Link Budget Calculation Marco Zennaro and Carlo Fonda the Abdus Salam International Centre for Theoretical Physics
[email protected]
Link Planning •How far can we go? •How much power can we use? •What kind of antennas should be use? •Are all the cables the same?
dB math • decibels are a relative measurement unit unlike the absolute measurement of milliwatts • the decibel (dB) is an expression of the relationship between a variable quantity and a known reference quantity • the calculation of decibels uses a logarithm to allow very large or very small relations to be represented with a conveniently small number • on the logarithmic scale, the reference cannot be zero because the log of zero does not exist!
dB math • the reference point that relates the logarithmic dB scale to the linear watt scale is:
1 mW = 0 dBm • the m in dBm refers to the fact that the reference is 1 mW and therefore a dBm measurement is a measurement of absolute power
dB math •to convert mW to dBm: P(dBm)= 10 log P(mW) •to convert dBm to mW: P(mW)= log-1 (P(dBm)/10) •gains and losses are ADDITIVE
dB math • gain or loss in an RF system may be referred to by absolute power measurement (10W of power) or by a relative power measurement (half of its power) • -3dB = half the power in mW • +3dB = double the power in mW • -10dB = one tenth the power in mW • +10dB = ten times the power in mW
dB math
• 10 mW + 3 dB = 20 mW • 100 mW - 3dB = 50 mW • 10 mW + 10 dB = 100 mW • 300 mW - 10 dB = 30 mW
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dB math •+43 dBm •43dB = 10dB + 10dB + 10dB + 10dB + 3dB •1 mW x 10 = 100 mW •100 mW x 10 = 1000 mW •1000 mW x 10 = 10000 mW •10000 mW x 2 = 20000 mW = 20 W
dB math •-26 dBm •-26dB = - 10dB - 10dB - 3dB - 3dB •1 mW / 10 = 100 uW •100 uW / 10 = 10 uW •10 uW / 2 = 5 uW •5 uW / 2 = 2.5 uW
dB math •when quantifying the gain of an antenna, the decibel units are represented by dBi •the i stands for isotropic, which means that the change in power is referenced against an isotropic radiator •an isotropic radiator is a theoretical ideal transmitter that produces an e.m. field in all directions with equal intensity at a 100% efficiency
antenna gain •an antenna element is a passive device •the antenna can create the effect of amplification by virtue of its physical shape
•by intentional radiator we mean the RF device and all cabling and connectors up to, but not including, the antenna
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intentional radiator •any reference to “power output of the Intentional Radiator” refers to the power output at the end of the last cable or connector before the antenna •if a 30 mW transmitter loses 15 mW of power in the cables and another 5 mW from the connectors, the power of the intentional radiator is 10 mW
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EIRP • the EIRP is the Equivalent Isotropically Radiated Power •EIRP is the power actually radiated by the antenna element and is important because •it is regulated by the FCC or other regulatory agency •it is used in calculating whether or not a wireless link is viable
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EIRP • suppose a transmitting station uses a 10 dBi antenna (which amplifies the signal 10 times) and is fed by 100 mW from the intentional radiator • the EIRP is 1000 mW or 1 W • the FCC has rules defining both the power output at the intentional radiator and the antenna element
EIRP •the FCC enforces certain rules regarding the power radiated by the antenna element, depending on whether the implementation is point-to-multipoint or point-to-point •PtMP links are typically configured in a star topology •when an omnidirectional antenna is used, the FCC automatically considers the link a PtMP link
PtMP •in the setup of a PtMP link, the FCC limits the EIRP to 4 Watts •the power limit set for the intentional radiator is 1 Watt •is the transmitting LAN devices are adjustable with respect to their output power, then the system can customized to the needs of the user
PtMP •suppose a radio transmitting at 1 Watt(+30 dBm) is connected directly to a 12 dBi omnidirectional antenna •the total output power at the antenna is about 16 Watts, which is well above the 4 Watts limit •the FCC stipulates that for each 3dBi above the antenna’s initial 6dBi of gain, the power of the intentional radiator must be reduced by 3dB below the initial +30dBm
PtMP •for our example, since the antenna gain is 12dBi, the power of the intentional radiator must be reduced by 6dB •this reduction will result in an intentional radiator power of 24 dBm, or 36 dM of EIRP which is 4 Watts •the end result is that the power at the intentional radiator must never be more than 1 Watt, and the EIRP must never be above 4 Watts for a PtMP connection
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PtP • Ptp links include a single directional transmitting antenna and a single directional receiving antenna • the FCC mandates that for every 3 dBi above the initial 6 dBi of antenna gain, the power at the intentional radiator must be reduced by 1 dB from the initial +30 dBm • consider the previous example: 1W (+30 dBm) at the intentional radiator and a 12 dBi antenna (directional antenna in this case)
PtP • the total output power is still 16 Watts • since the antenna gain is 12 dBi, the power at the intentional radiator must be reduced by 2 dB • this reduction will result in an intentional radiator power of 28 dBm (30-2), and an EIRP of 40 dBm or 10 Watts • in the case of PtP links, the power of the intentional radiator is still limited to 1 Watt, but the limit of the EIRP increases with the gain of the antenna
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Fresnel zone • the Fresnel Zone occupies a series of concentric ellipsoid-shaped areas around the Line-of-Sight path • the Fresnel Zone is important to the integrity of the RF link because it defines an area around the LOS that can introduce RF signal interference if blocked • objects in the Fresnel Zone as trees, hilltops and buildings can diffract or reflect the main signal away from the receiver
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Fresnel zone • the radius of the Fresnel Zone at its widest point can be calculated as r=72.6 x sqrt(d/4f) where d is the link distance in miles, f is the frequency in GHz and the answer r is in feet r=17.32 x sqrt(d/4f) where d is the link distance in km, f is the frequency in GHz and the answer r is in meters
Fresnel zone • considering the importance of the Fresnel Zone, it is important to quantify the degree to which it can be blocked • typically, 20%-40% Fresnel Zone blockage introduces little to no interference into the link • it is better to err to the conservative side allowing no more than 20% blockage of the Fresnel Zone • http://www.terabeam.com/support/calculations/ fresnel-zone.php
Propagation Basics Signal power is diminished by geometric spreading of the wavefront, commonly known as Free Space Loss
1.
Signal power is attenuated as the wave passes through solid objects as trees, walls, windows and floors of buildings
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The signal is scattered and can interfere if there are objects in the beam of the transmit antenna even if these objects are not in the direct path between the transmitter and the receiver
3.
Free Space Loss • geometric spreading happens because the wavefront radiated signal energy expands as a function of the distance from the transmitter • using decibels to express the loss and using 2.45 GHz as the signal frequency, the equation for the Free Space Loss is
Lfsl = 40 + 20*log(r) where Lfsl is expressed in dB and r in meters
Attenuation •when the RF signal passes through solid objects, some of the signal power is absorbed •the most convenient way to express this is by adding an “allowed loss” to the Free Space •attenuation can vary greatly depending upon the structure of the object the signal is passing through •metal in the barrier greatly increases the attenuation
Attenuation • trees account to 10 to 20 dB of loss per tree in the direct path. Loss depends upon the size and the type of tree • walls account to 10 to 15 dB depending upon the construction • floors of buildings account 12 to 27 dB of loss. Floors with concrete and steel are a the high end and wood floors at the low end • mirrored walls have very high loss because the reflective coating is conductive
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Scattering • antenna diversity was devised for the purpose of compensating the multipath • antenna diversity means using multiple antennas in order to compensate the conditions that cause multipath • antenna switching diversity: multiple antennas on multiple inputs, with a single receiver. The signal is received through only one antenna at a time • transmission diversity: transmits out of the antenna last used for reception. Can alternate antennas for retries
Scattering • a simple way of applying the effects of scattering is to change the exponent on the distance factor of the Free Space Loss formula like this:
L(dB) = 40 + 10 * n * log(r) • the exponent tends to increase with the range in an environment with a lot of scattering • calculating a range can often require some iteration of the exponent to be used
Total Loss • when Free Space Loss, Attenuator and Scattering are combined, the loss is
L(dB) = 40 +10*n*log(r) + L(allowed)
Link Margin • the performance of any communication link depends on the quality of the equipment being used • link margin is a way of quantifying equipment performance • an 802.11 link has an available link margin that is determined by four factors
Link Margin • Transmit Power • Transmit Antenna Gain • Receive Antenna Gain • Minimum Received Signal Strength or Level • the link margin is
TX(power)+TX(ant gain)+RX(ant gain)-RSL
Link Margin •the link factors are usually listed in the manufacturer’s data sheets for the equipment being used •note that the minimum RSL is dependent upon rate and the 1 Mbps rate is used for maximum range •TX power can also be rate dependent but manufacturers rarely indicate this
Maximum Range the maximum range is achieved when the signal loss is less than the link margin • we must know the equipment parameters and must estimate the allowed loss and the scattering exponent to complete the calculation • the equipment parameters can be found on the data sheets
maximum range. TX power can also be rate dependent but manufacturers rarely indicate this. Maximum range. The maximum range is achieved when the signal loss expressed in Equation 4 is less than the link margin expressed in Equation 5. The system operator needs to know the equipment parameters and must estimate the allowed loss and the scattering exponent to complete the calculation. Example parameters are shown in Tables 1 and 2.
Maximum Range
Table 1. Application Dependent Environment Parameters Allowed Loss Scattering Application (dB) Exponent Outdoor free space 0 2 2.5 at 200m 3 at 400m Outdoor, no barriers 0 3.5 > 500m Outdoor with trees 10 to 20 3 to 4 Outdoor buildings 0 4 Indoor - no barriers 0 2.5 Indoor partitions 0 3.5 12 to 27 (floors) Indoor walls & floors 10 to 15 (walls) 4 to 5
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Example
Marina Park Urban café Conference room Office cubicles Condo, apartment
Example 1 • suppose a university wants to setup a point-to-multipoint link
Example 1 • Access Point: •TX Power: 13 dBm •TX Antenna Gain: 8.5 dBi • PC Cards: •RX Antenna Gain: 0 dBi •RX Sensitivity: -89 dBm
Example 1 •the link margin is TX(power)+TX(ant gain)+RX(ant gain)-RSL 13+8.5+0-(-89)= 110.5 dB
Example 1 •we can estimate the allowed loss to be 10 dB if the park had a modest number of trees mixed with open spaces and use a scattering exponent of 3 •to get the maximum range we would solve 110.5=40+10*3*log(rmax)+10 rmax=102 meters
Example 1 • using the same equation to calculate the range assuming free space loss only (exponent=2, and allowed loss=0) 110.5=40+10*2*log(rmax)+0 rmax=3264 meters • this example shows that environmental factors can play a significant role in diminishing the signal strength