COURSE INFORMATON
Course Title Code Semester L+P Hour Credits ECTS
Engineering Mechanics II (Dynamics) ME   253 3 3 3 5

Prerequisites and co-requisites
Recommended Optional Programme Components None

Language of Instruction English
Course Level First Cycle Programmes (Bachelor's Degree)
Course Type
Course Coordinator Asst.Prof.Dr. Mehmet İlteriş SARIGEÇİLİ
Instructors
Prof.Dr.VEBİL YILDIRIM1. Öğretim Grup:A
Prof.Dr.VEBİL YILDIRIM2. Öğretim Grup:A
 
Assistants
Goals
Comprehension of the general structure of dynamics of both particles and rigid bodies, and their applications in real engineering problems.
Content
Kinematics and kinetics of both particles and rigid bodies.

Learning Outcomes
1) Comprehension of both the general structure of a dynamical problem and engineering assumptions for the solution process.
2) Determination of the kinematical quantities and the relations among them in rectilinear motion of particles.
3) Applications of learning outcomes of Math I to the motion diagrams of particles in rectilinear motions.
4) Applications of learning outcomes of Math II/Integral to the rectilinear motions of particles.
5) Learning of the determination of several particles in restilinear motion.
6) comprehension ofabsolute and relative motions.
7) Comprehension of 2D/3D motions of particles in Cartesian coordinates.
8) mid-term exam
9) Comprehension of 2D/3D motions of particles in tangential-normal coordinates.
10) Comprehension of 2D/3D motions of particles in polar/cylindrical coordinates.
11) Comprehension of the general plane motion of rigid bodies.
12) application on rigid body kinematics
13) Comprehension of the application principles of Newton's second law on particles and rigid bodies.
14) reinforcement of the learning outcomes of Newton's second law with examples.
15) güncellenecektir


Course's Contribution To Program
NoProgram Learning OutcomesContribution
12345
1
Student become equipped with the basic knowledge of math, science and engineering
X
2
Students gain a command of basic concepts, theories and principles in mechanical engineering
X
3
Students are able to design and carry out experiments in the basic fields of mechanical engineering, and interpret the results and the data obtained from the experiments
X
4
Students become equipped with a variety of skills and knowledge regarding engineering techniques
X
5
Students are able to design a system, component or process in order to meet the needs of various engineering problems within technical, economic, environmental, manufacturability, and sustainability limits.
X
6
Students independently review and learn the applications in an enterprise, make a critical assessment of the problems faced with, formulate problems and propose solutions by selecting the proper technique
X
7
Students take initiative in identification, design, development and use of a product or production process.
X
8
Students become aware of the necessity of lifelong learning and continuously self-renew
X
9
Students use English effectively for technical or non-technical topics orally or in wirtten form.
X
10
Students become effective in using computer, computer-aided drafting, design, analysis, and presentation
X
11
Students have good communicatino skills with a tendency to work in teams, and are able to work effectively as a member of an interdisciplinary team
X
12
Students become aware of the technical and ethical responsibilities, as well as being inquisitive and innovative
X

Course Content
WeekTopicsStudy Materials _ocw_rs_drs_yontem
1 Introduction to Dynamics: Definition, classifications, Assumptions: particle and rigid body. previous courses Lecture
Discussion
2 Rectilinear motion of particles. Relations among the kinematical quatities. Construction of a dynamic problem. Derivative / Math I Lecture
Discussion
Drilland Practice
3 motion diagrams and their interpretetions. Graphing of functions / Math I Lecture
Drilland Practice
4 Determination of the motion of a particle when the acceleration is given as a function. Integral / Math II Lecture
Drilland Practice
Problem Solving
5 Motion of several particles. previous courses Lecture
Drilland Practice
Problem Solving
6 Absolute and relative motions of particles. Vectors Lecture
Drilland Practice
7 Curvilinear motion of particles: Cartesian coordinates. previous courses Lecture
Drilland Practice
8 Mid-Term Exam previous courses Lecture
Drilland Practice
Problem Solving
Testing
9 Curvilinear motion of patricles: Tangential and normal Coordinates previous courses Lecture
Drilland Practice
Problem Solving
10 Curvilinear motion of particles: Polar and Cylindrical coordinates. previous courses Lecture
Drilland Practice
Problem Solving
11 Kinetics of particles: Newton's second law of motion previous courses Lecture
Drilland Practice
Problem Solving
12 Examples for kinetics in different coordinates. previous courses Lecture
Drilland Practice
Problem Solving
13 Kinematics of rigid bodies: determination of rotation, translat,on and general plane motions. Statics of rigid bodies Lecture
Discussion
Drilland Practice
14 Examples for rigd body kinematics previous courses Lecture
Drilland Practice
Problem Solving
15 Kinetics of rigid bodies previous courses Lecture
Drilland Practice
Problem Solving
16-17 Term Exams previous courses Drilland Practice
Problem Solving

Recommended or Required Reading
Textbook
Additional Resources