01042445112675
FORID:9
UTF-8
 Home
 Contact Us
 Site Map

o









o







o











Facts
SRM in Focus
Vision and Mission
History
From the Chancellor
Administrative Organization
Faculties, Schools and Departments
Programs
Accreditation and Ranking
Research at SRM
The Campus
Our Campus
Campus Tour
Campus View
Student Services
Library
Sports
Building Details
Student Accommodation
Welcome to SRM Hostels
Sanctity of the Hostels
Vision
Housing
Hostels for Men
Hostels for Women
International Hostel
Dining Hall
Mess Rules
Mess Timings
Amenities
About SRM
Search
Search





o




o

o
o
Who Can Apply?
How and When to Apply?
Fees Structure
Wardens / Deputy Wardens
Contact Us
Global Connections
International Advisory Board
Corporate Advisory Board
Panel of Foreign Faculty
Strategic Alliance
Student Achievements
SRM represented in UN delegation!
Visiting SRM
Contact us
o
















o

















Admission India
Admission Procedure
How to Apply
Apply Online
Download Application
Purchase Application
Application by Post
Test City Centers
Important Dates
Counseling
Courses Offered
Eligibility
Tuition Fees
Fee Refund
Hostel Fees
FAQs
Contact Us
Admission International
Categories
Who can Apply
Admission Procedure
Apply Online
Download Application
Courses Offered
Eligibility
Important Dates
Tuition Fees
Visa Requirement & Health Regulations
Electronic Fund Transfer Form
Migration & Declaration Forms (A1 - A4)
Hostel Fee
Code of Conduct
Support Services
FAQs
Contact

Admission
o


o


o







o
o
Twining & Dual Degree
Twining Degree
Dual Degree
Financial Aid
Scholarships
Loans
Downloads
University Info
Engineering Info
Medicine Info
Science Info
Guide to Entrance Exam
International Prospectus
Scholarship form
Applicant Login
Pre-enrollment
o





o

o
Colleges and Schools
College of Engineering
College of Medicine
School of Management
College of Sciences & Humanities
o
o
o
o
Academic Research
Funded Research
Research Institute
Other Research Initiatives
o
o
o
o
o
o
 Campus Life
Arts & Culture
Athletics & Fitness
Student Life
Public Service
Caste Discrimination
Healthy living
DEPARTMENT OF ELECTRICAL AND ELECTRONICS ENGINEERING

Academics
தமிழ்ப்பேராயம்
Departments
Departments A-Z
ISTE Chapter


Research
About the department
Infrastructure

UNDERGRADUATE



B.Tech (EEE - PEOs & Student Outcomes)
B.Tech (EEE - 2007 - 2008 Curriculum)
B.Tech (EEE - 2010 - 2011 Lesson plan)
 B.Tech (2011 - 2012 Lesson plan)
POSTGRADUATE


M.Tech. (Power Electronics and Drives 2008 - 2009 Curriculum)
 M.Tech. (Power System)
 M.Tech. (Power System) - Part Time
 M.Tech. (Power Systems 2008 - 2009)
 M.Tech (2010 - 2011 Lesson plan)
 M.Tech (2011 - 2012 Lesson plan)
M.Tech. (Power Electronics and Drives 2011 - 2012 Lesson plan)
 M.Tech. (Power System 2011 - 2012 Lesson plan)
DOCTORAL

Ph.D
FACULTY
Home > Engineering > Department of Electrical and Electronics Engineering > Postgraduate > M.Tech. (Power
System)
Post-Graduate Programmes
M.Tech (Power System)
Eligibility: B.E./ B.Tech (EEE/ ECE/ ICE)
Duration: 2 years in 4 Semesters
Semester 1
COURSE CODE
COURSE NAME
L
T
P
C
Applied Mathematics for Electrical Engineers
3
1
0
4
Theory
MA511
UNIT I
ADVANCED MATRIX THEORY
9
Computation of the greatest and the least eigen values of a matrix by power method - Modal matrix - Spectral
matrix - Hermitian form - Bilinear-Quadratic forms - Sylvester's theorem - Power series of matrices Application of matrices to solution of Differential equations.
UNIT I I
LINEAR PROGRAMMING
9
Graphical Method - Simplex method - Duality Theorems - Dual Simplex method - Integer programming
UNIT I I I
NON LINEAR PROGRAMMING AND DYNAMIC PROGRAMMING
9
Non-linear programming with special reference to quadratic programming - Kuhn-Tucker conditions - Wolfe's
modified simplex method - Dynamic programming - Bellman's principle of optimality
UNIT IV
CALCULUS OF VARIATIONS
Concepts of functionals - Euler's equation - Brachistochrone problem - Variational problems involving several
unknown functions - Functionals involving two or more independent variables - Variational problems with
moving boundaries - Isoperimetric problems
9
UNIT V
RANDOM PROCESSES
9
Probability - Baye's Theorem for conditional probability - Random variables - Distribution function - Density
function - Variance and covariance - Stochastic process - Auto correlation - Auto covariance - Cross
correlation and cross covariance - Stationary process - Auto correlation and cross correlation functions Power spectrum
TUTORIAL
TOTAL
15
60
TEXT BOOKS





Dass H.K., Engineering Maths, S. Chand and Co, 2003 (Unit I - Chapter 19, Section 19.33 - 19.38)
Grewal B.S., Higher Engineering Mathematics, Khanna Publishers. 36th Edition (Unit I - Chapter 24 Section
24.8)
Kanti Swarup, Gupta P.K., Manmohan, Operations Research , Sultan Chand, 11th Edition - 2003. (Unit II Chapter 3, Section 3.1 - 3.3, Chapter 4 Section 4.1 - 4.4, Chapter 5 Section 5.1 - 5.4, 5.7 - 5.9 Chapter 7
Section 7.1 - 7.4 Unit III - Chapter 13, Section 13.1 - 13.4, Chapter 25, Section 25.1 - 25.5)
Venkataraman M.K., Higher Engineering Mathematics, National Publishing Co., 4th Edition, July 1992. (Unit IV
- Chapter 9 Section 1, 2, 3, 5, 8, 9, 11 - 15, 17)
Veerajan T., Probability, Statistics and Random Processes, Tata Mc Graw Hill, 2004. (Unit V - Chapter 1
Section 1.1 - 1.9, Chapter 2 Section 2.1 - 2.31, Chapter 3 Section 3.1 - 3.60, Chapter 6 Section 6.2 - 6.37)
REFERENCE BOOKS








Shanti Narayanan, A Text Book of Matrices - S.Chand & Co.
Gupta P.P., Yadav R.P.S., Malik G.S., Mathematical Physics, Kedarnath Ramnath, Meerut
Papoulis A., Probability, Random Variables and Stochastic Processes, Mc Graw Hill.
Kreyszig E., Advanced Engineering Mathematics, Wiley Eastern
Louis A. Pipes and Hartell, Applied Mathematics for Engineers and Physicists, Mc Graw Hill.
PS521
System Theory
3
1
PURPOSE
To impart students to have a fair knowledge about the use of advanced mathematical techniques in Control
Engineering problems.
INSTRUCTIONAL OBJECTIVES
To gain knowledge about state variable representation models
To understand reduction techniques and realization of transfer functions
To get exposed to state space design and analysis of non-linear systems
UNIT I
STATE VARIABLE REPRESENTATION
0
9
Normalisation of differential equations. Introduction to state variable representation models of linear continuous
time system solution of state equation, by various methods.
UNIT I I
CONTROLLABILITY AND OBSERVABILITY
Diagonalization of matrices. Calculation of generalized eigen vectors. Reduction to canonical and Jordan's
canonical form. Gilberts and Kalman's test for controllability and observability.
9
4
UNIT I I I
REALISATION OF TRANSFER FUNCTION
9
Impulse response and transfer function matrices. Properties of transfer functions, reducibility, Realization of
transfer functions. Controllability and observability canonical forms .
UNIT IV
STATE VARIABLE DESIGN
9
State space design. Controllable and observable companion forms. Design by state feedback and pole
placements.
UNIT V
NON-LINEAR SYSTEMS
9
Non linear systems. Phase plane analysis method of isoclines equilibrium points stability concepts and
definitions. Lyaponouv's stability criteria- Routh Hourwitz stability criteria .
TUTORIAL
TOTAL
15
60
REFERENCE BOOKS








Gopal .M, "Modern control theory", Wiley Eastern Ltd., 1993
Doebelin, E.O, "Control systems Principles and Design", John Wiley, 1990
Gopal .M, "Digital control and state variable methods", Wiley Eastern Ltd., 1993
Ogata .K, "Modern Control Engineering" 4th Edition Prentice Hall 1997
Nagarath.I.J. and Gopal.M, "Control system Engineering", Wiley Eastern 1993
PS523
Power System Modeling and Analysis I
3
1
PURPOSE
To enable the students to develop the understanding of power system components modeling and steady state
analysis of power system.
INSTRUCTIONAL OBJECTIVES
To understand the concept of power system studies in planning and analysis
To mathematically model power system components like synchronous machine, transformer and transmission
line
To utilize these models in power system steady state analysis
UNIT I
POWER SYSTEM STUDIES
0
7
Overview of power system modeling for various studies -Distinction between steady state, Quasi steady state
and transient modeling of power systems - Generation system planning - transmission system planning steady state and transient analysis - load forecasting.
UNIT I I
MATHEMATICAL TECHNIQUES
8
Overview - mathematics for basic power system analysis - algebraic equation - differential algebraic equation differential equation, numerical solution of algebraic equations - Gauss elimination method and bifactorization
method - sparsity techniques for large system - sparsity oriented network solution.
UNIT I I I
LOAD FLOW ANALYSIS
9
4
Bus classification, Power flow model using Y bus computational aspects of power flow problem - Gauss Seidel
iterative technique - Newton Raphson method - Fast decoupled power flow method - Multi area power flow
analysis with tie line control -contingency & sensitivity analysis.
Special PURPOSE power flow studies - Harmonic Power flow, three Phase load flow, distribution power flow.
UNIT IV
SHORT CIRCUIT ANALYSIS
9
Symmetrical short circuit analysis, Symmetrical components and sequence impedances. Algorithm for
symmetrical fault analysis using Z bus - Unsymmetrical fault analysis using symmetrical components Algorithm for unsymmetrical fault analysis using Z bus - limitations.
UNIT V
SYNCHRONOUS MACHINE MODELING
12
Physical description of synchronous machine - Mathematical description of a synchronous machine - dqo
transformation - Per unit representation - Equivalent circuit - Steady state analysis - transient performance
characteristics - Magnetic saturation - simplified model with damper neglected - classical model - constant flux
linkage model including the effect of sub transient circuits.
TUTORIAL
TOTAL
15
60
REFERENCE BOOKS









Stagg.G.W. & Abiad. A.H., "Computer methods in Power Systems Analysis", McGraw ill International Editions,
1968
Elgerd.Olle L., "Electric Energy systems theory An Introduction", Tata Mc Graw Hill Edition, 1982
George L.Kusic, "Computer Aided Power Systems Analysis", Prentice Hall of India Ltd., 1986
John J. Grainger & Stevenson .D, "Power System Analysis", McGraw Hill International Editions, 1994
Singh L.P., "Advanced power system analysis", Wiley Eastern limited, 1986
Kundur. P "Power system stability and control", McGraw Hill, 1994
PS525
Power System Control and Operation I
PS527
Power System Protection
PURPOSE
To impart knowledge on various aspects of protective relaying for power system components.
INSTRUCTIONAL OBJECTIVES
To learn about various types of protective relays for power system
To acquire an in-depth knowledge on the protection of transmission lines and generators
To understand the concept of digital protection and computer relaying for power system
UNIT I
3
3
1
0
INTRODUCTION
0
0
9
Review of basic protection - Static relays - advantages - Basic construction - characteristics of protective
relays - Phase & amplitude comparators - Over current relays - different types of time - Over current relays differential protection scheme.
UNIT I I
DISTANCE PROTECTION
Transmission line protection - fault clearing times - Types of distance relays - Evaluation of distance relay
performance during swings - prevention of tripping during transient conditions - automatic re-closing - Three-
10
3
4
zone protection.
UNIT I I I
APPARATUS PROTECTION
10
Protection of generators - Stator protection - rotor protection - generator out-of-step protection - protection of
transformers - Magnetizing in-rush current Buchholz relay - over fluxing protection.
UNIT IV
SYSTEM RESPONSE TO SEVERE UPSETS
8
Nature of system response to serve upsets - frequency actuated schemes for load shedding and islanding.
UNIT V
DIGITAL PROTECTION & COMPUTER RELAYING
8
Factors considered in maintenance scheduling for generating units , turbine - boilers - introduction to
maintenance scheduling using mathematical programming.
TUTORIAL
TOTAL
15
60
REFERENCE BOOKS

Madhava Rao.T.S, "Power System protection :Static relay with Microprocessor applications", Tata McGraw
Hill, 1989
Ram.B, Viswakarma.D.N, "Power System Protection and Switch Gear", Tata McGraw Hill, 1995
Ram.B, "Fundamentals of Microprocessors and Microcomputers" Dhanpat Rai & Sons, 1985
Kundur.P, "Power System Stability and Control", Tata McGraw Hill, 1994



Elective I
Total
3
18
1
5
0
8
4
23
Semester 2
COURSE CODE
COURSE NAME
L
T
P
C
Power System Modeling and Analysis II
3
1
0
4
Theory
PS522


PURPOSE
To enable the students to develop the understanding of power system components modeling and steady state
analysis of power system.
INSTRUCTIONAL OBJECTIVES
To understand the concept of power system components modeling
To utilize these models in power system small signal and transient stability analysis
UNIT I
INTRODUCTION
7
Review of machine modeling - classification of power system stability - small signal stability analysis of SMIB classical machine - Type I machine .
UNIT I I
EXCITATION SYSTEMS
8
Excitation systems requirement - Types of excitation systems - Dynamic performance measures - Control and
protective functions - Modeling of Excitation systems - IEEE simulation models .
UNIT I I I
SMALL SIGNAL STABILITY
10
Small signal stability analysis including excitation system - Power system stabilizer on small signal stability small signal stability of multimachine systems - analysis of large systems- characteristics of small signal
stability problems. Methods of improving small signal stability.
UNIT IV
TRANSIENT STABILITY
10
Transient stability analysis - solution methods of DA systems - simultaneous - implicit method - dommel -sato
algorithm involving classical and Type I machine - interfacing excitation system model with transient stability
algorithm. Hydraulic turbines and governing systems - Steam turbines and governing systems - Thermal
energy systems - IEEE simulation model - interfacing of steam and hydro turbine-governor model.
UNIT V
STATIC VAR SYSTEMS
10
Static var systems - configuration - TCR + FC - TSC and interfacing with transient stability algorithm - induction
motor modeling and interfacing with transient algorithm - method of improving transient stability.
TUTORIAL
TOTAL
15
60
REFERENCE BOOKS







Kundur.P, " Power System Stability and Control", McGraw Hill Publishing Company, Newyork, 1994
Anderson P.M and Fouad A.A, " Power System Control and Stability", Galgotia Publications, NewDelhi, 1981
G.W.Stagg and A.H.El.Abiad, "Computer Methods in Power System Analysis", McGraw Hill Newyork, 1968
IEEE recommended practice for excitation system models for power system stability studies, IEEE standard
421.5, 1992
IEEE recommended practice for excitation system models for power system stability studies, IEEE standard
421.5, 1992
P2524
Power System Control and Operation II
PS526
EHV AC and HVDC Transmission
PURPOSE
To elicit the advantages of EHV AC and HVDC transmission systems.
INSTRUCTIONAL OBJECTIVES
To understand the various aspects of EHV AC and HVDC system and its operation
To understand about the harmonics and its effects on power system
UNIT I
3
3
1
0
INTRODUCTION
Automatic generation control - plant and system level control - ALFC of single area system - modeling - static
and transient response - ALFC of multi area system - modeling - static and transient response of two area
system - development of state variable model of two area system - digital load frequency controller Decentralized control.
0
0
9
4
4
UNIT I I
CORONA
10
Bundled conductors-Surface voltage gradient on single, double and more than three conductor bundles-Effects
of corona-power loss-charge voltage diagram with corona-attenuation of traveling waves due to corona lossnoise generation and their characteristics-corona pulses, their generation and properties (qualitative study
only) - problems of EHV AC transmission at power frequency.
UNIT I I I
HVDC TRANSMISSION
10
HVDC Transmission- Rectification and inversion process a brief introduction - constant current and constant
extinction angle modes of operation- DC transmission system - harmonics on AC and DC sides - filters for their
suppression - multi terminal DC transmission systems-parallel operation of AC and Dc transmission - voltage
stability in AC/DC systems - recent trends in HVDC transmission.
UNIT IV
OVERHEAD EHV TRANSMISSION
7
Design of EHV lines-Design factors under steady state-steady state limits-line insulation coordination based
upon transient over voltages-design examples.
UNIT V
UNDERGROUND EHV TRANSMISSION
9
EHV Cable transmission - Characteristics of EHV cables - desired properties of cable insulation materials design basis of cable insulation. EHV testing - standard specifications and standard wave shapes for testinggeneral lay out of EHV laboratory.
TUTORIAL
TOTAL
15
60
REFERENCE BOOKS


Begamudre R.D , "Extra High Voltage AC Transmission Engineering", Wiley Eastern Ltd., second edition,
1991
Padiyar K.R, "HVDC Power Transmission system technology and System Interaction" , New Age International
(P) Ltd., Publishers, 1990
Elective I
ELective II

Practical
PS528
Power System Simulation Lab
PURPOSE
To impart knowledge in power system analysis for various studies using software.
INSTRUCTIONAL OBJECTIVES
To impart knowledge in power system analysis for various studies using software
LIST OF EXPERIMENTS





Formation of YBus and Zbus
Power flow analysis: Gauss-seidel, Newton Raphson, Fast Decoupled
Symmetrical and unsymmetrical short circuit analysis
Transient stability analysis
DC power flow analysis
3
3
0
0
0
0
3
3
0
0
3
2



Optimal power flow
Voltage stability analysis
Small signal stability analysis
TOTAL
45
REFERENCE BOOKS

Laboratory Manual
PS530
Total
Seminar
0
15
0
3
2
5
1
21
COURSE CODE
COURSE NAME
L
T
P
C
Power System Modeling and Analysis III
3
1
0
4
Semester 3
Theory
PS621


PURPOSE
To provide a comprehensive base on torsional and voltage stability analysis in Power Systems.
INSTRUCTIONAL OBJECTIVES
To understand the concept of turbine - generator torsional characteristics and its impact on the Power System
To understand the basics of Generation, transmission system and load modeling and its effects on voltage
stability analysis
UNIT I
TORSIONAL ANALYSIS
7
Review of multi mass rotor-Turbine - generator torsional characteristics - interaction with power system
controls - Sub Synchronous resonance - counter measure to SSR problems - Impact of network - Switching
disturbances.
UNIT I I
TRANSMISSION SYSTEM ASPECTS
10
Power system stability classification - Voltage stability - Voltage collapse
Transmission system aspects : single load infinite bus system - maximum deliverable power - Power voltage
relationships - Generator reactive power requirement - Effect of compensation - VQ curves - Effect of
Adjustable transformer ratios - problems.
UNIT I I I
GENERATOR ASPECTS
8
Review of synchronous machine theory - frequency and voltage controllers - Limiting device affecting voltage
stability - Voltage reactive power characteristics of synchronous generators - capability curves - Effect of
machine limitations on deliverable power - problems.
UNIT IV
LOAD ASPECTS
Voltage dependence of Loads - Load restoration dynamics - Induction motors - Load tap changers Thermostatic Load recovery - generic Aggregate load models - HVDC links - problems.
8
UNIT V
VOLTAGE STABILITY ANALYSIS
12
Mathematical Background: Differential equations - Bifurcation - DA Systems - Multiple time scales - Loadability
- Sensitivity and bifurcation analysis - eigen vector & singular vector properties - Bifurcation surface - Types of
counter measures - Classification of instability mechanism - counter measures to short term instability Corrective actions against long term instability.
TUTORIAL
TOTAL
15
60
REFERENCE BOOKS



Kundur.P, "Power System Stability and Control", McGraw Hill Publishing Company, New York, 1994
Anderson P.M and Fouad A.A, " Power System Control and Stability", Galgotia Publications, NewDelhi, 1981
Thierry van cutsem, & costas vournas, "Voltage stability of Electric Power Systems", Kluwer Academic
Publishers, 1998
Taylor, C.W. "power system voltage stability", McGraw Hill, NewDelhi, 1993

PRACTICAL
PE623
Total
Elective IV
Elective V
Elective VI
3
3
3
0
0
0
0
0
0
3
3
3
Project Phase I
0
12
0
1
12
12
6
19
Semester 4
COURSE CODE
COURSE NAME
L
T
P
C
Project Phase II
3
0
24
1
18
2
24
1
Theory
PS622
Total
LIST OF ELECTIVES FOR SIXTH SEMESTER
COURSE CODE
COURSE NAME
L
T
P
C
PS571
Solid State Drives
3
0
0
3


PURPOSE
To enrich the student about the operation of solid state devices and their applications to electrical machines.
INSTRUCTIONAL OBJECTIVES
To understand the operation of various types of solid state drives
To utilize these drives for controlling different types of motors
UNIT I
RECTIFIER CONTROL OF DC MOTORS
Methods of speed control and braking of DC motors. Analysis of series and separately excited DC motor with
single phase and three phase converters operating in different modes and configurations.
9
UNIT I I
CHOPPER CONTROL OF DC MOTORS
9
Analysis of series and separately excited DC motor fed from different choppers for both time ratio control and
current limit control - Four quadrant control. Microcomputer implementation of control function for DC drives.
UNIT I I I
STATOR VOLTAGE AND FREQUENCY CONTROL OF INDUCTION MOTOR
9
Torque slip characteristics - methods speed control of 3-phase induction motor. Comparison of different ac
power controllers - Speed reversal - closed loop control - variable frequency operation - constant flux operation
- principle of vector control.
UNIT IV
ROTOR RESISTANCE AND SLIP POWER RECOVERY CONTROL SCHEME
9
Types of rotor choppers - Torque Equation - Constant torque operation - Time ratio control strategy Combined stator voltage control and rotor resistance control --sub synchronous operation - static scherbius
drive operation - closed loop control.
UNIT V
SYNCHRONOUS MOTOR DRIVE
9
Introduction to synchronous motor - starting methods - Need for leading power factor operation - Open loop
VSI fed drive and its characteristics - torque angle control - self control - power factor control.
TUTORIAL
TOTAL
15
60
REFERENCE BOOKS









Dubey G.K, "Power Semiconductor controlled Drives", Prentice Hall international, New Jersey, 1989
Sen P.C., "Thyristor DC Drives", John Wiley & Sons, Newyork 1981
Murphy J.M.D., Turnbill F.G., "Thyristor control of AC motor", Pergamon Press, Oxford 1988
Subramanyam.V., "Electric Drives - Concepts and applications", Tata McGraw Hill Publishing Co., Ltd., New
Delhi 1994
Sheperal, Wand Hully, L.N., "Power Electronic and Motor control", Cambridge University Press, Cambridge,
1987
PS573
Material Science and Technology
3
PS575
Fuzzy Logic and Expert Systems of Power System
3
PURPOSE
This course gives a fundamental understanding of the Object Oriented concepts with the help of the
programming language C ++.
INSTRUCTIONAL OBJECTIVES
Basic concepts of Object Oriented programming
C and C ++ language concepts and programming
Detailed understanding of OOPS concepts like Inheritance and Polymorphism
Advanced concepts like Templates and file I/O
UNIT I
0
0
OBJECT ORIENTED PROGRAMMING
Traditional Programming Approach - Structured Methodology - Object Oriented Concepts - Objects and
Classes - Instance - Messages - Methods - Encapsulation - Inheritance - polymorphism - Dynamic binding -
0
0
10
3
3
Benefits of Object Oriented Programming - C++ Pointers - Runtime binding - Dynamic Objects - Self referential
classes.
UNIT I I
C++ PROGRAMMING
10
C++ Classes and Methods - Members - Message Passing - Creation and Initialization - Constructor and
Destructor functions - Reference variables - Inline functions - Friend functions - Default arguments.
UNIT I I I
ADVANCED FEATURES
8
Inheritance - Benefits - Cost of inheritance - Execution speed - Program size - Message passing overhead Program complexity - Derived Classes - Abstract classes - Multiple inheritance - Access Control.
UNIT IV
POLYMORPHISM
7
Polymorphism - Overloading - Operator overloading - Function overloading - Overriding - Deferred methods Virtual functions.
UNIT V
FILES AND STREAMS
9
Templates - List Templates - Function templates - Template arguments.
Streams - Input -Output - Formatting - Files and Streams - Exception handling.
TUTORIAL
TOTAL
15
60
REFERENCE BOOKS




Bjarne Stroustrup , "The C++ Programming Language" , 2nd edition , Wesley, 1997
Robert Lafore , "Mastering Turbo C++" , BPB Publications , 2000
Yashavant Khanitkar , "Programming in C++" , 4th edition, BPB Publications, 1999
Venugopal , K, R , Raj kumar , Ravishankar , T. , "Mastering C ++ " , Tata McGraw Hill Publication Company
Ltd , 1997
LIST OF ELECTIVES FOR SEVENTH SEMESTER
COURSE CODE
COURSE NAME
L
T
P
C
PS572
Power System Reliability and Planning
3
0
0
3


PURPOSE
The students acquire a comprehensive idea on the various aspects of planning and reliability on power system.
INSTRUCTIONAL OBJECTIVES
To acquire knowledge about the various aspects of load forecasting
To learn about the concept of reliability analysis on generation system planning, transmission system planning
and expansion planning and distribution system planning
UNIT I
LOAD FORECASTING
Load Forecasting- objectives of forecasting -load growth patterns and their importance in planning - load
forecasting based on discounted multiple regression technique - weather sensitive load forecasting -
9
determination of annual load forecasting - use of AI in load forecasting.
UNIT I I
GENERATION SYSTEM RELIABILITY
9
Generation system Reliability Analysis-Probabilistic generation and load models - determination of LOLP and
expected value of demand not served - determination of reliability of isolated and interconnected generation
systems.
UNIT I I I
TRANSMISSION SYSTEM RELIABILITY
8
Transmission system Reliability Analysis-Deterministic contingency analysis- probabilistic load flow - fuzzy
load flow - probabilistic transmission system reliability analysis - determination of reliability indices like LOLP
and expected value of demand not served.
UNIT IV
TRANSMISSION SYSTEM PLANNING
7
Expansion Planning-Basic concepts on expansion planning - procedure followed for integrated transmission
system planning, capacitor placement problem in transmission system and radial distribution system.
UNIT V
DISTRIBUTION SYSTEM PLANNING
9
Distribution System Planning Overview-Introduction, subtransmission lines and distribution substation - design
of primary and secondary systems - distribution system protection and coordination of protective devices.
TOTAL
60
REFERENCE BOOKS






Sullivan R.L, "Power System Planning", McGraw Hill, New York, 1977
Roy Billington & Allan Ronald, "Power system Reliability", Pitman advanced publishing program, 1986
Turan Gonen, "Electric power distribution system Engineering", McGraw Hill, 1986
PS574
Power Distribution Systems
3
PURPOSE
To enable the student acquire a comprehensive idea on various aspects of power distribution systems.
INSTRUCTIONAL OBJECTIVES
To acquire the knowledge on power distribution systems, planning, design and operation
To understand the aspects of system protection and maintenance
To optimize the distribution systems
UNIT I
0
INTRODUCTION
0
9
Loads and Energy forecasting preliminary surveys, Statistical methods, System study, Factors in Power
system loading, Future distribution systems.
UNIT I I
SYSTEM CALCULATIONS
Planning, Design and operation methodology, System calculations load flow, effect of abnormal loads, voltage
control, load variations system losses.
9
3
UNIT I I I
OVERHEAD AND UNDERGROUND SYSTEMS
9
Over head and under ground lines. Choice of system, design of overhead lines. Line accessories. Under
ground system. Cable ratings. Thermo Mechanical effects in cable system. Selection of cables. Fault location.
UNIT IV
DISTRIBUTION SYSTEM PROTECTION
9
System protection and maintenance. Fuses, Switching devices and circuit breakers, Protective relaying.
Protective schemes. Maintenance of lines and transformers. Maintenance methods and costs. System over
voltages and protection.
UNIT V
DISTRIBUTION SYSTEM OPTIMIZATION
9
Optimization of Distribution systems, cost of schemes, Long and short term planning, Network cost modeling,
Economic loading of distribution transformers, Power capacitors, Size and location.
TOTAL
60
REFERENCE BOOKS








Pabla. A.S., "Electric power distribution systems", Tata McGraw Hill, 1992
Turen Gonen, "Electric Distribution systems engineering", Mcgraw Hill International, 1986
Glenn W. Stagg and EI-Abiad., "Computer methods in Power System Analysis", McGraw Hill International,
1968
Miller T.J E, "Reactive Power control in Electric Systems", John Wiley and Sons
Cotton.H, "The Transmission and distribution of Electrical Energy", The English Universities Press
Uppal.S.L , "Electric Power", Khanna Publishers, 1998
PS576
Insulation Technology
3
PURPOSE
The students acquire knowledge in various insulating materials and its properties and their choice.
INSTRUCTIONAL OBJECTIVES
To understand the properties of various insulating materials
To study about the breakdown mechanism in various dielectric materials
UNIT I
0
GENERAL PROPERTIES OF INSULATING MATERIALS
0
15
Requirements for insulating materials - electrical properties - molecular properties of dielectrics - dependence
of permittivity on temperature, pressure, humidity and voltage - permittivity of mixtures - practical importance of
permittivity-behavior of dielectrics under alternating fields - complex dielectric constants-bipolar relaxation and
dielectric loss - dielectric strength.
UNIT I I
BREAKDOWN MECHANISMS IN GASEOUS DIELECTRICS
8
Behavior of gaseous dielectrics in electric fields-gaseous discharges-different ionization processes-effect of
electrodes on gaseous discharge - Townsend's theory - streamer theory - electronegative gases and their
influence on gaseous discharge - Townsend's criterion for spark break down-gaseous discharges in nonuniform fields - breakdown in vacuum insulation.
UNIT I I I
BREAKDOWN MECHANISMS IN SOLID DIELECTRICS
8
3
Intrinsic breakdown of solid dielectrics - electromechanical breakdown - streamer breakdown and thermal
breakdown of solid dielectrics - erosion-electrochemical breakdown - tracking in dielectrics and treeing.
UNIT IV
BREAKDOWN MECHANISMS IN LIQUID DIELECTRICS
6
Electronic breakdown of - cavitation breakdown of liquid dielectrics - suspended particle theory of breakdown
of liquid dielectrics.
UNIT V
INSULATION MATERIALS
8
Natural inorganic insulating materials - synthetic inorganic insulating materials - natural organic insulating
materials - synthetic organic insulating materials.
TOTAL
45
REFERENCE BOOKS







Adrianus, J.Dekker, "Electrical Engineering materials", Prentice Hall of India Pvt. Ltd., New Delhi, 1979
Van Vlack, "Elements of materials science", Addison Wesley, 1964
Kuffel, E., Zaengl, W.S. and Kuffel J., "High Voltage Engineering Fundamentals", Newness, Second Edition,
Butterworth-Heinemann Publishers, New Delhi, 2000
Dissado. L.A., Fothergill. J.C, "Electrical Degradation and Breakdown in Polymers", Peter Peregrinus, 1992
PS578
ANN Applied to Power System
3
0
PURPOSE
To enrich the student with clear knowledge on Artificial Neural Network and its applications to power systems.
INSTRUCTIONAL OBJECTIVES
To have an idea on Neural Network concepts
To get a clear vision on different types of networks and their features
To have a knowledge on ANN implementation to power system problems
UNIT I
INTRODUCTION
0
9
Neural Network concepts definition and building blocks. Connection signal data types, Input classes and
geometries, Processing Elements N dimensional Geometry.
UNIT I I
TRAINING OF ANN
9
Learning Law, Self adaptation Equations. Definitions. Coincidence performance, competitive, filter and
spatiotemporal learning.
UNIT I I I
ASSOCIATIVE NETWORKS
9
Associative networks. Definitions. The hop field network. BAM Associative network theorems. Adaptive
resonant theory ART-1. Single layer perceptions.
UNIT IV
MULTI LAYER NETWORKS
Multi layer data transformation structures. Back propagation network general feed forward networks.
9
3
UNIT V
APPLICATIONS
9
Pattern recognition problems in Power Systems. Load forecasting. ANN implementation in Matlab.
Characteristics of neutral network controllers.
TOTAL
45
REFERENCE BOOKS






Robert Hect Nielsen, "Neuro computing", Addson - Wesley Publishing Co., 1990
Jacek M. Zurada, "Introduction to Artificial Neural systems", Jako Publishing House.1999
Matlab V-6 Manual
Dayjoff J. Van Nostrand Reinhold., "Neural Network Architectures - An Introduction".2000
PS580
Digital Signal Processing
PURPOSE
To impart knowledge on various aspects of Digital Signal Processing techniques.
INSTRUCTIONAL OBJECTIVES
To learn about various discrete signals and its properties
To get a brief idea on the design of digital filters and its application on signal processing
UNIT I
3
0
0
INTRODUCTION
7
Characteristics and classification of signals - examples of signals - multichannel - multi-dimensional continuous versus discrete - analog versus digital - concepts of signal processing - advantages of digital signal
processing over analog processing.
UNIT I I
DISCRETE TIME SYSTEMS
10
Discrete time signals - Linearity, shift invariance - sequences - Stability and causality - Frequency domain
response - Z-transform - Theorems & properties - Structure for discrete time system - direct, cascade and
parallel, ladder.
UNIT I I I
DISCRETE FOURIER TRANSFORMER
10
Discrete fourier series - Properties - Sampling Z-transformer - discrete fourier transform - properties - Linear &
circular convolution - Decimation-in-time and decimation-in-frequency - FFT algorithms.
UNIT IV
DIGITAL FILTER DESIGN
10
Introduction - Properties of IIR filter - Design of IIR filters - Impulse invariance & Bilinear transformation
techniques - Properties FIR filters - Design of FIR -filters using windows - Comparison of IIR & FIR digital
filters.
UNIT V
EFFECTS OF FINITE WORD LENGTH
8
Introduction - A/D quantisation noise - Co-efficient quantisation - Quantization in sampling analog signals overflow errors - product round off errors - limit cycles due to product round off - finite word length effects in IIR
and FIR filters, discrete fourier transform.
TOTAL
45
3
REFERENCE BOOKS




Alan V. Oppenheim, Ronald W.Schafer, "Digital signal processing", Prentice Hall of India pvt Ltd., 2002
John G.Proakis, Dimitris G.Manolakis, "Digital signal processing", Prentice Hall of India pvt Ltd., third
edition.1996
Sanjit K.Mitra, "Digital signal processing", Tata Mc Graw Hill, .1998
Alan V. Oppenheim, Ronald W.Schafer, "Discrete-time signal processing", Prentice Hall of India pvt Ltd., 1998
LIST OF ELECTIVES FOR EIGHTH SEMESTER
COURSE CODE
COURSE NAME
L
T
P
C
PS671
Static and Digital Relaying of Power Systems
3
0
0
3
PS673
Electrical Transients in Power Systems
3
0
0
3
PS675
Reactive Power Compensation in Power System
3
0
0
3
PS677
Power Line Carrier Communication
3
0
0
3
PS679
HVDC and Facts
3
0
0
3
PS681
Power Quality Management
3
0
0
3
SCHEME OF EXAMINATION
COURSE
DURATION IN HOURS
INTERNAL MARKS
EXTERNAL MARKS
TOTAL
PASSING MINIMUM
External
Internal
All Theory And Practical Courses
3 hrs
30
70
100
35
50
Project Work
-
150
450
600
-
300
Comprehension
-
100
-
100
-
-
© SRM University, India. All rights reserved.
 Site Map
 Contact Us