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Lecture
Fundamental Theorems of Circuits and Systems
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Related lectures (32)
Analysis of Circuits with Dependent Sources
Explores the analysis of circuits with dependent sources, node-voltage analysis, Thévenin equivalent circuits, and OPAMP fundamentals.
Circuit Analysis: Thevenin and Norton Theorems
Explores circuit analysis using Thevenin and Norton theorems to simplify complex circuits for analysis.
Circuit Analysis: Thevenin and Norton Equivalents
Explores Thevenin and Norton equivalents, mesh and nodal analysis, and planar circuits.
Thevenin and Norton Theorems in Alternating Regime: Superposition Principle
Explores Thevenin and Norton theorems in alternating regime, emphasizing superposition principle and complex time domains.
Fundamental Theorems: Linear Circuits
Covers fundamental theorems in linear circuits, including superposition and source conversion.
Superposition Principle: Circuits Analysis
Covers the superposition principle in circuit analysis, simplifying complex circuits for easier evaluation through individual component analysis and result summation.
Linear Circuits in Sinusoidal Regime
Explores linear circuits in sinusoidal regime, covering phasors, impedance, power calculations, Thevenin/Norton equivalents, and frequency analysis.
Thévenin-Norton Theorems
Explains the Thévenin and Norton theorems for simplifying electrical circuits with equivalent sources and impedances.
S-Domain Circuit Analysis: Part 2
Delves into s-domain circuit analysis, covering theorems, analysis methods, and stability concepts.
Thevenin and Norton Theorems
Covers the Thevenin and Norton theorems for simplifying complex circuits into equivalent sources and internal resistances.
Step Response of RLC Circuits and Quadrupoles
Analyzes the step response of RLC circuits and introduces the concept of quadrupoles.
Matrix Representation: Circuit Equations
Covers the process of writing circuit equations in matrix form and solving for currents using the inversion method.
Linear Passive Circuits: Thevenin and Norton Theorems
Explains Thevenin's and Norton's theorems, superposition principle, dividers, and RC circuits.
Single-Phase Sinusoidal Circuits
Covers peak, mean, and rms values, average power, phase advance, and sinusoidal circuits.
Thevenin and Norton Theorems
Covers Thevenin and Norton theorems for simplifying complex circuits into equivalent ones.
Circuit Analysis: Thevenin's Theorem
Explores circuit analysis using Thevenin's theorem to simplify complex circuits into equivalent ones with a single source and resistor.
Analysis and Resolution Methods
Covers the analysis of circuits, real voltage and current sources, and circuit processing.
Electrotechnique: Basics and Applications
Covers the basics of electrotechnique, including linear elements, current regimes, power types, and practical applications.
Electrotechnique: Basics and Applications
Covers the basics of electrotechnique, including linear elements, regimes, power types, and practical applications.
Noise in Two-port Networks
Covers the analysis of noise in two-port networks, Y-parameters, substrate resistance extraction, and the noise factor.
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