SYLLABUS OF 2012 BATCHES

For the students admitted from the Academic year 2012-2013(R 2012)
Sri Ramakrishna Engineering College, Coimbatore-22
Department of Electrical and Electronics Engineering
Regulations: 2012
Curriculum
Semester III Electrical and Electronics Engineering Marks
Code No. Course Title L T P C CA FE Total
THEORY
12MA2301 Transforms and Partial Differential
Equations 3 1 0 4 20 80 100
12EE2302 Analysis and Synthesis of Electrical
Networks 3 1 0 4 20 80 100
12EE2303 Electromagnetic Field Theory 3 1 0 4 20 80 100
12EE2304 Measurements and Instrumentation 3 0 0 3 20 80 100
12EE2305 Analog Electronic Circuits 3 0 0 3 20 80 100
12EE2306 Digital Principles and Design 3 0 0 3 20 80 100
PRACTICALS
12EE2307 Measurements and Instrumentation
Laboratory 0 0 3 2 20 80 100
12EE2308 Electronic Circuits Laboratory 0 0 3 2 20 80 100
Total 18 3 6 25 - - -
Semester IV Electrical and Electronics Engineering Marks
THEORY
12MA2001 Numerical Methods 3 1 0 4 20 80 100
12EE2402 DC Machines and Transformers 3 1 0 4 20 80 100
12EE2403 Transmission & Distribution of
Electrical Energy 3 0 0 3 20 80 100
12EE2404 IC Fabrication and Linear Integrated
Circuits 3 0 0 3 20 80 100
12EE2405 Introduction to Signals and Systems 3 0 0 3 20 80 100
12EE2406 Principles of Communication
Engineering 3 0 0 3 20 80 100
PRACTICALS
12EE2407 DC Machines and Transformers
Laboratory 0 0 3 2 20 80 100
12EE2408 Linear Integrated Circuits Laboratory 0 0 3 2 20 80 100
Total 18 2 6 24 - - -
Page 1 of 85

Semester V Electrical and Electronics Engineering Marks
THEORY
12EE2501 Control System Engineering 3 1 0 4 20 80 100
12EE2502 Synchronous and Induction Machines 3 1 0 4 20 80 100
12EE2503 Power System Protection & Switchgear 3 0 0 3 20 80 100
12EE2504 Microprocessors and Microcontrollers 3 0 0 3 20 80 100
12EE2505 Digital Signal Processing for Electrical
Engineers 3 0 0 3 20 80 100
12EE2506 Data Structures and Developing
Algorithms 3 0 0 3 20 80 100
PRACTICALS
12EE2507 Synchronous and Induction Machines
Laboratory 0 0 3 2 20 80 100
12EE2508 Data Structures and Algorithms
Laboratory 0 0 3 2 20 80 100
12EN2001 Communication skills laboratory 0 0 2 1 20 80 100
Total 18 2 8 25 - - -
Semester VI Electrical and Electronics Engineering Marks
THEORY
12EE2601 Electric Machine Design 3 1 0 4 20 80 100
12EE2602 Power System Analysis 3 1 0 4 20 80 100
12EE2603 Power Electronics 3 1 0 4 20 80 100
12EE2604 Embedded System Engineering 3 0 0 3 20 80 100
12EE2605 Management Concepts and Practices 3 0 0 3 20 80 100
Elective I 3 0 0 3 20 80 100
PRACTICALS
12EE2607 Control Systems Laboratory 0 0 3 2 20 80 100
12EE2608 DSP and Microprocessors
Laboratory 0 0 3 2 20 80 100
Total 18 3 6 25 - - -
Page 2 of 85

Semester VII Electrical and Electronics Engineering Marks
THEORY
12EE2701 Electric Energy- Generation, Utilisation
and Conservation 3 0 0 3 20 80 100
12EE2702 Electric Drives and Controls 3 0 0 3 20 80 100
12EE2703 Power System Economics and Control
Techniques 3 1 0 4 20 80 100
12ME2001 Total Quality Management 3 0 0 3 20 80 100
Elective II 3 0 0 3 20 80 100
Elective III 3 0 0 3 20 80 100
PRACTICALS
12EE2707 Power Electronics and Drives
Laboratory 0 0 3 2 20 80 100
12EE2708 Power System Simulation Laboratory 0 0 3 2 20 80 100
12EE2709 Comprehensive Viva Voce 0 0 2 1 100 100
Total 18 1 8 24 - - -
Semester VIII Electrical and Electronics Engineering Marks
THEORY
Elective IV 3 0 0 3 20 80 100
Elective V 3 0 0 3 20 80 100
Elective VI 3 0 0 3 20 80 100
PRACTICALS
12EE2804 Project Work 0 0 18 6 20 80 100
Total 9 0 18 15 - - -
Electives Electrical and Electronics Engineering Marks
Page 3 of 85

Group Code No. Course Title L T P C CA FE Total
Group I
12CS2001 Java Programming 3 0 0 3 20 80 100
12EE2E01 Introduction to Data Base Management System 3 0 0 3 20 80 100
12EE2E02 DSP based System Design 3 0 0 3 20 80 100
12EE2E03 Introduction to Computer Architecture 3 0 0 3 20 80 100
Group II
12EE2E04 LabView and Virtual Instrumentation 3 0 0 3 20 80 100
12EE2E05 Power Quality 3 0 0 3 20 80 100
12EE2E06 Transients in Power System 3 0 0 3 20 80 100
12EE2E07 Networking in Smart Grids 3 0 0 3 20 80 100
12EE2E08 Soft Computing Techniques 3 0 0 3 20 80 100
12EE2E09 EHV AC and DC Power Transmission 3 0 0 3 20 80 100
12EE2E10 Digital System Design 3 0 0 3 20 80 100
12EE2E11 Analog VLSI Design 3 0 0 3 20 80 100
Group III
12EE2E12 Electronic Product Design 3 0 0 3 20 80 100
12EE2E13 Computer Aided Design of Electrical Apparatus 3 0 0 3 20 80 100
12EE2E14 High Voltage Engineering 3 0 0 3 20 80 100
12EE2E15 Opto Electronics 3 0 0 3 20 80 100
12EE2E16 Nano Science 3 0 0 3 20 80 100
12EE2E17 Distributed Control System 3 0 0 3 20 80 100
12EE2E18 Flexible AC Transmission Systems 3 0 0 3 20 80 100
12EE2E19 AI Applications to Power Systems 3 0 0 3 20 80 100
12EE2E20 Robotics Technology and Flexible Automation 3 0 0 3 20 80 100
12EE2E21 Special Electrical Machines 3 0 0 3 20 80 100
12EE2E22 Non-conventional Energy Sources 3 0 0 3 20 80 100
12IT2002 Soft Skills 3 0 0 3 20 80 100
12IT2004 Business Intelligence and its Applications 3 0 0 3 20 80 100
Total credits for the Course - 190
L : Lecture *CA : Continuous assessment
T : Tutorial *FE : Final Examination
P : Practical
C : Credits
Criterion for passing:
· Minimum Marks (FE) : 50/100 (In the Final Examination)
· Minimum Marks (CA+FE) : 50
Page 4 of 85

SEMESTER III
12MA2301 TRANSFORMS AND PARTIAL DIFFERENTIAL EQUATIONS 3 1 0 4
(Common to all branches of Engineering and Technology except BME)
AIM
The course aims to develop the skills of the students in the areas of Partial differential equations, Boundary value
problems and Transform techniques. This will be necessary for their effective studies in a large number of
engineering subjects like heat conduction, communication systems, electro optics and electromagnetic theory.
OBJECTIVES
At the end of the course the students would
· Be capable of mathematically formulating certain practical problems in terms of partial differential equations,
solve them and physically interpret the results.
· Have gained the knowledge of Fourier series, their different possible forms and the frequently needed practical
harmonic analysis that an engineer may have to make from discrete data.
· Have obtained capacity to formulate and identify certain boundary value problems encountered in engineering
practices, decide on applicability of the Fourier series method of solution, solve them and interpret the results.
· Have grasped the concept of expression of a function, under certain conditions, as a double integral leading to
identification of transform pair, and specialization on Fourier transform pair, their properties, the possible
special cases with attention to their applications.
· Have learnt the basics of Z-Transform in its applicability to discretely varying functions, gained the skill to
formulate certain problems in terms of difference equations and solve them.
UNIT- I PARTIAL DIFFERENTIAL EQUATIONS 12
Formation of partial differential equations by elimination of arbitrary constants and arbitrary functions – Solution of
of first order partial differential equations of the forms F(p,q) = 0, Z= px + qy + F(p,q) and F(z,p,q) = 0 – Lagrange’s
linear equation – Linear partial differential equations of second and higher order with constant coefficients.
UNIT- II FOURIER SERIES 12
Dirichlet’s conditions – General Fourier series – Odd and Even functions – Half range sine series and cosine series –
Parseval’s identity – Harmonic Analysis.
UNIT- III BOUNDARY VALUE PROBLEMS 12
Classification of second order quasi linear partial differential equations – Solutions of one dimensional wave
equation (Problems only) – One dimensional heat equation (Problems only) -Steady state solution of two-dimensional
heat equation in Cartesian coordinates (Insulated edges excluded) Problems only.
UNIT- IV FOURIER TRANSFORMS 12
Fourier integral theorem (without proof) – Fourier transform pair - Sine and Cosine transforms – Properties–
Transforms of simple functions – Convolution theorem – Parseval’s identity.
UNIT- V Z -TRANSFORMS AND DIFFERENCE EQUATIONS 12
Z-transform– Elementary properties– Inverse Z-transform– Convolution theorem– Formation of difference
equations (Direct problems only) – Solution of difference equations using Z - Transform.
Total Periods (45+15T): 60
TEXT BOOKS
Page 5 of 85

1. Kandasamy.P.,Thilagavathy.K., and Gunavathy.K., “Engineering Mathematics’’, S. Chand &
Company ltd., Volume II, New Delhi, 2011.
2. Grewal.B.S., “Higher Engineering Mathematics”, Khanna Publishers, 40th Edition, New Delhi,
2008.
REFERENCE BOOKS
1. Wylie C. Ray and Barrett Louis.C., “Advanced Engineering Mathematics”, McGraw-Hill, Inc.,
6thEdition, New York, 1995.
2. Andrews.L.A., and Shivamoggi B.K., “Integral Transforms for Engineersand Applied
Mathematicians”, Macmillen , 1st Edition, New York ,1988.
3. Churchill.R.V. and Brown.J.W., “Fourier Series and Boundary Value Problems”, McGraw-Hill
Book Co., 4th Edition, Singapore,1987.
Page 6 of 85

12EE2302 ANALYSIS AND SYNTHESIS OF ELECTRICAL NETWORKS 3 1 0 4
AIM
To provide depth knowledge on network analysis and synthesis concepts
OBJECTIVES
· To understand the concepts of graph theory
· To learn about two port networks
· To study about network functions of one port and two port networks
· To understand the concept of network synthesis
· To study about active and passive filters
UNIT – I GRAPH THEORY 12
Graph of a Network – Definitions – Tree - Co tree – Link - Basic loop and basic cut set - Incidence matrix - Cut set
matrix - Tie set matrix – Duality - Loop and Nodal methods of analysis.
UNIT – II TWO PORT NETWORKS 12
Characterization of LTI two port networks – Z, Y, ABCD and h parameters - Reciprocity and symmetry – Inter
relationships between the parameters - Inter-connections of two port networks - Ladder and Lattice networks - T & I
Representation.
UNIT – III NETWORK FUNCTIONS 12
Concept of Complex frequency, Transform Impedances Network functions of one port and two port networks,
concept of poles and zeros, properties of driving point and transfer functions, time response and stability from pole
zero plot.
UNIT – IV NETWORK SYNTHESIS 12
Positive real functions - definition and properties- properties of RL, RC & LC - pointing functions-synthesis of RL,
RC, LC driving point admittance functions using Foster and Cauer first and second forms.
UNIT – V FILTERS 12
Image parameters and characteristics impedance- Passive and active filters fundamentals - Low pass filters- High
pass filters - Constant K type filters- Introduction to active & passive filters.
Total Periods (45 +15T): 60
TEXT BOOKS
1. Van – Valkenburg M.E., “Network Analysis”, Prentice Hall of India, 3rd Edition, New Delhi, 2011.
2. Sudhakar A., and Shyammohan, “Circuits and Networks Analysis and Synthesis”, Tata McGraw Hill
Publishing Co. Ltd., 3rd Edition, New Delhi, 2007.
REFERENCES
1. Chakrabati A, “Circuits Theory (Analysis and synthesis)”, Dhanpath Rai & Sons, New Delhi, 1999.
2. Van Valkenburg M.E., “Introduction to Modern Network Synthesis”, Wiley Eastern Limited, 1999.
3. Jagan N.C., and Lakshminarayanan C., “ Network Analysis”, B.S.Publications, 2008.
4. Suresh Kumar K.S.,”Electric Circuits and Networks”, Pearson Education, 2009.
Page 7 of 85

12EE2303 ELECTROMAGNETIC FIELD THEORY 3 1 0 4
AIM
This subject aims to provide the student an understanding of the fundamentals of electromagnetic fields and
their applications in electrical engineering.
OBJECTIVES
To impart knowledge on
· Sources and effects of electromagnetic fields.
· Concepts of electrostatics, electrical potential, energy density and their applications.
· Concepts of magnetostatics, magnetic flux density, scalar and vector potential and its applications.
· Faraday’s laws, induced emf and their applications.
· Concepts of electromagnetic waves and pointing vector.
UNIT- I INTRODUCTION 12
Sources and effects of electromagnetic fields – Vector fields – Different co-ordinate systems – Vector calculus –
Gradient, Divergence and Curl - Divergence theorem – Stoke’s theorem.
UNIT - II ELECTROSTATICS 12
Coulomb’s Law – Electric field intensity – Field due to point and continuous charges – Gauss’s law and application
– Electrical potential – Electric field and equipotential plots – Electric field in free space, conductors, dielectric
– Dielectric polarization, Electric field in multiple dielectrics – Boundary conditions, Poisson’s and Laplace’s
equations – Capacitance-Energy density – Dielectric strength.
UNIT - III MAGNETOSTATICS 12
Lorentz Law of force, magnetic field intensity – Biot–savart Law - Ampere’s Law – Magnetic field due to straight
conductors, circular loop, infinite sheet of current – Magnetic flux density (B) – B in free space, conductor,
magnetic materials – Magnetization – Magnetic field in multiple media – Boundary conditions – Scalar and vector
potential – Magnetic force – Torque – Inductance – Energy density – Magnetic circuits.
UNIT - IV ELECTRODYNAMIC FIELDS 12
Faraday’s laws, induced emf – Transformer and motional EMF, Maxwell’s equations (differential and integral
forms) – Displacement current – Relation between field theory and circuit theory.
UNIT - V ELECTROMAGNETIC WAVES 12
Generation – Electro Magnetic Wave equations – Wave parameters; velocity, intrinsic impedance, propagation
constant – Waves in free space, lossy and lossless dielectrics, conductors-skin depth, Poynting vector – Plane
wave reflection and refraction.
Total Periods (45 +15T): 60
TEXT BOOKS
1. William .H. Hayt, “Engineering Electromagnetics”, Tata McGraw Hill, 7th Edition, 2006.
2. Gangadhar K.A, “Field Theory”, Khanna Publishers, 13th Edition, New Delhi, 1997.
REFERENCES
1. John.D.Kraus, “Electromagnetics”, McGraw Hill book Co., 4th Edition, New York, 1992.
2. Joseph. A.Edminister, “Theory and Problems of Electromagnetics”, Schaum Series, Tata McGraw Hill, 2nd
Edition, 2006.
3. Kraus and Fleish, “Electromagnetics with Applications”, McGraw Hill International Editions, 5th Edition,
1999.
4. Mathew N.O.Sadiku, ‘Elements of Electromagnetics’, 3rd Edition, Oxford University Press, 2003.
Page 8 of 85

12EE2304 MEASUREMENTS AND INSTRUMENTATION 3 0 0 3
AIM
To provide adequate knowledge in electrical instruments and measurements techniques.
OBJECTIVES
· To make the student have a clear knowledge of the basic laws governing the operation of the
instruments, relevant circuits and their working.
· Introduction to general instrument system, error, calibration etc. Emphasis is laid on analog and digital
techniques used to measure voltage, current, energy and power etc.
· To have an adequate knowledge of comparison methods of measurement.
· Elaborate discussion about storage & display devices.
· Exposure to various transducers and data acquisition system.
UNIT - I INTRODUCTION 9
Functional elements of an instrument – Static and dynamic characteristics – Errors in measurement – Statistical
evaluation of measurement data – Primary and secondary standards - Calibration.
UNIT - II ELECTRICAL AND ELECTRONICS INSTRUMENTS 9
Principle and types of analog and digital voltmeters, ammeters, multimeters – Average ,RMS and peak responding
type meters- Digital Phase meter- Single and three phase wattmeters and energy meters – Magnetic
measurements – Determination of B-H curve and measurements of iron loss – Instrument transformers –
Instruments for measurement of frequency and phase- Power factor meters.
UNIT - III COMPARISON METHODS OF MEASUREMENTS 9
D.C. & A.C. potentiometers - D.C & A.C bridges - transformer ratio bridges - self-balancing bridges. Interference &
screening – Multiple earth and earth loops - Electrostatic and electromagnetic interference – Grounding
techniques.
UNIT - IV STORAGE AND DISPLAY DEVICES 9
Magnetic disk and tape – Recorders, digital plotters and printers (qualitative treatment only), LED, LCD & dot
matrix display – DSO, MSO, Digital transceiver recorder, Power measurement and analysis, Real time
spectrum analysers.
UNIT - V TRANSDUCERS AND DATA ACQUISITION SYSTEM 9
Classification of transducers – Selection of transducers – Resistive, capacitive & inductive transducers –
Piezoelectric, optical and digital transducers – Elements of data acquisition system – A/D, D/A converters.
Total periods: 45
TEXT BOOKS
1. Doebelin E.O., “Measurement Systems – Application and Design”, Tata McGraw Hill publishing
company, 5th Edition, 2006.
2. Sawhney, A.K. “A Course in Electrical & Electronic Measurements & Instrumentation”, Dhanpat Rai and
Co, 2004.
REFERENCES
1. Golding,E.W., and Widdis,F.C., “Electrical Measurements and Measuring Instruments”, A H Wheeler &
Company, 5th Edition, 2003.
2. Kalsi H.S., ‘Electronic Instrumentation’, Tata McGraw Hill publishing company, 2nd Edition, New Delhi,
2004.
3. Bouwens, A.J. “Digital Instrumentation’, Tata McGraw Hill Publishing Company, 1997.
4. Moorthy, D.V.S. “Transducers and Instrumentation, Prentice Hall of India Pvt Ltd, 2003.
5. Martin Reissland, ‘Electrical Measurements’, New Age International (P) Ltd., Delhi, 2001.
6. Gupta, J. B. “A Course in Electronic & Electrical Measurements”, Kataria & Sons, Delhi, 2003.
Page 9 of 85

12EE2305 ANALOG ELECTRONIC CIRCUITS 3 0 0 3
AIM
To introduce the concept of realizing circuits using active and passive devices for signal generation and
amplification.
OBJECTIVES
· To learn and analyse the process of AC to DC conversion.
· To expose the students to study the different biasing and configurations of the amplifier circuits.
· To study the characteristics of tuned amplifier.
· To expose the students to various amplifiers and oscillator circuits with feedback concepts.
· To learn the wave shaping process and circuits.
UNIT - I RECTIFIERS AND POWER SUPPLY CIRCUITS 9
Half wave & full wave rectifier analysis - Inductor filter – Capacitor filter - Series voltage regulator – Switched
mode power supply.
UNIT - II TRANSISTOR BIASING AND AMPLIFIERS 9
Need for biasing-Types of biasing-Fixed and self biasing of BJT & FET – Stability factor - Fixed bias circuit, Load
line and quiescent point analysis. Small signal analysis of CE, CC & Common source amplifiers – Cascade and
Darlington connections, transformer coupled class A, B & AB amplifiers – Push-pull amplifiers.
UNIT - III DIFFERENTIAL AND TUNED AMPLIFIERS 9
Differential amplifiers – Common mode and differential mode analysis - DC and AC analysis - Characteristics of
tuned amplifiers – Single & double tuned amplifier.
UNIT - IV FEEDBACK AMPLIFIER AND OSCILLATOR 9
Characteristics of negative feedback amplifiers – Voltage / current, series/shunt feedback – Theory of sinusoidal
oscillators – Hartley, Colpitts, and crystal oscillators - Phase shift and Wien bridge oscillators.
UNIT - V WAVE SHAPING CIRCUITS AND OSCILLATORS 9
RC wave shaping circuits – Diode clampers and clippers – Multivibrators – Schmitt triggers – Barkhausen’s
criterion for Oscillation- UJT based saw tooth oscillators.
Total periods: 45
TEXT BOOKS
1. David A. Bell, “Electronic Devices & Circuits”, Prentice Hall of India/Pearson Education, 4th Edition,
Eighth printing, 2004.
2. Jacob Millman & Christos.C.Halkias, “Integrated Electronics: Analog and Digital Circuits and System”,
Tata McGraw Hill, 2002.
REFERENCES
1. Robert. L. Boylestad & Lo Nashelsky, “Electronic Devices & Circuit Theory”, 8th Edition, Pearson
Education, 2002 / PHI.
2. Jacob Millman & Herbert Taub, “Pulse, Digital & Switching Waveforms”, Tata McGraw Hill Publishing
Co, 2nd Edition, New Delhi, 2008.
3. Donald L.Schilling and Charles Belove, “Electronic Circuits”, Tata McGraw Hill Publishing Co., 3rd
Edition, 2003.
4. Floyd, “Electronic Devices”, Pearson Education India, 7th Edition, New Delhi, 2005.
Page 10 of 85

12EE2306 DIGITAL PRINCIPLES AND DESIGN 3 0 0 3
AIM
To introduce the fundamentals of digital circuits, combinational and sequential circuits.
OBJECTIVES
· To study various number systems and to simplify the mathematical expressions using Boolean functions –
simple problems.
· To study implementation of combinational circuits
· To study the design of various synchronous and asynchronous circuits.
· To expose the students to various memory devices.
UNIT - I NUMBER SYSTEM & BOOLEAN ALGEBRA 9
Binary, Octal, Decimal, Hexadecimal - Number base conversions – 1’s and 2’s complements - Signed Binary
numbers - Binary Arithmetic - Binary codes: Weighted – BCD - 2421- Gray code -Excess 3 code - ASCII – Error
detecting and correcting codes - De-Morgan’s Theorem- Principle of Duality- Boolean expression – Boolean
function - Minimization of Boolean expressions – Sum of Products (SOP) – Product of Sums (POS) – Minterm –
Maxterm - Karnaugh map Minimization – Don’t care conditions - Quine McCluskey method.
UNIT - II COMBINATIONAL CIRCUITS 9
Logic Gates: AND, OR, NOT, NAND, NOR, Exclusive-OR and Exclusive-NOR - Implementations of Logic
Functions using gates, NAND, NOR – Combinational circuits: Adder- Subtractor – Serial adder/ Subtractor -
Parallel adder / Subtractor- Carry look ahead adder- BCD adder- Magnitude Comparator- Multiplexer/
Demultiplexer- Encoder / decoder – Parity Generator/Checker – code converters.
UNIT - III SYNCHRONOUS SEQUENTIAL CIRCUITS 9
Latches and Flip flops SR, JK, T, D and Master slave – Characteristic table and equation –Application table – Edge
triggering –Level Triggering –Realization of one flip flop using other flip flops –Asynchronous / Ripple counters –
Synchronous counters –Modulo – n counter – Classification of sequential circuits: Moore and Mealy circuits -
Design of Synchronous counters: state diagram- State table –State minimization –State assignment – Register: shift
registers- Universal shift register.
UNIT - IV ASYNCHRONOUS SEQUENTIAL CIRCUIT 9
Design of fundamental mode and pulse mode circuits – primitive state / flow table – Minimization of primitive state
table –state assignment – Excitation table – Excitation map - cycles – Races – Hazards: Static –Dynamic – Essential
– Hazards elimination.
UNIT - V PROGRAMMABLE LOGIC DEVICES, MEMORY AND LOGIC FAMILIES 9
Memories: ROM, PROM, EPROM, PLA, PAL and FPGA - Digital logic families: TTL, ECL and CMOS.
Total periods: 45
TEXT BOOKS
1. Morris Mano M., “Digital Design”, Pearson Education Inc., 4th Edition, New Delhi, 2008.
2. John.M Yarbrough, “Digital Logic Applications and Design”, Vikas publishing house, New Delhi, 2006.
REFERENCES
1. Salivahanan S. and Arivazhagan S., “Digital Circuits and Design”, Vikas Publishing House Pvt. Ltd, 4th
Edition, New Delhi, 2004.
2. Thomas L. Floyd, “Digital Fundamentals”, Pearson Education Inc., 10th Edition, New Delhi, 2008.
3. Charles H.Roth. “Fundamentals of Logic Design”, Thomson Publication Company, 2003.
4. Donald P.Leach and Albert Paul Malvino, “Digital Principles and Applications”, Tata McGraw Hill
Publishing Company Limited, 5th Edition, New Delhi, 2003.
Page 11 of 85

5. Jain R.P., “Modern Digital Electronics”, Tata McGraw–Hill publishing company limited,3rd Edition, New
Delhi, 2003.
Page 12 of 85

12EE2307 MEASUREMENT AND INSTRUMENTATION LABORATORY 0 0 3 2
AIM
The aim of this lab is to fortify the students with an adequate work experience in the measurement of
different quantities and also the expertise in handling the instruments involved.
OBJECTIVES
To train the students in the measurement of displacement, resistance, inductance, torque and angle etc., and
to give exposure to AC, DC bridges and transient measurement.
1. Study of displacement and pressure transducers
2. Measurement of high resistance using Kelvin’s double bridge and Megger
3. Measurement of frequency using Wien bridge
4. To study dielectric behavior (using Schering bridge and standard capacitor)
5. Measurement of inductance using maxwell’s bridge
6. Instrumentation amplifiers
7. Measurement of transients using DSO
8. Calibration of single-phase energy meter
9. Calibration of current transformer (both measurement and protection)
10. Measurement of three phase power and power factor
11. Measurement of iron loss
12. Measurement systems using LabVIEW and MATLAB
13. Design and construction of resistive and capacitive dividers
Practical 45
Page 13 of 85

12EE2308 ELECTRONIC CIRCUITS LABORATORY 0 0 3 2
AIM
This laboratory aims to train the students in both analog and digital electronics circuits so that they can
acquire practical knowledge in electronics.
1. Single Phase Half and Full wave rectifier with inductive and capacitive filters.
2. RC coupled and differential amplifier.
3. Frequency response of common emitter amplifiers.
4. RC Phase shift, Hartley, Colpitts oscillators
5. Astable / Monostable multivibrator
6. Series voltage regulator.
7. Study of Basic Digital gates.
(Verification of truth table for AND, OR, EXOR, NOT, NOR, NAND, JK FF, RS FF, D FF)
8. Implementation of Boolean Functions, Adder/ Subtractor circuits
9. Code converters, Parity generator and parity checking, Excess 3, 2s Complement, Binary to grey code
using suitable IC’s.
10. Encoders and Decoders
11. Multiplexer/ De-multiplexer: Study of 4:1; 8:1 multiplexer and Study of 1:4; 1:8 Demultiplexer
12. Shift Registers: Design and implementation of 4-bit shift registers in SISO, SIPO, PISO, PIPO modes
using suitable IC’s.
Practical 45
Page 14 of 85

SEMESTER IV
12MA2001 NUMERICAL METHODS 3 1 0 4
AIM
With the present development of the computer technology, it is necessary to develop efficient algorithms for
solving problems in Science, Engineering and Technology.
OBJECTIVES
At the end of the course, the students would be acquainted with the basic concepts in numerical methods and their
uses are summarized as follows
· The solution of nonlinear (algebraic or transcendental) equations, system of linear equations and eigen
value problem of matrix can be obtained numerically where analytical methods fail to give solution.
· When huge amounts of experimental data are involved, the methods discussed on interpolation will be
useful in constructing approximate polynomial to represent the data and to find the intermediate values.
· The numerical differentiation and integration find application when the function in the analytical form is
too complicated or the huge amounts of data are given.
· The methods introduced in the solution of ordinary differential equations and partial differential equations
will be useful in attempting any engineering problem.
UNIT- I SOLUTION OF EQUATIONS AND EIGENVALUE PROBLEMS 12
Solution of algebraic and transcendental equations– Regula-Falsi method– Newton’s method– Solution of linear
system by Gaussian elimination and Gauss-Jordon methods– Inverse of a matrix by Gauss Jordon method - Iterative
methods: Gauss Jacobi and Gauss-Seidel methods – Eigen value of a matrix by power method.
UNIT-II INTERPOLATION AND APPROXIMATION 12
Newton’s forward and backward interpolation– Lagrange’s interpolation– Newton’s divided difference interpolation
– Interpolating with a cubic spline
UNIT-III NUMERICAL DIFFERENTIATION AND INTEGRATION 12
Derivatives using Newton’s forward and backward interpolation– Numerical integration by trapezoidal and
Simpson’s 1/3 and 3/8 rules- Romberg’s method– Two and Three point Gaussian quadrature formula– Double
integrals using trapezoidal and Simpson’s rule.
UNIT-IV INITIAL VALUE PROBLEMS FOR ORDINARY DIFFERENTIAL
EQUATIONS 12
Single step methods: Taylor series method– Euler and modified Euler methods– Fourth order Runge– Kutta method
for solving first and second order equations– Multistep methods: Milne’s and Adam’s predictor and corrector
methods.
UNIT-V BOUNDARY VALUE PROBLEMS IN ORDINARY AND PARTIAL DIFFERENTIAL
EQUATIONS 12
Finite difference solution of second order ordinary differential equation– Finite difference solution of one
dimensional heat equation by explicit and implicit methods– One dimensional wave equation and two dimensional
Laplace and Poisson equations.
Total Periods (45+15T): 60
TEXT BOOKS
1. Gerald.C.F. andWheatley.P.O. “Applied Numerical Analysis”, Pearson Education Asia, 6th
2. Kandasamy.P., Thilagavathy.K. andGunavathy.K., “Numerical Methods”, S.Chand Co. Ltd., 3rd
REFERENCE BOOKS
Page 15 of 85

1. Veerarajan.T., “Numerical Methods”, Tata McGraw Hill Pub.Co.Ltd, 2 nd Edition, New Delhi,
2011.
2. Burden.R.L. andFaires.T.D., “Numerical Analysis”, Thomson Asia Pvt. Ltd., 7th Edition,
Singapore, 2002.
Page 16 of 85

12EE2402 DC MACHINES AND TRANSFORMERS 3 1 0 4
AIM
To introduce the basic concepts of rotating machines and to expose the students to the concepts of DC machines
and Transformers and analyse their performance.
OBJECTIVES
· Principles of electromechanical energy conversion and basic concepts in rotating machines.
· Construction, principle of operation and performance of DC generators.
· Principle of operation, performance, starting methods and speed control of DC motors.
· Construction, principle of operation and performance of transformers.
· Losses and efficiency, testing of DC machines and transformers.
UNIT - I BASIC CONCEPTS OF ROTATING MACHINES 8
Principles of electromechanical energy conversion – Single and multiple excited systems – Field energy and co-energy
– Force and Torque - MMF of distributed A.C. windings – Rotating magnetic field – Generated voltage –
Torque in round rotor machine.
UNIT - II DC GENERATORS 9
Constructional details – Principle of operation - EMF equation – Methods of excitation – Self and separately excited
generators – Characteristics of series, shunt and compound generators – Armature reaction and commutation –
Parallel operation of DC shunt and compound generators.
UNIT - III DC MOTORS 9
Principle of operation – Back EMF and torque equations – Characteristics of series, shunt and compound motors –
Starting of DC motors – Types of starters – Speed control of DC series and shunt motors.
UNIT - IV TRANSFORMERS 10
Constructional details - principle of operation – types - EMF equation – Transformation ratio – Transformer on no-load
– Transformer on load - Equivalent circuit - Regulation - Parallel operation of transformers - Three phase
transformer connections - Auto transformer.
UNIT - V TESTING OF DC MACHINES AND TRANSFORMERS 9
Losses and efficiency in DC machines and transformers – Condition for maximum efficiency Testing of DC
machines – Brake test, Swinburne’s test, Hopkinson’s test and Retardation test – Testing of transformers – Polarity
test - Open circuit and short circuit tests – Sumpner’s test – All day efficiency.
Note: UNIT 5 may be covered along with UNIT 2, 3, and 4.
Total periods (45+15T): 60
TEXT BOOKS
1. Kothari D.P., & Nagrath I.J., “Electric Machines”, Tata McGraw Hill Publishing Company Ltd, 3rd Edition,
2004.
2. Albert E. Clayton and Hancock N. N., “The performance and Design of Direct Current Machines”, Oxford
and IBH Publishing Company Pvt. Ltd., New Delhi, 1990.
REFERENCES
1. Gupta J.B., “Theory and Performance of Electrical Machines”, S.K.Kataria and Sons,14th Edition, 2009.
2. Fitzgerald.A.E., Charles Kingsely Jr, Stephen D.Umans, “Electric Machinery”, McGraw Hill Books
Company, 6th Edition, 2003.
3. Irving L. Kosow “Electric Machinery and Transformers” PHI, New Delhi, 2nd Edition, 1991.
Page 17 of 85

12EE2403 TRANSMISSION AND DISTRIBUTION OF ELECTRICAL ENERGY 3 0 0 3
AIM
To become familiar with the function of different components used in Transmission and Distribution levels
of power systems and modeling of these components.
OBJECTIVES
· To develop expression for computation of fundamental parameters of lines.
· To categorize the lines into different classes and develop equivalent circuits for these classes.
· To analyse the voltage distribution in insulator strings and cables and methods to improve the same.
Structure of electric power system: Various levels such as generation, transmission and distribution; HVDC and
EHV AC transmission: comparison of economics of transmission, technical performance and reliability, application
of HVDC transmission system. FACTS (qualitative treatment only): TCSC, SVC, STATCOM, UPFC.
UNIT - II TRANSMISSION LINE PARAMETERS 9
Parameters of single and three phase transmission lines with single and double circuits: Resistance, inductance and
capacitance of solid, stranded and bundled conductors: Symmetrical and unsymmetrical spacing and transposition;
application of self and mutual GMD; skin and proximity effects; interference with neighbouring communication
circuits. Typical configuration, conduct types and electrical parameters of 400, 220, 110, 66 and 33 kV lines.
UNIT - III MODELLING AND PERFORMANCE OF TRANSMISSION LINES 9
Classification of lines: Short line, medium line and long line; equivalent circuits, attenuation constant, phase
constant, surge impedance; transmission efficiency and voltage regulation; real and reactive power flow in lines:
Power-angle diagram; surge-impedance loading, load ability limits based on thermal loading, angle and voltage
stability considerations; shunt and series compensation, Ferranti effect and corona loss.
UNIT - IV INSULATORS AND CABLES 9
Insulators: Types, voltage distribution in insulator string and grading, improvement of string efficiency.
Underground cables: Constructional features of LT and HT cables, capacitance, dielectric stress and grading,
thermal characteristics.
UNIT - V SUBSTATION, GROUNDING SYSTEM AND DISTRIBUTION SYSTEM 9
Types of substations; bus-bar arrangements; substation bus schemes: single bus scheme, double bus with double
breaker, double bus with single breaker, main and transfer bus, ring bus, breaker-and-a-half with two main buses,
double bus-bar with bypass isolators.
Resistance of grounding systems: Resistance of driven rods, resistance of grounding point electrode, grounding
grids; design principles of substation grounding system; neutral grounding.
Radial and ring-main distributors; interconnectors; AC distribution: AC distributor with concentrated load; three-phase,
four-wire distribution system; sub-mains; stepped and tapered mains.
Total periods: 45
TEXT BOOKS
1. Gupta B.R, “Power System Analysis and Design”, S.Chand and company, New Delhi, 2008.
2. Singh S.N, “Electric Power Generation, Transmission and Distribution”, Prentice Hall of India Pvt. Ltd,
New Delhi, 2004.
REFERENCES
1. Luces M.Fualkenberry, Walter Coffer, “Electrical Power Distribution and Transmission”, Pearson
education, 2007.
2. Begamudre R.D, “Extra high voltage AC Transmission Engineering”, NewAge International (P) Ltd.,
January 2009.
3. Central Electricity Authority (CEA), “Guidelines for Transmission System Planning”, New Delhi
4. Tamil Nadu Electricity Board Handbook, 2003.
Page 18 of 85

12EE2404 IC FABRICATION AND LINEAR INTEGRATED CIRCUITS 3 0 0 3
AIM
To expose the students to the concepts of IC fabrication, characteristics of op-amp, applications of op-amp
and special ICs.
OBJECTIVES
· To study the IC fabrication.
· To study characteristics of Op-amp, sine wave oscillators and waveform generators using Op-amp
ICs.
· To study the applications of Op-amp.
· To study internal functional blocks and applications of special ICs like 555 IC Timer, 565 IC PLL,
723 & LM317 IC Regulators, and AD533 IC Analog multiplier.
· To study the various types of ADCs and DACs.
UNIT - I IC FABRICATION 9
IC classification, fundamental of monolithic IC technology- Epitaxial growth- Masking and etching- Diffusion of
impurities- Isolation Techniques- Metallization- Packaging- Fabrication of Transistors, Diodes, Capacitors and
Resistors- Fabrication of a typical circuit.
UNIT - II CHARACTERISTICS OF OPAMP 9
Ideal OP-AMP characteristics- DC characteristics- Voltage series feedback and shunt feedback amplifiers-
Differential amplifier- AC characteristics- Frequency response of OP-AMP- Basic applications of op-amp–
Summer, differentiator and integrator.
UNIT - III APPLICATIONS OF OPAMP-I 9
Instrumentation amplifier- First and second order active filters- V/I & I/V converters- Comparators- Sine wave
oscillators- Square, triangular and sawtooth wave generators- Peak detector- Clipping and Clamping circuits.
UNIT - IV APPLICATIONS OF OPAMP-II 9
S/H circuit- D/A converter- R-2R ladder and weighted resistor types- A/D converter - Dual slope, successive
approximation and flash types.
UNIT -V SPECIAL IC”S AND THEIR APPLICATIONS 9
555 Timer IC – Functional block diagram & applications; 565 IC-Phase lock loop- Functional block diagram and
applications, LM317 and 723 IC voltage regulators, MA 7840 IC switching regulator- MCT2E IC opto-coupler-
-AD533 IC Analog multiplier.
Total periods: 45
TEXT BOOKS
1. Ramakant A.Gayakward, “Op-amps and Linear Integrated Circuits”, 4th Edition, Pearson Education, New
Delhi, 2011.
2. Roy Choudhary D, Sheil B.Jani, “Linear Integrated Circuits”, 4th Edition, New Age International Publishers,
2010
REFERENCES
1. Jacob Millman, Christos C. Halkias, “Integrated Electronics: Analog and Digital circuitssystem”, 2nd Edition,
Tata McGraw Hill, 2011.
2. Robert F. Coughlin, Fredrick F. Driscoll, “Op-amps and Linear ICs”, Pearson Education, 6th Edition, 2011.
3. David A. Bell, “Op-amp & Linear ICs”, Prentice Hall of India, 2nd Edition, 1997.
4. Salivahanan S, V.S. Kanchana Bhaaskaran, “Linear Integrated Circuits”, New Delhi, Tata McGraw-Hill, 2008.
Page 19 of 85

12EE2405 INTRODUCTION TO SIGNALS AND SYSTEMS 3 1 0 3
AIM
To study and analyze the characteristics of continuous and discrete signals and systems.
OBJECTIVES
· To study the properties and representation of discrete and continuous signals.
· To study the sampling process and analysis of discrete system using Z-transform.
· To analyse continuous time system using Fourier and Laplace transforms.
· To learn about analysis and synthesis of discrete time systems.
· To learn about system with impulse response.
UNIT - I REPRESENTATION OF SIGNALS 9
Continuous and discrete time signals: Classification of Signals – Periodic and aperiodic – Even and odd – Energy
and power signals – Deterministic and random signals–periodicity – Properties of discrete time complex exponential
UNIT impulse – UNIT step impulse functions –Transformation in independent variable of signals: time scaling,
time shifting. Determination of Fourier series - Representation of continuous time and discrete time periodic signals.
UNIT - II ANALYSIS OF CONTINUOUS TIME SIGNALS AND SYSTEMS 9
Continuous time Fourier Transform and Laplace Transform analysis with examples – Properties of the Continuous
time Fourier Transform and Laplace Transform basic properties, Parseval’s relation, and convolution in time and
frequency domains.
Basic properties of continuous time systems: Linearity, Causality, time invariance, stability, magnitude and Phase
representations of frequency response of LTI systems -Analysis and characterization of LTI systems using Laplace
transform: Computation of impulse response and transfer function using Laplace transform.
UNIT - III SAMPLING THEOREM AND Z-TRANSFORM 9
Representation of continuous time signals by its sample - Sampling theorem – Reconstruction of a Signal from its
samples, aliasing – Discrete time processing of continuous time signals, sampling of band pass signals - Basic
principles of z-transform - Z-transform definition – Region of convergence – Properties of ROC – Properties of z-transform
– Poles and Zeros – Inverse z-transform using Contour integration – Residue Theorem, Power Series
expansion and Partial fraction expansion, Relationship between z-transform and Fourier transform.
UNIT - IV DISCRETE TIME SYSTEMS 9
Computation of Impulse response & Transfer function using Z Transform. DTFT Properties and examples – LTI-DT
systems -Characterization using difference equation – Block diagram representation – Properties of convolution
and the interconnection of LTI Systems-Static variable equations and matrix representation of system.
UNIT - V SYSTEMS WITH FINITE AND INFINITE DURATION IMPULSE RESPONSE 9
Systems with finite duration and infinite duration impulse response – recursive and non-recursive discrete time
system – realization structures – direct form – I, direct form – II, cascade and parallel forms.
TEXT BOOKS
1. AlanV.Oppenheim, Alan S.Willsky with Hamid Nawab.S, “Signals & Systems”, 3/e, Pearson Education,
2000.
REFERENCES
1. John G.Proakis and Dimitris G.Manolakis, “Digital Signal Processing, Principles, Algorithms and
Applications”, 4/e PHI, 2007.
2. M.J.Roberts, “Fundamentals of Signals and Systems”, TMH 2008.
3. K.Lindner, “Signals and Systems”, McGraw Hill International, 2000.
4. H.P.Hsu, “Signals and systems “, Schaum”s outlines, Tata McGraw-Hill Co Ltd., 2006.
Page 20 of 85

12EE2406 PRINCIPLES OF COMMUNICATION ENGINEERING 3 0 0 3
AIM
To introduce the concepts of communication systems engineering using wire and wireless medium
OBJECTIVES
· To introduce different methods of analog communication and their significance.
· To introduce Digital Communication methods for high bit rate transmission..
· To introduce the concepts of source and line coding techniques for enhancing rating of transmission of
minimizing the errors in transmission.
· To introduce MAC used in communication systems for enhancing the number of users.
· To introduce various media for digital communication
UNIT - I ANALOG COMMUNICATION 9
AM – Frequency spectrum – Vector representation – Power relations – Generation of AM – DSB,DSB/SC, SSB,
VSB AM Transmitter & Receiver; FM and PM – Frequency spectrum – Power relations : NBFM & WBFM,
Generation of FM and DM, Amstrong method & Reactance modulations :FM & PM frequency.
UNIT - II DIGITAL COMMUNICATION 9
Pulse modulations – Concepts of sampling and sampling theormes, PAM, PWM, PPM, PTM,quantization and
coding : DCM, DM, slope overload error. ADM, DPCM, OOK systems –ASK, FSK, PSK, BSK, QPSK, QAM,
MSK, GMSK, applications of Data communication.
UNIT - III SOURCE CODES, LINE CODES & ERROR CONTROL (Qualitative only) 9
Primary communication – Entropy, properties, BSC, BEC, source coding : Shaum, Fao, Huffman coding : noiseless
coding theorum, BW – SNR trade off codes: NRZ, RZ, AMI, HDBP, ABQ,MBnB codes : Efficiency of
transmissions, error control codes and applications:convolutions & block codes.
UNIT - IV MULTIPLE ACCESS TECHNIQUES 9
SS&MA techniques: FDMA, TDMA, CDMA, SDMA application in wire and wireless communication: Advantages
(merits), Wi-Fi, i-pad, i-pod, Blue tooth devices.
UNIT - V SATELLITE, OPTICAL FIBER – POWERLINE, SCADA 9
Orbits: types of satellites: frequency used link establishment, MA techniques used in satellite Communication, earth
station; aperture actuators used in satellite – Intelsat and Insat: fibers – Types: sources, detectors used, digital filters,
optical link: power line carrier communications: SCADA
Total periods: 45
TEXT BOOKS
1.Taub & Schiling “Principles of communication systems” Tata McGraw hill 2007
2.Das J, Chatterjee P.K., Mullik S.K., “Principles of digital communication” New Age International, 2nd Edition,
2012.
REFERENCES
1. Kennedy and Davis “Electronic communication systems” Tata McGraw hill, 4th edition, 1993, 35th Reprint
(2008).
2. Sklar “Digital communication fundamentals and applications“ Pearson Education, 2nd Edition, 2001
3. Bary le, Memuschmidt, digital Communication, Kluwer Publication, 2004.
4. Lathi B.P, “Modern digital and analog communication systems” Oxford University Press, 4th Edition, 2009.
Page 21 of 85

12EE2407 DC MACHINES AND TRANSFORMERS LABORATORY 0 0 3 2
AIM
To expose the students to the operation of D.C. machines and transformers and give them
experimental skill.
EXPERIMENTS
1. Open circuit and load characteristics of D.C separately and self excited shunt generator
2. Load characteristics of D.C. compound generator with differential and cumulative connections
3. Load characteristics of D.C. shunt motor
4. Load characteristics of D.C. compound motor
5. Load characteristics of D.C series motor
6. Swinburne”s test
7. Speed control of D.C shunt motor
8. Hopkinson”s test on D.C motor – generator set
9. Load test on single-phase transformer and
10. Open circuit and short circuit tests on single phase transformer
11. Sumpner”s test on transformers
12. Separation of no-load losses in single phase transformer
Practical 45
Additional experiments
13. Study of D.C.motor starters
14. Three phase transformer connections
Page 22 of 85

12EE2408 LINEAR INTEGRATED CIRCUITS LABORATORY 0 0 3 2
AIM
To impart practical knowledge to the students to understand the basic concepts and applications of op-amps
and special ICs.
OUTCOMES
After successful completion of this course, the students will be able to,
· Design op-amp circuits for practical applications.
· Design voltage regulators, A/D and D/A converters for practical applications.
· Design Astable and Monostable multivibrators using 555 Timer IC for practical applications.
· Design frequency multiplier using 565 PLL IC for practical applications.
LIST OF EXPERIMENTS
1. Inverting and non-inverting amplifiers
2. Integrator and differentiator
3. Square and Triangular wave generators
4. Op-Applications – Adder, Subtractor, Averaging amplifier
5. Comparators using LM311 IC
6. 555 Timer IC Applications- Astable and Monostable multivibrator
7. Analog to Digital and Digital to Analog Converters.
8. 565 PLL IC Applications - Frequency multiplier
9. 723 IC and LM317 IC Voltage Regulators
10. Differential and Instrumentation amplifier
11. Measurement of op-amp parameters
Practical 45
Page 23 of 85

V SEMESTER
12EE2501 CONTROL SYSTEM ENGINEERING 3 1 0 4
AIM
To expose the students to the basic concepts of control systems.
OBJECTIVES
· To understand the open loop and closed loop systems.
· To understand the modelling of physical systems using transfer function and state space approach.
· To understand time domain and frequency domain analysis of control systems.
· To understand the compensation techniques used to stabilize control systems.
UNIT - I CONTROL SYSTEM MODELLING 9
System concept- Open loop and closed loop systems- Modelling of electrical, mechanical, and electromechanical
systems- Transfer function of DC generator- DC and AC servomotor- Electrical analogy of mechanical systems-
Block diagram representation of systems- Block diagram reduction Techniques- Signal flow graphs- Mason”s gain
formula- Examples.
UNIT - II TIME DOMAIN ANALYSIS 9
Standard Test signals–Time response of first and second order systems- Performance parameters- Type and order of
systems- Steady state error constants - Generalized error series– Steady state error- Introduction to P, PI and PID
controllers- Design of PID controllers.
UNIT - III FREQUENCY DOMAIN ANALYSIS 9
Frequency domain specifications – Peak resonance- Resonant frequency- Bandwidth and cut-off rate- Correlation
between time and frequency response of second order systems- Bode plots- Polar plots- Determination of closed
loop response from open loop response.
UNIT - IV STABILITY ANALYSIS 9
Characteristic equation – Location of roots of characteristic equation for stability– Absolute stability and Relative
stability- Routh Hurwitz criterion for stability- Root locus– Effect of pole- Zero addition, Nyquist stability criterion-
Gain margin- phase margin.
UNIT – V COMPENSATOR AND STATE SPACE REPRESENTATION 9
Design of lag, lead, and lag-lead compensator using Bode plot - Modelling of physical systems using state space
approach- Advantages of state space approach over transfer function model.
TEXT BOOKS
1. Nagrath I.J and Gopal M, “Control Systems Engineering”, New Age International Publishers, 5th edition, 2008.
REFERENCESS
1. Benjamin C. Kuo, “Automatic Control Systems”, John Wiley and Sons, 9th Edition, 2010.
2. Gopal M, “Control Systems, Principles & Design”, Tata McGraw Hill, New Delhi, 3rd Ed., 2008.
3. Bandyopadhyay M.N,“Control Engineering Theory and Practice”, Prentice Hall of India, 2003
4. Ogata K, “Modern Control Engineering”, 5th edition, Pearson Education, New Delhi, 2010.
5. Norman S. Nise, Control Systems Engineering, 5th Edition, John Wiley, New Delhi, 2009.
6. Samarjit Ghosh, Control systems, Pearson Education, New Delhi, 2004.
Page 24 of 85

12EE2502 SYNCHRONOUS AND INDUCTION MACHINES 3 1 0 4
AIM
To expose the students to the concepts of synchronous and asynchronous machines and to analyse their
performance.
OBJECTIVES
· Construction and performance of salient and non – salient type synchronous generators.
· Principle of operation and performance of synchronous motor.
· Construction, principle of operation and performance of induction machines.
· Starting and speed control of three-phase induction motors.
· Construction, principle of operation and performance of single phase induction motors and special
machines.
UNIT - I SYNCHRONOUS GENERATOR 9
Constructional details – Types of rotors – emf equation – Synchronous reactance – Armature reaction – Voltage
regulation – e.m.f, m.m.f, z.p.f and A.S.A methods – Synchronizing and parallel operation – Synchronizing torque -
Change of excitation and mechanical input – Two reaction theory – Determination of direct and quadrature axis
synchronous reactance using slip test – Operating characteristics - Capability curves.
UNIT - II SYNCHRONOUS MOTOR 8
Principle of operation – Torque equation – Operation on infinite bus bars - Phasor diagrams -V and inverted V
curves - Hunting – Power input and power developed equations – Starting methods – Current loci for constant
power input, constant excitation and constant power developed.
UNIT - III THREE PHASE INDUCTION MOTOR 12
Constructional details – Types of rotors – Principle of operation – Slip – Equivalent circuit – Slip-torque
characteristics - Condition for maximum torque – Losses and efficiency – Load test - No load and blocked
rotor tests - Circle diagram – Separation of no load losses – Double cage rotors – Induction generator –
Synchronous induction motor.
UNIT - IV STARTING AND SPEED CONTROL OF THREE PHASE INDUCTION MOTOR 7
Need for starting – Types of starters – Stator resistance and reactance, autotransformer and star-delta starters – Rotor
resistance starter – Speed control – Change of voltage, frequency, number of poles and slip – Cascaded
connection – Slip power recovery scheme.
UNIT - V SINGLE PHASE INDUCTION MOTORS AND SPECIAL MACHINES 9
Constructional details of single phase induction motor – Double revolving field theory and operation – Equivalent
circuit – No load and blocked rotor test – Performance analysis – Starting methods of single-phase induction
motors - Special machines - Shaded pole induction motor, reluctance motor, repulsion motor, hysteresis motor,
stepper motor and AC series motor.
TEXT BOOKS
1. Kothari D.P and Nagrath I.J., “Electric Machines”, Tata McGraw Hill Publishing Company Ltd, 4th Edition, 2010.
REFERENCES
1. Gupta J.B, “Theory and Performance of Electrical Machines”, S.K.Kataria and Sons, 2002.
2. Murugesh Kumar K, “Induction and synchronous machines” Vikas publishing house Pvt Ltd., 2009.
3. Sheila.C.Haran, “Electrical Machines II”, Scitech Publications, 2nd Edition 2008.
4. Say M.G, “Alternating Current Machines”, 5th Edition, Pitman, 1992.
5. Bhimbhra P.S, “Electrical Machinery”, Khanna Publishers, 2003.
Page 25 of 85

Page 26 of 85

12EE2503 POWER SYSTEM PROTECTION AND SWITCHGEAR 3 0 0 3
AIM
To study the various faults and protection schemes in power systems.
OBJECTIVES
· To discuss the need for the protection and various protection schemes.
· To study relays characteristics
· To study apparatus protection
· To understand the method of circuit breaking, arcing phenomena – various arc theories-capacitive and
inductive breaking
· To understand the working of different types of circuit breakers and their testing methods
Principles and need for protective schemes – nature and causes of faults – types of faults – fault current calculation
using symmetrical components – Earthing – Zones of protection and essential qualities of protection – Protection
schemes – CTs and PTs and their applications.
UNIT - II PROTECTIVE RELAYS 9
Operating principles of relays, the universal relay, electromagnetic relays (including torque equation, relay
characteristics): over current, directional, distance and differential relays, negative sequence relays, frequency relays
- static relays (including amplitude and phase comparators), Introduction to numerical relays.
UNIT - III APPARATUS PROTECTION 9
Apparatus protection – transformer, generator, motor - protection of bus bars, transmission lines
UNIT - IV THEORY OF CIRCUIT INTERRUPTION 9
Physics of arc phenomena and arc interruption, Restriking voltage & Recovery voltage, rate of rise of recovery
voltage, resistance switching, current chopping, Interruption of capacitive current – DC circuit breaking.
UNIT - V CIRCUIT BREAKERS 9
Types of Circuit Breakers – Oil and Air blast circuit breakers (Qualitative Treatment only), SF6 and Vacuum circuit
breakers - Air break circuit breakers – comparative merits of different circuit breakers – Testing of circuit breakers.
Total periods: 45
TEXT BOOKS
1. Badri Ram, Vishwakarma, “Power System Protection and Switchgear”, Tata McGraw Hill Publishing Co.
Ltd., 2001.
2. Bhuvanesh Oza,Nirmal-Kumar Nair, Rashesh Mehta,Vijay Makwana, “Power System Protection &
Switchgear”, First Edition, Tata McGraw hill, 2010.
REFERENCE BOOKS
1. Sunil S. Rao, “Switchgear and Protection”, Khanna publishers, New Delhi, 1986.
2. Wadhwa C.L., “Electrical Power Systems”, New age International (P) Ltd., Fourth Edition, 2005.
Page 27 of 85

3. Paithankar Y.G., and Bhide S.R., “Fundamentals of Power System Protection”, Prentice Hall of India Pvt.
Ltd., New Delhi – 110001, 2003.
4. Van A. R. and Warrington C., “Protective Relays - Their Theory and Practice: Vol. I and Vol. II”, Third
Edition, Chapman and Hall Ltd.
5. Madhavrao T.S., “Power System Protection: Static Relays”, Tata McGraw Hill Publishing Co. Ltd., Second
Edition, 2008.
6. Lythall R.T., “J and P Switchgear Handbook”, Newness Butterworths, 1972.
7. Prof. S.A. Soman, IIT, Bombay, Web course on “Power System Protection”, http://www.nptel.iiim.ac.in
8. Madhavrao T.S., “Digital Numerical Relays”, Tata McGraw Hill Publishing Co. Ltd., 2005.
Page 28 of 85

12EE2504 MICROPROCESSORS AND MICRO CONTROLLERS 3 0 0 3
AIM
To introduce Microprocessor Intel 8085, Arm processor and Micro Controllers
OBJECTIVES
· To study about architecture and programming of 8085.
· To learn about Pentium processor.
· To study about arm processor.
· To study about 8051 microcontroller.
· To learn about PIC microcontroller.
UNIT - I 8085 PROCESSOR & PROGRAMMING 9
Functional block diagram – Memory interfacing - Interrupt structure.- Instruction set and addressing modes-
Assembly language format-simple programming exercises.
UNIT - II PENTIUM PROCESSOR 9
Intel Pentium processors-Superscalar architecture and signals-special registers-cache structure-memory
management-Instruction set-Simple programs.
UNIT - III ARM PROCESSOR 9
The ARM architecture-ARM Assembly Language Program-ARM organization-Instruction set-The thumb
Instruction set-ARM CPU cores.
UNIT - IV MICRO CONTROLLER 8051 9
Functional block diagram - Instruction set and addressing modes – Interrupt structure-simple programming
exercises- Use of C compliers for 8051.
UNIT - V PIC MICROCONTROLLER 9
CPU Architecture-Instruction set-Interrupts-I2C bus-Timers-I/O port expansion-UART.
Total periods: 45
TEXT BOOKS
1. Gaonkar, S., “Microprocessor Architecture Programming and Application”, Penram International, Fifth
2. Muhammad Ali Mazidi & Janice Gilli Mazidi, “The 8051 Micro Controller and Embedded Systems”,
Pearson Education, 5th Indian reprint, 2003.
3. Barry. B. Bery “The Intel Microprocessors 8086/8088,80186/80188,80286,80386,80486,pentium and
Pentium pro processor-Architecture, programming and Interfacing”, Prentice Hall of India pvt.Ltd.,
Seventh Edition, 2006.
REFERENCES
1. Steve Furber, “ARM Sytem –On Chip architecture”, Addison Wesley, 2000.
2. John.B.Peatman, “Design with PIC Microcontrollers” Pearson Education, 1998.
Page 29 of 85

12EE2505 DIGITAL SIGNAL PROCESSING FOR ELECTRICAL ENGINEERS 3 1 0 3
AIM
To study the signal processing methods, processors and applications.
OBJECTIVES
· To study DFT and its computation
· To study the design techniques for digital filters
· To study the finite word length effects in signal processing
· To study the fundamentals of digital signal processors.
· To study the DSP applications
UNIT - I FAST FOURIER TRANSFORM 9
Introduction to DFT – Efficient computation of DFT- Properties of DFT – FFT algorithms – Radix-2 FFT
algorithms – Decimation in Time – Decimation in Frequency algorithms – convolution- overlap save method.
UNIT - II DESIGN OF INFINITE IMPULSE RESPONSE DIGITAL FILTER 9
Review of design of analogue Butterworth and Chebyshev Filters- Frequency transformation in analog domain –
Design of IIR digital filters using impulse invariance technique – Design of IIR digital filters using bilinear
transformation – pre warping – Frequency transformation in digital domain – Realization - Direct form I, Direct
form II, cascade and parallel.
UNIT - III DESIGN OF FINITE IMPULSE RESPONSE DIGITAL FILTERS 9
Linear phase response of FIR- Windowing techniques for design of linear phase FIR filters: Rectangular-
Hamming- Hanning- Blackman and Kaiser Windows. Gibbs phenomenon – Frequency sampling technique-.
Realization of FIR filters-lattice structure- Comparision of FIR & IIR.
UNIT - IV FINITE WORD LENGTH EFFECTS & DIGITAL SIGNAL PROCESSOR 9
Quantization noise – derivation for quantization noise power – Binary fixed point and floating-point number
representations – Comparison – truncation and rounding error – input quantization error-coefficient quantization
error – limit cycle oscillations-dead band- overflow error-signal scaling-scaling-Introduction to general and special
purpose hardware for DSP – Harvard architecture-Pipelining – Addressing Modes – Overview of Architecture and
instruction set of TMS320C50.
UNIT – V APPLICATIONS OF DIGITAL SIGNAL PROCESSING 9
Speech and Audio Signal Processing- Radar Signal Processing- Vocal Mechanism-Speech Technology- Parameters
of Speech- Speech Analysis- Speech Loading- Digital Processing of Audio Signals- Biomedical-ECG, EEG.
TEXT BOOKS
1. John G Proakis- Dimtris G Manolakis- Digital Signal Processing Principles- Algorithms and Application-
Pearson/PHI- 4th /e- 2007.
2. Allan V.Openheim, Ronald W.Sehafer & John R.Buck-“Discrete Time Signal Processing”, second /e-
Pearson/Prentice Hall.
3. Mitra S.K, “Digital Signal Processing- A Computer based approach”- Tata McGraw-Hill- 1998- New
Delhi.
REFERENCES
1. Venkataramani B & Bhaskar M, “Digital Signal Processor Architecture- Programming and
application” TMH 2002.
2. Johny R ”Johnson Introduction to Digital Signal Processing” Prentice Hall- 1984.
3. Li Tan, “Digital Signal Processing” Elsevier-2008.
Page 30 of 85

12EE2506 DATA STRUCTURES AND DEVELOPING ALGORITHMS 3 0 0 3
AIM
To provide an in-depth knowledge in problem solving techniques and data structures.
OBJECTIVES
· To learn the systematic way of solving problems
· To understand the different methods of organizing large amounts of data
· To learn to program in C
· To efficiently implement the different data structures
· To efficiently implement solutions for specific problems
UNIT - I INTRODUCTION TO DATA STRUCTURES 9
Abstract data types - Sequences as value definitions - Data types in C - Pointers in C -Data structures and C - Arrays
in C - Array as ADT - One dimensional array -Implementing one dimensional array - Array as parameters - Two
dimensional array -Structures in C - Implementing structures - Unions in C - Implementation of unions -Structure
parameters - Allocation of storage and scope of variables. Recursive definition and processes: Factorial function -
Fibonacci sequence - Recursion in C - Efficiency of recursion.
UNIT - II STACK, QUEUE AND LINKED LIST 9
Stack definition and examples – Primitive operations – Example - Representing stacks in C - Push and pop operation
implementation. Queue as ADT - C Implementation of queues - Insert operation - Priority queue - Array
implementation of priority queue. Inserting and removing nodes from a list-linked implementation of stack, queue
and priority queue - Other list structures - Circular lists: Stack and queue as circular list -Primitive operations on
circular lists. Header nodes - Doubly linked lists - Addition of long positive integers on circular and doubly linked
list.
UNIT - III TREES 9
Binary trees: Operations on binary trees - Applications of binary trees - Binary tree representation - Node
representation of binary trees - Implicit array representation of binary tree – Binary tree traversal in C - Threaded
binary tree - Representing list as binary tree - Finding the Kth element - Deleting an element. Trees and their
applications: C representation of trees - Tree traversals - Evaluating an expression tree - Constructing a tree.
UNIT -IV SORTING AND SEARCHING 9
General background of sorting: Efficiency considerations, Notations, Efficiency of sorting. Exchange sorts; Bubble
sort; Quick sort; Selection sort; Binary tree sort; Heap sort. Heap as a priority queue - Sorting using a heap-heap sort
procedure - Insertion sorts: Simple insertion - Shell sort - Address calculation sort - Merge sort -Radix
sort.Sequential search: Indexed sequential search - Binary search - Interpolation search.
UNIT - V GRAPHS 9
Application of graph - C representation of graphs - Transitive closure - Warshall”s algorithm – Shortest path
algorithm - Linked representation of graphs - Dijkstra”s algorithm - Graph traversal - Traversal methods for graphs -
Spanning forests - Undirected graph and their traversals - Depth first traversal - Application of depth first traversal -
Efficiency of depth first traversal - Breadth first traversal - Minimum spanning tree - Kruskal”s algorithm - Round
robin algorithm.
Total periods: 45
TEXT BOOKS
1. Aaron M. Tenenbaum, Yeedidyah Langsam, Moshe J. Augenstein, “Data structures using C”, Pearson
Education, 2004 / PHI
REFERENCES
1. Balagurusamy E, “Programming in Ansi C”, Fifth Edition, Tata McGraw Hill Publication, 2010.
2. Robert L. Kruse, Bruce P. Leung Clovis L.Tondo, “Data Structures and Program Design in C”, Pearson
Education, 2000 / PHI.
Page 31 of 85

12EE2507 SYNCHRONOUS AND INDUCTION MACHINES LABORATORY 0 0 3 2
AIM
To expose the students to the operation of synchronous machines and induction motors and give them
experimental skill.
EXPERIMENTS
1. Regulation of three phase alternator by emf and mmf methods.
2. Regulation of three phase alternator by ZPF and ASA methods.
3. Regulation of three phase salient pole alternator by slip test.
4. Measurements of negative sequence and zero sequence impedance of alternators.
5. V and Inverted V curves of three Phase Synchronous Motor.
6. Load test on three-phase induction motor.
7. No load and blocked rotor test on three-phase induction motor.
8. Separation of No-load losses of three-phase induction motor.
9. Load test on single-phase induction motor
10. No load and blocked rotor test on single-phase induction motor.
Practical 45
Additional experiments
11. Study of starters for synchronous and induction motors.
12. Parallel operation of three phase alternators.
Page 32 of 85

12EE2508 DATA STRUCTURES AND ALGORITHMS LABORATORY 0 0 3 2
AIM
To train the students in developing algorithms and writing programs in data structures.
EXPERIMENTS
1. Queue implementation using arrays.
2. Stack implementation-using arrays.
3. Singly, doubly and circular liked list implementation and all possible operation on lists.
4. Queue and Stack implementation using linked list
5. Binary search tree implementation using linked list and possible operations on binary search trees
6. In-order, pre-order and post order traversals.
7. Quick sort implementation and its efficiency calculation.
8. Binary Search implementation.
9. Graph implementation-using arrays and list structure.
10. Depth first and Breadth first traversal in graphs.
Practical 45
Page 33 of 85

12EN2001 COMMUNICATION SKILLS LABORATORY 0 0 2 1
AIM
Globalization has brought in numerous opportunities for the teeming millions, with more focus on the students over
all capability apart from academic competence. Many students, particularly those from non- English medium
schools, find that they are not preferred due to their inadequacy of communication skills and soft skills, despite
possessing sound knowledge in their subject area along with technical capability. Keeping in view their pre-employment
needs and career requirements, this course on Communication Skills Laboratory will prepare students
to adapt themselves with ease to the industry environment, thus rendering them as prospective assets to industries.
The course will equip the students with the necessary communication skills that would go a long way in helping
them in their profession.
OBJECTIVES
· To equip students of engineering and technology with effective speaking and listening skills in English.
· To help them develop their soft skills and people skills, which will make
The transition from college to workplace smoother and help them to excel in their jobs.
· To enhance students’ performance at Placement Interviews, Group Discussions and other recruitment exercises.
I.PC based session (weightage- 40%)
A. English Language Lab
1. Listening Comprehension
Listening and typing- Listening and sequencing of sentences - Filling in the blanks - Listening and answering
the questions.
2. Reading Comprehension and Vocabulary
Filling in the blanks - Cloze Exercises - vocabulary building –Verbal Passages.
3. Speaking.
Phonetics: Intonation - Ear Training - Correct Pronunciation - Sound recognition exercises - Common Errors in
English.
Conversations: Face to Face Conversation - Telephone Conversation -Role play activities (Students take on
roles and engage in Conversation)
B. Career Lab
(Samples are available to learn and practice in the class room session)
1. Resume / Report preparation / Letter writing
Structuring the resume / report - Letter writing / E-mail Communication -Samples.
2. Presentation skills
Elements of an effective presentation - Structure of a presentation - Presentation tools - Voice Modulation-
Audience analysis - Body Language -Video Samples
3. Group Discussion
Page 34 of 85

Why is GD part of selection process? - Structure of a GD - Moderator- Led and other GDs - Strategies in GD -
Team work - Body Language - Mock GD -Video samples
4. Interview Skills
Kinds of Interviews -Required Key Skills - Corporate culture - Mock Interviews -Video Samples
5. Corporate Etiquette: Telephone etiquette-email etiquette-dining etiquette
II Class Room Session (Weightage - 60 %) Periods
· Presentation Skills.
· Group Discussion.
· Presenting a Sales Plan.
· Presenting a Company Profile
· Product Demonstration.
· Mock Interview.
· Introducing a famous personality to the Audience.
· Welcome address & Vote of thanks.
· Case Study.(Related to Engineering).
· Decision Making & Problem Solving Techniques.
Note:
Class room sessions are practice sessio
Page 35 of 85

VI SEMESTER
12EE2601 ELECTRIC MACHINE DESIGN 3 1 0 4
AIM
To expose the students to the concept of design of various types of electrical machines
OBJECTIVES
To provide sound knowledge about constructional details and design of various electrical machines.
· To study mmf calculation and thermal rating of various types of electrical machines.
· To design armature and field systems for D.C. machines.
· To design core, yoke, windings and cooling systems of transformers.
· To design stator and rotor of induction machines.
· To design stator and rotor of synchronous machines and study their thermal behaviour.
Major considerations in Electrical Machine Design - Electrical Engineering Materials – Space factor –Choice of
Specific Electrical and Magnetic loadings - Thermal considerations - Heat flow –Temperature rise - Rating of
machines – Standard specifications.
UNIT - II D.C. MACHINES 9
Output equation – Main dimensions - Choice of specific loadings – Choice of number of poles – Armature design –
Design of field poles and field coil – Design of commutator and brushes – Losses and efficiency calculations.
UNIT - III TRANSFORMERS 9
Output rating of single phase and three phase transformers – Optimum design of transformers – Design of core,
yoke and windings for core and shell type transformers – Equivalent circuit parameter from designed data – Losses
and efficiency calculations – Design of tank and cooling tubes of transformers.
UNIT IV THREE PHASE INDUCTION MOTORS 9
Output equation – Main dimensions – Choice of specific loadings – Design of stator – Design of squirrel cage and
slip ring rotor – Equivalent circuit parameters from designed data – Losses and efficiency calculations.
UNIT V SYNCHRONOUS MACHINES 9
Output equation – Choice of specific loadings – Main dimensions – Short circuit ratio – Design of stator and rotor of
cylindrical pole and salient pole machines - Design of field coil - Performance calculation from designed data -
Introduction to computer aided design.
TEXT BOOKS
1. Sawhney A.K, “A Course in Electrical Machine Design”, Dhanpat Rai and Sons, New Delhi, 2004.
2. Sen S.K, “Principles of Electrical Machine Design with Computer Programmes”, Oxford and IBH
Publishing Co.Pvt Ltd., New Delhi, 1987.
REFERENCES
1. Agarwal R.K, “Principles of Electrical Machine Design”, S.K.Kataria and Sons, Delhi, 2009.
2. Mittle V.N and Mittle A, “Design of Electrical Machines”, Standard Publications and Distributors, Delhi,
2002.
Page 36 of 85

12EE2602 POWER SYSTEM ANALYSIS 3 1 0 4
AIM
To become familiar with the modeling of various power system components and different methods of
analysis for power system planning and operation.
OBJECTIVES
· To model steady-state operation of large-scale power systems and to solve the power flow problems using
efficient numerical methods suitable for computer simulation.
· To model and analyse power systems under abnormal (fault) conditions.
· To model and analyse the dynamics of power system for small-signal and large signal disturbances and o
design the systems for enhancing stability.
Overview of Power System Analysis: Importance of system planning and operational analysis; Distinction between
steady state, quasi steady state and transient analysis; Per phase analysis of symmetrical three phase system, single
line diagram, per UNIT representation; different models for generator, load and transmission lines based on the
analysis of interest – π equivalent circuit of transformer with off nominal-tap ratio.
UNIT - II BASICS OF ANALYSIS AND COMPONENT MODELLING 9
Primitive network and its matrices, bus admittance matrix formation by inspection method and singularity
transformation method, bus impedance matrix formation by L-U factorisation of bus admittance matrix and by
building algorithm. Symmetrical component transformation, sequence impedances and sequence networks.
UNIT - III POWER FLOW ANALYSIS 9
Importance of power flow analysis in planning and operation of power systems; Power flow problem: Description of
the problem, classification of buses into P-Q buses, P-V (voltage-controlled) buses and slack bus. Power flow
equations and solution: Development of power flow model in complex variable form, Iterative solution using Gauss-
Seidel and Newton-Raphson methods including Q-limit check for voltagecontrolled buses, flow chart- numerical
examples.
UNIT - IV FAULT ANALYSIS 9
Symmetrical short circuits: Thevenin”s theorem and applications, short circuit analysis - Numerical examples. Short
circuit capacity - Circuit breaker selection. Unsymmetrical short circuits: Derivation of fault current for LG, LL,
LLG short circuits and development of interconnection of sequence networks.
UNIT - V STABILITY ANALYSIS 9
Description of power system stability problem; importance of stability analysis in power system planning and
operation; classification of power system stability. Single Machine Infinite Bus (SMIB) system: Development of
swing equation; power-angle equation; Equal Area Criterion; determination of critical clearing angle and time;
algorithm for numerical solution of swing equation using modified Euler method; usage of numerical algorithm for
determination of critical clearing time by trial and error – Digital simulation.
TEXT BOOKS
1. Hadi Saadat, “Power System Analysis”, Tata McGraw Hill Publishing Company Ltd., 2nd Edition, New
Delhi, 2009.
2. John J. Grainger and W.D. Stevenson Jr., “Power System Analysis”, Tata McGraw Hill Publishing
Company Ltd., New Delhi,2003.
3. Kothari D.P, Nagarath I.J., “Power System Engineering”,Tata McGraw-Hill Publishing Company Ltd., 2nd
Edition, NewDelhi, 2008.
REFERENCES
Page 37 of 85

1. Kundur P, “Power System Stability and Control, Tata McGraw-Hill Publishing Company Ltd., New Delhi, 1994.
2. Nagrath I.J. and Kothari D.P., “Modern Power System Analysis”, Tata McGraw-Hill Publishing Company Ltd.,
3rd Edition, New Delhi, 2003.
3. Olle. I. Elgerd, “Electric Energy Systems Theory – An Introduction”, Tata McGraw Hill Publishing Company
Limited, 2nd Edition, New Delhi, 2008.
Page 38 of 85

12EE2603 POWER ELECTRONICS 3 1 0 4
AIM
To introduce the application of electronic devices for conversion, control and conditioning of electric power.
OBJECTIVES
· To get an overview of different types of power semi-conductor devices and their switching characteristics.
· To understand the operation, characteristics and performance parameters of controlled rectifiers.
· To study the operation, switching techniques and basic topologics of DC-DC switching regulators.
· To learn the different modulation techniques of pulse width modulated inverters and to understand the
harmonic reduction methods.
· To know the practical application for power electronics converters in conditioning the power supply.
UNIT - I POWER SEMI-CONDUCTOR DEVICES 9
Structure, operation and characteristics of SCR, TRIAC, power transistor, MOSFET and IGBT. Driver and snubber
circuits for MOSFET - Turn-on and turn-off characteristics and switching losses.
UNIT - II LINE COMMUTATED CONVERTERS 9
2,4 pulse converter with R,RL,RLE loads, effect of free wheeling diode – continuous and discontinuous conduction
mode - Effect of source inductance and load inductance – introduction to 3,6 pulse converter - Dual converters-
Series converters. Basic principle of operation of single phase cycloconverter- AC voltage controllers.
UNIT - III DC TO DC CONVERTERS 9
Step-down and step-up choppers - Time ratio control and current limit control – class of choppers - Switching mode
regulators: Buck, boost, buck-boost and cuk converter - Resonant switching based SMPS.
UNIT - IV INVERTERS 9
Single phase and three phase (both 1200 mode and 1800 mode) inverters - PWM techniques: Sinusoidal PWM,
modified sinusoidal PWM and multiple PWM - Voltage and harmonic control - Series resonant inverter - Current
source inverters.
UNIT - V APPLICATIONS 9
Uninterrupted power supply topologies - Flexible AC transmission systems - Shunt and series static VAR
compensator - Unified power flow controller- HVDC Transmission.
TEXT BOOKS
1. Bimbhra P.S, “Power Electronics” , Khanna Publishers, New Delhi, 2012
2. Singh M.D, Khandchandni K.B, Power Electronics, Tata Mc Graw Hill, 2nd Edition, 2007
REFERENCES
1. Muhammad H. Rashid, “Power Electronics: Circuits, Devices and Applications”, Pearson
Education, 3rd edition, 2004 / PHI
2. Cyril.W.Lander, “Power Electronics”, McGraw Hill International, 3rd edition, 1994
3. Bimal K. Bose, “Modern Power Electronics and AC Drives”, Pearson Education, 2003
4. Jagannathan V., “Introduction to Power Electronics”, Prentice Hall of India, 2004
Page 39 of 85

12EE2604 EMBEDDED SYSTEM DESIGN 3 0 0 3
AIM
To understand the basic concepts of embedded system design and its applications to various fields.
OBJECTIVES
To provide a clear understanding of
· Embedded system terminologies and its devices.
· Various Embedded software Tools
· Design and architecture of Memories.
· Architecture of processor and memory organizations.
· Input/output interfacing
· Various processor scheduling algorithms.
· Basics of Real time operating systems.
· Introduction to PIC and its applications.
UNIT - I INTRODUCTION TO EMBEDDED SYSTEMS 9
Introduction to embedded real time systems – The build process for embedded systems – Types of memory –
Memory management methods.
UNIT - II EMBEDDED SYSTEM ORGANIZATION 9
Structural UNITs in processor , selection of processor & memory devices – DMA – I/O devices : timer & counting
devices – Serial communication using I2C , CAN USB buses – Parallel communication using ISA , PCI ,PCI/X
buses – Device drivers
UNIT - III PROGRAMMING AND SCHEDULING 9
Intel I/O instructions – Synchronization - Transfer rate, latency; interrupt driven input and output - Nonmaskable
interrupts, software interrupts, Preventing interrupts overrun - Disability interrupts. Multithreaded programming –
Context Switching, Preemptive and non-preemptive multitasking, semaphores. Scheduling-thread states, pending
threads, context switching
UNIT - IV REAL-TIME OPERATING SYSTEMS 9
Introduction to basic concepts of RTOS, UNIX as a Real Time Operating system – Unix based Real Time operating
system - Windows as a Real time operating system – POSIX – RTOS-Interrupt handling - A Survey of
contemporary Real time Operating systems:PSOS, VRTX, VxWorks, QNX, чC/OS-II, RT Linux – Benchmarking
Real time systems – Basics.
UNIT - V PIC MICROCONTROLLER BASED EMBEDDED SYSTEM DESIGN 9
PIC microcontroller – MBasic compiler and Development boards – The Basic Output and digital input –
Applications
Total periods: 45
TEXT BOOKS
1. Rajkamal, “Embedded system-Architecture, Programming, Design”, Tata Mc graw Hill, 2nd Edition, 2008.
2. Daniel W. Lewis ,”Fundamentals of Embedded Software”, Pearson College Division, 2nd Edition, 2012.
REFERENCES
1. Jack R Smith “Programming the PIC microcontroller with MBasic” Elsevier, 2005
2. Tammy Noergaard, “Embedded Systems Architecture”, Elsevier, 2005
3. Rajib Mall “Real-Time systems Theory and Practice” Pearson Education, 2007
4. Sriram. V.Iyer & Pankaj Gupta, “Embedded real time systems Programming”, Tata McGraw Hill, 2004.
Page 40 of 85

12EE2605 MANAGEMENT CONCEPTS AND PRACTICES 3 0 0 3
AIM
To expose the students to Management concepts and techniques.
OBJECTIVE
Knowledge on the management concepts is essential for all kinds of people in all kinds of organizations. After
studying this course, students will be able to have a clear understanding of the basic concepts and functions of
management, human resource management, Marketing Management & Financial Management, accounting
concepts, Management Information System & Production/Operations, Social and Ethical Issues in Management.
Students will also gain some basic knowledge on international aspect of management.
UNIT - I BASIC CONCEPTS AND FUNCTIONS OF MANAGEMENT 9
Planning: Nature Purpose and OBJECTIVEs of Planning; Organizing; Nature and Purpose of Organizing; Authority
and Responsibility; Staffing, Supply of Human Resources; Performance Appraisal; Controlling; System and Process
of Controlling; Control Techniques.
UNIT - II HUMAN RESOURCE MANAGEMENT 9
Nature and Scope of Human Resource Planning; Training and Development : Recruitment and Selection; Career
Growth; Absenteeism: Grievances; Motivation and its Types; Need for Motivation: Reward and Punishment;
Models of Motivation; Leaders; Kinds of Leaders, Leadership Styles, roles and Functions of Leaders; Conflict
Management; Kinds and ; Causes of Conflict; Settlement of Conflicts. Group and Team Working, organizational
Design and Development.
UNIT–III MARKETING MANAGEMENT & FINANCIAL MANAGEMENT, ACCOUNTING
CONCEPTS 9
Marketing Environment: Consumer Markets and Buyer Behaviour; Marketing Mix, Advertising and Sales
Promotions; Channels of Distribution. Financial Management and Accounting Concepts Book Keeping; Financial
Statements Analysis: Financial Ratios: Capital Budgeting: break-even Analysis Production/Operations Management
Planning and Design of Production and Operations Systems; Facilities Planning Location, Layout and Movement of
materials; Materials Management and Inventory Control; Maintenance Management PERT & CPM.
UNIT– IV MANAGEMENT INFORMATION SYSTEM & PRODUCTION/OPERATIONS
MANAGEMENT 9
Role of Information in decision making; Information System Planning, Design and Implementation Evaluation and
Effectiveness of the Information System. Statistical Quality Control, Total Quality Management and ISO
Certification. Production/Operations Management: Planning and Design of Production and Operations Systems;
Facilities Planning Location, Layout and Movement of materials; Materials Management and Inventory Control;
Maintenance Management PERT & CPM.
UNIT - V SOCIAL AND ETHICAL ISSUES IN MANAGEMENT 9
Ethics in Management, Social Factors; Unfair and Restrictive Trade Practices. Strategic and Technology
Management Need, Nature, Scope and Strategy SWOT analysis, value chain concept.
Total periods: 45
TEXT BOOKS
1. Kotler Philip, “Marketing Management”, Prentice Hall of India, 11th Edition, 2003.
2. Luthans Fred, “Human Resource Management”, McGraw-Hill Inc., 1997
3. Robbins Stephen, P., “Organizational Behaviours Concepts, Controversies and Application”, Prentice Hall,
Englewood, Cliffs, New Jersey, 2010.
4. Khan, M.Y. & Jain, P.K., “Financial Management”, Tata McGraw-Hill, 4th Edition, 2004.
Page 41 of 85

REFERENCES
1. Porter Michael, “Competitive Advantage”, The Free Press, 1985.
2. Porter Micheal, “Competitive Strategy”, The Free Press, 1980.
3. Bhushan, Y.K., “Fundamentals of Business Organization and Management”, Sultan Chand and Sons, 1965.
4. Ahuja, K.K., “Industrial Management”, Khanna Publishers, 1998.
Page 42 of 85

12EE2607 CONTROL SYSTEMS LABORATORY 0 0 3 2
AIM
To provide a platform for understanding the basic concepts of control system and to apply them for the
design and control of practical systems.
OBJECTIVES
After successful completion of this course, the students will be able to,
· Experimentally determine transfer functions of practical systems.
· Obtain the step response of practical systems.
· Carry out the stability analysis of practical systems.
· Design PID controller for practical systems.
List of EXPERIMENTS
1. Open loop and closed loop speed control of dc servo motor.
2. Determination of transfer function of armature controlled DC servomotor.
3. Determination of transfer function of AC servomotor.
4. Determination of transfer function of a third order (or higher order) system from its frequency response.
5. Determination of transfer function of a higher order system with two or more sub systems.
6. Step response of type-0 and type-1 UNITy feedback first and second order systems.
7. Stability analysis of third order (or higher order) systems.
8. Design of a second order (or third order) system for the desired specifications.
9. Design of PID controller for a given system.
10. Study of any one closed-loop control system such as dc position control, temperature control water level
control systems.
11. MATLAB simulation of step response of LTI systems.
12. Stability analysis of LTI systems using Root locus, Bode and Nyquist plots.
Practical 45
Page 43 of 85

12EE2608 DSP AND MICROPROCESSORS LABORATORY 0 0 3 2
AIM
To expose the students to gain programming skills in DSP and Microprocessors.
DSP
1. Generation of basic sequences using MATLAB
UNIT sample sequence
UNIT step sequence
UNIT ramp sequence
2. Computation of Fast Fourier Transform using MATLAB
DIT – FFT algorithm
DIF – FFT algorithm
3. Design and simulation of FIR filter using windowing technique
4. Design and simulation of IIR filter using Bilinear Transformation and Impulse Invariant method.
5. Generation of following waveforms using TMS320C50 trainer Kit
Sine wave
Square wave
Saw tooth wave
Triangular wave
6. Linear convolution and circular convolution using TMS320C50 trainer Kit
MICROPROCESSORS:
1. Simple arithmetic operations: Multi precision addition / subtraction / multiplication / division.
2. Programming with control instructions: Increment / Decrement. Ascending / Descending order. Maximum /
minimum of numbers.
3. Rotate instructions. Hex / ASCII / BCD code conversions.
4. Interface EXPERIMENTS: A/D Interfacing. D/A Interfacing. Traffic light controller.
5. Interface EXPERIMENTS: Simple EXPERIMENTS using 8251, 8279, 8253, and 8254.
6. Programming practice on assembler and simulator tools.
Practical 45
Page 44 of 85

VII SEMESTER
12EE2701 ELECTRIC ENERGY GENERATION, UTILISATION AND CONSERVATION
3 0 0 3
AIM
To expose the students to the main aspects of electric energy generation, utilization and conservation.
OBJECTIVES
· Conventional methods of generation and conservative methods.
· Principle and design of illumination systems and
· Methods of heating and welding
· Electric traction systems and their performance.
· Industrial applications of electric drives.
UNIT - I GENERATION 9
Generation of electrical power by conventional methods – Introduction to the concept of distributed generation –
Effect on system operation.
UNIT - II CONSERVATION 9
Economics of generation – Definitions – Load curves – Number and size of UNITs – Cost of electrical energy –
Tariff – Need for electrical energy conservation – Methods – Energy efficient equipment – Energy management –
Energy auditing. Economics of power factor improvement – Design for improvement of power factor using power
capacitors – Power quality – Effect on conservation.
UNIT - III ILLUMINATION 9
Definition and meaning of terms used in illumination Engineering – Classification of light sources – Laws of
illumination - Nature of radiation – Photometry – Lighting calculations – Design of illumination systems (for
residential, industrial, commercial, health care, street lightings, sports, administrative complexes) - Types of lamps:
Incandescent lamps, sodium vapour lamps, mercury vapour lamps, fluorescent lamps - Energy efficiency lamps.
UNIT - IV HEATING AND WELDING 9
Introduction – Advantages of Electric heating – Modes of heat transfer – Methods of heating, requirement of heating
material – Design of heating element – Furnaces – Welding generator – Welding transformer and its characteristics.
Requirements of good weld – Preparation of work – Electrodes – Power supply for arc welding.
UNIT - V ELECTRIC TRACTION 9
Introduction – Requirements of an ideal traction system – Supply systems – Mechanics of train movement –
Traction motors and control – Multiple UNITs – Braking – Current collection systems – Recent trends in electric
traction.
Total periods: 45
TEXT BOOKS
1. Openshaw Taylor E, “Utilization of Electrical Energy in SI UNITs”, Orient Longman Pvt.Ltd, 2003.
2. Gupta B.R, “Generation of Electrical Energy”, Eurasia Publishing House (P) Ltd, New Delhi, 2009.
REFERENCES
1. Partab H, “Art and Science of Utilisation of Electrical Energy”, Dhanpat Rai and Co, New Delhi, 2004
2. Gopal.K.Dubey, “Fundamentals of Electrical Drives”, Narosa Publishing House, New Delhi, 2nd edition,
2004.
Page 45 of 85

3. Wadhwa C.L, “Generation, Distribution and Utilization of Electrical Energy”, New Age International Pvt.Ltd,2nd
Edition, 2003
4. Gupta J.B, “Utilization of Electric Power and Electric Traction”, S.K.Kataria and Sons, 2002.
Page 46 of 85

12EE2702 ELECTRIC DRIVES AND CONTROL 3 0 0 3
AIM
To expose the students to the concepts of electric drives and controls.
OBJECTIVES
· To learn about basic concepts of electric drives.
· To learn about different types of DC drives.
· To study about Induction motor drives.
· To learn about special machines drives.
· To understand design of controllers for drives.
UNIT - I Introduction to Electric Drives 9
History and development of Electric Drives, Classification of Electric Drives, Basic elements & advantages of
variable speed drives- Joint Speed-Torque characteristics of various types of loads and drive motors- Modes of
operation, closed loop control of drives - Selection of power rating for drive motors with regard to thermal
overloading and load variation-Load Equalization.
UNIT - II Dc Drives 9
Speed control of DC motors - Ward - Leonard scheme - drawbacks - Thyristor converter fed dc drives: Single, two
and four quadrant operations - Chopper fed DC drives : - Time ratio control and current limit control - Single, two
and four quadrant operations – Effect of ripples on the motor performance.
UNIT - III Three Phase Induction Motor Drives 9
Speed control of 3 phase Induction Motors - Stator control: PWM &V/f control, rotorcontrol: Rotor resistance
control - Static control of rotor resistance using DC chopper - Static Krammer and Scherbius drives – Introduction to
Vector Controlled Induction Motor Drives.
UNIT - IV Drives for Special Machines 9
Speed control of 3 phase Synchronous Motors - True synchronous and self controlled modes of operations - DC
servo drives principle of operation AC servo drives principle of operation - Principle and control of Stepper motor
and Switched Reluctance Motor drives.
UNIT - V Digital Control and Drive Applications 9
Digital techniques in speed control - Advantages and limitations - Microprocessor/Microcontroller and PLC based
control of drives, networking of drives - Selection of drives and control schemes for Steel rolling mills, Paper mills,
Cement mills, Machine tools, Lifts and Cranes. Solar and battery powered drives.
Total periods: 45
TEXT BOOKS
1. Dubey, G.K., “Fundamentals of Electrical Drives”, Narosa Publishing House, 2nd Edition, New Delhi,
2004.
2. Bose, B.K., “Modern Power Electronics and AC Drives", Prentice Hall India Ltd., New Delhi, 2002.
REFERENCES
1. Ion Boldea and Nasar S. A., “Electric Drives”, CRC Press LLC, New York, 2nd Edition, 2006.
2. Krishnan R, “Electric Motor Drives: Modelling, Analysis and Control, Prentice Hall of India Pvt. Ltd., New
Delhi, 2002.
3. Vedam Subramanyam, “Electric Drives: Concepts and Applications”, Tata McGraw Hill Publishing
Company Limited, New Delhi, 2004.
Page 47 of 85

12EE2703 POWER SYSTEM ECONOMICS AND CONTROL TECHNIQUES 3 1 0 4
AIM
To become familiar with the preparatory work necessary for meeting the next day’s power system
operation and the various control actions to be implemented on the system to meet the minute-to-minute variation of
system load.
OBJECTIVES
· To get an overview of system operation and control.
· To understand & model power-frequency dynamics and to design power-frequency controller.
· To understand & model reactive power-voltage interaction and different methods of control for
maintaining voltage profile against varying system load.
System load variation: System load characteristics, load curves daily, weekly and annual, load-duration curve, load
factor, diversity factor. Reserve requirements: Installed reserves, spinning reserves, cold reserves, hot reserves.
Overview of system operation: Load forecasting, UNIT commitment, load dispatching. Overview of system control:
Governor Control, LFC, EDC, AVR, system voltage control, security control.
UNIT - II REAL POWER - FREQUENCY CONTROL 8
Fundamentals of speed governing mechanism and modeling: Speed-load characteristics – Load sharing between two
synchronous machines in parallel; concept of control area, LFC control of a single-area system: Static and dynamic
analysis of uncontrolled and controlled cases, Economic Dispatch Control. Multi-area systems: Two-area system
modeling; static analysis, uncontrolled case; tie line with frequency bias control of two-area system derivation, state
variable model.
UNIT - III REACTIVE POWER–VOLTAGE CONTROL 9
Typical excitation system, modeling, static and dynamic analysis, stability compensation; generation and absorption
of reactive power: Relation between voltage, power and reactive power at a node; method of voltage control:
Injection of reactive power. Tap-changing transformer, numerical problems - System level control using generator
voltage magnitude setting, tap setting of OLTC transformer and MVAR injection of switched capacitors to maintain
acceptable voltage profile and to minimize transmission loss.
UNIT - IV UNIT COMMITMENT AND ECONOMIC DISPATCH 9
Statement of UNIT Commitment (UC) problem; constraints in UC: spinning reserve, thermal UNIT constraints,
hydro constraints, fuel constraints and other constraints; UC solution methods: Priority-list methods, forward
dynamic programming approach, numerical problems only in priority-list method using full-load average production
cost. Incremental cost curve, co-ordination equations without loss and with loss, solution by direct method and λ-
iteration method. (No derivation of loss coefficients.) Base point and participation factors. Economic dispatch
controller added to LFC control.
UNIT - V COMPUTER CONTROL OF POWER SYSTEMS 10
Energy control centre: Functions – Monitoring, data acquisition and control. System hardware configuration –
SCADA and EMS functions: Network topology determination, state estimation, security analysis and control.
Various operating states: Normal, alert, emergency, inextremis and restorative. State transition diagram showing
various state transitions and control strategies.
TEXT BOOKS
1. Olle. I. Elgerd, “Electric Energy Systems Theory – An Introduction”, Tata McGraw Hill Publishing
Company Ltd, New Delhi, 2nd Edition, 2008
2. Allen.J.Wood and Bruce F.Wollenberg, “Power Generation, Operation and Control”, John Wiley & Sons,
Inc., 2003
3. Kundur P, “Power System Stability & Control”, Tata-McGraw Hill publications,USA,2005
Page 48 of 85

REFERENCES
1. Kothari D.P and Nagrath I.J, “Modern Power System Analysis”, 3rd Edition, Tata McGraw Hill Publishing
Company Limited, New Delhi, 2003.
2. Grigsby L.L, “The Electric Power Engineering, Hand Book”, CRC Press and IEEE Press, 2001.
Page 49 of 85

12ME2001 TOTAL QUALITY MANAGEMENT 3 0 0 3
AIM
To provide a platform to have a sound understanding of the basic concepts to the students of TQM.
OBJECTIVES
· To enable the students understand the principles of Quality Management
· To provide students details of quality planning and TQM techniques
UNIT – I INTRODUCTION 7
Definition of Quality, Dimensions of Quality, Factors affecting Quality, Quality Planning, Quality costs,
Comparison of TQM concept with older concept, Leadership – Concepts, characteristics and role of Quality leaders,
Deming Philosophy, Barriers to TQM Implementation.
UNIT – II TQM PRINCIPLES 11
Customer satisfaction – Customer Perception of Quality, Customer Complaints, Service Quality, Customer
Retention, Employee Involvement – Motivation, Empowerment, Teams, Recognition and Reward, Performance
Appraisal.Continuous Process Improvement – Juran Trilogy, PDSA Cycle, 5S, Kaizen. Taguchi’s Quality
Engineering - Quality Loss Function, Parameter and Tolerance design, signal to noise ratio. Supplier Partnership –
Concept of Quality Circle -Business Excellence Model-Rajiv Gandhi National Quality Award
UNIT – III STATISTICAL PROCESS CONTROL (SPC) 9
The seven tools of Quality, Statistical methods for quality improvement. Process control -Control charts for
variables: X, R charts and Control charts for attributes – P, np, c and u charts. Concept of Process Capability,
Concept of six sigma, New seven management tools.
UNIT – IV TQM TOOLS 9
Benchmarking – Reasons to Benchmark, Benchmarking Process, Quality Function Deployment (QFD) – House of
Quality, QFD Process, Benefits, Taguchi Quality Loss Function, Total Productive Maintenance (TPM) – Concept,
Improvement Needs, FMEA – Stages of FMEA.
UNIT – V QUALITY SYSTEMS 9
Quality Management System: Need for QMS, Elements, Reasons for implementation of Quality System, ISO
9000:2008: Classification, Quality System Requirements, Documentation of Quality System, Quality Auditing, ISO
14000 – Environmental Management System, Major elements of EMS, EMS Model, Benefits.
Total Periods: 45
TEXT BOOKS
1. Dale.H.Besterfiled, et al., “Total Quality Management”, Pearson Education Asia, 2nd Edition, 1999,
Indian Reprint, 2002.
2. James.R.Evans, &William.M.Lidsay., “Management and Control of Quality”, Thompson Learning,
2005.
REFERENCE BOOKS
1. SubburajRamasamy., “Total Quality Management”, Tata McGraw Hill, NewDelhi, 2005
2. Narayana.V and Sreenivasan.N.S., “Quality Management – Concepts and Tasks”, New Age
International Edition, 1996.
3. KanishkaBedi., “Total Quality Management”, Oxford University Press, 2006.
4. Mukherjee.P.N, “Total Quality Management”, Prentice Hall, 2005.
5. Suganthi .L., Anand.A.Samuel., “Total Quality Management”, Prentice Hall of India, 2008.
12EE2707 POWER ELECTRONICS AND DRIVES LABORATORY 0 0 3 2
Page 50 of 85

AIM
To introduce the basic concepts of power electronics and drives.
EXPERIMENTS
1. Characteristics of SCR, TRIAC.
2. AC phase control using TRIAC/ SCR with R and RL load.
3. Transient characteristics of SCR and MOSFET
4. AC to DC fully controlled converter & half controlled converter
5. Step down and step up MOSFET based choppers
6. IGBT based single-phase & three phase PWM inverter
7. Simulation of closed loop control of converter fed DC motor.
8. Simulation of closed loop control of chopper fed DC motor.
9. Simulation of VSI fed 3 phase induction motor.
10. Speed control of DC motor using 3 Phase Rectifier.
11. Speed control of 3 phase induction motor using PWM inverter.
12. PLC based drives.
Practical 45
Page 51 of 85

12EE2708 POWER SYSTEM SIMULATION LABORATORY 0 0 3 2
AIM
To acquire software development skills and experience in the usage of standard packages necessary for
analysis and simulation of power system required for its planning, operation and control.
OBJECTIVES
I. To develop simple C programs for the following basic requirements:
a) Formation of bus admittance and impedance matrices and network solution.
b) Power flow solution of small systems using simple method, Gauss-Seidel P.F. Method.
c) UNIT Commitment and Economic Dispatch.
II. To acquire experience in the usage of standard packages for the following analysis / simulation / control
functions.
d) Steady-state analysis of large system using NRPF and FDPF methods.
e) Quasi steady-state (Fault) analysis for balanced and unbalanced faults.
f) Transient stability simulation of multimachine power system.
g) Simulation of Load-Frequency Dynamics and control of power system.
EXPERIMENTS
1. Computation of Parameters and Modelling of Transmission Lines
2. `Formation of Bus Admittance and Impedance Matrices and Solution of Networks.
3. Load Flow Analysis - I: Solution of Load Flow And Related Problems Using Gauss-Seidel Method
4. Load Flow Analysis - II: Solution of Load Flow and Related Problems Using Newton-Raphson and Fast-
Decoupled Methods
5. Fault Analysis
6. Transient and Small Signal Stability Analysis: Single-Machine Infinite Bus system
7. Transient Stability Analysis of Multimachine Power Systems
8. Electromagnetic Transients in Power Systems
9. Load – Frequency Dynamics of Single- Area and Two-Area Power Systems
10. Economic Dispatch in Power Systems.
Practical 45
Page 52 of 85

12EE2709 COMPREHENSIVE VIVAVOCE 0 0 2 1
AIM
To encourage the students to comprehend the knowledge acquired from the first Semester to Seventh
Semester of B.E Degree Course through periodic exercise.
· Electric Circuit Theory
· Electronic Devices
· Analog and Digital Electronics
· DC Machines and Transformers
· Electromagnetic Field Theory
· Measurements and Instrumentation
· Transmission and Distribution of Electric Energy
· Linear Integrated Circuits
· Control System Engineering
· Synchronous and Induction Machines
· DSP and Microprocessors
· Power System Protection and Switch Gear
· Power System Analysis
· Electric Machine Design
· Power System Economics and Control Techniques
· Electric Energy Generation, Utilization and Conversion
· Electric drives and controls.
Page 53 of 85

12EE2801 PROJECT WORK 0 0 18 100
Aim
To enable the students to identify and solve electrical engineering problems.
Objectives
· To develop and apply electrical/computer engineering knowledge acquired through earlier
semesters for successfully solving engineering problems
· To function effectively in multidisciplinary teams
· To effectively communicate technical information in multiple formats and
· To kindle the interest in life-long learning
Procedure
· Project work is to identify and provide solution to an application oriented problem, which will be
experimental in nature and others will be based on some innovative / theoretical work.
· Each project has to be carried out by a group of students. In order to ensure participation of each student,
the group size should be preferably 3/4 students for Under Graduate courses. Formation of project groups
should be done such that each group has representation of students with varying academic merit from best
to average.
· Each project group has to prepare and submit the project report at the time of end semester project work
and viva voce examination.
Page 54 of 85

ELECTIVES
GROUP I
12CS2001 JAVA PROGRAMMING 3 0 0 3
AIM
To motivate the students to understand the concepts of Java Programming.
OBJECTIVE
· To provide necessary skills to write Java programs and work with applet and applications.
· To familiarize the concepts and practices of packages and multi threaded applications.
· To perform event handling functionality in response to GUI events.
· To create application with database connectivity along with client server architecture.
· To study the concepts of files, streams and sockets.
UNIT - I INTRODUCTION TO JAVA 9
Object Oriented language: Overview – The JAVA Environment – Comparing JAVA C and C++ – Keywords &
Operators – Identifiers – Literal – Expressions – Control Statements – Arrays & Strings – Command line Arguments
– Data members – Methods – Overloading Constructors – Class Assignment – This – Static members & methods –
Final – Super keyword – Exception Handling.
UNIT - II INHERITANCE, PACKAGES AND THREADS 9
Abstract classes – Inheritance: Types – Single – Mutilevel – Hierarchical – Interfaces: defining – implementing –
Packages: Introduction – Importing packages – Implementation – Multithreaded Programming: Thread model –
Creating a thread – Creating multiple thread – Thread Exceptions – Thread Priority – Synchronization – Inter thread
communication.
UNIT - III AWT AND APPLET 9
HTML: Introduction – Webpage design – Basic Tags – Simple programs – Applet: Lifecycle – Simple Applet
Display– Labels – Text fields – Buttons – Combo Boxes – Passing parameters to applet – AWT: Windows
fundamentals – Creating frame Window – AWT Controls – Event handling: Sources of events – Event Delegation
Model – Event Classes – Event Listener interfaces– Adapter classes – AWT Classes –Working with graphics –
Working with Color – Working with font – Layout Managers – Menu Bars and menus.
UNIT - IV DATABASE CONNECTIVITY 9
JDBC: Architecture – JDBC Connectivity – Drivers – Setting up a database – Setting up tables – Establishing
connection – Getting Data from a table – Select – Update – Record Sets – Prepared Statements – Callable
Statements.
UNIT - V INPUT/OUTPUT STREAMS AND NETWORKING BASICS 9
Input Output: I/O classes and Interfaces – The Character Stream – Buffered Reader and Buffered Writer –
Serialization – Files – Java and Net: Stream classes – Socket – InetAddress – URL Connection – TCP/IP sockets –
Data grams – Simple client/server program.
Total periods: 45
TEXT BOOKS
1. Herbert Schildt, The Complete Reference “Java”, Seventh edition Tata McGraw Hills, 2011.
REFERENCES
1. Balaguruswamy E, Programming with java , Fourth Edition,TMH,2007.
2. Deitel H M and Deitel P J, “JAVA - How to Program”, Prentice Hall of India / Pearson Education, New
Delhi, Seventh Edition, 2007.
3. Elliote Harold Rusty, Network Programming, Third Edition 2004.
4. Steven Holzner et al, “ Java 2 Programming”, Dream Tech Press, 2001.
Page 55 of 85

5. Bernard Van Haecke, “JDBC 3 Jaba Database Connectivity”, Wiley-Dream Tech Press India P Ltd, 2002.
Page 56 of 85

12EE2E01 INTRODUCTION TO DATABASE MANAGEMENT SYSTEMS 3 0 0 3
AIM
To expose the students to the concept of database management system and different data models.
OBJECTIVES
· To learn the basics in database systems
· To learn about E-R model and its structure
· To study about relational commercial languages and relational database design
· To learn about network data model
· To study the concept of hierarchical data model
Purpose of database systems – Data abstraction – Data models – Instances and schemas – Data independence – Data
definition language – Database manager – Database users over all system structure.
UNIT - II E-R MODEL 8
E-R model – E-R diagram, reducing E-R diagram to tables.relational model: Structure of relational databases – the
relational algebra – Tuple and domain relational calculus modifying the databases.
UNIT - III RELATIONAL COMMERCIAL LANGUAGES 7
SQL - Query – by – example, Query integrity constraints – Domain constraints – Referential integrity – functional
dependencies – Assertions – Triggers.
UNIT - IV RELATIONAL DATABASE DESIGN 10
Pitfalls in relational database designs – Normalisation using multivalued dependencies, join dependencies. Domain-key
normalform. Mapping relational data to file data directory storage, buffer management. Typical database design
approach for: Airline reservation systems – Inventory control – Library information system.
UNIT - V NETWORK DATA MODEL 9
DBTG set construct and restrictions, Expressing M:N relationship DBTG, cycles in DBTG, data description in
network model, scheme and sub scheme, DBTG data manipulation facility, Data base manipulation.
UNIT - VI HIERARCHIAL DATA MODEL 7
Tree concepts, data definition, data manipulation, updation, implementation of the hierarchical databases, additional
features of the hierarchical DML.
Total periods: 45
TEXT BOOKS
1. Abraham, Siberschatz, Henry.F.Korth and Sudharshan. S, “Database System Concepts”, McGraw Hill, New
Delhi, 2002.
2. Ramez Elmasri and Shamkant Navethe, “Fundamentals of Database Systems”, Pearson Education, New
Delhi, 2003.
REFERENCES
1. Raghu, Ramakrishnan, “Database Management Systems”, Tata McGraw Hill, 3rd Edition New Delhi,
2004.
2. Thomas Connolly. Carolyn Begg, “Database system” Pearson education Limited, 3rd Edition, New Delhi,
2002.
3. Jeffrey A. Hoffer, Mary B.Presscott, Fred R Mcfadden “ Modern database Management Pearson Education,
New Delhi, 2002.
12EE2E02 DSP BASED SYSTEM DESIGN 3 0 0 3
Page 57 of 85

AIM
To impart knowledge on digital signal processors, programming concepts and its applications.
OBJECTIVES
· To understand the internal architecture of different types of digital signal processors.
· To learn about simple programming concepts in DSP.
· To study about development tools in DSP implementations.
· To study about a few applications using digital signal processors
UNIT- I ARCHITECTURE FOR PROGRAMMABLE DIGITAL SIGNAL PROCESSING
DEVICES 9
Basic architectural features – DSP computational building blocks; multiplier, shifter, Multiply and
Accumulate(MAC) UNIT – Arithmetic and Logic UNIT – Bus Architecture – Onchip memory, Data Addressing
Capabilities; Addressing modes; Special addressing modes, Programmability & Program execution. Speed issues:
Harvard architecture –parallelism – pipelining – system level parallelism and pipelining. Features for external
interfacing.
UNI - II DIGITAL SIGNAL PROCESSORS 9
Commercial Digital Signal Processing devices – Architecture of TMS320C54XX Digital signal processors – Bus
Structures – CPU – Internal memory and memory mapped registers – Data addressing modes of the TMS320C54XX
processors - Memory space of 54XX processors – Program control.
UNIT - III PROGRAMMING CONCEPTS 9
Instructions and Programming – simple program using TMS320C54XX processors. On chip peripherals: Hardware
Timer – Host port Interface – clock generator – Serial I/O ports – Interrupts – Pipeline operation of the
TMS320C54XX processors.
UNIT - III DEVELOPMENT TOOLS FOR DIGITAL SIGNAL PROCESSING
IMPLEMENTATIONS 9
DSP Development tools – DSP system design kit(DSK) – Software for development – Assembler and the Assembly
source file – Linker and Memory Allocation – C/C++ compiler – Code composer studio – Building a Project, Debug
Options. DSP software development Examples.
UNIT - IV APPLICATIONS OF PROGRAMMABLE DSP DEVICES 9
Position control system for Hard disk drive – DSP based Power Meter : Power measurement system – Software for
Power Meter.
Total periods: 45
TEXT BOOK
1.Avatar Singh and S.Srinivasan, “Digital Signal Processing : Implementations using DSP microprocessors with
examples from TMS320C54XX”, Thompson Brooks / Cole, 2004.
REFERENCESS
1. TMS320C54X DSP Reference set Volume 1 – CPU and Peripherals (Literature No.SPRU131)
2. TMS320C54X DSP Reference set Volume 2 – Mnemonic instruction set (Literature No.SPRV 172)
3. TMS320C54X DSP Reference set Volume 4 – Applications Guide (Literature No. SPRV 173)
4. TMS320C54X DSP Reference set Volume 5 – Enhanced Peripherals (Literature No. SPRV 302)
Page 58 of 85

12EE2E04 INTRODUCTION TO COMPUTER ARCHITECTURE 3 0 0 3
AIM
To Study the structure and behavior of processors, memories and input and output units and to study their
interactions.
OBJECTIVES
· To study the various representations of data, register transfer language for micro-operations
and organization and design of a digital computer.
· To teach the concept of micro-programmed control unit, the central processing
unit, stack and instruction formats.
· To Study the various arithmetic operation’s algorithms and their hardware implementations and concept of
pipelining and vector processing.
· To illustrate the techniques to communicate with input and output devices.
· To study the organization and operation of various memories and memory management hardware.
UNIT - I DATA REPRESENTATION, MICRO-OPERATIONS AND ORGANIZATIONAND
DESIGN 13
Data representation: Data types, complements, fixed–point representation, floating-point representation, other binary
codes, error detection codes.
Register transfer and micro operations: Register transfer language, register transfer, bus and memory transfers,
arithmetic micro-operations, logic micro-operations, shift micro-operations, arithmetic logic shift UNIT.
Basic computer organization and design: Instruction codes, computer registers, computer instructions, timing and
control, instruction cycle, memory reference instructions, input-output and interrupt. Complete computer
description, design of basic computer, design of accumulator logic.
UNIT - II CONTROL AND CENTRAL PROCESSING UNIT 8
Micro programmed control: Control memory, address sequencing, micro-program example, and design of control
UNIT. Central processing UNIT: General register organization, stack organization, instruction formats, addressing
modes, data transfer and manipulation, program control,reduced instruction set computer.
UNIT - III COMPUTER ARITHMETIC, PIPELINE AND VECTOR PROCESSING 8
Computer arithmetic: Addition and subtraction, multiplication algorithms, division algorithms, floating-point
arithmetic operations, decimal arithmetic UNIT, decimal arithmetic operations. Pipeline and vector processing:
Parallel processing, instruction pipeline, vector processing array processors
UNIT - IV INPUT-OUTPUT ORGANIZATION 8
Input-output organization: Peripheral devices, input-output interface, asynchronous data transfer, modes of transfer,
priority interrupt, direct memory access, input-output processor, serial communication.
UNIT - V MEMORY ORGANIZATION 8
Memory organization: Memory hierarchy, main memory, auxiliary memory, associative memory, cache memory,
virtual memory, memory management hardware.
Total periods: 45
TEXT BOOK
1.Morris Mano, “Computer System Architecture”, 3rd Edition, Pearson Education, 2002 / PHI.
REFERENCES
1. Vincent P.Heuring and Harry F.Jordan, “Computer Systems Design and Architecture”, Pearson Education
Asia Publications, 2002.
2. John P.Hayes, “Computer Architecture and Organization”, Tata McGraw Hill, 3rd Edition, New Delhi
1998.
3. Andrew S.Tanenbaum, “Structured Computer Organization”, 4th Edition, Prentice Hall of India/Pearson
Page 59 of 85

Education, 2002.
4. William Stallings, “Computer Organization and Architecture”, 6th Edition, Prentice Hall of India/Pearson
Education, 2003.
Page 60 of 85

GROUP II
12EE2E04 LABVIEW AND VIRTUAL INSTRUMENTATION 3 0 0 3
AIM
To expose the students with the comprehensive knowledge in virtual instrumentation and some of its
applications.
OBJECTIVES
· To review background information required for studying virtual instrumentation.
· To study the importance and applications of virtual instrumentation.
· To study the basic building blocks of virtual instrumentation.
· To study the graphical programming concepts in LabVIEW.
· To study the hardware interfacing concepts in LabVIEW.
· To study a few applications in virtual instrumentation.
UNIT - I FUNDAMENTALS OF VIRTUAL INSTRUMENTATION 9
General Functional description of a digital instrument - Block diagram of a Virtual Instrument - Physical quantities
and Transducers- Role of Hardware and Software in Virtual instrumentation- User interfaces- Architecture of a
Virtual instrument- Advantages of Virtual instruments over conventional instruments.
UNIT - II SOFTWARE OVERVIEW 9
LabVIEW - Graphical user interfaces - Controls and Indicators - “G” programming - Data types - Data flow
programming - Editing - Debugging and Running a Virtual instrument - Graphical programming pallets - Front
panel objects - Controls, Indicators, Object properties and their configuration - Typical
examples.
UNIT - III PROGRAMMING STRUCTURE 9
FOR loops, WHILE loop, CASE structure, formula node, Sequence structures - Arrays and Clusters – Array
operations - Bundle - Bundle/Unbundle by name, graphs and charts - String and file I/O - High level and Low level
file I/O”s - Attribute modes Local and Global variables.
UNIT - IV DATA ACQUISITION AND INSTRUMENT CONTROL 9
DAQ Components- Buffers: Buffered and non buffered I/O- Triggering- Analog I/O- Digital I/O- Counters and
timers- Data Acquisition: Analog and Digital signals, Analog interfacing, Types of grounding- Instrument control:
VISA, GPIB, VXI and PXI.
UNIT- V SIMPLE APPLICATIONS IN VI 9
Measurement of voltage and current- Measurement of frequency – Temperature indicator – ON/OFF controller – P-I-
D controller- Simulation of a simple second order system – Generation of HTML page.
Total periods: 45
TEXT BOOKS
1. Jerome Jovitha, “Virtual Instrumentation and LabVIEW”, PHI Learning, 1st Edition, New Delhi, 2010.
REFERENCES
1.Garry M Johnson, "LabVIEW Graphical Programming", Tata McGraw Hill, 2nd Edition, 1996.
2. Sanjay Gupta and Joseph John, “Virtual Instrumentation Using LabVIEW”, Tata McGraw-Hill, 1st Edition,
2005.
3. LabVIEW: Basics I & II Manual, National Instruments, 2006
4. Barry Paron, “Sensors, Transducers and LabVIEW", Prentice Hall, 2000.
5. Kevin James, “PC Interfacing and Data Acquisition: Techniques for Measurement, Instrumentation and
Control”, Newnes, 2000.
Page 61 of 85

12EE2E05 POWER QUALITY 3 0 0 3
AIM
To study the various issues affecting Power Quality, their production, monitoring and suppression.
OBJECTIVES
· To study the production of voltages sags, overvoltages and harmonics and methods of control.
· To study various methods of power quality monitoring.
UNIT - I INTRODUCTION TO POWER QUALITY 9
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. Computer Business Equipment Manufacturers
Associations (CBEMA) curve.
UNIT - II VOLTAGE SAGS AND INTERRUPTIONS 9
Sources of sags and interruptions, estimating voltage sag performance, motor starting sags, estimating the sag
severity, mitigation of voltage sags, active series compensators, static transfer switches and fast transfer switches.
UNIT - III OVERVOLTAGES 9
Sources of over voltages: Capacitor switching, lightning, ferro resonance; mitigation of voltage swells: Surge
arresters, low pass filters, power conditioners – Lightning protection, shielding, line arresters, protection of
transformers and cables, computer analysis tools for transients, PSCAD and EMTP.
UNIT - IV HARMONICS 9
Harmonic distortion: Voltage and current distortion, harmonic indices, harmonic sources from commercial and
industrial loads, locating harmonic sources; power system response characteristics, resonance, harmonic distortion
evaluation, devices for controlling harmonic distortion, passive filters, active filters, IEEE and IEC standards.
UNIT - V POWER QUALITY MONITORING 9
Monitoring considerations: Power line disturbance analyzer, per quality measurement equipment, harmonic /
spectrum analyzer, flicker meters, disturbance analyzer, applications of expert system for power quality monitoring.
Total periods: 45
REFERENCES
1. Roger.C.Dugan, Mark.F.McGranagham, Surya Santoso, H.Wayne Beaty, “Electrical Power Systems
Quality” McGraw Hill, 2003
2. PSCAD User Manual.
Page 62 of 85

12EE2E06 TRANSIENTS IN POWER SYSTEM 3 0 0 3
AIM
To impart knowledge on different types of transients in power system.
OBJECTIVES
· To learn about sources of transients in power system.
· To study about different types of switching transients.
· To impart depth knowledge on lighting transients.
· To learn about transient response and its computation.
· To get knowledge on transients in integrated power system.
UNIT- I INTRODUCTION AND SURVEY 5
Source of transients, various types of power systems transients, effect of transients on power systems, importance of
study of transients in planning.
UNIT - II SWITCHING TRANSIENTS 10
Introduction, circuit closing transients: RL circuit with sine wave drive, double frequency transients, observations in
RLC circuit and basic transforms of the RLC circuit. Resistance switching: Equivalent circuit for the resistance
switching problems, equivalent circuit for interrupting the resistor current. Load switching: Equivalent circuit,
waveforms for transient voltage across the load, switch; normal and abnormal switching transients. Current
suppression, current chopping, effective equivalent circuit. Capacitance switching, effect of source regulation,
capacitance switching with a restrike, with multiple restrikes, illustration for multiple restriking transients, ferro
resonance.
UNIT - III LIGHTNING TRANSIENTS 10
Causes of over voltage, lightning phenomenon, charge formation in the clouds, rate of charging of thunder clouds,
mechanisms of lighting strokes, characteristics of lightning strokes; factors contributing to good line design,
protection afforded by ground wires, tower footing resistance. Interaction between lightning and power system:
Mathematical model for lightning.
UNIT - IV TRAVELLING WAVES ON TRANSMISSION LINE COMPUTATION OF
TRANSIENTS 10
Computation of transients: Transient response of systems with series and shunt lumped parameters and distributed
lines. Travelling wave concept: step response, Bewely”s lattice diagram, standing waves and natural frequencies,
reflection and refraction of travelling waves.
UNIT - V TRANSIENTS IN INTEGRATED POWER SYSTEM 10
The short line and kilometric fault, distribution of voltage in a power system: Line dropping and load rejection;
voltage transients on closing and reclosing lines; over voltage induced by faults; switching surges on integrated
system; EMTP for transient computation.
Total periods: 45
TEXT BOOKS
1. Allan Greenwood, “Electrical Transients in Power Systems”, Wiley Interscience, New York, 2nd Edition 1991.
2. Begamudre R.D, “Extra High Voltage AC Transmission Engineering”, New Age International, 2007.
REFERENCES
1. M.S.Naidu and V.Kamaraju, “High Voltage Engineering”, Tata McGraw Hill, 2nd Edition, 2000.
Page 63 of 85

12EE2E07 NETWORKING IN SMART GRIDS
3 0 0 3
AIM
To expose the students to the concept of Smart Grids
OBJECTIVES
· Explain the roles of distributed generation technologies, communication infrastructures, advanced metering
infrastructure, advanced control methods, and demand management in smart grid operation
· Discuss operating principles and develop simplified models of smart grid components
· Analyze the impact of smart grid component integration on distribution network operation
UNIT I INTRODUCTION TO SMART GRID AND EMERGING TECHNOLOGIES 9
Traditional Power Systems- limited flow control and monitoring, centralized generation, low utilization; Smart
Grids- concept, WAN, FAN, HAN; early smart grid initiatives; overview of the technologies required.
UNIT II INFORMATION AND COMMUNICATION TECHNOLOGIES 9
Data Communication-dedicated and shared channels, switching techniques, communication channels, layered
architecture and protocols; communication technologies; information security- encryption and decryption,
authentication, digital signatures, cyber security standards;
UNIT III SENSING, MEASUREMENT, CONTROL AND AUTOMATION TECHNOLOGIES
9
Smart metering- overview of the hardware used, communications infrastructure and protocols for smart metering,
demand side integration; distribution automation equipment- substation automation equipment, faults in the
distribution system, voltage regulation;
UNIT IV POWER ELECTRONICS IN THE SMART GRID 9
Renewable energy generation- fault current limiting-shunt compensation - series compensation- FACTS- HVDC-PHEV
Technology
UNIT V DEMAND MANAGEMENT 9
Distribution Management Systems- introduction, data sources and associated external systems, modelling and
analysis tools, applications; Transmission system operation- introduction, data sources, energy management
systems, wide area applications, visualisation techniques
Lecture Hours: 45
TEXT BOOK:
1. Smart Grid: Technology and Applications Janaka Ekanayake, Nick Jenkins, Kithsiri Liyanage, Jianzhong
Wu, Akihiko Yokoyama
ISBN: 978-0-470-97409-4 Hardcover 310 pages April 2012 Wiley
REFERENCES
1. Smart Grid Communications and Networking
Edited by Ekram Hossain
Edited by Zhu Han
Edited by H. Vincent Poor Publisher: Cambridge University Press, Print Publication Year: 2012
2. Smart Grids
Nouredine Hadjsaïd (Editor), Jean-Claude Sabonnadière (Editor)
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ISBN: 978-1-84821-261-9 Hardcover 350 pages May 2012, Wiley-ISTE
WEBSITES
2. www.siemens.co.in/Smart-Grid
3. www.abb.com/smartgrids
Page 65 of 85

12EE2E08 SOFT COMPUTING TECHNIQUES 3
0 0 3
AIM
To cater the knowledge of Neural Networks and Fuzzy Logic Control and use these for controlling real
time systems.
OBJECTIVES
· To expose the students to the concepts of feed forward neural networks.
· To provide adequate knowledge about feed back neural networks.
· To teach about the concept of fuzziness involved in various systems. To provide adequate knowledge about
fuzzy set theory.
· To provide comprehensive knowledge of fuzzy logic control and adaptive fuzzy logic and to design the
fuzzy control using genetic algorithm
· To provide adequate knowledge of application of fuzzy logic control to real time systems
Approaches to intelligent control. Architecture for intelligent control. Symbolic reasoning system, rule-based
systems, the AI approach. Knowledge representation. Expert systems.
UNIT - II NEURAL NETWORKS 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
UNIT - III GENETIC ALGORITHM 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.
UNIT - IV 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 and defuzzification. Fuzzy knowledge and rule bases. Fuzzy
modeling and control schemes for nonlinear systems. Selforganizing fuzzy logic control. Fuzzy logic control for
nonlinear time-delay system.
UNIT=V APPLICATIONS 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.
Total periods: 45
TEXT BOOKS
1. Padhy.N.P., Artificial Intelligence and Intelligent System, Oxford University Press, 2005.
2. KOSKO, B. "Neural Networks and Fuzzy Systems", Prentice-Hall of India Pvt. Ltd., 1994.
REFERENCES
1. Jacek.M.Zurada, "Introduction to Artificial Neural Systems", Jaico Publishing House, 1999.
2. KLIR G.J. & FOLGER T.A. "Fuzzy sets, uncertainty and Information", Prentice-Hall of India Pvt. Ltd., 1993.
Page 66 of 85

3. Zimmerman H.J. "Fuzzy set theory-and its Applications"-Kluwer Academic Publishers, 1994.
4. Driankov, Hellendroon, "Introduction to Fuzzy Control", Narosa Publishers.
5. Goldberg D.E. “Genetic algorithms in Search, Optimization and Machine learning”, Addison Wesley, 1989.
Page 67 of 85

12EE2E09 EHV AC and DC POWER TRANSMISSION 3 0 0 3
AIM
To develop the skills in the area of HVDC power transmission with the analysis of HVDC converters,
harmonics and design of filters.
OBJECTIVE
· To understand the concept, planning of DC power transmission and comparison with AC
· power transmission.
· To analyze HVDC converters.
· To study about compounding and regulation.
· To analyze harmonics and design of filters.
· To learn about HVDC cables and simulation tools.
Introduction of DC Power transmission technology – Comparison of AC and DC transmission – Application of DC
transmission – Description of DC transmission system – Planning for HVDC transmission – Modern trends in DC
transmission.
UNIT - II ANALYSIS OF HVDC CONVERTERS 9
Pulse number – Choice of converter configuration – Simplified analysis of Graetz circuit – Converter bridge
characteristics – Characteristics of a twelve pulse converter – Detailed analysis of converters.
UNIT - III COMPOUNDING AND REGULATIONS 9
General – Required regulation – Inverter compounding – Uncompounded inverter – Rectifier compounding –
Transmission characteristics with the rectifier and inverter compounding – Communication link – Current regulation
from the inverter side – Transformer tap changing
UNIT - IV HARMONICS AND FILTERS 9
Introduction – Generation of harmonics – Design of AC filters and DC filters – Interference with neighbouring
communication lines.
UNIT- V HVDC CABLES AND SIMULATION OF HVDC SYSTEMS 9
Introduction of DC cables – Basic physical phenomenon arising in DC insulation – Practical dielectrics – Dielectric
stress consideration – Economics of DC cables compared with AC cables.
Introduction to system simulation – Philosophy and tools – HVDC system simulation – Modeling of HVDC systems
for digital dynamic simulation.
Total periods : 45
TEXT BOOKS
1. Padiyar, K. R., “HVDC power transmission system”, Wiley Eastern Limited, 1st edition, New Delhi, 1990,
Reprint (2005).
2. Edward Wilson Kimbark, “Direct Current Transmission”, Vol. I, Wiley interscience, New York, London, Sydney,
1971.
REFERENCES
1. Colin Adamson and Hingorani N G, “High Voltage Direct Current Power Transmission”, Garraway Limited,
London, 1960.
2. Arrillaga, J., “High Voltage Direct Current Transmission”, Peter Pregrinus, London, 1983.
3. Rakosh Das Begamudre, “Extra High Voltage AC Transmission Engineering”, New Age
Interantional (P) Ltd., New Delhi, 1990.
Page 68 of 85

12EE2E10 DIGITAL SYSTEM DESIGN 3 0 0 3
AIM
To introduce to the concept of Digital system design.
OBJECTIVES
· To Study the structure of Standard and complex PLDs and system design using PLDs.
· To introduce building blocks of FPGA.
· To introduce VHDL.
· To study about concurrent and sequential statements.
· To introduce subprograms, Packages, and its configurations
UNIT - I SYSTEM DESIGN USING PLDs AND CPLDs 9
Structure of Standard PLDs and Complex PLDs (CPLDs) – Design of combinational and sequential circuits using
PLDs and CPLDs – Design of state machines using Algorithmic State Machines (ASM) chart as a design tool.
UNIT - II INTRODUCTION TO FIELD PROGRAMMABLE GATE ARRAYS (FPGAs) 9
Types of FPGA – Xilinx XC3000 series: Logic Cell Array (LCA) - Configurable Logic Blocks (CLB) –
Input/Output Blocks (IOB) – Programmable Interconnection Points (PIP) – Introduction to Xilinx XC4000 family –
Design examples.
UNIT - III INTRODUCTION TO VHDL 9
Digital System Design process – Levels of abstraction – Need for Hardware Description Languages – VHDL:
Design entities, Architectural body – Data types - Scalar types - Composite types - Access types - File types –
Operators and expressions –Data objects.
UNIT - IV CONCURRENT AND SEQUENTIAL STATEMENTS 9
Concurrency – Signal Assignment – Conditional Signal Assignment – Signal Drivers – Inertial, Transport and delta
delays – Sequential control – Wait-if–Case – Loop – Next – Exit – Null process – Component instantiation – Block
– Generics – Assert.
UNIT - V SUBPROGRAMS, PACKAGES AND CONFIGURATIONS 9
Functions – Procedure– Package – Package declarations – Sub program declaration – Package body – Libraries –
Predefined attributes – Configuration – Behavioural, Dataflow and Structural modeling of digital circuits.
Total periods: 45
TEXT BOOKS
1. Nelson V.P., Nagale H.T., Carroll B.D., and Irwin J.D., "Digital Logic Circuit Analysis and Design", Prentice
Hall International Inc. 1995
2. Perry D.V., " VHDL: Programming by Example", Tata McGraw-Hill Publishing Company, 4th Edition, 2002.
REFERENCES
1. Palmer J.E., and Perlman D.E., " Introduction to Digital Systems", Schaum”s Outline Series, Tata McGraw
Hill, New Delhi, 1996.
2. Dueck R.K., “Digital Design with CPLD applications and VHDL”, Thomson Delmar Learning, 2001
3. Navabi, Z.," VHDL: Analysis and Modelling of Digital Systems", McGraw-Hill, New Delhi, 2nd Edition, 1998.
4. Roth C.H., “Digital Systems Sesign using VHDL”, Thomson Delmar Learning, 2001
5. Programmable Logic Devices Data book and Design Guide", National Semiconductors, 1989.
6. The Programmable Logic Data Book”, Xilinx, 1994.
12EE2E11 ANALOG VLSI DESIGN 3 0 0 3
Page 69 of 85

AIM
To introduce the technology & concepts of ANALOG VLSI.
OBJECTIVES:
· To study device modelling for various devices.
· To introduce basic building blocks of analog VLSI.
· To study different types of amplifiers using BJT and MOS.
· To study the design concept of operational amplifier.
· To understand switched capacitor circuits.
· To study data converter circuits
·
UNIT - I DEVICE MODELLING 9
Introduction to Analog Design-MOS device model-DC, small signal and large signal model. Diode model- DC,
small signal and high frequency model.BJT: DC small signal and high frequency model. Passive components in
MOS technology.
UNIT - II BASIC BUILDING BLOCKS 9
Switches, Active Resistors, Current Mirrors: Types of Current mirrors-Simple,Widlar,Wilson and Cascode-Active
loads, Voltage and Current REFERENCES Widlar Current Source, Band Gap Referenced Circuits.
UNIT - III AMPLIFIERS (BJT & MOS) 9
Single stage amplifiers-.Multistage Amplifiers:Darlington, Cascode and Differential Amplifiers Frequency response
of Amplifiers: CE, CS, Cascode and Differential Amplifiers, Gilbert Multiplier cell.
UNIT - IV OPERATIONAL AMPLIFIER 9
Bipolar Operational Amplifier, Design Considerations, Basic Two stage MOS Opamp-Output stages Frequency
response and Frequency Compensation,Comparators- charactersitic and two stage comparators.
UNIT - V SWITCHED CAPACITOR CIRCUITS 9
General Considerations, Sampling Switches, Switched Capacitor Amplifier, Switched Capacitor Integrator.
Total periods: 45
TEXT BOOK
1. Grey, Hurst, Lewis and Meyer, “Analysis and Design of Analog Integrated Circuits”,, John Wiley & Sons
Inc,4th Edition 2001.
2. Behzad Razavi, “Design of Analog CMOS Integrated Circuits”, Tata McGraw Hill Edition, New Delhi, 2002.
3. Jacob Baker R, Harry Li, David E.Boyce, “CMOS Circuit Design, Layout and Simulation”, IEEE Press, 1998.
REFERENCES
1. Phillip E.Allen & Douglas R Holberg, “CMOS Analog Circuit Design”, Oxford University Press 2002, 2nd
Edition.
2. David A. John, Ken Martin, " Analog Integrated Circuit Design” John Wiley & Sons, 2002.
Page 70 of 85

GROUP III
12EE2E12 ELECTRONIC PRODUCT DESIGN 3 0 0 3
AIM
To introduce different design techniques of electronic products.
To introduce basic building blocks of PCB design.
OBJECTIVES
· To study the phases of development of electronic product.
· To study low power design techniques.
· To understand ergonomics for electronic design.
· To study electromagnetic interference and noise sources.
· To understand PCB layout planning.
· To study Film master preparation.
· To study different image transfer techniques
UNIT - I DESIGN METHODOLOGY: 6
Concept of a product - Electronic product design - Work content of a product - Systems concept of electronic
product - Phases of development of electronic product - Pre-study phase, study phase and design phase - Industrial
design - User centered design.
UNIT - II CREATIVITY IN DESIGN TECHNIQUES: 6
Integration of creativity - Requirements in design - Low power design - Input / output interface - Thermal design,
approach of thermal management, basic thermal calculation - Heat sink selection - Fan and forced cooling.
UNIT- III ERGONOMICS FOR ELECTRONIC PRODUCTS: 6
Ergonomics requirements for products - Principles and rules of Ergonomics- Anthropometry - Control panel design
- Ergonomics in work places, utility - Chassis and cabinet design - Typical professional electronic equipments.
UNIT- IV ELECTROMAGNETIC INTERFERENCE: 6
Noise in electronic equipments - Electromagnetic interference (EMI) - Methods of noise coupling, noise sources
-Capacitor coupling and shielding inductive coupling and shielding , grounding , single point, multi point
grounding and hardware grounds.
UNIT - V PCB ART WORK GENERATION: 6
Lay out planning - Lay out rules and considerations - Lay out sketch - Artwork generation, basic approaches -
Artwork taping guidelines -Resistance, capacitance and inductance of PCB conductors - Conductor spacing -
Supply and ground conductor considerations.
UNIT - VI FILM MASTER PREPARATION: 5
Film emulsion parameters - Film master dimension stability - Reprographic camera - Film processing and
developing - Copper clad laminates, manufacturing process - Electrical and physical characteristics of laminates
-Types of laminates and properties.
UNIT - VII IMAGE TRANSFER TO PCBs 5
Board cleaning - Photo printing - Photoresist types -Coating process for wet film resists - Processing stages for wet
film - Dry film resist - Plating of PCBs - Principles of immersion, electroless plating and electroplating types.
UNIT - VIII ETCHING AND SOLDERING OF PCB 5
Types and operation, Etching machines - Etchant systems - Soldering, principles of solder connections - Solder
alloys - Soldering fluxes - Soldering techniques - Solder masks - Testing and quality control of soldering.
Total periods: 45
Page 71 of 85

TEXT BOOKS
1. Kim R. Fowler., "Electronic Instrument Design" Oxford press, England, 1997.
2. Walter C. Bosshart., "Printed Circuit Boards Design and Technology", Tata McGraw Hill Publishing Company
Ltd., New Delhi, 1983.
REFERENCES
1. John R. Barnes., "Electronic System Designing : Interference and Noise Control Techniques", Prentice Hall, New
Jersey,1987
2. Rao N.J., "Structuring of an Electronic Product”, CEDT Publication, Indian Institute of science, Bangalore, 1983.
Page 72 of 85

12EE2E13 COMPUTER AIDED DESIGN OF ELECTRICAL APPARATUS 3 0 0 3
AIM
To introduce the basics of Computer Aided Design technology for the design of Electrical Machines.
OBJECTIVES:
At the end of this course the student will be able to
· Learn the importance of computer aided design method.
· Understand the basic electromagnetic field equations and the problem formulation for CAD
· applications.
· Become familiar with Finite Element Method as applicable for Electrical Engineering.
· Know the organization of a typical CAD package.
· Apply Finite Element Method for the design of different Electrical apparatus.
Conventional design procedures – Limitations – Need for field analysis based design – Review of Basic principles
of energy conversion – Development of Torque/Force.
UNIT - II MATHEMATICAL FORMULATION OF FIELD PROBLEMS 9
Electromagnetic Field Equations – Magnetic Vector/Scalar potential – Electrical vector /Scalar potential – Stored
energy in Electric and Magnetic fields – Capacitance - Inductance- Laplace and Poisson”s Equations – Energy
functional.
UNIT - III PHILOSOPHY OF FEM 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.
UNIT – IV CAD PACKAGES 9
Elements of a CAD System –Pre-processing – Modelling – Meshing – Material properties- Boundary Conditions –
Setting up solution – Post processing.
UNIT- V DESIGN APPLICATIONS 9
Voltage Stress in Insulators – Capacitance calculation - Design of Solenoid Actuator – Inductance and force
calculation – Torque calculation in Switched Reluctance Motor.
Total periods: 45
TEXT BOOKS
1. S.J Salon, “Finite Element Analysis of Electrical Machines”, Kluwer Academic Publishers, London, 1995.
2. Nicola Bianchi, “Electrical Machine Analysis using Finite Elements”, CRC Taylor& Francis, 2005.
REFERENCES
1. Joao Pedro, A. Bastos and Nelson Sadowski, “Electromagnetic Modeling by Finite Element Methods”, Marcell
Dekker Inc., 2003.
2. P.P.Silvester and Ferrari, “Finite Elements for Electrical Engineers”, Cambridge University Press,1983.
3. D.A.Lowther and P.P Silvester, “Computer Aided Design in Magnetics”, Springer Verlag, New York, 1986
4. S.R.H.Hoole, “Computer Aided Analysis and Design of Electromagnetic Devices”, Elsevier, New York,
1989.
5. User Manuals of MAGNET, MAXWELL & ANSYS Softwares.
Page 73 of 85

12EE2E14 HIGH VOLTAGE ENGINEERING 3 0 0 3
AIM
To expose the students to various types of over voltage transients in power system and its effect on power
system.
- Generation of over voltages in laboratory.
- Testing of power apparatus and system.
OBJECTIVES
· To understand the various types of over voltages in power system and protection
methods.
· Generation of over voltages in laboratories.
· Measurement of over voltages.
· Nature of Breakdown mechanism in solid, liquid and gaseous dielectrics.
· Testing of power apparatus and insulation coordination.
UNIT - I OVER VOLTAGES IN ELECTRICAL POWER SYSTEMS 6
Causes of over voltages and its effects on power system – Lightning, switching surges and temporary over voltages
– protection against over voltages – Bewley”s lattice diagram.
UNIT - II ELECTRICAL BREAKDOWN IN GASES, SOLIDS AND LIQUIDS 10
Gaseous breakdown in uniform and non-uniform fields – Corona discharges – Vacuum breakdown – Conduction
and breakdown in pure and commercial liquids – Breakdown mechanisms in solid and composite dielectrics.
UNIT - III GENERATION OF HIGH VOLTAGES AND HIGH CURRENTS 10
Generation of High DC, AC, impulse voltages and currents. Tripping and control of impulse generators.
UNIT - IV MEASUREMENT OF HIGH VOLTAGES AND HIGH CURRENTS 10
Measurement of High voltages and High currents – Digital techniques in high voltage measurement.
UNIT- V HIGH VOLTAGE TESTING & INSULATION COORDINATION 9
High voltage testing of electrical power apparatus – Power frequency, impulse voltage and DC testing –
International and Indian standards – Insulation Coordination.
Total periods: 45
TEXT BOOK
1. Naidu M. S., and Kamaraju V., “High Voltage Engineering”, Tata McGraw Hill, 4th Edition, 2009.
REFERENCES
1. Kuffel E., and Zaengel W. S., “High Voltage Engineering Fundamentals”, Pergamon Press, Oxford, London,
1986.
2. Kuffel E., and Abdullah M., “High Voltage Engineering”, Pergamon Press, Oxford, 1999.
3. Alston L. L., Oxford University Press, New Delhi, 1st Indian Edition, 2006.
Page 74 of 85

12EE2E15 OPTO ELECTRONICS 3 0 0 3
AIM
Expose the students to basics of optoelectronic devices and circuits.
OBJECTIVES
· To understand elements of solid state physics
· To learn about display devices and lasers
· To study different types of optical detection devices
· To understand analog and digital modulation techniques and modulators
· To learn about optoelctornic integrated circuits
UNIT - I ELEMENTS OF LIGHT AND SOLID STATE PHYSICS 9
Wave nature of light- Polarization- Interference- Diffraction- Light Source- review of Quantum Mechanical
concept- Review of Solid State Physics- Review of Semiconductor Physics and Semiconductor Junction Device.
UNIT- II DISPLAY DEVICES AND LASERS 9
Introduction- Photo Luminescence- Cathode Luminescence- Electro Luminescence- Injection Luminescence-
Injection Luminescence- LED- Plasma Display- Liquid Crystal Displays- Numeric Displays- Laser Emission-
Absorption- Radiation- Population Inversion- Optical Feedback- Threshold condition- Laser Modes- Classes of
Lasers- Mode Locking- laser applications.
UNIT- III OPTICAL DETECTION DEVICES 9
Photo detector- Thermal detector- Photo Devices- Photo Conductors- Photo diodes- Detector Performance.
UNIT- IV OPTOELECTRONIC MODULATOR 9
Introduction- Analog and Digital Modulation- Electro-optic modulators- Magneto Optic Devices- Acoustoptic
devices- Optical- Switching and Logic Devices.
UNIT- V OPTOELECTRONIC INTEGRATED CIRCUITS 9
Introduction- hybrid and Monolithic Integration- Application of Opto Electronic Integrated Circuits-
Integrated transmitters and Receivers- Guided wave devices.
Total periods: 45
TEXT BOOKS
1.Wilson and Haukes- “Opto Electronics – An Introduction”- Pearson/Prentice Hall of India Pvt-Ltd, New
Delhi- 2007.
2. Bhattacharya “Semiconductor Opto Electronic Devices”- Pearson/Prentice Hall of India Pvt. Ltd., New
Delhi, 2006.
REFERENCES
1. Jasprit Singh- “Opto Electronics – As Introduction to materials and devices”-McGraw-Hill International /e-
1998.
2.Joachim Piprek, “Semiconductor Optoelectronic Devices”, Elsevier, 2003.
3.Kasap S. O., Safa Kasap, “Optoelectronics and Photonics: Principles and Practices”, PHI, 2001.
Page 75 of 85

12EE2E16 NANO SCIENCE 3 0 0 3
AIM
Expose the students to basics of nano science and technology.
Nanoscale Science and Technology - Implications for Physics, Chemistry, Biology and Engineering classifications
of nano structured materials- nano particles- quantum dots, nano wires-ultra-thin films multilayered materials.
Length Scales involved and effect on properties: Mechanical, Electronic, optical, Magnetic and Thermal properties.
Introduction to properties and motivation for study (qualitative only).
UNIT- II PREPARATION METHODS 5
Bottom-up Synthesis-Top-down Approach: Precipitation, Mechanical Milling, Colloidal routes, Self assembly,
Vapour phase deposition, MOCVD, Sputtering, Evaporation, Molecular Beam Epitaxy, Atomic Layer Epitaxy,
MOMBE.
UNIT - III PATTERNING AND LITHOGRAPHY FOR NANOSCALE DEVICES 5
Introduction to optical/UV electron beam and X-ray Lithography systems and processes, Wet etching, dry (Plasma
/reactive ion) etching, Etch resists-dip pen lithography
UNIT- IV PREPARATION ENVIRONMENTS 10
Clean rooms: specifications and design, air and water purity, requirements for particular processes, Vibration free
environments: Services and facilities required. Working practices, sample cleaning, Chemical purification, chemical
and biological contamination, Safety issues, flammable and toxic hazards, biohazards.
UNIT - V CHARACTERIZATION TECHNIQUES 10
X-ray diffraction technique, Scanning Electron Microscopy - environmental techniques, Transmission Electron
Microscopy including high-resolution imaging, Surface Analysis techniques- AFM, SPM, STM, SNOM, ESCA,
SIMS- Nano indentation
Total periods: 45
TEXT BOOKS
1. A.S. Edelstein and R.C. Cammearata, eds., “Nanomaterials: Synthesis, Properties and Applications”, Institute
of Physics Publishing, Bristol and Philadelphia, 1996.
2. N John Dinardo, Nanoscale charecterisation of surfaces & Interfaces, Second edition, Weinheim Cambridge,
Wiley-VCH, 2000.
REFERENCES
1. Timp G (Editor), “Nanotechnology”, AIP press/Springer, 1999.
2. Akhlesh Lakhtakia (Editor) ,“The Hand Book of Nano Technology, Nanometer Structure, Theory, Modeling and
Simulations”, Prentice-Hall of India (P) Ltd, New Delhi, 2007.
Page 76 of 85

12EE2E17 DISTRIBUTED CONTROL SYSTEM 3 0 0 3
OBJECTIVE
· To understand the basic industrial communication protocols.
· To know the industrial application of PLC, SCADA, and open systems.
· To impart knowledge about PLC and the programming
· To give adequate information in the interfaces used in DCS.
UNIT- I INTRODUCTION TO AUTOMATION 9
Plant Automation and Control Systems Strategy, Evolution of instrumentation and control, Role of automation in
industries, Benefits of automation, Introduction to automation tools PLC, DCS, SCADA, Hybrid DCS/PLC,
Automation strategy evolution, Performance criteria and Safety Systems.
UNIT - II PROGRAMMABLE LOGIC CONTROLLER (PLC) 9
Basics of PLC – Architecture of PLC – Advantages – Types of PLC-Applications of PLC”s- Specifications of
advanced PLC”s. PLC Programming – Simple process control programs are using Relay Ladder Logic and Boolean
logic methods – Structured text, Sequential flow chart, State diagrams. System configuration hardware, system
sizing and selection, wiring diagram, PLC installation, interfacing to PC.
UNIT - III INTRODUCTION TO DCS 9
DCS- Basic Packages Introduction, analog control, direct digital control, distributed process Control, DCS
configuration with associated accessories, control console equipment, control UNIT (Relay Rack mounted
equipments), local control UNITs and attributes of DCS & DCS Flow Sheet symbols. DCS System Integration I/O
hardware stations, Set-point station control, Supervisory Computer Tasks & configurations, system integration with
PLCs and computers.
UNIT - IV INDUSTRIAL PROTOCOL 9
Instrumentation Standard Protocols, HART Protocol, frame structure, programming, implementation examples,
Benefits, Introduction, Advantages and Limitations of Field bus, FDS configuration, Comparison with other field
bus standards including Device net, Profibus, Controlnet, CAN, Industrial Ethernet, MAP and TOP.
UNIT - V APPLICATIONS 9
Industrial applications of PLC, SCADA, DCS and open systems for following plants; Cement plant, Thermal power
plant, Steel Plant, Glass manufacturing plant, Paper and Pulp plant.
Total periods: 45
TEXT BOOKS
1. Dieter K. Hammer, Lonnie R. Welch, Dieter K. Hammer, “Engineering of Distributed Control Systems”,
Nova Science Publishers, USA, 2001.
2. John Mcbrewster, Frederic P.Miller, Agnes F.Vandome, “Distributed Control System”, Alphascript
publishers, Mauritius, 2010.
REFERENCES:
1. Gary Dunning, “Introduction to Programmable Logic Controllers”, Thomson Business Information, New
Delhi, 2nd Edition, 2009.
2. Bolton. W, “Programmable Logic Controllers”, Elsevier India Private Limited, 5th Edition, New Delhi, 2010.
Page 77 of 85

12EE2E18 FLEXIBLE AC TRANSMISSION SYSTEMS 3 0 0 3
AIM
To enhance the transmission capability of transmission system by shunt and series compensation using
static controllers.
OBJECTIVES
· To understand the concept of flexible AC transmission and the associated problems.
· To review the static devices for series and shunt control.
· To study the operation of controllers for enhancing the transmission capability.
UNIT-IINTRODUCTION 9
Reactive power control in electrical power transmission lines - Uncompensated transmission line – Series
compensation - Basic concepts of Static VAR Compensator (SVC) - Thyristor Switched Series capacitor (TCSC) -
Unified Power Flow Controller (UPFC).
UNIT-II STATIC VAR COMPENSATOR (SVC) AND APPLICATIONS 9
Voltage control by SVC –Advantages of slope in dynamic characteristics – Influence of SVC on system voltage –
Design of SVC voltage regulator – Applications: Enhancement of transient stability – Steady state power transfer –
Enhancement of power system damping- Prevention of voltage instability.
UNIT-III THYRISTOR CONTROLLED SERIES CAPACITOR (TCSC) AND APPLICATIONS
9
Operation of the TCSC - Different modes of operation - Modeling of TCSC - Variable reactance model - Modeling
of stability studies - Applications: Improvement of the system stability limit - Enhancement of system damping -
Voltage collapse prevention.
UNIT-IV EMERGINGFACTSCONTROLLERS 9
Static Synchronous Compensator (STATCOM) – Principle of operation – V-I Characteristics –UPFC – Principle of
operation – Modes of operation – Applications – Modeling of UPFC for power flow – Studies.
UNIT-V CO-ORDINATION OF FACTS CONTROLLERS 9
Controller interactions – SVC – SVC interaction - Co-ordination of multiple controllers using linear control
techniques – Control coordination using genetic algorithms.
Total Periods: 45
TEXT BOOK
1. Mohan Mathur, R., Rajiv. K. Varma, “Thyristor – Based Facts Controllers for Electrical Transmission Systems”,
IEEE press and John Wiley & Sons, Inc.
REFERENCES
1. A.T.John, “Flexible AC Transmission System”, Institution of Electrical and Electronic Engineers (IEEE), 1999.
2. Narain G.Hingorani, Laszio. Gyugyl, “Understanding FACTS Concepts and Technology of Flexible AC
Transmission System”, Standard Publishers, Delhi, 2001.
Page 78 of 85

12EE2E19 AI APPLICATIONS TO POWER SYSTEMS 3 0 0 3
AIM
To learn the various Artificial Intelligence Techniques and their application to Power Systems.
OBJECTIVES
· To study about Artificial Neural Networks, Genetic Algorithm and Fuzzy Logic System.
· To apply AI techniques to Power Systems.
UNIT I INTRODUCTION 9
Approaches to intelligent control – Architecture for intelligent control – Symbolic reasoning system – rule-based
systems – the AI approach –Knowledge representation. Expert systems.
UNIT II ARTIFICIAL NEURAL NETWORKS 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.
UNIT III GENETIC ALGORITHM 9
Basic concept of Genetic algorithm and detailed 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.
UNIT IV 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 and defuzzification – Fuzzy knowledge and rule
bases – Fuzzy modelling and control schemes for nonlinear systems – Self-organizing fuzzy logic control – Fuzzy
logic control for nonlinear time-delay system.
UNIT V APPLICATIONS TO POWER SYSTEMS 9
GA application to power system optimisation problems, Neural Network Application to Load Forecasting,
Contingency Analysis, Application of Fuzzy Logic Controllers to Power System Stability.
TOTAL: 45 PERIODS
TEXT BOOKS:
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.
REFERENCES:
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.
Page 79 of 85

12EE2E20 ROBOTICS TECHNOLOGY AND FLEXIBLE AUTOMATION 3 0 0 3
AIM
To provide comprehensive knowledge of robotics in the design, analysis and control point of view.
OBJECTIVES
· To study the various classifications of robots and fields of robotics.
· To study the various drives and control systems of robots.
· To study the different types of sensors and vision systems used in robotics.
· To study the programming techniques used in robotics.
· To study the basic building blocks of automation
· To understand the importance of PLC and CNC
UNIT - I CLASSIFICATION OF ROBOTIC SYSTEMS 6
Basic structure of a robot - Classification of robots: Cartesian, Cylindrical, Spherical, Articulated, SCARA.
Accuracy, resolution and repeatability of robots. Robot application in manufacturing: Material transfers - Machine
loading and unloading - Processing operations - Assembly and inspection.
UNIT - II DRIVES AND CONTROL SYSTEMS 6
Hydraulic and Pneumatic systems: cylinders, control valves, hydro motor. Types of mechanical power drive, rotary
to linear motion conversion mechanisms. Robot end effectors. Servomotors – Operation, stepper motors - control
loops using current and voltage amplifier. Robot controllers - configuration of robot controller.
UNIT - III SENSORS AND VISION SYSTEMS 8
Types of sensors, tactile sensors, proximity sensors and speed sensors – Encoder, resolvers. Vision systems: Image
processing and analysis, Segmentation, Feature extraction, Object Recognition.
UNIT - IV ROBOT PROGRAMMING 6
Lead through programming - Textual programming, programming examples - Social and Economical Aspects of
Robots - Typical layouts of robots in Industries.
UNIT - V AUTOMATION 6
Advantages of automation, building blocks of automation. Automatic feeding lines, material-handling devices,
ASRS, transfer lines, automatic inspection, intelligent automation.
Total periods: 45
TEXT BOOKS
1. Mikell P. Weiss G.M., Nagel R.N., Odraj N.G., Industrial Robotics, McGraw-Hill Singapore, 1996.
2. Ghosh, Control in Robotics and Automation: Sensor Based Integration, Allied Publishers, Chennai, 1998.
REFERENCES
1. Bolton W, “Mechatronics”, Pearson Education Asia, 2002.
2. Fu K.S, Gonzalez R.C, and C S G Lee, “Robotics: Control, Sensing, Vision and Intelligence”, McGraw Hill,
New Delhi, 1987.
Page 80 of 85

12EE2E21 SPECIAL ELECTRICAL MACHINES 3 0 0 3
AIM
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.
OBJECTIVES
· Construction, principle of operation and performance of synchronous reluctance motors.
· Construction, principle of operation and performance of stepping motors.
· Construction, principle of operation and performance of switched reluctance motors.
· Construction, principle of operation and performance of permanent magnet brushless D.C. motors.
UNIT - I SYNCHRONOUS RELUCTANCE MOTORS 9
Constructional features – Types – Axial and radial air gap motors – Operating principle – Reluctance – Phasor
diagram - Characteristics – Vernier motor.
UNIT- II STEPPING MOTORS 9
Constructional features – Principle of operation – Variable reluctance motor – Hybrid motor – Single and multi stack
configurations – Theory of torque predictions – Linear and non-linear analysis – Characteristics – Drive circuits.
UNIT- III SWITCHED RELUCTANCE MOTORS 9
Constructional features – Principle of operation – Torque prediction – Power controllers – Non-linear analysis –
Microprocessor based control - Characteristics – Computer control.
UNIT - IV PERMANENT MAGNET BRUSHLESS D.C. MOTOR 9
Principle of operation – Types – Magnetic circuit analysis – EMF and torque equations – Power controllers – Motor
characteristics and control.
UNIT - V PERMANENT MAGNET SYNCHRONOUS MOTORS 9
Principle of operation – EMF and torque equations – Reactance – Phasor diagram – Power controllers - Converter -
Volt-ampere requirements – Torque speed characteristics - Microprocessor based control.
Total periods: 45
TEXT BOOKS
1. Miller T.J.E., “Brushless Permanent Magnet and Reluctance Motor Drives”, Clarendon Press, Oxford, 1989.
2. Aearnley, “Stepping Motors – A Guide to Motor Theory and Practice”, Peter Perengrinus, London, 1982.
REFERENCES
1. Kenjo T, “Stepping Motors and Their Microprocessor Controls”, Clarendon Press London, 1984.
2. Kenjo T and Nagamori S., “Permanent Magnet and Brushless DC Motors”, Clarendon Press, London, 1988.
Page 81 of 85

12EE2E22 NON CONVENTIONAL ENERGY SOURCES 3 0 0 3
AIM
To expose the students to the various nonconventional energy sources and thier importance.
OBJECTIVES
· To understand the need to develop new energy technologies
· To study thermal power generation.
· To understand photo voltaic energy conversion.
· To study the various components of wind energy conversion scheme
and the principles of MHD power
generation
· To study miscellaneous energy sources like Geothermal energy and
Bio-mass.
UNIT I INTRODUCTION 9
Trends in energy consumption - World energy scenario - Energy sources and their availability - Conventional and
renewable sources - Need to develop new energy technologies.
UNIT II SOLAR THERMAL ELECTRIC CONVERSION 9
Principle of solar thermal power generation - Low and medium temperature systems - Stirling cycle - Solar thermal
power generation - Brayton cycle - Tower concept - Cost effectiveness.
UNIT III PHOTO - VOLTAIC ENERGY CONVERSION 9
Solar radiation and measurement - Solar cells and their characterisation - Influence of insulation and temperature -
PV arrays - Electrical storage with batteries - Charge controllers.
UNIT IV POWER CONDITIONING SCHEMES 9
DC Power conditioning converters - Maximum power point tracking algorithms - AC Power conditioners -
Line commutated Thyristor Inverters - Synchronised Operation with grid supply - Stand alone inverter -
Applications - Economic analysis of PV systems.
UNIT V WIND ENERGY SYSTEMS 9
Basic principle of wind energy conversion - Nature of wind - Power in the wind - Components of a wind energy
conversion system - Classification of WECS - Generator control - Load control.
Total periods: 45
TEXT BOOK
1. Rao. S, and Paruklekar, “Energy Technology – Non Conventional, Renewable and Conventional”, Khanna Pub,
New Delhi 1999.
2. Mukund R. Patel, “Wind and Solar Power Systems”, CRC Press LLC, New York, 2006.
REFERENCES
1. Rai, G.D., "Non Conventional Energy Sources", Khanna Publishers, New Delhi, 1993.
2. Garg, H.P., and Prakash, J., "Solar Energy - Fundamentals and Applications", Tata McGraw Hill, New Delhi,
1997.
Page 82 of 85

12IT2002 SOFT SKILLS 3 0 0 3
AIM
The proposed elective course exposes the students to those soft skills which are crucial to an employee”s
ability to work “smarter”. The Core Modules of this Elective includes Strengthening English, Art of
Communication, Working in Teams, and Interview & GD handling skills amongst other related topics.
OBJECTIVE
At the end of this elective, student shall be able to / develop the skills necessary to:
· Have competent knowledge of grammar with an understanding of its basic rules.
· Speak and write appropriately applying these rules.
· Communicate effectively and enhance their interpersonal relationship building skills with renewed self
confidence.
· Work together in teams and accomplish OBJECTIVEs in a cordial atmosphere.
· Face interviews, GDs and presentations.
· Understand and develop the etiquette necessary to present oneself in a professional setting.
UNIT- I EFFECTIVE ENGLISH – WRITTEN AND SPOKEN ENGLISH 8
Basic rules of Grammar - Parts of Speech – Tenses – Verbs, Sentence Construction - Vocabulary – Idioms &
Phrases – Synonyms – Antonyms, Dialogues and Conversations – Writing, Exercises to practice and improve these
skills.
UNIT - II ART OF COMMUNICATION & THE HIDDEN DATA INVOLVED 8
Verbal Communication - Effective Communication - Active listening – Paraphrasing - Feedback, Non Verbal
Communication - Body Language of self and others, Importance of feelings in communication - Dealing with
feelings in communication
UNIT - III WORLD OF TEAMS 8
Self Enhancement - importance of developing assertive skills- developing self confidence – developing emotional
intelligence, Importance of Team work – Team vs. Group - Attributes of a successful team – Barriers involved,
working with Groups – Dealing with People- Group Decision Making
UNIT - IV INTERVIEW, GD & PRESENTATION SKILLS 8
Interview handling Skills – Self preparation checklist – Grooming tips: do’s & don’ts – mock interview & feedback,
GD skills – Understanding the OBJECTIVE and skills tested in a GD – General types of GDs – Roles in a GD –
Do’s & Don’ts – Mock GD & Feedback, Presentation Skills – Stages involved in an effective presentation –
selection of topic, content, aids – Engaging the audience – Time management – Mock Presentations & Feedback
UNIT - V BUSINESS ETIQUETTE & ETHICS 8
Grooming etiquette – Telephone & E-mail etiquette – Dining etiquette – Do”s & Don”ts in a formal setting – how to
impress, Ethics – Importance of Ethics and Values – Choices and Dilemmas faced – Discussions from news
headlines.
Total periods: 45
REFERENCES
1. The Seven Habits of Highly Effective People -Stephen R. Covey.
2. All the books in the “Chicken Soup for the Soul” series.
3. Man’s search for meaning – Viktor Frankl
4. The greatest miracle in the world – Og Mandino
5. Goal - Eliyahu Goldratt.
6. Working with Emotional Intelligence - David Goleman.
7. Excel in English – Sundra Samuel, Samuel Publications
8. Developing Communication Skills by Krishna Mohan and Meera Banerji; MacMillan India Ltd., Delhi
Page 83 of 85

9. Essentials of Effective Communication, Ludlow and Panthon; Prentice Hall of India.
10. Effective Presentation Skills (A Fifty-Minute Series Book) by Steve Mandel
11. “Strategic interviewing” by Richaurd Camp, Mary E. Vielhaber and Jack L. Simonetti – Published by Wiley
India Pvt. Ltd
12. “Effective Group Discussion: Theory and Practice” by Gloria J. Galanes, Katherine Adams , John K. Brilhart
Page 84 of 85

12IT2004 BUSINESS INTELLIGENCE AND ITS APPLICATION 3 0 0 3
AIM
The proposed elective course exposes students to business intelligence domain. It provides knowledge on basics of
data integration, multi-dimensional data modeling and enterprise reporting.
OBJECTIVE
At the end of this elective, student will be able to:
· Differentiate between Transaction Processing and Analytical applications and describe the need for
Business Intelligence
· Demonstrate understanding of technology and processes associated with Business Intelligence framework
· Demonstrate understanding of Data Warehouse implementation methodology and project life cycle
· Given a business scenario, identify the metrics, indicators and make recommendations to achieve the
business goal
· Design an enterprise dashboard that depicts the key performance indicators which helps in decision making
· Demonstrate application of concepts in Microsoft BI suite
UNIT - I INTRODUCTION TO BUSINESS INTELLIGENCE 4
Introduction to OLTP and OLAP, BI Definitions & Concepts, Business Applications of BI, BI Framework, Role of
Data Warehousing in BI, BI Infrastructure Components – BI Process, BI Technology, BI Roles & Responsibilities
UNIT- II BASICS OF DATA INTEGRATION 12
Concepts of data integration need and advantages of using data integration, introduction to common data integration
approaches, introduction to ETL using SSIS, Introduction to data quality, data profiling concepts and applications
UNIT - III INTRODUCTION TO MULTI-DIMENSIONAL DATA MODELING 6
Introduction to data and dimension modeling, multidimensional data model, ER Modeling vs. multi dimensional
modeling, concepts of dimensions, facts, cubes, attribute, hierarchies, star and snowflake schema, introduction to
business metrics and KPIs, creating cubes using SSAS
UNIT- IV BASICS OF ENTERPRISE REPORTING 12
Introduction to enterprise reporting, concepts of dashboards, balanced scorecards, introduction to SSRS
Architecture, enterprise reporting using SSRS
UNIT -V TUTORIALS 6
The assignments for Electives could include the following.
Seminars from the topics related to Business Intelligence space
Relevant lab exercises to get exposure to BI concepts & tool
Total periods: 45
REFERENCES
1. Business Intelligence by David Loshin
2. Business intelligence for the enterprise by Mike Biere
3. Business intelligence roadmap by Larissa Terpeluk Moss, Shaku Atre
4. Successful Business Intelligence: Secrets to making Killer BI Applications by Cindi Howson
5. Delivering business intelligence with Microsoft SQL server 2008 by Brain, Larson
6. Foundations of SQL Server 2005 Business Intelligence by Lynn Langit
7. Information dashboard design by Stephen Few
Page 85 of 85

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SYLLABUS OF 2012 BATCHES