DIGIMAT LEARNING MANAGEMENT PLATFORM

Electrical Engineering (11,689 Video Lectures)

Link NPTEL Course Name NPTEL Lecture Title
Link Nonlinear Dynamical Systems Lecture 1 - Introduction
Link Nonlinear Dynamical Systems Lecture 2 - First Order systems
Link Nonlinear Dynamical Systems Lecture 3 - Classification of Equilibrium points
Link Nonlinear Dynamical Systems Lecture 4 - Lipschitz Functions
Link Nonlinear Dynamical Systems Lecture 5 - Existence/uniqueness theorems
Link Nonlinear Dynamical Systems Lecture 6 - Existence/uniqueness of solutions to differential equations
Link Nonlinear Dynamical Systems Lecture 7 - Lyapunov theorem on stability
Link Nonlinear Dynamical Systems Lecture 8 - Extension of Lyapunov's Theorem in different contexts
Link Nonlinear Dynamical Systems Lecture 9 - LaSalle's Invariance principle, Barbashin and Krasovski theorems, periodic orbits
Link Nonlinear Dynamical Systems Lecture 10 - Bendixson criterion and Poincare-Bendixson criterion. Example: Lotka Volterra predator prey model
Link Nonlinear Dynamical Systems Lecture 11 - Bendixson and Poincare-Bendixson criteria van-der-Pol Oscillator
Link Nonlinear Dynamical Systems Lecture 12 - Scilab simulation of Lotka Volterra predator prey model, van-der-Pol Oscillator Review of linearization, operating point/operating trajectory
Link Nonlinear Dynamical Systems Lecture 13 - Signals, operators
Link Nonlinear Dynamical Systems Lecture 14 - Norms of signals, systems (operators), Finite gain L2 stable
Link Nonlinear Dynamical Systems Lecture 15 - Nyquist plots and Nyquist criterion for stability
Link Nonlinear Dynamical Systems Lecture 16 - Interconnection between linear system & non-linearity, passive filters
Link Nonlinear Dynamical Systems Lecture 17 - Passive filters, Dissipation equality, positive real lemma
Link Nonlinear Dynamical Systems Lecture 18 - Positive real lemma proof
Link Nonlinear Dynamical Systems Lecture 19 - Definition for positive realness and Kalman Yakubovich-Popov Theorem
Link Nonlinear Dynamical Systems Lecture 20 - Kalman-Yakubovich-Popov Lemma/theorem and memoryless nonlinearities
Link Nonlinear Dynamical Systems Lecture 21 - Loop tranformations and circle criterion
Link Nonlinear Dynamical Systems Lecture 22 - Nonlinearities based on circle criterion
Link Nonlinear Dynamical Systems Lecture 23 - Limit cycles
Link Nonlinear Dynamical Systems Lecture 24 - Popov criterion continuous, frequency-domain theorem
Link Nonlinear Dynamical Systems Lecture 25 - Popov criterion continuous, frequency-domain theorem
Link Nonlinear Dynamical Systems Lecture 26 - Describing function method
Link Nonlinear Dynamical Systems Lecture 27 - Describing Function : 2
Link Nonlinear Dynamical Systems Lecture 28 - Describing : optimal gain
Link Nonlinear Dynamical Systems Lecture 29 - Describing : optimal gain
Link Nonlinear Dynamical Systems Lecture 30 - Describing functions : Jump Hysteresis
Link Nonlinear Dynamical Systems Lecture 31 - Describing functions : sufficient conditions for existence of periodic orbits non existence of periodic orbits
Link Nonlinear Dynamical Systems Lecture 32 - Describing functions for nonlinearities
Link Nonlinear Dynamical Systems Lecture 33 - Ideal relay with Hysteresis and dead zone
Link Nonlinear Dynamical Systems Lecture 34 - Dynamical systems on manifolds-1
Link Nonlinear Dynamical Systems Lecture 35 - Dynamical systems on manifolds-2
Link Power System Dynamics and Control Lecture 1 - Introduction
Link Power System Dynamics and Control Lecture 2 - Introduction
Link Power System Dynamics and Control Lecture 3 - Analysis of Dynamical Systems
Link Power System Dynamics and Control Lecture 4 - Analysis of Dynamical Systems (Continued.)
Link Power System Dynamics and Control Lecture 5 - Analysis of LINEAR Time Invariant Dynamical Systems
Link Power System Dynamics and Control Lecture 6 - Analysis of LINEAR Time Invariant Dynamical Systems (Continued.)
Link Power System Dynamics and Control Lecture 7 - Stiff Systems, Multi Time Scale Modeling
Link Power System Dynamics and Control Lecture 8 - Numerical Integration
Link Power System Dynamics and Control Lecture 9 - Numerical Integration (Continued.)
Link Power System Dynamics and Control Lecture 10 - Numerical Integration (Continued.)
Link Power System Dynamics and Control Lecture 11 - Modeling of Synchronous Machines
Link Power System Dynamics and Control Lecture 12 - Modeling of Synchronous Machines (Continued.)
Link Power System Dynamics and Control Lecture 13 - Modeling of Synchronous Machines (Continued.)
Link Power System Dynamics and Control Lecture 14 - Modeling of Synchronous Machines. dq0 transformation (Continued.)
Link Power System Dynamics and Control Lecture 15 - Modeling of Synchronous Machines. Standard Parameters
Link Power System Dynamics and Control Lecture 16 - Modeling of Synchronous Machines. Standard Parameters
Link Power System Dynamics and Control Lecture 17 - Synchronous Generator Models using Standard Parameters
Link Power System Dynamics and Control Lecture 18 - Synchronous Generator Models using Standard Parameters. PER UNIT REPRESENTATION
Link Power System Dynamics and Control Lecture 19 - Open Circuit Response of a Synchronous Generator
Link Power System Dynamics and Control Lecture 20 - Synchronous Machine Modeling. Short Circuit Analysis (Continued.)
Link Power System Dynamics and Control Lecture 21 - Synchronous Machine Modeling. Short Circuit Analysis (Continued.) Synchronization of a Synchronous Machine
Link Power System Dynamics and Control Lecture 22 - Synchronization of a Synchronous Machine (Continued.)
Link Power System Dynamics and Control Lecture 23 - Simplified Synchronous Machine Models
Link Power System Dynamics and Control Lecture 24 - Excitation Systems
Link Power System Dynamics and Control Lecture 25 - Excitation System Modeling
Link Power System Dynamics and Control Lecture 26 - Excitation System Modeling. Automatic Voltage Regulator
Link Power System Dynamics and Control Lecture 27 - Excitation System Modeling. Automatic Voltage Regulator (Continued.)
Link Power System Dynamics and Control Lecture 28 - Excitation System Modeling. Automatic Voltage Regulator (Simulation)
Link Power System Dynamics and Control Lecture 29 - Excitation System Modeling. Automatic Voltage Regulator (Simulation) – (Continued.)
Link Power System Dynamics and Control Lecture 30 - Excitation System Modeling. Automatic Voltage Regulator. Linearized Analysis
Link Power System Dynamics and Control Lecture 31 - Load Modeling
Link Power System Dynamics and Control Lecture 32 - Induction Machines, Transmission Lines
Link Power System Dynamics and Control Lecture 33 - Transmission Lines. Prime Mover Systems
Link Power System Dynamics and Control Lecture 34 - Transmission Lines (Continued.) Prime Mover Systems
Link Power System Dynamics and Control Lecture 35 - Prime Mover Systems. Stability in Integrated Power System
Link Power System Dynamics and Control Lecture 36 - Stability in Integrated Power System: Two Machine Example
Link Power System Dynamics and Control Lecture 37 - Two Machine System (Continued.)
Link Power System Dynamics and Control Lecture 38 - Stability in Integrated Power System: Large Systems
Link Power System Dynamics and Control Lecture 39 - Frequency/Angular Stability Programs. Stability Phenomena: Voltage Stability Example
Link Power System Dynamics and Control Lecture 40 - Voltage Stability Example (Continued.). Fast Transients: Tools and Phenomena
Link Power System Dynamics and Control Lecture 41 - Torsional Transients: Phenomena of Sub-Synchronous Resonance
Link Power System Dynamics and Control Lecture 42 - Sub-Synchronous Resonance. Stability Improvement
Link Power System Dynamics and Control Lecture 43 - Stability Improvement
Link Power System Dynamics and Control Lecture 44 - Stability Improvement. Power System Stabilizers
Link Power System Dynamics and Control Lecture 45 - Stability Improvement (Large Disturbance Stability)
Link Control Engineering (Prof. S.D. Agashe) Lecture 1 - The Control Problem
Link Control Engineering (Prof. S.D. Agashe) Lecture 2 - Some More Examples
Link Control Engineering (Prof. S.D. Agashe) Lecture 3 - Different Kinds of Control Systems
Link Control Engineering (Prof. S.D. Agashe) Lecture 4 - History of Feedback
Link Control Engineering (Prof. S.D. Agashe) Lecture 5 - Modern Control Problems
Link Control Engineering (Prof. S.D. Agashe) Lecture 6 - DC Motor Speed Control
Link Control Engineering (Prof. S.D. Agashe) Lecture 7 - System Modelling, Analogy
Link Control Engineering (Prof. S.D. Agashe) Lecture 8 - Causes of System Error
Link Control Engineering (Prof. S.D. Agashe) Lecture 9 - Calculation of Error
Link Control Engineering (Prof. S.D. Agashe) Lecture 10 - Control System Sensitivity
Link Control Engineering (Prof. S.D. Agashe) Lecture 11 - Automatic Control of DC Motor
Link Control Engineering (Prof. S.D. Agashe) Lecture 12 - Proportional Control
Link Control Engineering (Prof. S.D. Agashe) Lecture 13 - Non-Unity Feedback
Link Control Engineering (Prof. S.D. Agashe) Lecture 14 - Signal-Flow Graph
Link Control Engineering (Prof. S.D. Agashe) Lecture 15 - Mason's Gain Formula
Link Control Engineering (Prof. S.D. Agashe) Lecture 16 - Signal-Flow Graph for DC Motor Control
Link Control Engineering (Prof. S.D. Agashe) Lecture 17 - Steady-State Calculations
Link Control Engineering (Prof. S.D. Agashe) Lecture 18 - Differential Equation Model and Laplace Transformation Model
Link Control Engineering (Prof. S.D. Agashe) Lecture 19 - D-Operator Method
Link Control Engineering (Prof. S.D. Agashe) Lecture 20 - Second-Order System Response
Link Control Engineering (Prof. S.D. Agashe) Lecture 21 - Frequency Response
Link Control Engineering (Prof. S.D. Agashe) Lecture 22 - Laplace Transformation Theorems
Link Control Engineering (Prof. S.D. Agashe) Lecture 23 - Final Value Theorem
Link Control Engineering (Prof. S.D. Agashe) Lecture 24 - Transfer Function and Pole-Zero Diagram
Link Control Engineering (Prof. S.D. Agashe) Lecture 25 - 'Good' Poles and 'Bad' Poles
Link Control Engineering (Prof. S.D. Agashe) Lecture 26 - Signal Flow Graph with Transfer Functions
Link Control Engineering (Prof. S.D. Agashe) Lecture 27 - s-Domain and t-Domain
Link Control Engineering (Prof. S.D. Agashe) Lecture 28 - Second-Order System Response in s-Domain
Link Control Engineering (Prof. S.D. Agashe) Lecture 29 - Integral Feedback
Link Control Engineering (Prof. S.D. Agashe) Lecture 30 - Root-Locus Method
Link Control Engineering (Prof. S.D. Agashe) Lecture 31 - Root-Locus Rules
Link Control Engineering (Prof. S.D. Agashe) Lecture 32 - Asymptotes of Root Locus
Link Control Engineering (Prof. S.D. Agashe) Lecture 33 - Routh Array
Link Control Engineering (Prof. S.D. Agashe) Lecture 34 - Singular Cases
Link Control Engineering (Prof. S.D. Agashe) Lecture 35 - Closed Loop Poles
Link Control Engineering (Prof. S.D. Agashe) Lecture 36 - Controller in the Forwarded Path
Link Control Engineering (Prof. S.D. Agashe) Lecture 37 - Mapping of Control in the Complex-Plane
Link Control Engineering (Prof. S.D. Agashe) Lecture 38 - Encirclement by a Curve
Link Control Engineering (Prof. S.D. Agashe) Lecture 39 - Nyquist Criterion
Link Control Engineering (Prof. S.D. Agashe) Lecture 40 - Application of the Nyquist Criterion
Link Control Engineering (Prof. S.D. Agashe) Lecture 41 - Polar Plot and Bode Plots
Link Control Engineering (Prof. S.D. Agashe) Lecture 42 - Logarithmic Scale for Frequency
Link Control Engineering (Prof. S.D. Agashe) Lecture 43 - 'Asymptotic' DB Gain
Link Control Engineering (Prof. S.D. Agashe) Lecture 44 - Compensating Network
Link Control Engineering (Prof. S.D. Agashe) Lecture 45 - Nichols' Chart
Link Control Engineering (Prof. S.D. Agashe) Lecture 46 - Time Domain Methods of Analysis and Design
Link Control Engineering (Prof. S.D. Agashe) Lecture 47 - State-Variable Equations
Link Power Electronics Lecture 1 - Power Electronics
Link Power Electronics Lecture 2 - Power Electronics
Link Power Electronics Lecture 3 - Power Electronics
Link Power Electronics Lecture 4 - Power Electronics
Link Power Electronics Lecture 5 - Power Electronics
Link Power Electronics Lecture 6 - Power Electronics
Link Power Electronics Lecture 7 - Power Electronics
Link Power Electronics Lecture 8 - Power Electronics
Link Power Electronics Lecture 9 - Power Electronics
Link Power Electronics Lecture 10 - Power Electronics
Link Power Electronics Lecture 11 - Power Electronics
Link Power Electronics Lecture 12 - Power Electronics
Link Power Electronics Lecture 13 - Power Electronics
Link Power Electronics Lecture 14 - Power Electronics
Link Power Electronics Lecture 15 - Power Electronics
Link Power Electronics Lecture 16 - Power Electronics
Link Power Electronics Lecture 17 - Power Electronics
Link Power Electronics Lecture 18 - Power Electronics
Link Power Electronics Lecture 19 - Power Electronics
Link Power Electronics Lecture 20 - Power Electronics
Link Power Electronics Lecture 21 - Power Electronics
Link Power Electronics Lecture 22 - Power Electronics
Link Power Electronics Lecture 23 - Power Electronics
Link Power Electronics Lecture 24 - Power Electronics
Link Power Electronics Lecture 25 - Power Electronics
Link Power Electronics Lecture 26 - Power Electronics
Link Power Electronics Lecture 27 - Power Electronics
Link Power Electronics Lecture 28 - Power Electronics
Link Power Electronics Lecture 29 - Power Electronics
Link Power Electronics Lecture 30 - Power Electronics
Link Power Electronics Lecture 31 - Power Electronics
Link Power Electronics Lecture 32 - Power Electronics
Link Power Electronics Lecture 33 - Power Electronics
Link Power Electronics Lecture 34 - Power Electronics
Link Power Electronics Lecture 35 - Power Electronics
Link Power Electronics Lecture 36 - Power Electronics
Link Power Electronics Lecture 37 - Power Electronics
Link Power Electronics Lecture 38 - Power Electronics
Link Power Electronics Lecture 39 - Power Electronics
Link Power Electronics Lecture 40 - Power Electronics
Link Power Electronics Lecture 41 - Power Electronics
Link Power Electronics Lecture 42 - Power Electronics
Link Power Electronics Lecture 43 - Power Electronics
Link Fabrication of Silicon VLSI Circuits using the MOS technology Lecture 1 - Introduction Micro to Nano A Journey into Intergrated Circuit Technology
Link Fabrication of Silicon VLSI Circuits using the MOS technology Lecture 2 - Introduction Micro to Nano A Journey into Intergrated Circuit Technology
Link Fabrication of Silicon VLSI Circuits using the MOS technology Lecture 3 - Crystal Properties and Silico Growth
Link Fabrication of Silicon VLSI Circuits using the MOS technology Lecture 4 - Crystal Properties and Silico Growth (Continued...)
Link Fabrication of Silicon VLSI Circuits using the MOS technology Lecture 5 - IC Fab Labs and Fabrication of IC
Link Fabrication of Silicon VLSI Circuits using the MOS technology Lecture 6 - Diffusion
Link Fabrication of Silicon VLSI Circuits using the MOS technology Lecture 7 - Diffusion (Continued...)
Link Fabrication of Silicon VLSI Circuits using the MOS technology Lecture 8 - Solid State Diffusion
Link Fabrication of Silicon VLSI Circuits using the MOS technology Lecture 9 - Solid State Diffusion (Continued...)
Link Fabrication of Silicon VLSI Circuits using the MOS technology Lecture 10 - Solid State Diffusion (Continued...)
Link Fabrication of Silicon VLSI Circuits using the MOS technology Lecture 11 - Thermal Oxidation of Silicons
Link Fabrication of Silicon VLSI Circuits using the MOS technology Lecture 12 - Thermal Oxidation of Silicons
Link Fabrication of Silicon VLSI Circuits using the MOS technology Lecture 13 - Thermal Oxidation of Silicons
Link Fabrication of Silicon VLSI Circuits using the MOS technology Lecture 14 - Thermal Oxidation of Silicons (Continued...)
Link Fabrication of Silicon VLSI Circuits using the MOS technology Lecture 15 - Thermal Oxidation of Silicons (Continued...)
Link Fabrication of Silicon VLSI Circuits using the MOS technology Lecture 16 - Lithography
Link Fabrication of Silicon VLSI Circuits using the MOS technology Lecture 17 - Lithography
Link Fabrication of Silicon VLSI Circuits using the MOS technology Lecture 18 - Lithography
Link Fabrication of Silicon VLSI Circuits using the MOS technology Lecture 19 - ION Implantation
Link Fabrication of Silicon VLSI Circuits using the MOS technology Lecture 20 - ION Implantation
Link Fabrication of Silicon VLSI Circuits using the MOS technology Lecture 21 - ION Implantation and Silicon IC Processing Flow for CMOS Technology
Link Fabrication of Silicon VLSI Circuits using the MOS technology Lecture 22 - ION Implantation and Silicon IC Processing Flow for CMOS Technology
Link Fabrication of Silicon VLSI Circuits using the MOS technology Lecture 23 - Silicon IC Processing Flow for CMOS Technology
Link Fabrication of Silicon VLSI Circuits using the MOS technology Lecture 24 - Thin Film Deposition
Link Fabrication of Silicon VLSI Circuits using the MOS technology Lecture 25 - Thin Film Deposition
Link Fabrication of Silicon VLSI Circuits using the MOS technology Lecture 26 - Thin Film Deposition
Link Fabrication of Silicon VLSI Circuits using the MOS technology Lecture 27 - Thin Film Deposition and Etching in VLSI Processing
Link Fabrication of Silicon VLSI Circuits using the MOS technology Lecture 28 - Etching in VLSI Processing and Back -End Technology
Link NOC:Computational Electromagnetics and Applications Lecture 1 - Lecture 1
Link NOC:Computational Electromagnetics and Applications Lecture 2 - Lecture 2
Link NOC:Computational Electromagnetics and Applications Lecture 3 - Lecture 3
Link NOC:Computational Electromagnetics and Applications Lecture 4 - Exercise 1
Link NOC:Computational Electromagnetics and Applications Lecture 5 - Exercise 2
Link NOC:Computational Electromagnetics and Applications Lecture 6 - Exercise 3
Link NOC:Computational Electromagnetics and Applications Lecture 7 - Lab Tour 1
Link NOC:Computational Electromagnetics and Applications Lecture 8 - Summary week 1
Link NOC:Computational Electromagnetics and Applications Lecture 9 - Lecture 4
Link NOC:Computational Electromagnetics and Applications Lecture 10 - Lecture 5
Link NOC:Computational Electromagnetics and Applications Lecture 11 - Exercise 4
Link NOC:Computational Electromagnetics and Applications Lecture 12 - Exercise 5
Link NOC:Computational Electromagnetics and Applications Lecture 13 - Exercise 6
Link NOC:Computational Electromagnetics and Applications Lecture 14 - Summary Week 2
Link NOC:Computational Electromagnetics and Applications Lecture 15 - Lecture 6
Link NOC:Computational Electromagnetics and Applications Lecture 16 - Lecture 7
Link NOC:Computational Electromagnetics and Applications Lecture 17 - Lecture 8
Link NOC:Computational Electromagnetics and Applications Lecture 18 - Exercise 7
Link NOC:Computational Electromagnetics and Applications Lecture 19 - Exercise 8
Link NOC:Computational Electromagnetics and Applications Lecture 20 - Summary Week 3
Link NOC:Computational Electromagnetics and Applications Lecture 21 - Lecture 9
Link NOC:Computational Electromagnetics and Applications Lecture 22 - Lecture 10
Link NOC:Computational Electromagnetics and Applications Lecture 23 - Lecture 11
Link NOC:Computational Electromagnetics and Applications Lecture 24 - Lecture 12
Link NOC:Computational Electromagnetics and Applications Lecture 25 - Lecture 13
Link NOC:Computational Electromagnetics and Applications Lecture 26 - Lecture 14
Link NOC:Computational Electromagnetics and Applications Lecture 27 - Exercise 9
Link NOC:Computational Electromagnetics and Applications Lecture 28 - Lab Tour - 2
Link NOC:Computational Electromagnetics and Applications Lecture 29 - Summary Week 4
Link NOC:Computational Electromagnetics and Applications Lecture 30 - Lecture 15
Link NOC:Computational Electromagnetics and Applications Lecture 31 - Lecture 16
Link NOC:Computational Electromagnetics and Applications Lecture 32 - Lecture 17
Link NOC:Computational Electromagnetics and Applications Lecture 33 - Lecture 18
Link NOC:Computational Electromagnetics and Applications Lecture 34 - Exercise 10
Link NOC:Computational Electromagnetics and Applications Lecture 35 - Summary week 5
Link NOC:Computational Electromagnetics and Applications Lecture 36 - Lecture 19
Link NOC:Computational Electromagnetics and Applications Lecture 37 - Lecture 20
Link NOC:Computational Electromagnetics and Applications Lecture 38 - Lecture 21
Link NOC:Computational Electromagnetics and Applications Lecture 39 - Lecture 22
Link NOC:Computational Electromagnetics and Applications Lecture 40 - Exercise 11
Link NOC:Computational Electromagnetics and Applications Lecture 41 - Summary week 6
Link NOC:Computational Electromagnetics and Applications Lecture 42 - Exercise 12
Link NOC:Computational Electromagnetics and Applications Lecture 43 - Exercise 13
Link NOC:Computational Electromagnetics and Applications Lecture 44 - Exercise 14
Link NOC:Computational Electromagnetics and Applications Lecture 45 - Exercise 15
Link NOC:Computational Electromagnetics and Applications Lecture 46 - Exercise 16
Link NOC:Computational Electromagnetics and Applications Lecture 47 - Exercise 17
Link NOC:Computational Electromagnetics and Applications Lecture 48 - Summary week 7
Link NOC:Computational Electromagnetics and Applications Lecture 49 - Lecture 23
Link NOC:Computational Electromagnetics and Applications Lecture 50 - Lecture 24
Link NOC:Computational Electromagnetics and Applications Lecture 51 - Lecture 25
Link NOC:Computational Electromagnetics and Applications Lecture 52 - Exercise 18
Link NOC:Computational Electromagnetics and Applications Lecture 53 - Exercise 19
Link NOC:Computational Electromagnetics and Applications Lecture 54 - Lab tour 3
Link NOC:Computational Electromagnetics and Applications Lecture 55 - Summary week 8
Link NOC:Computational Electromagnetics and Applications Lecture 56 - Lecture 26
Link NOC:Computational Electromagnetics and Applications Lecture 57 - Lecture 27
Link NOC:Computational Electromagnetics and Applications Lecture 58 - Lecture 28
Link NOC:Computational Electromagnetics and Applications Lecture 59 - Lecture 29
Link NOC:Computational Electromagnetics and Applications Lecture 60 - Lecture 30
Link NOC:Computational Electromagnetics and Applications Lecture 61 - Lecture 31
Link NOC:Computational Electromagnetics and Applications Lecture 62 - Lab tour 4
Link NOC:Computational Electromagnetics and Applications Lecture 63 - Summary week 9
Link NOC:Computational Electromagnetics and Applications Lecture 64 - Lecture 32
Link NOC:Computational Electromagnetics and Applications Lecture 65 - Lecture 33
Link NOC:Computational Electromagnetics and Applications Lecture 66 - Lecture 34
Link NOC:Computational Electromagnetics and Applications Lecture 67 - Lecture 35
Link NOC:Computational Electromagnetics and Applications Lecture 68 - Exercise 20
Link NOC:Computational Electromagnetics and Applications Lecture 69 - Lab tour 5
Link NOC:Computational Electromagnetics and Applications Lecture 70 - Summary week 10
Link NOC:Computational Electromagnetics and Applications Lecture 71 - Lecture 36
Link NOC:Computational Electromagnetics and Applications Lecture 72 - Lecture 37
Link NOC:Computational Electromagnetics and Applications Lecture 73 - Lecture 38
Link NOC:Computational Electromagnetics and Applications Lecture 74 - Lecture 39
Link NOC:Computational Electromagnetics and Applications Lecture 75 - Lecture 40
Link NOC:Computational Electromagnetics and Applications Lecture 76 - Summary week 11
Link NOC:Computational Electromagnetics and Applications Lecture 77 - Lecture 41
Link NOC:Computational Electromagnetics and Applications Lecture 78 - Lecture 42
Link NOC:Computational Electromagnetics and Applications Lecture 79 - Lecture 43
Link NOC:Computational Electromagnetics and Applications Lecture 80 - Lecture 44
Link NOC:Computational Electromagnetics and Applications Lecture 81 - Exercise 21
Link NOC:Computational Electromagnetics and Applications Lecture 82 - Exercise 22
Link NOC:Computational Electromagnetics and Applications Lecture 83 - Summary week 12
Link NOC:Basic Electronics Lecture 1 - A brief history of electronics
Link NOC:Basic Electronics Lecture 2 - Superposition
Link NOC:Basic Electronics Lecture 3 - Useful circuit techniques - 1
Link NOC:Basic Electronics Lecture 4 - Useful circuit techniques - 2
Link NOC:Basic Electronics Lecture 5 - Phasors - 1
Link NOC:Basic Electronics Lecture 6 - Phasors - 2
Link NOC:Basic Electronics Lecture 7 - RC/RL circuits in time domain - 1
Link NOC:Basic Electronics Lecture 8 - RC/RL circuits in time domain - 2
Link NOC:Basic Electronics Lecture 9 - RC/RL circuits in time domain - 3
Link NOC:Basic Electronics Lecture 10 - RC/RL circuits in time domain - 4
Link NOC:Basic Electronics Lecture 11 - RC/RL circuits in time domain - 5
Link NOC:Basic Electronics Lecture 12 - Simulation of RC circuit
Link NOC:Basic Electronics Lecture 13 - Diode circuits - 1
Link NOC:Basic Electronics Lecture 14 - Diode circuits - 2
Link NOC:Basic Electronics Lecture 15 - Diode circuits - 3
Link NOC:Basic Electronics Lecture 16 - Diode circuits - 4
Link NOC:Basic Electronics Lecture 17 - Diode circuits - 5
Link NOC:Basic Electronics Lecture 18 - Diode circuits - 6
Link NOC:Basic Electronics Lecture 19 - Diode rectifiers - 1
Link NOC:Basic Electronics Lecture 20 - Diode rectifiers - 2
Link NOC:Basic Electronics Lecture 21 - Diode rectifiers - 3
Link NOC:Basic Electronics Lecture 22 - Bipolar Junction Transistor - 1
Link NOC:Basic Electronics Lecture 23 - Bipolar Junction Transistor - 2
Link NOC:Basic Electronics Lecture 24 - Bipolar Junction Transistor - 3
Link NOC:Basic Electronics Lecture 25 - BJT amplifier - 1
Link NOC:Basic Electronics Lecture 26 - BJT amplifier - 2
Link NOC:Basic Electronics Lecture 27 - BJT amplifier - 3
Link NOC:Basic Electronics Lecture 28 - BJT amplifier - 4
Link NOC:Basic Electronics Lecture 29 - BJT amplifier - 5
Link NOC:Basic Electronics Lecture 30 - BJT amplifier - 6
Link NOC:Basic Electronics Lecture 31 - BJT amplifier - 7
Link NOC:Basic Electronics Lecture 32 - Introduction to op-amps
Link NOC:Basic Electronics Lecture 33 - Op-amp circuits - 1
Link NOC:Basic Electronics Lecture 34 - Op-amp circuits - 2
Link NOC:Basic Electronics Lecture 35 - Op-amp circuits - 3
Link NOC:Basic Electronics Lecture 36 - Difference amplifier
Link NOC:Basic Electronics Lecture 37 - Instrumentation amplifier - 1
Link NOC:Basic Electronics Lecture 38 - Instrumentation amplifier - 2
Link NOC:Basic Electronics Lecture 39 - Op-amp nonidealities - 1
Link NOC:Basic Electronics Lecture 40 - Op-amp nonidealities - 2
Link NOC:Basic Electronics Lecture 41 - Bode plots - 1
Link NOC:Basic Electronics Lecture 42 - Bode plots - 2
Link NOC:Basic Electronics Lecture 43 - Bode plots - 3
Link NOC:Basic Electronics Lecture 44 - Op-amp filters
Link NOC:Basic Electronics Lecture 45 - Simulation of op-amp filter
Link NOC:Basic Electronics Lecture 46 - Precision rectifiers - 1
Link NOC:Basic Electronics Lecture 47 - Precision rectifiers - 2
Link NOC:Basic Electronics Lecture 48 - Precision rectifiers - 3
Link NOC:Basic Electronics Lecture 49 - Simulation of triangle-to-sine converter
Link NOC:Basic Electronics Lecture 50 - Schmitt triggers - 1
Link NOC:Basic Electronics Lecture 51 - Schmitt triggers - 2
Link NOC:Basic Electronics Lecture 52 - Schmitt triggers - 3
Link NOC:Basic Electronics Lecture 53 - Sinusoidal oscillators - 1
Link NOC:Basic Electronics Lecture 54 - Sinusoidal oscillators - 2
Link NOC:Basic Electronics Lecture 55 - Introduction to digital circuits
Link NOC:Basic Electronics Lecture 56 - Boolean algebra
Link NOC:Basic Electronics Lecture 57 - Karnaugh maps
Link NOC:Basic Electronics Lecture 58 - Combinatorial circuits - 1
Link NOC:Basic Electronics Lecture 59 - Combinatorial circuits - 2
Link NOC:Basic Electronics Lecture 60 - Combinatorial circuits - 3
Link NOC:Basic Electronics Lecture 61 - Introduction to sequential circuits
Link NOC:Basic Electronics Lecture 62 - Latch and flip-flop
Link NOC:Basic Electronics Lecture 63 - JK flip-flop
Link NOC:Basic Electronics Lecture 64 - D flip-flop
Link NOC:Basic Electronics Lecture 65 - Shift registers
Link NOC:Basic Electronics Lecture 66 - Counters - 1
Link NOC:Basic Electronics Lecture 67 - Counters - 2
Link NOC:Basic Electronics Lecture 68 - Simulation of a synchronous counter
Link NOC:Basic Electronics Lecture 69 - 555 timer
Link NOC:Basic Electronics Lecture 70 - Digital-to-analog conversion - 1
Link NOC:Basic Electronics Lecture 71 - Digital-to-analog conversion - 2
Link NOC:Basic Electronics Lecture 72 - Analog-to-digital conversion
Link NOC:Antennas Lecture 1 - Antenna Introduction - I
Link NOC:Antennas Lecture 2 - Antenna Introduction - II
Link NOC:Antennas Lecture 3 - Antenna Introduction - III
Link NOC:Antennas Lecture 4 - Antenna Fundamentals - I
Link NOC:Antennas Lecture 5 - Antenna Fundamentals - II
Link NOC:Antennas Lecture 6 - Antenna Radiation Hazards - I
Link NOC:Antennas Lecture 7 - Antenna Radiation Hazards - II
Link NOC:Antennas Lecture 8 - Dipole Antennas - I
Link NOC:Antennas Lecture 9 - Dipole Antennas - II
Link NOC:Antennas Lecture 10 - Dipole Antennas - III
Link NOC:Antennas Lecture 11 - Monopole Antennas - I
Link NOC:Antennas Lecture 12 - Monopole Antennas - II
Link NOC:Antennas Lecture 13 - Loop Antennas
Link NOC:Antennas Lecture 14 - Slot Antennas
Link NOC:Antennas Lecture 15 - Linear Arrays - I
Link NOC:Antennas Lecture 16 - Linear Arrays - II
Link NOC:Antennas Lecture 17 - Linear Arrays - III
Link NOC:Antennas Lecture 18 - Planar Arrays
Link NOC:Antennas Lecture 19 - Microstrip Antennas (MSA)
Link NOC:Antennas Lecture 20 - Rectangular MSA
Link NOC:Antennas Lecture 21 - MSA Parametric Analysis - I
Link NOC:Antennas Lecture 22 - MSA Parametric Analysis - II
Link NOC:Antennas Lecture 23 - Circular MSA
Link NOC:Antennas Lecture 24 - Broadband MSA - I
Link NOC:Antennas Lecture 25 - Broadband MSA - II
Link NOC:Antennas Lecture 26 - Broadband MSA - III
Link NOC:Antennas Lecture 27 - Broadband MSA - IV
Link NOC:Antennas Lecture 28 - Broadband MSA - V
Link NOC:Antennas Lecture 29 - Compact MSA - I
Link NOC:Antennas Lecture 30 - Compact MSA - II
Link NOC:Antennas Lecture 31 - Compact MSA - III
Link NOC:Antennas Lecture 32 - Tunable MSA - I
Link NOC:Antennas Lecture 33 - Tunable MSA - II
Link NOC:Antennas Lecture 34 - Circularly Polarized MSA - I
Link NOC:Antennas Lecture 35 - Circularly Polarized MSA - II
Link NOC:Antennas Lecture 36 - Circularly Polarized MSA - III
Link NOC:Antennas Lecture 37 - MSA Arrays - I
Link NOC:Antennas Lecture 38 - MSA Arrays - II
Link NOC:Antennas Lecture 39 - MSA Arrays - III
Link NOC:Antennas Lecture 40 - Helical Antennas - I
Link NOC:Antennas Lecture 41 - Helical Antennas - II
Link NOC:Antennas Lecture 42 - Helical Antennas - III
Link NOC:Antennas Lecture 43 - Helical Antennas - IV
Link NOC:Antennas Lecture 44 - Helical Antennas - V
Link NOC:Antennas Lecture 45 - Horn Antennas - I
Link NOC:Antennas Lecture 46 - Horn Antennas - II
Link NOC:Antennas Lecture 47 - Horn Antennas - III
Link NOC:Antennas Lecture 48 - Horn Antennas - IV
Link NOC:Antennas Lecture 49 - Horn Antennas - V
Link NOC:Antennas Lecture 50 - Yagi-Uda and Log-Periodic Antennas - I
Link NOC:Antennas Lecture 51 - Yagi-Uda and Log-Periodic Antennas - II
Link NOC:Antennas Lecture 52 - Yagi-Uda and Log-Periodic Antennas - III
Link NOC:Antennas Lecture 53 - IE3D Session TA - I
Link NOC:Antennas Lecture 54 - IE3D Session TA - II
Link NOC:Antennas Lecture 55 - IE3D Session TA - III
Link NOC:Antennas Lecture 56 - Reflector Antennas - I
Link NOC:Antennas Lecture 57 - Reflector Antennas - II
Link NOC:Antennas Lecture 58 - Reflector Antennas - III
Link NOC:Antennas Lecture 59 - Reflector Antennas - IV
Link NOC:Antennas Lecture 60 - Lab Session
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 1 - Module 1 - Lecture 1 - Introduction
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 2 - Module 1 - Lecture 2 - Origin of Wavelets
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 3 - Module 1 - Lecture 3 - Haar Wavelet
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 4 - Module 2 - Lecture 1 - Dyadic Wavelet
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 5 - Module 2 - Lecture 2 - Dilates and Translates of Haar Wavelets
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 6 - Module 2 - Lecture 3 - L2 Norm of a Function
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 7 - Module 3 - Lecture 1 - Piecewise Constant Representation of a Function
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 8 - Module 3 - Lecture 2 - Ladder of Subspaces
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 9 - Module 3 - Lecture 3 - Scaling Function for Haar Wavelet Demo
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 10 - Demonstration 1: Piecewise constant approximation of functions
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 11 - Module 4 - Lecture 1 - Vector Representation of Sequences
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 12 - Module 4 - Lecture 2 - Properties of Norm
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 13 - Module 4 - Lecture 3 - Parseval's Theorem
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 14 - Module 5 - Lecture 1 - Equivalence of sequences and functions
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 15 - Module 5 - Lecture 2 - Angle between Functions and their Decomposition
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 16 - Demonstration 2: Additional Information on Direct-Sum
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 17 - Module 6 - Lecture 1 - Introduction to filter banks
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 18 - Module 6 - Lecture 2 - Haar Analysis Filter Bank in Z-domain
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 19 - Module 6 - Lecture 3 - Haar Synthesis Filter Bank in Z-domain
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 20 - Module 7 - Lecture 1 - Moving from Z-domain to frequency domain
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 21 - Module 7 - Lecture 2 - Frequency Response of Haar Analysis Low pass Filter bank
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 22 - Module 7 - Lecture 3 - Frequency Response of Haar Analysis High pass Filter bank
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 23 - Module 8 - Lecture 1 - Ideal two-band filter bank
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 24 - Module 8 - Lecture 2 - Disqualification of Ideal filter bank
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 25 - Module 8 - Lecture 3 - Realizable two-band filter bank
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 26 - Demonstration 3: Demonstration: DWT of images
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 27 - Module 9 - Lecture 1 - Relating Fourier transform of scaling function to filter bank
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 28 - Module 9 - Lecture 2 - Fourier transform of scaling function
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 29 - Module 9 - Lecture 3 - Construction of scaling and wavelet functions from filter bank
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 30 - Demonstration 4: Demonstration: Constructing scaling and wavelet functions
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 31 - Module 10 - Lecture 1 - Introduction to upsampling and down sampling as Multirate operations
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 32 - Module 10 - Lecture 2 - Up sampling by a general factor M- a Z-domain analysis.
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 33 - Module 10 - Lecture 3 - Down sampling by a general factor M- a Z-domain analysis
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 34 - Module 11 - Lecture 1 - Z domain analysis of 2 channel filter bank.
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 35 - Module 11 - Lecture 2 - Effect of X (-Z) in time domain and aliasing
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 36 - Module 11 - Lecture 3 - Consequences of aliasing and simple approach to avoid it
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 37 - Module 12 - Lecture 1 - Revisiting aliasing and the Idea of perfect reconstruction
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 38 - Module 12 - Lecture 2 - Applying perfect reconstruction and alias cancellation on Haar MRA
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 39 - Module 12 - Lecture 3 - Introduction to Daubechies family of MRA
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 40 - Module 13 - Lecture 1 - Power Complementarity of low pass filter
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 41 - Module 13 - Lecture 2 - Applying perfect reconstruction condition to obtain filter coefficient
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 42 - Module 14 - Lecture 1 - Effect of minimum phase requirement on filter coefficients
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 43 - Module 14 - Lecture 2 - Building compactly supported scaling functions
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 44 - Module 14 - Lecture 3 - Second member of Daubechies family
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 45 - Module 15 - Lecture 1 - Fourier transform analysis of Haar scaling and Wavelet functions
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 46 - Module 15 - Lecture 2 - Revisiting Fourier Transform and Parseval's theorem
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 47 - Module 15 - Lecture 3 - Transform Analysis of Haar Wavelet function
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 48 - Module 16 - Lecture 1 - Nature of Haar scaling and Wavelet functions in frequency domain
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 49 - Module 16 - Lecture 2 - The Idea of Time-Frequency Resolution
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 50 - Module 16 - Lecture 3 - Some thoughts on Ideal time- frequency domain behavior
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 51 - Module 17 - Lecture 1 - Defining Probability Density function
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 52 - Module 17 - Lecture 2 - Defining Mean, Variance and “containment in a given domain”
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 53 - Module 17 - Lecture 3 - Example: Haar Scaling function
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 54 - Module 17 - Lecture 4 - Variance from a slightly different perspective
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 55 - Module 18 - Lecture 1 - Signal transformations: effect on mean and variance
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 56 - Module 18 - Lecture 2 - Time-Bandwidth product and its properties
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 57 - Module 18 - Lecture 3 - Simplification of Time-Bandwidth formulae
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 58 - Module 19 - Lecture 1 - Introduction
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 59 - Module 19 - Lecture 2 - Evaluation of Time-Bandwidth product
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 60 - Module 19 - Lecture 3 - Optimal function in the sense of Time-Bandwidth product
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 61 - Module 20 - Lecture 1 - Discontent with the “Optimal function”.
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 62 - Module 20 - Lecture 2 - Journey from infinite to finite Time-Bandwidth product of Haar scaling function
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 63 - Module 20 - Lecture 3 - More insights about Time-Bandwidth product
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 64 - Module 20 - Lecture 4 - Time-frequency plane
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 65 - Module 20 - Lecture 5 - Tiling the Time-frequency plane
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 66 - Module 21 - Lecture 1 - STFT: Conditions for valid windows
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 67 - Module 21 - Lecture 2 - STFT: Time domain and frequency domain formulations
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 68 - Module 21 - Lecture 3 - STFT: Duality in the interpretations
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 69 - Module 21 - Lecture 4 - Continuous Wavelet Transform (CWT)
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 70 - Demonstration 5
Link NOC:Fundamentals of Wavelets, Filter Banks and Time Frequency Analysis Lecture 71 - Student’s Presentation
Link NOC:Analog Circuits (2017) Lecture 1 - Module 1 - Introduction
Link NOC:Analog Circuits (2017) Lecture 2 - Module 2 - Poles and zeros
Link NOC:Analog Circuits (2017) Lecture 3 - Module 3 - OP-AMPs
Link NOC:Analog Circuits (2017) Lecture 4 - Module 4 - Application of Op-Amps
Link NOC:Analog Circuits (2017) Lecture 5 - Module 5 - Inverting amplifier and Non Inverting amplifier
Link NOC:Analog Circuits (2017) Lecture 6 - Module 1 - Non Idealities in Op-AMP (Finite Gain, Finite Bandwidth and Slew Rate)
Link NOC:Analog Circuits (2017) Lecture 7 - Module 2 - Non Idealities in Op-AMP (Offset Voltage and Bias Current)
Link NOC:Analog Circuits (2017) Lecture 8 - Module 3 - Bode Plot
Link NOC:Analog Circuits (2017) Lecture 9 - Module 4 - Frequency Response
Link NOC:Analog Circuits (2017) Lecture 10 - Module 1 - Frequency Response (High Frequency Response)
Link NOC:Analog Circuits (2017) Lecture 11 - Module 2 - Frequency Response example
Link NOC:Analog Circuits (2017) Lecture 12 - Module 3 - Feedback
Link NOC:Analog Circuits (2017) Lecture 13 - Module 4 - Effects of Feedback
Link NOC:Analog Circuits (2017) Lecture 14 - Tutorial 1 and 2
Link NOC:Analog Circuits (2017) Lecture 15 - Module 1 - Effect of feedback and stability
Link NOC:Analog Circuits (2017) Lecture 16 - Module 2 - Stability
Link NOC:Analog Circuits (2017) Lecture 17 - Module 3 - Stability and pole location
Link NOC:Analog Circuits (2017) Lecture 18 - Module 4 - Stability and Pole location continuation
Link NOC:Analog Circuits (2017) Lecture 19 - Tutorial 3
Link NOC:Analog Circuits (2017) Lecture 20 - Module 1 - Gain Margin – An example
Link NOC:Analog Circuits (2017) Lecture 21 - Module 2 - Frequency Compensation
Link NOC:Analog Circuits (2017) Lecture 22 - Module 3 - Filters
Link NOC:Analog Circuits (2017) Lecture 23 - Module 4 - Filter prototypes
Link NOC:Analog Circuits (2017) Lecture 24 - Tutorial 4
Link NOC:Analog Circuits (2017) Lecture 25 - Tutorial 5
Link NOC:Analog Circuits (2017) Lecture 26 - Tutorial 6
Link NOC:Analog Circuits (2017) Lecture 27 - Module 1 - Chebyshev Prototype, Filter transformation
Link NOC:Analog Circuits (2017) Lecture 28 - Module 2 - Filter Transformations (Continued....)
Link NOC:Analog Circuits (2017) Lecture 29 - Module 3 - Active Filters
Link NOC:Analog Circuits (2017) Lecture 30 - Module 4 - Non Linear Applications of OPAMPS
Link NOC:Analog Circuits (2017) Lecture 31 - Module 5 - Limiter, Diodes
Link NOC:Analog Circuits (2017) Lecture 32 - Module 1 - Oscillators
Link NOC:Analog Circuits (2017) Lecture 33 - Module 2 - Oscillator Amplitude Control , Quadrature Oscillator
Link NOC:Analog Circuits (2017) Lecture 34 - Module 3 - Multivibators
Link NOC:Analog Circuits (2017) Lecture 35 - Module 4 - Multivibrators (Continued...)
Link NOC:Analog Circuits (2017) Lecture 36 - Module 5 - Monostable Multivibator
Link NOC:Analog Circuits (2017) Lecture 37 - Module 1 - Zener Effect, Rectifiers
Link NOC:Analog Circuits (2017) Lecture 38 - Module 2 - Rectifiers
Link NOC:Analog Circuits (2017) Lecture 39 - Module 3 - Clamper, Peak Rectifier, Super diodes
Link NOC:Analog Circuits (2017) Lecture 40 - Module 4 - BJT DC Circuits
Link NOC:Analog Circuits (2017) Lecture 41 - Module 5 - Current Mirror
Link NOC:Microwave Theory and Techniques Lecture 1 - Microwave Theory and Techniques Introduction - I
Link NOC:Microwave Theory and Techniques Lecture 2 - Microwave Theory and Techniques Introduction - II
Link NOC:Microwave Theory and Techniques Lecture 3 - Microwave Theory and Techniques Introduction - III
Link NOC:Microwave Theory and Techniques Lecture 4 - Effects of Microwaves on Human Body - I
Link NOC:Microwave Theory and Techniques Lecture 5 - Effects of Microwaves on Human Body - II
Link NOC:Microwave Theory and Techniques Lecture 6 - Waveguides - I: Parallel Plane Waveguides
Link NOC:Microwave Theory and Techniques Lecture 7 - Waveguides - II: Parallel Plane Waveguides
Link NOC:Microwave Theory and Techniques Lecture 8 - Waveguides - III: Rectangular Waveguides
Link NOC:Microwave Theory and Techniques Lecture 9 - Transmission Lines - I: Coaxial Cables, Strip Lines and Microstrip Lines
Link NOC:Microwave Theory and Techniques Lecture 10 - Transmission Lines - II: Transmission Line Model, Open and Short Circuited Lossless Transmission Lines
Link NOC:Microwave Theory and Techniques Lecture 11 - Smith Chart and Impedance Matching - I: using Quarter Wave Transformer
Link NOC:Microwave Theory and Techniques Lecture 12 - Smith Chart and Impedance Matching - II: using Lumped Components
Link NOC:Microwave Theory and Techniques Lecture 13 - Smith Chart and Impedance Matching - III: using Short and Open Circuited Stubs
Link NOC:Microwave Theory and Techniques Lecture 14 - ABCD - Parameters
Link NOC:Microwave Theory and Techniques Lecture 15 - S - Parameters
Link NOC:Microwave Theory and Techniques Lecture 16 - Power Dividers - I: Two-way, Three-way and Four-way Equal Power Dividers
Link NOC:Microwave Theory and Techniques Lecture 17 - Power Dividers - II: Unequal, Broadband and Compact Power Dividers
Link NOC:Microwave Theory and Techniques Lecture 18 - Microwave Couplers - I: Coupled Line Directional Couplers
Link NOC:Microwave Theory and Techniques Lecture 19 - Microwave Couplers - II: Branch Line Couplers
Link NOC:Microwave Theory and Techniques Lecture 20 - Microwave Couplers - III: Rat race Coupler and Applications
Link NOC:Microwave Theory and Techniques Lecture 21 - Microwave Filters - I: Filters and Low Pass Butterworth Filter
Link NOC:Microwave Theory and Techniques Lecture 22 - Microwave Filters - II: Low Pass Chebyshev Filters
Link NOC:Microwave Theory and Techniques Lecture 23 - Microwave Filters - III: Microstrip Realization, Transformation from LPF to other Filters
Link NOC:Microwave Theory and Techniques Lecture 24 - Microwave Filters - IV: Band Pass Filters
Link NOC:Microwave Theory and Techniques Lecture 25 - Microwave Filters - V: Coupled Line and Tunable Band Pass Filters
Link NOC:Microwave Theory and Techniques Lecture 26 - Microwave Diodes: PN Junction , Varactor, Schottky, PIN, Tunnel, and GUNN Diodes
Link NOC:Microwave Theory and Techniques Lecture 27 - Microwave Attenuators: Fixed and Variable Attenuators
Link NOC:Microwave Theory and Techniques Lecture 28 - Microwave RF Switches: Series and Shunt SPST
Link NOC:Microwave Theory and Techniques Lecture 29 - Series and Shunt SPDT Switches and Introduction to Phase Shifters
Link NOC:Microwave Theory and Techniques Lecture 30 - Microwave Phase Shifters: Switched and Loaded Line
Link NOC:Microwave Theory and Techniques Lecture 31 - Microwave Transistors: BJT, HBT, JFET, MOSFET, MESFET and HEMT
Link NOC:Microwave Theory and Techniques Lecture 32 - Microwave Amplifiers - I: Basics and Power Gain Expressions
Link NOC:Microwave Theory and Techniques Lecture 33 - Microwave Amplifiers - II: Stability and Constant Gain Circles
Link NOC:Microwave Theory and Techniques Lecture 34 - Microwave Amplifiers - III: Design Example
Link NOC:Microwave Theory and Techniques Lecture 35 - Low Noise Amplifiers - I: Noise Sources and Noise Figure
Link NOC:Microwave Theory and Techniques Lecture 36 - Low Noise Amplifiers - II: NF Circles and LNA Design
Link NOC:Microwave Theory and Techniques Lecture 37 - Power Amplifiers
Link NOC:Microwave Theory and Techniques Lecture 38 - Microwave Tubes - I : Linear Beam Tubes- Two Cavity Klystron
Link NOC:Microwave Theory and Techniques Lecture 39 - Microwave Tubes - II: Linear Beam Tubes- Reflex Klystron and TWT
Link NOC:Microwave Theory and Techniques Lecture 40 - Microwave Tubes - III: Crossed Field Tubes- Magnetron
Link NOC:Microwave Theory and Techniques Lecture 41 - Microwave Oscillators - I
Link NOC:Microwave Theory and Techniques Lecture 42 - Microwave Oscillators - II
Link NOC:Microwave Theory and Techniques Lecture 43 - Microwave Mixers - I: Fundamentals
Link NOC:Microwave Theory and Techniques Lecture 44 - Microwave Mixers - II: Circuits
Link NOC:Microwave Theory and Techniques Lecture 45 - Microwave Mixers - III: Design
Link NOC:Microwave Theory and Techniques Lecture 46 - Fundamentals of Antennas
Link NOC:Microwave Theory and Techniques Lecture 47 - Dipole, Monopole, loop and Slot Antennas
Link NOC:Microwave Theory and Techniques Lecture 48 - Linear and Planar Arrays
Link NOC:Microwave Theory and Techniques Lecture 49 - Microstrip Antennas
Link NOC:Microwave Theory and Techniques Lecture 50 - Horn and Helical Antennas
Link NOC:Microwave Theory and Techniques Lecture 51 - Yagi - Uda, Log-Periodic and Reflector Antennas
Link NOC:Microwave Theory and Techniques Lecture 52 - RF MEMS and Microwave Imaging
Link NOC:Microwave Theory and Techniques Lecture 53 - Microwave Systems
Link NOC:Microwave Theory and Techniques Lecture 54 - Microwave Measurements and Lab Demonstration
Link NOC:Microwave Theory and Techniques Lecture 55 - CST Software Introduction with Filter Design
Link NOC:Microwave Theory and Techniques Lecture 56 - Power Divider and Combiner Design in CST
Link NOC:Microwave Theory and Techniques Lecture 57 - Hybrid Coupler Design
Link NOC:Microwave Theory and Techniques Lecture 58 - Antenna Design and Amplifier Simulation in CST
Link NOC:Microwave Theory and Techniques Lecture 59 - Mixer Design in NI AWR Software - I
Link NOC:Microwave Theory and Techniques Lecture 60 - Mixer Design in NI AWR Software - II
Link NOC:Principles of Digital Communications Lecture 1 - Course Overview
Link NOC:Principles of Digital Communications Lecture 2 - Introduction to Information Theory
Link NOC:Principles of Digital Communications Lecture 3 - Entropy and its properties
Link NOC:Principles of Digital Communications Lecture 4 - Lossless Source Coding Theorem
Link NOC:Principles of Digital Communications Lecture 5 - Prefix Codes and Kraft’s Inequality
Link NOC:Principles of Digital Communications Lecture 6 - Huffman Coding
Link NOC:Principles of Digital Communications Lecture 7 - Discrete Memory-less Channels : Mutual Information
Link NOC:Principles of Digital Communications Lecture 8 - Channel Capacity - I
Link NOC:Principles of Digital Communications Lecture 9 - Channel Capacity - II
Link NOC:Principles of Digital Communications Lecture 10 - Channel Coding Theorem
Link NOC:Principles of Digital Communications Lecture 11 - Differential Entropy - I
Link NOC:Principles of Digital Communications Lecture 12 - Differential Entropy - II
Link NOC:Principles of Digital Communications Lecture 13 - Channel Capacity - III
Link NOC:Principles of Digital Communications Lecture 14 - Channel Capacity - IV
Link NOC:Principles of Digital Communications Lecture 15 - Summary of Information Theory
Link NOC:Principles of Digital Communications Lecture 16 - Signal Space Representations - I
Link NOC:Principles of Digital Communications Lecture 17 - Signal Space Representations - II
Link NOC:Principles of Digital Communications Lecture 18 - Vector Representation of a Random Process
Link NOC:Principles of Digital Communications Lecture 19 - AWGN Vector Channel
Link NOC:Principles of Digital Communications Lecture 20 - Basics of Signal Detection: ML,MAP Detection
Link NOC:Principles of Digital Communications Lecture 21 - ML,MAP Detectors for AWGN Channel
Link NOC:Principles of Digital Communications Lecture 22 - Optimal Receiver: Matched Filter
Link NOC:Principles of Digital Communications Lecture 23 - Probability of error for Optimal Receiver
Link NOC:Principles of Digital Communications Lecture 24 - Probability of Error for M-ary Scheme
Link NOC:Principles of Digital Communications Lecture 25 - Pulse Code Modulation: Quantization
Link NOC:Principles of Digital Communications Lecture 26 - Uniform Quantizer
Link NOC:Principles of Digital Communications Lecture 27 - Step Size and Quantization Noise
Link NOC:Principles of Digital Communications Lecture 28 - Non-uniform Quantizer (Lloyd-Max Quantizer)
Link NOC:Principles of Digital Communications Lecture 29 - Companded Quantization - I
Link NOC:Principles of Digital Communications Lecture 30 - Companded Quantization - II
Link NOC:Principles of Digital Communications Lecture 31 - Differential Pulse Code Modulation DPCM - I
Link NOC:Principles of Digital Communications Lecture 32 - DPCM-II (Linear Prediction)
Link NOC:Principles of Digital Communications Lecture 33 - Delta Modulation
Link NOC:Principles of Digital Communications Lecture 34 - M-ary PCM/PAM - I
Link NOC:Principles of Digital Communications Lecture 35 - M-ary PCM/PAM - II
Link NOC:Principles of Digital Communications Lecture 36 - Line Coding - I
Link NOC:Principles of Digital Communications Lecture 37 - Line Coding - II
Link NOC:Principles of Digital Communications Lecture 38 - Line Coding - III
Link NOC:Principles of Digital Communications Lecture 39 - Pulse Shaping for Zero ISI - I
Link NOC:Principles of Digital Communications Lecture 40 - Pulse Shaping for Zero ISI - II
Link NOC:Principles of Digital Communications Lecture 41 - Pulse Shaping for Zero ISI - III
Link NOC:Principles of Digital Communications Lecture 42 - Partial Response Signaling - I
Link NOC:Principles of Digital Communications Lecture 43 - Partial Response Signaling - II
Link NOC:Principles of Digital Communications Lecture 44 - Principle of Invariance of Probability of Error
Link NOC:Principles of Digital Communications Lecture 45 - Binary ASK and PSK
Link NOC:Principles of Digital Communications Lecture 46 - Binary Frequency Shift Keying - I
Link NOC:Principles of Digital Communications Lecture 47 - Binary Frequency Shift Keying - II
Link NOC:Principles of Digital Communications Lecture 48 - Quadrature Phase Shift Keying - I
Link NOC:Principles of Digital Communications Lecture 49 - Quadrature Phase Shift Keying - II
Link NOC:Principles of Digital Communications Lecture 50 - Quadrature Phase Shift Keying - III
Link NOC:Principles of Digital Communications Lecture 51 - Continuous Phase Frequency Shift Keying
Link NOC:Principles of Digital Communications Lecture 52 - Minimum Shift Keying - I
Link NOC:Principles of Digital Communications Lecture 53 - Minimum Shift Keying - II
Link NOC:Principles of Digital Communications Lecture 54 - M-ary Coherent ASK (M-ASK)
Link NOC:Principles of Digital Communications Lecture 55 - M-ary PSK
Link NOC:Principles of Digital Communications Lecture 56 - M-ary Quadrature Amplitude Modulation (M-QAM)
Link NOC:Principles of Digital Communications Lecture 57 - M-ary FSK
Link NOC:Principles of Digital Communications Lecture 58 - Comparison of M-ary Schemes
Link NOC:Principles of Digital Communications Lecture 59 - Non-coherent BFSK
Link NOC:Principles of Digital Communications Lecture 60 - Differential Phase Shift Keying
Link NOC:Principles of Digital Communications Lecture 61 - Channel Coding - I
Link NOC:Principles of Digital Communications Lecture 62 - Channel Coding - II
Link NOC:Principles of Digital Communications Lecture 63 - Channel Coding - III
Link NOC:Principles of Digital Communications Lecture 64 - Channel Coding: Hamming Codes
Link NOC:Principles of Digital Communications Lecture 65 - Channel Coding: Decoding using Standard Arrays
Link NOC:Fundamental of Power Electronics Lecture 1 - Familiarization with Power Electronic Systems
Link NOC:Fundamental of Power Electronics Lecture 2 - Overview of Basic Power Electronic Circuits from Laymans Point of View
Link NOC:Fundamental of Power Electronics Lecture 3 - Applications, Definitions, and Nature of Power Electronic Circuits
Link NOC:Fundamental of Power Electronics Lecture 4 - Components of a Power Electronic System
Link NOC:Fundamental of Power Electronics Lecture 5 - Analysis of Switched Networks
Link NOC:Fundamental of Power Electronics Lecture 6 - Review of engineering maths for power electronic circuit analysis
Link NOC:Fundamental of Power Electronics Lecture 7 - Review of semiconductor physics
Link NOC:Fundamental of Power Electronics Lecture 8 - P-N Junction
Link NOC:Fundamental of Power Electronics Lecture 9 - Power Diodes
Link NOC:Fundamental of Power Electronics Lecture 10 - Thyristors
Link NOC:Fundamental of Power Electronics Lecture 11 - Motivation for rectifier capacitor filter
Link NOC:Fundamental of Power Electronics Lecture 12 - Circuit Operation
Link NOC:Fundamental of Power Electronics Lecture 13 - Designing the circuit
Link NOC:Fundamental of Power Electronics Lecture 14 - Simulation setup for NgSpice and gEDA schematic capture
Link NOC:Fundamental of Power Electronics Lecture 15 - Simulating the circuit
Link NOC:Fundamental of Power Electronics Lecture 16 - Practicals
Link NOC:Fundamental of Power Electronics Lecture 17 - Inrush current limiting - Intro
Link NOC:Fundamental of Power Electronics Lecture 18 - Inrush current limiting - Resistor solution
Link NOC:Fundamental of Power Electronics Lecture 19 - Inrush current limiting - Thermistor solution
Link NOC:Fundamental of Power Electronics Lecture 20 - Inrush current limiting - Transformer solution
Link NOC:Fundamental of Power Electronics Lecture 21 - Inrush current limiting - MOSFET solution
Link NOC:Fundamental of Power Electronics Lecture 22 - Inrush current limiting - Relay, contactor
Link NOC:Fundamental of Power Electronics Lecture 23 - Three phase rectifier capacitor filter
Link NOC:Fundamental of Power Electronics Lecture 24 - Simulation - 3 phase rectifier capacitor filter
Link NOC:Fundamental of Power Electronics Lecture 25 - Power factor - Motivation
Link NOC:Fundamental of Power Electronics Lecture 26 - Power factor - Discussion
Link NOC:Fundamental of Power Electronics Lecture 27 - Power factor - Sinusoidal
Link NOC:Fundamental of Power Electronics Lecture 28 - Power factor for rectifier cap filter
Link NOC:Fundamental of Power Electronics Lecture 29 - Passive power improvement circuit
Link NOC:Fundamental of Power Electronics Lecture 30 - Simulation - power factor improvement
Link NOC:Fundamental of Power Electronics Lecture 31 - Linear regulators - Intro
Link NOC:Fundamental of Power Electronics Lecture 32 - Shunt regulator
Link NOC:Fundamental of Power Electronics Lecture 33 - Example on shunt regulator
Link NOC:Fundamental of Power Electronics Lecture 34 - Non-ideality and solution
Link NOC:Fundamental of Power Electronics Lecture 35 - Applications of shunt regulator
Link NOC:Fundamental of Power Electronics Lecture 36 - Series regulator
Link NOC:Fundamental of Power Electronics Lecture 37 - Efficiency of series
Link NOC:Fundamental of Power Electronics Lecture 38 - Negative and dual voltage regulators
Link NOC:Fundamental of Power Electronics Lecture 39 - Over current limiting circuits
Link NOC:Fundamental of Power Electronics Lecture 40 - Improvements to series regulator
Link NOC:Fundamental of Power Electronics Lecture 41 - Regulator performance parameters
Link NOC:Fundamental of Power Electronics Lecture 42 - Datasheet of few IC regulators
Link NOC:Fundamental of Power Electronics Lecture 43 - Common IC regulator circuits
Link NOC:Fundamental of Power Electronics Lecture 44 - Practicals 1
Link NOC:Fundamental of Power Electronics Lecture 45 - Switched mode DC-DC converter intro
Link NOC:Fundamental of Power Electronics Lecture 46 - Volt-sec and Amp-sec balance
Link NOC:Fundamental of Power Electronics Lecture 47 - Input-output relationship
Link NOC:Fundamental of Power Electronics Lecture 48 - Buck converter - operation and waveforms
Link NOC:Fundamental of Power Electronics Lecture 49 - Buck converter - component selection
Link NOC:Fundamental of Power Electronics Lecture 50 - Primary configurations
Link NOC:Fundamental of Power Electronics Lecture 51 - Boost converter
Link NOC:Fundamental of Power Electronics Lecture 52 - Buck-Boost converter
Link NOC:Fundamental of Power Electronics Lecture 53 - Simulating the primary converters
Link NOC:Fundamental of Power Electronics Lecture 54 - Forward converter
Link NOC:Fundamental of Power Electronics Lecture 55 - Core reset in forward converter
Link NOC:Fundamental of Power Electronics Lecture 56 - Simulating with lossy core reset
Link NOC:Fundamental of Power Electronics Lecture 57 - Simulating with lossless core reset
Link NOC:Fundamental of Power Electronics Lecture 58 - Flyback converter
Link NOC:Fundamental of Power Electronics Lecture 59 - Simulating the flyback converter
Link NOC:Fundamental of Power Electronics Lecture 60 - Octave mfile for design
Link NOC:Fundamental of Power Electronics Lecture 61 - Magnetics design intro
Link NOC:Fundamental of Power Electronics Lecture 62 - Magnetics review
Link NOC:Fundamental of Power Electronics Lecture 63 - Permeance
Link NOC:Fundamental of Power Electronics Lecture 64 - Inductor value and energy storage
Link NOC:Fundamental of Power Electronics Lecture 65 - Inductor area product
Link NOC:Fundamental of Power Electronics Lecture 66 - Inductor design
Link NOC:Fundamental of Power Electronics Lecture 67 - Inductor example
Link NOC:Fundamental of Power Electronics Lecture 68 - Transformer design
Link NOC:Fundamental of Power Electronics Lecture 69 - Transformer example
Link NOC:Fundamental of Power Electronics Lecture 70 - Forward converter design mfile
Link NOC:Fundamental of Power Electronics Lecture 71 - Pushpull converter
Link NOC:Fundamental of Power Electronics Lecture 72 - Flux walking in pushpull
Link NOC:Fundamental of Power Electronics Lecture 73 - PWM generation
Link NOC:Fundamental of Power Electronics Lecture 74 - Simulation of pushpull converter
Link NOC:Fundamental of Power Electronics Lecture 75 - Half bridge converter
Link NOC:Fundamental of Power Electronics Lecture 76 - Simulation of halfbridge converter
Link NOC:Fundamental of Power Electronics Lecture 77 - Full bridge converter
Link NOC:Fundamental of Power Electronics Lecture 78 - Simulation of fullbridge converter
Link NOC:Fundamental of Power Electronics Lecture 79 - Area products and mfiles
Link NOC:Fundamental of Power Electronics Lecture 80 - Intro for drive circuits
Link NOC:Fundamental of Power Electronics Lecture 81 - BJT base drive
Link NOC:Fundamental of Power Electronics Lecture 82 - BJT base drive example
Link NOC:Fundamental of Power Electronics Lecture 83 - Multi-stage base drive
Link NOC:Fundamental of Power Electronics Lecture 84 - Base drive with speed-up circuit
Link NOC:Fundamental of Power Electronics Lecture 85 - Base drive with isolation
Link NOC:Fundamental of Power Electronics Lecture 86 - MOSFET gate drive
Link NOC:Fundamental of Power Electronics Lecture 87 - MOSFET drive with isolation
Link NOC:Fundamental of Power Electronics Lecture 88 - Over-current protection
Link NOC:Fundamental of Power Electronics Lecture 89 - Snubber circuits
Link NOC:Fundamental of Power Electronics Lecture 90 - Intro for close loop control
Link NOC:Fundamental of Power Electronics Lecture 91 - Close looping dc-dc converters
Link NOC:Fundamental of Power Electronics Lecture 92 - Simulation of close loop control
Link NOC:Fundamental of Power Electronics Lecture 93 - Current control for battery charger application
Link NOC:Fundamental of Power Electronics Lecture 94 - Instability in current control and slope compensation
Link NOC:Fundamental of Power Electronics Lecture 95 - Slope compensated current control
Link NOC:Fundamental of Power Electronics Lecture 96 - Simulation of current control
Link NOC:Fundamental of Power Electronics Lecture 97 - Single phase inverter with sinusoidal pwm
Link NOC:Fundamental of Power Electronics Lecture 98 - Simulation of sinusoidal PWM
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 1 - Course Outline and Introduction
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 2 - Analytical and Numerical Methods
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 3 - Revisiting EM Concepts: Vector Algebra and Coordinate Systems
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 4 - Revisiting EM Concepts: Vector Calculus and Electrostatics
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 5 - Revisiting EM Concepts: Current Densities and Electric Fields in Materials
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 6 - Revisiting EM Concepts: Electrostatic Boundary Conditions and Shielding
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 7 - Revisiting EM Concepts: Magnetostatics
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 8 - Revisiting EM Concepts: Magnetic Forces and Materials
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 9 - Revisiting EM Concepts: Time Varying Fields
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 10 - Revisiting EM Concepts: Theory of Eddy Currents
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 11 - FEM: Variational Approach
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 12 - Finding Functional for PDEs
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 13 - Whole Domain Approximation
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 14 - 1D FEM: Problem Definition and Shape Function
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 15 - 1D FEM: Procedure
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 16 - 1D FEM: Scilab Code
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 17 - 2D FEM: Problem Definition and Shape Functions
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 18 - 2D FEM: Procedure
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 19 - 2D FEM Scilab Code: Manual Meshing
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 20 - 2D FEM Code: Gmsh and Scilab
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 21 - Computation of B and H Field and Method of Weighted Residuals
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 22 - Galerkin Method
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 23 - Calculation of Leakage Inductance of a Transformer
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 24 - Calculation of Inductance of an Induction Motor and a Gapped-Core Shunt Reactor
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 25 - Insulation Design Using FE Analysis
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 26 - Quadratic Finite Elements
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 27 - Time Harmonic FE Analysis
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 28 - Calculation of Eddy Current Losses
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 29 - Eddy Losses in Transformer Windings
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 30 - Torque Speed Characteristics of an Induction Motor and FE Analysis of Axisymmetric Problem
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 31 - Permanent Magnets: Theory
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 32 - Permanent Magnets: FEM Implementation
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 33 - Periodic and Antiperiodic Boundary Conditions in Rotating Machines
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 34 - FE Analysis of Rotating Machines
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 35 - Voltage Fed Coupled Circuit Field Analysis
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 36 - Current Fed Coupled Circuit Field Analysis
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 37 - Transient FE Analysis
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 38 - Nonlinear FE Analysis
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 39 - Computation of Forces using Maxwell Stress Tensor
Link NOC:Electrical Equipment and Machines: Finite Element Analysis Lecture 40 - Computation of force using virtual work method
Link NOC:Digital Signal Processing and its Applications Lecture 1 - Introduction: Digital signal processing and its objectives
Link NOC:Digital Signal Processing and its Applications Lecture 2 - Introduction to sampling and Fourier Transform
Link NOC:Digital Signal Processing and its Applications Lecture 3 - Sampling of sine wave and associate complication
Link NOC:Digital Signal Processing and its Applications Lecture 4 - Review of Sampling Theorem
Link NOC:Digital Signal Processing and its Applications Lecture 5 - Idealized Sampling, Reconstruction
Link NOC:Digital Signal Processing and its Applications Lecture 6 - Filters And Discrete System
Link NOC:Digital Signal Processing and its Applications Lecture 7 - Answering questions from previous lectures
Link NOC:Digital Signal Processing and its Applications Lecture 8 - Desired requirements for discrete system
Link NOC:Digital Signal Processing and its Applications Lecture 9 - Introduction to phasors
Link NOC:Digital Signal Processing and its Applications Lecture 10 - Advantages of phasors in discrete systems
Link NOC:Digital Signal Processing and its Applications Lecture 11 - What do we want from a discrete system?
Link NOC:Digital Signal Processing and its Applications Lecture 12 - Linearity - Homogeneity and Additivity
Link NOC:Digital Signal Processing and its Applications Lecture 13 - Shift Invariance and Characterization of LTI systems
Link NOC:Digital Signal Processing and its Applications Lecture 14 - Characterization of LSI system using it’s impulse response
Link NOC:Digital Signal Processing and its Applications Lecture 15 - Introduction to convolution
Link NOC:Digital Signal Processing and its Applications Lecture 16 - Convolution: Deeper ideas and understanding
Link NOC:Digital Signal Processing and its Applications Lecture 17 - Characterisation of LSI systems, Convolution-properties
Link NOC:Digital Signal Processing and its Applications Lecture 18 - Response of LSI Systems to Complex Sinusoids
Link NOC:Digital Signal Processing and its Applications Lecture 19 - Convergence of Convolution and Bibo Stability
Link NOC:Digital Signal Processing and its Applications Lecture 20 - Commutativity and Associativity
Link NOC:Digital Signal Processing and its Applications Lecture 21 - BIBO Stability of an LSI system
Link NOC:Digital Signal Processing and its Applications Lecture 22 - Causality and memory of an LSI system
Link NOC:Digital Signal Processing and its Applications Lecture 23 - Frequency response of an LSI system
Link NOC:Digital Signal Processing and its Applications Lecture 24 - Introduction and conditions of Stability
Link NOC:Digital Signal Processing and its Applications Lecture 25 - Vectors and Inner Product
Link NOC:Digital Signal Processing and its Applications Lecture 26 - Interpretation of Frequency Response as Dot Product
Link NOC:Digital Signal Processing and its Applications Lecture 27 - Interpretation of Frequency Response as Eigenvalues
Link NOC:Digital Signal Processing and its Applications Lecture 28 - Discrete time fourier transform
Link NOC:Digital Signal Processing and its Applications Lecture 29 - DTFT in LSI System and Convolution Theorem.
Link NOC:Digital Signal Processing and its Applications Lecture 30 - Definitions of sequences and Properties of DTFT
Link NOC:Digital Signal Processing and its Applications Lecture 31 - Introduction to DTFT, IDTFT
Link NOC:Digital Signal Processing and its Applications Lecture 32 - Dual to convolution property
Link NOC:Digital Signal Processing and its Applications Lecture 33 - Multiplication Property, Introduction to Parseval’s theorem
Link NOC:Digital Signal Processing and its Applications Lecture 34 - Introduction and Property of DTFT
Link NOC:Digital Signal Processing and its Applications Lecture 35 - Review of Inverse DTFT
Link NOC:Digital Signal Processing and its Applications Lecture 36 - Parseval’s Theorem and energy and time spectral density
Link NOC:Digital Signal Processing and its Applications Lecture 37 - Discussion on Unit Step
Link NOC:Digital Signal Processing and its Applications Lecture 38 - Introduction to Z transform
Link NOC:Digital Signal Processing and its Applications Lecture 39 - Example of Z transform
Link NOC:Digital Signal Processing and its Applications Lecture 40 - Region of Convergence
Link NOC:Digital Signal Processing and its Applications Lecture 41 - Properties of Z transform
Link NOC:Digital Signal Processing and its Applications Lecture 42 - Z- Transform
Link NOC:Digital Signal Processing and its Applications Lecture 43 - Rational System
Link NOC:Digital Signal Processing and its Applications Lecture 44 - Introduction and Examples of Rational Z Transform and their Inverses
Link NOC:Digital Signal Processing and its Applications Lecture 45 - Double Pole Examples and their Inverse Z Transform
Link NOC:Digital Signal Processing and its Applications Lecture 46 - Partial Fraction Decomposition
Link NOC:Digital Signal Processing and its Applications Lecture 47 - LSI System Examples
Link NOC:Digital Signal Processing and its Applications Lecture 48 - Why are Rational Systems so important?
Link NOC:Digital Signal Processing and its Applications Lecture 49 - Solving Linear constant coefficient difference equations which are valid over a finite range of time
Link NOC:Digital Signal Processing and its Applications Lecture 50 - Introduction to Resonance in Rational Systems
Link NOC:Digital Signal Processing and its Applications Lecture 51 - Characterization of Rational LSI system
Link NOC:Digital Signal Processing and its Applications Lecture 52 - Causality and stability of the ROC of the system function
Link NOC:Digital Signal Processing and its Applications Lecture 53 - Recap of Rational Systems and Discrete Time Filters
Link NOC:Digital Signal Processing and its Applications Lecture 54 - Specifications for Filter Design
Link NOC:Digital Signal Processing and its Applications Lecture 55 - Four Ideal Piecewise Constant Filters
Link NOC:Digital Signal Processing and its Applications Lecture 56 - Important Characteristics Of Ideal Filters
Link NOC:Digital Signal Processing and its Applications Lecture 57 - Synthesis of Discrete Time Filters, Realizable specifications
Link NOC:Digital Signal Processing and its Applications Lecture 58 - Realistic Specifications for low pass filter. Filter Design Process
Link NOC:Digital Signal Processing and its Applications Lecture 59 - Introduction to Filter Design. Analog IIR Filter,FIR discrete-time filter, IIR discrete-time filter
Link NOC:Digital Signal Processing and its Applications Lecture 60 - Analog to discrete transform
Link NOC:Digital Signal Processing and its Applications Lecture 61 - Intuitive transforms, Bilinear Transformation
Link NOC:Digital Signal Processing and its Applications Lecture 62 - Steps for IIR filter design
Link NOC:Digital Signal Processing and its Applications Lecture 63 - Analog filter design using Butterworth Approximation
Link NOC:Digital Signal Processing and its Applications Lecture 64 - Butterworth filter Derivation And Analysis of butterworth system function
Link NOC:Digital Signal Processing and its Applications Lecture 65 - Chebychev filter Derivation
Link NOC:Digital Signal Processing and its Applications Lecture 66 - Midsem paper review discussion
Link NOC:Digital Signal Processing and its Applications Lecture 67 - The Chebyschev Approximation
Link NOC:Digital Signal Processing and its Applications Lecture 68 - Next step in design: Obtain poles
Link NOC:Digital Signal Processing and its Applications Lecture 69 - Introduction to Frequency Transformations in the Analog Domain
Link NOC:Digital Signal Processing and its Applications Lecture 70 - High pass transformation
Link NOC:Digital Signal Processing and its Applications Lecture 71 - Band pass transformation
Link NOC:Digital Signal Processing and its Applications Lecture 72 - Frequency Transformation
Link NOC:Digital Signal Processing and its Applications Lecture 73 - Different types of filters
Link NOC:Digital Signal Processing and its Applications Lecture 74 - Impulse invariant method and ideal impulse response
Link NOC:Digital Signal Processing and its Applications Lecture 75 - Design of FIR of length (2N+1) by the truncation method,Plotting the function V(w)
Link NOC:Digital Signal Processing and its Applications Lecture 76 - IIR filter using rectangular window, IIR filter using triangular window
Link NOC:Digital Signal Processing and its Applications Lecture 77 - Proof that frequency response of an fir filter using rectangular window function centred at 0 is real
Link NOC:Digital Signal Processing and its Applications Lecture 78 - Introduction to window functions
Link NOC:Digital Signal Processing and its Applications Lecture 79 - Examples of window functions
Link NOC:Digital Signal Processing and its Applications Lecture 80 - Explanation of Gibb’s Phenomenon and it’s application
Link NOC:Digital Signal Processing and its Applications Lecture 81 - Comparison of FIR And IIR Filter’s
Link NOC:Digital Signal Processing and its Applications Lecture 82 - Comparison of FIR And IIR Filter’s
Link NOC:Digital Signal Processing and its Applications Lecture 83 - Comparison of FIR And IIR Filter’s
Link NOC:Digital Signal Processing and its Applications Lecture 84 - Introduction and approach to realization (causal rational system)
Link NOC:Digital Signal Processing and its Applications Lecture 85 - Comprehension of Signal Flow Graphs and Achievement of Pseudo Assembly Language Code
Link NOC:Digital Signal Processing and its Applications Lecture 86 - Introduction to IIR Filter Realization and Cascade Structure
Link NOC:Digital Signal Processing and its Applications Lecture 87 - Cascade Parallel Structure
Link NOC:Digital Signal Processing and its Applications Lecture 88 - Lattice Structure
Link NOC:Digital Signal Processing and its Applications Lecture 89 - Recap And Review of Lattice Structure, Realization of FIR Function
Link NOC:Digital Signal Processing and its Applications Lecture 90 - Backward recursion, Change in the recursive equation of lattice
Link NOC:Digital Signal Processing and its Applications Lecture 91 - Lattice structure for an arbitrary rational system
Link NOC:Digital Signal Processing and its Applications Lecture 92 - Example realization of lattice structure for rational system
Link NOC:Digital Signal Processing and its Applications Lecture 93 - Introductory Remarks of Discrete Fourier Transform and Frequency Domain Sampling
Link NOC:Digital Signal Processing and its Applications Lecture 94 - Principle of Duality, The Circular Convolution
Link NOC:Stochastic Control and Communication Lecture 1 - Decision Making under Uncertainty
Link NOC:Stochastic Control and Communication Lecture 2 - Expected Utility Theory - I
Link NOC:Stochastic Control and Communication Lecture 3 - Expected Utility Theory - II
Link NOC:Stochastic Control and Communication Lecture 4 - Expected Utility Theory - III
Link NOC:Stochastic Control and Communication Lecture 5 - Role of Information in Decision Making
Link NOC:Stochastic Control and Communication Lecture 6 - State Space Modelling of Sequential Decision Making, Example of Inventory Control
Link NOC:Stochastic Control and Communication Lecture 7 - Inventory Control Problem (Continued...)
Link NOC:Stochastic Control and Communication Lecture 8 - Policy-A Closed Loop Solution to Stochastic Control Problem
Link NOC:Stochastic Control and Communication Lecture 9 - Introduction to Markov Decision Processes (MDP)
Link NOC:Stochastic Control and Communication Lecture 10 - Types of Policy in MDP
Link NOC:Stochastic Control and Communication Lecture 11 - Interpreting randomised decision rules
Link NOC:Stochastic Control and Communication Lecture 12 - Stationary Transition Probability: State Diagram Representation and example of Markov policies
Link NOC:Stochastic Control and Communication Lecture 13 - Example of History Dependent Policies
Link NOC:Stochastic Control and Communication Lecture 14 - Complexity of the problem using brute force approach
Link NOC:Stochastic Control and Communication Lecture 15 - Principle of Optimality
Link NOC:Stochastic Control and Communication Lecture 16 - Dynamic Programming Algorithm
Link NOC:Stochastic Control and Communication Lecture 17 - DP Algo applied to Inventory Control Problem
Link NOC:Stochastic Control and Communication Lecture 18 - DP Algo applied to Inventory Control Problem (Continued...)
Link NOC:Stochastic Control and Communication Lecture 19 - DP Algo applied to Inventory Control Problem (Continued...)
Link NOC:Stochastic Control and Communication Lecture 20 - Optimal Stopping Problem
Link NOC:Stochastic Control and Communication Lecture 21 - Optimal Stopping Example: Secretary Problem
Link NOC:Stochastic Control and Communication Lecture 22 - Optimal Stopping Example: Secretary Problem (Continued...)
Link NOC:Stochastic Control and Communication Lecture 23 - Optimal Stopping Example: Secretary Problem (Continued...)
Link NOC:Stochastic Control and Communication Lecture 24 - Linear System Quadratic Cost Problem
Link NOC:Stochastic Control and Communication Lecture 25 - Linear System Quadratic Cost Problem (Continued...)
Link NOC:Stochastic Control and Communication Lecture 26 - Solving it via DP algorithm (Continued...)
Link NOC:Stochastic Control and Communication Lecture 27 - Equivalence between Optimal HR Policyand optimal Markov Deterministic Policy
Link NOC:Stochastic Control and Communication Lecture 28 - Stochastic Control under incomplete state information
Link NOC:Stochastic Control and Communication Lecture 29 - Stochastic Control under incomplete state information (Continued...)
Link NOC:Stochastic Control and Communication Lecture 30 - Stochastic Control under incomplete state information: Example
Link NOC:Stochastic Control and Communication Lecture 31 - Stochastic Control under incomplete state information: Example (Continued...)
Link NOC:Stochastic Control and Communication Lecture 32 - Stochastic Control under incomplete state information: Example (Continued...)
Link NOC:Stochastic Control and Communication Lecture 33 - Stochastic Control under incomplete state information: Example (Continued...)
Link NOC:Stochastic Control and Communication Lecture 34 - LQ systems with Imperfect Information - I
Link NOC:Stochastic Control and Communication Lecture 35 - LQ systems with Imperfect Information - II
Link NOC:Stochastic Control and Communication Lecture 36 - LQ systems with Imperfect Information - III
Link NOC:Stochastic Control and Communication Lecture 37 - LQ systems with Imperfect Information - IV
Link NOC:Stochastic Control and Communication Lecture 38 - Filtering - I
Link NOC:Stochastic Control and Communication Lecture 39 - Filtering - II
Link NOC:Stochastic Control and Communication Lecture 40 - Kalman Filtering - I
Link NOC:Stochastic Control and Communication Lecture 41 - Kalman Filtering - II
Link NOC:Stochastic Control and Communication Lecture 42 - Kalman Filtering - III
Link NOC:Stochastic Control and Communication Lecture 43 - Belief State Formulation - I
Link NOC:Stochastic Control and Communication Lecture 44 - Belief State Formulation - II
Link NOC:Stochastic Control and Communication Lecture 45 - Information Structures - I
Link NOC:Stochastic Control and Communication Lecture 46 - Information Structures - II
Link NOC:Stochastic Control and Communication Lecture 47 - Witsenhausen Problem - I
Link NOC:Stochastic Control and Communication Lecture 48 - Witsenhausen Problem - II
Link NOC:Stochastic Control and Communication Lecture 49 - Witsenhausen Problem - III
Link NOC:Stochastic Control and Communication Lecture 50 - Witsenhausen Problem - IV
Link NOC:Stochastic Control and Communication Lecture 51 - Witsenhausen Problem - V
Link NOC:Stochastic Control and Communication Lecture 52 - Witsenhausen Problem - VI
Link NOC:Stochastic Control and Communication Lecture 53 - Witsenhausen Problem - VII
Link NOC:Stochastic Control and Communication Lecture 54 - Team Decision Theory - I
Link NOC:Stochastic Control and Communication Lecture 55 - Team Decision Theory - II
Link NOC:Stochastic Control and Communication Lecture 56 - Team Decision Theory - III
Link NOC:Stochastic Control and Communication Lecture 57 - Team Decision Theory - IV
Link NOC:Stochastic Control and Communication Lecture 58 - Team Decision Theory - V
Link NOC:Stochastic Control and Communication Lecture 59 - Team Decision Theory - VI
Link NOC:Stochastic Control and Communication Lecture 60 - Team Decision Theory - VII
Link NOC:Stochastic Control and Communication Lecture 61 - Communication Theory - I
Link NOC:Stochastic Control and Communication Lecture 62 - Communication Theory - II
Link NOC:Stochastic Control and Communication Lecture 63 - Communication Theory - III
Link NOC:Stochastic Control and Communication Lecture 64 - Communication Theory - IV
Link NOC:Stochastic Control and Communication Lecture 65 - Communication Theory - V
Link NOC:Applied Linear Algebra (2024) Lecture 1 - Introduction - Part A
Link NOC:Applied Linear Algebra (2024) Lecture 2 - Introduction - Part B
Link NOC:Applied Linear Algebra (2024) Lecture 3 - Introduction - Part C
Link NOC:Applied Linear Algebra (2024) Lecture 4 - Equivalent Systems - Part A
Link NOC:Applied Linear Algebra (2024) Lecture 5 - Equivalent Systems - Part B
Link NOC:Applied Linear Algebra (2024) Lecture 6 - Equivalent Systems - Part C
Link NOC:Applied Linear Algebra (2024) Lecture 7 - Solution of Ax = b - Part A
Link NOC:Applied Linear Algebra (2024) Lecture 8 - Solution of Ax = b - Part B
Link NOC:Applied Linear Algebra (2024) Lecture 9 - Solution of Ax = b - Part C
Link NOC:Applied Linear Algebra (2024) Lecture 10 - Rings, Integral Domains and Fields - Part A
Link NOC:Applied Linear Algebra (2024) Lecture 11 - Rings, Integral Domains and Fields - Part B
Link NOC:Applied Linear Algebra (2024) Lecture 12 - Rings, Integral Domains and Fields - Part C
Link NOC:Applied Linear Algebra (2024) Lecture 13 - Vector Spaces and Subspaces - Part A
Link NOC:Applied Linear Algebra (2024) Lecture 14 - Vector Spaces and Subspaces - Part B
Link NOC:Applied Linear Algebra (2024) Lecture 15 - Vector Spaces and Subspaces - Part C
Link NOC:Applied Linear Algebra (2024) Lecture 16 - Unions, Intersection, Sums of Subspaces - Part A
Link NOC:Applied Linear Algebra (2024) Lecture 17 - Unions, Intersection, Sums of Subspaces - Part B
Link NOC:Applied Linear Algebra (2024) Lecture 18 - Generating sets, Linear independence and basis - Part A
Link NOC:Applied Linear Algebra (2024) Lecture 19 - Generating sets, Linear independence and basis - Part B
Link NOC:Applied Linear Algebra (2024) Lecture 20 - Generating sets, Linear independence and basis - Part C
Link NOC:Applied Linear Algebra (2024) Lecture 21 - Ordered basis and co-ordinates - Part A
Link NOC:Applied Linear Algebra (2024) Lecture 22 - Ordered basis and co-ordinates - Part B
Link NOC:Applied Linear Algebra (2024) Lecture 23 - Ordered basis and co-ordinates - Part C
Link NOC:Applied Linear Algebra (2024) Lecture 24 - Rank-Nullity Theorem (Matrices) - Part A
Link NOC:Applied Linear Algebra (2024) Lecture 25 - Rank-Nullity Theorem (Matrices) - Part B
Link NOC:Applied Linear Algebra (2024) Lecture 26 - Rank-Nullity Theorem (Matrices) - Part C
Link NOC:Applied Linear Algebra (2024) Lecture 27 - Rank-Nullity Theorem (Linear Transformation) - Part A
Link NOC:Applied Linear Algebra (2024) Lecture 28 - Rank-Nullity Theorem (Linear Transformation) - Part B
Link NOC:Applied Linear Algebra (2024) Lecture 29 - Rank-Nullity Theorem (Linear Transformation) - Part C
Link NOC:Applied Linear Algebra (2024) Lecture 30 - Isomorphism and Inverses - Part A
Link NOC:Applied Linear Algebra (2024) Lecture 31 - Isomorphism and Inverses - Part B
Link NOC:Applied Linear Algebra (2024) Lecture 32 - Isomorphism and Inverses - Part C
Link NOC:Applied Linear Algebra (2024) Lecture 33 - Dual Basis and Annihilator - Part A
Link NOC:Applied Linear Algebra (2024) Lecture 34 - Dual Basis and Annihilator - Part B
Link NOC:Applied Linear Algebra (2024) Lecture 35 - Dual Basis and Annihilator - Part C
Link NOC:Applied Linear Algebra (2024) Lecture 36 - Dual maps and double dual - Part A
Link NOC:Applied Linear Algebra (2024) Lecture 37 - Dual maps and double dual - Part B
Link NOC:Applied Linear Algebra (2024) Lecture 38 - Dual maps and double dual - Part C
Link NOC:Applied Linear Algebra (2024) Lecture 39 - Quotient spaces and quotient map - Part A
Link NOC:Applied Linear Algebra (2024) Lecture 40 - Quotient spaces and quotient map - Part B
Link NOC:Applied Linear Algebra (2024) Lecture 41 - Quotient spaces and quotient map - Part C
Link NOC:Applied Linear Algebra (2024) Lecture 42 - Inner Product Spaces - Part A
Link NOC:Applied Linear Algebra (2024) Lecture 43 - Inner Product Spaces - Part B
Link NOC:Applied Linear Algebra (2024) Lecture 44 - Inner Product Spaces - Part C
Link NOC:Applied Linear Algebra (2024) Lecture 45 - Gram Schmidt Procedure - Part A
Link NOC:Applied Linear Algebra (2024) Lecture 46 - Gram Schmidt Procedure - Part B
Link NOC:Applied Linear Algebra (2024) Lecture 47 - Gram Schmidt Procedure - Part C
Link NOC:Applied Linear Algebra (2024) Lecture 48 - Best Approximation of a Vector - Part A
Link NOC:Applied Linear Algebra (2024) Lecture 49 - Best Approximation of a Vector - Part B
Link NOC:Applied Linear Algebra (2024) Lecture 50 - Best Approximation of a Vector - Part C
Link NOC:Applied Linear Algebra (2024) Lecture 51 - Projection map and summary of Ax = b - Part A
Link NOC:Applied Linear Algebra (2024) Lecture 52 - Projection map and summary of Ax = b - Part B
Link NOC:Applied Linear Algebra (2024) Lecture 53 - Projection map and summary of Ax = b - Part C
Link NOC:Applied Linear Algebra (2024) Lecture 54 - Linear Differential Equations - Part A
Link NOC:Applied Linear Algebra (2024) Lecture 55 - Linear Differential Equations - Part B
Link NOC:Applied Linear Algebra (2024) Lecture 56 - Introduction to Eigen values and Eigen vectors - Part A
Link NOC:Applied Linear Algebra (2024) Lecture 57 - Introduction to Eigen values and Eigen vectors - Part B
Link NOC:Applied Linear Algebra (2024) Lecture 58 - Introduction to Eigen values and Eigen vectors - Part C
Link NOC:Applied Linear Algebra (2024) Lecture 59 - Singular Value Decomposition - Part A
Link NOC:Applied Linear Algebra (2024) Lecture 60 - Singular Value Decomposition - Part B
Link NOC:Applied Linear Algebra (2024) Lecture 61 - Singular Value Decomposition - Part C
Link NOC:Applied Linear Algebra (2024) Lecture 62 - Algebraic and geometric multiplicities - Part A
Link NOC:Applied Linear Algebra (2024) Lecture 63 - Algebraic and geometric multiplicities - Part B
Link NOC:Applied Linear Algebra (2024) Lecture 64 - A-Invariant Subspaces - Part A
Link NOC:Applied Linear Algebra (2024) Lecture 65 - A-Invariant Subspaces - Part B
Link NOC:Applied Linear Algebra (2024) Lecture 66 - A-Invariant Subspaces - Part C
Link NOC:Applied Linear Algebra (2024) Lecture 67 - Minimal Polynomial-I - Part A
Link NOC:Applied Linear Algebra (2024) Lecture 68 - Minimal Polynomial-I - Part B
Link NOC:Applied Linear Algebra (2024) Lecture 69 - Minimal Polynomial-I - Part C
Link NOC:Applied Linear Algebra (2024) Lecture 70 - Minimal Polynomial-I - Part D
Link NOC:Applied Linear Algebra (2024) Lecture 71 - Minimal Polynomial-II - Part A
Link NOC:Applied Linear Algebra (2024) Lecture 72 - Minimal Polynomial-II - Part B
Link NOC:Applied Linear Algebra (2024) Lecture 73 - Minimal Polynomial-II - Part C
Link NOC:Applied Linear Algebra (2024) Lecture 74 - Minimal Polynomial-II - Part D
Link NOC:Applied Linear Algebra (2024) Lecture 75 - Cayley Hamilton Theorem - Part A
Link NOC:Applied Linear Algebra (2024) Lecture 76 - Cayley Hamilton Theorem - Part B
Link NOC:Applied Linear Algebra (2024) Lecture 77 - Cayley Hamilton Theorem - Part C
Link NOC:Applied Linear Algebra (2024) Lecture 78 - Jordan Canonical Form - Part A
Link NOC:Applied Linear Algebra (2024) Lecture 79 - Jordan Canonical Form - Part B
Link NOC:Applied Linear Algebra (2024) Lecture 80 - Jordan Canonical Form - Part C
Link NOC:Applied Linear Algebra (2024) Lecture 81 - Algebraic Graph Theory and Consensus - Part A
Link NOC:Applied Linear Algebra (2024) Lecture 82 - Algebraic Graph Theory and Consensus - Part B
Link NOC:Applied Linear Algebra (2024) Lecture 83 - Algebraic Graph Theory and Consensus - Part C
Link NOC:Applied Linear Algebra (2024) Lecture 84 - Positive Matrices and Leontieff's Model - Part A
Link NOC:Applied Linear Algebra (2024) Lecture 85 - Positive Matrices and Leontieff's Model - Part B
Link NOC:Digital Communication using GNU Radio Lecture 1 - Introduction to Digital Communication
Link NOC:Digital Communication using GNU Radio Lecture 2 - Understanding GNU Radio features for Digital Communication: Basic blocks, input and output
Link NOC:Digital Communication using GNU Radio Lecture 3 - Understanding GNU Radio features for Digital Communication: Advanced blocks, hardware interfacing
Link NOC:Digital Communication using GNU Radio Lecture 4 - Fundamentals of Digital Communication: Signal Processing methods, vectors, and relevant GNU Radio Examples - Part 1
Link NOC:Digital Communication using GNU Radio Lecture 5 - Fundamentals of Digital Communication: Signal Processing methods, vectors, and relevant GNU Radio Examples - Part 2
Link NOC:Digital Communication using GNU Radio Lecture 6 - Complex Baseband Signal Representation
Link NOC:Digital Communication using GNU Radio Lecture 7 - Real Passband Signal Representation, Up and Down Conversion of Complex Baseband Signals
Link NOC:Digital Communication using GNU Radio Lecture 8 - Random Variables and Random Processes
Link NOC:Digital Communication using GNU Radio Lecture 9 - Fundamentals of Digital Modulation
Link NOC:Digital Communication using GNU Radio Lecture 10 - Linear Modulation Methods: Amplitude Shift Keying (ASK)
Link NOC:Digital Communication using GNU Radio Lecture 11 - Linear Modulation Methods: Phase Shift Keying (PSK)
Link NOC:Digital Communication using GNU Radio Lecture 12 - Linear Modulation Methods: Quadrature Amplitude Modulation (QAM) and Frequency Shift Keying (FSK)
Link NOC:Digital Communication using GNU Radio Lecture 13 - Pulse Shaping for ISI Free Signaling
Link NOC:Digital Communication using GNU Radio Lecture 14 - ASK using Raised Cosine (RC) and Root-Raised Cosine (RRC) Pulse Shaping
Link NOC:Digital Communication using GNU Radio Lecture 15 - Basics of Detection: Properties of Gaussian Random Variables
Link NOC:Digital Communication using GNU Radio Lecture 16 - Basics of Detection: Gaussian Random Vectors and Hypothesis Testing
Link NOC:Digital Communication using GNU Radio Lecture 17 - Optimal Receivers for M-ary Signaling
Link NOC:Digital Communication using GNU Radio Lecture 18 - Gram-Schmidt Orthogonalisation
Link NOC:Digital Communication using GNU Radio Lecture 19 - Optimal Reception of M-ary Signals in AWGN
Link NOC:Digital Communication using GNU Radio Lecture 20 - Detection and Optimal Decision for On-Off Signaling in AWGN Channel
Link NOC:Digital Communication using GNU Radio Lecture 21 - Detection and Optimal Decision for M-ary Signaling
Link NOC:Digital Communication using GNU Radio Lecture 22 - Python for GNU Radio
Link NOC:Digital Communication using GNU Radio Lecture 23 - Extending GNU Radio Features using Python
Link NOC:Digital Communication using GNU Radio Lecture 24 - Constructing and Visualising Constellations using GNU Radio
Link NOC:Digital Communication using GNU Radio Lecture 25 - Understanding matched filtering using GNU Radio
Link NOC:Digital Communication using GNU Radio Lecture 26 - Histograms in GNU Radio
Link NOC:Digital Communication using GNU Radio Lecture 27 - Visualising Symbol Error Rate in GNU Radio
Link NOC:Digital Communication using GNU Radio Lecture 28 - Signal-to-Noise Ratio and Symbol Error Probability - Part 1
Link NOC:Digital Communication using GNU Radio Lecture 29 - Signal-to-Noise Ratio and Symbol Error Probability - Part 2
Link NOC:Digital Communication using GNU Radio Lecture 30 - Symbol error rate and Bit error rate
Link NOC:Digital Communication using GNU Radio Lecture 31 - Computing bit error rates in GNU Radio
Link NOC:Digital Communication using GNU Radio Lecture 32 - End-to-end Digital Communication System Simulation in GNU Radio
Link NOC:Digital Communication using GNU Radio Lecture 33 - Parameter Estimation for Practical Receivers - Part 1
Link NOC:Digital Communication using GNU Radio Lecture 34 - Parameter Estimation for Practical Receivers - Part 2
Link NOC:Digital Communication using GNU Radio Lecture 35 - Phase Locked Loop and Differential Modulation
Link NOC:Digital Communication using GNU Radio Lecture 36 - Maximum Likelihood delay estimate for a single symbol in GNU Radio
Link NOC:Digital Communication using GNU Radio Lecture 37 - Maximum Likelihood delay estimate for multiple symbols in GNU Radio
Link NOC:Digital Communication using GNU Radio Lecture 38 - Phase offse estimation in GNU Radio
Link NOC:Digital Communication using GNU Radio Lecture 39 - Phase Locked Loop in GNU Radio
Link NOC:Digital Communication using GNU Radio Lecture 40 - Costas Loop and Differential PSK in GNU Radio
Link NOC:Digital Communication using GNU Radio Lecture 41 - Channel Equalisation
Link NOC:Digital Communication using GNU Radio Lecture 42 - Detection Strategy for Dispersive Channels
Link NOC:Digital Communication using GNU Radio Lecture 43 - Maximum Likelihood sequence estimation: Viterbi Algorithm
Link NOC:Digital Communication using GNU Radio Lecture 44 - Suboptimal Channel Equalisation: Zero-forcing Receiver
Link NOC:Digital Communication using GNU Radio Lecture 45 - Zero forcing Receiver in GNU Radio
Link NOC:Digital Communication using GNU Radio Lecture 46 - Suboptimal Channel Equalisation: Linear Minimum mean-square error receiver
Link NOC:Digital Communication using GNU Radio Lecture 47 - LMMSE Receiver in GNU Radio
Link NOC:Digital Communication using GNU Radio Lecture 48 - Parallelising Frequency Selective Channels
Link NOC:Digital Communication using GNU Radio Lecture 49 - Orthogonal Frequency Division Multiplexing (OFDM)
Link NOC:Digital Communication using GNU Radio Lecture 50 - OFDM in the prescence of dispersive channels
Link NOC:Digital Communication using GNU Radio Lecture 51 - Equalisation using OFDM in GNU Radio
Link NOC:Digital Communication using GNU Radio Lecture 52 - Error Control Coding: Parity Check Codes
Link NOC:Digital Communication using GNU Radio Lecture 53 - Error Control Coding: Repetition Codes
Link NOC:Digital Communication using GNU Radio Lecture 54 - Error Control Coding: Linear Block Codes
Link NOC:Digital Communication using GNU Radio Lecture 55 - Repetition Codes in GNU Radio
Link NOC:Digital Communication using GNU Radio Lecture 56 - Error Control Coding: Perfect Codes
Link NOC:Digital Communication using GNU Radio Lecture 57 - Error Control Coding: Hamming Codes
Link NOC:Digital Communication using GNU Radio Lecture 58 - (7,4) Hamming Code in GNU Radio
Link NOC:Digital Communication using GNU Radio Lecture 59 - Rate and error-free Communication
Link NOC:Digital Communication using GNU Radio Lecture 60 - Quantisation
Link NOC:Digital Communication using GNU Radio Lecture 61 - Visualising Quantisation in GNU Radio
Link NOC:Digital Communication using GNU Radio Lecture 62 - Course Summary
Link Circuit Theory Lecture 1 - Review of Signals and Systems
Link Circuit Theory Lecture 2 - Review of Signals and Systems
Link Circuit Theory Lecture 3 - Network Equations; Initial and Final Conditions
Link Circuit Theory Lecture 4 - Problem Session 1
Link Circuit Theory Lecture 5 - Step, Impulse and Complete Responses
Link Circuit Theory Lecture 6 - 2nd Order Circuits:Magnetically Coupled Circuits
Link Circuit Theory Lecture 7 - Transformer Transform Domain Analysis
Link Circuit Theory Lecture 8 - Problem Session 2 : Step,Impulse
Link Circuit Theory Lecture 9 - Network Theorems and Network Functions
Link Circuit Theory Lecture 10 - Network Functions (Continued.)
Link Circuit Theory Lecture 11 - Amplitude and Phase of Network Functions
Link Circuit Theory Lecture 12 - Problem Session 3 : Network Theorems Transform
Link Circuit Theory Lecture 13 - Poles, Zeros and Network Response
Link Circuit Theory Lecture 14 - Single Tuned Circuits
Link Circuit Theory Lecture 15 - Single Tuned Circuits (Continued.)
Link Circuit Theory Lecture 16 - Double Tuned Circuits
Link Circuit Theory Lecture 17 - Double Tuned Circuits (Continued.)
Link Circuit Theory Lecture 18 - Problem Session 4 : Network Functions, Analysis
Link Circuit Theory Lecture 19 - Double Tuned Circuits (Continued.)
Link Circuit Theory Lecture 20 - Concept of Delay and Introduction
Link Circuit Theory Lecture 21 - Two-port Networks (Continued.)
Link Circuit Theory Lecture 22 - Problem Session 5
Link Circuit Theory Lecture 23 - Minor - 1
Link Circuit Theory Lecture 24 - The Hybrid & Transmission Parameters of 2 ports
Link Circuit Theory Lecture 25 - Problem Session 6 : Two - port networks
Link Circuit Theory Lecture 26 - Two - port Network parameters
Link Circuit Theory Lecture 27 - Two-port Interconnections
Link Circuit Theory Lecture 28 - Interconnection of Two-port Networks (Continued.)
Link Circuit Theory Lecture 29 - Problem Session 7 : Two-port Networks (Continued.)
Link Circuit Theory Lecture 30 - Scattering Matrix
Link Circuit Theory Lecture 31 - Scattering Parameters of a Two-port
Link Circuit Theory Lecture 32 - Problem Session 8 : Two- port Parameters
Link Circuit Theory Lecture 33 - Solutions of Minor - 2 Problems
Link Circuit Theory Lecture 34 - Insertion Loss
Link Circuit Theory Lecture 35 - Example of Insertion Loss and Elements
Link Circuit Theory Lecture 36 - Elements of Realizability Theory (Continued.)
Link Circuit Theory Lecture 37 - Positive Real Functions
Link Circuit Theory Lecture 38 - Testing of Positive Real Functions
Link Circuit Theory Lecture 39 - Problem Session 9
Link Circuit Theory Lecture 40 - More on PRF's and their Synthesis
Link Circuit Theory Lecture 41 - LC Driving Point Functions
Link Circuit Theory Lecture 42 - LC Driving Point Synthesis (Continued.)
Link Circuit Theory Lecture 43 - RC and RL Driving Point Synthesis
Link Circuit Theory Lecture 44 - Problem Session 10 : LC Driving Point Synthesis
Link Circuit Theory Lecture 45 - RC & RL One-port Synthesis (Continued.)
Link Circuit Theory Lecture 46 - Elementary RLC One-port Synthesis
Link Circuit Theory Lecture 47 - Properties and Synthesis of Transfer Parameters
Link Circuit Theory Lecture 48 - Resistance Terminated LC Ladder
Link Circuit Theory Lecture 49 - Resistance Terminated LC Ladder (Continued.)
Link Circuit Theory Lecture 50 - Problem session 11: Two-port Synthesis
Link Circuit Theory Lecture 51 - Network Transmission Criteria
Link Control Engineering (Prof. M. Gopal) Lecture 1 - Introduction to control problem
Link Control Engineering (Prof. M. Gopal) Lecture 2 - Basic Feedback Structure
Link Control Engineering (Prof. M. Gopal) Lecture 3 - Introduction to Control Problem (Continued.)
Link Control Engineering (Prof. M. Gopal) Lecture 4 - Dynamic Systems and Dynamic Response
Link Control Engineering (Prof. M. Gopal) Lecture 5 - Dynamic Systems and Dynamic Response (Continued.)
Link Control Engineering (Prof. M. Gopal) Lecture 6 - Dynamic Systems and Dynamic Response (Continued.)
Link Control Engineering (Prof. M. Gopal) Lecture 7 - Dynamic Systems and Dynamic Response (Continued.)
Link Control Engineering (Prof. M. Gopal) Lecture 8 - Dynamic Systems and Dynamic Response (Continued.)
Link Control Engineering (Prof. M. Gopal) Lecture 9 - Dynamic Systems and Dynamic Response (Continued.)
Link Control Engineering (Prof. M. Gopal) Lecture 10 - Models of Industrial Control Devices and Systems
Link Control Engineering (Prof. M. Gopal) Lecture 11 - Models of Industrial Control Devices and Systems (Continued.)
Link Control Engineering (Prof. M. Gopal) Lecture 12 - Models of Industrial Control Devices and Systems( Continued.)
Link Control Engineering (Prof. M. Gopal) Lecture 13 - Models of Industrial Control Devices and Systems( Continued.)
Link Control Engineering (Prof. M. Gopal) Lecture 14 - Models of Industrial Control Devices and Systems( Continued.)
Link Control Engineering (Prof. M. Gopal) Lecture 15 - Models of Industrial Control Devices and Systems( Continued.)
Link Control Engineering (Prof. M. Gopal) Lecture 16 - Models of Industrial Control Devices and Systems (Continued.)
Link Control Engineering (Prof. M. Gopal) Lecture 17 - Models of Industrial Control Devices and Systems (Continued.)
Link Control Engineering (Prof. M. Gopal) Lecture 18 - Models of Industrial Control Devices and Systems (Continued.)
Link Control Engineering (Prof. M. Gopal) Lecture 19 - Basic Principles of Feedback Control
Link Control Engineering (Prof. M. Gopal) Lecture 20 - Basic Principles of Feedback Control (Continued.)
Link Control Engineering (Prof. M. Gopal) Lecture 21 - Basic Principles of Feedback Control (Continued.)
Link Control Engineering (Prof. M. Gopal) Lecture 22 - Basic Principles of Feedback Control (Continued.)
Link Control Engineering (Prof. M. Gopal) Lecture 23 - Concepts of stability and Routh Stability Criterion
Link Control Engineering (Prof. M. Gopal) Lecture 24 - Concepts of stability and Routh Stability Criterion (Continued.)
Link Control Engineering (Prof. M. Gopal) Lecture 25 - Concepts of stability and Routh Stability Criterion (Continued.)
Link Control Engineering (Prof. M. Gopal) Lecture 26 - The Performance of Feedback Systems
Link Control Engineering (Prof. M. Gopal) Lecture 27 - The Performance of Feedback Systems (Continued.)
Link Control Engineering (Prof. M. Gopal) Lecture 28 - The Performance of Feedback Systems (Continued.)
Link Control Engineering (Prof. M. Gopal) Lecture 29 - The Performance of Feedback Systems (Continued.)
Link Control Engineering (Prof. M. Gopal) Lecture 30 - Compensator Design Using Root Locus Plots
Link Control Engineering (Prof. M. Gopal) Lecture 31 - Compensator Design Using Root Locus Plots (Continued.)
Link Control Engineering (Prof. M. Gopal) Lecture 32 - Compensator Design Using Root Locus Plots (Continued.)
Link Control Engineering (Prof. M. Gopal) Lecture 33 - Compensator Design Using Root Locus Plots (Continued.)
Link Control Engineering (Prof. M. Gopal) Lecture 34 - Compensator Design Using Root Locus Plots (Continued.)
Link Control Engineering (Prof. M. Gopal) Lecture 35 - The Nyquist Stability Criterion and Stability Margins
Link Control Engineering (Prof. M. Gopal) Lecture 36 - The Nyquist Stability Criterion and Stability Margins (Continued.)
Link Control Engineering (Prof. M. Gopal) Lecture 37 - The Nyquist Stability Criterion and Stability Margins (Continued.)
Link Control Engineering (Prof. M. Gopal) Lecture 38 - The Nyquist Stability Criterion and Stability Margins (Continued.)
Link Control Engineering (Prof. M. Gopal) Lecture 39 - Feedback System Performance Based on the Frequency Response
Link Control Engineering (Prof. M. Gopal) Lecture 40 - Feedback System Performance Based on the Frequency Response (Continued.)
Link Control Engineering (Prof. M. Gopal) Lecture 41 - Compensator Design Using Frequency Response Plots
Link Embedded Systems Lecture 1 - Embedded Systems: Introduction
Link Embedded Systems Lecture 2 - Embedded Hardware
Link Embedded Systems Lecture 3 - PIC: Instruction Set
Link Embedded Systems Lecture 4 - PIC Peripherals On Chip
Link Embedded Systems Lecture 5 - ARM Processor
Link Embedded Systems Lecture 6 - More ARM Instructions
Link Embedded Systems Lecture 7 - ARM: Interrupt Processing
Link Embedded Systems Lecture 8 - Digital Signal Processors
Link Embedded Systems Lecture 9 - More on DSP Processors
Link Embedded Systems Lecture 10 - System On Chip (SOC)
Link Embedded Systems Lecture 11 - Memory
Link Embedded Systems Lecture 12 - Memory Organization
Link Embedded Systems Lecture 13 - Virtual Memory and Memory Management Unit
Link Embedded Systems Lecture 14 - Bus Structure
Link Embedded Systems Lecture 15 - Bus Structure - 2
Link Embedded Systems Lecture 16 - Bus Structure - 3 Serial Interfaces
Link Embedded Systems Lecture 17 - Serial Interfaces
Link Embedded Systems Lecture 18 - Power Aware Architecture
Link Embedded Systems Lecture 19 - Software for Embedded Systems
Link Embedded Systems Lecture 20 - Fundamentals of Embedded Operating Systems
Link Embedded Systems Lecture 21 - Scheduling Policies
Link Embedded Systems Lecture 22 - Resource Management
Link Embedded Systems Lecture 23 - Embedded - OS
Link Embedded Systems Lecture 24 - Networked Embedded Systems - I
Link Embedded Systems Lecture 25 - Networked Embedded Systems - II
Link Embedded Systems Lecture 26 - Networked Embedded Systems - III
Link Embedded Systems Lecture 27 - Networked Embedded Systems - IV
Link Embedded Systems Lecture 28 - Designing Embedded Systems - I
Link Embedded Systems Lecture 29 - Designing Embedded Systems - II
Link Embedded Systems Lecture 30 - Designing Embedded Systems- III
Link Embedded Systems Lecture 31 - Embedded System Design - IV
Link Embedded Systems Lecture 32 - Designing Embedded Systems - V
Link Embedded Systems Lecture 33 - Platform Based Design
Link Embedded Systems Lecture 34 - Compilers for Embedded Systems
Link Embedded Systems Lecture 35 - Developing Embedded Systems
Link Embedded Systems Lecture 36 - Building Dependable Embedded Systems
Link Embedded Systems Lecture 37 - Pervasive and Ubiquitous Computing
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 1 - Electric Energy Systems A Perspective
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 2 - Structure of Power Systems
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 3 - Conventional Sources of Electric Energy
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 4 - Hydroelectric Power Generation
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 5 - Non Conventional Energy Sources
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 6 - Renewable Energy (Continued.)
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 7 - Energy Storage
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 8 - Deregulation
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 9 - Air Pollutants
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 10 - Transmission Line Parameters
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 11 - Capacitance of Transmission Lines
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 12 - Characteristics and Performance of Transmission Lines
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 13 - Voltage Regulation (VR)
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 14 - Power Flow through a Line
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 15 - Methods of Voltage Control
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 16 - Compensation of Transmission Lines
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 17 - Compensation of Transmission Lines (Continued.)
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 18 - Underground Cables
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 19 - Cables (Continued.)
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 20 - Insulators for Overhead Lines
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 21 - HVDC
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 22 - HVDC (Continued.)
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 23 - Distribution Systems
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 24 - Automatic Generation Control
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 25 - Automatic Generation Control (Continued.)
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 26 - Load Flow Studies
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 27 - Load Flow Problem
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 28 - Load Flow Analysis (Continued.), Gauss Siedel Method
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 29 - Newton Raphson (NR), Load Flow Method
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 30 - Fast Decoupled Load Flow
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 31 - Control of Voltage Profile
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 32 - Optimal System Operation (Economic Operation)
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 33 - Optimal Unit Commitment
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 34 - Optimal Generation Scheduling
Link Power System Generation, Transmission and Distribution (Encapsulated from earlier Video) Lecture 35 - Optimal Load Flow (Continued.) and Hydro Thermal Scheduling
Link Power System Dynamics Lecture 1 - Introduction to Power System Stability Problem - Part-1
Link Power System Dynamics Lecture 2 - Introduction to Power System Stability Problem - Part-2
Link Power System Dynamics Lecture 3 - Introduction to Power System Stability Problem - Part-3
Link Power System Dynamics Lecture 4 - Solution of Switching Equation
Link Power System Dynamics Lecture 5 - The Equal Area Criterion for Stability - Part-1
Link Power System Dynamics Lecture 6 - The Equal Area Criterion for Stability - Part-2
Link Power System Dynamics Lecture 7 - Transient Stability Analysis of a Multi Machine System
Link Power System Dynamics Lecture 8 - Modeling of Synchronous Machine - Part-1
Link Power System Dynamics Lecture 9 - Modeling of Synchronous Machine - Part-2
Link Power System Dynamics Lecture 10 - Modeling of Synchronous Machine - Part-3
Link Power System Dynamics Lecture 11 - Modeling of Synchronous Machine - Part-4
Link Power System Dynamics Lecture 12 - Synchronous Machine Representation for Stability Studies - Part-1
Link Power System Dynamics Lecture 13 - Synchronous Machine Representation for Stability Studies - Part-2
Link Power System Dynamics Lecture 14 - Excitation Systems - Part-1
Link Power System Dynamics Lecture 15 - Excitation Systems - Part-2
Link Power System Dynamics Lecture 16 - Modeling of Excitation Systems - Part-1
Link Power System Dynamics Lecture 17 - Modeling of Excitation Systems - Part-2
Link Power System Dynamics Lecture 18 - Small Signal Stability of a Single Machine Infinite Bus System - Part-1
Link Power System Dynamics Lecture 19 - Small Signal Stability of a Single Machine Infinite Bus System - Part-2
Link Power System Dynamics Lecture 20 - Small Signal Stability of a Single Machine Infinite Bus System - Part-3
Link Power System Dynamics Lecture 21 - Small Signal Stability of a Single Machine Infinite Bus System - Part-4
Link Power System Dynamics Lecture 22 - Small Signal Stability of a Single Machine Infinite Bus System - Part-5
Link Power System Dynamics Lecture 23 - Dynamic Modeling of Steam turbines and Governors
Link Power System Dynamics Lecture 24 - Dynamic modeling of Hydro Turbines and Governors
Link Power System Dynamics Lecture 25 - Load modeling for Stability Studies
Link Power System Dynamics Lecture 26 - Numerical Integration Methods for Solving a Set of Ordinary Nonlinear Differential Equation
Link Power System Dynamics Lecture 27 - Simulation of Power System Dynamic Response
Link Power System Dynamics Lecture 28 - Dynamic Equivalents for Large Scale Systems - Part-1
Link Power System Dynamics Lecture 29 - Dynamic Equivalents for Large Scale Systems - Part-2
Link Power System Dynamics Lecture 30 - Dynamic Equivalents for Large Scale Systems - Part-3
Link Power System Dynamics Lecture 31 - Direct Method of Transient Stability Analysis - Part-1
Link Power System Dynamics Lecture 32 - Direct Method of Transient Stability Analysis - Part-2
Link Power System Dynamics Lecture 33 - Sub Synchronous Oscillations - Part-1
Link Power System Dynamics Lecture 34 - Sub Synchronous Oscillations - Part-2
Link Power System Dynamics Lecture 35 - Voltage Stability - Part-1
Link Power System Dynamics Lecture 36 - Voltage Stability - Part-2
Link Power System Dynamics Lecture 37 - Voltage Stability - Part-3
Link Power System Dynamics Lecture 38 - Voltage Stability - Part-4
Link Power System Dynamics Lecture 39 - Methods of Improving Stability - Part-1
Link Power System Dynamics Lecture 40 - Methods of Improving Stability - Part-2
Link Analog Electronic Circuits Lecture 1 - Review of DC Models of Diodes & BJT's
Link Analog Electronic Circuits Lecture 2 - Review of DC Models of BJT (Continued...) and FET
Link Analog Electronic Circuits Lecture 3 - FET Characteristics and Models
Link Analog Electronic Circuits Lecture 4 - Problem Session-1 on DC Analysis of BJT Circuits
Link Analog Electronic Circuits Lecture 5 - BJT Biasing and Bias Stability
Link Analog Electronic Circuits Lecture 6 - BJT Bias Stability (Continued...)
Link Analog Electronic Circuits Lecture 7 - FET Biasing, Current Sources
Link Analog Electronic Circuits Lecture 8 - Problem Session-2 on FET and BJT Characteristics and Biasing
Link Analog Electronic Circuits Lecture 9 - Current Mirrors; BJT Small Signal Models
Link Analog Electronic Circuits Lecture 10 - Small Signal Amplifiers: Mid Frequency Analysis
Link Analog Electronic Circuits Lecture 11 - Mid Frequency Analysis of the CE and CB Amplifier
Link Analog Electronic Circuits Lecture 12 - Problem Session-3 on Mid- Frequency Analysis of CE Amplifiers
Link Analog Electronic Circuits Lecture 13 - Midband Analysis of CB and CC Amplifiers
Link Analog Electronic Circuits Lecture 14 - Midband Analysis of FET Amplifiers
Link Analog Electronic Circuits Lecture 15 - Problem Session-4 on Midband Analysis of Amplifiers
Link Analog Electronic Circuits Lecture 16 - High Frequency Response of Small Signal Amplifiers
Link Analog Electronic Circuits Lecture 17 - High Frequency Response of Small Signal Amplifiers (Continued...)
Link Analog Electronic Circuits Lecture 18 - Low Frequency Response of Small Signal Amplifiers
Link Analog Electronic Circuits Lecture 19 - Problem Session-5 on Frequency Response of Small Signal Amplifiers
Link Analog Electronic Circuits Lecture 20 - Differential Amplifiers
Link Analog Electronic Circuits Lecture 21 - Differential Amplifiers (Continued...)
Link Analog Electronic Circuits Lecture 22 - Discussion on Minor-1 Problems and Differential Amplifiers (Continued...)
Link Analog Electronic Circuits Lecture 23 - Problem Session-6 on Frequency Response of Small Signal Amplifiers (Continued...) and Differential Amplifiers
Link Analog Electronic Circuits Lecture 24 - Use of Current Mirrors in Differential Amplifiers
Link Analog Electronic Circuits Lecture 25 - FET Differential Amplifiers and Introduction to Power Amplifiers
Link Analog Electronic Circuits Lecture 26 - Class B, Class AB and Class A Power Amplifiers
Link Analog Electronic Circuits Lecture 27 - Class A Power Amplifiers; Efficiency Considerations
Link Analog Electronic Circuits Lecture 28 - Problem Session-7 on Deferential and Power Amplifiers
Link Analog Electronic Circuits Lecture 29 - Introduction to Feedback Amplifiers
Link Analog Electronic Circuits Lecture 30 - Advantages of Negative Feedback Amplifiers
Link Analog Electronic Circuits Lecture 31 - Analysis of Feedback Amplifiers
Link Analog Electronic Circuits Lecture 32 - Analysis of the Series - Series and Other Feedback Configurations
Link Analog Electronic Circuits Lecture 33 - Problem Session-8 on Feedback Amplifiers
Link Analog Electronic Circuits Lecture 34 - Sinusoidal Oscillators : An Example of Positive Feedback
Link Analog Electronic Circuits Lecture 35 - More on Oscillators
Link Analog Electronic Circuits Lecture 36 - Solutions to Minor-2 Exam and Concluding Discussions on Oscillators
Link Analog Electronic Circuits Lecture 37 - Problem Session-9 on Oscillators
Link Analog Electronic Circuits Lecture 38 - Tuned (or Narrowband) Amplifiers
Link Analog Electronic Circuits Lecture 39 - Widebanding Techniques : Introduction & Use of Inductors
Link Analog Electronic Circuits Lecture 40 - Widebanding By Using an Inductance
Link Analog Electronic Circuits Lecture 41 - Problem Session-10 on Tuned Amplifiers
Link Analog Electronic Circuits Lecture 42 - Widebanding by Using Compound Devices
Link Analog Electronic Circuits Lecture 43 - Cascode Configuration as Wideband Amplifier
Link Analog Electronic Circuits Lecture 44 - Widebanding by Local Feedback
Link Analog Electronic Circuits Lecture 45 - Problem Session-11 on Minor-3 Problems & Widebanding by Compound Devices
Link Analog Electronic Circuits Lecture 46 - Widebanding by Local Feedback and Feedback Cascades
Link Analog Electronic Circuits Lecture 47 - Widebanding by Overall Feedback and Dual Loop Feedback
Link Analog Electronic Circuits Lecture 48 - The Differential Pair and the Gilbert Cell as Wideband Amplifiers
Link Analog Electronic Circuits Lecture 49 - Correction to Gilbert Cell Analysis and Operational Amplifier Imperfections
Link Analog Electronic Circuits Lecture 50 - Op-Amp offsets, Compensation and Slew Rate
Link Analog Electronic Circuits Lecture 51 - Op-Amp Compensation, Slew Rate and Some Problems
Link Digital Communication Lecture 1 - Introduction to the Course
Link Digital Communication Lecture 2 - Digital Representation of Analog Signals, Delta Modulation
Link Digital Communication Lecture 3 - Digital Representation of Analog Signals, Pulse Code Modulation
Link Digital Communication Lecture 4 - Digital Representation of Analog Signals
Link Digital Communication Lecture 5 - Quantization Noise in Delta Modulation (Continued...) and Time Division Multiplexing
Link Digital Communication Lecture 6 - Introduction to Line Coding
Link Digital Communication Lecture 7 - Spectral Properties of Line Codes: General Relations
Link Digital Communication Lecture 8 - Spectral Properties of Line Codes: On-off / Polar / Bipolar Signalling
Link Digital Communication Lecture 9 - Spectral Properties of Line Codes: Duobinary Manchester and HDB Codes
Link Digital Communication Lecture 10 - Baseband Pulse Shaping: Nyquist's First Criterion
Link Digital Communication Lecture 11 - Baseband Pulse Shaping; Raised Cosine Family of Pulses
Link Digital Communication Lecture 12 - Partial Response Signalling: Duobinary and Modified Duobinary Pulse Shaping
Link Digital Communication Lecture 13 - Precoding for Duobinary and Modified Duobinary Systems
Link Digital Communication Lecture 14 - Precoding for Modified Duobinary Systems (Continued...) and General Partial Response Signalling
Link Digital Communication Lecture 15 - Binary Baseband Digital Modulation Techniques
Link Digital Communication Lecture 16 - M’ary Baseband Digital Modulation Techniques
Link Digital Communication Lecture 17 - Passband Digital Modulations - I : PSK and QPSK
Link Digital Communication Lecture 18 - Passband Digital Modulations - II : Offset QPSK
Link Digital Communication Lecture 19 - Passband Digital Modulations - III : Minimum Shift Keying (MSK)
Link Digital Communication Lecture 20 - Passband Digital Modulations - IV : MSK (Continued...) : Passband Waveforms for M’ary Signalling
Link Digital Communication Lecture 21 - Passband Modulations for Band Limited Channels
Link Digital Communication Lecture 22 - Baseband and Passband Digital Demodulations : General Issues and Concepts
Link Digital Communication Lecture 23 - Digital Modulation Part - II Matched Filters
Link Digital Communication Lecture 24 - Matched Filters and Coherent Demodulation-I
Link Digital Communication Lecture 25 - Coherent Demodulation for Binary Wave Form
Link Digital Communication Lecture 26 - Demodulators for Binary Waveforms (Continued...) : Coherent and Noncoherent Receivers for Orthogonal Signalling (OOK and FSK)
Link Digital Communication Lecture 27 - Performance Analysis of Binary Digital Modulations: Signal and Noise Statistics in Coherent and Noncoherent Receivers
Link Digital Communication Lecture 28 - Error Rates for Binary Signalling : Coherent Receivers
Link Digital Communication Lecture 29 - Performance of Non Coherent FSK and Differential Phase Shift Keying
Link Digital Communication Lecture 30 - Demodulation of DPSK and M\'ary Signals
Link Digital Communication Lecture 31 - Performance of M\'ary Digital Modulations
Link Digital Communication Lecture 32 - Performance of M\'ary Digital Modulations (Continued...)
Link Digital Communication Lecture 33 - Introduction to Information Theory, Part-1
Link Digital Communication Lecture 34 - Source Coding
Link Digital Communication Lecture 35 - Error Free Communication Over a Noisy Channel
Link Digital Communication Lecture 36 - The Concept of Channel Capacity
Link Digital Communication Lecture 37 - Error Correcting Codes
Link Digital Communication Lecture 38 - Error Correcting Codes (Continued...)
Link Introduction To Electronic Circuits Lecture 1 - Introduction to the Course and Basic Electrical Quantity
Link Introduction To Electronic Circuits Lecture 2 - R.L.C. Components, Energy Considerations, Sources and Circuit Laws
Link Introduction To Electronic Circuits Lecture 3 - KCL, KVL and Network Analysis
Link Introduction To Electronic Circuits Lecture 4 - Networks Theorems ( Thevenin's Norton's )
Link Introduction To Electronic Circuits Lecture 5 - Source Transformation; Super Position Theorem and Non-Linear One-Ports
Link Introduction To Electronic Circuits Lecture 6 - Signal Wave Forms
Link Introduction To Electronic Circuits Lecture 7 - Periodic Wave Forms and Elements of Amplifiers
Link Introduction To Electronic Circuits Lecture 8 - Operational Amplifiers and Diodes
Link Introduction To Electronic Circuits Lecture 9 - Rectifiers and Power Supplies
Link Introduction To Electronic Circuits Lecture 10 - Wave Shaping Circuits
Link Introduction To Electronic Circuits Lecture 11 - More on Wave Shaping Circuits and Introduction to Natural Response of Circuits
Link Introduction To Electronic Circuits Lecture 12 - Natural Response (Continued...)
Link Introduction To Electronic Circuits Lecture 13 - Natural Response of 2nd Order Circuit
Link Introduction To Electronic Circuits Lecture 14 - Natural Response of 2nd Order Circuit (Continued...)
Link Introduction To Electronic Circuits Lecture 15 - Impedance Functions, Poles, Zeros and their Applications
Link Introduction To Electronic Circuits Lecture 16 - Natural Response and Poles and Zeros and Introduction to Forced Response
Link Introduction To Electronic Circuits Lecture 17 - Phasors and their Applications in AC Ckts, analysis
Link Introduction To Electronic Circuits Lecture 18 - More About Phasors and Introduction to Complete Response
Link Introduction To Electronic Circuits Lecture 19 - Complete Response of Electrical Circuits
Link Introduction To Electronic Circuits Lecture 20 - AC Circuit Analysis
Link Introduction To Electronic Circuits Lecture 21 - Filter Circuits and Resonance
Link Introduction To Electronic Circuits Lecture 22 - Resonance (Continued...)
Link Introduction To Electronic Circuits Lecture 23 - General Network Analysis
Link Introduction To Electronic Circuits Lecture 24 - Two-Port Networks
Link Introduction To Electronic Circuits Lecture 25 - Semiconductor Physics
Link Introduction To Electronic Circuits Lecture 26 - Semiconductor Physics (Continued...)
Link Introduction To Electronic Circuits Lecture 27 - More About Diodes Including Zener Diodes
Link Introduction To Electronic Circuits Lecture 28 - Bipolar Junction Transistors
Link Introduction To Electronic Circuits Lecture 29 - Transistors Characteristics and Biasing
Link Introduction To Electronic Circuits Lecture 30 - BJT Biasing and Introduction to Power Amplifiers
Link Introduction To Electronic Circuits Lecture 31 - BJT Power Amplifiers
Link Introduction To Electronic Circuits Lecture 32 - Power Amplifier
Link Introduction To Electronic Circuits Lecture 33 - Power Amplifiers (Continued...) and an Introduction to Small Signal Modelling of BJT
Link Introduction To Electronic Circuits Lecture 34 - Small Signal Model and Small Signal Amplifiers
Link Introduction To Electronic Circuits Lecture 35 - Small Signal Amplifiers (Continued...)
Link Introduction To Electronic Circuits Lecture 36 - Small Signal Amplifier (Continued...)
Link Introduction To Electronic Circuits Lecture 37 - Small Signal Amplifiers (Continued...)
Link Introduction To Electronic Circuits Lecture 38 - Negative Feedback
Link Introduction To Electronic Circuits Lecture 39 - Digital Circuits
Link Introduction To Electronic Circuits Lecture 40 - Digital Circuits (Continued...)
Link NOC:Analog Electronic Circuit Lecture 1 - Introduction to Analog Circuits Introduction to the Diode
Link NOC:Analog Electronic Circuit Lecture 2 - Diodes, Introduction to The Transistor
Link NOC:Analog Electronic Circuit Lecture 3 - MOS Device, Characteristics
Link NOC:Analog Electronic Circuit Lecture 4 - DC operating point
Link NOC:Analog Electronic Circuit Lecture 5 - DC operating point, amplifier design
Link NOC:Analog Electronic Circuit Lecture 6 - Common source amplifier, small signal analysis
Link NOC:Analog Electronic Circuit Lecture 7 - Common gate, common drain
Link NOC:Analog Electronic Circuit Lecture 8 - Common gate circuit
Link NOC:Analog Electronic Circuit Lecture 9 - Source degenerated amplifier
Link NOC:Analog Electronic Circuit Lecture 10 - Swing limits
Link NOC:Analog Electronic Circuit Lecture 11 - Swing limits (Continued...), multi transistor amplifiers
Link NOC:Analog Electronic Circuit Lecture 12 - Multi-transistor amplifiers
Link NOC:Analog Electronic Circuit Lecture 13 - Introduction to current sources
Link NOC:Analog Electronic Circuit Lecture 14 - Current sources/mirrors (Continued...)
Link NOC:Analog Electronic Circuit Lecture 15 - Current sources, biasing
Link NOC:Analog Electronic Circuit Lecture 16 - Differential circuits
Link NOC:Analog Electronic Circuit Lecture 17 - Differential amplifiers-I
Link NOC:Analog Electronic Circuit Lecture 18 - Differential amplifiers-II
Link NOC:Analog Electronic Circuit Lecture 19 - Differential amplifiers-III
Link NOC:Analog Electronic Circuit Lecture 20 - Self biased active load diff. amp
Link NOC:Analog Electronic Circuit Lecture 21 - Diff. Cascode amplifier, two stage amplifiers
Link NOC:Analog Electronic Circuit Lecture 22 - Two stage diff. amps, op-amps
Link NOC:Analog Electronic Circuit Lecture 23 - Op-amps, OTAs
Link NOC:Analog Electronic Circuit Lecture 24 - Circuits with op-amps
Link NOC:Analog Electronic Circuit Lecture 25 - Capacitance in MOS devices
Link NOC:Analog Electronic Circuit Lecture 26 - Common source, drain, gate-revisited
Link NOC:Analog Electronic Circuit Lecture 27 - Common gate, common drain with capacitances
Link NOC:Analog Electronic Circuit Lecture 28 - Cascode, cascade-revisit with capacitance
Link NOC:Analog Electronic Circuit Lecture 29 - Cascade amplifier (with capacitance)
Link NOC:Analog Electronic Circuit Lecture 30 - Diversion: 2-pole systems phase margin
Link NOC:Analog Electronic Circuit Lecture 31 - Diversion Continued: Two Pole Systems
Link NOC:Analog Electronic Circuit Lecture 32 - Compensation
Link NOC:Analog Electronic Circuit Lecture 33 - Op-amp Design with Compensation
Link NOC:Analog Electronic Circuit Lecture 34 - Unity Gain Bandwidth
Link NOC:Analog Electronic Circuit Lecture 35 - Power Amplification
Link NOC:Analog Electronic Circuit Lecture 36 - Power Amplifiers-2
Link NOC:Analog Electronic Circuit Lecture 37 - Power Amplifiers- Class A,B,AB,C ClassD
Link NOC:Analog Electronic Circuit Lecture 38 - Class D Amplifiers, Push-pull Amplifiers
Link NOC:Analog Electronic Circuit Lecture 39 - Introduction to Voltage Regulators
Link NOC:Analog Electronic Circuit Lecture 40 - Voltage Regulators- line, load; Conclusion Regulation
Link NOC:Nonlinear and Adaptive Control Lecture 1 - Introduction
Link NOC:Nonlinear and Adaptive Control Lecture 2 - Preliminaries
Link NOC:Nonlinear and Adaptive Control Lecture 3 - Model Reference Adaptive Control - Part 1
Link NOC:Nonlinear and Adaptive Control Lecture 4 - Model Reference Adaptive Control - Part 2
Link NOC:Nonlinear and Adaptive Control Lecture 5 - Model Reference Adaptive Control - Part 3
Link NOC:Nonlinear and Adaptive Control Lecture 6 - Adaptive Command Tracking
Link NOC:Nonlinear and Adaptive Control Lecture 7 - Robust Model Reference Adaptive Control - Part 1
Link NOC:Nonlinear and Adaptive Control Lecture 8 - Robust Model Reference Adaptive Control - Part 2
Link NOC:Nonlinear and Adaptive Control Lecture 9 - Robust Model Reference Adaptive Control - Part 3
Link NOC:Nonlinear and Adaptive Control Lecture 10 - Robust Model Reference Adaptive Control - Part 4
Link NOC:Information Theory, Coding and Cryptography Lecture 1 - Introduction to Information Theory
Link NOC:Information Theory, Coding and Cryptography Lecture 2 - Entropy, Mutual Information, Conditional and Joint Entropy
Link NOC:Information Theory, Coding and Cryptography Lecture 3 - Measures for Continuous, Random Variable, Relative Entropy
Link NOC:Information Theory, Coding and Cryptography Lecture 4 - Variable Length Codes, Prefix Codes
Link NOC:Information Theory, Coding and Cryptography Lecture 5 - Source Coding Theorem
Link NOC:Information Theory, Coding and Cryptography Lecture 6 - various source coding Techniques: Huffman, Arithmetic, Lempel Ziv, Run Length
Link NOC:Information Theory, Coding and Cryptography Lecture 7 - Optimum Quantizer, Practical Application of Source Coding: JPEG Compression
Link NOC:Information Theory, Coding and Cryptography Lecture 8 - Introduction to Super Information
Link NOC:Information Theory, Coding and Cryptography Lecture 9 - Channel Models and Channel Capacity
Link NOC:Information Theory, Coding and Cryptography Lecture 10 - Noisy Channel Coding Theorem
Link NOC:Information Theory, Coding and Cryptography Lecture 11 - Gaussian Channel and Information Capacity Theorem
Link NOC:Information Theory, Coding and Cryptography Lecture 12 - Capacity of MIMO Channels
Link NOC:Information Theory, Coding and Cryptography Lecture 13 - Introduction to Error Control Coding
Link NOC:Information Theory, Coding and Cryptography Lecture 14 - Introduction to Galois Field
Link NOC:Information Theory, Coding and Cryptography Lecture 15 - Equivalent Codes, Generator Matrix and Parity Check Matrix
Link NOC:Information Theory, Coding and Cryptography Lecture 16 - Systematic Codes, Error Detections and Correction
Link NOC:Information Theory, Coding and Cryptography Lecture 17 - Erasure and Errors, Standard Array and Syndrome Decoding
Link NOC:Information Theory, Coding and Cryptography Lecture 18 - Probability of Error, Coding Gain and Hamming Bound
Link NOC:Information Theory, Coding and Cryptography Lecture 19 - Hamming Codes, LDPC Codes and MDS Codes
Link NOC:Information Theory, Coding and Cryptography Lecture 20 - Introduction to Cyclic Codes
Link NOC:Information Theory, Coding and Cryptography Lecture 21 - Generator Polynomial, Syndrome Polynomial and Matrix Representation
Link NOC:Information Theory, Coding and Cryptography Lecture 22 - Fire Code, Golay Code, CRC Codes and Circuit Implementation of Cyclic Codes
Link NOC:Information Theory, Coding and Cryptography Lecture 23 - Introduction to BCH Codes: Generator Polynomials
Link NOC:Information Theory, Coding and Cryptography Lecture 24 - Multiple Error Correcting BCH Codes, Decoding of BCH Codes
Link NOC:Information Theory, Coding and Cryptography Lecture 25 - Introduction to Reed Solomon (RS) Codes
Link NOC:Information Theory, Coding and Cryptography Lecture 26 - Introduction to Convolutional Codes
Link NOC:Information Theory, Coding and Cryptography Lecture 27 - Trellis Codes: Generator Polynomial Matrix and Encoding using Trellis
Link NOC:Information Theory, Coding and Cryptography Lecture 28 - Vitrebi Decoding and Known good Convolutional Codes
Link NOC:Information Theory, Coding and Cryptography Lecture 29 - Introduction to Turbo Codes
Link NOC:Information Theory, Coding and Cryptography Lecture 30 - Introduction to Trellis Coded Modulation (TCM)
Link NOC:Information Theory, Coding and Cryptography Lecture 31 - Ungerboek's Design Rules and Performance Evaluation of TCM Schemes
Link NOC:Information Theory, Coding and Cryptography Lecture 32 - TCM for Fading Channel and Space Time Trellis Codes (STTC)
Link NOC:Information Theory, Coding and Cryptography Lecture 33 - Introduction to Space Time Block Codes (STBC)
Link NOC:Information Theory, Coding and Cryptography Lecture 34 - Space Time Codes
Link NOC:Information Theory, Coding and Cryptography Lecture 35 - Space Time Codes (Continued...)
Link NOC:Information Theory, Coding and Cryptography Lecture 36 - Introduction to Cryptography: Symmetric key and Asymmetric Key Cryptography
Link NOC:Information Theory, Coding and Cryptography Lecture 37 - Some Well-Known Algorithms: DES, IDEA, PGP, DH Protocol
Link NOC:Information Theory, Coding and Cryptography Lecture 38 - Introduction to Physical Layer Security: Notion of Secrecy Capacity
Link NOC:Information Theory, Coding and Cryptography Lecture 39 - Secrecy Outage Capacity, Secrecy Outage Probability, Cooperative Jamming
Link Engineering Electromagnetics Lecture 1 - Introduction
Link Engineering Electromagnetics Lecture 2 - Transmission Lines : Wave Propagation
Link Engineering Electromagnetics Lecture 3 - Transmission Lines : Reflection,Transmission; Travelling Waves
Link Engineering Electromagnetics Lecture 4 - Transmission Lines : Travelling Waves (Continued...); Sinusoidal Signals; Impedence Transformation
Link Engineering Electromagnetics Lecture 5 - Transmission Lines : Standing Wave Ratio:Measurement of Impedence
Link Engineering Electromagnetics Lecture 6 - Transmission Lines : General Transmission Lines Equations,Low loss,Transmission Lines,Transmission Lines as Circuit Elements
Link Engineering Electromagnetics Lecture 7 - Transmission Lines : Section as Circuit Elements
Link Engineering Electromagnetics Lecture 8 - Transmission Lines : Velocities of Propagation, Transmission Lines Charts
Link Engineering Electromagnetics Lecture 9 - Transmission Lines : Smith Chart
Link Engineering Electromagnetics Lecture 10 - Transmission Lines : Impedance Matching using Stub-Lines
Link Engineering Electromagnetics Lecture 11 - Transmission Lines : Transmission Lines Parameters; (primary Constants)
Link Engineering Electromagnetics Lecture 12 - Wave Propagation
Link Engineering Electromagnetics Lecture 13 - Wave Propagation (Continued...)
Link Engineering Electromagnetics Lecture 14 - Wave Propagation : Polarisation,Poynting Vector
Link Engineering Electromagnetics Lecture 15 - Wave Propagation : Power Flow,Complex Poynting vector,wave equation for a conducting Medium
Link Engineering Electromagnetics Lecture 16 - Wave Propagation : Conducting Medium;Conductors and Dielectrics Depth of Penetration;Surface Impedance
Link Engineering Electromagnetics Lecture 17 - Wave Propagation : Surface Impedance; Power Loss in a Conductor Reflection at a Perfect conductor (Normal Inc.)
Link Engineering Electromagnetics Lecture 18 - Reflection and Refraction of waves : Reflection at the Surface of a Conducting Medium,Reflection at a Perfect Conductor (Oblique Inc.)
Link Engineering Electromagnetics Lecture 19 - Reflection and Refraction of waves (Continued...)
Link Engineering Electromagnetics Lecture 20 - Reflection and Refraction of waves (Continued...) - 1
Link Engineering Electromagnetics Lecture 21 - Reflection and Refraction of waves (Continued...); The Plane slab
Link Engineering Electromagnetics Lecture 22 - Reflection and Refraction of waves (Continued...); Transmission Line Analogy for Planes Waves
Link Engineering Electromagnetics Lecture 23 - Wave Guides
Link Engineering Electromagnetics Lecture 24 - Wave Guides (Continued...) Parallel plane Guide,Transverse Electric Waves,Field Distribution,Superposition of Plane Waves
Link Engineering Electromagnetics Lecture 25 - Wave Guides (Continued...)
Link Engineering Electromagnetics Lecture 26 - Wave Guides (Continued...) Parallel plane Guide,Characteristics of TE and Tm Waves,TEM Waves,Wave Impedances
Link Engineering Electromagnetics Lecture 27 - Wave Guides (Continued...) - 1
Link Engineering Electromagnetics Lecture 28 - Wave Guides (Continued...) - 2
Link Engineering Electromagnetics Lecture 29 - Wave Guides (Continued...) Rectangular Wave Guides
Link Engineering Electromagnetics Lecture 30 - Wave Guides (Continued...)
Link Engineering Electromagnetics Lecture 31 - Wave Guides (Continued...) Rectangular Wave Guides - 1
Link Engineering Electromagnetics Lecture 32 - Resonators General Properties
Link Engineering Electromagnetics Lecture 33 - Resonators (Continued...) Transmission Line Resonators
Link Engineering Electromagnetics Lecture 34 - Resonators (Continued...) Wave Guide Resonators
Link Engineering Electromagnetics Lecture 35 - Radiation
Link Engineering Electromagnetics Lecture 36 - Radiation (Continued...)
Link Engineering Electromagnetics Lecture 37 - Radiation (Continued...) - 1
Link Engineering Electromagnetics Lecture 38 - Radiation (Continued...) - 2
Link Engineering Electromagnetics Lecture 39 - Radiation (Continued...) Monopole Antennas half Wave Dipole Antenna
Link Engineering Electromagnetics Lecture 40 - Radiation (Continued...)
Link Engineering Electromagnetics Lecture 41 - Radiation (Continued...) 2 - Element Arrays,Yagi-Uda Array
Link NOC:Principles of Digital Communications (2018) Lecture 1 - Introduction
Link NOC:Principles of Digital Communications (2018) Lecture 2 - Signal Spaces : Waveforms and Vector Spaces
Link NOC:Principles of Digital Communications (2018) Lecture 3 - Inner Product and Orthogonal Expansion
Link NOC:Principles of Digital Communications (2018) Lecture 4 - Signal Spaces : Gram Schmidt Orthogonalization and Receiver Structures
Link NOC:Principles of Digital Communications (2018) Lecture 5 - Signal Spaces : Fourier Series and Related expansions
Link NOC:Principles of Digital Communications (2018) Lecture 6 - Signal Spaces : Bandwidth and Degree of Freedom
Link NOC:Principles of Digital Communications (2018) Lecture 7 - Random Variables and Random Processes : Discrete Random Variable
Link NOC:Principles of Digital Communications (2018) Lecture 8 - Random Variables and Random Processes : Continuous Random Variable
Link NOC:Principles of Digital Communications (2018) Lecture 9 - Random Variables and Random Processes : Multiple Random Variable
Link NOC:Principles of Digital Communications (2018) Lecture 10 - Random Variables and Random Processes : Random Vectors
Link NOC:Principles of Digital Communications (2018) Lecture 11 - Random Variables and Random Processes : Introduction to Random Process
Link NOC:Principles of Digital Communications (2018) Lecture 12 - Random Variables and Random Processes : Properties of Random Process
Link NOC:Principles of Digital Communications (2018) Lecture 13 - Random Variables and Random Processes : Gaussian Random Process - Part 1
Link NOC:Principles of Digital Communications (2018) Lecture 14 - Random Variables and Random Processes : Gaussian Random Process - Part 2
Link NOC:Principles of Digital Communications (2018) Lecture 15 - Random Variables and Random Processes : Types of Random Process
Link NOC:Principles of Digital Communications (2018) Lecture 16 - Random Variables and Random Processes : Random Process through an LTI system
Link NOC:Principles of Digital Communications (2018) Lecture 17 - Random Variables and Random Processes : Spectral description of Random Process
Link NOC:Principles of Digital Communications (2018) Lecture 18 - Waveform Coding
Link NOC:Principles of Digital Communications (2018) Lecture 19 - Modulation : Complex Baseband Representation of Passband Signals - Part 1
Link NOC:Principles of Digital Communications (2018) Lecture 20 - Modulation : Complex Baseband Representation of Passband Signals - Part 2
Link NOC:Principles of Digital Communications (2018) Lecture 21 - Modulation : Complex Baseband Representation of Passband Signals - Part 3
Link NOC:Principles of Digital Communications (2018) Lecture 22 - Modulation : Spectral Description of Sources - Part 1
Link NOC:Principles of Digital Communications (2018) Lecture 23 - Modulation : Spectral Description of Sources - Part 2
Link NOC:Principles of Digital Communications (2018) Lecture 24 - Modulation : Spectral Description of Sources using Markov Chains and Cyclostationary Random Processes
Link NOC:Principles of Digital Communications (2018) Lecture 25 - Modulation : Nyquist Pulses
Link NOC:Principles of Digital Communications (2018) Lecture 26 - Modulation : Pulse Amplitude Modulation and Quadrature Amplitude Modulation - Part 1
Link NOC:Principles of Digital Communications (2018) Lecture 27 - Modulation : Pulse Amplitude Modulation and Quadrature Amplitude Modulation - Part 2
Link NOC:Principles of Digital Communications (2018) Lecture 28 - Modulation : Orthogonal Modulation Schemes
Link NOC:Principles of Digital Communications (2018) Lecture 29 - Modulation : Differential Modulation Schemes
Link NOC:Principles of Digital Communications (2018) Lecture 30 - Detection : Maximum Aposteriori Probability (MAP) Detector and Maximum Likelihood (ML) Detector
Link NOC:Principles of Digital Communications (2018) Lecture 31 - Detection : Vector Detection
Link NOC:Principles of Digital Communications (2018) Lecture 32 - Detection : Theorem of Irrelevance and Waveform Detection
Link NOC:Principles of Digital Communications (2018) Lecture 33 - Detection : Sequence Detection
Link NOC:Principles of Digital Communications (2018) Lecture 34 - Detection : Performance of Binary Signalling Schemes
Link NOC:Principles of Digital Communications (2018) Lecture 35 - Detection : Performance of M-ary Signaling Schemes
Link NOC:Principles of Digital Communications (2018) Lecture 36 - Detection : Performance of Orthogonal Modulation Schemes and Bit-Level Demodulation
Link NOC:Principles of Digital Communications (2018) Lecture 37 - Detection : Performance of Non-Coherent Systems Systems
Link NOC:Principles of Digital Communications (2018) Lecture 38 - Detection : Fading Channel
Link NOC:Electric Vehicles - Part 1 Lecture 1 - Introduction - EV Historical Background
Link NOC:Electric Vehicles - Part 1 Lecture 2 - Introduction - EV Benefits of Using EVs
Link NOC:Electric Vehicles - Part 1 Lecture 3 - Introduction - EV Overview of types of EVs and its Challenges
Link NOC:Electric Vehicles - Part 1 Lecture 4 - Introduction - EV Motor Drive Technologies
Link NOC:Electric Vehicles - Part 1 Lecture 5 - Introduction - EV Energy Source Technologies
Link NOC:Electric Vehicles - Part 1 Lecture 6 - Introduction - EV Battery Charging Technologies
Link NOC:Electric Vehicles - Part 1 Lecture 7 - Introduction - EV Vehicle to Grid
Link NOC:Electric Vehicles - Part 1 Lecture 8 - Introduction - EV Subsystems and Configurations
Link NOC:Electric Vehicles - Part 1 Lecture 9 - Introduction - HEV Subsystems and Configurations
Link NOC:Electric Vehicles - Part 1 Lecture 10 - Introduction - HEV Subsystems and Modes of Operation
Link NOC:Electric Vehicles - Part 1 Lecture 11 - Vehicle Dynamics Introduction and tractive effort
Link NOC:Electric Vehicles - Part 1 Lecture 12 - Vehicle Dynamics and dynamic equation
Link NOC:Electric Vehicles - Part 1 Lecture 13 - Vehicle Dynamics simulation dynamic equation constant Fte
Link NOC:Electric Vehicles - Part 1 Lecture 14 - Vehicle Dynamics dynamic equation variable Fte
Link NOC:Electric Vehicles - Part 1 Lecture 15 - Vehicle Dynamics simulation dynamic equation variable Fte
Link NOC:Electric Vehicles - Part 1 Lecture 16 - Vehicle Dynamics Modelling and simulation in Simulink
Link NOC:Electric Vehicles - Part 1 Lecture 17 - Summary Electric Vehicles Part 1 Course
Link NOC:Electric Vehicles - Part 1 Lecture 18 - Basics of DC Motor Drive
Link NOC:Electric Vehicles - Part 1 Lecture 19 - Realization of DC Chopper
Link NOC:Electric Vehicles - Part 1 Lecture 20 - Open Loop Operation of Chopper Fed DC Motor Drive
Link NOC:Electric Vehicles - Part 1 Lecture 21 - Review of Control Theory
Link NOC:Electric Vehicles - Part 1 Lecture 22 - Modeling and Current Controller Design for Separately Excited DC Motor Drive
Link NOC:Electric Vehicles - Part 1 Lecture 23 - Speed Controller Design and Performance Evaluation of DC Motor Drive
Link NOC:Electric Vehicles - Part 1 Lecture 24 - Fundamentals of Three Phase Induction Motor
Link NOC:Electric Vehicles - Part 1 Lecture 25 - Equivalent Circuit and Torque-Speed Characteristics of Induction Motor
Link NOC:Electric Vehicles - Part 1 Lecture 26 - Starting and Speed Control of Induction Motor
Link NOC:Electric Vehicles - Part 1 Lecture 27 - Realisation of DC to AC Power Converter
Link NOC:Electric Vehicles - Part 1 Lecture 28 - Impact of Non-Sinusoidal Voltage on Induction Motor
Link NOC:Electric Vehicles - Part 1 Lecture 29 - Selective Harmonic Elimination and Optimal Pulse Width Modulation Techniques
Link NOC:Electric Vehicles - Part 1 Lecture 30 - Switching Energy Losses and Sine-Triangle PWM
Link NOC:Electric Vehicles - Part 1 Lecture 31 - Analysis of Sine-Triangle PWM
Link NOC:Electric Vehicles - Part 1 Lecture 32 - Simulation Studies on Open Loop Induction Motor Drive
Link NOC:Power Electronics Lecture 1 - Introduction to Power Electronics
Link NOC:Power Electronics Lecture 2 - Power Devices: Diodes and SCR
Link NOC:Power Electronics Lecture 3 - Power Devices: SCR, Triac, GTO and BJT
Link NOC:Power Electronics Lecture 4 - Power Devices: BJT, MOSFET and IGBT
Link NOC:Power Electronics Lecture 5 - Single-phase Uncontrolled Rectifiers
Link NOC:Power Electronics Lecture 6 - Single-phase Controlled Rectifiers - I
Link NOC:Power Electronics Lecture 7 - Single-phase Controlled Rectifiers - II
Link NOC:Power Electronics Lecture 8 - Three Phase Rectifiers - I
Link NOC:Power Electronics Lecture 9 - Numericals on devices and Single-phase Rectifiers
Link NOC:Power Electronics Lecture 10 - Three Phase Rectifiers - II
Link NOC:Power Electronics Lecture 11 - Dual Converter and Communication Overlap
Link NOC:Power Electronics Lecture 12 - Communication Overlap - II and AC-AC Converter-Introduction
Link NOC:Power Electronics Lecture 13 - Single-Phase and Three-Phase AC Voltage Controllers
Link NOC:Power Electronics Lecture 14 - Three-Phase AC Voltage Controllers and Cycloconverters
Link NOC:Power Electronics Lecture 15 - Non-Isolated DC-DC Converters - I
Link NOC:Power Electronics Lecture 16 - Non-Isolated DC-DC Converters - II
Link NOC:Power Electronics Lecture 17 - Isolated DC-DC Converters - I
Link NOC:Power Electronics Lecture 18 - Isolated DC-DC Converters - II and Cuk Converters
Link NOC:Power Electronics Lecture 19 - Voltage Source Inverters
Link NOC:Power Electronics Lecture 20 - VSI PWM Techniques - I
Link NOC:Power Electronics Lecture 21 - VSI PWM Techniques - II
Link NOC:Power Electronics Lecture 22 - SPWM and SVM Technique
Link NOC:Power Electronics Lecture 23 - Current Source Inverter
Link NOC:Power Electronics Lecture 24 - Power Electronics Applications
Link NOC:Electrical Machines Lecture 1 - Introduction to Electrical Machines - I
Link NOC:Electrical Machines Lecture 2 - Single-phase and Three-phase AC Circuits, Magnetic circuits
Link NOC:Electrical Machines Lecture 3 - Magnetic Circuit - II
Link NOC:Electrical Machines Lecture 4 - Magnetic Circuit - III
Link NOC:Electrical Machines Lecture 5 - Transformers - Introduction
Link NOC:Electrical Machines Lecture 6 - Transformers - Amp-Turn Balance, Ideal and practical transformers
Link NOC:Electrical Machines Lecture 7 - Transformer Equivalent circuit and Reducing leakage
Link NOC:Electrical Machines Lecture 8 - Transformer equivalent circuit parameter determination
Link NOC:Electrical Machines Lecture 9 - Transformers - Voltage regulation and efficiency
Link NOC:Electrical Machines Lecture 10 - Auto-transformers
Link NOC:Electrical Machines Lecture 11 - PU notation and Intoduction to Instrument transformers
Link NOC:Electrical Machines Lecture 12 - Instrument Transformers and All Day Efficiency
Link NOC:Electrical Machines Lecture 13 - Three Phase Transformers - I
Link NOC:Electrical Machines Lecture 14 - Three Phase Transformers - II
Link NOC:Electrical Machines Lecture 15 - Electromechanical Energy Conversion - I
Link NOC:Electrical Machines Lecture 16 - Electromechanical Energy Conversion - II
Link NOC:Electrical Machines Lecture 17 - Electromechanical Energy Conversion - III
Link NOC:Electrical Machines Lecture 18 - DC Machines-Introduction, Constructional Features
Link NOC:Electrical Machines Lecture 19 - DC Machines - EMF and Torque Equations and Generator Operation
Link NOC:Electrical Machines Lecture 20 - DC Machines - OCC and Load Charactristics Classification
Link NOC:Electrical Machines Lecture 21 - DC Machines - Armature Reaction
Link NOC:Electrical Machines Lecture 22 - DC Machines - Voltage Build-up and Load Characteristics
Link NOC:Electrical Machines Lecture 23 - DC Generator Characteristics and Introduction to DC Motors
Link NOC:Electrical Machines Lecture 24 - DC Motors: Basics and Speed-Torque Relationship
Link NOC:Electrical Machines Lecture 25 - DC Motor: Speed Control (Shunt and Separately Exicited Motor)
Link NOC:Electrical Machines Lecture 26 - DC Motor: Speed Control (Series and Compound Motor)
Link NOC:Electrical Machines Lecture 27 - DC Machine: Starting and Braking
Link NOC:Electrical Machines Lecture 28 - DC Machine: Comutation
Link NOC:Electrical Machines Lecture 29 - 3 Phase Induction Machine: Constructional Features and Principle of Operation
Link NOC:Electrical Machines Lecture 30 - 3 Phase Induction Machine: Equivalent Circuit
Link NOC:Electrical Machines Lecture 31 - 3 Phase Induction Machine: Speed Torque Characteristics
Link NOC:Electrical Machines Lecture 32 - Testing of Induction Motor: OC and SC Test
Link NOC:Electrical Machines Lecture 33 - 3 Phase Induction Machine: Starting Methods
Link NOC:Electrical Machines Lecture 34 - Synchronous Machines: Introduction
Link NOC:Electrical Machines Lecture 35 - Synchronous Machines: Constructional Features
Link NOC:Electrical Machines Lecture 36 - Numerical Session
Link NOC:Electrical Machines Lecture 37 - Synchronization of Alternators
Link NOC:Electrical Machines Lecture 38 - Synchronous Machines: Equivalent Circuit and Phasor Diagram
Link NOC:Electrical Machines Lecture 39 - Synchronous Machines: OC and SC Test
Link NOC:Electrical Machines Lecture 40 - Synchronous Machines: Power Angle Relationship, V and Inverted V Curves
Link NOC:Electrical Machines Lecture 41 - Single Phase Induction Motors
Link Special Electromechanical Systems Lecture 1 - Special Electromechanical Systems (Introduction)
Link Special Electromechanical Systems Lecture 2 - Classification of Machines
Link Special Electromechanical Systems Lecture 3 - Single and Two-Phase Motors
Link Special Electromechanical Systems Lecture 4 - Single-Phase Induction Motors-Analysis
Link Special Electromechanical Systems Lecture 5 - Starting of Single-Phase Induction Motors
Link Special Electromechanical Systems Lecture 6 - Single-Phase Induction Motors Analysis
Link Special Electromechanical Systems Lecture 7 - Induction Motors Analysis by Symmetrical Components
Link Special Electromechanical Systems Lecture 8 - Modelling of 1-Phase Induction Motor (One and Two Windings)
Link Special Electromechanical Systems Lecture 9 - Asymmetrical Induction Motor Generalized Rotating Field Theory
Link Special Electromechanical Systems Lecture 10 - Generalized Rotating Field Theory (Continued...)
Link Special Electromechanical Systems Lecture 11 - Generalized Rotating Field Theory (Continued...)
Link Special Electromechanical Systems Lecture 12 - Generalized Rotating Field Theory (Continued...)
Link Special Electromechanical Systems Lecture 13 - Analysis of Asymmetrical Machine by Generalized Rotating Field Theory
Link Special Electromechanical Systems Lecture 14 - Analysis of Asymmetrical Machine
Link Special Electromechanical Systems Lecture 15 - Analysis of Asymmetrical Induction Machine
Link Special Electromechanical Systems Lecture 16 - Generalised Rotating-Field Theory of Wound Rotor Ind. Machine Having Asymmetry in Stator and Rotor Windings
Link Special Electromechanical Systems Lecture 17 - Generalised Rotating-Field Theory of Wound Rotor Ind. Machine Having Asymmetry in Stator and Rotor Windings (Continued...)
Link Special Electromechanical Systems Lecture 18 - Testing of Small Electrical Machines
Link Special Electromechanical Systems Lecture 19 - Testing of 1-Phase Induction Motors
Link Special Electromechanical Systems Lecture 20 - Variable Reluctance (VR) Motors
Link Special Electromechanical Systems Lecture 21 - Switched Reluctance Motor (Continued...)
Link Special Electromechanical Systems Lecture 22 - Switched Reluctance Motor (Continued...)
Link Special Electromechanical Systems Lecture 23 - Switched Reluctance Motor (Continued...)
Link Special Electromechanical Systems Lecture 24 - Stepper Motors
Link Special Electromechanical Systems Lecture 25 - Stepper Motors (Continued...)
Link Special Electromechanical Systems Lecture 26 - Induction Generators
Link Special Electromechanical Systems Lecture 27 - Induction Generators (Continued...)
Link Special Electromechanical Systems Lecture 28 - Doubly Fed Induction Generators
Link Special Electromechanical Systems Lecture 29 - Self Excited Induction Generators
Link Special Electromechanical Systems Lecture 30 - Self Excited Induction Generators (Continued...)
Link Special Electromechanical Systems Lecture 31 - Permanent Magnet Machines
Link Special Electromechanical Systems Lecture 32 - Squareware Permanent Magnet Brushless Motor Drive
Link Special Electromechanical Systems Lecture 33 - Sine Wave Permanent Magnet Brushless Motor Drives
Link Special Electromechanical Systems Lecture 34 - Permanent Magnet Synchronous Motors
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 1 - Basic Understanding of Converter (Introduction to Power Converters)
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 2 - Basic Understanding of Converter (Half Bridge and Full Bridge Circuit Operation)
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 3 - Basic Understanding of Converter (Sinusoidal Pulse width Modulation and Three Phase Circuit)
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 4 - Basic Understanding of Converter (Harmonics in Sinusoidal PWM)
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 5 - Third harmonic addition in Sine PWM
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 6 - Introduction to Space Vectors
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 7 - Space Vector PWM - Timing Calculation
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 8 - Space Vector PWM - Switching Sequence
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 9 - Space Vector PWM - Using Carriers
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 10 - Basic Introduction to Power Devices
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 11 - Introduction to Multilevel Converters
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 12 - Cascaded H-bridge Multilevel Converters
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 13 - Output Voltage Waveform Synthesis in CHB Converter and Basic of Asymmetrical CHB Converters
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 14 - Cascaded H-Bridge Converters: Phase-Shifted PWM
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 15 - Cascaded H-Bridge Converters: Level-Shifted PWM
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 16 - Fault Tolerant Operation of Cascaded H-Bridge Converter - Part I
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 17 - Fault Tolerant Operation of Cascaded H-Bridge Converter - Part II
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 18 - Modular Multilevel Converter - Topology and Operation
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 19 - Modular Multilevel Converter - Arm and Cell Voltage Ratings
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 20 - Modular Multilevel Converter - Arm Currents
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 21 - Modular Multilevel Converter - Arm Energy Balancing
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 22 - Modular Multilevel Converter - Different Circuit Topologies
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 23 - Modular Multilevel Converter - PWM Technique and Capacitor Voltage Balancing
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 24 - Modular Multilevel Converter - Fault Tolerant Operation and Commercial Production
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 25 - Design of Components in MMC
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 26 - Neutral Point Clamped Converter - Circuit Topology - Part I
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 27 - Neutral Point Clamped Converter - Circuit Topology - Part II
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 28 - Neutral Point Clamped Converter - Space Vector Diagram
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 29 - Neutral Point Clamped Converter - Space Vector PWM
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 30 - NPC - Sinusoidal PWM and Space Vector PWM using Single Carrier Strategy
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 31 - Neutral Point Clamped Converter - Mid-point Voltage Fluctuations
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 32 - Neutral Point Clamped Converter - Capacitor Voltage Balancing
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 33 - Neutral Point Clamped Converter - Another Strategy of Capacitor Voltage Balancing
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 34 - Other Topologies of NPC Converters - Higher Level NPC, TNPC and Active NPC
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 35 - Multipulse Transformer - Part I
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 36 - Multipulse Transformer - Part II
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 37 - A Case Study on MMC and CHB
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 38 - Basics of Gate Driver Circuits
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 39 - Gate Driver Circuits - Turn-on and Turn-off Process
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 40 - Gate Driver Circuits - Features of Gate Drivers and Basics of Bootstrap Functionality
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 41 - Condition Monitoring of Converters
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 42 - Other Converter Topologies
Link NOC:High Power Multilevel Converters - Analysis, Design and Operational Issues Lecture 43 - Summary of the Course
Link NOC:Introduction to Embedded System Design Lecture 1 - Introduction
Link NOC:Introduction to Embedded System Design Lecture 2 - Introduction continued with Project demos
Link NOC:Introduction to Embedded System Design Lecture 3 - Modular Approach to ESD
Link NOC:Introduction to Embedded System Design Lecture 4 - Modular Approach to ESD (Continued...)
Link NOC:Introduction to Embedded System Design Lecture 5 - Salient Features of Modern Microcontrollers
Link NOC:Introduction to Embedded System Design Lecture 6 - Salient Features of Modern Microcontrollers (Continued...)
Link NOC:Introduction to Embedded System Design Lecture 7 - Elements of Microcontroller Ecosystem
Link NOC:Introduction to Embedded System Design Lecture 8 - Elements of Microcontroller Ecosystem (Continued...)
Link NOC:Introduction to Embedded System Design Lecture 9 - Power Supply for Embedded Systems
Link NOC:Introduction to Embedded System Design Lecture 10 - Power Supply for Embedded Systems (Continued...)
Link NOC:Introduction to Embedded System Design Lecture 11 - Introduction to MSP430
Link NOC:Introduction to Embedded System Design Lecture 12 - MSP430 Architecture
Link NOC:Introduction to Embedded System Design Lecture 13 - MSP430 Architecture- (Continued...) And Introduction to Lunchbox
Link NOC:Introduction to Embedded System Design Lecture 14 - Programming Methods for MSP430
Link NOC:Introduction to Embedded System Design Lecture 15 - Physical Interfacing - 1
Link NOC:Introduction to Embedded System Design Lecture 16 - Physical Interfacing - 2
Link NOC:Introduction to Embedded System Design Lecture 17 - Physical Interfacing - 3
Link NOC:Introduction to Embedded System Design Lecture 18 - Physical Interfacing - 4
Link NOC:Introduction to Embedded System Design Lecture 19 - Physical Interfacing - 5
Link NOC:Introduction to Embedded System Design Lecture 20 - Physical Interfacing - 6
Link NOC:Introduction to Embedded System Design Lecture 21 - GIT, CCS Installation and Embedded C
Link NOC:Introduction to Embedded System Design Lecture 22 - MSP430 Digital I/O
Link NOC:Introduction to Embedded System Design Lecture 23 - MSP430 Digital I/O: Switch Interfacing
Link NOC:Introduction to Embedded System Design Lecture 24 - MSP430 Clock System and Reset
Link NOC:Introduction to Embedded System Design Lecture 25 - Interrupts in MSP430
Link NOC:Introduction to Embedded System Design Lecture 26 - Interrupts in MSP430 (Continued...)
Link NOC:Introduction to Embedded System Design Lecture 27 - Interfacing Seven Segment Displays with MSP430; Low Power Modes in MSP430
Link NOC:Introduction to Embedded System Design Lecture 28 - Interfacing Liquid Crystal Displays (LCD)
Link NOC:Introduction to Embedded System Design Lecture 29 - MSP430 Timer Module: Introduction and Timer Capture
Link NOC:Introduction to Embedded System Design Lecture 30 - Pulse Width Modulation, PWM using Timer Capture
Link NOC:Introduction to Embedded System Design Lecture 31 - Analog to Digital Converter in the MSP430
Link NOC:Introduction to Embedded System Design Lecture 32 - ADC and DAC using R2R Ladder and Random number generation using LFSR
Link NOC:Introduction to Embedded System Design Lecture 33 - Serial Communication Protocols, USCI Module in MSP430
Link NOC:Introduction to Embedded System Design Lecture 34 - MSP430 Timer in Capture Mode
Link NOC:Introduction to Embedded System Design Lecture 35 - Coding Ninja
Link NOC:Introduction to Embedded System Design Lecture 36 - Building an Electronics Project
Link NOC:Introduction to Embedded System Design Lecture 37 - Circuit Prototyping Techniques
Link NOC:Introduction to Embedded System Design Lecture 38 - Single Purpose Computers
Link NOC:Introduction to Embedded System Design Lecture 39 - Single Purpose Computers (Continued...)
Link NOC:Introduction to Embedded System Design Lecture 40 - Recap of Course Coverage and Project Demonstration from Concept to Final
Link NOC:Power Quality Lecture 1 - Power Quality - An Introduction
Link NOC:Power Quality Lecture 2 - Power Quality Standards and Monitoring
Link NOC:Power Quality Lecture 3 - Power Quality Standards and Monitoring (Continued...)
Link NOC:Power Quality Lecture 4 - Passive Shunt and Series Compensations
Link NOC:Power Quality Lecture 5 - Passive Shunt and Series Compensations (Continued...)
Link NOC:Power Quality Lecture 6 - Passive Shunt and Series Compensations (Continued...)
Link NOC:Power Quality Lecture 7 - Active Shunt Compensation
Link NOC:Power Quality Lecture 8 - Active Shunt Compensation (Continued...)
Link NOC:Power Quality Lecture 9 - Active Shunt Compensation (Continued...)
Link NOC:Power Quality Lecture 10 - Active Series Compensation
Link NOC:Power Quality Lecture 11 - Active Series Compensation (Continued...)
Link NOC:Power Quality Lecture 12 - Unified Power Quality Compensators
Link NOC:Power Quality Lecture 13 - Unified Power Quality Compensators (Continued...)
Link NOC:Power Quality Lecture 14 - Unified Power Quality Compensators (Continued...)
Link NOC:Power Quality Lecture 15 - Loads Which Cause Power Quality Problems
Link NOC:Power Quality Lecture 16 - Loads Which Cause Power Quality Problems (Continued...)
Link NOC:Power Quality Lecture 17 - Passive Power Filters
Link NOC:Power Quality Lecture 18 - Passive Power Filters (Continued...)
Link NOC:Power Quality Lecture 19 - Passive Power Filters (Continued...)
Link NOC:Power Quality Lecture 20 - Shunt Active Power Filters
Link NOC:Power Quality Lecture 21 - Shunt Active Power Filters (Continued...)
Link NOC:Power Quality Lecture 22 - Shunt Active Power Filters (Continued...)
Link NOC:Power Quality Lecture 23 - Active Series Power Filters
Link NOC:Power Quality Lecture 24 - Active Series Power Filters (Continued...)
Link NOC:Power Quality Lecture 25 - Active Series Power Filters (Continued...)
Link NOC:Power Quality Lecture 26 - Hybrid Power Filters
Link NOC:Power Quality Lecture 27 - Hybrid Power Filters (Continued...)
Link NOC:Power Quality Lecture 28 - Hybrid Power Filters (Continued...)
Link NOC:Power Quality Lecture 29 - AC-DC Converters That Cause Power Quality
Link NOC:Power Quality Lecture 30 - Improved Power Quality Converters - AC-DC Boost Converters
Link NOC:Power Quality Lecture 31 - Improved Power Quality Converters - AC-DC Boost Converters (Continued...)
Link NOC:Power Quality Lecture 32 - Improved Power Quality Converters - AC-DC Buck Converters
Link NOC:Power Quality Lecture 33 - Improved Power Quality Converters - AC-DC Buck-Boost Converters
Link NOC:Power Quality Lecture 34 - Improved Power Quality Converters - AC-DC Buck-Boost Converters (Continued...)
Link NOC:Power Quality Lecture 35 - Improved Power Quality Converters - AC-DC Buck-Boost Converters (Continued...)
Link NOC:Power Quality Lecture 36 - Three Phase AC-DC Improved Power Quality Converters
Link NOC:Power Quality Lecture 37 - Multipulse Converters
Link NOC:Power Quality Lecture 38 - Multipulse Converters (Continued...)
Link NOC:Power Quality Lecture 39 - Multipulse Converters (Continued...)
Link NOC:Power Quality Lecture 40 - Power Quality Improvement in Solar Energy Conversion System
Link NOC:Power Quality Lecture 41 - Power Quality Improvement in Solar Energy Conversion System (Continued...)
Link NOC:Power Quality Lecture 42 - Power Quality Improvement in Wind Energy Conversion System
Link NOC:Power Quality Lecture 43 - Power Quality Improvement in Diesel Generator Set Based Power Supply System
Link NOC:Power Quality Lecture 44 - Power Quality Improvement in Diesel Generator Set Based Power Supply System (Continued...)
Link NOC:Power Quality Lecture 45 - Power Quality Improvement in Distributed Generation Sources Based Microgrids
Link NOC:Introduction to Electrical Engineering Lecture 1
Link NOC:Introduction to Electrical Engineering Lecture 2
Link NOC:Introduction to Electrical Engineering Lecture 3
Link NOC:Introduction to Electrical Engineering Lecture 4
Link NOC:Introduction to Electrical Engineering Lecture 5
Link NOC:Introduction to Electrical Engineering Lecture 6
Link NOC:Introduction to Electrical Engineering Lecture 7
Link NOC:Introduction to Electrical Engineering Lecture 8
Link NOC:Introduction to Electrical Engineering Lecture 9
Link NOC:Introduction to Electrical Engineering Lecture 10
Link NOC:Introduction to Electrical Engineering Lecture 11
Link NOC:Introduction to Electrical Engineering Lecture 12
Link NOC:Introduction to Electrical Engineering Lecture 13
Link NOC:Introduction to Electrical Engineering Lecture 14
Link NOC:Introduction to Electrical Engineering Lecture 15
Link NOC:Introduction to Electrical Engineering Lecture 16
Link NOC:Introduction to Electrical Engineering Lecture 17
Link NOC:Introduction to Electrical Engineering Lecture 18
Link NOC:Introduction to Electrical Engineering Lecture 19
Link NOC:Introduction to Electrical Engineering Lecture 20
Link NOC:Introduction to Electrical Engineering Lecture 21
Link NOC:Introduction to Electrical Engineering Lecture 22
Link NOC:Introduction to Electrical Engineering Lecture 23
Link NOC:Introduction to Electrical Engineering Lecture 24
Link NOC:Introduction to Electrical Engineering Lecture 25
Link NOC:Introduction to Electrical Engineering Lecture 26
Link NOC:Introduction to Electrical Engineering Lecture 27
Link NOC:Introduction to Electrical Engineering Lecture 28
Link NOC:Introduction to Electrical Engineering Lecture 29
Link NOC:Introduction to Electrical Engineering Lecture 30
Link NOC:Introduction to Electrical Engineering Lecture 31
Link NOC:Introduction to Electrical Engineering Lecture 32
Link NOC:Introduction to Electrical Engineering Lecture 33
Link NOC:Introduction to Electrical Engineering Lecture 34
Link NOC:Introduction to Electrical Engineering Lecture 35
Link NOC:Introduction to Electrical Engineering Lecture 36
Link NOC:Introduction to Electrical Engineering Lecture 37
Link NOC:Introduction to Electrical Engineering Lecture 38
Link NOC:Introduction to Electrical Engineering Lecture 39
Link NOC:Introduction to Electrical Engineering Lecture 40
Link NOC:Introduction to Electrical Engineering Lecture 41
Link NOC:Introduction to Electrical Engineering Lecture 42
Link NOC:Transducers for Instrumentation Lecture 1
Link NOC:Transducers for Instrumentation Lecture 2
Link NOC:Transducers for Instrumentation Lecture 3
Link NOC:Transducers for Instrumentation Lecture 4
Link NOC:Transducers for Instrumentation Lecture 5
Link NOC:Transducers for Instrumentation Lecture 6
Link NOC:Transducers for Instrumentation Lecture 7
Link NOC:Transducers for Instrumentation Lecture 8
Link NOC:Transducers for Instrumentation Lecture 9
Link NOC:Transducers for Instrumentation Lecture 10
Link NOC:Transducers for Instrumentation Lecture 11
Link NOC:Transducers for Instrumentation Lecture 12
Link NOC:Transducers for Instrumentation Lecture 13
Link NOC:Transducers for Instrumentation Lecture 14
Link NOC:Transducers for Instrumentation Lecture 15
Link NOC:Transducers for Instrumentation Lecture 16
Link NOC:Transducers for Instrumentation Lecture 17
Link NOC:Transducers for Instrumentation Lecture 18
Link NOC:Transducers for Instrumentation Lecture 19
Link NOC:Transducers for Instrumentation Lecture 20
Link NOC:Transducers for Instrumentation Lecture 21
Link NOC:Transducers for Instrumentation Lecture 22
Link NOC:Transducers for Instrumentation Lecture 23
Link NOC:Transducers for Instrumentation Lecture 24
Link NOC:Transducers for Instrumentation Lecture 25
Link NOC:Transducers for Instrumentation Lecture 26
Link NOC:Transducers for Instrumentation Lecture 27
Link NOC:Transducers for Instrumentation Lecture 28
Link NOC:Transducers for Instrumentation Lecture 29
Link NOC:Transducers for Instrumentation Lecture 30
Link NOC:Transducers for Instrumentation Lecture 31
Link NOC:Transducers for Instrumentation Lecture 32
Link NOC:Transducers for Instrumentation Lecture 33
Link NOC:Transducers for Instrumentation Lecture 34
Link NOC:Transducers for Instrumentation Lecture 35
Link NOC:Transducers for Instrumentation Lecture 36
Link NOC:Computer-Aided Design of Electrical Machines Lecture 1 - Course Outline and Introduction
Link NOC:Computer-Aided Design of Electrical Machines Lecture 2 - Fundamental - I
Link NOC:Computer-Aided Design of Electrical Machines Lecture 3 - Equivalent Circuit Approach to Design
Link NOC:Computer-Aided Design of Electrical Machines Lecture 4 - Transformer Design - I
Link NOC:Computer-Aided Design of Electrical Machines Lecture 5 - Transformer Design - II
Link NOC:Computer-Aided Design of Electrical Machines Lecture 6 - Transformer Design - III
Link NOC:Computer-Aided Design of Electrical Machines Lecture 7 - Transformer Design - IV
Link NOC:Computer-Aided Design of Electrical Machines Lecture 8 - Windings in Electrical Machines
Link NOC:Computer-Aided Design of Electrical Machines Lecture 9 - Design of DC Machine - I
Link NOC:Computer-Aided Design of Electrical Machines Lecture 10 - Design of DC Machine - II
Link NOC:Computer-Aided Design of Electrical Machines Lecture 11 - Design of DC Machine - III
Link NOC:Computer-Aided Design of Electrical Machines Lecture 12 - Design of Three-Phase Induction Motors - I
Link NOC:Computer-Aided Design of Electrical Machines Lecture 13 - Design of Three-Phase Induction Motors - II
Link NOC:Computer-Aided Design of Electrical Machines Lecture 14 - Design of Three-Phase Induction Motors - III
Link NOC:Computer-Aided Design of Electrical Machines Lecture 15 - Design of Three-Phase Induction Motors - IV
Link NOC:Computer-Aided Design of Electrical Machines Lecture 16 - Design of Single-Phase Induction Machine - I
Link NOC:Computer-Aided Design of Electrical Machines Lecture 17 - Design of Single-Phase Induction Machine - II
Link NOC:Computer-Aided Design of Electrical Machines Lecture 18 - Design of Single-Phase Induction Machine - III
Link NOC:Computer-Aided Design of Electrical Machines Lecture 19 - Design of Three-Phase Synchronous Machines - I
Link NOC:Computer-Aided Design of Electrical Machines Lecture 20 - Design of Three-Phase Synchronous Machines - II
Link NOC:Computer-Aided Design of Electrical Machines Lecture 21 - Design of Three-Phase Synchronous Machines - III
Link NOC:Computer-Aided Design of Electrical Machines Lecture 22 - Design of Three-Phase Synchronous Machines - IV
Link NOC:Computer-Aided Design of Electrical Machines Lecture 23 - Design of Synchronous Reluctance Machines - I
Link NOC:Computer-Aided Design of Electrical Machines Lecture 24 - Design of Synchronous Reluctance Machines - II
Link NOC:Computer-Aided Design of Electrical Machines Lecture 25 - Design of Synchronous Reluctance Machines - III
Link NOC:Computer-Aided Design of Electrical Machines Lecture 26 - Design of Brushless PM Machines - I
Link NOC:Computer-Aided Design of Electrical Machines Lecture 27 - Design of Brushless PM Machines - II
Link NOC:Computer-Aided Design of Electrical Machines Lecture 28 - Design of Brushless PM Machines - III
Link NOC:Computer-Aided Design of Electrical Machines Lecture 29 - Design of Brushless PM Machines - IV
Link NOC:Computer-Aided Design of Electrical Machines Lecture 30 - Design of Brushless PM Machines - V
Link NOC:Computer-Aided Design of Electrical Machines Lecture 31 - Design of Switched Reluctance Machines - I
Link NOC:Computer-Aided Design of Electrical Machines Lecture 32 - Design of Switched Reluctance Machines - II
Link NOC:Computer-Aided Design of Electrical Machines Lecture 33 - Design of Switched Reluctance Machines - III
Link NOC:Computer-Aided Design of Electrical Machines Lecture 34 - Design of Stepper Machines - I
Link NOC:Computer-Aided Design of Electrical Machines Lecture 35 - Design of Stepper Machines - II
Link NOC:Computer-Aided Design of Electrical Machines Lecture 36 - Design of Axial Flux Machines - I
Link NOC:Computer-Aided Design of Electrical Machines Lecture 37 - Design of Axial Flux Machines - II
Link NOC:Computer-Aided Design of Electrical Machines Lecture 38 - Computer Aided Design and Analysis Method - I
Link NOC:Computer-Aided Design of Electrical Machines Lecture 39 - Computer Aided Design and Analysis Method - II
Link NOC:Computer-Aided Design of Electrical Machines Lecture 40 - Case Studies and Tutorials - I and II
Link NOC:Computer-Aided Design of Electrical Machines Lecture 41 - Tutorial-III : Determination of Transformer Operating Point
Link NOC:Computer-Aided Design of Electrical Machines Lecture 42 - Tutorial-IV
Link Advanced Control Systems Lecture 1 - Introduction
Link Advanced Control Systems Lecture 2 - Control structures and performance measures
Link Advanced Control Systems Lecture 3 - Time and frequency domain performance measures
Link Advanced Control Systems Lecture 4 - Design of controller
Link Advanced Control Systems Lecture 5 - Design of controller for SISO system
Link Advanced Control Systems Lecture 6 - Controller design for TITO processes
Link Advanced Control Systems Lecture 7 - Limitations of PID controllers
Link Advanced Control Systems Lecture 8 - PI-PD controller for SISO system
Link Advanced Control Systems Lecture 9 - PID-P controller for Two Input Two Output system
Link Advanced Control Systems Lecture 10 - Effects of measurement noise and load
Link Advanced Control Systems Lecture 11 - Identification of dynamic models of plants
Link Advanced Control Systems Lecture 12 - Relay control system for identification
Link Advanced Control Systems Lecture 13 - Off-line identification of process dynamics
Link Advanced Control Systems Lecture 14 - On-line identification of plant dynamics
Link Advanced Control Systems Lecture 15 - State space based identification
Link Advanced Control Systems Lecture 16 - State space analysis of systems
Link Advanced Control Systems Lecture 17 - State space based identification of systems - 1
Link Advanced Control Systems Lecture 18 - State space based identification of systems - 2
Link Advanced Control Systems Lecture 19 - Identification of simple systems
Link Advanced Control Systems Lecture 20 - Identification of FOPDT model
Link Advanced Control Systems Lecture 21 - Identification of second order plus dead time model
Link Advanced Control Systems Lecture 22 - Identification of SOPDT model
Link Advanced Control Systems Lecture 23 - Steady state gain from asymmetrical relay test
Link Advanced Control Systems Lecture 24 - Identification of SOPDT model with pole multiplicity
Link Advanced Control Systems Lecture 25 - Existence of limit cycle for unstable system
Link Advanced Control Systems Lecture 26 - Identification procedures
Link Advanced Control Systems Lecture 27 - Identification of underdamped systems
Link Advanced Control Systems Lecture 28 - Off-line identification of TITO systems
Link Advanced Control Systems Lecture 29 - On-line identification of TITO systems
Link Advanced Control Systems Lecture 30 - Review of time domain based identification
Link Advanced Control Systems Lecture 31 - DF based analytical expressions for on-line identification
Link Advanced Control Systems Lecture 32 - Model parameter accuracy and sensitivity
Link Advanced Control Systems Lecture 33 - Improved identification using Fourier series and wavelet transform
Link Advanced Control Systems Lecture 34 - Reviews of DF based identification
Link Advanced Control Systems Lecture 35 - Advanced Smith predictor controller
Link Advanced Control Systems Lecture 36 - Design of controllers for the advanced Smith predictor
Link Advanced Control Systems Lecture 37 - Model-free controller design
Link Advanced Control Systems Lecture 38 - Model Based PID controller Design - I
Link Advanced Control Systems Lecture 39 - Model Based PI-PD controller Design - II
Link Advanced Control Systems Lecture 40 - Tuning of reconfigurable PID controllers
Link NOC:Optimization Techniques for Digital VLSI Design Lecture 1 - Introduction to Digital VLSI Design Flow
Link NOC:Optimization Techniques for Digital VLSI Design Lecture 2 - High-level Synthesis (HLS) flow with an example
Link NOC:Optimization Techniques for Digital VLSI Design Lecture 3 - Automation of High-level Synthesis Steps
Link NOC:Optimization Techniques for Digital VLSI Design Lecture 4 - Impact of Coding Style on HLS Results
Link NOC:Optimization Techniques for Digital VLSI Design Lecture 5 - Impact of Compiler Optimizations on HLS Results
Link NOC:Optimization Techniques for Digital VLSI Design Lecture 6 - RTL Optimizations for Timing
Link NOC:Optimization Techniques for Digital VLSI Design Lecture 7 - Retiming
Link NOC:Optimization Techniques for Digital VLSI Design Lecture 8 - RTL Optimizations for Area
Link NOC:Optimization Techniques for Digital VLSI Design Lecture 9 - RTL Optimizations for Power
Link NOC:Optimization Techniques for Digital VLSI Design Lecture 10 - High Level Synthesis: Introduction to Logic Synthesis
Link NOC:Optimization Techniques for Digital VLSI Design Lecture 11 - Overview of FPGA Technology Mapping
Link NOC:Optimization Techniques for Digital VLSI Design Lecture 12 - Introduction to Physical Synthesis
Link NOC:Optimization Techniques for Digital VLSI Design Lecture 13 - Introduction to Digital VLSI Testing - I
Link NOC:Optimization Techniques for Digital VLSI Design Lecture 14 - Introduction to Digital VLSI Testing - II
Link NOC:Optimization Techniques for Digital VLSI Design Lecture 15 - Optimization Techniques for ATPG - Part I
Link NOC:Optimization Techniques for Digital VLSI Design Lecture 16 - Optimization Techniques for ATPG - Part II
Link NOC:Optimization Techniques for Digital VLSI Design Lecture 17 - Optimization Techniques for Design for Testability
Link NOC:Optimization Techniques for Digital VLSI Design Lecture 18 - High-level fault modeling and RTL level Testing
Link NOC:Optimization Techniques for Digital VLSI Design Lecture 19 - LTL/CTL based Verification
Link NOC:Optimization Techniques for Digital VLSI Design Lecture 20 - Verification of Large Scale Systems
Link NOC:Optimization Techniques for Digital VLSI Design Lecture 21 - BDD based verification
Link NOC:Optimization Techniques for Digital VLSI Design Lecture 22 - Verification: ADD based verification, HDD based verification
Link NOC:Optimization Techniques for Digital VLSI Design Lecture 23 - Verification: Symbolic Model Checking
Link NOC:Optimization Techniques for Digital VLSI Design Lecture 24 - Verification: Bounded Model Checking
Link NOC:Advanced Topics in Probability and Random Processes Lecture 1 - Probability Basics
Link NOC:Advanced Topics in Probability and Random Processes Lecture 2 - Random Variable - I
Link NOC:Advanced Topics in Probability and Random Processes Lecture 3 - Random Variable - II
Link NOC:Advanced Topics in Probability and Random Processes Lecture 4 - Random Vectors and Random Processes
Link NOC:Advanced Topics in Probability and Random Processes Lecture 5 - Infinite Sequence of Events - I
Link NOC:Advanced Topics in Probability and Random Processes Lecture 6 - Infinite Sequence of Events - II
Link NOC:Advanced Topics in Probability and Random Processes Lecture 7 - Convergence of Sequence of Random Variables
Link NOC:Advanced Topics in Probability and Random Processes Lecture 8 - Weak Convergence - I
Link NOC:Advanced Topics in Probability and Random Processes Lecture 9 - Weak Convergence - II
Link NOC:Advanced Topics in Probability and Random Processes Lecture 10 - Laws of Large Numbers
Link NOC:Advanced Topics in Probability and Random Processes Lecture 11 - Central Limit Theorem
Link NOC:Advanced Topics in Probability and Random Processes Lecture 12 - Large Deviation Theory
Link NOC:Advanced Topics in Probability and Random Processes Lecture 13 - Crammer's Theorem for Large Deviation
Link NOC:Advanced Topics in Probability and Random Processes Lecture 14 - Introduction to Markov Processes
Link NOC:Advanced Topics in Probability and Random Processes Lecture 15 - Discrete Time Markov Chain - 1
Link NOC:Advanced Topics in Probability and Random Processes Lecture 16 - Discrete Time Markov Chain - 2
Link NOC:Advanced Topics in Probability and Random Processes Lecture 17 - Discrete Time Markov Chain - 3
Link NOC:Advanced Topics in Probability and Random Processes Lecture 18 - Discrete Time Markov Chain - 4
Link NOC:Advanced Topics in Probability and Random Processes Lecture 19 - Discrete Time Markov Chain - 5
Link NOC:Advanced Topics in Probability and Random Processes Lecture 20 - Continuous Time Markov Chain - 1
Link NOC:Advanced Topics in Probability and Random Processes Lecture 21 - Continuous Time Markov Chain - 2
Link NOC:Advanced Topics in Probability and Random Processes Lecture 22 - Continuous Time Markov Chain - 3
Link NOC:Advanced Topics in Probability and Random Processes Lecture 23 - Martingale Process - 1
Link NOC:Advanced Topics in Probability and Random Processes Lecture 24 - Martingale Process - 2
Link NOC:Microwave Engineering Lecture 1 - Introduction to Microwave Engineering
Link NOC:Microwave Engineering Lecture 2 - Introduction to Transmission Line Theory
Link NOC:Microwave Engineering Lecture 3 - Lossy Transmission Line
Link NOC:Microwave Engineering Lecture 4 - Smith Chart
Link NOC:Microwave Engineering Lecture 5 - Introduction to Waveguides and Rectangular Waveguide
Link NOC:Microwave Engineering Lecture 6 - Circular Waveguide
Link NOC:Microwave Engineering Lecture 7 - Attenuation Waveguide
Link NOC:Microwave Engineering Lecture 8 - N-port microwave networks and equivalent voltages and currents
Link NOC:Microwave Engineering Lecture 9 - Scattering Matrix (S-Parameters) Part-1
Link NOC:Microwave Engineering Lecture 10 - Scattering Matrix (S-parameters) Part-2 and Transmission Matrix (ABCD-Parameters)
Link NOC:Microwave Engineering Lecture 11 - Impedance Matching Using L-Section and Series Stub Networks
Link NOC:Microwave Engineering Lecture 12 - Impedance Matching Using Shunt Stub, Double Stub and Quarter wave Transformer
Link NOC:Microwave Engineering Lecture 13 - Multisection Matching Networks and Tapered Lines
Link NOC:Microwave Engineering Lecture 14 - Series and Parallel RLC Resonators
Link NOC:Microwave Engineering Lecture 15 - Transmission Line Resonators
Link NOC:Microwave Engineering Lecture 16 - Waveguide Resonators
Link NOC:Microwave Engineering Lecture 17 - Introduction to power dividers
Link NOC:Microwave Engineering Lecture 18 - Directional couplers
Link NOC:Microwave Engineering Lecture 19 - Microwave Filters - Part 1
Link NOC:Microwave Engineering Lecture 20 - Microwave Filters - Part 2
Link NOC:Microwave Engineering Lecture 21 - Characteristics of Microwave BJT and FET
Link NOC:Microwave Engineering Lecture 22 - PIN Diodes and Control Circuits
Link NOC:Microwave Engineering Lecture 23 - Schottky Diodes and Detectors and Tunnel Diodes
Link NOC:Microwave Engineering Lecture 24 - Gunn Diodes, IMPATT Diodes and Varactor Diodes
Link NOC:Microwave Engineering Lecture 25 - Two-Port Power Gain and Stability
Link NOC:Microwave Engineering Lecture 26 - Design of single stage transistor amplifier (for maximum gain, specified gain, low noise)
Link NOC:Microwave Engineering Lecture 27 - RF oscillator
Link NOC:Microwave Engineering Lecture 28 - Limitations of Conventional Tubes at Microwave Ranges
Link NOC:Microwave Engineering Lecture 29 - Introduction to Klystron
Link NOC:Microwave Engineering Lecture 30 - Reflex Klystron, Magnetron and TWT
Link NOC:Microwave Engineering Lecture 31 - Ferrite Devices
Link NOC:Microwave Engineering Lecture 32 - Planar transmission lines for MIC
Link NOC:Microwave Engineering Lecture 33 - Lumped elements for MIC
Link NOC:Microwave Engineering Lecture 34 - Lumped inductor, HMIC and MMIC
Link NOC:Microwave Engineering Lecture 35 - Overview of Radar
Link NOC:Microwave Engineering Lecture 36 - Cellular Communication
Link NOC:Microwave Engineering Lecture 37 - Satellite Communication and Applications of Microwave
Link NOC:Microprocessors and Interfacing Lecture 1 - Microprocessor Operations
Link NOC:Microprocessors and Interfacing Lecture 2 - 8086 Flags
Link NOC:Microprocessors and Interfacing Lecture 3 - Functional Diagram of 8086
Link NOC:Microprocessors and Interfacing Lecture 4 - 8086 Common and Minimum Mode Signals
Link NOC:Microprocessors and Interfacing Lecture 5 - 8086 Maximum Mode Signals
Link NOC:Microprocessors and Interfacing Lecture 6 - 8086 Data Transfer Instructions
Link NOC:Microprocessors and Interfacing Lecture 7 - 8086 Arithmetic Instructions - I
Link NOC:Microprocessors and Interfacing Lecture 8 - 8086 Arithmetic Instructions - II
Link NOC:Microprocessors and Interfacing Lecture 9 - 8086 Logical Instructions
Link NOC:Microprocessors and Interfacing Lecture 10 - 8086 Branch and String Instructions
Link NOC:Microprocessors and Interfacing Lecture 11 - 8086 Interrupt and Machine Control Instructions
Link NOC:Microprocessors and Interfacing Lecture 12 - Sum of Products, Multi-byte addition
Link NOC:Microprocessors and Interfacing Lecture 13 - Largest number, 2's complement Programs
Link NOC:Microprocessors and Interfacing Lecture 14 - Programs on Subroutines
Link NOC:Microprocessors and Interfacing Lecture 15 - ROM, RAM
Link NOC:Microprocessors and Interfacing Lecture 16 - Example I
Link NOC:Microprocessors and Interfacing Lecture 17 - Example II
Link NOC:Microprocessors and Interfacing Lecture 18 - Architecture, Interfacing to Simple I/O
Link NOC:Microprocessors and Interfacing Lecture 19 - Keyboard Interface
Link NOC:Microprocessors and Interfacing Lecture 20 - 7-segment Display Interface
Link NOC:Microprocessors and Interfacing Lecture 21 - Multiplexed 7-sgment Display Interface
Link NOC:Microprocessors and Interfacing Lecture 22 - Stepper motor, Liquid level control
Link NOC:Microprocessors and Interfacing Lecture 23 - Traffic light control, A/D converter
Link NOC:Microprocessors and Interfacing Lecture 24 - D/A converter
Link NOC:Microprocessors and Interfacing Lecture 25 - Electronic weighing machine
Link NOC:Microprocessors and Interfacing Lecture 26 - Programable Interval Timer (8254)
Link NOC:Microprocessors and Interfacing Lecture 27 - Modes of 8254
Link NOC:Microprocessors and Interfacing Lecture 28 - Architecture of 8259
Link NOC:Microprocessors and Interfacing Lecture 29 - Initialization command words of 8259
Link NOC:Microprocessors and Interfacing Lecture 30 - Operational command words of 8259
Link NOC:Microprocessors and Interfacing Lecture 31 - 8237 Architecture, interfacing and Programming
Link NOC:Microprocessors and Interfacing Lecture 32 - Basic Concepts of serial I/O
Link NOC:Microprocessors and Interfacing Lecture 33 - Basic Concepts of serial I/O (Continued...)
Link NOC:Microprocessors and Interfacing Lecture 34 - Architecture of 8251
Link NOC:Statistical Signal Processing Lecture 1 - Overview of Statistical Signal Processing
Link NOC:Statistical Signal Processing Lecture 2 - Probability and Random Variables
Link NOC:Statistical Signal Processing Lecture 3 - Linear Algebra of Random Variables
Link NOC:Statistical Signal Processing Lecture 4 - Random Processes
Link NOC:Statistical Signal Processing Lecture 5 - Linear Shift Invariant Systems with Random Inputs
Link NOC:Statistical Signal Processing Lecture 6 - White Noise and Spectral Factorization Theorem
Link NOC:Statistical Signal Processing Lecture 7 - Linear Models of Random Signals
Link NOC:Statistical Signal Processing Lecture 8 - Estimation Theory - 1
Link NOC:Statistical Signal Processing Lecture 9 - Estimation Theory - 2: MVUE and Cramer Rao Lower Bound
Link NOC:Statistical Signal Processing Lecture 10 - Cramer Rao Lower Bound 2
Link NOC:Statistical Signal Processing Lecture 11 - MVUE through Sufficient Statistic - 1
Link NOC:Statistical Signal Processing Lecture 12 - MVUE through Sufficient Statistic - 2
Link NOC:Statistical Signal Processing Lecture 13 - Method of Moments and Maximum Likelihood Estimators
Link NOC:Statistical Signal Processing Lecture 14 - Properties of Maximum Likelihood Estimator (MLE)
Link NOC:Statistical Signal Processing Lecture 15 - Bayesian Estimators - 1
Link NOC:Statistical Signal Processing Lecture 16 - Bayesian Estimators - 2
Link NOC:Statistical Signal Processing Lecture 17 - Optimal linear filters: Wiener Filter
Link NOC:Statistical Signal Processing Lecture 18 - FIR Wiener filter
Link NOC:Statistical Signal Processing Lecture 19 - Non-Causual IIR Wiener Filter
Link NOC:Statistical Signal Processing Lecture 20 - Causal IIR Wiener Filter
Link NOC:Statistical Signal Processing Lecture 21 - Linear Prediction of Signals - 1
Link NOC:Statistical Signal Processing Lecture 22 - Linear Prediction of Signals - 2
Link NOC:Statistical Signal Processing Lecture 23 - Linear Prediction of Signals - 3
Link NOC:Statistical Signal Processing Lecture 24 - Review Assignment - 1
Link NOC:Statistical Signal Processing Lecture 25 - Adaptive Filters - 1
Link NOC:Statistical Signal Processing Lecture 26 - Adaptive Filters - 2
Link NOC:Statistical Signal Processing Lecture 27 - Adaptive Filters - 3
Link NOC:Statistical Signal Processing Lecture 28 - Review Assignment - 2
Link NOC:Statistical Signal Processing Lecture 29 - Adaptive Filters - 4
Link NOC:Statistical Signal Processing Lecture 30 - Adaptive Filters - 4 (Continued...)
Link NOC:Statistical Signal Processing Lecture 31 - Review Assignment - 3
Link NOC:Statistical Signal Processing Lecture 32 - Recursive Least Squares (RLS) Adaptive Filter - 1
Link NOC:Statistical Signal Processing Lecture 33 - Recursive Least Squares (RLS) Adaptive Filter - 2
Link NOC:Statistical Signal Processing Lecture 34 - Review Assignment - 4
Link NOC:Statistical Signal Processing Lecture 35 - Kalman Filter - 1
Link NOC:Statistical Signal Processing Lecture 36 - Vector Kalman Filter
Link NOC:Statistical Signal Processing Lecture 37 - Linear Models of Random Signals
Link NOC:Statistical Signal Processing Lecture 38 - Review - 1
Link NOC:Statistical Signal Processing Lecture 39 - Review - 2
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 1 - Introduction to Digital Image Processing
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 2 - Introduction to Computer Vision
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 3 - Introduction to Computer Vision and Basic Concepts of Image Formation
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 4 - Shape From Shading
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 5 - Image Formation: Geometric Camera Models - I
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 6 - Image Formation: Geometric Camera Models - II
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 7 - Image Formation: Geometric Camera Models - III
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 8 - Image Formation in a Stereo Vision Setup
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 9 - Image Reconstruction from a Series of Projections
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 10 - Image Reconstruction from a Series of Projections
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 11 - Image Transforms - I
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 12 - Image Transforms - II
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 13 - Image Transforms - III
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 14 - Image Transforms - IV
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 15 - Image Enhancement
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 16 - Image Filtering - I
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 17 - Image Filtering - II
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 18 - Colour Image Processing - I
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 19 - Colour Image Processing - II
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 20 - Image Segmentation
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 21 - Image Features and Edge Detection
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 22 - Edge Detection
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 23 - Hough Transform
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 24 - Image Texture Analysis - I
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 25 - Image Texture Analysis - II
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 26 - Object Boundary and Shape Representations - I
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 27 - Object Boundary and Shape Representations - II
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 28 - Interest Point Detectors
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 29 - Image Features - HOG and SIFT
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 30 - Introduction to Machine Learning - I
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 31 - Introduction to Machine Learning - II
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 32 - Introduction to Machine Learning - III
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 33 - Introduction to Machine Learning - IV
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 34 - Introduction to Machine Learning - V
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 35 - Artificial Neural Network for Pattern Classification - I
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 36 - Artificial Neural Network for Pattern Classification - II
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 37 - Introduction to Deep Learning
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 38 - Gesture Recognition
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 39 - Background Modelling and Motion Estimation
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 40 - Object Tracking
Link NOC:Computer Vision and Image Processing - Fundamentals and Applications Lecture 41 - Programming Examples
Link NOC:System Design through VERILOG Lecture 1 - Verilog Operators and Modules
Link NOC:System Design through VERILOG Lecture 2 - Verilog Ports, Data types and Assignments
Link NOC:System Design through VERILOG Lecture 3 - Basics of gate level modeling
Link NOC:System Design through VERILOG Lecture 4 - Half adder, full adder and ripple carry adder
Link NOC:System Design through VERILOG Lecture 5 - Parallel adder/subtractor
Link NOC:System Design through VERILOG Lecture 6 - Multiplier and comparator
Link NOC:System Design through VERILOG Lecture 7 - Decoder, encoder and multiplexer
Link NOC:System Design through VERILOG Lecture 8 - Demultiplexer, read only memory
Link NOC:System Design through VERILOG Lecture 9 - Review of flip-flops
Link NOC:System Design through VERILOG Lecture 10 - Verilog modeling of flip-flops
Link NOC:System Design through VERILOG Lecture 11 - Modeling of CMOS gates and Boolean functions
Link NOC:System Design through VERILOG Lecture 12 - Modeling using transmission gates, CMOS dalay times
Link NOC:System Design through VERILOG Lecture 13 - Signal strengths
Link NOC:System Design through VERILOG Lecture 14 - Basics of dataflow modeling
Link NOC:System Design through VERILOG Lecture 15 - Examples of dataflow modeling
Link NOC:System Design through VERILOG Lecture 16 - Basics of behavioral modeling
Link NOC:System Design through VERILOG Lecture 17 - Examples of behavioral modeling
Link NOC:System Design through VERILOG Lecture 18 - Verilog modeling of counters
Link NOC:System Design through VERILOG Lecture 19 - Verilog modeling of sequence detector
Link NOC:System Design through VERILOG Lecture 20 - Verilog modeling FSMs and shift registers
Link NOC:System Design through VERILOG Lecture 21 - Combinational circuit examples
Link NOC:System Design through VERILOG Lecture 22 - Sequential circuit examples
Link NOC:System Design through VERILOG Lecture 23 - Arithmetic and Logic Unit (ALU)
Link NOC:System Design through VERILOG Lecture 24 - Static RAM and Braun Multiplier
Link NOC:System Design through VERILOG Lecture 25 - FIR filter implementation
Link NOC:System Design through VERILOG Lecture 26 - Baugh-Wooley signed multiplier architecture
Link NOC:System Design through VERILOG Lecture 27 - IIR filter implementation
Link NOC:Usability Engineering Lecture 1 - Introduction to Usability
Link NOC:Usability Engineering Lecture 2 - Usability - Historical Foundations
Link NOC:Usability Engineering Lecture 3 - Standard Terminologies
Link NOC:Usability Engineering Lecture 4 - Elements of User Experience
Link NOC:Usability Engineering Lecture 5 - Usability in software development - I
Link NOC:Usability Engineering Lecture 6 - Usability in software development - II
Link NOC:Usability Engineering Lecture 7 - User Centered Design Process - I
Link NOC:Usability Engineering Lecture 8 - User Centered Design Process - II
Link NOC:Usability Engineering Lecture 9 - User Centered Design Process - III
Link NOC:Usability Engineering Lecture 10 - Requirement Analysis - I (A)
Link NOC:Usability Engineering Lecture 11 - Requirement Analysis - I (B)
Link NOC:Usability Engineering Lecture 12 - Requirement Analysis - I (C)
Link NOC:Usability Engineering Lecture 13 - Requirement Analysis - I (D)
Link NOC:Usability Engineering Lecture 14 - Requirement Analysis - I (E)
Link NOC:Usability Engineering Lecture 15 - Requirement Analysis - I (F)
Link NOC:Usability Engineering Lecture 16 - Requirement Analysis - II (A)
Link NOC:Usability Engineering Lecture 17 - Requirement Analysis - II (B)
Link NOC:Usability Engineering Lecture 18 - Requirement Analysis - II (C)
Link NOC:Usability Engineering Lecture 19 - Requirement Analysis - II (D)
Link NOC:Usability Engineering Lecture 20 - Requirement Analysis - III (A)
Link NOC:Usability Engineering Lecture 21 - Eye Tracker
Link NOC:Usability Engineering Lecture 22 - Demonstration of an Eye tracking device
Link NOC:Usability Engineering Lecture 23 - Requirement Analysis - III (B)
Link NOC:Usability Engineering Lecture 24 - Mapping Experiences
Link NOC:Usability Engineering Lecture 25 - Cognitive Issues - I
Link NOC:Usability Engineering Lecture 26 - Cognitive Issues - II
Link NOC:Usability Engineering Lecture 27 - Cognitive Issues - III
Link NOC:Usability Engineering Lecture 28 - Cognitive Issues - IV
Link NOC:Usability Engineering Lecture 29 - Competitive analysis and preparing for design briefing - I
Link NOC:Usability Engineering Lecture 30 - Competitive analysis and preparing for design briefing - II
Link NOC:Usability Engineering Lecture 31 - Conceptualization and Prototyping - I (A)
Link NOC:Usability Engineering Lecture 32 - Conceptualization and Prototyping - I (B)
Link NOC:Usability Engineering Lecture 33 - Conceptualization and Prototyping - I (C)
Link NOC:Usability Engineering Lecture 34 - Conceptualization and Prototyping - II (A)
Link NOC:Usability Engineering Lecture 35 - Conceptualization and Prototyping - II (B)
Link NOC:Usability Engineering Lecture 36 - Usability heuristics and testing - I
Link NOC:Usability Engineering Lecture 37 - Usability heuristics and testing - II
Link NOC:Usability Engineering Lecture 38 - Usability heuristics and testing - III
Link NOC:Usability Engineering Lecture 39 - Usability Testing (A)
Link NOC:Usability Engineering Lecture 40 - Usability Testing (B)
Link NOC:Usability Engineering Lecture 41 - Usability Testing (C)
Link NOC:Usability Engineering Lecture 42 - UI/UX design based on Garret model: a case study
Link NOC:Usability Engineering Lecture 43 - Effective contextual enquiry
Link NOC:Usability Engineering Lecture 44 - Contextual enquiry: case study
Link NOC:Probability and Random Processes Lecture 1 - Introduction
Link NOC:Probability and Random Processes Lecture 2 - Algebra of Events
Link NOC:Probability and Random Processes Lecture 3 - Axioms of Probability
Link NOC:Probability and Random Processes Lecture 4 - Example 1
Link NOC:Probability and Random Processes Lecture 5 - Example 2
Link NOC:Probability and Random Processes Lecture 6 - Example 3
Link NOC:Probability and Random Processes Lecture 7 - Example 4
Link NOC:Probability and Random Processes Lecture 8 - Example 5
Link NOC:Probability and Random Processes Lecture 9 - Conditional Probability
Link NOC:Probability and Random Processes Lecture 10 - Bayes Theorem 1
Link NOC:Probability and Random Processes Lecture 11 - Bayes Theorem 2
Link NOC:Probability and Random Processes Lecture 12 - A Brief Review
Link NOC:Probability and Random Processes Lecture 13 - Example 1
Link NOC:Probability and Random Processes Lecture 14 - Example 2
Link NOC:Probability and Random Processes Lecture 15 - Example 3
Link NOC:Probability and Random Processes Lecture 16 - Example 4
Link NOC:Probability and Random Processes Lecture 17 - Example 5
Link NOC:Probability and Random Processes Lecture 18 - Independent Events
Link NOC:Probability and Random Processes Lecture 19 - A Brief Review
Link NOC:Probability and Random Processes Lecture 20 - Example 1
Link NOC:Probability and Random Processes Lecture 21 - Example 2
Link NOC:Probability and Random Processes Lecture 22 - Example 3
Link NOC:Probability and Random Processes Lecture 23 - Example 4
Link NOC:Probability and Random Processes Lecture 24 - Discrete Random Variables
Link NOC:Probability and Random Processes Lecture 25 - Expectation
Link NOC:Probability and Random Processes Lecture 26 - Moments
Link NOC:Probability and Random Processes Lecture 27 - Variance
Link NOC:Probability and Random Processes Lecture 28 - Binomial Random Variables
Link NOC:Probability and Random Processes Lecture 29 - Poisson Random Variables
Link NOC:Probability and Random Processes Lecture 30 - More on Poission Random Variables
Link NOC:Probability and Random Processes Lecture 31 - Properties of the CDF
Link NOC:Probability and Random Processes Lecture 32 - A Brief Review - I
Link NOC:Probability and Random Processes Lecture 33 - A Brief Review - II
Link NOC:Probability and Random Processes Lecture 34 - Example 1
Link NOC:Probability and Random Processes Lecture 35 - Example 2
Link NOC:Probability and Random Processes Lecture 36 - Example 3
Link NOC:Probability and Random Processes Lecture 37 - Example 4
Link NOC:Probability and Random Processes Lecture 38 - Example 5
Link NOC:Probability and Random Processes Lecture 39 - Example 6
Link NOC:Probability and Random Processes Lecture 40 - Example 7
Link NOC:Probability and Random Processes Lecture 41 - Example 8
Link NOC:Probability and Random Processes Lecture 42 - Example 9
Link NOC:Probability and Random Processes Lecture 43 - Continuous Random Variables
Link NOC:Probability and Random Processes Lecture 44 - Expectation of Continuous random variables
Link NOC:Probability and Random Processes Lecture 45 - The uniform and the Gaussian Random variables
Link NOC:Probability and Random Processes Lecture 46 - The mean and variance of a Gaussian Random Variable
Link NOC:Probability and Random Processes Lecture 47 - The exponential random variable and other continuous distributions
Link NOC:Probability and Random Processes Lecture 48 - A Brief Review
Link NOC:Probability and Random Processes Lecture 49 - Example 1
Link NOC:Probability and Random Processes Lecture 50 - Example 2
Link NOC:Probability and Random Processes Lecture 51 - Example 3
Link NOC:Probability and Random Processes Lecture 52 - Example 4
Link NOC:Probability and Random Processes Lecture 53 - Example 5
Link NOC:Probability and Random Processes Lecture 54 - Functions of a random varible
Link NOC:Probability and Random Processes Lecture 55 - Functions of a random varible
Link NOC:Probability and Random Processes Lecture 56 - The moment generating function
Link NOC:Probability and Random Processes Lecture 57 - Conditional Distributions
Link NOC:Probability and Random Processes Lecture 58 - Bivariate Distributions
Link NOC:Probability and Random Processes Lecture 59 - Independence of Random Varibles
Link NOC:Probability and Random Processes Lecture 60 - Jointly Gaussian Random Varibales and Circular symmetry
Link NOC:Probability and Random Processes Lecture 61 - Jointly Discrete Random Variables
Link NOC:Probability and Random Processes Lecture 62 - One Function of two random variables
Link NOC:Probability and Random Processes Lecture 63 - Order Statistics
Link NOC:Probability and Random Processes Lecture 64 - Two functions of two random variables
Link NOC:Probability and Random Processes Lecture 65 - Joint Moments
Link NOC:Probability and Random Processes Lecture 66 - Joint Charactristic Functions
Link NOC:Probability and Random Processes Lecture 67 - Conditional Distributions for multiple random variables
Link NOC:Probability and Random Processes Lecture 68 - Conditional Expectations
Link NOC:Probability and Random Processes Lecture 69 - Examples
Link NOC:Probability and Random Processes Lecture 70 - Random Vectors
Link NOC:Probability and Random Processes Lecture 71 - Independence of Random Varibles
Link NOC:Probability and Random Processes Lecture 72 - Complex Random Varibales
Link NOC:Probability and Random Processes Lecture 73 - Covariance Matrices
Link NOC:Probability and Random Processes Lecture 74 - Conditional Densities
Link NOC:Probability and Random Processes Lecture 75 - Gaussianity
Link NOC:Probability and Random Processes Lecture 76 - Chi Squared Densities
Link NOC:Probability and Random Processes Lecture 77 - Examples
Link NOC:Probability and Random Processes Lecture 78 - Estimation Theory
Link NOC:Probability and Random Processes Lecture 79 - Measurements
Link NOC:Probability and Random Processes Lecture 80 - Sequences of Random Variables
Link NOC:Probability and Random Processes Lecture 81 - Laws of large numbers
Link NOC:Probability and Random Processes Lecture 82 - Random processes
Link NOC:Probability and Random Processes Lecture 83 - Stationarity, Cyclostationarity, Ergodicity
Link NOC:Probability and Random Processes Lecture 84 - Random Processes as Signals (PSD and LTI Response)
Link NOC:Probability and Random Processes Lecture 85 - White and Gaussian Processes Noise
Link NOC:Simulation of Communication Systems using Matlab Lecture 1 - Introduction
Link NOC:Simulation of Communication Systems using Matlab Lecture 2 - Basics of MATLAB
Link NOC:Simulation of Communication Systems using Matlab Lecture 3 - Data Types
Link NOC:Simulation of Communication Systems using Matlab Lecture 4 - Floating Point Numbers
Link NOC:Simulation of Communication Systems using Matlab Lecture 5 - Scripts and Flow of Control
Link NOC:Simulation of Communication Systems using Matlab Lecture 6 - The For Loop
Link NOC:Simulation of Communication Systems using Matlab Lecture 7 - Arrays
Link NOC:Simulation of Communication Systems using Matlab Lecture 8 - Indexing
Link NOC:Simulation of Communication Systems using Matlab Lecture 9 - Some Reuslts from Linear Algebra
Link NOC:Simulation of Communication Systems using Matlab Lecture 10 - Matrix Multiplication
Link NOC:Simulation of Communication Systems using Matlab Lecture 11 - Eigenvalues and Eigenvectors
Link NOC:Simulation of Communication Systems using Matlab Lecture 12 - Complex Numbers
Link NOC:Simulation of Communication Systems using Matlab Lecture 13 - Hermitian Matrices
Link NOC:Simulation of Communication Systems using Matlab Lecture 14 - Matrix Inversion
Link NOC:Simulation of Communication Systems using Matlab Lecture 15 - Signals
Link NOC:Simulation of Communication Systems using Matlab Lecture 16 - Convolution
Link NOC:Simulation of Communication Systems using Matlab Lecture 17 - Probability
Link NOC:Simulation of Communication Systems using Matlab Lecture 18 - Bayes Theorem
Link NOC:Simulation of Communication Systems using Matlab Lecture 19 - Random Varibles
Link NOC:Simulation of Communication Systems using Matlab Lecture 20 - Clinical Trials - I
Link NOC:Simulation of Communication Systems using Matlab Lecture 21 - Clinical Trials - II
Link NOC:Simulation of Communication Systems using Matlab Lecture 22 - Random Numbers
Link NOC:Simulation of Communication Systems using Matlab Lecture 23 - Random Disttributions
Link NOC:Simulation of Communication Systems using Matlab Lecture 24 - Histograms - I
Link NOC:Simulation of Communication Systems using Matlab Lecture 25 - Histograms - II
Link NOC:Simulation of Communication Systems using Matlab Lecture 26 - Functions of Random Variables
Link NOC:Simulation of Communication Systems using Matlab Lecture 27 - Generating Random Disttributions
Link NOC:Simulation of Communication Systems using Matlab Lecture 28 - Laws of Large numbers
Link NOC:Simulation of Communication Systems using Matlab Lecture 29 - Random Processes
Link NOC:Simulation of Communication Systems using Matlab Lecture 30 - Properties of Random Processes
Link NOC:Simulation of Communication Systems using Matlab Lecture 31 - Power Spectra
Link NOC:Simulation of Communication Systems using Matlab Lecture 32 - Signals and Noise
Link NOC:Simulation of Communication Systems using Matlab Lecture 33 - Stochastic Models
Link NOC:Simulation of Communication Systems using Matlab Lecture 34 - The AR-1 Process
Link NOC:Simulation of Communication Systems using Matlab Lecture 35 - Stochastic Models II
Link NOC:Simulation of Communication Systems using Matlab Lecture 36 - Yule Walker Equations
Link NOC:Simulation of Communication Systems using Matlab Lecture 37 - Markov Chains - I
Link NOC:Simulation of Communication Systems using Matlab Lecture 38 - Markov Chains - II
Link NOC:Simulation of Communication Systems using Matlab Lecture 39 - Markov Chains - III
Link NOC:Simulation of Communication Systems using Matlab Lecture 40 - Analog to Digital Coversion
Link NOC:Simulation of Communication Systems using Matlab Lecture 41 - K Means
Link NOC:Simulation of Communication Systems using Matlab Lecture 42 - Correlation
Link NOC:Simulation of Communication Systems using Matlab Lecture 43 - Predictive Coding
Link NOC:Simulation of Communication Systems using Matlab Lecture 44 - Image Compression
Link NOC:Simulation of Communication Systems using Matlab Lecture 45 - Transform Domain Compression
Link NOC:Simulation of Communication Systems using Matlab Lecture 46 - Multi Resolution Coding
Link NOC:Simulation of Communication Systems using Matlab Lecture 47 - Introduction to Communications
Link NOC:Simulation of Communication Systems using Matlab Lecture 48 - Low Pass and BandPass Signals
Link NOC:Simulation of Communication Systems using Matlab Lecture 49 - Signal Spaces
Link NOC:Simulation of Communication Systems using Matlab Lecture 50 - PAM
Link NOC:Simulation of Communication Systems using Matlab Lecture 51 - Detection
Link NOC:Simulation of Communication Systems using Matlab Lecture 52 - Effects of AWGN
Link NOC:Simulation of Communication Systems using Matlab Lecture 53 - ML Detection - I
Link NOC:Simulation of Communication Systems using Matlab Lecture 54 - ML Detection - II
Link NOC:Simulation of Communication Systems using Matlab Lecture 55 - The Union Bound
Link NOC:Simulation of Communication Systems using Matlab Lecture 56 - Symbol Error Rates
Link NOC:Simulation of Communication Systems using Matlab Lecture 57 - Choosing Constellations
Link NOC:Simulation of Communication Systems using Matlab Lecture 58 - Orthogonal Signalling
Link NOC:Simulation of Communication Systems using Matlab Lecture 59 - Non-Coherent Dection - 1
Link NOC:Simulation of Communication Systems using Matlab Lecture 60 - Non-Coherent Dection - 2
Link NOC:Simulation of Communication Systems using Matlab Lecture 61 - DPSK - I
Link NOC:Simulation of Communication Systems using Matlab Lecture 62 - DPSK - II
Link NOC:Simulation of Communication Systems using Matlab Lecture 63 - Introduction to Wireless Communications
Link NOC:Simulation of Communication Systems using Matlab Lecture 64 - Conclusion
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 1 - Introduction to Machine Learning
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 2 - Performance Measures of Classification
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 3 - Bias-Variance Tradeoff
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 4 - Regression
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 5 - Bayesian Decision Theory - 1
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 6 - Bayesian Decision Theory - 2
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 7 - Bayes Decision Theory - Binary Features
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 8 - Bayesian Decision Theory - 3
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 9 - Bayesian Decision Theory - 4
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 10 - Bayesian Belief Networks
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 11 - Parameter Estimation and Maximum Likelihood Estimation
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 12 - Parameter Estimation and Bayesian Estimation
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 13 - Concept of non-parametric techniques
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 14 - Density Estimation by Parzen Window
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 15 - Parzen Window and K nearest neighbor algorithm
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 16 - Linear Discriminant Functions and Perceptron Criteria - Part I
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 17 - Linear Discriminant Functions and Perceptron Criteria - Part II
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 18 - Linear Discriminant Functions and Perceptron Criteria - Part III
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 19 - Support Vector Machine - Part I
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 20 - Support Vector Machine - Part II
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 21 - Logistic Regression
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 22 - Decision Tree
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 23 - Hidden Markov Model (HMM)
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 24 - Ensemble Classifiers - Part I
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 25 - Ensemble Classifiers - Part II
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 26 - Dimensionality Problem and Principal Component Analysis
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 27 - Principal Component Analysis
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 28 - Linear Discriminant Analysis (LDA) - Part I
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 29 - Linear Discriminant Analysis (LDA) - Part II
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 30 - Gaussian Mixture Model and EM Algorithm
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 31 - K-means clustering.
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 32 - Fuzzy K-means clustering
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 33 - Hierarchical Agglomerative Clustering and Mean-shift Clustering
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 34 - Artificial Neural Networks for Pattern Classification - Part 1
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 35 - Artificial Neural Networks for Pattern Classification - Part 2
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 36 - Artificial Neural Networks for Pattern Classification - Part 3
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 37 - Introduction to Deep Learning and Convolutional Neural Network (CNN)
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 38 - Vanishing and Exploding Gradients in Deep Neural Networks
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 39 - CNN Architectures - LeNet-5 and AlexNet
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 40 - CNN Architectures - VGG 16, GoogLeNet and ResNet
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 41 - Generative Adversarial Networks (GAN) - Fundamentals and Applications
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 42 - U-Net: Convolutional Networks for Image Segmentation
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 43 - Introduction to Autoencoder and Recurrent Neural Networks (RNN)
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 44 - Programming Concepts - 1
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 45 - Programming Concepts - 2
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 46 - Problem Solving Session - 1
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 47 - Problem Solving Session - 2
Link NOC:Machine Learning and Deep Learning - Fundamentals and Applications Lecture 48 - Problem Solving Session - 3
Link NOC:Integrated Circuits and Applications Lecture 1 - Introduction to Integrated Circuits
Link NOC:Integrated Circuits and Applications Lecture 2 - Summing and Difference Amplifiers
Link NOC:Integrated Circuits and Applications Lecture 3 - Instrumentation Amplifier
Link NOC:Integrated Circuits and Applications Lecture 4 - Integrator and Diffrentiator
Link NOC:Integrated Circuits and Applications Lecture 5 - Precision Half Wave and Full Wave Rectifiers
Link NOC:Integrated Circuits and Applications Lecture 6 - Clipper and Clamper circuits
Link NOC:Integrated Circuits and Applications Lecture 7 - Logarithmic and Anti-logarithmic Amplifiers
Link NOC:Integrated Circuits and Applications Lecture 8 - DC Characteristics (Offset Currents and Voltages)
Link NOC:Integrated Circuits and Applications Lecture 9 - AC Charcterstics (Frequency Response)
Link NOC:Integrated Circuits and Applications Lecture 10 - AC Charcterstics (Compensation Techniques and Slew Rate)
Link NOC:Integrated Circuits and Applications Lecture 11 - Examples on Design of Adder and Subtractor Circuits
Link NOC:Integrated Circuits and Applications Lecture 12 - Examples on Transfer Function Computation
Link NOC:Integrated Circuits and Applications Lecture 13 - Examples on Instrumentation Amplifier
Link NOC:Integrated Circuits and Applications Lecture 14 - Examples on CMRR Computation
Link NOC:Integrated Circuits and Applications Lecture 15 - First Order Low Pass Filter
Link NOC:Integrated Circuits and Applications Lecture 16 - Second Order Low Pass Filter
Link NOC:Integrated Circuits and Applications Lecture 17 - Design of Butterworth Low Pass Filter
Link NOC:Integrated Circuits and Applications Lecture 18 - Design of Butterworth High Pass Filter
Link NOC:Integrated Circuits and Applications Lecture 19 - Design of Band Pass Filter
Link NOC:Integrated Circuits and Applications Lecture 20 - Design of Band Stop Filter
Link NOC:Integrated Circuits and Applications Lecture 21 - All Pass Filter
Link NOC:Integrated Circuits and Applications Lecture 22 - RC Phase Shift Oscillator
Link NOC:Integrated Circuits and Applications Lecture 23 - Wien Bridge, Colpitt's and Hartley Oscillators
Link NOC:Integrated Circuits and Applications Lecture 24 - Comparator and Schmitt Trigger Circuits
Link NOC:Integrated Circuits and Applications Lecture 25 - Square Wave and Triangular Waveform Generators
Link NOC:Integrated Circuits and Applications Lecture 26 - Monostable operation
Link NOC:Integrated Circuits and Applications Lecture 27 - Monostable applications - I
Link NOC:Integrated Circuits and Applications Lecture 28 - Monostable applications - II
Link NOC:Integrated Circuits and Applications Lecture 29 - Astable operation
Link NOC:Integrated Circuits and Applications Lecture 30 - Phase detectors
Link NOC:Integrated Circuits and Applications Lecture 31 - Voltage Controlled oscillator
Link NOC:Integrated Circuits and Applications Lecture 32 - PLL IC 565 operation
Link NOC:Integrated Circuits and Applications Lecture 33 - PLL Applications
Link NOC:Integrated Circuits and Applications Lecture 34 - Fixed Voltage Regulator
Link NOC:Integrated Circuits and Applications Lecture 35 - Adjastable Voltage Regulator
Link NOC:Integrated Circuits and Applications Lecture 36 - Switching Regulators
Link NOC:Integrated Circuits and Applications Lecture 37 - Weighted Resistor D/A Converter
Link NOC:Integrated Circuits and Applications Lecture 38 - R-2R Ladder D/A Converter
Link NOC:Integrated Circuits and Applications Lecture 39 - Inverted R-2R Ladder D/A Converter
Link NOC:Integrated Circuits and Applications Lecture 40 - Analog to Digital Converters
Link NOC:Integrated Circuits and Applications Lecture 41 - CMOS Inverter
Link NOC:Integrated Circuits and Applications Lecture 42 - CMOS NAND Gate
Link NOC:Integrated Circuits and Applications Lecture 43 - Transient Response of CMOS NAND and NOR Gates
Link NOC:Integrated Circuits and Applications Lecture 44 - Boolean function Realization using CMOS and Sizing
Link Advanced Electric Drives Lecture 1
Link Advanced Electric Drives Lecture 2
Link Advanced Electric Drives Lecture 3
Link Advanced Electric Drives Lecture 4
Link Advanced Electric Drives Lecture 5
Link Advanced Electric Drives Lecture 6
Link Advanced Electric Drives Lecture 7
Link Advanced Electric Drives Lecture 8
Link Advanced Electric Drives Lecture 9
Link Advanced Electric Drives Lecture 10
Link Advanced Electric Drives Lecture 11
Link Advanced Electric Drives Lecture 12
Link Advanced Electric Drives Lecture 13
Link Advanced Electric Drives Lecture 14
Link Advanced Electric Drives Lecture 15
Link Advanced Electric Drives Lecture 16
Link Advanced Electric Drives Lecture 17
Link Advanced Electric Drives Lecture 18
Link Advanced Electric Drives Lecture 19
Link Advanced Electric Drives Lecture 20
Link Advanced Electric Drives Lecture 21
Link Advanced Electric Drives Lecture 22
Link Advanced Electric Drives Lecture 23
Link Advanced Electric Drives Lecture 24
Link Advanced Electric Drives Lecture 25
Link Advanced Electric Drives Lecture 26
Link Advanced Electric Drives Lecture 27
Link Advanced Electric Drives Lecture 28
Link Advanced Electric Drives Lecture 29
Link Advanced Electric Drives Lecture 30
Link Advanced Electric Drives Lecture 31
Link Advanced Electric Drives Lecture 32
Link Advanced Electric Drives Lecture 33
Link Advanced Electric Drives Lecture 34
Link Advanced Electric Drives Lecture 35
Link Advanced Electric Drives Lecture 36
Link Advanced Electric Drives Lecture 37
Link Advanced Electric Drives Lecture 38
Link Advanced Electric Drives Lecture 39
Link Advanced Electric Drives Lecture 40
Link High Voltage DC Transmission Lecture 1 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 2 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 3 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 4 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 5 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 6 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 7 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 8 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 9 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 10 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 11 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 12 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 13 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 14 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 15 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 16 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 17 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 18 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 19 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 20 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 21 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 22 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 23 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 24 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 25 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 26 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 27 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 28 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 29 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 30 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 31 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 32 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 33 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 34 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 35 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 36 - High Voltage DC Transmission
Link High Voltage DC Transmission Lecture 37 - High Voltage DC Transmission
Link Intelligent Systems and Control Lecture 1 - Introduction to Intelligent Systems and Control
Link Intelligent Systems and Control Lecture 2 - Linear Neural networks
Link Intelligent Systems and Control Lecture 3 - Multi layered Neural Networks
Link Intelligent Systems and Control Lecture 4 - Back Propagation Algorithm revisited
Link Intelligent Systems and Control Lecture 5 - Non Linear System Analysis - Part I
Link Intelligent Systems and Control Lecture 6 - Non Linear System Analysis - Part II
Link Intelligent Systems and Control Lecture 7 - Radial Basis Function Networks
Link Intelligent Systems and Control Lecture 8 - Adaptive Learning rate
Link Intelligent Systems and Control Lecture 9 - Weight update rules
Link Intelligent Systems and Control Lecture 10 - Recurrent networks Back propagation through time
Link Intelligent Systems and Control Lecture 11 - Recurrent networks Real time recurrent learning
Link Intelligent Systems and Control Lecture 12 - Self organizing Map - Multidimensional networks
Link Intelligent Systems and Control Lecture 13 - Fuzzy sets - A Primer
Link Intelligent Systems and Control Lecture 14 - Fuzzy Relations
Link Intelligent Systems and Control Lecture 15 - Fuzzy Rule base and Approximate Reasoning
Link Intelligent Systems and Control Lecture 16 - Introduction to Fuzzy Logic Control
Link Intelligent Systems and Control Lecture 17 - Neural Control A review
Link Intelligent Systems and Control Lecture 18 - Network inversion and Control
Link Intelligent Systems and Control Lecture 19 - Neural Model of a Robot manipulator
Link Intelligent Systems and Control Lecture 20 - Indirect Adaptive Control of a Robot manipulator
Link Intelligent Systems and Control Lecture 21 - Adaptive neural control for Affine Systems SISO
Link Intelligent Systems and Control Lecture 22 - Adaptive neural control for Affine systems MIMO
Link Intelligent Systems and Control Lecture 23 - Visual Motor Coordination with KSOM
Link Intelligent Systems and Control Lecture 24 - Visual Motor coordination - quantum clustering
Link Intelligent Systems and Control Lecture 25 - Direct Adaptive control of Manipulators - Intro
Link Intelligent Systems and Control Lecture 26 - NN based back stepping control
Link Intelligent Systems and Control Lecture 27 - Fuzzy Control - a Review
Link Intelligent Systems and Control Lecture 28 - Mamdani type flc and parameter optimization
Link Intelligent Systems and Control Lecture 29 - Fuzzy Control of a pH reactor
Link Intelligent Systems and Control Lecture 30 - Fuzzy Lyapunov controller - Computing with words
Link Intelligent Systems and Control Lecture 31 - Controller Design for a T-S Fuzzy model
Link Intelligent Systems and Control Lecture 32 - Linear controllers using T-S fuzzy model
Link Power Systems Operation and Control Module 1 - Lecture 1
Link Power Systems Operation and Control Module 1 - Lecture 2
Link Power Systems Operation and Control Module 1 - Lecture 3
Link Power Systems Operation and Control Module 2 - Lecture 1
Link Power Systems Operation and Control Module 2 - Lecture 2
Link Power Systems Operation and Control Module 2 - Lecture 3
Link Power Systems Operation and Control Module 2 - Lecture 4
Link Power Systems Operation and Control Module 2 - Lecture 5
Link Power Systems Operation and Control Module 2 - Lecture 6
Link Power Systems Operation and Control Module 2 - Lecture 7
Link Power Systems Operation and Control Module 2 - Lecture 8
Link Power Systems Operation and Control Module 2 - Lecture 9
Link Power Systems Operation and Control Module 2 - Lecture 10
Link Power Systems Operation and Control Module 2 - Lecture 11
Link Power Systems Operation and Control Module 2 - Lecture 12
Link Power Systems Operation and Control Module 2 - Lecture 13
Link Power Systems Operation and Control Module 2 - Lecture 14
Link Power Systems Operation and Control Module 3 - Lecture 1
Link Power Systems Operation and Control Module 3 - Lecture 2
Link Power Systems Operation and Control Module 3 - Lecture 3
Link Power Systems Operation and Control Module 3 - Lecture 4
Link Power Systems Operation and Control Module 3 - Lecture 5
Link Power Systems Operation and Control Module 3 - Lecture 6
Link Power Systems Operation and Control Module 3 - Lecture 7
Link Power Systems Operation and Control Module 3 - Lecture 8
Link Power Systems Operation and Control Module 3 - Lecture 9
Link Power Systems Operation and Control Module 3 - Lecture 10
Link Power Systems Operation and Control Module 4 - Lecture 1
Link Power Systems Operation and Control Module 4 - Lecture 2
Link Power Systems Operation and Control Module 4 - Lecture 3
Link Power Systems Operation and Control Module 4 - Lecture 4
Link Power Systems Operation and Control Module 5 - Lecture 1
Link Power Systems Operation and Control Module 5 - Lecture 2
Link Power Systems Operation and Control Module 6 - Lecture 1
Link Power Systems Operation and Control Module 6 - Lecture 2
Link NOC:Electromagnetic theory Lecture 1 - Introduction to EMT
Link NOC:Electromagnetic theory Lecture 2 - Coulombs law
Link NOC:Electromagnetic theory Lecture 3 - Vector analysis-I and Introduction to coordinate system
Link NOC:Electromagnetic theory Lecture 4 - Rectangular coordinate system
Link NOC:Electromagnetic theory Lecture 5 - Vector analysis-II
Link NOC:Electromagnetic theory Lecture 6 - Introduction to Electric field
Link NOC:Electromagnetic theory Lecture 7 - Electric field-I
Link NOC:Electromagnetic theory Lecture 8 - Cylindrical coordinate system
Link NOC:Electromagnetic theory Lecture 9 - Transformation and Electric field-II
Link NOC:Electromagnetic theory Lecture 10 - Electric Potential-I
Link NOC:Electromagnetic theory Lecture 11 - Spherical co-ordinate system and Electric potential-II
Link NOC:Electromagnetic theory Lecture 12 - Vector Analysis-III and Electric potential-III
Link NOC:Electromagnetic theory Lecture 13 - Gauss’s law and its application-I
Link NOC:Electromagnetic theory Lecture 14 - Gauss’s law and its application-II
Link NOC:Electromagnetic theory Lecture 15 - Divergence and Poisson’s and Laplace’s equation
Link NOC:Electromagnetic theory Lecture 16 - Gauss’s law and its application -III
Link NOC:Electromagnetic theory Lecture 17 - Vector analysis –III (curl and its significance)
Link NOC:Electromagnetic theory Lecture 18 - Conductor and dielectric-I
Link NOC:Electromagnetic theory Lecture 19 - Polarization - I
Link NOC:Electromagnetic theory Lecture 20 - Polarization - II
Link NOC:Electromagnetic theory Lecture 21 - Polarization - II (Continued...)
Link NOC:Electromagnetic theory Lecture 22 - Boundary condition
Link NOC:Electromagnetic theory Lecture 23 - Continuity equation and Conductors - III
Link NOC:Electromagnetic theory Lecture 24 - Conductors – IV
Link NOC:Electromagnetic theory Lecture 25 - Conductors – IV (Continued...) and Capacitor - I
Link NOC:Electromagnetic theory Lecture 26 - Capacitor - II
Link NOC:Electromagnetic theory Lecture 27 - Capacitor - II (Continued...) and Equipotential Surfaces
Link NOC:Electromagnetic theory Lecture 28 - Solution of Laplace’s equation-I
Link NOC:Electromagnetic theory Lecture 29 - Solution of Laplace’s equation-I I and method of images-I
Link NOC:Electromagnetic theory Lecture 30 - Method of images-II
Link NOC:Electromagnetic theory Lecture 31 - Solution of Laplace’s equation-III
Link NOC:Electromagnetic theory Lecture 32 - Solution of Laplace’s equation-IV
Link NOC:Electromagnetic theory Lecture 33 - Introduction of magnetic field
Link NOC:Electromagnetic theory Lecture 34 - Biot savart law and its application
Link NOC:Electromagnetic theory Lecture 35 - Biot savart lawandits application-II
Link NOC:Electromagnetic theory Lecture 36 - Magnetic vector potential
Link NOC:Electromagnetic theory Lecture 37 - Magnetic force, torque and dipole
Link NOC:Electromagnetic theory Lecture 38 - Magnetic force, torque and dipole (Continued...)
Link NOC:Electromagnetic theory Lecture 39 - Magnetic materials-I
Link NOC:Electromagnetic theory Lecture 40 - Magnetic materials-I (Continued...) and Magnetic moment
Link NOC:Electromagnetic theory Lecture 41 - Magnetic materials-I (Continued...) and Boundary condition for Magnetic fields
Link NOC:Electromagnetic theory Lecture 42 - Inductor and calculation of inductance for different shapes
Link NOC:Electromagnetic theory Lecture 43 - Inductor and calculation of inductance for different shapes (Continued...)
Link NOC:Electromagnetic theory Lecture 44 - Faradays law and its application-I
Link NOC:Electromagnetic theory Lecture 45 - Faradays law and its application-II
Link NOC:Electromagnetic theory Lecture 46 - Displacement current
Link NOC:Electromagnetic theory Lecture 47 - Maxwell’s equation
Link NOC:Electromagnetic theory Lecture 48 - Wave propagation
Link NOC:Electromagnetic theory Lecture 49 - Solution of Helmholtz equation
Link NOC:Electromagnetic theory Lecture 50 - Uniform plane waves
Link NOC:Electromagnetic theory Lecture 51 - Polarization and Poynting Vector
Link NOC:Electromagnetic theory Lecture 52 - Wave reflections (Normal incidence)
Link NOC:Electromagnetic theory Lecture 53 - Waves in imperfect dielectrics and Good conductors
Link NOC:Electromagnetic theory Lecture 54 - Skin depth/effect
Link NOC:Electromagnetic theory Lecture 55 - Oblique incidence of waves
Link NOC:Electromagnetic theory Lecture 56 - Oblique incidence of waves (Continued...)
Link NOC:Electromagnetic theory Lecture 57 - Transmission line
Link NOC:Electromagnetic theory Lecture 58 - Transmission line model
Link NOC:Electromagnetic theory Lecture 59 - Steady state sinusoidal response of T-line-I
Link NOC:Electromagnetic theory Lecture 60 - Steady state sinusoidal response of T-line-II
Link NOC:Electromagnetic theory Lecture 61 - Steady state sinusoidal response of T-line-IIand Smith chart
Link NOC:Electromagnetic theory Lecture 62 - Application of smith chart-I
Link NOC:Electromagnetic theory Lecture 63 - Application of smith chart-II
Link NOC:Electromagnetic theory Lecture 64 - Impedance matching
Link NOC:Electromagnetic theory Lecture 65 - Transients on Transmission line-I
Link NOC:Electromagnetic theory Lecture 66 - Transients on Transmission line-II
Link NOC:Electromagnetic theory Lecture 67 - Pulse on Transmission line
Link NOC:Electromagnetic theory Lecture 68 - Capacitive termination in Transmission line
Link NOC:Electromagnetic theory Lecture 69 - Waveguide
Link NOC:Electromagnetic theory Lecture 70 - Waveguide Analysis
Link NOC:Electromagnetic theory Lecture 71 - TM modes in Waveguide
Link NOC:Electromagnetic theory Lecture 72 - Rectangular waveguide: TM modes
Link NOC:Electromagnetic theory Lecture 73 - Rectangular waveguide: TE modes
Link NOC:Electromagnetic theory Lecture 74 - Waveguide: Wavelength, Impedance and power calculation
Link NOC:Electromagnetic theory Lecture 75 - Waveguide losses
Link NOC:Electromagnetic theory Lecture 76 - Dielectric Waveguide
Link NOC:Electromagnetic theory Lecture 77 - Dielectric Waveguide (Continued...)
Link NOC:Electromagnetic theory Lecture 78 - Radiation and Antenna
Link NOC:Electromagnetic theory Lecture 79 - Hertzian Dipole Antenna
Link NOC:Electromagnetic theory Lecture 80 - Hertzian Dipole Antenna (Continued...)
Link NOC:Electromagnetic theory Lecture 81 - Quasi-statistics-I
Link NOC:Electromagnetic theory Lecture 82 - Quasi-statistics-II
Link NOC:Electromagnetic theory Lecture 83 - Long wire Antenna
Link NOC:Electromagnetic theory Lecture 84 - Group velocity and Phase velocity
Link NOC:Electromagnetic theory Lecture 85 - Numerical solution of Laplace's equation
Link NOC:Principles of Communication - Part 1 Lecture 1 - Basics - Definition of Energy and Power of Signals
Link NOC:Principles of Communication - Part 1 Lecture 2 - Frequency Domain Representation and Introduction to Discrete Fourier Series
Link NOC:Principles of Communication - Part 1 Lecture 3 - Discrete Fourier Series Example and Parseval's Theorem for Periodic Signals
Link NOC:Principles of Communication - Part 1 Lecture 4 - Fourier Transform (FT), Inverse Fourier Transform (IFT) of Continuous Signals, Example of FT of Pulse and Sinc Function
Link NOC:Principles of Communication - Part 1 Lecture 5 - Modulation Property of Fourier Transform, Dirac Delta or Unit Impulse Function - Definition and Fourier Transform
Link NOC:Principles of Communication - Part 1 Lecture 6 - Duality Property of Fourier Transform and Introduction to Linear Time Invatiant (LTI) Systems
Link NOC:Principles of Communication - Part 1 Lecture 7 - Transmission of Signal through Linear Time Invariant (LTI) Systems and Cross- Correlation of Signals
Link NOC:Principles of Communication - Part 1 Lecture 8 - Auto-Correlation of Signal and Energy Spectral Density (ESD)
Link NOC:Principles of Communication - Part 1 Lecture 9 - Example for Auto-Correlation of Signal and Energy Spectral Density (ESD)
Link NOC:Principles of Communication - Part 1 Lecture 10 - Introduction to Amplitude Modulation (AM), Modulation Index, Envelope Distortion and Over Modulation
Link NOC:Principles of Communication - Part 1 Lecture 11 - Spectrum of Amplitude Modulated(AM) Signals and Introduction to Envelope Detection
Link NOC:Principles of Communication - Part 1 Lecture 12 - Envelope Detection for Amplitude Modulated (AM) Signals and Time Constant for Capacitor in Envelope Detector
Link NOC:Principles of Communication - Part 1 Lecture 13 - Power of Amplitude Modulated (AM) Signals and Power Efficiency of AM Signals
Link NOC:Principles of Communication - Part 1 Lecture 14 - Double Sideband (DSB) Suppressed Carrier (SC) Modulation, Spectrum of DSB-SC Signals and Coherent Demodulation
Link NOC:Principles of Communication - Part 1 Lecture 15 - Double Sideband(DSB) Suppressed Carrier (SC) Demodulation, Non-coherent demodulation, Impact of Carrier Phase Offset
Link NOC:Principles of Communication - Part 1 Lecture 16 - Carrier Phase Offset Example for Double Sideband (DSB) Suppressed Carrier (SC) Demodulation- Wireless Cellular Communication with User Mobility
Link NOC:Principles of Communication - Part 1 Lecture 17 - Phase Synchronization using Costas Receiver for Double Sideband (DSB) Suppressed Carrier (SC) Demodulation
Link NOC:Principles of Communication - Part 1 Lecture 18 - Introduction to Quadrature Carrier Multiplexing (QCM) and Demodulation of QCM Signals.
Link NOC:Principles of Communication - Part 1 Lecture 19 - Introduction to Single Sideband (SSB) Modulation
Link NOC:Principles of Communication - Part 1 Lecture 20 - Generation of Single Sideband (SSB) Modulation Signals through Frequency Discrimination
Link NOC:Principles of Communication - Part 1 Lecture 21 - Frequency Domain Description of Hilbert Transform – Fourier Spectrum of the Hilbert Transformer
Link NOC:Principles of Communication - Part 1 Lecture 22 - Time Domain Description of Hilbert Transform – Impulse Response of the Hilbert Transformer
Link NOC:Principles of Communication - Part 1 Lecture 23 - Phase Shifting Method for Generation of Single Sideband (SSB) Modulated Signals based on Hilbert Transform
Link NOC:Principles of Communication - Part 1 Lecture 24 - Complex Pre-Envelope and Complex Envelope of Passband Signals
Link NOC:Principles of Communication - Part 1 Lecture 25 - Complex Pre- Envelope and Complex Envelope of QCM (Quadrature Carrier Modulated) Signals
Link NOC:Principles of Communication - Part 1 Lecture 26 - Introduction to Vestigial Side Band(VSB) Modulation and Non- Ideal Filtering, Spectral Efficiency
Link NOC:Principles of Communication - Part 1 Lecture 27 - Properties of Vestigial Side Band Filter for Reconstruction of Message Signal without Distortion
Link NOC:Principles of Communication - Part 1 Lecture 28 - Introduction to Angle Modulation, Description of Phase Modulation (PM) and Frequency Modulation (FM)
Link NOC:Principles of Communication - Part 1 Lecture 29 - Frequency Modulation (FM) with Sinusoidal Modulation Signal and Pictorial Examples, Insights of PM and FM signals
Link NOC:Principles of Communication - Part 1 Lecture 30 - Indirect Method for Generation of FM Signals - Generation of Narrowband FM Signal
Link NOC:Principles of Communication - Part 1 Lecture 31 - Indirect Method for Generation of FM Signals - Generation of Wideband FM Signal through Frequency Multiplication
Link NOC:Principles of Communication - Part 1 Lecture 32 - Spectrum of Frequency Modulated (FM) Signals
Link NOC:Principles of Communication - Part 1 Lecture 33 - Bandwidth of Frequency Modulated (FM) Signals - Carson's Rule
Link NOC:Principles of Communication - Part 1 Lecture 34 - Demodulation of Frequency Modulated (FM) Signals, Condition of Envelope Detection
Link NOC:Principles of Communication - Part 1 Lecture 35 - Analog to Digital Conversion of Signals and Introduction to Sampling
Link NOC:Principles of Communication - Part 1 Lecture 36 - Spectrum of Sampled Signal, Aliasing and Nyquist Sampling Theorem
Link NOC:Principles of Communication - Part 1 Lecture 37 - Ideal Impluse Train Sampling, Reconstruction of Original Signal from Samples, Sinc Interpolation
Link NOC:Principles of Communication - Part 1 Lecture 38 - Introduction to Pulse Amplitude Modulation (PAM), Sample and Hold, Flat Top Sampling
Link NOC:Principles of Communication - Part 1 Lecture 39 - Pulse Amplitude Modulation (PAM), Spectrum of PAM Signal , Reconstruction of Original Signal from PAM Signal, Equalization
Link NOC:Principles of Communication - Part 1 Lecture 40 - Introduction to Quantization, Uniform Quantizer, Mid- Tread Quantizer
Link NOC:Principles of Communication - Part 1 Lecture 41 - Quantization, Mid- Rise Quantizer, PDF and Power of Quantization Noise, Quantization Noise Power versus Quantizer Resolution
Link NOC:Principles of Communication - Part 1 Lecture 42 - Introduction to Lloyd- Max Quantization Algorithm, Optimal Quantizer Design
Link NOC:Principles of Communication - Part 1 Lecture 43 - Lloyd- Max Quantization Algorithm, Iterative Computation of Optimal Quantization Levels and Intervals
Link NOC:Principles of Communication - Part 1 Lecture 44 - Companding for Non- Uniform Quantization, Mu-law Compressor, A- Law Compressor
Link NOC:Principles of Communication - Part 1 Lecture 45 - Introduction to Delta Modulation, One-bit Quantizer
Link NOC:Principles of Communication - Part 1 Lecture 46 - Signal Reconstruction in Delta Modulation, Schematic Diagrams, Slope Overload Distortion and Granular Noise
Link NOC:Principles of Communication - Part 1 Lecture 47 - Differential Pulse Coded Modulation (DPCM), DPCM Signal Reconstruction and Schematic Diagram
Link NOC:Principles of Communication - Part 1 Lecture 48 - Frequency Mixing and Translation in Communication Systems, Heterodyne and Super Heterodyne Receivers
Link NOC:Principles of Communication - Part 1 Lecture 49 - Frequency Translation and Super Heterodyne Receivers, Problem of Image Frequency
Link NOC:Principles of Communication - Part 1 Lecture 50 - Frequency Division Multiplexing (FDM), Carrier Spacing in FDM
Link NOC:Principles of Communication - Part 1 Lecture 51 - Time Division Multiplexing (TDM), Operation of TDM, Sample Spacing in TDM
Link NOC:Principles of Communication - Part 1 Lecture 52 - Bandwidth Requirements for Time Division Multiplexing (TDM), The T1 TDM System : A Case Study
Link NOC:An Introduction to Coding Theory Lecture 1 - Introduction to Error Control Coding - I
Link NOC:An Introduction to Coding Theory Lecture 2 - Introduction to Error Control Coding - II
Link NOC:An Introduction to Coding Theory Lecture 3 - Introduction to Error Control Coding - III
Link NOC:An Introduction to Coding Theory Lecture 4 - Introduction to Linear Block Codes, Generator Matrix and Parity Check Matrix
Link NOC:An Introduction to Coding Theory Lecture 5 - Syndrome, Error Correction and Error Detection
Link NOC:An Introduction to Coding Theory Lecture 6 - Problem Solving Session - I
Link NOC:An Introduction to Coding Theory Lecture 7 - Decoding of Linear Block Codes
Link NOC:An Introduction to Coding Theory Lecture 8 - Distance Properties of Linear Block Codes - I
Link NOC:An Introduction to Coding Theory Lecture 9 - Distance Properties of Linear Block Codes - II
Link NOC:An Introduction to Coding Theory Lecture 10 - Problem Solving Session - II
Link NOC:An Introduction to Coding Theory Lecture 11 - Some Simple Linear Block Codes - I
Link NOC:An Introduction to Coding Theory Lecture 12 - Some Simple Linear Block Codes - II: Reed Muller Codes
Link NOC:An Introduction to Coding Theory Lecture 13 - Bounds on the Size of a Code
Link NOC:An Introduction to Coding Theory Lecture 14 - Problem Solving Session - III
Link NOC:An Introduction to Coding Theory Lecture 15 - Introduction to Convolutional Codes - I: Encoding
Link NOC:An Introduction to Coding Theory Lecture 16 - Introduction to Convolutional Codes - II: State Diagram, Trellis Diagram
Link NOC:An Introduction to Coding Theory Lecture 17 - Convolutional Codes: Classification, Realization
Link NOC:An Introduction to Coding Theory Lecture 18 - Convolutional Codes:Distance Properties
Link NOC:An Introduction to Coding Theory Lecture 19 - Decoding of Convolutional Codes - I: Viterbi Algorithm
Link NOC:An Introduction to Coding Theory Lecture 20 - Decoding of Convolutional Codes - II: BCJR Algorithm
Link NOC:An Introduction to Coding Theory Lecture 21 - Problem solving session - IV
Link NOC:An Introduction to Coding Theory Lecture 22 - Problem solving session - V
Link NOC:An Introduction to Coding Theory Lecture 23 - Performance Bounds for Convolutional Codes
Link NOC:An Introduction to Coding Theory Lecture 24 - Low Density Parity Check Codes
Link NOC:An Introduction to Coding Theory Lecture 25 - Decoding of Low Density Parity Check Codes - I
Link NOC:An Introduction to Coding Theory Lecture 26 - Decoding of Low Density Parity Check Codes - II: Belief Propagation Algorithm
Link NOC:An Introduction to Coding Theory Lecture 27 - Turbo Codes
Link NOC:An Introduction to Coding Theory Lecture 28 - Turbo Decoding
Link NOC:An Introduction to Coding Theory Lecture 29 - Problem Solving Sessions - VI
Link NOC:An Introduction to Coding Theory Lecture 30 - Distance Properties of Turbo Codes
Link NOC:An Introduction to Coding Theory Lecture 31 - Convergence of Turbo Codes
Link NOC:An Introduction to Coding Theory Lecture 32 - Automatic Repeat reQuest (ARQ) Schemes
Link NOC:An Introduction to Coding Theory Lecture 33 - Applications of Linear Codes
Link NOC:Principles of Communication Systems - Part II Lecture 1 - Introduction to Digital Communication Systems
Link NOC:Principles of Communication Systems - Part II Lecture 2 - Spectrum of Transmitted Digital Communication Signal and Wide Sense Stationarity
Link NOC:Principles of Communication Systems - Part II Lecture 3 - Spectrum of Transmitted Digital Communication Signal, Autocorrelation Function and Power Spectral Density
Link NOC:Principles of Communication Systems - Part II Lecture 4 - Spectrum of Transmitted Digital Communication Signal, Relation to Energy Spectral Density and Introduction to AWGN Channel
Link NOC:Principles of Communication Systems - Part II Lecture 5 - Additive White Gaussian Noise (AWGN) Properties, Gaussian Noise and White Noise
Link NOC:Principles of Communication Systems - Part II Lecture 6 - Structure of Digital Communication Receiver, Receiver Filter and Signal-to-Noise Power Ratio (SNR)
Link NOC:Principles of Communication Systems - Part II Lecture 7 - Digital Communication Receiver, Noise Properties and Output Noise Power
Link NOC:Principles of Communication Systems - Part II Lecture 8 - Digital Communication Receiver, Optimal SNR and Matched Filter
Link NOC:Principles of Communication Systems - Part II Lecture 9 - Probability of Error in Digital Communication and Probability Density Functions of Output
Link NOC:Principles of Communication Systems - Part II Lecture 10 - Probability of Error in Digital Communication, Optimal Decison Rule and Gaussian Q function
Link NOC:Principles of Communication Systems - Part II Lecture 11 - Introduction to Binary Phase Shift Keying (BPSK) Modulation, Optimal Decision Rule and Probability of Bit-Error or Bit-Error Rate (BER)
Link NOC:Principles of Communication Systems - Part II Lecture 12 - Introduction to Amplitude Shift Keying (ASK) Modulation
Link NOC:Principles of Communication Systems - Part II Lecture 13 - Optimal Decision Rule for Amplitude Shift Keying (ASK), Bit Error Rate (BER) and Comparison with Binary Phase Shift Keying (BPSK) Modulation
Link NOC:Principles of Communication Systems - Part II Lecture 14 - Introduction to Signal Space Concept and Orthonormal Basis Signals
Link NOC:Principles of Communication Systems - Part II Lecture 15 - Introduction to Frequency Shift Keying (FSK)
Link NOC:Principles of Communication Systems - Part II Lecture 16 - Optimal Decision Rule for FSK, Bit Error Rate (BER) and Comparison with BPSK, ASK
Link NOC:Principles of Communication Systems - Part II Lecture 17 - Introduction to Quadrature Phase Shift Keying (QPSK)
Link NOC:Principles of Communication Systems - Part II Lecture 18 - Waveforms of Quadrature Phase Shift Keying (QPSK)
Link NOC:Principles of Communication Systems - Part II Lecture 19 - Matched Filtering, Bit Error Rate and Symbol Error Rate for Quadrature Phase Shift Keying (QPSK)
Link NOC:Principles of Communication Systems - Part II Lecture 20 - Introduction to M-ary PAM (Pulse Amplitude Modulation), Average Symbol Power and Decision rules
Link NOC:Principles of Communication Systems - Part II Lecture 21 - M-ary PAM (Pulse Amplitude Modulation) -Part-II, Optimal Decision Rule and Probability of Error
Link NOC:Principles of Communication Systems - Part II Lecture 22 - M-ary QAM (Quadrature Amplitude Modulation) Part-I, Introduction, Transmitted Waveform and Average Symbol Energy
Link NOC:Principles of Communication Systems - Part II Lecture 23 - M-ary QAM (Quadrature Amplitude Modulation) - Part-II, Optimal Decision Rule, Probability of Error and Contellation Diagram
Link NOC:Principles of Communication Systems - Part II Lecture 24 - M-ary PSK (Phase Shift Keying) Part-I, Introduction , Transmitted Waveform and Constellation Diagram
Link NOC:Principles of Communication Systems - Part II Lecture 25 - M-ary PSK (Phase Shift Keying) - Part-II, Optimal Decision Rule, Nearest Neighbor Criterion and Approximate Probability of Error
Link NOC:Principles of Communication Systems - Part II Lecture 26 - Introduction to Information Theory, Relevance of Information Theory and Characterization of Information
Link NOC:Principles of Communication Systems - Part II Lecture 27 - Definition of Entropy, Average of Information / Uncertainity of source and Properties of Entropy
Link NOC:Principles of Communication Systems - Part II Lecture 28 - Entropy Example- Binary Source Maximum and Minimum Entropy of Binary Source
Link NOC:Principles of Communication Systems - Part II Lecture 29 - Maximum Entropy of Source with M-ary Alphabet, Concave/Convex Functions and Jensens Inequality
Link NOC:Principles of Communication Systems - Part II Lecture 30 - Joint Entropy , Definition of Joint Entropy of Two Sources and Simple Examples for Joint Entropy Computation
Link NOC:Principles of Communication Systems - Part II Lecture 31 - Properties of Joint Entropy and Relation between Joint Entropy and Marginal Entropies
Link NOC:Principles of Communication Systems - Part II Lecture 32 - Conditional Entropy, Example of Conditional Entropy and Properties of Conditional Entropy
Link NOC:Principles of Communication Systems - Part II Lecture 33 - Mutual Information, Diagrammatic Representation and Properties of Mutual Information
Link NOC:Principles of Communication Systems - Part II Lecture 34 - Simple Example of Mutual Information and Practical Example of Mutual Information-Binary Symmetric Channel
Link NOC:Principles of Communication Systems - Part II Lecture 35 - Channel Capacity, Implications of Channel Capacity, Claude E. Shannon- Father of Information Theory and Example of Capacity of Binary Symmetric Channel
Link NOC:Principles of Communication Systems - Part II Lecture 36 - Differential Entropy and Example for Uniform Probability Density function
Link NOC:Principles of Communication Systems - Part II Lecture 37 - Differential Entropy of Gaussian Source and Insights
Link NOC:Principles of Communication Systems - Part II Lecture 38 - Joint Conditional/ Differential Entropies and Mutual Information
Link NOC:Principles of Communication Systems - Part II Lecture 39 - Capacity of Gaussian channel - Part I
Link NOC:Principles of Communication Systems - Part II Lecture 40 - Capacity of Gaussian Channel - Part-II, Practical Implications and Maximum rate in bits\sec
Link NOC:Principles of Communication Systems - Part II Lecture 41 - Introduction to Source Coding and Data Compression, Variable Length codes and Unique Decodability
Link NOC:Principles of Communication Systems - Part II Lecture 42 - Uniquely Decodable Codes, Prefix-free code, Instantaneous Code and Average Code length
Link NOC:Principles of Communication Systems - Part II Lecture 43 - Binary Tree Representation of Code, Example and Kraft Inequality
Link NOC:Principles of Communication Systems - Part II Lecture 44 - Lower Bound on Average Code Length and Kullback-Leibler Divergence
Link NOC:Principles of Communication Systems - Part II Lecture 45 - Optimal Code length, Constrained Optimization and Morse Code Example
Link NOC:Principles of Communication Systems - Part II Lecture 46 - Approaching Lower Bound on Average code length and Block Coding
Link NOC:Principles of Communication Systems - Part II Lecture 47 - Huffman Code, Algorithm, Example and Average Code Length
Link NOC:Principles of Communication Systems - Part II Lecture 48 - Introduction to channel coding, Rate of Code, Repetition Code and Hamming Distance
Link NOC:Principles of Communication Systems - Part II Lecture 49 - Introduction to Convolutional Codes, Binary Field Arithmetic and Linear Codes
Link NOC:Principles of Communication Systems - Part II Lecture 50 - Example of Convolutional Code Output and Convolution Operation for Code generation
Link NOC:Principles of Communication Systems - Part II Lecture 51 - Matrix Representation of Convolutional Codes, Generator Matrix, Transform Domain Representation and Shift Register Architecture
Link NOC:Principles of Communication Systems - Part II Lecture 52 - State Diagram Representation of Convolutional Code, State transitions and Example of Code Generation using State transitions
Link NOC:Principles of Communication Systems - Part II Lecture 53 - Trellis Representation of Convolutional Code and Valid Code Words
Link NOC:Principles of Communication Systems - Part II Lecture 54 - Decoding of the Convolutional Code, Minimum Hamming distance and Maximum Likelihood Codeword Estimate
Link NOC:Principles of Communication Systems - Part II Lecture 55 - Principle of Decoding of Convolutional code
Link NOC:Principles of Communication Systems - Part II Lecture 56 - Viterbi Decoder for Maximum Likelihood Decoding of Convolutional Code Using Trellis Representation, Branch Metric Calculation, State Metric Calculation and Example
Link NOC:Applied Engineering Electromagnetics Lecture 1 - Introduction to Applied Elecromagnetics
Link NOC:Applied Engineering Electromagnetics Lecture 2 - Introduction to Transmission lines
Link NOC:Applied Engineering Electromagnetics Lecture 3 - Sinusoidal waves on Transmission lines
Link NOC:Applied Engineering Electromagnetics Lecture 4 - Terminating T-lines: Reflection and Transmission coefficient
Link NOC:Applied Engineering Electromagnetics Lecture 5 - Circuit parameters of a T-line
Link NOC:Applied Engineering Electromagnetics Lecture 6 - Lossy Transmission lines and primary constants
Link NOC:Applied Engineering Electromagnetics Lecture 7 - When to apply T-line Theory?
Link NOC:Applied Engineering Electromagnetics Lecture 8 - Standing Waves on T-lines
Link NOC:Applied Engineering Electromagnetics Lecture 9 - Lumped equivalent circuits of T-lines
Link NOC:Applied Engineering Electromagnetics Lecture 10 - Impedance transformation and power flow on T-lines
Link NOC:Applied Engineering Electromagnetics Lecture 11 - Graphical aid: Smith Chart Derivation
Link NOC:Applied Engineering Electromagnetics Lecture 12 - Smith chart applications
Link NOC:Applied Engineering Electromagnetics Lecture 13 - Further applications of Smith chart - Part 1
Link NOC:Applied Engineering Electromagnetics Lecture 14 - Further applications of Smith chart - Part 2
Link NOC:Applied Engineering Electromagnetics Lecture 15 - Impedance matching techniques - Part 1
Link NOC:Applied Engineering Electromagnetics Lecture 16 - Impedance matching techniques - Part 2
Link NOC:Applied Engineering Electromagnetics Lecture 17 - Impedance matching techniques - Part 3
Link NOC:Applied Engineering Electromagnetics Lecture 18 - T-lines in time domain: Lattice diagrams
Link NOC:Applied Engineering Electromagnetics Lecture 19 - Further examples of use of lattice diagrams
Link NOC:Applied Engineering Electromagnetics Lecture 20 - High-speed digital signal propagation on T-lines
Link NOC:Applied Engineering Electromagnetics Lecture 21 - Transient analysis with reactive termination and Time-domain reflectometry
Link NOC:Applied Engineering Electromagnetics Lecture 22 - Fault detection using TDR
Link NOC:Applied Engineering Electromagnetics Lecture 23 - Why Electromagnetics?
Link NOC:Applied Engineering Electromagnetics Lecture 24 - Rectangular coordinate systems
Link NOC:Applied Engineering Electromagnetics Lecture 25 - Cylindrical coordinate systems
Link NOC:Applied Engineering Electromagnetics Lecture 26 - Review of vector fields and Gradient
Link NOC:Applied Engineering Electromagnetics Lecture 27 - Divergence, Curl, and Laplacian operations
Link NOC:Applied Engineering Electromagnetics Lecture 28 - Towards Maxwells equations - Part 1
Link NOC:Applied Engineering Electromagnetics Lecture 29 - Towards Maxwells equations - Part 2
Link NOC:Applied Engineering Electromagnetics Lecture 30 - Faradays law
Link NOC:Applied Engineering Electromagnetics Lecture 31 - Completing Maxwells equations and Boundary conditions
Link NOC:Applied Engineering Electromagnetics Lecture 32 - Boundary conditions for Electromagnetic fields
Link NOC:Applied Engineering Electromagnetics Lecture 33 - Electrostatics-I: Laplace and Poissons equations
Link NOC:Applied Engineering Electromagnetics Lecture 34 - Electrostatics-II: Solving Laplaces equation in 1D
Link NOC:Applied Engineering Electromagnetics Lecture 35 - Electrostatics-III: Solving Laplaces equation in 2D
Link NOC:Applied Engineering Electromagnetics Lecture 36 - Electrostatics-IV: Finite Difference method for solving Laplaces equation
Link NOC:Applied Engineering Electromagnetics Lecture 37 - Magnetostatic fields-I: Biot-Savart Law
Link NOC:Applied Engineering Electromagnetics Lecture 38 - Magnetostatic fields-II: Calculation of magnetic fields
Link NOC:Applied Engineering Electromagnetics Lecture 39 - Inductance calculations
Link NOC:Applied Engineering Electromagnetics Lecture 40 - From Maxwells equations to uniform plane waves
Link NOC:Applied Engineering Electromagnetics Lecture 41 - Plane wave propagation in lossless dielectric media
Link NOC:Applied Engineering Electromagnetics Lecture 42 - Polarization of plane waves
Link NOC:Applied Engineering Electromagnetics Lecture 43 - Can an Ideal capacitor exist?
Link NOC:Applied Engineering Electromagnetics Lecture 44 - Skin effect in conductors
Link NOC:Applied Engineering Electromagnetics Lecture 45 - Skin effect in round wires
Link NOC:Applied Engineering Electromagnetics Lecture 46 - Finite difference method
Link NOC:Applied Engineering Electromagnetics Lecture 47 - Reflection of uniform plane waves
Link NOC:Applied Engineering Electromagnetics Lecture 48 - Application: Reflection from multiple media and anti-reflection coating.
Link NOC:Applied Engineering Electromagnetics Lecture 49 - Oblique incidence of plane waves
Link NOC:Applied Engineering Electromagnetics Lecture 50 - Total internal reflection
Link NOC:Applied Engineering Electromagnetics Lecture 51 - Application: Matrix analysis of reflection from multiple boundaries
Link NOC:Applied Engineering Electromagnetics Lecture 52 - Application: Fabry-Perot cavity and Multi-layer films
Link NOC:Applied Engineering Electromagnetics Lecture 53 - Introduction to waveguides
Link NOC:Applied Engineering Electromagnetics Lecture 54 - Rectangular waveguides
Link NOC:Applied Engineering Electromagnetics Lecture 55 - Attenuation and Dispersion in rectangular waveguides
Link NOC:Applied Engineering Electromagnetics Lecture 56 - Planar optical waveguides
Link NOC:Applied Engineering Electromagnetics Lecture 57 - Application: Optical Fibers
Link NOC:Applied Engineering Electromagnetics Lecture 58 - Application: WDM Optical Components
Link NOC:Applied Engineering Electromagnetics Lecture 59 - Mach-Zehnder Modulator
Link NOC:Applied Engineering Electromagnetics Lecture 60 - Wave Propagation in Anisotropic Medium
Link NOC:Applied Engineering Electromagnetics Lecture 61 - Wave Propagation in Ferrites
Link NOC:Applied Engineering Electromagnetics Lecture 62 - Magnetic Vector Potential - Part 1
Link NOC:Applied Engineering Electromagnetics Lecture 63 - Magnetic Vector Potential - Part 2
Link NOC:Applied Engineering Electromagnetics Lecture 64 - Fields of a Dipole Antenna
Link NOC:Applied Engineering Electromagnetics Lecture 65 - Antenna Parameters and Long wire Antenna
Link NOC:Applied Engineering Electromagnetics Lecture 66 - Friis Transmission Formula
Link NOC:Principles of Signals and Systems Lecture 1 - Principles of Signals and Systems- Introduction to Signals and Systems, Signal Classification - Continuous and Discrete Time Signals
Link NOC:Principles of Signals and Systems Lecture 2 - Analog and Digital Signals
Link NOC:Principles of Signals and Systems Lecture 3 - Energy and Power Signals
Link NOC:Principles of Signals and Systems Lecture 4 - Real Exponential Signals
Link NOC:Principles of Signals and Systems Lecture 5 - Memory/Memory-less and Causal/Non-Causal Systems
Link NOC:Principles of Signals and Systems Lecture 6 - Properties of Linear Systems
Link NOC:Principles of Signals and Systems Lecture 7 - Example Problems - 1
Link NOC:Principles of Signals and Systems Lecture 8 - Example Problems - 2
Link NOC:Principles of Signals and Systems Lecture 9 - Example Problems - 3
Link NOC:Principles of Signals and Systems Lecture 10 - Properties and Analysis of LTI Systems - I
Link NOC:Principles of Signals and Systems Lecture 11 - Properties and Analysis of LTI Systems - II
Link NOC:Principles of Signals and Systems Lecture 12 - Properties and Analysis of LTI Systems - III
Link NOC:Principles of Signals and Systems Lecture 13 - Properties of Discrete Time LTI Systems
Link NOC:Principles of Signals and Systems Lecture 14 - Example Problems LTI Systems - I
Link NOC:Principles of Signals and Systems Lecture 15 - Example Problems LTI Systems - II
Link NOC:Principles of Signals and Systems Lecture 16 - Example Problems DT-LTI Systems
Link NOC:Principles of Signals and Systems Lecture 17 - Laplace Transform
Link NOC:Principles of Signals and Systems Lecture 18 - Laplace Transform Properties - I
Link NOC:Principles of Signals and Systems Lecture 19 - Laplace Transform Properties - II
Link NOC:Principles of Signals and Systems Lecture 20 - Laplace Transform of LTI Systems
Link NOC:Principles of Signals and Systems Lecture 21 - Laplace Transform Example Problems - I
Link NOC:Principles of Signals and Systems Lecture 22 - Laplace Transform Example Problems - II
Link NOC:Principles of Signals and Systems Lecture 23 - Laplace Transform of RL, RC Circuit
Link NOC:Principles of Signals and Systems Lecture 24 - Z-Transform
Link NOC:Principles of Signals and Systems Lecture 25 - Z-Transform Properties - I
Link NOC:Principles of Signals and Systems Lecture 26 - Z-Transform Properties - II
Link NOC:Principles of Signals and Systems Lecture 27 - Z-Transform of LTI Systems
Link NOC:Principles of Signals and Systems Lecture 28 - Z-Transform Examples - I
Link NOC:Principles of Signals and Systems Lecture 29 - Z-Transform Examples - II
Link NOC:Principles of Signals and Systems Lecture 30 - Z-Transform Examples - III
Link NOC:Principles of Signals and Systems Lecture 31 - Z-Transform Examples - IV
Link NOC:Principles of Signals and Systems Lecture 32 - Inverse Z-Transform
Link NOC:Principles of Signals and Systems Lecture 33 - Fourier Analysis Introduction
Link NOC:Principles of Signals and Systems Lecture 34 - Complex Exponential and Trigonometric FS
Link NOC:Principles of Signals and Systems Lecture 35 - Conditions for Existence of FS
Link NOC:Principles of Signals and Systems Lecture 36 - Fourier Transform (FT) Introduction
Link NOC:Principles of Signals and Systems Lecture 37 - Properties of Fourier Transform - I
Link NOC:Principles of Signals and Systems Lecture 38 - Properties of Fourier Transform - II
Link NOC:Principles of Signals and Systems Lecture 39 - Fourier Transform - Parseval’s Relation
Link NOC:Principles of Signals and Systems Lecture 40 - Fourier Transform of LTI Systems
Link NOC:Principles of Signals and Systems Lecture 41 - FT- Ideal and Non-Ideal Filters
Link NOC:Principles of Signals and Systems Lecture 42 - Fourier Analysis Examples - I
Link NOC:Principles of Signals and Systems Lecture 43 - Fourier Analysis Examples - II
Link NOC:Principles of Signals and Systems Lecture 44 - Fourier Analysis Examples - III
Link NOC:Principles of Signals and Systems Lecture 45 - Fourier Analysis Examples - IV
Link NOC:Principles of Signals and Systems Lecture 46 - Fourier Analysis Examples - V
Link NOC:Principles of Signals and Systems Lecture 47 - Fourier Analysis Examples - VI
Link NOC:Principles of Signals and Systems Lecture 48 - Fourier Analysis Bode Plot - I
Link NOC:Principles of Signals and Systems Lecture 49 - Fourier Analysis Bode Plot - II
Link NOC:Principles of Signals and Systems Lecture 50 - Fourier Transform Examples: Filtering - Ideal Low Pass Filter
Link NOC:Principles of Signals and Systems Lecture 51 - Fourier Transform Problems: Unit Step Response of RC Circuit, Sampling of Continuous Signal
Link NOC:Principles of Signals and Systems Lecture 52 - Sampling: Spectrum of Sampled Signal, Nyquist Criterion
Link NOC:Principles of Signals and Systems Lecture 53 - Sampling: Reconstruction from Sampled Signal
Link NOC:Principles of Signals and Systems Lecture 54 - Fourier Analysis of Discrete Time Signals and Systems - Introduction
Link NOC:Principles of Signals and Systems Lecture 55 - Fourier Analysis of Discrete Time Signals - Duality, Parseval’s Theorem
Link NOC:Principles of Signals and Systems Lecture 56 - Discrete Time Fourier Transform: Definition, Inverse DTFT, Convergence, Relation between DTFT and z-Transform, DTFT of Common Signals
Link NOC:Principles of Signals and Systems Lecture 57 - Discrete Time Fourier Transform: Properties of DTFT - Linearity, Time Shifting, Frequency Shifting, Conjugation, Time-Reversal, Duality
Link NOC:Principles of Signals and Systems Lecture 58 - Discrete Time Fourier Transform: Properties of DTFT - Differentiation in Frequency, Difference in Time, Convolution, Multiplication, Parseval’s Relation
Link NOC:Principles of Signals and Systems Lecture 59 - DTFT: Discrete Time LTI Systems - LTI Systems Characterized by Difference Equations
Link NOC:Principles of Signals and Systems Lecture 60 - Discrete Fourier Transform - Definition, Inverse DFT, Relation between DFT and DFS, Relation between DFT and DTFT, Properties - Linearity, Time Shifting
Link NOC:Principles of Signals and Systems Lecture 61 - Discrete Fourier Transform: Properties - Conjugation, Frequency Shift, Duality, Circular Convolution, Multiplication, Parseval’s Relation, Example Problems for Fourier Analysis of Discrete Time Signals
Link NOC:Principles of Signals and Systems Lecture 62 - Example Problems: DFS Analysis of Discrete Time Signals, Problems on DTFT
Link NOC:Principles of Signals and Systems Lecture 63 - Example Problems: DTFT of Cosine, Unit Step Signals
Link NOC:Principles of Signals and Systems Lecture 64 - DTFT Example Problems - III
Link NOC:Principles of Signals and Systems Lecture 65 - DTFT Example Problems - IV
Link NOC:Principles of Signals and Systems Lecture 66 - DTFT Example Problems - V
Link NOC:Principles of Signals and Systems Lecture 67 - DFT Example Problems - I
Link NOC:Principles of Signals and Systems Lecture 68 - Example Problems: DFT, IDFT in Matrix form
Link NOC:Principles of Signals and Systems Lecture 69 - Group/Phase Delay - Part I
Link NOC:Principles of Signals and Systems Lecture 70 - Group/Phase Delay - Part II
Link NOC:Principles of Signals and Systems Lecture 71 - IIR Filter Structures: DF-I, DF-II
Link NOC:Principles of Signals and Systems Lecture 72 - IIR Filter Structures: Transpose Form
Link NOC:Principles of Signals and Systems Lecture 73 - IIR Filter Structures: Example
Link NOC:Principles of Signals and Systems Lecture 74 - IIR Filter Structures: Cascade Form
Link NOC:Principles of Signals and Systems Lecture 75 - IIR Filter: Parallel Form-I and II
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 1 - Vectors and Matrices - Linear Independence and Rank
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 2 - Eigenvectors and Eigenvalues of Matrices and their Properties
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 3 - Positive Semidefinite (PSD) and Postive Definite (PD) Matrices and their Properties
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 4 - Inner Product Space and it's Properties: Linearity, Symmetry and Positive Semi-definite
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 5 - Inner Product Space and it's Properties: Cauchy Schwarz Inequality
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 6 - Properties of Norm, Gaussian Elimination and Echleon form of matrix
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 7 - Gram Schmidt Orthogonalization Procedure
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 8 - Null Space and Trace of Matrices
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 9 - Eigenvalue Decomposition of Hermitian Matrices and Properties
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 10 - Matrix Inversion Lemma (Woodbury identity)
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 11 - Introduction to Convex Sets and Properties
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 12 - Affine Set Examples and Application
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 13 - Norm Ball and its Practical Applications
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 14 - Ellipsoid and its Practical Applications
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 15 - Norm Cone,Polyhedron and its Applications
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 16 - Applications: Cooperative Cellular Transmission
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 17 - Positive Semi Definite Cone And Positive Semi Definite (PSD) Matrices
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 18 - Introduction to Affine functions and examples
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 19 - norm balls and Matrix properties:Trace,Determinant
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 20 - Inverse of a Positive Definite Matrix
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 21 - Example Problems: Property of Norms,Problems on Convex Sets
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 22 - Problems on Convex Sets (Continued...)
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 23 - Introduction to Convex and Concave Functions
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 24 - Properties of Convex Functions with examples
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 25 - Test for Convexity: Positive Semidefinite Hessian Matrix
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 26 - Application: MIMO Receiver Design as a Least Squares Problem
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 27 - Jensen's Inequality and Practical Application
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 28 - Jensen's Inequality application
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 29 - Properties of Convex Functions
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 30 - Conjugate Function and Examples to prove Convexity of various Functions
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 31 - Examples on Operations Preserving Convexity
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 32 - Examples on Test for Convexity, Quasi-Convexity
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 33 - Examples on Convex Functions
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 34 - Practical Application: Beamforming in Multi-antenna Wireless Communication
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 35 - Practical Application: Maximal Ratio Combiner for Wireless Systems
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 36 - Practical Application: Multi-antenna Beamforming with Interfering User
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 37 - Practical Application: Zero-Forcing (ZF) Beamforming with Interfering User
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 38 - Practical Application: Robust Beamforming With Channel Uncertainity for Wireless Systems
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 39 - Practical Application: Robust Beamformer Design for Wireless Systems
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 40 - Practical Application: Detailed Solution for Robust Beamformer Computation in Wireless Systems Text
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 41 - Linear modeling and Approximation Problems: Least Squares
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 42 - Geometric Intuition for Least Squares
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 43 - Practical Application: Multi antenna channel estimation
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 44 - Practical Application:Image deblurring
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 45 - Least Norm Signal Estimation
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 46 - Regularization: Least Squares + Least Norm
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 47 - Convex Optimization Problem representation: Canonical form, Epigraph form
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 48 - Linear Program Practical Application: Base Station Co-operation
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 49 - Stochastic Linear Program,Gaussian Uncertainty
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 50 - Practical Application: Multiple Input Multiple Output (MIMO) Beamforming
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 51 - Practical Application: Multiple Input Multiple Output (MIMO) Beamformer Design
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 52 - Practical Application: Co-operative Communication, Overview and various Protocols used
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 53 - Practical Application: Probability of Error Computation for Co-operative Communication
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 54 - Practical Application:Optimal power allocation factor determination for Co-operative Communication
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 55 - Practical Application: Compressive Sensing
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 56 - Practical Application
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 57 - Practical Application- Orthogonal Matching Pursuit (OMP) algorithm for Compressive Sensing
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 58 - Example Problem: Orthogonal Matching Pursuit (OMP) algorithm
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 59 - Practical Application : L1 norm minimization and regularization approach for Compressive Sensing Optimization problem
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 60 - Practical Application of Machine Learning and Artificial Intelligence:Linear Classification, Overview and Motivation
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 61 - Practical Application: Linear Classifier (Support Vector Machine) Design
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 62 - Practical Application: Approximate Classifier Design
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 63 - Concept of Duality
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 64 - Relation between optimal value of Primal and Dual Problems, concepts of Duality gap and Strong Duality
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 65 - Example problem on Strong Duality
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 66 - Karush-Kuhn-Tucker (KKT) conditions
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 67 - Application of KKT condition:Optimal MIMO power allocation (Waterfilling)
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 68 - Optimal MIMO Power allocation (Waterfilling)-II
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 69 - Example problem on Optimal MIMO Power allocation (Waterfilling)
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 70 - Linear objective with box constraints, Linear Programming
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 71 - Example Problems II
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 72 - Examples on Quadratic Optimization
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 73 - Examples on Duality: Dual Norm, Dual of Linear Program (LP)
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 74 - Examples on Duality: Min-Max problem, Analytic Centering
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 75 - Semi Definite Program (SDP) and its application:MIMO symbol vector decoding
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 76 - Application:SDP for MIMO Maximum Likelihood (ML) Detection
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 77 - Introduction to big Data: Online Recommender System (Netflix)
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 78 - Matrix Completion Problem in Big Data: Netflix-I
Link NOC:Applied Optimization for Wireless, Machine Learning, Big Data Lecture 79 - Matrix Completion Problem in Big Data: Netflix-II
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 1 - Overview of fiber-optic communication systems
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 2 - Review of Maxwell’s equations
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 3 - Uniform plane waves (UWPs) in free-space
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 4 - Properties of UWPs (propagation constant, polarization, and Poynting vector)
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 5 - Boundary conditions and reflection from a PEC
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 6 - Obliquely incident waves-I (TE and TM waves, Snell’s laws)
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 7 - Obliquely incident waves-II (Reflection and transmission coefficients, Brewster angle)
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 8 - Total internal reflection
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 9 - Ray theory of dielectric slab waveguides
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 10 - Transverse resonance condition for slab waveguides
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 11 - Introduction to optical fibers
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 12 - Ray theory of light propagation in optical fibers
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 13 - Concept of waveguide modes
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 14 - Systematic procedure to obtain modes of a waveguide
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 15 - Systematic analysis of parallel plate metallic waveguide
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 16 - Systematic analysis of dielectric slab waveguides
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 17 - Further discussion on slab waveguides
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 18 - Modal analysis of step index optical fiber
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 19 - Properties of modes of step-index optical fiber - I
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 20 - Properties of modes of step-index optical fiber - II
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 21 - Linearly polarized modes
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 22 - Attenuation and power loss in fibers
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 23 - Introduction to dispersion in fibers
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 24 - Mathematical modelling of dispersion: Transfer function approach
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 25 - Pulse propagation equation and its solution
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 26 - Pre-chirped pulses and Inter and Intra-modal dispersion in optical fibers
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 27 - Beam Propagation Method
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 28 - Polarization Effects on Pulse Propagation
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 29 - Modes in Optical Fibres and Pulse Propagation in Optical Fibres
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 30 - Graded Index Fibers
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 31 - Light Sources, Detectors and Amplifiers
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 32 - Basics of Lasers-I (Structure of Lasers, Process of Photon Emission)
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 33 - Basics of Lasers-II (Einstein's Theory of Radiation)
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 34 - Basics of Lasers-III (Population Inversion and Rate Equation for Lasers)
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 35 - Basic Properties of Semiconductor Laser-I (Energy Gap, Intrinsic and Extrinsic Semiconductors)
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 36 - Basic Properties of Semiconductor Laser-II (Fermi Level)
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 37 - Optical Properties of Semiconductors-I (Direct Bandgap and Indirect Bandgap, Density of States)
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 38 - Optical Properties of Semiconductors-II (Gain, Absorption, Recombination rate) Homojunction Lasers
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 39 - Double Heterostructure Lasers, Introduction to Quantum Well Lasers
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 40 - Semiconductor Optical Amplifier
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 41 - Erbium-doped fiber amplifier
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 42 - Photodetectors
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 43 - Noise in Photodetectors
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 44 - Introduction to WDM components
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 45 - Couplers, Circulators, FRM and Filters
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 46 - Filter, MUX/DEMUX, Diffraction grating (FBG and Long period grating)
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 47 - Optical Modulators-I (Current modulation)
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 48 - Optical Modulators-II (Electro-optic modulators)
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 49 - Review of Communication Concepts-I (Deterministic and Random Signals, Baseband and Passband Signals)
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 50 - Review of Communication Concepts-II (Signal and vectors, Signal energy, Orthonormal basis functions)
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 51 - Intensity modulation/ Direct Detection
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 52 - BER discussion for OOK systems
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 53 - Higher order modulation and Coherent Receiver
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 54 - Coherent receiver for BPSK systems and BER calculation
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 55 - Recovering Polarization
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 56 - DSP algorithms for Chromatic dispersion mitigation
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 57 - DSP algorithms for Carrier phase estimation - I
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 58 - DSP algorithms for Carrier phase estimation - II
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 59 - Nonlinear effects in fiber
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 60 - Four wave mixing, Loss measurement, Dispersion measurement
Link NOC:Fiber-Optic Communication Systems and Techniques Lecture 61 - Lab Demonstration (Laser diode characteristics, Loss measurement, Optical Intensity Modulation)
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 1 - Introduction and Types of Transmission Lines
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 2 - Distributed Circuit Model of Uniform Transmission Line
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 3 - Voltage and Current Equation of the Transmission line
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 4 - Sinusoidal Excitation of Transmission Line (Propagation constant, Characteristic Impedance)
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 5 - Properties of Transmission Line (Reflection Coefficient, Input Impedance, Standing Wave Ratio)
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 6 - Power Calculations and Introduction to Smith Chart
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 7 - Smith Chart
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 8 - Additional Applications of Smith Chart
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 9 - Time domain Analysis of Transmission Line - I
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 10 - Time domain Analysis of Transmission Line - II
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 11 - Usage of Lattice Diagrams
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 12 - TDR analysis of Transmission Lines
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 13 - Introduction to Propagation of Electromagnetic Waves
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 14 - Uniform Plane Waves - I
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 15 - Uniform Plane Waves - II
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 16 - Poynting Vector, Average Power, Polarization
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 17 - Uniform Plane Waves in Lossy Medium
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 18 - Normal Incidence of Plane Waves
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 19 - Oblique Incidence of Plane Waves - I
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 20 - Oblique Incidence of Plane Waves - II
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 21 - Total Internal Reflection
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 22 - Slab Waveguides
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 23 - Optical Fibers
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 24 - Parallel Plate Waveguides
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 25 - Rectangular Waveguides
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 26 - Modes of Rectangular Waveguides
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 27 - Waveguides summary and Introduction to Radiation
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 28 - Solution to Electric Scalar Potential and Magnetic Vector Potential Equations
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 29 - Further discussion on Magnetic Vector Potential and Elementary Hertzian Dipole
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 30 - Near field and Far-field Antenna and Properties of Antennas
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 31 - Linear antenna - I
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 32 - Linear antenna - II and Properties of Transmitting and Receiving Antenna
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 33 - Friis Transmission Formula
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 34 - Antenna Array
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 35 - Wireless Channel
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 36 - Further discussion on Wireless Channel Modelling
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 37 - Diffraction - I
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 38 - Diffraction - II
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 39 - Distribution of Laser Beam
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 40 - Interference (Double slit experiment, Fabry Perot Interferometer)
Link NOC:Electromagnetic Waves in Guided and Wireless Media Lecture 41 - Summary
Link NOC:Basic Electric Circuits Lecture 1 - Basic Concepts
Link NOC:Basic Electric Circuits Lecture 2 - Sinusoids and Phasors
Link NOC:Basic Electric Circuits Lecture 3 - Circuit Elements - Part 1
Link NOC:Basic Electric Circuits Lecture 4 - Circuit Elements - Part 2
Link NOC:Basic Electric Circuits Lecture 5 - AC Power Analysis
Link NOC:Basic Electric Circuits Lecture 6 - RMS Voltage and Current
Link NOC:Basic Electric Circuits Lecture 7 - Topology
Link NOC:Basic Electric Circuits Lecture 8 - Star-Delta Transformation and Mesh Analysis
Link NOC:Basic Electric Circuits Lecture 9 - Mesh Analysis.
Link NOC:Basic Electric Circuits Lecture 10 - Nodal Analysis
Link NOC:Basic Electric Circuits Lecture 11 - Linearity Property and Superposition Theorem
Link NOC:Basic Electric Circuits Lecture 12 - Source Transformation
Link NOC:Basic Electric Circuits Lecture 13 - Duality
Link NOC:Basic Electric Circuits Lecture 14 - Thevenin's Theorem - 1
Link NOC:Basic Electric Circuits Lecture 15 - Thevenin's Theorem - 2
Link NOC:Basic Electric Circuits Lecture 16 - Norton's Theorem - 1
Link NOC:Basic Electric Circuits Lecture 17 - Norton's Theorem - 2
Link NOC:Basic Electric Circuits Lecture 18 - Maximum Power Transfer Theorem - 1
Link NOC:Basic Electric Circuits Lecture 19 - Maximum Power Transfer Theorem - 2
Link NOC:Basic Electric Circuits Lecture 20 - Reciprocity and Compensation Theorem
Link NOC:Basic Electric Circuits Lecture 21 - First Order RC Circuits
Link NOC:Basic Electric Circuits Lecture 22 - First Order RL Circuits
Link NOC:Basic Electric Circuits Lecture 23 - Singularity Functions
Link NOC:Basic Electric Circuits Lecture 24 - Step Response of RC and RL Circuits
Link NOC:Basic Electric Circuits Lecture 25 - Second Order Response
Link NOC:Basic Electric Circuits Lecture 26 - Step Response of Second Order Circuits-First Order and Second Order Circuits (Continued...)
Link NOC:Basic Electric Circuits Lecture 27 - Step Response of Parallel RLC Circuit-First Order and Second Order Circuits (Continued...)
Link NOC:Basic Electric Circuits Lecture 28 - Definition of the Laplace Transform
Link NOC:Basic Electric Circuits Lecture 29 - Properties of the Laplace Transform
Link NOC:Basic Electric Circuits Lecture 30 - Inverse Laplace Transform
Link NOC:Basic Electric Circuits Lecture 31 - Laplace Transform of Circuit Elements
Link NOC:Basic Electric Circuits Lecture 32 - Transfer Function
Link NOC:Basic Electric Circuits Lecture 33 - Convolution Integral
Link NOC:Basic Electric Circuits Lecture 34 - Graphical Approach of Convolution Integral
Link NOC:Basic Electric Circuits Lecture 35 - Network Stability and Network Synthesis
Link NOC:Basic Electric Circuits Lecture 36 - Impedance Parameters
Link NOC:Basic Electric Circuits Lecture 37 - Admittance Parameters
Link NOC:Basic Electric Circuits Lecture 38 - Hybrid Parameters
Link NOC:Basic Electric Circuits Lecture 39 - Transmission Parameters
Link NOC:Basic Electric Circuits Lecture 40 - Interconnection of Networks
Link NOC:Basic Electric Circuits Lecture 41 - Nodal and Mesh Analysis
Link NOC:Basic Electric Circuits Lecture 42 - Superposition Theorem and Source Transformation
Link NOC:Basic Electric Circuits Lecture 43 - Thevenin's, Norton's and, Maximum Power Transfer Theorem
Link NOC:Basic Electric Circuits Lecture 44 - Magnetically Coupled Circuits
Link NOC:Basic Electric Circuits Lecture 45 - Energy in Coupled Circuits and Ideal Transformer
Link NOC:Basic Electric Circuits Lecture 46 - Ideal Transformer and Introduction to Three-Phase Circuits
Link NOC:Basic Electric Circuits Lecture 47 - Balanced Three-Phase Connections
Link NOC:Basic Electric Circuits Lecture 48 - Balanced Wye-Delta and Delta-Delta Connections
Link NOC:Basic Electric Circuits Lecture 49 - Balanced Delta-Wye Connection and Power in Balanced Three-Phase System
Link NOC:Basic Electric Circuits Lecture 50 - Unbalanced Three-Phase System and Three-Phase Power Measurement
Link NOC:Basic Electric Circuits Lecture 51 - Introduction to Graphical Models
Link NOC:Basic Electric Circuits Lecture 52 - State Equations
Link NOC:Basic Electric Circuits Lecture 53 - State Diagram
Link NOC:Basic Electric Circuits Lecture 54 - State Transition Matrix
Link NOC:Basic Electric Circuits Lecture 55 - State Variable Method to Circuit Analysis
Link NOC:Basic Electric Circuits Lecture 56 - Characteristic Equation, Eigenvalues, and Eigenvectors-State Variable Analysis (Continued...)
Link NOC:Basic Electric Circuits Lecture 57 - Modeling of Mechanical Systems
Link NOC:Basic Electric Circuits Lecture 58 - Modeling of The Rotational Motion of Mechanical Systems
Link NOC:Basic Electric Circuits Lecture 59 - Modeling of Electrical Systems
Link NOC:Basic Electric Circuits Lecture 60 - Solving Analogous Systems
Link NOC:Fundamentals of Electric Drives Lecture 1 - Introduction to Electric Drives
Link NOC:Fundamentals of Electric Drives Lecture 2 - Dynamics of Electric Drives, Four Quadrant Operation, Equivalent Drive Parameters
Link NOC:Fundamentals of Electric Drives Lecture 3 - Equivalent Drive Parameters, Friction Components, Nature of Load Torque
Link NOC:Fundamentals of Electric Drives Lecture 4 - Steady State Stability, Load Equalization
Link NOC:Fundamentals of Electric Drives Lecture 5 - Load Equalization, Characteristics of DC Motor
Link NOC:Fundamentals of Electric Drives Lecture 6 - Speed Torque Characteristics of Separately Excited DC Motor and Series DC Motor
Link NOC:Fundamentals of Electric Drives Lecture 7 - Field Control of Series Motor, Motoring and Braking of Separately Excited and Series DC motors
Link NOC:Fundamentals of Electric Drives Lecture 8 - Speed Control of Separately Excited DC Motor Using Controlled Rectifiers
Link NOC:Fundamentals of Electric Drives Lecture 9 - Analysis of Single Phase Full Controlled Converter-fed Separately Excited DC Motor
Link NOC:Fundamentals of Electric Drives Lecture 10 - Speed Torque Characteristics of Full Controlled Converter-fed Separately Excited DC Motor, Analysis of Single Phase Half Controlled Converter-fed Separately Excited DC Motor
Link NOC:Fundamentals of Electric Drives Lecture 11 - Analysis of Single Phase Half Controlled Converter-fed Separately Excited DC Motor.
Link NOC:Fundamentals of Electric Drives Lecture 12 - Three Phase Full Controlled Converter-fed Separately Excited DC Motor, Multi-quadrant Operation of DC Motor
Link NOC:Fundamentals of Electric Drives Lecture 13 - Dual Converter-fed DC Motor, Multi-quadrant Operation Using Field Current Reversal
Link NOC:Fundamentals of Electric Drives Lecture 14 - DC Chopper-fed Separately Excited DC Motor for Motoring and Braking
Link NOC:Fundamentals of Electric Drives Lecture 15 - Two-quadrant DC Chopper, Four-quadrant DC Chopper
Link NOC:Fundamentals of Electric Drives Lecture 16 - Dynamic Braking of DC Motor by Chopper Controlled Resistor, Closed-loop Operation of DC Drives, Induction Motor Drives
Link NOC:Fundamentals of Electric Drives Lecture 17 - Speed Torque Characteristics of Induction Motor, Operation of Induction Motor from Non-sinusoidal Supply
Link NOC:Fundamentals of Electric Drives Lecture 18 - Operation of Induction Motor from Non-sinusoidal Supply
Link NOC:Fundamentals of Electric Drives Lecture 19 - Stator Current of Induction Motor with Non-sinusoidal Supply, Operation of Induction Motor with Unbalanced Voltage Supply
Link NOC:Fundamentals of Electric Drives Lecture 20 - Single Phasing of Induction Motor, Braking of Induction Motor
Link NOC:Fundamentals of Electric Drives Lecture 21 - Dynamic braking of induction motor, AC dynamic braking, DC dynamic braking
Link NOC:Fundamentals of Electric Drives Lecture 22 - Analysis of DC dynamic braking of induction motor
Link NOC:Fundamentals of Electric Drives Lecture 23 - Self-excited dynamic braking of induction motor, Speed control of induction motor using stator voltage regulator, Variable voltage variable frequency control
Link NOC:Fundamentals of Electric Drives Lecture 24 - Variable voltage variable frequency control of induction motor, Open loop V/F control
Link NOC:Fundamentals of Electric Drives Lecture 25 - Slip speed control of induction motor, Constant Volt/Hz control with slip speed regulation
Link NOC:Fundamentals of Electric Drives Lecture 26 - Closed-loop Volt/Hz control of induction motor with slip speed regulation, Multi-quadrant operation of induction motor drive
Link NOC:Fundamentals of Electric Drives Lecture 27 - Current Source Inverter (CSI) fed induction motor drive
Link NOC:Fundamentals of Electric Drives Lecture 28 - Closed-loop operation of current source inverter (CSI) fed induction motor drive, Control of slip ring induction motor - Static rotor resistance control
Link NOC:Fundamentals of Electric Drives Lecture 29 - Closed-loop operation of slip ring induction motor with static rotor resistance control, Slip power recovery in slip ring induction motor - Static Kramer drive
Link NOC:Fundamentals of Electric Drives Lecture 30 - Static Kramer drive and its closed-loop control, Introduction to synchronous motor
Link NOC:Fundamentals of Electric Drives Lecture 31 - Various types of synchronous motors, Equivalent circuit and phasor diagram of cylindrical synchronous motor, Speed-torque characteristics of cylindrical synchronous motor
Link NOC:Fundamentals of Electric Drives Lecture 32 - Phasor diagram of salient pole synchronous motor, Expression of power and torque for a salient pole synchronous motor, Synchronous reluctance motor, Open-loop V/f control of synchronous motor
Link NOC:Fundamentals of Electric Drives Lecture 33 - Open-loop V/f control, Torque-speed characteristics, Self controlled synchronous motor drive employing load commutated thyristor inverter
Link NOC:Fundamentals of Electric Drives Lecture 34 - Detailed analysis of commutation of load commutated thyrisor inverter, Derivation of overlap angle and margin angle, Closed-loop speed control scheme for load commutated inverter-fed synchronous motor drive
Link NOC:Fundamentals of Electric Drives Lecture 35 - Low cost brushless DC motor (BLDCM), Trapezoidal permanent magnet AC motor
Link NOC:Fundamentals of Electric Drives Lecture 36 - Trapezoidal permanent magnet AC motor, Derivation of power and torque, Closed-loop control of trapezoidal BLDC motor, Introduction to switched reluctance motor
Link NOC:Fundamentals of Electric Drives Lecture 37 - Construction and operating principle of switched reluctance motor
Link NOC:Fundamentals of Electric Drives Lecture 38 - Current/ voltage control for switched reluctance motor, operating modes of switched reluctance motor, Introduction to traction drives
Link NOC:Fundamentals of Electric Drives Lecture 39 - Current collector for mainline trains, Nature of traction load, Duty cycle of traction drives
Link NOC:Fundamentals of Electric Drives Lecture 40 - Duty cycle of traction drives, Distance between two stops, Calculation of total tractive effort and drive rating
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 1 - Introduction: Fuzzy Sets, Logic and Systems and Applications
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 2 - Introduction: Real Life Applications of Fuzzy Systems
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 3 - Fuzzy Sets and Fuzzy Logic Toolbox in MATLAB - I
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 4 - Fuzzy Sets and Fuzzy Logic Toolbox in MATLAB - II
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 5 - Membership Functions - I
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 6 - Membership Functions - II
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 7 - Nomenclatures used in Fuzzy Set Theory - I
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 8 - Nomenclatures used in Fuzzy Set Theory - II
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 9 - Nomenclatures used in Fuzzy Set Theory - III
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 10 - Set Theoretic Operations on Fuzzy Sets - I
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 11 - Set Theoretic Operations on Fuzzy Sets - II
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 12 - Properties of Fuzzy Sets - I
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 13 - Properties of Fuzzy Sets - II
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 14 - Properties of Fuzzy Sets - III
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 15 - Properties of Fuzzy Sets - IV
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 16 - Properties of Fuzzy Sets - V
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 17 - Distance between Fuzzy Sets - I
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 18 - Distance between Fuzzy Sets - II
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 19 - Distance between Fuzzy Sets - III
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 20 - Arithmetic Operations on Fuzzy Numbers - I
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 21 - Arithmetic Operations on Fuzzy Numbers - II
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 22 - Arithmetic Operations on Fuzzy Numbers - III
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 23 - Complement of Fuzzy Sets
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 24 - T-norm Operators
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 25 - S-norm Operators
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 26 - Parameterized T-Norm Operators
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 27 - Parameterized S-Norm Operators
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 28 - Fuzzy Relation - I
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 29 - Fuzzy Relation - II
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 30 - Operations on Crisp and Fuzzy Relations
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 31 - Projection of Fuzzy Relation Set
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 32 - Cylindrical Extension of Fuzzy Set
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 33 - Properties of Fuzzy Relation - I
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 34 - Properties of Fuzzy Relation - II
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 35 - Extension Principle
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 36 - Composition of Fuzzy Relations
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 37 - Properties of Composition of Fuzzy Relations
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 38 - Fuzzy Tolerance and Equivalence Relations - I
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 39 - Fuzzy Tolerance and Equivalence Relations - II
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 40 - Fuzzy Tolerance and Equivalence Relations - III
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 41 - Linguistic Hedges
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 42 - Linguistic Hedges and Negation/ Complement and Connectives
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 43 - Concentration and Dilation and Composite Linguistic Term and Some Examples
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 44 - Dilation and Composite Linguistic Term and Some Examples
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 45 - Some Examples on Composite Linguistic Terms
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 46 - Contrast Intensification of Fuzzy Sets
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 47 - Orthogonality of Fuzzy Sets
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 48 - Fuzzy Rules and Fuzzy Reasoning - I
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 49 - Fuzzy Rules and Fuzzy Reasoning - II
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 50 - Fuzzy Inference System
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 51 - Mamdani Fuzzy Model - I
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 52 - Mamdani Fuzzy Model - II
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 53 - Mamdani Fuzzy Model - III
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 54 - Example on Mamdani Fuzzy Model for Single Antecedent with Three Rules
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 55 - Example on Mamdani Fuzzy Model for Two Antecedents with Four Rules
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 56 - Larsen Fuzzy Model - I
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 57 - Larsen Fuzzy Model - II
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 58 - Larsen Fuzzy Model - III
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 59 - Tsukamoto Fuzzy Model
Link NOC:Fuzzy Sets, Logic and Systems and Applications Lecture 60 - TSK Fuzzy Model
Link NOC:Peer to Peer Networks Lecture 1 - Introduction to Peer to Peer Networks
Link NOC:Peer to Peer Networks Lecture 2 - Peer to Peer Network in Telephony:Voice over Internet Telephony (VoIP) and Distributed Hash Table (DHT)
Link NOC:Peer to Peer Networks Lecture 3 - Building DHT Networks
Link NOC:Peer to Peer Networks Lecture 4 - Logarithmic Partitioning of Node ID Space and Index Entry Authenticity
Link NOC:Peer to Peer Networks Lecture 5 - Implementation of Voice over Internet Telephony in P2P Way
Link NOC:Peer to Peer Networks Lecture 6 - Leaf Nodes, Core Nodes and Type of Messages in DHT Networks
Link NOC:Peer to Peer Networks Lecture 7 - Static and Dynamic Partitioning of Node ID Space: Fixed and Floating Partitioning
Link NOC:Peer to Peer Networks Lecture 8 - PASTRY Protocol: The Efficient Use of Internet Infrastructure
Link NOC:Peer to Peer Networks Lecture 9 - Understanding the PASTRY Protocol through Example
Link NOC:Peer to Peer Networks Lecture 10 - Kademlia: A DHT Routing Protocol
Link NOC:Peer to Peer Networks Lecture 11 - Tapestry: An Evolution of Kademlia
Link NOC:Peer to Peer Networks Lecture 12 - Understanding the Tapestry Protocol through Example
Link NOC:Peer to Peer Networks Lecture 13 - Multi-dimensional Distributed Hash Table: Mapping of Peers into Multidimensional Space
Link NOC:Peer to Peer Networks Lecture 14 - Multi-Layer DHT: A Design for Multiple Services
Link NOC:Peer to Peer Networks Lecture 15 - Keeping Pairs at Correct Root Nodes
Link NOC:Peer to Peer Networks Lecture 16 - Abrupt and Graceful Exit of Root Node: Maintaining Pairs Alive
Link NOC:Peer to Peer Networks Lecture 17 - Resilience of Pairs
Link NOC:Peer to Peer Networks Lecture 18 - A P2P Distributed File System
Link NOC:Peer to Peer Networks Lecture 19 - Storage Space Problem and Incentives to Share Storage
Link NOC:Peer to Peer Networks Lecture 20 - P2P Nodes Communications Challenges in Heterogeneous Network Environments
Link NOC:Peer to Peer Networks Lecture 21 - P2P Overlaid Multicast: Basic Design
Link NOC:Peer to Peer Networks Lecture 22 - P2P Overlaid Multicast: Alternate Design
Link NOC:Peer to Peer Networks Lecture 23 - A Design of P2P Email System
Link NOC:Peer to Peer Networks Lecture 24 - P2P Mailing List Services: A Basic Design
Link NOC:Peer to Peer Networks Lecture 25 - P2P Mailing List Services: An Alternate Design
Link NOC:Peer to Peer Networks Lecture 26 - P2P Web: A Basic Design
Link NOC:Peer to Peer Networks Lecture 27 - P2P Web Search Engine: A Basic Design
Link NOC:Peer to Peer Networks Lecture 28 - P2P Internet: On Being Anonymous
Link NOC:Peer to Peer Networks Lecture 29 - P2P in Blockchain
Link NOC:Peer to Peer Networks Lecture 30 - P2P Anonymous Communication
Link NOC:Peer to Peer Networks Lecture 31 - The Anonymous Communication on the Internet through TOR Network
Link NOC:Peer to Peer Networks Lecture 32 - An Introduction To TOR Browser: The Anonymity Preserving Access of the Web Sites
Link NOC:Peer to Peer Networks Lecture 33 - Hidden Services on TOR Network
Link NOC:Peer to Peer Networks Lecture 34 - MOOC Wrap-Up : Summary of the Course
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 1 - Vector Properties: Addition, Linear Combination, Inner Product, Orthogonality, Norm
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 2 - Vectors: Unit Norm Vector, Cauchy-Schwarz inequality, Radar Application
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 3 - Inner Product Application: Beamforming in Wireless Communication Systems
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 4 - Matrices, Definition, Addition and Multiplication of Matrices
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 5 - Matrix: Column Space, Linear Independence, Rank of Matrix, Gaussian Elimination
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 6 - Matrix: Determinant, Inverse Computation, Adjoint, Cofactor Concepts
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 7 - Applications of Matrices: Solution of System of Linear equations, MIMO Wireless Technology
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 8 - Applications of Matrices: Electric Circuits, Traffic flows
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 9 - Applications of Matrices: Graph Theory, Social Networks, Dominance Directed Graph, Influential Node
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 10 - Null Space of Matrix: Definition, Rank-Nullity Theorem, Application in Electric Circuits
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 11 - Gram-Schmidt Orthogonalization
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 12 - Gaussian Random Variable: Definition, Mean, Variance, Multivariate Gaussian, Covariance Matrix
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 13 - Linear Transformation of Gaussian Random Vectors
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 14 - Machine Learning Application: Gaussian Classification
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 15 - Eigenvalue: Definition, Characteristic Equation, Eigenvalue Decomposition
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 16 - Special Matrices: Rotation and Unitary Matrices, Application: Alamouti Code
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 17 - Positive Semi-definite (PSD) Matrices: Definition, Properties, Eigenvalue Decomposition
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 18 - Positive Semidefinite Matrix: Example and Illustration of Eigenvalue Decomposition
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 19 - Machine Learning Application: Principle Component Analysis (PCA)
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 20 - Computer Vision Application: Face Recognition, Eigenfaces
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 21 - Least Squares (LS) Solution, Pseudo-Inverse Concept
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 22 - Least Squares (LS) via Principle of Orthogonality, Projection Matrix, Properties
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 23 - Application: Pseudo-Inverse and MIMO Zero Forcing (ZF) Receiver
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 24 - Wireless Application: Multi-Antenna Channel Estimation
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 25 - Machine Learning Application: Linear Regression
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 26 - Computation Mathematics Application: Polynomial Fitting
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 27 - Least Norm Solution
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 28 - Wireless Application: Multi-user Beamforming
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 29 - Singular Value Decomposition (SVD): Definition, Properties, Example
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 30 - SVD Application in MIMO Wireless Technology: Spatial-Multiplexing and High Data Rates
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 31 - SVD for MIMO wireless optimization, water-filling algorithm, optimal power allocation
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 32 - SVD application for Machine Learning: Principal component analysis (PCA)
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 33 - Multiple signal classification (MUSIC) algorithm: system model
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 34 - MUSIC algorithm for Direction of Arrival (DoA) estimation
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 35 - Linear minimum mean square error (LMMSE) principle
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 36 - LMMSE estimate and error covariance matrix
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 37 - LMMSE estimation in linear systems
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 38 - LMMSE application: Wireless channel estimation and example
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 39 - Time-series prediction via auto-regressive (AR) model
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 40 - Recommender system: design and rating prediction
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 41 - Recommender system: Illustration via movie rating prediction example
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 42 - Fast Fourier transform (FFT) and Inverse fast Fourier transform (IFFT)
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 43 - IFFT/ FFT application in Orthogonal Frequency Division Multiplexing (OFDM) wireless technology
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 44 - OFDM system: Circulant matrices and properties
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 45 - OFDM system model: Transmitter and receiver processing
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 46 - Single-carrier frequency division for multiple access (SC-FDMA) technology
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 47 - Linear dynamical systems: definition and solution via matrix exponential
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 48 - Linear dynamical systems: matrix exponential via SVD
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 49 - Machine Learning application: Support Vector Machines (SVM)
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 50 - Support Vector Machines (SVM): Problem formulation via maximum hyperplane separation
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 51 - Sparse regression: problem formulation and relation to Compressive Sensing (CS)
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 52 - Sparse regression: solution via the Orthogonal Matching Pursuit (OMP) algorithm
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 53 - OMP Example for Sparse Regression
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 54 - Machine Learning Application: Clustering
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 55 - K-Means Clustering algorithm
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 56 - Introduction to Stochastic Processes and Markov Chains
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 57 - Discrete Time Markov Chains and Transition Probability Matrix
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 58 - Discrete Time Markov Chain Examples
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 59 - m-STEP Transition Probabilities for Discrete Time Markov Chains
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 60 - Limiting Behavior of Discrete Time Markov Chains
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 61 - Least Squares Revisited: Rank Deficient Matrix
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 62 - Least Squares using SVD
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 63 - Weighted Least Squares
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 64 - Weighted Least Squares Example
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 65 - Woodbury Matrix Identity - Matrix Inversion Lemma
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 66 - Woodbury Matrix Identity - Proof
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 67 - Conditional Gaussian Density - Mean
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 68 - Conditional Gaussian Density - Covariance
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 69 - Scalar Linear Model for Gaussian Estimation
Link NOC:Applied Linear Algebra for Signal Processing, Data Analytics and Machine Learning Lecture 70 - MMSE Estimate and Covariance for the Scalar Linear Model
Link NOC:Economic Operations and Control of Power Systems Lecture 1
Link NOC:Economic Operations and Control of Power Systems Lecture 2
Link NOC:Economic Operations and Control of Power Systems Lecture 3
Link NOC:Economic Operations and Control of Power Systems Lecture 4
Link NOC:Economic Operations and Control of Power Systems Lecture 5
Link NOC:Economic Operations and Control of Power Systems Lecture 6
Link NOC:Economic Operations and Control of Power Systems Lecture 7
Link NOC:Economic Operations and Control of Power Systems Lecture 8
Link NOC:Economic Operations and Control of Power Systems Lecture 9
Link NOC:Economic Operations and Control of Power Systems Lecture 10
Link NOC:Economic Operations and Control of Power Systems Lecture 11
Link NOC:Economic Operations and Control of Power Systems Lecture 12
Link NOC:Economic Operations and Control of Power Systems Lecture 13
Link NOC:Economic Operations and Control of Power Systems Lecture 14
Link NOC:Economic Operations and Control of Power Systems Lecture 15
Link NOC:Economic Operations and Control of Power Systems Lecture 16
Link NOC:Economic Operations and Control of Power Systems Lecture 17
Link NOC:Economic Operations and Control of Power Systems Lecture 18
Link NOC:Economic Operations and Control of Power Systems Lecture 19
Link NOC:Economic Operations and Control of Power Systems Lecture 20
Link NOC:Economic Operations and Control of Power Systems Lecture 21
Link NOC:Economic Operations and Control of Power Systems Lecture 22
Link NOC:Economic