|
Electronic Systems Engineering Courses
EE063 Digital Circuit Design II, (2,2,0)
Prereq. EE043
 Finite state machine:
Moore and Mealy machines traditional approach to design,
multi-input controller design- mnemonic state transition
diagram, use of VEMs and MSI components. Asynchronous
input-timing problems, synchronizing inputs,
handshaking. Asynchronous outputs-effects of timing
hazards and races. Digital system design: function,
specifications, partitioning, describing system
operation as algorithm; systolic arrays - identifying a
basic cell, arithmetic cell, multiplier cell Computer
aids to digital system design: simplification of Boolean
expressions, introduction to HILO.
EE073 Electronic Circuits II, (2,2,0)
Prereq. EE053
Multiple transistor
amplifiers: cascade stages, difference amplifier,
Darlington circuit, power amplifiers Noise : source and
models for bipolar and field effect transistor.
Feedback: concepts, effect on performance, stability.
Opamp: design, linear and non-linear applications
include: inverting and non-inverting amplifiers,
integrator, computation, voltage follower, comparator,
Schmitt trigger, Astable, monostable, logarithmic
amplifier, multiplier.
EE083
Signals and Systems, (2,2,0)
Prereq. None
Concepts of continuous
and discrete signals and systems. Singularity functions.
Differential and difference equations. Convolution,
Fourier transform. Z Transform. System transfer
function. State variables. Stability.
EE093
Electromagnetic Fields Theory, (2,2,0)
Prereq. PH023
Electric and magnetic
fields using vector analysis. Maxwell’s equations, laws
of Coulomb, Gauss, Ampere, and Fraday. Concepts of
energy and potential. Poisson and Laplace fields. Wave
equation and plane wave.
EE103
Power Electronics, (2,2,0)
Prereq. EE033, EE053
The application of
electronics to energy conversion and control.
Phase-controlled rectifier/ inverters, circuits, do/dc
converters, high-frequency inverters, and motion control
systems, uninteirruptable power supplies, variable speed
drives actives filtering and harmonic cancellation.
EE113
Analogue Network Design
Prereq.
EE073
Power
supplies: rectification, filtering, voltage regulation,
short-circuit and over voltage protection. Oscillations:
Barkhausen criterion, RC ladder and Wien bridge
oscillators, crystal oscillators, amplitude
stabilization.
Imperfection in Operational Amplifiers (Op-amps’s) and
their effects on network
design. Noise in analogue networks. Filters; filter
approximations; time-domain filters; passive filters,
sensitivity, cascade synthesis; coping methods. Negative
impedance converters ;sinusoidal oscillators. Nullor and
earth-point transformations. Logarithmic and
antilogarithmic amplifiers.
Top
EE123
Communications Engineering I,
(2,2,0)
Prereq. EE083
Amplitude Modulation; DSB-LC, DSB-SC, SSB, VSB,
modulators & demodulators. Frequency and Phase
modulation; modulators & demodulators. Radio receivers;
Super-heterodyning. Effect of noise on communications
systems; the performance of AM and FM systems in the
presence of noise. Communication link budgets.
EE133 Microprocessor Systems, (2,2,0)
Prereq. None
Microprocessor terminology.
.Microprocessor architecture registers ; A L U stacks
information flow and control . Microprocessor support
hardware , R AMS ,ROMS ,P L A s,counter timer.Hardware
and software of typical 8 – bit microprocessor .1/0
structure in microprocessor –based systems, interrupts
and D M A operations.Introduction to 16 –bit
microprocessor ,and bit –slice microprocessor .Design,
construction ,and programming of microprocessor- based
systems .
EE143
Feedback Control Systems, (2,2,0)
Prereq. EE083
Definition of control: difference
between open-loop and closed-loop control systems.
Representation of control systems by block diagrams.
Calculation of open-loop & closed-loop transfer
functions from the block diagram. Time response analysis
of 1st order control systems. Analysis of the different
types of 2nd order system: underdamped, critically
damped, and overdamped. Design of linear feedback
systems for command- following error, stability, and
dynamic response specifications.
EE153
Instrumentation, (2,2,0)
Prereq. None
Measurement systems for research
and manufacturing. Instrument characteristics. Digital
and analog techniques and device in instrumentation.
Transducers. Signal conditioners. Displays Control
devices. Statistics of measurement.
EE163
Communication Engineering II, (2,2,0)
Prereq. EE123
Digital
Communications: sampling theorem, analogue pulse
modulation techniques: PAM, PWM, PPM. Digital pulse
modulation techniques: PCM, APCM, DPCM. Delta
modulation, concepts of base band communication, effect
of noise on baseband communication and noise immunity.
Passband modulation: ASK, PSK, FSK. Effect of noise on
the pass band modulation.
EE173 Digital Signal processing, (2,2,0)
Prereq.
None
Introduction
to computer implemented signal processing system.
Sampling : Nyquist's theorem, Shannon's theorem,
representation of digital signals, digital impulse
response and transfer functions; density function,
correlation and convolution. Z-transforms, digital
Fourier transform, FFT algorithms; introduction to
digital filter design
EE183
Control Engineering, (2,2,0)
Prereq. EE143
State
Space Methods: Introduction to State Variables; problem
description in the time
domain using state variables – examples. Matrix
representation and survey of matrix algebra. Transfer
function; identification of state variables from
transfer function.
Impulse response (state transition
matrix; response of system to a given control).
Modal analysis; eigenvalues and
eigenvectors; matrix diagonalization. Stability of
linear systems; algebraic stability condition.
Controllability and Observability; decomposition
of a
system. Design of control systems using state variable
feedback. Estate estimator.
EE193 Assembly Language, (2,2,0)
Prereq. EE133
Assembly
Language programming, including subroutines, coroutines,
macros, interrupts and traps, relocation and loaders.
The instruction sets for the 8085 and 8086
microprocessors. Introduction to program constructs
(segments), variables and arrays, strings. Overview of
instruction set. Base index addressing. Conditional and
loop constructs.
EE203 Computer Aided Circuit Analysis,
(2,2,0)
Prereq. None
Network topology. Construction of
network graphs. Numerical network analysis: Nodal
analysis of linear and nonlinear networks, solution of
the Nodal equation. Standard form of state equations of
linear networks. Numerical solution of state equations
using approximate and matrix exponential methods.
Symbolic Network analysis: Spanning trees techniques.
Computer optimization of electronic
networks: single variable and n-variable numerical
methods including Golden-Section, Steepest-Descent,
Simplex, and Conjugate direction. Sensitivity
calculation.
Fault tolerance analysis: worst
case method, vetrex method and and statistical methods
including: method of moments and Monte-Carlo analysis.
EE213
Introduction To VLSI Systems, (2,2,0)
Prereq. EE033, EE053,
EE073
Large scale MOS design. Topics: MOS
transistors, static and dynamic MOS gates, stick
diagrams, programmable logic array and gate matrix
design, MOS circuit fabrication, design rules,
resistance and capacitance extraction, power and delay
estimates, scaling, MOS Combinational and sequential
logic design, registers and clocking schemes, memory,
data-path and control unit design. CAD for VLSI: CAD
process in IC design, different level of simulation,
placement and routing, symbolic design.
EE506 Final Year Project, (0,0,6)
Prereq. None
The
final year project is intended to bring together as much
as possible of the individual student’s knowledge and
experience gained during the preceding four years. The
project is also intended to give students a variety of
experience including design philosophy, drawing of
schematic circuit diagrams, design simulation using
electronics CAD tools, electronic wiring and
construction, electronic circuit testing and
troubleshooting.
Top
Back |
