Computer Engineering
Bachelor	Length of the Programme: 4	Number of Credits: 240	TR-NQF-HE: Level 6	QF-EHEA: First Cycle	EQF: Level 6

Ders Genel Tanıtım Bilgileri

School/Faculty/Institute

Faculty of Engineering

Course Code

DYN 201

Course Title in English

Engineering Mechanics: Dynamics

Course Title in Turkish

Mühendislik Mekaniği: Dinamik

Language of Instruction

Type of Course

Flipped Classroom,Project

Level of Course

Introductory

Semester

Fall

Contact Hours per Week

Lecture: 4

Recitation: -

Lab: -

Other: -

Estimated Student Workload

145 hours per semester

Number of Credits

6 ECTS

Grading Mode

Standard Letter Grade

Pre-requisites

Expected Prior Knowledge

None

Co-requisites

PHYS 101 - Physics I | PHYS 103 - Physics I

Registration Restrictions

Only Undergraduate Students

Overall Educational Objective

To learn the dynamics principles of accelerated motion of particles & rigid bodies, taking into account the geometric aspects of the motion in two dimensions as well as the forces causing the motion by using Newton’s second law, work-energy & impulse-momentum methods.

Course Description

This course provides the fundamental aspects of dynamics, covering the following topics: Kinematics of a particle: Rectilinear and curvilinear motion in rectangular, normal-tangential and polar coordinates. Planar kinematics of rigid bodies: Absolute/relative motion, instantaneous center of velocity, motion relative to rotating axes. Planar kinetics of particles: The force-mass-acceleration method. Work-energy and impulse-momentum relations. Planar kinetics of rigid bodies and the work-Energy method. Free and forced vibrations of particles and rigid bodies.

Course Description in Turkish

Bu ders dinamiğin temel kavramlarını içermektedir ve şu konuları kapsamaktadır: Parçacık kinematiği: Kartezyen, normal-teğetsel ve kutupsal koordinatlarda doğrusal ve eğrisel hareket. Katı cisimlerin düzlemsel kinematiği: Mutlak/bağıl hareket, anlık hız merkezi, dönen eksenlere göre hareket. Parçacıkların düzlemsel kinetiği: Kuvvet-kütle-ivme metodu. İş-enerji ve impals-momentum ilişkileri. Katı cisimlerin düzlemsel kinetiği ve iş-enerji metodu. Parçacıkların ve katı cisimlerin serbest ve zorlanmış titreşimleri.

Course Learning Outcomes and Competences

Upon successful completion of the course, the learner is expected to be able to:
1) solve kinematic problems of a particle and rigid bodies;
2) solve kinetic problems of a particle and rigid bodies;
3) solve free and forced vibration problems of particles and rigid bodies;
4) design, analyze and implement an either a mass-spring-damper vibration system with tuned-mass damper or a mechanism applied to a real-life machine such as an excavator, crane, etc;
5) communicate and collaborate on a team, setting goals, accomplishing tasks, and meeting deadlines to develop a project and professionally write its final report;
6) self-learn and apply new knowledge by his/her own means as a valuable life-long learning skill.

Program Learning Outcomes/Course Learning Outcomes	1	2	3	4	5	6
1) An ability to identify, formulate, and solve complex engineering problems by applying principles of engineering, science, and mathematics
2) An ability to apply engineering design to produce solutions that meet specified needs with consideration of public health, safety, and welfare, as well as global, cultural, social, environmental, and economic factors
3) An ability to communicate effectively with a range of audiences
4) An ability to recognize ethical and professional responsibilities in engineering situations and make informed judgments, which must consider the impact of engineering solutions in global, economic, environmental, and societal contexts
5) An ability to function effectively on a team whose members together provide leadership, create a collaborative and inclusive environment, establish goals, plan tasks, and meet objectives
6) An ability to develop and conduct appropriate experimentation, analyze and interpret data, and use engineering judgment to draw conclusions
7) An ability to acquire and apply new knowledge as needed, using appropriate learning strategies.

Relation to Program Outcomes and Competences

N None	S Supportive	H Highly Related

	Program Outcomes and Competences	Level	Assessed by
1)	An ability to identify, formulate, and solve complex engineering problems by applying principles of engineering, science, and mathematics	H	Exam,HW,Participation,Project
2)	An ability to apply engineering design to produce solutions that meet specified needs with consideration of public health, safety, and welfare, as well as global, cultural, social, environmental, and economic factors	S	Project
3)	An ability to communicate effectively with a range of audiences	N
4)	An ability to recognize ethical and professional responsibilities in engineering situations and make informed judgments, which must consider the impact of engineering solutions in global, economic, environmental, and societal contexts	N
5)	An ability to function effectively on a team whose members together provide leadership, create a collaborative and inclusive environment, establish goals, plan tasks, and meet objectives	S	Project
6)	An ability to develop and conduct appropriate experimentation, analyze and interpret data, and use engineering judgment to draw conclusions	N
7)	An ability to acquire and apply new knowledge as needed, using appropriate learning strategies.	S	Project

Prepared by and Date	DANTE DORANTES , November 2023
Course Coordinator	DANTE DORANTES
Semester	Fall
Name of Instructor	Prof. Dr. DANTE DORANTES

Course Contents

Week	Subject
1)	Kinematics of a particle: Components of velocity & acceleration in rectilinear motion.
2)	Components of velocity & acceleration in curvilinear motion.
3)	Natural, polar & cylindrical coordinates of curvilinear motion.
4)	Relative motion, constrained motion, and degrees of freedom.
5)	Kinematics of planar rigid bodies: Motion about a fixed axis/rotating axes, general motion, relative velocity/acceleration.
6)	Instantaneous center of rotation, Coriolis acceleration.
7)	Kinetics of a particle: Newton’s second law, equation of motion; linear & angular momentum, conservation of angular momentum.
8)	Work of a force, principle of work & energy, power & efficiency.
9)	Potential energy, conservation of energy, central forces.
10)	Principle of impulse of force, linear momentum, angular impulse & angular momentum.
11)	Kinetics of planar rigid bodies: Mass moment of inertia, parallel-axis theorem; general plane motion, angular momentum and moment equation; translation, fixed-axis rotation.
12)	General planar motion; constrained/unconstrained motion, and system of interconnected rigid bodies.
13)	Introduction to vibrations & time response: Particle/rigid free vibrations.
14)	Introduction to vibrations & time response: Rigid forced vibrations.

Required/Recommended Readings

• Engineering Mechanics: Dynamics. SI Version. J.L. Meriam, L.G. Kraige. John Wiley & Sons, Inc. 7th edition 2013, ISBN 9781118083451 (textbook) Other references: • Vector Mechanics for Engineers: Dynamics, SI, 12th Edition. Ferdinand P. Beer, E. Russell Johnston, Phillip J. Cornwell, Brian Self, McGraw-Hill 2020, 9813157860, 9789813157866 • Mechanics for Engineers: Dynamics. SI Edition. Russell C. Hibbeler & Kai Beng Yap. Pearson Education, 13th edition 2013, ISBN: 9789810692612; • Solving Dynamics Problems in MATLAB by Brian Harper to accompany • Solving Problems in Dynamics and Vibrations Using MATLAB, Parasuram Harihara & Dara W. Childs, New Age Intern. Publishers, 2007; • Solving Vibration Analysis Problems Using MATLAB, Rao V. Dukkipati, New Age Intern. Publishers, 2007 • An Engineer's Guide to MATLAB with Applications from Mechanical, Aerospace, Electrical, Civil, and Biological Systems Engineering, Prentice Hall, 3rd Edition, 2011

Teaching Methods

Flipped classroom

Homework and Projects

Project: Dynamic design, analysis and implementation of an either a mass-spring-damper vibration system with tuned-mass damper or a mechanism applied to a real-life machine such as an excavator, crane, etc.

Laboratory Work

None

Computer Use

MATLAB software

Other Activities

None

Assessment Methods

Assessment Tools	Count	Weight
Application	11	% 15
Homework Assignments	6	% 15
Project	1	% 30
Midterm(s)	2	% 40
TOTAL		% 100

Course Administration

dorantesd@mef.edu.tr
0212 395 36 40
Assessment: Flipped classroom practice (FCP) activities are conducted during online class time (20-40 min), by solving a similar previously solved exercise, but working in randomly formed teams, and emailing their solution photo to the instructor by the end of the class. The FCP evidence will be the only way to count student class attendance. Rules for attendance: attendance is taken during Flipped Classroom Practice. A minimum of 70% of attendance is mandatory. Rules for Flipped Classroom Practice: Missed Flipped Classroom Practice will be given a zero grade. Participation quizzes with flaws or lack of individual collaboration attitude during team work will be given a grade of one. Successful flipped classroom participation will be given a grade of two. Rules for late submission of the project: It will be discounted 20/100 by each delayed day. Rules for missing a midterm: Provided that a valid justification is approved by the university and presented, a make-up exam will be granted one week after the regular midterm date. Minimum grade to be allowed to pass the course: Satisfactory Project, Laboratory reports, and at least 70% attendance are mandatory to be allowed to pass the course. A reminder of proper classroom behavior, code of student conduct: YÖK Regulations Statement on plagiarism: YÖK Regulations http://www.mef.edu.tr/Yonetmelikler

ECTS Student Workload Estimation

Activity	No/Weeks	Hours			Calculation
	No/Weeks per Semester	Preparing for the Activity	Spent in the Activity Itself	Completing the Activity Requirements
Course Hours	22	0	2	1	66
Application	4	0	0.5	0.5	4
Project	3	3	14		51
Midterm(s)	2	10	4		28
Total Workload					149
Total Workload/25					6.0
ECTS					6