Course Information

Semester	Course Unit Code	Course Unit Title	T+P+L	Credit	Number of ECTS Credits
6	EEM338	Power Electronics	3+0+0	3	6

Course Details

Language of Instruction	Turkish
Level of Course Unit	Bachelor's Degree
Department / Program	Electrical-Electronics Engineering
Mode of Delivery	Face to Face
Type of Course Unit	Compulsory
Objectives of the Course	The objective of this course is to investigate the operation of the components used in power electronics and to design application specific circuits using those components.
Course Content	Power Computation methods; Semiconductor Power Switches; AC-DC Converters; Free wheeling diodes; Commutation; Regulators; Linear DC-DC Converters; Non isolated Switching mode DC-DC converters; Transformator Modeling; İsolated DC-DC Converters
Course Methods and Techniques
Prerequisites and co-requisities	None
Course Coordinator	Prof.Dr. Uğur ÇELTEKLİGİL
Name of Lecturers	Prof.Dr. Uğur ÇELTEKLİGİL
Assistants	None
Work Placement(s)	No

Recommended or Required Reading

Resources	D. W. Hart, Power Electronics, McGraw-Hill, 2011 N. Mohan, T.M. Undeland, and W.P. Robbins, Power Electronics: Converters, applications, and design, John Wiley and Sons Inc., 2007
	Lecture

Course Category

Mathematics and Basic Sciences	%10
Engineering	%50
Engineering Design	%40

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	3	42
Assignments	2	15	30
Mid-terms	1	20	20
Final examination	1	25	25
Total Work Load			Number of ECTS Credits 5 159

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

No	Learning Outcomes
1	The students will learn power calculation techniques.
2	The students will learn power electronic circuit components.
3	The students will analyse power electronic circuits.
4	The students will analyse and design AC-DC power converters.
5	The students will analyse and design DC-DC power converters.

Weekly Detailed Course Contents

Week	Topics	Study Materials	Materials
1	Power Computation Methods (Inductor, Capacitor, Energy Recovery)
2	Power Computation Methods (Effective and Average Value, Apparent Power and Power Factor)
3	Power Computation for AC circuits with sinusoidal source
4	Power Computation for non-sinusoidal periodic waveforms
5	Power Computation for non-linear load with sinusoidal source
6	AC-DC Converter design
7	Free wheeling diode; Commutation
8	Regulator Design
9	Midterm 1
10	Linear DC-DC Converters; Non-isolated Swithcing DC-DC Converters (Buck Converter)
11	Non-isolated Swithcing DC-DC Converters (Boost Converter, Buck-Boost Converter)
12	Magnetism Theory and Transformator Modeling
13	Isolated DC-DC Converter Design (Flyback Converter)
14	Isolated DC-DC Converter Design (Flyback Converter)

Contribution of Learning Outcomes to Programme Outcomes

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