35 mepco schlenk engineering college, sivakasi
TRANSCRIPT
35
MEPCO SCHLENK ENGINEERING COLLEGE, SIVAKASI
(AUTONOMOUS)
AFFILIATED TO ANNA UNIVERSITY, CHENNAI 600 025
REGULATIONS:MEPCO - R2013 (FULL TIME)
M.E. POWER ELECTRONICS AND DRIVES
Department Vision
To Render Services to Meet the Growing
Global Challenges of Engineering Industries
by Educating Students to become Exemplary
Professional Electrical and Electronics
Engineers of High Ethics
Department Mission
To Provide the Students a Rigorous Learning Experience in Understanding
Basics of Electrical & Electronics Engineering Built on the Foundation of
Science, Mathematics, Computing, and Technology by Emphasizing
Active Learning with Strongly Supported Laboratory Component
and Prepare them for Professional Careers
Programme Educational Objectives (PEOs)
I. Preparation: To prepare students to excel in Industry by Educating
Students along with High moral values and Knowledge.
II. Core Competence: To provide students with the fundamentals of
Electrical Engineering Sciences with more emphasis in Power
Electronics and Drives by way of analyzing and exploiting
engineering challenges in disparate systems during their professional
career.
36
III.Breadth: To train students with good engineering breadth so as to
comprehend, analyze, design, and create novel products and
solutions for the real life problems.
IV. Professionalism: To inculcate professional and ethical attitude,
effective communication skills, teamwork skills, multidisciplinary
approach, entrepreneurial thinking and an ability to relate
engineering issues to broader social context in students.
V. Learning environment: To provide students with an academic
environment aware of excellence, leadership, written ethical codes
and guidelines, and the self motivated life-long learning needed for a
successful professional career.
PG Programme Outcomes (POs)
1. Graduates will demonstrate knowledge of mathematics, engineering fundamentals and an engineering specialization to the conceptualization of engineering models.
2. Graduates will exhibit an ability to identify, formulate, research literature and solve engineering problems.
3. Graduate will reveal an ability to design Power Electronic circuits and conduct experiments with Power Electronics and Drive systems with an ability to analyze and interpret the data.
4. Graduate will demonstrate an ability to visualize and work on laboratory and multidisciplinary tasks.
5. Graduate will demonstrate skills to use modern engineering tools, software and equipment to analyze problems.
6. Graduate will exhibit knowledge of professional and ethical responsibilities.
7. Graduate will be able to communicate effectively in both verbal and written form.
8. Graduate will show the understanding of impact of engineering solutions on the society and also will be aware of contemporary issues.
9. Graduate will develop confidence for self education and ability for life-long learning.
10. Graduates can participate and succeed in competitive examinations.
37
CURRICULUM (I TO IV SEMESTER)
I SEMESTER
SL. NO.
COURSE CODE
COURSE TITLE L T P C
THEORY
1. 13MA172 Applied Mathematics for Electrical Engineers
3 1 0 4
2. 13PE101 Advanced Power Semiconductor Devices
3 0 0 3
3. 13PE102 Analysis of Power Converters 3 0 0 3
4. 13PE103 Analysis of Inverters 3 0 0 3
5. 13PE104 Analysis of Electrical Machines 3 0 0 3
6. Elective I 3 0 0 3
PRACTICAL
7. 13PE151 Power Electronics Laboratory 0 0 4 2
TOTAL 18 1 4 21
II SEMESTER
SL. NO.
COURSE CODE
COURSE TITLE L T P C
THEORY
1. 13PE201 Solid State DC Drives 3 1 0 4
2. 13PE202 Solid State AC Drives 3 1 0 4
3. 13PE203 Special Electrical Machines 3 0 0 3
4. 13PE204 Power Quality 3 0 0 3
5. Elective II 3 0 0 3
6. Elective III 3 0 0 3
PRACTICAL
7. 13PE251 Solid State Drives and Controls Laboratory
0 0 4 2
8. 13PE252 Technical Seminar * 0 0 2 1
TOTAL 18 2 6 23
* Internal Assessment only
38
III SEMESTER
SL.
NO.
COURSE CODE
COURSE TITLE L T P C
THEORY
1. 13PE301 Power Electronics for Renewable Energy Systems
3 0 0 3
2. Elective IV 3 0 0 3
3. Elective V 3 0 0 3
PRACTICAL
4. 13PE351 Project work (Phase I) 0 0 12 6
TOTAL 9 0 12 15
IV SEMESTER
SL.
NO.
COURSE CODE
COURSE TITLE L T P C
1. 13PE451 Project work (Phase II) 0 0 24 12
TOTAL 0 0 24 12
Total No. of Credits = 71
ELECTIVE COURSES
SL.
NO.
COURSE CODE
COURSE TITLE L T P C
1. 13PE401 Systems Theory 3 0 0 3
2. 13PE402 Application of MEMS Technology 3 0 0 3
3. 13PE403 Electromagnetic field computation and modelling
3 0 0 3
4. 13PE404 Advanced Digital Signal Processing
3 0 0 3
5. 13PE405 Micro Controller Based System Design
3 0 0 3
6. 13PE406 Flexible AC Transmission Systems
3 0 0 3
39
7. 13PE407 Energy Management and Auditing
3 0 0 3
8. 13PE408 Wind Energy Conversion Systems
3 0 0 3
9. 13PE409 Design of Controllers 3 0 0 3
10. 13PE410 High Voltage Direct Current Transmission
3 0 0 3
11. 13PE411 VLSI Architecture and Design Methodologies
3 0 0 3
12. 13PE412 Solar and Energy Storage Systems
3 0 0 3
13. 13PE413 Non- Linear Dynamics for Power Electronics Circuits
3 0 0 3
14. 13PE414 Smart Grid 3 0 0 3
15. 13PE415 Soft Computing Techniques 3 0 0 3
REGULATIONS – MEPCO – R2013 (PART TIME)
M.E POWER ELECTRONICS AND DRIVES
CURRICULUM (I TO VI SEMESTER)
I SEMESTER
SL. NO.
COURSE CODE
COURSE TITLE L T P C
THEORY
1. 13MA172 Applied Mathematics for Electrical Engineers
3 1 0 4
2. 13PE101 Advanced Power Semiconductor Devices
3 0 0 3
3. Elective I 3 0 0 3
PRACTICAL
TOTAL 9 1 0 10
40
II SEMESTER
SL. NO.
COURSE CODE
COURSE TITLE L T P C
THEORY
1. 13PE201 Solid State DC Drives 3 1 0 4
2. 13PE202 Solid State AC Drives 3 1 0 4
3. Elective II 3 0 0 3
PRACTICAL
4. 13PE252 Technical Seminar * 0 0 2 1
TOTAL 9 2 2 12
* Internal Assessment only
III SEMESTER
SL. NO.
COURSE CODE
COURSE TITLE L T P C
THEORY
1. 13PE102 Analysis of Power Converters 3 0 0 3
2. 13PE103 Analysis of Inverters 3 0 0 3
3. 13PE104 Analysis of Electrical Machines 3 0 0 3
PRACTICAL
4. 13PE151 Power Electronics Laboratory 0 0 3 2
TOTAL 9 0 3 11
IV SEMESTER
SL. NO.
COURSE CODE
COURSE TITLE L T P C
THEORY
1. 13PE203 Special Electrical Machines 3 0 0 3
2. 13PE204 Power Quality 3 0 0 3
3. Elective III 3 0 0 3
PRACTICAL
4. 13PE251 Solid State Drives and Controls Laboratory
0 0 3 2
TOTAL 9 0 3 11
41
V SEMESTER
SL. NO.
COURSE CODE
COURSE TITLE L T P C
THEORY
1. 13PE301 Power Electronics for Renewable Energy Systems
3 0 0 3
2. Elective IV 3 0 0 3
3. Elective V 3 0 0 3
PRACTICAL
4. 13PE351 Project work (Phase I) 0 0 12 6
TOTAL 9 0 12 15
VI SEMESTER
SL. NO.
COURSE CODE
COURSE TITLE L T P C
1. 13PE451 Project work (Phase II) 0 0 24 12
TOTAL 0 0 24 12
Total No. of
Credits : 71
ELECTIVE COURSES
SL. NO.
COURSE CODE
COURSE TITLE L T P C
1. 13PE401 Systems Theory 3 0 0 3
2. 13PE402 Application of MEMS Technology 3 0 0 3
3. 13PE403 Electromagnetic field computation and modelling
3 0 0 3
4. 13PE404 Advanced Digital Signal Processing
3 0 0 3
5. 13PE405 Micro Controller Based System Design
3 0 0 3
6. 13PE406 Flexible AC Transmission Systems
3 0 0 3
7. 13PE407 Energy Management and Auditing 3 0 0 3
8. 13PE408 Wind Energy Conversion Systems 3 0 0 3
9. 13PE409 Design of Controllers 3 0 0 3
42
10. 13PE410 High Voltage Direct Current Transmission
3 0 0 3
11. 13PE411 VLSI Architecture and Design Methodologies
3 0 0 3
12. 13PE412 Solar and Energy Storage Systems
3 0 0 3
13. 13PE413 Non- Linear Dynamics for Power Electronics Circuits
3 0 0 3
14. 13PE414 Smart Grid 3 0 0 3
15. 13PE415 Soft Computing Techniques 3 0 0 3
Syllabus
I SEMESTER
13MA172: APPLIED MATHEMATICS FOR
ELECTRICAL ENGINEERS
L T P C
3 1 0 4
Course Objectives:
To know the concept of Linear Algebra.
To provide the methods for solving system of equations.
To decompose the matrices into required form and its uses.
To familiarize the probability concepts and distributions.
To have a knowledge in linear programming.
Course Outcomes:
Upon completion of the course the student will be able
To expertise in Linear Algebra.
To obtain the solutions for system of simultaneous equations and
uses of diagonalisation of matrix applicable to electrical
engineering.
To familiar in decomposition of matrices.
To apply the probability concepts and distributions in engineering
application.
To expertise in linear programming.
43
UNITI LINEAR ALGEBRA 9+3
Vector space - Linear independence – Basis – Norm of a vector -
Orthogonalization – Gram-Schmidt Orthogonalization Process - Linear
transformation – Representation of Linear transformation by matrix –
Sum, composite and scalar multiple of Linear transformation - Change of
basis in an n dimensional space - orthogonal and unitary transformation
- Matrix Norms.
UNITII SIMILARITY TRANSFORMATION 9+3
Range space, Rank, Null space and Nullity of a matrix - Solution of
Linear Algebraic equations - Homogeneous equations - Non
homogeneous equations - consistent and inconsistent equations - eigen
values, eigen vectors and canonical form representation of linear
operators - Matrix representation of a linear operator in Jordan form &
Diagonal form.
UNITIII ADVANCED MATRIX THEORY 9+3
Eigen values using QR transformations – Generalized eigen vectors –
Canonical forms – Singular value decomposition and applications –
Pseudo inverse – Least square approximations
UNITIV ONE DIMENSIONAL RANDOM VARIABLES 9+3
Random variables - Probability function – moments – moment
generating functions and their properties – Binomial, Poisson,
Geometric, Uniform, Exponential, Gamma and Normal distributions –
Function of a Random Variable.
UNITV LINEAR PROGRAMMING 9+3
Formulation – Graphical solution – Simplex method – Two phase
method –Transportation and Assignment Problems.
TOTAL: 45 PERIODS
44
REFERENCE BOOKS:
1. Bronson, R., “Matrix Operation, Schaum’s outline series”, McGraw
Hill, New York, Second Edition, 2011.
2. Data, K.B, “Matrix and Linear Algebra”, Prentice Hall of India, New
Delhi, Second Edition, 2007.
3. Hoffman, Kenneth & Kunze, Ray, “Linear Algebra”, Prentice Hall of
India, New Delhi, 2009.
4. Walpole R. E., Myers R. H., Myers S. L., and Ye K., “Probability
and Statistics for Engineers & Scientists”, Asia, Eigth Edition,
2007.
5. Taha, H. A., “Operations Research: An Introduction”, Seventh
Edition, Pearson Education, Asia Edition, New Delhi, 2002.
13PE101 : ADVANCED POWER
SEMICONDUCTOR DEVICES
L T P C
3 0 0 3
Course Objectives:
To impart the knowledge of basics of power semiconductor
devices and its characteristics.
To study basic principle and operation of thyristors.
To study basic principle and operation of current controlled
transistors and voltage controlled devices.
To study basic principle and operation of firing and protecting
circuits.
Course Outcomes:
Upon completion of the course, students will be able to
know the basics of power semiconductor devices and its
characteristics.
know basic principle and operation of thyristors.
know basic principle and operation of current controlled transistors
45
and voltage controlled devices.
know basic principle and operation of firing and protection circuits.
UNIT I INTRODUCTION 9
Power switching devices overview – Attributes of an ideal switch,
application requirements, circuit symbols; Power handling capability –
SOA; Device selection strategy – On-state and switching losses – EMI
due to switching - Power diodes - Types, forward and reverse
characteristics, switching characteristics – rating.
UNIT II THYRISTORS 9
Thyristors – Physical and electrical principle underlying operating mode,
Two transistor analogy – concept of latching- Gate and switching
characteristics- commutation of thyristors - converter grade and inverter
grade; series and parallel operation- Models of Thyristors
UNIT III CURRENT CONTROLLED TRANSISTORS 9
Power BJT’s – Construction, static characteristics, switching
characteristics; Negative temperature co-efficient and secondary
breakdown; Power Darlington - comparison of BJT and Thyristor –
steady state and dynamic models of BJT.
UNIT IV VOLTAGE CONTROLLED DEVICES 9
Power MOSFETs and IGBTs – Principle of voltage controlled devices,
construction, types, static and switching characteristics, steady state
and dynamic models of MOSFET and IGBTs - Basics of GTO, MCT,
RCT and IGCT.
UNIT V FIRING AND PROTECTING CIRCUITS 9
Necessity of isolation, pulse transformer, opto-coupler – Gate drives
circuit: SCR – R, RC, UJT, MOSFET, IGBTs and base driving for power
BJT. - Over voltage, over current and gate protections; Design of
snubbers.
Heat transfer – conduction, convection and radiation, Electrical analogy
46
of thermal components- Thermal resistance and impedance, Guidance
for heat sink selection –Mounting types.
TOTAL: 45 PERIODS
REFERENCE BOOKS:
1. W Williams “Power Electronics Circuit Devices and Applications”,
McGraw-Hill, 1992.
2. Rashid M.H., “Power Electronics Circuits, Devices and Applications ",
Prentice Hall of India, Third Edition, New Delhi, 2004.
3. MD Singh and K.B Khanchandani, “Power Electronics”, Tata McGraw
Hill, 2001.
4. NedMohan, Undeland and Riobbins, “Power Electronics – Concepts,
applications and Design”, John Wiley and Sons, Singapore, 2000.
5. Philip T. krein, “Elements of Power Electronics”, Oxford University
Press -2004.
6. M.S.Jamil Asghar, “Power Electronics”, Prentice Hall of India private
Ltd -2004.
7. Vedam Subramaniyam, “Power Electronics – Devices, Converters
and Applications ", New Age international private Ltd., 2nd Edition,
2006.
13PE102 : ANALYSIS OF POWER
CONVERTERS
L T P C
3 0 0 3
Course Objectives:
To impart knowledge on steady state operation of single and three
phase AC-DC converters.
To study and analyze the operation of various DC-DC converters.
To study and analyze the operation of AC voltage controllers.
To study and analyze the operation of cycloconverters.
Course Outcomes:
Upon completion of the course, students will be able to
47
Know the basic concept of steady state operation of single and
three phase AC-DC converters.
Analyze the operation of various DC-DC converters.
Analyze the operation of AC voltage controllers.
Analyze the operation of cycloconverter.
UNIT I SINGLE PHASE AC-DC CONVERTER 9
Half wave, Semi and fully controlled converters with R, R-L, R-L-E loads
and freewheeling diodes and related problems. – Continuous and
discontinuous modes of operation - inversion operation – Sequence
control of converters – performance parameters: harmonics, ripple,
distortion, power factor– effect of source impedance and over lap – Dual
converter.
UNIT II THREE PHASE AC-DC CONVERTER 9
Half wave, Semi and fully controlled converter with R, R-L, R-L-E loads
and freewheeling diodes – inversion operation – performance
parameters – effect of source impedance and over lap – Dual converter.
UNIT III DC-DC CONVERTERS 9
Principles of step-down and step-up converters – classification of
chopper configuration –control strategy: time ratio and current limit
control -Analysis of buck, boost, buck-boost and Cuk regulators–
Resonant converters – ZCS and ZVS converters.
UNIT IV AC VOLTAGE CONTROLLERS 9
Principle of on-off and phase control - single phase half and full wave
and three phase AC voltage controllers – various configurations –
analysis with R and R-L loads – sequence control – two stage and multi
stage.
UNIT V CYCLOCONVERTERS 9
Principle of operation – single phase step-down and step-up
cycloconverters – output voltage equation-three phase half-wave
cycloconverters – three phase to single and three phase to three phase
48
converters – Matrix converters.
TOTAL: 45 PERIODS
REFERENCE BOOKS:
1. Ned Mohan, Undeland and Riobbins, “Power Electronics: converters,
Application and design”, John Wiley and sons.Inc, Newyork, 1995.
2. Rashid M.H., “Power Electronics Circuits, Devices and Applications ",
Prentice Hall of India, New Delhi, 1995.
3. Cyril W.Lander, “power electronics”, Third Edition McGraw hill-1993
4. P.C Sen.," Modern Power Electronics ", Wheeler publishing Co, First
Edition, New Delhi-1998.
5. P.S.Bimbra, “Power Electronics”, Khanna Publishers, Eleventh
Edition, 2003.
6. Bimal K Bose, “Modern Power Electronics and AC Drives”, Pearson
Education Asia 2002.
7. R W Erickson and D Maksimovic,”Fundamentals of Power
Electronics”, Springer, 2nd Edition.
8. Philip T.Krein, “Elements of Power Electronics” Oxford University
Press, 2004 Edition.
9. M.D. Singh and K.B Khanchandani, “Power Electronics”, Tata
McGraw Hill, 2001.
10. Vedam Subramanyam “Power Electronics”, by, New Age
International publishers, New Delhi 2nd Edition, 2006.
13PE103 : ANALYSIS OF INVERTERS L T P C
3 0 0 3
Course Objectives:
To impart the knowledge on basic operation of single phase
inverters
To understand the basic operation of three phase inverters.
To analyze the operation of CSI inverter.
To analyze the operation of multilevel inverter.
To analyze the operation of resonant inverter.
49
Course Outcomes:
Upon completion of the course, students will be able to
suggest the application of single phase inverters
demonstrate the operation of three phase inverters.
analyze the operation of CSI inverter.
evaluate the performance of multilevel inverter.
design and analyze the resonant inverter.
UNIT I SINGLE PHASE INVERTERS 9
Principle of operation of half and full bridge inverters – Performance
parameters – Voltage control of single phase inverters using various
PWM techniques – various harmonic elimination techniques.
UNIT II THREE PHASE VOLTAGE SOURCE
INVERTERS
9
180 degree and 120 degree conduction mode inverters with star and
delta connected loads – voltage control of three phase inverters: single,
multi pulse, sinusoidal, space vector modulation techniques.
UNIT III CURRENT SOURCE INVERTERS 9
Single phase CSI - load commutated inverters – Auto sequential current
source inverter (ASCI) - Operation of six-step thyristors inverter –
inverter operation modes – comparison of current source inverter and
voltage source inverters
UNIT IV MULTILEVEL INVERTERS 9
Multilevel concept – diode clamped – flying capacitor – cascade type
multilevel inverters - Comparison of multilevel inverters - application of
multilevel inverters
UNIT V RESONANT INVERTERS 9
Series and parallel resonant inverters - voltage control of resonant
inverters – Class E resonant inverter – resonant DC – link inverters.
TOTAL: 45 PERIODS
50
REFERENCE BOOKS:
1. Rashid M.H., “Power Electronics Circuits, Devices and Applications ",
Prentice Hall of India, 3rd Edition, New Delhi, 2004.
2. Jai P.Agarwal, “Power Electronics Systems”, Pearson Education,
Second Edition, 2002.
3. Bimal K.Bose “Modern Power Electronics and AC Drives”, Pearson
Education, Second Edition, 2003.
4. Ned Mohan,Undeland and Riobbins, “Power Electronics: converters,
Application and design”, John Wiley and sons.Inc,Newyork,1995.
5. Philip T. Krein, “Elements of Power Electronics” Oxford University
Press -2004.
6. P.C. Sen, “Modern Power Electronics”, Wheeler Publishing Co, First
Edition, New Delhi, 1998.
7. P.S.Bimbra, “Power Electronics”, Khanna Publishers, 11th Edition,
2003.
8. R W Erickson and D Makgimovic,”Fundamentals of Power
Electronics” Springer, 2nd Edition.
9. M.D. Singh and K.B Khanchandani, “Power Electronics”, Tata
McGraw Hill, 2001.
13PE104 : ANALYSIS OF ELECTRICAL
MACHINES
L T P C
3 0 0 3
Course Objectives:
To provide knowledge about the fundamentals of magnetic circuits,
energy, force and torque of multi-excited systems.
To analyze the steady state and dynamic state operation of DC
machine through mathematical modeling and simulation in digital
computer.
To provide knowledge on transformation of three phase variables to
two phase variables.
To analyze the steady state and dynamic state operation of three-
phase induction machines & synchronous machines using
51
transformation theory based mathematical modeling and digital
computer simulation.
Course Outcomes:
Upon completion of the course, students will be able to
design simple magnetic circuits by calculating energy, force and
torque for single and multi-excited systems.
Analyze the steady state and dynamic state operation of DC
machine through mathematical modeling
Analyze the theory of transformation of three phase variables to two
phase variables.
Analyze the steady state and dynamic state operation of three-phase
induction machines and synchronous machines.
UNIT I PRINCIPLES OF ELECTROMAGNETIC ENERGY
CONVERSION
9
Magnetic circuits-Principles of Electromagnetic Energy Conversion,
General expression of stored magnetic energy, co-energy and
force/torque, example using single and doubly excited system.
UNIT II DC MACHINES 9
Elementary DC machine and analysis of steady state operation - Voltage
and torque equations – dynamic characteristics of permanent magnet
and shunt d.c. motors – Time domain block diagrams - solution of
dynamic characteristic by Laplace transformation - computer simulation.
UNIT III REFERENCE FRAME THEORY 9
Static and rotating reference frames – transformation of variables –
reference frames –transformation between reference frames –
transformation of a balanced set –balanced steady state phasor and
voltage equations – variables observed from several frames of
reference.
52
UNIT IV INDUCTION MACHINES 9
Dynamic model of two phase induction machine, Transformation from
Three phase to two phase and vice versa – power equivalence – steady
state equivalent circuit- generalized model in arbitrary reference frame-
Induction motor models–voltage and torque equations in machine
variables and arbitrary reference frame variables – analysis of steady
state operation – free acceleration characteristics - analysis of dynamic
performance for load torque variations –computer simulation.
UNIT V SYNCHRONOUS MACHINES 9
Three phase synchronous machine - voltage and torque equations in
machine variables and rotor reference frame variables (Park’s
equations) – analysis of steady state operation -analysis of dynamic
performance for load torque variations –computer simulation.
TOTAL: 45 PERIODS
REFERENCE BOOKS:
1. A.E, Fitzgerald, Charles Kingsley, Jr, and Stephan D, Umanx,
“Electric Machinery”, Tata McGraw Hill, 5th Edition, 1992
2. D.P.Kothari, I.J.Nagrath,” Electrical Machines”, Tata McGraw-Hill
Education, 2004.
3. P S Bimbhra, “Generalized Theory of Electrical Machines”, Khanna
Publishers, 2008.
4. Paul C.Krause, Oleg Wasyzczuk, Scott S, Sudhoff, “Analysis of
Electric Machinery and Drive Systems”, John Wiley, Second Edition,
2010.
5. R. Krishnan, “Electric Motor & Drives: Modeling, Analysis and
Control”, Prentice Hall of India Pvt. Ltd., New Delhi, 2003.
6. Naser A and Boldea L, “Linear Electric Motors: Theory Design and
Practical Applications”, Prentice Hall Inc., New Jersy 1987.
53
13PE151 : POWER ELECTRONICS
LABORATORY
L T P C
0 0 4 2
Course Objectives:
To impart the knowledge of single phase and three phase AC-DC
converters.
To simulate the various DC-DC converters.
To simulate the various inverter circuits.
To simulate the ac voltage controllers and cycloconverters.
To design and simulate UPS and SMPS
Course Outcomes:
Upon completion of the course, students will be able to
Design, simulate and analyze various controlled rectifiers.
Design, simulate and analyze various DC-DC converters.
Design, simulate and analyze the single phase and three phase
inverters.
Design, simulate and analyze the ac voltage controllers and
cycloconverters.
Design and simulate the UPS and SMPS.
Sl.
No. List of Experiments
1. Simulation of Single phase Semi converter
2. Simulation of Single phase Fully controlled converter
3. Simulation of Single phase PWM inverter
4. Simulation of Three phase bridge inverter.
5. Simulation of Three phase semi converter
54
6. Simulation of Three phase fully controlled converter
7. Simulation of D.C-D.C Converters
8. Simulation of Resonant Converters
9. Simulation of single phase AC Voltage Controller and Cyclo
converter.
10. Simulation of Basic Multilevel Inverter.
11. Design and Simulation of UPS
12. Design and Simulation of SMPS
II SEMESTER
13PE201 : SOLID STATE DC DRIVES L T P C
3 1 0 4
Course Objectives:
To impart knowledge on operation and analysis of DC Motors.
To analyze the operation controlled rectifier fed DC Drives.
To analyze the operation Chopper fed DC Drives.
To understand the current and speed controllers for a closed loop
solid state DC motor drives.
Course Outcomes:
Upon completion of the course, students will be able to
Know the basic concept of steady state operation and transient
dynamics of a motor load system
Design and Analyze the operation of the various controlled rectifier
fed DC drive.
Design and Analyze the operation of the various chopper fed DC
55
drive
Analyze and Design the current and speed controllers for a closed
loop solid state DC motor drives.
UNIT I DC MOTORS FUNDAMENTALS AND
MECHANICAL SYSTEMS
12
DC motor- Types, induced emf, speed-torque relations; Speed control –
Armature and field control- Ward Leonard control – Braking methods-
Constant torque and constant horse power operation.
Characteristics of mechanical system – dynamic equations, components
of torque, types of load- Requirements of drives characteristics - stability
of drives – multi-quadrant operation- Drive elements, types of motor duty
and selection of motor rating.
UNIT II CONVERTER FED DC DRIVES 12
Principle of phase control – Fundamental relations- Analysis of series
and separately excited DC motor with single-phase and three-phase
converters – waveforms, performance parameters, performance
characteristics.
Continuous and discontinuous mode, Current ripple and its effect on
performance- Operation with freewheeling diode, Dual converter fed DC
drives-related problems.
UNIT III CHOPPER FED DC DRIVES 12
Introduction about chopper, control strategy, Class A, B, C, D and E
chopper controlled DC motor drive – performance analysis, Chopper
based implementation of braking methods, Multi-phase chopper; Related
problems.
UNIT IV CLOSED LOOP CONTROL 12
Modeling of drive elements – Equivalent circuit, transfer function of
separately excited DC motors, model of power converters- Sensing and
feedback elements. Closed loop control of armature and field control-
56
PLL and microcomputer control of dc drives.
UNIT V DESIGN OF CLOSED LOOP CONTROL 12
Closed loop speed control – current and speed loops, P, PI and PID
controllers – response comparison. Case study of converter and chopper
fed dc drive.
TOTAL: 60 PERIODS
REFERENCE BOOKS:
1. Gopal K Dubey, “Power Semiconductor controlled Drives”, Prentice
Hall Inc., New Jersy, 1989.
2. R.Krishnan, “Electric Motor Drives – Modeling, Analysis and Control”,
Prentice-Hall of India Pvt. Ltd., New Delhi, 2010.
3. Gobal K.Dubey, “Fundamentals of Electrical Drives”, Narosa
Publishing House, New Delhi, Second Edition ,2009
4. Vedam Subramanyam, “Electric Drives – Concepts and Applications”,
Tata McGraw Hill, Second Edition ,2010
5. P.C Sen “Thyristor DC Drives”, John wiley and sons, New York, 1981.
6. Buxbaum, A.Schierau, K.and Staughen, "A Design of control System
for d.c Drives ", Springer-Verlag, berlin, 1990.
13PE202:SOLID STATE AC DRIVES L T P C
3 1 0 4
Course Objectives:
To impart knowledge on operation and analysis of three phase
Induction Motors and Synchronous Motors.
To analyze the operation of AC Voltage controller fed AC Drives.
To analyze the operation VSI and CSI fed AC Drives.
To understand operation of the speed control of induction motor drive
from the rotor side.
57
To understand the field oriented control of induction machine.
To understand the operation of synchronous motor drives.
Course Outcomes:
Upon completion of the course, students will be able to
Know the concept of various operating regions of the induction motor
drives
Design and Analyze the operation of AC voltage controller fed
induction motor drives.
Design and Analyze the operation of VSI & CSI fed induction motor
control.
Design and Analyze the operation of the speed control of induction
motor drive from the rotor side.
Understand the field oriented control of induction machine.
Design and Analyze the operation of synchronous motor drives.
UNIT I STATOR VOLTAGE CONTROLLED INDUCTION
MOTORS
12
Introduction - Rotating magnetic field – torque production, Equivalent
circuit– Steady state performance equations, Variable voltage constant
frequency operation - Conventional method - Variable voltage
characteristics –- Control of Induction Motor by AC Voltage Controllers -
Waveforms - speed torque characteristics - Four quadrant operation –
Closed loop speed control - different braking methods – Related
Problems.
UNIT II STATOR FREQUENCY CONTROLLED
INDUCTION MOTORS
12
Constant voltage variable frequency operation - constant Volt/Hz
operation - speed torque characteristics, Analysis -Drive operating
regions, variable stator current operation and analysis, six step inverter
voltage and frequency control - PWM inverter fed induction motor drives
58
- CSI fed IM variable frequency drives -comparison - Closed loop speed
control - Related Problems.
UNIT III ROTOR CONTROLLED INDUCTION MOTOR
DRIVES
12
Review of rotor resistance control – Static rotor resistance control –
Performance Analysis, speed torque characteristics –Slip Power
Recovery scheme - Conventional method, Static Kramer drives , static
Scherbius drives , Analysis – modified Kramer drives - Related
Problems.
UNIT IV FIELD ORIENTED CONTROL 12
Field oriented control of induction machines – Theory – DC drive
analogy – Direct and Indirect methods – Flux vector estimation - Direct
torque control of Induction Machines – Torque expression with stator
and rotor fluxes, DTC control strategy.
UNIT V SYNCHRONOUS MOTOR DRIVES 12
Wound field cylindrical rotor motor – Equivalent circuits – performance
equations - Power factor control and V curves – starting and braking of
Synchronous motor drives – speed control of synchronous motors –
adjustable frequency operation of synchronous motors – principles of
synchronous motor control – voltage source inverter drive with open loop
control – self controlled and separate controlled synchronous motor –
self controlled synchronous motor drive using load commutated thyristor
inverter – Cycloconverter fed drive- Related Problems.
TOTAL: 60 PERIODS
REFERENCE BOOKS:
1. Bimal K Bose, “Modern Power Electronics and AC Drives”,
Prentice-Hall of India Pvt. Ltd., New Delhi, 2003.
2. Vedam Subramanyam, “Electric Drives – Concepts and
Applications”, Tata McGraw Hill, Second Edition ,2010
59
3. Gobal K.Dubey, “Fundamentals of Electrical Drives”, Narosa
Publishing House, New Delhi, Second Edition ,2009
4. Gopal K Dubey, “Power Semiconductor controlled Drives”,
Prentice Hall Inc., New Jersy, 1989.
5. R.Krishnan, “Electric Motor Drives – Modeling, Analysis and
Control”, Prentice-Hall of India Pvt. Ltd., New Delhi, 2003.
6. W.Leonhard, “Control of Electrical Drives”, Narosa Publishing
House, 1992.
7. Murphy J.M.D and Turnbull, “Thyristor Control of AC Motors”,
Pergamon Press, Oxford, 1988.
13PE203: SPECIAL ELECTRICAL MACHINES L T P C
3 0 0 3
Course Objectives:
To provide knowledge about the constructional features and
operating principles of various types of special electrical machines.
To compare and analyze the static and dynamic characteristics of
special electrical machines.
To provide knowledge about the different types of drive systems
and controllers used in special electrical machines.
Course Outcomes:
Upon completion of the course, students will be able to
know the construction and operating principles of special electrical
machines.
analyze the characteristics and performance of special electrical
machines.
analyze the different types of controllers and control techniques.
UNIT I STEPPING MOTORS 9
Constructional features - principle of operation - modes of excitation -
60
torque production in Variable Reluctance (VR) stepping motor –
Characteristics - Linear and Non Linear Analysis - Drive systems and
Control of stepping motor.
UNIT II SYNCHRONOUS RELUCTANCE MOTORS 9
Constructional features of axial and radial air gap Motors - operating
principle - reluctance torque – phasor diagram - motor characteristics
PERMANENT MAGNET SYNCHROUNOUS MOTORS
Principle of operation – EMF and Torque equations - Phasor diagram -
Power controllers – Torque speed characteristics – Self control, Vector
control, Microprocessor based control schemes.
UNIT III SWITCHED RELUTCANCE MOTORS 9
Constructional features-principle of operation-Inductance profile-Torque
equation- Types of Power controllers and converter topologies used –
Current control schemes – Torque Speed Characteristics – Hysteresis
and PWM -Microprocessor based controller and Sensorless Controller.
UNIT IV PERMANENT MAGNET BRUSHLESS DC
MOTORS
9
Commutation in DC motors, Difference between mechanical and
electronic commutators, Hall sensors, Optical sensors, Multiphase
Brushless motor, Square wave permanent magnet brushless motor
drives, Torque and Emf equation, Torque-Speed characteristics,
Controllers-Magnetic Circuit Analysis-Microprocessor based controller.
UNIT V LINEAR MOTORS 9
Linear Induction Motor (LIM) classification – construction – Principle of
operation – Concept of current sheet – goodness factor – DC Linear
Motor (DCLM) types – circuit equation - DCLM control applications –
Linear Synchronous Motor(LSM) – Types - Performance equations –
Applications.
TOTAL: 45 PERIODS
61
REFERENCE BOOKS:
1. Miller, T.J.E. “Brushless permanent magnet and reluctance motor
drives ", Clarendon Press, Oxford, 1989.
2. Kenjo, T, “Stepping motors and their microprocessor control ",
Clarendon Press, Oxford, 1989.
3. Naser A and Boldea L,”Linear Electric Motors: Theory Design and
Practical Applications”, Prentice Hall Inc., New Jersey 1987.
4. Kenjo, T and Naganori, S “Permanent Magnet and brushless DC
motors ", Clarendon Press, Oxford, 1989.
5. Kenjo, T. Power Electronics for the microprocessor Age, Oxford
University Press1994.
6. B.K. Bose, “Modern Power Electronics & AC drives”, Prentice-Hall of
India Pvt. Ltd., New Delhi, 2001.
7. R.Krishnan, “Electric Motor Drives – Modeling, Analysis and Control”,
Prentice-Hall of India Pvt. Ltd., New Delhi, 2003.
8. R.Krishnan, “Switched Reluctance Motor Drives: Modeling,
Simulation, Analysis, Design and Applications” CRC Press, 2001.
13PE204: POWER QUALITY L T P C
3 0 0 3
Course Objectives:
To impart knowledge on
The concept of the Power Quality Issues.
The concept of the Single phase linear and non linear loads
The concept of load compensation and voltage regulation using
DVR and analysis of classical load balancing problem.
The concept of instantaneous PQ theory and control of DSTATCOM
62
Course Outcomes:
Upon completion of the course, students will be able to
know the various power quality issues.
know the concept of power and power factor in single phase and
three phase systems supplying non linear loads.
know the conventional compensation techniques used for power
factor correction and load voltage regulation.
know the active compensation techniques used for power factor
correction and load voltage regulation.
UNIT I INTRODUCTION 9
Introduction – Characterisation of Electric Power Quality: Transients,
short duration and long duration voltage variations, Voltage imbalance,
waveform distortion, Voltage fluctuations, Power frequency variation,
Power acceptability curves – power quality problems: poor load power
factor, Non linear and unbalanced loads, DC offset in loads, Notching in
load voltage, Disturbance in supply voltage – Effect of harmonics in
power system equipments - Power quality standards.
UNIT II ANALYSIS OF LINEAR AND NON-LINEAR
SYSTEMS
9
Single phase static and rotating AC/DC converters, Three phase static
AC/DC converters, Battery chargers, Arc furnaces, Fluorescent lighting,
pulse modulated devices, Adjustable speed drives.
UNIT III CONVENTIONAL LOAD COMPENSATION
METHODS
9
Principle of load compensation and voltage regulation – classical load
balancing problem: open loop balancing – closed loop balancing, current
balancing – harmonic reduction and voltage sag reduction – analysis of
unbalance – instantaneous real and reactive powers – Extraction of
fundamental sequence component. Voltage Sag Lost Energy Index
(VSLEI)- Analysis of voltage flicker, Reduced duration and customer
impact of outages.
63
UNIT IV LOAD COMPENSATION USING DSTATCOM 9
Compensating single phase loads – Ideal three phase shunt
compensator structure – generating reference currents using
instantaneous PQ theory – Instantaneous symmetrical components
theory – Generating reference currents when the source is unbalanced
– Realization and control of DSTATCOM – DSTATCOM in Voltage
control mode.
UNIT V SERIES COMPENSATION AND POWER
DISTRIBUTION SYSTEM
9
Rectifier supported DVR – DC Capacitor supported DVR – DVR
Structure – voltage Restoration – Series Active Filter – Unified power
quality conditioner Utility-Customer interface –Harmonic filters: passive,
Active and hybrid filters –Custom power devices: Network reconfiguring
Devices, protecting sensitive loads using DVR, UPQC – control
strategies, Synchronous detection method – Custom power park –
Status of application of custom power devices.
TOTAL: 45 PERIODS
REFERENCE BOOKS:
1. Arindam Ghosh “Power Quality Enhancement Using Custom Power
Devices”, Springer International Edition, 2002
2. G.T.Heydt, “Electric Power Quality”, Stars in a Circle Publications, 2nd
edition 1994.
3. Roger.C.Dugan, Mark.F.McGranagham, Surya Santoso, H.Wayne
Beaty, “Electrical Power Systems Quality” McGraw Hill, 2004.
4. Jos Arrillaga, Neville R. Watson, “Power system harmonics”, 2nd
Edition, Wiley, 2003.
5. Derek A. Paice “Power electronic converter harmonics: Multipulse
Method for Clean Power” , Wiley-IEEE Press ,1999
64
13PE251 : SOLID STATE DRIVES AND
CONTROLS LABORATORY
L T P C
0 0 4 2
Course Objectives:
To impart knowledge on single phase and three phase AC-DC
converters fed dc drives.
To analyze the chopper fed dc motor drives.
To analyze the speed control of BLDC motor and SRM.
To analyze the inverter fed induction motor drives.
To make students to study and generate the gating signals using
microcontroller and FPGA
To make students to study and simulate the closed loop control of
converters fed dc drives.
Course Outcomes:
Upon completion of the course, students will be able to
Design and develop the controlled rectifier fed dc drives.
Design and analyze chopper fed dc drives
Design and analyze inverter fed induction motor drives.
Generate the gating pulses using micro controller and FPGA
Analyze the speed control of Stepper motor, BLDC motor and
SRM.
Design, simulate and analyze the closed loop control of converter
and chopper fed dc drives.
Sl.
No. List of Experiments
1. Single phase semi converter and full converter fed dc drive
2. Three phase semi converter and full converter fed dc drive
65
3. Chopper fed DC motor Drive
4. Single phase PWM inverters.
5. V/f control of three-phase induction motor.
6. Micro controller based speed control of Stepper motor.
7. Speed control of BLDC motor.
8. DSP based speed control of SRM motor.
9. Measurement of harmonics using power quality analyzer
10. Study of driver circuits and generation of PWM signals using
Microcontroller and FPGA.
11. DC-DC resonant converters.
12. Simulation of open and closed loop control of converter fed D.C.
motor drive
13. Simulation of open and closed loop control of chopper fed D.C.
motor drive
TOTAL: 45 PERIODS
13PE252 : TECHNICAL SEMINAR L T P C
0 0 2 1
Course Objectives:
To help students to acquire communication and presentational
skills and their application in social communication.
To enrich their knowledge on recent technical topics.
To create conditions for acquirement of other special skills
important for effective functioning of graduates in practice.
Course Outcomes:
Upon completion of the course, students will be able to
66
communicate their interest and present more effectively.
prepare quality and focused presentation.
learn skills essential for becoming successful student researchers,
such as strategies for negotiating the research process and critical
analysis of research papers.
face the placement interviews with confidence.
In this course, every student has to present at least two technical papers
on recent advancements in engineering/technology referring journal
papers and will be evaluated by the course instructor. During the
seminar session, each student is expected to present a topic, for
duration of about 18 to 20 minutes which will be followed by a discussion
for 5 minutes. Each student is responsible for selecting a suitable topic
that has not been presented previously. Every student is expected to
participate actively in the ensuing class discussion by asking questions
and providing constructive criticism.
III Semester
13PE301 : Power Electronics For Renewable
Energy Systems
L T P C
3 0 0 3
Course Objectives:
The objective of this course is to
Introduce the concept of standalone and grid connected renewable
energy systems.
Design different power converters namely AC to DC, DC to DC
and AC to AC converters for renewable energy systems.
Establish the concepts and recent developments in the field of
Hybrid Renewable Energy Systems.
Course Outcomes:
Upon completion of the course, students will be able to
67
Distinguish the stand alone and grid connected renewable energy
systems.
Design different power converters namely AC to DC, DC to DC
and AC to AC converters for renewable energy systems.
Explicate the recent developments in the field of Hybrid
Renewable Energy Systems.
UNIT I INTRODUCTION TO RENEWABLE ENERGY
SYSTEMS
9
Environmental aspects of electric energy conversion: impacts of
renewable energy generation on environment (cost-GHG Emission) -
Qualitative study of different renewable energy resources ocean,
Biomass, Hydrogen energy systems: operating principles and
characteristics of: Solar PV, Fuel cells, wind electrical systems-control
strategy, operating area.
UNIT II ELECTRICAL MACHINES FOR RENEWABLE
ENERGY CONVERSION
9
Review of reference theory fundamentals - principle of operation and
analysis: Induction Generator, Permanent Magnet Synchronous
Generator, Squirrel Cage Induction Generator and Doubly Fed Induction
Generator.
UNIT III POWER CONVERTERS 9
Solar: Block diagram of solar photo voltaic system: line commutated
converters (inversion-mode) - Boost and buck-boost converters-
selection of inverter, battery sizing, array sizing.
Wind: Three phase AC voltage controllers- AC-DC-AC converters:
uncontrolled rectifiers, PWM Inverters, Grid Interactive Inverters-matrix
converters.
UNIT IV ANALYSIS OF WIND AND PV SYSTEMS 9
Stand alone operation of fixed and variable speed wind energy
conversion systems and solar system-Grid connection Issues -Grid
68
integrated PMSG and SCIG Based WECS-Grid Integrated solar system
UNIT V Hybrid Renewable Energy Systems 9
Need for Hybrid Systems- Range and type of Hybrid systems- Case
studies of Diesel-PV, Wind-PV, Microhydel-PV, Biomass-Diesel
systems - Maximum Power Point Tracking (MPPT).
TOTAL: 45 PERIODS
REFERENCE BOOKS:
1. S.N.Bhadra, D. Kastha, & S. Banerjee “Wind Electrical Systems”,
Oxford University Press, 2009
2. Rashid .M. H “power electronics Hand book”, Academic press, 2001.
3. Rai. G.D, “Non conventional energy sources”, Khanna publishes,
1993.
4. Rai. G.D,” Solar energy utilization”, Khanna publishes, 1993.
5. Gray, L. Johnson, “Wind energy system”, prentice hall of India, 1995.
6. B.H.Khan “Non-conventional Energy sources”, Tata McGraw-hill
Publishing Company, New Delhi.
Electives
13PE401 : SYSTEMS THEORY L T P C
3 0 0 3
Course objectives:
The objective of the course is to
Introduce the mathematical modelling of physical systems for
analysis.
analyse the system based on controllability and observability
methods.
Introduce design techniques for effective control.
provide concept for analysing the stability of a system
Course Outcomes:
Upon completion of the course, students will be able to
Model the physical systems into mathematical model for easier
69
analysis.
Analyse the system controllability and observability.
Design and develop modal control technique for systems
Analyse the systems stability using Lyapunov’s theory.
UNIT I MODELLING AND STATE VARIABLE
FORMULATION - SISO AND MIMO SYSTEMS
9
Mathematical Modeling: electrical and electromechanical system - State
variable formulation of SISO and MIMO Systems - Concept of State-
State equation for Dynamic Systems - Time invariance and linearity -
Nonuniqueness of state model-State Diagrams.
UNIT II SOLUTION OF STATE EQUATION 9
Existence and uniqueness of solutions to Continuous-time state
equations - Solution of Nonlinear and Linear Time Varying State
equations - Evaluation of matrix exponential - System modes - Role of
Eigen values and Eigen vectors.
UNIT III CONTROLLABILITY AND OBSERVABILITY 9
Controllability and Observability- Stabilizability and Detectability-Test for
Continuous time Systems- Time varying and Time invariant case-Output
Controllability-Reducibility- System Realizations.
UNIT IV MODAL CONTROL 9
Introduction-Controllable and Observable Companion Forms-SISO and
MIMO Systems- The Effect of State Feedback on Controllability and
Observability- Pole Placement Design by State Feedback for SISO
Systems – Design of Full Order and Reduced Order Observers for SISO
Systems.
UNIT V STABILTY 9
Introduction-Equilibrium Points-Stability in the sense of Lyapunov-BIBO
Stability-Stability of LTI Systems-Equilibrium Stability of Nonlinear
Continuous Time Autonomous Systems-The Direct Method of Lyapunov
70
and the Linear Continuous-Time Autonomous Systems-Finding
Lyapunov Functions for Nonlinear Continuous Time Autonomous
Systems- Krasovskii and Variable Gradient Method.
TOTAL: 45 PERIODS
REFERENCE BOOKS:
1. M. Gopal, “Modern Control System Theory”, New Age International,
2005.
2. K. Ogatta, “Modern Control Engineering”, PHI, 2002.
3. D. Roy Choudhury, “Modern Control Systems”, New Age
International, 2005. John S. Bay, “Fundamentals of Linear State
Space Systems”, McGraw-Hill, 1999.
4. John J. D’Azzo, C. H. Houpis and S. N. Sheldon, “Linear Control
System Analysis and Design with MATLAB”, Taylor Francis, 2003.
5. Z. Bubnicki, ”Modern Control Theory”, Springer, 2005.
13PE402 : APPLICATION OF MEMS
TECHNOLOGY
L T P C
3 0 0 3
Course objectives :
The objective of this course is to
Introduce the concept of MEMS and MEMS material.
Develop new fabrication methods and more reliable MEMS
technology.
differentiate MEMS sensors and actuator based on electrostatic
and thermal principles.
Impart knowledge on the design of new MEMS device based on
various principles.
Course Outcomes:
Upon completion of the course, students will be able to
71
demonstrate the MEMS technology and MEMS materials.
distinguish the different fabrication methods used of MEMS
technology and packaging and reliability issues.
classify MEMS sensors and actuators working based on
electrostatic principles.
find suitable applications of MEMS sensors and actuators working
based on thermal principles.
Design MEMS devices that works based on various principles.
UNIT I MICRO-FABRICATION, MATERIALS AND
ELECTROMECHANICAL CONCEPTS
9
Overview of micro fabrication–silicon and other material based
fabrication processes- conductivity of semiconductors-crystal planes and
orientation-stress and strain-flexural beam bending analysis-torsional
deflections-Intrinsic stress-resonant frequency and quality factor-
photolithography.
UNIT II ELECTROSTATIC SENSORS AND
ACTUATION
9
Principle-material-design and fabrication of parallel plate capacitors as
electrostatic sensors-capacitive pressure sensor- comb drive -micro
motors- actuators-.Applications.
UNIT III THERMAL SENSING AND ACTUATION 9
Principle-material-design and fabrication of thermocouples- thermal
bimorph sensors- thermal resistor sensors- actuators-.Applications.
UNIT IV PIEZOELECTRIC SENSING AND ACTUATION 9
Piezo-electric effect - cantilever piezo electric actuator model -
properties of piezo-electric materials- Applications.
UNIT V CASE STUDIES 9
Acceleration sensors - gyroscopes-piezo-resistive sensors-magnetic
actuation-micro fluids applications-medical applications- optical MEMS.
TOTAL: 45 PERIODS
72
REFERENCE BOOKS:
1. Chang Liu, “Foundations of MEMS”, Pearson International Edition,
2006.
2. Tai-Ran Hsu, “MEMS and Microsystems Design and Manufacture”,
Tata McGraw Hill, 2002.
3. Stephen Senturia, “Microsystems Design”, Springer, 2006
4. Marc Madou, “Fundamentals of micro fabrication”,CRC Press, 1997.
5. Boston, “Micro machined Transducers Sourcebook”,WCB McGraw
Hill, 1998.
6. M.H.Bao “Micromechanical Transducers: Pressure sensors,
accelerometers and gyroscopes”, Elsevier, New York, 2000.
13PE403: ELECTRO MAGNETIC FIELD
COMPUTATION AND MODELLING
LT P C
3 0 0 3
Course Objectives:
To impart knowledge on
The concept of the fundamentals of Electromagnetic Field Theory.
The concept of problem formulation and computation of
Electromagnetic Fields using analytical and numerical methods.
The concept of mathematical modeling and design of electrical
apparatus.
Course Outcomes:
Upon completion of the course, students will be able to
know the fundamentals of Electromagnetic Field Theory.
Describe the basics in formulation and computation of
Electromagnetic Fields using analytical and numerical methods.
know the knowledge on Finite Difference and Finite Element
Method in solving Electromagnetic field problems.
know the concept of mathematical modeling and design of
electrical apparatus.
73
UNIT I INTRODUCTION 9
Review of basic field theory – Maxwell’s equations – Constitutive
relationships and Continuity equations – Laplace, Poisson and
Helmholtz equation – principle of energy conversion – force/torque
calculation
UNIT II BASIC SOLUTION METHODS FOR FIELD
EQUATIONS
9
Limitations of the conventional design procedure need for the field
analysis based design, problem definition, boundary conditions, solution
by analytical methods-direct integration method – variable separable
method – method of images.
UNIT III SOLUTION BY NUMERICAL METHODS 9
Finite Difference Method, Finite Element method – Charge
Simulation method – Boundary Elimination method - Variational
Formulation - Discretisation – Shape functions –Stiffness matrix –
Energy minimization - 1D and 2D planar and axial symmetry problems.
UNIT IV COMPUTATION OF BASIC QUANTITIES USING
FEM PACKAGES
9
Review of Basic quantities – Energy stored in Electric Field –
Capacitance – Magnetic Field – Linked Flux – Inductance – Force –
Torque – Skin effect – Resistance.
UNIT V DESIGN APPLICATIONS 9
Design of Insulators – Solenoidal actuators – Transformers – Rotating
machines – SRM – Induction Machines.
Total = 45 PERIODS
REFERENCE BOOKS:
1. Matthew. N.O. Sadiku, “Elements of Electromagnetics”, Fourth
74
Edition, Oxford University Press, First Indian Edition 2007.
2. K.J.Binns, P.J.Lawrenson, C.W Trowbridge, “The analytical and
numerical solution of Electric and magnetic fields”, John Wiley &
Sons, 1993.
3. Nicola Biyanchi , “Electrical Machine analysis using Finite Elements”,
Taylor and Francis Group, CRC Publishers, 2005.
4. Nathan Ida, Joao P.A.Bastos , “Electromagnetics and calculation of
fields”, Springer-Verlage, 1992.
5. S.J Salon, “Finite Element Analysis of Electrical Machines” Kluwer
Academic Publishers, London, 1995, distributed by TBH Publishers &
Distributors, Chennai, India.
6. Silvester and Ferrari, “Finite Elements for Electrical Engineers”
Cambridge University press, 1983.
WEB REFERENCES:
1. www.ansys.com
2. www.magnet.com
13PE404 : ADVANCED DIGITAL SIGNAL
PROCESSING
LT P C
3 0 0 3
Course Objectives:
To refresh the fundamentals of Digital Signal Processing.
To study multirate signal processing fundamentals.
To introduce the student to wavelet transforms.
To impart in-depth knowledge motor control signal processors.
Course Outcomes:
Upon completion of the course, students will be able to
Know the fundamentals of Digital Signal Processing.
Describe the basics of various types of transforms.
know the concept of multirate signal processing.
75
know the concepts and applications of Motor control signal
processors.
UNIT I INTRODUCTION 9
Introduction to two dimensional signal and systems – 2D – DFT
Transforms – Properties and applications – Discrete Hilbert Transform
and Discrete Cosine Transform – Properties and Applications – Short
term Fourier Transform – Gabor Transform – Properties and
Applications.
UNIT II WAVELET TRANSFORMS 9
Wavelets – Wavelet Analysis – The Continuous Wavelet Transform –
scaling – shifting – scale and frequency – The Discrete Wavelet
Transform – One Stage filtering – Approximation and Details – Filter
bank analysis – Multilevel Decomposition – Number of levels – Wavelet
reconstruction – Reconstruction filter- Reconstructing Approximations
and details- Multilevel Reconstruction – Wavelet packet synthesis-
Typical Applications. Recursive multi-resolution decomposition – Haar
Wavelet – Daubechies Wavelet.
UNIT III MULTIRATE SIGNAL PROCESSING 9
Decimation by a factor D – Interpolation by a factor I – Filter Design and
implementation for sampling rate conversion: Direct form FIR filter
structures – Polyphase filter structure.
UNIT IV MOTOR CONTROL SIGNAL PROCESSORS 9
Introduction- System configuration registers - Memory Addressing
modes – Instruction set – Programming techniques – simple programs
UNIT V PERIPHERALS OF SIGNAL PROCESSORS 9
General purpose Input/Output (GPIO) Functionality- Interrupts - A/D
converter-Event Managers (EVA, EVB)- PWM signal generation
Total = 45 PERIODS
76
REFERENCE BOOKS:
1. Roberto Crist, “Modern Digital Signal Processing”, Thomson
Brooks/Cole, 2004
2. Raghuveer. M. Rao, Ajit S.Bopardikar, “Wavelet Transforms,
Introduction to Theory and applications”, Pearson Education, Asia,
2000.
3. Hamid A.Toliyat, Steven Campbell, “DSP based electromechanical
motion control”, CRC Press, 2003.
13PE405 : MICRO CONTROLLER BASED
SYSTEM DESIGN
L T P C
3 0 0 3
Course objective:
The objective of the course is to
Introduce the knowledge of fundamental concepts in
microcontroller based system design.
Introduce about basics of I/O and RTOS role on microcontroller.
Introduce the knowledge of PIC microcontroller based system
design.
Provide a practical experience on microcontroller based
applications.
Course Outcomes:
Upon completion of the course, students will be able to
know the fundamentals of microcontroller based system design.
describe the basics of I/O and RTOS role on microcontroller.
Know the concept of PIC Microcontroller based system design
describe the case study experiences for microcontroller based
applications.
77
UNIT I 8051 ARCHITECTURE 9
Architecture – memory organization – addressing modes – instruction
set – Timers - Interrupts - I/O ports, Interfacing I/O Devices – Serial
Communication.
UNIT II 8051 PROGRAMMING 9
Assembly language programming – Arithmetic Instructions – Logical
Instructions –Single bit Instructions – Timer Counter Programming –
Serial Communication Programming Interrupt Programming – RTOS for
8051 – RTOSLite – FullRTOS – Task creation and run.
UNIT III PIC MICROCONTROLLER 9
Architecture – memory organization – RAM & ROM Allocation -
addressing modes – instruction set – PIC programming in Assembly &
C –I/O port, Data Conversion - MP-LAB.
UNIT IV PERIPHERAL OF PIC MICROCONTROLLER 9
Timers – CCP modules, Timer programming - Interrupts, I/O ports- I2C
bus-A/D converter-UART- DAC and Sensor Interfacing –Flash and
EEPROM memories.
UNIT V SYSTEM DESIGN – CASE STUDY 9
Interfacing LCD Display – Keypad Interfacing - Generation of Gate
signals for converters and Inverters - Motor Control – Controlling DC/
AC appliances – Measurement of frequency - Stand alone Data
Acquisition System.
TOTAL: 45 PERIODS
REFERENCE BOOKS:
1. John B.Peatman, “Design with PIC Microcontrollers”, Pearson
Education, Asia 2004.
2. Muhammad Ali Mazidi, Rolin D. Mckinlay, Danny Causey, “PIC
Microcontroller and Embedded Systems using Assembly and C for
78
PIC18”, Pearson Education, 2008.
3. John Iovine, “PIC Microcontroller Project Book”, McGraw Hill,
2000.
4. Myke Predko, “Programming and customizing the 8051
microcontroller”, Tata McGraw Hill 2001.
5. Muhammad Ali Mazidi, Janice G. Mazidi and Rolin D. McKinlay,
“The 8051 Microcontroller and Embedded Systems” Prentice Hall,
2005.
6. Rajkamal, “Microcontrollers - Architecture, Programming,
Interfacing & System Design”, 2nd edition Pearson, 2012.
7. I Scott Mackenzie and Raphael C.W. Phan, “The Micro controller”,
Pearson, Fourth edition 2012.
13PE406 : FLEXIBLE AC TRANSMISSION
SYSTEMS
LT P C
3 0 0 3
Course objective:
The objective of the course is to
introduce the basics of compensation techniques
educate the students about the working of voltage source
converters
illustrate the benefits of FACTS devices and some important
FACTS devices
to understand the applications of FACTS devices
introduce the concept of coordinating various controllers
Course Outcome:
Upon completion of the course, students will be able to
illustrate the effect of series and shunt compensation on power
system
79
demonstrates the use of various FACTS devices to mitigate power
system problems
model the FACTS devices for load flow and stability studies
suggest suitable techniques for coordinating various FACTS
devices
UNIT I INTRODUCTION 9
Review of basics of power transmission networks-control of power flow
in AC transmission line- Analysis of uncompensated AC Transmission
line- Passive reactive power compensation: Effect of series and shunt
compensation on power transfer capacity- Possible benefits from FACTS
controllers- types of FACTS controllers
UNIT II STATIC VAR COMPENSATOR (SVC) 9
Voltage control - voltage control by SVC – Advantages of slope in the
SVC dynamic characteristics – Influence of SVC on system voltage -
Modeling of SVC for load flow studies- Applications:: Transient stability
enhancement, Augmentation of Power System damping and Mitigation
of SSR
UNIT III THYRISTOR CONTROLLED SERIES
CAPACITOR (TCSC)
9
Concepts of Controlled Series Compensation – Operation of TCSC -
Analysis of TCSC – Modelling of TCSC for load flow studies and
stability studies – Brief overview of world’s first TCSC installation -
Applications of TCSC – Enhancement of system damping - SSR
mitigation and Operational concept of GCSC
UNIT IV VOLTAGE SOURCE CONVERTER BASED
FACTS CONTROLLERS
9
STATCOM-: Principle of operation, V-I curve and SSR mitigation
application, SSSC – Principle of operation, control system and power
flow control application, UPFC- principle of operation, modes of
operation and power flow control and oscillation damping application and
80
IPFC- operational concept. Modeling of STATCOM, SSSC, UPFC and
IPFC for power flow and stability studies
UNIT V CONTROLLERS AND THEIR COORDINATION 9
FACTS Controller interactions – SVC–SVC interaction, SVC-TCSC
interaction and TCSC-TCSC interaction - co-ordination of multiple
controllers using linear control techniques – Quantitative treatment of
control coordination.
TOTAL: 45 PERIODS
REFERENCE BOOKS:
1. Narain G.Hingorani, Laszio. Gyugyl, “Understanding FACTS
Concepts and Technology of Flexible AC Transmission System”,
Standard Publishers, Delhi 2001.
2. Mohan Mathur, R., Rajiv. K. Varma, “Thyristor – Based Facts
Controllers for Electrical Transmission Systems”, IEEE press and
John Wiley & Sons, Inc., 2002
3. K.R.Padiyar, “FACTS Controllers in Power Transmission and
Distribution”, New Age International(P) Ltd., Publishers, New Delhi,
Reprint 2008,
4. A.T.John, “Flexible AC Transmission System”, Institution of Electrical
and Electronic Engineers (IEEE), 1999.
5. V. K.Sood, “HVDC and FACTS controllers- Applications of Static
Converters in Power System”, Kluwer Academic Publisher, 2004.
13PE407: ENERGY MANAGEMENT AND
AUDITING
LT P C
3 0 0 3
Course objective:
The objective of the course is to
introduce the basics about energy management and auditing
81
educate the students about energy management in various
devices and systems
illustrate the concepts of metering for energy management Make
the student to understand the lighting systems and co-generation
Course Outcomes:
Upon completion of the course, students will be able to
design and implement energy management program
illustrate the method of determining electricity cost and loss
evaluation
illustrate the energy management techniques in various electrical
equipments
know about the choice and rating of electrical machineries for
selected applications
illustrate about metering methods, cost analysis techniques and
suitable energy standards.
UNIT I INTRODUCTION 9
Energy - Need for energy management - designing and starting an
energy management program – energy audit process ; accounting,
monitoring, targeting and reporting – BEE standards and star ratings
UNIT II ENERGY COST AND LOAD MANAGEMENT 9
Important concepts in an economic analysis - Economic models-Time
value of money-Utility rate structures- cost of electricity-Loss evaluation
Load management: Demand control techniques-Utility monitoring and
control system-HVAC and energy management-Economic justification
UNIT III ENERGY MANAGEMENT FOR MOTORS,
SYSTEMS, AND ELECTRICAL EQUIPMENT
9
Systems and equipment- Electric motors- Transformers and reactors-
Capacitors and synchronous machines – Choice and rating of Electrical
82
Machines.
UNIT IV METERING FOR ENERGY MANAGEMENT 9
Relationships between parameters-Units of measure-Typical cost
factors- Utility meters - Timing of meter disc for kilowatt measurement -
Demand meters - Paralleling of current transformers - Instrument
transformer burdens-Multitasking solid-state meters - Metering location
vs. requirements- Metering techniques and practical examples
UNIT V LIGHTING SYSTEMS & COGENERATION 9
Concept of lighting systems - The task and the working space -Light
sources - Ballasts -Luminaries - Lighting controls-Optimizing lighting
energy - Power factor and effect of harmonics on power quality - Cost
analysis techniques-Lighting and energy standards
Cogeneration: Forms of cogeneration - feasibility of cogeneration-
Electrical interconnection
TOTAL: 45 PERIODS
REFERENCE BOOKS:
1. Barney L. Capehart, Wayne C. Turner, and William J. Kennedy,
“Guide to Energy Management”, 5th Edition, The Fairmont Press, Inc.,
2006
2. Eastop T.D & Croft D.R, “Energy Efficiency for Engineers and
Technologists”, Logman Scientific & Technical, ISBN-0-582-03184,
1990.
3. Reay D.A, “Industrial Energy Conservation”, 1stedition, Pergamon
Press, 1977.
4. IEEE Recommended Practice for Energy Management in Industrial
and Commercial Facilities, IEEE, 1996.
5. Amit K. Tyagi, “Handbook on Energy Audits and Management”, TERI,
2003.
6. BEE standards
83
13PE408 : Wind Energy Conversion Systems L T P C
3 0 0 3
Course Objective:
To impart knowledge on the fundamental concepts and various
developments in the field of wind energy conversion systems for
electrical energy applications.
Course Outcomes:
Upon completion of the course, students will be able to
Know the fundamentals of wind energy and its conversion system
illustrate the aerodynamics of wind turbines energy conservation
techniques.
design and evaluate the performance of wind turbines
test and control the wind energy converters
demonstrate wind turbine controller and power quality issues.
UNIT I WIND RESOURCES, SITE SELECTION AND
WIND MILLS
9
The nature and geographical variation in the wind resources – long term
wind speed variation-annual and seasonal variations – synoptic and
diurnal variations, Turbulence, Gust wind Speeds – Extreme wind
speeds – wind speed prediction and forecasting. Wind patterns and wind
data - Site selection- Types of wind mills- Characteristics of wind
generators- Load matching.
UNIT II AERODYNAMICS OF WIND TURBINES 9
Aerodynamics - actuator disc concept – rotor disc theory – vortex
cylinder model of the actuator disc- rotor blade theory – breakdown of
the momentum theory – blade geometry – The effect of a discrete
number of blades – forces developed by blades – aerodynamic models –
braking systems – tower - control and monitoring system – power
performance – The method of acceleration potential –Stall delay –
84
Unsteady Flow – Dynamic Inflow.
UNIT III WIND TURBINE PERFORMANCE AND
DESIGN CONCEPTS
9
Rotor diameter – machine rating – rotational speed – number of blades –
teetering –power control – banking system – fixed and variable speed
operation – types of generators – design concept; blades, pitch bearing,
rotor hub, gear box, generator, mechanical brakes, nacelle bedplate,
yaw drive, tower, foundation - wind turbine performance measurement –
aerodynamic performance assessment – basis for design loads –
extreme loads –fatigue loading – stationary blade loading – blade loads
during operation.
UNIT IV CONTROL METHODS OF WIND ENERGY
CONVERTERS
9
Integration of wind energy converters to electrical networks – inverters -
wind energy conversion systems control methods- requirements and
strategies- energy storage – applications of wind energy.
UNIT V WIND TURBINE CONTROLLER AND POWER
QUALITY ISSUES
9
Function of the wind turbine controller – Closed loop control-issues and
objective- general techniques - Pitch actuators control system
implementation - Power quality-Reactive power - voltage flicker-
harmonics - Impact on Voltage Quality.
Total: 45 - Periods
REFERENCE BOOKS:
1. Tony Burton, David Shapre, Nick Jenkins, Ervin Bossanyi, “Wind
Energy Hand Book”, John Wiley and sons Inc, Dec.2001
2. Daniel, Hunt V, “Wind Power – A Handbook of WECS”, Van
Nostrend Co., New York, 1981.
3. Freris L.L., “Wind Energy Conversion”, Prentice Hall (UK) Ltd.,
1990.
85
4. Spera, D.A., Wind Turbine Technology: Fundamental concepts of
Wind Turbine Engineering, ASME Press, 1994.
5. Thomas Ackermann, “Wind Power in Power Systems”, John Wiley
& Sons, Ltd, 2005.
13PE409 : DESIGN OF CONTROLLERS LT P C
3 0 0 3
Course objectives:
The objective of the course is
To introduce the structure of PID controllers and the various
controllers performance specifications.
To know the practical problem in implementation of PID controllers.
To introduce the knowledge on design a control system with
conventional tuning PID controllers.
To provide in-depth knowledge of the application of advance tuning
methods for a system.
Course Outcomes:
Upon completion of the course, students will be able to
Implement the concept of PID Controller Structures and performance
specifications.
Identify and resolve the practical implementation issues of PID
controller
Design a control system with conventional tuning methods of PID
controllers.
Design the advanced PID tuning technology and its applications.
UNIT I INTRODUCTION TO PID CONTROL 9
Introduction of controllers – feedback, feed forward and cascade
controllers - PID control- modification of PID algorithm - Parallel PID
86
Controllers, Conversion to Time constant PID Forms, Series PID
Controllers, Simple PID Tuning
UNIT II PID CONTROLLER IMPLEMENTATION ISSUES 9
Bandwidth-Limited Derivative Control – Proportional Kick – Derivative
Kick – Integral Anti-Windup Circuits - Reverse-Acting Controller: Digital
Implementation – Operational aspects – Commercial controllers.
UNIT III CONTROLLER DESIGN 9
Control structures - Time and frequency domain performance measures
- Ziegler-Nichols' and Related Methods - Loop Shaping - Optimization
Methods - Pole Placement - Dominant Pole Design - Design for
Disturbance Rejection.
UNIT IV CONVENTIONAL TUNING METHODS OF PID
CONTROLLER
9
A spectrum of Tools – Step Response methods – Frequency response
methods – Phase locked loop methods - Complete process knowledge
– Assessment of Performance
UNIT V FUZZY LOGIC AND GENETIC ALGORITHM
METHODS IN PID TUNING
9
Fuzzy PID Supervision for an Automotive Application: Design and
Implementation, Multi-Objective Optimised Genetic Algorithm Fuzzy PID
Control, Application of Fuzzy PID Control in Robotics.
TOTAL: 45 PERIODS
REFERENCE BOOKS:
1. Johnson and H. Moradi, “PID Control: New Identifications and Design
Methods” Springer - Verlag, 2005.
2. Karl J. Astrom & Tore Hagglun. “PID Controllers: Theory, Design and
Tuning” International Society for Measurement and Control, 1995.
3. Cheng-Ching Yu, “Auto tuning of PID Controllers; A Relay Feedback
87
Approach” Springer, 2nd Edition, 2006.
4. Antonio Visioli, “Practical PID Control” Springer-Verlag London
Limited, 2006.
5. Guillermo J. Silva, Aniruddha Datta & S.R Bhattacharyya, “PID
Controllers for Time-Delay Systems” Printed in the United States of
America, 2005.
13PE410 : HIGH VOLTAGE DIRECT CURRENT
TRANSMISSION
L T P C
3 0 0 3
Course Objective :
To impart knowledge on the basic concepts of HVDC with existing
HVDC projects
Course Outcomes:
Upon completion of the course, students will be able to
Demonstrate the modern trends and planning of HVDC system.
Analyze various converters and associated control strategy and
understand the converter faults and its protection.
Design AC and DC filter to eliminate Harmonics
Analyse the MTDC systems and its control
Model of HVDC systems for Digital Dynamic Simulation and
demonstrate about the grounding of HVDC systems
UNIT I INTRODUCTION TO HVDC SYSTEM &
ANALYSIS OF CONVERTERS
9
Introduction of DC Power transmission technology – Comparison of AC
and DC transmission – Application of DC transmission – Description of
DC transmission system –. Pulse number – Choice of converter
configuration - Analysis of Graetz bridge circuit with and without overlap
- Characteristics of a twelve pulse converter
UNIT II HVDC SYSTEM CONTROL & FAULT
PROTECTION
9
88
DC link control of LCC – Control Characteristics – Control Hierarchy -
Firing Angle Control Scheme : IPC & EPC
HVDC SYSTEM FAULTS AND PROTECTION
Misoperation of Converters – Protection against over current and over
voltage – surge arrestors
UNIT III HARMONICS AND FILTERS 9
Introduction – Generation of harmonics – Characteristics and Non-
Characteristics harmonics Design of AC filters – Types of AC filters –
Single tuned Passive filters – minimum cost tuned filters – Design of
High pass filter- Design of DC filters –- PLC/RI noise filters – Telephone
Interference.
UNIT IV MULTITERMINAL AND MULTI-INFEED DC
SYSTEMS
9
Introduction to MTDC system – Types of MTDC systems – Comparison
of series and parallel MTDC systems – Control and protection of MTDC
systems: Current Margin Method – Voltage Limiting Control –
Decentralized Current Reference Balancing – Two ACR Method – Study
of MTDC systems – Multi-Infeed DC Systems.
UNIT V MODELLING, SIMULATION AND GROUNDING
OF HVDC SYSTEMS
9
Introduction to system simulation – Philosophy and tools – HVDC
system simulation – Modeling of HVDC systems for digital dynamic
simulation – Advantages and Problems with Ground Return – Basic
requirements in the Design of Ground Electrodes.
TOTAL: 45 PERIODS
TEXT BOOKS:
1. P. Kundur, “Power System Stability and Control”, McGraw-Hill, 2006.
2. E.W.Kimbark, “Direct Current Transmission” John Wiley & Sons.
3. K.R.Padiyar, , “HVDC Power Transmission Systems”, New Age
89
International (P) Ltd., New Delhi, 2002.
REFERENCE BOOKS:
1. J.Arrillaga, “High Voltage Direct Current Transmission”, Peter
Pregrinus, London 1983.
2. Erich Uhlmann, “Power Transmission by Direct Current”, BS
Publications, 2004.
3. V.K.Sood, HVDC and FACTS controllers – “Applications of Static
Converters in Power System”, April 2004, Kluwer Academic
Publisher.
4. S.Kakshaish, V.Kamaraju, “ HVDC Transmission”, TMH Publishers,
2012
5. S. Rao, EHV AC and HVDC Transmission Engg and Practice.
Khanna Pub., Delhi.1990.
13PE412 : Solar and Energy Storage Systems L T P C
3 0 0 3
Course Objectives:
The objective of this course is to
Introduce the concept of Thermal and Solar Photovoltaic systems.
Learn about Photovoltaic module configurations and MPPT
algorithms.
Introduce the knowledge about the Magnetic, Electric and
Chemical Energy Storage system and their applications.
Know the applications of Superconductors in Energy generation.
Course Outcomes:
Upon completion of the course, students will be able to
Know the radiation principles and solar energy estimation.
Demonstrate Photovoltaic technology principles and techniques of
various solar energy conversions systems.
90
evaluate the performance of different energy generation
technologies and Superconducting magnetic energy storage
system.
select fuel cells for various applications.
UNIT I SOLAR RADIATION, COLLECTORS AND
THERMAL TECHNOLOGIES
9
Introduction to solar energy -Solar angles - day length, angle of
incidence on tilted surface - Sun path diagrams - shadow determination -
extraterrestrial characteristics - measurement and estimation on
horizontal and tilted surfaces - flat plate collector - evacuated tubular
collectors - concentrator collectors – concentrators with point focus -
heliostats - applications of solar thermal technology- operation of solar
heating and cooling systems.
UNIT II SOLAR PHOTOVOLTAIC SYSTEMS 9
Solar photovoltaic systems - operating principle- photovoltaic cell
concepts- Photovoltaic cell-characteristics –equivalent circuit- cell,
module and array- series and parallel connections- maximum power
point tracking- applications.
UNIT III APPLICATIONS OF SUPERCONDUCTORS IN
ENERGY
9
Superconducting wires and their characteristics, High field magnets for
production of energy by magnetic fusion, Energy generation - Magneto
hydrodynamics (MHD),energy storage, electric generators and role of
superconductors.
UNIT IV MAGNETIC AND ELECTRIC ENERGY
STORAGE SYSTEMS
9
Superconducting Magnet Energy Storage (SMES) systems; capacitor
and batteries: comparison and application; super capacitor:
Electrochemical Double Layer Capacitor (EDLC), principle of working,
structure, performance and application.
91
UNIT V CHEMICAL ENERGY STORAGE SYSTEMS 9
Introduction about fuel cells – design and principles of operation of a fuel
cell – classification of fuel cells, conversion efficiency of fuel cells. Types
of electrodes, work output and emf of fuel cell, Applications of fuel cells.
Introduction about Hydrogen energy – hydrogen production –
electrolysis, thermo chemical methods. Battery - Types of Batteries -
Equivalent Electrical Circuit - Battery Charging - Charge Regulators -
Battery Management
TOTAL: 45 PERIODS
REFERENCE BOOKS:
1. Mukund R. Patel, ‘Wind and Solar Power Systems: Design, Analysis,
and Operation, Second Edition, CRC Press, 2005.
2. S.P.Sukatme, ‘Solar Energy – Principles of thermal collection and
storage,’ second edition, Tata McGraw Hill, 1996.
3. Roger Messenger and Jerry Vnetre, ‘Photovoltaic Systems
Engineering,’ CRC Press, third edition, 2010.
4. Michael Tinkham, “Introduction to Superconductivity: Second Edition
(Dover Books on Physics)”, Publisher: Dover Publications; 2nd edition,
2004.
5. GD Rai, “Non Conventional Energy Sources”, Khanna Publishers,
New Delhi, 2004.
13PE413 : NON LINEAR DYNAMICS FOR
POWER ELECTRONIC CIRCUITS
L T P C
3 0 0 3
Course Objective:
The objective of the course is
To introduce the concepts of non linear behaviour of power
electronic converters.
To investigate the non linear behaviour of a power electronic
92
converters.
To provide the knowledge of how to analyse the non linear
phenomena in choppers and power electronic drives.
To introduce the new control techniques for control of non
linear in power electronic systems.
Course Outcomes:
Upon completion of the course, students will be able to
demonstrate the non linear behaviour of power electronic
converters.
select the techniques for investigation on non linear behaviour of
power electronic converters.
analyse the non linear phenomena in DC to DC converters.
analyse the non linear phenomena in AC and DC Drives.
develop new control techniques for control of non linear behaviour
in power electronic systems.
UNIT I BASICS OF NONLINEAR DYNAMICS 9
Basics of Nonlinear Dynamics: System, state and state space model,
Vector field- Modeling of Linear, nonlinear and Linearized systems,
Attractors , chaos, Point care map, Dynamics of Discrete time system,
Lyapunov Exponent, Bifurcations, Bifurcations of smooth map,
Bifurcations in piece wise smooth maps, border crossing and border
collision bifurcation.
UNIT II TECHNIQUES FOR INVESTIGATION OF
NONLINEAR PHENOMENA
9
Techniques for experimental investigation, Techniques for numerical
investigation, Computation of averages under chaos, Computations of
spectral peaks, Computation of the bifurcation and analyzing stability.
UNIT III NONLINEAR PHENOMENA IN DC-DC
CONVERTERS
9
Border collision in the Current Mode controlled Boost Converter,
93
Bifurcation and chaos in the Voltage controlled Buck Converter with
latch, Bifurcation and chaos in the Voltage controlled Buck Converter
without latch, Bifurcation and chaos in Cuk Converter. Nonlinear
phenomenon in the inverter under tolerance band control.
UNIT IV NONLINEAR PHENOMENA IN MOTOR
DRIVES
9
Nonlinear Phenomenon in Current controlled and voltage controlled DC
Drives, Nonlinear Phenomenon in PMSM Drives.
UNIT V CONTROL OF CHAOS 9
Hysteresis control, Sliding mode and switching surface control, OGY
Method, Pyragas method, Time Delay control. Application of the
techniques to the Power electronics circuit and drives.
TOTAL: 45 PERIODS
REFERENCE BOOKS:
1. George C. Vargheese, S Banerjee, “Nonlinear Phenomena in Power
Electronics”, IEEE Press, July 2001
2. Steven H Strogatz, “Nonlinear Dynamics and Chaos”, Westview
Press, 1994
3. Chi Kong Tse, “Complex Behaviour of Switching Power Converters”,
CRC Press, 2003.
13PE414 : Smart Grid L T P C
3 0 0 3
COURSE OBJECTIVES:
To impart knowledge on
Smart Grid technologies, different smart meters and advanced
metering infrastructure.
94
power quality management issues in Smart Grid.
high performance computing techniques for Smart Grid
application.
COURSE OUTCOMES:
Upon completion of the course, students will be able to
understand the concept of smart grid technologies
understand the smart meters and their role
analyze the power quality issues in smart grid
apply high performance computing for smart grid
UNIT I INTRODUCTION TO SMART GRID 9
Evolution of Electric Grid, Concept, Definitions and Need for Smart Grid,
Smart grid drivers, functions, opportunities, challenges and benefits,
Difference between conventional & Smart Grid, Concept of Resilient
&Self Healing Grid, Present development & International policies in
Smart Grid, Diverse perspectives from experts and global Smart Grid
initiatives.
UNIT II SMART GRID TECHNOLOGIES 9
Technology Drivers, Smart energy resources, Smart substations,
Substation Automation, Feeder Automation ,Transmission systems:
EMS, FACTS and HVDC, Wide area monitoring, Protection and control,
Distribution systems: DMS, Volt/VAr control, Fault Detection, Isolation
and service restoration, Outage management, High-Efficiency
Distribution Transformers, Phase Shifting Transformers, Plug in Hybrid
Electric Vehicles (PHEV).
UNIT III SMART METERS AND ADVANCED
METERING INFRASTRUCTURE
9
Introduction to Smart Meters, Advanced Metering infrastructure (AMI)
drivers and benefits, AMI protocols, standards and initiatives, AMI needs
in the smart grid, Phasor Measurement Unit(PMU), Intelligent Electronic
Devices(IED) & their application for monitoring & protection.
95
UNIT IV POWER QUALITY MANAGEMENT IN
SMART GRID
9
Power Quality & EMC in Smart Grid, Power Quality issues of Grid
connected Renewable Energy Sources, Power Quality Conditioners for
Smart Grid, Web based Power Quality monitoring, Power Quality Audit.
UNIT V HIGH PERFORMANCE COMPUTING FOR
SMART GRID APPLICATIONS
9
Local Area Network (LAN), House Area Network (HAN), Wide Area
Network (WAN), Broadband over Power line (BPL), IP based Protocols,
Basics of Web Service and CLOUD Computing to make Smart Grids
smarter, Cyber Security for Smart Grid
TOTAL: 45 PERIODS
REFERENCE BOOKS:
1. Stuart Borlase “Smart Grid: Infrastructure, Technology and
Solutions”, CRC Press, 2012.
2. Janaka Ekanayake, Nick Jenkins, KithsiriLiyanage, Jianzhong Wu,
Akihiko Yokoyama, “Smart Grid: Technology and Applications”, John
Wiley & Sons, March 2012.
3. Lars T. Berger and Krzysztof Iniewski, “Smart Grid Applications,
Communications, and Security”, John Wiley & Sons, March 2012.
4. Vehbi C. Güngör, DilanSahin, TaskinKocak, Salih Ergüt, Concettina
Buccella, Carlo Cecati, and Gerhard P. Hancke, “Smart Grid
Technologies: Communication Technologies and Standards IEEE
Transactions On Industrial Informatics”, Vol. 7, No. 4, November
2011.
96
13PE411 : VLSI ARCHITECTURE AND DESIGN
METHODOLOGIES
L T P C
3 0 0 3
Course Objectives:
To impart knowledge on
the concept of VLSI design process and processing technology
the concept of Programmable ASICs
the concept of design, simulation and testing
Course Outcomes:
Upon completion of the course, students will be able to
know of the characteristics of CMOS circuit construction and the
comparison between different state-of-the-art CMOS technologies
and processes
analyse the different types of ASICs design and Logic cell
architecture and interconnects.
analyze and design small scale combinational logic circuits using
HDLs.
know the importance of testing and its types in VLSI circuits.
UNIT I INTRODUCTION 9
Overview of VLSI design methodology: Trends in IC technology, VLSI
design process - Architectural design - Logical design - Physical design -
Layout styles - Full custom, Semicustom approaches.
UNIT II CMOS PROCESSING TECHNOLOGY AND
INTRODUCTION TO CMOS CIRCUITS
9
CMOS Processing Technology: Silicon Semiconductor Technology,
Basic CMOS Technology. Introduction to CMOS Circuits: MOS
Transistors, MOS Transistor Switches, CMOS Logic, submicron
technology and GaAs VLSI technology. Introduction to Analog VLSI.
97
UNIT III PROGRAMMABLE ASICs 9
Types of ASICs- Design flow- Anti fuse- Static RAM- EPROM and
EEPROM technology-PREP bench marks- Actel ACT- Xilinx LCA-
Altera FLEX- Altera MAX DS & AC inputs and outputs, clock and power
inputs- Xilinx I/O blocks.
UNIT IV PROGRAMMABLE ASIC DESIGN SOFTWARE 9
Actel ACT- Xilinx LCA- Xilinx FPLD- Altera MAX 5000 and 7000- Altera
MAX 9000- Design Systems- Logic synthesis- Half gate ASIC- chematic
entry- low level design language- PLA tools-EDIF- CFI design
representation.
UNIT V LOGIC SYNTHESIS, SIMULATION AND
TESTING
9
Basic features of VHDL language for behavioral modeling and
simulation- summary of VHDL data types- Dataflow and structural
modeling- VHDL and logic synthesis- types of simulation boundary scan
test- fault simulation- automatic test pattern generation.
TOTAL: 45 PERIODS
REFERENCE BOOKS:
1. Neil H.E Weste and Kamran Eshraghian, “Principles of CMOS
VLSI Design”, 2nd Edition, Addition Wesley, 2000.
2. M.J.S Smith “Application Specific Integrated Circuits”, Pearson
Education, 2008.
3. Amar Mukherjee, “Introduction to NMOS and CMOS VLSI System
Design”, Prentice Hall, 1986.
4. Frederick J. Hill and Gerald R. Peterson, “Computer Aided Logical
Design with emphasis on VLSI”, 1995.
5. William I.Fletcher “An Engineering Approach to Digital Design”,
Prentice Hall of India, 1996.
98
13PE415 : SOFT COMPUTING TECHNIQUES L T P C
3 0 0 3
Course Objectives:
To impart knowledge on
emerging area of soft computing techniques.
fuzzy logic systems, artificial neural networks and optimization
techniques.
Course Outcomes:
Upon completion of the course, students will be able to
elucidate the concept of soft computing techniques and their
applications.
apply Fuzzy Logic and Artificial Neural Networks for real world
problems.
apply Genetic Algorithm and particle swarm optimization for power
electronic optimization problems.
UNIT I INTRODUCTION TO SOFT COMPUTING,
ARTIFICIAL NEURAL NETWORKS
9
Introduction to Soft Computing:
Introduction to soft computing - soft computing vs. hard computing -
various types of soft computing techniques - applications of soft
computing.
Artificial Neural Networks:
Neuron - Nerve structure and synapse - Artificial Neuron and its model -
activation functions - Neural network architecture: single layer and multi-
layer feed forward networks - McCulloch-Pitts neuron model - perceptron
model - Adaline and Madaline - multilayer perceptron model - back
propagation learning methods - effect of learning rule co-efficient - back
propagation algorithm - factors affecting back propagation training -
99
applications.
UNIT II RECURRENT NEURAL NETWORKS 9
Counter propagation network – architecture - functioning and
characteristics of counter propagation network - Hopfield / Recurrent
network – configuration - stability constraints - associative memory and
characteristics - limitations and applications - Hopfield v/s Boltzman
machine - Adaptive Resonance Theory: Architecture – classifications -
Implementation and training - Associative Memory.
UNIT III FUZZY LOGIC SYSTEM 9
Introduction to crisp sets and fuzzy sets - basic fuzzy set operation and
approximate Reasoning - Introduction to fuzzy logic modeling and
control – Fuzzification - inferencing - defuzzification - Fuzzy knowledge
and rule bases - Fuzzy modeling and control schemes for non-linear
systems - Self-organizing fuzzy logic control - Fuzzy logic control for
non-linear time-delay systems.
UNIT IV EVOLUTIONARY ALGORITHMS 9
Basic concept of Genetic algorithm and algorithmic steps - adjustment of
free Parameters - Solution of typical optimization problems using genetic
algorithm - Concept on particle swarm optimization and ant-colony
search techniques.
UNIT V APPLICATIONS 9
Identification and control of linear and non-linear dynamic systems using
Neural Network - Stability analysis of Neural-Network interconnection
systems - Design of fuzzy logic controller - Stability analysis of fuzzy
control systems - GA application to power electronic optimization
problems.
TOTAL: 45 PERIODS
REFERENCE BOOKS:
1. Sivanandam S.N., Deepa S.N., “Principles of Soft Computing”,
100
Wiley India Pvt. Ltd., 2nd Edition, 2011.
2. Jacek.M.Zurada, "Introduction to Artificial Neural Systems", Jaico
Publishing House, New Edition, 2012.
3. KOSKO B., "Neural Networks and Fuzzy Systems", Prentice-Hall
of India Pvt. Ltd., 1994.
4. Zimmerman H.J., "Fuzzy set theory-and its Applications"-Kluwer
Academic Publishers, 3rd Edition, 1996.
5. Timothy J. Ross, “Fuzzy Logic with Engineering Applications”
Wiley India, 3rd Edition, 2012.
6. KLIR G.J., FOLGER T.A., “Fuzzy sets, uncertainty and
Information”, Prentice-Hall of India Pvt. Ltd., 1993.
7. Goldberg D.E., “Genetic algorithms in Search, Optimization and
Machine learning”, Addison Wesley, 1989.