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Question Bank IA 1

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8 views7 pages

Question Bank IA 1

Uploaded by

nathiyagoutham
Copyright
© © All Rights Reserved
We take content rights seriously. If you suspect this is your content, claim it here.
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Download as PDF, TXT or read online on Scribd
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State Ohms Law and give its limitations.

Find the equivalent resistance of the circuit.

Define ideal voltage and ideal current source. Draw its characteristic curve.
Mesh current method is based on KCL and node voltage method is based on KVL- True or False.
Justify
Distinguish between Mesh and Loop of an electric circuit.
State Thévenin’s theorem. Draw its equivalent circuit.
Write the required expression to transform the circuit from Delta to a star.
Give the condition when Maximum Power transfers in the circuit.
Write the Linearity Properties.
Define Impedance, conductance and susceptance.
What is admittance? What are its components?
State KCL and KVL.
Define voltage, current and power.
A 3A current source has internal resistance of 2Ω. Find the voltage experienced by a load of 3Ω
while connected to the load.
What are the limitations of maximum power transfer theorem?
State Thevenin’s theorem.
Write about Network Reduction Technique.
Draw the equivalent delta circuit shown in below figure.

The sine and cosine are essentially the same function, but with a 90° phase difference. Justify?
What is natural response and forced response?
Determine the current through the 2ohm resistance.

Give the voltage division rule and current division rule.


State Kirchhoff’s current Law.
Give the formula for finding equivalent resistance when R1 and R2 are connected in Series and
Parallel.
What are the limitations of maximum power transfer theorem?
Define dual networks. List out four pairs of dual quantities.
Recall the statement of Norton’s theorem.
Write the required expression to transform the circuit from star to a Delta.
Compare Time-Domain and Frequency-Domain Voltage–Current expressions.
Define phasor transformation.
Calculate the value of Voltages V1, V2 and V3 by using Nodal Analysis CO1 BTL-3 16
Method.

Determine the voltages in each branch by Nodal method. CO1 BTL-3 16

For the network shown below, obtain the currents i1, i2, i3 using Mesh CO1 BTL-3 16
analysis.

Determine the various branch currents and power in each resistor for CO1 BTL-3 16
the given circuit using mesh analysis.

13.(a) Compute the current in 23Ω resistor of the following figure, by applying CO2 BTL-3 16
the superposition principle.
13.(b) CO2 BTL-3 16

Find the voltage drop across 12ohm resistor using Norton’s theorem.
14.(a) Find the Thevenin’s equivalent for the circuit given below. CO2 BTL-3 16

Find the value of RL at which maximum power is transferred to RL. CO2 BTL-3 16
Also find the maximum power delivered.

Derive the forced response of the series RL circuit. CO3 BTL-3 16

For the network shown below, obtain the current ratio (I1/I2) using CO3 BTL-3 16
mesh analysis where v1= 10<0 degree

For the network shown below, obtain the currents i1, i2, i3 using Mesh
analysis.
Determine the mesh current for the given circuit.

Determine the nodal voltages for the circuit given below.

For the given circuit, compute the voltage across each current source.

For the given circuit find the current through 10ohm resistance using
Thevenin’s theorem.

Calculate the current in 4ohm resistance using Superposition theorem.


For the circuit given, what value of RL will ensure that it absorbs the
maximum possible amount of power? Find its maximum power.

Using Mesh analysis find the mesh currents.

Determine the equivalent impedance of the network shown in Figure


given an operating frequency of 5 rad/s.

15.(b) Employ nodal analysis to determine the two nodal voltages v1 (t) and
v2 (t).

Determine the current ix for the given circuit using nodal analysis.

Determine the nodal voltages for the Fig, making use of the super-node
technique as appropriate.
Calculate the power dissipated by each resistor in the circuit given.

Determine values for the three mesh currents for the given circuit.

Using superposition to consider each source one at a time, compute ix


and determine the percentage of ix arising from each source.

Determine the Thévenin’s equivalent of the circuit and find the load
current if is connected to 4.7Ω resistor to the open terminals.

Evaluate the three unknown currents in the circuit of Figure.


Find the value of RL for maximum power transfer. Also calculate the
maximum power.

Use nodal analyses find V1 and V2.

In the circuit of the figure shown below, find the values of V1 and V2
by nodal analysis.

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