Education Information System | Duzce University

Course Information

Course Title	Code	Language	Type	Semester	L+U Hour	Credits	ECTS
Dynamic	MM209	Turkish	Compulsory	3. Semester	3 + 0	3.0	5.0

Prerequisite Courses
Course Level	Undergraduate
Mode of delivery	face to face
Course Coordinator	Doç. Dr. Fikret POLAT
Instructor(s)	Doç. Dr. Fikret POLAT (Güz)
Goals	It is one of the fundamental subjects of Mechanical and Mechanical Engineering and contains basic information for the courses of machine dynamics, design and mechanization techniques.
Course Content

Learning Outcomes

#	Öğrenme Kazanımı
1	Analyzes kinematic and kinetic knowledge of linear motion in dynamic state.
1	Analyzes kinematic and kinetic knowledge of linear motion in dynamic state.
1	Analyzes kinematic and kinetic knowledge of linear motion in dynamic state.
2	Study the kinematic and kinetic knowledge of dynamic systems in curvilinear motion.
2	Study the kinematic and kinetic knowledge of dynamic systems in curvilinear motion.
2	Study the kinematic and kinetic knowledge of dynamic systems in curvilinear motion.
3	The planer examines the kinematic and kinetic knowledge of the moving object in the dynamic state.
3	The planer examines the kinematic and kinetic knowledge of the moving object in the dynamic state.
3	The planer examines the kinematic and kinetic knowledge of the moving object in the dynamic state.

Lesson Plan (Weekly Topics)

Week	Topics/Applications	Method
1. Week	Displacement, Speed, Acceleration
1. Week	Displacement, Speed, Acceleration
1. Week	Displacement, Speed, Acceleration
2. Week	Application
2. Week	Application
2. Week	Application
3. Week	Linear and curvilinear movements of particles
3. Week	Linear and curvilinear movements of particles
3. Week	Linear and curvilinear movements of particles
4. Week	Application
4. Week	Application
4. Week	Application
5. Week	Plane motion and kinetics of particles
5. Week	Plane motion and kinetics of particles
5. Week	Plane motion and kinetics of particles
6. Week	Application
6. Week	Application
6. Week	Application
7. Week	Kinematics and kinetics of rigid bodies
7. Week	Kinematics and kinetics of rigid bodies
7. Week	Kinematics and kinetics of rigid bodies
8. Week	Kinematics and kinetics of rigid bodies
8. Week	midterm exam
8. Week	midterm exam
9. Week	Application
9. Week	Application
9. Week	Application
10. Week	Work and Energy
10. Week	Work and Energy
10. Week	Work and Energy
11. Week	Application
11. Week	Application
11. Week	Application
12. Week	Impulse and Momentum
12. Week	Impulse and Momentum
12. Week	Impulse and Momentum
13. Week	Application
13. Week	Application
13. Week	Impulse and Momentum
14. Week	Application
14. Week	Application
14. Week	Application

*Midterm and final exam dates are not specified in the 14-week course operation plan. Midterm and final exam dates are held on the dates specified in the academic calendar with the decision of the University Senate.

The Matrix for Course & Program Learning Outcomes

No	Program Requirements	Level of Contribution
No	Program Requirements	1	2	3	4	5
1	Sufficient knowledge in mathematics, science, and discipline-specific engineering topics; the ability to apply theoretical and practical knowledge in these areas to solve complex engineering problems.

Relations with Education Attainment Program Course Competencies

Program Requirements	DK1	DK2	DK3
PY1	35	35	30

Recommended Sources

Ders Kitabı veya Notu	Ders Kitabı veya Ders Notu bulunmamaktadır.
Diğer Kaynaklar	1- Meriam, L James and L G Kraige, Engineering Mechanics- Dynamics, John Wiley New York, 1996 2- S.S. Bhavıkattı and K.G. Rajashekarappa , Engineering Mechanics, John Wiley, New York,1994 3- J C Grassie, Applied mechanics for Engineers, Spottiswoode, Ballantyne and Co. Ltd,London,1962 4- R B Gupta, Engineering Mechanics and Strength of Materials, Laxmi publications, New delhi, 1986 1- Meriam, L James and L G Kraige, Engineering Mechanics- Dynamics, John Wiley New York, 1996 2- S.S. Bhavıkattı and K.G. Rajashekarappa , Engineering Mechanics, John Wiley, New York,1994 3- J C Grassie, Applied mechanics for Engineers, Spottiswoode, Ballantyne and Co. Ltd,London,1962 4- R B Gupta, Engineering Mechanics and Strength of Materials, Laxmi publications, New delhi, 1986 Hibbeler, R. C. (2004). Engineering mechanics: dynamics. Pearson Educación. 1- Meriam, L James and L G Kraige, Engineering Mechanics- Dynamics, John Wiley New York, 1996 2- S.S. Bhavıkattı and K.G. Rajashekarappa , Engineering Mechanics, John Wiley, New York,1994 3- J C Grassie, Applied mechanics for Engineers, Spottiswoode, Ballantyne and Co. Ltd,London,1962 4- R B Gupta, Engineering Mechanics and Strength of Materials, Laxmi publications, New delhi, 1986 1- Meriam, L James and L G Kraige, Engineering Mechanics- Dynamics, John Wiley New York, 1996 2- S.S. Bhavıkattı and K.G. Rajashekarappa , Engineering Mechanics, John Wiley, New York,1994 3- J C Grassie, Applied mechanics for Engineers, Spottiswoode, Ballantyne and Co. Ltd,London,1962 4- R B Gupta, Engineering Mechanics and Strength of Materials, Laxmi publications, New delhi, 1986 Hibbeler, R. C. (2004). Engineering mechanics: dynamics. Pearson Educación.

ECTS credits and course workload

ECTS credits and course workload		Quantity	Duration (Hour)	Total Workload (Hour)
Ders İçi	Class Hours	14	3	42
Ders Dışı	Other Activities	1	81.5	81.5
Sınavlar	Midterm 1	1	2	2
Sınavlar	Final	1	2	2
Total Workload				127.5
*AKTS = (Total Workload) / 25,5		ECTS Credit of the Course		25.5 5.0