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Test: Signal Flow Graphs - 2 - Electrical Engineering (EE) MCQ


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10 Questions MCQ Test GATE Electrical Engineering (EE) Mock Test Series 2025 - Test: Signal Flow Graphs - 2

Test: Signal Flow Graphs - 2 for Electrical Engineering (EE) 2024 is part of GATE Electrical Engineering (EE) Mock Test Series 2025 preparation. The Test: Signal Flow Graphs - 2 questions and answers have been prepared according to the Electrical Engineering (EE) exam syllabus.The Test: Signal Flow Graphs - 2 MCQs are made for Electrical Engineering (EE) 2024 Exam. Find important definitions, questions, notes, meanings, examples, exercises, MCQs and online tests for Test: Signal Flow Graphs - 2 below.
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Test: Signal Flow Graphs - 2 - Question 1

Mason's rule is applied to

Detailed Solution for Test: Signal Flow Graphs - 2 - Question 1

Mason's rule or Mason’s gain formula is applied to signal flow graph for finding the transfer function.

Test: Signal Flow Graphs - 2 - Question 2

Assertion (A): Signal flow graph is applicable to the linear systems.
Reason (R): Signal flow graph method of finding the transfer function of a system is very simple and does not require any reduction technique.

Detailed Solution for Test: Signal Flow Graphs - 2 - Question 2

Signal flow graph is applicable to the linear systems because output is proportional to gain of the system

Reason (R) is also true but is not a correct explanation of assertion (A)

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Test: Signal Flow Graphs - 2 - Question 3

Consider the following three cases of signal flow graph and their corresponding transfer functions:

Q. Which of the above relations is/are correctly matched?

Detailed Solution for Test: Signal Flow Graphs - 2 - Question 3


Hence, only 1 is correctly matched.

Test: Signal Flow Graphs - 2 - Question 4

The signal flow graph shown below has M number of forward path and N number of individual loops.

Q. ​What are the values of M and N ?

Detailed Solution for Test: Signal Flow Graphs - 2 - Question 4

There are three forward paths. The gain of the forward path are:

  • M1 = G1G2G3G4G5
  • M2 = G1G6G4G5
  • M3 = G1G2G7

There are four loops with loop gains:
N1= - G4H1

N2= - G2G7H2

N3= - G6G4G5H2

N4= - G2G3G4G5H2

Test: Signal Flow Graphs - 2 - Question 5

The signal flow graph for a certain feedback control system is given below.

Now, consider the following set of equations for the nodes:

  1.  x2= a1x1+a5x3+a6x4+a7x5
  2. x3=a2x
  3. x4=a3x
  4. x5=a4x4+a8x3

Q. Which of the above equations are correct?

Detailed Solution for Test: Signal Flow Graphs - 2 - Question 5

Correct Answer :- b

Explanation : x2 = a1x1 + a5x3 + a6x4 + a7x5

x3 = a2x2

x4  a3x3 + a9x5

x5 = a4x4 + a8x3

Test: Signal Flow Graphs - 2 - Question 6

The gain C(s)/R(s) of the signal flow graph shown below is

Detailed Solution for Test: Signal Flow Graphs - 2 - Question 6

Gain of forward paths are:
P1 = G1G2G3 and P2 = G4
Here, Δ1 = 1
and Δ2 = (1 + G1G2— G2G3)
Individual loops are:
L1 = -G1G2
and L2 = G2G3
Non-touching loop = Nil

Test: Signal Flow Graphs - 2 - Question 7

The signal flow diagram of a system is shown in the given figure. The number of forward paths and the number of pairs of non-touching loops are respectively

Detailed Solution for Test: Signal Flow Graphs - 2 - Question 7

The forward paths are
— A B C D E F
— A B D E F
— A B E F i.e., 3
The loop B C B and D D are non-touching loop
Hence alternative (C) is the correct choice.

Test: Signal Flow Graphs - 2 - Question 8

The signal flow graph of the RLC circuit of figure (i) is shown in figure (ii)

The values of G1 and H1 are respectively 

Detailed Solution for Test: Signal Flow Graphs - 2 - Question 8

Converting the given circuit in s-domain and writing the equations, we get:

Also, from given SFG, we have

Test: Signal Flow Graphs - 2 - Question 9

The closed loop transfer function CIR for the signal graph shown below is

Detailed Solution for Test: Signal Flow Graphs - 2 - Question 9

Number of forward paths are two, 

Test: Signal Flow Graphs - 2 - Question 10

Consider the following statements with regards to the signal flow graph shown below.

1. The number of forward paths are 2.
2. The number of forward paths are  5.
3. The number of loops are 3.
4. The number of loops are 5,
5. The number of non-touching loop pairs is 1.
6. The number of non-touching loop pairs is nil.

Q. Which of these statements are correct?

Detailed Solution for Test: Signal Flow Graphs - 2 - Question 10

Explanation: Given signal flow graph properties:

  • Forward paths: Paths from input to output that do not revisit any node.
  • Loops: Closed paths that start and end at the same node.
  • Non-touching loop pairs: Sets of loops that do not share any common node.

Let's evaluate each statement:

  1. The number of forward paths are 2.

    • To verify the number of forward paths, we need to count distinct paths from input to output that do not revisit nodes.
    • By tracing in the graph, we can identify 2 such paths.

    Conclusion: This statement is correct.

  2. The number of forward paths are 5.

    • Given that we found 2 forward paths, this statement contradicts the first statement.

    Conclusion: This statement is incorrect.

  3. The number of loops are 3.

    • Loops are closed paths. Counting the distinct loops in the graph reveals 3 closed loops.

    Conclusion: This statement is correct.

  4. The number of loops are 5.

    • If there are only 3 loops, this statement is incorrect.

    Conclusion: This statement is incorrect.

  5. The number of non-touching loop pairs is 1.

    • Non-touching loop pairs are sets of loops that do not share any node.
    • Counting such pairs in the graph shows there is 1 pair.

    Conclusion: This statement is correct.

  6. The number of non-touching loop pairs is nil.

    • If we identified 1 non-touching loop pair, this statement contradicts that observation.

    Conclusion: This statement is incorrect.

Therefore, the correct answer is: a) 2, 3 and 5


     
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