CIRCUIT AND NETWORK THEORY
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Skilled in Odisha
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Course Overview
Schedule of Classes
Course Curriculum
1 Subject
CIRCUIT AND NETWORK THEORY
9 Exercises • 95 Learning Materials
UNIT 1 - MAGNETIC CIRCUITS
1.1 Definitions of magnetizing force, magnetic flux, permeability, reluctance
1.2 Develop the concept of Magnetic Circuit
1.3 Problems on simple Magnetic Circuits
1.4 Problems on magnetic circuits
1.5 Problems on simple magnetic circuits
1.6 Problems on simple magnetic circuits
1.7 Compare magnetic circuit and electric circuit
1.8 B-H curve
1.9 Hysteresis loop
1.10 Assessment
Exercise
1.11 FAQ
UNIT 2 - COUPLED CIRCUITS
2.1 Introduction to electromagnetic induction and Faraday's laws
2.2 Problems on induced e.m.f.
2.3 Dynamically and statically induced e.m.f
2.4 Problems on dynamically induced e.m.f
2.5 Lenz's law, Flemings right hand rule
2.6 Concept of self and mutual inductance
2.7 Expressions for self and mutual inductance
2.8 Problems on self and mutual inductance
2.9 Problems on self and mutual inductances
2.10 Co-efficient of coupling
2.11 Inductance
2.12 Assessment
Exercise
2.13 FAQ
UNIT 3 - CIRCUIT ELEMENTS AND ANALYSIS
3.1 Circuit concepts
3.2 Mesh analysis for D.C. excitation
3.3 Node analysis for D.C. and A.C. circuit
3.4 Super mesh and super node analysis
3.5 Constant voltage and current sources
3.6 Dependent and independent sources
3.7 Assessment
Exercise
3.8 FAQ
UNIT 4 - NETWORK THEOREMS
4.1 Circuit transformation
4.2 Problems on circuit transformation
4.3 Thevenin's theorem in sinusoidal excitation
4.4 Thevenin's theorem for D.C. excitation
4.5 Norton's theorem for sinusoidal excitation
4.6 Norton's theorem for D.C. excitation
4.7 Maximum power transfer theorem for sinusoidal excitation
4.8 Maximum power transfer theorem for D.C. excitation
4.9 Superposition theorem for sinusoidal excitation
4.10 Superposition theorem for D.C. excitation
4.11 Assessment
Exercise
4.12 FAQ
UNIT 5 - AC CIRCUIT AND RESONANCE
5.1 Introduction to A.C.
5.2 Definitions of alternating quantities
5.3 Concept of reactance, impedance, susceptance and admittance
5.4 Real and reactive power
5.5 Pure resistance in AC circuit
5.6 Pure inductance in A.C. Circuits
5.7 Pure capacitance in A.C. circuits
5.8 RL, RC and RLC series circuits
5.9 A.C. through RC parallel circuit
5.10 A.C. through RL parallel circuit
5.11 Parallel RLC circuit
5.12 Series resonance
5.13 Q-Factor and Magnification factor
5.14 Relation between resonance frequency and Half power frequency
5.15 Problems on series and parallel resonance circuit
5.16 Assessment
Exercise
5.17 FAQ
UNIT 6 - POLYPHASE CIRCUIT
6.1 Three phase system
6.2 Relation between line and phase values of balanced star connection
6.3 Relationship between line and phase values of balanced delta connection
6.4 Measurement of power in three phase system
6.5 Measurement of power by two wattmeter method
6.6 Power measurement in balanced and unbalanced load
6.7 Numerical problems on two wattmeter method
6.8 Numerical problems on two wattmeter method
6.9 Numerical problems on balanced three phase star connected system
6.10 Numerical problems on balanced three phase delta connected system
6.11 Assessment
Exercise
6.12 FAQ
UNIT 7 - TRANSIENTS
7.1 D.C. Transient response of R-L series circuit using differential equation
7.2 D.C. Transient response of R-C series circuit using differential equation
7.3 D.C. Transient response of R-L- C series circuit using differential equation
7.4 D.C. Transient response of R-L series circuit using Laplace equation
7.5 Problems based on D.C. Transient response of R-L series circuit using Laplace equation
7.6 D.C. Transient response of R-C series circuit using Laplace equation
7.7 Problems based on D.C. Transient response of R-C series circuit using Laplace equation
7.8 D.C. Transient response of R-L-C series circuit using laplace equation
7.9 Problems based on D.C. Transient response of R-L-C series circuit using laplace equation
7.10 Assessment
Exercise
7.11 FAQ
UNIT 8 - TWO-PORT NETWORK
8.1 Two port network Parameter
8.2 Transmission parameters
8.3 Hybrid parameters
8.4 Inter relationship of different parameter
8.5 Concept of transformed network
8.6 Two port network parameter using transformed variables
8.7 Assessment
Exercise
8.8 FAQ
UNIT 9 - FILTERS
9.1 Introduction to filters
9.2 Properties of symmetrical networks
9.3 Filter fundamentals
9.4 Constant K-Low Pass filter
9.5 Constant K-High Pass filter
9.6 m-derived T section filter and m-derived π section filter
9.7 Termination with m-derived half sections
9.8 Band pass filter
9.9 Band elimination filters
9.10 Illustrative problems
9.11 Assessment
Exercise
9.12 FAQ
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Skilled in Odisha
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