1661 Electrical and Electronics Engineering PhD

GENERAL INFORMATION
The Electrical and Electronics Engineering program is constituted of seven divisions called Electronics, Circuits and Systems, Electromagnetic Fields and Microwave Technique, Communication, Control, Electrical Machines and Electrical Institutions. In this program, in various specialized options, sufficient number of both theoretical and application-specific courses are offered by academic members of Electrical and Electronics Engineering Department for graduate students. In the 2011-2012 education year the Electrical and Electronics Engineering program is active with 1 Professor, 5 Associate Professors, 8 Assistant Professors, 1 expert and 3 research assistants.

Objective
The purpose of the Electrical and Electronics Engineering graduate program is to educate students that are expert at one of the fields such as Electronics, Circuits and Systems, Electromagnetic Fields and Microwave Technique, Communication, Control, Electrical Machines and Electrical Institutions.


Admission Requirements
First cycle degree, acceptable score on centralized graduate entrance exam, placement through local oral/written exam and certificate of English proficiency

Graduation Requirements
A student must complete the required course load (21 PAU credits) with a CGPA of at least 3.30/4.00; and additionally complete two courses for educational evaluation and one course for scientific research techniques; present two research seminars, pass the qualifier exam and successfully prepare and defend a PhD thesis.

Career Opportunties
Graduates who succesfully completed doctorate degree may apply to both in the same or related disciplines in higher education institutions at home or abroad to get a position in academic staff or to governmental R&D centres to get expert position.

Qualification Awarded
Electrical And Electronics Engineering Phd

Level of Qualification
Third Cycle (Doctorate Degree)

Recognition of Prior Learning
A successful student who has completed at least one semester in another institution / department of the university or another post-graduate program of another higher education institution may be admitted to the post-graduate programs by horizontal transfer. The conditions for acceptance by horizontal transfer are determined by the Senate.

Qualification Requirements and Regulations
A student must complete the required course load (21 PAU credits) with a CGPA of at least 3.30/4.00; and additionally complete two courses for educational evaluation and one course for scientific research techniques; present two research seminars, pass the qualifier exam and successfully prepare and defend a PhD thesis.

Access to Further Studies
A student graduated with a good PhD Degree may carry on an academic carrier as a lecturer or post doctorate researcher.

Mode of Study
Full Time

Examination Regulations, Assessment and Grading
Measurement and evaluation methods that is applied for each course, is detailed in "Course Structure&ECTS Credits".

Contact (Programme Director or Equivalent)
PositionName SurnamePhoneFaxE-Mail
 Prof. Dr. ABDULLAH TAHSİN TOLA+90 258 296 3196 attola@pau.edu.tr


PROGRAM LEARNING OUTCOMES
1Having sufficient fundamental mathematics and scientific knowledge related to electrical and electronics engineering; ability to use these theoretical and practical backgrounds for solving electrical and electronics engineering problems.
2The ability of detecting, describing, modeling, analyzing and solving the electrical and electronics engineering problems; the ability to select and apply appropriate analytical and modeling methods to this end.
3The ability of designing a system, system component or process to serve needs under the realistic restrictions such as economy, environmental problems, feasibility, productivity, ethics, healthiness, safety, social and political aspects; the ability of applying modern designing methods to fulfill this aim.
4Graduates with the practice of selecting and using appropriate technical and engineering tools necessary for electrical and electronics engineering applications, and with the ability of effective use of information science technologies.
5Graduates with the ability of designing and conducting experiments, data acquisition and analysis and making conclusions for considering electrical and electronics engineering problems.
6Graduates with the ability of participating in disciplinary and inter-disciplinary project groups effectively.
7Graduates with the effective oral and official communication skills in Turkish Language and knowledge at least one foreign language.
8Graduates with motivation to life-long learning and the conscious of sharing information, and with abilities of searching the potential resources for information or knowledge regarding a given engineering issue, using databases and other information resources, pursuing the developments in electrical and electronics engineering profession and updating oneself continuously.
9Graduates with well-structured responsibilities in profession and ethics.
10Graduates with knowledge about applications in business life related to electrical and electronics engineering, and with consciousness about taking initiative, making innovation and feasible development.
11Graduates with consciousness of the results and effects of electrical and electronics engineering solutions and applications on healthiness, environment and safety from the perspective of society and universe, and with knowledge of age’s problems and awareness of the juridical results of engineering solutions.
TEACHING & LEARNING METHODS
NameComments
LecturingLecturing is one of the methods that come first, where the teacher is in the center. It is a method where the teacher actively describes topics and the students are passive listeners. With this method, lesson proceeds in the form of report, description and explanation.
DebateDepending on the situation, debate is a tool that allows all students, or a specific portion of the class to participate in the lesson. In this method, members of the group discuss a topic by addressing the various points of view and discuss alternative opinions about problem-solving.
DemonstrationIn this method the teacher demonstrates, an experiment, test, in front of the class. And then assists students to do so too. Students learn not only by just by looking and watching, but also by taking part and participating. This method is usually applied when teaching skills.
Case Study Case studies require students to actively participate while using an analytical perspective to think about real and problematic events. The problematic event may be real or very close to real life. Student(s) working on the documents that include the necessary data and descriptions of the
Problem SolvingThe name given to any doubt or ambiguity that arises is, a problem. Problems which usually have a role in human life, that have preventing or annoying aspects are solved by considering the stages of scientific methods. (a) Problems are determined. (b) The problem is identified. 
Cooperative LearningCooperative Learning is; a kind of learning that is based on the students working together for a common purpose. Children with different skills come together in heterogeneous groups to learn by helping each other. Students gain experiences such as becoming aware of the unity
Questions –AnswersThe different types of Questions used (associative, differential, assessment, requesting information, motivating, and brainstorming) although students get in to more active positions during the process; the method is teacher-centered. If possible Questions, that serve a purpose and
Simulation Expresses situations where in real life learning is dangerous, difficult to reach and expensive and where students work on models which are very similar to the real thing. For example, before airplane pilots and astronauts embark their aircrafts and spacecrafts, they perform applications
ProjectProject-based learning is a learning way which leads students to deal with interesting problems and to create extraordinary products at the end of this. It allows students to use their creativity and it requires them to look at events perceptively.
Observation Although we generally get information related to the nature through observations, the Observation method can also be used for other situations and under other conditions. We try to reach certain generalizations by thinking about our findings which we gather from our observations.
Testing Means reaching results by using various information with certain mechanisms, which are set up to imitate natural events in artificial environments and to have students take a certain topics and applying them to reach certain aims/objectives. Nature researchers, scientists, and educators
Programmed InstructionAt its basis lays the Individualization of instruction. Programmed instruction is an individual teaching technique, guided by the reinforcement principles of Skinner. Its Basic principles are: the principle of small steps, the principle of effective participation, the achievement principle, the
DebateDebate is a type of discussion on a topic in compliance with certain rules and procedures. Debate, is two groups of students in either twos or threes, putting forward points, which are for or against an idea, proposal, point, action or recommendation.  The aim is to discuss topic ideas that
Six Hat ThinkingThe Six hat thinking technique, is based on looking at a topic from different angles. Individuals learn to, develop the ability to face events from different points of view and to improve their empathizing skills. Because thoughts are looked upon from of every aspect, issues raised can be
Brainstorming Brainstorming is a group work process that has been regulated to reach solutions for a problem without limitations or evaluation. The purpose of brainstorming is to make it easier for students to express themselves and to generate ideas. This technique is used as a high-level discussion

Learning Outcomes - NQF-HETR Relation
NQF-HETR CategoryNQF-HETR Sub-CategoryNQF-HETRLearning Outcomes
INFORMATION  01
INFORMATION  02
SKILLS  01
SKILLS  02
SKILLS  03
SKILLS  04
COMPETENCIESCommunication and Social Competence 01
COMPETENCIESCommunication and Social Competence 02
COMPETENCIESCommunication and Social Competence 03
COMPETENCIESCompetence to Work Independently and Take Responsibility 01
COMPETENCIESCompetence to Work Independently and Take Responsibility 02
COMPETENCIESCompetence to Work Independently and Take Responsibility 03
COMPETENCIESField Specific Competencies 01
COMPETENCIESField Specific Competencies 02
COMPETENCIESField Specific Competencies 03
COMPETENCIESLearning Competence 01
    

Learning Outcomes - Fields of Education Relation (Academic)
FOE CategoryFOE Sub-CategoryFOELearning Outcomes
INFORMATION  01
INFORMATION  02
SKILLS  01
SKILLS  02
SKILLS  03
SKILLS  04
SKILLS  05
COMPETENCIESCommunication and Social Competence 01
COMPETENCIESCommunication and Social Competence 02
COMPETENCIESCompetence to Work Independently and Take Responsibility 01
COMPETENCIESCompetence to Work Independently and Take Responsibility 02
COMPETENCIESCompetence to Work Independently and Take Responsibility 03
COMPETENCIESField Specific Competencies 01
COMPETENCIESField Specific Competencies 02
COMPETENCIESLearning Competence 01
COMPETENCIESLearning Competence 02
COMPETENCIESLearning Competence 03
COMPETENCIESLearning Competence 04
    

Learning Outcomes - Fields of Education Relation (Vocational)
No Records to Display

COURS STRUCTURE & ECTS CREDITS
Year :
1st Semester Course Plan
Course CodeCourse TitleL+P HourECTSCourse Type
ELK 521 OPTIMIZATION TECHNIQUES 3+0 7,5 Compulsory
- Elective 3+0 7,5 Elective
- Elective 3+0 7,5 Elective
- Elective 3+0 7,5 Elective
  Total 30  
1st Semester Elective Groups : Elective
Course CodeCourse TitleL+P HourECTSCourse Type
ELK 501 ADVANCED MICROCONTROLLER SYSTEMS 3+07,5Elective
ELK 502 FUZZY CONTROL SYSTEMS DESIGN AND ANALYSIS 3+07,5Elective
ELK 503 PROGRAMMABLE LOGIC DEVICES - I 3+07,5Elective
ELK 504 LASER ELECTRONICS 3+07,5Elective
ELK 506 COMPUTER OPERATING SYSTEMS AND UNIX 3+07,5Elective
ELK 507 COMPUTER NETWORKS 3+07,5Elective
ELK 508 INTEGRATED CIRCUITS TEST PROBLEMS AND MINIATURIZATION 3+07,5Elective
ELK 509 HIGH DENSITY INTEGRATED DESIGN 3+07,5Elective
ELK 510 INDUCTION HEATING SYSTEMS 3+07,5Elective
ELK 511 VHDL PROGRAMMING OF HIGH DENSITY INTEGRATED CIRCUITS 3+07,5Elective
ELK 512 SEMICONDUCTOR PHYSICS AND DEVICES 3+07,5Elective
ELK 513 OPTICAL FIBER COMMUNICATIONS 3+07,5Elective
ELK 514 THEORY OF LINEAR CIRCUITS 3+07,5Elective
ELK 515 EXTERNALLY LINEAR INTERNALLY NONLINEAR CIRCUITS 3+07,5Elective
ELK 516 LINEAR AND NONLINEAR OPTICS 3+07,5Elective
ELK 517 STATISTICAL DIGITAL SIGNAL PROCESSING AND MODELING - I 3+07,5Elective
ELK 518 ADAPTIVE SIGNAL PROCESSING - I 3+07,5Elective
ELK 520 MACHINE LEARNING 3+07,5Elective
ELK 522 ARTIFICIAL NEURAL NETWORKS 3+07,5Elective
ELK 523 NONLINEAR DYNAMICS AND CHAOS 3+07,5Elective
ELK 524 NONLINEAR CONTROL 3+07,5Elective
ELK 525 COMPUTATIONAL INTELLIGENCE 3+07,5Elective
ELK 528 THEORY OF FUNCTIONS WITH COMPLEX VARIABLES 3+07,5Elective
ELK 529 COMPUTER AIDED NUMERICAL ANALYSIS 3+07,5Elective
ELK 530 MICROWAVE FILTER DESIGN 3+07,5Elective
ELK 531 ADVANCED MICROWAVE TECHNIQUES 3+07,5Elective
ELK 532 MICROWAVE CIRCUITS 3+07,5Elective
ELK 533 ADVANCED POWER ELECTRONICS 3+07,5Elective
ELK 534 POWER SUPPLIES 3+07,5Elective
ELK 535 OPTICAL WAVE GUIDE 3+07,5Elective
ELK 536 ADVANCED CMOS VLSI DESIGN 3+07,5Elective
ELK 537 ADVANCED ACTIVE CIRCUIT DESIGN 3+07,5Elective
ELK 538 LABVIEW GRAPHICAL PROGRAMMING LANGUAGE 3+07,5Elective
ELK 540 TWO-DIMENSIONAL IMAGE PROCESSING AND APPLICATIONS 3+07,5Elective
ELK 541 MULTI-DIMENSIONAL IMAGE PROCESSING AND APPLICATIONS 3+07,5Elective
ELK 543 COMPUTER AIDED DESIGN IN MAGNETICS - I 3+07,5Elective
ELK 544 COMPUTER AIDED DESIGN IN MAGNETICS - II 3+07,5Elective
ELK 545 GENERALIZED THEORY OF ELECTRICAL MACHINES 3+07,5Elective
ELK 546 SPECIAL ELECTRICAL MACHINES 3+07,5Elective
ELK 547 POWER SYSTEMS DYNAMICS AND CONTROL 3+07,5Elective
ELK 548 WIRELESS SENSOR NETWORKS AND APPLICATIONS 3+07,5Elective
ELK 549 CURRENT-MODE ANALOG CIRCUIT DESIGN 3+07,5Elective
ELK 550 LOW VOLTAGE/POWER ANALOG INTEGRATED INTEGRATED CIRCUIT DESIGN 3+07,5Elective
ELK 551 COMPUTER SIMULATIONS OF SEMICONDUCTOR DEVICES 3+07,5Elective
ELK 552 ADVANCED APPLIED POWER ELECTRONICS 3+07,5Elective
ELK 554 ROBOTICS KINEMATICS 3+07,5Elective
ELK 555 ADAPTIVE CONTROL SYSTEMS 3+07,5Elective
ELK 557 PATTERN RECOGNITION 3+07,5Elective
ELK 558 LINEAR SYSTEM THEORY 3+07,5Elective
ELK 559 OPTIMAL CONTROL THEORY 3+07,5Elective
ELK 560 DESIGN OF ELECTRICAL MACHINES 3+07,5Elective
ELK 561 ENERGY PRODUCING SYSTEMS 3+07,5Elective
ELK 562 SYSTEM IDENTIFICATION 3+07,5Elective
ELK 563 DIGITAL CONTROL 3+07,5Elective
ELK 564 ELECTRICAL MACHINES CONTROL 3+07,5Elective
ELK 565 DIGITAL SIGNAL PROCESSORS AND CONTROL APPLICATIONS 3+07,5Elective
ELK 573 POWER QUALITY IN ELECTRICAL SYSTEMS 3+07,5Elective
ELK 574 ELECTROMAGNETIC COMPATIBILITY 3+07,5Elective
ELK 575 POWER SYSTEM ANALYSIS AND MODELING 3+07,5Elective
ELK 576 POWER SYSTEM PROTECTION 3+07,5Elective
ELK 577 DIRECT-CURRENT ENERGY SYSTEMS 3+07,5Elective
ELK 578 ELECTRICAL NETWORKS AND INSTITUTIONS 3+07,5Elective
ELK 579 DESIGN OF PHOTOVOLTAIC SYSTEMS 3+07,5Elective
ELK 580 PRODUCTION TECHNOLOGIES OF PHOTOVOLTAICS 3+07,5Elective
ELK 581 FUEL CELL SYSTEMS 3+07,5Elective
ELK 582 NUMERICAL METHODS IN ELECTROMAGNETICS 3+07,5Elective
ELK 583 FUZZY LOGIC APPLICATIONS IN MICROWAVE CIRCUITS 3+07,5Elective
ELK 584 ANALOG FILTER DESIGN 3+07,5Elective
ELK 585 ACTIVE CIRCUIT SYNTHESIS 3+07,5Elective
ELK 593 CONTROL OF ROBOT MANIPULATORS 3+07,5Elective
ELK 601 ANALYSIS OF DC-DC CONVERTERS 3+07,5Elective
ELK 602 DESIGN OF THE HIGH POWER DENSITY SWITCHED MODE POWER SUPPLIES 3+07,5Elective
ELK 645 PHOTONİCS- I 3+07,5Elective
ELK 646 PHOTONİCS-II 3+07,5Elective

2nd Semester Course Plan
Course CodeCourse TitleL+P HourECTSCourse Type
ELK 698 SEMINAR - I 0+2 7,5 Compulsory
ELK 527 ADVANCED ENGINEERING MATHEMATICS 3+0 7,5 Compulsory
- Elective 3+0 7,5 Elective
- Elective 3+0 7,5 Elective
  Total 30  
2nd Semester Elective Groups : Elective
Course CodeCourse TitleL+P HourECTSCourse Type
ELK 501 ADVANCED MICROCONTROLLER SYSTEMS 3+07,5Elective
ELK 502 FUZZY CONTROL SYSTEMS DESIGN AND ANALYSIS 3+07,5Elective
ELK 503 PROGRAMMABLE LOGIC DEVICES - I 3+07,5Elective
ELK 504 LASER ELECTRONICS 3+07,5Elective
ELK 506 COMPUTER OPERATING SYSTEMS AND UNIX 3+07,5Elective
ELK 507 COMPUTER NETWORKS 3+07,5Elective
ELK 508 INTEGRATED CIRCUITS TEST PROBLEMS AND MINIATURIZATION 3+07,5Elective
ELK 509 HIGH DENSITY INTEGRATED DESIGN 3+07,5Elective
ELK 510 INDUCTION HEATING SYSTEMS 3+07,5Elective
ELK 511 VHDL PROGRAMMING OF HIGH DENSITY INTEGRATED CIRCUITS 3+07,5Elective
ELK 512 SEMICONDUCTOR PHYSICS AND DEVICES 3+07,5Elective
ELK 513 OPTICAL FIBER COMMUNICATIONS 3+07,5Elective
ELK 514 THEORY OF LINEAR CIRCUITS 3+07,5Elective
ELK 515 EXTERNALLY LINEAR INTERNALLY NONLINEAR CIRCUITS 3+07,5Elective
ELK 516 LINEAR AND NONLINEAR OPTICS 3+07,5Elective
ELK 517 STATISTICAL DIGITAL SIGNAL PROCESSING AND MODELING - I 3+07,5Elective
ELK 518 ADAPTIVE SIGNAL PROCESSING - I 3+07,5Elective
ELK 520 MACHINE LEARNING 3+07,5Elective
ELK 522 ARTIFICIAL NEURAL NETWORKS 3+07,5Elective
ELK 523 NONLINEAR DYNAMICS AND CHAOS 3+07,5Elective
ELK 524 NONLINEAR CONTROL 3+07,5Elective
ELK 525 COMPUTATIONAL INTELLIGENCE 3+07,5Elective
ELK 528 THEORY OF FUNCTIONS WITH COMPLEX VARIABLES 3+07,5Elective
ELK 529 COMPUTER AIDED NUMERICAL ANALYSIS 3+07,5Elective
ELK 530 MICROWAVE FILTER DESIGN 3+07,5Elective
ELK 531 ADVANCED MICROWAVE TECHNIQUES 3+07,5Elective
ELK 532 MICROWAVE CIRCUITS 3+07,5Elective
ELK 533 ADVANCED POWER ELECTRONICS 3+07,5Elective
ELK 534 POWER SUPPLIES 3+07,5Elective
ELK 535 OPTICAL WAVE GUIDE 3+07,5Elective
ELK 536 ADVANCED CMOS VLSI DESIGN 3+07,5Elective
ELK 537 ADVANCED ACTIVE CIRCUIT DESIGN 3+07,5Elective
ELK 538 LABVIEW GRAPHICAL PROGRAMMING LANGUAGE 3+07,5Elective
ELK 540 TWO-DIMENSIONAL IMAGE PROCESSING AND APPLICATIONS 3+07,5Elective
ELK 541 MULTI-DIMENSIONAL IMAGE PROCESSING AND APPLICATIONS 3+07,5Elective
ELK 543 COMPUTER AIDED DESIGN IN MAGNETICS - I 3+07,5Elective
ELK 544 COMPUTER AIDED DESIGN IN MAGNETICS - II 3+07,5Elective
ELK 545 GENERALIZED THEORY OF ELECTRICAL MACHINES 3+07,5Elective
ELK 546 SPECIAL ELECTRICAL MACHINES 3+07,5Elective
ELK 547 POWER SYSTEMS DYNAMICS AND CONTROL 3+07,5Elective
ELK 548 WIRELESS SENSOR NETWORKS AND APPLICATIONS 3+07,5Elective
ELK 549 CURRENT-MODE ANALOG CIRCUIT DESIGN 3+07,5Elective
ELK 550 LOW VOLTAGE/POWER ANALOG INTEGRATED INTEGRATED CIRCUIT DESIGN 3+07,5Elective
ELK 551 COMPUTER SIMULATIONS OF SEMICONDUCTOR DEVICES 3+07,5Elective
ELK 552 ADVANCED APPLIED POWER ELECTRONICS 3+07,5Elective
ELK 554 ROBOTICS KINEMATICS 3+07,5Elective
ELK 555 ADAPTIVE CONTROL SYSTEMS 3+07,5Elective
ELK 557 PATTERN RECOGNITION 3+07,5Elective
ELK 558 LINEAR SYSTEM THEORY 3+07,5Elective
ELK 559 OPTIMAL CONTROL THEORY 3+07,5Elective
ELK 560 DESIGN OF ELECTRICAL MACHINES 3+07,5Elective
ELK 561 ENERGY PRODUCING SYSTEMS 3+07,5Elective
ELK 562 SYSTEM IDENTIFICATION 3+07,5Elective
ELK 563 DIGITAL CONTROL 3+07,5Elective
ELK 564 ELECTRICAL MACHINES CONTROL 3+07,5Elective
ELK 565 DIGITAL SIGNAL PROCESSORS AND CONTROL APPLICATIONS 3+07,5Elective
ELK 573 POWER QUALITY IN ELECTRICAL SYSTEMS 3+07,5Elective
ELK 574 ELECTROMAGNETIC COMPATIBILITY 3+07,5Elective
ELK 575 POWER SYSTEM ANALYSIS AND MODELING 3+07,5Elective
ELK 576 POWER SYSTEM PROTECTION 3+07,5Elective
ELK 577 DIRECT-CURRENT ENERGY SYSTEMS 3+07,5Elective
ELK 578 ELECTRICAL NETWORKS AND INSTITUTIONS 3+07,5Elective
ELK 579 DESIGN OF PHOTOVOLTAIC SYSTEMS 3+07,5Elective
ELK 580 PRODUCTION TECHNOLOGIES OF PHOTOVOLTAICS 3+07,5Elective
ELK 581 FUEL CELL SYSTEMS 3+07,5Elective
ELK 582 NUMERICAL METHODS IN ELECTROMAGNETICS 3+07,5Elective
ELK 583 FUZZY LOGIC APPLICATIONS IN MICROWAVE CIRCUITS 3+07,5Elective
ELK 584 ANALOG FILTER DESIGN 3+07,5Elective
ELK 585 ACTIVE CIRCUIT SYNTHESIS 3+07,5Elective
ELK 593 CONTROL OF ROBOT MANIPULATORS 3+07,5Elective
ELK 601 ANALYSIS OF DC-DC CONVERTERS 3+07,5Elective
ELK 602 DESIGN OF THE HIGH POWER DENSITY SWITCHED MODE POWER SUPPLIES 3+07,5Elective
ELK 645 PHOTONİCS- I 3+07,5Elective
ELK 646 PHOTONİCS-II 3+07,5Elective

3rd Semester Course Plan
Course CodeCourse TitleL+P HourECTSCourse Type
FBE 897 DEVELOPMENT AND LEARNING 3+0 7,5 Compulsory
FBE 896 PLANNING AND ASSESSMENT IN EDUCATION 3+2 7,5 Compulsory
ELK 699 SEMINAR - II 0+2 7,5 Compulsory
FBE 610 METHODS OF RESEARCH AND ETHICS 3+0 7,5 Compulsory
  Total 30  

4th Semester Course Plan
Course CodeCourse TitleL+P HourECTSCourse Type
ENS 600 PROFICIENCY EXAM PREPARATION 0+0 20 Compulsory
ENS 602 THESIS PROPOSAL PREPARATION 0+0 10 Compulsory
  Total 30  

5th Semester Course Plan
Course CodeCourse TitleL+P HourECTSCourse Type
ELK 600 PHD THESIS 0+0 20 Compulsory
ELK 800 PHD EXPERTISE FIELD COURSES 8+0 10 Compulsory
  Total 30  

6th Semester Course Plan
Course CodeCourse TitleL+P HourECTSCourse Type
ELK 600 PHD THESIS 0+0 20 Compulsory
ELK 800 PHD EXPERTISE FIELD COURSES 8+0 10 Compulsory
  Total 30  

7th Semester Course Plan
Course CodeCourse TitleL+P HourECTSCourse Type
ELK 600 PHD THESIS 0+0 20 Compulsory
ELK 800 PHD EXPERTISE FIELD COURSES 8+0 10 Compulsory
  Total 30  

8th Semester Course Plan
Course CodeCourse TitleL+P HourECTSCourse Type
ELK 600 PHD THESIS 0+0 20 Compulsory
ELK 800 PHD EXPERTISE FIELD COURSES 8+0 10 Compulsory
  Total 30  


COURSE & PROGRAM LEARNING OUTCOMES
Year : Compulsory Courses
Course TitleC/EPO 01PO 02PO 03PO 04PO 05PO 06PO 07PO 08PO 09PO 10PO 11
ADVANCED ENGINEERING MATHEMATICSC***********
DEVELOPMENT AND LEARNINGC           
GRADUATE COUNSELINGC           
METHODS OF RESEARCH AND ETHICSC           
OPTIMIZATION TECHNIQUESC*****      
PHD EXPERTISE FIELD COURSESC*********  
PHD THESISC*********  
PLANNING AND ASSESSMENT IN EDUCATIONC********   
PROFICIENCY EXAM PREPARATIONC           
SEMINAR - IC * * ***   
SEMINAR - IIC * * ***   
THESIS PROPOSAL PREPARATIONC           
Click to add elective courses...
Elective Courses
Course TitleC/EPO 01PO 02PO 03PO 04PO 05PO 06PO 07PO 08PO 09PO 10PO 11
ACTIVE CIRCUIT SYNTHESISE           
ADAPTIVE CONTROL SYSTEMSE*****      
ADAPTIVE SIGNAL PROCESSING - IE****** *   
ADVANCED ACTIVE CIRCUIT DESIGNE****** *  *
ADVANCED APPLIED POWER ELECTRONICSE***********
ADVANCED CMOS VLSI DESIGNE****** *  *
ADVANCED MICROCONTROLLER SYSTEMSE***********
ADVANCED MICROWAVE TECHNIQUESE***********
ADVANCED POWER ELECTRONICSE****** *   
ANALOG FILTER DESIGNE           
ANALYSIS OF DC-DC CONVERTERSE           
ARTIFICIAL NEURAL NETWORKSE*****      
COMPUTATIONAL INTELLIGENCEE*****      
COMPUTER AIDED DESIGN IN MAGNETICS - IE******  ***
COMPUTER AIDED DESIGN IN MAGNETICS - IIE******  ***
COMPUTER AIDED NUMERICAL ANALYSISE***********
COMPUTER NETWORKSE***********
COMPUTER OPERATING SYSTEMS AND UNIXE***********
COMPUTER SIMULATIONS OF SEMICONDUCTOR DEVICESE***********
CONTROL OF ROBOT MANIPULATORSE           
CURRENT-MODE ANALOG CIRCUIT DESIGNE****** *  *
DESIGN OF ELECTRICAL MACHINESE******  ***
DESIGN OF PHOTOVOLTAIC SYSTEMSE           
DESIGN OF THE HIGH POWER DENSITY SWITCHED MODE POWER SUPPLIESE           
DIGITAL CONTROLE*****      
DIGITAL SIGNAL PROCESSORS AND CONTROL APPLICATIONSE           
DIRECT-CURRENT ENERGY SYSTEMSE           
ELECTRICAL MACHINES CONTROLE****** *   
ELECTRICAL NETWORKS AND INSTITUTIONSE           
ELECTROMAGNETIC COMPATIBILITYE           
ENERGY PRODUCING SYSTEMSE***********
EXTERNALLY LINEAR INTERNALLY NONLINEAR CIRCUITSE********   
FUEL CELL SYSTEMSE           
FUZZY CONTROL SYSTEMS DESIGN AND ANALYSISE***********
FUZZY LOGIC APPLICATIONS IN MICROWAVE CIRCUITSE           
GENERALIZED THEORY OF ELECTRICAL MACHINESE******  ***
HIGH DENSITY INTEGRATED DESIGNE****** *  *
INDUCTION HEATING SYSTEMSE****** *   
INTEGRATED CIRCUITS TEST PROBLEMS AND MINIATURIZATIONE******     
LABVIEW GRAPHICAL PROGRAMMING LANGUAGEE***********
LASER ELECTRONICSE***********
LINEAR AND NONLINEAR OPTICSE***********
LINEAR SYSTEM THEORYE*****      
LOW VOLTAGE/POWER ANALOG INTEGRATED INTEGRATED CIRCUIT DESIGNE****** *  *
MACHINE LEARNINGE*****      
MICROWAVE CIRCUITSE***********
MICROWAVE FILTER DESIGNE***********
MULTI-DIMENSIONAL IMAGE PROCESSING AND APPLICATIONSE****** *   
NONLINEAR CONTROLE*****      
NONLINEAR DYNAMICS AND CHAOSE*****      
NUMERICAL METHODS IN ELECTROMAGNETICSE           
OPTICAL FIBER COMMUNICATIONSE***********
OPTICAL WAVE GUIDEE***********
OPTIMAL CONTROL THEORYE*****      
PATTERN RECOGNITIONE*****      
PHOTONİCS- IE           
PHOTONİCS-IIE           
POWER QUALITY IN ELECTRICAL SYSTEMSE           
POWER SUPPLIESE****** *   
POWER SYSTEM ANALYSIS AND MODELINGE           
POWER SYSTEM PROTECTIONE           
POWER SYSTEMS DYNAMICS AND CONTROLE****** * * 
PRODUCTION TECHNOLOGIES OF PHOTOVOLTAICSE           
PROGRAMMABLE LOGIC DEVICES - IE***********
ROBOTICS KINEMATICSE*****      
SEMICONDUCTOR PHYSICS AND DEVICESE***********
SPECIAL ELECTRICAL MACHINESE****** *   
STATISTICAL DIGITAL SIGNAL PROCESSING AND MODELING - IE********   
SYSTEM IDENTIFICATIONE*****      
THEORY OF FUNCTIONS WITH COMPLEX VARIABLESE***********
THEORY OF LINEAR CIRCUITSE********   
TWO-DIMENSIONAL IMAGE PROCESSING AND APPLICATIONSE****** *   
VHDL PROGRAMMING OF HIGH DENSITY INTEGRATED CIRCUITSE***********
WIRELESS SENSOR NETWORKS AND APPLICATIONSE***********
L+P: Lecture and Practice
C: Compulsory
E: Elective
PQ: Program Learning Outcomes
TH [5]: Too High
H [4]: High
M [3]: Medium
L [2]: Low
TL [1]: Too Low
None [0]: None
FOE [0]: Field of Education
NQF-HETR : National Qualifications Framework For Higher Education in Turkey
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