CMO 24 s2008 Annex III Course Specification For The BSECE
CMO 24 s2008 Annex III Course Specification For The BSECE
CMO 24 s2008 Annex III Course Specification For The BSECE
D. ALLIED SUBJECTS
Course Name:
Course Description
Course Objectives
Course Outline
Laboratory
Equipment
Course Name:
Course Description
Number of Units for
Lecture and
Laboratory
Number of Contact
Hours per week
Prerequisite
DISCRETE MATHEMATICS
This course deals with logic, sets, proofs, growth of functions, theory of numbers,
counting techniques, trees and graph theory.
3 units Lecture
3 hours /week
College Algebra
Course Objectives
Upon completion of the course, the student must be able to:
prove theorems and using logic
demonstrate knowledge of the basic concepts of discrete mathematics.
apply counting techniques in calculation of discrete probabilities.
use trees and graph theory in dealing with discrete mathematics problems.
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o
o
Course Outline
o
o
o
o
o
Laboratory
Equipment
Course Name:
Course Description
Number of Units for
Lecture and
Laboratory
Number of Contact
Hours per week
Prerequisite
Course Objectives
Course Outline
Laboratory
Equipment
Course Name
Course Description
No. of Units for
Lecture and
Laboratory
No. of Contact
Hours per week
Prerequisites
Course Objectives
BASIC THERMODYNAMICS
A course dealing with the thermodynamic properties of pure substances, ideal and
real gases and the study and application of the laws of thermodynamics in the
analysis of processes and cycles. It includes introduction to vapor and gas cycles.
2 units lecture
2 hours/ week
Integral Calculus, Physics 2
To give the students a good background on the principles underlying the
utilization of energy in the thermal systems; open and closed systems; and
introduction to gas and vapor cycles.
1. Introduction
2. Basic Principles, Concepts and definition
3. First Law of Thermodynamics
4. Ideal Gases/ Ideal Gas Laws
5. Processes of Ideal Gases
6. Properties of Pure Substance
7. Processes of Pure Substance
8. Introduction to cycle analysis: Second Law of Thermodynamics
9. Introduction to Gas and vapor cycles
None
FUNDAMENTALS OF MATERIALS SCIENCE AND ENGINEERING
Structure and composition of materials (metals, polymers, ceramics and
composites). Processing, properties and behavior in service environments.
3 units lecture
3 hours lecture
General Chemistry, Physics 2
At the end of the course the student must be able to:
1. Identify the importance of materials to mankind through specific examples
of materials which have had significant impact to civilization
2. Identify the different ways of classifying various materials
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Course Outline
Laboratory
Equipment
3. Identify the different material properties and how these are affected by the
composition and structure
4. Determine the ways by which material properties can be engineered or
modified to meet certain requirements related to their intended use
5. Select the appropriate material(s) for a given application
6. Evaluate feasibility of designs based on material considerations
1. Introduction (1)
2. Atomic structure and interatomic bonding (2)
3. Atomic arrangement in solids (4)
4. Structural imperfections and diffusion (5)
5. Electronic structures and processes (3)
6. Metals and their properties (4)
7. Polymers and their properties (2)
8. Ceramics and their properties (4)
9. Composite materials (3)
10. Materials selection and design considerations (3)
11. Economic, Environmental and Societal Issues in Materials Science and
Engineering
None
E. PROFESSIONAL/MAJOR SUBJECTS
Course Name:
Course Objectives
2. To apply the laws to a given situation and know the rights and obligations of
the parties.
3. Learn the intricacies of obligations and contracts.
Course Outline
Laboratory
Equipment
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Course Name:
CIRCUITS 1
Fundamental relationships in circuit theory, mesh and node equations;
Course Description resistive networks, network theorems; solutions of network problems using
Laplace transform; transient analysis; methods of circuit analysis.
Number of Units for
Lecture and
3 units lecture, 1 unit lab
Laboratory
Number of Contact
3 hours lec, 3 hours lab
Hours per week
Pre-requisite
Course Objectives
Course Outline
Laboratory
Equipment
Course Name:
CIRCUITS 2
Complex algebra and phasors; simple AC circuits, impedance and admittance;
mesh and node analysis for AC circuits; AC network theorems; power in AC
Course Description
circuits; resonance; three-phase circuits; transformers; two-port network
parameters and transfer function.
Number of Units for
Lecture and
3 units lecture, 1 unit lab
Laboratory
Number of Contact
3 hours lec, 3 hours lab
Hours per week
Prerequisite
Circuits 1
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Course Objectives
Course Outline
Laboratory
Equipment
1.
2.
3.
4.
5.
6.
7.
8.
9.
10.
11.
Course Name:
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Course Outline
Laboratory
Equipment
2.
3.
4.
5.
6.
7.
8.
9.
10.
11.
12.
13.
14.
Course Name:
Course Description
Number of Units for
Lecture and
Laboratory
Number of Contact
Hours per week
Prerequisite
30
Course Objectives
Course Outline
Laboratory
Equipment
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Course Name:
INDUSTRIAL ELECTRONICS
Course Objectives
Course Outline
Laboratory
Equipment
electronic power controls and understand how they are designed and their
applications.
1. Filtered Power Supply
2. Voltage Multiplier
3. Voltage regulators
4.1Automatic Voltage Regulators
4. Polyphase Rectifiers
5. SCRs
6. UJT
7. PUT
8. TRIAC, DIAC and other thyristors
9. Optoelectronic Devices and Sensors
10. Automatic Welding System
11. Transducers
12. Interfacing techniques
12.1 Introduction to Programmable Logic Circuits
13.Introduction to Robotics
Electronics Training Module or set of equipment and components that can
perform the following experiments:
1. Filters
2. Voltage Multiplier
3. Voltage Regulator
4. SCR
5. UJT
6. TRIAC, DIAC and other thyristors
7. Application of power electonics devices e.g IGBT, thyristors
7.1 Motor Speed Controls
7.2 Automatic Welding Controls
8. Design Project
Recommended List of Equipment:
Power Supplies, Signal Generator, Oscilloscope, Curve Tracer, Digital
Multimeter.
Course Name:
Course Description
Number of Units for
Lecture and
Laboratory
Number of Contact
Hours per week
Prerequisite
VECTOR ANALYSIS
This course deals with vector algebra, vector calculus, vector analysis, and their
applications.
3 units lec
3 hours lec
Integral Calculus
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Course Objectives
Course Outline
Algebra of Vectors
Equality of Vectors, Addition, Subtraction, Scalar Product,
Vector Product
Vector and Scalar Functions of one variable
Calculus of Vectors and vector identities
Derivative of a vector function
Directional Derivative, The del operator
Gradient, Divergence, Curl
Line Integral
Surface Integral
Volume Integral
Integral Theorems
Green's Lemma
Divergence Theorem
Stokes' Theorem
Applications
Laboratory
Equi
pmen
t
Course Name:
Course Description
ELECTROMAGNETICS
This course deals with electric and magnetic fields, resistive, dielectric and
magnetic materials, coupled circuits, magnetic circuits and fields, time-varying
electromagnetic fields, and Maxwells equations.
Course Objectives
Course Outline
Laboratory
Equipment
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Course Name:
Course Description
Number of Units for
Lecture and
Laboratory
Number of Contact
Hours per week
Prerequisite
Course Objectives
Course Outline
Laboratory
Equipment
Course Name:
Course Description
Electromagnetics, Circuits 2
The objective of the course is to introduce the concepts of energy conversion
using transducers and be able to familiarize the students with the several
applications of these devices.
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Course Outline
Laboratory
Equipment
Course Name:
Course Description
1.
2.
3.
4.
5.
6.
PRINCIPLES OF COMMUNICATIONS
Bandwidth; filters; linear modulation; angle modulation; phase locked loop; pulse
modulation; multiplexing techniques; noise analysis; radio transmitters and
receivers.
Course Objectives
Course Outline
Laboratory
Equipment
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Course Name:
Course Description
Course Objectives
Course Outline
Laboratory
Equipment
Course Name:
Course Description
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Prerequisite
Course Objectives
Course Outline
Laboratory
Equipment
Course Name:
Course Description
Course Objectives
Course Outline
37
Laboratory
Equipment
Course Name:
Course Description
Prerequisite
Course Objectives
Course Outline
8. Fiber Optics
Training Modules in Transmission lines, antennas, microwave and Optical Fibre
Communications Systems to perform the following laboratory exercises:
1. Transmission Lines
2. Antennas
3. Measurement of Frequency, Wavelength, Phase Velocity in Waveguides
4. Generation of Microwaves
5. Detection of Microwaves
6. Attenuation measurement
7. Optical Fibre System: numerical aperture, attenuation, modal theory
MICROPROCESSOR SYSTEMS
1. The course covers concepts involving microprocessor/ microcontroller
systems architecture/organization including microprocessor/microcontroller
programming, interfacing techniques, memory systems and bus standards.
2. In the laboratory the students will be involved with experiments using micro
controllers and the use of microprocessor/ micro controller development
systems and other tools. Experiment topics include: assembly language
programming topics, interfacing with input and output devices, data transfer
between micro controller-based circuits and the PC via the serial port and
parallel port.
3 units lec, 1 unit lab
3 hours lec, 3 hours lab
Logic Circuits and Switching Theory,
Computer Fundamentals and Programming,
Electronic Circuit Analysis and Design
Upon completion of the course, the student must be able to:
1. explain the concepts behind microprocessor systems and their components
2. differentiate between microprocessors and microcontrollers, between
microprocessors, and between microcontrollers based on architecture
3. develop programs to run on microprocessors/ micro controller systems
using both assembly language and high-level language via crosscompilation
4. explain how to interface microprocessors/ microcontrollers to memory, I/O
devices, and other system devices
5. explain the organization/architecture of existing computer systems (Ex.
desktops, workstations, etc.)
6. analyze the capabilities of different processors
7. program a specific microcontroller system to accept input, process data and
control physical devices
1.
2.
3.
4.
5.
6.
7.
8.
9.
Architecture
Assembly Language Programming Building Microcomputer
I/Q Interface
Overview of Z8 Microcontroller Family; Z8 Development Environment
Source Code Components; Target System Components and Z8
Connections; Basic Debugger Operations and Creating Programs
Creating Programs
Basic I/Q and Basic Programming
Speaker and Relays Interfacing; and One Time Programming
Interrupts and Hardware Timers
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Laboratory
Equipment
emulators,
personal
Course Name:
Course Description
Course Objectives
Course Outline
1.
2.
3.
4.
5.
6.
7.
8.
9.
10.
11.
12.
13.
14.
15.
16.
17.
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Laboratory
Equipment
Course Name:
Course Description
DIGITAL COMMUNICATIONS
Random variables, bit error rate; matched filter; Digital modulation techniques;
ASK, FSK, QAM, PSK/QPSK, CDMA and W-CDMA systems; signal space;
generalized orthonormal signals; information measures-entropy; channel capacity;
efficient encoding; error correcting codes information theory; data compression;
coding theory.
Course Outline
Laboratory
Equipment
Principles of Communications
Upon completion of the course, the student must be able to conceptualize,
analyze and design a digital communication system.
1.
2.
3.
4.
5.
6.
7.
8.
9.
10.
11.
Course Name:
DATA COMMUNICATIONS
Data communication systems; terminals, modems; terminal control units;
multiplexers; concentrators; front-end processors; common carrier services;
Course Description
data communication system design; computer network models; TCP/IP
principles; LAN; WAN; sample case studies
Number of Units for 3 units lec, 1 unit lab
Lecture and
40
Laboratory
Number of Contact
Hours per week
Prerequisite
Digital Communications
Course Objectives
Course Outline
Laboratory
Equipment
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Advanced Statistics
CAD-Tool Design
Solid State Physics & Fabrication
WIRELESS COMMUNICATION
(COMMUNICATION TRACK ELECTIVE)
Course Description
Covers Signal Transmission Modes; Spread Spectrum Modulation System;
42
Course Objectives
Course Outline
Laboratory
Equipment
Course Name:
Course Description
Wireless Communications
Upon completion of the course, the student must be able to conceptualize, analyze
and design a communication system.
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Course Outline
Laboratory
Equipment
Course Objectives
Course Outline
Laboratory
Equipment
BROADCAST ENGINEERING
(COMMUNICATION TRACK ELECTIVE)
Discusses operation of audio and video equipment including amplifiers,
processors, audio/video mixers, distribution amps, TV cameras, microphones,
monitors systems integration, studio electro-acoustics and lighting , TV and
Course Description
radio transmitters and propagation, coverage map calculation and frequency
analysis, broadcast networking , broadcast ancillary services ( STLs and
satellite links). Also includes CATV technology and DTH.
Course Name:
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Course Objectives
Course Outline
Laboratory
Equipment
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ADVANCED ELECTROMAGETISM
(COMMUNICATION TRACK ELECTIVE, ALSO FOR MICRO
ELECTRONICS TRACK)
This course deals with the study of Maxwells equations, the propagation and
Course Description
transmission of electromagnetic waves in different media, and their applications.
Number of Units for
Lecture and
3 units lecture, 1 unit lab
Laboratory
Course Name:
Number of Contact
Hours per week
Year and Term to Be
Taken
Prerequisite
Course Objectives
Course Outline
Laboratory
Equipment
E-2. MICROELECTRONICS TRACK
INTRODUCTION TO ANALOG INTEGRATED CIRCUIT DESIGN
(MICROELECTRONICS TRACK)
Focuses on Analog IC Fabrication processes, Analog device Modeling and Circuit
Course Description simulation. Design and Characterization of Analog circuit building blocks such
Amplifiers, Comparators, Operational Amplifiers and other analog systems.
Number of Units for
Lecture and
2 units lecture, 1 unit lab
Laboratory
Number of Contact
2 hours lec, 3 hours lab
Hours per week
Course Name:
Course Objectives
Course Outline
Laboratory
Unix Workstation
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Equipment
Course Objectives
Course Outline
Laboratory
Equipment
47
Course Objectives
Course Outline
Laboratory
Equipment
Course Name:
Course Description
Course Objectives
Course Outline
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Laboratory
Equip
ment
1.
2.
3.
4.
5.
6.
7.
8.
Course Objectives
Course Outline
Laboratory
Equip
ment
lecture - 3 hours
Basic Electronics, Electromagnetics
Upon completion of the course, the student must be able to
1. discuss applications of power electronics
2. identify different types of electronic power supply
3. analyze various power supply designs
4. evaluate power supply performance
5. appreciate energy efficient of electronics power supply
Fundamentals of Power Electronics
1. Semiconductors Switches
2. Passive Components for Electronics Power supply
3. Rectifiers
4. Pase controlled rectifiers and converters
5. Switch-Mode Power Supply
6. Inverters
7. Resonant Converters
1. Spectrum Analyzer
2. Oscilloscope
3. Signal Generator
4. Multi-meter
5. Watt meter
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Course Objectives
Course Outline
Laboratory
Equipment
Course Name
Course Description
1.
2.
3.
4.
Spectrum Analyzer
Oscilloscope
Multi-Meter, Clamp Meter
Watt Meter
50
Course Outline
Laboratory
Equipment
1.
2.
3.
4.
1.
2.
3.
4.
5.
6.
7.
8.
Course Outline
Laboratory
Equipment
1.
2.
3.
4.
DC Motors
AC Motors
Servo Motors and Controls
DC Power Supply
51
Course Objectives
Course Outline
Laboratory
Equipment
PHYSIOLOGY
(BIOMEDICAL ELECTRONICS TRACK)
The objective of this course is to present the basic principles of human physiology
which apply to homeostasis, cell membrane potentials and transport mechanisms,
Course Description nerve and muscle, and heart and the circulatory system, microcirculation and the
lymphatic system, the blood, the respiratory system, the renal system, the
gastrointestinal system and the endocrine system.
Number of Units for
Lecture and
2 units lecture, 1 unit lab
Laboratory
Number of Contact
2 hours lec, 3 hours lab
Hours per week
Course Name:
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Prerequisite
Cell Biology and Genetics, Organic chemistry, Biochemistry, Cell biology and
genetics, Anatomy
Upon successful completion of this course, the student will:
Understand the roles of blood and its flow, blood pressure and how they
are regulated; basic functions of the components of the blood plasma; the
processes that result in the coagulation of the blood
Understand the function of the hormones of the pancreatic islets and their
regulation of plasma glucose concentration
Course Objectives
Course Outline
Cardiovascular
Circulatory
Respiratory
Endocrine
Gastrointestinal
Neuromuscular
Skeletal
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Course Outline
The microcirculation
Blood components
The kidneys
The liver
Laboratory
Equipment
Muscle physiology
Cardiac Physiology
Vascular physiology
54
Course Objectives
Course Outline
Introduction to imaging
Radiation
Computed tomography
Ultrasound imaging
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BIOMECHANICS
(BIOMEDICAL ELECTRONICS TRACK)
This course is an introduction to the biomechanics of human movement, with
applications to occupational, rehabilitation, forensic and sports biomechanics.
Course Description Topics covered include kinematics; anthropometry; kinetics; mechanical work,
energy, and power; synthesis of human movement; muscle mechanics; and
kinesiological electromyography.
Number of Units for
Lecture and
lecture - 2 units, Laboratory 1 unit
Laboratory
Course Name:
Number of Contact
Hours per week
Prerequisite
Course Objectives
Course Outline
Laboratory Exercises
lecture - 2 hours
laboratory 3 hours
Fundamentals of Biomedical Engineering
Mechanics and Dynamics
Upon successful completion of this course, the student will:
define the terms, anatomical axes, and planes associated with human
movement
Anthropometry
Joint motion
Measurement and use of anthropometic data for the development of linksegment models
56
Laboratory
Equipment
MATLAB Software
BIOMATERIALS
(BIOMEDICAL ELECTRONICS TRACK)
This course deals with the principles, which apply, to the properties and
selection of different types materials used in medical applications. Topics
Course Description
include metals, ceramics, polymers, composites, biological tissues, wound
healing, and the interaction between biological tissues and artificial materials.
Number of Units for
Lecture and
3 units lecture
Laboratory
Number of Contact
3 hours lecture
Hours per week
Course Name:
Course Objectives
Course Outline
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corrosion
Laboratory
Equipment
None.
BIOPHYSICAL PHENOMENA
(MEDICAL ELECTRONICS TRACK)
This course presents the fundamental principles of classical thermodynamics, heat
Course Description transfer, fluid mechanics, and mass transport and the application of these
principles to the solution of problems with focus on biomedical engineering.
Number of Units for
Lecture and
2 units lecture, 1 unit lab
Laboratory
Number of Contact
2 hours lecture, 3 hours lab
Hours per week
Course Name:
state the First Law of thermodynamics and apply it to open and closed
systems
58
Course Outline
Flow measurement
Energy balance
59
Laboratory
Equipment
Course Name
Course Description
The nature of technical communication; skills and strategies for reading and
writing literature reviews, journal articles, and technical reports; making oral
presentations.
3 units lecture
Number of Contact
Hours per Week
3 hours lecture
Prerequisites
English 1
English 2
Course Objectives
Course Outline
Laboratory Equipment
60
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