Network Circuits Analysis

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About Course

The Network Circuits Analysis course begins with a description of circuit elements, sources.

Understanding of various interesting network theorems applied to solve linear, time-invariant network problems efficiently in time and s-domain. The steady and transient solution of network problems with various sources including impulse source,?(t). Representing a circuit in the s-domain (Laplace domain).Two-port networks. Graph, tree of networks and use them to solve large network problems using matrices.

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What Will You Learn?

  • learn the fundamentals of Network Analysis

Course Content

Network Analysis

  • Network Analysis
    00:00
  • Lecture 01: Introduction: KVL, KCL and Power Balance
    00:00
  • Lecture 02: Voltage and Current Sources
    00:00
  • Lecture 03: Simple Networks with Voltage and Current Sources
    00:00
  • Lecture 04: Mesh Analysis – I
    00:00
  • Lecture 05: Mesh Analysis – II
    00:00
  • Lecture 06: Nodal Analysis – I
    00:00
  • Lecture 07: Nodal Analysis – II
    00:00
  • Lecture 08: Nodal Analysis – III
    00:00
  • Lecture 09: Inductor – I
    00:00
  • Lecture 10: Initial Condition for Inductor
    00:00
  • Lecture 11: Energy Stored in Inductor with Example
    00:00
  • Lecture 12: R-L Series Circuit Analysis
    00:00
  • Lecture 13: Retrieving Energy or Discharging of Inductor Energy
    00:00
  • Lecture 14: Capacitor: Relationship of Voltage and Current and Initial Condition
    00:00
  • Lecture 15: Charging of a Capacitor – Voltage, Current and Energy During Charging
    00:00
  • Lecture 16: Discharge of a Charged Capacitor
    00:00
  • Lecture 17: Linearity of R, L, C – Inductor with Initial Current and Capacitor with Initial Voltage
    00:00
  • Lecture 18: General Method for Solving Linear Differential Equation – I
    00:00
  • Lecture 19: General Method for Solving Linear Differential Equation – II
    00:00
  • Lecture 20: General Method for Solving Linear Differential Equation – III
    00:00
  • Lecture 21: Problem Solving: Application
    00:00
  • Lecture 22: R – L Circuit with Sinusoidal Excitation
    00:00
  • Lecture 23: R – C Circuit with Sinusoidal Exponential
    00:00
  • Lecture 24: Solution Due to Exponential Forcing Function
    00:00
  • lecture 25: Mesh and Nodal Analysis with Time Varying Source
    00:00
  • Lecture 26: Circuit Analysis with Phasor – I
    00:00
  • Lecture 27: Circuit Analysis with Phasor – II
    00:00
  • Lecture 28: Circuit Analysis with Phasor – III
    00:00
  • Lecture 29: Concept of Active and Reactive Power in A.C Circuit – I
    00:00
  • Lecture 30: Concept of Active and Reactive Power in A.C Circuit – II
    00:00
  • Lecture 31: Expression for Complex Power in A.C Circuit
    00:00
  • Lecture 32: Numerical Example
    00:00
  • Lecture 33: Mesh and Nodal Analysis in A.C Circuit, Introduction to Impulse Function
    00:00
  • Lecture 34: Odd and Even Functions, Relation between Unit Step and Impulse Function
    00:00
  • Lecture 35: Solution of Differential Equation with Impulse Excitation
    00:00
  • Lecture 36: Numerical Example when Excitation is Impulse
    00:00
  • Lecture 37: Self and Mutual Inductances – I
    00:00
  • Lecture 38: Dot Convention in Mutually Coupled Coils
    00:00
  • Lecture 39: Mutually Coupled Coils in Series and Parallel
    00:00
  • Lecture 40: Energy Stored in Mutually Coupled Coils
    00:00
  • Lecture 41: Steady State Response with Sinusoidal Excitation when the Coils are Mutually Coupled
    00:00
  • Lecture 42: Basics of Signals in Brief
    00:00
  • Lecture 43: Laplace Transform – I
    00:00
  • Lecture 44: Laplace Transform – II
    00:00
  • Lecture 45: Laplace Transform Applied to Circuit Analysis – I
    00:00
  • Lecture 46: Laplace Transform Applied to Circuit Analysis – II
    00:00
  • Lecture 47: Numerical Examples – I
    00:00
  • Lecture 48: Numerical Examples – II
    00:00
  • Lecture 49: General Second Order Circuit Analysis with L.T – I
    00:00
  • Lecture 50: General Second Order Circuit Analysis with L.T – II
    00:00
  • Lecture 51: Network Theorem – I
    00:00
  • Lecture 52: Network Theorem – II
    00:00
  • Lecture 53: Norton’s Theorem
    00:00
  • Lecture 54: Thevenin Theorem
    00:00
  • Lecture 55: Star-Delta and Delta-Star Transformation
    00:00
  • Lecture 56: Telligen’s Theorem
    00:00
  • Lecture 57: Reciprocity Theorem
    00:00
  • Lecture 58: Maximum Power Transfer Theorem
    00:00
  • Lecture 59: Graph Theory Applied to Network Analysis – I
    00:00
  • Lecture 60: Graph Theory Applied to Network Analysis – II
    00:00
  • Lecture 61: Graph Theory Applied to Network Analysis – III
    00:00
  • Lecture 62: Graph Theory Applied to Network Analysis – IV
    00:00
  • Lecture 63: Graph Theory Applied to Network Analysis – V
    00:00
  • Lecture 64: Mesh Analysis with Graph Theory
    00:00
  • Lecture 65: Nodal Analysis with Graph Theory
    00:00
  • Lecture 66: Cut-Set Analysis with Graph Theory
    00:00
  • Lecture 67: Numerical Examples of Network Analysis with Graph Theory
    00:00
  • Lecture 68: Circuit Analysis with Dependent Sources – I
    00:00
  • Lecture 69: Circuit Analysis with Dependent Sources – II
    00:00
  • Lecture 70: Circuit Analysis with Dependent Sources – III
    00:00
  • Lecture 71: Two Port Network – I
    00:00
  • Lecture 72: Two Port Network – II
    00:00
  • Lecture 73: Two Port Network – III
    00:00
  • Lecture 74: Two Port Network – IV
    00:00
  • Lecture 75: Two Port Network – V
    00:00
  • Lecture 76: Two Port Network – VI
    00:00
  • Lecture 77: Two Port Network – VII
    00:00
  • Lecture 78: Gyrator
    00:00
  • Lecture 79: Ideal Op – Amp
    00:00
  • Lecture 80: Examples of Ideal Op-Amp Circuits – I
    00:00
  • Lecture 81: Examples of Ideal Op-Amp Circuits – II
    00:00
  • Lecture 82: General Impedance Transfer Circuit and Concluding Remarks
    00:00

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