Control Systems : Theory And Applications
Control Systems : Theory And Applications
Published 7/2025
MP4 | Video: h264, 1920x1080 | Audio: AAC, 44.1 KHz
Language: English | Size: 363.04 MB | Duration: 1h 49m
Published 7/2025
MP4 | Video: h264, 1920x1080 | Audio: AAC, 44.1 KHz
Language: English | Size: 363.04 MB | Duration: 1h 49m
Mathematical Modeling, System Analysis, and Feedback Control Techniques
What you'll learn
Understand and apply mathematical modeling techniques for mechanical and electrical systems.
Perform block diagram reduction and analyze systems using signal flow graphs.
Analyze transient and steady-state responses and compute system errors using standard performance indices.
Determine the stability of linear time-invariant systems using Routh-Hurwitz criterion and root locus method.
Apply state variable methods for modeling, analysis, and design of control systems.
Requirements
Mathematics Foundations-Laplace Transforms
Description
Control Systems: Theory and Applications is a foundational course designed to provide students with a comprehensive understanding of the principles and techniques used in the modeling, analysis, and design of control systems in engineering. It bridges theoretical concepts with real-world implementation, laying the groundwork for advanced study or industrial applications in automation, robotics, mechatronics, and electrical systems.The course introduces both classical control strategies—such as transfer function-based analysis, root locus, Bode plots, and Nyquist plots—and modern control approaches, including state-space modeling. Core topics include system modeling using differential equations, Laplace transforms, block diagram reduction, time-domain and frequency-domain responses, feedback control, stability analysis, and controller design (PI, PD and PID controllers) and compensator design.In addition to strong theoretical foundations, the course places emphasis on practical insights, demonstrating how control systems are utilized in real-life applications across aerospace, automotive systems, power generation, industrial automation, and biomedical devices.Students will engage with analytical methods as well as simulation tools such as MATLAB/Simulink, enhancing their ability to visualize and test system behavior. By the end of the course, learners will be proficient in designing and evaluating control strategies that meet performance, stability, and robustness requirements for a variety of dynamic systems and applications.
Overview
Section 1: Introduction
Lecture 1 Introduction to Control Systems and Their Types
Lecture 2 Need for Mathematical Modeling and Idealized Elements in Translational System
Lecture 3 Determining the Transfer Function of Mechanical Translational Systems- Problem 1
Lecture 4 Determining the Transfer Function of Mechanical Translational Systems- Problem 2
Lecture 5 Key Elements of Mechanical Rotational Systems
Lecture 6 Determining the Transfer Function for Mechanical Rotational Systems-Problem
Lecture 7 Analogous Systems
Lecture 8 Conversion of Mechanical Systems to Electrical Systems-f–V and f–I Analogies
Lecture 9 Block Diagram Reduction Rules
Lecture 10 Evaluation of Transfer Functions Using Block Diagram Reduction Techniques
Lecture 11 Introduction to Signal Flow Graphs
Lecture 12 Evaluation of Transfer Functions Using Signal Flow Graphs
Undergraduate Engineering Students Particularly from Electrical, Electronics, Instrumentation branches.