5.1 THE AMPLIFIER BLOCK 227Time average of[v(t)v(t)]=1
2Re[
V ̄V ̄∗]
=∣
∣V ̄
∣
∣^2
2
The maximum power is derived from a Thévenin source when it is loaded by a resistance
equal toRTh. The maximum power thus obtainable, known asavailable power PAV L, is given byPAV L=∣
∣V ̄Th
∣
∣^2
8 RTh
In this circuit,
∣
∣V ̄in
∣
∣^2 = R2
i
(Ri+RTh)^2∣
∣V ̄Th
∣
∣^2Note that the peak value of the sinusoid is used here for the magnitude of the phasor in these
expressions. Thus,GP=PL
PAV L=4 A^2 RLRi^2 RTh
(Ro+RL)^2 (Ri+RTh)^2
Substituting the values given, one getsGP=4 ( 1 )^2 ( 100 ) 108 (20,000)
( 100 + 100 )^2 (10,000+20,000)^2=200
9= 22. 22Note that although the amplifier’s open-circuit voltage amplificationAis only unity, substantial
power gain is obtained in this case since the current gain is greater than unity andGP=GVGI.
In applications of microwave technology, the function of the amplifier is to magnify very small
power to a measurable level with as little random noise as possible. The source signal may be
from a radio telescope, and the available power may be determined by the power captured by the
antenna dish.EXAMPLE 5.1.3
Quite often an amplifier is used as a component of an amplifier circuit. Consider the amplifier
circuit shown in Figure E5.1.3, which contains an amplifier block as an internal component. Find
the input resistanceRi′, the output resistanceR′o, and the open-circuit voltage amplificationA′of
the larger circuit.
RS ABvout R 2Amplifier
block
with constants
Ri, Ro, AvS RL+−R 1+−CDvin+−Figure E5.1.3
SolutionThe input resistance looking into terminalsAandBis