B.sc. in Electrical Engineering_studyplan

7/31/2019 B.sc. in Electrical Engineering_studyplan

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ELECTRICAL ENGINEERING DEPARTMENT

Undergraduate Study Plan

A minimum of 159 semester credit hours are required to obtain the B.Sc. degree in Electrical

Engineering. These requirements are as follows:

1. The student must abide by the conditions stated in the regulations for the award of the B.Sc.degree in the Jordan University of Science and Technology which is decreed by theUniversity Council of Deans in accordance with the bylaw of 1987 for the award of scientific

degrees

2. University Requirements of Basic Sciences:

These comprise 25 credit hours divided into:

i) Core courses: (16 credit hours)

Arab 101, Arab 103, Engl 111, Engl 112, CS 100, MS 100 +

ii) Elective courses:(9 credit hours) to be chosen from courses as detailed under Program of

study and Degree Requirements

3. Faculty Requirements:

These comprise 29 credit hours as follows:

Math 101, Math 102, Math 201, Math 203, Phys 101, Phys 102, Phys 107, Chem 101 , Chem

102, Chem 107, CS 115

4. Department Requirements:

These comprise 105 credit hours divided as follows:

4.1 Department Core Courses:

These courses comprise 73 credit hours and as follows:

a) Basic Engineering Sciences: (8 Credit Hours)

ME 161, ME 215, ME 261, EE 200

b) Probability, Mathematics, Numerical Analysis: (12 Credit Hours)

EE 204, EE 300, EE 301, EE 302

c) Electromagnetics: (6 Credit Hours)

EE 207, EE 307

d) Circuits: (7 Credit Hours)

EE 210, EE 214, EE 316

e) Electronics: (11 Credit Hours)

EE 220, EE 320, EE 322, EE 420, EE 422

f) Instrumentation and Measurement: (3 Credit Hours)

EE 324, EE 426

+ Required from all Jordanian students, graded on Pass/Fail basis. Non Jordanian students should register for analternative elective course of their choice

* Those who passed the Jordanian General Secondary Certificate examination related to these courses will beexempted


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g) Power and Machines: (7 Credit Hours)

EE 332, EE 336, EE 337

h) Communications: (4 Credit Hours)

EE 450, EE 452.

i) Computers: (7 Credit Hours)CIE 254, CIE 255, CIE 353

j) Control Systems: (4 Credit Hours)

EE 412, EE 416.

k) Graduation Projects: (4 Credit Hours)

EE 591, EE 592.

4.2 Specialization Packages:

The student selects one of two specialization packages offered by the department. Each

package consists of 23 credit hours divided into:(17) Credit hours specialization core courses.

(6) Credit hours specialization elective courses.

designed to provide enough depth in a particular area. More experience in the

specialization can be gained through the graduation project. The specialization packages

are:

A)Communications and Electronics Option:

i) Core Courses:

EE 451, EE 455, EE 527, EE 528, EE 529, EE 552, EE 553, EE591A, EE592A.ii) Elective Courses:

a)Communications:EE 512, EE 550, EE 554, EE 555, EE 556, EE 557, EE 558, EE 559.

b)Electronics:EE 520, EE 521, EE 522, EE 523, EE 524.

c)Electromagnetic:EE 506, EE 507, EE 508.

B) Power and Machines Option:

i) Core Courses:

EE 430, EE 431, EE 531, EE 532, EE 533, EE 534, EE 535, EE591B, EE592B.

ii) Elective Courses:

EE 530, EE 536, EE 537, EE 538, EE 539.

4.3 Department Elective Courses:

The student in each option is required to complete an additional 6 credit hours from the

elective courses of his/ her option or from courses in other options and/or courses from

the Computer or the Biomedical engineering departments of level 400 and above aftertaking the consent of the head of department.


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4.4 Engineering Practice: EE 490 (3 Credit Hours)

Not less than 8 weeks to be taken, in the summer semester, after finishing 120 credit

hours.

Course Numbering

To facilitate course numbering, the second digit in a course number is related to the area as

follows:

0: Electromagnetics or General Electrical Engineering

1: Circuits or Control systems

2: Electronics

3: Power and Machines

4: Digital Systems and Circuits

5: Communication Circuits and Systems

6: Computer Systems, Programming and Applications

7: Communications and Electronics Applications

8: Special Topics

9: Projects and Seminars

The following notation will be also used:

C: Credit Hours

H: Lecture Hours

L: Laboratory Hours


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COURSE # COURSE TITLE C.H. PRE-REQUISITE

EE 200 Engineering Drawing 1 CS 100

EE 204 Linear Algebra 3 Math 201, CS 100

EE 207 Electromagnetics I 3Phys 102, Math 201, Math

203(COR)

EE 210 Circuits I 3 Phys 102, Math 203 (COR)

EE 212 Circuits (Non EE) 3 Phys 102, Math 203 (COR)EE 214 Circuits II 3 EE 210

EE 220 Electronics I 3 EE 210

EE 300 Signals and Systems Analysis 3 EE 204, EE 214

EE 301 Applied Probability Theory 3 EE 300

EE 302 Numerical Analysis 3 EE 204, CS 115

EE 303 Principles of Elect. Eng. (Non EE) 3 Phys 102, Math 102

EE 304 Electric Drives (Non EE) 3 EE 303

EE 306 Electrical Engineering Lab. (Non EE) 1 EE 304

EE 307 Electromagnetics II 3 EE 207

EE 316 Circuits Lab. 1 EE 214

EE 320 Electronics II 3 EE 220

EE 321 Electronics I (Non EE) 3 EE 303EE 322 Electronic Circuits Lab. 1 EE 316, EE 320

EE 324 Instrumentations & Measurements 2 EE 320

EE 325 Electronics I (For Biomedical Engineering) 3 EE 212

EE 327 Electronics II (For Biomedical Engineering 3 EE 325

EE 332 Electrical Machines I 3 EE 207, EE 214

EE 336 Electrical Machines Lab. I 1 EE 332

EE 337 Power Systems 3 EE 204, EE 332

EE 412 Control Systems 3 EE 300

EE 416 Control Systems Lab. 1 EE 412

EE 420 Digital Electronic Circuits 3 EE 320

EE 422 Digital Electronic Circuits Lab. 1 EE 420

EE 426 Instrumentations & Measurements Lab. 1 EE 324EE 430 Power Systems Analysis 3 EE 337

EE 431 Electrical Machines II 3 EE 332

EE 450 Principles of Communication Systems 3 EE 301

EE 451 Digital Communications 3 EE 450

EE 452 Communication Lab. 1 EE 450

EE 455 Digital Filters 3 EE 300

EE 490 Engineering Practice 3 After completing 120 C.H.

EE 506 Antennas 3 EE 307

EE 507 Radio Wave Propagation 3 EE 307

EE 508 Electromagnetic Interference and Compatibility 3 EE 307, EE 450

EE 512 Digital Control 3 EE 412

EE 520 VLSI Design 3 EE 320, CIE 254EE 521 Solid State Electronic Devices 3 EE 320

EE 522 Optoelectronics 3 EE 320

EE 523 Advanced Electronic Circuits 3 EE 420

EE 524 Integrated Circuits 3 EE 420

EE 525 Electronics II (Non EE) 3 EE 321

EE 527 Communication Electronics 3 EE 420, EE 450

EE 528 Microwave Electronics 3 EE 307, EE 320

EE 529 Microwave Lab. 1 EE 528

EE 530 Power Systems Protection 3 EE 337

EE 531 Electric Drives 3 EE 431

EE 532 Power Electronics 3 EE 320, EE 332

EE 533 Power Transmission and Distribution 3 EE 337EE 534 Power Systems Lab. 1 EE 430, EE 533

EE 535 Electrical Machines Lab. II 1 EE 336, EE 431

EE 536 Power Systems and Power Electronics 3 EE 430, EE 532


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EE 537 Switched Mode Converters 3 EE 532

EE 538 High Voltage Engineering 3 EE 430

EE 539 New Electrical Machines 3 EE 431

EE 550 Digital Signal Processing 3 EE 455

EE 552 Digital Communication Lab. 1 EE 451

EE 553 Communication Systems 3 EE 451

EE 554 Computer Communication Networks 3 EE 451

EE 555 Optical Fiber Communication Systems 3 EE 451EE 556 Radar Systems 3 EE 307, EE 450

EE 557 Television Systems 3 EE 450

EE 558 Satellite Communication Systems 3 EE 451

EE 559 Mobile Communication Systems 3 EE 451

EE 580A Special Topics in Electrical Engineering 3

EE 580B Special Topics in Electrical Engineering 2

EE 580C Special Topics in Electrical Engineering 1

EE 591 Graduation Project I 1

EE 592 Graduation Project II 1 EE 490, EE 591

First Year

First Semester

COURSE # COURSE TITLE C.H.

Math 101 Calculus I 3

CS 100 Introduction to Computers 3

Phys 101 General Physics I 3

Chem 101 General Chemistry I 3

Arab 103 Arabic language 3

Engl 111 English I 3

Total 18

Second Semester


Math 102 Calculus II 3

Phys 102 General Physics II 3

Phys 107 General Physics Lab. 1

Chem 102 General Chemistry II 3

Chem 107 General Chemistry Lab. 1

Arab 103 Arabic Lab. 1

Engl 112 English II 3

MS 100 Military Science 3

Total 18

Those who passed the Jordanian General Secondary Certificate examination related to these courses will beexempted


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Second Year

First Semester


Math 201 Intermediate Analysis 3

Math 203 Differential Equations 3

ME 161 Engineering Workshops 2

EE 200 Engineering Drawing 1

EE 210 Circuits I 3

CS 115 The C++ Programming Language 3

Total 15

Second Semester


ME 215 Engineering Mechanics 3

EE 204 Linear Algebra 3

EE 207 Electromagnetics I 3

EE 214 Circuits II 3

EE 220 Electronics I 3

CIE 254 Digital Logic Design and Computer Architecture 3

Total 18

Third Year

First Semester


EE 316 Circuits Lab. 1

EE 300 Signals and Systems Analysis 3

EE 307 Electromagnetics II 3EE 320 Electronics II 3

EE 332 Electrical Machines I 3

CIE 255 Digital Logic Design Lab. 1

University Elective 3

Total 17

Second Semester


EE 301 Applied Probability Theory 3

EE 302 Numerical Analysis 3

EE 322 Electronic Circuits Lab. 1

EE 324 Instrumentations & Measurements 2

EE 336 Electrical Machines Lab. I 1

EE 337 Power Systems 3

CIE 353 Microprocessors Systems 3

ME 261 Engineering Economics 2

Total 18

Fourth Year - Communication & Electronics

First Semester


EE 412 Control Systems 3EE 420 Digital Electronic Circuits 3

EE 450 Principles of Communication Systems 3


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EE 455 Digital Filters 3


Total 15

Second Semester


EE 416 Control Systems Lab. 1EE 422 Digital Electronic Circuits Lab. 1

EE 426 Instrumentations & Measurements Lab. 1

EE 451 Digital Communications 3

EE 452 Communication Lab. 1

Department Elective 3


Total 13

Summer Semester

EE 490 Engineering Practice: Not less than 8 weeks to be taken in accredited establishments.

Fifth Year - Communication & ElectronicsFirst Semester


EE 528 Microwave Electronics 3

EE 552 Digital Communication Lab. 1

EE 553 Communication Systems 3


Specialization Elective 3


Total 14

Second Semester


EE 527 Communication Electronics 3

EE 529 Microwave Lab. 1

EE 592 Graduation Project II 3


Total 10

Fourth Year - Power and Machines

First Semester


EE 412 Control Systems 3

EE 420 Digital Electronics Circuits 3

EE 430 Power Systems Analysis 3

EE 450 Principles of Communication Systems 3


Total 15

Second Semester


EE 416 Control Systems Lab. 1EE 422 Digital Electronics Circuits Lab. 1

EE 426 Instrumentations & Measurements Lab. 1

EE 431 Electrical Machines II 3


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EE 452 Communication Lab. 1



Total 13

Summer Semester

EE 490 Engineering Practice: Not less than 8 weeks to be taken in accredited establishments.

Fifth Year - Power and Machines

First Semester


EE 532 Power Electronics 3

EE 533 Power Transmission and Distribution 3

EE 535 Electrical Machines Lab. II 1




Total 14

Second Semester


EE 531 Electric Drives 3

EE 534 Power Systems Lab. 1

EE 592 Graduation Project II 3


Total 10


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Course Description

EE 200: Engineering Drawing (1C, 3H)

Orthographic and isometric drawing and sketching using computer drafting packages. This

includes an introduction to the CAD packages and applications relevant to the electrical

engineering

Pre: Math 111

EE 204: Linear Algebra (3C, 3H)

Gaussian elimination; the theory of simultaneous linear equations; orthogonal projections and

least squares; determinants; eigenvalues and eigenvectors; computer applications

Pre: Math 111,Math 201 and Math 203

EE 207: Electromagnetic I (3C, 3H)

Vector analysis. Electrostatic fields. Magnetostatic fields. Solution of Laplaces and Poissons

equations. Faradays law and applications

Pre: Phys 103, Math 201 and Math 203

EE 210: Circuits I (3C, 3H)

Units and definitions; experimental laws and simple circuits; useful techniques of circuit

analysis; inductance and capacitance; source-free RL and RC circuits; application of the unit-

step forcing function; The RLC circuits; the sinusoidal forcing function; the phasor concept;

the sinusoidal steady-state response

Pre: Phys 103; Math 203 (COR)

EE 212: Circuits (3C, 3H)

(Non EE-students)

Basic concepts and Units; useful techniques of circuit analysis; inductance and capacitance

responses including: RC, RL and RLC circuits; sinusoidal forcing function; phasor concept;

sinusoidal steady states; average power and RMS values

Pre: Phys 103; Math 203 (COR)

EE 214: Circuits II (3C, 3H)

Average power and RMS values; polyphase circuits; Laplace transform theory and

application; complex frequency; frequency response; magnetically coupled circuits; general

two-port networks; state-variable analysis

Pre: EE 210EE 220: Electronics I (3C, 3H)

Semiconductor materials; intrinsic, N-type and P-type semiconductors; carriers; density of

state and Fermi function; distribution of carriers; conductivity and drift current; diffusion

current; Einstein relationship; PN junction; depletion region characteristics; forward and

reverse biasing; I-V relationship; diode circuits and applications; bipolar junction transistor:

theory, dc biasing, symmetrical swing; field-effect transistor: theory, dc biasing, symmetrical

swing

Pre: EE 210

EE 300: Signals and Systems Analysis (3C, 3H)Concepts of linear time invariant systems; discrete and continuous time systems; application

of Laplace and Fourier transforms to linear systems; Z-transform; system function; frequency


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response and simulation in the frequency domain; discrete Fourier series and fast Fourier

transform; computer applications

Pre: EE 204,EE 214

EE 301: Applied Probability Theory (3C, 3H)

Probability principles and set theory; random variables and operations performed on random

variables, various distribution functions; random processes from the view-point of temporaland spectral characterization; response of linear time-invariant systems to random inputs

Pre: EE 300

EE 302: Numerical Analysis (3C, 3H)

Machine epsilon; round-off error; linear systems of equations; Gauss elimination and iterative

methods; largest eigenvalue using power methods; spline interpolation; numerical integration;

ordinary differential equations; nonlinear equations; zeros of polynomials; one dimensional

optimization; least squares data fitting; singular value decomposition; uniform random

number generator

Pre: EE 204, CIS 115

EE 303: Principles of Electrical Engineering (3C, 3H)

(Non EE-students)

Electrical quantities; circuit principles; DC analysis; AC analysis; polyphase circuits;

transformers; semiconductor diodes; bipolar transistors; field effect transistors; thyristors;

operational amplifiers

Pre: Phys 103, Math 103

EE 304: Electric Drives (3C, 3H)

(Non EE-students)

Introduction to electric drives; DC drives; AC drives: induction motors, synchronous motors,

reluctance and stepping motors; servomotor drives

Pre: EE 303

EE 306: Electrical Engineering Lab. (1C, 3L)

(Non EE-students)

DC circuits, diodes, transistors, thyristors and operational amplifiers; transformers; dc motors;

synchronous motors; three-phase and single phase induction motors

Pre: EE 304EE 307: Electromagnetic II (3C, 3H)

Maxwells equations; transmission lines; plane waves: propagation, reflection and refraction;

wave-guides and cavities; introduction to antennas

Pre: EE 207

EE 316: Circuits Lab. (1C, 3L)

Resistors and resistive circuits; potentiometers; superposition principle; Thevenins theorem

and maximum power transfer; RLC current and voltage characteristics; frequency response of

RL, RC and RLC circuits; series and parallel resonant circuits; transient response

Pre: EE 214

EE 320: Electronics II (3C, 3H)


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Small signal analysis of BJT and FET amplifiers; multistage amplifiers; frequency response

of single and multistage amplifiers; Darlington pair amplifiers; differential amplifiers;

operational amplifier theory; slew rate, offset and frequency response of operational

amplifiers; application of operational amplifiers: summation, subtraction, integration and

differentiation; oscillators

Pre: EE 220

EE 321: Electronics I (3C, 3H)

(Non EE-student)

Diode circuit analysis (DC&AC), bipolar junction transistors: theory, circuits and

applications; field effect transistors: theory, circuits and application; introduction to

operational amplifiers and applications

Pre: EE 303

EE 322: Electronic Circuits Lab. (1C, 3L)

Frequency response of CE, CB, CC, CS, & CD amplifiers; multistage amplifiers; cascade CE-

CE, cascade CE-CC, cascade CB-CE; RC and direct coupled amplifiers; Darlingtonamplifiers; differential amplifiers; emitter coupled amplifiers; operational amplifiers

familiarization; applications of inverter and non-inverter, differentiator and integrator;

oscillators

Pre: EE 316, EE 320

EE 324: Instrumentation & Measurements (2C, 2H)

Units, dimensions, and standards; measurement errors; displacement transducers; temperature

transducers; photoelectric transducers; electromechanical instruments; analogue electronic

multi-meters; digital multi-meters; oscilloscopes; power measurements; dc power supplies

Pre: EE 320

EE 325: Electronics I (3C, 3H)

(Biomedical Engineering students)

Semiconductor materials; intrinsic, N-type and P-type semiconductors; drift and diffusion

currents; P-N junctions; I-V characteristics; diode circuits and applications; BJT concepts and

operation; I-V characteristics; CE, CB and CC configurations; dc biasing and small-signal

analysis; JFET and MOSFET concepts and operation; biasing, CS, CG and CD

configurations; dc and small-signal analysis

Pre: EE 212


(Biomedical Engineering students)

Multistage amplifiers; frequency response; operational amplifiers and applications;

oscillators; comparators; Schmitt triggers; BJT and FET switches; transistor logic gates; MOS

logic gates; multivibrators; D/A and A/D conversion

Pre: EE 325

EE 332: Electrical Machines I (3C, 3H)

Construction and principle of operation of transformers, ideal and non-ideal transformers,

performance characteristics of transformers: three-phase transformer connections, auto-instrument transformer; three-winding transformers, DC machines construction and

classification, performance equations, generator characteristics, motor characteristics, starting


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and control of motors; synchronous machines construction, synchronous generator and motor

operation; three-phase induction motors construction and operation, performance calculations,

starting and speed control; single phase induction motors; small synchronous motors;

universal motor

Pre: EE 207, EE 214

EE 336: Electrical Machines Lab. I (IC, 3L)Transformers; DC motors; DC generators; three -phase induction motors; single-phase

induction motor, three-phase synchronous generator and motor; single-phase synchronous

generator and motors; AC series motor

Pre: EE 216, EE 332

EE 337: Power Systems (3C, 3H)

Basic Concepts and Per Unit Impedances; Phase shift in transformers; Series impedance of

transmission lines; Capacitance of transmission lines; Current and voltage relations of a

transmission lines; Admittance model and network calculations; Impedance model and

network calculations; Power flow solutionsPre: EE 332

EE 412: Control Systems (3C, 3H)

Transfer function; block diagram; signal flow graph; mathematical modeling of physical

systems; time-domain analysis and design of control systems; root locus techniques;

frequency-domain analysis and design of control systems; state-space description

Pre: EE 300

EE 416: Control Systems Lab. (1C, 3L)

Measurement of motor characteristics: armature connection and field connection; transientresponse of motor; properties of operational amplifier unit; closed-loop position control

system; speed control system; reversible speed control; dead band and transient

characteristics; passive network compensation; stabilization with tachogenerator feedback:

frequency response measurement

Pre: EE 412

EE 420: Digital Electronic Circuits (3C, 3H)

Diodes and transistors as switches; switching and speed limitations RTL; DTL; TTL, ECL, IL

and MOS logic gates; comparators and Schmitt triggers; analog switches, A/D and D/A

converters; sample and hold circuit; mono-stable and a stable multi-vibrators and timing

circuits

Pre: EE 320

EE 422: Digital Electronic Circuits Lab. (1C, 3L)

Transistor as a switch; TTL logic specifications; mono-stable and a stable multi-vibrators;

comparators and Schmitt triggers; A/D and D/A converters; IC timers; sweep voltage

waveforms; sample and hold circuit and interfacing of logic gates.

Pre: EE 420

EE 426: Instrumentation & Measurements Lab. (1C, 3L)

Displacement transducers; temperature transducers; photoelectric transducers; the use ofoperational amplifiers in electronic instrumentation; power measurements; oscilloscopes; dc

power supplies


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Pre: EE 324

EE 430: Power System Analysis (3C, 3H)

Power system economics; load and energy forecasting; computer based load flow calculations

and control; economic operation of power systems; power system stability; power system

control; power system planning and reliability calculations

Pre: EE 337

EE 431: Electrical Machines II (3C, 3H)

Electromechanical system: force equation, doubly and multiply excited systems; engineering

aspects of practical electric machine performance; dynamic analysis of synchronous motors

and polyphase induction motors; reluctance motors; stepping motors

Pre: EE 332

EE 450: Principles of Communication Systems (3C, 3H)

Signal analysis: equivalent low-pass and band pass models, Hilbert transform, power spectral

density; amplitude modulation and demodulation: large carrier and suppressed carrier, singleside band and vestigial side band, coherent and non-coherent detection.

Angle modulation and demodulation. FM and PM, wideband and narrow-band FM,

Transmission bandwidth, generation and demodulation of FM, FM stereo multiplexing. Noise

representation and analysis: SNR analysis of AM and FM systems. Pulse modulation

techniques: sampling theorem, PAM, PPM, PWM

Pre: EE 301

EE 451: Digital Communications (3C, 3H)

Quantization and pulse code modulation, delta modulation, and noise analysis in PCM and

DM systems, TDM. Base band digital systems: digital signaling over channels without andwith inter-symbol interference and additive gaussion noise. Error probability analysis. Pass-

band digital systems: signal and system models of ASK, PSK, DPSK, FSK and QAM. Signal-

space representation and receiver model. Error probability analysis of digital modulation

techniques for coherent and non-coherent detection. Power spectra of digital signals.

Synchronization. Introduction to Information Theory. Introduction to Error control coding.

Introduction to spread spectrum systems.

Pre: EE 450

EE 452: Communications Lab. (1C, 3L)

Tuned circuits and crystals; AM modulators; AM demodulators; super-heterodyne radio

receiver; FM modulators; FM demodulators; harmonic analysis of modulated waveforms

Pre: EE 322, EE 450

EE 455: Digital Filters (3C, 3H)

Discrete time signals and systems; the Z-transform; frequency analysis of discrete time

systems; the discrete Fourier transform; introduction to digital filters; finite and infinite

impulse response filters; digital filter realization

Pre: EE 300

EE 490: Engineering Practice (3C)

The student has to spend at least 8 weeks of engineering training at recognized companies andestablishments during the summer semester after completing 120 C.H.

EE 506: Antennas (3C, 3H).


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Electromagnetic fields of current distributions; antenna fundamentals and definitions; dipoles;

antenna arrays; aperture and micro-strip antennas; broadband antennas..

Pre: EE 307

EE 507: Radio Wave Propagation (3C, 3H)

Electromagnetic spectrum; receiver systems; reflection, refraction, diffraction and scattering

of waves; ground waves, sky waves, tropospheric waves and space waves; precipitationeffects on propagation of waves; satellite and microwave communication links

Pre: EE 307

EE 508: Electromagnetic Interference and Compatibility (3C, 3H)

Coupling mechanisms; EMC regulations for electronic systems; basic electromagnetic

principles; non-ideal behavior of components; signal spectra; radiated emissions, conducted

emissions and susceptibility; crosstalk and shielding.

Pre: EE 307, EE 450

EE512: Digital Control (3C, 3H)Linear, discrete, dynamic-systems analysis: linear discrete equations, discrete transfer

functions, stability and Jurys test, discrete models of sampled-data systems; design of digital

control systems using transform techniques: control system specifications, z-plane design

using root locus, frequency-response methods with z-transform, PID control, Ziegler-Nichols

PID tuning; design of digital control systems using state-space methods: control law design,

estimator design, regulator design: combined control law and estimator, integral control,

control ability and observe ability.

Pre: EE 412

EE 520: VLSI Design (3C, 3H)

Evolution of VLSI; design system concepts; evolution of integrated-circuit design

approaches; physical design tools; review of solid state device concepts; device structures;

device modeling and circuit simulation; MOS circuit design; test methodologies for VLSI;

VLSI process development

Pre: EE 320, CIE 254

EE 521: Solid State Electronic Devices (3C, 3H)

Carrier modeling; carrier action; equation of state; volt-ampere characteristics; admittance and

switching response and FET non-ideal characteristic and switching

Pre: EE 320

EE 522: Optoelectronics (3C, 3H)

Light propagation; solid state-physics; modulation of light; display devices; light sources

(lasers, LED) driving circuits; photo-detectors driving circuits; optical communication

systems

Pre: EE 320

EE 523: Advanced Electronic Circuits (3C, 3H)

Feedback theory; frequency response and stability; power amplifiers and outpostages class A,

B, AB and C; active filters, switched capacitor filters, oscillators, current mirrors and current

sources

Pre: EE 420


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EE 524: Integrated Circuits (3C, 3H)

Latches and flip-flops; semiconductor memories (RAM&ROM); registers, counters, switches;

A/D and D/A converters; MESFET and Schottky diodes and transistors.

Pre: EE 420


(Non EE-student)

Comparators; Schmitt triggers; BJT and FET switches; transistor logic gates; MOS logic

gates; flip-flops; D/A and A/D conversion; timing circuits using discrete components and

555-timers ; oscillators ; power amplifiers; active filters

Pre: EE 321

EE 527: Communication Electronics (3C, 3H)

Parallel resonant circuit; impedance transformation; tuned amplifiers; large signal operation

of amplifier; near sinusoidal oscillator; super-heterodyne; receivers; mixers; AM, FM

modulation and demodulation; phase locked loopPre: EE 420, EE 450

EE 528: Microwave Electronics (3C, 3H)

Transmission lines and wave-guides microwave resonators; microwave network analysis;

passive microwave devices; ferromagnetic components; microwaves filters; microwave tubes;

solid state microwave devices and circuits

Pre: EE 307, EE 320

EE 529: Microwave Lab. (1C, 3L)

Measurement of frequency and wavelength; measurement of voltage standing wave ratio;

measurement of microwave power; characteristics of reflex klystron; directional couplers;

antenna radiation pattern and plane wave propagation

Pre: EE 528

EE 530: Power Systems Protection (3C, 3H)

Relay operating principles; current and voltage transformers; generator protection; motor

protection; transformer protection; bus protection; transmission line protection.

Pre: EE 337

EE 531: Electric Drives (3C, 3H)

Variable speed drive systems; separately excited DC motors; single and three phase rectifierswith motor load; three phase induction motor speed control by ac power controller and slip-

energy recovery; induction motors with voltage-source inverters; synchronous motor drives

Pre: EE 431

EE 532: Power Electronics (3C, 3H)

Power semiconductor devices: diodes, thyristors, transistors; uncontrolled rectifiers: single-

phase, bi-phase, three-phase, effect of source inductance; phase-controlled rectifiers: single-

phase, bi-phase, three phase, effect of source inductance. AC-AC converters: single-phase,

cycloconverter, single phase transformers tap changer; inverters: single-phase, three-phase

DC-DC converters: step-down converter, step-up converter, fly back converterPre: EE 320, EE 332


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EE 533: Power Transmission and Distribution (3C, 3H)

Overhead power lines: construction, sag and tension analysis; underground power cables;

circuit breakers; fuses; disconnect switches; substation design; earthing.

Pre: EE 337

EE 534: Power Systems Lab. (1C, 3L)

Transmission line performance under different operating conditions; load characteristics; real

and reactive power flow and control for a transmission line; characteristics of different types

of relays; power system protection using relays; measurement of sequence components;

balanced and unbalanced faults; power system transients and stability.

Pre: EE 430, EE 533

EE 535: Electrical Machines Lab. II (1C, 3L)

Three-phase transformer characteristics and group connections; no-load characteristics for DC

generators; starting and speed characteristics of DC motors; starting, loading and V-curves for

synchronous motors; synchronization of a synchronous generator; testing of three-phase

squirrel-cage induction motors and three-phase induction motor with slipring rotor; specialmotors

Pre: EE 336, EE431

EE 536: Power Systems and Power Electronics (3C, 3H)

Semiconductor devices for power engineering applications: thyristors gate turn-off thyristors,

MOS controlled thyristors; transistors. Common power electronic circuits: rectifiers,

converters, inverters, and impact of power electronic loads on power quality. HVDC:

converter plant, transmission plant, control strategies; flexible AC transmission: conventional

and advanced devices, shunt compensation, static VAR compensation, series compensation

angle compensation, quadrature boosters, unified power flow controllerPre: EE 430, EE 532

EE 537: Switched Mode Converters (3C, 3H)

Overview of power capabilities and switching speeds of power semiconductors. DC-DC

switched-mode converters: types, design, control, applications. DC-AC switched-mode

inverters: types, design, control of AC output, applications; computer simulation of switched-

mode converters

Pre: EE 532

EE 538: High Voltage Engineering (3C, 3H)

Generation and measurement of high voltage; electrostatic field and field stress control;

electrical breakdown in gases, solids and liquids; non-destructive insulation test techniques;

overvoltages and insulation coordination

Pre: EE 430.

EE 539:New Electrical Machines (3C, 3H)

Linear Electric machines: comparison with rotating machines; linear induction motors:

simplified electromagnetic field theory, force equation, characteristics; superconducting ac

generators and motors; variable reluctance motors: performance and characteristics; printed-

circuit motors

Pre: EE 431

EE 550: Digital Signal Processing (3C, 3H)


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Sampling and reconstruction of signals; multirate digital signal processing; analysis and

modeling of random signals; power spectrum estimation; digital signal processing

applications in: communication matched filtering, complex demodulation, FM and AM

conversion, carrier recovery and symbol detection

Pre: EE 455

EE 552: Digital Communication Lab. (1C, 3L)Digital waveform generators, waveform analysis; pulse amplitude modulators and

demodulators; sample and hold circuits; Delta modulation; PCM; ASK, FSK, PSK, DPSK

systems

Pre: EE 451, EE 452

EE 553: Communication Systems (3C, 3H)

Propagation of RF waves; ground, sky and space waves; antennas for HF, VHF, UHF and

microwaves; time and frequency division multiplexing techniques; introduction to microwave

satellite and fiber optic communication systems.

Pre: EE 451

EE 554: Computer Communication networks (3C, 3H)

Introduction to queuing theory; physical data link and network layers; network topologies;

basic performance evaluation methods; circuit and packet switching; local area networks;

telephone system; integrated services digital networks.

Pre: EE 451

EE 555: Optical fiber Communication Systems (3C, 3H)

Components, advantages and classifications of fiber communication systems; dielectric sLab.

wave-guide; step index fiber, graded index fiber, light sources, photodetectors, noise in theoptical receiver, receiver sensitivity, heterodyne detection, analog and digital signal

transmission.

Pre: EE 451

EE 556: Radar Systems (3C, 3H)

Radar fundamentals; radar equation; radar detection theory; radar types; surveillance, tracking

and electronic countermeasure in radar; marine, military and civil radar; design and performance

of radar systems.

Pre: EE 307, EE 450

EE 557: Television Systems (3C, 3H)

An overview of photometry fundamentals. Video signal composition; scanning; monochrome

television receivers; television broadcast transmitters; color television theory; primary and

secondary colors, composite color video signal; television broadcast standards: PAL,

SECAM, NTSC; closed-circuit television; 3-D television; large-screen projection; HDTV

systems.

Pre: EE 450

EE 558: Satellite Communication Systems (3C, 3H)

Overview of satellite communication; earth station technology; channel characterization and

link budget calculations; transponders and transponder model; channelization; frequencyplans; propagation and interference considerations; satellite access techniques; introduction to

satellite networks.


18/18

Pre: EE 451

EE 559: Mobile Communication Systems (3C, 3H)

An overview of mobile communication systems; channel characterization; signal

transmission; error probability analysis; systems to combat fading; diversity and combining

schemes; error rate performance for a digital communication system with diversity over

mobile channels; cellular mobile system.Pre: EE 451

EE 591: Graduation Project I (1C)

Project preparation and theory in the semester preceding the graduation semester.

EE 592: Graduation Project II (3C)

Implementation of the project prepared in graduation semester. A technical report is required.

Pre: EE 591

B.sc. in Electrical Engineering_studyplan

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