• Basic information
• Learning outcomes
• Contents
• Assessment
• Workload

Learning outcomes

Upon successful completion of this course, students will be able to:

1. Comprehend basic circuit theory

   Contribution to Program Outcomes

   1. Obtain basic knowledge of Electronics Engineering.
   2. Formulate and solve engineering problems

   Method of assessment

   1. Written exam
   2. Term paper
2. Recognize fundamental concepts of AC circuits

   Contribution to Program Outcomes

   1. Obtain basic knowledge of Electronics Engineering.
   2. Apply the mathematical, scientific and engineering knowledge for real life problems
   3. Formulate and solve engineering problems

   Method of assessment

   1. Written exam
   2. Term paper
3. Develop the ability to solve ac circuits

   Contribution to Program Outcomes

   1. Obtain basic knowledge of Electronics Engineering.
   2. Design and conduct experiments, as well as analyze and interpret data
   3. Formulate and solve engineering problems

   Method of assessment

   1. Written exam

Contents
Week 1:	Sinusoidal Steady-State Analysis.
Week 2:	Phasor Concepts, Passive Elements in the Frequency Domain, Ideal Transformer.
Week 3:	Source Transformation, Thevenin and Norton Theorems in the Frequency Domain.
Week 4:	Sinusoidal Steady-State Power Calculations. Complex Power, Maximum Power Transfer.
Week 5:	Three Phase Circuits.
Week 6:	Power Calculations in the Three Phase Circuits.
Week 7:	The Laplace Transform Fundamentals, The Step Function, The Impulse Function.
Week 8:	Circuit Analysis using Laplace Transform, Circuit Elements in the s domain, Applications.
Week 9:	Circuit Analysis using Laplace Transform, Circuit Analysis in the s domain, Transfer Function Concept.
Week 10:	Project Presentations.
Week 11:	Passive Filter Circuits.
Week 12:	Active Filter Circuits.
Week 13:	Fourier Series and Fourier Transform.
Week 14:	Two-Port Networks.
Week 15*:	.
Week 16*:	.
Textbooks and materials:	Electric Circuits, Nilsson Riedel, Pearson, 10th Edition, 2015.
Recommended readings:	1) Introduction to Electric Circuits, R. C. Dorf, J. A. Svoboda, Wiley, 9. Baskı, ISBN: 0-471-19246-5 . 2) Fundamentals of Electric Circuits, C. K. Alexander, M. N. O. Sadıku, McGraw Hill, 2000. 3) Electrical Engineering: Principles and Applications, A. R. Hambley, Prentice Hall, 1997. 4) An Introduction to Circuit Analysis: A Systems Approach, D. E. Scott, McGraw Hill, 1987. 5) Devre Teorisine Giriş, Fehmi Uçar, Birsen Yayınevi, 1982. 6) Devre Analizi Dersleri, Kısım I, Prof. Dr. Yılmaz Tokad, Uludağ Üniversitesi Basımevi, 1981. 7) Introduction to PSpice: Supplement to Electric Circuits, J. W. Nilsson, S. A. Riedel, 4. Baskı, Literatür, 1994. 8) Elektrik-Elektronik Mühendisliğinin Temelleri - Alternatif Akım Devreleri Cilt2, Uğur Arifoğlu, Alfa Basım Yayım Dağıtım, Mart 2000, ISBN: 975-316-403-3.
	* Between 15th and 16th weeks is there a free week for students to prepare for final exam.

Assessment
Method of assessment	Week number	Weight (%)
Mid-terms:	0	0
Other in-term studies:		0
Project:	10	40
Homework:	0	0
Quiz:		0
Final exam:	16	60
	Total weight:	(%)

Workload
Activity	Duration (Hours per week)	Total number of weeks	Total hours in term
Courses (Face-to-face teaching):	3	14
Own studies outside class:	1	14
Practice, Recitation:	1	14
Homework:	0	0
Term project:	0	0
Term project presentation:	0	0
Quiz:	0	0
Own study for mid-term exam:	8	1
Mid-term:	6	1
Personal studies for final exam:	14	1
Final exam:	2	1
		Total workload:
		Total ECTS credits:	*
	* ECTS credit is calculated by dividing total workload by 25. (1 ECTS = 25 work hours)