Elecrical Circuit Theory and Networks

Submitted by tushar pramanick on Mon, 08/15/2011 - 15:45

Contents

 

1.     Basic Circuit Elements and Waveforms
  1.1   Circuit Components
  1.2   Definitions of Electrical Circuits
  1.3   Conservation of Energy
  1.4   Source of Electrical Energy
  1.5   Standard Input Signals
  1.6   Sinusoidal Signal
       
2.     Mesh and Node Analysis
  2.1   Kirchhoff's Laws
  2.2   Source Transformation
  2.3   Mesh and Node Analysis
  2.4   Network Equations for RLC Network
  2.5   Magnetic Coupling
       
3.     Graph Theory and Network Equation
  3.1   Incidence Matrix
  3.2   Cut-Set Matrix
  3.3   Tie-Set Matrix and Loop Currents
  3.4   Trees of a Graph
  3.5   Analysis of Networks
  3.6   Network Equilibrium Equation
  3.7   Duality
  3.8   General Network Transformations
       
4.     Fourier Series
  4.1   Trigonometric Fourier Series
  4.2   Evaluation of Fourier Coefficients
  4.3   Waveform Symmetry
  4.4   Fourier Series in Optimal Sense
  4.5   Exponential Form of Fourier Series
  4.6   Fourier Transform
       
5.     The Laplace Transform
  5.1   Laplace Transformation
  5.2   Some Basic Theorems
  5.3   Gate Function
  5.4   Impulse Function
  5.5   Laplace Transform of Periodic Functions
       
6.     Application Laplace Transform
  6.1   Solution of Linear Differential Equation
  6.2   Heaviside's Partial Fraction Expansion
  6.3   Kirchhoff's Laws
  6.4   Solution of Network Problems
       
7.     Network Theorems
  7.1   Superposition Theorem
  7.2   Reciprocity Theorem
  7.3   Thevenin's Theorem
  7.4   Norton's Theorem
  7.5   Millman's Theorem
  7.6   Maximum Power Transfer Theorem
  7.7   Substitution Theorem
  7.8   Compensation Theorem
  7.9   Tellegen's Theorem
       
8.     Resonance
  8.1   Series Resonance
  8.2   Parallel Resonance
       
9.     Analogous System
  9.1   Mechanical Elements
  9.2   D'Alembert's Principle
  9.3   Force-Voltage Analogy
  9.4   Force-Current Analogy
  9.5   Mechanical Couplings
  9.6   Electro-Mechanical System
  9.7   Liquid-Level System
       
10.     Two-Port Network
  10.1   Characterization of Linear Time-Invariant Two-Port Networks
  10.2   Open-Circuit Impedance Parameters
  10.3   Short-Circuit Admittance Parameters
  10.4   Transmission Parameters
  10.5   Inverse Transmission Parameters
  10.6   Hybrid Parameters
  10.7   Inverse Hybrid Parameters
  10.8   Interrelationships between the Parameters
  10.9   Interconnection of Two-Port Networks
  10.10   Two-Port Symmetry
  10.11   Input Impedance in terms of Two-Port Parameters
  10.12   Output Impedance
  10.13   Image Impedance
  10.14   Transistors as Two-Port Active Network
  10.15   Network Components
       
11.     Attenuators
  11.1   Nepers, Decibels
  11.2   Lattice Attenuator
  11.3   T-Type Attenuator
  11.4   π-Type Attenuator
  11.5   L-Type |ittenuator
  11.6   Ladder type Attenuator
  11.7   Balanced Attenuators
  11.8   Insertion Loss
       
12.     Conventional Filters
  12.1   Image Impedance
  12.2   Hyperbolic Trigonometry
  12.3   Propagation Constant
  12.4   Properties of Symmetrical Network
  12.5   Filter Fundamentals
       
13.     Convolution Integral
  13.1   Graphical Convolution
       
14.     State Variable Analysis
  14.1   Transfer Function
  14.2   State Transition Matrix
15.     Network Functions
  15.1   Poles and Zeros
  15.2   Transient Responses
       
16.     Passive Network Synthesis
  16.1   Driving Point and Transfer Impedence Function
  16.2   LC Network
  16.3   Two Terminal R-L and R-C Network
       
17.     Feedback System
  17.1   Block Diagram Representation
  17.2   Signal Flow Graph
  17.3   Routh-Hurwitz Stability Criterion
       

 

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