K.S.Rangasamy College of Technology - R 2008 …ksrct.ac.in/admin/file_manager/source/academic/curriculum/ME_PED_R... · 1 P.K.Gupta, D.S.Hira, “ Operations Research”, S.Chand

BoS Chairman 33 : M.E. POWER ELECTRONICS AND DRIVES - REGULATION 2008 - CURRICULUM

K.S.Rangasamy College of Technology - Autonomous Regulation

R 2008

Department Electrical and Electronics

Engineering

Programme Code & Name 33 : M.E. Power Electronics and

Drives


K.S.Rangasamy College of Technology, Tiruchengode – 637 215

Curriculum for the programmes under Autonomous Scheme

Regulation R 2008

Department Department of Electrical and Electronics Engineering

Programme Code & Name 33 : M.E. Power Electronics and Drives

Semester I

Course Code

Course Name Hours / Week Credit Maximum Marks

L T P C CA ES Total

THEORY

08330101S Applied Mathematics 3 1 0 4 50 50 100

08330102C Modeling and Analysis of Electrical Machines

3 1 0 4 50 50 100

08330103C Advanced Power Semiconductor Devices

3 0 0 3 50 50 100

08330104C Analysis of Power Converters 3 0 0 3 50 50 100

083301**E Elective I 3 0 0 3 50 50 100

083301**E Elective II 3 0 0 3 50 50 100

PRACTICAL

08330107P Modeling & Simulation Laboratory

0 0 3 2 50 50 100

Total 18 2 3 22 700

Semester II

Course Code


L T P C CA ES Total

THEORY

08330201C Digital Signal Processors 3 1 0 4 50 50 100

08330202C Advanced Solid State Drives 3 1 0 4 50 50 100

08330203C Simulation of Power Electronic Systems

3 0 0 3 50 50 100

08330204S Embedded Systems 3 0 0 3 50 50 100

083302**E Elective III 3 0 0 3 50 50 100

083302**E Elective IV 3 0 0 3 50 50 100

PRACTICAL

08330207P Power Electronics & Drives Laboratory

0 0 3 2 50 50 100

08330208P Technical Report Preparation and Presentation I

0 0 3 2 100 00 100

Total 18 2 3 22 700




Regulation R 2008



Semester III

Course Code


L T P C CA ES Total

THEORY

083303**E Elective V 3 0 0 3 50 50 100

083303**E Elective VI 3 0 0 3 50 50 100

083303**E Elective VII 3 0 0 3 50 50 100

PRACTICAL

08330304P Technical Report Preparation and Presentation II

0 0 3 2 100 00 100

08330305P Project Work - Phase I 0 0 3 6 100 00 100

Total 9 0 6 17 500

Semester IV

Course Code Course Name Hours / Week Credit Maximum Marks

L T P C CA ES Total

PRACTICAL

08330401P Project Work - Phase II 0 0 30 20 50 50 100

Total 0 0 30 20 100




Regulation R 2008



List of Electives

Course Code


L T P C CA ES Total

I Semester

08330141E High Voltage DC Transmission 3 0 0 3 50 50 100

08330142E Non Conventional Energy Sources 3 0 0 3 50 50 100

08330143E Advanced Digital System Design 3 0 0 3 50 50 100

08330144E Digital Signal Processing 3 0 0 3 50 50 100

08330145E Software Engineering 3 0 0 3 50 50 100

08330146E Finite Element Analysis 3 0 0 3 50 50 100

08330147E Linear and Non Linear System Theory

3 0 0 3 50 50 100

08330148E Digital Instrumentation 3 0 0 3 50 50 100

List of II Semester

08330261E Intelligent Control 3 0 0 3 50 50 100

08330262E DSP Controller for Power Electronics Application

3 0 0 3 50 50 100

08330263E Flexible AC Transmission System 3 0 0 3 50 50 100

08330264E VLSI Design 3 0 0 3 50 50 100

08330265E Operating Systems 3 0 0 3 50 50 100

08330266E Object Oriented Programming and their application in Electrical Drives

3 0 0 3 50 50 100

List of III Semester

08330381E Computer Communication and Networks

3 0 0 3 50 50 100

08330382E Advances in power electronics 3 0 0 3 50 50 100

08330383E Computer Aided Design of Electrical Drives

3 0 0 3 50 50 100

08330384E Robotics and Automation 3 0 0 3 50 50 100

08330385E Reliability Engineering 3 0 0 3 50 50 100

08330386E Power Quality Management 3 0 0 3 50 50 100

08330387E Electrical Energy Conservation and Management

3 0 0 3 50 50 100

08330388E Special Electrical Machines 3 0 0 3 50 50 100

08330389E Advanced Microprocessor and Microcontroller Design

3 0 0 3 50 50 100

BoS Chairman 33 : M.E. POWER ELECTRONICS AND DRIVES - REGULATION 2008 – SYLLABUS

K.S.Rangasamy College of Technology - Autonomous Regulation R 2008

Department Electrical and Electronics Engineering

Programme Code & Name 33: M.E. Power Electronics and

Drives

Semester I


L T P C CA ES Total

08330101S APPLIED MATHEMATICS 3 1 0 4 50 50 100

Objective(s)

The course is aimed at developing the basic Mathematical Skills of Engineering Students that are imperative for effective understanding of Engineering Subjects. The topics introduced will serve as basic tools for specialized studies in many Engineering fields, significantly in fluid mechanics, field theory and communication Engineering.

1 CALCULUS OF VARIATION Total Hrs 12

Functional – Euler‟s equation – Variational problems involving one unknown function – Several unknown functions – Functionals dependent on higher order derivatives – Several independent variables – Isoperimetric problems.

2 Z – TRANSFORM Total Hrs 12

Transform of standard functions – Convolution – Initial and Final value problems – Shifting Theorem – Inverse transform (Using Partial Fraction – Residues) – Solution of difference Equations using Z – Transform.

3 RANDOM PROCESSES Total Hrs 12

Classification – Auto correlation – Cross correlation – Ergodicity – Power spectral density function – Poisson processes.

4 LINEAR PROGRAMMING Total Hrs 12

Simplex algorithm – Two-phase and Big–M method – Duality theory – Dual simplex method -Transportation and Assignment problems.

5 NON - LINEAR PROGRAMMING Total Hrs 12

Formulation of non–linear programming problem – Constrained optimization with equality constraints – Constrained optimization with inequality constraints – Saddle point problem – Graphical method of non–linear programming problem involving only two variables – Kuhn-tucker conditions with non-negative constraints – Wolfe‟s modified simplex method.

Total hours to be taught Lecture: 45, Tutorial: 15, Total: 60

Text book(s):

1 M.K.Venkataraman, “Higher Mathematics for Engineering & Science”, National Publishing Company, 2000.

Reference(s) :

1 P.K.Gupta, D.S.Hira, “ Operations Research”, S.Chand & Co., 1999.

2 Kandasamy, “Engineering Mathematics Volume – II”, S.Chand & Co., 2001.

3 T.Veerarajan,”Probability, Statistics & Random Processes”, Tata McGraw Hill., 2002.



Department Electrical and

Electronics Engineering Programme Code & Name

33: M.E. Power Electronics and Drives

Semester I

Course Code


L T P C CA ES Total

08330102C MODELING AND ANALYSIS OF ELECTRICAL MACHINES

3 1 0 4 50 50 100

Objective(s) To know about the modeling of various machines and analysis of the modeling using the reference frames

1 MODELING OF DC MACHINES Total Hrs 12

Equivalent circuit and Electro magnetic torque-Electromechanical modeling-Field excitation: separate, shunt, series and compound excitation-commutator action. Effect of armature mmf-Analytical fundamentals: Electric circuit aspects-magnetic circuit aspects-inter poles.

2 DYNAMIC MODELING OF INDUCTION MACHINES Total Hrs 12

Equivalent circuits- steady state performance equations-Dynamic modeling of induction machines: Real time model of a two phase induction machines, Three phase to two phase transformation-Electromagnetic torque-generalized model in arbitrary reference frames-stator reference frames model-rotor reference frames model-synchronously rotating reference frame model.

3 PHASE CONTROLLED AND FREQUENCY CONTROLLED INDUCTION MACHINES

Total Hrs 12

Stator voltage control: Steady state analysis-approximate analysis-slip power recovery scheme: principle of operation-steady state analysis range of slip equivalent circuit-performance-static scherbius drive. Constant Volts/Hz controls implementation-steady state performance-dynamic simulation. PWM Voltages: Generation-machine model-steady state performance.

4 VECTOR CONTROLLED INDUCTION MACHINES Total Hrs 12

Principle of vector control-direct vector control: flux and torque processor-DVC in stator reference frames with space vector modulation. Indirect vector control scheme: Derivation and implementation. Flux weakening operation: principle-flux weakening in stator flux linkage and rotor flux linkage.

5 SPECIAL MACHINES Total Hrs 12

Permanent magnet and characteristics-synchronous machines with PMs: Machine configuration-flux density distribution-types of PMSM-Variable Reluctance Machines: Basics-analysis-practical configuration-circuit wave forms for torque production stepping motors.


Text book(s):

1 R.Krishnan.”Electric motor & Drives: Modeling, Analysis and Control”, Prentice Hall of India, 2001.

Reference(s) :

1 Charles kingsley, Jr., A.E.Fityzgerald, Stephen D.Umans “Electric Machinery”, Tata McGraw Hill, Sixth Edition, 2002.

2 Miller, T.J.E.”Brushless permanent magnet and reluctance motor drives”, Oxford, 2005.

3 C.V.Jones, ”The Unified Theory of Electrical Machines”, Butterworth, London, 1967.




Programme Code & Name 33: M.E. Power Electronics and Drives

Semester I


L T P C CA ES Total

08330103C ADVANCED POWER SEMICONDUCTOR DEVICES

3 0 0 3 50 50 100

Objective(s) To know about the construction, physics of operation, safe operating areas and protection circuits for various semiconductor devices.

1 INTRODUCTION Total Hrs 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.

2 CURRENT CONTROLLED DEVICES Total Hrs 9

BJTs – Construction, static characteristics, switching characteristics- Negative temperature coefficient and secondary breakdown – Power Darlington – Thyristors – Physical and electrical principle underlying operating mode – Two transistor analogy – Effect of K and ico on ia – concept of latching – Gate and switching characteristics – Converter grade and inverter grade and other types; series and parallel operation – Comparison of BJT and Thyristor – Steady state and dynamic models of BJT and Thyristor.

3 VOLTAGE CONTROLLED DEVICES Total Hrs 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, FCT, RCT and IGCT.

4 FIRING AND PROTECTING CIRCUITS Total Hrs 9

Necessity of isolation – pulse transformer – opto-coupler; Gate drive circuit for SCR, MOSFET, IGBTs and base driving for power BJT – overvoltage, over current and gate protections, Design of snubbers.

5 THERMAL PROTECTION Total Hrs 9

Heat transfer – conduction, convection and radiation – Cooling – liquid cooling, vapour – phase cooling; Guidance for heat sink selection – Thermal resistance and impedance – Electrical analogy of thermal components, heat sink types and design – Mounting types.

Total hours to be taught 45

Text book(s):

1 Mohan, Undeland and Robins, “Power Electronics – Concepts, applications and design”, John Wiley and sons, Singapore, 2000.

Reference(s) :

1 B.W. Williams, “Power Electronics – Devices, Drivers, Applications and passive components”, Macmillan, (2/e), 1992.

2 Rashid M.H., “Power Electronics circuits, Devices and Applications”, Prentice Hall India, Third Edition, Newdelhi, 2004.

3 M.D. Singh and K.B. Khanchandani, “Power Electronics”, Tata McGraw Hill, 2001.





Semester I


L T P C CA ES Total

08330104C ANALYSIS OF POWER CONVERTERS

3 0 0 3 50 50 100

Objective(s) The subject deals with the semiconductor switches, their applications in various conversions of power.

1 ANALYSIS OF SWITCHED CIRCUITS Total Hrs 12

Ideal models of power switches – analysis of the thyristor controlled half wave rectifier – R, L, RL, RC load circuits – load circuit with electromotive force – thyristor specifications – heat sink calculations – Surge currents – limitation on di/dt, dv/dt, classification and analysis of commutation.

2 CONTROLLED RECTIFIERS Total Hrs 12

Continuous and discontinuous modes of single phase half wave and full wave rectifiers – half controlled configurations – RL circuit with electromotive force for continuous and discontinuous operation. Effect of transformer leakage reactance – operating domains of three phase full converters and semi converters.

3 DC-DC SWITCH MODE CONVERTERS Total Hrs 12

DC-DC converter systems – control of DC-DC converters, Buck converters – Continuous and discontinuous modes – Boost converters – continuous and discontinuous modes – Buck boost converters – continuous and discontinuous and discontinuous modes. Cuck converters – continuous and discontinuous models – DC-DC converter comparison; ZVS and ZCS resonant converters.

4 CHOPPERS Total Hrs 12

Classification of DC chopper circuits – analysis of type A chopper and type B chopper – voltage, current and load commutation of choppers – step up chopper – pulse width modulated AC choppers – Current topologies and Harmonic elimination methods.

5 INVERTERS Total Hrs 12

Characteristics – output voltage and waveform control – bridge inverters – single phase and three phase versions – MOSFET, IGBT inverters analysis and design; Current source inverters – Concepts of multilevel inverters.


Text book(s):

1 B.R.Gupta , and v singhal, “ Power Electronics” , S.K.Kataria & Sons, NewDelhi 2007.

2 Ned Mohan, Undeland and Robbins, “Power Electronics: concepts, applications and design”, John wiley and sons, Singapore, 2000.

Reference(s) :

1 Dubey G.K., Doralda S.R., Joshi A., and sinha R.M.K., “Thyristorised power controllers”, Wiley Eastern Limited, 1986.

2 Rashid M.H., “Power Electronics Circuits, Devices and Applications”, PHI, (3/e), 2004.

3 Sen P.C., “Thyristor DC Drives”, John Wiley and sons. 1981.



Department Electrical & Electronics Engineering Programme Code

& Name 33 : M.E. Power Electronics &

Drives

Semester I

Course Code Course Name Hours / Week Credit Maximum marks

L T P C CA ES Total

08330107P MODELING & SIMULATION LABORATORY

0 0 3 2 50 50 100

Any 10 Experiments

1. Modeling of simple PN Junction diode. Total Hrs 3

2. Modeling of Silicon Controlled Rectifier Total Hrs 3

3. Modeling of MOSFET / IGBT / BJT Total Hrs 3

4.

Simulation of Single phase Semi converter a) R Load. b) RL load. c) RLE (Motor) Load

Total Hrs 3

5.

Simulation of Single phase Fully controlled converter. a) R Load. b) RL load. c) RLE (Motor) Load

Total Hrs 3

6. Simulation of Single phase Dual converter Total Hrs 3

7. Simulation of Three phase semi converter Total Hrs 3

8. Simulation of Three phase fully controlled converter Total Hrs 3

9. Simulation of Single phase full bridge Inverter Total Hrs 3

10. Simulation of Three phase full bridge inverter. a) 180 degree mode operation b) 120 degree mode operation

Total Hrs 3

11 Simulation of PWM inverters a) Sinusoidal PWM b) Square PWM

Total Hrs 3

12 Simulation of Three phase AC Voltage Controller. a) Lamp load b) Motor load

Total Hrs 3






Semester II


L T P C CA ES Total

08330201C DIGITAL SIGNAL PROCESSORS

3 1 0 4 50 50 100

Objective(s)


Need and benefits of Digital Signal Processing – Typical signal processing operations: Convolution, correlation. Filtering, transformation and modulation - Algorithms for signal processing – Basic architecture of DSPs‟ - Fundamentals of fixed point DSP architecture – Fixed point number representation and computation –Fundamentals of floating point DSP architecture – floating point number representation and computation.

2 TEXAS PROCESSORS Total Hrs 12

Study of TMS 320 C 5x processor - architecture – addressing modes – instruction Set – programming.

3 PERIPHERALS and INTERFACES OF DSP Total Hrs 12

Peripherals interface - Digital and analog Interface – Host interface – Memory Interface – DMA ports – Serial ports – Applications.

4 COMMERCIAL DSP DEVICES Total Hrs 12

TMS C240 processor and ADSP 2181 processor- Architecture – Addressing modes – Program control – Instruction and programming – simple programs – Special Features – PWM generation.

5 MOTOR CONTROL APPLICATIONS Total Hrs 12

Controller implementation using TMS 320 F 2407 and TMS 320 F 2812 for AC and DC motor speed control.


Text book(s):

1 Sanjit K Mitra, “Digital Signals Processing: A Computer based approach,” Tata McGraw Hill, Second edition, 2004.

Reference(s) :

1 Avatar Singh and S.Srinivasan, “Digital Signal Processing: Implementation using DSP microprocessors with examples from TMS 320C54XX, Thompson Brooks/Cole, 2004.

2 3 K.Padmanabhan et al. “A Practical approach to Digital Signal Processing”, New Age Publications, 2001.

3 B. Venkataramani et al. “Digital Signal Processor – Architecture, Programming and Applications” , TMH, New Delhi 2002.

4 TMS320F/C24\x DSP controllers, Reference Guide-Literature No: SPRU160C , June 1994.





Semester II


L T P C CA ES Total

08330202C ADVANCED SOLID STATE DRIVES

3 1 0 4 50 50 100

Objective(s) To introduce the students to recent advance in solid state drives

1 MOTORS FUNDAMENTALS AND MECHANICAL SYSTEMS

Total Hrs 12

DC motor - Types, induced emf, speed-torque relations; Speed control – Armature and field control; Ward Leonard control – Constant torque and constant horse power operations. Review of Induction Motor operation – Equivalent circuit – Performance of the machine with variable voltage, rotor resistance variation, pole changing and cascaded induction machines, slip power recovery – Static Kramer Drive. Synchronous, Brushless DC and Switched Reluctance Drives.

2 CONVERTER AND CHOPPER CONTROL Total Hrs 12

Principle of phase control – Series and separately excited DC motor with single phase and three phase converters – waveforms, performance parameters, performance characteristics - Operation with free wheeling diode schemes; Drive employing dual converter. Introduction to time ratio control and frequency modulation; Class A, B, C, D and E chopper controlled DC motor – performance analysis, multi-quadrant control.

3 VSI AND CSI FED INDUCTION MOTOR CONTROL Total Hrs 12

AC voltage controller fed induction machine operation – Energy conservation issues – V/f operation theory – requirement for slip and stator voltage compensation. CSI fed induction machine – Operation and characteristics - PWM controls.

4 FIELD ORIENTED CONTROL Total Hrs 12

Field oriented control of induction machines – Theory – DC drive analogy – Direct or Feed back vector control - Indirect or Feed forward vector control – Flux vector estimation - Space Vector Modulation control.

5 DIRECT TORQUE CONTROL Total Hrs 12

Direct torque control of Induction Machines – Torque expression with stator and rotor fluxes, DTC control strategy – optimum switching vector selection – reduction of torque ripple methods.


Text book(s):

1 Gopal K Dubey, “Power Semiconductor controlled Drives”, Prentice Hall Inc., New Yersy, 1989.

2 Bimal K Bose, “Modern Power Electronics and AC Drives” , Pearson Education Asia 2002.

Reference(s) :

1 Vedam Subramanyam, “Electric Drives – Concepts and Applications”, Tata McGraw Hill, 2000.

2 R.Krishnan, “Electric Motor Drives – Modeling, Analysis and Control”, Prentice- Hall of India Pvt. Ltd., New Delhi, 2003.

3 Austin Hughes, “Electric Motors and Drives – Fundamentals, Types and Applications”, Elsevier – a division of Reed Elsevier India private Limited, NewDelhi, 2006.





Semester II


L T P C CA ES Total

08330203C SIMULATION OF POWER ELECTRONIC SYSTEMS

3 0 0 3 50 50 100

Objective(s)


Need for Simulation - Challenges in simulation - Classification of simulation programs - Overview of PSPICE, MATLAB and SIMULINK. Mathematical Modeling of Power Electronic Systems: Static and dynamic models of power electronic switches - Static and dynamic equations and state-space Representation of power electronic systems.

2 PSPICE Total Hrs 12

File formats - Description of circuit elements - Circuit description – Output variables - Dot commands - SPICE models of Diode, Thyristor, Triac, BJT, Power MOSFET, IGBT and MCT.

3 MATLAB and SIMULINK Total Hrs 12

Toolboxes of MATLAB - Programming and file processing in MATLAB – Model definition and model analysis using SIMULINK - S-Functions - Converting SFunctions to blocks.

4 SIMULATION USING PSPICE, MATLAB and SIMULINK Total Hrs 12

Diode rectifiers -Controlled rectifiers - AC voltage controllers - DC choppers – PWM inverters – Voltage source and current source inverters - Resonant pulse inverters - Zero current switching and zero voltage switching inverters.

5 SIMULATION OF DRIVES Total Hrs 12

Simulation of speed control schemes for DC motors – Rectifier fed DC motors – Chopper fed DC motors – VSI and CSI fed AC motors – PWM Inverter – DC link inverter.


Text book(s):

1 Ramshaw. E., Schuuram D. C., “PSpice Simulation of Power Electronics Circuits – An Introductory Guide”, Springer, New York, 1996.

2 Chee-Mun Ong, "Dynamic Simulation of Electric Machinery : Using MATLAB/ Simulink", Prentice Hall PTR, New Jersey, 1998.

Reference(s) :

1 Ned Mohan, "Power Electronics: Computer Simulation Analysis and Education using PSPICE", Minnesota Power Electronics Research and Education, USA, 1992.

2 Bimal K Bose, "Power Electronics and Variable Frequency Drives", IEEE Press, New Jersey, 1996.

3 "The PSpice User's Guide", Microsim Corporation, California, 1996.





Semester II


L T P C CA ES Total

08330204S EMBEDDED SYSTEMS 3 0 0 3 50 50 100

Objective(s)

1 PIC MICROCONTROLLER 16F87X Total Hrs 9

Architecture - Features – Resets –Memory Organisations : Program Memory, Data Memory – Instruction Set – simple programs. Interrupts –I/O Ports –Timers- CCP Modules- Master Synchronous serial Port(MSSP)- USART –ADC- I2C.

2 EMBEDDED PROCESSORS Total Hrs 9

ARM processor- processor and memory organization, Data operations, Flow of Control, CPU Bus configuration, ARM Bus, Memory devices, Input/output devices, Component interfacing, designing with microprocessor development and debugging, Design Example : Alarm Clock.

3 EMBEDDED PROGRAMMING Total Hrs 9

Programming in Assembly Language(ALP) Vs High level language – C program elements, Macros and Functions – Use of pointers – NULL pointers – use of function calls – multiple function calls in a cyclic order in the main function pointers – Function queues and interrupt service Routines queues pointers – Concepts of Embedded programming in C++ - Object oriented programming – Embedded programming in C++, C program compilers – Cross compiler – optimization of memory codes.

4 EMBEDDED SYSTEM CO-DESIGN Total Hrs 9

Embedded System project management – Embedded system design and Co-Design Issues in System Development process – Design cycle in the development phase for an embedded system – Uses of Target system or its emulator and In-Circuit Emulator – Use of software Tools for Development of an embedded system – Use of scopes and logic analyzers for system hardware tests – Issues in Embedded System Design.

5 REAL-TIME OPERATING SYSTEMS Total Hrs 9

Operating system services –I/O subsystems – Network operating systems –Interrupt Routines in RTOS Environment – RTOS Task scheduling models, Interrupt – Performance Metric in Scheduling Models – IEEE standard POSIX functions for standardization of RTOS and inter-task communication functions – List of Basic functions in a Preemptive scheduler – Fifteen point strategy for nchronization between processors, ISRs, OS Functions and Tasks – OS security issues- Mobile OS.


Text book(s):

1 Raj Kamal , Embedded Systems Architecture, Programming and Design, Tata McGraw-Hill, New Delhi, 2003.

2 Wayne Wolf, Computers as Components: Principles of Embedded Computing System Design, Morgan Kaufman Publishers, 2001.

Reference(s) :

1 Frank Vahid and Tony Givargi Embedded System Design: A Unified Hardware/Software Introduction, s, John Wiley & Sons, 2000.

2 John B Peatman, Design with PIC Microcontrollers, Prentice Hall of India, 2007.

3 Ajay V Deshmukh Microcontroller Theory and Applications, Tata McGraw Hill, 2007.



Department Electrical & Electronics Engineering Programme Code

& Name 33 : M.E. Power Electronics &

Drives

Semester II

Course Code Course Name Hours / Week Credit Maximum marks

L T P C CA ES Total

08330207P POWER ELECTRONICS & DRIVES LABORATORY

0 0 3 2 50 50 100

1. Analysis of Dual Converter Fed DC Motor Drive Total Hrs 3

2. Chopper Fed DC Drive Total Hrs 3

3. DSP controlled AC drive Total Hrs 3

4. Performance study of Stator Voltage Controlled Induction Motor Drive Total Hrs 3

5. Analysis of Vector Controlled Induction Motor Drive Total Hrs 3

6. Harmonic Analysis of Converter Fed Drive Total Hrs 3

7. IGBT Based Three Phase PWM Inverter Total Hrs 3

8. IGBT Based Three Phase SVPWM Inverter Total Hrs 3

9. Simulation of Power Electronic Systems using PSpice Total Hrs 3

10. Modeling and Simulation of Electric Drives using MATLAB Total Hrs 3





Engineering Programme Code & Name


Semester II

Course Code Course Name Hours / Week

Credit

Maximum Marks

L T P CA ES Total

08330208P TECHNICAL REPORT PREPARATION AND PRESENTATION I

0 0 3 2 50 50 100

Objective(s) To provide exposure to the students to refer, read and review the research articles in referred journals and conference proceedings, technical report writing and presentation skills of the students.

Methodology

Each student is allotted to a faculty of the department by the HOD By mutual discussions, the faculty guide will assign a topic in the general / subject

area to the student. The students have to refer the Journals and Conference proceedings and collect the

published literature. The student is expected to collect atleast 20 such Research Papers published in the

last 5 years. Using OHP/Power Point, the student has to make presentation for 15-20 minutes

followed by 10 minutes discussion. The student has make two presentations, one at the middle and the other near the

end of the semester. The student has to write a Technical Report for about 30-50 pages (Title page, One

page Abstract, Review of Research paper under various subheadings, Concluding Remarks and List of References). The technical report has to be submitted to the HOD one week before the final presentation, after the approval of the faculty guide.

Execution

Week Activity

I Allotment of Faculty Guide by the HoD

II Finalizing the topic with the approval of Faculty Guide

III-IV Collection of Technical papers

V-VI Mid semester presentation

VII-VIII Report writing

IX Report submission

X-XI Final presentation

Evaluation

50% by Continuous Assessment and 50% by End Semester examination 3 Hrs/week and 2 credits

Component Weightage

Mid semester presentation 25%

Final presentation (Internal) 25%

End Semester Examination Report 30%

Presentation 20%

Total 100%




Engineering Programme Code & Name


Semester III

Course Code Course Name Hours / Week

Credit

Maximum Marks

L T P CA ES Total

08330304P TECHNICAL REPORT PREPARATION AND PRESENTATION II

0 0 3 2 50 50 100

Objective(s) To provide exposure to the students to refer, read and review the research articles in referred journals and conference proceedings. To improve the technical report writing and presentation skills of the students.

Methodology

Each student is allotted to a faculty of the department by the HOD By mutual discussions, the faculty guide will assign a topic in the general / subject

area to the student. The students have to refer the Journals and Conference proceedings and collect the

published literature. The student is expected to collect atleast 20 such Research Papers published in the

last 5 years. Using OHP/Power Point, the student has to make presentation for 15-20 minutes

followed by 10 minutes discussion. The student has make two presentations, one at the middle and the other near the

end of the semester. The student has to write a Technical Report for about 30-50 pages (Title page, One

page Abstract, Review of Research paper under various subheadings, Concluding Remarks and List of References). The technical report has to be submitted to the HOD one week before the final presentation, after the approval of the faculty guide.

Execution

Week Activity

I Allotment of Faculty Guide by the HoD

II Finalizing the topic with the approval of Faculty Guide

III-IV Collection of Technical papers

V-VI Mid semester presentation

VII-VIII Report writing

IX Report submission

X-XI Final presentation

Evaluation

50% by Continuous Assessment and 50% by End Semester examination 3 Hrs/week and 2 credits

Component Weightage

Mid semester presentation 25%

Final presentation (Internal) 25%

End Semester Examination Report 30%

Presentation 20%

Total 100%



Department Electrical and Electronics Engineering Programme

Code & Name 33: M.E. Power

Electronics and Drives

Semester I


L T P C CA ES Total

08330141E HIGH VOLTAGE DIRECT CURRENT TRANSMISSION

3 0 0 3 50 50 100

Objective(s) To study the general aspeers of HVDC system, Power Electric Circuits used in HVDC system, the protection of HVDC system againer faults Harmonios in HVDC as their reduction and the simulation of HVDC system.

1 GENERAL ASPECTS Total Hrs 9

Historical development of HVAC and DC links – kinds of DC links-HVDC projects in India and abroad – advantages and disadvantages of HVDC transmission -Applications of DC transmission – economic factors – development of power devices for HVDC transmission – thyristors – light activated thyristors – MOS controlled thyristors (MCTs) –Switching and steady state characteristics–Cooling of Thyristors Problem.

2 THYRISTOR CONVERTERS Total Hrs 10

Three phase fully controlled thyristor bridge converters – operation as rectifiers and line commutated inverters – converter equivalent circuits – parameters and characteristics of rectifiers and inverters – series and parallel arrangement of thyristors – multibridge converters.

3 CONTROL OF CONVERTERS AND REACTIVE POWER CONTROL

Total Hrs 9

Gate control – basic means of control and modes of operation – power reversal –desired features of control – control characteristics – constant current control –constant extinction angle control – stability of control – tap changer control – power control and current limits. Reactive Power Requirements – Reactive Power Control during Steady State and Transients.

4 PROTECTION OF HVDC SYSTEMS, HARMONICS, FILTERS AND GROUND RETURN

Total Hrs 9

Basics of protection of HVDC systems – DC reactors – voltage and current oscillations – DC line oscillations – clearing line faults and re-energizing the line –circuit breakers – over voltage protection -Characteristics and uncharacteristics harmonics – troubles caused by harmonics – means of reducing harmonics ––harmonic filters – Corona and Radio interference- ground return and ground Electrodes.

5 SIMULATION OF HVDC SYSTEMS Total Hrs 8

Introduction – System Simulation: Philosophy and Tools – HVDC System Simulation – Modeling of HVDC Systems for Digital Dynamic Simulation – Digital Dynamic Simulation of Converters and DC Systems


Text book (s):

1 Kimbark E.X., “Direct Current Transmission”, Vol. I, Wiley Interscience, New York 1971.

2 Allan Greenwood, „Electrical Transients in Power Systems‟, John Wiley and Sons New York, 1992.

Reference (s):

1 Kory(ed) B. J., “ High Voltage Direct Current Converters and Systems”. Macdonald & Co, London 1995.

2 Adamson and Hingorani N.G., “High Voltage Direct Current Power Transmission”, Garraway ltd., England, 1960.






Semester I


L T P C CA ES Total

08330142E NON CONVENTIONAL ENERGY SOURCES

3 0 0 3 50 50 100

Objective(s) To study variable energy resources like solar energy, wind energy etc.,

1 SOLAR ENERGY Total Hrs 9

Introduction to solar energy: solar radiation, availability, measurement and estimation – Solar thermal conversion devices and storage – solar cells and photovoltaic conversion – PV systems – MPPT. Applications of PV Systems – solar energy collectors and storages.

2 WIND ENERGY Total Hrs 9

Introduction – Basic principles of wind energy conversion – wind data and energy estimation – site selection consideration – basic components of wind energy conversion system –Types of wind machines – basic components of wind electric conversion systems. Schemes for electric generations – generator control, load control, energy storage – applications of wind energy – Inter connected systems.

3 CHEMICAL ENERGY SOURCES Total Hrs 9

Introduction – fuel cells – design and principles of operation of a fuel cell – classification of fuel cells. Types of fuel cells – conversion efficiency of fuel cells. Types of electrodes, work output and emf of fuel cell, Applications of fuel cells. Hydrogen energy: Introduction – hydrogen production – electrolysis, thermo chemical methods, Westing House Electro-chemical thermal sulphur cycle. Fossil fuel methods. Hydrogen storage, Utilization of hydrogen gas.

4 ENERGY FROM OCEANS Total Hrs 9

Introduction, ocean thermal electric conversion (OTEC), methods of ocean thermal electric power generation, open cycle OTEC system, closed OTEC cycle. Energy from tides: Basic principles of tidal power, component of tidal power plants, operation methods of utilization of tidal energy, site requirements, storage, advantages and limitations of tidal power generation. Ocean waves, energy and power from the waves, wave energy conversion devices.

5 GEOTHERMAL ENERGY Total Hrs 9

Introduction, estimation of geothermal power, nature of geothermal fields, geothermal sources, inter connection of geothermal fossil systems, prime movers for geo thermal energy conversion. Application of geothermal energy. Energy from biomass: Introduction, Biomass conversion technologies, photosynthesis, classification of biogas plants. Biomass Energy conversion, Energy from waste.


Text book (s):

1. SP Sukatme, “Solar Energy – Principles of thermal collection and storage, second edition, Tata McGraw Hill, 1991.

2. GD Rai, “Non Conventional Energy Sources”, khanna Publishers, New Delhi.

Reference (s):

1. J.A. Duffie and W.A. Beckman, “Solar Engineering of Thermal Processes”, Second Edition, John Wiley, New York, 1991.

2. D.Y. Goswami, F. Kreith and J.F. Kreider, “Principles of Solar Engineering, Taylor and Francis, Philadelphia, 2000.

3. D.D. Hall and R.P. Grover, “Bio-Mass Regenerable Energy, John Wiley, Newyork, 1987.

4. J. Twidell and T. Weir, “ Renewable Energy Resources”, E&FN Spon Ltd., London, 1986.






Semester I


L T P C CA ES Total

08330143E ADVANCED DIGITAL SYSTEM DESIGN

3 0 0 3 50 50 100

Objective(s) To learn the design of digital control algorithms, and the programming language for digital control.

1 SEQUENTIAL LOGIC OPTIMIZATION Total Hrs 9

Sequential Circuit Optimization Using State Based Models, Sequential Circuit Optimization Using Network Models, Implicit Finite State machine Traversal Methods, Testability Considerations for Synchronous Circuits.

2 ASYNCHRONOUS FINITE STATE MACHINES Total Hrs 9

Scope, Asynchronous Analysis, Design of Asynchronous Machines, Cycle and Races, Plotting and Reading the Excitation Map, Hazards, Essential Hazards Map Entered Variable, MEV Approaches to Asynchronous Design, Hazards in Circuit Developed by MEV Method.

3 DIGITAL SYSTEM TESTING Total Hrs 9

Fault Models, Fault Equivalence, Fault Location, Fault Dominance, Single and Multiple Stack Faults, Testing for Single Stack Faults, Algorithms, Random test Generation, Adhoc Design for Testability Techniques, Classical Scan Designs, Boundary Scan Standards, Built-In-Self-Test, Test Pattern Generation, BIST Architecture examples.

4 HIGH SPEED DIGITAL DESIGN Total Hrs 9

Frequency, Time and Distance, Capacitance and Inductance Effects, High Speed Properties of Logical Gates, Speed And Power, Measurement Techniques, Rise Time and Bandwidth of Oscilloscope probes, Self Inductance , Signal pickup and loading effects of probes, clock distribution, clock skew and methods to reduce skew, Controlling crosstalk on clock lines, Delay adjustments, Clock oscillators and clock jitter.

5 SYSTEM DESIGN USING VHDL Total Hrs 9

Specification of combinational systems using VHDL, Basic language element of VHDL, Types of Modeling, Design of serial adder with accumulator, State graph for Control network, Design of Binary Multiplier and Binary Divider, Flip-Flops, Registers, Counters, Sequential Machines, Combinational Logic Circuits.


Text book (s):

1 Fletcher, “An Engineering Approach to Digital Design”, PHI 2004.

2 Parag K Lala , “Digital Circuit Testing And Testability”, Academic 1997.

Reference (s):

1 Miron Abramovici et. al, “Digital System Testing And Testable Design”, Jaico Publishing House 2001.

2 Howard Johnson and Martin Graham, High Speed Digital Design : Handbook of Black Magic, PHI PTR.

3 Masakazu Shoji, “High Speed Digital Circuits”, Addison Wesley Publishing Co.

4 J.Bhaskar, “A VHDL Primer”, Addison Wesley 1999.

5 C.H.Roth, “Digital System using VHDL”, PWS Publishing.

6 Z.Navabi, “VHDL-Analysis And Modeling of Digital Systems”, MGH.






Semester I


L T P C CA ES Total

08330144E DIGITAL SIGNAL PROCESSING 3 0 0 3 50 50 100

Objective(s)

To classify signals and systems & their mathematical representation. To analyse the discrete time systems. To study various transformation techniques & their computation. To study about filters and their design for digital implementation. To study about a programmable digital signal processor & quantization effects.

1 DISCRETE TIME SIGNALS AND SYSTEMS Total Hrs 9

Representation of discrete time signal – classifications – Discrete time – system – Basic operations on sequence – linear – Time invariant – causal – stable – solution to difference equation – convolution sum – correlation – Discrete time Fourier series – Discrete time Fourier transform.

2 FOURIER AND STRUCTURE REALIZATION Total Hrs 9

Discrete Fourier transform – properties – Fast Fourier transform – Z-transform – structure realization – Direct form – lattice structure for FIR filter – Lattice structure for IIR Filter.

3 FILTERS Total Hrs 9

FIR Filter – windowing technique – optimum equiripple linear phase FIR filter – IIR filter – Bilinear transformation technique – impulse invariance method – Butterworth filter – chebyshev filter.

4 MULTISTAGE REPRESENTATION Total Hrs 9

Sampling of band pass signal – antialiasing filter – Decimation by an integer factor – interpolation by an integer factor – sampling rate conversion – implementation of digital filter banks – sub-band coding – Quadrature mirror filter – A/D conversion – Quantization – coding – D/A conversion – Introduction to wavelets.

5 DIGITAL SIGNAL PROCESSORS Total Hrs 9

Fundamentals of fixed point DSP architecture – Fixed point number representation and computation – Fundamentals of floating point DSP architecture – floating point number representation and computation – study of TMS 320 C 50 processor – Basic programming – addition – subtraction – multiplication – convolution – correlation – study of TMS 320 C 54 processor – Basic programming – addition – subtraction – multiplication – convolution – correlation.


Text book (s):

1 John G.Proakis, Dimitris G.Manolakis, “Digital Signal Processing: Principles, Algorithms and Applications”, PHI.

2 B.Venkatramani & M.Bhaskar, “Digital Signal Processors architecture, Programming and Applications”, TMH, 2002.

Reference (s):

1 A.V. Oppenheim and R.W.Schafer, Englewood “Digital Signal Processing”, Prentice- Hall, Inc, 1975.

2 Rabiner and Gold, “Theory and Application of Digital Signal Processing”, A comprehensive, Industrial – Strength DSP reference book.

3 S.Salivahanan, A.Vallavaraj and C.Gnanapriya “Digital Signal Processing”, TMH, 2000.






Semester I


L T P C CA ES Total

08330145E SOFTWARE ENGINEERING 3 0 0 3 50 50 100

Objective(s) To learn the basics and requirements of Software Engineering, the architecture and design of software and the software cost estimation.

1 OVERVIEW OF SOFTWARE ENGINEERING Total Hrs 9

Introduction – FAQs about Software Engineering – Professional and Ethical responsibility – Computer-based system engineering – Emerging system properties – System and their environment – System modeling – System engineering process – System procurement. Software processes – Process models – Process iteration – Software specification – Software design – Software Validation – Software evolution – Automated process support. Project management – Management activities – Project planning – Project scheduling – Risk management.

2 REQUIREMENTS Total Hrs 9

Functional and non-functional requirements – User requirements – System requirements – Software requirements document – Requirements engineering processes – Feasibility studies – Requirements elicitation and analysis – Requirements – validation - Requirements management. System models – Context models – Behavioral models – Data models – Object Models – CASE workbenches. Software prototyping – Prototyping in the software process – Rapid prototyping techniques – User interface prototyping. Formal specification – Formal specification in the software process – Interface specification – Behavioral specification.

3 ARCHITECTURE AND SOFTWARE DESIGN Total Hrs 9

System structuring -Repository model – Client server model – Abstract machine model – Control models – Modular decomposition – Domain-specific software architecture – Distributed system architectures – multiprocessor architectures – client server architectures – CORBA. Object-oriented design – Objects and object classes – Object oriented design process – Design evolution. Real-time software design – System design – Real-time executives – Monitoring and control systems. Design with reuse – Component-based development – Application families – Design patterns. User interface design – User interface design principles – User interaction – Information presentation – User support interface evaluation.

4 CRITICAL SYSTEMS AND DEPENDABILITY Total Hrs 9

Critical systems – Availability and reliability – Safety – Security. Critical systems specification and development – Software reliability specification – Safety specification – Security specification – Fault minimization – Fault tolerance – Fault-tolerant architectures – Safe system design. Verification and Validation planning – Automated static analysis – Clean room software development. Software testing – Defect testing – Integration testing – Object oriented testing – Testing workbenches. Critical systems validation – Formal methods and critical systems – Reliability validation – Safety assurance – Security assessment.

5 SOFTWARE COST ESTIMATION Total Hrs 9

Productivity – Estimation techniques – Algorithmic cost modeling – Project duration and staffing. Quality management – Quality assurance and standards – Quality planning - Quality control – Software measurement and metrics. Process improvement – Process and Product Quality – Process analysis and modeling – Process measurement – The SEI process Capability Maturity Model – Process classification.

Total hours to be taught Total: 45

Text book (s):

1 Ian Sommerville, “Software Engineering”, Sixth Edition, Pearson Education, 2001.

Reference (s):

1 Jawadekar, “Software Engineering”, Tata McGraw-Hill, 2004.

2 Fairley, “Software Engineering Concepts”, Tata McGraw Hill, 2004.






Semester I


L T P C CA ES Total

08330146E FINITE ELEMENT ANALYSIS 3 0 0 3 50 50 100

Objective(s) To study the concept of basic concept of FEM. To study the solution of plane elasticity problem and parametric formulation.

1 1D FINITE ELEMENT ANALYSIS Total Hrs 9

Historical Background - Weighted Residual Methods - Basic Concepts of FEM - Variational Formulation of B.V.P - Ritz Method - Finite Element Modeling - Element Equations - Linear and Quadratic Shape functions - Bar, Beam Elements - Applications to Heat Transfer.

2 FINITE ELEMENT ANALYSIS OF 2D PROBLEMS Total Hrs 9

Basic Boundary Value Problems in 2 Dimentions - Triangular, quadrilateral, higher order elements - Poissons and Laplace Equations - Weak Formulation - Elements Matrices and Vectors - Application to Solid mechanics, Heat transfer, Fluid Mechanics.

3 ISO PARAMETRIC FORMULATION Total Hrs 9

Natural Co-ordinate System - Lagrangian Interpolation Polynomials - Iso-parametric Elements - Formulation - Numerical Intergration - 1D -2D Triangular elements - rectangular elements - Illustrative Examples.

4 SOLUTION TO PLANE ELASTICITY PROBLEMS Total Hrs 9

Introduction to Theory of Elasticity - Plane Stress - Plane Strain and Axisymmetric Formulation - Principle of virtual work - Element matrices using energy approach.

5 SPECIAL TOPICS Total Hrs 9

Dynamic Analysis - Equation of Motion - Mass Matrices - Free Vibration analysis - Natural frequencies of Longitudinal - Transverse and torsional vibration - Introduction to transient field problems. Non linear analysis. Use of software - h & p elements - special element formulation.


Text book (s):

1 Reddy J.N. "An Introduction to the Finite Element Method" , Mc Graw Hill, International Edition, 1993.

Reference (s):

1 Segerlind L.J., "Applied Finite Element Analysis" , John Wiley, 1984.

2 Rao S.S., "Finite Element Method in Engineering", Pergamon Press, 1989.

3 Chandrupatla & Belagundu , " Finite Elements in Engineering ", Prentice Hall of India Private Ltd., 1997.

4 1. http://www.vector-space.com 2. http://www.mech.port.ac.uk/sdalby/mbm/CTFRProg.htm






Semester I


L T P C CA ES Total

08330147E LINEAR AND NON LINEAR SYSTEM THEORY

3 0 0 3 50 50 100

Objective(s) To study the concept of states space representation of a system. To study the behavior of linear & non-linear system and analysis of their stability.

1 PHYSICAL SYSTEMS AND STATE ASSIGNMENT Total Hrs 9

Systems: Electrical - Mechanical – Hydraulic – Pneumatic – Thermal systems –Modelling of some typical systems like DC Machines - Inverted Pendulum.

2 STATE SPACE ANALYSIS Total Hrs 9

Realisation of State models – Non-uniqueness - Minimal realisation – Balanced realisation – Solution of state equations: – State transition matrix and its properties - Free and forced responses – Properties: Controllability and observability- Stabilisability and detectability – Kalman decomposition.

3 MIMO SYSTEMS –FREQUENCY DOMAIN DESCRIPTIONS Total Hrs 9

Properties of transfer functions – Impulse response matrices – Poles and zeros of transfer function matrices – Critical frequencies – Resonance – Steady state and dynamic response – Bandwidth- Nyquist plots-Singular value analysis.

4 NON-LINEAR SYSTEMS Total Hrs 9

Types of non-linearity – Typical examples – Equivalent linearization - Phase plane analysis – Limit cycles – Describing functions- Analysis using Describing functions- Jump resonance.

5 STABILITY Total Hrs 9

Stability concepts – Equilibrium points – BIBO and asymptotic stability – Direct method of Liapunov – Application to non-linear problems – Frequency domain stability criteria – Popov‟s method and its extensions.


Text book (s):

1 M.Gopal, “Modern Control Engineering”, Wiley, 1996.

2 J.S. Bay, “ Linear State Space Systems”, McGraw-Hill, 1999.

Reference (s):

1 K. Ogatta, “Modern Control Engineering”, Pearson Education Asia, Low priced Edition, 1997.

2 G.J.Thaler, “Automatic control systems”, Jaico publishers, 1993.

3 Eroni-Umez and Eroni, “ System dynamics & Control”, Thomson Brooks/ Cole, 1998.






Semester I


L T P C CA ES Total

08330148E DIGITAL INSTRUMENTATION 3 0 0 3 50 50 100

Objective(s) To learn the concept of digital principles, digital Instrumentation setup to measure various parameters and the recent rends in digital instrumentation.


Digital codes – Memory devices – Basic building blocks – Gates, FF and counters – Discrete data handling – Sampling – Sampling theorem – Aliasing errors – Reconstruction – Extrapolation – Synchronous and asynchronous sampling.

2 DIGITAL METHODS OF MEASUREMENTS Total Hrs 12

Review of A/D, D/A techniques – F/V and V/F conversion techniques – Digital voltmeters and multimeters – Automation and accuracy of digital voltmeters and multimeters – Digital phase meters – Digital tachometers – Digital frequency, period and time measurements – Low frequency measurements – Automatic time and frequency scaling – Sources of error – Noise – Inherent error in digital meters, hidden errors in conventional ac measurements – RMS detector in digital multimeters – Mathematical aspects of RMS.

3 DIGITAL DISPLAY & RECORDING DEVICES Total Hrs 8

Digital storage oscilloscopes – Digital printers and plotters – CDROMS – Digital magnetic tapes, dot matrix and LCD display CROs, colour monitor, digital signal analyser and digital data acquisition.

4 SIGNAL ANALYSIS Total Hrs 8

Amplifiers, filters, transmitter, receiver, wireless base and mobile station test sets, noise figures meters, RF network analyser and high frequency signal sources.

5 CURRENT TRENDS IN DIGITAL INSTRUMENTATION Total Hrs 8

Introduction to special function add on cards – Resistance card – Input and output cards – Counter, test and time of card and digital equipment construction with modular designing; interfacing to microprocessor, micro controllers and computers - Computer aided software engineering tools (CASE) – Use of CASE tools in design and development of automated measuring systems – Interfacing IEEE cards – Intelligent and programmable instruments using computers.


Text book (s):

1 Bouwens, A.J., “Digital Instrumentation”, McGraw Hill, 1984.

Reference (s):

1 John Lenk, D., “Handbook of Micro computer based Instrumentation and Control”, PHI, 1984.

2 Doebelin, „Measurement System, Application & Design‟, IV Ed, McGraw-Hill, 1990.






Semester II


L T P C CA ES Total

08330261E INTELLIGENT CONTROL 3 0 0 3 50 50 100

Objective(s) To introduce the various artificial intelligent techniques like Artificial Neural Network, Genetic algorithm and Fuzzy logic system and their applications to power system. To learn the usage of MATLAB tool box to the above intelligent techniques.


Approaches to intelligent control, Architecture for intelligent control, Symbolic reasoning system, rule-based systems, the AI approach, Knowledge representation, Expert systems.

2 ARTIFICIAL NEURAL NETWORKS Total Hrs 9

Concept of Artificial Neural Networks and its basic mathematical model, McCulloch-Pitts neuron model, simple perceptron, Adaline and Madaline, Feed-forward Multilayer Perceptron. Learning and Training the neural network. Data Processing: Scaling, Fourier transformation, principal-component analysis and wavelet transformations. Hopfield network, Self-organizing network and Recurrent network. Neural Network based controller.

3 GENETIC ALGORITHM Total Hrs 9

Basic concept of Genetic algorithm and detail algorithmic steps, adjustment of free parameters, Solution of typical control problems using genetic algorithm. Concept on some other search techniques like tabu search and ant-colony search techniques for solving optimization problems.

4 FUZZY LOGIC SYSTEM Total Hrs 9

Introduction to crisp sets and fuzzy sets, basic fuzzy set operations and approximate reasoning. Introduction to fuzzy logic modeling and control. Fuzzification, inferencing and defuzzification. Fuzzy knowledge and rule bases. Fuzzy modeling and control schemes for nonlinear systems. Self-organizing fuzzy logic control. Fuzzy logic control for nonlinear time-delay system.

5 APPLICATIONS Total Hrs 9

GA application to power system optimisation problem, Case studies: Identification and control of linear and nonlinear dynamic systems using Matlab-Neural Network toolbox. Stability analysis of Neural-Network interconnection systems. Implementation of fuzzy logic controller using Matlab fuzzy-logic toolbox. Stability analysis of fuzzy control systems.


Text book (s):

1 Jacek.M.Zurada, "Introduction to Artificial Neural Systems", Jaico Publishing House, 1999.

2 KOSKO, B. "Neural Networks and Fuzzy Systems", Prentice-Hall of India Pvt. Ltd., 1994.

Reference (s):

1 KLIR G.J. & FOLGER T.A. "Fuzzy sets, uncertainty and Information", Prentice-Hall of India Pvt. Ltd., 1993.

2 Zimmerman H.J. "Fuzzy set theory-and its Applications"-Kluwer Academic Publishers, 1994.

3 Driankov, Hellendroon, "Introduction to Fuzzy Control", Narosa Publishers.






Semester II


L T P C CA ES Total

08330262E DSP CONTROLLER FOR POWER ELECTRONICS APPLICATION

3 0 0 3 50 50 100

Objective(s) To study the special processor for electrical drives and interface with digital signal processors


Fourier Transform – DFT – FFT – Signal processing – Digital filters – FIR and IIR filters – Need for special hardware for DSP

2 TEXAS PROCESSORS FOR DSPI Total Hrs 9

Architecture – Addressing modes – Instruction set – Programming – Peripherals – memory – Applications.

3 ANALOG DEVICES PROCESSORS FOR DSP Total Hrs 9

Architecture – Addressing modes – Instruction set – Programming – Peripherals – memory – Applications

4 INTERFACE WITH DIGITAL SIGNAL PROCESSORS Total Hrs 9

Digital and analog Interface – Host interface – Memory interface – DMA ports – Serial ports.

5 SPECIAL PROCESSORS FOR MOTOR CONTROL Total Hrs 9

Programs and special features for motor control – PWM generation – Fuzzy and neural control – Online simulation – Programs for PID controllers and compensators.


Text book (s):

1 Emmanuel C. Ifeachor, Barrie W. Jervis, “ Digital signal processing – A practical approach”, Second edition, Pearson education, Asia 2001.

2 Rabiner and Gold, “Theory and Application of Digital Signal Processing”, A comprehensive, Industrial – Strength DSP reference book.

Reference (s):

1 A.V.Oppenheim et.al, „Discrete-time Signal Processing‟ Pearson education, 2000.

2 Lars Wanhammer, “DSP Integrated Circuits”, Academic press, New York 1999.

3 Texas Instruments – Manuals






Semester II


L T P C CA ES Total

08330263E FLEXIBLE AC TRANSMISSION SYSTEM

3 0 0 3 50 50 100

Objective(s) To learn the implementation of power electronics in power systems. To study the advanced methodology to control the power flow.


FACTS-a toolkit, Basic concepts of Static VAR compensator, Resonance damper, Thyristor controlled series capacitor, Static condenser, Phase angle regulator, and other controllers.

2 SERIES COMPENSATION SCHEMES Total Hrs 9

Sub-Synchronous resonance, Torsional interaction, torsional torque, Compensation of conventional, ASC, NGH damping schemes, Modelling and control of thyristor controlled series compensators.

3 UNIFIED POWER FLOW CONTROL Total Hrs 9

Introduction, Implementation of power flow control using conventional thyristors, Unified power flow concept, Implementation of unified power flow controller.

4 DESIGN OF FACTS CONTROLLERS Total Hrs 9

Approximate multi-model decomposition, Variable structure FACTS controllers for Power system transient stability, Non-linear variable-structure control, variable structure series capacitor control, and variable structure resistor control.

5 STATIC VAR COMPENSATION Total Hrs 9

Basic concepts, Thyristor controlled reactor (TCR), Thyristors switched reactor (TSR), Thyristor switched capacitor (TSC), saturated reactor (SR), Fixed Capacitor (FC).


Text book (s):

1 Narin G.Hingorani, "Flexible AC Transmission ", IEEE Spectrum, April 1993, pp 40-45.

2 Narin G. Hingorani, "High Power Electronics and Flexible AC Transmission Systems IEEE High Power Engineering Review, 1998.

Reference (s):

1 Narin G.Hingorani, " Power Electronics in Electric Utilities: Role of Power Electronics infuture power systems ", Proc. of IEEE, Vol.76, no.4, April 1988.

2 Einar V.Larsen, Juan J. Sanchez-Gasca, Joe H.Chow, " Concepts for design of FACTS Controllers to damp power swings ", IEEE Trans On Power Systems, Vol.10, No.2, May 1995.

3 Gyugyi L., "Unified power flow control concept for flexible AC transmission ", IEEE Proc-C Vol.139, No.4, July 1992.






Semester II


L T P C CA ES Total

08330264E VLSI DESIGN 3 0 0 3 50 50 100

Objective(s) To study the MOS circuits design process and digital circuit and systems. To study the analog VLSI and high speed VLSI.

1 MOS TECHNOLOGY AND CIRCUITS Total Hrs 9

MOS Technology and VLSI, Process parameters and considerations for BJT, MOS and CMOS, Electrical properties of MOS circuits and Device modeling.

2 MOS CIRCUIT DESIGN PROCESS Total Hrs 9

MOS Layers, Stick diagram, Layout diagram, Propagation delays, Examples of combinational logic design, Sealing of MOS circuits.

3 DIGITAL CIRCUITS AND SYSTEMS Total Hrs 9

Programmable Logic Array ( PLA ) and Finite State Machines, Design of ALUs, Memories and Registers.

4 ANALOG VLSI AND HIGH SPEED VLSI Total Hrs 9

Introduction to Analog VLSI, Realisation of Neural Networks and Switched capacitor filters, Sub-micron technology and GaAs VLSI technology.

5 HARDWARE DESCRIPTION LANGUAGES Total Hrs 9

VHDL background and basic concepts, Structural specifications of hardware design organisation and parametrisation.


Text book (s):

1 Douglas A. Pucknell and Kamran Eshraghian, Basic VLSI Design Systems and Circuits, Prentice Hall of India Pvt Ltd., 1993.

2 Wayne Wolf, Modern VLSI Design, 2nd Edition, Prentice Hall,1998.

Reference (s):

1 Amar Mukherjee, Introduction to NMOS and CMOS VLSI System Design, Prentice Hall, 1986.

2 Randall .L.Geiger and P.E. Allen, VLSI Design Techniques for Analog and Digital Circuits, McGraw Hill International Company, 1990.

3 Fabricious. E , Introduction to VLSI Design, McGraw Hill, 1990.

4 Navabi .Z., VHDL Analysis and Modeling of Digital Systems, McGraw Hill, 1993.






Semester II


L T P C CA ES Total

08330265E OPERATING SYSTEMS 3 0 0 3 50 50 100

Objective(s) To study the basics of operating systems. To learn the process synchronization, memory management and disk scheduling approaches in operating systems. To study the case studies in operating systems.

1 Unit I Total Hrs 9

Introduction – Operating systems and services – Processes – CPU Scheduling approaches.

2 Unit II Total Hrs 9

Process synchronization – Semaphores – Deadlocks – Handling deadlocks – Multithreading.

3 Unit III Total Hrs 9

Memory management – Paging – Segmentation – Virtual memory – Demand paging – Replacement algorithms.

4 Unit IV Total Hrs 9

Disk Scheduling approaches – File systems – Design issues – User interfaces to file systems – I / O device management.

5 Unit V Total Hrs 9

Case study – Design and implementation of the UNIX OS, process model and Structure – Memory management – File system – UNIX I / O management and Device drivers – Windows – System components – Process management – Memory management – File systems – Networking


Text book (s):

1 Abraham Silberschatz Peter B. Galvin, G.Gagne, “Operating System Concepts”, 6th Edition, Wesley

Publishing company, 2003.

Reference (s):

1 M.J.Bach, Design of the UNIX Operating System, Prentice Hall, 1986.






Semester II


L T P C CA ES Total

08330266E

OBJECT ORIENTED PROGRAMMING AND ITS APPLICATIONS TO ELECTRICAL ENGINEERING

3 0 0 3 50 50 100

Objective(s) To study fundamental of object oriented programming and advanced features

1 OBJECT ORIENTED PROGRAMMING PARADIGM Total Hrs 9

Introduction - reusability - security - object oriented programming fundamentals - abstraction - encapsulation - derivation - object oriented languages and packages.

2 CLASSES AND OBJECTS Total Hrs 9

Introduction to C++ - procedural oriented approach to C++ - data types - control structures - problem solving - standard input and output streams - C++ enhancements - function prototypes - default reference variables - constants - classes - constructors - destructors - constraint objects - member objects and the functions.

3 ADVANCED FEATURES Total Hrs 9

Dynamic memory allocation pointers - new and delete operators - classes with pointers - copy constructor - static member - friend classes - friend functions - operator overloading.

4 POLYMORPHISM AND INHERITANCE Total Hrs 9

Function overloading - connection classes - derived classes - class conversion -protected members – virtual functions - dynamic binding - abstract classes - multiple inheritance - templates - error handling.

5 CASE STUDIES Total Hrs 9

Overview of typical object oriented systems - case studies - application to electrical engineering.


Text book (s):

1 Stanley B. Lipman, "C++ primer ", Addison Wesley, 1989.

Reference (s):

1 K.R. Dittrich et al, "On object oriented data base system ", Springer verlag, 1991.

2 Bertrand Meyar, "Object software construction ", Prentice Hall, 1988.






Semester III


L T P C CA ES Total

08330381E COMPUTER COMMUNICATION AND NETWORKS

3 0 0 3 50 50 100

Objective(s) To expose the students in the area of Computer Networks, Network transport layers, Queuing theory, presentation layer and application layer.

1 COMPUTER NETWORKS Total Hrs 9

Evolution of data networks, Network architecture, OSI Reference model examples of networks, Application of networks, Physical layer, and communication medium characteristics.

2 MEDIUM ACCESS SUB LAYER AND DATA LINK LAYER Total Hrs 9

Local area networks, conventional channel allocation methods, pure-ALOHA, SALOHA, Finite population ALOHA, Controlled ALOHA, Reservation ALOHA, Design issues for packet radio networks – IEEE Standard for LAN-Ethernet: CSMA/CD LAN, Token passing ring. Data link layer design issues – Service primitives – Stop and wait Sliding window protocols – Comparison of stop and wait and sliding window protocols.

3 NETWORK AND TRANSPORT LAYERS Total Hrs 9

Network layer design issues Routing algorithm - Congestion control algorithms internetworking. Transport layer design issues – Connection management – A simple transport protocol on top of X.25.

4 QUEUING THEORY AND CAPACITY ASSIGNMENT Total Hrs 9

M/M/I Queues/G/I Queues, priority queuing capacity assignment for terminal networks and distributed networks, concentration and buffering for finite and infinite buffers ad block storage.

5 PRESENTATION LAYER AND APPLICATION LAYER Total Hrs 9

Design issues – Abstract syntax notation – Data compression techniques – Cryptography – Remote procedure call - Design Issues – File transfer access and management, Electronic mail – Virtual terminals – Other applications.


Text book (s):

1 Andrew S.Tanenbaum, “Computer Networks”, 4th Edition, Prentice Hall of India, 2003.

2 D.Bertsekas and R.Gallager, “Data networks”, 2nd Edition, Prentice Hall of India, 2003.

Reference (s):

1 Godbole and Kahate, “Computer Communication Networks (Ascent Series)”, McGraw Hill, 2003.

2 M.Schwartz, “Computer Communications”, Tata McGraw Hill, 2002.

3 Achyut S Godbole, “Data Communications and Networking”, Tata McGraw Hill, 2002.






Semester III


L T P C CA ES Total

08330382E ADVANCES IN POWER ELECTRONICS

3 0 0 3 50 50 100

Objective(s) To study the basic concept of FACTS and application power electronics. To study the modeling, analysis, and emerging devices and circuits of power electronics.

1 RESONANT CONVERTERS Total Hrs 9

Zero voltage and Zero current switching – Classification of resonant converters - Basic resonant circuit concepts - Load resonant converters - Resonant switch converters - Zero voltage switching, clamped voltage topologies -Resonant DC link Inverters and Zero voltage switching - High frequency link integral half cycle converters - Applications in SMPS and lighting.

2 IMPROVED UTILITY INTERFACE Total Hrs 9

Generation of current harmonics – Current harmonics and power factor – Harmonic standards and recommended practices - Need for improved utility interface - Improved single phase utility interface - Improved three phase utility interface - Electromagnetic interference.

3 FACTS Total Hrs 9

Introduction - Principles of reactive power control in load and transmission line compensation - Series and shunt reactive power compensation - Concepts of Flexible AC Transmission System (FACTS) - Static var compensators (SVC) - Thyristor controlled reactor - Thyristor switched capacitor - Solid state power control - Static condensers - Controllable series compensation - Thyristor controlled phase angle regulator and unified power flow control.

4 MODELING AND ANALYSIS Total Hrs 9

Modeling and methods of analysis of SVC and FACTS controllers - System control and protection - Harmonics and filters – Simulation and study of SVC and FACTS under dynamic conditions.

5 EMERGING DEVICES AND CIRCUITS Total Hrs 9

Power Junction Field Effect Transistors - Field Controlled Thyristors - JFET based devices Vs other power devices - MOS controlled thyristors - Power integrated circuits - New semiconductor materials for power devices.


Text book (s):

1 Ned Mohan., Undeland and Robbins, " Power Electronics: Converters, Applications and Design ", John Wiley and Sons (Asia) Pte Ltd, Singapore, 2003.

2 Rashid, M.H., “Power Electronics – Circuits, Devices and Applications”, Pearson Education (Singapore) Pte. Ltd, New Delhi, 2004./ Prentice Hall of India, New Delhi.

Reference (s):

1 Bimal K Bose, “Modern Power Electronics – Evolution, Technology and application”, Jaico Publishing House, Mumbai, 2006.

2 Mohan Mathur P, Rajiv K Varma, “Thyristor – Based Facts Controllers for Electrical Transmission Systems”, John Wiley and Sons Inc., IEEE Press,USA, 2002.

3 Roger C Dugan, Maric F Mcgranaghan, “Electrical Power System Quality”, Mc-Graw Hill Inc, New York, 1996.






Semester III


L T P C CA ES Total

08330383E COMPUTER AIDED DESIGN OF ELECTRICAL DRIVES

3 0 0 3 50 50 100

Objective(s) To learn the design of electrical drives using FEM and CAD packages.


Conventional design procedures – Limitations – Need for field analysis based design.

2 MATHEMATICAL FORMULATION OF FIELD PROBLEMS Total Hrs 10

Electromagnetic Field Equations – Magnetic Vector/Scalar potential – Electrical vector /Scalar potential – Stored energy in field problems – Inductance- Development of torque/force- Laplace and Poisson‟s Equations – Energy functional - Principle of energy conversion.

3 PHILOSOPHY OF FEM Total Hrs 10

Mathematical models – Differential/Integral equations – Finite Difference method – Finite element method – Energy minimization – Variational method- 2D field problems – Discretisation – Shape functions – Stiffness matrix – Solution techniques.

4 CAD PACKAGES Total Hrs 10

Elements of a CAD System –Pre-processing – Modelling – Meshing – Material properties- Boundary Conditions – Setting up solution – Post processing.

5 DESIGN APPLICATIONS Total Hrs 10

Design of Solenoid Actuator – Induction Motor – Insulators – Power transformer


Text book (s):

1 S.J Salon, “Finite Element Analysis of Electrical Machines.” Kluwer Academic Publishers, London, 1995.

2 S.R.H.Hoole, “Computer – Aided, Analysis and Design of Electromagnetic Devices”, Elsevier, New York, Amsterdam, London, 1989.

Reference (s):

1 P.P. Silvester and Ferrari, “Finite Elements for Electrical Engineers” Cambridge University press, 1983.

2 D.A.Lowther and P.P Silvester, “Computer Aided Design in Magnetics”, Springer verlag, New York, 1986.






Semester III


L T P C CA ES Total

08330384E ROBOTICS AND AUTOMATION 3 0 0 3 50 50 100

Objective(s) To study the geometric configuration of robots, Dynamics and kinematics of robot arm, and automation through control of Robot manipulators.


Geometric configuration of robots – Manipulators – Drive systems – Internal and external sensors – End effectors – Control systems – Robot programming languages and applications – Introduction to robotic vision.

2 ROBOT ARM KINEMATICS Total Hrs 9

Direct and inverse kinematics – Rotation matrices – Composite rotation matrices – Euler angle representation – Homogenous transformation – Denavit Hattenberg representation and various arm configuration.

3 ROBOT ARM DYNAMICS Total Hrs 9

Lagrange – Euler formulation, joint velocities – Kinetic energy – Potential energy and motion equations – Generalised D‟Alembert equations of motion.

4 PLANNING OF MANIPULATOR TRAJECTORIES Total Hrs 9

General consideration on trajectory planning joint interpolation & Cartesian path trajectories.

5 CONTROL OF ROBOT MANIPULATORS Total Hrs 10

PID control computed, torque technique – Near minimum time control – Variable structure control – Non-linear decoupled feedback control – Resolved motion control and adaptive control.


Text book (s):

1 Fu, K.S. Gonazlez, R.C. and Lee, C.S.G., “Robotics (Control, Sensing, Vision and Intelligence), McGraw-Hill, 1968 (II printing).

2 Wesley, E. Sryda, “Industrial Robots: Computer interfacing and Control” PHI, 1985.

Reference (s):

1 Asada and Slotine, “Robot Analysis and Control”, John Wiley and Sons, 1986.

2 Philippe Coiffet, “Robot Technology” Vol. II (Modelling and Control), Prentice Hall INC, 1981.

3 Saeed B. Niku, “Introduction to Robotics, Analysis, systems and Applications”, Pearson Education, 2002.

4 Groover M. P. Mitchell Wesis., “Industrial Robotics Technology Programming and Applications”, Tata McGraw-Hill, 1986.






Semester III


L T P C CA ES Total

08330385E RELIABILITY ENGINEERING 3 0 0 3 50 50 100

Objective(s) To introduce the concept of reliability and its qualitative and quantitative aspects

Prerequisite Probability Theory

1 RELIABILITY CONCEPT Total Hrs 7

Reliability function – failure rate – mean time between failures (MTBF) – mean time to failure (MTTF) – A priori and a posteriori concept – mortality curve – useful life – availability – maintainability – system effectiveness.

2 FAILURE DATA ANALYSIS Total Hrs 10

Time to failure distributions – Exponential, normal, Gamma, Weibull, ranking of data- probability plotting techniques – Hazard plotting.

3 RELIABILITY PREDICTION MODELS Total Hrs 12

Series and parallel systems – RBD approach – Standby systems – m/n configuration – Application of Bayes‟ theorem – cut and tie set method – Markov analysis – Fault Tree Analysis – limitations.

4 RELIABILITY IMPROVEMENT Total Hrs 10

Different method, Redundancy (Element, unit, standby), optimization, Reliability cost trade off.

5 MAINTAINABILITY AND AVAILABILITY Total Hrs 6

Qualitative and Quantitative aspects, Reliability and maintainability trade off, MTTR, optimal maintenance.


Text book (s):

1 L.S.Srinath, „Reliability Engineering‟ Affiliated East West Press Publishers Ltd., New Delhi, 2006.

2 E.Balagurusamy, „Reliability Engineering‟ Tata McGraw Hill, New Delhi, 2003.

Reference (s):

1 R.Billinton, „Power System Reliability Evaluation‟ Gordon & Breach, NewYork, 2005.

2 Shooman M.L., „Probabilities Reliability an Engineering Approach‟, McGraw Hill, NewYork.

3 Sandler G.H., „System Reliability Engineering‟, Prentice Hall, New York.






Semester III


L T P C CA ES Total

08330386E POWER QUALITY ENGINEERING 3 0 0 3 50 50 100

Objective(s) To expose the students the quality of power, various power quality issues and the solutions provided for that issues.


Definitions – Power quality, Voltage quality – Power quality issues : Short duration voltage variations, Long duration voltage variations, Transients, Waveform distortion, Voltage imbalance, Voltage fluctuation, Power frequency variations, low power factor – Sources and Effects of power quality problems – Power quality terms – Power quality and Electro Magnetic Compatibility (EMC) Standards.

2 SHORT INTERRUPTIONS & LONG INTERRUPTIONS Total Hrs 10

Introduction – Origin of short interruptions : Voltage magnitude events due to re-closing, Voltage during the interruption – Monitoring of short interruptions –Influence on induction motors, Synchronous motors, Adjustable speed drives, Electronic equipments – Single phase tripping : Voltage during fault and post fault period, Current during fault period –Prediction of short Interruptions. Definition – Failure, Outage, Interruption – Origin of interruptions – Causes of long interruptions – Principles of regulating the voltage – Voltage regulating devices, Applications: Utility side, End-User side –Reliability evaluation – Cost of interruptions.

3 VOLTAGE SAG & TRANSIENTS Total Hrs 12

Introduction – Definition – Magnitude, Duration – Causes of Voltage Sag – Three Phase Unbalance – Phase angle jumps – Load influence on voltage sags on Adjustable speed drives, Power electronics loads, Sensitive loads - Stochastic assessment of voltage sags -Overview of mitigation methods. Definition – Power system transient model – Principles of over voltage protection - Types and causes of transients – Devices for over voltage protection - Capacitor switching transients –Lightning transients – Transients from load switching.

4 WAVEFORM DISTORTION, WIRING AND GROUNDING Total Hrs 10

Introduction – Definition and terms – Harmonics, Harmonics indices, Inter harmonics, Notching – Voltage Vs Current distortion – Harmonics Vs Transients – Sources and effects of harmonic distortion – System response characteristics – Principles of controlling harmonics – Standards and limitation - Definitions and terms – Reasons for grounding –National Electrical Code (NEC) grounding requirements – Utility Power system grounding –End-User power system grounding – Wiring and grounding problems.

5 POWER QUALITY SOLUTIONS Total Hrs 6

Introduction – Power quality monitoring : Need for power quality monitoring, Evolution of power quality monitoring, Deregulation effect on power quality monitoring – Power factor improvement – Brief introduction to power quality measurement equipments and power conditioning equipments – Planning, Conducting and Analyzing power quality survey –Mitigation and control techniques - Active Filters for Harmonic Reduction.


Text book (s):

1 1 Roger C. Dugan, Mark F. McGranaghan and H.Wayne Beaty, "Electrical Power Systems Quality", McGraw-Hill, New York, 2nd Edition, 2002.

2 2 Barry W.Kennedy, “Power Quality Primer”, McGraw-Hill, New York, 2000.

Reference (s):

1 Sankaran.C, "Power Quality", CRC Press, Washington, D.C., 2002.

2 Math H.J.Bollen, "Understanding Power Quality Problems: Voltage Sags and Interruptions", IEEE Press, New York, 2000.

3 Arrillaga.J, Watson.N.R and Chen.S, "Power System Quality Assessment", John Wiley & Sons Ltd., England, 2000.






Semester III


L T P C CA ES Total

08330387E ELECTRICAL ENERGY CONSERVATION AND MANAGEMENT

3 0 0 3 50 50 100

Objective(s) To study the Electrical Energy and Safety Audit and the Electrical Energy Conservation In Driven Equipments.

1 ELECTRICAL ENERGY AND SAFETY AUDIT Total Hrs 9

Overview of Electricity Act – Energy conservation act - Electrical energy audit – tools for electrical energy audit - billing elements - tariff system, energy and demand charge, electrical demand and load factor improvement, power factor correction, power demand control, demand shifting – Electrical Safety Auditing.

2 ELECTRIC MOTORS Total Hrs 9

Motors efficiency, idle running - motor selection – factors affecting motor performance, efficiency at low load – high efficiency motors - reduce speed/variable drives, load reduction - high-starting torque, rewound motors, motor generator sets, energy efficiency in transformers - Case studies

3 ELECTRICAL ENERGY CONSERVATION IN DRIVEN EQUIPMENTS

Total Hrs 9

Input electrical energy requirements in pumps – fans and compressors – load factor estimation in the equipments – different types of VFD, energy conservation potential – electrical energy conservation in refrigeration and A/C system, operation and maintenance practices for electrical energy conservation case studies.

4 ENERGY CONSERVATION IN INDUSTRIAL LIGHTING Total Hrs 9

Choice of lighting - energy saving - control of lighting - lighting standards – light meter audit - methods to reduce costs – summary of different lighting technologies – Case Studies.

5 ENERGY EFFICIENCY AND DEMAND SIDE MANAGEMENT

Total Hrs 9

Basic concepts – Co-generation – importance of demand side management – virtues of DSM – efficiency gains - estimation of energy efficiency potential, cost effectiveness, payback period, barriers for energy efficiency and DSM – Case Studies.


Text book (s):

1 Openshaw Taylor E., “Utilisation of Electric Energy”, Orient Longman Ltd, 2003.

2 Donald R. Wulfingoff, “Energy Efficiency Manual”, Energy Institute Press, 1999.

Reference (s):

1 Tripathy S.C., “Electrical Energy Utilization and Conservation”, TMH, 1991.

2 Cyril G. Veinott, Joseph E. Martin, “Fractional & Sub Fractional HP Electric Motor”, McGraw Hill, 1987.

3 Abhay Jain, “How to Achieve Energy Conservation”, Electrical India, Feb‟04, pp.48-53.

4 Ashok Bajpai, “Key Role of Energy Accounting and Audit in Power System”, Electrical India, Apr‟04, pp.38-47.






Semester III


L T P C CA ES Total

08330388E SPECIAL ELECTRICAL MACHINES

3 0 0 3 50 50 100

Objective(s) To expose the students to the construction, principle of operation and performance of special electrical machines as an extension to the study of basic electrical machines.

1 STEPPING MOTOR Total Hrs 9

Constructional features - Principle of operation-Modes of excitation-Torque production in Variable Reluctance (VR) stepping motor – Dynamic characteristics- Drive systems and circuit for open loop control - Closed loop control of stepping motor – Applications.

2 SWITCHED RELUCTANCE MOTOR AND LINEAR INDUCTION MOTOR

Total Hrs 9

Constructional features – Principle of operation – Torque equation – Power controllers – Characteristics and control – Magnetic Levitation - Linear Induction Motor-Applications.

3 PERMANENT MAGNET DC MOTOR Total Hrs 9

Principles of PMDC motor – Fundamentals of permanent magnets – Kinds of permanent magnets – Structure of field system – Armature structure – Brushes and commutator - Moving coil motors: classification – Types – Characteristics – Disc motors.

4 PERMANENT MAGNET BRUSHLESS DC MOTOR Total Hrs 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.

5 PERMANENT MAGNET SYNCHRONOUS MOTOR Total Hrs 9

Principle of operation – EMF, power input and torque expressions – Phasor diagram – Vector control – Control strategies – Flux weakening operation – Speed controller design - Sensorless control.


Text book(s):

1 Miller, T.J.E. “Brushless Permanent Magnet and Reluctance Motor Drives”, Clarendon Press, Oxford 1989.

2 Kenjo.T and Naganori S. “Permanent Magnet and Brushless DC Motors”, Clarendon Press, Oxford 1989.

3 Kenjo.T, “Stepping Motors and their Microprocessor Control “, Clarendon Press, Oxford 1989.

Reference(s):

1 Krishnan. R, “Electric Motor Drives” Pearson Prentice Hall, India, 2007.

2 Laithwaite, Induction Machines for special purposes.






Semester III


L T P C CA ES Total

08330389E ADVANCED MICROPROCESSORS AND MICROCONTROLLERS DESIGN

3 0 0 3 50 50 100

Objective(s) To study the architecture of PENTIUM and Arm. To study and design process of MOTOROLA 68HC11 MICRO CONTROLLERS

1 MICROPROCESSOR ARCHITECTURE Total Hrs 9

Instruction set – Data formats – Instruction formats – Addressing modes – Memory Hierarchy – register file – Cache – Virtual memory and paging – Segmentation – Pipelining – The instruction pipeline – pipeline hazards – Instruction level parallelism – reduced instruction set – Computer principles – RISC versus CISC – RISC properties – RISC evaluation – On-chip register files versus cache evaluation.

2 HIGH PERFORMANCE CISC ARCHITECTURE – PENTIUM Total Hrs 9

The software model – functional description – CPU pin descriptions – RISC concepts – bus operations – Super scalar architecture – pipe lining – Branch prediction – The instruction and caches – Floating point unit – protected mode operation – Segmentation – paging – Protection – multitasking – Exception and interrupts – Input/Output – Virtual 8086 model – Interrupt processing – Instruction types – Addressing modes – Processor flags – Instruction set – Basic programming the Pentium Processor.

3 HIGH PERFORMANCE RISC ARCHITECTURE: ARM Total Hrs 9

The ARM architecture – ARM organization and implementation – The ARM instruction set – The thumb instruction set – Basic ARM Assembly language program – ARM CPU cores.

4 MOTOROLA 68HC11 MICRO CONTROLLERS Total Hrs 9

Instructions and addressing modes – operating modes – Hardware reset – Interrupt system – Parallel I/O ports – Flats – Real time clock – Programmable timer – pulse accumulator – serial communication interface – A/D converter – hardware expansion – Basic Assembly Language programming.

5 PIC MICRO CONTROLLER Total Hrs 9

CPU Architecture – Instruction set – Interrupts – Timers – Memory – I/O port expansion – I2C bus for peripheral

chip access – A/D converter – UART.


Text book (s):

1 Daniel Tabak, “Advanced Microprocessors” McGraw Hill. Inc., 1995.

2 John.B. Peatman, “Design with PIC Micro controller”, Pearson Education, 1988.

Reference (s):

1 James L. Antonakos , “The Pentium Microprocessor” Pearson Education, 1997.

2 James L Antonakos, “An Introduction to the Intel family of Microprocessors” Pearson Education, 1999.

3 Gene. H.Miller, “Micro Computer Engineering”, Pearson Education, 2003.

4 Steave Furber, “ARM system – on – chip architecture” Addison Wesley, 2000.

Documents

K.S.Rangasamy College of Technology - R 2008 …ksrct.ac.in/admin/file_manager/source/academic/curriculum/ME_PED_R... · 1 P.K.Gupta, D.S.Hira, “ Operations Research”, S.Chand