Course Information

Semester	Course Unit Code	Course Unit Title	T+P+L	Credit	Number of ECTS Credits
4	EEE 202	CIRCUIT THEORY-II	4+0+2	5	7

Course Details

Language of Instruction	English
Level of Course Unit	Bachelor's Degree
Department / Program	ELECTRICAL-ELECTRONICS E.
Mode of Delivery	Face to Face
Type of Course Unit	Compulsory
Objectives of the Course	The purpose of the course is to teach students the analysis, design, and power calculations (complex, reactive, real, apparent powers) of circuits powered by alternating current, the conditions for maximum power delivery, the calculation of circuit parameters in the phasor and Laplace domains, the design of passive and active filters, and their analysis using Fourier series approximation.
Course Content	1)The sinusoidal source • The sinusoidal response 2)The phasor •Passive circuit elements in the phasor domain , Kirchhoff’s Laws in the frequency domain 3) Series, paralel and Delta-Y simplification • Source transformations and Thevenin-Norton Equivalent Circuits 4) The Node Voltage Method • The Mesh Current Method 5) Instantaneous power • Average and reactive power • rms value and power calculations • Complex power •Power calculations • Maximum power transfer 6) Review of self inductance • The concept of mutual inductance • The polarity of the mutually induced voltages • Energy calculations 7) The linear transformer • The ideal transformer 8) Circuit elements in s-domain • Circuit analysis in the s-domain • The transfer function • The transfer function in partial fraction expension 9) The transfer function and convolution integral • The transfer function and steady-state sinusoidal response 10) Low pass filters • High pass filters • Band pass filters • Bode diagram 11) Fourier Series Analysis • Fourier coefficients • Effect of symmetry • Trigonometric form of Fourier Series 12) Average power calculations with periodic functions • rms value of a periodic function • The exponential form of Fourier Series 13) Derivation of the Fourier Transform • Circuit applications
Course Methods and Techniques	Face to face
Prerequisites and co-requisities	( EEE 201 )
Course Coordinator	None
Name of Lecturers	Prof.Dr. Ergun Erçelebi https://eee.gantep.edu.tr/pages.php?url=akademik-personel-2 ercelebi@gantep.edu.tr Prof.Dr. Arif Nacaroğlu https://eee.gantep.edu.tr/pages.php?url=akademik-personel-2 arif1@gantep.edu.tr
Assistants	None
Work Placement(s)	No

Recommended or Required Reading

Resources	Fundamentals of Electric Circuits, Charles K. Alexander, Mathew N.O. Sadiku. Electric Circuits, Nilsson Riedel. Circuit Analysis-Theory and Practice, Robbins.

Course Category

Mathematics and Basic Sciences	%20
Engineering	%60
Engineering Design	%20

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

In-Term Studies	Quantity	Percentage
Mid-terms	2	% 40
Practice	10	% 20
Final examination	1	% 40
Total	13	% 100

ECTS Allocated Based on Student Workload

Activities	Quantity	Duration	Total Work Load
Course Duration	12	4	48
Hours for off-the-c.r.stud	12	4	48
Mid-terms	2	10	20
Practice	5	5	25
Laboratory	10	5	50
Final examination	1	10	10
Total Work Load			Number of ECTS Credits 7 201

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

No	Learning Outcomes
1	Analysis of linear-time invariant dynamic circuits, and simple linear time-varying and nonlinear dynamic circuits,
2	Analysis of phasor domain circuits, power calculations
3	Concept of maximum power transfer and determination conditions for maximum power transfer
4	Analysis of mutually coupled circuits
5	Analysis of s-domain circuits.
6	Concept of transfer function and to calculate the output of a system (electrical circuit) using convolution integral
7	Design passive and active filters.
8	Analysis of circuits powered by non-sinusoidal periodic signals using Fourier series approximation

Weekly Detailed Course Contents

Week	Topics	Study Materials	Materials
1	Sinüzoidal kaynak • Sinüzoidal tepki
2	The phasor • Passive circuit elements in the phasor domain , Kirchhoff’s Laws in the frequency domain
3	Series, paralel and Delta-Y simplification • Source transformations and Thevenin-Norton Equivalent Circuits
4	• The Node Voltage Method • The Mesh Current Method
5	• Instantaneous power • Average and reactive power • rms value and power calculations • Complex power •Power calculations • Maximum power transfer
6	• Review of self inductance • The concept of mutual inductance • The polarity of the mutually induced voltages • Energy calculations
7	1st Mid
8	• The linear transformer • The ideal transformer
9	• Circuit elements in s-domain • Circuit analysis in the s-domain • The transfer function • The transfer function in partial fraction expension
10	The transfer function and convolution integral • The transfer function and steady-state sinusoidal response
11	• Low pass filters • High pass filters • Band pass filters • Bode diagram
12	• Average power calculations with periodic functions • rms value of a periodic function • The exponential form of Fourier Series
13	• Derivation of the Fourier Transform • Circuit applications
14	2nd Mid

Contribution of Learning Outcomes to Programme Outcomes

	P1	P2	P3	P4
All			4	4
C1	4	4
C2	4	4
C3	4	4
C4	4	4
C5	4	4
C6	4	4
C7	4	4
C8	4	4

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https://obs.gantep.edu.tr/oibs/bologna/progCourseDetails.aspx?curCourse=337725&lang=en