EEE 200: STUDENTS WORK EXPERIENCE PROGRAMME I
Course Learning Outcomes $11. Understand the establishment’s services, products and goals $12. Understand the roles of available departments and the contribution of their own department to the operation of the establishment $13. Build confidence to work individually and team spirit to work with others in their establishment $14. Correlate contents learnt in the curriculum with experience in the field, and learn to apply industry standard tools to problem-solving $15. Deliver and present their work experience effectively through written and oral communication $16. Recognize the importance of self-learning and development |
EEE 201: APPLIED ELECTRICITY I
Course Learning Outcomes $11. Understand the basics of electric power, voltage, current, power sources and identify various active and passive components $12. Describe various configurations of linear resistive networks and analyse them using various network theorems such as KCL,KVL, Norton, Thevenin and Superposition theorems $13. Differentiate between linear and non-linear resistive networks $14. Understand basic logic gates and digital circuits $15. Identify different solid state devices $16. Use simulation software to simulate and analyse linear and nonlinear resistive networks and digital circuits |
EEE 202: APPLIED ELECTRICITY II
Course Learning Outcomes $11. Understand magnetic field of currents in space $12. Compute initial conditions and step response for current and voltage in first order RL and RC inductor and capacitor circuits. $13. Compute initial conditions and time response for current and voltage in second order RLC circuits. $14. Compute the response of RLC circuits to sinusoidal steady state $15. Design and analyse RLC circuits using phasor techniques $16. Explain the basic concepts of magnetic circuits, mutual inductance, and the operation of transformers, generators and motors $17. Discuss various types of measuring instruments $18. Use simulation software to simulate and analyze first order and second order circuits |
EEE 210: INTRODUCTION TO ELECTRICAL AND ELECTRONICS ENGINEERING
Course Learning Outcomes $11. Understand the Electrical and Electronic Engineering programme and ethical responsibilities as both a student and professional engineer $12. Understand the disciplines and opportunities available in the field of electrical and electronic engineering $13. Understand several contemporary issues in power, communications and control systems engineering $14. Write simple programs using MATLAB $15. Understand the need for life-long learning |
EEE 231: ENGINEERING MATHEMATICS I
Course Outcomes $11. Apply the fundamental concepts of limits, continuity and differentiation $12. Learn to find the solution of constant coefficient differential equations $13. Learn the techniques of partial differentiation of functions of several variables and use this to solve problems related to maxima and minima $14. Acquire knowledge about the ideas and techniques of matrices, determinants and vector algebra $15. Acquire knowledge of vector calculus and its application in electromagnetic fields $16. Apply MATLAB to basic Engineering mathematics problems |
EEE 232: ENGINEERING MATHEMATICS II Course Learning Outcomes $11. Model different physical systems using second order differential equations $12. Learn to solve second order differential equations arising in different physical systems and fields $13. Evaluate line integrals and multiple integrals in rectangular, polar, spherical and cylindrical coordinates $14. Acquire knowledge of applications of line, double and triple integrals, including Green’s theorem, Stoke’s theorem and Divergence theorem. $15. Acquire knowledge of functions of complex variables, linear and non-linear transformations and mapping $16. Apply MATLAB to basic Engineering mathematics problems |
EEE 300: STUDENTS’ WORK EXPERIENCE PROGRAMME II
Course Learning Outcomes $11. Understand the establishment’s services, products and goals $12. Understand the roles of available departments and the contribution of their own department to the overall operation $13. Build confidence to work individually and team spirit to work with others in their establishment $14. Correlate contents learnt in class with field experience, and learn to apply industry standard tools to problem-solving $15. Deliver and present their work experience effectively through written and oral communication $16. Recognize the importance of self-learning and development
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EEE 308: DIGITAL CIRCUIT ANALYSIS AND DESIGN
Course Learning Outcomes $11. Differentiate between analogue and digital signals and devices $12. Understand principles of operation of Analog to Digital Converter (ADC) and Digital to Analog Converter (DAC) $13. Analyze the building blocks of Combinational logic circuits $14. Analyze the building blocks of sequential logic circuits and illustrate the concept of synchronous and asynchronous sequential circuits $15. Understand various concepts in interfacing digital devices with the analog world- parallel and serial transmission, microcomputer, microprocessors and microcontrollers $16. Differentiate between RAM and ROM and understand the technologies behind them $17. Understand the power requirements of digital elements
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EEE 310: MEASUREMENT & INSTRUMENTATION Course Learning Outcomes $11. Recognize the evolution and history of units and standards in Measurements. $12. Understand the working principle of instruments for measuring various electrical engineering parameters such as current, voltage, resistance, power, energy , etc $13. Select appropriate sensors and transducers in measuring physical parameters $14. Understand various signal manipulation techniques $15. Acquire knowledge of biomedical instrumentation principles $16. Think of innovative ideas to improve existing measurement technologies
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EEE 313: ELECTRONIC CIRCUITS I Course Learning Outcomes $11. Acquire basic knowledge on the working principles of various semi-conductor devices such as diodes and BJTs $12. Develop capability in analysis of BJT and FET amplifier circuits $13. Develop competence in frequency response analysis of amplifiers $14. Design signal and power amplifiers using BJTs and FETs $15. Acquire knowledge on basic digital electronics circuits $16. Analyze and design combinatorial circuits
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EEE 320: ELECTRONIC CIRCUITS II Course Learning Outcomes $11. Analyze important electronic circuits (amplifiers, filters, oscillators) $12. Use simulation software $13. Build, make measurements, and troubleshoot electronic circuits $14. Analyse and design wave-shaping sequential circuits $15. Understand various memory circuits, logic families (including TTL, ECL, RTL, DTL) and IC technologies |
EEE 315: ELECTRICAL MACHINES I Course Learning Outcomes $11. Understand the energy conversion principles in electrical machines $12. Understand the fundamental characteristics of various types of DC machines-generators, motors and their shunt and series characteristics $13. Understand the concept of equivalent circuit in transformers $14. Conduct simple tests on electrical machines and transformers $15. Understand the construction and design issues associated with electrical machines
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EEE 314: ELECTRICAL MACHINES II Course Learning Outcomes $11. Understand the fundamental theory and principles of rotating machines. $12. Understand the equivalent circuit representation and analysis of Induction motors and synchronous machines. $13. To also introduce the students to the characteristics of motors and their applications at home and in the industry. $14. Understand the construction and design issues associated with electrical machines.
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EEE 317: USE OF ENGINEERING SOFTWARE PACKAGES Course Learning Outcomes $11. Understand the need for software packages in solving engineering problems $12. Know the main features of the MATLAB, LabVIEW and SIMULINK environments and use their GUIs effectively $13. Design simple algorithms to solve problems $14. Write simple programs in MATLAB to solve scientific and mathematical problems $15. Develop basic Virtual Instruments in LabVIEW $16. Simulate basic electrical circuits in Simulink |
EEE 316: APPLIED COMPUTER PROGRAMMING Course Learning Outcomes $11. Understand the need for software packages in solving engineering problems $12. Know the main features of the MATLAB, LabVIEW and SIMULINK environments and use their GUIs effectively $13. Design simple algorithms to solve problems $14. Write simple programs in MATLAB to solve scientific and mathematical problems $15. Develop basic Virtual Instruments in LabVIEW $16. Simulate basic electrical circuit in Simulink
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EEE 318: ELECTRIC CIRCUIT THEORY II Course Learning Outcomes $11. Analyze circuits using basic circuit laws and network simplification theorems $12. Know realizability requirements in network synthesis $13. Synthesize one port network using Foster and Cauer Forms. $14. Analyze series resonant and parallel resonant circuits $15. Evaluate two-port network parameters, design attenuators and equalizers $16. Apply CAD tools in filter design
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EEE 319: MINI PROJECT I Course Learning Outcomes $11. Identify, formulate and solve engineering problems $12. Learn teamwork while undertaking short research $13. Acquire/Apply report writing skills $14. Use ICT and software tools in design and implementation of electrical/electronic devices $15. Develop communication skills by presenting their results before an evaluation panel $16. Acquire capability for self-development and life-long learning
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EEE 321: ELECTRIC CIRCUIT THEORY I Course Learning Outcomes $11. Apply the knowledge of different circuit theorems to electrical networks $12. Determine system response of electrical networks to step, ramp, impulse, exponential and sinusoidal input signals $13. Understand and apply Laplace transform for steady state and transient analysis and carry out pole-zero analysis $14. Analyze two-port, ladder and star-delta networks $15. Apply software tools in analyzing electric circuits
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EEE 323: ELECTROMAGNETIC FIELDS AND WAVES I Course Learning Outcomes $11. Understand the basic mathematical concepts related to electromagnetic vector fields. $12. Apply the principles of electrostatics to the solutions of problems relating to electric field and electric potential, boundary conditions and electric energy density. $13. Apply the principles of magneto statics to the solutions of problems relating to magnetic field and magnetic potential, boundary conditions and magnetic energy density. $14. Understand the concepts related to Faraday‘s law, induced emf and Maxwell‘s equations. $15. Apply Maxwell‘s equations to solutions of problems relating to transmission lines and uniform plane wave propagation. |
EEE 331: ENGINEERING MATHEMATICS III
Course Learning Outcomes $11. Solve equations using bisection, iteration, interpolation and central differences numerical techniques $12. Understand the meaning of Operations Research apply it in solving linear programming problems $13. Apply Laplace transforms to the solution of differential equations $14. Calculate Fourier series representing periodic functions $15. Understand gamma, beta and error functions $16. Use computational tools to solve problems involving ordinary and partial differential equations
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EEE 332: ENGINEERING MATHEMATICS IV Course Learning Outcomes $11. Develop mathematical models for various physical systems $12. Solve ordinary differential equations using numerical methods (including Euler-Cauchy, Runge Kutta and predictor-corrector methods) $13. Extend the techniques of Fourier series to non-periodic functions by means of Fourier integrals and Fourier transforms $14. Explain Sturm-Liouville theory and apply orthogonality to the solution of differential equations $15. Solve partial differential equations with given initial and boundary conditions; $16. Use computational tools to solve problems and applications of Ordinary Differential Equations and Partial Differential Equations
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EEE 400 STUDENTS’ INDUSTRIAL WORK EXPERIENCE SCHEME Course Learning Outcomes $11. Understand the establishment’s services, products and goals $12. Understand the roles of available departments and the contribution of their own department to the operation of the establishment $13. Build confidence to work individually and team spirit to work with others in their establishment $14. Correlate contents learnt in the curriculum with experience in the field, and learn to apply industry standard tools to problem-solving $15. Deliver and present their work experience effectively through written and oral communication $16. Recognize the importance of self-learning and development
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EEE 401: ELECTRIC POWER PRINCIPLES Course Learning Outcomes $11. Gain awareness of the general structure of modern power systems $12. Understand the process of power generation from conventional and non-conventional energy sources $13. Calculate transmission line parameters and determine factors affecting transmission line performance $14. Know types of overhead insulators and underground cables as well as factors guiding their selection $15. Know the various protection equipment in the power system (e.g. circuit breakers, isolators, relays)
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EEE 407: INTRODUCTION TO CONTROL ENGINEERING Course Learning Outcomes $11. Understand open loop and closed loop control systems and their physical meaning $12. Construct mathematical model of physical system, via transfer function and state variable method $13. Analyze system behavior and stability using mathematical models and evaluating the system performance, in time domain $14. Use software tools to aid understanding of control system performance
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EEE 413: DIGITAL ELECTRONICS Course Outcomes
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EEE 415: SIGNALS AND SYSTEMS
Course Learning Outcomes $11. Recognise, sketch, manipulate and classify basic signals commonly used in engineering applications; $12. Formulate the input-output description of continuous time (CT) linear systems and identify system properties of linearity, time (in)variance, causality, memory and stability; $13. Analyse and synthesise systems as a composite of sub-systems through series, parallel and feedback combinations; $14. Use Fourier transform methods to obtain CT LTI systems’ outputs in the steady state; $15. Define Laplace transforms and manipulate s-domain transfer functions describing CT LTI systems; $16. Obtain z-transforms for discrete time systems |
EEE 417: PRINCIPLES OF COMMUNICATION ENGINEERING Course Learning Outcomes $11. Describe and analyse some of the building blocks of modern communication systems $12. Describe the concept and techniques for performing signal modulation in communication systems; $13. Analyse the performance of Amplitude Modulation (AM), Phase Modulation (PM) and Frequency Modulation (FM) systems; $14. Understand Pulse modulation systems: PAM, PWM, PPM and their generation, detection and applications $15. Differentiate between multiplexing techniques $16. Introduction to radio and TV transmission
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EEE 421: ELECTROMAGNETIC FIELDS AND WAVES II Course Learning Outcomes $11. Understand general electromagnetic wave propagation phenomena in different media and apply the boundary conditions for electric and magnetic fields at different interfaces. $12. Identify the transmission line as an element in a circuit, name its parameters, and use Smith chart to solve transmission line problems. $13. Identifying various types of transmission lines and waveguides, their performance, characteristics, and practical applications. $14. Understand the theory of antennas and radiating elements
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EEE 423: MINI PROJECT II Course Learning Outcomes $11. Identify, formulate and solve engineering problems $12. Learn teamwork while undertaking short research $13. Acquire/Apply report writing skills $14. Use ICT and software tools in design and implementation of electrical/electronic devices $15. Develop communication skills by presenting their results before an evaluation panel $16. Acquire capability for self-development and life-long learning
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EEE 501: FINAL YEAR PROJECT I Course Learning Outcomes $11. Understand and apply formal design methodology to generate the design constraints and specifications/requirements for a system $12. Demonstrate technical presentation skills, both written and oral $13. Create engineering documents that include analysis, schematics, software and scheduling necessary to complete the research $14. Use computer design tools to document schematics, wiring, interconnections and create project layout $15. Function individually and as a team player $16. Understand the broader impact of engineering solutions on society $17. Design and construct experiments to generate, analyse and interpret data $18. Recognize the need for life-long learning $19. Understand professional ethics and responsibility $110. Understand contemporary issues of design, such as patents, engineering standards |
EEE 502: FINAL YEAR PROJECT II
Course Learning Outcomes $11. Understand and apply formal design methodology to generate the design constraints and specifications/requirements for a system $12. Demonstrate technical presentation skills, both written and oral $13. Create engineering documents that include analysis, schematics, software and scheduling necessary to complete the research $14. Use computer design tools to document schematics, wiring, interconnections and create project layout $15. Function individually and as a team player $16. Understand the broader impact of engineering solutions on society $17. Design and construct experiments to generate, analyse and interpret data $18. Recognize the need for life-long learning $19. Understand professional ethics and responsibility $110. Understand contemporary issues of design, such as patents, engineering standards
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EEE 504: DIGITAL SIGNAL PROCESSING Course Learning Outcomes $11. Differentiate between continuous time and discrete time signals and systems $12. Analyze linear time invariant discrete time systems and represent total response in various formats $13. Determine the Discrete Time Fourier Transform, Discrete Fourier Transform (DFT) and z-transform for discrete time signals $14. Apply DFT in signal representation and system analysis and compute DFT using Fast Fourier Transform algorithms $15. Design IIR and FIR filters and understand their realization structures $16. Understand finite word-length effects in digital filter implementation $17. Apply software tools in digital signal processing
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EEE 507: ADVANCED CIRCUIT TECHNIQUES Course Learning Outcomes $11. Understand the physical structure of analog/digital integrated circuits and their layout $12. Analyze and design basic analog integrated circuits $13. Use software tools to design and simulate analog integrated circuits $14. Use basic analog integrated circuits to build bigger systems |
EEE 509: CONTROL SYSTEMS ENGINEERING Course Learning Outcomes $11. Analyse response of a second order control system using software tools $12. Analyze and interpret system stability through Root Locus, Bode plot and Nyquist plot $13. Design Lag, Lead, Lead-Lag compensators $14. Analyze torque- speed characteristics of DC and AC servomotors $15. Analyze the effect of P, PI, PD and PID controllers on a control system |
EEE 510: RELIABILITY ENGINEERING Course Learning Outcomes $11. Introduce concepts and methods in the field of reliability engineering $12. Use total quality management tools to measure and evaluate the quality of products $13. Perform reliability analysis of a system and designing the same $14. Differentiate between hardware and software reliability $15. Evaluate the use of reliability engineering for industrial activities. |
EEE 525: POWER ELECTRONICS Course Learning Outcomes $11. Describe basic operation and compare performance of various power semiconductor devices, passive components and switching circuits $12. Analyse the operating principles and modulation strategies for single-phase and three phase diode rectifiers, thyristor-based converters, as well as, switch-mode DC/DC power electronic converters and DC/AC inverters. $13. Model and simulate the electrical, thermal and electromagnetic performance of power electronic systems using simulation tools. $14. Identify the critical areas in application levels and derive typical alternative solutions, select suitable power converters to control Electrical Motors and other industry grade apparatus |
EEE 528: DATA COMMUNICATIONS AND NETWORKS Course Learning Outcomes $11. Describe network components and architectures $12. Explain the fundamental principles of computer communication at the physical layer, data link layer and network layer. $13. Describe some standardized and popular networks, including Ethernet and WiFi $14. Explain the principles of network programming $15. Design and implement client-server applications using socket programming
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EEE 530: ASSEMBLY LANGUAGE PROGRAMMING
Course Learning Outcomes $11. Get hands on experience with Assembly Language Programming. $12. Study interfacing of peripheral devices with 8086 microprocessor. $13. Understand techniques for faster execution of instructions and improve speed of operation and performance of microprocessors. $14. Learn fundamentals of designing embedded systems $15. Write and debug programs in TASM/MASM/hardware kits |
EEE 527: BROADCASTING AND INTERNET TECHNOLOGY Course Learning Outcomes
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EEE 534: DESIGN OF ELECTRICAL AND ICT SERVICES
Course Learning Outcomes $11. Work independently and inter-dependently in coming up with electrical installation designs using modern tools $12. Understand and comply with published electrical codes and safety standards. $13. Select and order appropriate electrical parts (materials) based on blueprints and drawings. $14. Calculate electrical circuit loads and design/draw the electrical circuits. $15. Install electrical systems/equipment in new construction under supervision
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EEE 529: MOBILE & PERSONAL COMMUNICATION SYSTEMS
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EEE 521: INTRODUCTION TO MODERN CONTROL
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EEE 533: MICROCOMPUTER HARDWARE AND SOFTWARE TECHNIQUES Course Learning Outcomes
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EEE 535: POWER SYSTEM ENGINEERING I
Course Learning Outcomes $11. Model transmission lines and generators $12. Solve load flow and short circuit calculations $13. Solve the problems related to the economic dispatch of power, plant scheduling, unit commitment $14. Understand automatic generation control and voltage regulation $15. Use software tools to model power system operation
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EEE 536: POWER SYSTEM ENGINEERING II Course Learning Outcomes $11. Understand power stability problems and analyze dynamical systems $12. Understand the operation of various protective devices in power system $13. Outline factors affecting power system expansion planning, operation and management $14. Develop load forecasting models
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EEE 537: ELECTRICAL ENERGY CONVERSION AND STORAGE Course Learning Outcomes
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EEE 538: SATELLITE COMMUNICATIONS Course Learning Outcomes $1·
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EEE 540: DIGITAL COMPUTER NETWORKS Course Learning Outcomes $1·
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EEE 542: SYSTEM DESIGN & VHDL PROGRAMMING
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EEE 544: SWITCHGEAR AND HIGH VOLTAGE ENGINEERING
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EEE 546: DIGITAL COMMUNICATION PRINCIPLES
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