Eee Ruet Syllabus

Editorial Board: Dr. Md. Fayzur Rahman, Professor and Head (EEE) Dr. Mirza Golam Rabbani, Associate Professor (EEE) Dr. Md. Ashraful Hoque, Associate Professor (EEE) Md. Zahurul Islam Sarkar, Assistant Professor (EEE) Amit Roy Chowdhury, Technical Officer (EEE)

Cover Concept: Amit Roy Chowdhury (EEE) Cover Design: Sujan Sarkar (The Bengal Press) Computer Compose: Md. Asif Iqbal (EEE)

DISCLAIMER The information contained in this booklet are intended to provide guidance to those who are concerned with both undergraduate and postgraduate studies in Electrical & Electronic Engineering. No responsibility will be borne by the Department of Electrical & Electronic Engineering or the Bangladesh Institute of Technology, Rajshahi if any inconvenience or expenditure is caused to any person because of the information of this booklet or any error in quoting the rules and regulations described herein. Also the information contained in it is subject to change at any time without any prior notification.

Edition: 1st Edition, May 2003.

Address for Correspondence: Head Department of Electrical & Electronic Engineering, Bangladesh Institute of Technology (BIT), Rajshahi Rajshahi-6204, Bangladesh. Phone: +88-0721-750356, +880-0721-750742-43,Ext. 403(off) Fax: +88-0721-750356 Email : [email protected]

Printed at The Bengal Press, Ranibazar, Rajshahi.

Published by Department of Electrical & Electronic Engineering, Bangladesh Institute of Technology (BIT), Rajshahi Rajshahi-6204, Bangladesh.

PREFACE Bangladesh Institute of Technology (BIT), Rajshahi offers both undergraduate and post-graduate programs. The undergraduate system follows the semester system and the post-graduate system follows the course system. The up-to-date rules and regulations, as approved by the Academic Council of BIT, have been incorporated in full in this booklet for information of the students, teachers and advisers. The departmental and non-departmental courses, together with details of courses offered to students of this department, are also presented in this book. It is worth mentioning that the departmental and the non-departmental courses for Electrical & Electronic Engineering students have undergone a major revision to cater recent advancements in the field of Electrical & Electronic Technology. The revised curriculum as incorporated in this booklet has been approved by the 93rd meeting of the Academic Council of BIT Rajshahi on 19th May’2003. The postgraduate degree program follows the course system. The rules and regulations of the postgraduate students have been incorporated in this booklet. Some general information about this institute, its historical background, facilities and information on the teaching department and the institute administration have also been included. The students are advised to be in touch with the course coordinator of the department so as to be aware of any changes made by the appropriate authority.

Professor Dr. Md. Fayzur Rahman Head Department of Electrical & Electronic Engineering BIT, Rajshahi. May 2003.

CONTENTS About the Institute The Institute Location Campus List of Committees Library facilities Student Health Service Computer Center Directorate of Student Welfare Games and Sports Students Hall of Residences Auditorium Complex and Seminar Hall Departments Academic Support Units BIT Administration

1 1 1 1 1 2 2 2 2 3 3 4 4 4 5

The Department of Electrical & Electronic Engineering The Department List of Faculty Members Laboratory facilities of the Department Consultancy, research and Testing Services Electrical & Electronic Engineering Association

6 6 6 9 9 9

Academic Ordinance for Undergraduate Studies

10

Academic Ordinance for Postgraduate Studies

30

Syllabus Summary of Undergraduate Course plan Courses offered to the undergraduate students Summary of Courses Detail Syllabus

42 42 43 43 48

Postgraduate Courses of the Department of Electrical and Electronic Engineering Detail Syllabus

81 83

ABOUT THE INSTITUTE The Institute: Bangladesh Institute of Technology, Rajshahi is one of the four Institutes of Technology created as the center of excellence for higher studies, research and development in science, engineering and technology in Bangladesh. It was established as Engineering College, Rajshahi in 1964, and was converted to Bangladesh Institute of Technology, Rajshahi (BIT Rajshahi) in 1986, to provide with powers to decide it’s own academic policy, to conduct own examinations and to award its own degrees. Location: The Institute is located on the North side of Rajshahi-Natore-Dhaka road at Kazla, 5 kilometers east of Rajshahi city, on 152 acres of land. Known as Green Campus with so many varieties of trees, the campus is laid out with picturesque landscape by the side of famous Padma river and Rajshahi University. Campus: The Campus presents spectacle of harmony in architecture and natural beauty. The campus area has been divided into different functional zones: (i) Residence for students, (ii) Residential zones of faculty and other supporting staff, (iii) Academic zone for academic buildings and laboratories/workshops, and (iv) Cultural cum social and recreational zones for students. A branch of Rupali Bank, a post office, an auditorium and a medical center are located on the campus. For the education of the children of the institute employees, there is one school cum college. The shopping center includes a branch of general stores, barber shop, photo copying facilities and restaurant. List of Committees: The Institute has following statutory committees: 1) Board of Governors (BOG). 2) Academic Council. 3) Board of Discipline. 4) Finance Committee. 5) Planning and Development Committee. 6) Committee for Advanced Studies and Research (CASR).

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7) Committee for Post Graduate Courses and Studies (CPGCS). 8) Committee for Undergraduate Courses and Studies. Library Facilities: a) Central Library The central library building is within the walking distance from the academic building. It is compact building with built-in facilities to provide the following services to the students and teachers. i) Acquisition and processing of books, journals and other published materials. ii) Issue and receipt of books. iii) Research and Journal section. iv) Reading room. b) Rental Library Each degree awarding department has its own rental library that provides books on rent to the students. Students Health Service: An on campus medical center provides primary and basic health care facilities to the students (residential and non-residential) free of charges. Two full-time MBBS doctors, one compounder and two staffs provide these facilities to the students. For specialized consultation on complicated cases, the center refers the patients to specialist consultants Computer Center: The central computer center plays an important role in the teaching and research of the students of different departments and provides useful services in data processing required in various sectors on national development. Each department also has separate computer laboratory where the students and the teachers of the respective departments can use computers for their thesis and research works. These computer centers are equipped with Pentium based machines operated under Windows and LINUX/UNIX operating system. Directorate of Student Welfare: The Directorate of Student Welfare is responsible for the various activities related to the physical, social and other aspects of welfare of the students. These include arrangement of supervision for halls of residence, programs for physical education, games and sports, supervision of the 2

programs of co-curricular activities of students through the Central Student Union and through the students union of the various halls of residence. It is also responsible for providing health services through the students health center, to direct students consulting to organize programs, in arranging employment for students and to organize and maintain contact with the alumni of BIT, etc. The Central Students Union, most of its members are elected by the students, maintains and aids the new students in their introduction to the BIT as well as in looking after the problems of the students. The student unions of the various residential halls also arrange their individual socio-culture activities, literary competitions etc and help the hall management in the day-to –day functioning of the halls.

All halls are set in gardens and frontal green plantations and lawns and all halls are within easy walking distance of the institute. The students live in these halls on community basis, while a single room depending on its size, is shared by 2, 3 or 4 students. Each hall has a common room facility. A provost and few assistant provosts administrate each hall.

Games And Sports Facilities: The sports center of the BIT provides excellent facilities to students for acquiring physical fitness that is indispensable for a healthy mind and body. The institute maintains a beautiful play ground, tennis lawn and basket ball court. The sports center arranges a colorful athletic competition every year in the form of annual sports meet. For improvement of the standard of games and spots, regular coaching by experts is arranged. The institute arranges inter-year, inter-departmental football, cricket, basket ball and volleyball competition. Teacher student friendly games are also arranged at times.

Departments: BIT has now four teaching departments. At present undergraduate programs leading to Bachelor of Science in Engineering (B.Sc. Engg.) degrees are offered in 4 departments.

Students Hall of Residences: There are 5 halls of residence at BIT campus. The total capacity of these halls is about 1000. Followings are the halls with their respective capacities. Some of the halls are named after the national hero who sacrificed their lives in the liberation war of Bangladesh in 1971. The existing capacity is around 80% of the total number of students of BIT. Non residential students are to be attached with a hall so that the administrative control on the students becomes hall based. Serial No.

Name of the halls

1. 2. 3. 4. 5.

Shahid Lt. Selim Hall Shahid Shahidul Islam Hall Shahid Abdul Hamid Hall Tin Shed Hall (Extension) Ladies Hall 3

Residential capacity 350 225 225 100 100

Auditorium Complex And Seminar Hall: The institute has an Auditorium Complex with modern facilities having a seating capacity of about 700 which is capable of holding conferences, seminars and other cultural programs. Besides this there is an airconditioned seminar room with capacity of 40 in the department of Electrical & Electronic Engineering.

Department of Civil Engineering (CE) Department of Electrical & Electronic Engineering (EEE) Department of Mechanical Engineering (ME) Department of Computer Science & Engineering (CSE). Post graduate programs leading to Master of Science in Engineering (M. Sc. Engg.) or Master of Engineering (M. Engg.) degrees are offered only in three departments. Department of Civil Engineering (CE) Department of Electrical & Electronic Engineering (EEE) Department of Mechanical Engineering (ME) Academic Support Units: a) Administrative Building This is a three-storied building. It accommodates the offices of director, registrar and three departmental Heads: Civil Engineering, Mechanical Engineering and Computer Science and Engineering. Rupali Bank and Post office are situated in this building. The laboratories of Physics and Chemistry departments are also situated in this building. At present the CSE department run their laboratory

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in the 2nd floor of this building. Some the students attend their classes in the 1st and 2nd floor. b) Laboratories of Other Departments. The Civil Engineering department has 4 laboratories: (1) Soil Mechanics Lab, (2) Strength of Materials Lab, (3) Fluid Mechanics Lab, and (4) Environment Lab The Mechanical Engineering department has 7 laboratories: (1) Fluid Mechanics Lab, (2) Heat Engine Lab, (3) Machine Shop, (4) Wood Shop, (5) Boiler Shop, (6) Sheet Metal & Welding Shop and (7) Foundry Shop. Computer Science engineering department has three Laboratories at present. BIT Administration On the recommendation of different committees, the Board of Governors (BOG) approve the policies and operational procedures of the Institute. The committees are : the Academic Council, the Committee of Planning and Development and the Finance Committee. The Director is the administrative head of the Institute. The Registrar coordinates academic programs and administration. Chairman, BOG: Professor Dr. Md. M. Anwar Hussain Director: Professor Dr. Md. Keramat Ali Mollah Registrar (In-Charge):Mr. Md. Ismail Hossain

The Department of Electrical & Electronic Engineering. The Department The department with 23 faculty members is active with various program in Electrical & Electronic Engineering. The department offers basic and advanced optional courses. The department has a number of wellestablished laboratories, namely, Electronics Laboratory, Electrical Machine Laboratory, Electrical Measurement Laboratory, Power Electronics Laboratory, Microwave and Telecommunication Laboratory and Computer Laboratory. In addition to the above laboratory the department has a workshop. Well equipped computer facilities are provided by the department for the students, faculty members as well as the researchers. Modern machines with latest software are available in the Computer laboratory. The department has a Rental library room with current journals that provides an excellent opportunities for research. Books are provided to the students on rent basis for each semester from the rental library. Students are encouraged for academic excellence by awarding prized, medals and certificates for year wise performance. An official award named as “Joynal Memorial Award” is also given to the student who obtains the highest grade point amongst the second year students of all disciplines. The department has a vital role to solve the local industrial problems by providing testing and consulting facilities. Different organizations and other people of various disciplines are being trained time to time with computer literacy by the department. It also arranges co curriculum activities among the students such as cultural, games, debate, etc. every year. List of Faculty Members 1.

A. M. Rezaul Karim Talukder

Professor

B. Sc. Engg.(BUET), M.Sc. Engg. (Canada) Field of Specialization: Power System, Power Station, Switchgear & Protection, Electrical Measurement.

2.

Dr. Md. Yeakub Hussain

Professor

B. Sc. Engg.(RU), M.Sc. Engg. (BUET), Ph.D (IIT) Field of Specialization: Power System Stability, Power System Operation, Electrical Machine.

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6

3.

Dr. Md. Mortuza Ali

Professor

B. Sc. Engg.(RU), M.Sc. Engg. (Japan), Ph.D (Japan) Field of Specialization: High Power Microwave devices, Electromagnetic Compatibility.

13. Ajoy Krishno Sarker

Assistant Professor

B. Sc. Engg.(BITR). Field of Interest: Communication Engineering.

(Abroad on Higher Studies)

14. S. M. Abdur Razzak 4.

Dr. Md. Ruhul Amin

Professor

B. Sc. Engg.(RU), M.Sc. Engg. (BUET), Ph.D (Japan) Field of Specialization: High power Microwave, Solar photo voltaic.

Assistant Professor

B. Sc. Engg.(BITR). Field of Interest: Digital Communication, Electrical Motor Drives.

15. Md. Shamsuzzaman 5.

Dr. Muhammad Abdul Goffar Khan

Professor

B. Sc. Engg.(RU), M.Sc. Engg. (BUET), Ph.D (IITK) Field of Specialization: Computer Methods in Power System, High Voltage Engg, SCR Controlled Drives, Renewable Energy.

6.

Dr. Md. Fayzur Rahman

16. Md. Hasan Ali Professor

B. Sc. Engg.(RU), M.Sc. Engg. (India), Ph.D (South Korea) Field of Specialization: High Voltage Discharge Application

7.

Dr. Kazi Khairul Islam

Associate Professor

Dr. Mirza Golam Rabbani

Associate Professor

Dr. Md. Ashraful Hoque


Lecturer

B. Sc. Engg.(BITK). Field of Interest: Communication Engineering


18. Md. Shamim Anower

B. Sc. Engg.(RU), M.Sc. Engg. (IIT), Ph.D (Singapore) Field of Specialization: Power System, Computer Aided Design

9.

Lecturer

B. Sc. Engg.(BITR). Field of Interest: Power System

17. I. M. T. R. Al Wazedi

B. Sc. Engg.(RU), M.Sc. Engg. (IIT), Ph.D (IIT) Field of Specialization: Instrumentation & Control System, Energy System, Power Electronic Circuits & System.

8.

Lecturer

B. Sc. Engg.(BITR). M. Engg.(Singapore) (Abroad on Higher Studies) Field of Specialization: Communication Network and Simulation

Lecturer

B. Sc. Engg.(BITR). Field of Interest: Power System & Communication.

19. Md. Zulfiquar Ali Bhotto

Lecturer

B. Sc. Engg.(BITR). Field of Interest: Electronic & Communication.

Associate Professor

B. Sc. Engg.(BUET), M.Sc. Engg. (Canada), Ph.D (Canada) Field of Specialization: Power Electronic Circuits, Electric Motor Drive

10. Md. Shahiduzzaman

Assistant Professor

B. Sc. Engg.(BITR), M.Sc. Engg. (Chaina). (Abroad on Higher Studies) Field of Specialization: Database Management System

11. Md. Rafiqul Islam Sheikh

Assistant Professor

B. Sc. Engg.(BITR), M.Sc. Engg. (BITR). Field of Specialization: Power system Protection & Control, Digital System Design.

12. Md. Zahurul Islam Sarkar

20. Md. Faruk Hossain

Lecturer

B. Sc. Engg.(BITR). Field of Interest: Microprocessor, Control system, Numerical Electronic, Power systems, Digital Electronics, Electrical Machine.

21. Md. Jahangir Hossain

Lecturer

B. Sc. Engg.(BITR). Field of Interest: Electrical Machine, Control System, Electronic.

22. Md. Abdullah Al Hafiz

Lecturer

B. Sc. Engg.(IUT). Field of Interest: Electronic Switchgear & VLSI

Assistant Professor

B. Sc. Engg.(BITR), M.Sc. Engg. (BITR). . Field of Specialization: Electromagnetic Field and Electromagnetic Compatibility.

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23. Amit Roy Chowdhury

Technical Officer

B. Sc. Engg.(BITR), MSc. Engg (BITR). Field of Specialization: Energy System Modeling, System Dynamics, Computer Simulation.

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Laboratory Facilities of the Department The department provides adequate laboratory, library and other facilities to it’s members and students. The departmental undergraduate courses are laboratory intensive and this requirement is catered by the following laboratories at present. 1. Electrical Circuits Laboratory 2. Electrical Machine Laboratory 3. Electronics Laboratory 4. Electrical Measurement and Instrumentation Laboratory 5. Power Electronics Laboratory 6. Microwave and Telecommunication Laboratory 7. Electrical Workshop Laboratory 8. Computer Laboratory 9. High Voltage Laboratory (Under Construction) Students in first and second year have to undertake laboratory/Sessional classes in Physics, Chemistry, Mechanical Engineering and in different workshops.

Academic Ordinance for Undergraduate Studies for the Award of Bachelor of Science in Engineering Degree (From First Year of Session 2000-2001)

1. Definitions: 1.1 “Institute” means the Bangladesh Institute of Technology, Rajshahi abbreviated as BIT, Rajshahi. 1.2 “Board” means the Board of Governors of the Institute. 1.3 “Academic Council” means the Academic Council of the Institute 1.4 “The Committee of Courses and Studies” means the Committee for Under graduate Courses and Studies (CUGCS) of a Degree Awarding Department of the Institute.

Electrical & Electronic Engineering Association: To facilitate academic and extra-academic activities of the students & teachers of the department there is an ‘Electrical & Electronic Engineering Association’ consisting of class representatives who are elected by the students themselves. The Association works under the direct supervision and guidance of the Head of the Department. The major source of the Association fund is contribution made by the department students and the teachers. The head of the department nominates one faculty member to act as honorary treasurer of the association.

2. Departments: 2.1 Degree Awarding Departments: The institute has the following Degree Awarding Departments: i) Department of Civil Engineering ii) Department of Computer Science and Engineering iii) Department of Electrical & Electronic Engineering iv) Department of Mechanical Engineering v) Any other department to be instituted by the Board on the recommendation of the Academic Council. 2.2 Teaching Departments: The institute has the following teaching departments as defined in the statutes: i) Department of Chemistry ii) Department of Civil Engineering iii) Department of Electrical & Electronic Engineering iii) Department of Humanities iv) Department of Mathematics v) Department of Mechanical Engineering vi) Department of Physics vii) Department of Computer Science & Engineering ix) Any other department to be instituted by the Board on the recommendation of the Academic Council.

9

10

Consultancy, Research and testing services: Another significant part of the department activities is the testing. advisory and consultancy services including research and development work for industries and organizations of national importance. These services are regularly offered by the department and are considered to be of great help by the clients. These types of activities provide the teachers the opportunities to gain some valuable experience. Such interaction between the institute and the industry extends the role of the institute in the national development.

3. Degrees Offered: The Institute offers courses leading to the award of the following degrees i) Bachelor of Science in Civil Engineering abbreviated as B.Sc. Engg. (Civil); ii) Bachelor of Science in Computer Science & Engineering abbreviated as B. Sc. Engg. (Computer Science & Engineering); iii) Bachelor of Science in Electrical & Electronic Engineering abbreviated as B. Sc. Engg. (Electrical & Electronic); iv) Bachelor of Science in Mechanical Engineering abbreviated as B. Sc. Engg. (Mechanical); v) Any other degree that may be awarded by a department on the approval of the Board on the recommendation of the Academic Council. 4. Student Admission, Equivalence and Admission of Transfer 4.1 The four academic years of study for the degree of B. Sc. Engineering shall be designated as first year class, second year class, third year class and fourth year class in succeeding higher levels of study. Students shall generally be admitted into the first year class. In special cases, students may be admitted in to a higher year class on the recommendation of the appropriate Equivalence Committee and Department concerned. 4.2 The Academic Council for admission forms an Admission Committee in each academic session into first year B. Sc. Engineering class. 4.3 A candidate for admission into the first year class must have passed the H.S.C. Examination at least in the Second Division from a Higher Secondary Education Board in Bangladesh (after 12 years of schooling) with Physics, Chemistry and Mathematics as his/her subjects of examination in higher secondary examination or examination recognized as equivalent to, and must also fulfill all other requirements as may be prescribed by the Admission Committee. 4.4 The rules and conditions for admission into various courses of studies or departments shall be framed by the Academic Council on the recommendation of the Admission Committee. 4.5 All candidates for admission into the courses of B. Sc. Engg. must be citizens of Bangladesh unless the candidature is against the 11

seats that are reserved for foreign students. Candidates for all seats except the reserved ones, if any, shall be selected on the basis of merit. The rules for admission into the reserved seats shall be framed by the Academic Council on the recommendation of the Admission Committee. 4.6 No student shall ordinarily be admitted in the first year class after the corresponding classes start or after the call goes out for admission into the next session, which ever is earlier. Newly admitted students should be notified the date of commencement of classes. 4.7 Admission on of a newly admitted student in the first year class will be canceled if for first two consecutive weeks after the start of class he/she remains absent without prior permission. If any student fails to report due to unavoidable circumstances within stipulated first two weeks time, he/she may appeal within next four weeks to the Academic Council. The Council’s decision will be final. 4.8 An Equivalence Committee consisting of at least five members for a period of 3 years shall be formed by the Academic Council to consider the equivalence of different public examinations. 4.9 A candidate seeking admission on transfer from other Institute or University should apply to the Registrar of the Institute. The Registrar will refer the case to the Head of the Department concerned and also to the Equivalence Committee. On receiving the opinions of the Head of the Department and of the Equivalence Committee, the matter will be placed before the Academic Council. The Academic Council’s decision will be communicated to the Head of the Department and the candidate. 4.10 There shall be no transfer in the first year class. 4.11 Every student being admitted to the Institute shall be examined by a competent medical officer as may be provided in the admission rules. 5. Method of Course offering and Instruction: The undergraduate curricula at BIT, Rajshahi are based on course system. The salient features of course system is: i) Number of theoretical course and examination papers will not exceed five in each semester. ii) The absence of passes of fail on an annual basis. iii) Continuous evaluation of student’s performance. 12

iv) Evaluation by using Letter Grades and Grade Points instead of numerical grades. s v) Introduction of some additional optional courses and thus enable students to select courses accurse according to his/her interest as far as possible. vi) Opportunity for students to choose fewer or more courses than the normal courses load depending on his/her capabilities and needs. vii)

viii)

The flexibility to allow the student to progress at his/her own pace depending on his/her ability or convenience, subject to the regulations on credit and minimum grade point average (GPA) requirements and Promotion of the teacher-student contact. In the curriculum for the undergraduate programs, besides the professional courses pertaining to each discipline, there is a strong emphasis on acquiring a thorough knowledge in basic sciences of mathematics, physics and chemistry and subject in humanities and social sciences. Emphasis has been given to introduce courses dealing with professional practices, project planning and management, socio- economic and environmental aspects of development projects, communication skills etc. This will help the students to interact more positively with society.

6. Academic Calendar: 6.1 The academic year shall ordinary be divided into two semesters. 6.2 There are final examinations at the end of each semester conducted by the respective degree awarding departments of the Institute. 6.3 On the approval of the Academic Council an academic schedule for the year is announced for general notification before the start of the academic year. The schedule for an academic year may be prepared according to the following guidelines: Semester-I Classes Mid-semester recess Recess before examination Semester Final examination* Publication of results

No. of weeks 13 1 2 2.1+ 1.6 20 1

Inter-semester Recess 13

Semester-II Classes Mid-semester recess Recess before examination Semester Final examination* Publication of results Inter-session break, Ramjan and other vacations throughout the session.

No. of weeks 13 1 2 2.1+ 1.6 20 11 Total = 52

* There shall be at least two examination dates in a week + The digit after the decimal indicates number of days 7. Duration of Course and Course Structure: 7.1 The B.Sc. Engineering courses extend over a period of four academic years (8 semesters) each of a normal duration of one calendar year, which is divided as necessary for the purpose of academic program and conduct of examinations. 7.2 The curricula of the B.Sc. Engineering degree is the different department is as proposed by the committee of courses and approved by the board of Governors on the recommendation of the Academic Council. 7.3 The Committee of courses and studies review the curricula at least once every academic year and put forward suggestions to the Academic council. 7.4 Teaching for the courses is reckoned in credits and the credits allotted to various courses are determined by the committee of courses and studies with the following guidelines: Nature of Course Contact hour No. of Credit i) Theory Lecture 1 hour/week 1 ii) Tutorial 1 hour/week 1 iii) Independent 3/2 hour/week 0.75 Lab/Sessional/ design 2 hour/week 1 3 hour/week 1.5 iv) Combined theory and Credits may be calculated on the Lab/Sessional basic of number of credits assigned to i), and ii) v) Project/ thesis 6 hour/ week 3 vii) Field work 2 week of field work 1 14

7.5

In the case of combined theory and lab/sessional course, theory and related sessional course should be considered together for grading and assigning credits for example, a course requiring three lectures per week, one hour tutorial and three hours laboratory/sessional instruction per week may be assigned (3+1+1.5)= 5.5 credits. 7.6 The total number of credits that a students has to completed successfully for the award of B.Sc. Engineering degree are between 150-162. The maximum period of candidature is seven years i.e., 3 years (6 semesters) more than the normal time required to completed the course. 7.7 The total number of credits per week in a semester. However, a student may be allowed to register for less than 15 credits in a semester if i) He is considered academically weak. ii) Number of credits required for graduation is less than 15 in that semester and iii) Student can not find appropriate courses for registration subject to the approval of the adviser. 7.8 The Total contact hours for students inclosing lecture, tutorial and lab/sessional is around 25 period per week, each period being of 50 to 55 minutes duration with a bread of 5 minutes. 7.9. There should be an empty slot in the class routine to accommodate back logged course if necessary. 7.10 In each degree awarding department, one of the senior teachers nominated by the Head of the Department acts as Course Coordinator who acts as Member Secretary to the committee of Courses and Studies. 7.11 A course plan for each course, approved by the Course Coordinator, showing details of lectures may be announced at start of each semester. 7.12 Project & Thesis should preferably be of 3 credits. Credit in any theory subject does not exceed 4 and than in sessional subject does not exceed 1.5. 7.13 Theory and the related sessional course is designed as a combined course whose credit does not exceed 5.5. 8. Course Designation and numbering System:

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a) b)

Each course is designated by a three to four letter word identifying the department, which offers it following, by a three-digit number with the following criteria: The first digit corresponds to the year in which the course is normally taken by the students. The 2nd and 3rd digits are reserved for departmental use indicating major area. The course designation system is illustrated by one example as shown below: Course No. EEE 101C Course Title: Electrical Circuit-I EEE for Electrical and Electronic Engineering 1 for 1st year 01 for Electrical Circuit C for Theory & Sessional combined course

9. Type of courses: The courses included in undergraduate curricula are divided into several groups as follows. 9.1

9.2

9.3

Core Courses: In each discipline a number of courses are identified as core courses which form the nucleus of the respective bachelor’s degree program. A student has to complete all of the designated core courses for his discipline. Pre-requisite Course: Some of the core courses are identified as pre-requisite courses. A pre-requisite course is one, which is required to be completed before some other course(s) can be taken. Any such course, on which one or more subsequent courses build up, may be offered in each of the two regular semester. Optional Courses: Apart from the core courses, Students have to complete a number of courses which are optional in nature. In that, Students have some choose the required number of courses from a specified group/number of courses.

10. Departmental Monitoring Committee and student Adviser: 10.1 Each department constitutes a Departmental Monitoring Committee with two teachers of the Department as members nominated by the Committee of Courses studies and Head of the Department as chairman. This committee monitors and evaluates the performance of the course system within the Department. The committee may 16

also propose from time to time to the Committee of courses and Studies any changes and modifications needed for upgrading/changing the Undergraduate Curriculum and the Course System. 10.2 Student Adviser: An advisory board will be appointed for a batch of students of each department to advise each student on the courses to be taken by the student. The advisory board or one of its members as decided by the board will discuss with the student his academic program and then decide the number and nature of courses for which he can register. However, it is the student’s responsibility to keep contact with his adviser who will review and eventually approve the student’s specific plan of study and check on subsequent progress. 11. Registration Requirements: Each and every student must register for the courses he/she intends to take during a given semester on the basis of the advice and consent of his/her adviser. 11.1 Registration Procedure: Student will fill up his/her Course Registration Form in consultation with and under the guidance of his/her adviser and must submit to the Registrar’s Office within one week from the commencement of the class. Late registration after this date will not be accepted unless the student submits a written appeal to the Registrar through the concerned Head and can document extenuating circumstances such as medical problems or some other academic commitments which precluded enrolling prior to the last date of registration. Moreover, students who fail to register during the designated dates for registration will be charged a late registration fee. However, no registration will be accepted after two weeks from the commencement of the class. 11.2 Limits on the Credit Hours to be registered: The total number of credit hours for which a student should register shall be between 15 to 22 credits per week in a semester. However, a student may be allowed to register for less than 15 credits in a semester if i) he is considered academically weak ii) number of credits required for graduation is less than 15 in that semester and iii) student can not find appropriate courses for registration subject to the approval of the adviser. 17

11.3 Pre-Condition for Registration: A student will be allowed to register in those courses subject to the capacity constrains and satisfaction of pre-requisite courses. If a student fails in a prerequisite course in any semester, the concerned Department Monitoring Committee may allow him to register for a course which build on the pre-requisite course provided his attendance and grades in continuous assessment in the said pre-requisite course is found to be satisfaction. Registration will be done at the beginning of each semester. Late registration is however, permitted during the first week on payment of a late registration fee. Students having out standing dues to the Institute or a hall of residence shall not. be permitted to register. All students have therefore, to clear their dues and get a clearance or no dues certificate, on the production of which, they will be given necessary Course Registration Forms and complete the course registration procedure. Registration Forms are normally availably in the Register’s office. An orientation program will be conducted for only the first year students at the beginning of the first semester when they will be handed over the registration package on producing enrollment slip/proof of admission. 11.4 Pre-Registration: Pre-registration for course to be offered in a particular semester will be done on the specified date before the end of the previous semester. All students in consultation with the advisor are required to complete pre-requisition formalities., failing which a fine may be decided by the authority will have to be paid before registration in the next term. Further a student who does not pre-register may not get the courses desired by him subsequently. 11.5 Registration Deadline: Student must register for the courses to be taken before the commencing of each and no late registration will be accepted after one week of classes which may be relaxed up to maximum of two weeks for the newly admitted first year students. Late registration after this date will not be accepted unless the student submits a written appeal to the Registrar through the concerned head and can document extenuating circumstances such as medical problems ( physically incapacitated and not able to be presented) or some other academic commitments which precluded enrolling prior to the last date of registration. 11.6 Penalty for Late Registration: Students who fail to register during the designated dates for registration are charged a late 18

registration fee decided by the authority. This extra fee will not be waived whatever be the reason for late registration. 11.7 Course Adjustment Procedure: A student would have some limited options to add or delete courses from his/her registration list within the first two weeks from the beginning of the semester. Adjustment of initially registered courses in any semester can be done by duly completing the Course Adjustment Form. These forms are normally available in the Registration’s office. For first year students such forms can be included in the registration packet at the time of orientation. Any student willing to add or drop courses will have to fill up a Course Adjustment From in consultation with and under the guidance of his/her adviser. The original copy of the course Adjustment From will be submitted to the Registrar’s Office and then the requisite number of photo copies will be made by the Registrar’s Office for distribution to the concerned Adviser, Head and the student. All changes in courses must be approved by the adviser and the Head of the department concerned. The Course Adjustment From will have to be submitted to the Registrar’s Office after duly filled in and signed by the concerned persons. To add/drop a course respective teacher’s consent will be required. 11.8 Withdrawal from a Semester: If a student is unable to complete the semester Final Examination due to illness, accident or any other valid reason etc. he/she may apply to the Head of the degree awarding department for total withdrawal from the semester within a week after the end of the semester final examination. However, he/she may choose not withdraw any laboratory/sessional/ design course if the grade obtained in such a course is ‘D’ or better. The application must be supported by a medical from any authorized Medical Officer. 11.9 Registration Fee :Each student will pay a registration fee of Tk. 15/= per credit and must submit the document of payment along with the registration form to the Registrar’s office. It must be noted here that, any fraction in credit will be considered as a next higher integer credit for calculating registration fee. 12. Striking off the Names and Readmission: 12.1 The name of the students shall be struck of removed from the rolls on the following grounds:

19

i)

Non-payment of Institute fees and dues within the prescribed period. ii) Forced to discontinue his/her studies under disciplinary rules. iii) Withdrawal of names from the rolls of the Institute on grounds acceptable to the Director of the Institute after having cleared all dues.

12.2

12.3 12.4

12.5

iv) Could not earn required credits for graduation as outlined in the respective curriculum and/or fulfill CGPA requirement within the maximum allowed time of 7 academic years. Every student whose name has been struck off the rolls by exercise of the clauses (ii) of Article 12.1 seeking readmission after expiry of the period for which he/she was forced to discontinue his/her studies, shall submit an application to the Head of the Department in the prescribed form before the commencement of the session to which he/she seeks readmission. The Head of the Department shall forward the application to the Director of the Institute with his remarks. In case the readmission is allowed the student will be required on payment of all dues to get him/herself admitted not later than one week from the date of permission given by the Director. All readmission should preferably be completed before the session start. The percentage of attendance of the readmitted students shall be counted from the date of readmission. No student has withdrawn his/her name under clause (iii) of Article 12.1 shall be given readmission. In case s student whose name has been struck off rolls under clause (i) of Article 12.1 seeks readmission within the session in which his/her name was struck off, he/she shall be readmitted on payment of all the arrears fees and dues. But if he/she seeks readmission in any subsequent session, the procedure for his/her readmission will be same as described under Article 12.2. The application of a student for readmission will be considered if he/she applies within two academic sessions from the semester of discontinuance of his/her studies in the Institute. Other than Department as punishment under ordinance if the Institute relation to discipline, a student of any kind failing for any other reason whatsoever to become a candidate for a semester final examination in which he/she ought to have had in the usual process of his/her progressive academic activities, shall be considered to have discontinued his/her studies for the relevant 20

semester together with striking the name off from current roll and two such discontinuance periods will be considered equivalent to that for one academic session. The maximum period of discontinuance under no circumstances is to exceed two academic sessions during a student’s period of studies for the degree. 12.6 In case any application for readmission is rejected, the student may appeal to the Academic Council shall be final. 12.7 A student, whose name has been struck off the rolls by exercise of clause (iv) of Article 12.1, is not eligible to seek readmission.

where n is the total number of courses passed by the student in the semester, Ci is the number of credits allotted to a particular course i and Gi is the grade point corresponding to the grade awarded for i- th course. The overall or Cumulative grade point average (CGPA) gives the cumulative performance of the student from first semester up to any other semester to which it refers and is computed by dividing the total grade points (Ci Gi ) accumulated up to the date by the total credit (Ci). Both GPA and CGPA will be rounded off to the second place of decimal for reporting.

13. Grading System : The letter grade system shall be used to assess the performance of the student and shall be as follows:

14. Distribution of Marks : 14.1 The distribution of marks for a given course will be as follows i) Theory courses: Class participation and performance 10% Quizzes/Class tests 20% Semester final exam (3 hours duration) 70% Total 100%

Numerical Grade 80% or above 75% to less than 80% 70% to less than 75% 65% to less than 70% 60% to less than 65% 55% to less than 60% 50% to less than 55% 45% to less than 50% 40% to less than 45% Less than 40%

Letter Grade A+ A AB+ B BC+ C D F

Grade Point 4.0 3.75 3.5 3.25 3.0 2.75 2.5 2.25 2.0 0

A grade ‘X’ shall be awarded for courses (like project & thesis, design, etc.) in the odd semester which continue through to the even semester.

ii) Independent laboratory/sessional/design/field work courses Class participation and attendance 10% Quizzes 15% Performance/reports 50% Viva voce (conducted by the department) 25% Total iii) Project and thesis: Viva voce (conducted by a viva voce committee) Supervisor (internal examiner) External examiner Total

13.1 Calculation of GPA and CGPA: Grade point average (GPA) is the weighted average in a semester. ‘F’ grades do not count for GPA calculation. GPA of a semester will be calculated as follows. n



Grade Point Average



C

G

C

i

n



i1

21

i

i1

i

100% 20% 50% 30% 100%

iv) Combined theory & laboratory/Sessional courses: Assessment for the theory part of the course will be done as per guideline i) and that for the laboratory/sessional part as per guideline ii) above. Total marks in a combined course will then be calculated on the basis of theory to laboratory/Sessional credit ratio. 14.2 It is desirable that weightage on continuous assessment as described in Article 14.1 such as quizzes and class tests, class participation and attendance etc. should be increased up to 50% 22

and weightage on semester final examination should be reduced to above 50% gradually. 14.3 Basis for awarding marks for class participation and attendance will be as follows:

Attendance 90% and above 85% to less than 90% 80% to less than 85% 75% to less than 80% 70% to less than 75% 65% to less than 70% 60% to less than 65% Less than 60%

Marks 10% 9% 8% 7% 6% 5% 4% 0%

14.4 The students whose percentage of attendance will fall short of 75% in any of the theory, lab/sessional courses for which he/she has registered in one academic year shall not be eligible for the award of any type of scholarship/stipend /grant for the following academic session.

v)

All class shall ordinarily be of equal value. The result of each individual class test shall be posted for information of the students preferably before the next class test is held.

16. Earned Credits: The courses in which a student has obtained ‘D’ or a higher grade will only be counted as credits earned by him/her. A student, who obtains a ‘F’ grade in any Core Course in any semester. he/she will have to repeat the course. If a student obtains a ‘F’ in an Optional Course, he/she may choose to repeat the course. If a student obtains a ‘F’ in an Optional Course, he/she may choose to repeat the course or take a substitute course if available. ‘F’ grades will not be counted for GPA calculation but will stay permanently on the Grade sheet and Transcript. A student obtaining ‘D’ grade in a course will be allowed to repeat the course for the purpose of grade improvement if CGPA of the student falls below 2.20 . In such case he/she will be awarded the new grade thus he/she obtains or retains his/her previous grade if he/she fails.

15. Class Tests/Quizzes i) For 2 credit courses 3 best out of 4, for 3 credit courses 4 best out of 5 and 4 credit courses 5 best of 6 quizzes/class test may be taken for awarding grade. These may be considered as the minimum as the minimum recommended number of quizzes/class tests for any course. If the number of quizzes/class tests administered in a courses exceeds these suggested minimum numbers, then two thirds best of all may be considered. ii) Duration of quizzes/class tests should not exceed 15 minutes and materials covered should be what were taught in 2 to 3 previous class or most recent classes. iii) for convenience of conduction the class tests/quizzes a half an hour time slot should be kept at the beginning of each working day. iv) The dates for the quizzes/class test shall be fixed by the Head or Course Coordinator and shall be announced accordingly.

17. Performance Evaluation: The minimum CGPA requirement for obtaining a B. Sc. Engineering degree is 2.2. The performance of a student will be evaluated in terms of two indices, viz. semester grade point average and cumulative grade point average. Student will be considered to be making normal progress toward a degree if their CGPA for all courses attended is 2.2 or more. Students who regularly maintain semester GPA or 2.20 or better are making good progress toward their degrees and are in good standing with the Institute. Students who fail to maintain this minimum rate of progress will not be in good standing. This can happen when one or more of the following conditions exist: i) Semester GPA falls below 2.20 or ii) Cumulative GPA falls below 2.20 iii) Earned credits fall below 15 times the number of Semester attended/studies. All such students can make up deficiencies in GPA and credit requirements by completing courses of next semester(s) and

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24

backlog courses, if there be any, with better grades. When GPA and credit requirements are achieved, The student is returned to good standing. Students whose GPA will fall below 2.20 will have to be notified so that the necessary remedial measures can be taken. 18. Honors, Director’s List and Board of Governors (BOG)Gold medal Candidates for Bachelor’s degree in engineering will be awarded the degree with honors if their CGPA is 3.75 or better. In recognition of excellent performance, the names of students who maintains good standing with the Institute obtaining SGPA of 3.75 or above in two regular semesters in each academic year may be published in the Director’s List in each department. Students who have received ‘F’ grade in any course during any of the two regular semesters will not be considered for Director’s List in that year. If a students can show extraordinary brilliance and obtains all A or better grades in all the courses he/she attended and fulfills the credit requirement for graduation will be honored by awarding BOG gold medal in a special function/convocation. 19. Student Classification: For a number of reasons it is necessary to have a definite system by which to classify students as First year, Second year, Third year and Fourth year. At BIT regular student are classified according to the number of credit hours earned towards a degree. The following classification applies to the students. Year First year Second year Third year Fourth year

Earned credits 0 to 35 36 to 70 71 to 105 106 and above

20. Registration for the Second & subsequent Semester: A student is normal required to earn at least 15 credit in semester. At the end of each semester, the students will be categorized as follows: Category - 1 : Consisting of student who have passed all the courses prescribed for the semester and have no backlog of courses. A student belonging to 25

Category 1 will be eligible to register for all courses prescribed for the next semester. Category - 2 : Consisting of students who have earned at least 15 credits in the semester but do not belong to category 1. A student belonging to Category 2 is advised to take at least one course less in the next semester subject to the condition that he/she has to register for such backlog courses as may be prescribed by the adviser. Category -3 : Consisting of student who have failed to earn 15 credits in the semester. A students belonging to Category 3 is advised to take at least two courses less subject for registration for minimum of 15 credits. However, he/she will be required to register for such backlog courses as may prescribed by the adviser. 21. Probation and Suspension: Undergraduate students who regularly maintain semester GPA of 2.20 or better satisfying the minimum credit requirements are making good progress toward their degrees and are in good standing with the Institute. Students who fail to maintain this minimum rate of progress may be placed on academic probation. The status of academic probation is a reminder/warning to the student that satisfactory progress towards graduation is not being made. A student may be placed on academic probation when either of the following conditions exists: i) The Semester GPA falls below 2.20 or ii) The cumulative GPA falls below 2.20 Students on probation are subject to such restriction with respect to courses and extracurricular activities as may be imposed by the respective Head of the Department. The minimum period of probation is one semester, but the usual period is for one academic year. The allows student and opportunity to improve the GPA through the completion of additional course work during the period that the student is on probation. The probation is extended for additional semester until the student achieves an overall GPA if 2.20 or better. When that condition is achieved, the student is returned to good standing. 26

Academic probation is not be taken lightly-it is very serious matter. A student on academic probation who fails to maintain a GPA of at least 2.20 during two consecutive academic years may be suspended from this Institute. A student who has been suspended may apply for consideration to the Director, but this application will not be considered until the student has been suspended at least one full semester. Petitions for reinstatement must set forth clearly the reasons for the previous unsatisfactory academic record and it must delineate the new conditions that have been created to prevent the recurrence of such work. Each such petition is considered individually on its own merits. After consideration of the petition is considered individually on its own merits. After consideration of the petition and perhaps after consultation with the student, adviser and the respective Head of the Department, Director in some cases; reinstate the student if this is the first suspension. However, a second suspension will be regarded as final and absolute. 22. Measures for Helping Academically weak Students: The following provisions are made as far as possible to help academically weak students to enable them to complete their studies within the maximum period of seven years. a)

All such students whose Cumulative Grade Point Average (CGPA) is less than 2.20 at the end of a semester may be given a load not exceeding four theory/combined courses in the next semester.

b) For other academic deficiencies, some basic and core courses may be offered during the regular semester under special arrangement in order to enable the student to partially make –up for the reduced load during regular semester.

Following criteria are followed for determining academically weak students. i)

CGPA falling below 2.20

ii) Semester grade point average (SGPA) falling below 2.20 points below that of previous semester. 27

iii) Earned credit calling below 15 times the number of semester attended. 23. Minimum Earned credit and GPA Requirements for Obtaining Degree: Minimum credit requirements for the awarded of Bachelor of Engineering Degree will be decided by the respective committee of courses and studies. The minimum CGPA requirements for obtaining a Bachelor of Engineering Degree are 2.20. A student may take additional courses with the consent of his/her adviser in order to raise CGPA, but he/she may take a maximum of 15 such additional credits beyond respective credit requirements for bachelor’s degree during his/her entire period of student. 24. Time Limits of Completion of Bachelor’s Degree: A students must complete his/her students within a maximum period of seven years for engineering.

25. Industrial/ Professional Training Requirements: Depending on each Department’s own requirement a student may have to complete a prescribed number of days of industrial/ professional training in addition of minimum credit and other requirements, to the satisfaction of the concerned department. 26. Application for Graduation and Award of Degree: A student who has fulfilled all the academic requirements for bachelor’s degree will have to apply to the Register/Director through his/her Adviser for graduation. Provisional degree will be awarded in completion of credit and GPA requirements. Such provisional degree will be confirmed by the academic council. 27. Inclusion of repeaters from present system to the new courses system Repeater students will be included in the courses system of curricula as and when such situation will arise. 27.1 Equivalence of Courses and Grades: Equivalence of courses passed previously by any repeater student shall be determined by the respective Committee of Courses & Studies for the purpose of: a) Allowing course exemption and 28

b) Conversion of present grades into proposed grades in exempted courses. 27.2 Time Limit for Completion of Bachelor’s Degree: Time allowed for a student included in Course System from Previous System to complete studies leading to a bachelor’s degree will be proportional to the remaining credits to be completed by him/her. A student in engineering for example, having earned 40 credit hours through equivalence and exemption (for previously completed courses) out of a total requirement of 162 credits for bachelor’s degree will get. (7 yr. X 122/162 = 5.25) = 5-1/2 years (rounded to next higher half-a year) or 11 (eleven) Regular semester to fulfill all requirements for bachelor’s degree. 27.3 Relaxation of Course Registration for Repeaters: Relaxation of course Registration for a student transferred to course system from Previous system: - the requirement of registration of minimum 15 credit hours in a semester shall waived for only the semester of the year where he/she has been transferred in course system provided that he/she has been granted exemption in some of the courses offered in those terms. 28. Absence during Semester: A Student should not be absent quizzes tests etc. during the semester. Such absence will naturally lead to reduction in points/marks, which count towards the final grade. Absence in semester final examination will result in ‘F’ grade. A Student who has been absent for short periods, up to a maximum of three week due to illness, should approach the course teacher(s) or the course coordinators(s) for a make-up quizzes or assignments immediately on returning to the classes. Such request should be supported by medical certificate from Institute medical officer. The medical certificate issued by a registered medical practitioner (with the registration number shown explicitly or the certificates) will also be acceptable only in those cases where the students has valid reason for his/her absence from the Institute.

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00

Academic Ordinance for Postgraduate Studies for the Award of Master of Science in Engineering/ Master of Engineering/Master of Philosophy/Doctor of Philosophy Degree 1. Definitions 1.1 ‘Academic Council’ means the Academic Council of the Institute. 1.2 ‘BOG’ means the Board of Governors of the Institute. 1.3 ‘CPGCS’ means the Committee for Post-Graduate Course and Studies in a degree awarding departing of the institute. 1.4 ‘DSC’ means the Doctoral Scrutiny Committee. 1.5 ‘Institute’ means Bangladesh Institute of Technology, Rajshahi abbreviated as BIT, Rajshahi. 1.6 ‘CASR’ means the Committee for Advanced Studies and Research of the Institute. CASR shall consist of the following members: i) Director - Chairman ii) Two Heads of the degree awarding department by -

i) Civil Engineering abbreviated as M. Engg. (CE). ii) Electrical & Electronic Engineering abbreviated as M. Engg. (EEE). iii) Mechanical Engineering abbreviated as M. Engg. (ME). iv) Computer Science and Engineering abbreviated as M. Engg. (CSE) 2.3 Master of Philosophy in i) Mathematics abbreviated as M. Phil (Math) ii) Physics abbreviated as M. Phil (Phy) iii) Chemistry abbreviated as M. Phil (Chem) 2.4 Doctor of Philosophy in i) Civil Engineering abbreviated as Ph.D (CE) ii) Electrical & Electronic Engineering abbreviated as Ph.D. (EEE) iii) Mechanical Engineering abbreviated as Ph.D. (ME) iv) Computer Science and Engineering abbreviated as Ph.D. (CSE) v) Mathematics abbreviated as Ph.D. (Math)

Members

vi) Physics abbreviated as Ph.D. (Phy) vii) Chemistry abbreviated as Ph.D.( Chem)

rotation not below the rank of Associate Professor iii) One Professor from each department from the rest of the degree awarding departments by rotation. iv) One Professor outside the Institute nominated by the Director. Direct will nominate one secretary of the CASR At Least 40% members will fulfil the quoram.

-Members

2.5. The above degree may be offered in any other discipline approved by BOG on the recommendation of the Academic Council.

-Member

The post graduate degree to be offered under this ordinance are as follows. 2.1 Master of Science in i) Civil Engineering abbreviated as M. Sc. Engg. (CE). ii) Electrical & Electronic Engineering abbreviated as M.Sc.Engg. (EEE). iii) Mechanical Engineering abbreviated as M.Sc. Engg. (ME). iv) Computer Science and Engineering abbreviated as M.Sc Engg. (CSE) 2.2 Master of Engineering in

3. Admission 3.1 For admission to the courses leading to the award of the Degree of M. Sc. Engg./M. Engg. in any branch, a candidate must have a B. Sc. Engg. or an equivalent degree in the relevant/ related field with good academic records from any recognized Institute/University. 3.2 For admission to the courses leading to the award of M. Phil degree in any branch of Science, a student must have an M. Sc. degree in the relevant branch or equivalent degree from any recognized Institution or University with good academic record (No third class/division in any level of study). 3.3 For admission to the courses leading to the award of Ph.D degree in any branch, a candidate must have an M. Sc Engg./M. Engg./M. Phil or an equivalent degree in the relevant branch from any

30

31

2. Degrees Offered

recognized Institution or University with good academic record. A student in M. Sc. Engg./M. Engg./ M. Phil program may be transferred to Ph.D. program if he shows excellent progress in Masters thesis after completion of courses evaluated by thesis examination committee and approved by Academic Council on the recommendation of CPGCS and CASR. 3.4

3.5

3.6

3.7 3.8

Application for admission to the above courses shall be invited through regular means of advertisement and shall be received through prescribed application from. On the recommendation of CPGCS, the rules for admission into various departments of the Institute for post-graduate Studies may be amended from time to time by the Academic council through CASR. For admission a candidate may be required to appear at a written/oral test conducted by a Selection Committee as constituted by the respective CPGCS. Every selected candidate shall get himself registered with the Institute. Each student shall be assigned by the respective CPGCS, an adviser from the teachers of the department, not below the rank of an Assistant Professor. Prior to each enrollment and course registration for any semester, the Adviser/Supervisor (as appointed by Articles 8/10 of this Ordinance) shall check and approve the student’s schedule for subjects, Prerequisites as recommended by the Selection Committee and total credit hours.

3.9

Every registered candidate shall get himself enrolled on payment of prescribed fees and other dues before the commencement of each semester. 3.10 Eligibility for the admission of foreign students in the aforementioned post-graduate program will be examined by the equivalence committee. 4. Academic Regulations 4.1 The minimum duration of the M.Sc. Engg./M. Engg./ M. Phil course shall be of three semesters. A candidate for the masters degree must complete all requirements for the degree within Five academic years from the date of his first admission. 4.2

The minimum duration of the Ph. D course shall be of Six semesters. A student must complete all the requirements for Ph. D 32

4.3

4.4

4.5

degree with in seven academic years from the date of his first admission. Duration of each semester shall not be less than 24 weeks. Including course registration and semester and examination. There shall be two semesters in one academic year. Academic progress shall be measured in terms of credit hours earned by a student. One credit hour for theory course shall normally require one hour of class attendance per week for one semester. While one credit hour for thesis, Project or laboratory class should normally require three hours of work per week for one semester. The number of credit hours for each subject shall be as specified in the syllabus of the respective department. Minimum requirements of the theory and thesis/Project credit hours to be earned by a students for different degrees are as outline in the following table: Degree Theory Thesis Project Total M. Sc Engg 18 18 36 M. Engg 30 6 36 M. Phil 24 24 48 Ph. D 9 45 54

4.6

There shall be two categories of students, namely full time students and part time students. 4.6.1. Students, Serving in different organization may be admitted as part time students with a written consent from the employer. A part time student may be assigned a maximum of 9 credit hours of course work in a semester. 4.6.2 Full time students must register for a minimum of 12 credit hours and a maximum of 15 credit hours per semester. A full time student shall not be allowed to be in the employment of any organization (even as part time employee). However, they may be awarded teaching research assistantship. A student already in employed may be admitted as full time students only if he is on leave or deputation from his employer. 4.6.3. If a full time student gets an employment while he/she is in a running semester, he/she may be allowed to continue the rest of that semester with prior approval of the Head of the department and the employer.

33

4.7 4.8

The subject that shall be offered in any semester shall be as determined by the relevant department. After the first semester the CPGCS may consider a student’s application to transfer the credits earned elsewhere if the following conditions are fulfilled. i) The credits should be earned from a recognized Institution or University. ii) Maximum 50% Credit-Hours in course work may be transferred. iii) Credits earned before Five academic years from the date of application will not be considered. iv) Only B+ or higher grades will be considered. The student’s performance in the first semester and the standard and application of the courses studies elsewhere should be specially considered in giving such approval.

5. Grading System 5.1 Letter grade system will be applied in assessment of the performance of a student in semester examination. Numerical marking may be made in answer scripts, tests etc. but all final grading to be reported to the Head of the department in prescribed form, shall be in the letter grade system as outlined below. .

Marks obtained 90% and above 80% to below 90% 70% to below 80% 60% to below 70% 50% to below 60% Below 50%

Grades A+ A B+ B C F I S U W

Description Grade Points Excellent 4.0 Very good 3.5 Good 3.0 Average 2.5 Pass 2.0 Fail 0.0 Incomplete Satisfactory Unsatisfactory Withdrawn

F-Subject in which the students gets F grades shall not be counted towards credit hour requirements and for the calculation of Grade Point Average (GPA). 34

I-Given only when a student is unable to complete the course because of circumstances beyond his control. It must be made up by the close of the next two semesters or the incomplete grade becomes a failure. He/ She may however, be allowed to register without further payment of tuition fees for the course. S-or U- Satisfactory or unsatisfactory. Used only as final grade for thesis/ Project and non-credit courses. Grade for thesis or project which will be continuing shall be recorded as ‘In progress’. If however, thesis is discontinued “Incomplete” grade shall be recorded. W-Officially withdrawn from a course. A student must withdraw officially from a course within two working weeks of the commencement of the semester or else his grade in that course shall be recorded as ‘F’ unless he/she is eligible to get a grade of I (incomplete). A student may be permitted to withdraw and change his/her course within the specified period with the approval of his/her adviser and Head of the department. 5.2

Official withdrawal: A student may withdraw from the program for a total period of Five academic years for Ph.D student and Three academic years for Masters student, on the recommendation of the supervisor (and co-supervisor, if any) with prior permission from the Head of the department, if he/she is unable to continue the program due to any unavoidable circumstances of his/her own or of the Institute. Such withdrawal period will be assessed as academic exemption toward article 4.1/4.2.

6. Conduct of Examination : 6.1 For all post-graduate degrees in Engineering/Sciences in addition to tests. assignments and/or examination during the semester as may be given by the teachers(s) concerned, there shall be a written examination at the end of the semester and/or other tests for each of the subjects offered in a semester. The dates of such examination will be announced by the Head of the respective department at least two weeks before the commencement of the examinations. The final grade in a subject shall be based on the performance in all tests, assignments and/or examinations. 35

6.2

6.3

6.4

Each examiner will submit the final grades obtained by student(s) in each subject in prescribed form to the Head of the department. The Head of the department will appoint tabulators for each semester, subject to the approval of the Director. Three copies of the tabulation sheet will be prepared for a semester,(i) One for Director, (ii) One for Controller of Examination and (iii) One for Head of the department. Cumulative grades earned by a student shall be announced by the office of the Controller of Examination at the end of each semester. Students may collect a copy of transcript from the Controller of Examination at the end of each semester, on payment of the prescribed fees. The respective teacher(s) of each theory course offered in a semester will be the paper setter and script examiner for the semester examination.

7. Qualifying Requirements: 7.1 The qualifying requirement of the degree is that a student must earn a minimum grade point average of 2.65 for masters and 2.75 for Ph. D degree, based on the weighted average in his course work. GPA ia calculated as GPA = (Ci Gi) / Ci, where, Ci is the credit hour in a particular subject and Gi is the grade point corresponding to the grade obtained by the student in that subject. GPA and CGPA will be rounded off to the second place of decimal. 7.2

7.3 7.4 7.5

The C grades up to a maximum of two subject may be ignored for calculation of grade point average (GPA) at the written request of the student provided he/she has completed the total course credit hour requirement with a minimum weighted GPA of 2.65 in the remaining subjects. No subject shall be repeated unless it is compulsory requirement of the degree as department by the CPGCS. Performance in all the subjects shall be reflected in the transcript. If F grade is obtained in three or more subjects by a student, he/she shall not be allowed to continue the program. If the end of the 1st semester, the GPA falls below 2.5 (including C grades) he/she shall not be allowed to continue the program. In addition to successful completion of course work every student shall submit a thesis on his/her research work or report on his/her 36

project work fulfilling the requirements as details in Articles 9,10,11 M. Sc. Engg/ M. Phil students should preferably have a publication/ paper. 8. 8.1

8.2

8.3

8.4

8.5

8.6

8.7

Thesis/Project. for M.Sc. Engineering/M. Engg./M. Phil degree Research work for a thesis/project shall be carried out under the supervision of full time teacher who is a member of CPGCS to the relevant department. A co-supervisor from within or sutside the department/ Institute may be appointed. The tentative research proposal of thesis/project and the supervisor and co-supervisor (if any) shall be approved by the CASR on recommendation of CPGCS before the completion of course work requirements of the student concerned. The research work must be carried out in this Institute. In special circumstances it may be carried out at a place(s) recommended by the supervisor in consolation with the Head of the department and approved by the CASR. A seminar shall have to be presented by M. Sc. Engg/ M. Phil student on the progress of his/her research work, within the next semester after completion of course work. The Head of the department will keep a record of it send a report to the Director in prescribed form. Every student shall submit to the Head of the department, through his/her supervisor requirement number of type written copies of his/her thesis/project report in the approved format on or before a date to be fixed by the Head of the department in consultation with the supervisor concerned. The student shall certify that the research work was done by his/her and that the same work has not been submitted elsewhere for any degree or award (except for publication). The thesis/project should demonstrate an evidence of satisfactory knowledge in the field of research undertaken by the student and must be an original contribution to engineering/science and worth of publication. Every student submitting a thesis/project report in partial fulfillment of the requirement of a degree shall be required to appear at an oral examination , on a date or dates fixed by the Head of the department in consultation with supervisor and must satisfy the examiners that he/she is capable of intelligently applying the results of this research to the solution of problem, of 37

8.8

undertaking independent work, and also afford evidence of satisfactory knowledge related to the theory and technique used in his research work. Examination Committee for M. Sc. Engg./M. Phil thesis: The Head of the department, in consultation with the supervisor shall propose to the Director for the approval of Academic council a panel of examiners for thesis and oral examination, usually one month before the date of thesis examination. The Examination Committee shall be constituted as follows. Supervisor Co-Supervisor Head of the department

Chairman Member Member

One external member from outside the Institute/department

External member

Two alternate names should be proposed.

One or two members from within or Three alternate outside the department, not below Member names should the rank of Assistant Professor, be proposed. having research experience. 8.9 Examination Committee for M. Engg. Project: The Head of the department, in consultation with the supervisor shall propose to the Director for the approval of the Academic council a panel of examiners for project and oral examination, usually one month before the date of project examination. The examination committee shall be constituted as follows.

Supervisor Co-Supervisor Head of the department

Chairman Member Member

One external member from outside the Institute/department

External member

One or two member from within or outside the department, not below the rank of Assistant Professor, having research experience. 38

Member

Two alternate names should be proposed. Three alternate names should be proposed.

8.10 If an examiner is unable to accept the appointment or has to relinquish his appointment before/during the examination, the Director may appoint another examiner in his place in consultation with the Head of the department and the supervisor, without, further reference to the CPGCS, subject to the approval of Academic Council. 8.11 The Head of the department will arrange to keep a record of the thesis/Project examination in tabulation sheet and send a report to the Director in prescribed format, along with the comments of the thesis examiners. In this report he will also confirm that the student has completed the course and other requirements (if any) for the award of the degree. 9. Comprehensive Examination for Ph.D. Student. 9.1 Every Ph.D. Student shall appear at a comprehensive examination, ordinarily held soon after the completion of the course requirements. The CPGCS will form an examination committee named Doctoral scrutiny Committee (D.S.C) and will be constituted by the supervisor as chairman; co-supervisor, Head of the department, one teacher not below the rank of Assistant Professor from allied field of research and at least two other teachers usually within the department not below the rank of Assistant Professor, as members. The date and time of the comprehensive examination shall be fixed by the CPGCS on the request of the supervisor. 9.2 The comprehensive examination shall comprise a written examination and/or an oral examination to test the knowledge of the student related to the subject(s) of his research and allied field. If s student fails to qualify in a comprehensive examination he shall be given one more chance to appear in the examination as scheduled by the CPGCS. The Head of the department will send a report of the comprehensive examination in prescribed form, to the Director. 10. Thesis for Ph. D. students. 10.1 Research work for a thesis shall be carried out under the supervision of a full time teacher who is a member of CPGCS to the relevant department. A co-supervisor from within or outside the department/Institute may be appointed. The title of thesis and the supervisor and co-supervisor (if any) shall be approved by the 39

10.2

10.3

10.4

10.5

10.6

10.7

10.8

10.9

CPGCS before the completion of course requirements of the student concerned, on the recommendation of the Head of the department. The Research work must be carried out in this Institute. In special circumstances it may be carried out at a place (s) recommended by the supervisor in consultation with the Head of the department and approved by the CASR. A semester shall have to be presented by the student after passing the comprehensive examination. The seminar will show the evidences that the research work selected by the student is compatible towards the award of a Ph. D degree as will be evaluated by the DSC. The Head of the department will keep a record of it and send a report to the Director in prescribed form. Open seminar: Before submitting the thesis, the student will present the open seminar, showing the achievements in the research towards the award of Ph.D. degree as will be evaluated by the DSC. The Head of the department will keep a record of it and send a report to the Director in prescribed form. Every student shall submit required number of copies synopsis and Thesis in prescribed format to the Head of the department, Through his/her supervisor for distribution among the members of the examination committee and the experts. The student shall certify that the research work was done by him/her and that the work has not been submitted elsewhere for degree or award (except publication). The supervisor, in consultation with the Head of the department, will propose a panel of 6 names of the experts in the related field of research from outside the department, at least 3 of which should be from outside the country, to the Director. The Director will send the copies of the synopsis to the experts’ proposed by the supervisor, seeking their consent to be external examiner for the thesis. On receipt of their consent, he will select two external expert members of whom one outside from outside the country and send the copies of the thesis to them. Expert’s report in prescribed form should be collected. Copies of the experts’ reports may be given to the student through the supervisor, if there are any further queries to be cleared or questions to be answered by the student. Such answers should be directly sent to the expert concerned and final report should be collected. 40

10.10 The thesis should demonstrate and evidence of satisfactory knowledge in the field of research undertaken by the student and must be an original contribution to engineering/science and worthy of publication. In support of this the student should have at least two publication in journal of International standard. 10.11 Every Student submitting a thesis in partial fulfillment of the requirement of a Ph.D. degree shall be required to appear at an oral examination, on a data or dates fixed by the Head of the department in consultation with supervisor and must satisfy the examiners that he is capable of intelligently applying the results of this research to the solution of problems, of undertaking independent work, and also afford evidence of satisfactory knowledge related to the theory and technique used in his research work. 10.12 On receipt of favorable experts’ report the Head of the department, in consultation with the supervisor shall propose to the Director, for the approval of Academic Council, a panel of examiners for thesis and oral examination, usually one month before the date of thesis examination. The Examination Committee approved by CASR shall be constituted with the following members as described below. Supervisor Other members of D.S.C One external member from outside the Institute.

Chairman Members External Member

10.13 If an examiner is unable to accept the appointment or has to relinquish his appointment before/during the examination, the Director may appoint another examiner in his place in consultation with the Head of the department and the supervisor. 10.14 A Student who has been transferred to the Ph.D. program from the masters program may be awarded masters degree, on recommendation of the supervisor, if the student fails to qualify for the award of the Ph.D. degree. In that case that student must have to fulfil all the requirements for the said degree. 10.15 The Head of the department will arrange to keep a record of the thesis examination in tabulation sheet and send a report to the Director in prescribed format, along with the comments (if any) of the members of the examination committee. In this report he will 41

also confirm that the student has completed the course and other requirements (if any) for the award of the degree. 11. Cancellation of Studentship: i) Non-payment of dues within prescribed period. ii) Failing to proceed with the program as prescribed by this ordinance. iii) Failing to make satisfactory progress as reported by the adviser/supervisor through the CPGCS and approved by the Academic Council. iv) Forced to discontinue his studies under disciplinary rules. v) Withdrawn officially from all the course works including thesis/project. 12.

Academic Fees: Academic fees will be prescribed by the appropriate authority of this Institute from time to time.

42

SYLLABUS

Summary of Undergraduate Course Plan

Theory Sessional Sl. Year/ No of No of No Semester Credits Credits Course Course 1 1st/1st 5 15 3 3.75 2 1st/2nd 5 16 3 3 3 2nd/3rd 5 16 4 3.75 4 2nd /4th 5 15 4 3.75 5 3rd/5th 5 15 4 4.50 6 3rd/6th 5 16 5 5.25 7 4th/7th 5 14 3 3.25 8 4th/8th 5 15 4 4.25 Total 40 122 30 31.5

43

Total Credits 18.75 19.00 19.75 18.75 19.50 21.25 17.25 19.25 153.50

Financial Account & Economics analysis 9 Math 115 Engineering Mathematics-III Total No. of Theory Courses : 5 No. of Lab/Sessional Courses : 3

Courses offered to the undergraduate students of Electrical & Electronic Engineering Department

8

SUMMARY OF COURSES First Semester Sl. No

Course No.

Course Title

1

EEE 101 Electrical Circuit-I Electrical Circuit-I 2 EEE 102 Sessional 3 EEE 190 Engineering Graphics Technical English, 4 Hum 111 Communication & Report Writing Engineering Mathematics-I 5 Math 111 (Differential Calculus & Integral Calculus) Engineering Mathematics-II 6 Math 113 (Differential Equation & Matrices) 7 Phy 111 Physics 8 Phy 112 Physics Sessional Total No. of Theory Courses : 5 No. of Lab/Sessional Courses: 3

Theory Contact Credits Hrs/week 3 3

Sessional Total Contact Credits Credits Hrs/week 3 3

1.5

1.5

3

1.5

1.5

2

Sl. No. 1

2 3

3

3

3 4

3

3

4

3

5 6 7 8

4

4 3/2 0.75 0.75 15 7.5 3.75 18.75 Total contact Hrs/week: 22.5 Total Credits :18.75

15

4

4

3 16

3 3 16 6 3.0 19.0 Total contact Hrs/week : 22.0 Total Credits : 19.0

9

Course No.

Course Title

EEE 200 Electrical Shop Practice EEE 211 Prerequisite Electronic Circuit- I EEE101 EEE 212 Electronic Circuit- I Sessional EEE 221 Prerequisite Electrical Machine- I EEE101 EEE 222 Electrical Machine- I Sessional Math 211 Engineering Mathematics-IV Math 213 Engineering Mathematics-V ME 291 Basic Mechanical Engineering Basic Mechanical Engineering ME 292 Sessional Total

Theory Sessional Total Contact Contact Credits Credits Credits Hrs/week Hrs/week 3 1.5 1.5 3

1 2

EEE 103 Prerequisite EEE101 EEE 104

3

EEE 151

4

EEE 152

5 7

Chem 111 Chem 112

Course Title

Theory Sessional Total Contact Contact Credits Credits Credits Hrs/week Hrs/week

Electrical Circuit-II

3

Electrical Circuit-II Sessional Fundamentals of Computing Fundamentals of Computing Sessional General Chemistry General Chemistry Sessional

3

3 3/2

3

0.75

Sl. No . 1

2

3 1.5

3

3

3

3 4 3

3 4 3

16

0.75 3

3/2

16

0.75

0.75

0.75 3 4 3

3/2

0.75

0.75

7.5

3.75

19.75

Total contact Hrs/week: 23.5 Total Credits : 19.75

0.75

0.75

Course No. EEE 201 Prerequisites EEE101, Math213 EEE 213 Prerequisite EEE211


Course Title

Linear Circuit system

3

3

3

Electronic Circuit-II

3

3

3

3

EEE 214

Electronic Circuit-II Sessional

4

EEE 233 Prerequisite EEE221

Electrical Machine-II

1.5 3

3/2

44

0.75

3 3

3

3

Fourth Semester

Second Semester Course No.

3 3/2

No. of Theory Courses : 5 No. of Lab/Sessional Courses :4

Sl. No

4

Third Semester

2 2

Hum 113

3/2 3

45

3

0.75

0.75 3

Electrical Machine-II Sessional

5

EEE 234

6


3/2

Computational Methods in Electrical Engineering

7

EEE 252

Computational Methods in Electrical Engineering Sessional

8


Introduction to digital System & Design

3

Introduction to digital EEE 254 9 System & Design Sessional Total No. of Theory Courses : 5 No. of Lab/Sessional Courses : 4

3

1.5

3

1.5

3

3/2 15

0.75 3

3

3

0.75

0.75

0.75

15 7.5 3.75 18.75 Total contact Hrs/week : 22.5 Total Credits :18.75

Fifth Semester Sl. No 1 2

Course No.

Course Title

EEE 300 EEE 311 Prerequisite EEE211

Electronic Shop Practice Electronic Circuit-III

3

EEE 312

Electronic Circuit-III Sessional

4


Electrical Machine-III

5

EEE 322

Electrical Machine-III Sessional

3

3 3/2

3

46

3

3

0.75

3

0.75 3

3/2

EEE 341 Electromagnetic Fields 6 Prerequisite & Waves Math 115 EEE 351 Microprocessor & Micro 7 Prerequisite Computer System EEE253 Microprocessor & Micro 8 EEE 352 Computer System Sessional Legal Issues for 9 Hum 311 Engineers & Introduction to Management Total No. of Theory Courses :5 No. of Lab/Sessional Courses : 4

Course No.

1

EEE 301

2

EEE 302

3 4 5

0.75

3

0.75

3

3 1.5

Industrial Electronics

1.5 3 3

15 9 4.5 19.50 Total contact Hrs/week : 24.0 Total Credits : 19.5

3

0.75

3

Industrial Electronics Sessional` Advance Computer Programming

EEE 361

Sl. Course No. No

2

15

3/2

0.75 3

3/2

0.75

0.75

3

1.5

1.5

4

4

4

3

3

3 3

3

1.5

3

3 3/2

16

1.5

0.75

0.75

16 10.5 5.25 21.25 Total contact Hrs/week : 26.5 Total Credits : 21.25

Seventh Semester

1

3


Control System Control System Sessional

3

3 3


Theory Sessional Total Contact Contact Credits Credits Credits Hrs/week Hrs/week 3 3 3

Course Title

Power Transmission & Distribution Measurement & 7 EEE 371 Instrumentation Measurement & 8 EEE 372 Instrumentation Sessional Electronic Circuit for 9 EEE 381 Communication System Electronic Circuit for 10 EEE 382 Communication System Sessional Total No. of Theory Courses : 5 No. of Lab/Sessional Courses : 5 6


Sixth Semester Sl. No

EEE 400 EEE 461 Prerequisite EEE 361 EEE 462

4

EEE 481

5

EEE 482

Course Title

Theory Contact Credits Hrs/week

Project & Thesis Power System Power System Sessional Communication Engineering Communication Engineering Sessional

3

Sessional Total Contact Credits Credits Hrs/week 3 1 1

3

3 3

3

3

1.5 3

3/2

47

1.5

0.75

0.75

6 7

EEE 4* EEE 4**

Elective I Elective I Project Planning, 8 Hum 411 Management & Engineering Total *EEE467 (High Voltage Engineering) ** EEE 441 (Microwave Circuits) No. of Theory Courses : 5 No. of Lab/Sessional Courses : 3

3 3

3 3

3 3

2

2

2

14

14

7.5

3.25

1 2

Course No.

Course Title

Total contact Hrs/week : 21.5 Total Credits : 17.25


Project & Thesis

3

EEE465

4

EEE466

5 6

EEE 4* EEE 4

7

EEE 4 #

8

EEE 4

9

EEE 4##

Power Station Power System Protection & Switchgear Power System Protection & Switchgear Sessional Elective I Elective II Elective II Sessional Elective II Elective II Sessional Total



3

3

3

3

3

3

3/2 3 3

3

15

0.75

3 3

15

0.75 3 3

3/2

0.75

0.75

3/2

0.75

0.75

7.5

4.25

19.25

3

3

* EEE487 (Digital Signal Processing)  EEE451 (Computer Methods in Power System)  EEE452 (Computer Methods in Power System Sessional) # EEE443 (Microwave Devices) ## EEE444 (Microwave Devices Sessional) No. of Theory Courses : 5 No. of Lab/Sessional Courses : 4

Total contact Hrs/week : 22.50 Total Credits : 19.25

Prerequisite courses are indicated in the detail syllabus.

48

(7th and 8th Semesters) Group –A

17.25

Eighth Semester Sl. No

Summary of Elective Courses

Elective-I EEE 413 (Opto Electronics) EEE 441 (Microwave Circuits) EEE 483 (Fiber Optic Communication) EEE 487 (Digital Signal Processing)

Elective-II EEE 443 (Microwave Devices) EEE 444 (Microwave Devices Sessional) EEE 485 (Digital Communication) EEE 486 (Digital Communication Sessional) EEE 489 (Digital Filter Design) EEE 490 (Digital Filter Design Sessional)

Group- B Elective-I EEE 407 (Renewable Energy) EEE 421(Generalized Machine Theory)

Elective-II EEE 451 (Computer Methods in Power System) EEE 452 (Computer Methods in Power System Sessional)

EEE 467 (High Voltage Engineering EEE 469 (Economic Operation and Control of Power System)

Group- C Elective-I Elective-II EEE 401 (Advanced Control System) EEE 403 (Design of Control System) EEE 433 (Fundamental of Electric Drives) EEE 404 (Design of Control System Sessional) EEE 453 (Neural Networks) EEE 435 (Power Converters) EEE 457 (Discrete Mathematics) EEE 436 (Power Converters Sessional) EEE 469 (Theory of Algorithms) EEE 470 (Theory of Algorithms Sessional) EEE 471 (Transducers and Instrumentation) EEE 472 (Transducers and Instrumentation sessional) EEE 473 (Biomedical Engineering) EEE 474 (Biomedical Engineering Sessional)

49

COURSES FOR THE FIRST SEMESTER (Revised on Sl. No 1 2 3 4

5

6 7 8

Course No.

by the committee of Courses and Studies for UG) Course Title

EEE 101 Electrical Circuit-I Electrical Circuit-I EEE 102 Sessional EEE 190 Engineering Graphics Technical English, Hum 111 Communication & Report Writing Engineering Mathematics-I Math 111 (Differential Calculus & Integral Calculus) Engineering Mathematics-II Math 113 (Differential Equation & Matrices) Phy 111 Physics Phy 112 Physics Sessional Total

Theory Contact Credits Hrs/week 3 3

Sessional Total Contact Credits Credits Hrs/week 3 3

1.5

1.5

3

1.5

1.5

2

2

2

3

3

3

3

3

3

4

4

15

15

3/2 7.5

4 0.75 0.75 3.75 18.75

Credits : 3

Introduction of electrical power sources, ideal and practical sources, and linear circuit elements. DC analysis of series, parallel and series-parallel circuits: Kirchhoff’s Voltage and current laws, voltage, current, power and energy. Sinusoidal wave: Average and effective values, form factor, peak factor, phase relation and phasors. Steady state AC analysis of series, parallel and series -parallel circuits: phase relation between voltage and current, concept of impedance, power, power factor, phasor diagram. Network theorems: Superposition theorem, Thevenin’s theorem, Norton’s theorem, maximum power transfer theorem, substitution theorem and reciprocity theorem. Frequency response of ac circuits, resonance phenomena. Magnetic circuit and concepts: flux, fields, permeability reluctance, analysis of series, parallel and series- parallel magnetic circuit.

50

Sessional based on the theory of course EEE 101 EEE 190 (Engineering Graphics) Contact hour/week: 3 (Sessional)

Credits : 1.5

Credit : 1.5

Introduction. Orthographic projections. Pictorial views. Drawing standards and practices. Interpenetrating of surfaces. Development of surfaces. Machine drawings. Technical sketching. Introduction to computer-aided-drawing. Hum 111 (Technical English, Communication & Report Writing) Contact hours/week : 2 Credits : 2 Construction of sentences. Transformation of sentences. Use of Prepositions, Question words, Phrases and Idioms. Comprehension. Composition of current affairs. Precis writing. Reporting technical information. Commercial correspondence and tenders. Math 111 Engineering Mathematics -I (Differential Calculus & Integral Calculus) Contact hours/week : 3

DETAIL SYLLABUS EEE 101 (Electrical Circuit-I) Contact hours/week : 3

EEE 102 (Electrical Circuit-I sessional) Contact hours/week : 3

Credits : 3

Differential Calculus : Differentiation and its geometrical interpretation. Successive differentiation of various type of function. Rolle’s theorem, Mean value theorem. Divergency and Convergency of series. Functions of several independent variables, Partial Differentiation, Euler’s theorem, Jacobian. Series expansion of functions with one or more variables by Taylor’s theorem, Maclaurin’s series. Tangent, normal and curvature. Determination and application of maximum and minimum values of functions and points of inflection. Integral Calculus : Definition and properties of integration. Integration by the method of substitution. Integration by parts, standard integrals, integration by the method of successive reduction. Definite integrals, its properties and use in summing series. Wally’s formulae. Improper integrals, Beta and Gamma function. Area under a plane curve and area of the rigion enclosed by curves in Cartesian and Polar co-ordinates. Introduction to Trapezoidal and Simpson’s rules. Length of curves in 51

Cartesian and Polar co-crdinates, parametric and pedal equations. Intrinsic equation. Volumes of solids or revolution. Volumes of hollow solids of revolution by shell method. Area of surface of revolution. Math 113 Engineering Mathematics-II (Differential Equation & Matrices) Contact hours/week : 3

Credits : 3

Differential Equation : Degree and order of ordinary differential equations. Solution of first order differential equations by various methods. Solutions of linear equations of second and higher order with constant coefficients. Solution of homogeneous linear equations. Solution of higher order differential equations in absence of dependent/independent variables. Series solutions of differential equations, the Frobenius method. Matrices : Definition, equality, addition, subtraction, multiplication, transposition, inversion, rank. Vector space and linear transformations. Eigen values and eigen vectors. Application of eigen values to systems of differential equations. Phy 111 (Physics) Contact Hours/Week : 4

Sound : Simple harm`onic motion, wave motion, Principle of superposition. Beats, Dispersion, Phase and group velocities, Doppler’s effect, Free and forced vibrations. Physical Optics: Theories of light: Hyugen’s principle and construction. Interference of light: Young’s double slit experiment, Fresnel bi-prism, Newton’s rings, interferometers. Diffraction of light: Fresnel and Fraunhoffer diffraction, diffraction by single and double slit diffraction gratings. Polarization, production and analysis of polarized light, optical activity, optics of crystals.

Phy 112 (Physics Sessional) Contact hour/week: 3/2

Laboratory experiments based on the theory of courses Phy 111.

COURSES FOR THE SECOND SEMESTER

Credits: 4

Atomic structure. Thompsons, Rutherford and Bhor’s atomic model. Atomic arrangement in solids. Different types of bonds in solidsmetallic, Vander Walls and ionic bond. Electronic structure of materials: Free electron the theory, Metallic conduction. Energy bands, Brillouin zones, Temperature dependence of metallic conductivity. Semiconductors: Band theory, intrinsic and extrinsic semiconductors, Fermi levels, mobility and electrical conductivity, carrier diffusion and life time. Magnetic materials: Properties, Dia,-Para - and Ferro-magentism, Hysteresis loop, B-H curve, Energy losses in magnetic materials and their measurements. Soft and hard magnetic materials, ferrities. Thermal electricity: thermocouple, Seebeck effect, Peltier and Thompson effect, Thermo-emf. Photoelectricity: Laws of photoemission and Einstein’s equation. Photoelectric cell and its use.

52

Credit : 0.75

Sl. No 1 2

Course No. EEE 103 Prerequisite EEE101 EEE 104

3

EEE 151

4

EEE 152

5

Chem 111

7

Chem 112

8

Hum 113

9

Math 115


Course Title

Electrical Circuit-II

3

Electrical Circuit-II Sessional Fundamentals of Computing Fundamentals of Computing Sessional General Chemistry General Chemistry Sessional Financial Account & Economics analysis Engineering Mathematics-III Total

53

3

3 3/2

3

3

0.75

3

3 3

1.5

1.5

3/2

0.75

0.75

3

4

4

3 16

3 16

0.75

3

4 6

3.0

3 19.0

Polyphase system, balanced and unbalanced three phase circuit analysis. Two-port analysis. Coupled circuit. Introduction to filter.

conduction, Transport number, Kohl-Rausch’s law. Ionization of water and concept of pH. Different types of cells, Cell emf. Single electrode potentials, their determination and application. Secondary Cells or Accumulators, lead accumulator and alkaline accumulator. Different types of solutions. Factors influencing the solubility of a substance, solution of gas in liguids. Colligative properties of dilute solution. Lechatelier’s theorem and some of its important industrial applications. Thermochemistry, chemical kinetics.

EEE 104 (Electrical Circuit-II Sessional) Contact hours/week :3/2

Chem 112 (General Chemistry Sessional) Contact hours/week : 3/2

DETAIL SYLLABUS EEE 103 (Electrical Circuit-II) Prerequisite EEE101 Contact hours/week :3

Credits: 3

Credits: 0.75

Credits: 0.75

Sessional based on the theory of course EEE 103.

Laboratory experiments based on theory of course Chem 111

EEE 151 (Fundamentals of Computing) Contact hours/week: 3

Hum 113 (Financial Account & Economics analysis) Contact hours/week : 4

Credits: 3

Introduction to Computer Fundamentals: Types and generation of computers, basic organization and functional units. Different types of computer language. compiler, Interpreter, Assembler. Operating Systems and Application software. Hardware : Input, output and memory devices, keyboard, mouse, OMR, OCR, CD-ROM, Printers, CRT, microfilm, floppy disk, hard disk, magnetic tape, etc. Programming Concepts: Algorithms and flow chart construction. Writing debugging and running programs using C. Variables, expression, type, operators, decisions, loops, functions, arrays, pointer and its applications, Input/Output file. EEE 152 (Fundamentals of Computing Sessional) Contact hours/week: 3

Credits: 1.5

Sessional based on the theory of course EEE 151 Chem 111 (General Chemistry) Contact hours/week : 3

Credits: 3

Different types of chemical bonds and their properties. Modern concepts of acids and bases. Problems involving acid base titration. Properties and uses of noble gases. Electrochemistry, Mechanism of electrolytic 54

Credits: 4

Accountancy : Basic accounting principles, Transaction, Journal, Ledger and Accounts. Cash book, Bank Reconciliation statement. Preparation of Financial Statement. Cost Accounts and its objects. Cost classification. Elements of costs, preparation of cost sheet. Overhead allocation. Use of Relevant costs in Decision-Making, Standard costing. Material cost variance. Break even analysis. Economics: Nature of the economics theory- applicability of economic theories to the problem of developing countries. Some basic conceptssupply, demand and their elasticity. The relationship among average, margin and total and their derivation. Equilibrium- stable, straight and dynamic equilibrium. Consumer’s equilibrium- indifference curve, Producer’s equilibrium- isoquant. Production-factors of production, production possibility curve equilibrium of firm, fixed cost and variable cost, the short run and the long run. The cost curves and supply curves, law of returns and external economics and diseconomies. Economics of development and planning basic concept- saving, investment, GNP, NNP, per-capita income, growth rate, policy instruments of development, Fiscal policy, monetary policy and trade policy, their relative applicability in Bangladesh, some planning tools-capital output ratio, input analysis, planning in Bangladesh-five year plans of Bangladesh, development problems related to agriculture, industry and population of Bangladesh.

55

Math 115 (Engineering Mathematics-III) Contact hours/week : 3

DETAIL SYLLABUS Credits: 3

Co-ordinate Geometry : Co-ordinate Geometry of two dimension-Change of axis, Transformation of co-ordinates, simplification of equations of curves. Co-ordinate Geometry of three dimension System of coordinates, distance between two points, section formula, projection, direction cosines, equations of planes and lines. Vector Analysis: Addition and subtraction of vectors, scalar and vector product of two vectors, Differentiation and integration of vectors, line, surface and volume integrals. Gradient of a scalar function, divergence and curl of a vector function. Physical significance of gradient, divergence and curl. Conservative systems. Gauss’s divergence theorem, Stoke’s theorem and Green’s theorem, and their applications in engineering problems.

COURSES FOR THE THIRD SEMESTER

Sl. No. 1 2 3 4 5 6 7 8 9

Course No.

Course Title

EEE 200 Electrical Shop Practice EEE 211 Prerequisite Electronic Circuit- I EEE101 EEE 212 Electronic Circuit- I Sessional EEE 221 Prerequisite Electrical Machine- I EEE101 EEE 222 Electrical Machine- I Sessional Math 211 Engineering Mathematics-IV Math 213 Engineering Mathematics-V ME 291 Basic Mechanical Engineering Basic Mechanical Engineering ME 292 Sessional Total

56


3

3 3/2

3

3

3 4 3

3 4 3

16

0.75 3

3/2

16

0.75

0.75

EEE 200 (Electrical Shop Practice) Contact hours/week: 3 (Sessional)

Credits:1.5

Electrician’s tools, splices, soldering, code practices. Electrical and electronic symbols, Safety rules, electricity rules and electricity codes. Electrical wiring system design drawing and estimation for residential and commercial house wiring and Industrial installation wiring. Use of meggers, Insulation test, Grounding earth resistance measurement using earth resistance tester. Battery charging.

EEE 211 (Electronic Circuit-I) Prerequisite : EEE 101 Contact hours/week: 3

Credits: 3

Signals, their origin and processing in electronic system. Development of electronic processing devices; Vacuum tubes and semiconductor devices; P-N junction semiconductor diodes; Application of diode as rectifier, Zener diode and its application. BJT, FET, MOSFET : Characteristics, Biasing techniques, Stabilization factors, Compensation. Equivalent circuits, single stage amplifiers at midband frequencies. Power amplifiers. Heat sink.

EEE 212 (Electronic Circuit-I Sessional) Contact hours/week: 3/2

Credits: 0.75

0.75 3 4 3

3/2

0.75

0.75

7.5

3.75

19.75


EEE 221 (Electrical Machine-I) Prerequisite EEE101 Contact hours/week: 3

Credits: 3 57

DC generator: Principle of electromagnetic induction. Construction of generator armature winding. Theory and analysis of armature reaction, eddy current and commutation over air gap, flux distribution. Type of generator. Voltage build-up process. Performance of DC motor: Principle of operation, Back e.m.f; power stages; performance characteristics, loss and efficiency. Starting of motor and speed control scheme. Operation of motor fed form diode and thyrister rectifier and chopper. Electrical breaking, regenerative and degenerative. Application and testing of motor. Single phase transformers. Parallel Operation of DC Generator.

EEE 222 (Electrical Machine-I Sessional) Contact hours/week: 3/2

Credits: 0.75


Math 211 (Engineering Mathematics-IV) Contact hours/week : 3

Credits: 3

Complex Variable : Function of a complex variable. Caushy’s integral theorem. Integral, derivative. Tailor’s series, Laurent’s series. Singular point and residue. Geometrical representation and conformal mapping. Application of conformal mappings in electrostatics, electromagnetic fields. Flow equations, Blessius flow. Harmonic Analysis. Statistical Analysis: Frequency and relative frequency. Probability, sample space, probability of finite space. Random variable. Measure of central tendency. Mean, Media, Mode, Quartile deviation, Mean Absolute Deviation. Measures of dispersion; Variance, Co-variance; Standard deviation. Probability density function. Continuous and discrete distribution. Ensemble and exsemble average of stochastic process. Equivalent distribution. Correlation and regression analysis. Normal probability distribution. probability equation and its derivatives. Normal curve and its properties. Probability integral and it’s evaluation by ascending and descending power series. Different discrete distribution; 58

control limit. Laplace-demovire theorem. Law of large number, Poisson’s law. Theory of errors and Gaussian law of errors; Arithmetic mean, weighted mean. Most probable value, measures of precision. Mean square error, probable error and average error. Rejection of observation, confidence limit

Math 213 (Engineering Mathematics-V) Contact hours/week : 4

Credits: 4

Fourier Analysis : Fourier Series, Fourier Coefficients, even and odd functions. Properties of Fourier series, Convergence of Fourier Series, extension of internal of Fourier series, Fourier integral, Sine and Cosine integrals and Laplace integral. Laplace Transform : Properties of Laplace transform, its basic theorem, application of Laplace transform for solution of ordinary differential equatiuon. Error function and error complement. Gamma function. Simple partial differential equation with intial and boundary conditions of being not more than secong degrees and not more than three independent variables. Laplace, Poission and diffusion equations. Application of Laplace transform to partial differential equation. Partial Differential Equation: Derivation of equations, One dimensional wave equation, two dimensional wave equation steady state heat flow equation, solution of partial differential equation by separation of variables, D’ Alembert solution. Harmonics : Solutions of Laplace’s equation, Rectangular, Cylindrical and Spherical harmonics.

ME 291 (Basic Mechanical Engineering) Contact hours/week: 3

Credits: 3

Study of fuels. Steam generation units with accessories and mountings. Study of steam generation and steam turbines. Introduction to internal combustion engines and their cycles. Study of SI and CI engines and gas turbines with their accessories.

59

Refrigeration and air conditioning with their application. Refrigeration equipment: compressors, condensers and evaporators.

DETAIL SYLLABUS

Type of fluid machinery. Study of impulse and reaction turbine. Pelton wheel and Kalpan turbine. Study of centrifugal and axial flow machines. Pumps, fans, blowers and compressors. Study of reciprocation pumps.

ME 292 (Basic Mechanical Engineering Sessional) Contact hours/week: 3/2

Credits: 0.75

EEE 201 ( Linear circuit System) Prerequisites : EEE 101, Math 213 Contact hours/week: 3

Credits:3

Response to non-sinusoidal voltage, L-system. Transform methods, Purpose and nature of transform, Fourier and Laplace transforms. Impulse function. Convolution integral and their application to network and system analysis. Filter equations, modern filters, Z–Transform.

Sessional based on the theory of course ME 291. EEE 213 (Electronic Circuit - II) Contact hours/week: 3

COURSES FOR THE FOURTH SEMESTER Sl. No . 1

2

Course No. EEE 201 Prerequisites EEE101, Math213 EEE 213 Prerequisite EEE211


Course Title

Linear Circuit system

3

3

3

Electronic Circuit-II

3

3

3

3

EEE 214

Electronic Circuit-II Sessional

4


Electrical Machine-II

5

EEE 234

Electrical Machine-II Sessional

6


Computational Methods in Electrical Engineering

7

EEE 252

Computational Methods in Electrical Engineering Sessional

8


9

EEE 254

3/2 3

3

Introduction to digital System & Design Introduction to digital System & Design Sessional Total

60

15

0.75

3

1.5

3

15

0.75 3

3

3

0.75

BJT, FET, MOSFET multistage amplifier circuits. Frequency response of single stage and multistage amplifiers. Introduction to CMOS and its applications. Introduction to operational amplifiers: Basic linear and non linear applications. Frequency response, bandwidth and other practical limitation of op-amps, compensation techniques. Feedback concept, Improvement of amplifier characteristics by negative feedback. Classification, analysis of feedback amplifier. Sinusoidal oscillators: Concept and its classification. Active filters. Negative impedance converters.

3 3/2

3

0.75

Credits:3

1.5

EEE 214 (Electronic Circuit – II Sessional) Contact hours/week: 3/2

Credits:0.75

Sessional based on the theory of course EEE 213. EEE 233 (Electrical Machine-II) Contact hours/week: 3

Credits:3

3

3/2

0.75

0.75

7.5

3.75

18.75

Three phase transformer connections, three phase to six phase transformation. Auto - transformer, Instrument transformers. Parallel operation of transformers. Polyphase induction motor: Construction and operating principle. Electrical equivalent circuit, Power and torque in induction motor, 61

Torque - Speed characteristics, speed regulation, Losses and efficiency, Circle diagram, speed control. Starting of motor, method of breaking, plugging. Induction generator. Starting and Speed control, Single phase induction motor. EEE 234 (Electrical Machine-II Sessional) Contact hours/week: 3/2

EEE 254 (Introduction to digital System & Design Sessional) Contact hours/week: 3/2 Credits:0.75 Sessional based on the theory of course EEE 253.

Credits:0.75

Sessional based on the theory of course EEE233C EEE 251 (Computational Methods in Electrical Engineering) Contact hours/week: 3 Credits:3 Computer algorithm Mathematical modeling of physical systems. Iterative Techniques, Solution of simultaneous equations, Interpolation, Curve fitting, Mathematical Modeling. Solution of Differential Equations. Application of the above techniques in Electrical & Electronic Engineering through computer program. EEE 252 (Computational Methods in Electrical Engineering Sessional) Contact hours/week: 3 Credits:1.5 Sessional: Based on the theory of course EEE 251. EEE 253 (Introduction to digital System & Design) Prerequisite :EEE211C Contact hours/week: 3

Credits:3

Number system. Conversion and arithmetic of number systems. Numeric and alphanumeric codes. Boolean algebra. Different practical methods of simplifying Boolean function. Introduction to logic gates. Analysis, synthesis, design and use of practical combinational circuits. Encoder, decoder, multiplexer, demultiplexer, adder, subtractor, comparator, PLA etc. Introduction to flip-flops. Analysis and synthesis of sequential circuits. Design and use of registers, counters, buses etc. Design of data handling and arithmetic circuits. Semiconductor memories, RAM, ROM, PROM, EPROM, EEPROM etc. 62

63

COURSES FOR THE FIFTH SEMESTER Sl. No 1 2

Course No.

Course Title


Electronic Shop Practice Electronic Circuit-III

3

EEE 312

Electronic Circuit-III Sessional

4


Electrical Machine-III

5

EEE 322

Electrical Machine-III Sessional

6

7 8 9


3

3 3/2

3

3

3

0.75 3

3/2

EEE 341 Electromagnetic Fields Prerequisite & Waves Math 115 EEE 351 Microprocessor & Micro Prerequisite Computer System EEE253 Microprocessor & Micro EEE 352 Computer System Sessional Legal Issues for Hum 311 Engineers & Introduction to Management Total

0.75

0.75

3

0.75

Credits:3

Wave shaping: Linear and non-linear wave shaping, Clipping and Clamping circuits, Non Linear function circuits. Negative resistance switching circuits. Timing circuits; Bi-stable, mono-stable and Astable multivibrators, Sweep and staircase generator, IC 555 and its application. Application of op-amp in timing circuits, Comparators, Schimtt’s Trigger. Pulse generator, VCO, PLL, Blocking oscillators. EEE 312 (Electronic Circuit-III Sessional) Contact hours/week: 3/2 Sessional based on the theory of course of EEE311.

3

3

3 3

3

3

15

15

1.5

1.5 3

9

4.5

19.50

Credits: 1.5

Introduction to formal procedures of preventive maintenance. Circuit tracing, trouble shooting fault repairing, soldering and de-soldering of electronic circuits. Design of PCB layout, etching. Radio receivers: Principles of operations, circuit tracing, fault finding by signal injection alignment. TV camera, B/W TV, color TV. CD player and VCD player.

EEE 321 (Electrical Machine-III) (Prerequisite : EEE 233) Contact hours/week: 3

Credits:3

Principle of Electromagnetic energy conversion system. Synchronous generator : Alternator construction. Armature winding, airgap flux and voltage compensation. Determination of machine parameters. vector diagram and alternator regulation by different methods. Parallel operation, Synchronization. Transient condition of alternator, transient and sub-transient reactances, Blondel’s two reaction analysis. Power balance, loss and efficiency. Synchronous motor: Characteristics, operation and vector diagram. Effect of excitation on power factor and motor performance. Application and testing of Synchronous motor. Synchronous capacitor and power factor improvements. Special machine: Welding machine, Brushless machines, universal motor, stepper motor, reluctance motor, repulsion motor, servomotor, Hysteresis motor, permanent magnet motor and electrostatic motor. EEE 322 (Electrical Machine-III Sessional) Contact hours/week: 3/2 Sessional based on the theory of course EEE 321.

64

Credits:0.75

3

DETAIL SYLLABUS

EEE 300 (Electronic Shop Practice) Contact hours/week: 3 (Sessional)

EEE 311 (Electronic Circuit-III) Prerequisite : EEE 211 Contact hours/week: 3

65

Credits:0.75

EEE 341 (Electromagnetic Fields & Waves) Prerequisite : Math 115 Contact hours/week: 3

Hum 311 (Legal Issues for Engineers & Introduction to Management) Contact hours/week: 3 Credits:3 Credits:3

Electrostatics and Magnetostatics using vector methods. Fields in dielectrics and conductors. Boundary conditions of Electric and Magnetic fields. Time Varying Fields; Maxwell’s equation and poynting vector. Uniform plane wave; Transmission and reflection. Skin effect and Surface resistance. Wave guides. Introduction to radiator antenna. EEE 351 (Microprocessor & Micro Computer System) Prerequisite : EEE 253 Contact hour/week: 3

Credits:3

Microcomputer Architecture: Basic microcomputer blocks, microcomputer bus structure. Microprocessor Architecture: Generalized microprocessor architecture. Basic concepts of 8085. Details study of 8-bitIntel 8086 microprocessor architecture and pin diagram. Familiarization with Z80, MC 68000, 80286 and Pentium Series. Microcomputer Programming: Introduction to machine and assemble language programming. Detail study of 8086 instruction sets with assembly language programming examples. Memory subsystem: Memory Module design Intel 8086 family memory IC’s and interfacing them with microprocessor. Familiarization with different memory technology. I/O Subsystem : Introduction to parallel and Serial I/O. Detail study of Intel 8086 family chips and interfacing them with microprocessor. Comparison of the architecture based on hardware features such as addressing modes interrupt structures, instruction execution, multiprogramming abilities and memory management. Microprocessor interfacing : Introduction to some available microprocessor peripheral ICs and their application; Timing diagram, Interrupts, I/O Systems, DMA- based data transfer, memory interfacing, A/D and D/A converter interfacing; introduction to microcomputers.

Business and industrial law: Law of contract, elements of a valid contract. Consideration. Parties competent to contact. Sale of goods and hire purchase. Negotiable instrument. Industrial law in Bangladesh. Factories act. Industrial relation ordinance. Workmen’s compensation. Industrial Management: Administration management and organization. Authority and responsibility. Scientific management. Organization structures. Organization chart. Span of control. Personnel management: Selection and Recruitment of employees. Traning and its types. Promotion. Wage system and incentive. Job evaluation and merit rating Plant layout, layout of physical facilities. Transportation and storage. Material handling and maintenance policy. Production control in intermittent and continuous manufacturing industry, functions of production control. Promotion, motivation, job redesign leadership organizational change and conflict. Purchase procedures: Inventory control. Need of control and methods of control. Factors affection inventory build -up. Economic lot size and reorder point. Marketing Management: Concepts, strategy, sales promotion, patent laws, patent laws, Management of innovation and changes.

EEE 352 (Microprocessor & Micro Computer System Sessional) Contact hour/week: 3 Credits:1.5 Sessional based on the theory of course EEE 351. 66

67

variable characterization of systems, transition matrix, canonical forms. Controllability and observability.

COURSES FOR THE SIX SEMESTER Sl. No

Course No.

1

EEE 301

2

EEE 302

3 4


5


6

EEE 361

7

EEE 371

8

EEE 372

9

EEE 381

10

EEE 382

Theory Sessional Total Contact Contact Credits Credits Credits Hrs/week Hrs/week 3 3 3

Course Title Control System Control System Sessional

3/2

0.75

0.75

EEE 302 (Control System Sessional) Contact hours/week: 3/2

Credits: 0.75

Sessiona based on the theory of course EEE 301.

Industrial Electronics

3

3

Industrial Electronics Sessional` Advance Computer Programming Power Transmission & Distribution Measurement & Instrumentation Measurement & Instrumentation Sessional Electronic Circuit for Communication System Electronic Circuit for Communication System Sessional Total

3 3/2

0.75

0.75

3

1.5

1.5

4

4

4

3

3

3 3

3

16

1.5

1.5

3

16

3 3/2

0.75

0.75

10.5

5.25

21.25

EEE 313 (Industrial Electronics) (Prerequisite EEE253) Contact hours/week: 3

Credits: 3

Introduction to power switching devices and their terminal characteristics. Snubber circuits. Single and three phase line frequency diode rectifiers and line frequency phase controlled rectifiers. Thyristor circuits and its control with commutation techniques. Cycloconverters, dc-dc switch mode converters, UPS, DC choppers: classification. Step up, step down choppers. Single phase PWM inverters. Introduction to three phase inverters. Voltage controlled inverters. Advanced modulation techniques. Introduction to induction, dielectric and microwave heating. EEE 314 (Industrial Electronics Sessional) Contact hours/week: 3/2

Credits: 0.75

DETAIL SYLLABUS Sessional based on the theory of course EEE 313. EEE 301 (Control System) Contact hours/week: 3 (T)

Credits: 3

Introductory Concepts: Open loop versus closed loop feedback system. Input output relationship. Transfer function. DC machine dynamics, performance criteria, sensitivity and accuracy. Analysis of control systems time and frequency domain error constants. Stability of control system : Routh -Harwith criterion, bode plot. Nyquist method. Root locus techniques. Frequency response analysis. Nicholes chart, compensation. Introduction to non-linear control system. State

68

EEE 350 (Advance Computer Programming) Prerequisite EEE251 Contact hours/week: 3 (Sessional) Credits: 1.5 (Sessional) Solution of various Electrical and Electronic Engineering Problems using dedicated software. EEE 361 (Power Transmission & Distribution) Contact hours/week: 4

69

Credits: 4

Inductance and capacitance of transmission lines : Calculation of inductance and capacitance of transmission lines of different geometrical configurations. Representation of transmission lines: Short, medium and long length approximations, voltage and current relations on transmission line. Generalized circuit constants. Voltage control in transmission system; Tap changing transformers and voltage regulators; booster transformers; induction regulator. Power factor control: Static condenser, Synchronous condenser, Ferranti effect. Power distribution: D.C & A.C distribution calculation for different network configuration. Insulators of overhead transmission lines: Types of insulators and their coordination. Electric stress calculations and string efficiency. Insulator testing. Mechanical characteristics of transmission lines : Sag calculations and stress analysis. Insulated cable: Insulating materials, Electric stress grading of single phase and three phase cable. Dielectric losses and heating. Modern development, testing of insulated cables. Corona power loss. Kelvin’s law, Economic conductor section, limitations, and selection of ideal voltage. EEE 371 (Measurement & Instrumentation) Contact hours/week: 3

Credits:3

Magnetic measurement: Ballistic galvanometer, Tangent galvanometer, D-Arsonval galvanometer. Flux meter, Flux and Flux density measurement. Determination of iron losses and their separation. Measuring instruments : Classification of measuring instruments. Ammeter, Voltmeter, wattmeter, AVO meter, Energy meter, Amperehour meter and Maximum demand meter for measuring AC and DC quantities. Speed, frequency and phase difference measurements. Illumination measurement. Electronic measuring instruments: Digital instruments, VTVM, Q-meter and CRO. Instrumentation : Extension of instrument range. Use of C.T. and P.T and calculation of their burden, Instrumentation of substation. Measurement of non-electrical quantities: Transducer. Measurement of temperature, pressure, displacement, velocity, acceleration. Strain gauge and their applications. EEE 372(Measurement & Instrumentation Sessional) Contact hours/week: 3 Credits:1.5 Sessional based on the theory of course EEE 371.

EEE 381 (Electronic Circuit for Communication System) Contact hours/week: 3 Credits: 3

Introduction to modulation and demodulation : AM, DSB, SSB, VSB, FM & PM. Radio communications: Properties and propagation of radio waves

Introduction : Methods of measurement. Statistical method applied to field of measurement and error analysis and calibration. Resistance, Inductance and Capacitance measurements: Different methods of measuring high, medium and low resistances. Methods of measuring self and mutual inductance and capacitance measurement. A.C. and DC bridge methods, Measurement of insulation and earth resistances. Localization of cable fault.

70

Radio Receivers: Receiver types, TRF and super heterodyne receivers, AM & FM Receiver. Television : Introduction, principle of operation, transmitter and receiver and their circuits. Receiving and transmitting antenna. Camera tube, Picture tube, Electron beam scanning, T-lines, balum, duplexer, Vestigial side-band filters and their circuits. Introduction to color TV, VCR. CCTV, CATV, MATV, TV Booster.

71

Radar : Introduction, radar-equation, Pulse and MTI Radar, CW and FM Radar. Delay lines and cancellers, range getting.

EEE 382 (Electronic Circuit for Communication System Sessional) Contact hours/week: 3/2 Credits: 0.75

Sessional based on the theory of course EEE 381. COURSES FOR THE SEVENTH SEMESTER

Sl. Course No. No 1 2 3

EEE 400 EEE 461 Prerequisite EEE 361 EEE 462

4

EEE 481

5

EEE 482

6 7

EEE 4* EEE 4**

8

Hum 411

Course Title


Project & Thesis Power System Power System Sessional Communication Engineering Communication Engineering Sessional Elective I Elective I Project Planning, Management & Engineering Total

3


3 1.5

3

1.5 3

3/2

0.75

Representation of power system, single line diagrams, impedance and reactance diagrams, per unit system of calculations. Reactance of synchronous generators and its equivalent circuits. Symmetrical fault calculation. Limitation of short circuit current using reactors. Symmetrical components; Positive, Negative, and Zero sequence networks of generators, transformers and lines. Unsymmetrical fault calculation. Power and reactive power flow calculations of simple systems. Load flow studies of large systems. Control of voltage, power and reactive power. Power System stability: Dynamic equations of rotating machines. Swing equation, solution of swing equation. Steady state and transient stability limit of a two machine problem, equal area criterion. Methods of improving stability.

Sessional based on theory course EEE 462. EEE481 (Communication Engineering) Contact hours/week: 3

3 3

3 3

2

2

2

14

14

7.5

3.25

EEE 462 (Power System Sessional) Contact hours/week: 3

0.75

3 3

17.25

*EEE467 (High Voltage Engineering) ** EEE 441 (Microwave Circuits) DETAIL SYLLABUS FOR COMPULSORY COURSES EEE 400 (Project & Thesis) Contact hours/week: 3

Credits: 3

3 3

3

EEE 461 (Power System) Prerequisite: EEE361 Contact hours/week: 3

Credits: 3

Analysis of power and energy signals using Fourier methods. Cross Correlation and auto correlation functions. Spectral density. Signal transmission through linear systems. Basics of probability and random variables. Sources and characteristics of thermal and shot noise, noise temperature, noise figure, noise equivalent bandwidth. Analog pulse modulation: Generation, Spectra and Detection of PAM, PWM and PPM. Quantization of analogue signals; Quantization noise, PCM, log PCM, DM, ADM, DPCM and ADPCM.Information theory, Introduction to Telephony and Satellite communication.

Credits: 1 72

Credits: 1.5

73

EEE482 (Communication Engineering Sessional) Contact hours/week: 3/2 Credits: 0.75 Sessional based on the theory of course EEE 481

* EEE487 (Digital Signal Processing)  EEE451 (Computer Methods in Power System)  EEE452 (Computer Methods in Power System Sessional) # EEE443 (Microwave Devices) ## EEE444 (Microwave Devices Sessional)

Hum 411 (Project Planning Management and Engineering) Contact hours/week: 2 (T) Credits: 2 DETAIL SYLLABUS FOR COMPULSORY COURSES Definitions of project and project management in the Engineering point of view. Project Initiation: Project selection, Project manager, Project organization and Project planning. Project feasibility study.

EEE 400 (Project & Thesis) Contact hours/week: 3

Credits:2

Project Implementation: Project management, Budgeting and cost estimation, Project control, and Human aspects of project management. Network techniques of project management; PERT, CPM and Gantt Charts.

EEE 463 (Power Station) Prerequisite: EEE461C Contact hours/week: 3

Credits: 3

COURSES FOR THE EIGHTH SEMESTER Sl. No 1 2

Course No.

Course Title


Project & Thesis

3

EEE465

4

EEE466

5 6

EEE 4* EEE 4

7

EEE 4

8

EEE 4#

9

EEE 4

##

Power Station Power System Protection & Switchgear Power System Protection & Switchgear Sessional Elective I Elective II Elective II Sessional Elective II Elective II Sessional Total



3

3

3

3

3

3

3/2 3 3

3 3

3

3

74

15

0.75 3 3

3/2

15

0.75

0.75

0.75 3

3/2

0.75

0.75

7.5

4.25

19.25

Introduction to thermal, hydro, nuclear and magneto-hydrodynamic power stations. Nuclear reactor, reactor construction and control. Power reactors. Central station reactors. Nuclear hazards. Variable load problems, plotting and analysis of load curves, chronological load curves and load duration curve. Energy load curve and its use. Load factor, capacity factor, demand factor, utilization factor, diversity factor etc. and there impact over the cost analysis of power generation and utilization. Load forecasting, selection of units and plant location. Load shearing: Base load and peak load plants. Use of chronological load curves to distribute load among units. Power plant Economics: Economic operation of power plants. Input output curve, heat rate curve, incremental rate curve. Use of incremental rate curve for optimum load scheduling. Transmission line loss, determination of loss co-efficient. Economic conductor selection, Kelvin’s law. Graphical method for location of distribution systems. Tariff and tariff design. Bus system. Importance of power control. Current limiting reactors. Different types of bus system layout. Forces on bus section in case of short circuit.

75

EEE 465 (Power system protection and switchgear) Contact hours/week: 3

Credits: 3

Philosophy of switchgear and protection. Circuit breakers, principle of arc extinction in DC and AC circuit breakers. Recovery voltage, rate of rise of recovery voltage and other transient phenomena. Switching surges. Disconnection of unloaded transformer and transmission line. Speed of circuit breaker. Construction, operation, rating and testing of bulk oil and minimum oil breaker, SF6 circuit breaker, ABCD and ACB. Selection of circuit breaker. Travelling wave in transmission line. Surge absorber, lightning arrester, horn gap, its rating and testing. Protective relaying: Relay voltage rating, high, medium and low. Basic protective zone. Relaying Scheme. Electromechanical Relays: Principal, general equation. overcurrent, balanced current, overvoltage, distance, directional, positive sequence, negative sequence and differential relays and their applications. Static relays: Introduction to solid state device in the construction of static relays. Different type of static relays. Generator protection. Transformer protection, Bucholz’s relay. Protection of bus bar, transmission line, feeder etc. Relay testing. EEE 466 (Power system protection and switchgear Sessional) Contact hours/week: 3/2 Credits:0.75 Sessional based on the theory of course EEE 465.

DETAIL SYLLABUS FOR ELECTIVE COURSES (7th and 8th Semesters) Group –A Elective-I EEE 413 (Opto Electronics) EEE 441 (Microwave Circuits) EEE 483 (Fiber Optic Communication) EEE 487 (Digital Signal Processing)

Elective-II EEE 443 (Microwave Devices) EEE 444 (Microwave Devices Sessional) EEE 485 (Digital Communication) EEE 486 (Digital Communication Sessional) EEE 489 (Digital Filter Design) EEE 490 (Digital Filter Design Sessional)

Group- B Elective-I EEE 407 (Renewable Energy) EEE 421(Generalized Machine Theory)

Elective-II EEE 451 (Computer Methods in Power System) EEE 452 (Computer Methods in Power System Sessional)

EEE 467 (High Voltage Engineering EEE 469 (Economic Operation and Control of Power System)

Group- C Elective-I Elective-II EEE 401 (Advanced Control System) EEE 403 (Design of Control System) EEE 433 (Fundamental of Electric Drives) EEE 404 (Design of Control System Sessional) EEE 453 (Neural Networks) EEE 435 (Power Converters) EEE 457 (Discrete Mathematics) EEE 436 (Power Converters Sessional) EEE 469 (Theory of Algorithms) EEE 470 (Theory of Algorithms Sessional) EEE 471 (Transducers and Instrumentation) EEE 472 (Transducers and Instrumentation sessional) EEE 473 (Biomedical Engineering) EEE 474 (Biomedical Engineering Sessional)

76

77

EEE 413 (Opto Electronics) Contact hours/week: 3

Elective-I/II Courses EEE 401 (Advanced Control System) Prerequisite: EEE301 Contact hours/week: 3

Credits: 3

Modeling of physical systems, concepts of state, state-space, controllability and observability. Sensitivity and error analysis. Nonlinear systems, singular points, phase plane analysis, Lyapunov stability, describing functions, on-off and dual mode systems. Sampled data systems. Computer controlled systems. EEE 403(Design of Control System) Contact hours/week: 3

Credits: 3

Linear multivariable control systems. Equivalence of internal and external stability of feedback control systems and the stabilization problem. State factorization approach for solving stabilization problem. Feedback system design. Solution of H2 and Ha problems. Robust stabilization, graph topology and graph metric. EEE 404 (Design of Control System Sessional) Contact hours/week: 3/2

Credits: 3

Credits: 0.75

Credits: 3

Importance of renewable energy, sources. Statistics regarding solar radiation and wind speed. Insulation: geographical distribution, atmospheric factors, measurements. Solar cell: principle of operation, spectral response, factors affecting conversion efficiency, I-V characteristics, maximum power output. PV modules and arrays: stationary and tracking. PV systems: stand alone, battery storage , inverter interfaces with grid. Wind turbine generators: types, operational characteristics, cut-in and cut-out speed, control, grid interfacings, ACDC-AC link.

78

Light : Nature of light, Polarization, superposition, interference, diffraction, sources, blackbody radiation. Modulation of light : Elliptical polarization, Birefringence, quarter wave plate, optical activity, electro-optic effect, Kerr modulators, scanning and switching, magneto –optic devices, acousto-optic effect, nonlinear optics. Display devices: Luminescence, photoluminescence, cathodoluminescent, LED materials, LED construction, response time, plasma displays, LCD, numerical display. Lasers : Emission and absorbs ion, Einstein relation, optical feedback, laser losses, line shape function, modes, classes of laser, laser applications, distance measurements, holography. Photo detectors : Thermal detectors, photon devices, vacuum photodiodes, Noise, Image intensifier, junction detectors, detector arrays. Optical communication system: Fiber optic communication, integrated optics. Noncommunication applications: Optical fiber sensors, Light guiding fiber. EEE 421 (Generalized Electric Machines) Contact hours/week: 3

Sessional based on the theory of course EEE 403 EEE 407 (Renewable Energy) Contact hours/week: 3

Credits: 3

Introduction to Generalized Machine theory; Kronis primitive machine; Moving to fixed axis transformation; Park’s transformation; Three-phase to d-q transformation;P Variable coefficient transformation; other transformations. Matrix analysis of machine; Three phase synchronous and Induction machine and two phase servo motor analysis; Diagonalization by change of variable. Symmetrical three phase machines.

EEE 433 (Fundamentals of Electric Drives) Prerequisite: EEE313 Contact hours/week: 3

Credits: 3

Motor load dynamics, starting, braking and speed control of dc and ac motors. DC drives: converter and chopper control. AC Drives: Operation of induction and synchronous motors from voltage and current inverters, 79

slip power recovery, pump drives using ac line controllers and self controlled synchronous motor drives. EEE 435 (Power Converters) Prerequisite: EEE433 Contact hours/week: 3

Credits: 3

PWM ac dc converters, PWM dual converters, Cycloconverters, Hybrid resonant dc-dc converters, Inverters and Induction heating, resonant dc link inverters, dc- dc converters with different commutation schemes, PWM inverters, switching dc power supplies, power conditions and uninterruptible power supplies. EEE 436 (Power Converters Sessional) Contact hours/week: 3/2

Credits: 0.75

Sessional based on the theory of course EEE 435 EEE 441 (Microwave Circuits) Prerequisite: EEE341 Contact hours/week: 3

EEE 451 (Computer Methods in power system analysis) Prerequisite: EEE461 Contact hours/week: 3

General review of network theory, matrix analysis and computer modeling. Incidence matrices, primitive networks and formation of impedance and admittance network matrices. Algorithms for formation of network matrices. Three-phase networks: Symmetrical components and sequence impedance, balanced and unbalanced faults, fault impedance and admittance matrices. Short circuit studies using Zbus and Zloop, open circuit fault studies. Load flow studies, power flow equations, Gauss-Seidal, Newton-Raphson, Decoupled methods of load flow analysis. Three phase load flow. EEE 452 (Computer Methods in power system analysis Sessional) Contact hours/week: 3/2 Credits: 0.75 Sessional based on the theory of course EEE 451 EEE 453 (Neural Networks) Contact hours/week: 3

Credits: 3

UHF transmission lines. Wave guides, strip line, slot line; microwave circuit design principles; passive circuits; impedance transformers; filters, hybrids, isolators etc., Detection and measurements of microwave signals. EEE 443 (Microwave Devices) Prerequisite: EEE441 Contact hours/week: 3

Credits: 3

Microwave Electronics: Transit time effect velocity modulation. Microwave amplifier and oscillator; Klystron (Multicavity and reflex), Magnetron, TWT. Semiconductor microwave devices. Microwave Antenna: Horn antenna, Rhombic and slot antenna; parabolic antenna. Antenna arrays and their feeding techniques. EEE 444 (Microwave Devices Sessional) Contact hours/week: 3/2 Sessional based on the theory of course EEE 443 80

Credits: 0.75

Credits: 3

Credits: 3

Theory of representation; Two computational paradigms; Multi layer networks; Auto associative and hetero-associative nets; learning in neural nets: Supervised and unsupervised learning; Application of neural nets; Neural network simulator. EEE 457 (Discrete Mathematics) Contact hours/week: 3

Credits: 3

Set theory, Elementary number theory, Graph theory, Paths and trees, Generating functions, Algebraic structures, Semigraph, Permutation graph, Lattices, Finite fields and Coding theory, Linear programming, Mathematical logic, Propositional calculus and predicate calculus Notion of interpretation, validity consistency, and completeness; Introduction to combination counting techniques, recurrence relations. EEE 467 (High Voltage Engineering) Contact hours/week: 3 Credits: 3 Ionization and decay process: Townsend’s first and second ionization coefficient. Electric breakdown in gases. Townsend’s criterion for spark 81

breakdown. Sparking potential. Penning effect. Corona discharges, power loss calculation. Breakdown of solid and liquid dielectrics. Generation of high voltage: Alternating voltage, transformer cascade. Series resonant circuit for high voltage ac testing. Test of dc and ac cable. Transient Voltage: Impulse wave shape. Impulse voltage generator and its mathematical analysis. Design consideration of impulse generators. Triggering of impulse generators. DC voltage doubler and cascade circuits. Electrostatic generator, voltage stabilization. Measurement of high voltage. Electrostatic voltmeter, sphere gap. Potential divider. High Voltage testing of power system equipment. Oil testing. Design consideration of transmission line based on direct stroke. High voltage transient in transmission line. High voltage lightning arrester. Insulation co-ordination. EEE 469 (Economic Operation and Control of Power System) Prerequisite: EEE461 Contact hours/week: 3 Credits: 3 Economic load dispatch, loss formula, introduction to mathematical programming, hydro-thermal scheduling systems, power system security, optimal real and reactive power dispatch, state estimation, load frequency control, energy control center. EE 469 (Theory of Algorithms) Contact hours/week: 3

Credits: 3

Notion of algorithms. Space and time complexity; Notations, Paradigms: Divide-and-Conquer, Branch-and-Bound, Back tracing, Dynamic Programming. Greedy methods, NP-completeness. Examples from graph theory, Computational geometry, optimization, numerical analysis and Data processing. EE 470 (Theory of Algorithms Sessional) Contact hours/week: 3/2

Credits: 0.75

Sessional based on the theory of course EEE 469 EEE 471 (Transducers and Instrumentation) Contact hours/week: 3

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Introduction : Functional elements of Instrumentation system, classification, standards and calibration of different instruments, use of personal computer in instrumentation. Static performance of Instruments : Errors and uncertainties, propagation of uncertainties, Accuracy, Precision, Resulation, Linearity etc., Impedance loading and matching, selection of instruments. Transducer elements : Analog and digital transducer, Active and passive transducer. Construction, operating principle and characteristics of Resistive , Inductive and capacitive transducer, Strain Gauge, Light dependent transducer, LVDT, Piezoelectric, Hall effect transducer, Thermistor, Thermocouple, RTD, Proximity transducer. Data Acquisition and display : Amplifiers, Compensators, Filters, A-D and D-A converter, Data transmission elements, Display and recording elements. Motion measurement : Relative and absolute motion, Linear and rotational motion measurement. Force measurement : Pneumatic and elastic force, measurement of time varying force. Pressure measurement : High, moderate and low (Vacuum) pressure measurement. Torque and power measurement : transmission dynamometers, noncontact dynamometers. Temperature measurement : Measurement of ambient temperature, temperature monitoring and control, measurement of high temperature, use of RTD, Pyrometers. Flow measurement : Linear resistance element flow meter, Ultrasonic flow meter, electromagnetic flow meter. Hot wire anemometer, Laser Doppler anemometer. Acoustic measurement : Sound pressure and power level, Loudness, sound level meter. Microphones, Piezoelectric crystal type microphone, Electrodynamics type microphone, Carbon microphone. Computer aided instrumentation : Example of a few open loop and closed loop control system using different transducers and personal computer. EEE 472 (Transducers and Instrumentation Sessional) Contact hours/week: 3/2 Credits: 0.75

Credits: 3

Sessional: Sessional based on theory of course EEE 471

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EEE 473 (Biomedical Engineering) Contact hours/week: 3

Credits: 3

Medical terminology, cell physiology, membrane potential, action potential, excitation and rhythmically. Rhythmic excitation of heart. Transducers used in medical diagnostics. Biomedical Instrumentation: Normal Electrocardiograph, ECG simulator, Watch filter, ECG amplifier, pulse beat monitor, pace maker, galvanic skin resistance detector, respiratory and suction apparatus. Electronic stethoscope. Electronic clinical thermometer, blood flow and pressure monitoring recorders, metabolic rate measurement. Special topics: Bio-telemetry, application of ultrasonic and laser in biology and medicine. Clinical X- ray equipment. Fluoroscopy. Infrared heating. EEE 474 (Biomedical Engineering Sessional) Contact hours/week: 3/2

Credits: 0.75

Sessional based on the theory of course EEE 473

EEE 483 (Fiber Optic Communication) Prerequisite: EEE481 Contact hours/week: 3

Credits: 3

Introduction : Historical perspective, basic system, nature of light, advantages and applications of fiber optic. Optics review : Ray theory and applications, lenses, imaging, numerical aperture, diffraction. Light wave fundamentals : Electromagnetive waves, Dispersion, polarization, resonant cavities, reflection at plane boundary, critical angle. Integrated optic wave guides : Slab wave guide, Modes in symmetric and asymmetric wave guide, coupling, Dispersion and distortion, Integrated optic components. Optic fiber wave guide : Step index fiber, graded index fiber, attenuation, pulse distortion and information rate, construction of optic fiber, optic fiber cables. Light sources : LED, LD, distributed feedback LD, optical amplifiers, fiber laser, vertical cavity surface emitting laser diode. 84

Light detectors : Photo detection, photo multiplier, semiconductor photodiode, PIN photodiode, avalanche photodiode. Couplers and connectors : Connector principle, end preparation, splices, connectors, source coupling. Network distribution and fiber components : Directional couplers, star couplers, switches, isolator, wave-length division multiplexing, fiber bragg grating. Modulation : LED modulation, LD modulation, Analogue and digital modulation, modulation formats, optic heterodyne receivers. Noise and detection : Thermal shot and noise, SNR, error rates, receiver circuit design. System design : Analogue and digital system design, few real life problems and examples. EEE 485 (Digital Communications) Prerequisite: EEE381 Contact hours/week: 3

Credits: 3

Concept of information. Digital binary modulation schemes: ASK, FSK, PSK, DPSK, QPSK, MSK, and spectral properties. Coherent and noncoherent detection, correlation and matched filter receivers, Phase locked loop (PLL) system. Continuous and discrete signal and systems. Sampling Random process, density spectrum, Representation of digitally modulated signal and spectral analysis. EEE 486 (Digital Communications Sessional) Contact hours/week: 3/2

Credits: 0.75

Sessional based on the theory of course EEE 485 EEE 487 (Digital signal processing) Contact hours/week: 3

Credits: 3

Review of discrete time signals and systems. Sampling of CT signals: aliasing, pre-filtering, decimation and interpolation , A/D, D/A, conversion, quantization noise . Filter design techniques. DFT Computation. Fourier analysis of signals using DFT. Finite register length effect. DSP hardware. Applications. 85

EEE 489 (Digital filter design) Contact hours/week: 3

Credits: 3

Introduction to digital signal processing . Discrete time signals, linear systems. Z- transform , H- transform. Frequency domain representation of discrete time systems and signals, discrete Fourier series and discrete Fourier transform (DFT), Convolution and Correlation, computation of the DFT. Signal flow graph representation of digital networks. Tellegen’s theorem. Digital filters: IIR and FIR filters, filter design. Digital signal processors. Probability and stochastic process, a discrete- time random process, spectrum representation of infinite energy signals, response of linear systems to random signal. Adaptation algorithm, all-zero and lattice adaptive filters, application of adaptive filtering. Model-based signal processing.

EEE 490 (Digital filter design Sessional) Contact hours/week: 3/2 Sessional based on the theory of course EEE 489

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Credits: 0.75

Revised Course Structure for Postgraduate Programs of the Department of Electrical and Electronic Engineering

Compulsory Courses Course No. EEE 6000 EEE 6001

Course Title Thesis/ Project Engineering Analysis

Credit Hours 18/ 6 3

Elective Courses EEE 6002 Selected Current Topics in EEE Energy System Course Course Title No. EEE 6101 Energy Conversion EEE 6102 Rural Energy System EEE6103 Renewable Energy Unconventional Energy Sources and Energy EEE6104 Converters EEE 6105 Physical System Modeling Control System EEE 6201 Modern Control Theory EEE 6202 Introduction to Adaptive Control EEE 6203 Optimal Control Theory EEE6204 Robust Control Systems EEE 6205 Digital Control Theory EEE 6206 Multivariable Control Systems EEE6207 Microprocessor Based Industrial Control EEE6208 Artificial Neural Networks Power System EEE 6301 Advanced Power System Analysis EEE 6302 Advanced Power System Stability EEE 6303 Optimization of Power System Operation EEE 6304 Power System Planning EEE 6305 Computer Aided Power System Design EEE 6306 Power System Reliability 87

3 Credit Hours 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3

Course Credit Course Title No. Hours EEE 6307 Power System Control and Instrumentation 3 EEE6308 Power System Transients 3 EEE 6309 Advanced Protective Relaying 3 EEE6310 Generalized Machine Theory 3 Power Electronics and Drives EEE 6401 Power Electronics Converters I 3 EEE 6402 Power Electronics Converters II 3 EEE6403 Electric Drives 3 EEE 6404 Modeling & Control of Electric Drives 3 Power Electronics Applications in Power EEE 6405 3 Systems Advanced Electronics EEE6501 Integrated Circuit Technology 3 EEE6502 Linear and Digital IC Applications 3 EEE6503 VLSI System Design 3 EEE6504 Computer Aided VLSI Design 3 EEE 6505 Gaseous Electronics 3 EEE 6506 Biomedical Electronics 3 Information Processing and Telecommunication EEE 6601 Information and Coding Theory 3 EEE 6602 Statistical Signal Theory 3 EEE6603 Satellite Communication 3 EEE 6604 Data Communication 3 EEE6605 Cellular Mobile Communication 3 EEE6606 Optical Fibre System 3 EEE6607 Optical Fibre Communication 3 EEE 6608 Digital Signal Processing 3 EEE 6609 Digital Circuit Design 3 EEE 6610 Digital Filter Design 3 EEE 6611 Digital Image Processing 3 Advanced Electromagnetics and Microwaves EEE 6701 Advanced Electromagnetic Theory 3 EEE 6702 Antennas and Propagation 3 EEE6703 Computational Electromagnetics 3 EEE6704 Microwave Solid State Devices 3 EEE 6705 High Power Microwave Devices 3 88

Course No. EEE 6706 EEE 6707 EEE 6708 EEE 6709 EEE 6801 EEE 6802 EEE 6803 EEE 6804 EEE 6805 EEE 6806 EEE 6807 EEE 6901 EEE 6902 EEE 6903 EEE 6904 EEE 6905 EEE 6906

Course Title Plasma Engineering-I Plasma Engineering-II Relativistic Electron Beam Technology Fusion Science and Technology Computer Aided Systems Architecture of Microprocessor & Microcomputer Design and Organization of Microcomputer Computer Simulation of Electrical & Electronic Circuits Computer in Electrical Engineering Computer aided instrumentation and sensor application Computer aided optoelectronics application Computer aided simulation of physical systems High Voltage Engineering Behavior of Dielectric under High Voltage Insulators for high voltage High voltage Power Equipment Engineering Insulating properties of Vacuum under high voltage Insulating properties of SF6 under high voltage HVDC power transmission

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Credit Hours 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3

hydro-electric, and biomass. Different manifestations of biomass utilization are discussed, including combustion and biofuels. Hydrogen production from renewable energy, and the use of hydrogen in heat engines and fuel cells.

Detail Syllabus

EEE 6001: Engineering Analysis Credit: 3

Contact Hours/week: 3

Professional methods of dealing with problems. Mathematical and physical principles applied to problems of diverse topics in Electrical Engineering. Simulation Techniques; Statistical Methods. EEE 6002 : Selected Current Topics in EEE Credit: 3


The respective instructor will determine the detailed syllabus. EEE 6101: Energy Conversion Credit: 3


Energy conversion process; Direct electrical energy conversion; Electromechanical energy conversion; Electrical energy conversion from integrated renewable energy sources.

EEE 6104: Unconventional Energy Sources and Energy Converters Credit: 3 Contact Hours/week: 3 Review of various energy sources. Importance of unconventional sources such as solar, biogas, wind, tidal etc. Study of typical energy converters such as high performance motors, special generators driven by biogas engines, wind turbines etc. Mini-hydro generators. Modern state-of-the art and futuristic systems in this area. EEE 6105: Physical System Modeling Credit: 3

Development of conceptual framework for physical system; Transformation of physical system into mathematical form; Protection and prediction of system response; System stability analysis; Controlling the system response; Policy prescription for optimum system response. EEE 6201 : Modern Control Theory. Credit: 3

EEE 6102: Rural Energy System Credit: 3




Role of energy; Rural energy flow in developing countries; Energy demand-supply balance; Impact of rural energy flow on rural development and physical quality of life; Economic constraints for sustaining the energy flow; Rural energy system simulation for development planning.

General introduction; State space concept; System design by state transition. method, Concept of controllability and observability. Optional control variational calculus method; Principle of maximum and dynamic programming. Stochastic and adaptive control processes. On-line computer control. EEE 6202 : Introduction to Adaptive Control Credit: 3 Contact Hours/week: 3

EEE 6103: Renewable Energy Credit: 3


Solar constant, solar flux at the earth’s surface, beam and diffuse solar flux, and solar beam angles. Direct methods of using solar energy, including solar-thermal, solarthermal-electric, solar photovoltaic, and passive solar heating and lighting. Indirect methods of using solar energy, including wind turbines,

The underlying adaptive control schemes including Lyapunov based direct adaptive control scheme, self-tuning regulator and model reference adaptive control. Least squares estimate and the relevant issues in relation with parameter adaptation. Intelligent control; some simple iterative learning control schemes. Case studies of various engineering control problems will provide insight and useful design guideline

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EEE 6203 : Optimal Control Theory Credit: 3


The Optimal control problem. Cost functional. Use of calculus of variations in optimal control. Optimization by Pontryagin’s maximum principle and dynamic programming; applications. Linear regulator problems. Computational methods of solving two-point boundary value problems. EEE 6204 : Robust Control Systems Credit: 3


Linear Quadratic Regulators: return ratio & difference, sensitivity function. Kalman's optimality condition. Gain/phase margins, robustness to time delay and nonlinearity. Characterization of sensitivity. Kharitonov theorem robustness. Singular values - properties, application in stability, robustness and sensitivity. Robustness of discrete time Linear Quadratic Regulator (LQR) systems. EEE 6205 : Digital Control theory Credit: 3


Discrete-time signals and systems, Z-transform, pulse transfer functions. Compensator design by root locus, error coefficients and frequency response. State-space models of discrete time systems, controllability, observability, stability, state estimation, Kalman filtering. Linear regulation. Parameter estimation. EEE 6206 : Multivariable Control Systems Credit: 3 Contact Hours/week: 3 Multivariable Systems: multivariable systems descriptions, zeros, poles and stability, Interaction and input-output paring. System Performance: performance specifications, system uncertainties, robust stability and performance. Frequency Domain Design: sequential loop design, characteristic locus method, Nyquist Array method. Optimal Design: Linear quadratic control, H-infinity control, predictive control.

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EEE 6207 : Microprocessor Based Industrial Control Credit: 3 Contact Hours/week: 3 Process Control Computer Systems : Minis, micros, classification by hardware features and software facilities, performance evaluation techniques. Characteristics of Digital Processors Organization, instruction set, characteristics for process control, input/output arrangements, addressing techniques, memory systems. Process Control System Software : Review of availability of process control languages, application packages, operating system for real-time process control. System Selection Criteria : Specification, environment, hardware and software requirements. Maintenance, procurement procedures, cost/ performance/availability ratios. Development Tools : Development systems for micros, software tools, logic analyzer, cross assemblers and compilers, simulators, emulators, in-house vs. turn-key trade off. EEE 6208 : Artificial Neural Networks Credit: 3


Introduction & Motivation; Biological Neural Networks and simple models; The Artificial Neuron Model; Hopfield Nets; Energy Functions and Optimization; Perceptrons & Threshold Logic machines; Multilayer Networks-their variants and Applications; Capacity of Mutilayer Networks; Backpropagation; Recurrent Nets; Tree Structured Networks; Unsupervised Learning; Hebbian Learning, Principal Component Analysis; Competitive Learning, Feature Mapping, Self Organizing Maps, Adaptive Resonance Theory. Hardware Realization of ANNs. Recent Trends and Future Directions. EEE 6301: Advanced Power System Analysis Credit: 3 Contact Hours/week: 3 Algorithms for formation of bus admittance and impedance matrices. Power flow solutions : Gauss Seidel, Newton Raphson, Fast decoupled power flow. Short circuit studies. Sparsity exploitation in power system studies. Static equivalents for power systems. Concepts of security states and security analysis in power systems. State estimation in power systems, Voltage stability analysis.

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EEE 6302: Advanced Power System Stability Credit: 3 Contact Hours/week: 3

calculation of system generation schedule, computer controlled dynamic performance.

Voltage Stability: P-V and Q-V curves; Static analysis, sensitivity and continuation method; Dynamic analysis, local and global bifurcations; Control area, Margin prediction; Stability of AC-DC systems, Stability Analysis: Lyapnov's criteria, Energy functions for detailed & reduced order models, Stability boundary

EEE 6306 : Power System Reliability Credit: 3

EEE 6303: Optimization of Power System Operation Credit: 3 Contact Hours/week: 3 General Principle of Optimization its application to power system planning, design and operation. Probability analysis for bulk power security and outage data. Economic operation of power system, economic operation of thermal plants, combined thermal and hydro-electric plants. Theory of economic operation of interconnected areas. Development and application of transmission loss formulae for economic operation of power systems. Methods of optimum scheduling and dispatch of generator EEE 6304 : Power System Planning. Credit: 3


Basic Probability Theory : Review of probability concepts. Probability distributions. Application of binomial distribution to engineering problems. Probability distribution in reliability evaluation. Network modeling and evaluation of simple and complex systems. System reliability evaluation using probability distributions. Frequency and duration techniques. Generation System Reliability Evaluation : Concept of LOLP and E(DNS) : Evaluation of these indices for isolated systems. Generation system. Reliability analysis using the frequency and duration techniques. Transmission System Reliability Evaluation: Evaluation of the LOLP and E(DNS) indices for an isolated transmission system. Distribution System Reliability Evaluation : Reliability analysis of radial systems with perfect and imperfect switching. EEE 6307 : Power Systems Control and Instrumentation Credit: 3 Contact Hours/week: 3


Basic objective of power system planning; Generation expansion planning process. Electrical demand forecasting; Current demand forecasting approaches. Generating planning; economic analysis, expected energy generation, expected fuel cost, Booth-Baleriux cummulant and segmentation methods. Probabilistic simulation of hydro and energy limited units. Expected energy production cost of interconnected systems. Economic aspects of interconnection. Different aspects of load management; effect of load management of reliability on production cost. Joint ownership of generation. EEE 6305: Computer Aided Power System Design Credit: 3 Contact Hours/week: 3

Control of voltage, frequency and tie-line power flows, Q-v and P-f control loops. Mechanism of real and reactive power control.Net interchange tie-line bias control. Optimal, sub-optimal and decentralized controllers. Discrete-mode AGC. Time-error and inadvertent interchange correction techniques. On-line computer control. Distributed digital control. Data acquisition systems. Emergency control, preventive control, system wide optimization, SCADA.

EEE 6308 : Power Systems Transients Credit: 3


Load flow study for large power system, optimal power flow studies, DOMMEL and TINNEY’s method, digital computer methods of

Origin and nature of transients and surges. Surge parameters of plant. Equivalent circuit representations. Lumped and distributed circuit transients .Line energisation and de-energisation transients. Earth and earthwire effects. Current chopping in circuit breakers. Short line fault

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condition and its relation to circuit breaker duty. Trapped charge effects. Effect of source and source representation in short line fault studies. Control of transients. Lightning phenomena. Influence of tower footing resistance and earth resistance. Traveling waves in distributed parameter multiconductor lines, parameters as a function of frequency. Simulation of surge diverters in transient analysis. Influence of poleopening and pole recolsing. Fourier integral and Z transform methods in power system transients. Bergeron methods of analysis and the use of the EMTP package. . EEE 6309: Advanced Protective Relaying Credit: Contact Hours/week: 3 Advanced protective relaying, Basic protection schemes, relay terminology, relay as comparators, static relays, Application of solid state devices, differential relaying systems, distance relaying schemes, protection of multiterminal lines, new types of relaying criteria, special problems, digital protection. EEE 6310 : Generalized Machine Theory Credit: 3


Primitive machine representation, generalized torque equation, Park's transformation, dc machine, induction machine and synchronous machine representation, Equivalent circuits and fault analysis

EEE 6401: Power Electronics Converters I Credit: 3


Power semiconductor devices: Structure, characteristics, ratings and protection. Single phase and 3-phase line commutated converters: Fullycontrolled, half-controlled and dual converters. converters with improved performance. Single phase and 3-phase AC controller. cycloconverters. Static VAR compensators. EEE 6402: Power Electronics Converters II Credit: 3


link inverters, dc-dc converters with different commutation schemes, PWM inverters, Switching dc power supplies power conditioners and uninterruptible power supplies. EEE 6403 : Electric Drives Credit: 3


Motor Load dynamics. starting, Braking and speed control of DC and AC motors. DC drives; converter and chopper control. AC drives; Operation of induction and synchronous motors from voltage and current inverters. Transfer function and stability analysis Slip power recovery. Pump drives using AC line controller and self-controlled synchronous motor drives. Case study of Industrial drives. EEE 6404 : Modeling & Control of Electric Drives Credit: 3


Modeling of AC and DC motors. DC Drives; Cascade control structure, symmetric optimization of speed loop. AC Drives; self controlled synchronous motor drive, inverter and cycloconverter-fed drives. Scalar and Vector control schemes for speed and torque regulation, Drives for traction and other applications. EEE 6405 : Power Electronics Applications In Power Systems Credit: 3 Contact Hours/week: 3 Basics of flexible AC transmission systems, controlled rectifier and energy storage plants, Tap changers and phase shifters, Thyristor controlled VAR compensation and series compensation, modern (synchronous link converter) VAR compensators, unified power flow controller (UPFC) and interline power flow controller, power quality conditioners, power electronics in power generation. EEE 6501 : Integrated Circuit Technology Credit: 3


PWM ac-dc converter, PWM dual converter, Cycloinverters, Hybrid resonant dc-dc converters, Inverters for induction heating, resonant dc

IC components - their characterization and design. Analysis and design of basic logic circuits. Linear ICs. Large Scale Integration. Computer simulation of ICs and layout design. High Voltage ICs. GaAs MESFET

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and GaAs ICs. Failure, reliability and yield of ICs. Fault modeling and testing. EEE 6502 : Linear and Digital IC Applications. Credit: 3 Contact Hours/week: 3 Linear IC applications, Combinational and sequential circuits; Available IC gates and flip-flops. Design of Combinatorial circuits using Karnaugh map; Counters and Shift registers; Active filters using OP Amps; Precision wave shaping circuits; Switching circuits using OP Amps, TTL and CMOS gates. EEE 6503 : VLSI System Design Credit: 3


Emphasis on the synthesis based approach to VLSI Design. Relevant issues related to physical design automation such as placement, floor planning, routing and compaction are covered. Combinational & sequential logic synthesis issues and algorithms are discussed. Detailed coverage of HDLs and high level synthesis algorithms and issues. EEE 6504 : Computer Aided VLSI Design Credit: 3


Hardware Description Languages; Verifying behaviour prior to system construction simulation and logic verification; Logic Synthesis PLA based synthesis and multilevel logic synthesis; Logic optimization; Logic Simulation Compiled and event simulators; Relative advantages and disadvantages; Layout Algorithms Circuit partitioning, placement, and routing algorithms; Design rule verification; Circuit compaction; Circuit extraction and post-layout simulation; Automatic Test Program Generation; Combinational testing D Algorithm and PODEM algorithm; Scan-based testing of sequential circuits; Testability measures for circuits.

Glow discharge, Are discharge, High frequency discharge, Tigger discharge. Electrical breakdown in vacuum; Triggered vacuum gap switches. EEE 6506 : Biomedical Electronics. Credit: 3


The need to study biological instrumentation; biological amplifiers and their interfacing with electrodes for activity monitoring solid state transducers for pressure flow, temperature and other physiological parameters and related instrumentation for long-term use. Low power consuming circuits especially for implantable pace makers; drift problem and its compensation, telemetry of biological signals. Digital signal processing and imagery-construction suitable for scanning, for example, CAT, PET, NMR and ultrasonics with a special reference to instrumentation principles. EEE 6601 : Information and Coding Theory Credit: 3 Contact Hours/week: 3 Entropy and mutual information, rate distortion function, source coding, variable length coding, discrete memory less channels, capacity cost functions, channel coding, linear block codes, cyclic codes. Convolution codes, sequential and probabilistic decoding, majority logic decoding, burst error-correcting codes.

EEE 6602 : Statistical Signal Theory Credit: 3


Introduction; Motion of gas particles. Excitation and Ionization of gases; Mobility, Diffusion, Recombination; Basic process of spark breakdown,

Representation of deterministic signals : Orthogonal representation of signals. Dimensionality of signal spaces. Construction of orthogonal basis functions. Time-bandwidth relationship : RMS duration and bandwidth, uncertainty relations. Random Processes : Definition and classification, stochastic integrals, Fourier transforms of random processes, stationary and non-stationary processes, correlation functions. Ergodicity, power spectral density, transformations of random processes by linear systems. Representation of random processes (via sampling, KL expansion and narrow band representations), special random processes (white Gaussian noise, Wiener-Levy processes, shot-noise processes,

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EEE 6505 : Gaseous Electronics. Credit: 3


Markov processes). Optimum Filtering : Matched filters for deterministic signals in white and colored Gaussian noise. Wiener filters for random signals in white and colored Gaussian noise. Discrete and continuous time filters. EEE 6603 : Satellite Communication Credit: 3


Introduction. Historical background and overall perspective; Satellite network modeling ; Link calculations; FM analysis; TV Transmission; Digital modulation; Error control; Multiple access; FDMA, TDMA, CDMA. Orbital considerations; Launching; Atmospheric effects; Transponders; Earth Stations; VSATs. EEE 6604 : Data Communication Credit: 3


Review of data communication techniques. Data transmission, line coding, error control coding. Data switching, circuit switching, message & packet switching. Network model ISO-OSI model, primitives and services. Elements of queuing. Data link control Simplex, pipelined and sliding window protocols, simplex performance analysis. X 25 data link layer. Random access techniques. Pure, slotted and finite population ALOHAs. Stability in ALOHAs. Routing and congestion control Static, adaptive, centralized and distributed routing procedures, congestion control. Local Area Networks LAN topologies and protocols, IEEE 802x protocols, implementation and performance issues. High speed LANs. Transport layer. Quality of service, transport classes. Design issues, buffer management, synchronization. Session and presentation layer synchronization issues, formatting, data compression, data security. EEE 6605 : Cellular Mobile Communication Credit: 3


Mobile Radio Channel Modeling; Modulation Techniques; Cellular System Concepts; Equalization, Diversity and Channel Coding; Speech Coding; Multiple Access Techniques; Case Study: GSM, IS-95 and IMT2000 WCDMA.

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EEE 6606 : Optical Fibre System Credit: 3


Review of semiconductor physics - radiative recombination. LEDs, optical cavity, DH and other lasers. P-I-N and APD detectors, detector noise. Optical fibers - ray and mode theories, multimode and single-mode fibers, attenuation, dispersion. Gaussian beams. Power coupling, splices and connectors. EEE 6607 : Optical Fibre Communication Credit: 3


Fiber optic transmitter and receiver designs. Link analyses. Line Coding. Coherent optical communication systems. Multiplexing schemes. Local area networks, FDDI, SONET and SDH. Fiber optic sensors and signal processing. Optical Amplifiers. Photonic Switching. Solutions in optical fibers.

EEE 6608 : Digital Signal Processing. Credit: 3


Introduction discrete time systems, Z- transforms; Flow graphs and matrix representation of digital network. Wave digital filters, Discrete Fourier transform, Fast Fourier transform, Digital filter design. EEE 6609: Digital Circuit Design Credit: 3


The course will present advance techniques of digital circuit design. It will concentrate on the design of sequential circuits, micro programming viewed as a sequential circuit and fault tolerant design. Basic review of Combinational circuit design using k-map, multiplexers and EPROMs. Introduction to sequential circuits; fundamental mode circuits. Concept of state, construction of state diagrams. Event driven circuits using RS latch, multiplexers and EPROMs Clock driven circuits using JK flip-flops, counters and EPROMs. Microprogramming and use of AMD 2909 microsequencer and sequential circuits. Reliable design theory and techniques.

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Some examples like Data Acquinition system, microprocessor peripheral interface, digital printer interface and DMA controller will be taken up. EEE 6610: Digital Filter Design Credit: 3

assumed current distribution. Aperture antennas : slot, waveguide, horn, reflector and printed antennas. Analysis using field equivalence principle and Fourier transform methods. Linear arrays. Broadband antennas. Antenna measurements.


Discrete time signals and systems Z transforms. Structures for digital filters. Designs procedures for FIR and IIR Filters.

EEE 6611: Digital Image Processing Credit: 3


Digital Image Fundamentals; Image Enhancement in Spatial Domain: Gray Level Transformation, Histogram Processing, Spatial Filters; Image Transforms: Fourier Transform and their properties, Fast Fourier Transform, Other Transforms; Image Enhancement in Frequency Domain; Color Image Processing; Image Warping and Restoration; Image Compression; Image Segmentation: edge detection, Hough transform, region based segmentation; Morphological operators; Representation and Description; Features based matching and Bayes classification; Introduction to some computer vision techniques: Imaging geometry, shape from shading, optical flow; Laboratory exercises will emphasize development and evaluation of image processing methods. EEE 6701 : Advanced Electromagnetic theory Credit: 3 Contact Hours/week: 3 Transmission line theory; Green's function and integral transform techniques; Wave propagation and polarization parameters; reflection and transmission across an interface; waveguides, cavity resonators, scattering by cylinders, wedges, spheres etc. Geometric theory of diffraction EEE 6702 : Antennas and Propagation Credit: 3


Review of the theory of electromagnetic radiation. Introduction to various antenna types wire, loop and helix antennas, analysis using 102

EEE 6703 : Computational Electromagnetics Credit: 3 Contact Hours/week: 3 Review of analytical methods: Separation of variables conformal transformation: Green's function. Finite difference method: Iterative solution: relaxation and acceleration processes: Finite difference time domain method (FDTD); different boundary conditions. Finite element method: Discretization of solution region: shape functions: element matrices and global matrix; method of solution. Method of moments; Basis functions; weighted residuals; method of least squares; numerical integration EEE 6704 : Microwave Solid State Devices Credit: 3


Two terminal devices and circuits : Junction diodes PIN, Schottky, Varactor, tunnel diodes. Design and analysis of switches, limiters, phase shifters, modulators, harmonic generators and parametric amplifiers. Transferred Electron Devices-Gunn, LSA. Avalanche Transit Time Devices-IMPATT, TRAPATT and their circuits. Bipolars, JFET and MESFET. Design of oscillators and amplifiers EEE 6705 : High-Power Microwave Devices Credit: 3


Microwave amplifiers and oscillators; Principle of generation of millimeter and sub-millimeter waves from FAST WAVE devices (including FELs and Electron Cyclotron Masers), SLOW WAVE devices (including Klystrons, Magnetrons Cerenkov Masers, BWOs, RDGs and NWCGs), and PLASMA devices (including VIRCATORS and reditrons). Details study of electromagnetic Slow Wave Systems. General Properties of Slow Wave Structures, Analysis of Cold Slow Wave structures, Interaction of Electron Beam with Electromagnetic Field supported by Slow Wave Structures.

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EEE 6706 : Plasma Engineering - I Credit: 3


General Concepts of Plasma; Generation and Application of plasma; Single particle and collective nature of Plasma; Motion of charged particles in Electric and Magnetic Fields; Fluid Theory of Plasma; waves in unmagnetized and magnetized plasmas; Diffusion and resitivity of Plasma. EEE 6707 : Plasma Engineering - II Credit: 3


Equilibrium and stability of Plasma. Electron beam interaction with plasma; amplifying wave and absolute instability, interaction in a one dimensional system (Longitudinal and Transverse interaction), interaction with cold plasma in systems of finite transverse dimensions. EEE 6708: Relativistic Electron Beam Technology. Credit: 3 Contact Hours/week: 3 Introduction to REB; Generation of REB; Propagation of REB. Theory of particle acceleration in liner accelerator. Special theory of Relativity; Dynamics of relativistic particles and electromagnetic fields. EEE 6709 : Fusion Science And Technology. Credit: 3


Introduction to Nuclear Fusion; Fusion reaction and fuel resources; Plasma confinement, Tokamak confinement physics; Thermonuclear devices based on pinch effect; Mirror like devices. Fusion technology; Plasma heating; Introduction to a commercial Tokamak Fusion Power Plant. EEE 6801 : Architecture of Microprocessors and Microcomputers Credit: 3 Contact Hours/week: 3

Bit-Slice processors: Basic structure of control unit of a microprocessor. Organization of bit slice processors like AM2903 and Intel 3008 Comparison with microprocessor chips. Architecture of microcomputers like SDK- 85, HP 5032, SDK- 86, single chip microcomputer 8748, intelligent CRT terminal, microprocessor development system like Intellect series II and III, BBCmicrocontrollers PLCS, graphics processors and floppy disk controllers; arithmetic processors like Intel 8087 and 80287; EET processors and arry processors. EEE 6802 : Design and Organization of Microcomputer Systems and Application. Credit: 3 Contact Hours: 3 Hrs/Week Number system: Floating point arithmetic. Organization of a small computer control unit and I/O structures. Various aspects of machine language, Assembly language and assemblers. Typical programmable and non programmable peripheral support LSI. Single chip microprocessor. Microprocessor based signal processing and control instrumentation. Microprocessor based system design.

EEE 6803 : Computer Simulation of Electrical and Electronic Circuits. Credit: 3 Contact Hours: 3 Hrs/Week DC analysis of liner network; solution of simultaneous, sparse, linear equations; DC analysis of nonlinear circuits, transient analysis of linear and nonlinear circuits, hybrid analysis. Circuit models for common semiconductor devices like BJT, MOSFET, thyristor. Macromodels for analog ICs like the opamp. Implementation of a general purpose circuit analysis program like SPICE. EEE 6804 : Computer in Electrical Engineering. Credit: 3 Contact Hours/week: 3

Internal organization of the Intel 8085, M6800, Z80, M6809, Rockwell 6502, Intel 8086/88, M6800 and Z8000 Microprocessors. Comparison of the architectures based on hardware feature such as addressing modes interrupt structures, instruction execution, multiprogramming abilities and memory management.

Prerequisite: Students will be required to have a general knowledge about microcomputers and database and spread sheet programs. They are also required to have a fair knowledge of programming in either C or Pascal.

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Use of microcomputers in different fields of electrical engineering for design, simulation, analysis etc. Demonstration program development in one of the above fields. EEE 6805 : Computer aided instrumentation and sensor application Credit : 3 Contact Hours/week : 3 Review of different types of sensors and their operation characteristics, Signal conditioning and driver circuits, ADC and DAC applications, Signal multiplexing, interfacing techniques interfacing external circuit with pc, serial and parallel port, port programming, reading data from outside pc, sending data to port loop and closed loop instrumentation Practical examples dealing with linear and angular displacement, force, light, temperature and acoustic signals. introduction to different types of standard interfacing bus such as GPIB, HPIB IEEE488 etc. EEE 6806 : Computer aided Optoelectronics application Credit : 3 Contact Hours/ week: 3 Elements of optoelectronics Light and laser Light, Laser system. Photo detectors, Radiometry and light coupling systems and applications, fiber optics telephone link, optical imaging using CCD cameras, Laser scanning camera, interfacing camera with pc.

Time required for inception of breakdown channel and again of solid dielectrics; Treeing process. Insulation properties of vacuum and gases other than air. Gas insulated systems. EEE 6902 : Insulators for high voltage Credit : 3

Contact Hours/weeks : 3

Introduction, functions of insulators, classification, insulation materials, manufacturing processes of different insulators, terminal fitting of insulators, insulator life, contamination, testing of insulators, remedies of flashover, insulators for special application, hot-sticks. EEE 6903 : High Voltage Power Equipment Engineering Credit : 3 Contact Hours/weeks : 3 Basic Concept of circuit interruption, Impulse characteristics and corona, Lightning, traveling wave propagation, lightning protective devices, design of lightning proof transmission lines, grounding, Insulator coordination. EEE 6904 : Insulating properties of vacuum under high voltage Credit : 3 Contact Hours/weeks : 3

Basic concept of simulation, system modeling simulation of continuous and time discrete system, queuing simulation, pert network, simulation software, simulation examples of some real life physical systems of different types.

Review of breakdown mechanism in air uniform and non uniform field, micro discharges, factors affecting breakdown in vacuum, electrode gap, electrode materials, surface contamination, area effect, temperature effect, type of applied voltage, breakdown under dc, ac impulse voltage, frequency of applied voltage, Effect of pressure recovery of insulation property after breakdown, flash over across solid used in vacuum, Remedies.

EEE 6901 : Behavior of Dielectrics Under High Voltage Credit : 3 Contact Hours / week: 3

EEE 6905: Insulating properties of SF6 under high voltage Credit : 3 Contact Hours/weeks : 3

Classification of Electric Field, Schwaiger factor, Numerical estimation of Electric Fields. Charge Simulation Method. Breakdown mechanism: Development of Avalanches Streamer and Leader Processed, arcs: Intrinsic and practical strength of dielectrics.

General properties of SF6 review of breakdown mechanism in gas, breakdown mechanism in SF6 are interruption, current chopping in SF6 mixture of SF6 with other gases, SF, insulated equipments. SF6 circuit breakers, SF6 insulated underground cables, SF6 insulated substations,

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EEE 6807 : Computer Aided Simulation of Physical Systems Credit: 3 Contact Hours/week: 3

SF6 gas filling and handling plants, Insulation co-ordination in SF6 insulated substations, Future trends. EEE 6906 : HVDC power transmission Credit : 3

Contact Hours/weeks : 3

DC power transmission technology, HVDC converters system control, faults and protection, smoothing reactors, reactive power control, multi terminal dc system, analysis of ac/dc dynamic simulation of converters and dc systems.

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Eee Ruet Syllabus

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