Department of Electrical and Electronic Engineering Syllabus

Department of Electrical and Electronic Engineering

First YearSemester I

Course no. / Course Title / Hours/Week
Theory + Lab / Credits / Pre-requisite
EEE 101 / Electrical Circuits I / 3 + 0 / 3.0 / N/A
CSE 133 / Structured Computer Programming / 3 + 0 / 3.0 / N/A
CSE 134 / Structured Computer Programming Lab. / 0 + 6 / 3.0 / N/A
ENG 101 / English Language I / 2 + 0 / 2.0 / N/A
ENG 102 / English Language I Lab. / 0 + 2 / 1.0 / N/A
CSE 108 / Computer Aided Engineering Drawing / 0 + 4 / 2.0 / N/A
MAT 101 / Co-ordinate Geometry and Linear Algebra / 3 + 0 / 3.0 / N/A
PHY 103 / Mechanics, Wave, Heat & Thermodynamics / 3 + 0 / 3.0 / N/A
PHY 104 / Physics I Lab / 0 + 3 / 1.5 / N/A
Total / 14 + 15 / 21.5

First YearSemester II

Course no. / Course Title / Hours/Week
Theory + Lab / Credits / Pre-requisite
EEE 123 / Electrical Circuits II / 3 + 0 / 3.0 / EEE 101
EEE 124 / Electrical Circuits Lab. / 0 + 3 / 1.5 / EEE 101
EEE 126 / Electrical Circuit Simulation Lab / 0 + 3 / 1.5 / EEE 101
PHY 207 / Electromagnetism, Optics & Modern Physics / 3 + 0 / 3.0 / PHY 103
PHY 204 / Physics II Lab. / 0 + 3 / 1.5 / PHY 104
CHE 101 / General Chemistry / 3 + 0 / 3.0 / N/A
CHE 102 / General Chemistry Lab (Inorganic and Quantitative Analysis Lab) / 0 + 3 / 1.5 / N/A
ENG 103 / English Language II / 2 + 0 / 2.0 / ENG 101
ENG 104 / English Language II Lab / 0 + 2 / 1.0 / ENG 102
MAT 103 / Differential and Integral Calculus / 3 + 0 / 3.0 / MAT 101
Total / 14 + 14 / 21

Second YearSemester I

Course no. / Course Title / Hours/Week
Theory + Lab / Credits / Pre-requisite
EEE 221 / Electronics I / 3 + 0 / 3.0 / EEE 101 & 123
EEE 222 / Electronic Circuit Simulation Lab. / 0 + 3 / 1.5 / EEE 124 & 126
EEE 223 / Electrical Machines I / 3 + 0 / 3.0 / EEE 101 & 123
EEE 224 / Electrical Machines I Lab. / 0 + 3 / 1.5 / EEE 124 & 126
EEE 229 / Electromagnetic Fields and Waves / 3 + 0 / 3.0 / MAT 102
CSE 209 / Numerical Analysis / 2 + 0 / 2.0 / CSE 135
CSE 210 / Numerical Analysis Lab. / 0 + 2 / 1.0 / CSE 136
BAN 243 / Cost and Management Accounting / 3 + 0 / 3.0 / N/A
MAT 221 / Vector Analysis and Complex Variables / 3 + 0 / 3.0 / MAT 103
Total / 17 + 08 / 21

Second YearSemester II

Course no. / Course Title / Hours/Week
Theory + Lab / Credits / Pre-requisite
EEE 225 / Electrical Machines II / 3 + 0 / 3.0 / EEE 223
EEE 226 / Electrical Machines II Lab / 0 + 3 / 1.5 / EEE 224
EEE 227 / Electronics II / 3 + 0 / 3.0 / EEE 221
EEE 228 / Electronics Lab / 0 + 3 / 1.5 / EEE 222
STA 202 / Basic Statistics & Probability / 4 + 0 / 4.0 / N/A
ECO 103 / Principles of Economics / 4 + 0 / 4.0 / N/A
MAT 223 / Ordinary and Partial Differential Equations / 3 + 0 / 3.0 / MAT 221
Total / 17 + 06 / 20

Third YearSemester I

Course no. / Course Title / Hours/Week
Theory + Lab / Credits / Pre-requisite
EEE 321 / Signals and Linear Systems / 3 + 0 / 3.0 / EEE 101 & 123
EEE 323 / Digital Electronics / 3 + 0 / 3.0 / EEE 221
EEE 324 / Digital Electronics Lab / 0 + 3 / 1.5 / EEE 222
EEE 325 / Power System I / 3 + 0 / 3.0 / EEE 101 & 123
EEE 326 / Power System I Lab / 0 + 3 / 1.5 / EEE 124 & 126
EEE 327 / Electrical Properties of Materials / 3 + 0 / 3.0 / EEE 101 & 123
EEE 328 / Electrical Services Design / 0 + 3 / 1.5 / EEE 101 & 123
IPE 301 / Industrial & Business Management / 3 + 0 / 3.0 / N/A
Total / 15 + 09 / 19.5

Third YearSemester II

Course no. / Course Title / Hours/Week
Theory + Lab / Credits / Pre-requisite
EEE 329 / Digital Communication Engineering / 3 + 0 / 3.0 / MAT 204
EEE 330 / Digital Communication Engineering Lab / 0 + 3 / 1.5 / MAT 204
EEE 331 / Digital Signal Processing I / 3 + 0 / 3.0 / EEE 321
EEE 332 / Digital Signal Processing I Lab / 0 + 3 / 1.5 / EEE 321
EEE 333 / Microprocessor & Assembly Language / 3 + 0 / 3.0 / EEE 323
EEE 334 / Microprocessor & Assembly Language Lab / 0 + 3 / 1.5 / EEE 324
EEE 335 / Control System I / 3 + 0 / 3.0 / EEE 323
EEE 336 / Control System I Lab / 0 + 3 / 1.5 / EEE 324
EEE 3** / Option I / 3 + 0 / 3.0 / Option list
Total / 15 + 12 / 21

Fourth YearSemester I

Course no. / Course Title / Hours/Week
Theory + Lab / Credits / Pre-requisite
EEE 400 / Project/Thesis (Initial work) / 0 + 4 / 2.0 / Completion of 300 level courses
EEE 421 / Solid State Devices / 3 + 0 / 3.0 / EEE 221
EEE 423 / Computer Interfacing and Industrial Automation / 3 + 0 / 3.0 / EEE 333 & 335
EEE 424 / Computer Interfacing and Industrial Automation Lab / 0 + 3 / 1.5 / EEE 334 & 336
EEE 4** / Option II / 3 + 0 / 3.0 / Option list
EEE 4** / Option III / 3 + 0 / 3.0 / Option list
EEE 4** / Option III Lab / 0 + 3 / 1.5 / Option list
EEE 4** / Option IV / 3 + 0 / 3.0 / Option list
Total / 15 + 10 / 20

Fourth YearSemester II

Course no. / Course Title / Hours/Week
Theory + Lab / Credits / Pre-requisite
EEE 408 / Project/Thesis / 0 + 8 / 4.0 / Completion of 300 level courses
EEE 4** / Option V / 3 + 0 / 3.0 / Option list
EEE 4** / Option V Lab / 0 + 3 / 1.5 / Option list
EEE 4** / Option VI / 3 + 0 / 3.0 / Option list
EEE 4** / Option VII / 3 + 0 / 3.0 / Option list
EEE 4** / Option VIII / 3 + 0 / 3.0 / Option list
EEE 4** / Option VIII Lab / 0 + 3 / 1.5 / Option list
Total / 12 + 14 / 19

Credit Hour

/ Group
EEE 445
EEE 446 / Power System Protection
Power System Protection Lab / 3.0
1.5 / Power
(any one)
EEE 447
EEE 448 / High Voltage Engineering
High Voltage Engineering Lab / 3.0
1.5
EEE 461
EEE 462 / VLSI II
VLSI II Lab / 3.0
1.5 / Electronics
(any one)
EEE 463
EEE 464 / Programmable ASIC Design
Programmable ASIC Design Lab / 3.0
1.5
EEE 481
EEE 482 / Optical Fiber Communication
Optical Fiber Communication Lab / 3.0
1.5 / Communication
CSE 361
CSE 362 / Computer Networking
Computer Networking Lab / 3.0
1.5 / Computer

Option VI Courses

Course Number

Course Title

Credit Hour

/ Group
EEE 449 / Power System Reliability / 3.0 / Power
EEE 465 / Optoelectronics / 3.0 / Electronics
EEE 483 / Telecommunication Engineering / 3.0 / Communication
CSE 329 / Computer Architecture / 3.0 / Computer

Option VII Courses

Course Number

Course Title

Credit Hour

/ Group
EEE 451 / Power System Operation and Control / 3.0 / Power
EEE 467 / Semiconductor Device Theory / 3.0 / Electronics
EEE 485 / Cellular Mobile and Satellite Communication / 3.0 / Communication
CSE 415 / Multimedia Communications / 3.0 / Computer

Option VIII (Interdisciplinary) Courses

Course Number

Course Title

Credit Hour

/ Group
EEE 487
EEE 488 / Control System II
Control System II Lab / 3.0
1.5 / Interdisciplinary
EEE 489
EEE 490 / Renewable Energy Systems
Renewable Energy Systems Lab / 3.0
1.5 / Interdisciplinary
EEE 491
EEE 492 / Biomedical Instrumentation
Biomedical Instrumentation Lab / 3.0
1.5 / Interdisciplinary
EEE 493
EEE 494 / Measurement and Instrumentation
Measurement and Instrumentation Lab / 3.0
1.5 / Interdisciplinary

Detailed Syllabus

Core Courses:

EEE 101 ELECTRICAL CIRCUITS I
3 hours/Week, 3 Credits
Circuit variables and elements: Voltage, current, power, energy, independent and dependent sources, and resistance. Basic laws: Ohm’s law, Kirchoff’s current and voltage laws. Simple resistive circuits: Series and parallel circuits, voltage and current division, wye-delta transformation. Techniques of circuit analysis: Nodal and mesh analysis including super node and super mesh. Network theorems: Source transformation, Thevenin’s, Norton’s and superposition theorems with applications in circuits having independent and dependent sources, maximum power transfer condition and reciprocity theorem. Energy storage elements: Inductors and capacitors, series parallel combination of inductors and capacitors. Responses of RL and RC circuits: Natural and step responses.
Magnetic quantities and variables: Flux, permeability and reluctance, magnetic field strength, magnetic potential, flux density, magnetization curve. Laws in magnetic circuits: Ohm’s law and Ampere’s circuital law. Magnetic circuits: series, parallel and series-parallel circuits.
Pre-requisite: N/A
Textbook: Introductory circuit analysis by Boylestad
Reference: Networks, lines and fields by J. D. Ryder
EEE 103 INTRODUCTION TO ELECTRICAL AND ELECTRONIC CIRCUITS
2 Hours/Week, 2 Credits
Voltage and Current, Ohm’s law, Series circuits, Parallel circuits, Series-Parallel circuits, Capacitors, Inductors, R-L and R-L-C Circuits, Sinusoidal alternating wave forms, Square Waves and R-C response;
Diode circuits, Transistor circuits, Op Amp. circuits, Popular ICs, Logic gates, Flip-Flops, and Counter.
EEE 104 INTRODUCTION TO ELECTRICAL AND ELECTRONIC CIRCUITS LAB
2 Hours/Week, 2 Credits
Laboratory works based on EEE 103 course
EEE 105 INTRODUCTION TO ELECTRICAL AND ELECTRONIC CIRCUITS
3 Hours/Week, 3 Credits
Voltage and Current, Ohm’s law, Series circuits, Parallel circuits, Series-Parallel circuits, Capacitors, Inductors, R-L and R-L-C Circuits, Sinusoidal alternating wave forms, Square Waves and R-C response;
Diode circuits, Transistor circuits, Op Amp. circuits, Popular ICs, Logic gates, Flip-Flops, and Counter.
Single phase transformer, Introduction to three phase transformer; DC machines: DC generator principle, types, characteristics and performances. AC machines: Single phase induction motor, three phase induction motor, introduction to synchronous machines; Oscilloscope; Transducers: Strain, temperature, pressure, speed and torque measurements.
EEE 106 INTRODUCTION TO ELECTRICAL AND ELECTRONIC CIRCUITS LAB
3 Hours/Week, 1.5 Credits
Laboratory works based on EEE 103/EEE 105.
EEE 107 ELECTRICAL AND ELECTRONIC CIRCUIT ANALYSIS
4 Hours/Week, 4 Credits
a. Circuit Models: Linear circuit elements, Ohm’s law, Voltage and Current sources, Kirchoff’s voltage and Current law, Voltage and Current Divider rules, Series Parallel Circuits, Circuit Theorem: Thevenin’s, Norton’s, Maximum power transfer, Superposition Reciprocity Theorem DC analysis: Source conversion, Branch Current, Mesh analysis, Nodal Analysis, Bridge Network, Delta-Y conversion Transient and Time Domain Analysis: Transient in RC, RL and RLC circuits, Reactance, Average power AC theory and Frequency Domain Analysis: Phasors, Source conversion, Series Parallel AC circuits, Mesh analysis, Nodal Analysis Resonance: Series, Parallel resonance circuit, Q values
b. Semiconductors: Semiconductor materials, Energy levels, n, p type Semiconductor Devices: Diode, Transistor, FET, Optoelectronic devices and their uses in circuits Operational Amplifier: Basic operation and use in construction of analog circuits
EEE 108 ELECTRICAL AND ELECTRONIC CIRCUIT ANALYSIS LAB
6 Hours/Week, 3 Credits

Use of measuring Equipment: Multi-meter, Frequency meter and Oscilloscope
Test of Ohm’s Law plot of I-V, P-V curve
I-V curve for Si, Ge and Zenor diodes
Measurement of time constant in RC circuit
Construction of a High pass and Low pass filter using RC circuit
Measurement of Resonance frequency and Q value of a RLC circuit
Making AND/OR gates using transistors
FET as voltage controlled resistor
Op amp as Inverting amplifier
OP Amp as Differentiator and Integrator
Optical data communication using LED and photodiode
Electronic Project

EEE 123ELECTRICAL CIRCUITS II
3 hours/Week, 3 Credits
Sinusoidal functions: Instantaneous current, voltage, power, effective current and voltage, average power, phasors and complex quantities, impedance, real and reactive power, power factor. Analysis of single phase AC circuits: Series and parallel RL, RC and RLC circuits, nodal and mesh analysis, application of network theorems in AC circuits, circuits with non-sinusoidal excitations, transients in AC circuits, passive filters. Resonance in AC circuits: Series and parallel resonance. Magnetically coupled circuits. Analysis of three phase circuits: Three phase supply, balanced and unbalanced circuits, and power calculation.
Pre-requisite: EEE 101ELECTRICAL CIRCUITS I
Textbook: Introductory circuit analysis by Boylestad
Reference: Networks, lines and fields by J. D. Ryder
EEE 124ELECTRICAL CIRCUITS LAB
3 hours/Week, 1.5 Credits
In this course students will perform experiments to verify practically the theories and concepts learned in EEE-101 and EEE 123.
1. To familiar with the operation of different electrical instruments.
2. To verify the following theorems:

KCL and KVL theorem,
Superposition theorem,
Thevenin’s theorem,
Norton’s theorem and
Maximum power transfer theorem

3. To design and construct of low pass and high pass filter and draw their characteristics curves.
4. To investigate the voltage regulation of a simulated transmission network.
Study the characteristics of Star-Delta connection
5. Study the frequency response of an RLC circuit and find its resonant frequency.
6. To perform also other experiments relevant to this course.
Pre-requisite: EEE 101ELECTRICAL CIRCUITS I
Textbook: Introductory circuit analysis by Boylestad
Reference: Networks, lines and fields by J. D. Ryder
EEE 126ELECTRICAL CIRCUIT SIMULATION LAB
3 hours/Week, 1.5 Credits
Simulation laboratory based on EEE-1011 and EEE-1113 theory courses. Students will verify the theories and concepts learned in EEE-1011 and EEE-1113 using simulation software like PSpice and Matlab. Students will also perform specific design of DC and AC circuits theoretically and by simulation.
Pre-requisite: EEE 101ELECTRICAL CIRCUITS I
Textbook: Introductory circuit analysis by Boylestad
Reference: Networks, lines and fields by J. D. Ryder
EEE 201 DIGITAL LOGIC DESIGN

3 Hours/Week, 3 Credits

Logic Families: TTL, CMOS, ECL, Tristate
Logic Gates: AND, OR, NAND, NOR, X-OR, X-NOR, Circuit Design
Flipflops: SR, JK, D, Master Slave, Application, Synchronization
Logic Circuits: Coder, Decoder, Mux, Dmux
Counters: Synchronous, Asynchronous, Up/Down, Ripple, Cascading
Registers: Shift registers
Memory Devices: ROM, RAM, Static, Dynamic, Memory Operation
Arithmatic Circuits: Adder, Carry, Look Ahead, ALU
PAL: Microprogram Control, FPGA, HDLA
EEE 202 DIGITAL LOGIC DESIGN LAB
4 Hours/Week, 2 Credits

Logic circuits using combination of gates
Bounce-less switch using RS latch
0-9 second timer using 555, counters and 7-segment display
Scrambler/De-scrambler circuit using latch for data communication
Design of nano-computer
Write, Read and Display contents of memory devices.
Project with PAL/FPGA/Microcontroller

EEE 221ELECTRONICS I
3 hours/Week, 3 Credits
P-N junction as a circuit element: Intrinsic and extrinsic semiconductors, operational principle of p-n junction diode, contact potential, current-voltage characteristics of a diode, simplified DC and AC diode models, dynamic resistance and capacitance. Diode circuits: Half wave and full wave rectifiers, rectifiers with filter capacitor, characteristics of a Zener diode, Zener shunt regulator, clamping and clipping circuits. Bipolar Junction Transistor (BJT) as a circuit element: current components, BJT characteristics and regions of operation, BJT as an amplifier, biasing the BJT for discrete circuits, small signal equivalent circuit models, BJT as a switch. Single stage mid-band frequency BJT amplifier circuits: Voltage and current gain, input and output impedance of a common base, common emitter and common collector amplifier circuits. Metal Oxide Semiconductor Field Effect Transistor (MOSFET) as circuit element: structure and physical operation of an enhancement MOSFET, threshold voltage, Body effect, current-voltage characteristics of an enhancement MOSFET, biasing discrete and integrated MOS amplifier circuits, single-stage MOS amplifiers, MOSFET as a switch, CMOS inverter. Junction Field-Effect-Transistor (JFET): Structure and physical operation of JFET, transistor characteristics, pinch-off voltage. Differential and multistage amplifiers: Description of differential amplifiers, small-signal operation, differential and common mode gains, RC coupled mid-band frequency amplifier.
Pre-requisite: EEE 101 Electrical Circuits I & EEE 123Electrical Circuits II
Textbook: Electronics Devices by R. L. Boylestad
Reference: Electronics Principles. By Malvino
EEE 222ELECTRONIC CIRCUIT SIMULATION LAB
3 hours/Week, 1.5 Credits
Simulation laboratory based on EEE-221 theory course. Students will verify the theories and concepts learned in EEE 221
using simulation software like PSpice and Matlab. Students will also perform specific design of electronics circuits theoretically and by simulation.

To familiar with electronics devices and Laboratory Equipments.
To study of V-l Characteristics curve of P-N junction diode.
To study of V-l Characteristics curve of a Zener diode.
To study of Half-Wave Rectification circuit.
To study of Full-Wave Rectification circuit (Bridge & Cente- tap)
To familiar with NPN and PNP Transistors.
To study of Full-Wave filter circuit.
To study of Common Emitter (CE) Transistor Amplifier circuits.
To study of Clipping and clamping circuit.
To study of output characteristics of an FET.
To study of JFET as an amplifier.

To study of output characteristics of a JFET.
Pre-requisite: EEE 124 Electrical Circuits Lab & EEE 126Electrical Circuit Simulation Lab
Textbook: Electronics Devices by R. L. Boylestad
Reference: Electronics Principles. By Malvino
EEE 223 ELECTRICAL MACHINES I
3 hours/Week, 3 Credits
Transformer: Ideal transformer- transformation ratio, no-load and load vector diagrams; actual transformer- equivalent circuit, regulation, short circuit and open circuit tests. Three phase induction motor: Rotating magnetic field, equivalent circuit, vector diagram, torque-speed characteristics, effect of changing rotor resistance and reactance on torque-speed curves, motor torque and developed rotor power, no-load test, blocked rotor test, starting and braking and speed control. Single phase induction motor: Theory of operation, equivalent circuit and starting.
Pre-requisite: EEE 101 Electrical Circuits I & EEE 123Electrical Circuits II
Textbook: Energy conversion by Kenneth C. Weston
Reference: Energy conversion: systems, flow physics and engineering by Professor Reiner Decher
EEE 224 ELECTRICAL MACHINES I LAB
3 hours/Week, 1.5 Credits
This course consists of two parts. In the first part, students will perform experiments to verify practically the theories and concepts learned in EEE 223. In the second part, students will design simple systems using the principles learned in EEE 223.
Pre-requisite: EEE 124 Electrical Circuits Lab & EEE 126Electrical Circuit Simulation Lab
Textbook: Energy conversion by Kenneth C. Weston
Reference: Energy conversion: systems, flow physics and engineering by Professor Reiner Decher
EEE 225 ELECTRICAL MACHINES II
3 hours/Week, 3 Credits
Synchronous Generator: excitation systems, equivalent circuit, vector diagrams at different loads, factors affecting voltage regulation, synchronous impedance, synchronous impedance method of predicting voltage regulation and its limitations. Parallel operation: Necessary conditions, synchronizing, circulating current and vector diagram. Synchronous motor: Operation, effect of loading under different excitation condition, effect of changing excitation, V-curves and starting. DC generator: Types, no-load voltage characteristics, build-up of a self excited shunt generator, critical field resistance, load-voltage characteristic, effect of speed on no-load and load characteristics and voltage regulation. DC motor: Torque, counter emf, speed, torque-speed characteristics, starting and speed regulation. Introduction to wind turbine generators Construction and basic characteristics of solar cells.
Pre-requisite: EEE 223 Electrical Machines I
Textbook: Energy conversion by Kenneth C. Weston
Reference: Energy conversion: systems, flow physics and engineering by Professor Reiner Decher