Edmonds' algorithm: Difference between revisions

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The '''power gain''' of an [[electrical network]] is the ratio of an output [[Power (physics)|power]] to an input power. Unlike other [[Signal (electronics)|signal]] [[gain]]s, such as [[voltage]] and [[Electric current|current]] gain, "power gain" may be ambiguous as the meaning of terms "input power" and "output power" is not always clear. Three important power gains are '''operating power gain''', '''transducer power gain''' and '''available power gain'''. Note that all these definitions of power gains employ the use of average (as oppose of instantaneous) power quantities and therefore the term "average" is often suppressed, which can be confusing at occasions.
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==Operating power gain==
 
The operating power gain of a [[two-port network]], G<sub>P</sub>, is defined as:
 
:<math>G_P = \frac{P_\mathrm{load}}{P_\mathrm{input}}</math>
 
where
*P<sub>load</sub> is the maximum time averaged power delivered to the load, where the maximization is over the load impedance, i.e., we desire the load impedance which maximizes the time averaged power delivered to the load.
*P<sub>input</sub> is the time averaged power entering the network
 
If the time averaged input power depends on the load impedance, one must take the maximum of the ratio--not just the maximum of the numerator.
 
==Transducer power gain==
 
The transducer power gain of a two-port network, G<sub>T</sub>, is defined as:
 
<math>G_T = \frac{P_\mathrm{load}}{P_\mathrm{source,max}}</math>
 
where
*P<sub>load</sub> is the average power delivered to the load
*P<sub>source,max</sub> is the maximum available average power at the source
 
In terms of [[y-parameters]] this definition can be used to derive:
 
:<math>G_T = \frac{4|y_{21}|^2 \Re{(Y_L)}\Re{(Y_S)}}{|(y_{11}+Y_S)(y_{22}+Y_L)-y_{12}y_{21}|^2}</math>
 
where
*Y<sub>L</sub> is the load admittance
*Y<sub>S</sub> is the source admittance
 
This result can be generalized to z, h, g and y-parameters as:
 
:<math>G_T = \frac{4|k_{21}|^2 \Re{(M_L)}\Re{(M_S)}}{|(k_{11}+M_S)(k_{22}+M_L)-k_{12}k_{21}|^2}</math>
 
where
*k<sub>xx</sub> is a z, h, g or y-parameter
*M<sub>L</sub> is the load value in the corresponding parameter set
*M<sub>S</sub> is the source value in the corresponding parameter set
 
P<sub>source,max</sub> may only be obtained from the source when the load [[Electrical impedance|impedance]] connected to it (i.e. the equivalent [[input impedance]] of the two-port network) is the [[complex conjugate]] of the source impedance, a consequence of the [[maximum power theorem]].
 
==Available power gain==
 
The available power gain of a two-port network, G<sub>A</sub>, is defined as:
 
<math>G_A = \frac{P_\mathrm{load,max}}{P_\mathrm{source,max}}</math>
 
where
*P<sub>load,max</sub> is the maximum available average power at the load
*P<sub>source,max</sub> is the maximum power available from the source
 
Similarly P<sub>load,max</sub> may only be obtained when the load impedance is the complex conjugate of the [[output impedance]] of the network.
 
==References==
*[http://rfic.eecs.berkeley.edu/~niknejad/ee142_fa05lects/pdf/lect4.pdf Lecture notes on two-port power gain]
 
{{DEFAULTSORT:Power Gain}}
[[Category:Electrical parameters]]
[[Category:Two-port networks]]

Latest revision as of 17:00, 3 January 2015

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