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Lec 00 Introduction of Control System || GATE-2022

Lec 01 Basic Concept of Control System || GATE-2022

Lec 02 Open Loop & Closed Loop Control System || Control System || GATE-2022

Lec 03 Transfer Function, Negative Feedback & Positive Feedback || Control System || GATE-2022

Lec 04 Concept of OLTF & CLTF || Control System || GATE-2022

Lec 05 Dominant Pole Concept & Time Constant for a System || Control System || GATE-2022

Lec 06 DC Gain of a Transfer Function || Control System || GATE-2022

Lec 07 Question Discussion on Dominant Pole Concept || Control System || GATE-2022

Lec 08 Sensitivity of a System wrt Forward & Feedback Path Parameters || Control System || GATE-2022

Lec 09 Question Discussion on Sensitivity Concept || Control System || GATE-2022

Know about the CONTROL system | Why control system is so important for GATE?

Lec 10 Laplace Transform of Some Basic Functions Part-01 || Control System || GATE-2022

Lec 11 Laplace transform of some basic functions part 02 | Control System for GATE

Lec 12 Significance of poles and condition for stability | Control System for GATE

Lec 13 Initial value and final value theorem | Control System for GATE

Lec 14 Question discussion on initial and final value theorems | Control System for GATE

Lec 15 Impulse response and Step response | Control System for GATE

Lec 16 Question Discussion on Basic concepts Part 01

Lec 17 Question Discussion on Basic concepts Part 02

Lec 18 Question discussion on basic concepts part 03

Lec 19 Question discussion on basic concepts part 04

Lec 20 Question discussion on basic concepts part 05

Complete Revision of Basic Concept of Control system Chapter 01 Part 01

Complete revision of Basic concepts of control system chapter 01/part 02

Lec 21 Introduction of Block diagram and SFG

Lec 22 Question discussion on Block diagram reduction

Lec 23 Terminology of Signal flow graph

Lec 24 Mason's Gain Formula

Lec 25 Question discussion on Mason's gain formula part 01

Lec 26 Question discussion on mason's gain formula part 02

Lec 27 Question discussion on mason's gain formula part 03

Lec 28 Question discussion on mason's gain formula part 04

Lec 29 Limitation of Mason's gain formula

Lec 30 How to draw an SFG from an ELECTRICAL network?

Lec 31 Complete revision of Block diagram and SFG

Lec 32 Time Response Analysis | Control Systems

Lec 33 Time domain analysis | First order system

Lec 35 Time domain analysis | First order system| Second order system

Lec 36 second order system | Undamped| Underdamped | Critical damped| Over damped system

Lec 37 Damping Ratio | Natural frequency of oscillation | second order system

Lec 38 Undamped | Underdamp | Critical damp | Over damped system for series and parallel RLC circuit

Lec 39 Quality factor | Time domain parameters of first order system

Lec 40 Step response of second order system

Lec 41 Brief of Impulse response and Step response of second order system

Lec 42 Time domain parameters of first order system | Delay time | Rise time | settling time

Lec 43 Time domain parameters of second order system | Delay, Rise, Peak and settling time

Lec 44 Maximum peak overshoot, settling time for under damped system

Lec 45 Question discussion on time domain parameters | Second order system part 01

Lec 47 Question discussion on time domain parameters | Second order system part 03

Lec 48 Question discussion on time domain parameters | Second order system part 04

Lec 49 Question discussion on time domain parameters | Second order system part 05

Lec 50 Question discussion on time domain parameters | Second order system part 06

Lec 51 Analysis of Steady State Error for Unity Feedback System | Complete Control System

Lec 52 Analysis of steady state error for unity feedback system and questions

Lec 53 Noise and disturbance elimination from the system

Lec 54 Sinusoidal response of an LTI system

Lec 55 Steady state error for unity feedback system question discussion

Lec 56 Steady state error for Non Unity feedback system

Lec 57 Steady state error for Non unity feedback system by Kuo method

Lec 58 Complete revision of Time Domain Analysis

Lec 59 Stability analysis | Routh hurwitz criteria

Lec 60 Concept of Row of Zeros | Routh Hurwitz criteria continue

Lec 61 Concept of sign change occurs above and below ROZ | Routh hurwitz criteria continue

Lec 62 Concept of auxiliary equation | Two ROZ | Routh Hurwitz criteria

Lec 63 Concept of Third order system stability | Routh Hurwitz

Lec 64 Question discussion on Routh Hurwitz

Lec 65 Root Locus Diagram | Important Concept | Control Systems

Lec 66 Relationship between OLTP poles & zeros to CLTF poles & zeros | Root Locus | Control system

Lec 68 Centroid, Break point, angle of asymptote concept in Root Locus | Control system

Lec 69 Angle of departure | Root locus | Control system

Lec 70 Question discussion on Root locus | Control system

Lec 71 Addition of Pole and Zero into the system | Root Locus | Control System

Lec 72 Complimentary root locus | Inverse root locus | Control system

Lec 73 Introduction of Bode Plot | Control system

Lec 74 How to draw Bode Plot for Pole and Zero at origin | Bode Plot | Control system

Lec 75 Bode plot for finite pole and zero | Corner frequency | Error | Control system

Lec 76 Error in Bode Plot | Control System

Lec 77 How to get TF from Bode Plot | Control system

Lec 78 Question discussion on Bode Plot | Control System

Lec 79 Polar Plot | Introduction | Control system

Lec 80/81 Polar plot basics | Control System

Lec 83 Polar plot | Gain Margin and Phase crossover frequency

Lec 84 Stability from Gain-Phase plot | Polar Plot

Lec 86 Nyquist Plot | important GATE concept continue |Control system

Lec87 Nyquist Plot | Principle of Argument | Control System

Lec 88 Nyquist Plot | Question discussion | Control system

Lec 89 Compensator and Controller | Control System for GATE

Lec 90 Lead Compensator | Control System for GATE

Lec 92 Complete Lag compensator, Lead-lag, Lag-Lead Compensator

Lec 93 Compensator | Important Question Discussion

Lec 94 Introduction of Controller | Control system for GATE

Lec 95 Proportional, Derivative and Integral controller

Lec 96 Frequency Response of Second Order System

Lec 97 State Space Analysis | Control System for GATE

Lec 98 State space model for Differential Equation

Lec 99 State Model for Differential Equation and Transfer function | State space analysis

Lec 100 Controllability and Observability | State space analysis

Lec 101 Question Discussion on state space continue

Description:

Embark on a comprehensive journey through control systems with this extensive course designed for GATE-2022 preparation. Explore fundamental concepts, transfer functions, feedback systems, and advanced topics like root locus, Bode plots, and state space analysis. Delve into time and frequency domain analyses, stability criteria, and compensator design. Master key techniques for solving complex control system problems through numerous question discussions and practical examples. Enhance your understanding of crucial topics such as Laplace transforms, block diagrams, signal flow graphs, and various types of controllers. Benefit from in-depth explanations of important theorems, system responses, and stability analysis methods to thoroughly prepare for the GATE exam.

Control System Full Course for GATE-2022 Demos

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