Please note - Swinburne University of Technology
Please note - Swinburne University of Technology
Please note - Swinburne University of Technology
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EE254 Electrical Design<br />
No. <strong>of</strong> hours per week: two hours for two<br />
semesters<br />
Prerequisites: EE188 Electronics, Circuits and<br />
Computing<br />
Instruction: lectureshutorials/laboratory<br />
Assessment: project/examination/assignment<br />
A second-year subject in the degree <strong>of</strong> Bachelor <strong>of</strong><br />
Engineering (Electrical- unstreamed).<br />
Subject aims<br />
To introduce the principles <strong>of</strong> coil design, heating and<br />
cooling, D.C. power supply design, printed circuit board<br />
design, amplifier design and programmable logic controllers.<br />
Subject description<br />
lntroduction to electrical design: electrical, magnetic and<br />
physical properties <strong>of</strong> materials.<br />
Coil design: series and shunt coils. Winding area, space<br />
factor, temperature rise and power dissipations. Project.<br />
Heating and cooling: heat generation, storage and<br />
dissipation. Conduction, convection and radiation. General<br />
heating equation, cyclic heating and heatsink design.<br />
DC power supplies: transformers, rectifiers, regulators and IC<br />
regulators. Split supply project.<br />
Printed circuit board design: track sizing, standards,<br />
construction methods and s<strong>of</strong>tware tools.<br />
Amplifier design: BJT amplifiers, bias conditions and small<br />
signal model. Two stage amplifier design project. S<strong>of</strong>tware<br />
tools. lntroduction to programmable logic controllers.<br />
TextslReferences<br />
Electrical Engineering Design Data. <strong>Swinburne</strong> Press, 1983<br />
Sedra, A.S. and Smith K.G. Microelectronic Circuitr 2nd ed, New<br />
York: Holt. Rinehart and Winston, 1987<br />
~~258 Electrical Machines<br />
No. <strong>of</strong> hours per week: four hours for two<br />
semesters<br />
Prerequisites: EE188 Electronics, Circuits and<br />
Computing<br />
Instruction: lectureskutorials/laboratory<br />
Assessment: examination/assignment<br />
z<br />
A second-year subject in the degree <strong>of</strong> Bachelor <strong>of</strong><br />
% Engineering (Electrical- unstreamed).<br />
rn<br />
3 Subject aims<br />
'!$ To introduce the principles <strong>of</strong> magnetic circuits,<br />
electromechanical energy conversion, transformers, induction<br />
2. machines and power electronics.<br />
u3 Subject description<br />
Magnetic circuits: reluctance, permanence, and inductance <strong>of</strong><br />
magnetic circuits <strong>of</strong> series and parallel form. Calculations for<br />
non-linear magnetic circuits. Properties <strong>of</strong> magnetic circuit<br />
materials.<br />
lntroduction to electromechanical energy conversion: voltagecurrent,<br />
energy storage and forceltoque expressions for<br />
singly and doubly excited transducers. Means <strong>of</strong> torque<br />
production.<br />
Transformers: uses, types and modes <strong>of</strong> construction. Ideal<br />
transformer equations for emfs, emf ratio, mmf balance,<br />
current ratios. Phasor diagram. The practical transformer,<br />
equivalent circuit, voltage regulation, efficiency. Instrument<br />
transformers.<br />
lntroduction to rotating machinery: construction and<br />
principles <strong>of</strong> operation <strong>of</strong> three-phase induction machines,<br />
direct current machines.<br />
Power electronics: devices. The power diodes and the silicon<br />
control rectifier. Characteristics and ratings and specifications.<br />
Simple trigger circuits. AC to DC conversion: single phase<br />
and three phase half wave and full wave converters using<br />
diodes. Average voltage and ripple factor. Converters using<br />
SCR's with a resistive load. Application to speed control <strong>of</strong> a<br />
D.C. motor. An introduction to harmonic content and<br />
effective power factor.<br />
References<br />
Bell, D.A. Electronic Instrumentation and Measurements. Reston, V.A.:<br />
Reston Pub. Co., 1983<br />
Chapman, S.J. Electric Machinery Fundamentals. 2nd ed, New York:<br />
McGraw-Hill, 1991<br />
Helfrick, A.D. and Cooper, WD. Modern Electronics Instrumentation &<br />
Measurement Techniques Englewood Cliffs, N.J.: Prentice-Hall, 1990<br />
Sen, 'C. Principles <strong>of</strong> Electrical Machines and hwer Elmmnics. New<br />
York: Wiley, 1989<br />
Slemon, C.R. and Straughen, A. Electric Machines. Reading, Mass.:<br />
Addison-Wesley, 1980<br />
EE263 Computer Systems Engineering<br />
No. <strong>of</strong> hours per week: three hours for two<br />
semesters<br />
Prerequisites: EE188 Engineering Science,<br />
Electronics and Computing<br />
Instruction: lecturesllaboratory<br />
Assessment: examinationlassignmentl<br />
laboratory<br />
A second-year subject in the degree <strong>of</strong> Bachelor <strong>of</strong><br />
Engineering (Electrical- unstreamed).<br />
Subject aims<br />
For students to demonstrate a sound understanding <strong>of</strong> data<br />
abstraction and structured programming in PASCAL, and<br />
basic computer organisation.<br />
Subject description<br />
Data structures: Pascal pointer types, lists, stacks, queues,<br />
trees, directed and undirected graphs and algorithms for the<br />
manipulation <strong>of</strong> these structures, file types and<br />
organisations.<br />
Elementary computer organisation using Pascal as the<br />
descriptive language: the Von-Neumann fetch-execute cycle,<br />
simple single register architectures, their constraints and<br />
evolution to multiple register architectures (immediate, direct,<br />
register, register indirect and indexed addressing modes).<br />
Pascal to assembly language mappings for a multiple-register<br />
architecture. Informal treatment <strong>of</strong> parser construction from<br />
a language's syntax using assembly language as an example.<br />
The assembly process. The fetch decode and execution<br />
process for the multiple-register machine.<br />
Internal representation <strong>of</strong> data types. Integer and floating<br />
point arithmetic.<br />
References<br />
Egan, G .K. Introduction to Computer Systems. Hawthorn: <strong>Swinburne</strong><br />
Press, 1991<br />
Nyh<strong>of</strong>f, L.S. and Leestma. 5. Advanced Programming in Pascal with<br />
Data Structures. New York, MacMillan, 1988<br />
Sedgewick, R. Algorithms. 2nd 4. Reading. Mass.: Addison-Wesley,<br />
1988<br />
Tanenbaum, A.S. Structured Computer Organisation. 3rd ed,<br />
Englewood Cl~ffs, N.J.: Prentice-Hall, 1990<br />
Tenenbaum, A.M. and Augustein, M .J. Data Structures Using Pascal.<br />
Englewood Cliffs, N.J.: Prentice-Hall, 1981<br />
EE282<br />
Communication Principles<br />
No. <strong>of</strong> hours per week: two hours for two<br />
semesters<br />
Prerequisites: EE188 Electronics, Circuits and<br />
Computing<br />
Instruction: lectures/tutoriaIsllaboratory<br />
Assessment: examinationlassignment