NCHU Course Outline

Course Name	(中) 自動控制(2211)
	(Eng.) Automatic Control
Offering Dept	Department of Bio-industrial Mechatronics Engineering
Course Type	Elective	Credits	3	Teacher	CHU, WEN-LIN
Department	Department of Bio-industrial Mechatronics Engineering/Undergraduate	Language	English	Semester	2025-SPRING
Course Description	First of all, we will introduce what is a control system, and then start to introduce the development history and concept of the control system, define the control system and explain the importance of the control system for this course.
Prerequisites				self-directed learning in the course	N

Relevance of Course Objectives and Core Learning Outcomes(%)			Teaching and Assessment Methods for Course Objectives
Course Objectives	Competency Indicators	Ratio(%)	Teaching Methods	Assessment Methods
In this course will introduce mathematics used in control systems, control system components, draw system block diagrams and signal flow diagrams. Understand the topics of control topics such as transfer function, system stability, time domain analysis, root locus, etc. Using Matlab’s control system toolbox software to for practical operation, so that students can better understand how to apply the relevant knowledge of automatic control system.			Lecturing	Attendance Assignment Quiz
Course Content and Homework/Schedule/Tests Schedule
Week Course Content Week 1 Course Introduction Teaching Methods Introduction to Control Systems Week 2 1. Introduction to control system -Control System Components -Control System Classification -History and Development of Control Theory -Implementation of Controller Week 3 2. Mathematical Basis of Control System -Differential Equation -Complex Numbers and Functions of Complex Variables -Laplace Transform Week 4 2. Mathematical basis of control system -Inverse Laplace Transform -Application of Laplace Transformation Week 5 3. System description of classical control - Systematic Classification - Transfer Function -Block Diagram of The Control System - Signal flow chart Week 6 3. System description of classical control - Mason’s Rule -Signal Flow Chart of State Equation Week 7 Compensatory leave Week 8 3. System Description of Classical Control - Mathematical Models of Mechanical Systems - Mathematical Models of Circuit Systems - Mathematical Models of Electromechanical Systems - Mathematical model of the converter Week 9 Midterm Exam Week 10 4. Stability - Routh-Hurwitz Criterion - Routh-Hurwitz Criterion- Special Case - Routh-Hurwitz Criterion- Additional Examplle Week 11 5. Steady-state Errors - Steady-state Errors for Unity Feedback System Week 12 5. Steady-state Errors - Steady Errors Constants and System Type - Steady-state Errors Specifications Week 13 5. Steady-state Errors - Steady-stats Error for Disturbance - Sensitivity Week 14 6. Root Locus Techniques - Defining the Root Locus - Properties of the Root Locus Week 15 6. Root Locus Techniques - Sketching the Root Locus 7. Frequncy Response Techniques - Introduction to the Nyquist Criterion Week 16 Self-learning (Browse industry and academic related multimedia materials) Week 17 Self-learning (Browse industry and academic related multimedia materials) Week 18 Final Exam
Evaluation
Attendance: 10% Regular grade:20% Midterm grade:35% Final exam grade:35%
Textbook & other References
Bibliography: Control Systems Engineering, 8/e (IE-Paperback) Publisher: Wiley Publication date: 2019-02-01
Teaching Aids & Teacher's Website
Office Hours
Sustainable Development Goals, SDGs(Link URL)
08.Decent Work and Economic Growth   09.Industry, Innovation and Infrastructure   12.Responsible Consumption include experience courses：N

Please respect the intellectual property rights and use the materials legally.Please respect gender equality.
Update Date, year/month/day：None	Printed Date, year/month/day：2025 / 11 / 10
The second-hand book website：http://www.myub.com.tw/