Second Cycle Programmes    (Master's Degree)
II. Master (non-thesis EE) - Institute for Graduate Studies in Pure and Applied Sciences - Mechanical Engineering - Mechanical Engineering
General Description  |  Key Learning Outcomes  |  Course Structure Diagram with Credits
General Description ^
Qualification Awarded
The students who completed the programme successfully are awarded with “ the Master Degree in the Mechanical Engineering
Specific Admission Requirements
Admission and Registration of Master Programme are done according to “Regulation of Graduate Education and Examination (Article II- Admission to Graduate Programmes). The language of instruction during the Master of Science degree education in Mechanical Engineering Department is English. The candidates who fulfill the requirements for acceptance conditions determined by the Institute for Graduate Studies in Pure and Applied Sciences make their applications at the period specified in the Academic Calendar. The candidates whose applications are accepted must have the scientific examinations given by the main scientific disciplines at the declared days. The candidates who succeeded in the scientific examination and fulfill the requirements for registration conditions to Master programme of the Institute for Graduate Studies in Pure and Applied Sciences are registered respecting to the quotas.
Qualification Requirements and Regulations
The language of education is English. The education period is 4 academic terms. Completing 60 ECTS credits after succeeding all the courses in the Department Curriculum and by presenting the graduation project, it is adequate to graduate.
Access to Further Studies
Graduate students who fullfilled the required conditions of Mechanical Engineering programme can be accepted in Ph. D. programmes as long as they satisfy the requirements of the institution they applied whether in their field or not according to their results in post graduate education examinations (ALES, UDS, KPDS).
Graduation Requirements
Students are expected to complete a minimum of 30 credits and give a seminar which is non-credit. After completing this minimum requirement, the student should prepare a graduation project with his/her thesis advisor.
Mode of Study (Full-Time, Part-Time, E-Learning )
Full-Time
Key Learning Outcomes ^
1 Ability to acquire and apply knowledge of mathematics, applied science, and engineering in mechanical engineering
2 Ability to design and analyze a system, system component or process to meet designated needs
3 Recognition of the national and international impacts of engineering solutions on health, safety and environment
4 Ability to solve problems by using scientific research methods
5 Ability to design and conduct experiments, collect and critically analyze data
6 Ability to use the modern engineering techniques, tools and information technologies effectively.
7 Ability to participate in teamwork and conduct multi-disciplinary study
8 Have updated information in the field of his/her proficiency of graduate education
9 Ability to study individually
10 Capacity to transfer the current developments in his/her fields and his/her own studies by means of written oral as well as visual devices at different levels
11 Understanding of social, professional and ethical responsibility
12 Have an ability to develop new strategical approaches and solutions by taking responsibilities in the case of unforeseen and complex situations in his/her field
13 Ability to pursue and develop technology
14 Ability to conduct studies individually in advanced levels by using self-learning and critical thinking abilities
15 Ability to synthesize published literature on a topic in mechanical engineering.
Course Structure Diagram with Credits ^
T : Theoretical P: Practice
No Course Unit Code Course Unit Title Type of Course T P ECTS
1 ME-E1..5-TZ Elective - 1..5 Elective 15 0 30
Total 15 0 30
No Course Unit Code Course Unit Title Type of Course T P ECTS
1 ME798 Semester Project Compulsory 0 1 5
2 ME-E6..10-TZ Elective - 6..10 Elective 15 0 25
Total 15 1 30
Elective
1 . Semester > ME-E1..5-TZ Elective - 1..5
No Course Unit Code Course Unit Title Type of Course T P ECTS
1 ME701 Numerical Methods for Engineers Compulsory 3 0 6
2 ME702 Advanced Strength of Materials Compulsory 3 0 6
3 ME703 Advanced Mathematics for Engineers Compulsory 3 0 6
4 ME704 Mathematical Methods for Engineers Compulsory 3 0 6
5 ME705 Advanced Fluid Mechanics Compulsory 3 0 6
6 ME706 Advanced Heat and Mass Transfer Compulsory 3 0 6
7 ME707 Advanced Dynamics Compulsory 3 0 6
8 ME709 Advanced System Dynamics and Control Compulsory 3 0 6
9 ME710 Principles of Design Compulsory 3 0 6
10 ME711 Advanced Thermodynamics Compulsory 3 0 6
11 ME712 Kinematic and Dynamic Analysis of Mechanisms Compulsory 3 0 6
12 ME713 Mechanics of Composite Materials Compulsory 3 0 6
13 ME714 Applied Elasticity Compulsory 3 0 6
14 ME715 Design Optimization Compulsory 3 0 6
15 ME716 Finite Element Method Compulsory 3 0 6
16 ME717 Computer Aided Design Compulsory 3 0 6
17 ME718 Computational Methods in Dynamics Compulsory 3 0 6
18 ME719 Introduction Continuum Mechanics Compulsory 3 0 6
19 ME720 Principles of Robotics Compulsory 3 0 6
20 ME721 Artificial Intelligent Techniques in Engineering Applications Compulsory 3 0 6
21 ME722 Analysis and Design of Discrete Time Systems Compulsory 3 0 6
22 ME723 Advanced Material Science Compulsory 3 0 6
23 ME724 Industrial Process Control Compulsory 3 0 6
24 ME725 Advanced Probability Compulsory 3 0 6
25 ME726 Non-Traditional Production Processes Compulsory 3 0 6
26 ME727 Advanced Vibrations Compulsory 3 0 6
27 ME728 Optimal Control Systems Compulsory 3 0 6
28 ME729 Vibration Measurement and Analysis Compulsory 3 0 6
29 ME730 Computational Fluid Dynamics Compulsory 3 0 6
30 ME731 Solar Energy Utilization Compulsory 3 0 6
31 ME732 Combustion Compulsory 3 0 6
32 ME733 Internal Combustion Engine Modeling Compulsory 3 0 6
33 ME734 Design of Thermo-Fluid Systems Compulsory 3 0 6
34 ME735 Advanced Heating , Ventilation and Air Conditioning Compulsory 3 0 6
35 ME736 Introduction to Renewable Energy Systems and Technologies Compulsory 3 0 6
36 ME737 Ideal Fluid Flow Compulsory 3 0 6
37 ME738 Second Law Analysis and Thermo-economics of Energy Systems Compulsory 3 0 6
38 ME739 Fluid Power Control Compulsory 3 0 6
39 ME740 Turbulent Flow Compulsory 3 0 6
40 ME742 Experimental Methods in Fluids Compulsory 3 0 6
41 ME751 Special Topics in Mechanics and Control Compulsory 3 0 6
42 ME752 Special Topics in Thermal Systems Compulsory 3 0 6
43 ME753 Special Topics in Thermal Sciences Compulsory 3 0 6
44 ME754 Special Topics in Transport Phenomenon Compulsory 3 0 6
45 ME755 Special Topics in Design and Manufacturing Compulsory 3 0 6
46 ME756 Special Topics in Mechanics and Control Compulsory 3 0 6
2 . Semester > ME-E6..10-TZ Elective - 6..10
No Course Unit Code Course Unit Title Type of Course T P ECTS
1 ME701 Numerical Methods for Engineers Compulsory 3 0 5
2 ME702 Advanced Strength of Materials Compulsory 3 0 5
3 ME703 Advanced Mathematics for Engineers Compulsory 3 0 5
4 ME704 Mathematical Methods for Engineers Compulsory 3 0 5
5 ME705 Advanced Fluid Mechanics Compulsory 3 0 5
6 ME706 Advanced Heat and Mass Transfer Compulsory 3 0 5
7 ME707 Advanced Dynamics Compulsory 3 0 5
8 ME709 Advanced System Dynamics and Control Compulsory 3 0 5
9 ME710 Principles of Design Compulsory 3 0 5
10 ME711 Advanced Thermodynamics Compulsory 3 0 5
11 ME712 Kinematic and Dynamic Analysis of Mechanisms Compulsory 3 0 5
12 ME713 Mechanics of Composite Materials Compulsory 3 0 5
13 ME714 Applied Elasticity Compulsory 3 0 5
14 ME715 Design Optimization Compulsory 3 0 5
15 ME716 Finite Element Method Compulsory 3 0 5
16 ME717 Computer Aided Design Compulsory 3 0 5
17 ME718 Computational Methods in Dynamics Compulsory 3 0 5
18 ME719 Introduction Continuum Mechanics Compulsory 3 0 5
19 ME720 Principles of Robotics Compulsory 3 0 5
20 ME721 Artificial Intelligent Techniques in Engineering Applications Compulsory 3 0 5
21 ME722 Analysis and Design of Discrete Time Systems Compulsory 3 0 5
22 ME723 Advanced Material Science Compulsory 3 0 5
23 ME724 Industrial Process Control Compulsory 3 0 5
24 ME725 Advanced Probability Compulsory 3 0 5
25 ME726 Non-Traditional Production Processes Compulsory 3 0 5
26 ME727 Advanced Vibrations Compulsory 3 0 5
27 ME728 Optimal Control Systems Compulsory 3 0 5
28 ME729 Vibration Measurement and Analysis Compulsory 3 0 5
29 ME730 Computational Fluid Dynamics Compulsory 3 0 5
30 ME731 Solar Energy Utilization Compulsory 3 0 5
31 ME732 Combustion Compulsory 3 0 5
32 ME733 Internal Combustion Engine Modeling Compulsory 3 0 5
33 ME734 Design of Thermo-Fluid Systems Compulsory 3 0 5
34 ME735 Advanced Heating , Ventilation and Air Conditioning Compulsory 3 0 5
35 ME736 Introduction to Renewable Energy Systems and Technologies Compulsory 3 0 5
36 ME737 Ideal Fluid Flow Compulsory 3 0 5
37 ME738 Second Law Analysis and Thermo-economics of Energy Systems Compulsory 3 0 5
38 ME739 Fluid Power Control Compulsory 3 0 5
39 ME740 Turbulent Flow Compulsory 3 0 5
40 ME742 Experimental Methods in Fluids Compulsory 3 0 5
41 ME751 Special Topics in Mechanics and Control Compulsory 3 0 5
42 ME752 Special Topics in Thermal Systems Compulsory 3 0 5
43 ME753 Special Topics in Thermal Sciences Compulsory 3 0 5
44 ME754 Special Topics in Transport Phenomenon Compulsory 3 0 5
45 ME755 Special Topics in Design and Manufacturing Compulsory 3 0 5
46 ME756 Special Topics in Mechanics and Control Compulsory 3 0 5

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