GAZI UNIVERSITY INFORMATION PACKAGE - 2019 ACADEMIC YEAR

COURSE DESCRIPTION
DYNAMICS/İNM -205
Course Title: DYNAMICS
Credits 2 ECTS 2
Semester 3 Compulsory/Elective Compulsory
COURSE INFO
 -- LANGUAGE OF INSTRUCTION
  Turkish
 -- NAME OF LECTURER(S)
  Prof.Salih Yazıcıoğlu
 -- WEB SITE(S) OF LECTURER(S)
  http://www.websitem.gazi.edu.tr/site/syazicioglu
 -- EMAIL(S) OF LECTURER(S)
  syazicioglu@gazi.edu.tr
 -- LEARNING OUTCOMES OF THE COURSE UNIT
Student will be able to; analyze the problems related with particle kinematics
Determine the kinematical quantities for relative and dependent motion
Define the components of kinematical quantities in certain coordinate systems
Write the equation of motion for different coordinate systems and solve kinetic problems
Solve particle kinetics problems using energy methods
Solve particle kinetics problems using momentum methods
Analyze systems of rigid bodies and define the kinematic quantities for each rigid body
Solve rigid body kinetics problems using energy and momentum methods
Solve particle and rigid body vibration problems
 -- MODE OF DELIVERY
  The mode of delivery of this course is Face to face
 -- PREREQUISITES AND CO-REQUISITES
  There is no prerequisite or co-requisite for this cours
 -- RECOMMENDED OPTIONAL PROGRAMME COMPONENTS
  There is no recommended optional programme component for this course.
 --COURSE CONTENT
1. Week  Introduction: Course information, particle kinematics, definition of motion, rectilinear motion, relative and dependent motion, graphical solutions
2. Week  Curvilinear motion: Cartesian components, normal and tangential components, cylindrical and polar components
3. Week  Planar relative motion: Motion of coordinate frame, planar relative motion
4. Week  Particle kinetics: Newton’s laws of motion, equation of motion in Cartesian coordinate system, polar components
5. Week  Particle kinetics: Friction, equation of motion for system of particles
6. Week  Energy methods: Work done by a force, work and energy principle, work and energy principle for system of particles, conservation of energy
7. Week  Momentum methods: Linear momentum and impulse, particle systems, angular momentum, conservation of momentum
8. Week  Midterm Exam
9. Week  Momentum methods: Collisions
10. Week  Rigid body kinematics: Planar motion, translation and rotation about a fixed axis. Velocity and acceleration analysis for absolute and relative motion
11. Week  Rigid body kinetics: Mass moment of inertia, equation of motion
12. Week  Rigid body kinetics: Energy methods
13. Week  Rigid body kinetics: Momentum methods
14. Week  Rigid body kinetics: Momentum methods
15. Week  Vibrations: Particle and rigid body vibrations
16. Week  Final Exam
 -- RECOMMENDED OR REQUIRED READING
  1. Vector Mechanics For Engineers, Dynamics, F.P. Beer ve E.R. Johnston, Mc Graw. Hill., 6th Edition.
 -- PLANNED LEARNING ACTIVITIES AND TEACHING METHODS
  Lecture, Question & Answer, Demonstration, Drill - Practise
 -- WORK PLACEMENT(S)
  Not Applicable
 -- ASSESSMENT METHODS AND CRITERIA
 
Quantity
Percentage
 Mid-terms
1
35
 Assignment
1
5
 Exercises
0
0
 Projects
0
0
 Practice
0
0
 Quiz
0
0
 Contribution of In-term Studies to Overall Grade  
40
 Contribution of Final Examination to Overall Grade  
60
 -- WORKLOAD
 Efficiency  Total Week Count  Weekly Duration (in hour)  Total Workload in Semester
 Theoretical Study Hours of Course Per Week
14
3
42
 Practising Hours of Course Per Week
0
 Reading
0
 Searching in Internet and Library
0
 Designing and Applying Materials
0
 Preparing Reports
0
 Preparing Presentation
0
 Presentation
0
 Mid-Term and Studying for Mid-Term
1
2
2
 Final and Studying for Final
1
2
2
 Other
0
 TOTAL WORKLOAD: 
46
 TOTAL WORKLOAD / 25: 
1.84
 ECTS: 
2
 -- COURSE'S CONTRIBUTION TO PROGRAM
NO
 PROGRAM LEARNING OUTCOMES
1
2
3
4
5
1Having a sufficient substructure concerning basic mathematics as well as natural and applied sciences, also having the competence in use of theoretical knowledge along with application experiences in engineering solutionsX
2Equipped with determination, formulation and solution skills of complex engineering problems, and having the ability to select and apply appropriate analysis and modeling methodsX
3Ability to design a complex system, process, equipment or product meeting certain needs under realistic limitations and conditions. In this way, having the skill to use modern designing methods (realistic limitations and conditions include subjects such as economics, environmental conditions, sustainability, productivity, ethics, health, security, social and political problems)X
4Having the ability to develop, select and use of modern methods and tools, talented to use of informatics technologies effectivelyX
5Having the ability to design an experimental setup, carry out experiments, acquire data, analyze and interpret the outcomesX
6Having the ability to study in interdisciplinary and multidisciplinary teams effectively and talented to carry out individual studiesX
7Having the ability in written and oral Turkish communication and use of a foreign language (at least)X
8Awareness of the necessity of lifelong learning, having the ability to access knowledge, following developments in science and technology and renewing himself/herselfX
9Awareness of professional and ethical responsibilitiesX
10Having informed of applications in professional life including project and amendment management, awareness of entrepreneurship, reformism and sustainable developmentX
11Information regarding the universal and social effects of engineering applications on health, environment and security as well as problems of era; awareness of legal results of engineering solutionsX
12Possessing administrative skillsX