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Sequence of Course Offerings for ETE
Credit Hour
Distribution:
|
Trimester |
Theory Credit |
Lab./Project Credit |
Total Credit |
|
Trimester 1 |
6.0(+*6.0) |
0.0 |
6.0 |
|
Trimester 2 |
12.0 |
1.0 |
13.0 |
|
Trimester 3 |
12.0 |
1.0 |
13.0 |
|
Trimester 4 |
12.0 |
2.0 |
14.0 |
|
Trimester 5 |
9.0 |
3.0 |
12.0 |
|
Trimester 6 |
12.0 |
0.0 |
13.0 |
|
Trimester 7 |
12.0 |
1.0 |
13.0 |
|
Trimester 8 |
9.0 |
2.0 |
12.0 |
|
Trimester 9 |
9.0 |
3.0 |
12.0 |
|
Trimester 10 |
9.0 |
2.5 |
11.5 |
|
Trimester 11 |
9.0 |
2.0 |
11.0 |
|
Trimester 12 |
9.0 |
4.0 |
13.0 |
|
Total |
120 |
20.5 |
140.5 |
*Non-credit
courses with total 6 contact
hours
|
SI. No. |
Course Code |
Course Title |
Credit Hour |
|
1. |
ENG 101/ENG 002 |
|
3.00* |
|
2. |
PHY 101 |
|
3.00 |
|
3. |
MATH 003* |
|
3.00* |
|
4. |
MATH 151 |
|
3.00 |
|
|
|
Subtotal |
12.00 |
*Non-credit mandatory course with 3
contact hours.
|
SI. No. |
Course Code |
Course Title |
Credit Hour |
|
1. |
ETE 101 |
|
3.00 |
|
2. |
PHY 103 |
Physics II |
3.00 |
|
3. |
PHY
104 |
Physics Lab |
1.00 |
|
4. |
ENG 103/ENG 101 |
|
3.00 |
|
5. |
MATH 155 |
|
3.00 |
|
|
|
Subtotal |
13.00 |
|
SI. No. |
Course Code |
Course Title |
Credit Hour |
|
1. |
ETE 103 |
(Pre-requisite ETE 101) |
3.00 |
|
2. |
ETE 104 |
|
1.00 |
|
3. |
ENG 103 |
|
3.00 |
|
4. |
MATH 201 |
|
3.00 |
|
5. |
ACT 111 |
|
3.00 |
|
|
|
Subtotal |
13.00 |
|
SI. No. |
Course Code |
Course Title |
Credit Hour |
|
1. |
ETE 105 |
(Pre-requisite ETE 103) |
3.00 |
|
2. |
CHEM 101 |
|
3.00 |
|
3. |
CHEM 102 |
|
1.00 |
|
4. |
MATH 203 |
|
3.00 |
|
5. |
EEE 121 |
|
3.00 |
|
6. |
EEE 122 |
|
1.00 |
|
|
|
Subtotal |
14.00 |
|
SI. No. |
Course Code |
Course Title |
Credit Hour |
|
1. |
ETE 110 |
(Pre-requisite ETE 105) |
1.00 |
|
2. |
ETE 207 |
(Pre-requisite ETE 105) |
3.00 |
|
3. |
ETE 208 |
|
1.00 |
|
4. |
MATH 157 |
|
3.00 |
|
5. |
EEE 215 |
(Pre-requisite ETE 103) |
3.00 |
|
|
|
Subtotal |
11.00 |
|
SI. No. |
Course Code |
Course Title |
Credit Hour |
|
1. |
EEE
223 |
|
3.00 |
|
2. |
EEE 224 |
|
1.00 |
|
3. |
ETE 211 |
(Pre-requisite MATH 157,ETE
103) |
3.00 |
|
4. |
MATH 153 |
|
3.00 |
|
5. |
ECO 213 |
|
3.00 |
|
|
|
Subtotal |
13.00 |
|
SI. No. |
Course Code |
Course Title |
Credit Hour |
|
1. |
ETE 255 |
(Pre or corequisite ETE 211) |
3.00 |
|
2. |
ETE 301 |
(Pre-requisite PHY 103,MATH
153) |
3.00 |
|
3. |
ETE 303 |
(Pre-requisite MATH 201,PHY
103) |
3.00 |
|
4. |
EEE 423 |
(Pre-requisite CSI 121, CSE
223) |
3.00 |
|
5. |
EEE 424 |
|
1.00 |
|
|
|
Subtotal |
13.00 |
|
SI. No. |
Course Code |
Course Title |
Credit Hour |
|
1. |
EEE 313 |
|
3.00 |
|
2. |
ETE 309 |
(Pre-requisite ETE 211, ETE
255) |
3.00 |
|
3. |
ETE 310 |
|
1.00 |
|
4. |
ETE 311 |
(Pre-requisite ETE 211) |
3.00 |
|
6. |
ETE 312 |
|
1.00 |
|
|
|
Subtotal |
11.00 |
|
SI. No. |
Course Code |
Course Title |
Credit Hour |
|
1. |
CSE 323 |
|
3.00 |
|
2. |
CSE 324 |
|
1.00 |
|
3. |
ETE 455 |
|
3.00 |
|
4. |
ETE 456 |
|
1.00 |
|
5. |
ETE 495 |
(Pre-requisite ETE 309, ETE
255) |
3.00 |
|
|
|
Subtotal |
11.00 |
|
SI. No. |
Course Code |
Course Title |
Credit Hour |
|
1. |
ETE 400 |
Project and Thesis |
1.50 |
|
2. |
ETE 441 |
(Pre-requisite ETE 207, ETE
313) |
3.00 |
|
3. |
ETE 442 |
|
1.00 |
|
4. |
ETE 459 |
|
3.00 |
|
5. |
IPE 401 |
|
3.00 |
|
|
|
Subtotal |
11.50 |
|
SI. No. |
Course Code |
Course Title |
Credit Hour |
|
1. |
|
|
2.00 |
|
2. |
ETE 433 |
(Pre-requisite ETE 207, ETE
313) |
3.00 |
|
3. |
ETE 457 |
|
3.00 |
|
4. |
ETE *** |
|
3.00 |
|
|
|
Subtotal |
11.00 |
|
SI. No. |
Course Code |
Course Title |
Credit Hour |
|
1. |
ETE 400 |
|
3.00 |
|
2. |
ETE *** |
|
3.00 |
|
3. |
ETE *** |
|
3.00 |
|
4. |
ETE *** |
|
1.00 |
|
5. |
SOC 101 |
|
3.00 |
|
|
|
Subtotal |
13.00 |
LIST OF ELECTIVE COURSES (EEE
.......)
|
SI. No. |
Course
Code |
Course Title |
Credit Hour |
|
1. |
ETE 435 |
|
3.00 |
|
2. |
ETE 445 |
|
3.00 |
|
3. |
ETE 461 |
|
3.00 |
|
4. |
ETE 463 |
(Pre-requisite ETE 303, ETE
309) |
3.00 |
|
5. |
ETE 465 |
(Pre-requisite ETE 309, ETE
311) |
3.00 |
|
6. |
ETE 469 |
|
3.00 |
|
7. |
ETE 493 |
|
3.00 |
|
8. |
EEE 491 |
(Pre-requisite EEE 309, ETE
311) |
3.00 |
|
9. |
EEE 499 |
(Pre-requisite EEE 309, ETE
311) |
3.00 |
|
10. |
EEE 467 |
(Pre-requisite EEE 309, ETE
311) |
3.00 |
|
11. |
EEE 453 |
(Pre-requisite EEE 309, ETE
311) |
3.00 |
|
12. |
ETE 467 |
(Pre-requisite EEE 309, ETE
311) |
3.00 |
|
SI. No. |
Course Code |
Course Title |
Credit Hour |
|
1. |
ETE 443 |
|
3.00 |
|
2. |
ETE 444 |
|
1.00 |
|
3. |
ETE 447 |
(Pre-requisite ETE 207, CSE
223) |
3.00 |
|
4. |
ETE 448 |
|
1.00 |
|
5. |
ETE 451 |
|
3.00 |
|
6. |
ETE 452 |
|
1.00 |
|
7. |
ETE 497 |
(Pre-requisite ETE 309, ETE
255) |
3.00 |
|
8. |
ETE 498 |
|
1.00 |
|
9. |
CSE 421 |
|
3.00 |
|
10. |
CSE 422 |
|
1.00 |
Course Code:ENG 101/ ENG 002
Credit:3.00
Credit Hour:3.00
Prerequisite:n/a
The course
aims at developing proficiency in speaking, listening, reading, and writing of
English. It is generalized as a remedial course for students whose English need
considerable repair and as a foundation courses for ENG 103. The contents
include parts of speech, count and uncountable nouns and articles, agreement
between subject and verb, adverbs of frequency, tense and the sequence of
tenses, active and passive voices, types of sentences, prepositions: time,
place, action, directions, questions forms, multi-word verbs,
capitalization.
<<
Back
Course Code:MATH 003*
Credit:3.00
Credit Hour:3.00
Prerequisite:n/a
Number
System: Natural Number, Integer, Rational Number, Irrational Number, Real
Number, Even and Odd Number, Prime Number, Interval, Inequality; Functions:
One-to-one, Many-to-one Function, Domain, Range, Inverse Function, Even and Odd
Function; Graphs: Algebraic (Quadratic, Cubic) and Transcendental
(Trigonometric, Exponential, Logarithmic) Function, Absolute Value Function;
Graphing New Functions from Old: Translations, Reflections, Stretches and
Compressions; Differentiation: Limit, Continuity and Derivative of Functions;
Integration: Indefinite Integral, Integration by substitution. Definite
integral. Area under curves.
<<
Back
Differential and Integral
Calculus
Course Code:MATH 151
Credit:3.00
Credit Hour:3.00
Prerequisite:n/a
Differential
Calculus: Limits, Continuity and differentiability. Successive differentiation
of various types of functions. Leibnitz's theorem. Roller's theorem. Mean value
theorem. Taylor's and Maclaurin's theorems in finite and infinite forms.
Lagrange's form of remainders. Cauchy's form of remainders. Expansion of
functions by differentiation and integration. Evaluation of indeterminate forms
by L'Hospitals rule. Partial differentiation. Euler's theorem. Tangent and
Normal. Subtangent and subnormal in cartesian and polar co-ordinates.
Determination of Maximum and minimum values of functions and points of
inflection with applications. Curvature: radius, circle, centre and chord of
curvature, asymptotes and curved tracing.
Integral
Calculus : Integration by the method of substitution. Standard integrals.
Integration by successive reduction. Definite integrals, its properties and use
in summing series. Walli's formulate. Improper integrals. Beta function and
Gamma function. Area under a plane curve and area of a region enclosed by two
curves in cartesian and polar co-ordinate. Volumes of solids of revolution.
Volume of hollow solids of revolution by shell method Area of surface of
revolution. Jacobians. Multiple integrals with applications.
<<
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Course Code:PHY 101
Credit:3.00
Credit Hour:3.00
Prerequisite:n/a
Physical Optics: Theories of light:
Interference of light, Young's double slit experiment, Displacements of fringes
& its uses. Fressnel Bi-prism, Interference at wedge shaped films,
Newton's rings, Interferometers; Diffraction of light: Fresnel and Fraunhoffer
diffraction. Diffraction by single slit. Diffraction from a circular aperture,
Resolving power of optical instruments, Diffraction at double slit &
N-slits-diffraction grating; Polarization: Production & analysis of
polarized light, Brewster's law, Malus law, Polarization by double refraction.
Retardation plates. Nicol prism. Optical activity. Polarimeters,
Polaroid.
Waves
& Oscillations: Differential equation of a Simple
Harmonic Oscillator, Total energy & average energy, Combination of
simple harmonic oscillation, Lissajous figures, Spring-mass system, Calculation
of time period of torsional pendulum, Damped oscillation, Determination of
damping co-efficient. Forced oscillation. Resonance, Two-body oscillation.
Reduced mass Differential equation of a progressive wave, Power &
intensity of wave motion, Stationary wave, Group velocity & Phase
velocity. Architectural acoustics, Reverberation and Sabine's formula.
Modern
Physics: Michelson-Morley's experiment. Galilean transformation,
Special theory of relativity & its consequences; Quantum theory of
Radiation: Photo-electric effect, Compton effect, wave particle duality.
Interpretation of Bohr's postulates, Radioactive disintegration, Properties of
nucleus, Nuclear reactions, Fission. Fusion, Chain reaction, Nuclear
reactor.
<<
Back
Course Code:ETE 101
Credit:3.00
Credit Hour:3.00
Prerequisite:n/a
Circuit
variables and elements: Voltage, current, power, energy, independent and
dependent sources, resistance. Basic laws: Ohm's law, Kirchhoff'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 supernode 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.
<<
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Course Code:PHY 103
Credit:3.00
Credit Hour: 3.00
Prerequisite:n/a
Heat & thermodynamics: Principle of
temperature measurements: Platinum resistance thermometer, Thermo-electric
thermometer, Pyrometer; Kinetic theory of gases: Maxwell's distribution of
molecular speeds, Mean free path, Equipartition of energy, Brownian motion, van
der Waal's equation of state, Review of the First law of thermodynamics and its
application, Reversible & irreversible processes, Second law of
thermodynamics, Carnot; Efficiency of heat engines, Carnot theorem, Entropy and
Disorder, Thermodynamic Functions, Maxwell relations, Clausius-Clapeyron
equation, Gibbs phase rule, Third law of thermodynamics.
Properties
of Matter: States of matter; Elastic properties of solids:
Coefficients of elasticity, Energy calculation; Flow of liquids: Equation of
continuity, Laminar and turbulent flow, Reynolds number & its
significance, Bernoullis theorem and its application; Viscosity: poiseulles
equation, Motion in a viscous medium, Determination of coefficient of
viscosity; Surface tension: Surface tension as a molecular phenomenon, Surface
tension and surface energy, Capillarity and angle of contact, Quincke's
method.
<<
Back
Course Code:PHY 104
Credit:1.00
Credit Hour:1.00
Prerequisite:n/a
Experiments
based on Phy 103
<<
Back
Course Code: ENG
101
Credit:3.00
Credit Hour:3.00
Prerequisite:n/a
The course
aims at developing proficiency in speaking, listening, reading, and writing of
English. It is generalized as a remedial course for students whose English need
considerable repair and as a foundation courses for ENG 103. The contents
include parts of speech, count and uncountable nouns and articles, agreement
between subject and verb, adverbs of frequency, tense and the sequence of
tenses, active and passive voices, types of sentences, prepositions: time,
place, action, directions, questions forms, multi-word verbs,
capitalization.
<<
Back
Course Code:ENG 103
Credit:3.00
Credit Hour:3.00
Prerequisite:ENG 101
A course to
provide solid foundation on study skills in English reading writing, listening
comprehension and speaking. The course emphasizes the practice of
pronunciation, speed-reading, and effective writing and listening. The course
contents include the grammar parts of revision of tenses, use of idioms,
prepositions, modals, conditional sentence, use of linking words, use of
suffixes and prefixes, synonyms and antonyms, words with multi names, reading
parts include the skills in skimming, scanning, selecting information, writing
parts include planning, outlining, organizing ideas, topic sentences, paragraph
writing, essay writing, job applications, writing reports, writing research
report.
<<
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Ordinary and Partial
Differential Equations
Course Code:MATH 155
Credit:3.00
Credit Hour:3.00
Prerequisite:Math 151
Ordinary
Differential Equations: Degree and order of ordinary differential equations.
Formation of differential equations. Solutions of first order differential
equations by various methods. Solutions of general linear equations of second
and higher orders with constant coefficients. Solution of homogeneous linear
equations. Solution of differential equation of the higher order when the
dependent or independent variable is absent. Solution of differential equation
by the method based on the factorization of the operators. Frobenius method. Partial
differential equations: Wave equations. Particular solutions with boundary and
initial conditions.
<<
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Course Code:ETE 103
Credit:3.00
Credit Hour: 3.00
Prerequisite:n/a
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 simultaneously excited by sinusoidal
sources of several frequencies, transient response of RL and RC circuits with
sinusoidal excitation. Resonance in ac circuits: Series and parallel resonance.
Magnetically coupled circuits. Analysis of three phase circuits: Three phase
supply, balanced and unbalanced circuits, power calculation.
<<
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Course Code:ETE 104
Credit:1.00
Credit Hour:1.00
Prerequisite:n/a
This course
consists of two parts. In the first part, students will perform experiments to
verify practically the theories and concepts learned in EEE 101 and EEE 103. In
the second part, students will design simple systems using the principles
learned in EEE 101 and EEE 103.
<<
Back
Course Code:ENG 103
Credit:3.00
Credit Hour:3.00
Prerequisite:ENG 101
A course to
provide solid foundation on study skills in English reading writing, listening
comprehension and speaking. The course emphasizes the practice of
pronunciation, speed-reading, and effective writing and listening. The course
contents include the grammar parts of revision of tenses, use of idioms,
prepositions, modals, conditional sentence, use of linking words, use of
suffixes and prefixes, synonyms and antonyms, words with multi names, reading parts
include the skills in skimming, scanning, selecting information, writing parts
include planning, outlining, organizing ideas, topic sentences, paragraph
writing, essay writing, job applications, writing reports, writing research
report.
<<
Back
Coordinate Geometry and
Vector Analysis
Course Code:MATH 201
Credit:3.00
Credit Hour:3.00
Prerequisite:n/a
Two-dimensional
co-ordinate Geometry: Change of axes-transformation of co-ordinates,
simplification of equations of curves.
Three-dimensional
co-ordinate Geometry: System of co-ordinates, distance between two points,
section formula, projection, direction cosines, equations of planes and
lines.
Vector
Analysis: Definition of vectors. Equality, addition and multiplication of
vectors. Linear dependence and independence of vectors. Differentiation and
integration of vectors together with elementary applications. Definitions of
line, surface and volume integrals. Gradient of a scalar function, divergence
and curl of a vector function. Physical significance of gradient, divergence
and curls. Various formulae. Integral forms of gradient, divergence and curl.
Divergence theorem. Stoke's theorem, Green's theorem and Gauss's theorem.
<<
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Financial and Managerial
Accounting
Course Code:ACT 111
Credit:3.00
Credit Hour:3.00
Prerequisite:n/a
Financial
Accounting: Objectives and importance of accounting; Accounting as an
information system; Computerized system and applications in accounting.
Recording system: double entry mechanism; accounts and their classification;
Accounting equation; Accounting cycle: journal, ledger, trial balance;
Preparation of financial statements considering adjusting and closing entries;
Accounting concepts (principles) and conventions.
Financial
statement analysis and interpretation: ratio analysis.
Cost and
Management Accounting: Cost concepts and classification; Overhead cost: meaning
and classification; Distribution of overhead cost; Overhead recovery
method/rate; Job order costing: preparation of job cost sheet and quotation
price; Inventory valuation: absorption costing and marginal/variable costing
techniques; Cost-Volume-Profit analysis: meaning breakeven analysis,
contribution margin approach, sensitivity analysis.
Short-term
investment decisions: relevant and differential cost analysis. Long-term
investment decisions: capital budgeting, various techniques of evaluation of
capital investments.
<<
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Course Code:ETE 105
Credit:3.00
Credit Hour:3.00
Prerequisite:EEE 103
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: Basic structure. 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 BJT amplifier
circuits and their configurations: Voltage and current gain, input and output
impedances. Metal-Oxide-Semiconductor Field-Effect-Transistor (MOSFET) as
circuit element: structure and physical operation of MOSFETs, body effect,
current- voltage characteristics of MOSFETs, 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.
<<
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Course Code:CHEM 101
Credit:3.00
Credit Hour:3.00
Prerequisite:n/a
Atomic
structure, quantum numbers, electronic configuration, periodic table;
Properties and uses of noble gases; Different types of chemical bonds and their
properties; Molecular structure of compounds; Selective organic reactions;
Different types of solutions and their compositions; Phase rule, phase diagram
of mono component system; Properties of dilute solutions; Thermochemistry,
chemical kinetics, chemical equilibria; Ionization of water and pH concept;
Electrical properties of Solution.
<<
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Course Code:CHEM 102
Credit:1.00
Credit Hour:1.00
Prerequisite:n/a
Experiments
based on CHEM 101
<<
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Linear
Algebra and Matrices
Course Code:MATH 203
Credit:3.00
Credit Hour:3.00
Prerequisite:Math 155
Matrices:
Definition, equality, addition, subtraction multiplication, transposition,
inversion, rank. Equivalence, solution of equations by matrix method. Vector
space, Eigen values and Eigen vectors. Bassel's and Legendre's differential
equations.
<<
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Structured Programming
Language
Course Code:EEE 121
Credit: 3.00
Credit Hour:3.00
Prerequisite:n/a
Overview,
Structure of C program, Data Types and Data Type Qualifier, I/O Functions-Character
I/O, Formatted I/O, Character Set, Identifiers, Keywords and Contents,
Variables, Expressions, Statement and Symbolic Constants, Arithmetic operators,
Relational Operators and Logical Operators, Assignment Operators,
Increment/Decrement Operators, Unary Operator and Conditional Operator.,
Bit-wise Operators, Comma Operator, Precedence and Associativity, Branching:
The IF statement (break and continue statement), Branching: SWITCH statement,
GOTO statement and operator, Looping: FOR statement (break and continue),
Looping: WHILE and DO WHILE statement, Storage class: Automatic, Static,
Register and Extern, Functions: Access, Prototype, Argument Passing and Value
Receiving, Functions: Pass-by-value, Pass-by-reference and Value Receiving , Functions:
Command Line Parameter and Library Functions, Arrays: Initialization, Access,
Passing and Receiving , Arrays: 2D handling, Arrays: Sorting and Searching ,
String Handling , Structure: Initialization, Access, Passing and Receiving,
Structure: Embedded Structure, Union and Bit-fields, File: Types of File, Text
File Handling, File: Binary File Handling , File: Data File Management Program,
Pointer: Concept, Passing and Receiving, Memory Allocation and Release,
Pointer: List or Tree Management by Self-Referential Structure, Pointer:
Pointer and Multi-Dimensional Arrays, Enumeration, Macros, Pre-Processor and
Compiler , Directives, Library, Compiler and Linker, Segment and Memory Model,
Video Adapter, Modes and Graphics Initialization, Graphics Functions
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Structured Programming
Language Sessional
Course Code:EEE 122
Credit:3.00
Credit Hour:3.00
Prerequisite:n/a
Laboratory
work based on CSI 121
<<
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Course Code:ETE 110
Credit:1.00
Credit Hour:1.00
Prerequisite:EEE 105
Simulation
laboratory based on EEE 101, EEE 103 and EEE 105 theory courses. Students will
verify the theories and concepts learned in EEE 101, EEE 103 and EEE 105 using
simulation software like PSpice and Matlab. Students will also perform specific
design of DC and AC circuits theoretically and by simulation. Students will
learn how to write and debug programs for simulation of different mathematical
models.
<< Back
Course Code:ETE 207
Credit: 3.00
Credit Hour:3.00
Prerequisite:ETE 105
Frequency
response of amplifiers: Poles, zeros and Bode plots, amplifier transfer
function, techniques of determining 3 dB frequencies of amplifier circuits,
frequency response of single-stage and cascade amplifiers, frequency response
of differential amplifiers. Operational amplifiers (Op-Amp): Properties of
ideal Op-Amps, non-inverting and inverting amplifiers, inverting integrators,
differentiator, weighted summer and other applications of Op-Amp circuits,
effects of finite open loop gain and bandwidth on circuit performance, logic
signal operation of Op-Amp, dc imperfections. General purpose Op-Amp: DC
analysis, small-signal analysis of different stages, gain and frequency
response of 741 Op-Amp. Negative feedback: properties, basic topologies,
feedback amplifiers with different topologies, stability, frequency
compensation. Active filters: Different types of filters and specifications,
transfer functions, realization of first and second order low, high and band
pass filters using Op-Amps. Signal generators: Basic principle of sinusoidal
oscillation, Op-Amp RC oscillators, LC and crystal oscillators. Power
Amplifiers: Classification of output stages, class A, B and AB output
stages.
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Course Code:ETE 208
Credit:1.00
Credit Hour:1.00
Prerequisite:n/a
This course
consists of two parts. In the first part, students will perform experiments to
verify practically the theories and concepts learned in EEE 201 and EEE 207. In
the second part, students will design simple systems using the principles
learned in EEE 201 and EEE 207.
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Fourier and Laplace
Transforms
Course Code:MATH 157
Credit:3.00
Credit Hour:3.00
Prerequisite:Math 155
Laplace
Transforms: Definition. Laplace transforms of some elementary functions.
Sufficient conditions for existence of Laplace transforms. Inverse Laplace
transforms. Laplace transforms of derivatives. The unit step function. Periodic
function. Some special theorems on Laplace transforms. Partial fraction.
Solution of differential equations by Laplace transforms. Evaluation of
improper integrals.
Fourier
Analysis: Real and complex forms of Fourier series. Finite transform. Fourier
integral. Fourier transforms and their uses in solving boundary value
problems.
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Course Code:EEE 223
Credit:3.00
Credit Hour:3.00
Prerequisite:EEE 105
Number
systems and codes: number system, arithmetic, base conversion, signed number
representation and computer codes. Analysis and synthesis of logic circuits:
Boolean algebra, switching functions, switching circuits and combinational
logic circuits. Simplification of switching functions: K maps, Quine McCluskey
minimization method and Patrick's algorithm. Modular combinational circuit
design: decoders, encoders, multiplexers, demultiplexers, binary arithmetic
elements and comparators. Programmable logic devices: logic arrays, field
programmable logic arrays, programmable read only memory and programmable array
logic. Sequential devices: latches, flip-flops and timing circuits. Modular
sequential logic circuits: shift registers, counters and digital fraction rate
multipliers. Simple processors: simple digital system design.
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Course Code:EEE 224
Credit:1.00
Credit Hour:1.00
Prerequisite:n/a
This course
consists of two parts. In the first part, students will perform experiments to
verify practically the theories and concepts learned in CSE 223. In the second
part, students will design simple systems using the principles learned in CSE
223
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Course Code: EEE
215
Credit:3.00
Credit Hour:3.00
Prerequisite:EEE 103
Electromechanical
energy conversion fundamentals: Faraday's law of electromagnetic induction,
Fleming's rule and Lenz's law. Elementary generator: Commutation,
electromagnetic force, left hand rule, counter emf and comparison between
generator and motor action. 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.
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Signals and Linear Systems
Course Code:EEE 211
Credit:3.00
Credit Hour: 3.00
Prerequisite:Math 157 and EEE 103
Classification
of signals, basic operation on signals, elementary signals, representation of
signals using impulse function. Classification of systems, properties of Linear
Time Invariant (LTI) system like linearity, causality, time invariance, memory,
stability, invertibility. Time domain analysis of LTI systems, system
representation, order of system, solution techniques, impulse response,
convolution. Basic concepts of state variable representation of a system.
Frequency domain analysis of LTI systems, Fourier series and Fourier transforms
and their properties, system transfer function. Laplace transforms and its
properties, system transfer function, stability and frequency response,
different techniques of inverse Laplace transforms.
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Course Code: MATH
153
Credit:3.00
Credit Hour:3.00
Prerequisite:Math 201
Complex
Variable: Complex number system. General functions of a complex variable.
Limits and continuity of a function of a complex variable and related theorems.
Complex differentiation and the Cauchy-Riemann equations. Infinite series.
Convergence and uniform convergence. Line integral of a complex function Cauchy
integral formula. Liouville's theorem. Taylor's and Laurent's theorem. Singular
points. Residue, Cauchy's residue theorem.
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Course Code:ECO 213
Credit:3.00
Credit Hour:3.00
Prerequisite:n/a
Definition
of Economics; Economics and engineering; Principles of economics
Micro-Economics:
Introduction to various economic systems – capitalist, command and mixed
economy; Fundamental economic problems and the mechanism through which these
problems are solved; Theory of demand and supply and their elasticities; Theory
of consumer behavior; Cardinal and ordinal approaches of utility analysis;
Price determination; Nature of an economic theory; Applicability of economic
theories to the problems of developing countries; Indifference curve
techniques; Theory of production, production function, types of productivity;
Rational region of production of an engineering firm; Concepts of market and
market structure; Cost analysis and cost function; Small scale production and
large scale production; Optimization; Theory of distribution; Use of derivative
in economics: maximization and minimization of economic functions, relationship
among total, marginal and average concepts.
Macro-economics:
Savings; investment, employment; national income analysis; Inflation; Monetary
policy; Fiscal policy and trade policy with reference to Bangladesh; Economics
of development and planning.
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Microprocessor and
Interfacing
Course Code:EEE 423
Credit:3.00
Credit Hour:3.00
Prerequisite:EEE 121 and CSE 223
Introduction
to microprocessors. Intel 8086 microprocessor: Architecture, addressing modes,
instruction sets, assembly language programming, system design and interrupt.
Interfacing: programmable peripheral interface, programmable timer, serial
communication interface, programmable interrupt controller, direct memory
access, keyboard and display interface. Introduction to
micro-controllers.
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Microprocessor and
Interfacing Laboratory
Course Code:EEE 424
Credit:1.00
Credit Hour:1.00
Prerequisite:n/a
This course
consists of two parts. In the first part, students will perform experiments to
verify practically the theories and concepts learned in EEE 423. In the second
part, students will design simple systems using the principles learned in EEE
423.
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Probability and Random
Signal Analysis
Course Code:ETE 255
Credit:3.00
Credit Hour:3.00
Prerequisite:EEE 211
Probabilistic
and statistical analysis as applied to electrical signals and systems.
Statistics: Frequency distribution, Mean, Median, and other measures of central
tendency. Standard deviation and other measures of dispersion. Moments,
skenness and kurtosis. Probability and random variables. Distribution and
density functions and conditional probability. Expectation: Moments and
characteristic functions. Transformation of a random variable. Vector random
variables. Joint distribution and density. Independence. Sums of random variables.
Random Processes. Correlation functions. Process measurements. Gaussian and
Poisson random processes. Noise models. Stationarity and Ergodicity. Spectral
Estimation. Correlation and power spectrum. Cross spectral densities. Response
of linear systems to random inputs. Introduction to discrete time processes,
Mean-square error estimation, Detection and linear filtering.
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Electrical Properties of Materials
Course Code:ETE 301
Credit:3.00
Credit Hour:3.00
Prerequisite:PHY 103 and Math 153
Crystal
structures: Types of crystals, lattice and basis, Bravais lattice and Miller
indices. Classical theory of electrical and thermal conduction: Scattering,
mobility and resistivity, temperature dependence of metal resistivity,
Mathiessen's rule, Hall effect and thermal conductivity. Introduction to
quantum mechanics: Wave nature of electrons, Schrodinger's equation,
one-dimensional quantum problems - infinite quantum well, potential step and
potential barrier; Heisenberg's uncertainty principle and quantum box. Band
theory of solids: Band theory from molecular orbital, Bloch theorem,
Kronig-Penny model, effective mass, density-of-states. Carrier statistics:
Maxwell-Boltzmann and Fermi-Dirac distributions, Fermi energy. Modern theory of
metals: Determination of Fermi energy and average energy of electrons,
classical and quantum mechanical calculation of specific heat. Dielectric
properties of materials: Dielectric constant, polarization - electronic, ionic
and orientational; internal field, Clausius-Mosotti equation, spontaneous
polarization, frequency dependence of dielectric constant, dielectric loss and
piezoelectricity. Magnetic properties of materials: Magnetic moment,
magnetization and relative permittivity, different types of magnetic materials,
origin of ferromagnetism and magnetic domains. Introduction to
superconductivity: Zero resistance and Meissner effect, Type I and Type II
superconductors and critical current density.
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Engineering Electromagnetics
Course Code:ETE 303
Credit:3.00
Credit Hour:3.00
Prerequisite:Math 201 and Phy 103
Static
electric field: Coulomb's law for discrete and continuously distributed
charges, Gauss's law and its application, electrostatic potential, conductors
and dielectrics in static electric field, flux density - boundary conditions;
capacitance - electrostatic energy and forces, capacitance calculation of
different geometries; boundary value problems - Poisson's and Laplace's
equations. Steady electric current: Ohm's law, continuity equation, Joule's
law, resistance calculation. Static Magnetic field: Postulates of
magnetostatics, Biot-Savart's law, Ampere's law, vector magnetic potential,
magnetic dipole, magnetic field intensity and relative permeability, boundary
conditions for magnetic field, magnetic energy, magnetic forces, torque and
inductance of different geometries. Time varying fields and Maxwell's
equations: Faraday's law of electromagnetic induction, Maxwell's equations -
differential and integral forms, boundary conditions, potential functions; and
Poynting theorem. Plane electromagnetic wave: plane wave in loss less media -
Doppler effect, transverse electromagnetic wave, polarization of plane wave;
plane wave in lossy media - low-loss dielectrics, good conductors; group
velocity, instantaneous and average power densities, normal and oblique incidence
of plane waves at plane boundaries for different polarization.
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Course Code:ETE 313
Credit:3.00
Credit Hour:3.00
Prerequisite:ETE 301
Semiconductors
in equilibrium: Energy bands, intrinsic and extrinsic semiconductors, Fermi
levels, electron and hole concentrations, temperature dependence of carrier
concentrations and invariance of Fermi level. Carrier transport processes and
excess carriers: Drift and diffusion, generation and recombination of excess
carriers, built-in-field, Einstein relations, continuity and diffusion
equations for holes and electrons and quasi-Fermi level. PN junction: Basic
structure, equilibrium conditions, contact potential, equilibrium Fermi level,
space charge, non-equilibrium condition, forward and reverse bias, carrier
injection, minority and majority carrier currents, transient and ac conditions,
time variation of stored charge, reverse recovery transient and capacitance.
Bipolar junction transistor: Basic principle of pnp and npn transistors,
emitter efficiency, base transport factor and current gain, diffusion equation
in the base, terminal currents, coupled-diode model and charge control
analysis, Ebers-Moll equations and circuit synthesis. Metal-semiconductor
junction: Energy band diagram of metal semiconductor junctions, rectifying and
ohmic contacts. MOS structure: MOS capacitor, energy band diagrams and flat
band voltage, threshold voltage and control of threshold voltage, static C-V
characteristics, qualitative theory of MOSFET operation, body effect and
current-voltage relationship of a MOSFET. Junction Field-effect-transistor:
Introduction, qualitative theory of operation, pinch-off voltage and
current-voltage relationship.
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Course Code:ETE 309
Credit:3.00
Credit Hour:3.00
Prerequisite:EEE 211and EEE 255
Overview of
communication systems: fundamental elements, system limitations, message
source, bandwidth requirements, transmission media types, bandwidth and
transmission capacity. Noise: Source, characteristics of various types of noise
and signal to noise ratio. Information theory: Measure of information, source
encoding, error free communication over a noisy channel, channel capacity of a
continuous system and channel capacity of a discrete memory less system.
Communication systems: Analog and digital. Continuous wave modulation:
Transmission types - base-band transmission, carrier transmission; amplitude modulation
- introduction, double side band, single side band, vestigial side band,
quadrature; spectral analysis of each type, envelope and synchronous detection;
angle modulation instantaneous frequency, frequency modulation (FM) and phase
modulation (PM), spectral analysis, demodulation of FM and PM. Pulse
modulation: Sampling - sampling theorem, Nyquist criterion, aliasing,
instantaneous and natural sampling; pulse amplitude modulation - principle,
bandwidth requirements; pulse code modulation (PCM) - quantization principle,
quantization noise, differential PCM, demodulation of PCM; delta modulation
(DM) - principle, adaptive DM; line coding - formats and bandwidths. Digital
modulation: Amplitude-shift keying - principle, ON-OFF keying, bandwidth requirements,
detection, noise performance; phase-shift keying (PSK) - principle, bandwidth
requirements, detection, differential PSK, quadrature PSK, noise performance;
frequency-shift Keying (FSK) -principle, continuous and discontinuous phase
FSK, minimum-shift keying, bandwidth requirements, detection of FSK.
Multiplexing: Time- division multiplexing (TDM) - principle, receiver
synchronization, frame synchronization, TDM of multiple bit rate systems;
frequency-division multiplexing - principle, de-multiplexing;
wavelength-division multiplexing, multiple-access network - time-division
multiple-access, frequency-division multiple access; code-division multiple-
access (CDMA) - spread spectrum multiplexing, coding techniques and constraints
of CDMA. Communication system design: design parameters, channel selection
criteria and performance simulation.
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Course Code:ETE 310
Credit:1.00
Credit Hour:1.00
Prerequisite:n/a
Laboratory
experiments based on EEE 309
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Digital Signal Processing
Course Code:ETE 311
Credit:3.00
Credit Hour:3.00
Prerequisite:EEE 211
Introduction
to digital signal processing (DSP): Discrete-time signals and systems, analog
to digital conversion, impulse response, finite impulse response (FIR) and
infinite impulse response (IIR) of discrete-time systems, difference equation,
convolution, transient and steady state response. Discrete transformations:
Discrete Fourier series, discrete-time Fourier series, discrete Fourier
transform (DFT) and properties, fast Fourier transform (FFT), inverse fast
Fourier transform, Z transformation - properties, transfer function, poles and
zeros and inverse Z transform. Correlation: circular convolution,
auto-correlation and cross correlation. Digital Filters: FIR filters - linear
phase filters, specifications, design using window, optimal and frequency
sampling methods; IIR filters - specifications, design using impulse invariant,
bi-linear Z transformation, least-square methods and finite precision
effects.
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Digital Signal Processing
Lab
Course Code:ETE 312
Credit: 1.00
Credit Hour:1.00
Prerequisite:n/a
This course
consists of two parts. In the first part, students will perform experiments to
verify practically the theories and concepts learned in EEE 311. In the second
part, students will design simple systems using the principles learned in EEE
311.
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Course Code:CSE 323
Credit:3.00
Credit Hour:3.00
Prerequisite:ETE 309
Network
architectures- layered architectures and ISO reference model: data link
protocols, error control, HDLC, X.25, flow and congestion control, virtual
terminal protocol, data security, Local area networks, satellite networks,
packet radio networks, Introduction to ARPANET, SNA and DECNET, Topological
design and queuing models for network and distributed computing systems.
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Course Code:CSE 324
Credit:1.00
Credit Hour:1.00
Prerequisite:n/a
Laboratory
work based on CSE 323
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Course Code:ETE 455
Credit:3.00
Credit Hour:3.00
Prerequisite:ETE 309
Introduction:
Communication channels, mathematical model and characteristics. Probability and
stochastic processes. Source coding: Mathematical models of information,
entropy Huffman code and linear predictive coding. Digital transmission system:
Base band digital transmission, inter-symbol interference, bandwidth, power
efficiency, modulation and coding trade-off. Receiver for AWGN channels:
Correlation demodulator, matched filter demodulator and maximum likelihood
receiver. Channel capacity and coding: Channel models and capacities and random
selection of codes. Block codes and conventional codes: Linear block codes,
convolution codes and coded modulation. Spread spectrum signals and
system.
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Digital Communication
Laboratory
Course Code:ETE 456
Credit:1.00
Credit Hour:1.00
Prerequisite:n/a
This course
consists of two parts. In the first part, students will perform experiments to
verify practically the theories and concepts learned in ETE 455. In the second
part, students will design simple systems using the principles learned in ETE
455.
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Information Theory and
coding
Course Code:ETE 495
Credit:3.00
Credit Hour:3.00
Prerequisite:ETE 309 and ETE 255
Basic
concepts of information theory and its measurement, error coding in
communication systems. Entropy, zero-memory information source, Markov
information source. Adjoin source, language structure. Huffman codes, LZ,
arithmetic codes. Introduction to rate distortion theory. Channel coding
theorem, channel capacity, Shannon limit. Block codes: characteristics of block
codes, non-singular block codes, uniquely decodable codes, instantaneous codes,
Kraft’s inequality. Error detection, Burst error detecting and correcting
codes, linear block codes, binary cyclic codes, Hamming codes, BCH codes, and Read-Solomon
codes, encoding, Syndrome decoding and decoding algorithms. Introduction to
convolution codes, code tree, trellis, state diagram, maximum likelihood
decoding and the Viterbi algorithm. Trellis-coded modulation and Ungerboeck
codes. Introduction to Turbo coding. Selection of coding scheme.
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Course Code:ETE 400
Credit:1.50
Credit Hour:1.50
Prerequisite:n/a
A final
year project based on Electrical Engineering or Computer Engineering
Problems.
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Course Code:ETE 441
Credit: 3.00
Credit Hour:3.00
Prerequisite:ETE 207 and CSE 223
VLSI
technology: Top down design approach, technology trends and design styles.
Review of MOS transistor theory: Threshold voltage, body effect, I-V equations
and characteristics, latch-up problems, NMOS inverter, CMOS inverter,
pass-transistor and transmission gates. CMOS circuit characteristics and
performance estimation: Resistance, capacitance, rise and fall times, delay,
gate transistor sizing and power consumption. CMOS circuit and logic design:
Layout design rules and physical design of simple logic gates. CMOS subsystem
design: Adders, multiplier and memory system, arithmetic logic unit.
Programmable logic arrays. I/O systems. VLSI testing.
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Course Code:ETE 442
Credit:1.00
Credit Hour: 1.00
Prerequisite:n/a
This course
consists of two parts. In the first part, students will perform experiments to
verify practically the theories and concepts learned in ETE 441. In the second
part, students will design simple systems using the principles learned in ETE
441.
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Telecommunication
Engineering
Course Code:ETE 459
Credit:3.00
Credit Hour:3.00
Prerequisite:ETE 309
Introduction:
Principle, evolution, 'networks, exchange and international regulatory bodies.
Telephone apparatus: Microphone, speakers, ringer, pulse and tone dialing
mechanism, side-tone mechanism, local and central batteries and advanced
features. Switching system: Introduction to analog system, digital switching
systems - space division switching, blocking probability and multistage
switching, time division switching and two dimensional switching. Traffic
analysis: Traffic characterization, grades of service, network blocking
probabilities, delay system and queuing. Modem telephone services and network:
Internet telephony, facsimile, integrated services digital network,
asynchronous transfer mode and intelligent networks. Introduction to cellular
telephony and satellite communication.
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Course Code:IPE 401
Credit:3.00
Credit Hour:3.00
Prerequisite:n/a
Introduction,
evolution, management function, organization and environment. Organization:
Theory and structure; Coordination; Span of control; Authority delegation;
Groups; Committee and task force; Manpower planning.
Personnel
Management: Scope; Importance; Need hierarchy; Motivation; Job redesign;
Leadership; Participative management; Training; Performance appraisal; Wages
and incentives; Informal groups; Organizational change and conflict.
Cost and Financial Management; Elements of costs of products depreciation;
Break-even analysis; Investment analysis; Benefit cost analysis.
Management Accounting: Cost planning and control; Budget and budgetary
control; Development planning process.
Marketing Management:
Concepts; Strategy; Sales promotion; Patent laws.
Technology
Management: Management of innovation and changes; Technology life cycle; Case studies.
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Course Code:ETE 400
Credit:2.00
Credit Hour:2.00
Prerequisite: n/a
A final
year project based on Electrical Engineering or Computer Engineering
Problems.
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Course Code:ETE 433
Credit:3.00
Credit Hour:3.00
Prerequisite:ETE 207 and ETE 313
Optical
properties in semiconductor: Direct and indirect band-gap materials, radiative
and non-radiative recombination, optical absorption, photo-generated excess
carriers, minority carrier life time, luminescence and quantum efficiency in
radiation. Properties of light: Particle and wave nature of light,
polarization, interference, diffraction and blackbody radiation. Light emitting
diode (LED): Principles, materials for visible and infrared LED, internal and
external efficiency, loss mechanism, structure and coupling to optical fibers.
Stimulated emission and light amplification: Spontaneous and stimulated emission,
Einstein relations, population inversion, absorption of radiation, optical
feedback and threshold conditions. Semiconductor Lasers: Population inversion
in degenerate semiconductors, laser cavity, operating wavelength, threshold
current density, power output, optical and electrical confinement. Introduction
to quantum well lasers. Photo-detectors: Photoconductors, junction
photo-detectors, PIN detectors, avalanche photodiodes and phototransistors.
Solar cells: Solar energy and spectrum, silicon and schottky solar cells.
Modulation of light: Phase and amplitude modulation, electro-optic effect,
acousto-optic effect and magento-optic devices. Introduction to integrated
optics.
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Mobile Cellular
Communication
Course Code:ETE 457
Credit:3.00
Credit Hour:3.00
Prerequisite:ETE 309
Introduction:
Concept, evolution and fundamentals. Analog and digital .cellular systems.
Cellular Radio System: Frequency reuse, co-channel interference, cell splitting
and components. Mobile radio propagation: Propagation characteristics, models
for radio propagation, antenna at cell site and mobile antenna. Frequency
Management and Channel Assignment: Fundamentals, spectrum utilization,
fundamentals of channel assignment, fixed channel assignment, non-fixed channel
assignment, traffic and channel assignment. Handoffs and Dropped Calls: Reasons
and types, forced handoffs, mobile assisted handoffs and dropped call rate.
Diversity Techniques: Concept of diversity branch and signal paths, carrier to
noise and carrier to interference ratio performance. Digital cellular systems:
Global system for mobile, time division multiple access and code division
multiple access.
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Course Code:ETE ***
Credit:3.00
Credit Hour:3.00
Prerequisite:n/a
Elective
courses are divided into two categories: Elective I and Elective II. Elective I
courses are offered to build up the foundation on the specialized fields in
Telecommunication Engineering. Elective II courses are offered with their
companion laboratory courses so that the students get balanced education both
on theory and practice. Two courses from Elective I and one from Elective II
need to be taken.
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Course Code:ETE 400
Credit: 3.00
Credit Hour:3.00
Prerequisite:n/a
A final
year project based on Electrical Engineering or Computer Engineering Problems.
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Course Code:ETE ***
Credit:3.00
Credit Hour:3.00
Prerequisite:n/a
Elective
courses are divided into two categories: Elective I and Elective II. Elective I
courses are offered to build up the foundation on the specialized fields in
Telecommunication Engineering. Elective II courses are offered with their
companion laboratory courses so that the students get balanced education both
on theory and practice. Two courses from Elective I and one from Elective II
need to be taken.
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Course Code:ETE ***
Credit:3.00
Credit Hour:3.00
Prerequisite:n/a
Elective
courses are divided into two categories: Elective I and Elective II. Elective I
courses are offered to build up the foundation on the specialized fields in
Telecommunication Engineering. Elective II courses are offered with their
companion laboratory courses so that the students get balanced education both
on theory and practice. Two courses from Elective I and one from Elective II
need to be taken.
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Course Code:ETE ***
Credit:1.00
Credit Hour:1.00
Prerequisite:n/a
Elective
courses are divided into two categories: Elective I and Elective II. Elective I
courses are offered to build up the foundation on the specialized fields in
Telecommunication Engineering. Elective II courses are offered with their
companion laboratory courses so that the students get balanced education both
on theory and practice. Two courses from Elective I and one from Elective II need
to be taken.
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Society, Technology and
Engineering Ethics
Course Code:SOC 101
Credit:3.00
Credit Hour:3.00
Prerequisite:n/a
The course
aims at developing proficiency in speaking, listening, reading, and writing of
English. It is generalized as a remedial course for students whose English need
considerable repair and as a foundation courses for ENG 103. The contents
include parts of speech, count and uncountable nouns and articles, agreement
between subject and verb, adverbs of frequency, tense and the sequence of
tenses, active and passive voices, types of sentences, prepositions: time,
place, action, directions, questions forms, multi-word verbs,
capitalization.
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Analog Integrated
Circuits
Course Code:ETE 435
Credit:3.00
Credit Hour:3.00
Prerequisite:ETE 207
Review of
FET amplifiers: Passive and active loads and frequency limitation. Current
mirror: Basic, cascade and active current mirror. Differential Amplifier:
Introduction, large and small signal analysis, common mode analysis and
differential amplifier with active load Noise: Introduction to noise, types,
representation in circuits, noise in single stage and differential amplifiers
and bandwidth. Band-gap references: Supply voltage independent biasing,
temperature independent biasing, proportional to absolute temperature current
generation and constant transconductance biasing. Switch capacitor circuits:
Sampling switches, switched capacitor circuits including unity gain buffer,
amplifier and integrator. Phase Locked Loop (PLL): Introduction, basic PLL and charge
pumped PLL.
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Course Code:ETE 445
Credit:3.00
Credit Hour:3.00
Prerequisite: ETE
441
VLSI MOS
system design: Layout extraction and verification, full and semi-full custom
design styles, logical and physical positioning. Design entry tools: schematic
capture and HDL. Logic and switch level simulation. Static timing, concepts and
tools of analysis, solution techniques for floor planning, placement, global
routing and detailed routing. Application specific integrated circuit design
including FPGA.
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Course Code:ETE 461
Credit:3.00
Credit Hour:3.00
Prerequisite:ETE 303
Basics of
antenna: gain and effective area; radiation pattern, gain and radiation
impedance of monopole, dipole, folded dipole, array of isotropic radiators;
Antenna as an aperture: Babinet’s principle, horn and reflector type of
antenna. Printed antennas. Propagation of radio waves – broadcast and line of
sight, transmission and reception of radio waves, effect of earth’s curvature;
long, medium and short wave propagation, ionospheric propagation, scattering in
radio links, effect of rain and dust.
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Course Code:ETE 463
Credit:3.00
Credit Hour:3.00
Prerequisite:ETE 303 and ETE 309
Brief
history and overview of satellite communications, communication satellite
systems, communication satellites, orbiting satellites, satellite frequency
bands, satellite multi-access formats, the Regulatory Bodies. Frequency
allocations. Fundamental orbital laws, GEO, MEO, LEO satellites, subsystems of
a communication satellite, earth station, satellite link analysis, attenuation,
effect of rain on propagation. Modulation and multiplexing techniques for
satellite link, Communication payload, transponders, coverage. Multiple access
techniques: FDMA, SPADE, TDMA, CDMA, Antijam advantage of spectral spreading,
satellite jamming, DS-CDMA acquisition and tracking, FH-CDMA acquisition and
tracking, random access. Phase coherency in satellite systems: carrier
phase-noise, phase noise spectra, carrier frequency and phase stability, phase
errors in carrier referencing. Satellite ranging systems: ranging systems,
component-ranging codes, and tone-ranging systems. Inter-satellite links, VSAT
satellite system concept, link analysis, mobile-satellite communication
systems, mobile satellite channel, direct home TV broadcasting.
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Course Code:ETE 465
Credit:3.00
Credit Hour:3.00
Prerequisite:ETE 309 and ETE 311
Some basics
on television systems, multidimensional signals and Fourier transform, multidimensional
(space-time) sampling, interlaced and non-interlaced scanning: Information
theory: conditional and joint entropy and redundancy, source coding theorem,
statistical source models, mutual information rate distortion theory:
Predictive coding: linear prediction, quantization, optimum predictor; Discrete
two-dimensional transforms: DFT, DCT,. wavelet and Hadamard transforms;
Transform Coding with motion estimation, principles of MPEG coding; Modern
audiovisual terminals and communication systems.
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Telecommunication Policy and
Management
Course Code:ETE 469
Credit:3.00
Credit Hour:3.00
Prerequisite:ETE 309
International
telecommunication organizations, trans-border data flow, barriers to trade in
information equipment and services, development of competition, and World Trade
Organization telecommunication agreement. Policy problems created by the
vulnerability of telecommunication and computer networks to accidental or
intentional attacks, dependence of economic and military security on
telecommunication networks, information warfare, privacy and surveillance,
international trade and information security. Fundamentals of daily
telecommunication operations, including human factors in organization,
acquisition and procurement, research and development, logistical planning, and
relations with carriers and manufacturers.
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Special Topics on
Telecommunication Engineering
Course Code:ETE 493
Credit:3.00
Credit Hour:3.00
Prerequisite:ETE 309
This course
is aimed at covering topics of current interest and new technology of
Telecommunication Engineering
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Course Code:EEE 491
Credit: 3.00
Credit Hour:3.00
Prerequisite:ETE 309, ETE 311
Human body:
Cells and physiological systems. Bioelectricity: genesis and characteristics.
Linear and Nonlinear Models of Biological Systems.
Measurement
of bio-signals: Ethical issues, transducers, amplifiers and filters.
Electrocardiogram: electrocardiography, phono cardiograph, analysis and
interpretation of cardiac signals, cardiac pacemakers and defibrillator. Blood
pressure: systolic, diastolic mean pressure, electronic manometer, detector
circuits and practical problems in pressure monitoring. Electroencephalogram:
cerebral angiograph and analysis of EEG signals. Brain scans. Electromayogram
(EMG). Tomograph: Positron emission tomography and computer tomography.
Magnetic resonance imaging. Ultrasonogram. Telemedicine. Effect of
electromagnetic fields on human body.
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Introduction to Software
Radios
Course Code: EEE
499
Credit:3.00
Credit Hour:3.00
Prerequisite:ETE 309, ETE 311
Introduction
& Foundational Principles, RF Design for DSP Engineers, Digital Generation
of Signals, Analog to Digital Conversion, Equalization and Interference
Rejection, Synchronization, Demodulation and Decoding, Real-Time Programming
Issues, Case Studies in Software Radio Design
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Advanced DSP and Filter
Design
Course Code:EEE 467
Credit:3.00
Credit Hour:3.00
Prerequisite:ETE 309, ETE 311
Sampling,
interpolation, and decimation; Fast Fourier Transform (FFT), fast convolution
by FFT using the overlap-save or overlap-add methods; Bandpass sampling; IIR
and FIR filter design and implementation issues: filter structures, coefficient
quantization and sensitivity, finite wordlength arithmetic or signal
quantization, limit cycles, noise shaping; Spectral estimation methods, Basic
adaptive filtering.
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Optical Fiber Communication
Course Code:EEE 453
Credit:3.00
Credit Hour:3.00
Prerequisite:ETE 303 and ETE 313
Introduction.
Light propagation through optical fiber: Ray optics theory and mode theory.
Optical fiber: Types and characteristics, transmission characteristics, fiber
joints and fiber couplers. Light sources: Light emitting diodes and laser
diodes. Detectors: PIN photo-detector and avalanche photo-detectors. Receiver
analysis: Direct detection and coherent detection, noise and limitations.
Transmission limitations: Chromatic dispersion, nonlinear refraction, four wave
mixing and laser phase noises. Optical amplifier: Laser and fiber amplifiers,
applications and limitations. Multi-channel optical system: Frequency division
multiplexing, wavelength division multiplexing and co-channel interference.
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Course Code:ETE 467
Credit:3.00
Credit Hour:3.00
Prerequisite:ETE 303 and ETE 309
Some basics
on television systems, multidimensional signals and Fourier transform,
multidimensional (space-time) sampling, interlaced and non-interlaced scanning:
Information theory: conditional and joint entropy and redundancy, source coding
theorem, statistical source models, mutual information rate distortion theory:
Predictive coding: linear prediction, quantization, optimum predictor; Discrete
two-dimensional transforms: DFT, DCT,. wavelet and Hadamard transforms;
Transform Coding with motion estimation, principles of MPEG coding; Modern
audiovisual terminals and communication systems.
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Course Code:ETE 443
Credit:3.00
Credit Hour:3.00
Prerequisite:ETE 207
Power
semiconductor switches and triggering devices: BJT, MOSFET, SCR, IGBT, GTO,
TRIAC, UJT and DIAC. Rectifiers: Uncontrolled and controlled single phase and
three phase. Regulated power supplies: Linear-series and shunt, switching buck,
buck boost, boost and Cuk regulators. AC voltage controllers: single and three
phase. Choppers. DC motor control. Single phase cycloconverter. Inverters:
Single phase and three phase voltage and current source. AC motor control.
Stepper motor control. Resonance inverters. Pulse width modulation control of
static converters.
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Power Electronics
Laboratory
Course Code:ETE 444
Credit:1.00
Credit Hour:1.00
Prerequisite: n/a
This course
consists of two parts. In the first part, students will perform experiments to
verify practically the theories and concepts learned in ETE 443. In the second
part, students will design simple systems using the principles learned in ETE
443.
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Digital Integrated Circuits
Design
Course Code:ETE 447
Credit:3.00
Credit Hour:3.00
Prerequisite: ETE
207 & CSE 223
Switching,
timing, wave shaping, and logic circuits to generate waveforms and functions
used in pulse systems, instrumentation and computers. Latches, Flip-Flops and
Synchronous System Design. Advanced CMOS Logic Design: Pseudo-NMOS and Dynamic
Precharging, Domino-CMOS logic, No-Race-Logic, Single-Phase Dynamic Logic,
Dynamic Differential Logic. Digital Integrated System Building Blocks:
Multiplexers and Decoders, Barrel shifters, counters, digital adders, PLA. Integrated
memories: SRAM, DRAM, ROM.
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Digital Integrated Circuits
Design Laboratory
Course Code:ETE 448
Credit:1.00
Credit Hour:1.00
Prerequisite:n/a
This course
consists of two parts. In the first part, students will perform experiments to
verify practically the theories and concepts learned in ETE 447. In the second
part, students will design simple systems using the principles learned in ETE
447.
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Course Code:ETE 451
Credit: 3.00
Credit Hour:3.00
Prerequisite:EEE 303
Transmission
lines: Voltage and current in ideal transmission lines, reflection,
transmission, standing wave, impedance transformation, Smith chart, impedance
matching and lossy transmission lines. Waveguides: general formulation, modes
of propagation and losses in parallel plate, rectangular and circular
waveguides. Micro strips: Structures and characteristics. Rectangular resonant
cavities: Energy storage, losses and Q.
Radiation: Small current element, radiation resistance, radiation pattern and
properties, Hertzian and halfwave dipoles. Antennas: Mono pole, horn, rhombic
and parabolic reflector, array, and Yagi-Uda antenna.
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Microwave Engineering
Laboratory
Course Code:ETE 452
Credit:1.00
Credit Hour:1.00
Prerequisite:n/a
This course
consists of two parts. In the first part, students will perform experiments to
verify practically the theories and concepts learned in EEE 451. In the second
part, students will design simple systems using the principles learned in ETE
451.
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Course Code:ETE 497
Credit:3.00
Credit Hour: 3.00
Prerequisite:ETE 309 and ETE 255
Introduction
to Wireless Components: Antenna, Amplifier, Mixer, Oscillator, Resonant
Circuits.
Noise:
Thermal Noise, Shot Noise, Noise Voltage and Power, Mixing of Noise Noise
Temperature and Noise Figure (NF), NF of Cascaded Components, NF of passive
networks.
Effects of
Nonlinearity: Harmonics, Sensitivity and Dynamic Range, Gain Compression
(P1dB), Intermodulation Distortion, Third Order Intercept Point (IP3), IP2,
Intercept points of cascaded components.
Impedance
matching: Smith chart, L-Network, Pi Network Impedance matching. Impedance
matching using smith chart.
Filter:
Filter Design: Maximally Flat, Equal ripple, Linear Phase Filter, Filter
Scaling and Transformation. Butterworth, Chebyshev response.
Amplifiers
and Oscillators: S-Parameter, Power Gain, Stability, Stability Circles, Low
Noise Amplifier (LNA) design, Characteristics of Power Amplifier (PA) and
amplifier classes. Oscillator Tuning Range, Frequency Stability, Voltage
Controlled Oscillator (VCO), Oscillator Phase Noise. Amplifier and Oscillator
Design using S-parameters.2
Mixer:
Frequency Conversion, Image Frequency, Conversion Loss, Isolation, Diode Mixer,
Image Reject Mixer.
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RF Engineering Laboratory
Course Code:ETE 498
Credit:1.00
Credit Hour:1.00
Prerequisite:n/a
This course
consists of two parts. In the tirst part, students will perform experiments to
verify practically the theories and concepts learned in EEE 497. In the second
part, students will design sample systems using the principles learned in ETE
497.
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Microprocessor Based System
Design
Course Code:CSE 421
Credit:3.00
Credit Hour:3.00
Prerequisite:CSE 423
Limitations
of 16 bit processors. 32 bit microprocessors (Intel 80386/80486, Motorola
68000) internal architecture, addressing modes, instructions, memory and I/O
interfaces, system design, programming, applications to industrial process
control. Embedded processors architecture, advanced port, programming,
controller design for adjustable speed motor devices.
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Microprocessor Based System
Design Laboratory
Course Code:CSE 422
Credit:1.00
Credit Hour:1.00
Prerequisite: n/a
This course
consists of two parts. In the first part, students will perform experiments to
verify practically the theories and concepts learned in CSE 421. In the second
part, students will design simple systems using the principles learned in CSE
421.
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