Analog electronics circuits miscellaneous Easy Questions and Answers | Page - 54

Analog electronics circuits miscellaneous

Calculate the value of ν₀:

1. 6 V
1. – 6 V
1. –10 V
1. 10 V

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NA

Correct Option: C

NA

Calculate the value of A_νd = V₀
(V₁ – V₂)

1. 8
1. – 6
1. 6
1. – 8

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V_A = V₁
V_B = V₂
due to virtual ground. Let us assume that current I is flowing in the loop given below:
= V_A – V_B
2 kΩ

By applying KVL in the loop.
V_o – 6I – 2 I – 4 I = 0
or V_o = 12 I
V_o = 12. (V_A – V_B)
2

or V_o = 12 . (V₁ – V₂)
2

or V_o = 6 = A_vd
V₁ – V₂

Hence alternative (C) is the correct choice.

Correct Option: C

V_A = V₁
V_B = V₂
due to virtual ground. Let us assume that current I is flowing in the loop given below:
= V_A – V_B
2 kΩ

By applying KVL in the loop.
V_o – 6I – 2 I – 4 I = 0
or V_o = 12 I
V_o = 12. (V_A – V_B)
2

or V_o = 12 . (V₁ – V₂)
2

or V_o = 6 = A_vd
V₁ – V₂

Hence alternative (C) is the correct choice.

The approximate value of input impedance of a common emitter amplifier with emitter resistance Re is given by:

1. h_ie + A_l R_e
1. h_ie + (1 + h_fe) R_e
1. h_ie
1. (1 + h_fe) R_e

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NA

Correct Option: B

NA

Calculate V₀

1. – 7.5 V
1. 7.5 V
1. 8 V
1. – 8 V

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V_A = 2.5 V (due to virtual ground) By using potential divider method
V_A = V_o. 4
4 + 8

or 2.5 = V_o. 1
3

or V_o = 7.5

Correct Option: B

V_A = 2.5 V (due to virtual ground) By using potential divider method
V_A = V_o. 4
4 + 8

or 2.5 = V_o. 1
3

or V_o = 7.5

Find V₀

1. 4 V
1. – 4 V
1. 5 V
1. – 5 V

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V– = 5 V (due to virtual ground) apply KCL at node A
0.1 × 10^–3 = V_o – V_A
10 kΩ

or V_o = V_A – 0.1 × 10^–3 × 10 × 10³
V_o = 5 – 1 = 4 V

Correct Option: A

V– = 5 V (due to virtual ground) apply KCL at node A
0.1 × 10^–3 = V_o – V_A
10 kΩ

or V_o = V_A – 0.1 × 10^–3 × 10 × 10³
V_o = 5 – 1 = 4 V