Question 4.12: Determine the minimum and maximum voltage gain of the amplif...

On the data sheet, g_{m} is shown as y_{fs} . The range is 2000 μS to 8000 μS (shown as 2000 μmhos on the data sheet). The maximum value of r^{'}_{s} is
r^{'}_{s} = \frac{1}{g_{m} } = \frac{1}{2000  \mu S} = 500  \Omega

The ac source resistance , R_{s} ,is simply the load resistor, R_{L} , which is R_{S} . Substituting into Equation (4–9),

A_{v} = \frac{R_{s} }{r^{'}_{s} + R_{s} }

the minimum voltage gain is

A_{v(min)} = \frac{R_{s} }{r^{'}_{s}  +  R_{s} } = \frac{10  k\Omega }{500  \Omega  +  10  k \Omega } = 0.95

The minimum value of r^{'}_{s} is

r^{'}_{s} = \frac{1}{g_{m} } = \frac{1}{8000  \mu S} = 125  \Omega

The maximum voltage gain is then

A_{v(max)} = \frac{R_{s} }{r^{'}_{s}  +  R_{s} } = \frac{10  k\Omega }{125  \Omega  +  10  k \Omega } = 0.99

Notice that the gain is slightly less than 1. When r^{'}_{s} is small compared to the ac source resistance, then a good approximation is A_{v} = 1. Since the output voltage is at the source, it is in phase with the gate (input) voltage.