Welcome,
Guest
.
Login
.
Türkçe
NİNOVA
COURSES
HELP
ABOUT
Where Am I:
Ninova
/
Courses
/
Faculty of Mechanical Engineering
/
DNK 201E
/
Course Informations
Return to Faculty
Home Page
Course Information
Course Weekly Lecture Plan
Course Evaluation Criteria
Course Information
Course Name
Turkish
Dinamik
English
Dynamics
Course Code
DNK 201E
Credit
Lecture
(hour/week)
Recitation
(hour/week)
Laboratory
(hour/week)
Semester
1
3
3
-
-
Course Language
English
Course Coordinator
Tuğba Kuru
Course Objectives
Using Newtonian Mechanics, creating a dynamic model for ideal objects (particles and rigid bodies) by considering the effects of forces and being able to solve the model. With special titles;
• Definition and modeling of motion according to a stationary and moving observer
• Understanding motion under the effect of a central force
• Understanding the basic principles of two-dimensional rigid body motion
• Understanding the basic principles of three-dimensional rigid body motion
• Understanding the basic principles of vibration analysis
Course Description
Definitions and basic concepts. Particle kinematics. General planar and linear motion. Relative motion. Particle kinetics. Newton's laws. Impulse and momentum principles for a system of particles. Work and energy for a system of particles. Motion under the influence of centripetal force. Collision. Motion with variable mass. Rigid body kinematics. Rigid body kinetics. Work, energy, impulse and momentum for a rigid body. Rotation of a rigid body with a fixed axis. Planar rotation of a rigid body. Vibration of a rigid body.
Course Outcomes
Expectations from students who pass the course:
1. To be able to choose and use the appropriate axis set to solve particle motion
2. To be able to define particle motion according to the selected (fixed/moving) axes
3. To be able to establish a dynamic model in an accelerating axis set
4. To be able to use integral form equations of motion such as conservation of momentum/energy for the particle
5. To be able to use integral form equations of motion such as conservation of momentum/energy for a rigid body
6. To be able to create and analyze a dynamic model for a rigid body in planar motion
7. To be able to create and analyze a dynamic model for a rigid body in three-dimensional motion
8. To be able to calculate the trajectory with the help of a two-body problem in space
9. To be able to model and analyze basic simple problems in the case of vibration
Pre-requisite(s)
( ( FIZ 101 MIN. DD Veya FIZ 101E MIN. DD )
Veya ( FIZ 111 MIN. DD Veya FIZ 111E MIN. DD )
Veya ( FIZ 113 MIN. DD Veya FIZ 113E MIN. DD )
Veya GMI 103 MIN. DD
Veya GUV 103 MIN. DD )
Ve( ( MAT 101 MIN. DD Veya MAT 101E MIN. DD )
Veya ( MAT 103 MIN. DD Veya MAT 103E MIN. DD )
Veya GMI 099 MIN. DD
Veya GUV 099 MIN. DD
Veya ( MAT 111 MIN. DD Veya MAT 111E MIN. DD ) )
Required Facilities
Other
Textbook
1. R.C. Hibbeler, Engineering Mechanics:Dynamics, Pearson (14th Edition SI Units), 2017.
2. J.L. Meriam, L.G. Kraige, J.N. Bolton, Engineering Mechanics: Dynamics, Wiley (8th Edition SI Unit), 2016
Other References
Courses
.
Help
.
About
Ninova is an ITU Office of Information Technologies Product. © 2026