Chapter 10, Problem 10.23P

To determine

The $A_M,f_H,f_t,f_z$ and gain at high frequencies. Also, draw the bode plot for the given amplifier.

  $\begin{array}{l}{A}_M=-40\text{V/V}\\ f_H=72.34\text{ MHz}\\ f_t=2.89\text{ GHz}\\ f_z=31.83\text{ GHz}\end{array}$

  

Fig: Bode plot

Given Information:

  $\begin{array}{l}{R}_L^{\text{'}}=20\text{ k}\Omega \\ g_m=2\text{mA/V}\\ C_{gd}=10\text{fF}\\ C_L=100\text{fF}\end{array}$

Calculation:

The expression for gain in the CS amplifier is given by,

  $A_M=-g_m{R}_L^{\text{'}}$

Where $R_L^{\text{'}}$ is the load resistance and $g_m$ is the trans-conductance of the amplifier.

Plugging given values.

  $\begin{array}{c}{A}_M=-\left(2\text{mA/V}\right)\left(20\text{ k}\Omega \right)\\ =-40\text{V/V}\end{array}$

Write the equation for 3-dB frequency in terms of capacitance $C_{gd}$, $C_L$ and resistance $R_L^{\text{'}}$ as follows:

  $f_H=\frac{1}{2\pi \left(C_L+C_{gd}\right)R_L^{\text{'}}}$

Plugging given values.

  $\begin{array}{l}{f}_H=\frac{1}{2\pi \left(100\text{fF}+10\text{fF}\right)20\text{ k}\Omega }\\ f_H=\frac{1}{2\pi \left(100+10\right)\times {10}^{-15}\times 20\times {10}^3}\\ f_H=7.23\times {10}^7\text{Hz}\\ f_H=72.3\text{MHz}\end{array}$

The equation for unity gain frequency in terms of trans-conductance $g_m$ , capacitance $C_{gd}$, $C_L$ and resistance $R_L^{\text{'}}$ as follows:

  $\begin{array}{l}{f}_t=\left|A_M\right|f_H\\ f_t=40\text{V/V}\times 72.3\text{MHz}\\ f_t=2892\text{MHz}\\ f_t=2.892\text{GHz}\end{array}$ .

The equation for the frequency of the transmission zero in terms of trans-conductance $g_m$ , and capacitance $C_{gd}$ as follows:

  $f_z=\frac{g_m}{2\pi C_{gd}}$

Plugging value for parameters

  $\begin{array}{l}{f}_z=\frac{2\text{mA/V}}{2\pi \times 10\text{fF}}\\ f_z=\frac{2\text{mA/V}}{2\pi \times 10\times {10}^{-15}\text{F}}\\ f_z=31.83\text{ GHz}\end{array}$

  

  $\begin{array}{c}\text{Gain at}{f}_H=20{\log }_{10}\left(\left|A_M\right|\right)\text{dB}\\ =20{\log }_{10}40\mathrm{dB}\\ =32.04\mathrm{dB}\end{array}$

  $\text{Gain at}{f}_t=0\mathrm{dB}$

  $\begin{array}{c}\text{Gain}\text{Magnitude}A(s)=-g_m{R}^{\text{'}}{}_L\left(\frac{1-s\left(\frac{C_{gd}}{g_m}\right)}{1+s\left(C_L+C_{gd}\right)R^{\text{'}}{}_L}\right)\\ \text{as}\text{}s\to \infty \\ \left|A\right|=\left(\frac{C_{gd}}{C_{gd}+C_L}\right)\\ =\left(\frac{10fF}{100+10fF}\right)\\ =\frac{1}{11}\end{array}$

  $\begin{array}{c}\text{Gain at}{f}_z=20{\log }_{10}\left(\left|A\right|\right)\mathrm{dB}\\ =20{\log }_{10}\left(\frac{1}{11}\right)\text{dB}\\ =-20.82\mathrm{dB}\end{array}$

  

Fig: Bode plot