Automatic Control EE331

Automatic Control EE331

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What You Learn


Students can learn Introduction to control system, Reviewing to Laplace and Inverse Laplace, Electrical and Mechanical Modelling, Block diagram reductions, Stability issues, response and Steady state errors, State Space, Root locus analysis and design.

 

Requirements


Reviewing all previous mathematics (LaPlace and inverse LaPlace) and all electrical principals

Description


This course , students can learn all principal of automatic control.

Who This Course Is For


Students of the Faculty of Engineering in university education

Course Content


  • EE331 Course introduction 00:12:09

  • Ch.1 introduction to control system 00:31:51

  • Ch.1.1 introduction to control system 00:17:46

  • Ch.2.1 Electrical modeling 00:37:02

  • Ch.2.2 Tutorial of Electrical modeling 00:19:21

  • Ch.2.3 Mechanical modeling 00:27:29

  • Ch.2.4 relation between electrical and mechanical systems 00:27:04

  • Ch.2.5 tutorial of modeling 00:47:27

  • Ch.3.1 Laplace Transform 00:38:56

  • Ch.3.2 problems on Laplace transform 00:20:41

  • Ch.3.3 Inverse Laplace 00:31:18

  • Ch.3.4 problems 00:30:31

  • Ch.3.5 Tutorial 2 00:58:45

  • Ch.3.6 Tutorial 3 01:00:57

  • Ch.4.1 Block diagram reduction 00:42:28

  • Ch.4.2 Signal Flow Graph 00:47:08

  • Ch.4.3 Signal Flow graph 00:31:46

  • Ch.4.4 Problems 1 00:39:36

  • Ch.4.5 Problems 2 00:34:57

  • Ch.4.6 Problem 3 00:55:50

  • Ch.5.1 Routh Hurwitz Stability Case-1 00:36:53

  • Ch.5.2 Routh Hurwitz Stability Case-2&3 00:41:22

  • Ch.5.3 Routh Hurwitz Stability Problems 1 00:30:51

  • Ch.5.4 Routh Hurwitz Stability Major Problems 00:42:19

  • Ch.7.1 Time Domaine First and Second order systems 00:44:53

  • Ch.7.2 Second System Response's Parameters 00:37:21

  • Ch.7.3 Problems on Second Order systems 00:31:02

  • Ch.7.4 Steady State Errors 00:35:28

  • Ch.7.5 Relation between system type numbers and inputs errors 00:35:30

  • Ch.7.6 Error Problem 1 00:28:37

  • Ch.7.7 Error Problems 2 00:26:20

  • Ch.8.1 State Space Cases 00:40:50

  • Ch.2.6 Quiz problem 00:16:17

  • Ch.3.9 Quiz 00:22:20

  • ‏‏Ch.3.7 State Space Cases 00:40:50

  • Ch.3.8 State space problem 00:19:46

  • Ch.8.2 Transfer Function from State space 00:25:52

  • Ch.8.3 State transition matrix and response problem 00:26:29

  • Ch.8.4 State Space Problem 1 00:45:26

  • Ch.8.5 State Space Problem 2 00:42:43

  • Ch.3.10 Partial fraction of Complex poles 00:22:47

  • Ch.2.7 Important problems on modeling 00:57:31

  • Ch.9.1 Root locus introduction 01:14:55

  • Ch.9.2 Root locus problem 1 00:53:44

  • Ch.9.3 Root Locus problem 2 00:39:59

  • Ch.9.4 Root locus problem 3 00:25:54

  • Ch.9.5 Root locus problem 4 00:28:47

  • Ch.9.6 Root locus problem 5 00:30:36

  • Ch.11.1 Root locus design 00:41:02

  • Ch.11.2 Root locus PD design 00:57:57

  • Ch.11.3 follow Root locus PD design 00:18:43

  • Ch.8.6 Eigen vectors 00:11:09

  • Ch.8.7 State Transformation 00:24:25

  • Ch.11.4 Root locus PI design 00:51:03

  • Ch.11.5 Follow Root locus PI design 00:13:45

  • Ch.11.6 Ideal Derivative Root locus design 00:44:18

  • Ch.11.7 Lag Lead Root Locus design 00:40:19

  • Ch.11.8 Root locus design problem 1 00:36:10

  • Ch.11.9 Root Locus design problem 2 00:43:27

  • Ch.11.10 PID Fixed structures pole placement 1 00:40:09

  • Ch.10.1 Frequency domain analysis 00:45:35

  • Ch.10.2 Bode plots example 01:01:17

  • Ch.10.2 Bode plots example 01:01:17

  • Ch.11.11 Fixed structures problem 1 00:15:10

  • Ch.11.12 Algebraic compensation 00:15:35

  • Ch.11.13 Pole placement problems 00:22:23

  • Ch.10.3 Phase margin and Gain margin 00:28:23

  • Ch.10.4 Frequency responses problems 00:44:30

  • Ch.3.11 Major's problem 00:30:06

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138.4 USD 346

Limited Time Offer

  • Start Date
  • Language Arabic & English
  • Lectures 69
  • Duration 41.7 hours
  • Expire in days 90 day access
  • Certificate No