What you'll learnBDR Techniques, Mason's gain Formula, Polar Plots, Bode Plots, Nyquist Plots.
Electrical, Electronics and Instrumentation Engineering
Indepth Knowledge of Each Topic.
More than 15+ Hours of Content.
RequirementsA Basic Knowledge of Control Systems.
Description1. This Course targets the audience of Electrical, Electronics and Instrumentation Engineering Students.2. This Course is also called as Control Systems.3. If you have any experience in any Control Engineering Course prior to this then you can have a look.4. The Prerequisites required are mentioned in the Course Introduction Video.5. This is a Theoretical and Analytical Course.6. This Course is exclusively made from Beginners point of view.7. If you want to learn building Control Systems and Analyze there Performances.8. Solutions of Each Problem will be in Detail.8. You will be able to learn different topics with this Course like Routh Hurwitz Criteria, Polar Plots, Nyquist Plots.9. You will be able to handle Problems in Control Engineering after finishing this Course.Control Systems is one of the Easiest Course in the Field of Electrical, Electronics and Instrumentation Engineering – You can build Confidence by studying this Subject.With over 3+ Years of Experience and a 4.0 Instructor Rating in Udemy, I am Coming Up with Core Electronics Course of more than 15+ Hours of Theory and Problem Solving called Control Engineering - Complete Course (15+ Hours)The curriculum was developed over a period of 9 Months.If you are satisfied in any way, Check out my other Courses as well.So what are you waiting for? Click the buy now button and join me on this Wonderful course.
OverviewSection 1: Introduction
Lecture 1 Introduction
Section 2: Block Diagrams and their Reduction
Lecture 2 Block Diagrams
Lecture 3 Block Diagrams Connections and their Operations
Lecture 4 BDR Technique Example
Lecture 5 BDRT - SFG
Section 3: Mason's gain Formula
Lecture 6 Introduction of Mason' gain Formula
Lecture 7 Pk and B
Lecture 8 About Delta
Lecture 9 Touching and Non Touching Loops
Lecture 10 About Delta k
Lecture 11 Completing the Example
Lecture 12 Some Examples on Mason's Gain
Lecture 13 Self Loop [Exceptional Case]
Lecture 14 Self Loop - Part 2
Lecture 15 Self Loop - Part 3
Lecture 16 Finale
Section 4: Routh Hurwitz Criteria
Lecture 17 Routh Hurwitz Stability Criteria (Part 1)
Lecture 18 Routh Hurwitz Stability Criteria (Part 2)
Lecture 19 Routh Hurwitz Stability Criteria (Part 3)
Section 5: Time Response
Lecture 20 Initial and Final Value Theorem
Lecture 21 Time Domain Introduction
Lecture 22 Zero and First Order Response
Lecture 23 First order Response Parameters
Lecture 24 Step Response of Second Order
Lecture 25 Second Order Response Impulse
Lecture 26 2nd Order System Behaiviour wrt Damping Ratio
Lecture 27 Time Domain Parameters of Unit Step Underdamped
Lecture 28 Steady State Error Analysis
Lecture 29 Dominant Poles and Higher Order Systems
Section 6: Root Locus
Lecture 30 Introduction
Lecture 31 Rules
Lecture 32 Example
Lecture 33 RL Example 2
Lecture 34 Gain Margin in Root Locus - Control Systems
Lecture 35 Complementary Root Locus
Section 7: Frequency Response of Control Systems
Lecture 36 Introduction
Lecture 37 Magnitude Response of 2nd Order System
Lecture 38 Phase Response of 2nd Order System
Lecture 39 Resonance Frequency - Frequency Domain Parameters
Lecture 40 Resonance Peak - frequency Domain Parameters
Lecture 41 Bandwidth - Frequency Domain Parameters
Lecture 42 Example on Frequency Response
Lecture 43 Relation Between Time Domain and Frequency domain Parameters
Lecture 44 Example Relation Between FR and TR
Lecture 45 Introduction to Graphical methods of Frequency Response
Lecture 46 Intro to Polar Plots
Lecture 47 Example 1 (Polar Plots)
Lecture 48 Example 2 (Polar Plots)
Lecture 49 Example 3 (Polar Plots)
Lecture 50 Conclusion (Examples)
Lecture 51 More Examples (1)
Lecture 52 More Examples (2)
Lecture 53 Addition of Zeroes
Lecture 54 More Example (3)
Lecture 55 Wgc and Wpc
Lecture 56 Calculation of Wpc and Wgc
Lecture 57 Gain Margin (GM) and Phase Margin (PM)
Lecture 58 GM and PM Example
Lecture 59 Stability (Polar Plots)
Lecture 60 Full Example (Polar Plot)
Lecture 61 GM and PM of 2nd Order System
Lecture 62 Gain Phase Plot
Lecture 63 Gain Phase Plot Example
Lecture 64 Introduction to Nyquist Plots
Lecture 65 Mapping in Nyquist Plots
Lecture 66 Nyquist Plot (Example 1)
Lecture 67 Nyquist Plot (Example 2)
Lecture 68 Nyquist Plot (Example 3)
Lecture 69 Nyquist (Example 4)
Lecture 70 Nyquist (Example 4) with Different Contour
Lecture 71 Nyquist Stability Criteria
Lecture 72 Examples with Nyquist Criteria
Lecture 73 Example of No Infinite Circle
Lecture 74 Intro Bode Plots
Lecture 75 Building Blocks of Bode Plots
Lecture 76 Building Blocks of Bode Plots (Part 2)
Lecture 77 Bode Plot (Example 1)
Lecture 78 Bode Plot (Example 2)
Lecture 79 Construct Transfer Function from Bode Plot
Lecture 80 GM PM in Bode Plots
Lecture 81 Attention Attention!
Lecture 82 Static Error Coefficients from Bode Plots
Lecture 83 Examples of GM and PM in Bode Plots
Lecture 84 Example Bode Plot
Section 8: Controller And Compensators
Lecture 85 Compensator Intro
Lecture 86 Lead Compensator
Lecture 87 Lag Compensator
Lecture 88 Lead Compensator (Mag and Phase)
Lecture 89 Lag Compensator (Mag and Phase)
Lecture 90 Lag-Lead-Lead-Lag Compensator (Mag and Phase)
Lecture 91 Comparison Lead Lag
Lecture 92 Compensator Questions
Lecture 93 Controller Intro
Lecture 94 Proportional Controller
Lecture 95 Reset Controller
Lecture 96 Derivative Controller
Lecture 97 PI Controller
Lecture 98 Controller Question
Lecture 99 PD Controller
Lecture 100 PID Controller
Lecture 101 Controller Question 2
Section 9: State Variable Analysis
Lecture 102 Intro
Lecture 103 A Note Point!
Lecture 104 Link Between Transfer Function and State Variable Representation
Lecture 105 Example of a Network Circuit
Lecture 106 Transfer Function from State Equation
Lecture 107 Stability from Transfer Function
Lecture 108 Solution of State Equations
Lecture 109 [CORRECTION] Solution of State Equations
Lecture 110 Controllability and Observability
Section 10: Last Section
Lecture 111 Thank You Note!
Electronics and Telecommunication, Electrical, Instrumentation Engineering Students.
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