Multiple Op-Amp MCQ [Free PDF] - Objective Question Answer for Multiple Op-Amp Quiz

11. The characteristics of a non-inverting amplifier are identical to

A. Differential Amplifier with one op-amp
B. Differential Amplifier with two op-amp
C. Differential Amplifier with three op-amp
D. None of the mentioned

Answer: B

The characteristics of a non-inverting amplifier are identical to the differential amplifier with two op-amps as the gain of the amplifier are same. i.e. A = 1+(R_F /R₁).

12. How is it possible to vary the voltage from the closed-loop gain to the open-loop gain?

A. By using a differential amplifier with a larger gain
B. By using a differential amplifier with a small gain
C. By using a differential amplifier with variable gain
D. By using a differential amplifier with differential gain

Answer: C

The variable gain in the differential amplifier can be obtained by using a potentiometer. So, depending on the position of the wiper in the potentiometer, voltage gain can be varied from the closed-loop gain to the open-loop gain.

13. A differential amplifier with two op-amps has the following specifications:
R₁=R₃=1.5kΩ ; R_F=R₂=5.7kΩ. Compute the input resistance for the following circuit.

A. R_IFx = 83GΩ, R_IFy = 317GΩ
B. R_IFx = 90GΩ, R_IFy = 400GΩ
C. R_IFx = 59GΩ, R_IFy = 269GΩ
D. R_IFx = 36GΩ, R_IFy = 156GΩ

Answer: A

The input resistance of the first stage is given as R_IFy,

=> R_IFy = R_i*[1+(A *R₂)/( R₂+ R₃)]

= R_IFy = 2MΩ*[(1+200000*5.7kΩ)/(5.7kΩ+1.5kΩ)]

= 3.166*10¹¹ = 317GΩ.

Similarly the input resistance of the second stage amplifier is given as R_IFx,

=> R_IFx = R_i*[1+(A *R₁)/( R₁+ R_F)]

= R_IFx = 2MΩ*[(1+200000*1.5kΩ)/(5.7kΩ+1.5kΩ)] = 83GΩ.

14. Determine the output voltage from the diagram. Where V₁=-4.3Vpp and V₂ = -5.1Vpp sinewave at 1000hz.

A. 12 Vpp sinewave at 1000hz
B. 13.3 Vpp sinewave at 1000hz
C. 14 Vpp sinewave at 1000hz
D. 11 Vpp sinewave at 1000hz

Answer: B

In differential amplifier with two op-amps, R₁=R₃ and R_F=R₂.

The closed loop voltage gain, A_D = 1+( R_F/ R₁) = 1+(7.5kΩ/480Ω) = 16.62.

Output voltage , V_o = A_D(V₁– V₂) = 16.62(-4.3Vpp+5.1Vpp) = 13.29 =13.3 Vpp sinewave at 1000hz.

15. Determine the output resistance of the differential amplifier with three op-amps. The op-amp used is 741c, with A=200000 and R_o. The output and difference of input voltages are 44 and 11.

A. 5.5mΩ
B. 3.5mΩ
C. 2.4mΩ
D. 1.5mΩ

Answer: D

Gain A_D = V_o/V_id = 44/11 =4.

The output resistance of differential amplifier is given as

R_OF=R_o/[1+(A/AD)]

= 75/[1+(200000/4)] = 1.5mΩ.

16. Find the input resistance for the given circuit

A. R_IF = R_i*[1+(A*R₄+R₅)/(2* R₄+R₅)].
B. R_IF = R_i*[1+(A*R₄)/(2* R₄+R₅)].
C. R_IF = R_i*[1+(A*R₄+R₅)/(R₄+R₅)].
D. None of the mentioned

Answer: A

The input resistance of the op-amp with feedback is given as R_IF= R_i*(1+AB.

From the diagram, B=V_f/V_o = [R₄+R₅)/(2* R₄+R₅)].

Therefore, R_IF = R_i*[1+(A*R₄+R₅)/(2* R₄+R₅)].

17. The bandwidth of the differential amplifier increases, if the value of

A. Open loop voltage gain decreases
B. Closed-loop voltage gain decreases
C. Differential voltage gain decreases
D. All of the mentioned

Answer: B

The bandwidth of the differential amplifier is inversely proportional to the closed-loop voltage gain.

18. Calculate the bandwidth for the given circuit. (Where the 741 op-amp has a gain of 200000).

A. 560hz
B. 390khz
C. 25.6khz
D. 1.5Mhz

Answer: C

Gain of the amplifier

A_D = -{[1+(2*R₄/R₅)]*(R_F/R₁)}

= -{[1+(2*5kΩ/2.5kΩ)]*(3.9kΩ/500Ω)} (since, R_F = R₃ and R₂ = R₁).

=> A_D = -5*7.8=-39.

The bandwidth for the circuit is calculated as

f_F = (A*f_o)/A_D

= (200000*5hz)/39

(For 741 op-amp 5hz is the break frequency)

=> f_F = 25.6khz.

19. Calculate the output voltage. If V_x=3.9Vpp and V_y = 5.5 Vpp sinewave at 1khz for the following circuit.

A. 11 Vpp sinewave at 1Khz
B. -8Vpp Vpp sinewave at 1Khz
C. -10 Vpp sinewave at 1Khz
D. 6 Vpp sinewave at 1Khz

Answer: B

Voltage gain, A_D=-R_F/ R₁

= -15kΩ/3kΩ = -5kΩ.

The output voltage, V_o = – A_D*(V _x– V _y)

= 5*(3.9-5.5) = -8 Vpp sinewvae at 1Khz.

20. Miniaturization of components with superior performance can be obtained in

A. Integrated circuits
B. Discrete circuits
C. Both integrated and discrete circuits
D. None of the mentioned

Answer: A

All the components in integrated circuits are fabricated on the same chip, whereas in discrete circuits discrete components are used and occupy more area.

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