Electrical Engineering

To contribute in developing electrical and computer engineering principles and applications, and to prepare qualified and ethically responsible engineers who are capable of life-long learning, adhering to the highest professional standards, able to engage in engineering projects, and participate effectively in serving the community.

 

  • Be productive and responsible professionals in their field capable of communicating effectively with coworkers and clients.
  • Engage in lifelong learning, in a field characterized by rapid developments, including through research and graduate work.
  • Adhere to the highest ethical standards and demonstrate an involvement in professional activities and public services.
  1. An ability to apply knowledge of mathematics, science, and engineering principles.
  2. An ability to design and conduct experiments, to analyze and interpret data.
  3. An ability to design a system, component, or process to meet desired needs.
  4. An ability to function on multidisciplinary teams.
  5. An ability to identify, formulate, and solve engineering problems.
  6. An understanding of professional and ethical responsibility.
  7. An ability to communicate effectively.
  8. The broad education necessary to understand the impact of engineering solutions in a global and societal context.
  9. A recognition of the need for, and an ability to engage in life-long learning.
  10. A knowledge of contemporary issues.
  11. An ability to use the techniques, skills, and modern engineering tools necessary for engineering practice.

Planning, designing, and operating:

  • Electrical Power Systems.
  • Renewable Energy.
  • Generators, Motors and Drives.
  • Control Systems.
  • Power Electronic Systems.
  • PLC and Industrial Plants.
  • Electrical Installations.
  • Wired and Wireless Communication Systems.
  • Communication Networks.
  • Microwave, Radar, and Optical Fiber Systems.
  • Electronic and Security Systems.
  • Digital Signal Processing.
  • Computerized Systems.
  • Computer Networks.
  • Robotics.
  • Digital Systems.
  • Computer Aided Design.
  • Webpage and Database Design and Management.

The plan consists of 158 credits distributed as follows:

Requirements

Credit Hours

University Requirements

19-20

Faculty Requirements

30

Specialization Requirements

103

Free Elective Courses

6-5

Total

158

,
Specialization Requirements: 103 credits
  1. Compulsory Courses: 90 credits as follows

Course No.

Course Title

Prerequisite(s)

MATH2311

Calculus And Analytical Geometry 3

MATH1321

MATH234

Introduction to Linear Algebra

MATH1321

MATH330

Numerical Methods

MATH234, (COMP132 or COMP230 or COMP133 or COMP142)

MATH331

Ordinary Differential Equations

MATH1321

ENME232

Dynamics

ENCE232

ENME333

Thermodynamics

PHYS141

ENCS211

Digital Electronics And Computer Organization Lab

ENCS2304 or concurrent

ENCS234

Digital Systems

COMP133

ENCS238

Computer Structure and Organization

ENCS234

ENCS4308

Microprocessor and Embedded Systems

ENCS238

ENCS5101

Microprocessor and Embedded Systems Lab

ENCS4308

BUSA2302

Engineering Project Management

No Prerequisites

ENEE2102

Circuits Lab

(ENEE2305 or concurrent) , PHYS112

ENEE2301

Network Analysis 1

PHYS132

ENEE2302

Signals And Systems

MATH331

ENEE2303

Electronics 1

ENEE2301

ENEE2305

Network Analysis 2

ENEE2301, (ENEE2302 or Concurrent)

ENEE2307

Probability And Engineering Statistics

MATH1321

ENEE2408

Electrical Machines

ENEE2301

ENEE3101

Electrical Machines Lab

ENEE2102, ENEE2408

ENEE3102

Electronics Lab

PHYS112 (or concurrent ENEE3304)

ENEE3303

Principles Of Communication Systems

ENEE2302, (ENEE2307 or concurrent)

ENEE3304

Electronics 2

ENEE2303

ENEE3305

Power Electronics

ENEE2313, (ENEE2302 or concurrent)

ENEE3307

Electromechanical Principles and Applications

PHYS132

ENEE339

Communication Systems

ENEE2312, (ENEE2307 or concurrent)

ENEE3318

Electromagnetics

PHYS132, MATH2311

ENEE4104

Engineering Simulation Lab

ENEE2408, ENEE3304

ENEE4105

Control And Power Electronics Lab

ENEE4302, ENEE3305

ENEE4103

Communication Lab

ENEE3309

ENEE4202

Electrical Installation And Drawing

ENEE2301

ENEE4300

Training

Fourth year student and Department permission

ENEE4302

Control Systems 1

ENEE2305, ENEE2302

ENEE4304

Devices And Measurements

ENEE3304, (ENCS238 or concurrent)

ENEE4403

Power Systems

ENEE2408

ENEE5200

Introduction to Graduation Project

ENEE4300

ENEE5300

Graduation Project

ENEE5200, ENEE4300

 
  1. Optional courses:

13 credit hours as chosen from the following:

  1. Specialization students: have to finish all of the courses at one group (10 credit hours)

plus 3 optional credit hours from the following.

  1. General Path (No Specialization):  have to finish 16 credit hours including a lab

      (5 courses + lab) from the following:

 

Group

Course No.

Course Title

Prerequisite(s)

Group one:

Specialization of Communication

ENEE5101

Advanced Lab In Communication

ENEE4103, ENEE3401

ENEE4301

Applied Electromagnetics

ENEE3318

ENEE5304

Information And Coding Theory

ENEE3309 or ENEE339

ENEE5305

Wireless Communication

ENEE5302, ENEE3306

Group two:

Specialization of Computer

ENCS339

Operating Systems

ENCS238 or ENCS336

ENCS413

Computer Networks Lab

ENCS433 or ENCS436

ENCS436

Computer Networks

ENEE339 or ENEE3306

ENCS437

Computer Architecture

ENCS336 or ENCS238

Group three:

Specialization of Control and Power

ENEE5102

Power Electronics Lab

ENEE4403, (ENEE5303 or concurrent)

ENEE5303

Electrical Machines And Special Electrical Machines Management

ENEE2408,ENEE3305

ENEE5306

Protection And Automation In Electrical Power Systems

ENEE4403

ENEE5307

Renewable Energy And Photovoltaic Power Systems

ENEE3305,ENEE2408

Group four:

More optional Courses

ENEE5311

Special Topic In Communication Engineering

Fourth year and department approval

ENEE5312

Special Topic In Computer Engineering

Fourth year and department approval

ENEE5313

Special Topic In Power Engineering

Fourth year and department approval

ENEE5308

Control Systems 2

ENEE4302

ENCS531

Real Time And Embedded Systems

ENCS339,ENCS313

ENCS539

Special Topic In Computer Engineering

Fourth year and Department approval

  1. Student must successfully complete and obtain a cumulative average of 70% or more in the following courses: MATH1411, MATH1321, PHYS141, PHYS132, ENME121
  2. 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.