Need solution for this CB BJT circuit

Let us first find the \$R_{IN}\$ for this circuit with the help of a T-model:

As you can see \$R_{IN} = \frac{V_X}{I_X}\$

But we can not say that \$R_{IN}\$ is equal to \$ (R_g||1/g_m)+R_s\$ because this ignores the fact that \$g_m V_{gs}\$ flows into \$1/g_m\$ "resistance".

This \$(R_g||1/g_m)+R_s\$ can only tell us the voltage across \$1/g_m\$ "resistor".

But this will be easier to see in \$\pi\$-model

^{simulate this circuit – Schematic created using CircuitLab}

Now we see that all the \$I_X\$ current is flowing thought \$R_G\$ resistor. And \$I_S = I_X + I_D\$

So let us try to find \$R_{IN} = \frac{V_X}{I_X}\$ by applying the Kirchhoff's voltage law at the input loop.

\$V_X = R_GI_X + (I_X + I_D)R_S = R_GI_X + (I_X + g_m V_{GS})R_S \$

What is \$V_{GS}\$ in this case?

Well I hope that you see that \$V_{GS} = I_X R_G\$ therefore,

\$V_X = R_GI_X + (I_X + g_m I_X R_G)R_S = I_X( R_G + R_S + g_m R_G R_S)\$

And finally

\$R_{IN} = \frac{V_X}{I_X} = R_G + R_S + g_m R_G R_S = R_G(1 +g_m R_S) + R_S\$

So for your circuit \$R_{IN} = 3 \cdot R_G + 2\textrm{k}\Omega\$

As a side note.

Notice that this multiplication factor (\$3\$) is equal to:

\$ \frac{1}{1 - A_V} \$

Where \$ A_V \$ is the voltage gain without \$R_G\$ resistor.

\$A_V = \frac{R_S}{R_S + \frac{1}{g_m}} = \frac{2\textrm{k}\Omega}{2\textrm{k}\Omega + \frac{1}{1\textrm{mS}}} = 0.66(6) \$

\$ \frac{1}{1 - 0.66(6)} = 3 \$

Thus, form the input voltage source (\$V_X\$) point of view, the \$R_G\$ resistor looks bigger by a factor of \$ \frac{1}{1 - A_V} \$ And this is what we sometimes call a bootstrapping because we have a positive feedback here.

As for the output resistance \$R_{OUT}\$ you need to solve this circuit:

^{simulate this circuit}

\$I_X = \frac{V_X}{R_G} + \frac{V_X}{R_S} - g_m (0V - V_X) = \frac{V_X}{R_G} + \frac{V_X}{R_S} + g_m V_X = V_X(g_m + \frac{1}{R_G} +\frac{1}{R_S} ) \$

\$I_X = V_X(g_m + \frac{1}{R_G} +\frac{1}{R_S}) = V_X (\frac{g_m R_G R_S}{R_G R_S}+ \frac{R_S}{R_G R_S} + \frac{R_G}{R_G R_S}) =V_X \left(\frac{g_m R_G R_S + R_S + R_G}{R_G R_S}\right) \$

I hope that you see why \$R_4\$ do not appears in this equation. The situation will look completely different if you would add \$ ro = \frac {1}{\lambda I_D}\$ resistor (channel length modulation effect).

\$ V_X = \frac{I_X R_G R_S}{R_G + R_S + g_m R_G R_S}\$

therefore

\$R_{OUT} = \Large \frac{R_G R_S}{R_G(1 +g_m R_S) + R_S}\$

Some guidance only for homeworks:

Early effect (=the effective width of the base shrinks as reverse Vcb increases) can be seen as current gain increase as Vcb (and Vce) increases. That can be seen as AC conductance between C and E. If you have the curves Ic vs Vce at different base currents you see how Ic grows as Vce increases. As a simplest linearization you can insert in gain calculations to the AC model a leakakge resistor Va/Ic between C and E, where Va is the Early voltage and Ic is the operating point collector current.

I guess you are expected to use a large signal model and derive by yourself the linearized equations because you have the needed parameters such as VT and Is. Hopefully you can calculate partial derivatives to derive the linearized quantities such as Gm.

Here's a small screenshot taken from Early effect article in Wikipedia:

Gm is the partial derivative of Ic when the variable is Vbe. You must calculate the numerical value in the operating point.