Mechatronics Engineering

The mission of the program is to provide qualified students with a good foundation in Mechatronics Engineering in order to prepare them for a successful professional career and to contribute to the needs of society.

  • To prepare mechatronics engineering professionals with proper ethics, training, and knowledge needed to compete in local and international markets.
  • To provide graduates with proper background needed for research and graduate studies.
  • To provide graduates with proper tools needed for adaptation with the global technical and economic development and to be engaged in lifelong learning.
  1. Ability to apply mathematics, science and engineering principles.
  2. Ability to design and conduct experiments, analyze and interpret data.
  3. An ability to design a system, component, or process to meet desired needs within realistic constraints such as economic, environmental, social, political, ethical, health and safety, manufacturability, and sustainability
  4. Ability to function on multidisciplinary teams.
  5. Ability to identify, formulate and solve engineering problems.
  6. Understanding of professional and ethical responsibility.
  7. Ability to communicate effectively.
  8. the broad education necessary to understand the impact of engineering solutions in a global, economic, environmental, and societal context
  9. Recognition of the need for and an ability to engage in life-long learning.
  10. Knowledge of contemporary issues.
  11. Ability to use the techniques, skills and modern engineering tools necessary for engineering practice.

Mechatronics Engineering Fields

  • Computer-machine controls.
  • Sensors and control systems.
  • Automation and robotics.
  • Advancement of industrial technology.
  • Design and manufacturing of industrial machinery.
  • Computer aided design.
  • Microcontrollers and PLCs.
  • Automotive engineering and engine design
Study Plan

The study plan of the Mechatronics Engineering Program consists of 158 credit hours, distributed as follows:

Requirements

Credit Hours

University Requirements

19-20

Faculty Requirements

30

Program Requirements

102

Elective Courses

7-6

Total

158

 
 
,
Program Requirements (102 Credit Hours)

​Core Courses (99 Credit Hours) includes the following: 

  1. Compulsory courses (99 Credit Hours) include the following:

Course No.

Course Title

Prerequisite(s)

MATH2311

Calculus And Analytical Geometry 3

MATH1321

MATH234

Introduction to Linear Algebra

MATH1321

MATH330

Numerical Methods

MATH234, (COMP230 or COMP132, COMP142 or COMP133)

MATH331

Ordinary Differential Equations

MATH1321

ENEE2101

Basic Electrical Engineering Lab

PHYS112, ENEE2311

ENEE2311

Network Analysis 1

PHYS132

ENEE2360

Analog Electronics

ENEE2311 or ENEE2304

ENEE3103

Analog Electronics Lab

PHYS112, ENEE2360

ENEE4102

Fundamentals Of Electrical Machines Lab.

ENEE2101, ENEE4303

ENEE4303

Electrical Machines Fundamental S

ENEE2311

ENEE4401

Power Electronics and Drive

ENEE4303, ENEE2360

ENCS2110

Digital Electronics & Computer Organization Lab

ENCS238 or ENCS336 or ENCS432 or ENCS3341

ENCS2340

Digital Systems

COMP132 or COMP133 or COMP230 or COMP142

ENCS3341

Embedded Systems

ENCS2340

ENCS4101

Embedded Systems Lab.

ENCS3341

ENME2111

Mechanical Drawing

ENME1210

ENME232

Dynamics

ENCE232

ENMC3251

Statistical Analysis

MATH2311

ENMC3151

Engineering Measurement Lab

PHYS112, ENMC3251 or concurrent

ENME331

Material Science

CHEM143

ENME332

Machine Dynamics

ENME232

ENME333

Thermodynamics

PHYS141

ENMC4421

Design Of Machine Elements

ENCE232, ENME2111

ENME436

Machine Design 2

(ENME435 or ENMC4421), ENME332

ENME4380

Control Systems

MATH234,

(ENMC4310 or concurrent)

ENME537

Fluid Power Control

ENME4380, (ENME335 or ENMC4411)

ENMC3111

Computer Aided Engineering Lab.

ENME2111

ENMC4411

Thermal Fluid Engineering

ENME232, ENME333

ENMC411

Thermal Fluid Laboratory

ENMC4411

ENMC4300

Practical Training

Finishing 90 credits and Department Approval

ENMC4310

Mechanical Vibrations

ENME232, MATH331

ENMC3361

Sensors And Instrumentation

ENCS2340, ENEE2360

ENMC511

Mechatronics Laboratory

ENCS3341, (ENMC5371 or concurrent)

ENMC512

Control Laboratory

 ENMC5362 or concurrent

ENMC520

Introduction To Graduation Project

Finishing 112 credits and Department Approval

ENMC530

Graduation Project

ENMC520

ENMC5310

Advance Control Systems

ENME4380

ENMC5331

Mechatronics Systems Design

ENEE4401, ENME4380

ENMC5362

Digital Control Systems

ENCS3341, ENMC5310

ENMC5371

Industrial Automation

ENME537, ENEE4401

 

 

2. Elective Courses:
(3 credit hours from the following course):

Course Code

Course Title

Prerequisite(s)

ENMC532

Robotics

ENME332, ENME4380

ENMC534

Special Topic in Mechatronics

Department Approval

ENMC535

CAD/CAM/ CNC

(MATH330, ENMC3111) or (ENME433, MATH330)

 

ENME433

Production Engineering 1

ENME331

 
 
  1. Student must successfully complete and obtain a cumulative average of 70% or more in the following courses:

      MATH1411, MATH1321, PHYS141, PHYS132, ENME1210

  1. Department approval based on its capacity. In the case the number of applicants exceeds the enrolment capacity of the Department, only those with the highest overall competitive average grade will be admitted. The average grade will be calculated based on the grades of all course attempts.

The study plan of the Mechatronics Engineering Program consists of 158 credit hours, distributed as follows:

Requirements

Credit Hours

University Requirements

19-20

Faculty Requirements

30

Program Requirements

102

Elective Courses

7-6

Total

158