11:52

Simple ways to visualise wave polarisation and its effects in the lab

17:47

A Brief Demonstration of QUCS Software for RF Simulations

09:53

Using Subcircuit Libraries with SPICE: A brief tutorial

21:55

Demo 3: Synchronous and Asynchronous Counters using Structural/Behavioural Constructs in Verilog

20:10

Demo 2: Multiplexers, Latches, and Flipflops using Dataflow/Behavioural Constructs in Verilog

15:28

Demo 1: Multiplexer and Decoder using Behavioural Constructs in Verilog

38:56

Lecture 31: Introduction to Hardware Description Languages, and Programmable Logic Devices

53:12

Lecture 30: Conversion of Flipflops, and a Discussion on Memory Elements

45:14

Lecture 29: Design of Various Synchronous Sequential Circuits

46:05

Lecture 28: Working with Synchronous Counters

42:58

Lecture 27: Working with Ripple Counters, their Drawbacks, and Introduction to Synchronous Counters

50:49

Lecture 26: Frequency Division and Counting using Flipflops

42:45

Lecture 25: Flipflops and their Properties

47:46

Lecture 24: S-R Latches, D Latches and their Properties

42:42

Lecture 23: Introduction to Circuits with Feedback

36:24

Lecture 22: The Carry Look Ahead Adder

44:01

Lecture 21: Priority Encoders and Limitations of Ripple Carry Adders

36:23

Lecture 20: Working with Decoders

35:53

Lecture 19: Introduction to Decoders

44:16

Lecture 18: Realizing Large Logic Functions using Smaller Multiplexers

43:07

Lecture 17: Working with Multiplexers

40:53

Lecture 16: Introduction to Multiplexers

42:40

Lecture 15: A Look at Complex Circuits through Binary Arithmetic

42:35

Lecture 14: Diagonal and Offset Groups, and Don't Care Scenarios

46:37

Lecture 13: K-maps for Three- and Four-variable Functions

43:15

Lecture 12: Karnaugh Maps- A Technique to Minimize Logic Functions

35:23

Lecture 10: Alphanumeric Codes and Digital Signals

46:30

Lecture 11: Standardized Representation of Logic Functions

43:53

Lecture 9: Codes in Digital Systems

43:20

Lecture 8: Building Logic Circuits using MOSFETs

45:14

Lecture 7: MOSFET Physics

47:48

Lecture 6: The Electronics behind Logic Gates

47:03

Lecture 5: Binary Subtraction and Representation of Negative Numbers

44:52

Lecture 4: Introduction to Binary Arithmetic

47:19

Lecture 31: Unilaterality and its effects on design for stability and gain for MMIC amplifiers

49:51

Lecture 30: Working with Stability Circles

46:31

Lecture 3: Universal Gates and Properties of Boolean Algebra

47:49

Lecture 2: Basic Logic Functions and Gates

45:05

Lecture 1: Introduction to Logic, and Analog-Digital Conversion

51:13

Lecture 29: Stability Aspects of MMIC Amplifiers

49:11

Lecture 28: Power Gain Expressions for RF MMIC Amplifiers

01:01:01

Lecture 26: Bandwidth Estimation Techniques for MOS Devices and Circuits

47:09

Lecture 27: Analysis of RF MMIC Amplifiers Using S-Parameters

45:16

Lecture 25: The MOSFET from an RF Perspective

48:00

Lecture 24: Special Function RF Diodes

50:42

Lecture 23: Introduction to Solid State RF Devices

50:53

Lecture 21: Drawbacks of Coupled Lines and Introduction to Branch Line Hybrids

43:41

Lecture 22: Analysis of Branch Line Hybrids

50:57

Lecture 20: Coupled Line Directional Couplers

50:17

Lecture 19: Unequal Power Dividers, Circulators, and Introduction to RF Coupling

44:42

Lecture 18: Even-Odd Technique, and the Wilkinson Power Divider

46:43

Lecture 17: Analysis of Lossless Power Dividers

41:13

Lecture 16: Introduction to RF Power Dividers

55:46

Lecture 15: Properties of S Parameters and Transmission Parameters

01:02:51

Lecture 14: RL/RC Transformation and Introduction to RF Network Analysis

49:06

Lecture 13: Transformation of RL/RC Networks

51:10

Lecture 12: Impedance Matching Techniques for Complex Loads

46:44

Lecture 11: The Binomial Impedance Matching Transformer

50:41

Lecture 10: Increasing QWT Bandwidth Using The Theory of Small Reflections

47:10

Lecture 9: Matching Bandwidth of a QWT