The degree provides professional training in Electrical Engineering to enhance expertise of existing and future Electrical professionals through a curriculum that incorporates technical knowledge along with professional skills and stance necessary to function in academic, industries and applied setting. Through this program, a research-led environment will be created where students work with leading researchers to develop the skills required becoming Electrical professionals or conducting further research as PhD students.
The goals and objectives of the graduate program in Electrical Engineering are to prepare graduate students for careers in professional practice, research, and for further study towards doctoral degrees in Electrical Engineering. The EE Program will allow motivated researchers to expand their knowledge and acquire new skills in analysis and problem solving, creating challenging opportunities for a full, rewarding research career. The program will also cater the demands and needs of local industry and strategic research and development (R&D) organizations of the country. This graduate program will impart:
- Knowledge of the engineering principles
- Knowledge of current events and contemporary societal issues
- Knowledge of the state-of-the-art Information Technologies
- The broad education necessary to understand the impact of engineering solutions in a global, economic, environmental and societal context
- Facilitate systems engineering and project management
- Ability to communicate effectively (written, verbal and presentation) across all levels in the enterprise
- Ability to grow through life long acquisition of knowledge
- 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
- Ability to identify, formulate, and solve Electrical Engineering problems
- Ability to function in multidisciplinary teams
- Capability to use state-of-art engineering/computer tools necessary for engineering practice or research
- Skills to find and use available technical information
- Ability to communicate effectively in written reports
- Ability to design and conduct experiments, tests or simulations as well as to analyze and interpret data to validate assumptions and hypotheses
- Ability to evaluate current electrical engineering techniques
Entry Requirements
- A minimum of 16 years of education leading to BS/BE/BSc in Electrical/Electronics/Telecomm /Computer Engineering or equivalent. Applicants with undergraduate degree from non-relevant areas may be required to take some undergraduate courses to fulfill pre-requisite deficiencies as determined by the Graduate Admission Committee. The deficiency Cr. Hrs. will not be counted towards the minimum Cr. Hrs. requirement for the award of the MS degree.
- MSc Electronics and MS Physics are also eligible.
- Minimum 2.00/4.00 CGPA or 50% marks.
- Valid GRE Test score of at least 50% at the time of admission or 50% marks in the University entrance test as per HEC Approved Test.
- FUI interview.
Degree Requirement
Thesis and Non-Thesis Option: A student admitted in this program will have to complete the degree requirements by following any one of the options given below:
|
|
Area |
Cr. Hrs. |
|
a) |
24 Cr. Hrs course work with 6 Cr. Hrs Thesis |
30 |
|
b) |
Course work only (10 Courses) |
30 |
A student can choose subjects from the mentioned fields to complete the course work.
a. Control and Embedded Systems
|
Code |
Title |
CHs |
|
|
EE |
871 |
Linear Control Systems |
3 |
|
EE |
872 |
Optimal Control |
3 |
|
EE |
873 |
Fuzzy Control |
3 |
|
EE |
874 |
Adaptive Control |
3 |
|
EE |
875 |
Discrete Time Control Systems |
3 |
|
EE |
876 |
Probabilistic Robotics |
3 |
|
EE |
877 |
Mobile Robotics |
3 |
|
EE |
878 |
System Identification |
3 |
|
EE |
879 |
Robust Control |
3 |
|
EE |
970 |
Advanced Robotics |
3 |
|
EE |
971 |
Modeling & Simulation of Dynamic Systems |
3 |
|
EE |
972 |
Advanced Digital Control Systems |
3 |
|
EE |
973 |
Control System Optimization |
3 |
|
EE |
974 |
Networked & Embedded Control Systems |
3 |
|
EE |
975 |
Robust & Multivariable Control |
3 |
|
EE |
976 |
Optimal & Multivariable Control |
3 |
|
EE |
977 |
Nonlinear Control Systems |
3 |
|
EE |
979 |
Selected Topics in Control Systems |
3 |
|
EM |
800 |
Robotics - 1 |
3 |
|
EM |
805 |
Robotics - 2 |
3 |
|
MTS |
800 |
Advanced Robotics I |
3 |
|
MTS |
801 |
Advanced Robotics II |
3 |
|
MTS |
840 |
Data Acquisition and Control |
3 |
|
ME |
837 |
Nonlinear Dynamics |
3 |
b. Electronics, Communications and Computing
|
Code |
Title |
CHs |
|
|
EE |
801 |
Semiconductor Device Physics |
3 |
|
EE |
802 |
Quantum Mechanics |
3 |
|
EE |
803 |
Physical Electronics |
3 |
|
EE |
804 |
Photonic Devices |
3 |
|
EE |
805 |
Semiconductor Processing |
3 |
|
EE |
806 |
Thin Film Processing |
3 |
|
EE |
807 |
Thin Film Characterization |
3 |
|
EE |
808 |
Digital Integrated Circuit Design |
3 |
|
EE |
809 |
Analog Integrated Circuit Design |
3 |
|
EE |
900 |
Optoelectronic Devices & Materials |
3 |
|
EE |
901 |
Power Electronics & Electric Drives |
3 |
|
EE |
902 |
Nano-Electronics |
3 |
|
EE |
903 |
Advanced Semiconductor Device Theory |
3 |
|
EE |
904 |
Microchip Fabrication Technology |
3 |
|
EE |
905 |
Advanced Power Electronics |
3 |
|
EE |
906 |
Solid State Electronics |
3 |
|
EE |
907 |
Micro & Nano Fabrication |
3 |
|
EE |
908 |
Ultra High Speed Nano electronic Devices |
3 |
|
EE |
909 |
Selected Topics in Electronics |
3 |
|
EE |
501 |
Optimization Theory |
3 |
|
EE |
502 |
Advanced Computer Networks |
3 |
|
EE |
503 |
Image and Video Processing |
3 |
|
EE |
504 |
Array Signal processing |
3 |
|
EE |
505 |
Advanced Wireless Communication |
3 |
|
EE |
506 |
Artificial Intelligence |
3 |
c. Power systems
|
Code |
Title |
CHs |
|
|
EE |
861 |
Alternating Current Electrical Machines and Drives |
3 |
|
EE |
862 |
Power System Operation & Control |
3 |
|
EE |
863 |
Power System Analysis |
3 |
|
EE |
864 |
Advanced Machines |
3 |
|
EE |
865 |
Power Generation Operation & Control |
3 |
|
EE |
866 |
Power System Stability and Control |
3 |
|
EE |
867 |
Power Generation Economics |
3 |
|
EE |
868 |
Advanced Smart Grid |
3 |
|
EE |
869 |
Advanced Power System Transmission |
3 |
|
EE |
960 |
Power Quality |
3 |
|
EE |
961 |
Energy Management |
3 |
|
EE |
962 |
Integration of Green Energy sources with power system |
3 |
|
EE |
963 |
Optimization techniques in power systems |
3 |
|
EE |
964 |
Photovoltaic Systems |
3 |
|
EE |
965 |
Advanced Renewable Energy Systems |
3 |
|
EE |
966 |
High voltage DC Transmission System |
3 |
|
EE |
967 |
Computational methods in power system analysis |
3 |
|
EE |
968 |
Power System Transients |
3 |
|
EE |
969 |
Selected Topics in Power Systems |
3 |
d. Communication/ Telecommunication/ Networking
|
Code |
Title |
CHs |
|
|
EE |
851 |
Advanced Digital Communication Systems |
3 |
|
EE |
852 |
Information & Coding Theory |
3 |
|
EE |
853 |
Advanced Wireless Communication |
3 |
|
EE |
854 |
Optical Communication Systems |
3 |
|
EE |
855 |
Error Control Coding |
3 |
|
EE |
856 |
Software Defined Radio |
3 |
|
EE |
857 |
Advanced Satellite Communication Systems |
3 |
|
EE |
858 |
Communication Project Management |
3 |
|
EE |
859 |
Performance Analysis of Communication Networks |
3 |
|
EE |
950 |
Advanced Data Communication Systems |
3 |
|
EE |
951 |
Radar Systems |
3 |
|
EE |
952 |
Optimization theory |
3 |
|
EE |
953 |
Cellular and mobile communications |
3 |
|
EE |
954 |
Advanced concepts in radar systems |
3 |
|
EE |
955 |
Cyber security |
3 |
|
EE |
956 |
Digital image processing |
3 |
|
EE |
957 |
Modeling and simulation |
3 |
|
EE |
958 |
Smart grid |
3 |
|
EE |
959 |
Selected Topics in Communication Systems |
3 |
|
EE |
812 |
RF Communication System Design |
3 |
|
EE |
702 |
Advanced Computer Networks |
3 |