GAZI UNIVERSITY INFORMATION PACKAGE - 2019 ACADEMIC YEAR

COURSE DESCRIPTION
MECHANICS II (DINAMICS)/IM224E
Course Title: MECHANICS II (DINAMICS)
Credits 3 ECTS 6
Semester 4 Compulsory/Elective Compulsory
COURSE INFO
 -- LANGUAGE OF INSTRUCTION
  English
 -- NAME OF LECTURER(S)
  Prof. Dr. Tekin GULTOP, Prof. Dr. Kurtulus SOYLUK, Assoc. Prof. Dr. Bahadir ALYAVUZ
 -- WEB SITE(S) OF LECTURER(S)
  websitem.gazi.edu.tr/tgultop, websitem.gazi.edu.tr/ksoyluk, websitem.gazi.edu.tr/balyavuz
 -- EMAIL(S) OF LECTURER(S)
  tgultop@gazi.edu.tr, ksoyluk@gazi.edu.tr, balyavuz@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
  IM223E Mechanics I (Statics)
 -- 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  1st MIDTERM EXAMINATION
8. Week  Momentum methods: Linear momentum and impulse, particle systems, angular momentum, conservation of momentum
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  2nd MIDTERM EXAMINATION
13. Week  Rigid body kinetics: Energy methods
14. Week  Rigid body kinetics: Momentum methods
15. Week  Vibrations: Particle and rigid body vibrations
16. Week  
 -- RECOMMENDED OR REQUIRED READING
  FP Beer & ER Johnston, Vector Mechanics For Engineers, Dynamics R.C Hibbeler, Engineering Mechanics, Dynamics.
 -- PLANNED LEARNING ACTIVITIES AND TEACHING METHODS
  Lecture, Question & Answer, Recitation, Video shows, Photos, Slides
 -- WORK PLACEMENT(S)
  Not Applicable
 -- ASSESSMENT METHODS AND CRITERIA
 
Quantity
Percentage
 Mid-terms
2
100
 Assignment
0
0
 Exercises
0
0
 Projects
0
0
 Practice
0
0
 Quiz
0
0
 Contribution of In-term Studies to Overall Grade  
60
 Contribution of Final Examination to Overall Grade  
40
 -- WORKLOAD
 Efficiency  Total Week Count  Weekly Duration (in hour)  Total Workload in Semester
 Theoretical Study Hours of Course Per Week
13
3
39
 Practising Hours of Course Per Week
0
0
0
 Reading
13
4
52
 Searching in Internet and Library
1
6
6
 Designing and Applying Materials
0
0
0
 Preparing Reports
1
6
6
 Preparing Presentation
0
0
0
 Presentation
0
0
0
 Mid-Term and Studying for Mid-Term
2
15
30
 Final and Studying for Final
1
15
15
 Other
0
0
0
 TOTAL WORKLOAD: 
148
 TOTAL WORKLOAD / 25: 
5.92
 ECTS: 
6
 -- COURSE'S CONTRIBUTION TO PROGRAM
NO
 PROGRAM LEARNING OUTCOMES
1
2
3
4
5
1Have sufficient theoretical and practical background for a successful profession and application skills of fundamental scientific knowledge in the engineering practiceX
2Have skills and professional background in describing, formulating, modeling and analyzing the engineering problem, with a consideration for appropriate analytical solutions in all necessary situationsX
3Have the necessary technical, academic and practical knowledge and application confidence in the design and assessment of machines or mechanical systems or industrial processes with considerations of productivity, feasibility and environmental and social aspects.X
4Have the ability of designing and conducting experiments, conduction data acquisition and analysis and making conclusions
5Have the practice of selecting and using appropriate technical and engineering tools in engineering problems, and ability of effective usage of information science technologiesX
6Have ability of identifying the potential resources for information or knowledge regarding a given engineering issueX
7Have abilities and performance to participate multi-disciplinary groups together with the effective oral and official communication skills and personal confidenceX
8Have motivation for life-long learning and having known significance of continuous education beyond undergraduate studies for science and technologyX
9Is aware of the importance of safety and healthiness in the project management, workshop environment as well as related legal issues
10Have the ability for effective oral and official communication skills in Turkish Language and, at minimum, one foreign language
11Have consciousness for the results and effects of engineering solutions on the society and universe, awareness for the developmental considerations with contemporary problems of humanityX
12well-structured responsibilities in profession and ethics