Course Information

Semester	Course Unit Code	Course Unit Title	T+P+L	Credit	Number of ECTS Credits	Last Updated Date
7	EEE 456	INTRODUCTION TO DIGITAL CONTROL SYSTEMS	3+0+0	3	5	31.03.2026

Course Details

Language of Instruction	English
Level of Course Unit	Bachelor's Degree
Department / Program	ELECTRICAL-ELECTRONICS E.
Type of Program	Formal Education
Type of Course Unit	Elective
Course Delivery Method	Face To Face
Objectives of the Course	Modeling discrete-time systems Analyzing and designing discrete-time systems Understanding the feedback characteristics and concepts of discrete-time systems Performing stability analysis in discrete-time systems Analyzing digital control systems Designing digital control systems
Course Content	Review of discrete and analog system representations, z-transform sampling and reconstruction. Open loop and closed loop discrete time control systems. System timeresponse characteristics. Stability. Digital controller design.
Course Methods and Techniques	In person lectures and homeworks
Prerequisites and co-requisities	( EEE 352 )
Course Coordinator	Prof.Dr. Tolgay Kara
Name of Lecturers	Associate Prof.Dr. TOLGAY KARA
Assistants	None
Work Placement(s)	No

Recommended or Required Reading

Resources	Phillips, Charles L., and H. Troy Nagle. Digital control system analysis and design. Prentice Hall Press, 2007.
Course Notes	Provided in lectures

Course Category

Engineering	%50
Field	%50

Planned Learning Activities and Teaching Methods

Activities are given in detail in the section of "Assessment Methods and Criteria" and "Workload Calculation"

Assessment Methods and Criteria

ECTS Allocated Based on Student Workload

Activities	Quantity	Duration	Total Work Load
Course Duration	14	3	42
Hours for off-the-c.r.stud	14	4	56
Assignments	7	3	21
Mid-terms	2	8	16
Final examination	1	16	16
Total Work Load			Number of ECTS Credits 5 151

Course Learning Outcomes: Upon the successful completion of this course, students will be able to:

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1	Students are expected to have expertise in modeling, analyzing, and designing discrete-time systems.
2	Students are expected to understand the feedback features and concepts of discrete-time systems.
3	Students are expected to understand the stability concepts of discrete-time systems.
4	They are expected to be proficient in analyzing and designing digital control systems.

Weekly Detailed Course Contents

Week	Topics	Study Materials	Materials
1	1. Introduction to digital control systems
2	2. z-transform
3	3. Discrete time system models
4	4. Analysis of discrete-time control systems in the z-domain
5	5. Stability analysis in the z-domain
6	6. Analysis of transient and steady state in discrete-time
7	7. Analysis of digital control systems via root locus method
8	8. Design of digital control systems via root locus method
9	9. Analysis of digital control systems via frequency response method
10	10. Design of digital control systems via frequency response method
11	11. Analysis of digital control systems in state space
12	12. Design of digital control systems in state space
13	13. Practical issues in digital control systems
14	14. Concluding remarks

Contribution of Learning Outcomes to Programme Outcomes

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https://obs.gantep.edu.tr/oibs/bologna/progCourseDetails.aspx?curCourse=337789&lang=en