EEE/ETI 1202
CIRCUITS & NETWORK THEORY I
LECTURE 1
, Course Road Map
• Basic Concepts and definitions
• Electric current, voltage, power and energy
• Analysis of Simple circuits
• Ohms Laws, Resistance variation, KCL, KVL,
• Analysis of series and parallel circuits, voltage and current division.
• Nodal and Mesh analysis, source transformation, Star- Delta connection of
resistors.
• Circuit Theorems:
• Thevenin’s Theorem
• Norton’s Theorem
• Maximum Power Transfer Theorem
• Superposition Theorem
• Magnetic Circuits and Electric Field Circuits
,• Inductance & Capacitance
• Energy storage devices, inductance, power and energy in an inductor, combination of ser
and parallel inductors. RL- transients
• Capacitance, power and energy in a capacitor, combination of series and parallel capacito
RC- transients
• Sinusoidal circuit analysis: analysis of RLC circuits (series and parallel ac circuit
Application of Vector and complex numbers in a.c circuits analysis
• Two port systems
• Three phase circuit analysis
Sources
1. D. E. Scott, An Introduction to circuit analysis: A system approach, New York, McGraw-Hill
2. E. Hughes, Electrical and Electronic Technology, Prentice Hall
3. U.A. Bakshi and V.U. Bakshi, Basic Engineering, Technical Publications Pune,
4. V. K. Mehta, Rohit Mehta - Basic Electrical Engineering-S Chand (2017)
, Introduction
• Circuit analysis is the foundation for any aspect of electrical technology.
• An electric circuit or electric network is an interconnection of electric
elements linked together in a closed path so that an electric current ma
continuously flow.
• Alternatively, an electric circuit is essentially a pipe-line that facilitates th
transfer of charge from one point to another.
• Need to understand the elements that makes an electric circuit.
CIRCUITS & NETWORK THEORY I
LECTURE 1
, Course Road Map
• Basic Concepts and definitions
• Electric current, voltage, power and energy
• Analysis of Simple circuits
• Ohms Laws, Resistance variation, KCL, KVL,
• Analysis of series and parallel circuits, voltage and current division.
• Nodal and Mesh analysis, source transformation, Star- Delta connection of
resistors.
• Circuit Theorems:
• Thevenin’s Theorem
• Norton’s Theorem
• Maximum Power Transfer Theorem
• Superposition Theorem
• Magnetic Circuits and Electric Field Circuits
,• Inductance & Capacitance
• Energy storage devices, inductance, power and energy in an inductor, combination of ser
and parallel inductors. RL- transients
• Capacitance, power and energy in a capacitor, combination of series and parallel capacito
RC- transients
• Sinusoidal circuit analysis: analysis of RLC circuits (series and parallel ac circuit
Application of Vector and complex numbers in a.c circuits analysis
• Two port systems
• Three phase circuit analysis
Sources
1. D. E. Scott, An Introduction to circuit analysis: A system approach, New York, McGraw-Hill
2. E. Hughes, Electrical and Electronic Technology, Prentice Hall
3. U.A. Bakshi and V.U. Bakshi, Basic Engineering, Technical Publications Pune,
4. V. K. Mehta, Rohit Mehta - Basic Electrical Engineering-S Chand (2017)
, Introduction
• Circuit analysis is the foundation for any aspect of electrical technology.
• An electric circuit or electric network is an interconnection of electric
elements linked together in a closed path so that an electric current ma
continuously flow.
• Alternatively, an electric circuit is essentially a pipe-line that facilitates th
transfer of charge from one point to another.
• Need to understand the elements that makes an electric circuit.
