Download power systems specialization

DEPARTMENT OF ELECTRICAL ENGINEERING
NATIONAL INSTITUTE OF TECHNOLOGY KURUKKSHETRA
MASTER OF TECHNOLOGY (ELECTRICAL ENGINEERING)
POWER SYSTEMS SPECIALIZATION
W.E.F. 2006-07
FIRST SEMESTER
Course Title
Schedule of Teaching
Credit
No.
Lecturer Tutorial Practical Total Point
E-501 Advanced Power System
4
--4
4
Analysis
E-503 Power System Protection and
4
--4
4
Relaying
E-505 EHVAC Transmission
4
--4
4
E-507 Systems Engineering
4
--4
4
Elective-I
4
--4
4
E-509 Power Systems Lab
--3
3
1.5
E-511 Seminar-I
--1
1
1
Total
20
-4
24
22.5
E-501 APSA is a core course in 1st sem PED also.
E-507 SE is a core course in 1st sem CS also.
SECOND SEMESTER
Course Title
Schedule of Teaching
No.
Lecturer Tutorial Practical
E-502 Power System Operation
4
--And Control
E-504 Power Systems Dynamics
4
--and Stability
E-506 HVDC Transmission
4
--E-508 Power
Apparatus
and
4
--Machines
E-510 Information Security
4
-E-512 Computer Applications Lab
--3
E-514 Seminar-II
--1
Total
20
-4
E-508 PAM is a core course in 2nd sem PED also.
E-510 IS is a core course in 2nd sem PED and 2nd sem CS also.
Credit
Total Point
4
4
4
4
4
4
4
4
4
3
1
24
4
1.5
1.0
22.5
THIRD SEMESTER
Course
No.
E-601
E-603
Title
Elective-II
Elective-III
Simulation Lab
Dissertation
Seminar-I on Dissertation
Total
Schedule of Teaching
Lecturer Tutorial Practical
4
-4
---3
--9
8
--
Credit
Total Point
4
4
4
4
3
1.5
9
12
20
9.5
FOURTH SEMESTER
Course
No.
E-602
E-604
Title
Dissertation
Seminar-II on Dissertation
Total
For Theory Courses
Lecturer
----
Schedule of Teaching
Tutorial Practical
-20
---20
: During Semester Evaluation Weightage
End Semester Examination Weightage
Credit
Total Point
20
---20
--
= 40%
= 60%
For Laboratory Courses : During Semester Evaluation Weightage = 60%
End Semester Examination Weightage = 40%
Duration of end semester examination in each theory and laboratory course is three hours.
The examination in the subject of Dissertation is to be conducted jointly by two examiners, one of
which will be the dissertation supervisor, and the other, an external examiner.
The result of the examination in Dissertation shall be one of the followingApproved, Approved with Distinction, Rejected.
DEPARTMENT OF ELECTRICAL ENGINEERING
NATIONAL INSTITUTE OF TECHNOLOGY KURUKKSHETRA
MASTER OF TECHNOLOGY (ELECTRICAL ENGINEERING)
POWER SYSTEMS SPECIALIZATION
W.E.F. 2006-07
List of Courses under Electives-I, II, III
S No
1
2
3
4
5
6
7
8
9
10
11
12
Course No
E-701
E-703
E-705
E-707
E-709
E-711
E-713
E-715
E-717
E-719
E-533
E-561
Title
Transients in Power Systems
FACTS
Drives and Control
Power Systems Reliability
Power System Planning
Power Systems Communication
Wind Energy and Small Hydro energy Station
Special Topics In Power Systems
Intelligent Control
Cryptography
Modeling and Analysis of Electrical Machines
Microprocessors and Digital Signal Processors
E-705 D&C is an elective course in 3rd sem CS also.
E-717 IC is an elective course in 3rd sem PED and 3rd sem CS also.
E-719 Cryptography is an elective course in 3rd sem PED and 3rd sem CS also.
E-533 MAEM is also a core course in 1st sem PED.
E-561 MP&DSP is also an elective course in 1st sem PED and a core course in 1st sem
CS.
MASTER OF TECHNOLOGY (ELECTRICAL ENGINEERING)
POWER SYSTEMS SPECIALIZATION
W.E.F. 2006-07
Course No. E-501
L T P Total
4 0 0 4
Advanced Power System Analysis
(A core course in 1st sem PED also)
Credits-4
Duration of Exam- Three hours
During Semester Evaluation Weightage- 40%
End Semester Examination Weightage- 60%
Review of matrix operations, graph theory, and various circuit incidence matrices, primitive
network and matrix, Formation of various network matrices by singular transformation
interrelations.
Building algorithm for bus impedance matrix, Modification of bus impedance matrix for change
of reference bus for network changes, Formation of bus admittance matrix and modification,
Gauss elimination, Node elimination (Kron reduction), LU factorization, Schemes of Ordering,
Sparsity, Calculation of Z bus elements for Y bus.
Representation of three phase network elements, Treatment under balanced and unbalanced
excitation, Transformation matrices, Unbalanced elements.
Network short circuit studies using Z bus, Short circuit calculations for various types of faults.
Load flow studies, its importance. Classification of buses, load flow techniques, Iterative
solutions and computer flow charts using Gauss-Seidel and Newton-Raphson methods,
Decoupled and fast decoupled load flow solution, Representation of regulating and off nominal
ration transformers, Tie-line control, Comparison of methods.
Introduction to AC-DC load flow problems: formation and solutions.
Power system security, Contingency analysis using Z bus using sensitivity factors.
Introduction to state estimation, maximum likelihood weighted least square error estimation,
State estimate of an AC network.
References:
1. G.W. Stagg & A.H EI-Abaid, “Computer methods in Power system analysis”, McGraw Hill,
New York.
2. G.L Kusic., “Computer-Aided Power System Analysis”, Prentice Hall of India, New Delhi.
3. John J.Grainger and W.D.Stevenson, “Power System Analysis”, McGraw Hill, New York,
1994.
4. A.J. Wood & W.F. Wollenberg, “Power Generation, Operation, and Control”, 2 nd Edn, John
Wiley & Sons, New York, 1996.
5. O.I. Elgerd, “Electric Energy Systems Theory: An Introduction”, McGraw Hill, New York,
1982.
6. J. Arrillaga, C.P Arnold & Harker, “Computer Modeling of Electrical Power Systems”, John
Wiley & Sons.
MASTER OF TECHNOLOGY (ELECTRICAL ENGINEERING)
POWER SYSTEMS SPECIALIZATION
W.E.F. 2006-07
Course No. E-503
Power System Protection & Relaying
L T P Total
4 0 0 4
Credits-4
Duration of Exam- Three hours
During Semester Evaluation Weightage- 40%
End Semester Examination Weightage- 60%
Introduction: Need for protective systems, Zones of protection, classification or protective relays
and protective schemes, Current transformers and potential transformers, Advantages of static
relays.
Comparators: general equation of comparators, Analysis for amplitude comparator, analysis for
phase comparator, duality between amplitude and phase comparators, different types of amplitude
and phase comparators.
Static Relays:
Over current relays: Instantaneous over current relays, definite time overcorrect relays, directional
overcorrect relay, comparison with conventional relays, differential relays, operating and restraining
characteristics, types of differential relays, comparison with conventional relays, distance relays,
impedance relays, reactance relays, mho relay quadrilateral relays, elliptical relays, comparison with
conventional relays.
Distance protection: Principle of distance relaying, time grading of distance relays, schemes of
distance protection, distance protection by impedance, reactance and mho relays, Effect of power
swings on the performance of distance relays.
Pilot relaying schemes: Pilot wire protection, carrier current protection.
Protection of Generators and Motors: Types of faults, Stator and rotor protection against various
types of faults.
Protection of Transformers: Types of faults, differential protection schemes, harmonic restraint
relay, over flux protection, earthing transformer protection.
Bus Zone Protection: Types of Bus-bar faults, differential current protection frame leakage
protection.
Microprocessor based protective relays: Over current relay, impedance relay, reactance relay, mho
relay, microprocessor based distance relaying.
Testing and maintenance of static relays.
References:
1.
TSM Rao, “Power System Protection – Static Relays”, Tata McGraw Hill.
2.
S.P Patra, S.K Basu and S. Choudhary, “Power System Protection”, Oxford IBH Pub.
3.
B. Ravindernath and M. Chander, “Power System Protection and Switchgear”, Wiley
Eastern Ltd.
4.
Badri Ram and Vishwakarma, Power System Protection and Switchgear, TATA
McGraw Hill.
MASTER OF TECHNOLOGY (ELECTRICAL ENGINEERING)
POWER SYSTEMS SPECIALIZATION
W.E.F. 2006-07
Course No. E-505
EHV AC Transmission
L T P Total
4 0 0 4
Credits-4
Duration of Exam- Three hours
During Semester Evaluation Weightage- 40%
End Semester Examination Weightage- 60%
Introduction: Role of EHV AC Transmission, standard transmission voltages, average value of line
parameters, power handling capacity.
Line parameters Properties of bundled conductors, resistance, induction and capacitance of bundled
conductor lines, temperature rise of conductors and current carrying capacity. Voltage gradients on
conductors: Charge potential relations for multi-conductor lines, surface voltage gradient on
conductors, distribution of voltage gradient on sub conductors of bundle.
Corona Effects: Corona loss, attenuation of traveling waves, audible noise, limits for audible noise,
AN measurement and meters, Day night equivalent noise level, limits for radio interference fields,
RI excitation function, measurements of RI, RIV, Excitation function.
Switching Over voltages: Origin of over voltages and their types, over voltages due to interruption
of low inductive current and interruption of capacitive currents, Reduction of switching surges on
EHV systems.
Power frequency over voltages: Problems at power frequency, no-load voltage conditions and
charging current, voltage control using synchronous condensers, sub synchronous resonance in
series-capacitor compensated lines, state reactive compensating schemes.
Operational aspects of Power flow: Line loadability, effects of over load, reactive power limitations
and over voltage problem.
References:
1.
2.
3.
4.
Begamudre, “EHV AC Transmission engineering”, Wiley Easter Ltd. 2nd Ed.
Edison Electric Institute, “EHV transmission reference book”, GE Co.
EPRI, Palo Alto, “Transmission line reference book 345 KV”.
Rudenberg, “Transient performance of electric power systems” McGraw Hill.
MASTER OF TECHNOLOGY (ELECTRICAL ENGINEERING)
POWER SYSTEMS SPECIALIZATION
W.E.F. 2006-07
Course No. E-507
L T P Total
4 0 0 4
Systems Engineering
(A core course in 1st sem CS also)
Credits-4
Duration of Exam- Three hours
During Semester Evaluation Weightage- 40%
End Semester Examination Weightage- 60%
Optimization Theory:
Introduction to optimization theory, Importance in solving system engineering problems, Convex
sets & Functions; affine and convex sets, supporting and separating hyper planes, dual cones and
generalized inequalities.
Linear Programming problem; Formulation, Simplex Method, Dual Simplex method, sensitivity
analysis, duality in programming.
Introduction to nonlinear programming;
Unconstrained Optimization-formulation of quadratic optimization problems, gradient descent and
steepest descent methods, Newton’s method, self-concordance.
Constrained optimization – direct optimization, Cutting plane methods, methods of feasible
direction, analytic center cutting plane methods.
Multi-objective optimization.
Application to approximation and filling problems.
System Modeling:
Introduction, types of modeling, modeling of time-varying, distributed, stochastic, nonlinear,
discrete event and hybrid systems.
Conventional tools for linear system modeling, Introduction to non-conventional modeling tools ,
Neural models, fuzzy models.
Model simulation languages and tools.
References:
1.
2.
3.
4.
SS Rao, “Optimization theory and applications” Wiley Eastern Ltd.
KV Mittal, “Optimization methods”, Wiley Eastern Ltd.
NA Kheir, “System modeling and computer simulation” Marcel Decker, New York.
Korn G.A., “Interactive Dynamic System Simulation”, McGraw Hill, N.Y.
MASTER OF TECHNOLOGY (ELECTRICAL ENGINEERING)
POWER SYSTEMS SPECIALIZATION
W.E.F. 2006-07
Course No. E-502
L T P Total
4 0 0 4
Power System Operation & Control
Credits-4
Duration of Exam- Three hours
During Semester Evaluation Weightage- 40%
End Semester Examination Weightage- 60%
.
Load Characteristics and modeling, Load forecasting, Power Systems interconnection,
Unintegrated and integrated operation.
Thermal units cost models, Formulation and solution of optimum dispatch without
considering transmission losses using lagrange’s methods. General transmission loss formula and
B-Coefficients. Incremental transmission loss formula. Optimum dispatch considering transmission
losses. Penalty factor technique. Iterative computational procedure for dispatch problem. Load
dispatch center.
Unit commitment problem. Solution of the problem by priority list scheduling and using
dynamic programming principle.
Hydroelectric plant model. Energy scheduling, Incremental water rate. Coordination
equations for short-range hydrothermal scheduling with fixed head hydro plant. Computational
flow-chart. Optimal scheduling of hydrothermal system using discretization and gradient vector
approach.
Economics of inter-change of energy. Effect of transmission loss.
Load frequency control problem. Models of various subsystems of a generating unit.
Governor characteristics. Steady-state and dynamic analysis. Control area concept. Incorporating
proportional and integral type controllers. Area control error, LFC and economic dispatch, Twoarea LFC, Tie-line Control, SCADA systems.
Control of active and reactive power. Shunt and series compensation and associated analysis.
References:
1.
Allen J. Wood, and Bruce F. Wollenberg, “Power Generation, Operation and Control”,
John Wiley & Sons, Inc., New York.
2.
Olle I. Elgerd, “Electric Energy Systems Theory – An Introduction”, Mc Graw-Hill Book
Company, New York.
3.
John J. Grainger and William D. Stevenson, Jr., “Power System Analysis”, Mc Graw Hill
Book Company, Inc., New York.
4.
PSR Murty, “Power System Operation and Control”, Tata McGraw-Hill Publishing
Company Ltd., New Delhi.
5.
IJ Nagrath & DP Kothari, “Power System Engineering, Tata McGraw Hill Publishing
Co., Ltd. New Delhi.
6.
AK Mahalinabis, DP Kothari and SI Ahson, Computer-Aided Power System Analysis
and Control, Tata McGraw Hill Publishing Co. Ltd. New Delhi.
7.
BR Gupta, “Generation of Electrical Energy”, S. Chand & Co. Ltd. N. Delhi.
MASTER OF TECHNOLOGY (ELECTRICAL ENGINEERING)
POWER SYSTEMS SPECIALIZATION
W.E.F. 2006-07
Course No. E-504
L T P Total
4 0 0 4
Power System Dynamics & Stability
Credits-4
Duration of Exam- Three hours
During Semester Evaluation Weightage- 40%
End Semester Examination Weightage- 60%
Introduction Basic Concepts, Definitions and Classification of Power System Stability/
Synchronous machine modeling for stability studies: Basic equations of a synchronous machine, the
dq0 transformation, per unit representation, equivalent circuits for direct and quadrature axes, steady
state analysis, transient performance, magnetic saturation`, equations of motion, swing equation,
simplified model with ammortisseurs neglected, constant flux linkage model.
Excitation and prime mover controllers: Elements of excitation systems, types of excitation system,
dc,ac and static excitation systems, system representation by block diagram and state equations,
prime mover control system.
Small signal stability of power systems: Fundamental concepts of stability of dynamic systems,
Eigen properties of the state matrix, small signal stability of a single machine infinite bus system,
effects of excitation system, power system stabilizers, system state matrix with amortisseurs, small
signal stability of multi machine systems. Use of PSS to improve small signal stability.
Transient stability: Equal area criterion, numerical integration methods, simulation of power system
dynamic response, direct methods of transient stability analysis – description of transient energy
function approach, limitations of the direct methods. Methods of improving transient stability.
Voltage stability: Basic concepts related to voltage stability, voltage collapse, voltage stability
analysis – static and dynamic analysis, the continuation power flow analysis, prevention of voltage
collapse.
References:
1.
2.
3.
P. Kundur, ‘Power System Stability and Control’, Mc Graw Hill.
K.R. Padiyar, ‘Power System Dynamics’ BS Publications.
P.M Anderson and A.A Fouad ‘Power System Control and Stability’.
MASTER OF TECHNOLOGY (ELECTRICAL ENGINEERING)
POWER SYSTEMS SPECIALIZATION
W.E.F. 2006-07
Course No. E-506
L T P Total
4 0 0 4
Introduction:
H V D C Transmission
Credits-4
Duration of Exam- Three hours
During Semester Evaluation Weightage- 40%
End Semester Examination Weightage- 60%
Comparison of AC and DC transmission. Application of DC transmission Planning of
HVDC transmission.
HVDC Converters: Converter configuration, . Graetz Circuit. Converter bridge. Twelve-pulse
converter. Detailed analysis of converters.
HVDC System Control:
Principles of DC link control. Converter control characteristics.
Firing angle control. Current and extinction angle control. Starting and stopping of DC link. Power
control.
Reactive Power Control:
control during transients.
Sources of reactive power. Static var systems. Reactive power
Harmonics and Filters:
Generation of harmonics. Smoothing reactors, AC and DC filters
used for harmonic Elimination.
Converter Faults and Protection:
voltages.
Converter faults. Protection against over currents and over
AC and DC Systems: Parallel operation of AC and DC systems. Methods of control of power.
References:
1.
2.
3.
EW Kimbark, ‘Direct current Transmission’, Vol. I, Wiley Interscience.
J. Arrillaga, ‘High Voltage Direct Current Transmission’, Peter Peregrines.
KR Padiyar, ‘ HVDC Power Transmission Systems’, New Age International (P) Ltd.,
Publishers, 3rd Edition.
MASTER OF TECHNOLOGY (ELECTRICAL ENGINEERING)
POWER SYSTEMS SPECIALIZATION
W.E.F. 2006-07
Course No. E-508
L T P Total
4 0 0 4
Power Apparatus and Machines
(A core course in 2nd sem PED also)
Credits-4
Duration of Exam- Three hours
During Semester Evaluation Weightage- 40%
End Semester Examination Weightage- 60%
Generalized Theory of Electrical Machines: Introduction, primitive model, transformation, voltage
equations for induction and synchronous machines.
Induction Machines: Abnormal running operation, effect of space harmonics, slip power control,
capacitor self-excitation of induction machines and its applications.
Transformers: Transformer as a mutually coupled circuit, equivalent circuit from coupled circuit
approach.
Multicircuit Transformers:
transformers.
Advantage, theory, equivalent circuit, regulation, three circuit
Three phase autotransformers: Connections and Analysis
Parallel operation of dissimilar transformers. Harmonics; Inrush current phenomenon, effect
of load and three phase connections. Sequence impedances in transformers.
Special Machines:
Servomotors, stepper motors, synchros, BLDC motors.
References:
1.
2.
3.
4.
5.
MIT Staff, ‘Magnetic Circuits and Transformers’, MIT Press Cambridge.
L.F Blume,’Transformer Engineering’, John Wiley & Sons, Inc, N.Y.
Fitzgerald & Kingsley, ‘Electric Machinery’ McGraw Hill Co. New Delhi.
A Langsdorf, ‘Theory of alternating current Machinery’, McGraw Hill Co. New Delhi.
PS Bimbhra ‘Generalized Theory of Electrical Machines’ Khanna Publishers, New
Delhi.
MASTER OF TECHNOLOGY (ELECTRICAL ENGINEERING)
W.E.F. 2006-07
Course No. E-510
L T P Total
4 0 0 4
Information Security
(A common core course in 2nd sem PS, PED and CS)
Credits-4
Duration of Exam- Three hours
During Semester Evaluation Weightage- 40%
End Semester Examination Weightage- 60%
Information Security and privacy, introduction, Security levels, Security aims.
System Security – Security models, Security functions and Security Mechanisms,
Privacy enhancing Mechanisms, Access control: role based attribute based, Data base Security,
Secure programming, Security evaluation criteria.
Network Security – Security Threats and vulnerabilities, Firewalls, IDS, VPNS, Router Security,
Viruses, Worms, DoS, DDos attacks, OS Security, Security protocols, Security management, Audit
and Assurance, Standards, Availability, Survivability, Introduction to disaster recovery and
Forensics.
Introduction to Cryptography.
References:1. B. Matt, “Computer Security”, Pearson Education., New Delhi, 2003.
2. W. Stallings, “Cryptography and Network Security”, Pearson Education., New Delhi,
2003.
3. Rolf Oppliger, “Secrets technologies for world wide web”, 2nd Edition, Artech House,
2003.
MASTER OF TECHNOLOGY (ELECTRICAL ENGINEERING)
POWER SYSTEMS SPECIALIZATION
W.E.F. 2006-07
Course No. E-701
L T P Total
4 0 0 4
Transients in Power Systems
Credits-4
Duration of Exam- Three hours
During Semester Evaluation Weightage- 40%
End Semester Examination Weightage- 60%
Origin and nature of power system transients. Traveling waves on transmission lines.
General wave equation. Attenuation and distortion of waves. Reflection and refraction of traveling
waves at different line terminations. Traveling waves in multiconductor systems. Transition points
on multiconductor circuits.
Transient over voltages due to lightning. Theory of ground wires. Direct stroke to a tower.
Effect of reflection up and down the tower. Tower grounding and counterpoises. Switching
transients. Single and double frequency transients. Abnormal switching transients. Capacitance
switching. Kilometric fault. Line dropping and load ejection. Closing and reclosing of lines. High
charging currents. Over voltages induced by faults. Ferro-resonance. Switching transients in
integrated systems. Peaking switching over voltages in EHV lines and cables.
Transients in transformers. High frequency transients and voltage distribution in transformer
windings.
Protection of Power Systems against transients, and insulation coordination.
References:
1.
2.
3.
4.
5.
IV Begley, ‘Traveling waves in Transmission Systems’, John Wiley (1933,51), Dover.
R. Rudenberg. ‘Electric Stroke waves in Power Systems’, Harvard University Press,
Cambridge, Massachusetts.
Allan Greenwood, ‘Electric Transients in Power Systems’, Wiley Interscience.
CS Indulkar and DP Kothari, ‘Power System Transients, A Statistical Approach’,
Prentice-Hall of India Pvt Ltd., New Delhi. 110 001.
VA Venikov, ‘Transient phenomena in Electrical Power Systems’, Pergamon Press,
London.
MASTER OF TECHNOLOGY (ELECTRICAL ENGINEERING)
POWER SYSTEMS SPECIALIZATION
W.E.F. 2006-07
Course No. E-703
L T P Total
4 0 0 4
Flexible AC Transmission Systems (FACTS)
Credits-4
Duration of Exam- Three hours
During Semester Evaluation Weightage- 40%
End Semester Examination Weightage- 60%
Reactive Power Control in Electric Transmission Systems, Loading Capability and Stability
Considerations. Introduction to acts, related concepts and system requirements.
Principles of operation, control schemes and the characteristics of shunt compensation, facts
devices like statcom, SMES; series compensators like CSE, TCSC, SSSC, combined compensators
(UPFC) and phase shifters devices such as SPS, TCPAR.
Application considerations of FACT devices.
References:
1.
2.
3.
4.
Understanding FACTS: N.G Hingorani, J Gyugi (JEEE Press).
Flexible AC Transmission Systems (FACTS), Y.H.Song (JEEE Series).
Thyristor Based FACTS Controller for Electric Transmission Systems-R Mathur & P.K
Verma, IEEE Press (Wiley)
Reactive Power Control in Power Systems TSE Miller
MASTER OF TECHNOLOGY (ELECTRICAL ENGINEERING)
POWER SYSTEMS SPECIALIZATION
W.E.F. 2006-07
Course No. E-705
L T P Total
4 0 0 4
Drives and Control
(An elective course in 3rd sem CS also)
Credits-4
Duration of Exam- Three hours
During Semester Evaluation Weightage- 40%
End Semester Examination Weightage- 60%
Different Control Schemes of Electric Drives, Transient Analysis of different DC Motor
Drives Configurations, Controlled Rectifier-fed DC Drives. Transfer Functions of the Subsystems,
Design of Controllers, 12-pulse Converter for DC Motor Drives. Application Considerations of
Drives, Chopper-Controlled DC Drives.
Pulse Width Modulation for Electric Power Converters, Control and Estimation of Induction
Motor and Synchronous Motor Drives, Applications of Adjustable Speed Drives (ASDs) in
Industries and in Electric Utility Power Plants. Harmonic Analysis in ASDs.
References:
1.
2.
3.
4.
5.
Dubey, G.K. Fundamentals of Electrical Drives, Narosa Publishing House, New Delhi.
Krishan R. Electric Motor Drives: Modeling Analysis and Control: PHI Pvt Ltd. New
Delhi-2001.
Bose, B.K. Power Electronics and Variable Frequency Drives: Technology and
Applications, IEEE Press, 1997.
Bose B.K., Modern Power Electronics and AC Drives, Pearson Educational, Delhi, 2002.
Oliver, L.A, Adjustable Speed Drives: Application Guide, JARSCO Engineering Corp
and FPRI, Palo Alto 1992.
MASTER OF TECHNOLOGY (ELECTRICAL ENGINEERING)
POWER SYSTEMS SPECIALIZATION
W.E.F. 2006-07
Course No. E-707
L T P Total
4 0 0 4
Power Systems Reliability
Credits-4
Duration of Exam- Three hours
During Semester Evaluation Weightage- 40%
End Semester Examination Weightage- 60%
Review of probability theory, probability laws, binomial, Poisson’s, Normal Exponential, Gamma
and Weibull distributions.
Markov processes (discrete state and continuous time), State transition matrix and state transition
diagram.
Reliability definition, Hazard rate, General reliability function, Mean time to failure, mortality
curve, reliability evaluation using state enumeration, tie set and cut set methods, reliability indices
from state transition matrix and state transition diagram.
Models for generation system reliability evaluation, capacity outage probability, recursive
algorithm, loss of load indices, load forecast uncertainty, loss of energy indices, frequency and
duration methods, system risk indices,
Spinning capacity evaluation, load forecast uncertainty, derated capacity levels.
Reliability evaluation of two area interconnected system.
Conditional probability approach for evaluation reliability of a generation- transmission system.
Transmission system reliability evaluation using average interruption rate method and frequency and
duration methods, Stormy and normal weather effects, Markov processes approach.
Interruption indices for distribution systems and their evaluation for radial distribution systems.
Introduction to protective system reliability evaluation.
References:
1.
2.
3.
4.
5.
6.
M.L Shooman, “Probabilistic Reliability – An engineering approach”, RK Pub. Co.,
Florida.
C.O. Smith, “Introduction to reliability in design”, McGraw Hill, Tokyo.
R. Billinton, R.J Ringlee and A.J Wood, “Power System Reliability Calculations,
MIT Press, Cambridge.
J. Eudrenyl, “Reliability modeling in electric power systems”, John Wiley, NY.
C. Singh & R. Billinton, “System Reliability modeling and evaluation, Hutchisn London.
R.L Sullivan, “Power System Planning”, McGraw Hill New York.
MASTER OF TECHNOLOGY (ELECTRICAL ENGINEERING)
POWER SYSTEMS SPECIALIZATION
W.E.F. 2006-07
Course No. E-715
L T P Total
4 0 0 4
Special Topics in Power Systems
Credits-4
Duration of Exam- Three hours
During Semester Evaluation Weightage- 40%
End Semester Examination Weightage- 60%
Power System Restructuring and Deregulations.
1.
Introduction to Power System Deregulation Market Models Pool & Bilateral
International Experiences. Role of ISO, Market Power, Bidding and Auction
Mechanisms.
Transmission Open Access. Transmission Pricing. Impact of Congestion and Congestion
Management. ATC and Factor affecting ATC. Determination of ATC. Ancillary Services and
their management. Electricity Bill 2003 and its impact on ESI in India.
2.
Power System Computation and Computer Application.
OPF and its Formulation, Solution Techniques NLP Methods, LPOPF Interior Point Method. AI
Techniques and Genetic Algorithm.
SCADA & Distribution Automation. Energy management systems, Power system
communication, PICC Digital Communication, Microwave communication – Utility
communication architecture, Java and Web based technologies. Software Agents.
References:
1. Lei Lee Lai, Power System restructuring and deregulation. John Wiley and Sons, UK. 2001.
2. K. Bhattacharya, MHT Bollen and J.C Doolder, Operation of Restructured Power Systems,
Kluwer Academic Publishers, USA, 2001.
3. A.J Wood and B.F Wollenberg. Power System Operation and Control, John Wiley and Sons.
4. S.A Soman, S.A Khafasok, Shubha Pandit, Computational Methods for large Sparse Power
System Analysis: An Object Oriented Approach. Kluwer Academic Publishers.
MASTER OF TECHNOLOGY (ELECTRICAL ENGINEERING)
W.E.F. 2006-07
Course No. E-717
L T P Total
4 0 0 4
Intelligent Control
(A common elective course in 3rd sem PS, PED, and CS)
Credits-4
Duration of Exam- Three hours
During Semester Evaluation Weightage- 40%
End Semester Examination Weightage- 60%
Introduction to Soft Computing Methodologies – Artificial Neural Networks, Fuzzy Logic,
Genetic Algorithm.
Need for intelligent control, intelligent system models, introduction to system modeling
using ANN and Fuzzy logic.
Basic Fuzzy Logic System, Fuzzy Logic based system modeling, Fuzzy Logic based
Controller Design. Theoretical and implementation issues.
Artificial Neural Netwoks, human brain model, artificial neuron interneuron architecture,
types of ANN + feed forward and feedback. Supervised and unsupervised learning. Boltzman
Machine, recurrent neural architectures, neural modeling of engineering systems, ANN based
controller design, theoretical and implementation issues.
Introduction to neurofuzzy systems and their application to control of complex systems.
References:
1.
2.
3.
4.
Fuzzy Logic Control by T.J. Ross TM.H. Publications.
Fuzzy Logic Control by Drinnkov, Narosa Publishers.
Comprehensive Neural Networks by Simon Hekins, Pearson Publications.
Neuro Fuzzy and Soft Computing by J.S.R. Jang, C.T. Sun, E. Mizutani, P.H.I.
Publishers.
MASTER OF TECHNOLOGY (ELECTRICAL ENGINEERING)
W.E.F. 2006-07
Course No. E-719
L T P Total
4 0 0 4
Cryptography
(A common elective course in 3rd sem PS, PED, and CS)
Credits-4
Duration of Exam- Three hours
During Semester Evaluation Weightage- 40%
End Semester Examination Weightage- 60%
Introduction to Cryptography and information Security
Mathematical Foundation
Introduction to groups, rings and fields, structures of finite fields, groups constructed over points on
an elliptic curve. Congruences and residue classes, quadratic residues and square roots modulo
integer. Theory of computational complexity, fundamentals of probability theory, birthday paradox.
Basic Cryptographic techniques – Classical techniques, Symmetric techniques (AES & DES),
Asymmetric techniques – Discrete log problem, Deffie Hellman Key exchange, RSA algorithm,
ElGamal systems, Elliptic curve arithmetic and Cryptography.
Message authentications, Cryptographic Hash Functions, Hash algorithms, MD5 message digest
algorithm, Digital Signatures and authentication protocols.
References:1. W. Stallings, “Cryptography and Network Security”, Pearson Education., New Delhi, 2003.
2. W. Mao, “Modern Cryptography: Theory and practice”, Pearson Education., New Delhi,
2004.
MASTER OF TECHNOLOGY (ELECTRICAL ENGINEERING)
POWER ELECTRONICS & DRIVES SPECIALIZATION
W.E.F. 2006-07
Course No. E-533
Modeling & Analysis of Electric Machines
(A core course in 1st sem PED and an elective course in 3rd sem PS)
L T P Total
4 0 0 4
Credits-4
Duration of Exam- Three hours
During Semester Evaluation Weightage- 40%
End Semester Examination Weightage- 60%
Introduction to the modeling of electrical machines. Reference Frame Theory. Modeling
and Analysis of Induction and Synchronous Machines; Computer Simulations of Induction and
Synchronous machines: Speed and Torque Control in Induction and Synchronous motors. .
References:
1.
2.
3.
4.
5.
“Analysis of Electric Machinery and Drives Systems”, Krause, Paul C.
“Electric Machinery”, Fitzgerald, A.E.
“Dynamic Simulation of Electric Machinery”, Ong, C.M.
“The General Theory of Electrical Machines”, Adkins.
“Generalized Theory of Electrical Machines”, Bimbhra, P.S.
MASTER OF TECHNOLOGY (ELECTRICAL ENGINEERING)
CONTROL SYSTEMS SPECIALIZATION
W.E.F. 2006-07
Course No. E-561
Microprocessors & Digital Signal Processors
(A core course in 1st sem CS, and an elective course in 1st sem PS and 1st sem PED)
L T P Total
4 0 0 4
Credits-4
Duration of Exam- Three hours
During Semester Evaluation Weightage- 40%
End Semester Examination Weightage- 60%
Architecture of 8086 microprocessor, Development of 8086 processors, interrupt structure.
Addressing modes, Instruction set and application programs, Main Assembler Directives,
Interfacing D/A and A/D converters using programmable I/O devices.
Introduction to microcontrollers, Architecture of 8051 microcontroller, basic Instruction set,
programming, serial data communication, interfacing with D/A and A/D converters.
Introduction to Digital Signal Processors, Architectures of TMS-320 series, Instruction Set,
Programming and Interfacing.
Application of Microprocessors, Microcontrollers and Digital Signal Processing in Power and
Control Systems.
References:
1.
Gibson, “Microprocessors”, Prentice Hall of India.
2.
3.
K.J. Ayala, “Micro Controller”, Penram International.
Reference Manual of TMS-320 Digital Signal Processor.