Subject Objective

This subject provides knowledge of mathematical methods needed for engineering problem solving

Learning outcome

The students develop both their thinking and problem solving skills. Topics covered are: vector, functions of a complex variable; algebra, differential equations, mathematical distribution, and applications of mathematics in engineering calculations.

Credit Point

9

Hours

216 Hrs

Assessment

Assignment/ Final Examination/Online MCQ Test

Contents

An Introduction to theory of complex variables

Complex numbers

Functions

Differentiability

Integration in the complex plane

Integral theorems

Power series

Introduction of rational functions of trigonometric functions.

Continuous distribution

Exponential distribution

Normal distribution

Gamma distribution

Convergence in distribution

F   distribution

Discrete distribution

Binomial distribution

Poisson distribution

Elementary linear algebra

Algebra in Fⁿ Example problems

Geometric meaning of vectors

Geometric meaning of vector addition

Distance between points in Rn   Length of vector

Geometric meaning of scalar multiplication

Dot product

Cross product

System of equation geometry

System of equation – Algebric operation

Matrice arithmetic

Determinants –Basic technique & properties

Integration and differential equations

List of integrals

Introduction to background

Theorem of integration

Improper integrals

Improper integral problems

Integration of rational functions

Differential equations

First order ordinary differential equations

Homogenous equations

The general linear equations

Random variables

Simple introduction examples

Problems

Frequency and distribution functions in 1 dimension

Mathematical modelling preliminary

Introduction

Discrete time model

Maths 301 Introduction to Complex Variables

The residue Theorem

Fourier Transform

Integral theorem of complex analysis with applications to the evaluation of real integral

Introduction

Integral theorems – The green Theorem

Cauchy’s integral theorem

Cauchy’s residue theorem

Maths 302 Elementary Linear Algebra

A formula for the inverse

Cramer’s rule

Example 6.2.3 , 6.2.4 , 6.2.6, 6.2.7

Rank of a matrix

Example 8.2.9 , 8.2.10, 8.3.3 , 8.3.5, 8.3.6, 8.3.7, 8.3.8

Linear independence and bases

Linear transformation

Constructing the matrix of a linear transformation

Linear programming

Maths 401 Continuous Distribution

X² Distribution

F   Distribution

F   Distribution &   “ t “  Distribution

Estimation of parameters

Maths 402 Discrete Distribution

Geometric distribution

Pascal distribution

Negative binomial distribution

Hyper geometric distribution

Maths 303 Essential Engineering Mathematics

Vectors and matrices

Functions and limits , Example problems

Calculation of one variable ( Part 1) Differentiation,             

Calculation of one variable ( Part 1) Integration,             

Calculus of many variables,

Ordinary differential equations,

Complex function theory

Maths 501 Introduction to probability

Theoretical background

Playing card

Binomial distribution

Lotto    Example

Conditional probabilities –Baye’s formula

Maths 501 Linear algebra and matrices

Linear transformation matrices

Definition 2.1.1 to 2.1.3

i j   Entry of product  Definition 2.1.8

Rank of matrices

Row operations

Maths 502 Introductory Finite Difference Method for PDE

Partial differential equations. Example problems

Taylor theorem

Iterative solution methods

Jacobi Iteration

Gauss Seidel Iteration

Successive Relaxation method

Maths 601 Random Variables

Theoretical results

Frequencies and distribution ( 1 dimension )

Function of random variables

Subject Objective

This subject provides knowledge of calculus methods needed for engineering applications.

Learning outcome

The students develop both their thinking and problem solving skills. Topics covered are: vector calculus; functions of a complex variable; partial differential equations and boundary value problems; the concepts of quantum mechanics and Schrödinger's equation; and applications of mathematics in engineering calculations.

Credit Point

3

Hours

72

Assessment

Assignment/ Test/ Online MCQ Test

Contents

Calculus 1 a .pdf

Differentiation, Example problems

Integration, Example problems

Simple differential equations, Example problems

Calculus 2 a .pdf

Integration of trigonometric polynomials

Complex decomposition of a fraction between two polynomials

Chain rule

Calculation of the directional derivatives

An overview of integration in the plane and in the space

Line integrals

Surface integral

Green’s theorem in the plane

Calculus 2b 1.pdf

The range of functions in several variables

Line integral

Space integral

Line integral

Calculus 3b. pdf

Power series method in solution of problems, Example problems

Calculus 3C 1. pdf

Sequence in general

Calculus 4C 1. pdf

Sum function of Fourier series

Maths 303 Engineering Mathematics

Introduction and background

Integration of rational functions

Integration of trigonometric functions

Differential equations

Maths 403 Second Order Differential Equations

Power series solutions

Bessel equations and Bessel functions

Legendre polynomials

Differential equations

Subject Objective

This subject builds on and brings together the concepts introduced in the Mathematical and Physical Modelling subjects and in Introduction to Mechanical and Mechatronics Engineering.

Learning outcome

It is intended to provide students with a comprehensive overview of elementary mechanics, and lay the basis for further work in this area in later subjects. In particular, material discussed in this subject is taken further in Machine Dynamics and Mechanics of Solids subjects in subsequent stages.

Credit Point

1

Hours

24 Hr of Lecture+ 48 Hr of Tutorials

Assessment

Assignment/ Test/ Online MCQ Test

Contents

Stress   Example

Stress lectures

Strain  All examples

Strain lessons

Mechanical properties of materials

Mechanical properties of materials

Axial members

Axial members

Torsion of shaft

Torsion of shaft

Symmetric bending of beams

Symmetric bending of beams

Deflection of symmetric beams

Deflection of symmetric beams

Stress transformation

Stress transformation

Strain transformation

Strain transformation

Design and failure

Design and failure

Stability of columns

Stability of columns

Newton motion

One dimensional motion

Simple harmonic motion

Damped oscillation

X (t) = Ar e^{- rt/l} cos (wt –δ_r)

Rotating reference frame equations

Modern Mechanics Part 1

Modern Mechanics Part 2

Modern Mechanics Part 3

Modern Mechanics Part 4

Modern Mechanics Part A

Modern Mechanics Part B

Modern Mechanics Part C

ME 301 Applied Mathematics

Kinematics

Projectiles

Forces

Resistance forces

Resolving forces

Rigid bodies

Centre of gravity

Momentum

Energy

Circular motion

Gravitation and planetary motion

The language of vectors

Subject Objective

Thermodynamics

The objectives of this subject are to develop a fundamental understanding of applied thermodynamics in an engineering perspective, Strength of materials

Strength of materials

This subject draws on, and brings together, the knowledge and skills developed in earlier subjects such as Fundamentals of Mechanical Engineering,  Chemistry and Materials Science, and  Mechanics of Solids.

Learning outcome

Thermodynamics

Use thermodynamics effectively in the practice of engineering, lay the groundwork for subsequent studies in the fields related to energy systems and increase an awareness and emphasis on energy resources and environmental issues.

Strength of Materials

It also prepares students for the more dedicated design subjects to come and exposes them to practical aspects of mechanical engineering design. The objectives are that students should be able to: understand, describe and use the methodology of modelling material properties and behaviour; understand and describe the fundamental differences in the behaviour of different types of materials; understand and describe how and why things fail; realise the importance of material selection in engineering design; predict, or design to avoid, failure given the material, environment and loading conditions; and use analytical skills in stress analysis and knowledge of material properties in mechanical design..

Credit Point

3

Hours

72 Hrs

Assessment

Assignment/ Test/ Online MCQ Test

Contents

Heat Transfer. pdf

(1) Heat transfer mode  Example problems

(2) Conduction  Example problems

(3) Convection  Example problems

(4) Radiation  Example problems

(5) Heat Exchanger  Example problems

Theory of waves in materials.pdf

Materials-Preliminary

Materials- Basic mechanical properties

Basic wave phenomena

Harmonic waves

Elastic volume and shear waves

Rayleigh Elastic waves

Engineering Thermodynamics

General definition

Thermodynamics-Working fluids

Laws of Thermodynamics

Worked Example 3.1 to 3.25

ME434 Wind Turbines

Wind Energy

Theory of wind energy

Wind turbine types and components

Wind energy measurement, Wheel encoder  Worked

ME634 Pnuematics

Principle of pneumatics

Linear actuators

Flow control

Pnuematics sensors

Pnuematics symbols

Subject Objective

In this subject students are assumed to have knowledge of basic devices such as ideal and real voltage and current sources and loads; resistors; capacitors, inductors and coupled coils; diodes and operational amplifiers.

Learning outcome

To have basic circuit analysis skills such as Kirchhoff's current and voltage laws, Thevenin's and Norton's theorems, mesh and nodal analysis, symmetry, circuit transformation and superposition. Using this understanding as a starting point, the subject introduces the basic theoretical models that underpin signals and system analysis

Credit Point

3

Hours

72

Assessment

Assignment/ Test/ Online MCQ Test/ Online Simulated Practical

Contents

DC Circuit Analysis

Circuit Theory

Modulators

Analog, digital signals , electric current, power summary

Circuit analysis, electric potential, electric power, sign convection, electric source, Kirchoffs’ law

Circult elements, characteristics KCL, KVL

Resistor (Series, parallel, wheatstone bridge, Nodal analysis

Nodal analysis, mesh analysis

Superposition theorem, Thevenin’s theorem, Norton theorem, Maximum power transfer theorem,

Operational amplifier

Inverting amplifier circuit, Summing amplifier, Differential amplifier

Capacitor, Op-amp integrator, stored energy

Mutual inductance, time constant, transient

Transient response of 1 st order circuit, RL transient analysis, sequential switching

RC/RL Circuit , Propogation, Delay, DRAM

Semi conductor

PN Junction diode

Light emitting diode

MOSFET

Digital signal

CMOS Digital circuit

Combinational logic circuits

Flip flops

Propagation delay in timing diagram

Integrated circuit fabrication

Device isolation methods

Interconnected resistance and capacitance

Transistor scaling

Integrated circuit design for application in communications

Small signal amplifiers

Network noise intermodulation distortion

CAD for noise analysis

Snsors & Detectors

Low noise design methodology

Oscillators

Modulators and demodulators

Concepts in Electrical Circuit

Circuit theorem

Sinusoids & phasors

Frequency response

EE303 Engineering Circuit Analysis

Basic circuits

Basic Nodal and Mesh analysis

Linear and Superposition/ Source Transformation

RL/ RC Circuits

RLC Circuits

Sinusoidal steady state analysis

AC Power Circuit Analysis

Polyphase Circuits

Magnetically coupled circuits

Complex Frequency / Laplace Transform

Laplace Transform

Circuit analysis in “ S “ domain

Pole/ Zero constellation

Frequency Response

Two ports network

Fourier Circuit Analysis

Use of symmetry theory

EE404 Electrical Measurement ( 1 pt )

Measurement of inductance and capacitance

Measurement of  resistance

Magnetic measurement

High voltage measurement and tesating

Location of cable fault

Measurement of power

Measurement of energy

Subject Objective

The objectives of this subject are to consolidate fundamental knowledge of electric and magnetic fields; electric and magnetic circuits; how electric, magnetic and electromagnetic energy are interchanged;

Learning outcome

To model an electromechanical automation system using DC and AC motors and simulate its performance in open-loop and closed-loop control. Students also acquire skills in working with machines and equipment at normal mains supply voltage, in power instrumentation and control, PLCs and in experimental design and recording. Technical and theoretical content is expected to be acquired by students to the levels of 'know' (essential), 'familiar' (can solve problems if required) and 'aware' (have read/seen). Laboratory skills, ranging from electrical safety, measurements, design validation and experimental verification are an important focus of this subject.

Credit Point

2

Hours

48

Assessment

Assignment/ Test/ Online MCQ Test/ Online simulated Practical

Contents

Electro-mechanic -1.0.1 Scope of application

1.1  Electro-magnetic theory

1.1.1a Magnetic field system, Table 1.1

1.1.1.b Electric field system  Table 1.2

Lumped electro-mechanical elements

Lumped parameter-electro-mechanic

Rotating machines

Lumped parameter-electro mechanical dynamics

EE 502 Electrical Machines  

ME 301 Machine Principle 

Subject Objective

The objectives of this subject are to consolidate fundamental knowledge of electric and magnetic fields; electric and magnetic materials

Learning outcome

To understand how electric, magnetic and electromagnetic energy are interchanged.

Credit Point

1

Hours

24 + Tutorial 2 hr/ week

Assessment

Assignment/ Test/ Online MCQ Test

Contents

Electric field

Electrostatic potential

Dipole and quadrature pole movements

Batteries, resistors, ohm laws

Capacitors

Magnetic effect of an electric current

Force on current in a magnetic field

Electro-dynamics of moving bodies

Magnetic potential

Electro-magnetic Induction

Dimensions

Properties of magnetic materials

Alternating current

Laplace transform

Maxwell Equation

CGS Electricity & Magnetism

Magnetic dipole movement

Outlines

Electric field

Electrostatic Energy

Laplace’s equation (1)

Laplace’s equation (2)

Remarks on units

Green’s functions

Multipole expansion

Electro-static in matter

Boundary condition

Magneto statics (1)

Magneto statics (2)

Macroscopic magneto statics

Maxwell’s equation

DISC movement

Electro-magnetic plane waves

Reflection & refraction

Casual relation between D & E

Wave guides and load cavities

Electromagnetic radiation and scattering (1)

Electromagnetic radiation and scattering (2)

Scattering by small di-electric sphere

Electro-magnetism

Electro magnetic fields and moving charges

Multipole expansion

Magnetic constants and materials

Ampere law

Brief history of electro magnetism

Gauss’s law

Numerical solutions to Laplace’s equation

Small current loop

Curvilinear co-ordinate system

Problems

Dielectric tensors and constants

Analytic solution to Laplace equation

Magnetostatic boundary condition

Electrostatic boundary condition

Electromagnetic field

The gradient vector

Maxwell’s equation

Electro-magnetic wave propagation

BAE 407 Advanced Electro-magnetic Field & Materials

Electro dynamics

Introduction to electro statics

Boundary value problems in electro statics (1)

Boundary value problems in electro statics (2)

Multi-poles Macroscopic media –Dielectrics

Static and stationary magnetic fields

Maxwell’s equations

Plane wave and wave propogation

Wave guides and cavities

Radiation

The special theory of relativity

Particles and field dynamics

Charged particle collisions-Energy loss, Scattering

Radiation by moving charges

EMFT book.pdf

Summary of electro statics

Potential

Electro-magnetics waves

Classical optics

Conservation Law

Conservation Law

Conservation Law

Generic wave

Electromagnetic waves in vacuum

Electromagnetic waves in matter

Electromagnetic waves in conductor

Electromagnetic waves propagation

Electromagnetic waves field

Wave guides

Electromagnetic waves radiation

Electro-dynamics

Frequency

Di-electric materials and capacitance

Transmission Lines

Maxwell’s equations and electro-magnetic waves

Subject Objective

Analogue

The main objective of this subject is to familiarise students with basic electronic circuits, mainly with op-amps as active elements, and their applications.

Digital

The objectives of this subject are to enable students to master the fundamentals of digital and programmable electronic circuits and their engineering applications; master the hardware architecture of a typical small computer system; and understand the principles of low-level programming and gain an ability to write simple assembly code.

Learning outcome

Analogue

By the end of the subject, students should have acquired reasonable proficiency in the analysis of basic electronic circuits and be able to build and test circuits in the laboratory. Particular emphasis is placed on the practical, hands-on aspect of electronics to provide a solid foundation of working knowledge for basic analog electronic circuits using op-amps. Laboratory work is a significant proportion of in-class delivery so as to make students proficient in circuit construction, testing, troubleshooting and to give them a sound knowledge of the use of test instruments. Another objective is to show that practical electronic applications are relevant to other engineering and technical disciplines and may often be placed within a wider social or commercial context.

Digital

Students are introduced to the basics of concurrent and real-time application programming. Topics include digital sequential circuits; state diagram and its application in the design of digital circuits; basic hardware architectures of the digital computer in terms of its building blocks; how hardware integrates with software at the machine level; low-level language programming; internal architecture and design of a typical register-based central processing unit and a main memory subsystem, and their interdependence; concepts of computer system buses, as well as different types of input and output devices; interrupts; input and output; micro-controller theory; and hardware interfacing design techniques.

Credit Point

5

Hours

120

Assessment

Assignment/ Test/ Online MCQ Test/ Online Simulated Practicals

Contents

Semi conductor devices

Digital circuits

Number system basics

Introduction to logic gates

Combinational logic

Karnaugh map

Arithmetic circuit

Coders/ Multiplexers

Counters

Signal system representation

Fourier/ Z Transform

Discrete Fourier Transform

Principle of filter design

FIR filter design

Introduction

Intensity transformation & spatial filtering

Filtering in frequency domain

Discrete Fourier Transform

Butterworth Low Pass Filter

Butterworth High Pass Filter

Image restoration / Noise analysis

Introduction

Intensity transformation & spatial filtering

Filtering in frequency domain

Discrete Fourier Transform

Butterworth Low Pass Filter

Butterworth High Pass Filter

Image restoration / Noise analysis

Subject Objective

The subject introduces the basic methods used in the analysis and design of electric power networks.

Learning outcome

Its purpose is to give students a working knowledge of modern power system theory and practice. Techniques introduced in earlier circuit analysis subjects are further developed and applied to power system problems.

Credit Point

3

Hours

72

Assessment

Assignment/ Test/ Online MCQ Test/Online simulated practicals

Contents

Source of energy

Steam power station

Hydro power station

Diesel power station

Nuclear power station

Gas turbine power station

Variable load on power station

Interconnected grid system

Economic of power generation

Importance of high load factor

Tariffs

PF improvement

Supply system

Mechanical design of OH line

Corona

Sag

Electrical design of OH line

Performance of transmission line

Line generalised constants

UG cable

Capacitance in 3 core cable

Distribution system

DC Distribution

DC System

AC Distribution

Voltage control

Introduction to switch gear

Circuit breaker

Fuse

Relays

Protection transformers

Substation

Consequence of power quality

Power quality & applications

Power quality analysis

Power quality monitoring

Management, control and automation of power quality improvement

Integration of hybrid distribution units in power grid

Optimal location and control of multi hybrid model based wind shunt facts to enhance power quality

Power quality and voltage  sags indices in electrical power systems.

AASR Conductors

ARC Fault

Circuit breaker rating

Current transformer

Electrical bushing

Electrical fuse

Induction motor model

IP rating

Load factor

Load redundancy

Over current protection

Partial  discharge

Per unit system

Phase conversion

Resonance

RL Switching

Sequence network

Short circuit calculation

Symmetrical component

Transformer impedance

AC Power Transmission

Insulation Resistance test

Dry type transformer

Electrical software

Insulation resistance test

Designing for high temperature and pressure

Turbine components

Burning of fuel

Facts about fuel

Burning gas and oil

Selecting fuel

Water treatment

Heat exchanger

Computer control

System economics

Transmission & distribution system

Control of power and frequency

Control of voltage and reactive power

Load flow

Faults

System stability

Over voltage and insulation requirement

Substations and protection

Power line

Neutral earthing

Switch gear

Instrument

Protection

Power system

Generator response to system faults

Calculation of fault current

Symmetrical components

Commissioning electrical plant

Power system fundamental

Modern power system

Power control devices

Operational control system

Power conversion

Specialised testing & measurement devices

Voltage transient and line surge

Transmission of electrical energy

Corona

UG Cable

Voltage drop in distribution

Regulation

Line and machine chart

Voltage regulation stability

Fault calculation in line

Planning & design

Electrical design

Mechanical design (Over head)

Mechanical design (Under ground)

Metering

Conductor inductance & capacitance

Electric power system

Percentage and per unit quantities

Circuit constants

Assemblies of power system components

Power circuit stability

Subject Objective

This subject presents the theoretical basis for system analysis and gives students skills in using the techniques to design components of linear control systems..

Learning outcome

To do the  design and implementation of part of a control/communication system

To apply their knowledge to a real-life problem. Topics include signal types and their representation in the time and frequency domains; modelling systems with differential or difference equations and transforms of the equations; signal operations and processing; the relationship between discrete and continuous quantities and the mathematical techniques applicable to each; the effects of feedback; time and frequency domain performance of systems; system stability; and control design techniques and simple communication systems. Through learning activities students also gain study skills, including academic literacy skills, and an appreciation of the different fields of practice of engineering and the interdisciplinary nature of engineering.

Credit Point

1

Hours

24

Assessment

Assignment/ Test/ Online MCQ Test

Contents

Controllability of linear control system

Finite dimensional linear control system

Linear partial differential equations

Introduction to intelligent control system with high degrees of autonomy

Overview of field

System identification

Digital and analog

System metrics

System modelling

Classical control

Transform

Transfer functions

Sampled data system

System delays

Poles and zeros

Modern control

State space equation

Linear system solution

Subject Objective

The objective of this subject is to enable students to model with validation control systems and to analyse, design and implement both analog and digital controllers so that the controlled systems conform with given specifications

Learning outcome

Emphasis is placed on laboratory work, the theoretical content of the subject being only that required to produce successful designs.

 To work on reduced scale models of actual industrial processes. The equipment is based upon experience gained with authentic control applications and is suitably modified for student use.

To follow the usual sequence adopted in industry, i start with the calibration of transducers and actuators leading on to dynamic response testing, physical modelling, model verification and finally to controller design, implementation and testing.

Credit Point

4

Hours

96

Assessment

Assignment/ Test/ Online MCQ Test/ Programmable Control Program software applications

Topics include linear and nonlinear modelling of control systems using Newton's rules, analogous networks or Lagrangian techniques; linearisation and development of linear, time-invariant transfer functions; development of lead-lag compensators or PID controllers using classical control design techniques such as root locus, Bode gain and phase diagrams, Nyquist plots and Nichols chart; development of state-variable equations from differential equations; development of state-variable feedback controllers and state observers; open-loop pulse transfer functions and discrete-time state models; discretisation using backward difference, bilinear, step-invariance or pole-zero mapping; development of digital PID controllers, deadbeat controllers and discrete-time state-variable feedback controllers; describing functions and limit cycles for nonlinear control systems; and the development of linear controllers for nonlinear systems using describing function techniques.

Contents

Gain

Block diagram

Feedback control loop

Bode plot

Nichol chart

Stability

Stability

Routh Hurwitz Criterion, Root Locus

Nyquist Criterion

State Space Stability

Controllers & Compensators

Controllability & Observability

System Specifications

Controllers, Compensators

Z -  Transform

Application of input/ output linearization

Non linear control for 2 stages PF correction converter

Non linear observer based control allocation

Transfer functions and their responses

Frequency response/ Plotting

Closed loop control

Controller design

Introduction to linearized dynamic model

Transfer function model of physical systems

Transient performance / S- Plane

Feedback system modelling / Performance

Dynamic compensation of feedback system

Introduction

Phase plane method

Analog Signal Conditioning

Digital Signal Conditioning

Final Control

Discrete State Control

Controller Principle

Analog Controller

Digital Controller

Control  Loop Characteristics

Introduction to numerical control machinery

Numerical control system

Programming co-ordinates

Two axis programming

Three axis programming

Maths for numerical control programming

Subject Objective

The primary objective of this subject is the development of a working knowledge of power systems analysis and design.

Learning outcome

Emphasis is placed on the derivation of equivalent circuits, mathematical models of devices and the system, and on methods of analysis and measurement. Material covered includes electricity supply chain building blocks, system analysis, real/reactive power and load flow analysis, dynamic and transient stability.

Credit Point

1

Hours

24

Assessment

Assignment/ Test/ Online MCQ Test

Contents

Overview

Real & Reactive power injected bus

Classification of buses

Classification of buses

Preparation of data for load flow

Load flow by Gauss Seidel method

Updating load bus voltage

Updating PV bus voltage

Convergence of the algorithm

Solution of a set of non linear equation by Newton Raphson method

Load flow by Newton Raphson method

Load flow algorithm

Formation of Jacobian matrix

Formation of Jacobian matrix

Solution of Newton Raphson load flow

Load flow results

Load flow results

Load flow programs in MATHLAB

Forming Y bus matrix

Gauss Seidel Load Flow

Solving non linear equation using Newton Raphson method

Newton Raphson load flow

Transformer

Transmission line model

Gauss Seidel Algorithm

Newton Raphson Iteration

DC Power Flow Algorithm

Modelling

Transient Stability

Power Apps Transient Stability validiation document for single pole open/ close simulation

 (Power flow analysis + FAULT ANALYSIS + Power system dynamics and Stability)

Static Analysis

Introduction

Network model

Active & reactive power flow

Nodal formation of power flow problem

Basic power flow problem

Solution of power flow problems

Fault analysis

Power system dynamics and stability

Synchronous machine model

The swing equation

Power swing in simple system

Oscillation in multi machine system

Voltage stability

Control of reactive power voltage

Subject Objective

The primary objective of this subject is the development of a working knowledge of optimal power systems operation.

Learning outcome

The subject aims to provide students with a knowledge and understanding of elements of the supply chain and how they function in the National Electricity Market; demand-side management options including smart meters; load forecasting and optimal load scheduling for secure energy supply and use; protection schemes for transmission and distribution networks; communications in power systems, including communication media, architectures, automation, standards, protocols and security; and basic design, connection and standards of current and voltage instrument transformers for protection and metering applications.

Credit Point

1

Hours

24

Assessment

Assignment/ Test/ Online MCQ Test

Contents

Introduction

Power Flow Analysis

Classic Economic Dispatch

Linear programming method

Mathematical model of economic dispatch

Linear programming model

Optimization of power system performance using facts devices

Optimization of dynamical system

Matrix Eigen Value Method

Subject Objective

The primary objective of this subject is the development of a working knowledge of power systems operation and protection. The subject aims to provide students with a knowledge and

Learning outcome

To provide the understanding of elements of the supply chain and how they function in transmission and distribution networks; communications in power systems, basic design, connection and standards of current and voltage instrument transformers for protection and metering applications.

Credit Point

2

Hours

48

Assessment

Assignment/ Test/ Online MCQ Test/ Simulated Online Practical

Contents

Transient in RL circuit

Symmetrical fault

Transient in RL circuit

DC Source

AC Source

Faults in AC Circuit

Short circuit in unloaded synchronous generator

Symmetrical faults in power system

Calculation of fault current using Z bus matrix

Circuit breaker selection

Symmetrical components & representation of faulted network

Overview

Overview

Real & reactive power

Real & reactive power

Orthogonal Transformation

Sequence circuit for star load

Sequence circuit for delta load

Sequence circuit for synchronous generator

Sequence circuit for symmetrical transmission line

Sequence circuit for transformer

Star/ Star Connected Transformer

Delta/Delta Connected Transformer

Star/ Delta Connected Transformer

Sequence Network

Un- symmetrical Faults

Introduction

Single line to ground fault

Line to line fault

Two lines to ground fault

Fault current computation using sequence network

Transient Stability

Introduction

Power angle relationship

Swing equation

Equal area criterion

Equal area criterion

Multi machine stability

Oscillation in “ S “ Two areas System

Compensation of power transmission

Introduction

Ideal shunt compensator

Improving voltage profile

Improving power angle characteristics

Improving stability margin

Improving damping power oscillations

Ideal series compensator

Impact of series compensator for voltage profile

Improving power angle characteristics

Improving power angle characteristics

Alternate mode to voltage injection

Alternate mode to voltage injection

Comparison of two modes of operation

Power flow control and power swing damping

Different types of relays and settings

·         Technical feasibility of various options

·         Cost of options

·         Type of transmission AC/DC

·         Number of circuits

·         Conductor type

·         Transmission loss

·         Reactive power support requirements

·         Reliability

·         Quality of power supply

·         Stability aspects of the interconnected system

·         Operational planning

·         Short circuit levels and breaker requirements

·         over voltages and control

·         Insulation coordination at substations

·         Substation arrangements at the end of line, including switching arrangements.

·         Insulation requirements.

·         Protection, monitoring, control and automation requirements

·         Study of harmonics where needed [as in case of HVDC or when a terminating station is close to sources of harmonics]

·         Basic and Detailed engineering related to transmission towers, routes, substations

Power system stability

Power system stability Guidelines

Power system stability guidelines for determination and report

Direct stability analysis of electric power system using energy functions

Power system stability –New opportunity for control

Typical power quality and harmonic measurement plots

Robust power system stabilizer design using particle swarm optimisation techniques

Harmonic analysis

Power quality

Electrical protection for power system

Substation automation

Introduction to power quality

Harmonic model of transformer

Substation automation

Modelling analysis of synchronous machines

Life time reduction

Power system modelling under non sinusoidal condition

Impact of power quality on reliability

Role of filters in power system

Subject Objective

The objectives of this subject are to enable students to: acquire an understanding of the nature of power semiconductor devices and their control and use in switch-mode;

Learning outcome

To understand the arrangement and topology of the circuits in which switch-mode devices are used; appreciate the use of power electronic circuits in high-power applications such as motor drives; be aware of the electromagnetic interference problems associated with power electronic systems; use commercial software for the rigorous circuit analysis of real power electronic systems; analysis and design circuits to meet specific specifications; and fabricate basic power electronic circuits such as a chopper.

Credit Point

2

Hours

48

Assessment

Assignment/ Test/ Online MCQ Test/ Simulated online practical

Contents

Basic semiconductor physics

PN Junction semiconductor

Power switching devices

Electrical rating of switching devices

Cooling

Load/ switch communication

Driving semiconductor & thyristor

Protecting diode / Thyristor/ Transistors

Switching circuit energy recovery

Series , parallel devices operation protection

Naturally commutating converter

AC Voltage Regulator

DC choppers

Power inverters

Switched mode & resonant DC-DC power supplies

Capacitors

Soft magnetic materials

Resistors

AC Induction motor control

Motor control MCU

Networking for motor control system

DC motor control design

Motor control electronic devices

Power semi conductors

Robotics Application

Robotic Gears

Interfacing

Robotic Sensors

Communication

Subject Objective

To work effectively in industry as middle level managers

Learning outcome

To acquire the introductory skills in  business information system, engineering management, supervision, quality control, manufacturing management , human resources management, budgeting, operation and managerial decision making.

Credit Point

1

Hours

24

Assessment

Assignment/ Test/ Online MCQ Test

Contents

Subject Objective

This subject provides basic skills in Java/ C/C++/C# programming and software design,

Learning outcome

To acquire the skill practice in  object-oriented (OO) programming concepts, data flow, control flow, arrays, and the basics of sorting and searching algorithms.

To illustrate a design process using a set of design notations and design rules, and shows how to develop a correct, readable and reusable solution from a problem specification.

Credit Point

3

Hours

72

Assessment

Assignment/ Test/ Online MCQ Test/ Programming software application

Contents

Subject Objective

The objectives of this subject are to introduce students to the basic concepts and terminology used in telecommunication networks and a system-level view of network operation.

Learning outcome

To understand the evolution of telecommunication networks; services and applications (voice, video, data, location-based services, multimedia, gaming, etc.); network protocols (TCP/IP, OSI); transmission and switching basics; transmission media; access networks; PSTN; internet (dial up, broadband, ISP); network security; mobile networks (2G, 2.5G, 3G, 4G); data networks (LANs, wireless LANs, WANs, SANs, PANs, enterprise networks); VoIP networks; and convergence in telecommunication networks, next generation networks (NGN) and digital identity in networks.

Credit Point

1

Hours

24

Assessment

Assignment/ Test/ Online MCQ Test

Contents

Computer Network

Peer to peer networking

Client server networking

Network hardware

Network cable

Hub

Wired network

Wireless network card

Firewall

Wiring the network

Wiring the network

Running the network program

Viewing network connection

Network set up on additional computers

Viewing network connection

Subject Objective

This subject introduces students to the fundamentals of contemporary software engineering.

Learning outcome

To overview of the agile and non-agile software engineering principles, methods, tools and techniques is presented. Current trends and challenges in the practice of software engineering are explored.

To apply contemporary agile requirements analysis, planning, architecture, design, implementation and testing practices to software engineering project work in small teams.

Credit Point

2

Hours

48

Assessment

Assignment/ Test/ Online MCQ Test/ Software Design Practice

Contents

Introduction

Software process

Feasibility study

Project management

Documentation, Requirement analysis

Requirement specification

Business/ Legal aspect

Source code management

Formal specification

Object oriented design 1

Object oriented design 2

Object oriented design 3

System Architecture 1

System Architecture 2

System Architecture 3

Design for utility

Performance of computer system

Coding standard/ Tools for designing 1

Dependable system 1 Reliability

Dependable system 2 Validation

Law aspect

Risks in software engineering

Software engineering as engineering

What is Nano technology?

Motivation for Nano technology

Scaling laws

Nano technology

Subject Objective

On completion of this subject, students have learned the skills to systematically analyse network operations and performance, and also have the ability to appreciate approaches in designing communication and computer networks.

Learning outcome

To understand the communication architecture.

To provide the necessary background in understanding operations of TCP/IP, the mostly widely implemented protocol stack in computer networks, on a layer-by-layer basis.

Credit Point

2

Hours

48

Assessment

Assignment/ Test/ Online MCQ Test

Contents

Communication fundamental

Information & bandwidth

Amplitude modulation transmission

Amplitude modulation reception

Single side banded communication

Frequency modulation –Transmission

Frequency modulation –Reception

Communication Techniques

Communication Receivers

Pulse Modulation

Code transmission

ISDN

Transmission lines

Wave propagation

Antenna

Fibre optics

Overview of data communication

Data terminals

Massage and transmission channels

Asynchronous modems and interfaces

Synchronous modem and digital transmission

Protocol and error control

RF Transmission

Transmission Lines & Antennas, Video signals

Subject Objective

To work effectively in industry as middle level managers

Learning outcome

To acquire the advanced skills in  business information system, engineering management, supervision, quality control, manufacturing management , human resources management, budgeting, operation and managerial decision making.

Credit Point

5

Hours

120

Assessment

Assignment/ Test/ Online MCQ Test+ Submission of engineering design project ( Minor thesis)

Subject Objective

To work effectively in M & E Engineer in building construction & building service industry

Learning outcome

To understand the methods of building construction

To understand aircondition & refrigeration systems.

To design the water supply system for building

To design fire protection, building automation systems

Credit Point

2

Hours

48

Assessment

Assignment/ Test/ Online MCQ Test/ Building service design project.

Contents

Making building

Foundations

Wood

Interior finish for wood light frame construction

Wall types

Concrete construction

Controlling the temperature of mass

Electric heat

Humidification

Air-conditioning –Cooling / Comfort

Air-distribution & Balance

Reference Tables

Sanitation & Water Supply

Building Electrical & Mechanical System  Part 1

Theory of heat

Solar heat

Humidification

Air-conditioning-Cooling

Air-distribution & Balance

Air-conditioning Calculation worksheets

Subject Objective

This subject presents the theoretical basis for system analysis and gives students skills in using the techniques to design components of communication systems.

Learning outcome

io understand radio  & microwave signal types and their representation in the time and frequency domains; modelling systems with differential or difference equations and transforms of the equations; design of antenna, propagation principle

Credit Point

2

Hours

48

Assessment

Assignment/ Test/ Online MCQ Test

Contents

Introduction to radio wave propagation

Propagation features/ Overviews

Electromagnetic waves, Prpagation through atmosphere

Antenna

Radio wave propagation fundamentals

Antennas and propagation

Mobile radio propagation

Propagation

Wave propagation

Radio navigation

Wireless communication

Microwave antenna and radio wave propagation

Distributed element circuit analysis techniques

Matching networks

Couplers, combiners, dividers

Mixers

Gain and stability

Noise

Electromagnetism and RF Propagation

Antenna Fundamental

Communication system

RF Safety

Design of microwave filters (Vol 1)

Mechanically & magnetically tunable microwave filters

Design of microwave filters (Vol 1)

General applications of filter structure in microwave engineering

Properties of some common microwave filter elements