ELECTRICAL-ELECTRONICS ENGINEERING (MASTER) (WITH THESIS) (ENGLISH)
Qualification Awarded	Program Süresi	Toplam Kredi (AKTS)	Öğretim Şekli	Yeterliliğin Düzeyi ve Öğrenme Alanı
	2	120	FULL TIME	TYÇ, TR-NQF-HE, EQF-LLL, ISCED (2011):Level 7 QF-EHEA:Second Cycle TR-NQF-HE, ISCED (1997-2013): 52

Ders Genel Tanıtım Bilgileri

Course Code:

3026002004

Ders İsmi:

Numerical Methods for Electromagnetic

Ders Yarıyılı:

Fall

Ders Kredileri:

Theoretical	Practical	Labs	Credit	ECTS
3	0	0	3	6

Language of instruction:

Ders Koşulu:

Ders İş Deneyimini Gerektiriyor mu?:

Other Recommended Topics for the Course:

Type of course:

Department Elective

Course Level:

Master

TR-NQF-HE:7. Master`s Degree

QF-EHEA:Second Cycle

EQF-LLL:7. Master`s Degree

Mode of Delivery:

Face to face

Course Coordinator :

Prof. Dr. Çağatay ULUIŞIK

Course Lecturer(s):

Course Assistants:

Dersin Amaç ve İçeriği

Course Objectives:	Numerical solution of matrix equations and matrix eigenvalue problems. Method of moments. Finite difference and finite element methods. Variational methods. Spectral domain approach. The use of above methods in the solution of various antenna and scattering problems, and in the analysis of passive microwave components.
Course Content:	Numerical solution of matrix equations and matrix eigenvalue problems. Method of moments. Finite difference and finite element methods. Variational methods. Spectral domain approach. The use of above methods in the solution of various antenna and scattering problems, and in the analysis of passive microwave components.

Learning Outcomes

The students who have succeeded in this course;

Learning Outcomes

1 - Knowledge
Theoretical - Conceptual
1) Solve numerically matrix equations and matrix eigenvalue problems.
2) Use Finite-difference and Finite-element (FEM) methods
3) Use Method of Moments (MoM).
4) Use FEM, MoM and Finite-difference methods in the solution of various antenna and scattering problems, and in the analysis of passive microwave components.
2 - Skills
Cognitive - Practical
3 - Competences
Communication and Social Competence
Learning Competence
Field Specific Competence
Competence to Work Independently and Take Responsibility

Ders Akış Planı

Week	Subject	Related Preparation
1)	Review of Electromagnetic Theory	R. F. Harrington, “Field Computation by Moment Methods”, The Macmillan Co., NY 1968. M. V. K., Chari, S., J., Salon, "Numerical Methods in Electromagnetism", Elsevier Science, 2000. M. N. O., Sadiku, "Numerical techniques in electromagnetics", CRC Press, 2001.
2)	Solutions of Wave Equations	R. F. Harrington, “Field Computation by Moment Methods”, The Macmillan Co., NY 1968. M. V. K., Chari, S., J., Salon, "Numerical Methods in Electromagnetism", Elsevier Science, 2000. M. N. O., Sadiku, "Numerical techniques in electromagnetics", CRC Press, 2001.
3)	Classification of EM Problems	R. F. Harrington, “Field Computation by Moment Methods”, The Macmillan Co., NY 1968. M. V. K., Chari, S., J., Salon, "Numerical Methods in Electromagnetism", Elsevier Science, 2000. M. N. O., Sadiku, "Numerical techniques in electromagnetics", CRC Press, 2001.
4)	Fullwave CEM Methods	R. F. Harrington, “Field Computation by Moment Methods”, The Macmillan Co., NY 1968. M. V. K., Chari, S., J., Salon, "Numerical Methods in Electromagnetism", Elsevier Science, 2000. M. N. O., Sadiku, "Numerical techniques in electromagnetics", CRC Press, 2001.
5)	Finite difference methods	R. F. Harrington, “Field Computation by Moment Methods”, The Macmillan Co., NY 1968. M. V. K., Chari, S., J., Salon, "Numerical Methods in Electromagnetism", Elsevier Science, 2000. M. N. O., Sadiku, "Numerical techniques in electromagnetics", CRC Press, 2001.
6)	Finite difference time domain (FDTD) method	R. F. Harrington, “Field Computation by Moment Methods”, The Macmillan Co., NY 1968. M. V. K., Chari, S., J., Salon, "Numerical Methods in Electromagnetism", Elsevier Science, 2000. M. N. O., Sadiku, "Numerical techniques in electromagnetics", CRC Press, 2001.
7)	FDTD algorithm applications for Maxwell's Equations	R. F. Harrington, “Field Computation by Moment Methods”, The Macmillan Co., NY 1968. M. V. K., Chari, S., J., Salon, "Numerical Methods in Electromagnetism", Elsevier Science, 2000. M. N. O., Sadiku, "Numerical techniques in electromagnetics", CRC Press, 2001.
8)	Midterm exam
9)	Method of moments (Part I)	R. F. Harrington, “Field Computation by Moment Methods”, The Macmillan Co., NY 1968. M. V. K., Chari, S., J., Salon, "Numerical Methods in Electromagnetism", Elsevier Science, 2000. M. N. O., Sadiku, "Numerical techniques in electromagnetics", CRC Press, 2001.
10)	Method of moments (Part II)	R. F. Harrington, “Field Computation by Moment Methods”, The Macmillan Co., NY 1968. M. V. K., Chari, S., J., Salon, "Numerical Methods in Electromagnetism", Elsevier Science, 2000. M. N. O., Sadiku, "Numerical techniques in electromagnetics", CRC Press, 2001.
11)	Variational methods	R. F. Harrington, “Field Computation by Moment Methods”, The Macmillan Co., NY 1968. M. V. K., Chari, S., J., Salon, "Numerical Methods in Electromagnetism", Elsevier Science, 2000. M. N. O., Sadiku, "Numerical techniques in electromagnetics", CRC Press, 2001.
12)	Finite element methods	R. F. Harrington, “Field Computation by Moment Methods”, The Macmillan Co., NY 1968. M. V. K., Chari, S., J., Salon, "Numerical Methods in Electromagnetism", Elsevier Science, 2000. M. N. O., Sadiku, "Numerical techniques in electromagnetics", CRC Press, 2001.
13)	The use of above methods in the solution of various antenna and scattering problems	R. F. Harrington, “Field Computation by Moment Methods”, The Macmillan Co., NY 1968. M. V. K., Chari, S., J., Salon, "Numerical Methods in Electromagnetism", Elsevier Science, 2000. M. N. O., Sadiku, "Numerical techniques in electromagnetics", CRC Press, 2001.
14)	The use of above methods in the analysis of passive microwave components	R. F. Harrington, “Field Computation by Moment Methods”, The Macmillan Co., NY 1968. M. V. K., Chari, S., J., Salon, "Numerical Methods in Electromagnetism", Elsevier Science, 2000. M. N. O., Sadiku, "Numerical techniques in electromagnetics", CRC Press, 2001.
15)	Final exam

Sources

Course Notes / Textbooks:	R. F. Harrington, “Field Computation by Moment Methods”, The Macmillan Co., NY 1968. M. V. K., Chari, S., J., Salon, "Numerical Methods in Electromagnetism", Elsevier Science, 2000. M. N. O., Sadiku, "Numerical techniques in electromagnetics", CRC Press, 2001.
References:	R. F. Harrington, “Field Computation by Moment Methods”, The Macmillan Co., NY 1968. M. V. K., Chari, S., J., Salon, "Numerical Methods in Electromagnetism", Elsevier Science, 2000. M. N. O., Sadiku, "Numerical techniques in electromagnetics", CRC Press, 2001.

Ders - Program Öğrenme Kazanım İlişkisi

Ders Öğrenme Kazanımları	1	2	3	4
Program Outcomes
1) Through scientific research in the field of Electrical-Electronics Engineering, they expand and deepen their knowledge, evaluate, interpret, and apply the information.
2) They have comprehensive knowledge of the current techniques and methods applied in Electrical-Electronics Engineering, as well as their limitations.
3) Using uncertain, limited, or incomplete data, they complement and apply knowledge through scientific methods; they can integrate information from different disciplines.
4) They are aware of new and emerging applications in Electrical-Electronics Engineering, and when necessary, they investigate and learn about them.
5) They define and formulate Electrical-Electronics Engineering problems, develop methods to solve them, and apply innovative approaches in the solutions.
6) They develop new and/or original ideas and methods; design complex systems or processes and develop innovative/alternative solutions in their designs.
7) They design and apply theoretical, experimental, and modeling-based research; they analyze and solve complex problems encountered during this process.
8) They can work effectively in both interdisciplinary and multidisciplinary teams, lead such teams, and develop solution approaches in complex situations; they can work independently and take responsibility.
9) They communicate effectively in both spoken and written forms using a foreign language at least at the B2 General Level of the European Language Portfolio.
10) They communicate the processes and results of their work in a systematic and clear manner, either in writing or verbally, in national and international contexts, both within and outside their field.
11) They are aware of the social, environmental, health, safety and legal aspects of Electrical and Electronics Engineering applications, project management and business life practices and are aware of the constraints these impose on engineering applications.
12) They observe social, scientific and ethical values in the stages of collecting, interpreting and announcing the data and in all professional activities.

Ders - Öğrenme Kazanımı İlişkisi

No Effect	1 Lowest	2 Low	3 Average	4 High	5 Highest

	Program Outcomes	Level of Contribution
1)	Through scientific research in the field of Electrical-Electronics Engineering, they expand and deepen their knowledge, evaluate, interpret, and apply the information.
2)	They have comprehensive knowledge of the current techniques and methods applied in Electrical-Electronics Engineering, as well as their limitations.
3)	Using uncertain, limited, or incomplete data, they complement and apply knowledge through scientific methods; they can integrate information from different disciplines.
4)	They are aware of new and emerging applications in Electrical-Electronics Engineering, and when necessary, they investigate and learn about them.
5)	They define and formulate Electrical-Electronics Engineering problems, develop methods to solve them, and apply innovative approaches in the solutions.
6)	They develop new and/or original ideas and methods; design complex systems or processes and develop innovative/alternative solutions in their designs.
7)	They design and apply theoretical, experimental, and modeling-based research; they analyze and solve complex problems encountered during this process.
8)	They can work effectively in both interdisciplinary and multidisciplinary teams, lead such teams, and develop solution approaches in complex situations; they can work independently and take responsibility.
9)	They communicate effectively in both spoken and written forms using a foreign language at least at the B2 General Level of the European Language Portfolio.
10)	They communicate the processes and results of their work in a systematic and clear manner, either in writing or verbally, in national and international contexts, both within and outside their field.
11)	They are aware of the social, environmental, health, safety and legal aspects of Electrical and Electronics Engineering applications, project management and business life practices and are aware of the constraints these impose on engineering applications.
12)	They observe social, scientific and ethical values in the stages of collecting, interpreting and announcing the data and in all professional activities.

Öğrenme Etkinliği ve Öğretme Yöntemleri

Proje Hazırlama

Ölçme ve Değerlendirme Yöntemleri ve Kriterleri

Yazılı Sınav (Açık uçlu sorular, çoktan seçmeli, doğru yanlış, eşleştirme, boşluk doldurma, sıralama)
Bireysel Proje

Assessment & Grading

Semester Requirements	Number of Activities	Level of Contribution
Project	1	% 30
Midterms	1	% 30
Semester Final Exam	1	% 40
total		% 100
PERCENTAGE OF SEMESTER WORK		% 60
PERCENTAGE OF FINAL WORK		% 40
total		% 100

İş Yükü ve AKTS Kredisi Hesaplaması

Activities	Number of Activities	Duration (Hours)	Workload
Course Hours	14	3	42
Study Hours Out of Class	14	10	140
Midterms	1	2	2
Final	1	2	2
Total Workload			186