Lectures related to Network Functions: Analysis and Design

The Frequency Response of RLC Circuits

Explores the frequency response of RLC circuits, operational amplifiers, and linear dependent sources, highlighting the historical significance of operational amplifiers.

Frequency Response: Network Functions

Explores network functions, frequency-response descriptors, Bode diagrams, and RLC circuit frequency responses.

Analog Circuits and Systems: The Laplace Transform

Covers the basics and applications of the Laplace transform in analyzing linear analog circuits.

Laplace Transforms: Circuit Analysis

Explores Laplace transforms in circuit analysis, emphasizing pole-zero diagrams and s-domain concepts.

S-Domain Circuit Analysis: Part 2

Delves into s-domain circuit analysis, covering theorems, analysis methods, and stability concepts.

Analysis of Circuits with Dependent Sources

Explores the analysis of circuits with dependent sources, node-voltage analysis, Thévenin equivalent circuits, and OPAMP fundamentals.

Feedback and Stability

Explores negative feedback in analog circuits, focusing on desensitizing gain, reducing distortion, controlling noise, and extending bandwidth.

Frequency Response: Descriptors and Bode Diagrams

Explores frequency-response descriptors, Bode diagrams, first-order responses, and RLC circuits.

Frequency Response of RLC Circuits

Explores the frequency response of RLC circuits, Bode diagrams, OPAMP history, and modern engineering applications.

Quadripoles and Frequency Response

Covers quadripoles, impedance matrices, reciprocity, and frequency response in circuits.

Basic Principles of Oscillators

Covers the fundamental principles of oscillators, including signal generators, OPAMP RC oscillator circuits, and multivibrators.

High-order Filters: LC Ladder Filters

Explores the design and simulation of high-order LC ladder filters using active-RC circuits and impedance normalization techniques.

Circuit Analysis: Thevenin and Norton Equivalents

Explores Thevenin and Norton equivalents, mesh and nodal analysis, and planar circuits.

Circuit Analysis: Thevenin and Norton Theorems

Explores circuit analysis using Thevenin and Norton theorems to simplify complex circuits for analysis.

Basic Concepts: Electric Circuits

Introduces the fundamental concepts of electric circuits, including basic elements and Kirchhoff's laws.

Linear Systems: Stability and Solutions

Explores stability and solutions of linear systems in continuous and discrete time.

Kirchhoff's Laws and DC Circuits

Explores Kirchhoff's laws in DC circuits, resistor analysis, and capacitor behavior.

Noise in Two-port Networks

Covers the analysis of noise in two-port networks, Y-parameters, substrate resistance extraction, and the noise factor.

Analog Circuits and Systems: Q&A Session

Covers a Q&A session on analog circuits, focusing on practice exams, filters, oscillators, and feedback structures.

Maximum Power Transfer Theorem and Analysis Methods

Explores the Maximum Power Transfer Theorem and Analysis Methods in linear circuits with practical examples.