Computer engineering (Academic Year 2019/2020) - Computer Engineering

Basic circuit theory

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Lesson n.1: Circuit Variables
Lesson n.2: Circuit Analysis The Purpose of Circuit Analysis n. 2.1 - Exercises for lesson 2 (A.Y. 2011/2012)
Lesson n.3: Kirchhoff s Current and Voltage Laws
Lesson n.4: Resistive Circuits
Lesson n.5: Simultaneous Equations
Lesson n.6: Node-Voltage Tecnique
Lesson n.7: Node-Voltage Method
Lesson n.8: Mesh Current Analysis
Lesson n.9: Source Transformation Theorem
Lesson n.10: Thevenin s and Norton s Theorems
Lesson n.11: Thevenin Equivalent and Maximum Power Transfer
Lesson n.12: Millman s and Superposition Theorems
Lesson n.13: Indipendence of Equations
Lesson n.14: Link Current Method
Lesson n.15: Energy Storage Elements
Lesson n.16: Transient Analysis
Lesson n.17: Natural and Step Responses of RL and RC Circuits
Lesson n.18: The Step Responses of RC Circuits
Lesson n.19: Sinusoidal Source and Sinusoidal Response
Lesson n.20: The Phasor and V-I Relationships for Circuit Elements
Lesson n.21: Techniques of Circuit Analysis
Lesson n.22: Techniques of Circuit Analysis - part II
Lesson n.23: Sinusoidal Steady-State Power Calculation
Lesson n.24: Complex Power
Lesson n.25: Maximum Power Transfer
Lesson n.26: Basic concepts of circuit theory
Lesson n.27: Circuits' properties
Lesson n.28: N-Ports
Lesson n.29: Power in circuits
Lesson n.30: Resonance
Lesson n.31: Transients