unequal lives or unequal initial investments. The difference arises because the IRR method assumes a reinvestment rate equal to the indicated rate of return for the shortest‐lived project. NPV assumes that funds can be reinvested at the required rate of return.
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EXERCISES
22‐14 (10 min.) Terminology. It is the marginal income tax rate that is important for planning investments because CRA income tax rates are progressive. It is the calendar year that is important to CRA, not the corporate fiscal year. All dispositions of eligible capital property must be reported in the calendar year the transaction occurred. Tax law on eligible capital property is both complex and highly detailed. Financial accountants signal the loss decline in capacity of a long‐term asset to generate revenue using one of three methods of amortization. The CRA, however, has tax laws requiring companies to deduct capital cost allowance (CCA) from the eligible capital expenditure made on an eligible capital property. Irrespective of when an eligible capital expenditure is made in a year, the half‐year rule means only half of the CCA can be deducted from taxable income in the year of acquisition of an eligible capital property. CRA calls the acquisition cost an adjusted cost base (ACB). When an eligible capital property is sold for more than the adjusted cost base plus sales expenses the difference is a capital gain. Once the exemption on taxable capital gains has been taken in full CRA taxes 50% of the capital gain reported in the calendar year. If the property is sold for less than the adjusted cost base plus sales expenses the difference is a capital loss. Up to 50% of a capital loss can be deducted from a taxable capital gain for the same year. The unamortized capital cost allowance is the relevant amount for calculating either a terminal loss or a recapture of UCC. If the eligible capital property is the last of its class to be disposed of, there is a special calculation to determine if there is either a terminal loss or a recapture of unamortized UCC. Any recapture of UCC is reported as normal taxable income. Any terminal loss can be 100% deducted from income for the year. After adjusting cash flow for tax considerations the excess present value index is calculated by dividing the present value of future net cash inflows by the present value of the initial investment. The index measures the cash flow return per dollar invested.
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Chapter 22
22‐15 (40 min.) New equipment purchase. 1.
(a) Present‐Value Relevant Discount Total Cash Factors Present Flows at 12% Value Initial workstation investment $(90,000) 1.000 $(90,000) Recurring after‐tax operating savings* 25,200 3.605 90,846 Tax shield from CCA** 23,021 1.000 23,021 Net present value $23,867 *42,000 (1 – 0.4) = $25,200 **($90,000 0.4) (0.25/(0.25 + 0.12)) ((2 + 0.12)/(2(1 + 0.12))) = $23,021 (b)
Year 1 2 3 4 5
Tax Operating Shield Cash CCA (CCA 0.40) Flows $11,250a $4,500 $25,200 19,688b 7,875 25,200 14,766c 5,906 25,200 11,075 4,430 25,200 8,306 3,322 25,200
Total Cash Flows $29,700 33,075 31,106 29,630 28,522
Cumulative Cash Flows $ 29,700 62,775 93,881 123,511 152,033
Payback period = 2 + (($90,000 – $62,775)/$31,106) = 2.875 years = 2.88 years a 0.25 1/2 90,000 = 11,250 b 0.25 (90,000 – 11,250) = 19,688 c 0.25 (90,000 –(11,250 + 19,688)) = 14,766 (c) 20% NPV: CCA Shield: [(90,000 x 0.25 x 0.4)/(0.25+0.20)] x ((1+(0.5 x 0.20)) / (1+0.20)) = 18,333 PV of cash flows = 25,200 x 2.991 = 75,373 NPV @ 20% = (90,000) + 75,373 + 18,333 = 3,706 22% NPV: CCA Shield: [(90,000 x 0.25 x 0.4)/(0.25+0.22)] x ((1+(0.5 x 0.22)) / (1+0.22)) = 17,422 PV of cash flows = 25,200 x 2.864 = 72,173 NPV @ 20% = (90,000) + 72,173 + 17,422 = (405) Interpolate: 20% + ((3,706 / (3,706 + 405)) x 2%) = 21.80% Proof: CCA Shield: [(90,000 x 0.25 x 0.4)/(0.25+0.2180)] x ((1+(0.5 x 0.2180)) / (1+0.2180)) = 17,510 PV of cash flows = 25,200 x 2.8757 = 72,429 NPV @ 21.80% = (90,000) + 72,469 + 17,510 = 21 (rounding)
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22‐16 (30 min.) 1.
Automated materials‐handling capital project, income taxes, sensitivity analysis.
(a) Relevant Cash Flows Initial equipment investment $(7,375,000) Recurring after‐tax operating savings* 1,800,000 Tax shield from CCA** 1,994,260 Net present value
Present‐Value Discount Total Factors Present at 12% Value 1.000 $(7,375,000) 3.037 5,466,600 1.000 1,994,260 $ 85,860
*$3,000,000 (1 – 0.4) = $1,800,000 **($7,375,000 0.4) (0.3/(0.3 + 0.12)) ((2 + 0.12)/(2(1 + 0.12))) = $1,994,260 (b)
Year 1 2 3 4
CCA $1,106,250 1,880,625 1,316,438 921,506
Tax Shield $442,500 752,250 526,575 368,602
Operating Cash Flows $1,800,000 1,800,000 1,800,000 1,800,000
Total Cash Flows $2,242,500 2,552,250 2,326,575 2,168,602
Cumulative Cash Flows $2,242,000 4,794,750 7,121,325 9,289,927
Payback period = 3 + (($7,375,000– $7,121,325)/2,168,602) = 3.12 years 2. 3.
0 = btocf (1 – 0.4)(3.037) – $7,375,000 + $1,994,260 btocf = $2,952,881 Other factors Just‐in‐Time Distributors should consider include: (a) Uncertainty regarding the annual operating cost savings of $3.0 million. Many firms have grossly underestimated the cost of maintaining and operating the automated materials‐handling equipment. (b) Benefits to Just‐in‐Time Distributors from implementing the automated materials‐handling system that are difficult to quantify; for example, any change in worker mentality regarding willingness to seek out other areas where automation could improve productivity. (c) Strategic factors. If competitors are implementing automation projects, Just‐in ‐ Time Distributors may well have to adopt automation to remain competitive in cost structure and around‐the‐clock service to customers.
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Chapter 22
22‐17 (40 min.) Total project versus differential approach, income taxes. (a) Total Project Approach Replace machine Initial new machine investment Disposal of old machine Recurring after‐tax cash operating costs* Tax shield from CCA** Net present value
Relevant Cash Flows $(87,600) 39,200 (33,600) 8,015
Present‐Value Discount Total Factors Present at 14% Value 1.000 $ (87,600) 1.000 39,200 2.322 (78,019) 1.000 8,015 $(118,404)
*$48,000 (1 – 0.3) = 33,600 **(($87,600– 39,200) 0.3) (0.2/(0.2 + 0.14)) ((2 + 0.14)/((2(1 + 0.14))) = $8,015 Keep machine Relevant Cash Flows Disposal of old machine at end of useful life $7,200 Recurring after‐tax cash operating costs* (50,400) Tax shield from CCA** (1,271) Net present value Total present value
Present‐Value Discount Total Factors Present at 14% Value 0.675 $ 4,860 2.322 (117,029) 0.675 (858) $(113,027)
*$72,000 (1 – 0.3) = 50,400 **((–$7,200 0.3) (0.2/(0.2 + 0.14)) = –$1,271 Net present value difference in favour of keeping old machine (b) Differential Approach Initial new machine investment Disposal of old machine Recurring after‐tax cash operating costs* Tax shield from CCA** Difference in terminal value Tax shield lost from terminal value Net present value
Relevant Cash Flows $(87,600) 39,200 16,800 8,015 (7,200) 1,271
$ 5,377
Present‐Value Discount Total Factors Present at 14% Value 1.000 $(87,600) 1.000 39,200 2.322 39,010 1.000 8,015 0.675 (4,860) 0.675 858 $ 5,377
*($72,000 – $48,000) (1 – 0.3) = $16,800
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22‐18 (30 min.) Capital budgeting methods, no income taxes. The table for the present value of annuities (Appendix B, Table 4) shows: 10 periods at 14% = 5.216 1a. Net present value = $28,000 (5.216) – $110,000 = $146,048 – $110,000 = $36,048 $110,000 = 3.93 years b. Payback period = $28,000 c. Internal rate of return: $110,000 = Present value of annuity of $28,000 at R% for 10 years, or what factor (F) in the table of present values of an annuity (Appendix B, Table 4) will satisfy the following equation. $110,000 = $28,000F $110,000 F = = 3.929 $28,000 On the 10‐year line in the table for the present value of annuities (Appendix B, Table 4), find the column closest to 3.929; 3.929 is between a rate of return of 20% and 22%. Interpolation can be used to determine the exact rate: Present Value Factors 20% 4.192 4.192 IRR rate –– 3.929 –– 22% 3.923 0.263 Difference 0.269 0.263 Internal rate of return = 20% + (2%) 0.269 = 20% + (0.978) (2%) = 21.96% d. Accrual accounting rate of return based on net initial investment: Net initial investment = $110,000 Estimated useful life = 10 years Annual straight‐line depreciation = $110,000 ÷ 10 = $11,000 $28,000 $11,000 Accrual accounting rate of return = $110,000 $17,000 = = 15.46% $110,000
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Chapter 22
22‐18 (cont’d) 2. Factors Saskatoon Hospital should consider include: a. Quantitative financial aspects. b. Qualitative factors, such as the benefits to its customers of a better eye‐testing machine and the employee‐morale advantages of having up‐to‐date equipment. c. Financing factors, such as the availability of cash to purchase the new equipment.
22‐19 (20 min.) Capital budgeting, income taxes. 1a.
Net after‐tax initial investment = $110,000 Annual after‐tax cash flow from operations (excluding the depreciation effect): Annual cash flow from operation with new machine Deduct income tax payments (30% of $28,000) Annual after‐tax cash flow from operations Income tax cash savings from annual depreciation deductions 30% $11,000
These three amounts can be combined to determine the NPV: Net initial investment; $110,000 1.00 10‐year annuity of annual after‐tax cash flows from operations; $19,600 5.216 10‐year annuity of income tax cash savings from annual depreciation deductions; $3,300 5.216 Net present value
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$28,000 8,400 $19,600 $3,300
$(110,000) 102,234 17,213 $ 9,447
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22‐19 (cont’d) b.
Payback period $110,000 = ($19,600 + $3,300) $110,000 = $22,900 = 4.80 years
c.
Internal rate of return:
F =
$110,000 = 4.803 $22,900
d.
2a.
b. c. d.
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Interpolation can be used to determine the exact rate: Present Value Factors 16% 4.833 4.833 IRR 4.803 18% 4.494 _____ 0.339 0.030 .030 2% IRR = 16% + .339 = 16.18% Accrual Accounting Rate of Return: $22,900 $11,000 $11,900 AARR = = $110,000 $110,000 = 10.82% Increase in NPV. From Table 2, the present value factor for 10 periods at 14% is 0.270. Therefore, the $10,000 terminal disposal price at the end of 10 years would have an after‐tax NPV of: $10,000 (1 0.30) 0.270 = $1,890 No change in the payback period of 4.80 years. The cash inflow occurs at the end of year 10. Increase in internal rate of return. The $10,000 terminal disposal price would raise the IRR because of the additional inflow. The AARR would increase because accrual accounting income in year 10 would increase by the $7,000 ($10,000 gain from disposal 30% $10,000) after‐tax gain on disposal of equipment. This increase in year 10 income would result in higher average annual AARR in the numerator of the AARR formula.
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Chapter 22
22‐20 (40 min.) Project risk, required rate of return. 1.
Drilling equipment project Relevant Cash Flows 1. Initial drilling equipment investment $(1,185,000) 2. Tax shield created by CCA* 227,335 3. Recurring cash‐operating flows $ 448,000 Additional income taxes at 30% (134,400) Recurring after‐tax cash‐operating flows each year for 5 years (excl. amort. effects) $ 313,600 Net present value
Present‐Value Discount Total Factors Present at 12% Value 1.000 $(1,185,000) 1.000 227,335
3.605
1,130,528 $ 172,863
*($1,185,000 0.3) (0.25/(0.25 + 0.12)) ((2 + 0.12)/2(1 + 0.12)) = $227,335 Production equipment project Initial production equipment investment $(850,000) Tax shield created by CCA* 163,067 Recurring operating cash flows** 248,500 Net present balue
1.000 1.000 3.037
$(850,000) 163,067 754,695 $ 67,762
*($850,000 0.3) (0.25/(0.25 + 0.12)) ((2 + 0.12)/2(1 + 0.12)) = $163,067 **$355,000 (1 – 0.3) = $248,500 At a 12% discount rate for both projects, the drilling equipment project has the higher NPV and would be preferred.
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22‐20 (cont’d) 2.
We calculate the NPV of the high‐risk drilling equipment project assuming a required rate of return of 18%. Present‐Value Relevant Discount Total Cash Factors Present Flows at 18% Value 1. Initial drilling equipment investment $(1,185,000) 1.000 $(1,185,000) 2. Tax shield created by CCA* $190,922 1.000 190,922 3. Recurring cash‐operating flows $448,000 Additional income taxes at 30% (134,400) Recurring after‐tax cash‐operating flows each year for 5 years (excl. amort, effects) $ 313,600 3.127 980,627 Net present value $ (13,451) *($1,185,000 0.3) (0.25/(0.25 + 0.18)) ((2+0.18)/2(1 + 0.18)) = $190,922
The lower‐risk production equipment project for the refinery discounted at 12% has an NPV of $67,762 (requirement 1) that is greater than the NPV of $(13,451) for the higher‐risk drilling equipment project for oil exploration discounted at 18%. 3.
Northern should favour the investment in the production equipment for the refinery because it has a positive NPV. It should not invest in the drilling equipment because this project has a negative NPV when discounted at the risk adjusted 18% required rate of return.
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Chapter 22
22‐21 (25 min.) Income taxes and inflation. 1.
The investment has a negative NPV of $(26,087) calculated as follows: Initial investment in special tools Tax shield created by CCA* Recurring cash flows from drill bits** Proceeds from disposal of equipment Lost tax shield because of disposal*** Net present value
Relevant Cash Flows $(254,200) 62,026 24,000 (6,340)
Present‐Value Discount Total Factors Present at 18% Value 1.000 $(254,200) 1.000 62,026 156,974 0.516 12,384 0.516 (3,271) $ (26,087)
*($254,200 0.4) (0.35/(0.35 + 0.18)) ((2 + 0.18)/(2(1 + 0.18))) = $62,026
**Calculation: Cash Inflow from Sales Year of Drill Bits (1) (2) 2011 $2.40 37,500 = $ 84,000 2012 $2.54 37,500 = $ 95,250 2013 $2.70 37,500 = $101,250 2014 $2.86 37,500 = $107,250
After‐Tax Cash Present‐ Inflow from Value Sales of Drill Discount Bits Factors at 18% (5) = 0.60 (2) $54,000 0.847 57,150 0.718 60,750 0.609 64,350 0.516
Total Present Value $ 45,738 41,034 36,997 33,205 $156,974
***(–$24,000 0.4) (0.35/(0.35 + 0.18) = –$6,340 2. 3.
There is no need to repeat requirement 1. Requirement 1 used nominal cash flows and nominal rates of return so it has already factored in the effects of inflation. Marco could have also taken inflation into account by considering real cash flows and real rates of return. Nominal cash flows can be converted into real cash flows by discounting each of the nominal cash flows by the inflation rate. Similarly, the after‐ tax real rate of return can be computed as [(1 + nominal rate) ÷ (1 + inflation rate)] – 1 = (1.18 ÷ 1.06) – 1 = 11.3%. Discounting real cash flows by the real rate of return would also result in a negative NPV of $(26,087).
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22‐22 (25 min.) Inflation and not‐for‐profit institution, no tax aspects. 1.
The KopiPro official calculated the following NPV using the 18.8% discount rate and real cash‐operating savings. Present‐Value Relevant Discount Cash‐Operating Factors Present Value Savings in Nominal Dollars at 18.8% of Cash Flows Year (1) (2) (3) = (l) (2) 2012 1,350 x 1.1 $1,485 0.842 $ 1,250 2013 1,485 x 1.1 1,633 0.709 1,158 2014 1,633 x 1.1 1,796 0.596 1,071 2015 1,796 x 1.1 1,976 0.502 992 2016 1,976 x 1.1 2,174 0.423 919 Present value of recurring cash‐operating savings 5,390 Net initial investment 5,500 Net present value ($ 110) Inflation effects are symmetric on cash inflows and outflows. On the one hand, cash savings in inflated dollars tomorrow have lower purchasing power than cash savings in inflated dollars today. On the other hand, inflated costs today have a real value lower than uninflated costs of yesterday. Inflation helps those who owe money because they repay over time in dollars with lower purchasing power than the dollars they borrowed. Inflation hurts those who lend money, for the same reason. Lenders factor inflation rate risk into their interest rates and, for a borrower, interest expense is a cash outflow. In the same vein, labour contracts often include escalation rates to account for anticipated inflation. It is important for managers assessing the financial viability of a project to ensure they distinguish those cash outflows that already include inflation from those that do not in order to avoid “double” discounting. Remember that the risk‐free rate of return is a lending rate. In this case the Canadian government is the borrower and hence the risk‐free rate it pays to lenders must include both time‐value of money, a factor for anticipated domestic inflation, and a factor for anticipated foreign exchange rate risk—otherwise lenders would not loan their money. Therefore even the risk‐free rate has been adjusted for inflation and the real rate of return is: Real rate of return = Nominal rate of return – Rate of inflation When companies set their required rates of return, unless they anticipate higher inflation rates and higher foreign exchange rate risk than those reflected in the risk‐free rate, they should avoid increasing their required rate of return based on these two factors. Therefore in 2b, the real rate of return is: Real rate of return = 18% – 10% = 8%
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Chapter 22
22‐22 (cont’d) 2.
a. The real rate of return required by KopiPro can be computed using the following relationship:
(1 real rate) = 1 + nominal rate 1 0.188 1.188 1.08 1 + inflation rate 1 0.10 1.10
Real rate of return required = 0.08 or 8% b. The net present value using real operating cash savings and real rates of return are as follows:
Present‐Value Relevant Discount Cash‐Operating Factors Present Value Savings in Real Dollars at 8% of Cash Flows Year (1) (2) (3) = (l) (2) 1 $1,350 0.926 $1,250 2 1,350 0.857 1,157 3 1,350 0.794 1,072 4 1,350 0.735 992 5 1,350 0.681 919 Present value of recurring cash‐operating savings 5,390 Net initial investment 5,500 Net present value ($ 110) 3. Requirements 1 and 2 when correctly done give the same NPV of ($110). Consistency is key in capital budgeting. To be correct, requirement 1 should use nominal cash flows and nominal rates of return. Requirement 2 uses real cash flows and real rates of return. Both are valid approaches.
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22‐23 (20 min.) Excess present value index. 1.
The following table shows the calculations of the net present values for the different projects in column 3 and the excess present‐value indexes in column 4. Project Design Pro Easychip Project C Project D
Net Initial Investment (1) $600,000 900,000 540,000 240,000
Total Present Value at 14% (2) $ 900,000 1,260,000 702,000 384,000
Net Present‐ Value (3) = (2) – (1) $300,000 360,000 162,000 144,000
Excess Present‐ Value Index (4) = (2) ÷ (1) 150% 140% 130% 160%
On basis of the excess present‐value index, ChipTech should choose Design Pro over Easychip. 2.
With a capital budget of $1,140,000 and given the rankings of NPVs, ChipTech must choose between
Design Pro + Project C for an NPV of $300,000 + $162,000 = $462,000 or Easychip + Project D for an NPV of $360,000 + $144,000 = $504,000 Note that if ChipTech chooses Design Pro, it can choose either Project C or Project D but not both, so it would prefer Project C because it has the higher NPV. If ChipTech chooses Easychip, the only project available to it, given the capital investment budget constraint of $1,140,000, is Project D. ChipTech should choose Easychip because together with Project D it gives a higher NPV than going with Design Pro and Project C. 3.
The excess present‐value index is a useful guide for identifying and choosing projects that will offer the best return on limited capital and that will thereby maximize net present value. But managers cannot base decisions involving mutually exclusive investments of different sizes solely on the excess present‐value index. The net present‐value method is the best general guide. In our example, ChipTech is better off choosing Easychip even though Design Pro has a higher excess present‐ value index. The reason is that by going with Easychip over Design Pro, ChipTech gains $60,000 in net present value and gives up only $18,000 when Project D is picked instead of Project C. This results in a net gain of $42,000, also equal to $504,000 – $462,000 calculated in requirement 2.
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Chapter 22
22‐24 (40 min.) New equipment purchase, income taxes. 1.
a. Solution NPV computation. NPV = $ 2,236 Present‐Value Relevant Discount Total Cash Factors Present Flows at 12% Value Initial machine investment $(88,000) 1.000 $(88,000) Recurring after‐tax operating savings* 21,600 3.037 65,599 Tax shield from CCA** 20,821 1.000 20,821 Proceeds from disposal of machine 8,000 0.636 5,088 Tax shield lost from terminal value*** (2,000) 0.636 (1,272) Net present value $ 2,236 *36,000 (1 – 0.4) = $21,600 **($88,000 0.4) (0.20/(0.20 + 0.12)) ((2 + 0.12)/(2(1 + 0.12))) = $20,821 ***(–$8,000 0.4) (0.20/ (0.20 + 0.12)) = –$2,000 b. Payback TaxOperating Total Cumulative Shield Cash Cash Cash Year CCA (CCA @ 0.40) Flows Flows Flows a) 1 $8,800 $3,520 $21,600 $25,120 $ 25,120 2 15,840b) 6,336 21,600 27,936 53,056 3 12,672c) 5,069 21,600 26,669 79,725 4 10,138 4,055 21,600 25,655 105,380
Payback period = 3 + (($88,000 – $79,725)/$25,655) = 3.33 years a) 0.20 1/2 88,000 = 8,800 b) 0.20 (88,000 – 8,800) = 15,840 c) 0.20 (88,000 –(8,800 + 15,840)) = 12,672
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22‐24 (cont’d) c.
Part a calculates the NPV as $2,236 using 12%. Therefore, the IRR, the discount rate at which the NPV of the cash flows is zero, must be greater than 12%. Using Trial and Error, use the tables to calculate the NPV for 14% IRR: Relevant Discount Total Cash Factors Present Flows at 14% Value Initial machine investment $(88,000) 1.000 $(88,000) Recurring after‐tax operating savings* 21,600 2.914 62,942 Tax shield from CCA** 19,434 1.000 19,434 Proceeds from disposal of machine 8,000 0.592 4,736 Tax shield lost from terminal value*** (1,882) 0.592 (1,114) Net present value $ (,2002) *36,000 (1 – 0.4) = $21,600 **($88,000 0.4) (0.20/(0.20 + 0.14)) ((2 + 0.14)/(2(1 + 0.14))) = $19,434 ***(–$8,000 0.4) (0.20/ (0.20 + 0.14)) = –$1,882
12%, NPV = $2,236 14%, NPV = ‐$2,002 Therefore, the IRR is between 12% and 14%.
2.
Both the net present value and internal rate of return methods use a discounted cash flow approach in which all expected future cash inflows and cash outflows of a project are measured as if they occurred at a single point in time. The payback method considers only cash flows up to the time when the expected future cash inflows recoup the net initial investment in a project. The payback method ignores profitability and the time value of money. However, the payback method is becoming increasingly important in the global economy. When the local environment in an international location is unstable and therefore highly risky for a potential investment, a company would likely pay close attention to the payback period for making its investment decision. In general, the more unstable the environment, the shorter the payback period desired.
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Chapter 22
22‐25 (40 min.) New equipment purchase, income taxes. 1.
a. Present Value Relevant Discount Total Cash Factors Present Flows at 12% Value Initial machine investment $(62,500) 1.000 $(62,500) Recurring after‐tax operating savings* 18,750 3.605 67,594 Tax shield from CCA** 14,788 1.000 14,788 Net present value $ 19,882 *31,250 (1 – 0.4) = $18,750 **($62,500 0.4) (0.20/(0.20 + 0.12)) ((2 + 0.12)/(2(1 + 0.12))) = $14,788 b. Payback Tax Operating Total Cumulative Shield Cash Cash Cash Year CCA (CCA 0.40) Flows Flows Flows 1 $6,250a $2,500 $18,750 $21,250 $21,250 2 11,250b 4,500 18,750 23,250 44,500 3 9,000c 3,600 18,750 22,350 66,850 4 7,200 2,880 18,750 21,630 88,480 Payback period = 2 + (($62,500 – $44,500)/$22,350) = 0.81 years a 0.20 1/2 62,500 = 6,250 b 0.20 (62,500 – 6,250) = 11,250 c 0.20 (62,500 – (6,250 + 11,250)) = 9,000
c. 22% NPV: CCA Shield: [(62,500 x 0.20 x 0.4)/(0.20+0.22)] x ((1+(0.5 x 0.22)) / (1+0.22)) = 10,831
PV of cash flows = 18,750 x 2.864 = 53,700 NPV @ 22% = (62,500) + 53,700 + 10,831 = 2,031 24% NPV: CCA Shield: [(62,500 x 0.20 x 0.4)/(0.20+0.24)] x ((1+(0.5 x 0.24)) / (1+0.24)) = 10,263 PV of cash flows = 18,750 x 2.745 = 51,469 NPV @ 24% = (62,500) + 51,469 + 10,263 = (768) Interpolate: 22% + ((2,031 / (2,031 + 768)) x 2%) = 23.45% Proof: CCA Shield: [(62,500 x 0.20 x 0.4)/(0.20+0.2345)] x ((1+(0.5 x 0.2345)) / (1+0.2345)) = 10,415 PV of cash flows = 18,750 x 2.777 = 52,070* NPV @ 23.45% = (62,500) + 52,070 + 10,415 = 15 (rounding) * calculated using financial calculator ** (52,070 / 18,750) = 2.777 Copyright © 2013 Pearson Canada Inc.
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22‐25 (cont’d) 2.
Both the net present value and internal rate of return methods use the discounted cash flow approach in which all expected future cash inflows and outflows of a project are measured as if they occurred at a single point in time. The net present value approach computes the surplus generated by the project in today’s dollars while the internal rate of return attempts to measure its effective return on investment earned by the project. The payback method, by contrast, considers nominal cash flows (without discounting) and measures the time at which the project’s expected future cash inflows recoup the net initial investment in a project. The payback method thus ignores the profitability of the project’s entire stream of future cash flows.
22‐26 (15‐20 min.) After‐tax NPV. 1.
(a) Before‐tax annual cash flow Amortization ($36,000 ÷ 6) Net income before tax Income tax expense Accounting income
$12,000 (6,000) 6,000 2,400 $ 3,600
After‐tax accrual accounting rate of return = $3,600 ÷ 36,000 = 10% 2.
(b)
Year 1 2 3
CCA $3,600 6,480 5,184
Operating Tax Cash Shield (40%) Flows $1,440 $12,000 2,592 12,000 2,074 12,000
Total Cash Flows $13,440 14,592 14,074
Cumulative Cash Flows $13,440 28,032 42,106
Payback period = 2 + (($36,000 – $28,032)/$14,074) = 2.6 years 3.
(b) Present‐Value Relevant Discount Total Cash Factors Present Flows at 15% Value Initial investment $(36,000) 1.000 $(36,000) Recurring after‐tax operating savings* 7,200 3.785 27,252 Tax shield from CCA** 7,692 1.000 7,692 Net present value $ (1,056) *$12,000 (1 – 0.40) = $7,200 **($36,000 0.4) (0.20/(0.20 + 0.15)) (2 + 0.15)/2(1 + 0.15)) = $7,692
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Chapter 22
22‐26 (cont’d) 4.
(b) Only one payment will be made which 5 years later must yield $36,000. Therefore, deduct the value of an annuity of four payments from the value of an annuity of five payments: 3.353 – 2.856 = 0.497
Note that 3.353 – 2.856 = 0.497 is the present value of a cash outflow of $1 occurring at the end of period 5. Alternatively stated, $1 is the future value of $0.497 invested five years ago. Therefore, to have $36,000 now, we need to invest its present value 5 years ago discounted at 15% equal to: $36,000 0.497 = $17,892 or (X) (1.15)5 = $36,000 X = $36,000 ÷ (1.15)5 = $36,000 ÷ 2.01135 = $17,898 Difference is rounding error
PROBLEMS 22‐27 (60 min.) Equipment replacement, no income taxes. 1.
Cash flows for modernizing alternative: Net Cash Initial Year Units Sold Contributions Investments a (1) (2) (3) = (2) × $18,000 (4) Jan. 1, 2013 –– –– $(33,600,000) Dec. 31, 2013 552 $ 9,936000 Dec. 31, 2014 612 11,016000 Dec. 31, 2015 672 12,096000 Dec. 31, 2016 732 13,176000 Dec. 31, 2017 792 14,256000 Dec. 31, 2018 852 15,336000 Dec. 31, 2019 912 16,416000 $6000000 a $80000 – $62000 = $18000 cash contribution per prototype.
Sale of Equip. at Termination (5) ––
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22‐27 (cont’d) Cash flows for replacement alternative: Net Cash Initial Year Units Sold Contributions Investments b (1) (2) (3) = (2) × $24,000 (4) Jan. 1, 2013 –– –– $(58,800,000) Dec. 31, 2013 552 $13,248000 Dec. 31, 2014 612 14,688000 Dec. 31, 2015 672 16,128000 Dec. 31, 2016 732 17,568000 Dec. 31, 2017 792 19,008000 Dec. 31, 2018 852 20,448000 Dec. 31, 2019 912 21,888000 $14400000 b $80000 – $56000 = $24000 cash contribution per prototype. 2.
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Sale of Equip. (5) $3600000
Payback period calculations for modernizing alternative: Cumulative Net Initial Investment Year Cash Inflow Cash Inflow Unrecovered at End of Year (1) (2) (3) (4) Jan. 1, 2013 –– –– $33,600,000 23,664000 Dec. 31, 2013 $ 9,936000 $ 9,936000 Dec. 31, 2014 11,016000 20,952000 12,648000 552000 Dec. 31, 2015 12,096000 33,048000 Dec. 31, 2016 13,176000 Payback = 3 + ($552,000 ÷ $13,176,000) = 3.04 years
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Chapter 22
22‐27 (cont’d)
3.
Payback period calculations for replace alternative: Cumulative Net Initial Investment Year Cash Inflow Cash Inflow Unrecovered at End of Year (4) (1) (2) (3) Jan. 1, 2013 –– –– $55,200,000 Dec. 31, 2013 $13,248000 $13,248000 41,952000 27,264000 Dec. 31, 2014 14,688000 27,936000 11,136000 Dec. 31, 2015 16,128000 44,064000 Dec. 31, 2016 17,568000 Payback = 3 + ($11,136,000 ÷ $17,568,000) = 3.63 years Modernizing alternative:
Present Value Discount Factors Year At 12% Jan. 1, 2013 1.000 Dec. 31, 2013 0.893 Dec. 31, 2014 0.797 Dec. 31, 2015 0.712 Dec. 31, 2016 0.636 Dec. 31, 2017 0.567 Dec. 31, 2018 0.507 Dec. 31, 2019 0.452 Total
Net Cash Present Flow Value $(33,600000) $(33,600,000) 8,872848 9,936000 11,016000 8,779,752 8,612,352 12,096000 13,176000 8,379,936 14,256000 8,083,152 7,775,352 15,336000 22,416000 10,132,032 $27,035,424
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22‐27 (cont’d)
Replace Alternative:
4.
22–1100
Present Value Discount Factors Net Cash Present Year At 12% Flow Value Jan. 1, 2013 1.000 $(55,200000) $(55,200,000) Dec. 31, 2013 0.893 13,248000 11,830,464 Dec. 31, 2014 0.797 14,688000 11,706,336 11,483,136 Dec. 31, 2015 0.712 16,128000 11,173,248 Dec. 31, 2016 0.636 17,568000 Dec. 31, 2017 0.567 19,008000 10,777,536 Dec. 31, 2018 0.507 20,448000 10,367,136 Dec. 31, 2019 0.452 36,288,000 16,402,176 Total $28,540,032 Using the payback period, the modernize alternative is preferred to the replace alternative. On the other hand, the replace alternative has a higher NPV than the modernize alternative and so should be preferred. However, the NPV amounts are based on best estimates. Pro Chips should examine the sensitivity of the NPV amounts to variations in the estimates. Nonfinancial qualitative factors should be considered. These could include the quality of the prototypes produced by the modernize and replace alternatives. These alternatives may differ in capacity and their ability to meet surges in demand beyond the estimated amounts. The alternatives may also differ in how workers increase their shop floor‐capabilities. Such differences could provide labour force externalities that can be the source of future benefits to Pro Chips.
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Chapter 22
22‐28 (40 min.)
Equipment replacement, income taxes. 1. & 2. Income tax rate = 30% Modernize Alternative Annual depreciation: $33,600000 7 years = $4800000 a year. Income tax cash savings from annual depreciation deductions: $4800000 0.30 = $1440000 a year. Terminal disposal of equipment = $6000000. After‐tax cash flow from terminal disposal of equipment: $6000000 0.70 = $4,200000. The NPV components are: a. Initial investment: NPV Jan. 1, 2013 $(33,600000) 1.000 $(33,600000) b. Annual after‐tax cash flow from operations (excluding depreciation): 6,210,994 Dec. 31, 2013 9,936000 0.70 0.893 2014 11,016000 0.70 0.797 6,145,826 2015 12,096,000 0.70 0.712 6,028,646 2016 13,176000 0.70 0.636 5,865,955 2017 14,256000 0.70 0.567 5,658,206 2018 15,336000 0.70 0.507 5,442,746 2019 16,416000 0.70 0.452 5,194,022 c. Income tax cash savings from annual depreciation deductions ($1,440,000 each year for 7 years): 6,572,160 $1,440,000 4.564 d. After‐tax cash flow from terminal sale of equipment: $4,200,000 0.452 1,898,400 Net present value of modernize alternative $ 15,416,955 Replace alternative Initial machine replacement = $58,800,000 Sale on Jan. 1, 2013, of equipment = $3,600,000 After‐tax cash flow from sale of old equipment: $3,600,000 0.70 = $2,520,000 Net initial investment: $58,800,000 $2,520,000 = $56,280,000 Annual depreciation: $58,800,000 7 years = $8,400,000 a year
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22‐28 (cont’d) Income‐tax cash savings from annual depreciation deductions: $8,400,000 0.30 = $2,520,000 After‐tax cash flow from terminal disposal of equipment: $14,400,000 0.70 = $10,080,000 The NPV components of the replace alternative are: a. Net initial investment Jan. 1, 2013 $(56,280,000) 1.000 $(56,280,000) b. Annual after‐tax cash flow from operations (excluding depreciation) 8,281,325 Dec. 31, 2013 $13,248,000 0.70 0.893 2014 14,688,000 0.70 0.797 8,194,435 2015 16,128,000 0.70 0.712 8,038,195 2016 17,568,000 0.70 0.636 7,821,274 2017 19,008,000 0.70 0.567 7,544,275 2018 20,448,000 0.70 0.507 7,256,995 2019 21,888,000 0.70 0.452 6,925,363 c. Income tax cash savings from annual depreciation deductions 11,501,280 ($2,520,000 each year for 7 years) $2,520,000 4.564 d. After‐tax cash flow from terminal sale of equipment, $10,080,000 4,556,160 0.452 Net present value of replace alternative $13,839,302 On the basis of NPV, Pro Chips should modernize rather than replace the equipment. Note that absent taxes, the replace alternative had a higher NPV than the modernize alternative. In making decisions, companies should always consider after‐tax amounts 3. Pro Chips would prefer to: a. have lower tax rates, b. have revenue exempt from taxation, c. recognize taxable revenues in later years rather than earlier years, d. recognize taxable cost deductions greater than actual outlay costs, and e. recognize cost deductions in earlier years rather than later years (including accelerated amounts in earlier years).
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Chapter 22
22‐29 (30‐40 min.) Inflation. 1. Initial machine investment Recurring cash‐operating savings for 5 years at 10% Net present value
Relevant Cash Flow $(12,000)
Present‐Value Discount Total Factors at 10% Present Value 1.000 $(12,000)
$3,600
3.791
13,648 $ 1,648
Initial machine investment Recurring cash‐operating savings* Tax shield created by CCA** Net Present Value
$(12,000) 2,160 3,273
1.000 3.791 1.000
$(12,000) 8,189 3,273 $ (538)
2.
*$3,600 (1 0.4) = $2,160 **($12,000 0.4) (0.25/(0.25 + 0.1)) ((2 + 0.1)/2(1 + 0.1)) = $3,273
3. The net present value of the machine will be the same as in requirement 1. This result can be illustrated by estimating the cash flows in nominal dollars and using a nominal discount rate: Nominal rate
= (1 + Real rate) (1 + Inflation rate) – 1 = (1.10) (1.20) – 1 = 1.32 – 1 = 0.32
Alternatively:
Real rate of interest Inflation rate Combination (0.10 0.20) Nominal rate of interest
0.10 0.20 0.02 0.32
Recurring cash‐operating savings (nominal dollars and a nominal discount rate): Cash‐Operating Savings in Real Year Dollars (1) (2) 2012 $3,600 2013 3,600 2014 3,600 2015 3,600 2016 3,600 Initial machine investment Net present value
Cash‐Operating Cumulative Savings in Inflation Nominal Rate Dollars (3) (4) = (2) (3) 1.200 $4,320 1.440 5,184 1.728 6,221 2.074 7,466 2.488 8,957
Nominal Dollar Present‐Value Total Discount Factor Present (32%) Value (5) (6) = (4) (5) 0.758 $ 3,275 0.574 2,976 0.435 2,706 0.329 2,456 0.250 2,239 (12,000) $ 1,652
Difference between requirement 1 and 3 is due to rounding of $4.
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22‐29 (cont’d) 4. Initial machine investment Recurring cash‐operating savings* Tax shield created by CCA** Net Present Value
Relevant Cash Flows $(12,000) 1,850
Present‐Value Discount Total Factors Present at 32% Value 1.000 $(12,000) 8,192 1.000 1,850 $ (1,958)
*Recurring after‐tax cash‐operating savings: After‐Tax Before‐Tax Cash‐Operating Nominal Dollar Cash‐Operating Tax Savings Present‐Value Total Savings (Nominal Payments (Nominal Discount Factor Present Year Dollars) (40%) Dollars) (32%) Value (5) (6) = (4) * (5) (1) (2) (3) = 0.4 (2) (4) = (2) (3) 2012 $4,320 $1,728 $2,592 0.758 $1,965 2013 5,184 2,074 3,110 0.574 1,785 2014 6,221 2,488 3,733 0.435 1,624 2015 7,466 2,986 4,480 0.329 1,474 2016 8,959 3,583 5,376 0.250 1,344 $8,192 **($12,000 0.4) (0.25/(0.25 + 0.32)) ((2 + 0.32)/(2(1 + 0.32))) = $1,850
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Chapter 22
22‐30 (40 min.) Assessing risk. 1. Present‐Value Relevant Discount Total Cash Factors Present Flows at 16% Value Initial machine investment $(144,000) 1.000 $(144,000) Proceeds from disposal of old machine 48,000 1.000 48,000 Tax shield created by CCA* 21,800 1.000 21,800 Recurring operating savings** 13,680 2.798 38,277 Proceeds from disposal of machine*** 12,000 0.552 6,624 Lost tax shield because of disposal**** (2,927) 0.552 (1,616) Net Present Value $ (30,915) *(($144,000 – $48,000) 0.4) (0.25/(0.25 + 0.16)) ((2 + .16)/(2(1 + 0.16))) = $21,800 **$300,000 ($0.24 – 0.168) (1 – 0.4) + ($18,000 – $16,800)0.6 = $13,680 ***$24,000 – $12,000 = $12,000 ****(–$12,000 0.4) (0.25/(0.25 + 0.16)) = –$2,927 WRL Company should retain the old equipment because the present value of the incremental cash flows is negative. 2.
3.
0 = –$144,000 + $48,000 + $21,800 + 2.798atcs + $6,624 –$1,616 atcs = $24,729 $24,729 – $13,680 = $11,049 WRL would have to save $11,049 more after‐tax dollars on an annual basis to earn a 16% rate of return. The qualitative factors that are important to WRL Company’s decision include the following:
(a) The lower operating costs (variable and fixed) of the new machine would enable WRL to meet future competitive or inflationary pressures to a greater degree than the business could using the old machine. (b) If the increased efficiency of the new machine provides a labour or energy cost savings, then additional increases in these costs in the future would make the new machine more attractive. (c) Maintenance and servicing of both machines should be reviewed in terms of reliability of the manufacturer and the costs. (d) Potential technological advances in machinery over the next four years should be evaluated. (e) Space requirements for the new machine should be reviewed and compared with the space requirements of the present equipment to determine if more or less space is required.
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22‐31 (35 min.) Capital budgeting, inventory changes. 1.
A schedule of relevant cash flows follows:
Sketch of Relevant Cash Flows
Year 0 Year 1 Acquire machines $(131,040) Sales 6,000 $30.00 $180,000 6,200 $30.00 7,700 $28.80 3,100 $26.40 Manufacturing costs 7,000 $14.40 (100,800) 6,500 $15.60 6,500 $16.80 3,000 $18.00 Marketing, distribution, and customer‐service costs 6,000 $3.60 (21,600) 6,200 $3.60 7,700 $3.60 3,100 $3.60 Disposal of machine Taxes (see schedule) (22,248) Net cash flow after tax ($131,040) $ 35,352 Year 1 Sales $180,000 COGS* 86,400 Mkt., dist. & cust.‐serv. 21,600 CCA 16,3801) Taxable income $55,620 Tax rate 40% Taxes $22,248
Year 2
Year 3
Year 4
$186,000
$221,760
$81,840
(101,400)
(109,200)
(54,000)
(22,320) (15,798) $ 46,482
(27,720) (17,896) $ 66,944
(11,160) 21,600 (1,710) $36,570
Year 2 $186,000 95,520 22,320 28,6652) $39,495 40% $15,798
Year 3 $221,760 127,800 27,720 21,4993) $44,741 40% $17,896
*Using FIFO: Year 1: 6,000 $14.40 = $86,400 Year 2: (1,000 $14.40) + (5,200 $15.60) = $95,520 Year 3: (1,300 $15.60) + (6,400 $16.80) = $127,800 Year 4: (100 $16.80) + (3,000 $18) = $55,680 (1/2) 0.25 $131,040 = $16,380 0.25 ($131,040 – $16,380) = $28,665 3)0.25 ($131,040 – $16,380 +$ 28,665)= $21,499 4)0.25 ($131,040 – ($16,380 + $28,665 + $21,499) – $21,600) = $10,724 1)
2)
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Year 4 $81,840 55,680 11,160 10,7244) $ 4,276 40% $ 1,710
Chapter 22
22‐31 (cont’d)
Year 0 Year 1 Year 2 Year 3 Year 4 Remaining CCA tax shield* Net present value
Relevant Cash Flows $(131,040) 35,352 46,482 66,944 36,570 7,847
Present‐Value Discount Total Factors Present at 16% Value 1.000 $(131,040) 0.862 30,473 0.743 34,536 0.641 42,911 0.552 20,187 0..552 4,331 $ 802
*(($131,040 – $16,380 – $28,665 – $21,499 – $10,724 – $21,600) 0.4) (0.25/(0.25 + 0.16)) = $7,847 The NPV for adding a new line of running shoes is a positive $802. Although the amounts arise in year 4, the income taxes are not filed until year 5. 22‐32 (40 min.) Mining, income taxes, inflation, sensitivity analysis. 1. Annual cash flow (Years 1‐5) Revenue ($490 4,800a) Cash‐operating costs Variable costs ($175 4,800) Technicians Maintenance Total operating cash costs Recurring operating cash flows Additional income taxes at 40% Recurring after‐tax operating cash flows each year for 5 years (excl. amort. effects)
$2,352,000
840,000 198,000 85,000
1,123,000 1,229,000 491,600
$ 737,400
400 troy lb × 12 ozt/lbt = 4,800 ozt
a)
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22‐32 (cont’d)
Year 1 2 3 4
CCA $540,000 918,000 642,600 449,820
Tax Shield $216,000 367,200 257,040 179,928
Operating Cash Flows $737,400 737,400 737,400 737,400
Total Cash Flows $ 953,400 1,104,600 994,440 917,328
Cumulative Cash Flows $ 953,400 2,058,000 3,052,440 3,969,768
Payback period = 3 + (($3,600,000 – $3,052,440)/$917,328) = 3.60 years 2.
The net present value of Sparkling Enterprises’ proposed acquisition of the extraction equipment is $31,796, as shown in the following calculation: Present‐Value Relevant Discount Total Cash Factors Present Flows at 12% Value Initial equipment investment $(3,600,000) 1.000 $(3,600,000) Recurring cash‐operating savings* 737,400 3.605 2,658,327 Tax shield created by CCA** 973,469 1.000 973,469 Net present value $ 31,796 *$1,229,000 (1 – 0.4) = $737,400 **(($3,600,000 0.4) 0.3/(0.3 + 0.12)) ((2 + 0.12) (2(1 + 0.12))) = $973,469
3.
In order for Sparkling Enterprises’ acquisition of the extraction equipment to break even from a net present‐value perspective, the revenue per ounce of gold must be at least $486.94, calculated as follows. 0 = –$3,600,000 + $973,469 + 3.605ozt ozt = $728,580 $728,580 = (4,800 (rev – $175) – $198,000 – $85,000) (1 – 0.4) rev = $486.94 Therefore, the minimum revenue per ounce is $486.94.
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Chapter 22
22‐32 (cont’d) 4.
Under the assumptions given here, requirement 2 has already calculated NPV using nominal cash flows and nominal rates of return. It has already taken inflationary effects into consideration. Hence no new calculations are necessary. The after‐tax net present value is $31,796 as calculated in requirement 2. Some students may question whether the assumptions specified in requirement 4 are appropriate since despite the 2% inflation per year, the revenues and cash‐operating costs are assumed to be the same each year for the 5 years. There is no inconsistency here. Despite the 2% increase in general price levels, the specific revenues per ounce of gold and the specific cash‐operating costs in this industry could well be the same either because of contractual reasons or because of the general economic conditions of supply and demand.
22‐33 (30 min.) Alternative approaches. 1. Use the total project approach because differential approach is more difficult to use when there are more than two options. 2. Present‐Value Relevant Cash Flows Option 1 Proceeds from disposal of plant $10,800,000 Lost tax shield because of disposal* (2,918,919) Net Present Value *(–$10,800,000 0.4) (0.25 / (0.25 + 0.12)) = –$2,918,919
Discount Factors at 12%
Total Present Value
1.000 1.000
$10,800,000 (2,918,919) $7,881,081
3.037 3.037 0.636 0.636
$5,247,936 1,036,467 1,526,400 (412,541) $7,398,262
Option 2 Recurring cash‐operating flows from rent* Discounts** Proceeds from disposal of plant Tax shield lost from terminal value*** Net Present Value
$1,728,000 341,280 2,400,000 (648,649)
*$240,000 12 (1 – 0.4) = $1,728,000 **$2,370,000 $2.40 0.1 (1 – 0.4) = $341,280 ***(–$2,400,000 0.4) (0.25 / (0.25 + 0.12)) = –$648,649
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22‐33 (cont’d) Option 3 Initial plant upgrade investment $(1,800,000) Tax shield created by CCA* 460,425 Recurring cash flows from manufacturing** Proceeds from disposal of plant 3,600,000 Tax shield lost from terminal value*** (972,973) Net Present Value
1.000 1.000 0.636 0.636
$(1,800,000) 460,425 4,526,856 2,289,600 (618,811) $ 4,858,070
*($1,800,000 0.4) (0.25/(0.25 + 0.12)) ((2 + 0.12)/2(1 + 0.12))) = $460,425
**Calculation:
Year (1) 1 2 3 4
Cash Inflow from Additional Cash Contribution Outflow for Net from Units Overhead Cash a Sold Costs Inflow (2) (3) (4)=(2)–(3) $2,160,000 $240,000 $1,920,000 3,240,000 240,000 3,000,000 4,320,000 240,000 4,080,000 1,080,000 240,000 840,000
Present‐ After‐Tax Cash Value Inflow from Discount Units Sold Factors at (5)=0.60 × (4) 12% $1,152,000 0.893 1,800,000 0.797 2,448,000 0.712 504,000 0.636
Total Present Value $1,028,736 1,434,600 1,742,976 320,544 $4,526,856
Contribution margin per unit = $50.40 – $24.96 – $7.68 – $6.96 = $10.80; ***(–$3,600,000 0.4) (0.25/(0.25 + 0.12)) = –$972,973 a
To maximize shareholder wealth, Waterford specialties should select Option 1, since it yields the highest net present value. 3.
Other nonfinancial and qualitative factors that Waterford should consider before making a decision are:
a.
The greater visibility Waterford Specialties Corporation would get from supplying souvenir jackets in the next Olympics. b. Strategic disadvantages of shutting down the plant or leasing it to Auburn, such as effect on worker morale. c. Reputational effects of being seen as a company that is quick to close down plants or lease them out rather than run them.
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Chapter 22
22‐34 (25 min.) Ranking of capital budgeting projects, alternative selection methods, capital rationing. 1.
2.
With no budget constraints, Firthing should use the net present‐value method for deciding which capital projects to include in the division’s capital budget submitted to Conglomerates Inc. This method will identify Projects A or D (mutually exclusive), B, E, and F as acceptable projects because each of these projects has a positive NPV. Project C is omitted because it has a negative net present value. Projects A and D are mutually exclusive, meaning that only one of these two projects can be pursued by Firthing. Since Project D has a higher NPV than Project A and since there are no budget constraints, Conglomerates should choose Project D over A. Firthing would select projects B, D, E, and F with an initial investment of $760,800 ($240,000 for B + $192,000 for D + $172,800 for E + $156,000 for F) and an NPV of $208,425 ($28,528 from B + $89,249 from D + $7,232 from E + $83,416 from F). The choice of these projects will maximize the value of these investments to Conglomerates. In a capital rationing situation, the goal is to maximize the total net present value for a group of projects. The capital investment projects Firthing should include in its capital expenditures budget if the budget is limited to (1) $540,000 or (2) $600,000 are presented below. a. Although other project combinations can be selected to utilize the $540,000 budget, the combination of Projects A, B, and F yields the greatest net present value when the excess budget monies are reinvested at the hurdle rate. This would lead to an investment of $523,200 ($127,200 for A + $240,000 for B + $156,000 for F) and an NPV of $195,564 ($83,620 from A + $28,528 from B + $83,416 from F). b. When the budget restriction is $600,000, the combination of Projects B, D, and F will yield the greatest net present value. This would lead to an investment of $588,000 ($240,000 for B + $192,000 for D + $156,000 for F) and an NPV of $201,193 ($28,528 from B + $89,249 from D + $83,416 from F). The excess present‐value index is a useful guide in making these choices. The highest excess present‐value indexes are those for projects A, F, D, and B. These are the most promising investments when faced with budget constraints. Of course A and D are mutually exclusive projects. NPV is maximized in our examples by including both B and F and then choosing D with its higher NPV if the budget permits (as in requirement 2b) or else going with A (as in requirement 2a).
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22‐35 (20 min.) NPV and inflation. 1. Without inflation or taxes this is a simple net present value problem, using a 10% discount rate Present value of initial investment, $(600,000) × 1.000 $(600,000) Present value of 6‐year annuity of annual cash savings ($140,000 × 4.355) 609,700 Net present value $ 9,700 2. With inflation, we adjust each year’s cash flow for the inflation rate to get nominal cash flows and then discount each cash flow separately using the nominal discount rate. Nominal rate = (1 + real rate) × (1 + inflation rate) −1 Nominal rate = (1.10)(1.055) −1 = 1.16 – 1 = .16 or 16% Present Value Cash Flow Cumulative Cash Inflows Inflation (Nominal Present Period (Real Dollars) Rate Dollars) Factor, 16% Value (4) (5) = (3) × (4) (1) (2) (3) = (1) × (2) 1 $140,000 1.055 $147,700 0.862 $127,317 2 140,000 1.1131 155,824 0.743 115,777 3 140,000 1.174 164,394 0.641 105,376 4 140,000 1.239 173,435 0.552 95,736 5 140,000 1.307 182,974 0.476 87,096 6 140,000 1.379 193,038 0.410 79,146 Total present value of annual net cash inflows in nominal 610,448 dollars Present value of initial investment, $(600,000) × 1.000 (600,000) Net present value $ 10,448 11.113 = (1.055)2 3. Both the unadjusted and adjusted NPV are positive. Based on financial considerations alone, Cost‐Less should buy the new cash registers. However, the effect of taxes should also be considered, as well as any pertinent non‐financial issues, such as potential improvements in customer response time from moving to the new cash registers.
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Chapter 22
22‐36 (35‐40 min.) NPV, inflation, and taxes. 1a. b.
Initial equipment investment Annual cash flow from operations Deduct income tax payments (0.30 × $140,000) Annual after‐tax cash flow from operations (excl. deprn. effects)
$(600,000) $140,000 42,000 $ 98,000
The terminal disposal price of the equipment is equal to the book value at disposal = $0, so these three amounts can be combined to determine the NPV at a 10% discount rate. Present value of net initial investment, $(600,000) × 1.000 $(600,000) Present value of 6‐year annuity annual after‐tax cash flow from operations, $98,000 × 4.355 426,790 Tax shield* $114,545 x 1.000 114,545 Net present value $ (58,665) *($600,000 0.3) (0.20/(0.20 + 0.10) ((2 + 0.10)/(2(1 + 0.10)) = $114,545 2. As in the previous problem, with inflation, we adjust each year’s cash flow for the inflation rate to get nominal cash flows and then discount each cash flow separately using the nominal discount rate. Nominal rate = (1 + real rate × (1 + inflation rate) – 1 = (1.10)(1.055) – 1 = 1.16 – 1 = 0.16 or 16%
Cumulative Cash Inflows Cash Flow Period (Real Dollars) Inflation Rate (Nominal Dollars) (1) (2) (3) = (1) × (2) 1
$140,000
1.055
$147,700
After‐Tax Cash Flows (4) = 0.7 × (3)
Present Value Factor, 16% Present Value (5) (6) = (4) × (5)
$103,390
0.862
$ 89,122
2
140,000
1.113
155,824
109,076
0.743
3
140,000
1.174
164,394
115,076
0.641
4
140,000
1.239
173,435
121,405
0.552
67,015
5
140,000
1.307
182,974
128,082
0.476
60,967
6
140,000
1.379
193,038
135,127
0.410
55,402
Total present value of annual net cash inflows
81,044 73,764
$ 427,314 114,545
Tax shield* $114,545 x 1.000 Present value of initial investment $(600,000) × 1.000
Net present value
$( 58,141)
(600,000)
*($600,000 0.3) (0.20/(0.20 + 0.10) ((2 + 0.10)/(2(1 + 0.10)) = $114,545
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22‐36 (cont’d) 3.
Without the effects of inflation, we get a negative net present value. When cash flows are adjusted for inflation, we again get a negative net present value. Using real data or nominal data will result in the same determination. Cost‐Less should not buy the new cash registers.
22‐37 (40‐50 min.) Governance, discounted cash‐flow analysis. Present‐Value Relevant Discount Total Cash Factors Present Flows at 12% Value Initial equipment investment $(1,275,000) 1.000 $(1,275,000) Initial working capital investment (260,000) 1.000 (260,000) Tax shield created by CCA* 293,521 1.000 293,521 † Cash flow from canceling lease (26,680) 1.000 (26,680) Additional working capital investment (240,000) 0.797 (191,280) Recurring rent cash flow forgone@ (38,400) 4.111 (157,862) # Recurring operating cash flows 1,531,393 Market research and sales promotion cash flows‡ (240,000) 0.893 (214,320) Recovery of working capital 500,000 0.507 253,500 Proceeds from disposal of equipment 360,000 0.507 182,520 § Lost tax shield from disposal (87,568) 0.507 (44,397) Net present value $ 91,395 *($1,275,000 0.36) (0.25/(0.25 + 0.12)) ((2 + 0.12)/(2(1 + 0.12))) = $293,521 †$42,000 (1 – 0.36) = $26,680 @$60,000 (1 – 0.36) = $38,400 #Recurring after‐tax cash‐operating flows ‡$375,000 (1 – 0.36) =$240,000 §($360,000 0.36) (0.25/(0.25 + 0.12)) =$87,568
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Chapter 22
22‐37 (cont’d) After‐Tax Present‐ Cash‐ Cash‐ Value Operating Operating Discount Total Year Flows Flows Factors Present at 12% Value (1) (2) (3) = 0.64 (2) 1 $480,000 $307,200 0.893 $ 274,330 2 480,000 307,200 0.797 244,838 3 720,000 460,800 0.712 328,090 4 720,000 460,800 0.636 293,069 5 720,000 460,800 0.567 261,274 6 400,000 256,000 0.507 129,792 $1,531,393 Crosslink should launch the new household product because investing in the product has a positive net present value. 2. Present‐Value Relevant Discount Total Cash Factors Present Flows at 12% Value Initial equipment investment $(1,680,000) 1.000 $(1,680,000) Initial working capital investment (260,000) 1.000 (260,000) Tax shield created by CCA* 386,757 1.000 386,757 Cash flow from cancelling lease** (26,880) 1.000 (26,880) Additional working capital investment (240,000) 0.797 (191,280) Recurring rent cash flow forgone*** (38,400) 4.111 (157,862) Recurring operating cash flows (see above) 1,531,393 Market research and sales promotion cash flows**** (240,000) 0.893 (214,320) Recovery of working capital 500,000 0.507 253,500 Proceeds from disposal of equipment 360,000 0.507 182,520 Lost tax shield from disposal***** (87,568) 0.507 (44,397) Net present value $ (220,569) *($1,680,000 0.36) (0.25/(0.25 + 0.12)) ((2 + 0.12)/(2(1 + 0.12))) = $386,757 **$42,000 (1 – 0.36) = $26,680 ***$60,000 (1 – 0.36) = $38,400 ****$375,000 (1 – 0.36) = $240,000 *****($360,000 0.36) (0.25/(0.25 + 0.12)) = $87,568
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22‐37 (cont’d) The overall NPV of the project would then be $(220,569). Marchand is unhappy with Ng’s revised analysis because the NPV of the project is now negative, possibly leading to the project being rejected. He would like to resume production in the plant, and reemploy his friends who had been laid off earlier. There is also the possibility that Marchand may be hired as a consultant by the new plant management after he retires next year. Considering the ethical issues, Ng should evaluate Marchand’s directives as follows: • Ng should present complete and clear reports and recommendations after appropriate analyses of relevant and reliable information. Marchand does not wish the report to be complete or clear, and has provided some information which is not totally reliable. • Ng should not disclose confidential information outside of the organization, but it also appears that Marchand wants to refrain from disclosing information to senior management that it should know about. • In evaluating Marchand’s directive as it affects Ng, Ng has an obligation to communicate unfavourable as well as favourable information and professional judgments or opinions. The responsibility to communicate information fairly and objectively, as well as to disclose fully all relevant information that could reasonably be expected to influence an intended user’s understanding of the reports and recommendations presented, is being hampered. Management will not have the full scope of information they should have when they are presented with the analysis. Ng should take the following steps to resolve this situation: • Ng should first investigate and see if Crosslink Inc. has an established policy for resolution of ethical conflicts and follow those procedures. • If this policy does not resolve the ethical conflict, the next step would be for Ng to discuss the situation with his supervisor, Marchand, and see if he can obtain resolution. One possible solution may be to present a “base case” and sensitivity analysis of the investment. Ng should make it clear to Marchand that he has a problem and is seeking guidance. • If Ng cannot obtain a satisfactory resolution with Marchand, he could take the situation up to the next layer of management, and inform Marchand that he is doing this. If this is not satisfactory, Ng should progress to the next, and subsequent, higher levels of management until the issue is resolved (i.e., the president, Audit Committee, or Board of Directors). • Ng may want to have a confidential discussion with an objective advisor to clarify relevant concepts and obtain an understanding of possible courses of action. • If Ng cannot satisfactorily resolve the situation within the organization, he may resign from the company and submit an informative memo to an appropriate person in Crosslink (i.e., the president, Audit Committee, or Board of Directors).
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Chapter 22
22‐38 (45‐60 min.) Introduction of new product, income taxes. Note: in parens it should say present value of annuity factor to clarify 1.
SFr. 720,000 = SFr. 240,000 (Present value of annuity factor 10 years)
(Present value of annuity factor 10 years) =
Thus IRR = 31%.
2.
Annual cash savings Taxes (240,000 – 72,000)0.45 After‐tax cash savings
720,000 = 164,400 (Present value of annuity factor 10 years)
(Present value of annuity factor 10 years) =
Thus IRR = 19%.
3.
After‐tax cash savings SFr. 164,400 Present value factor (10 years, 12%) 5.650 928,860 Initial investment 720,000 Net present value SFr. 208,860 Because the net present value is positive, Petrus should make the investment.
720, 000 = 3.0 240, 000
SFr. 240,000 75,600 164,400
720, 000 = 4.38 164, 400
4.
Annual Year Cash Savings 1 SFr. 240,000* 2 240,000 3 240,000 4 240,000 5 240,000 6 240,000 7 240,000 8 240,000 9 240,000 10 240,000
45% Taxes SFr. 0 64,800** 86,400*** 86,400 86,400 86,400 86,400 86,400 86,400 86,400
12% Present Present Net Value Factor Value SFr. 240,000 0.893 SFr. 214,320 175,200 0.797 139,634 153,600 0.712 109,363 153,600 0.636 97,690 153,600 0.567 87,091 153,600 0.507 77,875 153,600 0.452 69,427 153,600 0.404 62,054 153,600 0.361 55,450 153,600 0.322 49,459 Initial investment 962,363 Net present value 720,000 SFr. 358,283****
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22‐38 (cont’d) * 240,000 less 240,000 ** 240,000 less 96,000 0.45 ***240,000 less 48,000 0.45 **** Includes year 10 return of $360,000 × .322 = $115,920 5. Net present value (see #4 above) SFr. 358,283 Additional investment 360,000 Net present value SFr. (1,717) 6. Annual cash savings SFr. 240,000 Incremental taxes (240,000 – 24,000*) × 0.45 97,200 142,800 Present value factor (10 yrs., 12%) 5.650 806,820 Net investment 960,000 Net present value SFr. (153,180) *(720,000 – 240,000 – $240,000)/10 years = 24,000 7. Annual cash savings SFr. 240,000 Incremental taxes (240,000 – 48,000) × 0.45 86,400 153,600 Present value factor 5.650 867,840 Initial investment 1,200,000 Net present value SFr. (332,160) 8. There is a positive net present value of buying the new machine and thus it is advantageous to replace it now. 9. With an expected inflation rate of 4%, the discount factor should be reduced to 8%. Thus the present value factor in #7 above would be 6.710, which would increase the net present value to SFr. (169,344).
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Chapter 22
COLLABORATIVE LEARNING CASE
22‐39 (40 min.) Equipment replacement, income taxes, unequal project lives, 1.
governance. We use the total‐project approach to calculate the net present value of the decision to replace forklifts with the AMHS based on the original estimates Hatcher gave to Palmer. The NPV is $490,613 in favour of investing in the AMHS.
Investment in AMHS Present‐Value Relevant Discount Total Cash Factors Present Flows at 12% Value Initial AMHS investment $(5,490,500) 1.000 $(5,490,500) Initial working capital investment (1,125,000) 1.000 (1,125,000) Proceeds from disposal of forklift 155,000 1.000 155,000 Tax shield created by CCA* 1,442,763 1.000 1,442,763 Recurring operating cash flows** 864,000 5.650 4,881,600 Proceeds from disposal of AMHS 1,150,000 0.322 370,300 Tax shield loss because of disposal*** (328,571) 0.322 (105,800) Recovery of working capital 1,125,000 0.322 362,250 Net present value $ 490,613 *($5,490,500 – $155,000) 0.4) (0.3/(0.3 + 0.12)) ((2 + 0.12)/(2(1 + 0.12))) = $1,442,763 **$1,440,000 (1 – 0.4) = $864,000 Recurring cash operating flows equal: Increase in cash flow from higher sales revenue $840,000 Reduction in annual manufacturing costs over current costs 480,000 Reduction in annual maintenance costs over current costs 360,000 Increased annual operating costs over current costs (240,000) Recurring increased cash operating flows $1,440,000 ***($1,150,000 0.4) (0.3/(0.3 + 0.12)) = $328,571
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
22‐39 (cont’d) Keep Forklift Trucks Present‐Value Relevant Discount Total Cash Factors Present Flows at 12% Value 1a. Lease payment on forklift truck in year 9 $(105,000) Deduct income tax savings at 40% of $105,000 42,000 0.361 $(22,743) After‐tax cost of lease payment in year 9 $(63,000) 1b. Lease payment on forklift truck in year 10 $(105,000) Deduct income tax savings at 40% of $105,000 42,000 After‐tax cost of lease payment in year 10 $(63,000) Net present value of all cash flows
0.322
(20,286) $(43,029)
Net present value difference in favour of investment in AMHS ($490,613 – (–$43,029)) $533,642 2. The revised estimates of 8 years of useful life and $120,000 of estimated terminal disposal would result in a negative NPV of ($236,257). Investment in AMHS Present‐Value Relevant Discount Total Cash Factors Present Flows at 12% Value Initial AMHS investment $(5,490,500) 1.000 $(5,490,500) Initial working capital investment (1,125,000) 1.000 (1,125,000) Proceeds from disposal of forklift 155,000 1.000 155,000 Tax shield created by CCA* 1,442,763 1.000 1,442,763 Recurring operating cash flows** 864,000 4.968 4,292,352 Proceeds from disposal of AMHS 120,000 0.404 48,480 Tax shield loss because of disposal*** (34,286) 0.404 (13,852) Recover of working capital 1,125,000 0.404 454,500 Net present value $ (236,257) * ($5,490,500 – $155,000) 0.4) (0.3/(0.3 + 0.12)) ((2 + 0.12)/(2(1 + 0.12))) = $1,442,763 ** $1,440,000 (1 – 0.4) = $864,000 ***($120,000 0.4) (0.3/(0.3 + 0.12)) = $34,286.
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Chapter 22
22‐39 (cont’d) 3.
4.
Simon Palmer should evaluate Mark Hatcher’s directives as follows: • Palmer has a responsibility to present complete and clear reports and recommendations after appropriate analyses of relevant and reliable information. Hatcher does not wish the report to be complete or clear. • Palmer should not disclose confidential information outside of the organization, but it also appears that Hatcher wants to refrain from disclosing information to the Board that it should know about. • Hatcher is engaging in activities that could prejudice him from carrying out his duties ethically. • In evaluating Hatcher’s directive as it affects Palmer, Palmer has an obligation to communicate unfavourable as well as favourable information and professional judgments or opinions. • The responsibility to communicate information fairly and objectively, as well as to disclose fully all relevant information that could reasonably be expected to influence an intended user’s understanding of the reports and recommendations presented, is being hampered. The Board will not have the full scope of information that they should have when they are presented with the analysis. Simon Palmer should take the following steps to resolve this situation: • Palmer should first investigate and see if Modern Food Services (MFS) has an established policy for resolution of ethical conflicts and follow those procedures. • If such a policy does not resolve the ethical conflict, the next step would be for Palmer to discuss the situation with his supervisor, Hatcher, and see if he can obtain resolution. One possible solution may be to present a “base case” and sensitivity analysis of the investment. Palmer should make it clear to Hatcher that he has a problem and is seeking guidance. • If Palmer cannot obtain a satisfactory resolution with Hatcher, he could take the situation up to the next layer of management, and inform Hatcher that he is taking this action. If this approach is not satisfactory, Palmer should progress to the next, and subsequent, higher levels of management until the issue is resolved (i.e., the president, Audit Committee, or Board of Directors). • Since Hatcher has instructed him not to discuss the situation with anyone else at MFS, Palmer may want to have a confidential discussion with an objective advisor to clarify relevant concepts and obtain an understanding of possible courses of action. • If Palmer cannot satisfactorily resolve the situation within the organization, he may resign from the company and submit an informative memo to an appropriate person at MFS (i.e., the president, Audit Committee, or Board of Directors).
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22‐40 1.
Different methods, different ranking.
Project B Let F = Present‐value factor for an annuity of $1 for 10 years in Appendix A, Table 4 $120,000 = $24,000 F F = 5.000 for ten‐year life
The internal rate of return can be calculated by interpolation: Present‐Value Factors for Annuity of $1 for 10 Years 14% 5.216 5.216 IRR — 5.000 16% 4.833 — Difference 0.383 0.216 IRR = 14% + (0.216 / 0.383) (2%) = 15.1% Project C $240,000 = $84,000 F Let F = Present‐value factor for an annuity of $1 for 5 years in Appendix A, Table 4. F = 2.857 for five‐year life
The internal rate of return can be calculated by interpolation: Present‐Value Factors for Annuity of $1 for 5 Years 22% 2.864 2.864 IRR — 2.857 24% 2.745 — Difference 0.119 0.007 IRR = 22% + (0.007/0.119) (2%) = 22.1%
Project D $240,000 = PV of a four‐year annuity of $240,000 per year deferred five years
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Trial and error: At 18% $1 per year for 4 years 2.690 Multiply by $240,000, the total value of the annuity $645,600 Multiply by the present value of $1 five years hence 0.437 PV of annuity in arrears $282,127
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At 20% 2.589
At 22% 2.494
$621,360
$598,560
0.402 $249,787
0.370 $221,467
Chapter 22
22‐40 (cont’d) IRR = 20% + [(249,787 – 240,000) ÷ (249,787 – 221, 467)] (2%) = 20% = ($9,787 ÷ $28,320) (2%) = 20.69% = 20.7% Ranking of Projects Rank Project IRR Initial Investment 1 C 22.1% $240,000 2 D 20.7 240,000 3 B 15.1 120,000 4 A 14.0 120,000 5 E 12.6 240,000 6 F 12.0 60,000 2. Budget limit: $600,000 $660,000 $780,000 C C C D D D B B B F A F 3. Ranking by net present value, discounting at 16%: Rank Project Net Present Value 1 D $79,644 2 C 35,016 3 B (4,008) 4 F (4,061) 5 A (15,804) 6 E (43,156) Because 16% is the implicit reinvestment rate, these rankings are different from the rankings made on the basis of internal rates of return in requirement 1. Computations Project D PV of $240,000 per year for four years at 16% = $240,000 (2.798) $ 671,520 It is in arrears five years, so PV = $671,520 (0.476) 319,644 Net initial investment (240,000) Net present value $ 79,644 Project C PV of $84,000 per year for five years at 16% = $84,000 (3.274) $275,016 Net initial investment (240,000) Net present value $ 35,016
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22‐40 (cont’d) Project B PV of $24,000 per year for ten years at 16%= $24,000 (4.833) Net initial investment Net present value Project F PV at 16%: $27,600 × 0.862 24,000 × 0.743 12,000 × 0.641 12,000 × 0.552 Total PV Net initial investment Net present value Project A PV of annuity of $24,000 for 15 years = $24,000 × 5.575 Deduct deferral of 2 years = 24,000 × 1.605 PV of annuity in arrears PV of $12,000 due in 2 years = 12,000 × 0.743 Total PV Net initial investment Net present value Project E PV of annuity of $60,000 for 10 years = $60,000 × 4.833 Deduct deferral of 3 years = 60,000 × 2.246 PV of annuity in arrears PV of $36,000 due in 3 years = 36,000 × 0.641 PV of $18,000 due in 2 years = 18,000 × 0.743 PVof $6,000 due in 1 year = 6,000 × 0.862 Total PV Net initial investment Net present value
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$ 115,992 (120,000) $ (4,008)
$ 23,791 17,832 7,692 6,624 55,939 (60,000) $ (4,061)
$ 133,800 (38,520) 95,280 8,916 104,196 (120,000) $ (15,804)
$289,980 (134,760) 155,220 23,076 13,374 5,172 196,842 (240,000) $ (43,158)
Chapter 22
22‐40 (cont’d) 4.
Other influential factors include: (a) The risk linked with a given proposal may prompt management to judge it more or less attractive than other proposals that promise a comparable internal rate of return. (b) Future investment opportunities may affect the current relative attractiveness of alternative proposals. For example, if management expects that in five years hence the best available alternatives will bring less than 20%, Project D (which promises an internal rate of return of 20.7% for 9 years) may be preferable to Project C (which promises 22.1% for 5 years). However, if future opportunities are expected to bring equal or higher internal rates of return, a shorter‐lived project may be more attractive, even though a longer‐lived project may yield a higher rate of return. Thus, if a choice must be made now between E and F, Project F (12.0% for 4 years) may be chosen instead of Project E (12.6%, but it locks in capital for 10 years and necessitates a much larger investment).
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CHAPTER 23 TRANSFER PRICING AND MULTINATIONAL MANAGEMENT CONTROL SYSTEMS
SHORT‐ANSWER QUESTIONS 23‐1 A management control system is a means of gathering and using information to aid and coordinate the planning and control decisions throughout an organization and to guide the behaviour of its managers and employees. The goal of the system is to improve the collective decisions within an organization.
23‐2 To be effective, management control systems should be (a) closely aligned to an organizationʹs strategies and goals, (b) designed to support the organizational responsibilities of individual managers, and (c) able to motivate managers and employees to put in effort to attain selected goals desired by top management.
23‐3 Motivation combines goal congruence and effort. Motivation is the desire to attain a selected goal specified by top management (the goal‐congruence aspect) combined with the resulting pursuit of that goal (the effort aspect).
23‐4 The chapter cites five benefits of decentralization: 1. Creates greater responsiveness to local needs 2. Leads to gains from faster decision making 3. Increases motivation of subunit managers 4. Assists management development and learning 5. Sharpens the focus of subunit managers The chapter cites four costs of decentralization: 1. Leads to suboptimal decision making 2. Focuses managers’ attention on the subunit rather than the company as a whole 3. Increases costs of gathering information 4. Results in duplication of activities
23‐5 No. Organizations typically compare the benefits and costs of decentralization on a function‐by‐function basis. For example, companies with highly decentralized operating divisions frequently have centralized income tax strategies.
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Chapter 23
23‐6 No. A transfer price is the price one subunit of an organization charges for a product or service supplied to another subunit of the same organization. The two segments can be cost centres, profit centres, or investment centres. For example, the allocation of service department costs to production departments that are set up as either cost centres or investment centres is an example of transfer pricing.
23‐7 The three general methods for determining transfer prices are: 1. 2. 3.
Market‐based transfer prices Cost‐based transfer prices Negotiated transfer prices
23‐8 Transfer prices should have the following properties. They should 1. 2. 3. 4.
promote goal congruence, be useful for evaluating subunit performance, motivate management effort, and preserve a high level of subunit autonomy in decision making.
23‐9 No, the chapter illustration demonstrates how division operating incomes differ dramatically under the variable costs, full costs, and market price methods of transfer pricing.
23‐10 Transferring products or services at market prices generally leads to optimal decisions when (a) the market for the intermediate product market is perfectly competitive, (b) interdependencies of subunits are minimal, and (c) there are no additional costs or benefits to the company as a whole from buying or selling in the external market instead of transacting internally.
23‐11 One potential limitation of full‐cost‐based transfer prices is that they can lead to suboptimal decisions for the company as a whole. An example of a conflict between divisional action and overall company profitability resulting from an inappropriate transfer‐pricing policy is buying products or services outside the company when it is beneficial to overall company profitability to source them internally. This situation often arises where full‐cost‐based transfer prices are used. This situation can make the fixed costs of the supplying division appear to be variable costs of the purchasing division. Another limitation is that the supplying division may not have sufficient incentives to control costs if the full‐cost‐based transfer price uses actual costs rather than standard costs. The purchasing division sources externally if market prices are lower than full costs. From the viewpoint of the company as a whole, the purchasing division should source from outside only if market prices are less than variable costs of production, not full costs of production.
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23‐12 Reasons why a dual‐pricing approach to transfer pricing is not widely used in practice include: 1. In this approach, the manager of the supplying division uses a cost‐based method to record revenues and does not have sufficient incentives to control costs. 2. This approach does not provide clear signals to division managers about the level of decentralization top management wants. 3. This approach tends to insulate managers from the frictions of the marketplace because costs, not market prices, affect the revenues of the supplying division. 4. It leads to problems in computing the taxable income of subunits located in different tax jurisdictions.
23‐13 Yes. The general transfer‐pricing guideline specifies that the minimum transfer price equals the incremental cost per unit incurred up to the point of transfer plus the opportunity cost per unit to the supplying division. When the supplying division has idle capacity, its opportunity cost per unit is zero; when the supplying division has no idle capacity, its opportunity cost per unit is positive. Hence, the minimum transfer price will vary depending on whether the supplying division has idle capacity or not.
23‐14 Alternative transfer‐pricing methods can result in sizable differences in the reported operating income of divisions in different income tax jurisdictions. If these jurisdictions have different tax rates or deductions, the net income of the company as a whole can be affected by the choice of the transfer‐pricing method.
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Chapter 23
EXERCISES
23‐15
(10 min.) Terminology.
The CRA constrains global and provincial tax authorities constrain the interprovincial transfer pricing choice of management teams. A wise team will undertake an advance transfer price arrangement (APA) to avoid future tax liabilities. There are two interprovincial transfer‐price alternatives when no market‐based price exists. The alternatives are either cost‐based, which is a cost plus approach, or negotiated transfer prices that fall between a market and cost‐plus price. Of course a cost‐plus price may be either full absorption or variable cost ‐based and in the transfer the same company may use dual pricing. The transferring division charges at a cost‐based price while the receiving division pays at a market‐based price. The difference is billed to a common corporate account rather than to the divisions. This method reduces goal congruence problems between transferring divisions. There are three multinational corporate transfer price alternatives. The respective tax authorities scrutinize these related party transactions very carefully to ensure their jurisdictions receive the appropriate tax payments from each party in the transfer. The alternatives are the comparable uncontrolled price (CUP), resale price (RPM), cost‐plus (CPM), profit split (PSM) and transactional net margin method (TNMM). In addition to negotiating APA with governments corporations also minimize taxes by establishing legitimate subsidiaries in tax havens which share information with other governments.
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23‐16 (15 min.) Management control systems, balanced scorecard. Greystone follows a low‐cost strategy that emphasizes high quality, timeliness, and a multi‐skilled workforce. Accordingly, Greystone should adopt financial and non‐financial performance measures in its balanced scorecard that support this strategy. Examples of performance measures in each perspective are identified below. Revenue growth Operating income from productivity gain Financial perspective Operating income, EVA, ROI Gross margin percentage Growth in market share Customer satisfaction ratings Customer perspective Customer response time Number of customer complaints Number of new customers Yield Percent of defective tiles Internal‐business processes Manufacturing cycle efficiency perspective On‐time delivery Number of design and process changes made Employee turnover Employee satisfaction ratings Percent of employees trained in quality management Learning and growth perspective Hours of training Percent of compensation based on team incentives Information systems availability
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Chapter 23
23‐17 (15 min.) Decentralization, goal‐congruence, responsibility centres. 1.
The environmental‐management group appears to be decentralized because its managers have considerable freedom to make decisions. They can choose which projects to work on and which projects to reject. Top management will adjust the size of the environmental‐management group to match the demand for the group’s services by operating divisions.
2.
The environmental‐management group is a cost centre. The group is required to charge the operating divisions for environmental services at cost and not at market prices that would help earn the group a profit.
3.
The benefits of structuring the environmental‐management group in this way are: a. The operating managers have incentives to carefully weigh and conduct cost‐ benefit analyses before requesting the environmental group’s services. b. The operating managers have an incentive to follow the work and the progress made by the environmental team. c. The environmental group has incentives to fulfill the contract, to do a good job in terms of cost, time, and quality, and to satisfy the operating division to continue to get business. The problems in structuring the environmental‐management group in this way are: a. The contract requires extensive internal negotiations in terms of cost, time, and technical specifications. b. The environmental group needs to continuously “sell” its services to the operating division, and this could potentially result in loss of morale. c. Experimental projects that have long‐term potential may not be undertaken because operating division managers may be reluctant to undertake projects that are costly and uncertain, whose benefits will be realized only well after they have left the division. To the extent that the focus of the environmental‐management group is on short‐run projects demanded by the operating divisions, the current structure leads to goal congruence and motivation. Goal congruence is achieved because both operating divisions and the environmental‐management group are motivated to work toward the organizational goals of reducing pollution and improving the environment. The operating divisions will be motivated to use the
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23‐17 (cont’d) services of the environmental‐management group to achieve the environmental goals set for them by top management. The environmental‐management group will be motivated to deliver high‐quality services in a cost‐effective way to continue to create a demand for their services. The one issue that top management needs to guard against is that experimental projects with long‐term potential that are costly and uncertain may not be undertaken under the current structure. Top management may want to set up a committee to study and propose such long‐run projects for consideration and funding by corporate management.
23‐18 (25 min.) Cost centres, profit centres, decentralization. 1.
2. 3.
4.
23–1132
The Glass Department sends its product to the Wood and Metal Departments for finishing. The Glass Department does not negotiate internal prices. The Glass, Wood and Metal Departments are cost centres because they are only evaluated on output and cost control (cost variances). The three departments are centralized because upper management dictates their production schedules. A centralized department can be a profit centre. Centralization relates to the degree of autonomy that a department has for decision making. This concept is independent of the type of responsibility centre used to evaluate performance (for example the Glass Department could be a profit centre if upper management chooses a transfer price for the glass transferred from the Glass to the Wood and Metal Departments). A department may be organized as a profit centre but it will be centralized if it has little freedom in making decisions. a) With these changes, Fenster will be moving toward a more decentralized environment because each department will have more local decision‐making authority, such as the ability to set its own production schedule, buy and sell products in the external market and negotiate transfer prices. These changes also make all three departments profit centres (rather than cost centres) because the managers of each department are responsible for both costs and revenues. b) I would recommend that upper management evaluate the three departments as profit centres because profits would be a good indicator of how well each department is doing.
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Chapter 23
23‐19 (35 min.)
1.
Multinational transfer pricing, effect of alternative transfer‐ pricing methods, global income tax minimization.
This is a three‐country, three‐division transfer‐pricing problem with three alternative transfer‐pricing methods. Summary data in Canadian dollars are:
China Plant Variable costs: 1,000 Yuan ÷ 8 Yuan per $ = $125 per subunit Fixed costs: 1,800 Yuan ÷ 8 Yuan per $ = $225 per subunit South Korea Plant Variable costs: 360,000 Won ÷ 1,200 Won per $ = $300 per unit Fixed costs: 480,000 Won ÷ 1,200 Won per $ = $400 per unit U.S. Plant Variable costs: = $100 per unit Fixed costs: = $200 per unit Market prices for private‐label sale alternatives: China Plant: 3,600 Yuan ÷ 8 Yuan per $ = $450 per subunit South Korea Plant: 1,560,000 Won ÷ 1,200 Won per $ = $1,300 per unit The transfer prices under each method are:
a. Market price • China to South Korea = $450 per subunit • South Korea to U.S. Plant = $1,300 per unit b.
200% of full costs • China to South Korea 2.0 ($125 + $225) = $700 per subunit • South Korea to U.S. Plant 2.0 ($700 + $300 + $400) = $2,800 per unit
c. 300% of variable costs • China to South Korea 3.0 $125 = $375 per subunit • South Korea to U.S. Plant 3.0 ($375 + $300) = $2,025 per unit
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
23‐19 (cont’d)
Method A Internal Transfers at Market Price
1. China Division Division revenue per unit Cost per unit: Division variable cost per unit Division fixed cost per unit Total division cost per unit Division operating income per unit Income tax at 40% Division net income per unit 2. South Korea Division Division revenue per unit Cost per unit: Transferred‐in cost per unit Division variable cost per unit Division fixed cost per unit Total division cost per unit Division operating income per unit Income tax at 20% Division net income per unit Canadian Division Division revenue per unit Cost per unit: Transferred‐in cost per unit Division variable cost per unit Division fixed cost per unit Total division cost per unit Division operating income per unit Income tax at 30% Division net income per unit
$ 450 125 225 350 100 40 $ 60
$1,300 450 300 400 1,150 150 30 $ 120
$3,200 1,300 100 200 1,600 1,600 480 $1,120
Method B Internal Transfers at 200% of Full Costs $ 700 125 225 350 350 140 $ 210 $2,800 700 300 400 1,400 1,400 280 $1,120 $3,200 2,800 100 200 3,100 100 30 $ 70
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Method C Internal Transfers at 300$ of Variable Costs
$ 375 125 225 350 25 10 $ 15 $2,025 375 300 400 1,075 950 190 $ 760 $3,200 2,025 100 200 2,325 875 262.5 $ 612.5
Chapter 23
23‐19 (cont’d) 2.
Division net income: Market Price $ 60 120 1,120 $1,300
200% of Full Costs $ 210 1,120 70 $1,400
300% of Variable Cost $ 15.00 760.00 612.50 $1,387.50
China Division South Korea Division Canadian. Division User Friendly Computer, Inc. User Friendly will maximize its net income by using 200% of full costs as the transfer‐ price. This is because Method B sources the largest proportion of income in Korea, the country with the lowest income tax rate.
23‐20 (30 min.)
Transfer‐pricing methods, goal‐congruence.
1. Alternative 1: Sell as raw lumber for $200 per 100 board feet: Revenue $200 Variable costs 100 Contribution margin $100 per 100 board feet Alternative 2: Sell as finished lumber for $275 per 100 board feet: Revenue $275 Variable costs: Raw lumber $100 Finished lumber 125 225 Contribution margin $ 50 per 100 board feet British Columbia Lumber will maximize its total contribution margin by selling lumber in its raw form. An alternative approach is to examine the incremental revenues and incremental costs in the Finished Lumber Division: Incremental revenues, $275 – $200 $ 75 Incremental costs 125 Incremental loss $ (50) per 100 board feet
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
23‐20 (cont’d) 2.
Transfer price at 110% of variable costs: = $100 + ($100 0.10) = $110 per 100 board feet Sell as Raw Lumber $200 100 $100 $ 0 — $ 0
Sell as Finished Lumber $110 100 $ 10 $275 110 125 $ 40
Raw Lumber Division Division revenue Division variable costs Division operating income Finished Lumber Division Division revenue Transferred‐in costs Division variable costs Division operating income The Raw Lumber Division will maximize reported division operating income by selling raw lumber, which is the action preferred by the company as a whole. The Finished Lumber Division will maximize division operating income by selling finished lumber, which is contrary to the action preferred by the company as a whole. 3. Transfer price at market price = $200 per 100 board feet. Sell as Sell as Raw Lumber Finished Lumber Raw Lumber Division Division revenue $200 $200 Division variable costs 100 100 Division operating income $100 $100 Finished Lumber Division $ 0 $275 Division revenue — 200 Transferred‐in costs — 125 Division variable costs $ 0 $ (50) Division operating income
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Chapter 23
23‐20 (cont’d) Since the Raw Lumber Division will be indifferent between selling the lumber in raw or finished form, it would be willing to maximize division operating income by selling raw lumber, which is the action preferred by the company as a whole. The Finished Lumber Division will maximize division operating income by not further processing raw lumber and this is preferred by the company as a whole. Thus, transfer at market price will result in division actions that are also in the best interest of the company as a whole.
23‐21 (30 min.) Effect of alternative transfer‐pricing methods on division operating income.
Mining Division Revenue: $90, $661 200,000 units Costs: Division variable costs: $522 200,000 units Division fixed costs: $83 200,000 units Total division costs Division operating income Metals Division Revenues: $150 200,000 units Costs: Transferred‐in costs: $90, $66 200,000 units Division variable costs: $364 200,000 units Division fixed costs: $155 200,000 units Total division costs Division operating income
Method A Method B Internal Transfers Internal Transfers at at Market Prices 110% of Full Costs $18,000,000 $13,200,000 10,400,000 10,400,000 1,600,000 1,600,000 12,000,000 12,000,000 $ 1,200,000 $ 6,000,000 $30,000,000 $30,000,000 18,000,000 13,200,000 7,200,000 7,200,000 3,000,000 3,000,000 28,200,000 23,400,000 $ 6,600,000 $ 1,800,000
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23‐21 (cont’d) 1
$66 = Full manufacturing cost per unit in the Mining Division, $60 110%
2
Variable cost per unit in Mining Division = Direct materials + Direct manufacturing labour + 75% of manufacturing overhead = $12 + $16 + (75% $32) = $52
3
Fixed cost per unit = 25% of manufacturing overhead = 25%
$32 = $8
4
Variable cost per unit in Metals Division = Direct materials + Direct manufacturing labour + 40% of manufacturing overhead = $6 + $20 + (40% $25) = $36
5
Fixed cost per unit in Metals Division = 60% of manufacturing overhead = 60% $25 = $15 2. Bonus paid to division managers at 1% of division operating income will be as follows: Method A Method B Internal Transfers Internal Transfers at at Market Prices 110% of Full Costs Mining Division manager’s bonus (1% $6,000,000; 1% $1,200,000) $60,000 $ 12,000 Metals Division manager’s bonus (1% $1,800,000; 1% $6,600,000) 18,000 66,000 The Mining Division manager will prefer Method A (transfer at market prices) because this method gives $60,000 of bonus rather than $12,000 under Method B (transfers at 110% of full costs). The Metals Division manager will prefer Method B because this method gives $66,000 of bonus rather than $18,000 under Method A. 3. Brian Jones, the manager of the Mining Division, will appeal to the existence of a competitive market to price transfers at market prices. Using market prices for transfers in these conditions leads to goal congruence. Division managers acting in their own best interests make decisions that are also in the best interests of the company as a whole. Jones will further argue that setting transfer prices based on cost will cause Jones to pay no attention to controlling costs since all costs incurred will be recovered from the Metals Division at 110% of full costs.
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Chapter 23
23‐22 (30 min.) Transfer pricing, general guideline, goal‐congruence. 1.
2.
Using the general guideline presented in the chapter, the minimum price at which the Airbag Division would sell airbags to the Tivo Division is $90, the incremental costs. The Airbag Division has idle capacity (it is currently working at 80% of capacity). Therefore, its opportunity cost is zero—the Airbag Division does not forgo any external sales and as a result, does not forgo any contribution margin from internal transfers. Transferring airbags at incremental cost achieves goal congruence. Transferring products internally at incremental cost has the following properties: a. Achieves goal congruence—Yes, as described in requirement 1 above. b. Useful for evaluating division performance—No, because this transfer price does not cover or exceed full costs. By transferring at incremental costs and not covering fixed costs, the Airbag Division will show a loss. This loss, the result of the incremental cost‐based transfer price, is not a good measure of the economic performance of the subunit. c. Motivating management effort—Yes, if based on budgeted costs (actual costs can then be compared to budgeted costs). If, however, transfers are based on actual costs, Airbag Division management has little incentive to control costs. d. Preserves division autonomy—No. Because it is rule‐based, the Airbag Division has no say in the setting of the transfer price.
3.
If the two divisions were to negotiate a transfer price, the range of possible transfer prices will be between $90 and $125 per unit. The Airbag Division has excess capacity that it can use to supply airbags to the Tivo Division. The Airbag Division will be willing to supply the airbags only if the transfer price equals or exceeds $90, its incremental costs of manufacturing the airbags. The Tivo Division will be willing to buy airbags from the Airbag Division only if the price does not exceed $125 per airbag, the price at which the Tivo division can buy airbags in the market from external suppliers. Within the price range or $90 and $125, each division will be willing to transact with the other and maximize overall income of Quest Motors. The exact transfer price between $90 and $125 will depend on the bargaining strengths of the two divisions. The negotiated transfer price has the following properties. a. Achieves goal congruence—Yes, as described above.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
23‐22 (cont’d) b. Useful for evaluating division performance—Yes, because the transfer price is the result of direct negotiations between the two divisions. Of course, the transfer prices will be affected by the bargaining strengths of the two divisions. c. Motivating management effort—Yes, because once negotiated, the transfer price is independent of actual costs of the Airbag Division. Airbag Division management has every incentive to manage efficiently to improve profits. d. Preserves subunit autonomy—Yes, because the transfer price is based on direct negotiations between the two divisions and is not specified by headquarters on the basis of some rule (such as Airbag Division’s incremental costs). 4.
23–1140
Neither method is perfect, but negotiated transfer pricing (requirement 3) has more favourable properties than the cost‐based transfer pricing (requirement 2). Both transfer‐pricing methods achieve goal congruence, but negotiated transfer pricing facilitates the evaluation of division performance, motivates management effort, and preserves division autonomy, whereas the transfer price based on incremental costs does not achieve these objectives.
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Chapter 23
23‐23 (25 min.) 1.
2.
Multinational transfer pricing, global tax minimization.
Solution Exhibit 23‐23 shows the after‐tax operating incomes earned by the Canadian and Austrian divisions from transferring 1,000 units of Product 4A36 using (a) full manufacturing cost per unit, and (b) market price of comparable imports as transfer prices. There are many ways to proceed, but the first thing to note is that the transfer price that minimizes the total of company import duties and income taxes will be either the full manufacturing cost or the market price of comparable imports. Consider what happens every time the transfer price is increased by $1 over, say, the full manufacturing cost of $500. This results in the following:
a. an increase in Canadian. taxes of 40% $1 $0.400 b. an increase in import duties paid in Austria, 10% $1 0.100 c. a decrease in Austrian taxes of 44% $1.10 (the $1 increase in transfer price + $0.10 paid by way of import duty) (0.484) Net effect is an increase in import duty and tax payments of: $0.016 Hence, Zanello Company will minimize import duties and income taxes by setting the transfer price at its minimum level of $500, the full manufacturing cost.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
SOLUTION EXHIBIT 23‐23 Division Incomes of Canadian and Austrian Divisions from Transferring 1,000 Units of Product 4A36 Method A Method B Internal Transfers Internal Transfers at at Full Manufacturing Cost Market Price Canadian Division Revenue: $500, $650 1,000 units $650,000 $500,000 Costs: Full manufacturing cost: $500 1,000 units 500,000 500,000 Division operating income 0 150,000 Division income taxes at 40% 0 60,000 Division after‐tax operating income $ 0 $ 90,000 Austrian Division Revenue: $750 1,000 units $750,000 $750,000 Costs: Transferred‐in costs: $500 × 1,000, $650 × 1,000 units 500,000 650,000 Import duties at 10% of transferred‐ in price 50,000 65,000 $50 × 1,000, $65 × 1,000 units 550,000 715,000 Total division costs 200,000 35,000 Division operating income 88,000 15,400 Division income taxes at 44% $112,000 $ 19,600 Division after‐tax operating income Austrian Division Revenue, $750 1,000 units $750,000 Transferred in costs, $600 1,000 units 600,000 Import duties at 10% of transferred‐in price, $60 × 1,000 units 60,000 Division operating income 90,000 Division income taxes at 44% 39,600 Division after‐tax operating income $ 50,400 23–1142
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Chapter 23
23‐24 (40 min.)
Multinational transfer pricing, global tax minimization.
This is a two‐country two‐division transfer‐pricing problem with two alternative transfer‐pricing methods. Summary data in Canadian. dollars are: South Africa Mining Division Variable costs: 560 ZAR ÷ 7 = $80 per lb. of raw diamonds Fixed costs: 1,540 ZAR ÷ 7 = $220 per lb. of raw diamonds Market price: 3,150 ZAR ÷ 7 = $450 per lb. of raw diamonds Canadian Processing Division Variable costs = $150 per lb. of polished industrial diamonds Fixed costs = $700 per lb. of polished industrial diamonds Market price = $5,000 per lb. of polished industrial diamonds 1. The transfer prices are: a. 200% of full costs Mining Division to Processing Division = 2.0 × ($80 + $220) = $600 per lb. of raw diamonds b. Market price Mining Division to Processing Division = $450 per lb. of raw diamonds
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
23‐24 (cont’d)
2.
South Africa Mining Division Division revenue, $600, $450 4,000 Costs Division variable costs, $80 4,000 Division fixed costs, $220 4,000 Total division costs Division operating income Canadian Processing Division Division revenue, $5,000 2,000 Costs Transferred‐in costs, $600, $450 4,000 Division variable cost, $150 2,000 Division fixed costs, $700 2,000 Total division costs Division operating income
South Africa Mining Division Division operating income Income tax at 18% Division after‐tax operating income
Canadian. Processing Division Division operating income Income tax at 30% Division after‐tax operating income
200% of Full Cost $2,400,000 320,000 880,000 1,200,000 $1,200,000 $10,000,000 2,400,000 300,000 1,400,000 4,100,000 $ 5,900,000
200% of Full Cost $1,200,000 216,000 $ 984,000 $5,900,000 1,770,000 $4,130,000
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Copyright © 2013 Pearson Canada Inc.
Market Price $1,800,000 320,000 880,000 1,200,000 $ 600,000 $10,000,000 1,800,000 300,000 1,400,000 3,500,000 $ 6,500,000
Market Price $600,000 108,000 $492,000 $6,500,000 1,950,000 $4,550,000
Chapter 23
23‐24 (cont’d) 3.
South Africa Mining Division: After‐tax operating income Canadian Processing Division: After‐tax operating income Industrial Diamonds: After‐tax operating income
200% of Full Cost $ 984,000 4,130,000 $5,114,000
Market Price $ 492,000 4,550,000 $5,042,000
The South Africa Mining Division manager will prefer the higher transfer price of 200% of full cost and the Canadian Processing Division manager will prefer the lower transfer price equal to market price. Industrial Diamonds will maximize companywide net income by using the 200% of full cost transfer‐pricing method. This method sources more of the total income in South Africa, the country with the lower income tax rate. 4. Factors that executives consider important in transfer pricing decisions include: a. Performance evaluation b. Management motivation c. Pricing and product emphasis d. External market recognition Factors specifically related to multinational transfer pricing include: a. Overall income of the company b. Income or dividend repatriation restrictions c. Competitive position of subsidiaries in their respective markets
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
23‐25 (20 min.) Transfer‐pricing dispute. 1.
Company as a whole will not benefit if Division C purchases from external suppliers:
Purchase costs paid to external suppliers, 1,000 units $135 $135,000 Deduct: Savings in variable costs by reducing Division A output, 1,000 units $120 120,000 Net cost (benefit) to company as a whole as a result of purchasing from external suppliers $ 15,000 Any transfer price between $120 and $135 per unit will achieve goal congruence. Division managers acting in their own best interests will take actions that are in the best interests of the company as a whole. 2. Company as a whole will benefit if Division C purchases from external suppliers: Purchase costs paid to external suppliers, 1,000 units $135 $135,000 Deduct: Savings in variable costs, 1,000 units $120 $120,000 Savings due to A’s equipment and 138,000 facilities assigned to other operations 18,000 Net cost (benefit) to company as a whole as a result of purchasing from external suppliers $ (3,000) Division C should purchase from external suppliers. 3. Company as a whole will benefit if Division C purchases from external suppliers: Purchase costs paid to external suppliers, 1,000 units $115 $115,000 Deduct: Savings in variable costs by reducing Division A output, 1,000 units $120 120,000 Net cost (benefit) to company as a whole as a result of purchasing from external suppliers $ (5,000)
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Copyright © 2013 Pearson Canada Inc.
Chapter 23
23‐25 (cont’d) The three requirements are summarized below (in thousands): (1) (2) (3) Purchase costs paid to external suppliers $135 $135 $115 Relevant costs if purchased from Division A: Incremental (outlay) costs if purchased from Division A 120 120 120 Opportunity costs if purchased from Division A – 18 – 120 138 120 Total relevant costs if purchased from Division A Operating income advantage (disadvantage) to company as a result of purchasing from Division A $ 15 $ (3) $ (5) Goal congruence would be achieved if the transfer price is set equal to the total relevant costs of purchasing from Division A.
23‐26 (5 min.) Transfer‐pricing problem. The company as a whole would benefit in this situation if Division C purchased from external suppliers. The $15,000 disadvantage to the company as a whole as a result of purchasing from external suppliers would be more than offset by the $30,000 contribution margin of Division A’s sale of 1,000 units to other customers: Purchase costs paid to external suppliers, 1,000 units × $135 $135,000 Deduct variable cost savings, 1,000 units × $120 120,000 Net cost to the company as a result of purchasing from external suppliers $ 15,000 Division A’s sales to other customers, 1,000 units × $155 $155,000 Deduct: Variable manufacturing costs, $120 × 1,000 units $120,000 Variable marketing costs, $5 × 1,000 units 5,000 Total variable costs 125,000 Contribution margin from selling units to other customers $ 30,000
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
23‐27 (20min.) General guideline, transfer pricing. 1.
2.
3a.
3b.
3c.
23–1148
The minimum transfer price that the SD would demand from the AD is the net price it could obtain from selling its screens on the outside market: $120 minus $5 marketing and distribution cost per screen, or $115 per screen. The SD is operating at capacity. The incremental cost of manufacturing each screen is $80. Therefore, the opportunity cost of selling a screen to the AD is the contribution margin the SD would forego by transferring the screen internally instead of selling it on the outside market. Contribution margin per screen = $115 – $80 = $35 Using the general guideline, Incremental cost per Opportunity cost per Minimum transfer screen to the price per screen = screen inccurred up to + the point of transfer selling division = $80 + $35 = $115 The maximum transfer price the AD manager would be willing to offer SD is its own total cost for purchasing from outside, $120 plus $3 per screen, or $123 per screen. If the SD has excess capacity (relative to what the outside market can absorb), the minimum transfer price using the general guideline is: for the first 2,000 units (or 20% of output), $80 per screen because opportunity cost is zero; for the remaining 8,000 units (or 80% of output), $115 per screen because opportunity cost is $35 per screen. From the point of view of Shamrock’s management, all of the SD’s output should be transferred to the AD. This would avoid the $3 per screen variable purchasing cost that is incurred by the AD when it purchases screens from the outside market and it would also save the $5 marketing and distribution cost the SD would incur to sell each screen to the outside market. If the managers of the AD and the SD could negotiate the transfer price, they would settle on a price between $115 per screen (the minimum transfer price the SD will accept) and $123 per screen (the maximum transfer price the AD would be willing to pay). From requirements 1 and 2, we see that any price in this range would be acceptable to both divisions for all of the SD’s output, and would also be optimal from Shamrock’s point of view. The exact transfer price between $115 and $123 will depend on the bargaining strengths of the two divisions. Of course, Shamrockʹs management could also mandate a particular transfer price between $115 and $123 per screen.
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Chapter 23
23‐28 (20–30 min.) Pertinent transfer price.
This problem explores the “general transfer‐pricing guideline” discussed in the chapter. 1. No, transfers should not be made to Division B if there is no unused capacity in Division A. An incremental (outlay) cost approach shows a positive contribution for the company as a whole: $300 Selling price of final product Incremental cost per unit in Division A $120 Incremental cost per unit in Division B 150 270 Contribution margin per unit $ 30
However, if there is no excess capacity in Division A, any transfer will result in diverting products from the market for the intermediate product. Sales in this market result in a greater contribution for the company as a whole. Division B should not assemble the bicycle since the incremental revenue Europa can earn, $100 per unit ($300 from selling the final product – $200 from selling the intermediate product) is less than the incremental cost of $150 to assemble the bicycle in Division B. Alternatively, Europa’s contribution margin from selling the intermediate product exceeds Europa’s contribution margin from selling the final product:
Selling price of intermediate product $200 Incremental (outlay) cost per unit in Division A 120 Contribution margin per unit $ 80
Using the general guideline described in the chapter, Minimum transfer price
Additional incremental cos t Opportunity cos t + per unit to the = per unit incurred up to the point of transfer supplying division = $120 + ($200 – $120) = $200, which is the market price
The market price is the transfer price that leads to the correct decision; that is, do not transfer to Division B unless there are extenuating circumstances for continuing to market the final product. Therefore, Division B must either drop the product or reduce the incremental costs of assembly from $150 per bicycle to less than $100 (selling price, $300 – transfer price, $200).
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23‐28 (cont’d) 2.
3.
23–1150
If (a) A has excess capacity, (b) there is intermediate external demand for only 800 units at $200, and (c) the $200 price is to be maintained, then the opportunity costs per unit to the supplying division are $0. The general guideline indicates a minimum transfer price of: $120 + $0 = $120, which is the incremental or outlay costs for the first 200 units. B would buy 200 units from A at a transfer price of $120 because B can earn a contribution of $30 per unit [$300 – ($120 + $150)]. In fact, B would be willing to buy units from A at any price up to $150 per unit because any transfers at a price of up to $150 will still yield B a positive contribution margin. Note, however, that if B wants more than 200 units, the minimum transfer price will be $200 as computed in requirement 1 because A will incur an opportunity cost in the form of lost contribution of $80 (market price, $200 – outlay costs of $120) for every unit above 200 units that are transferred to B. The following schedule summarizes the transfer prices for units transferred from A to B: Units 0–200 200–1,000
Transfer Price $120–$150 $200
For an exploration of this situation when imperfect markets exist, see the next problem. Division B would show zero contribution, but the company as a whole would generate a contribution of $30 per unit on the 200 units transferred. Any price between $120 and $150 would induce the transfer that would be desirable for the company as a whole. A motivational problem may arise regarding how to split the $30 contribution between Division A and B. Unless the price is below $150, B would have little incentive to buy.
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Chapter 23
23‐28 (cont’d) Note: The transfer price that may appear optimal in an economic analysis may, in fact, be totally unacceptable from the viewpoints of (1) preserving autonomy of the managers, and (2) evaluating the performance of the divisions as economic units. For instance, consider the simplest case discussed previously, where there is idle capacity and the $200 intermediate price is to be maintained. To direct that A should sell to B at A’s variable cost of $120 may be desirable from the viewpoint of B and the company as a whole. However, the autonomy (independence) of the manager of A is eroded. Division A will earn nothing, although it could argue that it is contributing to the earning of income on the final product. If the manager of A wants a portion of the total company contribution of $30 per unit, the question is: How is an appropriate amount determined? This is a difficult question in practice. The price can be negotiated upward to somewhere between $120 and $150 so that some “equitable” split is achieved. A dual transfer‐pricing scheme has also been suggested, whereby the supplier gets credit for the full intermediate market price and the buyer is charged with only variable or incremental costs. In any event, when there is heavy interdependence between divisions, such as in this case, some system of subsidies may be needed to deal with the three problems of goal congruence, management effort, and subunit autonomy. Of course, where heavy subsidies are needed, a question can be raised as to whether the existing degree of decentralization is optimal.
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23‐29 (30–40 min.) Pricing in imperfect markets. An alternative presentation, which contains the same numerical answers, can be found at the end of this solution. 1.
Potential contribution from external intermediate sale is 1,000 ($195 – $120) Contribution through keeping price at $200 is 800 $80. Forgone contribution by transferring 200 units
$75,000 64,000 $11,000
Opportunity cost per unit to the supplying division by transferring internally:
$11,000 = $55 200
Transfer price = $120 + $55 = $175 An alternative approach to obtaining the same answer is to recognize that the incremental or outlay cost is the same for all 1,000 units in question. Therefore, the total revenue desired by A would be the same for selling outside or inside. Let X equal the transfer price at which Division A is indifferent between selling all units outside versus transferring 200 units inside.
1,000 $195 = (800 $200) + 200X X = $175
The $175 price will lead to the correct decision. Division B will not buy from Division A because its total costs of $175 + $150 will exceed its prospective selling price of $300. Division A will then sell 1,000 units at $195 to the outside; Division A and the company will have a contribution margin of $75,000. Otherwise, if 800 units were sold at $200 and 200 units were transferred to Division B, the company would have a contribution of $64,000 plus $6,000 (200 units of final product $30), or $70,000. A comparison might be drawn regarding the computation of the appropriate transfer prices between the preceding problem and this problem: Additional incremental cos t Opportunity cos t Minimum + = per unit incurred up per unit to transfer price to the point of transfer Division A
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Chapter 23
23‐29 (cont’d)
Perfect markets: = $120 + (Selling price – Outlay costs per unit) = $120 + ($200 – $120) = $200 Marginal revenues – Outlay costs Number of units transferred
Imperfect markets: = $120 +
= $120 +
$35,000 a $24,000 b = $175 200
a
Marginal revenue of Division A from selling 200 units outside rather than transferring to Division B = ($195 1,000) – ($200 800) = $195,000 – $160,000 = $35,000. b Incremental (outlay) costs incurred by Division A to produce 200 units = $120 200 = $24,000. Therefore, selling price ($195) and marginal revenues per unit ($175 = $35,000 ÷ 200) are not the same. The following discussion is optional. These points should be explored only if there is sufficient class time: Some students may erroneously say that the “new” market price of $195 is the appropriate transfer price. They may claim that the general guideline says that the transfer price should be $120 + ($195 – $120) = $195, the market price. This conclusion assumes a perfect market. However, in this case there are imperfections in the intermediate market. That is, the market price is not a good approximation of alternative revenue. If a division’s sales are heavy enough to reduce market prices, marginal revenue will be less than market price. It is true that either $195 or $175 will lead to the correct decision by B in this case. But suppose that B’s variable costs were $120 instead of $150. Then B would buy at a transfer price of $175 (but not at a price of $195, because then B would earn a negative contribution of $15 per unit [$300 – ($195 + $120)]. Note that if B’s variable costs were $120, transfers would be desirable:
Division A contribution is: [800 ($200 – $120)] + [200 ($175 – $120)] Division B contribution is: 200 [$300 – ($175 + $120)] Total contribution
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$75,000 1,000 $76,000
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
23‐29 (cont’d)
Or the same facts can be analyzed for the company as a whole: Sales of intermediate product, = $64,000 800 ($200 – $120) Sales of final products, 200 [300 – ($120 + $120)] = 12,000 Total contribution $76,000 If the transfer price were $195, B would not accept the transfer and would not earn any contribution. As shown above, Division A and the company as a whole will earn a total contribution of $75,000 instead of $76,000. 2a. Division A can sell 900 units at $195 to the outside market and 100 units to Division B, or 800 at $200 to the outside market and 200 units to Division B. Note that, under both alternatives, 100 units can be transferred to Division B at no opportunity cost to A. Using the general guideline, the minimum transfer price of the first 100 units [901–1000] is: TP1 = $120 + 0 = $120
If Division B needs 100 additional units, the opportunity cost to A is not zero, because Division A will then have to sell only 800 units to the outside market for a contribution of 800 ($200 – $120) = $64,000 instead of 900 units for a contribution of 900 ($195 – $120) = $67,500. Each unit sold to B in addition to the first 100 units has an opportunity cost to A of ($67,500 – $64,000) ÷ 100 = $35. Using the general guideline, the minimum transfer price of the next 100 units [801–900] is: TP2 = $120 + $35 = $155
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Chapter 23
23‐29 (cont’d)
2b.
Alternatively, the computation could be: Increase in contribution from 100 $7,500 more units, 100 $75 Loss in contribution on 800 units, 800 ($80 $75) 4,000 Net ʺmarginal revenueʺ $3,500 ÷ 100 units = $35 (Minimum) transfer price applicable to first 100 units offered by A is $120 + $0 = $120 per unit (Minimum) transfer price applicable to next 100 units offered by A is $120 + ($3,500 ÷ 100) = $155 per unit (Minimum) transfer price applicable to next 800 units = $195 per unit The manager of Division B will not want to purchase more than 100 units because the units at $155 would decrease his contribution ($155 + $150 > $300). Because the manager of Division B does not buy more than 100 units, the manager of Division A will have 900 units available for sale to the outside market. The manager of Division A will strive to maximize the contribution by selling them all at $195. This solution maximizes the companyʹs contribution: 900 ($195 – $120) = $67,500 100 ($300 – $270) = 3,000 $70,500 which compares favourably to: 800 ($200 – $120) 200 ($300 – $270)
= $64,000 = 6,000 $70,000
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
23‐29 (cont’d) ALTERNATIVE PRESENTATION (by James Patell) 1. Company Viewpoint a: Sell 1,000 units outside at $195 per unit b: Sell 800 units outside at $200 per unit, transfer 200 Price $195 Transfer price $200 Variable cost per unit 120 Variable cost per unit 120 Contribution $ 80 800 = $64,000 Contribution $ 75 1,000 = $75,000 Total contribution given up if transfer occurs* = $75,000 – $64,000 = $11,000 On a per‐unit basis, the relevant costs are: Incremental cost per unit incurred up to + Opportunity cost per unit = Transfer price to Division A the point of transfer $11,000 $120 + = $175 200 By formula, costs are: Lost opportunity to Increment cost per unit Gain when 1st 800 units incurred up to point + sell 200 units at $195 per unit, – sell at $200 per unit for contribution of $75 per unit instead of $195 per unit to transfer 200 $75 ($200 $195) 800 = $120 + – 200 200 = $120 + $75 – $20 = $175 *Contribution of $30 per unit by B is not given up if transfer occurs, so it is not relevant here. 2a. At most, Division A can sell only 900 units and can produce 1,000. Therefore, at least 100 units should be transferred at a transfer price no less than $120. The question is whether or not a second 100 units should be transferred:
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Chapter 23
23‐29 (cont’d) Company Viewpoint a: Sell 900 units outside at $195 per unit b: Sell 800 units outside at $200 per unit, transfer 100 Transfer price $195 Transfer price $200 Variable cost per unit 120 Variable cost per unit 120 $ 80 800 = $64,000 Contribution $ 75 900 = $67,500 Contribution Total contribution forgone if transfer of 100 units occurs = $67,500 – $64,000 = $3,500 (or $35 per unit) Incremental cost per unit Opportunity cost per unit = Transfer price incurred up to point of transfer + to Division A $120 + $35 = $155 2b. By formula: Lost opportunity to Incremental cost per unit Gain when 1st 800 units incurred up to point + sell 100 units at $195 per unit, – sell at $200 per unit for contribution of $75 per unit instead of $195 per unit of transfer 100 $75 [($200 $195) 800] = $120 + – 100 100 = $120 + $75 – $40 = $155 Transfer Price Schedule (minimum acceptable transfer price): Units Transfer Price 0–100 $120 101–200 $155 201–1,000 $195
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
PROBLEMS 23‐30 (30–35 min.) Effect of alternative transfer‐pricing methods on division operating income. 1. Kilograms of cranberries harvested Litres of juice processed (1,900 l. per 1,000 kg.) Revenue (344,736 l. $0.55263 per l.) Costs Harvesting Division Variable costs (181,440 kg. $0.2205 per kg.) Fixed costs (181,440 kg. $0.5511 per kg.) Total Harvesting Division costs Processing Division Variable costs (344,736 l.. $0.05263 per .l.) Fixed costs (344,736 l. $0.1053 per l.) Total Processing Division costs Total costs Operating income
23–1158
181,440 344,736 $190,511 $ 40,008 99,992
140,000 $ 18,143 36,301
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54,444 194,444 ($3,933)
Chapter 23
23‐30 (cont’d) 2. 200% of Full Costs
Market Price
Transfer price per kilogram (($0.2205 + $0.5511) 2; $1.3228) $1.5432 $1.3228 1. Harvesting Division Revenue (181,440 kg. $1.5432; $1.3228) $279,998 $240,009 Costs Division variable costs (181,440 l. $0.2205 per kg.) 40,008 40,008 Division fixed costs (181,440l. $0.5511 per kg.) 99,992 99,992 Total division costs 140,000 140,000 Division operating income $139,998 $100,009 Harvesting Division managerʹs bonus (5% of operating income) $7,000 $5,000 2. Processing Division $190,511 $190,511 Revenue (344,736 l. $0.55263 per l.) Costs Transferred‐in costs 279,998 240,009 Division variable costs (344,736 l. $0.05263 per l.) 18,143 18,143 Division fixed costs (344,736 l. $0.1053 per l.) 36,301 36,301 Total division costs 334,442 294,453 Division operating income $ (143,931) $ (103,942) Processing Division manager’s bonus (5% of operating income) $0 $0 3. Bonus paid to division managers at 5% of division operating income is computed above and summarized below: Internal Transfers Internal at 200% of Full Transfers Costs at Market Prices Harvesting Division manager’s bonus (5% × $139,998; 5% × $100,009) $7,000 $5,000 Processing Division manager’s bonus (5% × $0; 5% × $0) $0 $0
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
23‐30 (cont’d) The Harvesting Division manager will prefer to transfer at 200% of full costs because this method gives a higher bonus. The Processing Division manager will be indifferent since neither transfer cost results in positive operating income but would likely prefer the market price since it results in a lower operating loss. Crango may resolve or reduce transfer pricing conflicts by: Basing division managers’ bonuses on overall Crango profits in addition to division operating income. This will motivate each manager to consider what is best for Crango overall and not be concerned with the transfer price alone. Letting the two divisions negotiate the transfer price between themselves. However, this may result in constant re‐negotiation between the two managers each accounting period. Using dual transfer prices However, a cost‐based transfer price will not motivate cost control by the Harvesting Division manager. It will also insulate that division from the discipline of market prices.
23‐31 (25 min.) Goal‐congruence problems with cost‐plus transfer‐pricing methods, dual‐pricing system. 1.
Two examples of goal congruence problems that arise if a transfer price of 200% of full costs is mandated and Borges’ decentralization policy is adopted are: a. The Processing Division manager will prefer to buy cranberries from an external supplier at $1.3228 per kilogram, incurring some extra purchasing costs and lowering Crane’s overall operating income. Crango will incur costs of $1.3228 per kilogram and save variable costs of only $0.2205 per kilogram. b. The Harvesting Division manager is forced to sell to an outside purchaser (because the Processing Division prefers to purchase from an external supplier) when it is better for Crango Products to process internally.
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Chapter 23
23‐31 (cont’d) 2.
Transfer into buying division at market price Harvesting Division to Processing Division = $1.3228 per kilogram of cranberries Transfer out of selling division at 200% of full costs Harvesting Division to Processing Division = 2.0 × ($0.2205 + $0.5511) = $1.5432 per kilogram of cranberries
As calculated in Requirement 2 of 23‐30 and also shown below, under the dual transfer‐pricing policy, the Harvesting Division will earn an operating income of $140,000 and the Processing Division will earn an operating income of $(103,932). Harvesting Division Revenue (181,440 kg. $1.5432 per kg.) Costs Division variable costs (181,440 kg. $0.2205 per kg.) Division fixed costs (181,440 kg. $0.5511 per kg.) Total division costs Division operating income Processing Division Revenues (344,736 l. $0.55263 per l.) Costs Transferred in costs Division variable costs (344,736 l. $0.05263 per l.) Division fixed costs (344,736 l. $0.1053 per l.) Total division costs Division operating income
200% of Full Costs
Market Price
$279,998 40,008 99,992 140,000 $139,998
$190,511 240,009 18,143 36,301 294,453 $ (103,942)
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
23‐31 (cont’d) 3.
Under the dual transfer pricing policy,
Harvesting Division Processing Division Crango Products
Division Operating Income
$139,998 (103,942) $ 36,056
The overall company operating income from harvesting and processing 400,000 kilograms of cranberries is ($3,933) (see Problem 23‐30, requirement 1). A dual transfer‐pricing method entails using different transfer prices for transfers into the buying division and transfers out of the supplying division. As a result, the sum of division operating incomes does not equal the total company operating income. 4.
Problems which may arise if Crango Products uses the dual transfer‐pricing system include: a. It may reduce the incentives of the supplying division to control costs since every $1 of cost of the supplying division is transferred out to the buying division at $2.00. b. A dual transfer‐pricing system does not provide clear signals to the individual divisions about the level of decentralization top management seeks. c. It insulates the Harvesting Division manager from the frictions and the discipline of the marketplace because costs, not market prices, affect the revenue of the supplying division.
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Chapter 23
23‐32 (4050 min.) Transfer pricing, utilization of capacity. 1. Super‐chip Okay‐chip Selling price $60 $12 Direct material cost per unit 2 1 Direct manufacturing labour cost per unit 28 7 Contribution margin per unit $30 $ 4 Contribution margin per hour ($30 2; $4 0.5) $15 $ 8 Because the contribution margin per hour is higher for Super‐chip than for Okay‐ chip, OVIC should produce and sell as many Super‐chips as it can and use the remaining available capacity to produce Okay‐chip. The total demand for Super‐chips is 15,000 units, which would take 30,000 hours (15,000 2 hours per unit). OVIC should use its remaining capacity of 20,000 hours (50,000 – 30,000) to produce 40,000 Okay‐chips (20,000 0.5). 2. Options for manufacturing process‐control unit: Using Using Circuit Board Super‐chip Selling price $132 $132 Direct material cost per unit 60 2 Direct manufacturing labour cost per unit (Super‐chip) 0 28 60 Direct manufacturing labour cost per unit (process‐control unit) 50 Contribution margin per unit $ 22 $ 42
Overall Company Viewpoint Alternative 1: No Transfer of Super‐chips: Sell 15,000 Super‐chips at contribution margin per unit of $30 $450,000 Transfer 0 Super‐chips 0 Sell 40,000 Okay‐chips at contribution margin per unit of $4 160,000 Sell 5,000 Control units at contribution margin per unit of $22 110,000 Total contribution margin $720,000 Alternative 2: Transfer 5,000 Super‐chips to Process‐Control Division. These Super‐chips would require 10,000 hours to manufacture, leaving only 10,000 hours for the manufacture of 20,000 Okay‐chips (10,000 0.5):
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
23‐32 (cont’d) Sell 15,000 Super‐chips at contribution margin per unit of $30 $450,000 Transfer 5,000 Super‐chips to Process‐Control Division 0 Sell 20,000 Okay‐chips at contribution margin per unit of $4 80,000 Sell 5,000 Control units at contribution margin per unit of $42 210,000 Total contribution margin $740,000 OVIC is better off transferring 5,000 Super‐chips to the Process‐Control Division. 3. For each Super‐chip that is transferred, two hours of time (labour capacity) are given up in the Semiconductor Division, and, in those two hours, four Okay‐ chips could be produced, each contributing $4. Incremental cost Minimum transfer price Opportunity cost per unit for = + the Semiconductor Division per unit to per Super - chip the point of transfer = $30 + $16 = $46 per unit If the selling price for the process‐control unit were firm at $132, the Process‐ Control Division would accept any transfer price up to $50 ($60 price of circuit board $10 incremental labour cost if Super‐chip used). However, consider what happens if the transfer price of Super‐chip is set at, say, $49, and the price of the control unit drops to $108. From OVIC’s viewpoint: Using Using Circuit Board Using Super‐chip Selling price $108 $108 Direct material cost per unit 60 49 60 Direct manufacturing labour cost per unit 50 Contribution margin per unit $ –2 $ –1 Process‐Control Division will not produce any control units. From the company’s viewpoint, the contribution margin on the control unit if the Super‐chip is used is: Selling price $108 Direct material cost per unit 2 Direct manufacturing labour cost per unit (Super‐chip) 28 Direct manufacturing labour cost per unit (process‐control unit) 60 Contribution margin per unit $ 18
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Chapter 23
23‐32 (cont’d) The contribution margin per unit from producing Super‐chips for the process‐control unit exceeds the contribution margin of $16 from producing 4 Okay‐chips, each yielding a contribution margin of $4 per unit. Therefore, the Semiconductor Division should transfer 5,000 Super‐chips as the following calculations show: Alternative 1—No transfer (and, therefore, no sales of process‐control units): Sell 15,000 Super‐chips at contribution margin per unit of $30 $450,000 Sell 40,000 Okay‐chips at contribution margin per unit of $4 160,000 $610,000 Alternative 2—Transfer 5,000 Super‐chips: Sell 15,000 Super‐chips at contribution margin per unit of $30 $450,000 Sell 20,000 Okay‐chips at contribution margin per unit of $4 80,000 Sell 5,000 control units at contribution margin per unit of $18 90,000 $620,000 So, if the price for the control unit is uncertain, the transfer price must be set at the minimum acceptable transfer price of $46. 4. For a transfer of any amount between 0 and 10,000 Super‐chips (which require 2 hours each to produce), the opportunity cost is the production of Okay‐chips (which require ½ hour each). In this range, the relevant costs are equal to the transfer price of $46 established in part 3. If more than 10,000 Super‐chips are transferred, the opportunity cost becomes the sale of Super‐chips on the outside market. Now the minimum transfer price per Super‐ chip becomes: Incremental Opportunity cost per Super - cost per Super chip up to the + chip to the = $30 + ($60 – $30) = $60, the market price. point of Semiconductor transfer Division At this transfer price, it is cheaper for the Process‐Control Division to buy the circuit board for $60, since $10 of additional direct manufacturing labour cost is saved. The Semiconductor Division should at most transfer 10,000 Super‐chips: Internal Demand Transfer Price 0–10,000 $46 10,000–25,000 60
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
23‐33 (30–40 min.) International transfer pricing, taxes, goal‐congruence. 1.
2.
3a.
The minimum transfer price would be $82 to cover the variable production ($80 per unit) and shipping ($2 per unit) costs, because Calcia would want at a minimum zero contribution margin. The opportunity cost is $0 because there are no external customers for IP‐2007. The maximum transfer price would be the $100 market price that Argone would need to pay to acquire a product similar to IP‐2007 from the external market in the United States. To minimize income taxes, Gemini should use a transfer price of $82. Canada has a higher tax rate so goods coming from Canada should have the lowest transfer price. Calcia would not like a transfer price of $82 because it would report no operating income from the transfer. Argone would like a transfer price of $82 because it is lower than the outside market price of $100. Calcia’s after‐tax income on each unit from accepting the special order is: Revenue per unit $95.00 Variable cost per unit 80.00 Contribution margin per unit 15.00 Income taxes (0.38 × $15) 5.70 Increase in division income per unit after $ 9.30 tax It is easiest to see the solution to this problem if we assume a selling price for the product that Argone manufactures, for example, $150. (The actual selling price you choose is irrelevant.) Argone’s after‐tax income on each unit if Calcia accepts the special order and Argone buys the substitute product for IP‐2007 in the United States for $100 per unit is:
Revenue per unit Variable cost per unit Contribution margin per unit Income taxes (0.20 × $50) Increase in division income per unit after tax
23–1166
$150 100 50 10 $ 40
Gemini’s net income on each unit from Calcia accepting the special order is $9.30 + $40 = $49.30. If Calcia rejects the special order and instead transfers the units internally to Argone at $82 per unit, Calcia’s after‐tax income would be:
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Chapter 23
23‐33 (cont’d) Revenue per unit Variable cost per unit Contribution margin per unit Income taxes Increase in division income per unit after tax
3b. 3c.
3d.
Argone’s after‐tax income on each unit is: Revenue per unit Variable cost per unit Contribution margin per unit Income taxes (0.20 × $68) Increase in division income per unit after tax
$82 82 0 0 $ 0
$150.00 82.00 68.00 13.60 $ 54.40
Gemini’s net income on each unit as a result of Calcia rejecting the special order and transferring units of IP‐2007 to Argone at $82 per unit is $54.40 per unit. Accepting the special order will not maximize after‐tax operating income. After‐ tax operating income is maximized by rejecting the special order. Argone will not want Calcia to accept the special order. It is more costly to buy from the external market than from Calcia. Calcia will want to accept the special order because Calcia’s income per unit after‐tax increases by $9.30 per unit by accepting the special order rather than transferring IP‐2007 to Argone at $82 per unit and earning $0 operating income. Gemini should set the transfer price at $97 per unit. This will result in each division taking actions in its own best interest that is also in the best interest of Gemini as a whole acting as a decentralized organization. The opportunity cost of transferring IP‐2007 internally is $15 ($95 ─ $80) per unit for the first 10,000 units and $0 per unit thereafter.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
23‐33 (cont’d)
Using the general guideline, Minimum transfer Incremental cost per Opportunity cost per = unit inccurred up to + unit to the price the point of transfer selling subunit
So, minimum transfer price
$15 $97 per unit for the first 10,000 units = $82 $82 $0 $82 per unit for the next 10,000 units
Gemini should use these minimum transfer prices because they are also tax‐efficient. At a transfer price of $97 per unit for the first 10,000 units, Calcia is indifferent between accepting the special order or transferring internally. Calcia earns $15 per unit if it accepts the special order. It also earns $15 per unit if it transfers IP‐2007 to Argone ($97 ‐ $82 variable cost per unit). Argone will prefer to “buy” IP‐2007 from Calcia because the transfer price of $97 is less than the $100 price it would pay to buy a product similar to IP‐2007 in the United States. The increase in Gemini’s income will be as follows: From Calcia: $97.00 Revenue per unit Variable cost per unit 82.00 Contribution margin per unit 15.00 Income taxes (0.38 × $15) 5.70 Increase in division income per unit after tax $ 9.30 From Argone: Revenue per unit $150.00 Transfer price per unit 97.00 Contribution margin per unit 53.00 Income taxes (0.20 × $53) 10.60 Increase in division income per unit after tax $ 42.40 Increase in Gemini’s income = $9.30 + $42.40 = $51.70
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Chapter 23
23‐33 (cont’d) This net income is greater than the $49.30 net income that Gemini would earn if Calcia accepted the special order. It is less than the $54.40 that Gemini would earn if Calcia had transferred IP‐2007 at $82 per unit. Of course, if the transfer price is set at $82 per unit, Calcia would accept the special order, which would lead to a lower net income of $49.30. If Gemini wants to get the benefits of decentralization, it must be willing to suffer the consequences of higher taxes that Calcia would have to pay. Note that Gemini would not want to set the transfer price any higher than $97, the minimum transfer price that would induce Calcia to transfer internally to Argone. Why? Because setting the transfer price any higher would result in exactly the same action (transferring IP‐2007 internally) but at a higher cost because of the higher taxes that Calcia would have to pay in Canada. Consider for example a transfer price of $99 per unit. The increase in Gemini’s income will be as follows: From Calcia: $99.00 Revenue per unit Variable cost per unit 82.00 Contribution margin per unit 17.00 Income taxes (0.38 × $17) 6.46 Increase in division income per unit after tax $10.54 From Argone: Revenue per unit $150.00 Transfer price per unit 99.00 Contribution margin per unit 51.00 Income taxes (0.20 × $51) 10.20 Increase in division income per unit after tax $ 40.80 Increase in Gemini’s income $10.54 + $40.80 = $51.34, which is less than the $51.70 Gemini earns if the transfer price is set at $97 per unit. A transfer price of $97 is the most tax‐efficient transfer price consistent with Gemini operating as a decentralized organization. Note also that the transfer price cannot be set above $100 per unit because then Argone would buy a product similar to IP‐2007 in the United States rather than from Calcia. This would result in a lower profit before tax and higher overall taxes because of the higher tax rate in Canada.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
23‐34 (20 min.)
Dual Pricing.
1. Revenue
External Internal
Bottle Division Units Total $5.00 150,000 $750,000 $4.20 40,000 $168,000
Mixing Division Units Total $ 11.50 40,000 $460,000
Company $1,210,000 $ 168,000
Variable costs
$3.00
190,000
$918,000 $570,000
$1,378,000 $ 670,000 $ 120,000
Contribution margin Fixed costs
Divisional operating income
40,000 40,000
$460,000 $100,000 $120,000
$570,000
$220,000
$ 790,000
$348,000 $125,000
$240,000 $ 85,000
$223,000
$155,000
$ 378,000
$ 2.50 $ 3
$ 588,000 $ 210,000
Internal transfer adjustment: $3 x 0.40 x 40,000
$ 48,000
Operating income
$ 330,000
2.
23–1170
The internal sales are included in the companyʹs statement because the company cannot sell to itself. Therefore, it has to adjust $48,000 of dual pricing out of its income.
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Chapter 23
23‐35 (20 min.) Transfer pricing, goal‐congruence, governance. 1. Variable Cost (1) $120,000
Adjusted Variable Cost (2) $140,000
120,000 0 30,000 $(30,000)
140,000 0 10,000 $(10,000)
Transfer price($12; $14×10,000) Variable costs Contribution margin Fixed costs Operating loss 2.
3.
Benefit (3) = (2) – (1) $20,000 (20,000) 0 20,000 $20,000
I would recommend a lump sum transfer of $40,000 (say) from Department B to Department A plus a transfer price equal to the variable cost per unit of $12 per unit. This would generate some operating income for Department A while Department A continues to make transfers at variable costs. Such a transfer pricing arrangement avoids the suboptimal decision making that can result from full cost transfer prices. Variable cost transfer prices often provide valuable information for decision making. The fixed payment is the price that Department B pays for using the capacity of Department A. Asking the management accountant to reclassify costs is unethical. Lasker suggests that $14 per unit is a more appropriate variable cost per unit. However, he does not substantiate his claim with any costs that he thinks are misclassified. In fact, his variable cost per unit number seems arbitrary and specifically targeted to improve his transfer pricing negotiations. If that is the reason for his request and there is no fundamental problem with the current cost classifications, Bedford should not change the variable cost per unit. To do so would be unethical. To resolve this situation, Bedford should begin by explaining his decision to Lasker. If Lasker insists on using a higher variable cost per unit, then Bedford may need to alert Lasker’s supervisor in Whengon’s upper management.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
23‐36 1. 2.
23–1172
Apply transfer‐pricing methods.
Revenues 300 packets × $15 each Variable costs: Harvesting Processing Marketing Total variable costs Contribution margin Fixed costs: Harvesting Processing Marketing Total fixed costs Operating income
$4,500
1,000 × $0.24 500 × $0.96 300 × $0.36
$240 480 108
828 3,672
1,000 × $0.48 500 × $0.72 300 × $0.84
$480 360 252
1,092 $2,580
(a)
200% of Variable Cost Harvesting Division to Processing Division = 2.0 ($0.24) = $0.48 per kilogram of raw fish Processing Division to Marketing Division = 2.0 [($0.48 × 2)* + $0.96] = $3.84 per kilogram of processed fish
(b)
150% of Full Cost Harvesting Division to Processing Division = 1.5 ($0.24 + $0.48) = $1.08 per kilogram of raw fish Processing Division to Marketing Division = 1.5 [($1.08 × 2)* + $0.96 + $0.72] = $5.76 per kilogram of processed fish
(c)
Market Price Harvesting Division to Processing Division = $1.70 per kilogram of raw fish Processing Division to Marketing Division = $7.00 per kilogram of processed fish
*It takes two kilograms of raw tuna to produce one kilogram of fish fillets.
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Chapter 23
23‐36 (cont’d) 1. 2. 3.
HARVESTING DIVISION Division revenues $0.48, $1.08, $1.70, × 1,000 kg of raw fish Deduct: Division variable costs $0.24 × 1,000 kg of raw fish Division fixed costs $0.48 × 1,000 kg of raw fish Division operating income PROCESSING DIVISION Division revenues $3.84, $5.76, $7, × 500 kg of processed fish Deduct: Transferred‐in costs $0.48, $1.08, $1.70, × l,000 kg of raw fish Division variable costs $0.96 × 500 kg procsd. fish Division fixed costs $0.72 × 500 kg procsd. fish Division operating income MARKETING DIVISION Division revenues $15 × 300 two‐kg packets Deduct: Transferred‐in costs $3.84, $5.76, $7, × 500 kg of processed fish Division variable costs $0.36 × 300 two‐kg packets Division fixed costs $0.84 × 300 two‐kg packets Division operating income
Method A Internal Transfers at 200% of Variable Costs
Method B Internal Transfers at 150% of Full Costs
Method C Internal Transfers at Market Price
$ 480
$ 1,080
$1,700
240
240
240
480 $ (240)
480 $ 360
480 $ 980
$1,920
$2,880
$3,500
480
1,080
1,700
480
480
480
360 $ 600
360 $ 960
360 $ 960
$4,500
$4,500
$4,500
1,920
2,880
3,500
108
108
108
252 $2,220
252 $1,260
252 $ 640
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23‐36 (cont’d)
The division operating incomes are: Method A 200% of Method B Method C Variable 150% of Market Cost Full Cost Price Harvesting Division $ (240) $ 360 $ 980 Processing Division 600 960 960 Marketing Division 2,220 1,260 640 Oceanic Products $2,580 $2,580 $2,580 The bonus paid to each division manager under a 1% of division operating income (if positive) scheme is: Method A 200% of Method B Method C Variable 150% of Market Cost Full Cost Price Harvesting Division manager bonus — $ 3.60 $9.80* Processing Division manager bonus $ 6.00 9.60* 9.60* Marketing Division manager bonus 22.20* 12.60 6.40
*Preferred by division manager.
The Harvesting Division manager prefers the market price method. The Processing Division manager is indifferent between the 150% of full cost and market price methods. The Marketing Division manager prefers the 200% of variable cost method.
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Chapter 23
23‐37 1. 2. 3.
Market‐based transfer‐price method.
Alternative 1): Selling price $55 includes 10% of profit on full costs. The profit per piece is $5, while the full cost is $50 Full cost: $55 / (1 + 10%) = $50 Alternative 2) Selling price of $52.80 includes a 10% of profit on full costs. The profit per piece is $4.8, while the full cost is $48 Full cost: $52.8 / (1 + 10%) = $48 The transfer price represents 60% of Mark’s division full cost. Transfer price: $50 x 60% = $30 Clearly, the use of full costs with excess capacity is not the best situation for the company as a whole. To decide on the best alternative to maximize expected profitability in Mark’s division we have to consider the probability of each scenario. Alternative 1): The profit of $5 per unit would allow him to achieve a ROI of 20%, but the probability of winning the bid is 80%, therefore the expected ROI of this alternative is: 16% (20% with a probability of 80%) Alternative 2): The profit of $4.8 per unit would allow him to achieve a ROI of 18%, but the probability of winning the bid is 90%, therefore the expected ROI of this alternative is: 16.2% (18% with a probability of 90%) From the comparison of expected ROIs, Mark will prefer to submit a bid at $52.8 per piece (alternative 2)
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23‐37 (cont’d) 4.
Internal sourcing is the best because the overall profit is over 4 times bigger as shown in the following exhibit.
Alternative 1 Price to quote $ 55.00 Minus: Intermediate product cost: External supplier Internal supplier: Corporate allocated costs $ 1.50 Divisions Total own costs $ 13.50 Total costs $ 15.00 Markʹs Division Corporate allocated costs $ 2.00 Divisions Total own costs $ 18.00 Total costs $ 20.00 Profit $ 20.00
Alternative 2 $ 52.80
$ 28.00
$ 2.00 $ 18.00 $ 20.00 $ 4.80
23‐38
Transfer pricing and excess capacity.
This problem explores the “general transfer‐pricing guideline” discussed in the chapter. 1. No, transfers should not be made to Stuffing if there is no excess capacity in Grinding/Mixing. An incremental (outlay) cost approach shows a positive contribution for the company as a whole. $5 Selling price of final product Incremental costs in Grinding/Mixing $1 Incremental costs in Stuffing 2 3 Contribution (loss) $ 2 However, if there is no excess capacity in Grinding/Mixing, any transfer will result in diverting product from the market for the intermediate product. Sales in this market result in a greater contribution for the company as a whole. Stuffing should not prepare the sausages since the incremental revenue that Italian Sausages can earn, $1.75 per kilogram ($5 from selling the final product – $3.25 from selling the intermediate product) is less than the incremental costs of $2 to stuff the sausages in the Stuffing Division.
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23‐38 (cont’d) Selling price of intermediate product $3.25 Incremental (outlay) costs in Grinding/Mixing 1.00 Contribution (loss) $ 2.25
The general guideline described in the chapter is Minimum transfer price
=
Additional incremental costs per unit incurred up to the point of transfer
+
Opportunity costs per unit to the supplying division
= $1 + ($3.25 – $1) = $3.25, which is the market price
2.
Market price is the transfer price that leads to the correct decision; that is, do not transfer to Stuffing Division unless there are extenuating circumstances for continuing to market the final product. Therefore, Italian Sausages must either close the Stuffing Division and sell all its assets or reduce the incremental costs of stuffing from $2 per kilogram to less than $1.75. If (i) Grinding/Mixing has excess capacity, (ii) there is intermediate external demand for 5,000 kilograms at $3.25, and (iii) the $3.25 price is to be maintained, then the opportunity costs per unit to the supplying division are $0. The general guideline indicates a minimum transfer price of: $1 + $0 = $1, which is the incremental or outlay costs for the first 5,000 kilograms. The Stuffing Division would buy 5,000 kilograms of mixture at a transfer price of $1 because Stuffing can earn a contribution of $2 per kilogram [$5 – ($2 + $1)]. In fact, Stuffing would be willing to buy kilograms of mixture from Grinding/Mixing at any price up to $3 per kilogram because any transfers at a price of up to $3 will still yield Stuffing a positive contribution margin. Note, however, that if Stuffing wants more than 5,000 kilograms, the minimum transfer price will be $3.25 as computed in requirement 1 because Grinding/Mixing will incur an opportunity cost in the form of lost contribution of $2.25 (market price, $3.25 – outlay costs of $1) for every kilogram above 5,000 that is transferred to Stuffing. The following schedule summarizes the transfer prices for units transferred from Grinding/Mixing to Stuffing. Kilograms Transfer Price 0–5,000 $1–$3 more than 5,000 $3.25
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23‐38 (cont’d) 3.
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Stuffing Division will break even (zero contribution), but the company as a whole would generate a contribution of $2 per kilogram on the 5,000 kilograms of mixture transferred. Any price between $1 and $3 would induce the transfer that would be desirable for the company as a whole. A motivational problem may arise regarding how to split the $2 contribution between both divisions. Unless the price is below $3, Stuffing would have little incentive to buy. Note: The transfer price that may appear optimal in an economic analysis may, in fact, be totally unacceptable from the viewpoints of (1) preserving autonomy of the managers and (2) evaluating the performance of the divisions as economic units. For instance, consider the simplest case discussed above, where there is idle capacity and the $3.25 intermediate price is to be maintained. To direct that Grinding/Mixing should sell to Stuffing at Grinding/Mixing’s variable cost of $1 may be desirable from the viewpoint of Stuffing and the company as a whole. However, the autonomy (independence) of Grinding/Mixing manager is eroded. The Grinding/Mixing Division will earn nothing, although it could argue that it is contributing to the earning of income on the final product. If the manager of Grinding/Mixing wants a portion of the total company contribution of $2 per kilogram, the question is: How is an appropriate amount determined? This is a difficult question in practice. The price can be negotiated upward to somewhere between $1 and $3 so that some “equitable” split is achieved. A dual transfer pricing scheme has also been suggested whereby the supplier gets credit for the full intermediate market price and the buyer is charged only with variable or incremental costs. In any event, when there is heavy interdependence between divisions, such as in this case, some system of subsidies may be needed to deal with the three problems of goal congruence, management effort, and subunit autonomy. Of course, where heavy subsidies are needed, a question can be raised as to whether the existing degree of decentralization is optimal.
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Chapter 23
COLLABORATIVE LEARNING CASES
23‐39 (30 min.) 1. 2.
Transfer pricing, goal‐congruence.
See column (1) of Solution Exhibit 23‐39 The net cost of the in‐house option is $230,000. See columns (2a) and (2b) of Solution Exhibit 23‐39. As the calculations show, if Johnson Corporation offers a price of $38 per tape player, Orsilo Corporation should purchase the tape players from Johnson; this will result in an incremental net cost of $210,000 (column 2a). If Johnson Corporation offers a price of $45 per tape player, Orsilo Corporation should manufacture the tape players in‐house; this will result in an incremental net cost of $230,000 (column 2b). Comparing columns (1) and (2a), at a price of $38 per tape player from Johnson, the net cost of $210,000 is less than the net cost of $230,000 to Orsilo Corporation if it made the tape players in‐house. So, Orsilo Corporation should outsource to Johnson. Comparing columns (1) and (2b), at a price of $45 per tape player from Johnson, the net cost of $280,000 is greater than the net cost of $230,000 to Orsilo Corporation if it made the tape players in‐house. Therefore, Orsilo Corporation should reject Johnson’s offer. Now consider column (2x) of Solution Exhibit 23‐39. It shows that at a price of $40 per tape player from Johnson, the net cost is exactly $230,000, the same as the net cost to Orsilo Corporation of manufacturing in‐house (column 1). Thus, for prices between $38 and $40, Orsilo will prefer to purchase from Johnson. For prices greater than $40 (and up to $45), Orsilo will prefer to manufacture in‐house.
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SOLUTION EXHIBIT 23‐39 Buy 10,000 Buy 10,000 tape players Buy 10,000 Transfer tape players from tape players 10,000 tape from Johnson Johnson at from Johnson players to at $38. Sell $40. Sell at $45. Sell Assembly. 12,000 tape 12,000 tape 12,000 tape players in players in players in Sell 2,000 in outside outside outside outside market at $35 market at $35 market at market at $35 each each each $35 each (2a) (2x) (2b) (1) Incremental cost of Cassette Division supplying 10,000 tape players to Assembly Division $25 10,000; 0; 0; 0 $(250,000) $ 0 $ 0 $ 0
Incremental costs of buying 10,000 tape players from Johnson $0; $38 10,000; $40 10,000; $45 10,000
0
(380,000)
(400,000)
(450,000)
Revenue from selling tape players in outside market $35 2,000; 12,000; 12,000; 12,000
70,000
420,000
420,000
420,000
Incremental costs of manufacturing tape players for sale in outside market $25 2,000; 12,000; 12,000; 12,000
(50,000)
(300,000)
(300,000)
(300,000)
200,000
200,000
200,000
(150,000)
(150,000)
(150,000)
$(210,000)
$(230,000)
$(280,000)
Revenue from supplying head mechanism to Johnson $20 0; 10,000; 10,000; 10,000
0
Incremental costs of supplying head mechanism to Johnson $15 0; 10,000; 10,000; 10,000
0
Net costs
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Chapter 23
23‐39 (cont’d)
3.
The Cassette Division can manufacture at most 12,000 tape players and it is currently operating at capacity. The incremental costs of manufacturing a tape player are $25 per unit. The opportunity cost of manufacturing tape players for the Assembly Division is (1) the contribution margin of $10 (selling price, $35 minus incremental costs $25) that the Cassette Division would forgo by not selling tape players in the outside market plus (2) the contribution margin of $5 (selling price, $20 minus incremental costs, $15) that the Cassette Division would forgo by not being able to sell the head mechanism to external suppliers of tape players such as Johnson (recall that the Cassette division can produce as many head mechanisms as demanded by external suppliers, but their demand will fall if the Cassette Division supplies the Assembly Division with tape players). Thus, the total opportunity cost to the Cassette Division of supplying tape players to Assembly is $10 + $5 = $15 per unit. Using the general guideline,
cost per Opportunity cost per Minimum transfer = Incremental tape player up to the tape player to the price per tape player point of transfer selling division = $25 + $15 = $40 Thus, the minimum transfer price that the Cassette Division will accept for each tape player is $40. Note that at a price of $40, Orsilo is indifferent between manufacturing tape players in‐house or purchasing them from an external supplier.
4a.
4b.
The transfer price is set to $40 + $1 = $41 and Johnson is offering the tape players for $40.50 each. Now, for an outside price per tape player below $41, the Assembly Division would prefer to purchase from outside; above it, the Assembly Division would prefer to purchase from the Cassette Division. So, the Assembly division will buy from Johnson at $40.50 each and the Cassette Division will be forced to sell its output on the outside market. But for Orsilo, as seen from requirements 1 and 2, an outside price of $40.50, which is greater than the $40 cut‐off price, makes inhouse manufacture the optimal choice. So, a mandated transfer price of $41 causes the division managers to make choices that are sub‐optimal for Orsilo.
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23‐39 (cont’d) 4c.
When selling prices are uncertain, the transfer price should be set at the minimum acceptable transfer price. It is only if the price charged by the external supplier falls below $40 that Orsilo Corporation as a whole is better off purchasing from the outside market. Setting the transfer price at $40 per unit achieves goal congruence. The Cassette division will be willing to sell to the Assembly Division, and the Assembly Division will be willing to buy in‐house and this would be optimal for Orsilo, too.
23‐40 (40‐50 min.) Goal‐congruence, taxes, different market conditions. 1. Existing Frame New Frame Used by Assembly Sales price $450 Savings in purchase costs by making frames in‐house $480 Manufacturing costs: Direct materials $100 $150 Direct manufacturing labour 48 60 Variable manufacturing overhead 30 30 Total costs of manufacturing 178 $240 Contribution margin from new frame $272 Net savings in costs by making existing frame in house $240 If order for the new frame is accepted, TECA earns a contribution margin of $272 2,000 units. $544,000 In this case, Frames Division will only be in a position to supply 2,000 units to Assembly and Assembly will have to purchase 1,200 frames from outside. The incremental cost of 288,000 buying frames from outside is $240 1,200. Net benefit from accepting order $256,000 An alternative approach is to compare relevant costs of the accept order and reject order alternatives.
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23‐40 (cont’d) Accept Order Reject Order 1. Contribution margin from selling 2,000 units of new frame $272 2,000 $(544,000) 2. Incremental cost of making and transferring 2,000 units of old frames $240 2,000, 3,200 480,000 $768,000 3. Incremental costs of purchasing 1,200 units from outside $480 1,200 576,000 $ 512,000 $768,000 TECA should: (a) make 2,000 units of the new frames in the Frames Division, (b) make 2,000 units of the existing frames for the Assembly Division, and (c) have the Assembly Division purchase 1,200 frames that it requires from the outside market. 2. The options facing the Frames Division manager are (a) to sell 2,000 units of the special order frames and make 2,000 units for the Assembly Division or (b) to make 3,200 units for the Assembly Division. The contribution margin per unit from accepting the special order is $272 per unit. Let the transfer price be $X. Then we want to find X such that $272 2,000 + ($X – $240) 2,000 = ($X – $240) 3,200 ($X – $240) (3,200 – 2,000) = $544,000 $X – $240 = $544,000 / 1,200 $X ‐ $240 = $453.33 X = $693.33 For transfer prices below $693.33, the Frames Division gets more by selling 2,000 units outside and transferring 2,000 units to Assembly Division. It will not transfer more than 2,000 units to Assembly even though the transfer price is greater than the variable costs of manufacturing the existing frames, $240 plus the contribution margin per unit from accepting the special order of $272 equal to $512. Why? Because by transferring an additional 1,200 units it will have to give up $544,000 ($272 2,000) of contribution margin by not accepting the special order. The Frames Division manager would be willing to transfer the remaining 2,000 units for which it has capacity to the Assembly Division, provided the transfer price covers the Frames Division’s variable costs. So the range of transfer price that will induce the Frames Division manager to implement the optimal solution in requirement 1 is: $240 ≤ TP < $693.33
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23‐40 (cont’d) The Assembly Division manager would be willing to buy from the Frames Division so long as the transfer price is less than or equal to the price at which the Assembly Division can buy the frames on the outside market. TP ≤ $480 It will not buy the engines from the Frames Division if TP > $480. The range of TP that will result in both managers favouring the optimal actions in requirement 1 are TPs that satisfy the respective constraints described above. $240 ≤ TP ≤ $480 for the first 2,000 units $480 < TP < $693.33 for any additional units This transfer pricing scheme will induce both managers to transfer 2,000 units between the Frames and Assembly Divisions but no more. 3.
a. The full manufacturing costs of the frames transferred to the Assembly Division are:
Direct materials Direct manufacturing labour Variable manufacturing overheads Fixed manufacturing overhead : $624,000 / 2 = $312,000 And $312,000 / 2,000 frames since the frames transferred to the Assembly Division use up half the Frames Division’s capacity Total manufacturing cost
$150 60 30
156 $396
b.
A transfer price of $396 is in the optimal range identified in requirement 2 and so will achieve the optimal actions of selling 2,000 frames under the outside offer and transferring 2,000 frames to the Assembly Division as identified in requirement 1. (If we also want the Assembly Division manager to not ask for any additional frames beyond 2,000 units, the transfer price for any additional engines would have to be set such that $480 < TP < $693.33.) If the transfer price is set at $396, the Assembly Division manager will want more frames but the Frames Division manager will not have any incentive to transfer anything more than 2,000 units, preferring to supply 2,000 units for the special order.
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23‐40 (cont’d) c.
4.
a.
b.
5.
One advantage of full‐cost transfer pricing is that it is useful for the firm’s long‐run pricing decisions. One disadvantage of full‐cost transfer pricing is that costs that are fixed for the corporation as a whole look like variable costs from the viewpoint of the Assembly Division manager. This is because by choosing not to have a unit transferred from the Frames Division, the Assembly Division manager would appear to save both the variable and fixed costs of the frames. This could lead to suboptimal decisions. To minimize taxes, TECA should transfer the frames at the market price of $480. The Frames Division would pay no taxes on any income that it would report. By setting the transfer price as high as possible, the Assembly Division would minimize the income it would report and hence the taxes it would pay. Yes, as in part 3b, the transfer price of $480 is also within the range identified in requirement 2 and so will achieve the outcome desired in requirement 1 (sell 2,000 frames under the outside offer and transfer 2,000 frames to the Assembly Division).
Recommend that TECA use a transfer price of $480 for transferring frames from the Frames Division to the Assembly Division. This transfer price minimizes tax payments for TECA as a whole and also achieves goal congruence. That is, at a transfer price of $480 for all frames transferred from the Frames Division to the Assembly Division, both Divisions will be content with the following arrangement: (a) The Frames Division will make 2,000 frames for outside customers and 2,000 frames for the Assembly Division. (b) The Assembly Division will take 2,000 frames from the Frames Division and the remaining frames from the outside market.
Of course the Assembly Division manager would like to negotiate a price lower than $480 (but greater than $240) for the 2,000 frames from the Frames Division, but this would increase TECA’s tax payments. At a transfer price of $480, it would still be alright to evaluate each division’s performance on the basis of division operating income because the transfer price of $480 approximates the market prices for the frames transferred from the Frames Division to the Assembly Division. Market‐based transfer prices give top management a reasonably good picture of the contributions of the individual divisions to overall companywide profitability.
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CHAPTER 24 MULTINATIONAL PERFORMANCE MEASUREMENT AND COMPENSATION
SHORT‐ANSWER QUESTIONS
24‐1 Examples of financial and nonfinancial measures of performance are:
Financial: ROI, residual income, economic value added, and return on sales. Nonfinancial: Customer perspective: Market share, customer satisfaction. Internal‐business‐processes perspective: Manufacturing lead time, yield, on‐time performance, number of new product launches, and number of new patents filed. Learning‐and‐growth perspective: employee satisfaction, information‐system availability.
24‐2 The six steps in designing an accounting‐based performance measure are: 1. 2. 3. 4. 5. 6.
Choose performance measures that align with top management’s financial goals Choose the time horizon of each performance measure in Step 1 Choose a definition of the components in each performance measure in Step 1 Choose a measurement alternative for each performance measure in Step 1 Choose a target level of performance Choose the timing of feedback
24‐3 The DuPont method highlights that ROI is increased by any action that increases return on sales or investment turnover. ROI increases with 1. increases in revenues, 2. decreases in costs, or 3. decreases in investments, while holding the other two factors constant.
24‐4 Yes. Residual income (RI) is not identical to return on investment (ROI). ROI is a percentage with investment as the denominator of the computation. RI is an absolute monetary amount which includes an imputed interest charge based on investment.
24‐5 Economic value added (EVA) is a specific type of residual income measure that is calculated as follows: Economic value After-tax Weighted-average Total assets minus added (EVA) = operating income – cost of capital current liabilities
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24‐6 Definitions of investment used in practice when computing ROI are 1. 2. 3. 4.
Total assets available Total assets employed Total assets employed minus current liabilities Shareholders’ equity
24‐7 Current cost is the cost of purchasing an asset today identical to the one currently held if an identical asset can currently be purchased; it is the cost of purchasing an asset that provides services like the one currently held if an identical asset cannot be purchased. Historical‐cost‐based measures of ROI compute the asset base as the original purchase cost of an asset minus any accumulated depreciation. Some commentators argue that current cost is oriented to current prices, while historical cost is past‐oriented.
24‐8 Special problems arise when evaluating the performance of divisions in multinational companies because a. The economic, legal, political, social, and cultural environments differ significantly across countries. b. Governments in some countries may impose controls and limit selling prices of products. c. Availability of materials and skilled labour, as well as costs of materials, labour, and infrastructure may differ significantly across countries. d. Divisions operating in different countries keep score of their performance in different currencies.
24‐9 In some cases, the subunit’s performance may not be a good indicator of a manager’s performance. For example, companies often put the most skillful division manager in charge of the weakest division in an attempt to improve the performance of the weak division. Such an effort may yield results in years, not months. The division may continue to perform poorly with respect to other divisions of the company. But it would be a mistake to conclude from the poor performance of the division that the manager is performing poorly. A second example of the distinction between the performance of the manager and the performance of the subunit is the use of historical cost‐based ROIs to evaluate the manager even though historical cost‐based ROIs may be unsatisfactory for evaluating the economic returns earned by the organization subunit. Historical cost‐ based ROI can be used to evaluate a manager by comparing actual results to budgeted historical cost‐based ROIs.
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24‐10 Moral hazard describes situations in which an employee prefers to exert less effort (or to report distorted information) compared with the effort (or accurate information) desired by the owner because the employee’s effort (or validity of the reported information) cannot be accurately monitored and enforced.
24‐11 Rewarding managers on the basis of their performance measures only, such as ROI, subjects them to uncontrollable risk because managers’ performance measures are also affected by random factors over which they have no control. A manager may put in a great deal of effort but her performance measure may not reflect this effort if it is negatively affected by various random factors. Thus, when managers are compensated on the basis of performance measures, they will need to be compensated for taking on extra risk. Therefore, when performance‐based incentives are used, they are generally more costly to the owner. The motivation for having some salary and some performance‐based bonus in compensation arrangements is to balance the benefits of incentives against the extra costs of imposing uncontrollable risk on the manager.
24‐12 Benchmarking or relative performance evaluation is the process of evaluating a manager’s performance against the performance of other similar operations. The ideal benchmark is another operation that is affected by the same noncontrollable factors that affect the manager’s performance. Benchmarking cancels the effects of the common noncontrollable factors and provides better information about the managerʹs performance.
24‐13 When employees have to perform multiple tasks as part of their jobs, incentive problems can arise when one task is easy to monitor and measure while the other task is more difficult to evaluate. Employers want employees to intelligently allocate time and effort among various tasks. If, however, employees are rewarded on the basis of the task that is more easily measured, they will tend to focus their efforts on that task and ignore the others.
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24‐14 Diagnostic systems monitor critical performance factors —such as ROI, RI, EVA, ROS, customer satisfaction, and employee satisfaction— that help managers monitor progress toward attaining the company’s strategic goals. Boundary systems describe standards of behaviour and codes of conduct expected of all employees, especially actions that are off‐limits. Ethical behaviour on the part of managers is paramount. Belief systems articulate the mission, purpose, and core values of a company. They describe the accepted norms and patterns of behaviour expected of all managers and employees with respect to each other, shareholders, customers, and communities. Interactive control systems are formal information systems that managers use to focus organization attention and learning on key strategic issues. Interactive control systems track strategic uncertainties that businesses face. Measuring and rewarding managers for achieving critical performance variables is an important driver of corporate performance. But these diagnostic control systems must be counterbalanced by the other levers of control—boundary systems, belief systems, and interactive control systems—to ensure that proper business ethics, inspirational values, and attention to future threats and opportunities are not sacrificed to achieve business results. An excessive focus on diagnostic control systems and critical performance variables can cause an organization to ignore emerging threats and opportunities— changes in technology, customer preferences, regulations, and industry competition that can undercut a business. EXERCISES
24‐15 (10 min.) Terminology. Governance, or the management stewardship of assets they do not own, according to laws and regulations is more closely scrutinized than before. Legal reform in the US now mandates a shareholder vote on any executive compensation packages, referred to as a say on pay. While we are very familiar with executive bonus, a new clawback of previous compensation or a malus is becoming a feature of compensation. One important performance measure that could determine a bonus or malus is the accounting return on investment (ROI), calculated by dividing the net income by the investment made. Another measure is the ROR also called the imputed cost of investment which represents a return foregone from tying up cash in existing investments. A third measure is the economic value added (EVA) which is calculated by subtracting the total assets minus current liabilities multiplied by the weighted average cost of capital (WACC) from the after‐tax operating income. But executive performance is not the only factor or even the most important factor affecting corporate profitability, excellent governance and corporate social responsibility. Good management control systems will separate the effects good luck from good management on performance. Additional considerations when designing a good management control system include boundary systems, belief systems, intrinsic motivation, and interactivity.
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24‐16 (30 min.) ROI, comparisons of three companies. 1.
The separate components highlight several features of return on investment not revealed by a single calculation: a. The importance of investment turnover as a key to income is stressed. b. The importance of revenues is explicitly recognized. c. The important components are expressed as ratios or percentages instead of dollar figures. This form of expression often enhances comparability of different divisions, businesses, and time periods. d. The breakdown stresses the possibility of trading off investment turnover for income as a percentage of revenues so as to increase the average ROI at a given level of output.
2.
(Filled‐in blanks are in bold face.) Revenue Income Investment Income as a % of revenue Investment turnover Return on investment
Companies in Same Industry A B C $10,000,000 $1,000,000 $ 500,000 $ 50,000 $ 100,000 $ 50,000 $5,000,000 $ 5,000,000 $ 500,000 10% 10% 0.5% 2.0 0.1 2.0 20% 1% 1%
Income and investment alone shed little light on comparative performances because of disparities in size between Company A and the other two companies. Thus, it is impossible to say whether Bʹs low return on investment in comparison with A’s is attributable to its larger investment or to its lower income. Furthermore, the fact that Companies B and C have identical income and investment may suggest that the same conditions underlie the low ROI, but this conclusion is erroneous. B has higher margins but a lower investment turnover. C has very small margins (1/20th of B) but turns over investment 20 times faster. Introducing revenues to measure level of operations helps to disclose specific areas for more intensive investigation. Company B does as well as Company A in terms of income margin, for both companies earn 10% on revenues. But Company B has a much lower turnover of investment than does Company A. Whereas a dollar of investment in Company A supports two dollars in revenues each period, a dollar investment in Company B supports only ten cents in revenues each period. This suggests that the analyst should look
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Chapter 24
24‐16 (cont’d)
carefully at Company B’s investment. Is the company keeping an inventory larger than necessary for its revenue level? Are receivables being collected promptly? Or did Company A acquire its fixed assets at a price level that was much lower than that at which Company B purchased its plant? “On the other hand, C’s investment turnover is as high as A’s, but C’s income as a percentage of revenue is much lower. Why? Are its operations inefficient, are its material costs too high, or does its location entail high transportation costs?” “Analysis of ROI raises questions such as the foregoing. When answers are obtained, basic reasons for differences between rates of return may be discovered. For example, in Company B’s case, it is apparent that the emphasis will have to be on increasing turnover by reducing investment or increasing revenues. Clearly, B cannot appreciably increase its ROI simply by increasing its income as a percent of revenue. In contrast, Company C’s management should concentrate on increasing the percent of income on revenue.”
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24‐17 (30 min.) Analysis of return on invested assets, comparison of two divisions, DuPont method. 1.
Test Preparation Division 2011
Operating Revenues
Total Assets
$680
$7,960 $840 10% = $8,400 $1,160 11% = $10,545
$1920 $840 42% = $2,000 $10,545 5 = $2,109
8.5%
4.1
35.4%
10%
4.2
42%
11%
5
55%
$2,360
$1,280
26.3%
1.8
48.4%
3,000 $2,340 2 = $4,680
1,800
22%
1.7
36.7%
2,340
12.5%
2
25%
12.6%
3.2
40.6%
13.2%
3
39.5%
11.5%
3.4
39.2%
840
2013 Language Arts Department 2011
1,160
2013 Learning World Inc. 2011 2012 2013
$620 $3,000 22%= $660 $2,340 25% = $585 $1,300 $840 + $660 = $1,500 $1,160 + $585 = $1,745
$10,320 $3,200 $8,400 + $3,000 $2,000 + $1,800 = $11,400 = $3,800 $10,545 + $4,680 $2,109 + $2,340 = $15,225 = $4,449
24–1192
Operating Operating Income Revenues Total Total Assets Assets
Operating Income
2012
2012
Operating Income Operating Revenues
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Chapter 24
24‐17 (cont’d) 2. Based on revenues, Test Preparation is about twice as big as Language Arts. The Language Arts Department earns higher margins (operating income as a percent of operating revenues); the Test Preparation Division turns over its assets at more than twice the rate of the Language Arts Department (operating revenues as a multiple of total assets). The net result is that the ROI of the two divisions was similar (in the 30– 50% range). But whereas the ROI of the Test Preparation Division has been increasing from 2011 to 2013, the ROI of the Language Arts Department has been falling. Overall, this has resulted in Learning World showing stable ROI over the past three years.
24‐18 (10–15 min.)
ROI and RI.
1. Operating income = (Contribution margin per unit 150,000 units) – Fixed costs = ($720 – $500) 150,000 – $30,000,000 = $3,000,000 Operating income ROI = = $3,000,000 ÷ $48,000,000 = 6.25% Investment 2. Operating income = ROI × Investment [No. of pairs sold (Selling price – Var. cost per unit)] – Fixed costs = ROI Investment Let $X = minimum selling price per unit to achieve a 25% ROI 150,000 ($X – $500) – $30,000,000 = 25% ($48,000,000) $150,000X = $12,000,000 + $30,000,000 + $75,000,000 X = $780 3. Let $X = minimum selling price per unit to achieve a 20% rate of return 150,000 ($X – $500) – $30,000,000 = 20% ($48,000,000) $150,000X = $9,600,000 + $30,000,000 + $75,000,000 X = $764
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
24‐19 (20 min.) ROI and RI with manufacturing costs. 1.
The operating income is: Sales revenue ($12,000 × 10,000) Less: Direct materials ($3,000 × 10,000) Setup ($1,300 × 6,000) Production ($415 × 175,200) Gross margin Selling and administration Operating income
$120,000,000
$30,000,000 7,800,000 72,708,000 110,508,000 $ 9,492,000 7,340,000 $ 2,152,000
Average invested capital is ($13,500,000 + $13,400,000) ÷ 2 = $13,450,000 ROI = 2.
24–1194
$ 2,152,000 = 16% $13,450,000
Residual income = Operating income − (12% × Invested capital) = $2,152,000 − (12% × $13,450,000) = $2,152,000 − $1,614,000 = $538,000
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Chapter 24
24‐20 (25 min.) Financial and nonfinancial performance measures, goal‐congruence. 1.
2.
Operating income is a good summary measure of short‐term financial performance. By itself, however, it does not indicate whether operating income in the short run was earned by taking actions that would lead to long‐run competitive advantage. For example, Summit’s divisions might be able to increase short‐run operating income by producing more product while ignoring quality or rework. Harrington, however, would like to see division managers increase operating income without sacrificing quality. The new performance measures take a balanced scorecard approach by evaluating and rewarding managers on the basis of direct measures (such as rework costs, on‐time delivery performance, and sales returns). This motivates managers to take actions that Harrington believes will increase operating income now and in the future. The nonoperating income measures serve as surrogate measures of future profitability. The semiannual installments and total bonus for the Charter Division are calculated as follows: Charter Division Bonus Calculation For Year Ended December 31, 2013
January 1, 2013 to June 30, 2013 Profitability (0.02 $462,000) Rework (0.02 × $462,000) – $11,500 On‐time delivery No bonus—under 96% Sales returns [(0.015 × $4,200,000) – $84,000] 50% Semiannual installment Semiannual bonus awarded
July 1, 2012 to December 31, 2013 Profitability (0.02 $440,000) Rework (0.02 $440,000) – $11,000 On‐time delivery 96% to 98% Sales returns [(0.015 × $4,400,000) – $70,000] 50% Semiannual installment Semiannual bonus awarded Total bonus awarded for the year
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$ 9,240 (2,260) 0 (10,500) $ (3,520) $ 0
$ 8,800 (2,200) 2,000 (2,000) $ 6,600 $ 6,600 $ 6,600
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24‐20 (cont’d) The semiannual installments and total bonus for the Mesa Division are calculated as follows: Mesa Division Bonus Calculation For Year Ended December 31, 2013 January 1, 2013 to June 30, 2013 Profitability (0.02 $342,000) Rework (0.02 $342,000) – $6,000 On‐time delivery Over 98% [(0.015 $2,850,000) – $44,750] 50% Sales returns Semiannual bonus installment Semiannual bonus awarded July 1, 2013 to December 31, 2013 Profitability (0.02 $406,000) (0.02 $406,000) – $8,000 Rework On‐time delivery No bonus—under 96% Sales returns [(0.015 $2,900,000) – $42,500] which is greater than zero, yielding a bonus Semiannual bonus installment Semiannual bonus awarded Total bonus awarded for the year 3.
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$ 6,840 0 5,000 (1,000) $10,840 $10,840 $ 8,120 0 0 3,000 $11,120 $11,120 $21,960
The manager of the Charter Division is likely to be frustrated by the new plan, as the division bonus has fallen by more than $20,000 compared to the bonus of the previous year. However, the new performance measures have begun to have the desired effect––both on‐time deliveries and sales returns improved in the second half of the year, while rework costs were relatively even. If the division continues to improve at the same rate, the Charter bonus could approximate or exceed what it was under the old plan. The manager of the Mesa Division should be as satisfied with the new plan as with the old plan, as the bonus is almost equivalent. On‐time deliveries declined considerably in the second half of the year and rework costs increased. However, sales returns decreased slightly. Unless the manager institutes better controls, the bonus situation may not be as favourable in the future. This could motivate the manager to improve in the future but currently, at least, the
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Chapter 24
24‐20 (cont’d)
manager has been able to maintain his bonus with showing improvement in only one area targeted by Harrington. Ben Harrington’s revised bonus plan for the Charter Division fostered the following improvements in the second half of the year despite an increase in sales: An increase of 1.9% in on‐time deliveries. A $500 reduction in rework costs. A $14,000 reduction in sales returns. However, operating income as a percent of sales has decreased (11% to 10%). The Mesa Division’s bonus has remained at the status quo as a result of the following effects: An increase of 2.0 % in operating income as a percent of sales (12% to 14%). A decrease of 3.6% in on‐time deliveries. A $2,000 increase in rework costs. A $2,250 decrease in sales returns. This would suggest that revisions to the bonus plan are needed. Possible changes include: increasing the weights put on on‐time deliveries, rework costs, and sales returns in the performance measures while decreasing the weight put on operating income; a reward structure for rework costs that are below 2% of operating income that would encourage managers to drive costs lower; reviewing the whole year in total. The bonus plan should carry forward the negative amounts for one six‐month period into the next six‐month period incorporating the entire year when calculating a bonus; and developing benchmarks, and then giving rewards for improvements over prior periods and encouraging continuous improvement.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
24‐21 (25 min.) Goal‐incongruence and ROI. 1.
Bleefl would be better off if the machine is replaced. Its cost of capital is 6% and the IRR of the investment is 11%, indicating that this is a positive net present value project.
2.
The ROIs for the first five years are: Operating income1 End of year net assets Average net assets ROI
t1 $2,000 27,000 28,5002 7.02%
t 2 $2,000 24,000 25,500 7.84%
t3 $2,000 21,000 22,500 8.89%
t 4 $2,000 18,000 19,500 10.26%
t 5 $2,000 15,000 16,500 12.12%
1 2
Income is cash savings of $5,000 less $3,000 annual depreciation expense. ($30,000 + $27,000) ÷ 2 = $28,500 The manager would not want to replace the machine before retiring because the division is currently earning a ROI of 11%, and replacement of the machine will lower the ROI every year until the fifth year, when the manager is long gone.
3.
24–1198
Bleefl could use long term rather than short term ROI, or use ROI and some other long term measures to evaluate the Patio Furniture division to create goal congruence. Evaluating the managers on residual income rather than ROI would also achieve goal congruence. For example, replacing the machine increases residual income in Year 1. Residual income = Operating income − (6% × Average net assets) = $2,000 − (6% × 28,500) = $2,000 − $1,710 = $290
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Chapter 24
24‐22 (25 min.) ROI, RI, EVA. 1.
The required division ROIs using total assets as a measure of investment is shown in the row labeled (1) in Solution Exhibit 24‐22.
SOLUTION EXHIBIT 24‐22
(1)
(2)
(3)
2. 3.
4.
Total assets Current liabilities Operating income Required rate of return Total assets – current liabilities ROI (based on total assets) ($2,475,000 $33,000,000; $2,565,000 $28,500,000) RI (based on total assets – current liabilities) ($2,475,000 – (12% $26,400,000); $2,565,000 – (12% $20,100,000)) RI (based on total assets) ($2,475,000 – (12% $33,000,000); $2,565,000 – (12% $28,500,000))
New Car Division $33,000,000 $6,600,000 $2,475,000 12% $26,400,000
Performance Parts Division $28,500,000 $8,400,000 $2,565,000 12% $20,100,000
7.5%
9.0%
($693,000)
$153,000
($1,485,000)
($855,000)
The required division RIs using total assets minus current liabilities as a measure of investment is shown in the row labeled (2) in the table above. The row labeled (3) in the table above shows division RIs using assets as a measure of investment. Even with this new measure that is insensitive to the level of short‐term debt, the New Car Division has a relatively worse RI than the Performance Parts Division. Both RIs are negative, indicating that the divisions are not earning the 12% required rate of return on their assets. After‐tax cost of debt financing = (1– 0.4) × 10% = 6% After‐tax cost of equity financing = 15%
($18,000,000 6%) + ($12,000,000 15%) Weighted average = 9.6% cost of capital = $18,000,000 + $12,000,000
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24‐22 (cont’d) 5.
Operating income after tax 0.6 × operating income before tax $ 1,485,000 $1,539,000 (0.6 × $2,475,000; 0.6 × $2,565,000) Required return for EVA 9.6% × Investment (9.6% × $26,400,000; 9.6% × $20,100,000) 2,534,400 1,929,600 EVA (Optg. inc. after tax – reqd. return) $(1,049,400) $ (390,600) Both the residual income and the EVA calculations indicate that the Performance Parts Division is performing nominally better than the New Car Division. The Performance Parts Division has a higher residual income. The negative EVA for both divisions indicates that, on an after‐tax basis, the divisions are destroying value––the after‐tax economic returns from them are less than the required returns.
24‐23 (25–30 min.) ROI, RI, measurement of assets. The method for computing profitability preferred by each manager follows: Manager of Method Chosen Radnor Easttown Marion
RI based on net book value RI based on gross book value ROI based on either gross or net book value
Supporting Calculations: ROI Calculations Operating Income Operating Income Gross Book Value Net Book Value * Division Radnor $142,050 ÷ $1,200,000 = 11.84% (3) $142,050 ÷ $555,000 = 25.59% (3) Easttown $137,550 ÷ $1,140,000 = 12.07% (2) $137,550 ÷ $525,000 = 26.20% (2) Marion $ 92,100 ÷ $ 750,000 = 12.28% (1) $ 92,100 ÷ $330,000 = 27.91% (1)
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Chapter 24
24‐23 (cont’d)
RI Calculations Division
Operating Income – 10% Gross BV
Radnor $142,050 – $120,000 = $22,050 (2) Easttown $137,550 – $114,000 = $23,550 (1) Marion $ 92,100 – $ 75,000 = $17,100 (3) 1
1
Operating Income – 10% Net BV $142,050 – $55,500 = $86,550 (1) $137,550 – $52,500 = $85,050 (2) $ 92,100 – $33,000 = $59,100 (3)
Net book value is gross book value minus accumulated depreciation.
The biggest weakness of ROI is the tendency to reject projects that will lower historical ROI even though the prospective ROI exceeds the required ROI. RI achieves goal congruence because subunits will make investments as long as they earn a rate in excess of the required return for investments. The biggest weakness of RI is that it favours larger divisions in ranking performance. The greater the amount of the investment (the size of the division), the more likely that larger divisions will be favoured assuming that income grows proportionately. The strength of ROI is that it is a ratio and so does not favour larger divisions. In general, though, achieving goal congruence is very important. Therefore, the RI measure is often preferred to ROI.
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Instructor’s Solutions Manual for Cost Accounting, 6Ce
24‐24 (20 min.) Multinational performance measurement, ROI, RI.
Operating income Operating income = = 15% Total assets $8,000,000
1a.
Canadian. Divisionʹs ROI in 2014 =
Hence, operating income = 15% $8,000,000 = $1,200,000.
1b.
Norwegian Divisionʹs ROI in 2014 (based on kroners) =
2.
8,100,000 kroners = 15.43% 52,500,000 kroners
Convert total assets into dollars using the December 31, 2013 exchange rate, the rate prevailing when the assets were acquired (6 kroners = $1):
52,500,000 kroners = $8,750,000 6 kroner per dollar
Convert operating income into dollars at the average exchange rate prevailing during 2014 when operating income was earned (6.5 kroners = $1):
8,100,000 kroners = $1,246,154 6.5 kroners per dollar $1,246,154 Comparable ROI for Norwegian Division = = 14.24% $8,750,000
The Norwegian Division’s ROI based on kroners is helped by the inflation that occurs in Norway in 2014 (that caused the Norwegian kroner to weaken against the dollar from 6 kroners = $1 on 12‐31‐2013 to 7 kroners = $1 on 12‐31‐2014). Inflation boosts the divisionʹs operating income. Since the assets are acquired at the start of the year 2014, the asset values are not increased by the inflation that occurs during the year. The net effect of inflation on ROI calculated in kroners is to use an inflated value for the numerator relative to the denominator. Adjusting for inflationary and currency differences negates the effects of any differences in inflation rates between the two countries on the calculation of ROI. After these adjustments, the Canadian Division earned a higher ROI than the Norwegian Division.
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Chapter 24
24‐24 (cont’d) 3.
Canadian Division’s RI in 2014 = $1,200,000 (12% $8,000,000) = $1,200,000 $960,000 = $240,000 Norwegian Division’s RI in 2014 (in CAD) is calculated as: $1,246,154 (12% $8,750,000) = 1,246,154 $1,050,000 = $196,154. The Canadian Division’s RI also exceeds the Norwegian Division’s RI in 2014 by $43,846.
24‐25 (20 min.) ROI, RI, EVA, and performance evaluation. 1. ROI and residual income: Clothing Cosmetics Operating income after tax $ 600,000 $ 1,600,000 Net assets $3,000,000 $10,000,000 ROI ($600,000 ÷ $3,000,000; $1,600,000 ÷ $10,000,000) 20.00% 16.00% RI ($600,000 − 10% × 3,000,000; $1,600,000− 10% × $10,000,000) $ 300,000 $ 600,000 Which measure is being used to evaluate performance will determine which division gets the bonus. If the firm uses ROI, then the Clothing Division will get the bonus. However, the Cosmetics Division has much larger absolute and residual income. If the firm evaluates performance based on residual income, then the Cosmetics Division will get the bonus. The advantages of ROI are that it is easy to calculate and easy to understand. It combines revenue, cost, and investment into a single number, so that managers can clearly see what can be changed to increase returns. But ROI has limitations. Managers who are evaluated based on ROI have incentives to reject investments with ROIs below their divisions’ current average ROI, even when the investments have positive net present values.
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24‐25 (cont’d) Residual income has the advantage of goal congruence because any investment that earns more than the required capital charge increases RI, and thereby increases the managers’ performance evaluations. The measure is not subject to the “cutoff” problems that occur when managers compare a new investment’s ROI to the average ROI being earned on existing investments. However, RI is not as easy to measure because it requires the company to determine the amount of capital and the cost of capital for each business unit. 2. Clothing Cosmetics Adjusted operating income $ 720,000 $1,430,000 Net assets less current liabilities $2,600,000 $9,800,000 Revised ROI ($720,000 ÷ $2,600,000; $1,430,000 ÷ 9,800,000) 27.69% 14.59% EVA ($720,000 − 10% × $2,600,000; $1,430,000 − 10% × $9,800,000) $ 460,000 $ 450,000 Clothing Division will get the bonus because both EVA and ROI (using EVA’s definition of operating income and assets) are higher than those of the Cosmetics Division. 3. Since this is a manufacturing firm, there are a variety of nonfinancial performance measures such as market share, customer satisfaction, defect rates, and response times that can be used to ensure that managers do not increase short‐term operating income, residual income, or EVA at the expense of performance categories that are long‐term drivers of company value.
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Chapter 24
24‐26 (20–30 min.) Evaluate behavioural effects. 1a.
An evaluation of the three proposals to compensate Marks, the general manager of the Dexter Division follows: (i) Paying Marks a flat salary will not subject Marks to any risk, but it will provide no incentives for Marks to undertake extra physical and mental effort. (ii) Rewarding Marks only on the basis of Dexter Division’s ROI would motivate Marks to put in extra effort to increase ROI because Marks’s rewards would increase with increases in ROI. But compensating Marks solely on the basis of ROI subjects Marks to excessive risk because the division’s ROI depends not only on Marks’s effort but also on other random factors over which Marks has no control. For example, Marks may put in a great deal of effort, but, despite this effort, the divisionʹs ROI may be low because of adverse factors (such as high interest rates or a recession) which Marks cannot control. To compensate Marks for taking on uncontrollable risk, AMCO must pay him additional amounts within the structure of the ROI‐based arrangement. Thus, compensating Marks only on the basis of performance‐based incentives will cost AMCO more money, on average, than paying Marks a flat salary. The key question is whether the benefits of motivating additional effort justify the higher costs of performance‐ based rewards. Furthermore, the objective of maximizing ROI may induce Marks to reject projects that, from the viewpoint of the organization as a whole, should be accepted. This would occur for projects that would reduce Marks’s overall ROI but which would earn a return greater than the required rate of return for that project. (iii) The motivation for having some salary and some performance‐based bonus in compensation arrangements is to balance the benefits of incentives against the extra costs of imposing uncontrollable risk on the manager.
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24‐26 (cont’d) 1b.
2.
Marks’s complaint does not appear to be valid. The senior management of AMCO is proposing to benchmark Marks’s performance using a relative performance evaluation (RPE) system. RPE controls for common uncontrollable factors that similarly affect the performance of managers operating in the same environments (for example, the same industry). If business conditions for car battery manufacturers are good, all businesses manufacturing car batteries will probably perform well. A superior indicator of Marks’s performance is how well Marks performed relative to his peers. The goal is to filter out the common noise to get a better understanding of Marks’s performance. Marks’s complaint will be valid only if there are significant differences in investments, assets, and the business environment in which AMCO and Tiara operate. Given the information in the problem, this does not appear to be the case. Of course, using RPE does not eliminate the problem with the ROI measure itself. To keep ROI high, Marks will still prefer to reject projects whose ROI is greater than the required rate of return but lower than the current ROI. Superior performance measures change significantly with the managerʹs performance and not very much with changes in factors that are beyond the manager’s control. If Marks has no authority for making capital investment decisions, then ROI is not a good measure of Marks’s performance––it varies with the actions taken by others rather than the actions taken by Marks. AMCO may wish to evaluate Marks on the basis of operating income rather than ROI. ROI, however, may be a good measure to evaluate Dexterʹs economic viability. Senior management at AMCO could use ROI to evaluate if the Dexter Division’s income provides a reasonable return on investment, regardless of who has authority for making capital investment decisions. That is, ROI may be an inappropriate measure of Marks’s performance but a reasonable measure of the economic viability of the Dexter Division. If, for whatever reasons—bad capital investments, weak economic conditions, etc.—the Division shows poor economic performance as computed by ROI, AMCO management may decide to shut down the division even though they may simultaneously conclude that Marks performed well.
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Chapter 24
24‐26 (cont’d) 3.
There are two main concerns with Marks’s plans. First, creating very strong sales incentives imposes excessive risk on the sales force because a salesperson’s performance is affected not only by his or her own effort, but also by random factors (such as a recession in the industry) that are beyond the salespersonʹs control. If salespersons are risk averse, the firm will have to compensate them for bearing this extra uncontrollable risk. Second, compensating salespersons only on the basis of sales creates strong incentives to sell, but may result in lower levels of customer service and sales support (this was the story at Sears auto repair shops where a change in the contractual terms of mechanics to “produce” more repairs caused unobservable quality to be negatively affected). Where employees perform multiple tasks, it may be important to “blunt” incentives on those aspects of the job that can be measured well (for example, sales) to try and achieve a better balance of the two tasks (for example, sales and customer service and support). In addition, the division should try to better monitor customer service and customer satisfaction through surveys, or through quantifying the amount of repeat business.
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24‐27 (20 min.) Residual income and EVA, timing issues. 1. RI =Operating income – (WACC x Assets) = $649,000 – (0.08 x $5,690,000) = $649,000 ‐ $455,200 = $193,800 2. EVA = Adjusted operating income – (WACC x (Total assets – Current liabilities)) Operating income is adjusted as follows: Operating income $ 649,000 Add back this period’s advertising expense 100,000 Less amortized advertising (1/4 of year’s expense) (25,000) Adjusted operating income $ 724,000 Assets are adjusted as follows: Total assets $5,690,000 Plus capitalized, unamortized advertising 75,000 Adjusted total assets $5,765,000 EVA = $724,000 – (0.08 × ($5,765,000 − $700,000)) = $724,000 − $405,200 = $318,800 3. The differences between the RI and EVA results are due to two factors in this problem: the definition of capital and the treatment of advertising. EVA subtracts current liabilities from total assets when computing capital. Since some types of current liabilities represent sources of “free” short‐term funds (e.g., holding off payments to suppliers), they reduce the assets needed to produce income. If short‐term liabilities represent a source of funds, EVA more accurately reflects the assets that the company employed to achieve its operating income. Under traditional accounting rules, advertising is a period expense, and the costs and benefits of advertising are not matched if advertising’s effects affect revenues over multiple years. Consequently, EVA does a better job matching revenues and costs when the effects of advertising persist over multiple periods and solves the goal incongruence problem that sometimes arises with the ROI measure.
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Chapter 24
24‐28 (40‐50 min.) ROI performance measures based on historical cost and current cost. 1.
2.
ROI using historical cost measures: Passion Fruit $260,000 ÷ $680,000 = 38.24% Kiwi Fruit $440,000 ÷ $2,300,000 = 19.13% Mango Fruit $760,000 ÷ $3,240,000 = 23.46% The Passion Fruit Division appears to be considerably more efficient than the Kiwi Fruit and Mango Fruit Divisions. The gross book values (i.e., the original costs of the plants) under historical cost are calculated as the useful life of each plant (12 years) × the annual depreciation: Passion Fruit 12 x $140,000 = $1,680,000 Kiwi Fruit 12 x $200,000 = $2,400,000 = $2,880,000 Mango Fruit 12 x $240,000 Step 1: Restate long‐term assets from gross book value at historical cost to gross book value at current cost as of the end of 2013:
(Gross book value of long‐term assets at historical cost) / (Construction cost index in 2008 ÷ Construction cost index in year of construction). Passion Fruit $1,680,000 x (170 ÷ 100) = $2,856,000 Kiwi Fruit $2,400,000 x (170 ÷ 136) = $3,000,000 Mango Fruit $2,880,000 x (170 ÷ 160) = $3,060,000 Step 2: Derive net book value of long‐term assets at current cost as of the end of 2013. (Estimated useful life of each plant is 12 years.) (Gross book value of long‐term assets at current cost at the end of 2013) × (Estimated remaining useful life ÷ Estimated total useful life) Passion Fruit $2,856,000 x (2 ÷ 12) = $ 476,000 $3,000,000 x (9 ÷ 12) = $2,250,000 Kiwi Fruit Mango Fruit $3,060,000 x (11 ÷ 12) = $2,805,000
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24‐28 (cont’d) Step 3: Compute current cost of total assets at the end of 2013. (Assume current assets of each plant are expressed in 2013 dollars.) (Current assets at the end of 2013 [given]) + (Net book value of long‐term assets at current cost at the end of 2013 [Step 2]) Passion Fruit $400,000 + $476,000 = $ 876,000 Kiwi Fruit $500,000 + $2,250,000 = $2,750,000 Mango Fruit $600,000 + $2,805,000 = $3,405,000 Step 4: Compute current‐cost depreciation expense in 2013 dollars. Gross book value of long‐term assets at current cost at the end of 2013 (from Step 1) ÷ 12 Passion Fruit $2,856,000 ÷ 12 = $238,000 Kiwi Fruit $3,000,000 ÷ 12 = $250,000 Mango Fruit $3,060,000 ÷ 12 = $255,000 Step 5: Compute 2013 operating income using 2013 current‐cost depreciation expense. (Historical‐cost operating income – [Current‐cost depreciation expense in 2013 dollars (Step 4) – Historical‐cost depreciation expense]) Passion Fruit $260,000 – ($238,000 – $140,000) = $162,000 Kiwi Fruit $440,000 – ($250,000 – $200,000) = $390,000 Mango Fruit $760,000 – ($255,000 – $240,000) = $745,000 Step 6: Compute ROI using current‐cost estimates for long‐term assets and depreciation expense (Step 5 ÷ Step 3). Passion Fruit $162,000 ÷ $ 876,000 = 18.49% $390,000 ÷ $2,750,000 = 14.18% Kiwi Fruit Mango Fruit $745,000 ÷ $3,405,000 = 21.88%
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24‐28 (cont’d) Passion Fruit Kiwi Fruit Mango Fruit
3.
ROI: Historical Cost 38.24% 19.13 23.46
ROI: Current Cost 18.49% 14.18 21.88
Use of current cost results in the Mango Fruit Division appearing to be the most efficient. The Passion Fruit ROI is reduced substantially when the ten‐year‐old plant is restated for the 70% increase in construction costs over the 2003 to 2013 period. Use of current costs increases the comparability of ROI measures across divisions’ operating plants built at different construction cost price levels. Use of current cost also will increase the willingness of managers, evaluated on the basis of ROI, to move between divisions with assets purchased many years ago and divisions with assets purchased in recent years.
24‐29 (40–50 min.) Evaluating managers, ROI, DuPont method, value‐chain analysis of cost structure. 1. NetPro 2012 2013 On Point 2012 2013
ROI = Operating Income Operating Income Revenues = × Total Assets Revenues Total Assets 0.26 ($157.5 $600) 0.29 ($157.5 $540) 1.11 ($600 $540) 0.94 ($480 $510) 0.13 ($ 60.5 $480) 0.12 ($ 60.5 $510) 1.25 ($300 $240) 0.10 ($29.7 $300) 0.12 ($29.7 $240) 1.46 ($525 $360) 0.19 ($99.3 $525) 0.28 ($99.3 $360)
NetPro’s ROI has declined sizably from 2012 to 2013 largely because of a decline in operating income to revenues (return on sales or ROS). On Point’s ROI has more than doubled from 2012 to 2013, in large part due to an increase in operating income to revenues (return on sales or ROS). The DuPont analysis tells us that NetPro’s ROI decline arises from a serious degradation in its ROS, and not from any significant problem in assets turns, i.e., its management should probably examine and try to fix its eroding margins. This insight would not be available from a direct calculation of ROI.
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24‐29 (cont’d) 2.
NetPro
On Point 2012 2013 13% 18% 40 30 36 36 11 16 100% 100%
Business Function 2012 2013 Research and development a 16% 10% 35 Production 30 Marketing & Distribution 39 46 10 Customer Service 15 Total costs* 100% 100% a For example, $71.2 $442.5; $40.2 $419.5; $35.9 $270.3; $76.1 $425.7 *May sum to more than 100% due to rounding. Business functions with increases/decreases in the percentage of total costs from 2012 to 2013 are: NetPro On Point Increases Production Research and development Marketing & Distribution Customer service Decreases Research and development Production Customer service NetPro has decreased expenditures in two key business functions that are critical in the computer industry–– research and development and customer service. These costs are (using the chapter’s terminology) discretionary and they can be reduced in the short run without any short‐run effect on customers, but such action is likely to create serious problems in the long run. On Point, on the other hand, increased its percentage of total costs in these two areas. 3. Based on the information provided, Provan is the better candidate for president of Peach Computer. Both NetPro and On Point are in the same industry. Provan has been CEO of On Point at a time when it has considerably outperformed NetPro: a. The ROI of On Point has increased from 2012 to 2013, while that of NetPro has decreased. b. The computer magazine has given the highest ranking to On Point’s main product, while NetPro’s received a lower ranking.
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24‐29 (cont’d) c. On Point has received high marks for new products (the lifeblood of a computer company), while NetProʹs new‐product introductions have been described as “mediocre.” It is likely that On Point’s better rating for its current product is based on customer service and its better rating for its new product is based on research and development spending.
24‐30 (20 min.) ROI, RI, and multinational firms. 1.
Calculation of ROI and RI before currency translation: Canada France Investment in assets $3,490,000 2,400,000 eu Income for current year $ 383,900 266,400 eu ROI ($383,900 ÷ $3,490,000; 266,400 eu ÷ 2,400,000 eu ) 11.0% 11.1% RI ($383,900 − 0.10 × $3,490,000; 266,400 eu − 0.10 × 2,400,000 eu) $ 34,900 26, 400 eu Canada France Investment in assets $3,490,000 $2,880,000 (2,400,000 eu × $1.20) Income for current year $ 383,900 $ 346,320 (266,400 eu ×$1.30) ROI ($383,900 ÷ $3,490,000; $346,320 ÷ $2,880,000 ) 11.0% 12.0% RI ($383,900 − 0.10 × $3,490,000; $346,320 − 0.10 × $2,880,000) $ 34,900 $ 58,320 Without currency translation, the ROIs in Canada and France are similar, but after currency translation the ROI of France is substantially higher. Residual income is not comparable before currency translation given the different currencies used by the units. After translation, RI is higher in France. Together with the higher ROI, the RI results suggest that performance was better in France than in Canada.
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24‐30 (cont’d) 2.
Adjusting for differences in currency values makes the comparison of performance between foreign countries more meaningful since the accounting measures being examined are more comparable. However, changes in relative currency values can lead to misleading performance evaluations if interdependencies exist across units in different countries.
24‐31 (30‐40 min.) Multinational firms, differing risk, comparison of profit, ROI, and RI. 1.
Comparisons of after‐tax operating income using translated values:
Canada Germany NZ Operating revenues ($10,479,000; 5,200,000 eu × $1.32; 4,800,000 NZD × $0.67) $10,479,000 $6,864,000 $3,216,000 Operating expenses ($7,510,000; 3,600,000 eu × $1.32; 3,500,000 NZD × $0.67) 7,510,000 4,752,000 2,345,000 Operating income 2,969,000 2,112,000 871,000 Income tax at 40%; 30%; 20% 1,187,600 633,600 174,200 After‐tax operating income $ 1,781,400 $1,478,400 $ 696,800
In terms of after‐tax operating income, the Canadian division is doing best, with Germany a close second. However, the New Zealand division is far behind the other two in terms of operating income. 2. Comparison of ROI for each division. Canada Germany NZ 1. After‐tax operating income $1,781,400 $1,478,400 $696,800 2. Long‐term assets ($14,845,000; 9,856,000 eu × $1.25; 9,072,912 NZD × $0.64) $14,845,000 $12,320,000 $5,806,667 3. ROI (Row 1 ÷ Row 2) 12% 12% 12% Because of differences in the assets employed in each division, they all have the same return on investment despite the differences in after‐tax operating income.
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Chapter 24
24‐31 (cont’d) 3. Canada Germany NZ After‐tax operating income $ 1,781,400 $ 1,478,400 $ 696,800 Long‐term assets $14,845,000 $12,320,000 $5,806,667 Cost of capital (given) 6% 10% 13% Imputed cost of assets (cost of capital times long‐term assets $ 890,700 $ 1,232,000 $ 754,867 Residual income (After‐tax operating income less imputed cost of assets) $ 890,700 $ 246,400 $ (58,067) In contrast to the same ROIs found in each division, the Canada division is doing best using residual income, and New Zealand has negative residual income. These differences are due to differences in the cost of capital. 4. Comparison of ROI using pre‐tax operating income: Canada Germany NZ 1. Operating income (from requirement 1) $ 2,969,000 $ 2,112,000 $ 871,000 2. Long‐term assets $14,845,000 $12,320,000 $5,806,667 3. ROI (Row 1 ÷ Row 2) 20% 17.14% 15% The ROI computed using pre‐tax operating income is much higher than the 12% ROI for all divisions using after‐tax income. The differences arise from the different tax rates imposed on each division. The divisions should be compared on after‐tax dollars because selling prices and costs in each country reflect different expectations regarding income taxes. For instance, selling prices are likely to be higher in the US division, which has the highest tax rate.
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PROBLEMS
24‐32 (30–40 min.) ROI, RI, DuPont method, investment decisions, balanced scorecard. 1. 2013
ROI =
Revenue Operating Income Operating Income × = Total Assets Revenues Total Assets 0.239 ($4,620 ÷ $19,320) 0.224 ($4,620 $20,580) Print 0.939 ($19,320 $20,580) Internet 2.133 ($26,880 $12,600) 0.025 ($ 672 ÷ $26,880) 0.053 ($ 672 $12,600) The Print Division has a relatively high ROI because of its high income margin relative to Internet. The Internet Division has a low ROI despite a high investment turnover because of its very low income margin. 2. Although the proposed investment is small, relative to the total assets invested, it earns less than the 2013 return on investment (0.224) (All dollar numbers in millions): $4,620 = 0.224 2013 ROI (before proposal) = $20,580 $120 Investment proposal ROI = = 0.150 $800 $4,620 $120 = 0.222 2013 ROI (with proposal) = $20,580 $800 Given the existing bonus plan, any proposal that reduces the ROI is unattractive. 3a. Residual income for 2013 (before proposal, in millions): Operating Imputed Division Income Interest Charge Residual Income Print Internet
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$4,620 672
– –
$3,087 (0.15 × $20,580) = $1,533 1,890 (0.15 × $12,600) = (1,218)
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Chapter 24
24‐32 (cont’d) 3b.
Residual income for proposal (in millions): Operating Income
$120
Imputed Interest Charge –
$120 (0.15 × $800) =
Residual Income
$0
Investing in the fast‐speed printing press will have no effect on the Print Division’s residual income. As a result, if Mays is evaluated using a residual income measure, Mays would be indifferent to adopting the printing press proposal. 4.
As discussed in requirement 3b, Turner could consider using RI. The use of RI motivates managers to accept any project that makes a positive contribution to net income after the cost of the invested capital is taken into account. Making such investments will have a positive effect on News Mogul Group’s customers. Turner may also want to consider nonfinancial measures such as newspaper subscription levels, internet audience size, repeat purchase patterns, and market share. These measures will require managers to invest in areas that have favourable long‐run effects on News Mogul Group’s customers.
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24‐33 (20–30 min.) Division manager’s compensation. 1
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Consider each of the three proposals that Turner is considering: a. Compensate managers on the basis of division RI. The benefit of this arrangement is that managers would be motivated to put in extra effort to increase RI because managers’ rewards would increase with increases in RI. But compensating managers largely on the basis of RI subjects the managers to excessive risk, because each division’s RI depends not only on the manager’s effort but also on random factors over which the manager has no control. A manager may put in a great deal of effort, but the division’s RI may be low because of adverse factors (high interest, recession) that the manager cannot control. To compensate managers for taking on uncontrollable risk, Turner must pay them additional amounts within the structure of the RI‐based arrangement. Thus, using mainly performance‐based incentives will cost Turner more money, on average, than paying a flat salary. The key question is whether the benefits of motivating additional effort justify the higher costs of performance‐based rewards. The motivation for having some salary and some performance‐based bonus in compensation arrangements is to balance the benefits of incentives against the extra costs of imposing uncontrollable risk on the manager. Finally, rewarding a manager only on the basis of division RI will induce managers to maximize the division’s RI even if taking such actions are not in the best interests of the company as a whole. b. Compensate managers on the basis of companywide RI. Rewarding managers on the basis of companywide RI will motivate managers to take actions that are in the best interests of the company rather than actions that maximize a division’s RI. A negative feature of this arrangement is that each division manager’s compensation will now depend not only on the performance of that division manager but also on the performance of the other division managers. For example, the compensation of Mays, the manager of the Print Division, will depend on how well the manager of Internet performs, even though Mays himself may have little influence over the performance of these divisions. Therefore, compensating managers on the basis of companywide RI will impose extra risk on each division manager, and will raise the cost of compensating them, on average.
Copyright © 2013 Pearson Canada Inc.
Chapter 24
24‐33 (cont’d) c.
2.
3.
Compensate managers using the other division’s RI as a benchmark. The benefit of benchmarking or relative performance evaluation is to cancel out the effects of common noncontrollable factors that affect a performance measure. Taking out the effects of these factors provides better information about a manager’s performance. What is critical, however, for benchmarking and relative performance evaluation to be effective is that similar noncontrollable factors affect each division. It is not clear that the same noncontrollable factors that affect the performance of the Print Division (cost of newsprint paper, for example) also affect the performance of the Internet division. If the noncontrollable factors are not the same, then comparing the RI of one division to the RI of the other division will not provide useful information for relative performance evaluation. A second factor for Turner to consider is the impact that benchmarking and relative performance evaluation will have on the incentives for the division managers of the Print and Internet Divisions to cooperate with one another. Benchmarking one division against another means that a division manager will look good by improving his or her own performance, or by making the performance of the other division manager look bad.
Using measures like RI and ROI—diagnostic levers of control—can cause managers to cut corners and take other actions that boost short‐run performance but harm the company in the long run. Turner can guard against such problems by introducing and upholding strong boundary and belief systems of control within the company. Strict codes of conduct should govern what employees cannot do. Turner should also foster a culture where employees have a deep belief in the value of the company’s journalistic mission. Another potential problem of an excessive focus on diagnostic measures is a myopic disregard for emerging threats and opportunities. Interactive control systems, based on debate and discussion and regular review of strategic uncertainties and the competitive landscape can help overcome this problem. Turner should not only ask for regular reports on ROI, RI, etc., he should meet regularly with division managers, discuss 5‐ and 10‐year strategic plans, and obtain their field‐based inputs. Such regular dialogues will help surface emerging threats and opportunities, and the action plans that need to be taken in response.
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24‐34 (20 min.) Executive compensation, balanced scorecard. The percentage changes in net income and customer satisfaction in the three business units between 2012 and 2013 are: Retail Business Credit Banking Banking Cards Percentage change in net income ($3,220,000 − $2,800,000) ÷ $2,800,000; ($3,016,000 − $2,900,000) ÷ $2,900,000; ($2,722,500 − $2,750,000) ÷ $2,750,000 15% 4% (1%) Percentage change in customer satisfaction (73 − 73) ÷ 73; (75.6 − 70) ÷ 70; (79.35 − 69) ÷ 69 0% 8% 15% 1. The bonus formula indicates that the executives of the three units will receive the following 2013 bonuses as a percent of salary: Retail Banking: 15% + 0% = 15% of salary Business Banking: 4% + 8% = 12% of salary Credit Cards: 0% + 15% = 15% of salary 2. The results show an inverse relation between changes in net income and changes in customer satisfaction. When changes in net income are higher, changes in customer satisfaction are lower, and vice versa. This suggests that some units may be making investments in customer satisfaction to increase long‐term financial performance, even though these investments cause short‐term net income to decline. Alternatively, some units may be over‐investing in customer satisfaction initiatives, causing overall financial performance to decline. The company needs to examine whether one or both of these explanations is true. 3. The board of directors can set targets for changes in both net income and customer satisfaction. This would allow the company to take differences in the units, their competitive environments, and their customers into account when assessing performance. Target setting would also allow the company to reward managers when desirable investments in one dimension lead to short‐term declines in the other.
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24‐34 (cont’d) In addition, the board can improve the bonus plan by determining the relative importance of short‐term changes in net income and customer satisfaction. Currently, a 1% change in either measure receives the same weight in the bonus formula, and declines have no effect on bonus payouts. However, a 1% increase in one measure may be more valuable than a 1% increase in the other, and declines in either measure may have a bigger effect on long‐term value than increases. The payment formula can be modified by putting appropriate (and different) weights on each of these factors.
24‐35 (25 min.) Incentives in compensation (A. Spero, adapted). 1a.
1b.
Variable manufacturing cost per unit = $2 Fixed manufacturing cost per unit = $9,000,000 500,000 = $18 Total manufacturing cost per unit = $2 + $18 = $20 Revenue, $20 500,000 Variable manufacturing costs, $2 500,000 Fixed manufacturing costs, $18 500,000 Fixed marketing costs Total costs Operating loss Ending inventory: $0
$10,000,000 1,000,000 9,000,000 400,000 10,400,000 $ (400,000)
Variable manufacturing cost per unit = $2 Fixed manufacturing cost per unit = $9,000,000 600,000 = $15 Total manufacturing cost per unit = $2 + $15 = $17 Revenues, $20 500,000 $10,000,000 Variable manufacturing costs, $2 500,000 1,000,000 Fixed manufacturing costs, $15 500,000 7,500,000 Fixed marketing costs 400,000 Total costs 8,900,000 Operating income $ 1,100,000 Ending inventory = $17 per unit 100,000 units = $1,700,000
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24‐35 (cont’d) 2.
3.
It would not be ethical for Jones to produce more units just to show better operating results. Professional managers are expected to take better operating actions that are in the best interests of their shareholders. Jones’s action would benefit him at the cost of shareholders. Jones’s actions would be equivalent to “cooking the books,” even though he may achieve this by producing more inventory than was needed, rather than through fictitious accounting. Some students might argue that Jonesʹs behaviour is not unethical––he simply took advantage of the faulty contract the board of directors had given him when he was hired. Asking distributors to take more products than they need is also equivalent to “cooking the books.” In effect, distributors are being coerced into taking more product. This is a particular problem if distributors will take less product in the following year or alternatively return the excess inventory next year. Some students might argue that Jones’s behaviour is not unethical—it is up to the distributors to decide whether to take more inventory or not. So long as Jones is not forcing the product on the distributors, it is not unethical for Jones to push sales this year even if the excess product will sit in the distributors’ inventory.
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Chapter 24
23‐36 (15 min.) Incentives in compensation. 1.
2.
If Amy Kimbell “turns a blind eye” toward what she has just observed at the UFP log yard, she will be violating the competence, integrity, and objectivity standards for management accountants. Competence Perform professional duties in accordance with technical standards Integrity Communicate unfavourable as well as favourable information and professional judgments or opinions Refrain from engaging in or supporting any activity that would discredit the profession Credibility Communicate information fairly and objectively Disclose fully all relevant information that could reasonably be expected to influence an intended user’s understanding of the reports, comments, and recommendations. Kimbell should: a. Try to follow established policies to try to bring the issue to the attention of management through regular channels; then, if necessary, b. Discuss the problem with the immediate superior who is not involved in the understatement of quality and costs. c. Clarify relevant ethical issues with an objective advisor, preferably a professional person outside UFP. d. If all the above channels fail to lead to a correction in the organization, she may have to resign and become a “whistle‐blower” to bring UFP to justice. UFP is clearly emphasizing profit, driving managers to find ways to keep profits strong and increasing. This is a diagnostic measure, and over‐emphasis on diagnostic measures can cause employees to do whatever is necessary— including unethical actions—to keep the measures in the acceptable range, not attract negative senior management attention and possibly improve compensation and job reviews.
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24‐36 (cont’d) To avoid problems like this in the future, UFP needs to establish some strong boundary systems and codes of conduct. There should be a clear message from upper management that unethical behaviour will not be tolerated. Training, role‐ plays, and case studies can be used to raise awareness about these issues, and strong sanctions should be put in place if the rules are violated. An effective boundary system is needed to keep managers “on the right path.” UFP also needs to articulate a belief system of core values. The goal is to inspire managers and employees to do their best, exercise greater responsibility, take pride in their work, and do things the right way.
24‐37 (20‐30 min.) Various measures of profitability. The method for computing profitability preferred by each manager follows: Manager of Method Chosen Mastex Residual income based on net book value Banjo Residual income based on gross book value Randal ROI based on either gross or net book value The biggest weakness of ROI is the tendency to reject projects that will lower historical ROI even though the prospective ROI exceeds the required ROI. The biggest weakness of residual income is it favours larger divisions in ranking performance. The greater the amount of the investment (the size of the division), the more likely that larger divisions will be favoured assuming that income grows proportionately. Supporting Computations:
Return on Investment Calculations Operating Income Operating Income Division Gross Book Value Net Book Value* Mastex $57,000 ÷ $480,000 = 11.875% (3) $57,000 ÷ $240,000 = 23.750% (3) Banjo $55,200 ÷ $456,000 = 12.105% (2) $55,200 ÷ $228,000 = 24.211% (2) Randal $36,960 ÷ $300,000 = 12.320% (1) $36,960 ÷ $150,000 = 24.640% (1) Residual Income Calculations Division Operating Income – 10% Gross BV Operating Income – 10% Net BV* Mastex $57,000 – $48,000 = $9,000 (2) $57,000 – $24,000 = $33,000 (1) Banjo $55,200 – $45,600 = $9,600 (1) $55,200 – $22,800 = $32,400 (2) Randal $36,960 – $30,000 = $6,960 (3) $36,960 – $15,000 = $21,960 (3) *Net book value is one half of gross book value given that all assets were purchased ten years ago and have ten years useful life remaining, zero terminal disposal price, and straight‐line amortization
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Chapter 24
24‐38 (40‐50 min.) Evaluate accrual measures. 1.
2.
ROI using historical cost measures: Calistoga
:
$156, 000 $408, 000
=
38.24%
Alpine Springs
:
$264, 000 $1, 380, 000
=
19.13%
Rocky Mountains
:
$456, 000 $1, 944, 000
=
23.46%
The Calistoga Division appears to be considerably more efficient than the Alpine Springs and Rocky Mountain Divisions. The gross book values (i.e., the original costs of the plants) under historical cost are calculated as the useful life of each plant (12) the annual amortization: Calistoga Alpine Springs Rocky Mountains
: 12 $ 84,000 : 12 $120,000 : 12 $144,000
= = =
$1,008,000 $1,440,000 $1,728,000
Step 1: Restate long‐term assets from gross book value at historical cost to gross book value at current cost as of the end of 2013. Gross book valu e
Constru ction cost ind ex in 2007 of long-term assets Constru ction cost ind ex in year of constru ction at historical cost
Calistoga: Alpine Springs: Rocky Mountain:
$1,008,000 (170 ÷ 100) $1,440,000 (170 ÷ 136) $1,728,000 (170 ÷ 160)
$1,713,600 $1,800,000 $1,836,000
Step 2: Derive net book value of long‐term assets at current cost as of the end of 2013. (Assume estimated useful life of each plant is 12 years.) Gross book value of long‐term assets at current cost at the end of 2013
Calistoga: Alpine Springs: Rocky Mountains:
= = =
Estimated useful life remaining Estimated total useful life
$1,713,600 (2 ÷ 12) $1,800,000 (9 ÷ 12) $1,836,000 (11 ÷ 12)
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= = =
$ 285,600 $1,350,000 $1,683,000
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24‐38 (cont’d)
Step 3: Compute current cost of total assets at the end of 2013. (Assume current assets of each plant is expressed in 2007 dollars.) Net book value of long‐term assets at Current assets at the end of 2013 (given) current cost at the end of 2013 (Step 2)
$240,000 + $ 285,600 $300,000 + $1,350,000 $360,000 + $1,683,000
Calistoga: = $ 525,600 Alpine Springs: = $1,650,000 Rocky Mountains: = $2,043,000 Step 4: Compute current‐cost amortization expense in 2013 dollars. Gross book value of long‐term assets at current cost at the end of 2013 (from Step 1) (1 ÷ 12) = $142,800 Calistoga: $1,713,600 (1 ÷ 12) Alpine Springs: $1,800,000 (1 ÷ 12) = $150,000 Rocky Mountains: $1,836,000 (1 ÷ 12) = $153,000 Step 5: Compute 2013 operating income using 2013 current‐cost amortization. Current‐cost Historical‐cost amortization in Historical‐cost operating income amortization 2013 dollars (Step 4)
Calistoga: Alpine Springs: Rocky Mountains:
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$156,000 – ($142,800 – $ 84,000) $264,000 – ($150,000 – $120,000) $456,000 – ($153,000 – $144,000)
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= = =
$ 97,200 $234,000 $447,000
Chapter 24
Step 6: Compute ROI using current‐cost estimates for long‐term assets and amortization. Operating income for 2013 using 2013 current‐cost amortization (Step 5) Current cost of total assets at the end of 2013 (Step 3)
Calistoga: Alpine Springs: Rocky Mountains:
$ 97,200 ÷ $ 525,600 $234,000 ÷ $1,650,000 $447,000 ÷ $2,043,000
= = =
18.49% 14.18% 21.88%
ROI: ROI: Historical Cost Current Cost Calistoga 38.24% 18.49 % Alpine Springs 19.13 14.18 Rocky Mountains 23.46 21.88 Use of current cost results in the Rocky Mountains Division appearing to be the most efficient. The Calistoga ROI is reduced substantially when the ten year old plant is restated for the 70% increase in construction costs over the 2003 to 2013 period. 3.
Use of current costs increases the comparability of ROI measures across divisions operating plants built at different construction cost price levels. Use of current cost also will increase the willingness of managers, evaluated on the basis of ROI, to move from divisions with assets purchased many years ago to divisions with assets purchased in recent years.
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24‐39 Financial and nonfinancial performance measures, goal‐congruence. 1.
2.
Operating income is a good summary measure of short‐term financial performance. By itself, however, it does not indicate whether operating income in the short run was earned by taking actions that would lead to long‐run competitive advantage. For example, Leader Automotive Canada’s plants might be able to increase short‐run operating income by producing more product while ignoring quality or rework. The CEO, however, would like to see division managers increase operating income without sacrificing quality. The new performance measures take a balanced scorecard approach by evaluating and rewarding managers on the basis of direct measures (such as rework costs, on‐time delivery performance, and rejections or sales returns). This motivates managers to take actions that the CEO believes will increase operating income now and in the future. The nonoperating income measures serve as surrogate measures of future profitability. The semi‐annual installments and total bonus for the Alliston Plant are calculated as follows:
Alliston Division Bonus Calculation For Year Ended December 31, 2013 January 1, 2013 to June 30, 2013 Profitability (0.02) ($554,400) Rework (0.02 $554,400) – $13,800 On‐time delivery No bonus – under 96% Sales returns [(0.015 $5,040,000) – $100,800] 50% Semi‐annual installment Semi‐annual bonus awarded
$ 11,088 (2,712) 0 (12,600) $ (4,224) $ 0
July 1, 2013 to December 31, 2013 (0.02) ($528,000) (0.02 $528,000) – $13,200 96% to 98% [(0.015 $5,280,000) – $84,000] 50%
Profitability Rework On‐time delivery Sales returns Semi‐annual installment Semi‐annual bonus awarded Total bonus awarded for the year
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Copyright © 2013 Pearson Canada Inc.
$10,560 (2,640) 2,400 (2,400) $ 7,920 $ 7,920 $ 7,920
Chapter 24
24‐39 (cont’d)
The semi‐annual installments and total bonus for the Oshawa Plant are calculated as follows: Oshawa Plant Bonus Calculation For Year Ended December 31, 2013 Profitability Rework On‐time delivery Sales returns
January 1, 2013 to June 30, 2013 (0.02) ($410,400) (0.02 $410,400) – $7,200 Over 98% [(0.015 $3,420,000) – $53,700] 50%
Semi‐annual bonus installment Semi‐annual bonus awarded
3.
Profitability Rework On‐time delivery Sales returns
July 1, 2013 to December 31, 2013 (0.02) ($487,000) (0.02 $487,000) – $8,600 No bonus—under 96% [(0.015 $3,480,000) – $51,000] which is greater than zero, yielding a bonus of
$ 8,208 0* 6,000 (1,200) $13,008 $13,008
$ 9,740 0* 0
3,600
Semi‐annual bonus installment Semi‐annual bonus awarded
$13,340 $13,340
Total bonus awarded for the year * 2% operating income rework costs: No reduction.
$26,348
The manager of the Alliston Plant is likely to be frustrated by the new plan as the division bonus is more than $24,500 less than the previous year. However, the new performance measures have begun to have the desired effect—both on‐time deliveries and sales returns improved in the second half of the year while rework costs were relatively even. If the division continues to improve at the same rate, the Alliston Plant bonus could approximate or exceed what it was under the old plan. The manager of the Oshawa Division should be as satisfied with the new plan as with the old plan as the bonus is almost equivalent. However, there is no sign of improvements in the performance measures instituted by the CEO in this plant; as a matter of fact, on‐time deliveries declined considerably in the second half of the year. Unless the manager institutes better controls, the bonus situation may not be as favourable in the future. This could motivate the manager to improve in the future but currently, at least, the manager has been able to maintain his bonus without showing improvements in the areas targeted by the CEO.
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24‐39 (cont’d) The CEO’s revised bonus plan for the Alliston Plant fostered the following improvements in the second half of the year despite an increase in sales: • Increase of 1.9 percent in on‐time deliveries. • $600 reduction in rework costs. • $16,800 reduction in rejections (sales returns). However, operating income as a percentage of sales has decreased (11 to 10 percent) The Oshawa Plant’s bonus has remained at the status quo as a result of the following effects • Increase of 2.0 percent in operating income as a percent of sales (12 to 14 percent). • Decrease of 3.6 percent in on‐time deliveries. • $1,400 increase in rework costs. • $2,750 decrease in rejections (sales returns). This would suggest that there needs to be some revisions to the bonus plan. Possible changes include: • Increasing the weights put on on‐time deliveries, rework costs, and sales returns in the performance measures while decreasing the weight put on operating income. • Creating a reward structure for rework costs that are below two percent of operating income that would encourage managers to drive costs lower. • Reviewing the whole year in total. The bonus plan should carry forward the negative amounts for one six‐month period into the next six‐month period, incorporating the entire year when calculating a bonus. • Developing benchmarks, and then giving rewards for improvements over prior periods and encouraging continuous improvement.
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Chapter 24
24‐40 (30‐40 min.) Financial performance measures with uncertainty (CMA adapted). 1.
First we need to build a decision table to evaluate all the estimates:
Combinations B = Best L = Likely W = Worst
Expected sales (in thousands)
Contribution margin 55% (in thousands)
W(.15)xW(.20)=(.03) 0.75x100,000=75,000 0.55x75,000=41,250
Expected fixed costs (in thousands)
Expected income (in thousands)
1.20x25,000=30,000
0.03x11,250=337.50
W(.15)xL(.60)=(.09)
75,000
41,250
25,000
0.09x16,250=1,462.50
W(.15)xB(.20)=(.03)
75,000
41,250
0.80x25,000=20,000
0.03x21,250=637.50
L(.75)xW(.20)=(.15)
100,000
55,000
1.20x25,000=30,000
0.15x25,000=3,750
L(.75)xL(.60)=(.45)
100,000
55,000
25,000
0.45x30,000=13,500
L(.75)xB(.20)=(.15)
100,000
55,000
0.80x25,000=20,000
0.15x35,000=5,250
B(.10)xW(.20)=(.02) 1.25x100,000=125,000
68,750
1.20x25,000=30,000
0.02x38,750=775
B(.10)xL(.60)=(.06)
125,000
68,750
25,000
0.06x43,750=2,625
B(.10)xB(.20)=(.02)
125,000
68,750
0.80x25,000=20,000
0.02x48,750=975.00
Expected Outcome
29,312.50
Second we need to calculate the bonus: Expected net income $29,312,500 Minimum required $26,500,000 Excess obtained 2,812,500 Bonus: 1% of the excess $28,125 Conclusion: the expected value of the General Manager’s bonus is not enough to pay for the leisure boat. 2. The difference between the two remuneration schemes are as follows: Current Proposed Flat salary $75,000 $100,000 Expected bonus $28,125 ‐ ‐ ‐ ‐ ‐ Total remuneration $103,125 (1) $100,000 (2) (1) Expected remuneration, contains some uncertainty and partially depends on the manager’s effort. (2) Remuneration with certainty but does not depend on manager’s effort The general manager’s answer depends on his aversion to risk. If he is adverse to risk (dislikes risk) he will accept the change in remuneration. The proposed change in remuneration in the long run is not in the best interest of Electric Machines’ owners because the manager’s compensation is independent from his effort and results obtained.
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24‐41 (25 min.) Historical‐cost and current‐cost ROI measures. 1.
ROI = Operating Income Historical cost of investment ROI = Operating Income Current cost of investment
2.
Jane and Rutherford 28,000 50,000
28,000 120,000
= 56%
= 23.33%
Major Mackenzie and Keele 33,000 100,000 33,000 135,000
=33%
=24.44%
Weston and Langstaff 15,000 30,000 15,000 80,000
= 50%
=18.75%
Using investments at historical cost as the denominator, the location of Jane and Rutherford has the highest ROI and the location of Major Mackenzie and Keele the lowest. Using investment at current cost as the denominator, Major Mackenzie and Keele has the highest ROI and Weston and Langstaff the lowest. The choice of an appropriate measure depends on how World of 1 Dollar Ltd. judges the performance of its dollar stores. If World of 1 Dollar uses a single benchmark (say, 20%) in judging the performance of each store, the current cost measure will promote comparability among stores that were bought at different times or in areas with different real estate markets. Historical cost will give rise to differences in ROI among dollar stores that are unrelated to differences in operating efficiency. For example, in times of rising prices, the oldest store (Jane and Rutherford) will have a lower historical cost investment level than the newest store (Major Mackenzie and Keele) for comparable amounts of square metres of store space in comparable locations. The current cost differences of the investment in the Jane and Rutherford store and Major Mackenzie and Keele store, for example, are much smaller than the differences in historical costs, due largely to the different time periods in which the two stores were built. A drawback of current cost is that current cost estimates are difficult to obtain. If World of 1 Dollar Ltd. tailors the performance benchmark for each convenience store in its budgeting process, then the choice of a specific investment measure is less contentious. For example, if historical cost is used, the budgeted ROI benchmark for the Major Mackenzie and Keele store could be, say, 30%, whereas the budgeted ROI benchmark for the other two stores could be, say, 50%. Another benefit of tailoring the budget to each manager is that more incentives are provided to managers who are put in charge of poorly performing stores or stores in highly competitive markets.
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Chapter 24
24‐42 (20‐30 min.) Risk sharing, incentives, benchmarking, multiple tasks. 1.
An evaluation of the four proposals to compensate the new general manager of the Industrial Pumps Division follows: (i) Paying a flat salary will not subject the manager to any risk, but will provide no incentives for undertaking extra physical and mental effort. (ii) Rewarding the manager only on the basis of Industrial Pumps Division’s RI would motivate the manager to put in extra effort to increase RI because the rewards would increase with increases in RI. But compensating the divisional manager solely on the basis of RI subjects him or her to excessive risk, because the division’s RI depends not only on the manager’s effort but also on other random factors over which the manager has no control. For example, the new divisional manager may put in a great deal of effort, but despite this effort, the division’s RI may be low because of adverse factors such as high interest rates, or a recession. To compensate the divisional manager for taking on uncontrollable risk, Acme Inc. must pay additional amounts within the structure of the RI‐based arrangement. Thus, compensating the divisional manager only on the basis of performance‐based incentives will cost Acme more money, on average, than paying a flat salary. The key question is whether the benefits of motivating additional effort justify the higher costs of performance‐based rewards. This has not been a problem with Cynthia Franco due to her high intrinsic motivation, but now with the candidates available the lack of intrinsic motivation requires from Acme Inc. a new incentive scheme that can extract the greater effort possible from the new manager. Furthermore, linking the bonus to RI and not to ROI is a positive decision. The objective of maximizing ROI may induce the general manager to reject projects that, from the viewpoint of the organization as a whole, should be accepted. This would occur for projects that would reduce Industrial Pumps’ overall ROI but which would earn a return greater than the required rate of return for that project. (iii) The motivation for having some salary and some performance‐based bonus in compensation arrangements is to balance the benefits of incentives against the extra costs of imposing uncontrollable risk on the manager. The only caveat of proposal 3 is that the variable portion of the bonus be tied to ROI and not to RI. (iv) The motivation for having some salary and some performance‐based bonus in compensation arrangements is to balance the benefits of incentives against the extra costs of imposing uncontrollable risk on the manager. There are two caveats in proposal 4: one is that the variable portion of the bonus is tied to ROI and not to RI, and the other is whether, in fact, Pumps‐for‐All Ltd. is really comparable with Industrial Pumps Division.
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24‐42 (cont’d) The senior management of Acme Inc. is proposing to benchmark the division’s performance using a relative performance evaluation (RPE) system. RPE controls for common uncontrollable factors that similarly affect the performance of managers operating in the same environments (for example, the same industry). If business conditions for industrial pumps are good, all businesses manufacturing and selling industrial pumps will probably perform well. A superior indicator of the manager’s performance is how well the division performed relative to his peers. 2.
3.
The candidate’s complaint does not appear to be valid. The senior management of Acme Inc. is proposing to benchmark Industrial Pumps Division’s performance using a relative performance evaluation (RPE) system. RPE controls for common uncontrollable factors that similarly affect the performance of managers operating in the same environments (for example, the same industry). If business conditions for industrial pumps are good, all businesses manufacturing and selling industrial pumps will probably perform well. A superior indicator of the manager’s performance is how well the division performed relative to his peers. The goal is to filter out the common noise to get a better understanding of the manager’s performance. The complaint will only be valid if there are significant differences in investments, assets, and the business environment in which Pumps‐ for‐All and Industrial Pumps Division operate. Given the information in the problem, this does not appear to be the case. Superior performance measures change significantly with the manager’s performance and not very much with changes in factors that are beyond the manager’s control. If the divisional manager has no authority for making capital investment decisions, then ROI is not a good measure of his/her performance—it varies with the actions taken by others rather than the actions taken by him/her. Acme may wish to evaluate the divisional manager on the basis of operating income rather than ROI. ROI, however, may be a good measure to evaluate Industrial Pumps Division’s economic viability. Senior management at Acme Inc. could use ROI to evaluate if the division’s income provides a reasonable return on investment, regardless of who has authority for making capital investment decisions. That is, ROI may be an inappropriate measure of managers’ performance but a reasonable measure of the economic viability of the division. If, for whatever reasons (bad capital investments, weak economic conditions, etc.), the Division shows poor economic performance, as computed by ROI, Acme Inc. management may decide to shut down the division even though they may simultaneously conclude that the manager performed well.
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Chapter 24
24‐42 (cont’d) 4.
There are two main concerns with Cynthia’s plans. First, creating very strong sales incentives imposes excessive risk on the sales force, because a salesperson’s performance is affected not only by his or her own effort, but also by random factors (such as a recession in the industry) that are beyond the salesperson’s control. If salespersons are risk averse, the firm will have to compensate them for bearing this extra uncontrollable risk. Second, compensating salespersons only on the basis of sales creates strong incentives to sell, but may result in lower levels of customer service and sales support. (This was the case at Sears auto repair shops where a change in the contractual terms of mechanics to “produce” more repairs caused unobservable quality to be negatively affected.) Where employees perform multiple tasks, it may be important to “blunt” incentives on those aspects of the job that can be measured well (for example, sales) to try and achieve a better balance of the two tasks (for example, sales and customer service and support). In addition, the division should try to better monitor customer service and customer satisfaction through surveys, or through quantifying the amount of repeat business.
24‐43 (20 min.) Nonfinancial performance and levers of control (CMA adapted). 1. The issues facing Chang require an understanding of ethics and accounting. Chang is being pressured to violate the ethics of professional competence by James’s request to omit a portion of her report. By withholding data regarding the time and costs of training staff to operate the stamping machine and to manually assemble the recliners, she is providing senior management with an incomplete description of events that overstate the performance of Jones’s initiative. Additional pressure is being applied by James to violate the integrity of the process by asking Chang to rewrite her report in a more positive light. Chang has already identified the issues of scrap rates and throughput as significant in the low performance obtained by Jones. Any effort to downplay their impact on the evaluation of entering this new market segment undermines the integrity of process to examine all issues fairly. The changes to the report outlined by James violate its objectivity. James’s relationship with Jones as a family member leaves him in a conflict of interest to objectively evaluate Jones’s handling of this entire initiative. In response, James is applying pressure on Chang to soften her conclusions, as they will likely impact Jones’s career in the long term and on Jones’s subjective portion of bonuses in the short term. Finally, there may have been a violation of confidentiality because Jones was informed before the senior management. If Chang is confident that her research is sound and that her report findings are valid and a true reflection of the actual performance of the initiative, then she needs to explain this to James. If he continues with his pressures (including threats to the
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24‐43 (cont’d) subjective portion of Chang’s bonus), Chang must tell James that she feels that he is pressuring her to act in an unethical manner. If this does not result in James allowing Chang to act in the manner she believes is ethical, then she must proceed to James’s superior with this information. 2. Chang is preparing a report that will help diagnose whether this initiative is performing to expectations; she is contributing to a diagnostic control system but the integrity of the measurement and reporting is being threatened by James’ requests. Light Seating Canada motivates Jones and other managers to achieve pre‐ determined goals by holding managers accountable for and rewarding them for meeting these goals. In this situation, it is clear that one consequence of the pressure to perform is that managers (Jones and James) materially misstate non‐financial measures to obscure actual performance. Avoiding unethical and illegal behaviour requires that companies balance the push for performance resulting from diagnostic control systems, the first of four levers of control, with three other levers: boundary systems, belief systems, and interactive control systems. 24‐44 (20‐30 min.) Various measures of profitability. The method for computing profitability preferred by each manager follows: Manager of Method Chosen Ontario Residual income based on gross book value Quebec Residual income based on net book value Alberta ROI based on either gross or net book value The biggest weakness of ROI is the tendency to reject projects that will lower historical ROI even though the prospective ROI exceeds the required ROI. The biggest weakness of residual income is it favours larger divisions in ranking performance. The greater the amount of the investment (the size of the division), the more likely that larger divisions will be favoured, assuming that income grows proportionately as it does in the case of Ontario and Quebec divisions.
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Chapter 24
24‐44 (cont’d) Supporting Computations: Return on Investment Calculations Operating Income Operating Income Division Gross Book Value Net Book Value* Ontario $150,000 ÷ $1,000,000 = 15% (2) $150,000 ÷ $500,000 = 30% (2) Quebec $120,000 ÷ $1,000,000 = 12% (3) $120,000 ÷ $500,000 = 24% (3) Alberta $55,000 ÷ $350,000 = 15.71% (1) $55,000 ÷ $175,000 = 31.43% (1) Residual Income Calculations Division Operating Income – 12% Gross BV Operating Income – 12% Net BV* Ontario $150,000 – $120,000 = $30,000 (1) $150,000 – $60,000 = $90,000 (2) Quebec $120,000 – $120,000 = $0 (3) $120,000 – $60,000 = $60,000 (1) Alberta $55,000 – $42,000 = $13,000 (2) $55,000 – $21,000 = $34,000 (3) *Net book value is one half of gross book value, given that all assets were purchased ten years ago and have ten years useful life remaining, zero terminal disposal price, and straight‐line amortization.
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COLLABORATIVE LEARNING CASES 24‐45 (30 min.) ROI, RI, division manager’s compensation, nonfinancial measures.
1.
ROS =
Operating Income = $3,000,000 / $20,000,000 Sales
=
15%
ROI =
Operating Income = $3,000,000 / $15,000,000 Total Assets
=
20%
2.
a. ROI = 22% =
Operating Income = X / $15,000,000 Total Assets
Hence operating income = 22% 15,000,000 = $3,300,000 Operating income = Revenue – Costs, therefore: Costs = $20,000,000 – $3,300,000 = $16,700,000 Currently, Costs = $20,000,000 – $3,000,000 = $17,000,000 Costs need to be reduced by $300,000 ($17,000,000 – $16,700,000) b. ROI = 22% =
3. 4.
5.
Operating Income = $3,000,000 / X Total Assets
Hence X = $3,000,000 ÷ 22% = $13,636,364 Mandarin would need to decrease total assets in 2013 by $1,363,636 ($15,000,000 – $13,636,364). RI = Income – (Required rate of return Investment) = $3,000,000 – (0.18 $15,000,000) = $300,000 Mandarin wants RI to increase by 30% $300,000 = $90,000 That is, Mandarin wants RI in 2013 to be $300,000 + $90,000 = $390,000 If Mandarin cuts costs by $30,000 its operating income will increase to $3,000,000 + $30,000 = $3,030,000
RI2014 = $390,000 = $3,030,000 – (0.18 Assets) $2,640,000 = 0.18 Assets Assets = $2,640,000 ÷ 0.18 = $14,666,667
Mandarin would need to decrease total assets by $333,333 ($15,000,000 – $14,666,667). Key Products could use ROS to some degree. That way there is less focus on cutting costs and reduction in assets and more emphasis on actual revenues and how they translate into operating income. Key Products may also want to consider nonfinancial measures such as customer satisfaction and market share, quality, yield, and on‐time performance as well as monitor employee satisfaction and the development of employee skills.
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Chapter 24
24‐46 (40‐50 min.) ROI, RI, division manager’s compensation, nonfinancial measures (CGA adapted). The first issue is: Was focusing on quality the right decision for GA? Evidence from both sales and the quality‐cost report support the decision taken by management to focus on quality. External failure costs dropped from 8.2% of sales in 2011 to 1.15% of sales in 2013. Given that external failures are those captured by the customer, this percentage has a direct effect on product reputation. That sales had stopped plummeting and remained relatively stable for two years would indicate that the emphasis on quality to the customer was paying off. Still, product reputation is a valuable but fragile commodity. Given the level of competition, the question of whether GA responded in time remains to be answered. The second issue is to evaluate the compensation system and the transfer pricing policy. Why do all 3 divisions have to be profit centres? It seems that electronic circuits can be a cost centre and transfer at standard full cost might be the ideal. Why use RI with the required rate of return as the lowest ROI? It seems that electronic circuits is in a different business with a different margin ratio than the other 2 divisions. Why is the performance in quality being compared if electronic circuits cannot have ‘external failures’ according to company’s policies? Battery‐powered 2013 Electronic circuits Coffee makers small tools ROI 20% 10% 11% RI 500,000 – 250,000 0 660,000 – 600,000 50% of bonus pool: $50,000 $0 $12,000 financial performance Quality effort (level of Minimum Maximum Maximum appraisal and prevention) Quality costs as % of Low Very high Very high sales 50% of bonus pool: 5%–0%=5% of net 2%–1.2%=0.8% 3.2%–2.4% = 0.8% of net quality performance profit of net profit profit Quality performance 5% of net profit = 0.8% of net 0.8% of net profit = $5,280 bonus $25,000 profit = $5,600 Total bonus $75,000 $5,600 $17,280
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