Electronics and Communication Engineering (ECE) Exam  >  Electronics and Communication Engineering (ECE) Tests  >  Test: MOSFET Amplifier with CG Configuration - Electronics and Communication Engineering (ECE) MCQ

Test: MOSFET Amplifier with CG Configuration - Electronics and Communication Engineering (ECE) MCQ


Test Description

15 Questions MCQ Test - Test: MOSFET Amplifier with CG Configuration

Test: MOSFET Amplifier with CG Configuration for Electronics and Communication Engineering (ECE) 2024 is part of Electronics and Communication Engineering (ECE) preparation. The Test: MOSFET Amplifier with CG Configuration questions and answers have been prepared according to the Electronics and Communication Engineering (ECE) exam syllabus.The Test: MOSFET Amplifier with CG Configuration MCQs are made for Electronics and Communication Engineering (ECE) 2024 Exam. Find important definitions, questions, notes, meanings, examples, exercises, MCQs and online tests for Test: MOSFET Amplifier with CG Configuration below.
Solutions of Test: MOSFET Amplifier with CG Configuration questions in English are available as part of our course for Electronics and Communication Engineering (ECE) & Test: MOSFET Amplifier with CG Configuration solutions in Hindi for Electronics and Communication Engineering (ECE) course. Download more important topics, notes, lectures and mock test series for Electronics and Communication Engineering (ECE) Exam by signing up for free. Attempt Test: MOSFET Amplifier with CG Configuration | 15 questions in 45 minutes | Mock test for Electronics and Communication Engineering (ECE) preparation | Free important questions MCQ to study for Electronics and Communication Engineering (ECE) Exam | Download free PDF with solutions
Test: MOSFET Amplifier with CG Configuration - Question 1

In the following circuit, what is the voltage at the source of the M1?

Detailed Solution for Test: MOSFET Amplifier with CG Configuration - Question 1

The impedance looking into the source of M1 is 1/gm. Vin experiences a potential divider before entering the source of M1. The voltage drop across Rs is typically the voltage at the source and hence, it is equal to Vin * Rs / (Rs + 1/gm).

Test: MOSFET Amplifier with CG Configuration - Question 2

If Channel Length modulation is neglected, what is the voltage gain from the source to the drain for the CG stage shown below?

Detailed Solution for Test: MOSFET Amplifier with CG Configuration - Question 2

The voltage gain from the source of M1 to the drain of M1 can be found out from a small signal analysis and it’ll turn out to be gm * Rd. But the input voltage is a result of the potential divider between Rs and 1/gm. Hence, the overall voltage gain is gm * Rd * {Rs/ (Rs + 1/gm)}.

1 Crore+ students have signed up on EduRev. Have you? Download the App
Test: MOSFET Amplifier with CG Configuration - Question 3

If channel length modulation is neglected, what is the voltage gain for the following circuit from source to drain?

Detailed Solution for Test: MOSFET Amplifier with CG Configuration - Question 3

In absence of channel length modulation, ro = 0. The gain is simply gm * Rd. It should be noted that the CG stage doesn’t invert and hence the voltage gain is not -gm * Rd.

Test: MOSFET Amplifier with CG Configuration - Question 4

If channel length modulation is neglected, what is the voltage gain for the following CG stage?

Detailed Solution for Test: MOSFET Amplifier with CG Configuration - Question 4

The above circuit is quite similar to the CS stage with degeneration. But the CG stage doesn’t invert and after performing a small signal analysis, the voltage gain comes out to be Rd/(1/gm + Rs).

Test: MOSFET Amplifier with CG Configuration - Question 5

The current gain of a simple CG stage is approximate _______

Detailed Solution for Test: MOSFET Amplifier with CG Configuration - Question 5

The input to a CS stage is at the source of M1. This current simply flows into the channel and flows out of M1. Approximately, we can say that the overall current gain is unity since the gain contributes very low current.

Test: MOSFET Amplifier with CG Configuration - Question 6

If channel length modulation is neglected, what is the voltage gain of the following circuit?

Detailed Solution for Test: MOSFET Amplifier with CG Configuration - Question 6

This is a cascade of a CG stage preceding a CS stage. For the CG stage, the voltage gain is gm * Rd. But after this stage, the signal gets amplified by the CS stage with a factor of –(gm2* Rd1). Hence, the overall voltage gain is the product of both the factors ie –(gm1 * Rd * gm2 * Rd1). Note that since channel length modulation is absent, ro is not present in the expression of gain.

Test: MOSFET Amplifier with CG Configuration - Question 7

If channel length modulation is neglected, what is the voltage gain for the following circuit?

Detailed Solution for Test: MOSFET Amplifier with CG Configuration - Question 7

This is a cascade of a CG stage preceding a CS stage. For the CG stage, the voltage gain is gm * Rd. But after this stage, the signal gets amplified by a degenerated CS stage with a factor of -Rd / (1/gm2 + Rs). Hence, the overall voltage gain is the product of both the factors i.e. – {gm1 * Rd * Rd / (1/gm2 + Rs)}. Note that the input impedance looking into M2 is infinite ad hence the voltage gain of the C.G. stage remains unaffected by the C.S. stage (for low frequency operations only).

Test: MOSFET Amplifier with CG Configuration - Question 8

If channel length modulation is neglected, what is the voltage gain of the following circuit?

Detailed Solution for Test: MOSFET Amplifier with CG Configuration - Question 8

The impedance looking into the source of M1 is 1/gm1. Hence, the product of this times the transconductance of M2 will be the overall voltage gain i.e. gm2/gm1. Note that the gain is function of only the intrinsic parameters of the MOSFET and independent of other parameters.

Test: MOSFET Amplifier with CG Configuration - Question 9

What is the input impedance of the following CG stage?

Detailed Solution for Test: MOSFET Amplifier with CG Configuration - Question 9

The input impedance can be calculated by performing a small signal analysis at the input node. We need to set Vg and Vdd to 0V and apply a small input voltage at the source. Now, the impedance looking into the source is 1/gm and Rs is parallel to this impedance. Hence, the total input impedance is Rs || 1/gm.

Test: MOSFET Amplifier with CG Configuration - Question 10

What is the input impedance for the following circuit?

Detailed Solution for Test: MOSFET Amplifier with CG Configuration - Question 10

The input to the CG stage is placed at the source of M1. The impedance looking into the node of M1 is simply 1/gm. Hence, the input impedance is 1/gm. Rd || ro is the output impedance if channel length modulation is present.

Test: MOSFET Amplifier with CG Configuration - Question 11

If channel length modulation is present, what is the output impedance of the following circuit?

Detailed Solution for Test: MOSFET Amplifier with CG Configuration - Question 11

In presence of channel length modulation, ro appears to be in parallel to Rd. Hence, the total output impedance becomes Rd || ro. In the absence of channel length modulation, the output impedance is Rd only.

Test: MOSFET Amplifier with CG Configuration - Question 12

If channel length modulation is present. what is the overall output impedance of the following CG stage?

Detailed Solution for Test: MOSFET Amplifier with CG Configuration - Question 12

The impedance looking into the drain of M1 would be similar to that of a CS stage with source degeneration. That implies the impedance is Rs*(1+gm * ro) + ro. But this impedance is parallel to Rd. Hence, the overall output impedance becomes Rd || {Rs*(1+gm* ro) + ro}.

Test: MOSFET Amplifier with CG Configuration - Question 13

The voltage gain of a simple CG stage is greater than that of a follower.

Detailed Solution for Test: MOSFET Amplifier with CG Configuration - Question 13

The voltage gain of a follower is always less than that of a CG stage. This can be proven by a small signal analysis that the voltage gain for a follower is Rs/(1/gm + Rs) while that of the CG stage is gm * Rd. Hence the above statement is true.

Test: MOSFET Amplifier with CG Configuration - Question 14

If channel length modulation is present, what is the voltage gain of the following circuit?

Detailed Solution for Test: MOSFET Amplifier with CG Configuration - Question 14

This is a cascade of a CG stage preceding a CS stage. For the CG stage, the voltage gain is gm * (Rd || ro1). But after this stage, the signal gets amplified by the CS stage with a factor of – {gm2 * (Rd1 || ro2)}. Hence, the overall voltage gain is the product of both the factors i.e. – {gm1 * (Rd || ro1) * gm2 * (Rd1 || ro2)}. Note that the input impedance looking into M2 is infinite ad hence the voltage gain of the CG stage is typically unaffected by the CS stage (for low frequency operations only).

Test: MOSFET Amplifier with CG Configuration - Question 15

If channel length modulation is neglected, what is the overall voltage gain of the following circuit?

Detailed Solution for Test: MOSFET Amplifier with CG Configuration - Question 15

This is a cascade of CS stage preceding a CG stage. The voltage gain of the first stage is – (gm1 * Rd || 1/gm2). This is because the drain of M1 is connected to the source of M2 and the impedance looking into the source of M2 is 1/gm2. Now, the source of the CG stage is connected to Rd and hence the voltage gain due to this stage is affected by source degeneration and the voltage gain is Rd1/ (1/gm2 + Rd). The overall voltage gain is – {gm1 * (Rd || 1/gm2) * (Rd1/ (1/gm2 + Rd))}.

Information about Test: MOSFET Amplifier with CG Configuration Page
In this test you can find the Exam questions for Test: MOSFET Amplifier with CG Configuration solved & explained in the simplest way possible. Besides giving Questions and answers for Test: MOSFET Amplifier with CG Configuration, EduRev gives you an ample number of Online tests for practice

Top Courses for Electronics and Communication Engineering (ECE)

Download as PDF

Top Courses for Electronics and Communication Engineering (ECE)