The magnitude of the current gain and the relationship between R F , R E 2 and current gain using computer simulation.

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Answer 1

Question

Chapter 12, Problem 12.8TYU

To determine

The magnitude of the current gain and the relationship between RF, RE2 and current gain using computer simulation.

Expert Solution & Answer

Answer to Problem 12.8TYU

The relation between the current gain with the change in resistance RF and RE2 is depicted by the expression Ai={RFCgm1+AC[AB−1RF]−RFB}−1gm2[(RC2+RLRC2)]{{(1rπ2+gm2)+DAC+gm1}[(AB)−1RF]} and the plot for the relation is shown in Figure 6.

Explanation of Solution

Given:

The given diagram is shown in Figure 1

MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL), Chapter 12, Problem 12.8TYU , additional homework tip 1

Figure 1

Calculation:

Mark the nodes and redraw the circuit.

The given diagram is shown in Figure 2

MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL), Chapter 12, Problem 12.8TYU , additional homework tip 2

Figure 2

Mark the values and draw the PSpice circuit for the above circuit.

The required circuit is shown in Figure 3

MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL), Chapter 12, Problem 12.8TYU , additional homework tip 3

Figure 3

The snip for the drop box of the internal parameters of the transistor is shown in Figure 4

MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL), Chapter 12, Problem 12.8TYU , additional homework tip 4

Figure 4

The simulation settings to estimate the magnitude of the current gain as the value of RE2 is varied between 0.4 kΩ and 1.6 kΩ is shown in Figure 5

MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL), Chapter 12, Problem 12.8TYU , additional homework tip 5

Figure 5

Then left click on the trace option then select add trace and type “ABS(l(RL)L(li))” then command in the trace magnitude of the current gain as the emitter resistance varies between 0.4 kΩ and 1.6 kΩ . the required relation is shown in Figure 6

MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL), Chapter 12, Problem 12.8TYU , additional homework tip 6

Figure 6

By KCL the expression for the current Ii is given by,

Ii=Vπ1Rs||RB1||rπ1+Vπ1−Ve2RFVe2=Vπ1(RFRs||RB1||rπ1||RF)−IiRF

The expression for the node voltage is given by,

VC1=Vπ2+Ve2

Apply KCL at node VC1 .

gm1Vπ1+VC1RC1||RB2+Vπ2rπ2=0gm1Vπ1+Vπ2+Ve2RC1||RB2+Vπ2rπ2=0gm1Vπ1+Vπ2(1RC1||RB2||rπ2)+Ve2RC12||RB2=0

Substitute Vπ1(RFRs||RB1||rπ1||RF)−IiRF for Ve2 in the above equation.

gm1Vπ1+Vπ2(1RC1||RB2||rπ2)+1RC12||RB2[Vπ1(RFRs||RB1||rπ1||RF)−IiRF]=0Vπ1=IiRF(1RC12||RB2)−Vπ2(1RC||RB2||rπ2)gm1+[(RFRs||RB1||rπ1||RF)(1RC12||RB2)]

The expression for the output current is given by,

IO=−(gm2Vπ2)(RC2RC2+RL)Vπ2=−IOgm2(RC2+RLRC2)

Apply KCL at node Ve2 .

Vπ2rπ2+gm2Vπ2=Ve2RE2+Ve2−Vπ1RF(1rπ2+gm2)Vπ2+Vπ1RF=(1RE2+1RF)Ve2

Substitute Vπ1(RFRs||RB1||rπ1||RF)−IiRF for Ve2 in the above equation.

(1rπ2+gm2)Vπ2+Vπ1RF=(1RE2+1RF)(Vπ1(RFRs||RB1||rπ1||RF)−IiRF)(1rπ2+gm2)Vπ2+IiRF(1RE2+1RF)=Vπ1{[(RFRs||RB1||rπ1||RF)(1RE2+1RF)]−1RF}

Substitute IiRF(1RC12||RB2)−Vπ2(1RC||RB2||rπ2)gm1+[(RFRs||RB1||rπ1||RF)(1RC12||RB2)] for Vπ1 in the above equation.

[(1rπ2+gm2)Vπ2+IiRF(1RE2+1RF)]=[IiRF(1RC1||RB2)−Vπ2(1RC||RB2||rπ2)][gm1+[(RFRs||RB1||rπ1||RF)(1RC12||RB2)]]{[(RFRs||RB1||rπ1||RF)(1RE2+1RF)]−1RF}

Consider A=RFRs||RB1||rπ1||RF , B=1RE2+1RF , C=1RC1||RB2 and D=1RC1||RB2||rπ2 in the above equation. So the equation is,

[ ( 1 r π2 + g m2 ) V π2 + I i R F B ]= [ I i R F C− V π2 D ] [ g m1 +AC ] { AB− 1 R F }

V π2 { ( 1 r π2 + g m2 )+ D g m1 +AC [ AB− 1 R F ] }= I i { R F C g m1 +AC [ AB− 1 R F ]− R F B }

[ − I O g m2 ( R C2 + R L R C2 ) ]{ ( 1 r π2 + g m2 )+ D g m1 +AC [ AB− 1 R F ] }= I i { R F C g m1 +AC [ AB− 1 R F ]− R FB B }

I O I i = { R F C g m1 +AC [ AB− 1 R F ]− R F B } −1 g m2 [ ( R C2 + R L R C2 ) ]{ { ( 1 r π2 + g m2 )+ D AC+ g m1 }[ ( AB )− 1 R F ] }

Thus, the expression for the small signal current gain is,

Ai={RFCgm1+AC[AB−1RF]−RFB}−1gm2[(RC2+RLRC2)]{{(1rπ2+gm2)+DAC+gm1}[(AB)−1RF]}

Conclusion:

Therefore, the relation between the current gain with the change in resistance RF and RE2 is depicted by the expression Ai={RFCgm1+AC[AB−1RF]−RFB}−1gm2[(RC2+RLRC2)]{{(1rπ2+gm2)+DAC+gm1}[(AB)−1RF]} and the plot for the relation is shown in Figure 6

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