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Course Curriculum (w.e.f. Session 2013-14)

B.Tech. (Electrical Engineering)

DEPARTMENT OF ELECTRICAL ENGINEERING, Institute of Engineering & Technology

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Table of Contents

B.Tech. (EE) Course Structure ……………………………………………………………………………………………..……..i B.Tech. (EE) Syllabus .................................................................................................................... 1




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DEPARTMENT OF COMPUTER ENGINEERING & APPLICATIONS, Institute of Engineering & Technology

i

First Semester

S. NO.

CODE SUBJECT TEACHING SCHEME

CREDITS CONTACTS

HR/WK L T P 1. AHM101 Mathematics – I 3 1 0 4 4 2. AHP101 Engineering Physics – I 2 1 0 3 3

3. CSE101 Fundamentals of Computer & Programming

2 0 0 2 2

4. MEE102/ EEE101

Basic Thermodynamics/ Electrical Engineering

3 1 0 4 4

5. AHC101/ MEE101

Engineering Chemistry/ Manufacturing Process

3 1 0 4 4

6. MEE103/ ECE101

Applied Mechanics/ Electronics Engineering

3 1 0 4 4

PRACTICALS 7. AHE183 English in Practice – I 0 0 3 2 3

8. MEE182/ MEE181

Engineering Drawing/ EWS Practice Lab

0 0 3 2 3

9. AHC181/ AHP181

Chemistry Lab/ Physics Lab

0 0 2 1 2

10. CSE181 Computer Programming Lab 0 0 2 1 2

11. MEE183/ EEE181

Applied Mechanics Lab/ Electrical & Electronics Lab

0 0 2 1 2

12. EEE197 General Proficiency 0 0 0 1 - TOTAL 16 5 12 29 33

Second Semester

S.

NO. CODE SUBJECT

TEACHING SCHEME CREDITS

CONTACTS HRS/WK L T P

1. AHM102 Mathematics – II 3 1 0 4 4 2. AHP102 Engineering Physics - II 2 1 0 3 3

3. CSE102 Problem Solving using Computers

2 0 0 2 2

4. EEE101/ MEE102

Electrical Engineering/ Basic Thermodynamics

3 1 0 4 4

5. MEE101/ AHC101

Manufacturing Process/ Engineering Chemistry

3 1 0 4 4

6. ECE101/ MEE103

Electronics Engineering/ Applied Mechanics

3 1 0 4 4

PRACTICALS 7. AHE184 English in Practice – II 0 0 3 2 3

8. MEE181/ MEE182

EWS Practice Lab / Engineering Drawing

0 0 3 2 3

9. AHP181/ AHC181

Physics Lab/ Chemistry Lab

0 0 2 1 2

10. CSE182 Problem Solving Lab 0 0 2 1

11. EEE181/ MEE183

Electrical & Electronics Lab/ Applied Mechanics Lab

0 0 2 1 2

12. EEE198 General Proficiency 0 0 0 1 - TOTAL 16 5 12 29 33




ii

Third Semester

S. NO.


CREDITS CONTACTS

HR/WK L T P

1. AHM202 Computer based Numerical & Statistical Tech.

3 1 0 4 4

2. AHE201 Ethics & Values 2 0 0 2 2

3. EEE202 Electrical & Electronics Engg. Materials

3 1 0 4 4

4. ECE207 Analog & Digital Electronics 3 1 0 4 4 5. ECE201 Electromagnetic Field Theory 3 1 0 4 4 6. EEE201 Network Analysis & Synthesis 3 1 0 4 4

PRACTICALS 7. EEE281 Network Lab 0 0 2 1 2

8. ECE287 Analog & Digital Electronics Lab

0 0 2 1 2

9. EEE288 Simulation Lab-I 0 0 2 1 2 10. AHE281 Soft Skills-I 0 0 2 1 2 11. EEE297 GP 0 0 0 1 0

TOTAL 17 05 08 27 30

Fourth Semester

S. NO.


CREDITS CONTACTS

HR/WK L T P 1. AHM201 Mathematics III 3 1 0 4 4 2. CSE201 Data Structure using C 2 1 0 3 3 3. CEE201 Environmental studies 2 0 0 2 2 4. EEE203 Basic System Analysis 3 1 0 4 4

5. EEE204 Electrical Measurements & Measuring Instruments

3 1 0 4 4

6. EEE205 Electrical machine-I 3 1 0 4 4 PRACTICALS

7. EEE284 Measurement Lab 0 0 2 1 2 8. EEE285 Electrical machine Lab-I 0 0 2 1 2 9. EEE289 Simulation Lab-II 0 0 2 1 2

10. CSE281

Data Structures and algorithms Lab 0 0 2 1 2

11. AHE282 Soft Skills-II 0 0 2 1 2 12. EEE298 GP 0 0 0 1 0

TOTAL 16 05 10 27 31




iii

Fifth Semester

S. NO.


CREDITS CONTACTS

HR/WK L T P

1. AHS301/AHS302

Industrial Psychology/ Industrial Economics

2 0 0 2 2

2. AHE301/AHS303

Technical Writing/ Principle of management

2 1/0 0 3/2 3/2

3. EEE301 Electrical Machine-II 3 1 0 4 4 4. EEE302 Power Electronics 3 1 0 4 4 5. EEE303 Power System-I 3 1 0 4 4

6. ECE206 Microprocessors & Applications

3 1 0 4 4

PRACTICALS 7. EEE387 Colloquium 0 0 2 1 2 8. EEE382 Power Electronics Lab 0 0 2 1 2 9. ECE286 Microprocessors Lab 0 0 2 1 2

10. EEE383 Power System Lab-I 0 0 2 1 2 11. AHE381 Soft Skills-III 0 0 2 1 2 12. EEE397 GP 0 0 0 1 0

Total 16 5/4 10 27/26 31/30

Sixth Semester

S. NO.


CREDITS CONTACTS

HR/WK L T P

1. AHS302/AHS301

Industrial Economics/ Industrial Psychology

2 0 0 2 2

2. AHS303/ AHE301

Principles of management/ Technical Writing

2 0/1 0 2/3 2/3

3. EEE304 Power System-II 3 1 0 4 4 4. EEE305 Control System 3 1 0 4 4 5. ECE308 Analog & Digital

Communication 3 1 0 4 4

6. EEE306 Electrical Power Generation 3 1 0 4 4 PRACTICALS

7. EEE385 Control System Lab 0 0 2 1 2 8. EEE384 Power System Lab-II 0 0 2 1 2 9. ECE388 Communication Lab 0 0 2 1 2

10. EEE381 Electrical Machine Lab-II 0 0 2 1 2 11. AHE382 Soft Skills-IV 0 0 2 1 2 12. EEE398 GP 0 0 0 1 0

Total 16 4/5 10 26/27 30/31

NOTE: AT THE END OF SIXTH SEMESTER EACH STUDENT HAS TO UNDERGO AN INDUSTRIAL TRAINING PROGRAM OF MINIMUM FOUR WEEKS DURATION WHICH WILL BE EVALUATED AS EEE486 IN THE SEVENTH SEMESTER .




1

Seventh Semester

S. NO.

CODE SUBJECT TEACHING

SCHEME CREDITS CONTACTS

HR/WK L T P

1. EEE-401 Switchgear & Protection 3 1 0 4 4 2. EEE-402 Electric Drives 3 1 0 4 4 3. EEE-405-408 Professional Elective –I* 3 1 0 4 4 4. EEE-409-412 Professional Elective –II* 3 1 0 4 4 5. CSE-461-463, ECE-418 Open elective 3 1 0 4 4

TOTAL 15 5 0 20 20 PRACTICALS

1. EEE-481 Electric Drives Lab 0 0 2 1 2 2. EEE-482 Minor Project 0 0 6 3 6 3. EEE-483 Industrial Training 0 0 2 1 2 4. EEE-497 GP 0 0 0 1 0

TOTAL 0 0 10 6 10

Eighth Semester

S. NO.


SCHEME CREDITS CONTACTS

HR/WK L T P

1. EEE-403 Electrical Instrumentation & Process Control

3 1 0 4 4

2. EEE-404 Power system Operation & Control

3 1 0 4 4

3. EEE-413-416 Professional Elective –III* 3 1 0 4 4 4. EEE-417-420 Professional Elective –IV* 3 1 0 4 4

TOTAL 12 4 0 16 16 PRACTICALS

1. EEE484 Electrical Instrumentation Lab

0 0 2 1 2

2. EEE485 Project 0 0 14 7 14 3. EEE498 GP 0 0 0 1 0

TOTAL 0 0 16 9 16

NOTE: AT THE END OF SIXTH SEMESTER EACH STUDENT HAS TO UNDERGO AN INDUSTRIAL TRAINING PROGRAM OF MINIMUM FOUR WEEKS DURATION WHICH WILL BE EVALUATED AS EEE486 IN THE SEVENTH SEMESTER. * ANY ONE SUBJECT TO BE OFFERED UNDER EACH PROFESSIONAL ELECTIVE.




2

PROFESSIONAL ELECTIVES B. TECH (EE) Seventh Semester

ELECTIVE-I

S. NO.


SCHEME CREDITS CONTACT HRS/WK

L T P 1 EEE 405 Digital Control System 3 1 0 4 4 2 EEE 406 Power System Dynamics & Stability 3 1 0 4 4 3 EEE 407 Digital Signal Processing 3 1 0 4 4 4 EEE 408 Special electric machines 3 1 0 4 4

ELECTIVE-II

S. NO.



L T P 1 EEE 409 Advance Control System 3 1 0 4 4

2 EEE 410 Utilization of Electric power & traction

3 1 0 4 4

3 EEE 411 Bio-medical Instrumentation 3 1 0 4 4 4 EEE 412 Smart Grid 3 1 0 4 4

Eighth Semester ELECTIVE-III

S. NO.



L T P 1 EEE 413 Bio medical Signal Processing 3 1 0 4 4 2 EEE 414 High Voltage Engineering 3 1 0 4 4

3 EEE 415 Artificial intelligence & its applications to power system

3 1 0 4 4

4 EEE416 Telemetry & Data Transmission 3 1 0 4 4

ELECTIVE-IV

S. NO.



L T P 1 EEE 417 Industrial instrumentation 3 1 0 4 4 2 EEE 418 Restructured Power system 3 1 0 4 4

3 EEE 419 Power Quality in Power distribution Systems

3 1 0 4 4

4 EEE 420 Energy Conservation & Management 3 1 0 4 4

OPEN ELECTIVES

S. NO.



L T P 1 CSE 461 Human Computer Interaction 3 1 0 4 4 2 CSE 462 IT in Business 3 1 0 4 4 3 CSE 463 Soft Computing 3 1 0 4 4 4 ECE418 Digital image processing 3 1 0 4 4 5 MBA EDP 3 1 0 4 4




3

AAHHMM110011:: MMAATTHHEEMMAATTIICCSS II

Module No.

Content Teaching

Hours

I

Differential Calculus: Successive Differentiation, Leibnitz Theorem, Partial Differentiation, Euler’s Theorem on Homogeneous Functions, Differentiation of Composite and Implicit Functions, Total Derivatives, Leibnitz Rule of Differentiation Under the Integral Sign, Jacobian, Extreme of Functions of Several Variables, Lagrange’s Method of Undetermined Multipliers.

14

II

Ordinary Differential Equations: Introduction, Variables Separable & Linear Form of I Order and I Degree ODEs, Linear Differential Equations of Nth Order with Constant Coefficients, Euler – Cauchy Equations, Simultaneous Linear Differential Equations. Method of Variation of Parameters, Applications to Engineering Problems.

14

III

Matrices: Inverse of Matrix by Elementary Transformations, Rank of Matrix, Solution of Systems of Linear Equations, Linear Dependence And Independence, Complex Matrices, Eigen Values and Eigen Vectors, Cayley Hamilton Theorem, Diagonalization by Similarity Transformation.

11

References:

E. Kreyszig, “Advanced Engg. Mathematics”, John Wiley & Sons, 9th Ed. Peter V.O’Neil, “Advanced Engg. Mathematics”, Thomson Learning. M.D.Greenberg, “Advanced Engineering Mathematics”, Pearson Education Inc. Bali & Goyal, “A Text Book of Engg. Mathematics”, Infinity Science Press, U.S.A. Allen Jeffrey, Advanced Engineering Mathematics, Academic Press, Elseveir. B.V.Ramanna, Higher Engg. Mathematics, TMH.

L–T–P: 3–1–0 Semester I Credits: 04




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AAHHPP110011:: EENNGGIINNEEEERRIINNGG PPHHYYSSIICCSS II

Module No.

Content Teaching

Hours

I

Interference: Interference of Light, Principle of Superposition and Coherence of Light, Interference Due to Division of Wave front and Division of Amplitude, Theory of Biprism Experiment, Wedge Shaped Films, Newton’s Rings. Diffraction: Diffraction of Light, Fresnel and Fraunhofer Diffraction, Diffraction Due to Single Slit and N-Slits, Plane Diffraction Grating, Dispersive Power of Grating, Rayleigh’s Criterion and Resolving Power of Grating and Application.

10

II

Polarization: Introduction to Polarization Fundamentals, Phenomenon of Double Refraction, Nicol Prism, Production and Analysis of Plane, Circularly and Elliptically Polarized Light, Quarter and Half Wave Plates, Fresnel’s Theory of Optical Activity, Specific Rotation, Biquartz Polari meters. Laser: Spontaneous and Stimulated Emission of Radiation, Einstein’s Coefficients, Principle of Laser, Ruby Laser, Semiconductor Laser, Coherence, Characteristics of Laser Beam and Coherence Property, Laser Applications. Fiber Optics: Introduction, Principle of Optical Fiber, Classification of Fibers, Acceptance Angle and Acceptance Cone, Numerical Aperture, Propagation Mechanism and Attenuation in Optical Fiber.

10

III

Relativistic Mechanics: Basic Concepts, Inertial & Non-Inertial Frames, Galilean Transformations, Michelson- Morley Experiment, Einstein’s Postulates, Lorentz Transformation Equations, Length Contraction, Time Dilation, Addition of Velocities, Variation of Mass With Velocity, Mass Energy Equivalence.

10

References:

Optics Ajoy Ghatak (TMH) Optics-Brijlal & Subramaniam (S. Chand ) Optical Fibre & Laser Anuradha De. ( New Age ) Introduction to Special theory of relativity Robert Resnick Wiely & Sons Fundamental of Physics - Resnick, Halliday & Walker (Wiely )





5

CCSSEE110011:: FFUUNNDDAAMMEENNTTAALLSS OOFF CCOOMMPPUUTTEERR && PPRROOGGRRAAMMMMIINNGG

Module No.

Content Teaching

Hours

I

Introduction: Computer System, Generations of Computers, Classification of Computers. Introduction to Operating System: Batch Processing, Multi Programming, Multi User, Multi Tasking and Real Time Operating Systems. Computer Network: Introduction, Types and Applications. Number System: Decimal, Binary, Hexadecimal and Octal Number Systems and Their Inter Conversions. Generations of Programming Languages: Low, Assembly, High and 4GL. Language Processors: Compiler, Interpreter and Assembler, Linker, Loader, Algorithms and Flowcharts.

7

II

Introduction to The C Language: Structure of a C Program, Standard Input and Output in C, Operators and Expression, Type Conversion. Control Structures: Switch- Case, If -Else, While, Do- While and For Loop, Break and Continue Statement, Nested Loops.

7

III

Array: Introduction, Single and Multidimensional Arrays- Declaration, Initialization, Address Calculation. Operations on Arrays: Insertion, Deletion, Searching and Sorting. Strings: Declaration, Initialization, Input and Output of Strings, String Handling Functions.

7

Text Book:

Behrouz A. Forouzan and Richard F. Gilberg: “Computer Science – A structured Programming

Approach Using C”,C Language Learning, 2007. Reference Books:

K. N. King, “C Programming A Modern Approach”, W. W. Norton, 2nd Edition, 2008. Kernighan and Ritche, “The C Programming Language”, PHI, 2nd Edition, 2011. P. Dey and M. Ghosh, “Programming in C”, Oxford University Press 1st Edition, 2000.

Outcome: At the end of the course, students will be able to understand:

A new programming language well enough to implement simple algorithms. The strengths and weaknesses of programming languages as well as the domains for which they are

intended. The implementation, testing, debugging, and documentation procedures of programs in C.

Credits: 02 L–T–P: 2–0–0 Semester I




6

EEEEEE110011:: EELLEECCTTRRIICCAALL EENNGGIINNEEEERRIINNGG

Module No.

Content Teaching

Hours

I

DC circuit analysis & Network theorems: Fundamentals of electric circuits,

Kirchhoff’s laws, mesh analysis, node analysis, Thevenin theorem, maximum

power transfer theorem, superposition theorem.

Steady state AC analysis: AC fundamentals, average & rms values of different

AC waveforms, phasor algebra, analysis of series AC circuits, power triangle,

concept of power factor, power factor improvement.

13

II

Three phase AC circuits: Generation & advantages of three phase system, star

& delta connection, line & phase voltage/current relations.

Magnetic circuits: Faraday’s law, Self and mutual inductance, B-H

characteristics, hysteresis & eddy current losses, basics of magnetic circuit.

Single phase Transformers: : Constructional feature, Working Principle, EMF

equation, Ideal transformer, Equivalent Circuit, Phasor diagram , Definition of

voltage regulation and efficiency, Introduction to Auto-Transformer.

13

III

Rotating Electrical Machines:

Introduction to Electromechanical Energy Conversion. DC Machine:

Construction, Operating principle, Need of Starter, EMF Equation, Types of DC

Motor, Torque Equation, Characteristics and applications. Induction motor: 3-

phase: Construction & principle, Need of Starter, Torque Equation, Torque-slip

Characteristics.

Single Phase Induction motor: Principle and Starting methods. Synchronous

Motor: Operating principle and applications.

Electrical Installation and Illumination: Introduction to distribution of

electrical energy, Types of cables & switches, Electrical wiring. Fluorescent

sodium vapour and mercury lamp.

14

Text Books:

D.C. Kulshrestha, Electrical Enginerring, Tata McGraw Hill. References:

T.K. Nagsarkar & M.S.Sukhija, Basic Electrical Engineering, Edition 2008, Oxford University Press. H. Cotton, Advanced Electrical Technology,2nd Edition 2009, Wheeler Publishing. W.H. Hayt & J.E. Kennely, Engineering Circuit Analysis, 7th Edition, Mc Graw Hill. S.N.Singh, Electrical power generation, transmission & distribution, Eastern Economy Edition. I. J. Nagarath, Basic Electrical Engineering, 2nd Edition, Tata McGraw Hill. D. E. Fitzgerald & A. Grabel Higginbotham, Basic Electrical Engineering, 5th Edition, McGraw Hill. Edward Hughes, Electrical Technology, 3rd Edition, Pearson Education.





7

MMEEEE110011:: MMAANNUUFFAACCTTUURRIINNGG PPRROOCCEESSSS

Module No.

Content Teaching

Hours

I

Engineering Materials, Properties and Their Applications Engineering Materials-Plain Carbon Steel, Alloy Steel-Tool Steel and Stainless Steel, Non-Ferrous Metals and Alloys E.G. Cu Alloy-Brass, Bronze, Al Alloy-Duralumin, Composite Materials. Machining Processes Working Principles and Operations of Lathe, Drilling Machine, Grinding Machine and Shaper.

14

II

Metal Forming Processes Introduction to Hot & Cold Working Processes, E.g. Forging, Rolling, Extrusion and Drawing, Spinning, Bending Stretch Forming and Deep Drawing. Casting Processes Introduction to Various Types of Patterns and Their Allowances. Moulding Sand and Their Properties, Preparation of Sand Moulds, Basic Concepts of Core, Gating, Runner & Riser System, Defects in Sand Casting & Their Remedies.

17

III

Fabrication Processes Basic Concept and Applications of Arc Welding, Gas Welding, Spot Welding, Soldering and Brazing. Introduction to Advanced Machining Processes Ultrasonic Machining, Electrochemical Machining, Electric Discharge Machining.

17

References:

Chapman WAJ, “Workshop Technology” Part 1-3, Viva Books Pvt. Ltd. New Delhi. Hajra Chowdhary SK and Hajra Chowdhary AK “Workshop Technology” Media Promotors &

Publishers. Raghuwanshi RS, “Workshop Technology” Dhanpat Rai and Sons, New Delhi. Lindberg RA “Process and Materials of Manufacturing” Prentice Hall of India, New Delhi Jain RK “Production Technology” Khanna Publishers, New Delhi. Richard L, Little, “Welding and Welding Technology” Tata McGraw Hill, New Delhi. Taylor HF, Flemming, Merton C and Wulff J, “Foundry Engineering” Wiley Eastern Limited, New Delhi. Richard WH, Casl RL, Jr. and Philip C. Rosenthal, “ Principles of Metal Casting” Tata McGraw Hill

Publication Company Ltd., New Delhi. Jain V.K., “Advanced Machining Processes”, Allied Publishers, New Delhi. Jain K.C. and Chitale A.K., “Text book of Production Engineering” PHI Publication. Gupta, H.N., Gupta, R.C., Mital, Arun, “Manufacturing Processes”, New Age Publication.





8

EECCEE110011:: EELLEECCTTRROONNIICCSS EENNGGIINNEEEERRIINNGG

Module No.

Content Teaching

Hours

I

Transport phenomenon in semiconductors: Semiconductor materials; Intrinsic and Extrinsic semiconductors; Mass-action, law, Drift and diffusion of charge carriers. Junction diodes: p-n junction diode: construction, operation & characteristics; Zener and Avalanche breakdown mechanisms; Diode resistance and capacitance; Photodiode and LED. Diode applications: Rectifiers: half wave, full wave centre-tapped and bridge type.; Filters; Clippers Clampers; Voltage multipliers; Zener diode as voltage regulator; Regulated power supply.

14

II

Bipolar Junction Transistor (BJT): Bipolar junction transistor: construction & operation; CB,CE, CC configurations & their Characteristics; Operating point; Transistor as a switch; Need of biasing; Biasing methods: fixed bias, emitter bias, potential divider bias, voltage feedback bias; Bias stabilization; Stability factor; h-parameters; Small signal analysis of BJT amplifier. Field Effect Transistor (FET): Construction, operation & characteristics of JF E T- Shockley’s equation- Depletion & Enhancement type MOSFET; Biasing of JFET:-fixed bias, self bias and voltage divider bias; Biasing of depletion type & enhancement type MOSFET.

14

III

Digital Electronics: Number systems; Binary Addition & Subtraction; 1 ’ s and 2’s complement, Subtraction using 2 ’ s complement; Boolean algebra; Logic gates; Implementation of basic gates using universal gates; Realization of Boolean functions using basic & universal gates; Canonical forms(SOP & POS); Simplification of Boolean functions using Boolean postulates & K-map up to 4 variables with don’ t care condition; Basic concept of latch. Operational Amplifier (Op-Amp): Operational amplifier: Block diagram, ideal and practical Op-Amp characteristics; Inverting, non-inverting and differential configurations (open loop and closed loop); Applications of Op-Amp as buffer, adder, subtractor, integrator and differentiator.

13

References:

Robert L. Boylestad and Louis nashelsky, Electronic devices and circuit theory, Pearson Education/PHI, New Delhi.

Morris Mano, Digital design, Pearson Education. R.A. Gayakwad, Op-amps & linear Integrated circuits, PHI. R.J. Smith and R.C. Dorf Circuits, Devices and System, Willey, 5th edition. Jacob Millman and Christos C. Halkias, Integrated Electronics, TMH, New Delhi. H.S. Kalsi : Electronic Instrumentation, TMH, New Delhi.

i.





9

AAHHEE118833:: EENNGGLLIISSHH IINN PPRRAACCTTIICCEE 11

English in Practice I’ focuses on Communication Activities in Functional and Situational Contexts. It encourages

students to speak with fluency and accuracy as well as develop the four skills of reading, writing, listening and

speaking. The classes will be theme based to provide practice in a meaningful context which can be extended

outside the classroom.

COURSE OBJECTIVE

At the End of the Course, the Participant should be Able to- Understand and Communicate with English Speakers from Different Parts of the English-Speaking World. Discuss and plan Holidays in English. Understand and Tell Jokes and Stories. Discuss Elements of Popular Culture such as TV, Radio and Music. Talk & Write about past, memories and Ambitions in English. Communicate Important Personal Information in Spoken English. Discuss Health, and that of Others, in English.

Module No.

Content Lab Hours

I

Structural Input Use of Articles (Written Drill) Pp 49, & 50, Exercise 1,2,3,4 Singular & Plural Gender Nouns (Pp 61 Writing) Tenses (Pp 62 To 63, All Sections) Adjectives & Adverbs (Pp 82 Adjective & Adverbs) Prepositions (Place, Position, Instrument, Agent, Time) Pp 158 Exercise No.1, 2, Pp 159, Exercise No. 3) *All the Grammatical Elements Should be Discussed in the Light of the Exercises.

11

II

(A) Speaking and Listening Vocabulary of Character Description Shopping, Holidays (A List of Words Related To the Themes Can be Provided as A Supplement)

Activities Pp 118, Unit I, Listening Exercise No 1 (Track 002) Pp 119, Unit 1, Communication Exercise 4 (Track 003) Pp 121, Unit 3, Listening Exercise 1 (Track 009) Pp 132, Unit 9, Communication Exercise 4 (Track 026) (Text To be Used: Mani. P. English for Teaching.)

(B) Reading and Writing Vocabulary of Character Description History, Homes and Houses (A List of Words Can be Provided as A Supplement) Activities Pp 33, Describing A Process 1 & 2 [All the Sections To be Covered in the 2 Sessions Pp 37 To 38, Study Skills 1.A, B, C Pp 38, Writing 1 & 2 (Text To be Used: English for Engineers by Ris, Bangalore.)

13

Semester I

L–T–P: 0–0–3 Credits: 02




10

Text Books:

Mani .P & Deepthi, S, English for Teaching, CUP Regional Institute of English, ‘English for Engineers’, Bangalore, Foundation Books Pvt. Ltd.

References:

Hornby, A.S., An Advanced Learners’ Dictionary of Current English, OUP. Murphy, Raymond, Intermediate English Grammar, Cambridge University Press.

Material:

Audio-Video Material available in the language Lab and texts such as Newspapers etc

III

Structural Input Usage of Affixes In Forming Words Belonging to Different

Grammatical Categories E.G. –Al, Ness, Ed, Un-, IM-, -ISH, -Ism, Etc. Identification of Grammatical Categories of the Word In Sentences Error Correction With Reference to Subject & Verb Agreement (Pp

94 to 98 Exercise 26, K. R. Laxminarayanan, English for Technical Communication, Vol. 1 & 2, SciTech Pub. Pvt. Ltd)

Prepositions (Reason, Complement, Ingredient, Beneficiary)

11

IV

A. Speaking & Listening Vocabulary of Character Description Education, Defence (A List of Words Related to the Themes Can be Provided as A Supplement) Activities Pp 122, Unit 3, Listening Exercise 2 (Track 010) Pp 121, Unit 2, Communication Exercise 4 (Track 007) Pp 126 to 127, Unit 6, Listening Exercise 1 (Track 018) (Text to be Used: Mani, P. English for Teaching.)

B. Reading & Writing Activities Pp 48 Writing Pp 40 to 43, Reading, Chapter 1 & Comprehension Pp 44, Writing Section1 (Some More Activities Can be Added by Faculty) (Text to be Used: English for Engineers by Ris, Bangalore.)

9




11

MMEEEE118811:: EENNGGIINNEEEERRIINNGG WWOORRKKSSHHOOPP PPRRAACCTTIICCEE LLAABB

Module No.

Content Lab Hours

I

List of Experiments To Study the Working of Basic Machine Tools like Lathe M/C,

Shaper M/C, Drilling M/C and Grinding M/C. To Perform the Operations of Turning, Step Turning, Taper Turning

on Lathe. To Perform the Operations of Facing, Grooving and Knurling on

Lathe. To Perform the Operations of Marking, Filing and Sawing as Per

Given Dimensions. To Perform the Operations of Drilling Holes. To Perform the Operations of Making External and Internal

Threads Using Tapes and Dies. To Develop the Blank Dimensions Using Development Process. To Prepare A Funnel of Required Dimensions Using Joining

Processes. To Prepare Lap/Butt Joint By Arc Welding. To Prepare Lap/Butt Joint By Gas Welding. To Perform Different Operations in Carpentry Shop Such as Cutting,

Planning and Chiseling. To Prepare A Joint (Lap/T) By Using Wooden Specimen/Piece. To Prepare A Sand Mold For Solid Casting With the Help of Given

Pattern. To Prepare the Mold For Hollow Casting With the Help of Pattern

and Core. To Prepare Square Bolt Head By Upsetting Process.





12

AAHHPP118811:: PPHHYYSSIICCSS LLAABB

Any twelve experiments, at least five from each group

Module No.

Content Lab Hours

I

Group -A To Determine the Wavelength of Monochromatic Light by Newton’s

Rings. To Determine the Wavelength of Monochromatic Light With the Help

of Fresnel’s Biprism. To Determine the Focal Length of Two Lenses by Nodal Slide and to

Locate the Position of Cardinal Points. To Determine the Specific Rotation of Cane Sugar Solution Using Polari

meter. To Determine the Wavelength of Spectral Lines Using Plane

Transmission /Diffraction Grating. Measurement of Wavelength of Laser (He- Ne) Light Using Single Slit

Diffraction To Verify Stefan’s Law by Electrical Method. To Determine the Coefficient of Viscosity of Water by Poiseuille’s

Method. Group – B To Determine the Specific Resistance of the Material of A Given Wire

Using Carey Foster’s Bridge. To Study the Variation of Magnetic Field Along the Axis of Current

Carrying Circular Coil and Then to Estimate the Radius of the Coil. To Calibrate the Given Ammeter by Potentiometer. To Calibrate the Given Voltmeter by Potentiometer. To Study the Hall Effect and Determine Hall Coefficient, Carrier

Density and Mobility of A Given Semiconductor. To Determine the Energy Band Gap of A Given Semiconductor

Material. To Determine E.C.E. of Copper Using Tangent Or Helmholtz

Galvanometer. To Draw Hysteresis Curve of A Given Sample of Ferromagnetic

Material and Then to Determine the Magnetic Susceptibility and Permeability of the Given Specimen.

To Determine the Ballistic Constant of A Ballistic Galvanometer. Measurement of Fiber Attenuation and Aperture of Optical Fiber. To Determine High Resistance by Leakage Method.

24





13

CCSSEE118811:: CCOOMMPPUUTTEERR PPRROOGGRRAAMMMMIINNGG LLAABB

Module No.

Content Lab Hours

I

(1) Arithmetic Operations WAP to Perform Arithmetic Operation Over the Variables. WAP to Calculate Area of the Circle. WAP to Find the Sum of Digits of A Number. WAP to Find the Reverse of A String.. WAP to Implement Perimeter of A Rectangle

(2) Function WAP to Call A Function by Reference. WAP to Call A Function by Value. WAP to Calculate Factorial of A Number. WAP to Print A Table of A User Define Number. WAP to Generate Fibonacci Series

(3) Pointer WAP to Display the Contents of 2D Array Using Pointer. WAP to Sort an Array in Ascending Order Using Dynamic

Memory Allocation and Pointers. (4) Microsoft Office

MS Word Introduction. MS Excel Introduction MS Power point Introduction. MS Paint Brush Introduction.

(5) Pattern WAP to Design the Following Pattern * * * * * * * * * * * * * * * * * * * * * * * * * * * *

* *

24

L–T–P: 0–0–2 Credits: 01 Semester I




14

EEEEEE118811:: EELLEECCTTRRIICCAALL && EELLEECCTTRROONNIICCSS LLAABB

Module No.

Content Lab Hours

I

To Verify the Thevenin’s Theorem (DC Circuits). To Verify the Maximum Power Transfer Theorem (DC Circuits). Also

Draw Graph between Power and Load Resistance. To Verify the Superposition Theorem (DC Circuits). To Study the Phenomenon of Resonance in R-L-C Series Circuit and to

Draw Graph Between Frequency and Current. Also Show Half Power Points.

To Determine the V-I Characteristics of A Semiconductor Diode. Also Calculate Forward and Reverse Static and Dynamic Resistances.

To Study the Half Wave and Full Wave (Center Tapped) Rectifier With and Without Filter. Also to Calculate the Ripple Factor in Both Cases (Without Filter).

To Study Single Phase (Induction Type) Energy Meter. To Study Various Logic Gates Such As OR, AND, NOT, NAND, NOR. Study of CRO and Measurement of Voltage and Frequency Using CRO. V-I Characteristics of Zener Diode. Identification of Active and Passive Components. V-I Characteristics of Bipolar Junction Transistor in Common Base

Mode.

24





15

AAHHMM110022:: MMAATTHHEEMMAATTIICCSS IIII

Module No.

Content Teaching

Hours

I

Multiple Integrals: Double and Triple Integrals, Change of order of integration, Change of variables, Beta and Gamma functions. Applications to Dirichlet integrals. Fourier Series: Fourier series of period 2, Even and Odd functions, Fourier series for discontinuous functions, Half range sine and cosine series, change of interval.

14

II

Partial Differential Equations:

Solution of I order Lagrange's linear PDEs, Linear PDEs with constant coefficients, Classification of II order PDEs, Method of separation of variables, One dimensional wave equation, D'Alembert's solution, Heat conduction equations up to two dimensions.

12

III

Laplace Transform:

Properties of Laplace transform, Existence theorem, Laplace transform of derivatives and integrals, Unit step and Dirac - delta function, periodic functions, Partial Fractions, Properties of inverse Laplace transform, convolution theorem. Application to ODEs and integral equations.

14

References:

E. Kreyszig “Advanced Engg. Mathematics”, 9th Ed., John Wiley & Sons

Peter V.O’Neil: “Advanced Engg. Mathematics”, Thomson Learning

M.D.Greenberg: “Advanced Engineering Mathematics”, Pearson Education Inc.

Bali & Goyal “A Text Book of Engg. Mathematics”, Infinity Science Press, U.S.A.

Allen Jeffrey “Advanced Engineering Mathematics”, Academic Press, Elseveir

B.V.Ramanna “Higher Engg. Mathematics”, TMH.

L–T–P: 3–1–0 Semester II Credits: 04




16

AAHHPP110022:: EENNGGIINNEEEERRIINNGG PPHHYYSSIICCSS IIII

Module No.

Content Teaching

Hours

I

Electromagnetic : Inconsistency in Ampere’s Law, Displacement Current, Equation of Continuity, Maxwell’s Equations (Integral and Differential Forms), Propagation of E-M Waves in Free Space and in Conducting Media, Pointing Theorem and Pointing Vector. Electric and Magnetic Fields in Matter: Dielectric Behavior of Materials, Clausius-Mossotti Relation, Piezoelectricity (Qualitative), Magnetization, Dia, Para and Ferromagnetism, Langevin’s Theory for Dia and Para Magnetism.

16

II

Solid State Physics: Formation of Energy Bands in Solids. Intrinsic & Extrinsic Semiconductors, Donor and Acceptor Impurities, Fermi Level and Fermi Energy, P-N Junction Formation, Temperature Dependence of Conductivity and Mobility, Hall Effect. Origin of Superconductivity, Meissner Effect, Type-I & Type-II Super Conductors, London’s Equation, Application of Superconductors. Nanomaterials: Basic Principle of Nanoscience and Nanotechnology, Nanostructures, Bucky balls: Creation & Uses, Synthesis and Characterization of Carbon Nano-Tube (CNT), Application of Carbon Nanotubes.

14

III

Wave Mechanics: Wave Model, Wave- Particle Duality, Photoelectric Effect, De-Broglie Hypothesis. Phase and Group Velocities: Wave packet, Heisenberg’s Uncertainty Principle and its Applications, Wave Function and its Normalization. Schrödinger’s Wave Equation: Time Dependent and Time Independent Wave Equations, Particle in One Dimensional Potential Box. X-Ray Diffraction: Diffraction of X-Rays by Crystal Planes, Bragg’s Law, Bragg’s Spectrometer, Compton’s Effect.

14

References:

Beiser, Concept of Modern Physics, Tata Mc-Graw Hill. Kittel, Solid State Physics, 7th edition, Wiley Eastern. S.O. Pillai, Solid State Physics, 5th edition, New Age International Publication. V. Raghavan, Materials Science and Engineering, Prentice Hall India. Rechard Booker and Earl Boysen, Nanotechnology, Wiley International Publishing. David J. Griffith, Introduction to Electrodynamics, Prentice Hall of India.

L–T–P: 2–1–0 Credits: 03 Semester II




17

CCSSEE110022:: PPRROOBBLLEEMM SSOOLLVVIINNGG UUSSIINNGG CCOOMMPPUUTTEERRSS

Prerequisite: Fundamentals of Computer & Programming (CSE101).

Module No.

Content Teaching

Hours

I

Pointers: Declaration and Initialization of Pointer Variables, Accessing a Variable Through its Pointer, Pointer Arithmetic, Array of Pointers, Pointer to an Array. Functions: Declaration and Definition, Category of Functions, Parameter Passing Techniques – Call by Value and Call By Reference, Passing Arrays to Functions. Introduction To Storage Classes – Auto, Static, Extern and Register.

7

II

Recursion: Mechanics of Recursive Call, Implementation of Recursion, Recursion vs. Iteration. User Defined Types: Enum, Typedef, Union and Structure - Declaration, Initialization, Nested Structures, Arrays of Structures, Structure and Pointer, Passing Structure Through Function. Difference Between Structures and Union.

7

III

The C Preprocessor: Introduction, Macro Expansion and File Inclusion. File Handling: Data And Information, File Concepts, File Organization, Files In C, File Operations: Open, Read, and Close, Trouble in Opening a File. File Opening Modes, Working with Text Files. Introduction to Data Structures – Stack, Queue and Linked List and its Basic Operation.

7

Text Book:

Behrouz A. Forouzan and Richard F. Gilberg, “Computer Science – A Structured Programming Approach Using C”, C Language Learning (2007).

Reference Books:

K. N. King, “C Programming A Modern Approach”, W. W. Norton, 2nd Edition (2008). Kernighan and Ritche, “The C programming Language”, PHI, 2nd edition (2011). P. Dey and M. Ghosh, “Programming in C”, Oxford University Press 1st Edition (2000).

Outcome: At the End of The Course, Students Will be Able to Understand How to:

Write Programs that Perform Explicit Memory Management. Create Programs that Measure or Simulate Performance and Use Them to Analyze Behavior. Write The Programs for Compiler and Operating Systems.

Semester II L–T–P: 2–0–0 Credits: 02




18

MMEEEE110022:: BBAASSIICC TTHHEERRMMOODDYYNNAAMMIICCSS

Module No.

Content Teaching Hours

I

Basic Concepts: Thermodynamic Systems, State & Properties, Macroscopic & Microscopic Point of View. Thermodynamic Equilibrium & Processes, Zeroth Law of Thermodynamics, Temperature Scales, Work & Heat. First Law of Thermodynamics: First Law of Thermodynamics, Steady Flow Energy Equation for Closed and Open Systems, Application of First Law to Various Thermodynamic Systems Such As Boiler, Turbine, Compressor, Nozzle, Pump Etc. Second Law of Thermodynamics: Limitations of the First Law of Thermodynamics, Concept of Heat Engine, Heat Pump & Refrigerator, Second Law of Thermodynamics, Carnot Cycle, Theorems and Corollaries. Clausius Inequality, Concept of Entropy, Principle of Increase of Entropy of Universe, Entropy Change During Various Processes, Concept of Third Law of Thermodynamics.

17

II

Properties of Steam: Definition of Pure Substance, Phase Change, P-T Diagram and Pv-T Surfaces, Formation of Steam, Classification of Steam Generators, Concept and Determination of Dryness Fraction of Steam, Thermodynamic Properties of Steam, Steam Table and Mollier Diagram. Rankine Cycle,

10

III Gas Power Cycles and IC Engines: Air Standard Cycles and Efficiency, Otto Cycle, Diesel Cycle, Concept & Classification of IC Engines, Construction and Working of Two Stroke and Four-Stroke Engines, SI and CI Engines.

13

References:

Va Wylen G.J. & Sonnlog R.E.: Fundamentals of classical thermodynamics, John Wiley & Sons, Inc. NY. Wark Wenneth: Thermodynamics, Mc Graw Hill book Co. NY. Holman, J.P.: Thermodynamics, MC Graw Hill book Co. NY. Rogers G and Mayhew Y: Engineering Thermodynamics, Pearson Education. Jones J B and Hawkins J A: Engineering Thermodynamics, John Wiley and Sons. Joel R.: Basic Engineering Thermodynamics, Addison Wesley. Nag P. K.: Engineering Thermodynamics, TMH, India. Yadav R.: Thermodynamics and Heat Engines, Vol I & II (Sl Edition) Central Publishing House

Allahabad. Ballaney P.L.: Thermal Engineering, Khanna Publisher. Rajput R.K.: Thermal Engineering, Laxmi Publication. Arora C.P.: Engineering Thermodynamics, TMH, India.

L–T–P: 3–1–0 Semester II Credits: 04




19

AAHHCC110011:: EENNGGIINNEEEERRIINNGG CCHHEEMMIISSTTRRYY

Module No.

Content Teaching

Hours

I

Chemical Kinetics: Order and Molecularity of Reactions, Zero Order, First Order and Second Order Reactions. Integrated Rate Equations. Theories of Reaction Rates, Factors Affecting Rate of Reaction. Solid State: (1 Lect): Types of Unit Cell, Space Lattice (Only Cubes), Calculation of Density of the Unit Cell, Number of Atoms Per Unit Cell, Chemical Bonding: M.O. Theory and Its Applications in Homo & Hetero Diatomic Molecules. Hydrogen Bond, Metallic Bond and Their Applications. Semi-Conductor Organic Name Reactions and Stereochemistry. Name Reactions Ie.Aldol Condensation, Cannizaro Reaction, Types of Isomerism (Optical & Geometrical), Chirality, Element of Symmetry, Diastereomers, Optically Active Compounds, R-S Configuration and E-Z Geometrical Isomers, Conformation of Ethane, N-Butane Non Conventional Energy Source: Introduction to Solar Energy, Biomass and Biogas.

14

II

Introduction, Definition and Explanation of the Terms: Phase, Component and Degree of Freedom, Application of Phase Rule to One Component System (Water & CO2 System), Ph, Buffer Solution (Henderson Equation). Polymers: Polymerization and Its Classification. Thermoplastic and Thermosetting Resins. Properties of Polymers, Molecular Weights of Polymers, Elastomers. Organic Conducting and Biodegradable Polymers (PMMA, Polystyrene, Teflon, Neoprene, Buna-S, Buna-N Nylon 6, Nylon 66, Terylene, PLA, Poly Β Hydroxy Butyrate), Vulcanization of Rubber. Water Treatment: Introduction, Hardness and Its Units,, L-S Process, Calgon Process, Zeolite and Ion-Exchange Resins, Treatment of Municipal Water, Reverse Osmosis, Impurities in Water, Characterstics of Water, Treatment Process Includes Above Deleted Portions, Boiler Feed Water, Boiler Troubles and Remedial Measures Lubrication: Introduction to Lubrication, Classification, Properties & Uses.

17

III

Corrosion: Introduction, Consequences, Types, Theories of Corrosion, (Galvanic, Pitting, Stress, Water Line, Intergranular & Soil Corrosion) and Protection of Corrosion. Electrochemical Cell, Concentration Cell. Spectroscopy: Elementary Ideas and Simple Applications of UV, Visible, Infra-Red and NMR Spectral Techniques Fuels: Classification of Fuels. Analysis of Coal, Determination of Calorific Values, Synthetic Petrol Glass: Preparation, Varieties & Uses. Ceramics: Introduction, Classification, Scope & Application.

17

References:

Morrison Boyd, Organic Chemistry I.L. Finar, Organic Chemistry Y R Sharma, Elementary Organic Spectroscopy S. S. Dara, Text Book of Engg Chemistry Shashi Chawla, Engg Chemistry K M Mittal, Non Conventional Energy System Mars G Fontana, Corrosion Engg Attkins & others, Inorganic chemistry Attkins & others, Physical Chemistry Puri, Sharma and Pathania : Physical Chemistry Bahl and Tuli, Physical Chemistry

L–T–P: 3–1–0 Credits: 04 Semester II




20

MMEEEE110033:: AAPPPPLLIIEEDD MMEECCHHAANNIICCSS

Module No.

Content Teaching

Hours

I

Introduction Engineering Mechanics: Idealization of Bodies, Concept of Rigid Body, External Forces, Moments, Couples, Laws of Mechanics. Force Systems and Equilibrium Concurrent Forces in A Plane, Parallel Forces in A Plane, Free Body Diagram, Equation of Equilibrium and Their Applications to Various Systems of Forces. Friction Concepts of Friction, Dry Friction, Laws of Friction and Their Applications to Wedge, Ladder, Screw, Belt-Pulley System, Rolling Friction.

14

II

Distributed Forces and Moment of Inertia Centroid of Composite Figures, Area Moment of Inertia, Polar Moment of Inertia, Parallel Axis Theorem, Perpendicular Axis Theorem, Principle Moment of Inertia, Mass Moment of Inertia of Circular Ring, Disc, Cylinder, Sphere and Cone About Their Axis of Symmetry. Beams Different Support & Load Conditions, Shear Force and Bending Moment Diagrams For Point Load, Uniformly Distributed Load, Uniformly Varying Load.

12

III

Analysis of Plane Trusses Engineering Structures, Perfect Truss, Determination of Axial Forces in the Members, Method of Joints, Method of Section. Kinematics of Rigid Body Plain Motion of Rigid Body, Velocity and Acceleration Under Translation and Rotational Motion, Absolute Motion, Relative Motion. Kinetics of Rigid Body Force, Mass and Acceleration, Work, Power and Energy, Impulse and Momentum, D’Alembert’s Principle and Dynamic Equilibrium.

14

References:

Engineering Mechanics I.H. Shames, Prentice Hall of India Pvt. Ltd., New Delhi (EEE) Mechanics for Engineers (Statics and Dynamics) F.P. Beer & E.R. Johnston, TMH New Delhi Engineering Mechanics Statics & Dynamics by Dr. A.K. Tayal, Umesh Publications, Delhi Engineering Mechanics Statics Vol.I & Dynamics Vol-II by V.S. Mokashi (Tata McGraw- Hill) Engineering Mechanics Statics & Dynamics by J.L. Marriam & L.G. Kraig, John Wiley & Sons Ltd.

Credits: 04 L–T–P: 3–1–0 Semester II




21

AAHHEE118844:: EENNGGLLIISSHH IINN PPRRAACCTTIICCEE IIII

Keeping in Mind the Diverse Set of Students (as Far as Their Mother Tongues Are Concerned) in the Undergraduate

Programmes of the University, ‘English in Practice- II’ Focuses on Communication Activities in Functional and

Situational Contexts. It Encourages Students to Speak With Fluency and Accuracy as Well as to Develop the Four

Skills: Reading, Writing, Listening and Speaking. This Course Proposes Scope For the Participants to Learn the Art of

Speaking English as Standard Indian English Speaker. It Aims Not to Prescribe the Rules Which the Participants May

Find Difficult to Follow as A Non Native Speaker Rather It Facilitates Them to Improve Their Spoken Language

Without the Interference of Their Mother Tongues (MTI).

COURSE OBJECTIVE At the end of the course, the participant should be able to

• Read Articles on Subjects of General Interest • Review Grammar and Vocabulary So That One is Able to Speak with More Accuracy • Learn the Vocabulary and Phrases that are used in Social Gatherings and Networking Events • Listen to News and General Interest Programmes So That One Can Improve One’s Ability to Understand • Practice Speaking in Groups in Order to Gain Confidence by Using the Language • Practice Speaking in Real-Life Situations

Module No.

Content Lab Hours

I

Structural Input

It Includes More Specific Phonetic Exercises Designed to Address Core Problem Areas Which Non-Native Speakers Face, Air Flow Exercises For Continuant Sounds. It Gives An Opportunity to Get Continued Feedback on Self-Correction and Transfer of Techniques Learned in The First Course. Topics Include:

Contrastive Vowel Articulation Exercises. Words Spelled in The Same Way But Pronounced Differently. Exercises to Distinguish Voiced and Voiceless Continuants, As in

Words Like “Another Or Suspicious” in-Depth Post-Vocalic /L/ and /R/ Exercises. Pronunciation of Country Names Worldwide. Word Stress Exercises For Multi-Syllabic Words and Word Families.

Pronunciation of Individual Vowels and Consonants: Learn The International Phonetic Alphabet. Practice Articulating Both Long and Short Vowels. Learn How to Pronounce Consonants in All Environments: Initial,

Medial, and Final. Tongue Twisters & Articulation Exercises. Breath Exercises.

Word Stress Patterns: Rules of Both English and Foreign-Derived Words. Dividing Words Into Syllables. Syllable Length. Stressed and Unstressed Syllables. Word Form Stress Shift Patterns. Nouns, Adjectives & Adverbs Vs. Verbs. Compound Nouns.

Activities Pp 119, Unit-1, Pronunciation Exercise-10, Track 005 Pp-121 Unit-2,

11

Credits: 02 Semester: II L–T–P: 0–0–3




22

Pronunciation Exercise -11,Track-008 Pp-123, Unit-3, Pronunciation Exercise-12 & 13,Track 011 & 012. (Text to be Used: Mani, P. English For Teaching.)

II

Slrw Skill Enhancement Character Description

Imagining Future Cultural Differences Alternative Beliefs Media Music & Films Relationships Science & Technology Youth & Old Age Tradition Sports Society

(A List of Words Related to The Themes Can be Provided As A Supplement). Activities Odd Man Out Vocabulary Exercise. Short Text For Dictation. Dialogue For Pronunciation & Techniques. Discuss Questions Crossword Clues With Grid. # ‘Improve Your English- Cd1’ Can be Referred to Prepare The Above Mentioned Exercises.

13

III

Structural Input

Intonation, Rhythm, and Linking: Neutral Or “Unmarked” Patterns For Statements and Questions. Contrastive Stress and Usage. Content Vs. Function Words. Rhythm and Linking. Word Clustering/Grouping and Powerful Pauses.

Activities Exercises to be Based on The Following Factors: Asking Questions Using Tags (Isn't It? Ok?) Using Emphasis For Effect Being Polite Giving Opinions Agreeing and Disagreeing Complaining Small Talk Using Intonation to Show Emotion Using 'Natural' English Pp-123, Unit-3, Pronunciation, Exercise-14,Track-013, Pp-128, Unit-6, Pronunciation, Exercise- 8,Track-020 Pp-131, Unit-8, Pronunciation, Exercise-8,Track-024

11

IV

Slew Skill Enhancement Character Description Social & Political Issues Books Generation Changes National Traditions/Customs & Culture News

(A List of Words Related to The Themes Can be Provided As A Supplement). Activities

Odd Man Out Vocabulary Exercise

9




23

Text books:

Mani .P & Deepthi. S, English for Teaching, CUP Murphy, Raymond, English Grammar in Use: A Self-study Reference and Practice Book (With Answers

and CD ROM for Intermediate Students of English), Cambridge University Press. References:

Hornby, A.S., an Advanced Learners’ Dictionary of Current English, OUP. Murphy, Raymond, Intermediate English Grammar, Cambridge University Press.

Material:

‘Accent’, CD Available in ‘Language Lab’ with other audio-video Material available in the language Lab.

Short Text For Dictation Dialogue For Pronunciation & Techniques Organizing Text Crossword Clues With Grid

Material to be Used: ‘Accent’, Cd Available in ‘Language Lab’. Raymond Murphy, English Grammar in Use.

Advanced Grammar Exercises – Toefl Practice Tests.




24

MMEEEE118822:: EENNGGIINNEEEERRIINNGG DDRRAAWWIINNGG

Module No.

Content Lab Hours

I

Introduction to Drawing Instruments, Sheet Layout, Types of Lines and

Their Uses, Lettering, Concepts of Scales in Drawing and Their Types, Types

of Dimensioning, Application of Symbols and Conventions in Drawing

Practice, Geometrical Construction.

Theory of Projections, Orthographic & Oblique Projection, Projection of

Points, Lines, Planes and Solids, Development of Surfaces & Section of Solids,

Concepts of Isometric and Perspective Views.

Introduction to Computer Aided Drawing and Various Softwares Available in

The Market. Isometric Projection, Conversion of Pictorial Views to

Orthographic Views and Vice Versa, Computer Aided Drawing Using Auto

CAD.

36

References:

Bhatt N.D., Panchal V.M., Elementary Engineering Drawing, Charothar Publishing, Gujrat Dhawan R.K.; A Text book of Engineering Drawing, S.Chand Gopalkrishna K.R.; Engg. Graphics; Subhash Publishers, Banglore Trymbaka Murty.S; Computer Aided Engineering Drawing; T.K. International Publishing House Pvt.

Ltd. New Delhi. Luzadder Warren J., Duff John M., Fundamentals of Engineering Drawing with an introduction to

Interactive Computer Graphics for Design and Production, Practice-Hall of India Pvt. Ltd, New Delhi. Singh Ajit, “Machine Drawing’ Tata McGraw Hill, New Delhi.





25

AAHHCC118811:: CCHHEEMMIISSTTRRYY LLAABB

Any TEN Experiments are to be performed

Module No.

Content Lab Hours

I

Preparation and standardization of solutions.

To determine the constituents and amount of alkalinity of the supplied water sample.

To determine the percentage of available chlorine in given sample of bleaching powder.

To determine pH of a solution using a pH-meter and titration of such solution pH-metrically.

Determination of free CO2 in a given sample of water.

To determine the ferrous ion content in given iron ore by titrimetric analysis against standard K2Cr2O7 solution using K3[Fe(CN)]6 as an external indicator.

To determine iron concentration in the sample of water by colorimetric method. The method involves use of KCNS as color developing agent and the measurements are carried out at max 480 nm.

To determine the viscosity of an addition polymer like polystyrene sample by using Ostwald viscometer relative to water.

To determine the temporary and permanent hardness of water by using EDTA or complexometry.

To determine the equivalent weight of iron by chemical displacement method. The equivalent weight of copper is 63.5.

To determine chloride ion in a given water sample by Argentometric method (Mohr’s Method).

To determine the moisture content in a given sample of coal.

To determine the calorific value of a solid fuel by bomb calorimeter.

Show that inversion of cane sugar is the example of first order reaction by polarimeter.

24

Semester II Credits: 01

L–T–P: 0–0–2




26

CCSSEE118822:: PPRROOBBLLEEMM SSOOLLVVIINNGG LLAABB

Module No.

Content Lab Hours

I

Recursion WAP to calculate factorial of a number. WAP to generate table of any number. WAP to find GCD of two numbers. WAP to calculate nth term of Fibonacci Series 1,1,2,3,5,8. WAP to find the sum of digits of a number. WAP to find the reverse of a string.

Structure WAP to enter 10 records of student. Structure fields are Name, Roll

no, Marks. Calculate the average of their marks. Declare a structure which will contain the following data for three

employees. i. Emp_code 3 characters,

ii. First_name 20 characters, iii. Middle_initial 1 character, iv. Last_name 20 characters. v. The employee code to be stored in the structure are-E01,

E02, E03. Write a program to input names for 3 employees and printout initials of each.(e.g. Anil K Nehra will be printed as AKN) along their codes.

WAP to demonstrate, how structure is passed to a function. WAP to perform arithmetic operations using functions and switch

case and enumeration. Pointer

WAP to display the contents of 2D array using pointer. WAP to sort an array in ascending order using dynamic memory

allocation and pointers. File handling

WAP to copy the contents of a given file into another file. WAP to read the characters from a file and display the uppercase on

a console. Introduction to Data Structure

WAP to demonstrate various operations (create, push, pop, overflow, underflow, peek, display) of STACK using array implementation.

WAP to demonstrate various operations (create, enqueue, dequeue, overflow, underflow, peek, display) of Queue using array implementation.

WAP to demonstrate various operations [(create, Traversing, Searching, Inserting an element (at beginning, at end, after a given element), Deleting an element (from beginning, from end, after a given element)] of a linked List.

WAP to demonstrate various operations (create, Traversing, Searching, Inserting an element at beginning, Deleting an element from end) of a doubly linked List.

24





27

MEE183: APPLIED MECHANICS LAB

Module No.

Content Lab Hours

I

Group – (A) List of Experiments To conduct the tensile test and determine the ultimate tensile

strength, percentage elongation for a steel specimen on UTM. To determine the ultimate compressive strength for a specimen on

UTM. To conduct the Impact-tests (IZOD/CHARPY) on Impact-testing

machine to find the toughness. To determine the hardness of the given specimen using BRINELL/

Rockwell hardness testing machine. To determine coefficient of friction using inclined plane. To determine mechanical advantage velocity ratio and efficiency of

Worm and Worm Wheel. To measure deflection of simply supported beam and compare with

Theoretical values. Bending of simply-supported beams for theoretical & experimental

Deflection. To determine Modulus of Rigidity of a circular wire/rod. To determine Mass Moment of Inertia of a wheel.

Group – (B) Demonstration of simple and compound gear-trains. Demonstration of working of Belt-Pulley system. Demonstration of joints and members in a simple truss.

24





28

AAHHMM220022:: CCOOMMPPUUTTEERR BBAASSEEDD NNUUMMEERRIICCAALL && SSTTAATTIISSTTIICCAALL TTEECCHHNNIIQQUUEESS

Module No.

Content Teaching

Hours

I

Numerical Technique-I Solution of algebraic and Transcendental Equations: Bisection, Regula-Falsi, Newton Raphson Methods and Their Order of Conversions. Interpolation Finite Difference, Relation Between Operators, Missing Term Technique, Newton forward and Backward Difference Interpolation Formula, Gauss Forward and Backward difference formula, Langrange Interpolation Formula, Newton’s Divide Difference Formula.

13

II

Numerical Technique-II Numerical integration: Newton’s-Cote’s Quadrature Formula, Trapezoidal Rule, Simpson’s 1/3rd and 3/8th rules, Boole’s and Weddle’s Rule. Numerical solution of ordinary differential equations: Single and Multistep Method, Pickards Method, Ranga Kutta 4th Order method, Milnes predictor corrector method

13

III

Statistical Techniques Curve-fitting, Method of Least Square, Fitting of straight lines, Polynomials and Exponential Curves etc., Correlation, Linear Regression Analysis, Binomial, Poisson and Normal Distributions, Statistical Quality Control Method, X, R, P and NP Charts.

14

References:

Jain, Iyenger, “Jain: Numerical method for scientific and Engg. Computation”, New Age International. S.S. Sastry, “Introductory method of numerical analysis”, PHI. S.D.Conte and Carl de Boor: “Elementary of numerical analysis”, An algorithmic approach, TMH. M.Goyal, “Numerical method and statistical techniques using C”, Firewall Media. S.P.Gupta, “Statistical methods”, Sultan chand & sons.

Credits: 04 L–T–P: 3–1–0 Semester III




29

AAHHEE220011:: EETTHHIICCSS && VVAALLUUEESS

Module No.

Content Teaching

Hours

I

Conceptual Foundations: Foundations of Morality; Professional Ethics; Professional Standards in Engineering Practice; Major Theories of Ethics and Different Ethical Approaches; Normatively of Science and Technology. Professions and Moral Dilemmas: Contemporary Ethical Issues; Conflict of Interests; Contracts; Rights and Violations; Consent and Dissent; Privacy and Confidentiality; Consultancy; Allocation of Burdens and Benefits; Direct and Indirect Responsibility; Patents, Piracy and Clones.

14

II

Decision Making: Theoretical Bases; Foundational Values; Greater Welfare Approach; Risk-Benefit Analysis; Right-based Approach; Priority Allocation; Binding Grounds of Decisions; Public Norms and Professional Guidelines.

14

III Social Responsibility: Individual and Collective Responsibility; Corporate Social Responsibility; Justice and Fairness; Beneficence and Safety; Respect for Humanity, Life, and Nature; Sustainable Development.

11





30

EEEEEE220022:: EELLEECCTTRRIICCAALL && EELLEECCTTRROONNIICCSS EENNGGIINNEEEERRIINNGG MMAATTEERRIIAALLSS

Credits: 04 Semester III L-T-P: 3-1-0

Module No.

Content Teaching

Hours

I

A1: Crystal Structure of Materials: Bonds in Solids, Crystal Structure, Co-Ordination Number, Atomic Packing Factor, Miller Indices, Bragg’s Law and X-Ray Diffraction, Structural Imperfections, Crystal Growth. Energy Bands in Solids, Classification of Materials Using Energy Band. A2: Conductivity of Metals: Thermal Conductivity of Metals, Heat Developed in Current Carrying Conductors, Thermoelectric Effect.

14

II

B1: Properties: Super Conductivity and Super Conducting Materials, Properties And Applications of Electrical Conducting And Insulating Materials, Mechanical Properties of Materials, Optical Properties of Solids. B2: Mechanism of Conduction in Semiconductor Materials: Current Carriers in Semiconductors, Drift and Diffusion Currents, Continuity Equation, Hall Effect. B3: Semiconductor devices: Miscellaneous Semiconductor Devices, Properties of Semiconductor Materials.

14

III

C1: Dielectrics: Polarization Mechanisms and Dielectric Constant, Behavior in Static and Alternating Fields, Dielectric Loss, Piezoelectricity and Ferro electricity. C2: Magnetic Material: Origin of Permanent Magnetic Dipoles in Matters, Classification Diamagnetism, Para magnetism, Ferromagnetism, Ant ferromagnetism and Ferrimagnetisms, Properties of Magnetic Materials, Soft and Hard Magnetic Materials, Permanent Magnetic Materials, Magnetostriction.

14

Text Books:

T. K. Basak, “Electrical Engineering Materials”, New age International.

References:

Solymar, “Electrical Properties of Materials” Oxford University Press. Ian P. Hones, ” Material Science for Electrical and Electronic Engineering”, Oxford University Press. TTTI Madras, “Electrical Engineering Materials”, TMH Education Pvt. Ltd.

Navneet Gupta, “Electrical & Electronic Engineering Materials”, Dhanpat Rai & Sons. A.J. Dekker, “Electrical Engineering Materials” Prentice Hall of India R.K. Rajput,” Electrical Engg. Materials,” Laxmi Publications. C.S. Indulkar & S.Thiruvengadam, “An Introduction to Electrical Engg. Materials”, S.Chand & Co.




31

EECCEE220077:: AANNAALLOOGG && DDIIGGIITTAALL EELLEECCTTRROONNIICCSS

Module No.

Content Teaching

Hours

I

Special Diodes- LED, Varactor Diode, Photo diode, Schottky Diode, their characteristics and applications. Combinational Logic Circuits: Adder, Subtractor, Code Converters, Multiplexers/Demultiplexers, Encoders/Decoders. Sequential Logic Circuits: latches, flip-flops- S-R, T, D, J-K.

12

II

Shift Registers: Basic principle, serial and parallel data transfer, shift left/right registers- Serial in Serial Out, Parallel in serial Out, Parallel in serial Out, Parallel in Parallel Out, Universal shift register. Counters: Mode N Counters, Ripple Counters, Synchronous Counters, Ring/Johnson Counters. Feedback: General Feedback Structure; Properties of Negative Feedback; Series-series, Series-shunt, Shunt-series and Shunt-shunt Feedback Amplifiers.

14

III

Oscillators:- Basic Principle of Sinusoidal Oscillator, R-C Phase Shift and Wein Bridge Oscillators, Tuned Oscillators- Colpitts and Hartley; Crystal Oscillator OP-AMP Applications - Astable, Monostable and Bistable Multi vibrators, Schmitt Trigger, IC-555 Timer, Application of IC 555 as Monostable and Astable Multi vibrator. A/D and D/A Converters- Weighted Resistors & R-2R D-A Converter, Flash Type, Single Ramp & Dual Ramp A-D Converters.

14

References:

A.S. Sedra and K.C. Smith “Microelectronics Circuits”4th Edition, Oxford University Press ( India). R.A. Gayakwad, “OP-AMP and Linear Integrated Circuits” Third edition, Prentice Hall of India. Millman, J. and Grabel A, “Microelectronics2nd edition”, Mc Graw Hill S. Salivahanan & S Arivazhagan, “Digital Circuits and Design”, 3rd Edition, Vikas Publishing House Pvt.

Ltd. New Delhi.





32

EECCEE220011:: EELLEECCTTRROOMMAAGGNNEETTIICC FFIIEELLDD TTHHEEOORRYY

Module No.

Content Teaching

Hours

I

Review of Vector Algebra Scalar & Vectors, Unit Vectors, Vector Addition & Subtraction, Position Vector, Vector Multiplications, Components of Vector. Coordinate System & Transformation Cartesian, Cylindrical and Spherical Coordinates & Their Transformation. Vector Calculus Line, Surface and Volume Integrals, Gradient of a Scalar, Divergence of a Vector, Curl of a Vector, Divergence Theorem , Stokes’s Theorem. Electrostatics-I Coulomb’s Law & Field Intensity, Electric Fields Due to Continuous Charge Distributions. Electric Flux Density, Gauss’s law, Electric potential.

13

II

Electrostatics-II Electric Dipole, Energy Density in Electrostatic Field, Conductors and Current, Polarization in dielectrics, Continuity Equation and Relaxation Time, Boundary Conditions, Poisson’s and Laplace’s Equation, Capacitance, Method of Images. Magneto statics Biot-savart’s law, Ampere’s Circuit law, Magnetic flux density, The scalar and vector magnetic potential, Maxwell’s Equations for Static Field, Forces due to Magnetic Field, Magnetic Torque and Moment, Magnetization in Materials, Magnetic Boundary Conditions, Inductance, Magnetic Energy.

14

III

Maxwell’s Equations Faraday’s law, Displacement Current, Maxwell’s Equations in Point and Integral Forms, Retarded Potential E M Wave Propagation Wave Propagation in Lossy Dielectrics, Plane Wave in Lossless Dielectrics, Plane Wave in Free Space, Plane Wave in Good Conductors, Power and the Poynting Vector, Reflection of a Plane Wave at Normal and Oblique Incidence, Wave Polarization. Transmission Lines Transmission Line Parameters, Transmission Line Equation, Lossless and Low Loss Propagation, Wave Reflection and VSWR, Transmission Line of Finite Length,Reflection Coefficient, Standing Wave Ratio, Stub Matching, Smith Chart and Measurement of Inductance, Capacitance and Resistance With the Help of Smith Chart.

14

Text Book:

Jordan E.C. and Balmain K.G., “Electromagnetic wave and radiating Systems”, PHI Second edition. W.H. Hayt and J.A. Buck, “Electromagnetic Field Theory”, 7th TMH.

Reference Books:

M.N.O. Sadiku, “Elements of Electromagnetics”, 4th Ed, Oxford University Press Kraus, F “Electromagnetics” Tata McGraw Hill fifth edition. Ramo S, Whinnery T.R. and Vanduzer T, “Field and Waves in communication electronics” John Wiley

and sons third edition.





33

EEEEEE220011:: NNEETTWWOORRKK AANNAALLYYSSIISS && SSYYNNTTHHEESSIISS Credits: 04 Semester III L-T-P: 3-1-0

Module No.

Content Teaching

Hours

I

A1: Network Theorems (Applications to ac networks): Super-Position Theorem, Thevenin’s Theorem, Norton’s Theorem, Maximum Power Transfer Theorem, Millman’s Theorem, Compensation Theorem, Tellegen’s Theorem, Reciprocity Theorem. A2: Graph Theory: Graph of A Network, Concept of 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.

14

II

B1: Two Port Networks: Characterization of LTI Two Port Networks: ZY, ABCD and H Parameters, Reciprocity and Symmetry. Inter-Relationships Between The Parameters, Inter-Connections of Two Port Networks, Ladder and Lattice Networks. T & Π Representation. B2: Transient Analysis: RL, RC and RLC Circuits – Classical Approach. B3: Network Functions: Concept of Complex Frequency, Transform Impedances, Network Functions of One Port and Two Port Networks, Properties of Driving Point Immittance and Transfer Functions.

14

III

C1: Network Synthesis: Positive Real Function; Definition, Properties of LC, RC and RL Driving Point Functions, Synthesis of LC, RC and RL Driving Point Immittance, Functions Using Foster and Cauer First and Second Forms. C2: Filters: Image Parameters and Characteristics Impedance, Low Pass, Highpass, (Constant K Type) Filters, and Introduction To Active Filters.

14

Text Books:

D.Roy Choudhary, “Networks and Systems” 2nd Ed., New Age International (P) Ltd. Publishers.

References:

M.E. Van Valkenburg, “An Introduction to Modern Network Synthesis”, Wiley Eastern Ltd. Sudhakar, “Circuits & Networks: Analysis and Synthesis”, TMH Education Pvt. Ltd. K.S. Suresh Kumar, “Electric Circuits and Networks” Pearson Education. C.L Wadhwa, “Network Analysis and Synthesis (Including Linear System Analysis)” 3rd Ed., New Age

International Publishers. A.Chakrabarti, “Network Analysis & Synthesis”, Dhanpat Rai & Co.




34

EEEEEE228811:: NNEETTWWOORRKK LLAABB

Module

No. Content

Teaching Hours

I

Verification of Principle of Superposition with DC and AC Sources. Verification of Thevenin, Norton and Maximum Power Transfer

Theorems in ac Circuits. Verification of Tellegen’s Theorem for Two Networks of the Same

Topology. Determination of Transient Response of Current in RL and RC

Circuits with Step Voltage Input. Determination of Transient Response of Current in RLC Circuit

with Step Voltage Input for Under damped, Critically Damped and Over damped Cases.

Determination of Frequency Response of Current in RLC Circuit with Sinusoidal AC Input.

Determination of z and h Parameters (dc only) for a Network and Computation of Y and ABCD Parameters.

Determination of Driving Point and Transfer Functions of a Two Port Ladder Network and Verification with Theoretical Values.

Determination of Frequency Response of a Twin – T notch Filter. Determination of Attenuation Characteristics of a Low Pass / High

Pass Active Filters.

24





35

EECCEE228877:: AANNAALLOOGG && DDIIGGIITTAALL EELLEECCTTRROONNIICCSS LLAABB

Group A:

Module No.

Content Teaching

Hours

I

Group A: To Study Application of Zener Diode as a Voltage Regulator. To Study V-I Characteristic of JFET and MOSFET. Realization of BJT as a Buffer Amplifier. Realization of Multistage Amplifier Using BJT and Calculation of

Current Gain. Realization of JFET as Amplifier and Determine Various

Parameters. Realization of Tuned Amplifier and its Application as

Hartley/Colpitt Oscillator. Group B:

Realization of 4-bit Binary Decoder/ De-Multiplexer. Realization of 4-bit / 3-bit Multiplexer. Realization of Full-Adder & Full Sub-Tractor Using Logic Gates. Realization of Decimal to BCD Encoder Using IC 74147. Realization and Implementation of RS, JK, T and D flip-flop Using

Logic Gates. Realization and Implementation 4-bit Binary Ripple Counter

Using JK flip-flop. Realization and Implementation of Arithmetic Logic Unit.

24





36

EEEEEE228888:: SSIIMMUULLAATTIIOONN LLAABB--11

Module No.

Content Lab Hours

I

Software: PSPICE

To Determine Node Voltages and Branch Currents in a Resistive Network.

To obtain the venin’s Equivalent Circuit of a Resistive Network. To Obtain Transient Response of a Series R-L-C Circuit for Step

Voltage Input. To Obtain Transient Response of a Parallel R-L-C Circuit for

Step Current Input. To Obtain Transient Response of a Series R-L-C Circuit for

Alternating Square Voltage Waveform. To Obtain Frequency Response of a Series R-L-C Circuit for

Sinusoidal Voltage Input. To Determine Line and Load Currents in a Three Phase Delta

Circuit Connected to a 3-phase balanced ac Supply. To Plot Magnitude, Phase and Step Response of a Network

Function. To Determine Z,Y,G,H and Transmission Parameters of a Two

Part Network. To Obtain Transient Response of Output Voltage in a Single

Phase Half Wave Rectifier Circuit Using Capacitance Filter. To Obtain Output Characteristics of CE NPN Transistor. To Obtain Frequency Response of a R-C Coupled CE Amplifier. To Obtain Frequency Response of an op-Amp Integrator

Circuit. To Verify Truth Tables of NOT, AND or OR Gates Implemented

by NAND Gates by Plotting Their Digital Input and Output Signals.

24

References:

M.H. Rashid, “SPICE for Circuits and Electronics Using PSPICE” Prentice Hall of India, 2000. Paul W. Tuinenga, “SPICE: A guide to circuit Simulation and Analysis Using PSPICE”, Prentice Hall, 1992.





37

AAHHEE228811:: SSOOFFTT SSKKIILLLLSS--II

After Two Courses on Spoken English Namely Spoken English 1 & 2, This Course Focuses more on the use of English, Specifically in Business Situations. The Course is based on Diverse Range of Business Themes Which Help Students Visualize the Expectations from a Professional. Course Objective: Soft Skills-I Programme will ensure that the Students Gain Confidence and Belief in What They are Doing and Do Not Overly Doubt Themselves. Being Aware of Learning What They Need Both in and Out of the Classroom, They Will Acquire Clarity on what is expected from them.

Module No.

Content Lab Hours

I Who am I and why Am I Here, Change is The Only Constant, Learning to Learn, Technology know-how for a Fresher, Knowledge on Tools, Application Orientation, Career Management (Journey and options).

10

II Business Communication, Service Mindset, Customer Mindset, Myths about Business, Values in Business, Business Etiquette, Email Etiquette, Telephone Etiquette, Team Building, Role of a Manager.

10

III Attitude for Success, Role Models, Handling Peer Competition, Building Relationships, Branding Yourself.

10

References:

Cook, S. “The Effective Manager” (E-book). IT Governance Publishing. Lesikar, R. V., & Pettit J. B. “Business Communication: Theory and Application”. New Delhi: All India Traveller Book Seller. Bhatnagar, Nitin & Mamta Bhatnagar, “Effective Communication and Soft Skills: Strategies for Success”. New Delhi, Pearson (Dorling Kindersley, India Ltd.). Mohan, Krishan & NP Singh, Speaking English Effectively, New Delhi: Macmillan Publishers India Ltd. Pillalamarri, J. K. “Management of Soft Skills” Chennai: SciTech Publications. Rao, M.S. & Ramana, P.S.V., “Soft Skills for Better Employability”. ICFAI University Press.





38

AAHHMM220011:: MMAATTHHEEMMAATTIICCSS IIIIII

Module No.

Content Teaching

Hours

I

Solution Of Cubic and Biquadratic Equations :Cardon’s Method of solving Cubic equations, Descartes’ and Ferrari’s method of solving Biquadratic equations. Fourier Series: Fourier series of Period 2_ , Even and Odd functions, Fourier series for discontinuous functions, Half range sine and cosine series, Change of interval.

13

II

Fourier transform: Fourier sine and cosine integrals, Complex Fourier transform, Fourier sine and cosine transforms, Applications to heat conduction equations. Z- Transform: Properties of Z – transform, Inverse Z – transform, Partial fractional and Residue method, applications of Z –transform in solving difference equations.

13

III

Functions of a complex variable: Analytic functions, Cauchy - Reimann equations , Harmonic function, Milne’s Thomson method, Cauchy integral theorem, Taylor’s, Maclaurin’s and Laurent’s series ( withoutproof ), Zeros and Singularities, Residue, Cauchy Residue theorem, Contour integration involving unit circle.

14

References:

E. Kreyszig, “Advanced Engg. Mathematics”, John Wiley & Sons, 9th edition. Bali &Goyal, “A Text Book of Engg. Mathematics”, Infinity Science Press. Peter V.O’Neil, “Advanced Engg. Mathematics”, Thomson Learning. M.D.Greenberg, “Advanced Engineering Mathematics”, Pearson Education Inc. Allen Jeffrey, “Advanced Engineering Mathematics”, Academic Press. B.V.Ramanna, “Higher Engg. Mathematics”, TMH New Delhi.

Credits: 04 L–T–P: 3–1–0 Semester IV




39

CCSSEE220011:: DDAATTAA SSTTRRUUCCTTUURREESS UUSSIINNGG ‘‘CC’’

Module No.

Content Teaching

Hours

I

Introduction: Basic Terminology, Elementary Data Organization, Algorithm, Efficiency of an Algorithm, Time and Space Complexity, Asymptotic notations: Big-Oh, operations on data structure, Abstract Data Types (ADT) Stacks: Abstract Data Type, Primitive Stack operations: Push & Pop, Array and Linked Implementation of Stack in C, Application of stack: Prefix and Postfix Expressions, Evaluation of postfix expression, Recursion, Tower of Hanoi Problem, Simulating Recursion, Principles of recursion, Tail recursion, Removal of recursion. Queues: Operations on Queue: Create, Add, Delete, Full and Empty, implementation of queue using array and linked list, Circular queues, Dequeue and Priority Queue, application of queue. Linked lists: Array Implementation and Dynamic Implementation of Singly Linked Lists, Doubly Linked List, Circularly Linked List, Operations on a Linked List. Insertion, Deletion, Traversal, Polynomial Representation and Addition, Generalized Linked List, heterogeneous linked list versus homogeneous linked list.

9

II

Trees: Basic terminology, Binary Trees, Binary Tree Representation: Array Representation and Dynamic Representation, Complete Binary Tree, Algebraic Expressions, Extended Binary Trees, Array and Linked Representation of Binary trees, Tree Traversal algorithms: In order, Preorder and Post order, Threaded Binary trees, Traversing Threaded Binary trees, Huffman algorithm. Graphs: Terminology, Sequential and linked Representations of Graphs: Adjacency Matrices, Adjacency List, Adjacency Multi list, Graph Traversal : Depth First Search and Breadth First Search, Connected Component, Spanning Trees, Minimum Cost Spanning Trees: Primes and Kruskal algorithm. Transitive Closure and Shortest Path algorithm: Warshal Algorithm and Dijikstra Algorithm, Introduction to Activity Networks.

9

III

Search Trees: Binary Search Trees(BST), Insertion and Deletion in BST, Complexity of Search Algorithm, AVL trees, Introduction to m-way Search Trees, B Trees & B+ Trees. Searching: Sequential search, Binary Search, Comparison and Analysis. Sorting: Insertion Sort, Selection, Bubble Sort, Quick Sort, Two Way Merge Sort, and Radix Sort. Heap & Heap Sort & their Time Complexity.

8

References:

Aaron M. Tenenbaum, Yedidyah Langsam and Moshe J. Augenstein , Data Structures Using C and C++, PHI, 2nd Edition, Feb 1996.

Horowitz and Sahani , Fundamentals of Data Structures, W H Freeman & Co, 2004-05. Jean Paul Trembley and Paul G. Sorenson , An Introduction to Data Structures with applications,

TMH, 2nd Edition ,2007. R. Kruse, Data Structures and Program Design in C, Pearson Education, 2nd Edition , 2004. Lipschutz Schaum’s Outline Series, Data Structures, TMH, 12th Reprint, 2006. G A V Pai , Data Structures and Algorithms, TMH ,2009.





40

CCEEEE220011:: EENNVVIIRROONNMMEENNTTAALL SSTTUUDDIIEESS

Module No.

Content Teaching

Hours

I

Basics Of Environmental Studies: Environmental Studies: Introduction, Scope and Importance Environment: Concept, Natural and Anthropogenic Environment Natural Environment: Structure & Function of Atmosphere, Hydrosphere, Lithosphere and Biosphere Ecology and Ecosystem: Definitions Types, Structure & Functions of Ecosystem.

7

II

Natural Resources: Natural Resources: Introduction, Classification, Concept of Conservation Present Status and Major Issues Related to Water Resources, Forest Resources and Mineral Resources Energy Resources: Introduction, Classification, Energy Use Patterns, Energy Crisis, Alternative Energy Resources Present Status and Major Issues Related to Fossil Fuels, Hydroelectricity, Nuclear Energy, Solar Energy and Biomass Energy.

6

III

Current Environmental Problems: Effects of Human Activities on Environment: Effect of Agriculture, Housing, Mining, Transportation and Industries Environment Pollution: Causes, Effects and Control of Air Pollution, Water Pollution, Land Pollution and Noise Pollution Introduction and Management of Solid Wastes and Hazardous Wastes Global Environmental Challenges: Global Warming, Ozone Layer Depletion, Acid Rain, Urbanization, Overpopulation and Biodiversity Depletion.

7

IV

Environmental Protection: Environmental Protection: Role of Citizens, Role of Government, Initiatives by NGOs, Contribution of International Agencies and Conventions Approaches to Environmental Protection: Public Awareness, Environmental Education, Environmental Ethics, Environmental Laws and Environmental Economics Tools and Strategies: Environmental Impact Assessment, Life Cycle Assessment, Ecological Footprints and Sustainable Development Efforts towards Environmental Protection in India.

6

References:

Benny Joseph, Environmental Studies. Deswal&Deshwal, Textbook on Environmental Studies. AK De, Environmental Studies. Shashi K Singh and AnishaSingh, Environmental Science & Ecology. AgarwalandSangal, Environment & Ecology.





41

EEEEEE220033:: BBAASSIICC SSYYSSTTEEMM AANNAALLYYSSIISS

Credits: 04 Semester IV L-T-P: 3-1-0

Module No.

Content Teaching

Hours

I

Introduction to signals and systems: Classification of Signals, Transformations of Independent Variables(Time), Singularity Functions: Unit Step, Unit Ramp and Unit Impulse Function, Even And Odd Signals ,Periodic and Aperiodic Signals, Real Exponential Signals, Complex Exponential Signals, Energy and Power Signals, Basic systems: Causal and Non Causal, Linear & Nonlinear, Time Varying and Time Invariant, System With & Without Memory, Convolution Integral.

14

II

Fourier and Laplace Transform Analysis: Review of Fourier & Laplace Transforms, Transform of Basic Signals and Periodic and Complex Waveforms, Initial and Final Value Theorems, Inverse Laplace Transform , Application of Fourier and Laplace Transform To Analysis of Networks, Z-Transform Analysis: Concept of Z-Transform, ROC, Properties of Z-Transform, Inverse Z Transform, Initial and Final Value Theorems, Applications To Solution of Difference Equations.

14

III

Analogous System: Linear Mechanical Elements, Force-Voltage and Force-Current Analogy, Modeling of Mechanical and Electro-Mechanical Systems. State – Variable analysis: Introduction, State Space Representation of Linear Systems, Transfer Function and State Variables, State Transition Matrix, Solution of State Equations For Homogeneous and Non-Homogeneous Systems, Applications of State-Variable Technique To The Analysis of Linear Systems.

14

Text Books:

Choudhary D.Roy, “Networks & Systems”, 2nd Ed., New Age International Publishers. I.J. Nagrath, S.N. Saran, R. Ranjan and S.Kumar, “Singnals and Systems”, Tata Mc. Graw Hill.

References:

C.L.Wadhwa, “Network Analysis and Synthesis”, 3rd Ed., New Age International Publishers. Smarjit Ghosh, “Network Theory: Analysis and Synthesis” PHI Learning Pvt. Ltd. ME Van-Valkenburg, “Network Analysis”, 3rd Ed., PHI Learning Pvt. Ltd. B.P. Lathi, “Linear Systems & Signals” Oxford University Press. David K.Cheng; “Analysis of Linear System”, Narosa Publishing Co. Taan S. Elali & Mohd. A. Karim, “Continuous Signals and Systems with MATLAB” 2nd Edition, CRC

Press.




42

EEEEEE220044:: EELLEECCTTRRIICCAALL MMEEAASSUURREEMMEENNTTSS && MMEEAASSUURRIINNGG IINNSSTTRRUUMMEENNTTSS


Module No.

Content Teaching

Hours

I

Philosophy of Measurement: Methods of Measurement, Measurement System, Classification of Instrument System, Characteristics of Instruments & Measurement System, Errors in Measurement & Its Analysis, Standards. Analog Measurement of Electrical Quantities: Electrodynamics, Thermocouple, Electrostatic & Rectifier Type Ammeters, Voltmeters and Watt meters. Watt meters and Energy meter: Errors & remedies in Electrodynamics Wattmeter and Energy Meter.

14

II

Instrument Transformers: Instrument Transformers and Applications in the Extension of Instrument Range, Ratio and Phase Angle Errors, Testing. Measurement of Circuit Parameters: Different Methods of Measuring Low, Medium and High Resistances, Measurement of Inductance & Capacitance With The Help of AC Bridges,. B3: Potentiometer: Crompton Type DC Potentiometer, Polar Type & Co-Ordinate Type AC Potentiometers and Their Applications. Special Meters: Measurement of Speed, Frequency, Power Factor and Q

14

III

Magnetic Measurement: Ballistic Galvanometer, Flux Meter, Determination of Hysteresis Loop, Determination of Iron Losses. Digital Measurement: (1) Concept of Digital Measurement, Block Diagram Study of Digital Voltmeter, Frequency Meter Power Analyzer and Harmonics Analyzer; Digital Multi meter. Cathode Ray Oscilloscope: Basic CRO Circuit (Block Diagram), Cathode Ray Tube (CRT) & Its Components, Application of CRO in Measurement, Lissajous Pattern; Dual Trace, Dual Beam and Storage Oscilloscopes.

14

Text Book:

G.K. Banerjee, Electrical Measurement & Measuring Instruments, New Age International.

A.K. Sawhney, “A Course in Electrical & Electronic Measurements & Instrumentation”, Dhanpat Rai &

Sons India.

References:

Forest K. Harris, “Electrical Measurement”, Willey Eastern Pvt. Ltd. India. M.B. Stout, “Basic Electrical Measurement” Prentice hall of India, India. Helfrick and Cooper, “Modern Electronic Instrumentation & Measurement Techniques”, PHI

Learning. Rajendra Prashad, “Electrical Measurement &Measuring Instrument”, Khanna Publisher. J.B. Gupta, “Electrical Measurements and Measuring Instruments”, S.K. Kataria & Sons. MMS Anand, “Electronic Instruments and Instrumentation Technology”, PHI Learning.




43

EEEEEE220055:: EELLEECCTTRRIICCAALL MMAACCHHIINNEE II


Module No.

Content Teaching

Hours

I

Single phase Transformers: Brief Review of Single Phase Transformer, Polarity Test, Sumpner’s Test, Single Phase and 3-Phase Autotransformers. 3 Phase Transformer: Phasor Groups, Parallel Operation of Single and 3-Phase Transformers, Zig Zag Connections, 3-Phase To 2-Phase and 6-Phase Conversions, Harmonics and Excitation Phenomena in 3-Phase Transformers-Effect of Connections and Construction on Harmonics. Special purpose Transformers: Earthing Transformer, Pulse transformer, High frequency Transformer.

14

II

Energy Conversion Principle: Magnetic Field Energy and Co-Energy, Coupling-Field Reaction For Energy Conversion, Mechanical Work, Mechanical Forces and Torques in Singly and Doubly-Excited Systems. Concepts of Reluctance and Electromagnetic Torques. Singly Excited Electric –Field Systems. General concepts of Rotating Electrical Machines: Magnetic and Electric Circuits in Rotating Electrical Machines, Winding Coefficients, MMF of Distributed Windings. Torque in Terms of Flux and MMF in Wound-Rotor Machines.

14

III

DC Machines: Concept of Simplex Lap and Wave Windings. Action of Commutator, Methods of Excitation. Armature Reaction-Effects and Remedial Measures, Interpoles and Compensating Winding, Commutation Process: Causes of Bad Commutation, Method of Improving Commutation, Operating Characteristics. Starters, Speed Control, Losses, Efficiency and Testing Of D.C. Machines (Hopkinson’s And Swinburn’s Test).

14

Text Book:

I. J. Nagrath & D.P. Kothari, "Electric Machines” Tata McGraw Hill. Ashfaq Hussain, “Electric Machines”, Dhanpatrai & Sons

References:

Irving L. Koscow, “Electric Machine and Transformers”, Prentice Hall of India. M.G. Say, “The Performance and Design of AC machines”, Pit man & Sons. Bhag S. Guru and Huseyin R. Hizirogulu, “Electric Machinery and Transformers” Oxford University

Press. B.R. Gupta & Vandana Singhal, “Fundamentals of Electric Machines”, 3rd Ed., New Age International. A.E. Fitzgerald, C.Kingsley JR and Umans, ”Electric Machinery” 6th Edition, Tata McGraw Hill,

International Student Edition. Bhimbra, P.S, “Electric Machines”, Khanna Publishers.




44

EEEEEE228844:: MMEEAASSUURREEMMEENNTT LLAABB

Module No.

Content Teaching

Hours

I

Measurement of form factor of a rectified sine wave and determine source of error if R.M.S. Value is measured by a multi-meter.

Measurement of phase difference and frequency of a sinusoidal ac voltage using

C.R.O. Measurement of power and power factor of a single phase inductive

load and to Study effect of capacitance connected across the load on the power

factor. Measurement of low resistance by Kelvin’s double bridge. Measurement of inductance by Maxwell’s bridge. Measurement of inductance by Hay’s bridge. Measurement of inductance by Anderson’s bridge. Measurement of capacitance by Owen’s bridge. Measurement of capacitance by De Sauty Bridge. Measurement of capacitance by Schering Bridge.

24





45

EEEEEE228855:: EELLEECCTTRRIICCAALL MMAACCHHIINNEE LLAABB--II

Module

No. Content

Teaching Hours

I

To obtain magnetization characteristics of a D.C. shunt generator. To obtain load characteristics of a compound generator (a)

cumulatively compounded (b) differentially compounded. To obtain load characteristics of a D.C. shunt generator To obtain efficiency of a dc shunt machine using Swinburn’s test. To perform Hopkinson’s test and determine losses and efficiency of

DC machine. To obtain speed-torque characteristics of a dc shunt motor. To obtain speed control of dc shunt motor using (a) armature

resistance control (b) field control To study Ward Leonard method of speed control of dc motor. To perform polarity and ratio test of single phase transformer. To perform open circuit and short circuit test in single phase

transformer and find efficiency and voltage regulation. To obtain efficiency and voltage regulation of a single phase

transformer by Sumpner’s test. To perform polarity and ratio test on 3-phase transformer. To study various connections of 3-pahse transformers. To study Scott connection of transformers.

24





46

EEEEEE228899:: SSIIMMUULLAATTIIOONN LLAABB--IIII

Module

No. Content

Teaching Hours

I

MATLAB Based Experiments Solution of linear equations for under determined and over

determined cases. Determination of Eigen values and eigenvectors of a square matrix. Determination roots of a polynomial. Determination of polynomial using method of least square curve

fitting. Determination of polynomial fit, analyzing residuals, exponential fit

and error Bounds from the given data. Solution of differential equations using 4th order Runge-Kutta

method. Solution of differential equation using revised Euler method. Determination of time response of an R-L-C circuit. Solution of difference equation. Introduction to 3D plot.

24

Reference Books:

Almos Gilat, “MATLAB: An Introduction with Applications” Wiley India Ltd., 2004.





47

CCSSEE228811:: DDAATTAA SSTTRRUUCCTTUURREESS && AALLGGOORRIITTHHMMSS LLAABB

Module No.

Content Lab Hours

I

Program to demonstrate the various operations on Array based stack. Program to convert an infix expression into postfix expression. Program to evaluate a given postfix expression. Program to generate Fibonacci series using Recursion. Program to demonstrate the implementation of various operations on

linear Queue represented using an Array. Program to implement various operations in a Singly Linked List. Program to implement insertion, deletion and Traversal in a doubly

linked List. Program to implement polynomial addition using Linked List. Program to demonstrate the implementation of insertion and

traversals on a binary search tree. Program to implement Dijkstra’s Algorithm to find the shortest path

between source and destination. Program to search a given element as entered by the user using

Sequential Search. Program to demonstrate the use of binary search to search a given

element as entered by the user. Implementation of various sorting algorithms like Bubble Sort,

Insertion Sort, Selection Sort, Merge Sort, Quick Sort and Heap Sort.

24





48

AAHHEE228822:: SSOOFFTT SSKKIILLLLSS--IIII

Objectives:

To make the students aware of the primary skills and sub skills involved in using English effectively at the contemporary corporate workplace with a global presence.

To provide practice and guidance to enhance skills to the proficiency level expected by any organization.

Module No.

Content Lab Hours

I

Introduction to English and Grammar. Speaking face to face vs. over the phone. Auxiliary and Modal verbs. 4 Techniques of reading- Skim, Scan, Intensive, Extensive. ABC of writing, The KISS concept. Presenting ideas, information and opinions with clarity. Listening for information and making inferences. Intonation, Word stress, Pacing, Sound clarity.

10

II

Second level of reading to interpret information Subject Verb Agreement Understanding ideas and making inferences Indianism, Question Tags, Phrasal verbs Prepositions, Active and Passive voice Third level reading and data interpretation Sentence stress, connected speech Tenses

10

III

Adverbs, Adjectives, Modifiers, Collocation Discussing data and coming to conclusions Link expressions, Compound nouns Negotiation skills Business quiz, idioms and phrases Individual presentation on speaking and writing Feedback and Poster creation

10

References:

Hornby, A.S., An Advanced Learners’ Dictionary of Current English, OUP. Murphy, Raymond, Intermediate English Grammar, Cambridge University Press. Rizvi, Ashraf, M. Effective Technical Communication. New Delhi: Tata McGraw Hill. Infosys modules on English lab. PPT slides & videos provided by Infosys.

Material:

Audio-Video Material available in the Language Lab.





49

AAHHSS330011:: IINNDDUUSSTTRRIIAALL PPSSYYCCHHOOLLOOGGYY

Preamble: Industrial Psychology is concerned with the study of workplace behavior. It is a scientific discipline and an area of professional practice. As a scientific discipline, Industrial Psychology critically examines workplace behavior and experience with a goal to understand what influences people's behavior on the job, and what consequences their job behavior has for others around them and for the organizations in which they work. Thus, study of Industrial Psychology provides us a comprehensive insight for understanding the relationship between proper application of Industrial Psychology principles and individual, team, and organizational performance and basic assumptions about Human nature. Objectives of the Course: The course aims at giving an introduction to the workplace Psychology and the factors that affect it. This will help the students to manage their teams efficiently and effectively that in turn results into increased organizational effectiveness.

Module No.

Content Teaching

Hours

I

Introduction to Industrial Psychology: Definition, Brief History, Applications, Taylor’s Scientific Management Principles. Time and Motion Study, Human Relations Approach - Hawthorne Experiments.

07

II

Individual at Work Place: Definition & Theories of Motivation, Job Satisfaction. Stress: Concept, Sources, Consequences and Management. Organizational Culture: Concept, Nature, Elements and Types.

07

III

Leadership & Group Dynamics: Definition, Types of Leaders, Styles of Leadership & Theories of Group Formation. Recruitment and Selection: Methods of Recruitment, Steps in Selections Procedure. Performance Appraisal: Meaning & Traditional Methods of Appraisal. Training and Development: Concept & Methods of Training.

07

Text Book:

Michael G. Aamodt, Industrial/Organizational Psychology, Wadsworth, Cengage Learning, 2001. Reference Books:

M.L. Blum, and J.C. Naylor, Industrial Psychology, CBS Publishers & Distributors, 1984. Ronald Riggio, Introduction to Industrial/Organizational Psychology, Pearson Education, International Edition 5th Edition, Oct 2008.

Semester V/VI L–T–P: 2–0–0 Credits: 02




50

AAHHEE330011:: TTEECCHHNNIICCAALL WWRRIITTIINNGG

The syllabus aims to develop the writing skills of students in order to equip them with techniques of writing messages formally. The learners will be trained to use various modes of written communication generally used to disseminate information within and outside an organization.

Module No.

Content Teaching

Hours

I

Vocabulary: One Word Substitutions, Idioms & Phrases, Synonyms & Antonyms.

Correspondence Related to Meetings: Agenda & Minutes of A Meeting. Summarizing: Précis Writing. Technical Reports: Objectives, Characteristics & Significance, Types,

Structure & Format, Writing of Report.

18

II

Business Letters: Principles, Important Features & Structure. Types - Inquiry Letters, Quotation & Placing Orders, Claim & Complaint Letters, Sales & Credit Letters.

Official Correspondence: Memos, Circular Letters, E-Mail, D.O. Letters. Correspondence Related to Recruitment: Job Application &

Resume/Bio-Data.

15

III

Technical Proposal: Objectives, Characteristics & Significance; Types, Structure & Writing of Proposals.

Study Skills: Note Making & Note Taking. Technical Articles: Nature, Significance and Essentials, Journal Articles/

Research Papers.

12

Reference Books:

Rizvi, Ashraf. Effective Technical Communication, New Delhi: Tata McGraw Hill. Raman, Meenakshi; Sangeeta Sharma, Technical Communication: Principles and Practice, New Delhi,

Oxford University Press.

L–T–P: 2–1–0 Credits: 03 Semester V/VI




51

EEEEEE 330011:: EELLEECCTTRRIICCAALL MMAACCHHIINNEE--IIII

Credits: 04 Semester V L-T-P: 3-1-0

Module No.

Content Teaching

Hours

I

Synchronous Machine-I: Constructional Features, EMF Equation, Winding

Coefficients, Equivalent Circuit and Phasor Diagram, Armature Reaction, OC &

SC Tests, Voltage Regulation Using Synchronous Impedance Method, MMF

Method, New ASA Method, Parallel Operation of Synchronous Generators,

Operation on Infinite Bus, Synchronizing Power and Torque Coefficient.

Two Reaction Theory, Power Flow Equations of Cylindrical and Salient Pole Machines, Operating Characteristics.

14

II

Synchronous Machine-II: Starting Methods, Effect of Varying Field Current At Different Loads, V-Curves, Hunting & Use of Damper Winding, Synchronous Condenser – Application and Comparison With Ordinary Synchronous Machine. Three phase Induction Machine-I: Constructional Features, Rotating Magnetic Field, Principle of Operation Phasor Diagram, Equivalent Circuit, Torque and Power Equations, Torque-Slip Characteristics, No Load & Blocked Rotor Tests, Efficiency, Induction Generator & Its Applications.

14

III

Three Phase Induction Machine-II: Starting Deep Bar and Double Cage Rotors, Cogging & Crawling, Speed Control (With And Without EMF Injection in Rotor Circuit). Single Phase Induction Motor: Double Revolving Field Theory, Equivalent Circuit, No Load and Blocked Rotor Tests, Starting Methods, Repulsion Motor, Reluctance Motor. AC Commutator Motors: Universal Motor, Single Phase A.C. Series Compensated Motor, Stepper Motors.

14

Text Books:

D.P. Kothari & I.J. Nagrath, “Electric Machines”, Tata McGraw Hill. References:

P.S. Bhimbra, “Electrical Machinery”, Khanna Publisher. P.S. Bhimbra, “Generalized Theory of Electrical Machines”, Khanna Publishers. M.G. Say, “Alternating Current Machines”, Pitman & Sons. Fitzerald, A.E., Kingsley and S.D. Umans, “Electric Machinery”, McGraw Hill.




52

EEEEEE330022:: PPOOWWEERR EELLEECCTTRROONNIICCSS

Credits: 04 Semester V L-T-P: 3-1-0

Module No.

Content Teaching

Hours

I

Thyristor: Construction, Operation V-I, Switching (Turn-On And Turn-Off) and Gate Characteristics, Two Transistor Model, Methods of Turn-On, Operation of GTO, DIAC, TRIAC, Firing Circuits for SCR (R, RC Half Wave and RC Full Wave and UJT Triggering Circuits), Protection of Devices, Series and Parallel Operation of Thyristors. Commutation: Commutation Techniques of Thyristor.

12

II

Phase Controlled Converters: Single Phase Half Wave Controlled Rectifier With Resistive and Induction Loads, Effects of Freewheeling Diode, Single Phase Fully Controlled and Half Controlled Bridge Converters, Performance Parameters, Three Phase Half Wave Converters, Three Phase Fully Controlled and Half Controlled Bridge Converters, Effect of Source Impedance, Single Phase and Three Phase Dual Converters. Inverters: Introduction (VSI And CSI), VSI-Single Phase Half and Full Bridge Inverters for R, RL And RLC Loads, Three Phase Bridge Inverters 180° and 120° Mode Operations, CSI-Single Phase Series Resonant and Parallel Inverters, Voltage Control of Inverters, Harmonic Reduction Techniques.

15

III

DC-DC Converters: Principle of Step-Down Chopper, Step Down Chopper With R-L Load, Principle of Step-Up Chopper and Operation With RL Loads and Classification of Choppers and Multiphase Choppers. Chcloconverters: Basic Principle of Operation, Single Phase to Single Phase, Three Phase to Single Phase and Three Phase to Three Phase Cycloconverters, Output Voltage Equation. AC Voltage Controllers: Introduction, Single Phase Ac Voltage Controller With Resistive and Inductive Loads, Three Phase Ac Voltage Controllers (Various Configurations And Comparison Only).

15

Text Books:

M.H.Rashid, Power, “Electronics: Circuits, Devices & Applications”, Prentice Hall of India Ltd. P.S. Bhimbra, “Power Electronics”, Khanna Publishers.

References:

M.S. Jamil Asghar, “Power Electronics”, Prentice Hall of India Ltd.

Chakrabarti & Rai, “Fundamentals of Power Electronics & Drives”, Dhanpat Rai & Sons.

Ned Mohan, T.M.Undeland and W.P.Robbins, “Power Electronics: Converters, Applications and Design”,

Wiley India Ltd.

S. N. Singh, “A Text Book of Power Electronics”, Dhanpat Rai & Sons.

M.D. Singh & K.B.Khanchandani, “Power Electronics”, TMH.

V.R. Moorthy, “Power Electronics: Devices, Circuits, Industrial Applications”, Oxford Univ. Press.




53

EEEEEE330033:: PPOOWWEERR SSYYSSTTEEMM--II

Credits: 04 Semester V L-T-P: 3-1-0 Module

No. Content

Teaching Hours

I

Introduction: Structure of Power Systems, Growth of Power Systems-Indian Overview, Interconnections and Their Advantages Transmission Lines: Choice of Voltage and Frequency, Types of Conductors and Their Sizes, Kelvin’s Law, Bundled Conductors, Electrical Parameters of Transmission Lines-Resistance, Inductance and Capacitance, GMR and GMD, Calculation of Inductance & Capacitance of 1-Phase , 3- Phase Single Circuit & Double Circuit Lines, Skin Effect, Proximity Effect Transmission Line Performance: Characteristics and Performance of Power Transmission Lines-Short; Medium; Long Lines, Generalized Constants, Power Flow, Regulation, Ferranti Effect, Surge Impedance & Surge Impedance Loading.

15

II

Mechanical Design of Overhead Transmission Lines: Tension and Sag Calculations, Effect of Weather Conditions, Sag Template, Stringing Charts, Vibration Damper. Insulators: Insulator Types, String Efficiency & Methods to Improve String Efficiency (Capacitance Grading, Guard Ring) Corona and Interference With Communication Lines: Corona Visual and Disruptive, Critical Voltage, Corona Loss, Factors Affecting Corona, Methods of Reducing Corona, Electrostatic and Electromagnetic Interference With Communication Lines.

12

III

Insulated Cables: Constructional Features, Parameters, Cable Laying Procedures, Fault Location Methods, High Voltage Cables, Thermal Characteristics, Comparison of Rating of Single Core and Multi Core Cables; Distribution Systems: Primary and Secondary Distribution, Ring Main and Radial Systems, Systematic Design of Distribution Systems. EHV Transmission And HVDC Transmission: An Introduction to HVDC & E-HVAC Systems, Configurations & Comparison Indian Electricity Rules: Introduction and Familiarization.

13

Text Books:

C. L. Wadhwa, “Electrical Power Systems”, New age international Ltd.

References:

John J. Grainger & W. D. Stevenson, “Power System Analysis”, McGraw Hill. I.J. Nagrath and D.P. Kothari, “Modern Power System Analysis”, Tata McGraw Hill. O.I. Elgerd, “Electric Energy Systems Theory: An Introduction”, Tata McGraw Hill. J. Duncan Glover, “Power system analysis & design”, Cengage Learning. Ashfaq Hussain, “Power System”, CBS Publishers and Distributors. D.P. Kothari and I.J. Nagrath, “Power System Engineering”, TMH. B. R. Gupta, “Power System Analysis and Design”, S. Chand & Co.




54

EECCEE220066:: MMIICCRROOPPRROOCCEESSSSOORRSS AANNDD AAPPPPLLIICCAATTIIOONNSS

Module No.

Content Teaching

Hours

I

Microprocessor and Microprocessor Development Systems: Evolution of Microprocessor, Microprocessor architecture and its operations, memory, inputs-outputs (I/Os), data transfer schemes interfacing devices, architecture advancements of microprocessors, typical microprocessor development system. 8-bit Microprocessors 8085 microprocessor: pin configuration, internal architecture. Timing & Signals: control and status, interrupt: ALU, machine cycles, Instruction Set of 8085, Addressing Modes, Instruction format, op-codes, mnemonics, no. of bytes, RTL, variants, no. of machine cycles and T states Instruction Classification: Data transfer, arithmetic operations, logical operations, branching operation, machine control; Writing assembly Language programs, Assembler directives.

13

II

16-bit Microprocessors 8086 microprocessor: pin configuration, internal architecture. Timing & Signals: control and status, interrupt: ALU, machine cycles, Instruction Set of 8086, Addressing Modes, Instruction format, op-codes, mnemonics, no. of bytes, RTL, variants, no. of machine cycles and T states Interrupts: Hardware and software interrupts, responses and types.

13

III

Peripheral Interfacing: I/O programming: Programmed I/O, Interrupt Driven I/O, DMA I/O interface: serial and parallel communication, memory I/O mapped I/Os. Peripheral Devices: 8237 DMA controller, 8255- Programmable peripheral interface, 8253/8254 Programmable timer/counter. 8259 programmable Interrupt Controller, 8279-keyboard display controller, ADC/DAC interfacing. Introduction to Advanced Microprocessors and Microcontrollers.

13

Text Books:

Gaonkar, Ramesh S, “Microprocessor Architecture, programming and applications with the 8085” Pen ram International Publishing 5th Ed.

Ray, A.K. &Burchandi, K.M., “Advanced Microprocessors and Peripherals: Architecture, Programaming and Interfacing” Tata Mc. Graw Hill.

Reference Books:

Uffenbeck, John, “Microcomputers and Microprocessors” PHI/ 3rd Edition 5. Brey, Barry B. “INTEL Microprocessors” Prentice Hall ( India).

M. Rafiquzzaman, “Microprocessors- Theory and applications” PHI. B. Ram, “Advanced Microprocessor & Interfacing” Tata McGraw Hill. Renu Singh & B.P. Singh, “Microprocessor and Interfacing and applications” New Age International. Hall D.V., “Microprocessors Interfacing” Tata McGraw Hill. Liu and Gibson G.A., “Microcomputer Systems: The 8086/8088 Family” Prentice Hall (India).

Credits: 04 L–T–P: 3–1–0 Semester V




55

EEEEEE338822:: PPOOWWEERR EELLEECCTTRROONNIICCSS LLAABB

Module No.

Content Teaching

Hours

I

List of Experiments To study V-I characteristics of SCR and measure latching and holding

currents. To study UJT trigger circuit for half wave and full wave control. To study single-phase half wave controlled rectified with (i) resistive

load (ii) inductive load with And without free-wheeling diode.

To study single phase (i) fully controlled (ii) half controlled bridge rectifiers with resistive and Inductive loads.

To study three-phase fully/half controlled bridge rectifier with resistive and inductive loads.

To study single-phase ac voltage regulator with resistive and inductive loads.

To study single phase cyclo-converter To study triggering of (i) IGBT (ii) MOSFET (iii) power transistor To study operation of IGBT/MOSFET chopper circuit To study MOSFET/IGBT based single-phase series-resonant inverter. To study MOSFET/IGBT based single-phase bridge inverter.

SOFTWARE BASED EXPERIMENTS (PSPICE/MATLAB) To obtain simulation of SCR and GTO thruster. To obtain simulation of Power Transistor and IGBT. To obtain

simulation of single phase fully Controlled bridge rectifier and draw load voltage and load current

waveform for inductive load. To obtain simulation of single phase full wave ac voltage controller

and draw load voltage and load current waveforms for inductive load. To obtain simulation of step down dc chopper with L-C output filter

for inductive load and determine steady-state values of output voltage ripples in output voltage and load current.

24

Semester V L–T–P: 0–0–2 Credits: 01




56

EECCEE228866:: MMIICCRROOPPRROOCCEESSSSOORRSS LLAABB

Module No.

Content Teaching

Hours

I

List of Experiments 8085/8086 Based Experiments

Recursive Routine for Finding Factorial N. Assembly Language Program for 8086. Assembly Language Programs for 8086 to address and data transfer. Assembly Language Programs for 8086 to addition, subtraction. Assembly Language Programs for 8086 to block transfer. Assembly Language Programs for 8086 to find greatest numbers. Look up table method for finding the ASCII of an alphanumeric code. Interfacing with 8255 in I/O mode/BSR mode to 8085/8086 based

system. Interfacing with 8253to 8085/8086 based system. To 8085/8086 based system verification of Interrupts. Interfacing with ADC/DAC to 8085/8086 based system. Serial communication between two kits through RS-232C using 8251. Signed Multiplication using Booth's Algorithm. To perform microprocessor based stepper motor operation through

8085 kit. Mini Project on some interfacing applications.

24

Credits: 01 L–T–P: 0–0–2 Semester V




57

EEEEEE338833:: PPOOWWEERR SSYYSSTTEEMM LLAABB –– II

Module No.

Content Teaching

Hours

I

List of Experiments Hardware based

To study Ferranti effect and voltage distribution in H.V. long transmission line using transmission line model.

To find the A B C D parameters for long transmission line and calculate the Voltage regulation and efficiency.

To locate the fault in a cable using Murray loop test. To Study the Over voltage relay & draw its operating characteristics .

Simulation Based Experiments Using MATLAB , plot the graph of i(t),v(t),p(t),P,Q over an interval of

0 to 2π for a system having v(t)=100 cos𝛚t and i(t)=80cos(𝛚t-600). To calculate the inductance of 3 phase double circuit bundled

conductor transmission line. To calculate the capacitance for horizontal and equilateral triangle

spaced configuration of transmission lines. To calculate the sag and tension in transmission lines. To model the transmission line using SIMULINK model and hence

calculate its ABCD parameters. To study the steady state performance of a given HVDC system using

SIMULINK model.

24

Semester V L–T–P: 0–0–2 Credits: 01




58

AAHHEE338811:: SSOOFFTT SSKKIILLLLSS--IIIIII

This course focuses on the use of English, specifically in industry situations. The course is based on diverse range of business themes which help students visualize the expectations from a professional. Course Objectives:

Gain a functional understanding of Basic English. Practice language skills to eliminate errors in pronunciation and sentence construction. Understand and enhance interpersonal communication process.

Module No.

Content Teaching

Hours

I

Business Communication Skills English Language Enhancement Verbs, Tenses, Phrasal Verbs, Synonyms, Antonyms and homonyms Descriptive Words, Combining Sentences, Business Idioms

10

II

Indianisms in English, Frequently Mispronounced Words, Signposts in English.

The Art of Communication: The communication Process, Effective Listening,

Non Verbal Communication.

10

III

Intrapersonal & Interpersonal Relationship Skills Self-Awareness, Self Esteem & Confidence, Assertiveness and

Confidence Dealing with Emotions, The Team Concept, Elements of Teamwork,

Stages of Team Formation, What is an Effective Team? Essential Building Blocks of Effective Teams, Team Player Styles

10

Reference Books:

Cook, S. The Effective Manager ( e-book). IT Governance Publishing Lesikar, R. V., & Pettit J. B..Business Communication: Theory and Application. New Delhi: All India

Traveller Book Seller. Bhatnagar, Nitin & Mamta Bhatnagar, Effective Communication and Soft Skills: Strategies for

Success. New Delhi, Pearson (Dorling Kindersley, India Ltd.) Mohan, Krishan & NP Singh, Speaking English Effectively, New Delhi: Macmillan Publishers India Ltd. Pillalamarri, J. K. Management of Soft Skills Chennai: Schitech Publications Rao, M.S. & Ramana, P.S.V., Soft Skills for Better Employability. ICFAI University Press.

L–T–P: 0–0–2 Credits: 01 Semester V




59

AAHHSS330022:: IINNDDUUSSTTRRIIAALL EECCOONNOOMMIICCSS

Preamble: The Course of Industrial Economics Aims to Familiarize Students with the Basic Concepts of Economics Used in the Analysis of Firms and Industries and Act as a Guiding Tool in Decision Making with the Availability of Limited Resources in the Organization. Objectives: 1. To Familiarize Students with the Basic Concepts of Economics. 2. To Enable the Students to Make Better Decisions in their Course of Action.

Module No.

Content Teaching

Hours

I

Basic Economic Concepts: Meaning, Nature and Scope of Economics, Methodology of Economics - Deductive vs. Inductive, Economics Statics & Dynamics, Basic Economic Problems - Scarcity & Choice, Relation among Science, Engineering, Technology and Economics. Market Demand: Demand, Meaning and Types, Law of Demand, Exceptions to the Law of Demand, Elasticity of Demand, Methods of Measuring Elasticity of Demand, Marginal Utility Analysis.

07

II

Demand Forecasting: Meaning, Significance and Methods, Production Function, Laws of Returns to Scale & Diminishing Returns to Scale. Cost Concepts: - Meaning and Types of Costs, Short Run and Long Run Cost Curves.

07

III

Market Structure: Meaning of Market, Types of Market - Perfect Competition, Monopoly, Oligopoly, Monopolistic Competition. Inflation and Business Cycles: Causes, Effects and Methods to Control Inflation, Concepts of Business Cycles, Concept of National Income and Measurement.

07

Reference Books:

Dewett, K.K.(2005).Modern Economic theory. New Delhi. S. Chand. Geetika, G.,Ghosh, Piyali., & Choudhray,Purba.(2008).Managerial Economics.TMH. Dwivedi, D, N. (2005).Managerial Economics. New Delhi: Vikas Publishing House. Peterson, Craig, H. Lewis, Cris, W. & Jain, Sudhir, K. (2008).Managerial Economics. New Delhi: Pearson

Education.





60

AAHHSS330033:: PPRRIINNCCIIPPLLEESS OOFF MMAANNAAGGEEMMEENNTT

Preamble: Massive industrialization and rapid changes in business environment in the recent past has created a demand for professionally trained managers with more challenging and demanding roles to be played. Thus an understanding of management principles and practices is extremely required to cope with the dynamic need of present complex business environment which requires high degree of creativeness and innovativeness. Objectives of the Course: The course aims at giving an introduction of the basic concepts, principles and practices of management to the students. A comprehensive understanding of these principles will increase their decision making ability and sharpen their tools for the purpose. This course will help the students to become more sensible and responsive to the needs of changing environment.

Module No.

Content Teaching

Hours

I Management: Concept & Nature, Management as a Science and Art, Role of Management Principles; Fayol’s Principles of Management, Management Functions & Skills.

06

II

Planning: Steps and Types of Planning. Missions and Objectives: Formulation of Mission and Objective Setting. Organizing: Concept of Organization, Concept of Organization Structure, Concept of Authority and Responsibility, Essentials for Effective Coordination.

07

III

Staffing: Concept of Staffing, Factors Affecting Staffing. Directing: Concept and Principles of Direction; Concept of Motivation and Leadership. Communication: Concept and Process. Controlling: Concept of Controlling, Steps in Controlling and Types of Control.

07

Text Book:

L.M. Prasad – Principles & Practices of Management (Sultanchand & Sons, New Delhi). Reference Books:

Koontz – Principles of Management (Tata McGrew Hill, 1stEdition 2008). Robbins & Caulter – Management (Prentice Hall of India, 8thEdition). Parag Diwan – Management Principles and Practices (Excel Books, New Delhi). Stoner, Freeman, Gilbert. Jr. - Management (Prentice Hall of India, 6thEdition). Koontz, Weihrich - Essentials of Management (TMH, 5thEdition).





61

EEEEEE330044:: PPOOWWEERR SSYYSSTTEEMM –– IIII

Credits: 04 Semester VI L-T-P: 3-1-0 Module

No. Content

Teaching Hours

I

Representation of Power System: One Line Diagram, Impedance & Reactance Diagram, Per Unit System, Representation of Power System Components, Regulating Transformers (Tap Changing & Phase Shifting), Generators, Transmission Line and Loads, Phase Shift in Star-Delta Transformer, Sequence Impedance of Transmission Line, Transformer and Generators, Sequence Networks of Power System. Y-Bus and Z-Bus Formulation, Economic Operation of Power System.

15

II

Fault Analysis: Symmetrical Fault, Algorithm for Symmetrical Fault Analysis, Symmetrical Components of Unbalanced Phasors, Power Invariance, Unbalanced Faults (Single Line to Ground Fault, Line to Line and Double Line to Ground, Open Conductor Fault, Bus Impedance Matrix Method for The Analysis of Unsymmetrical Shunt Faults. Load Flow Study: Load Flow Problem, Power Flow Equations, Load Flow Solution Using Gauss Seidal and Newton Raphson Methods, Decoupling Between Real and Reactive Power Control, Decoupled and Fast Decoupled Methods, Comparison of Load Flow Methods, Reactive Power Compensation.

15

III

Transient Stability Studies: Types of Stability, Swing Equation , Equal Area Criterion & Its Applications; Step-By-Step Solution of Swing Curve ,Factors Affecting Stability of System & Methods of Improving Stability Surge Phenomenon Classification; Travelling Wave Equation for A Long Line; Surge Impedance; Voltage Profile Along The Line, Protection From Surge Phenomenon.

12

Text Books:

D.P. Kothari and I.J. Nagrath, “Power System Engineering”, TMH. B. R. Gupta, “Power System Analysis and Design”, S. Chand & Co.

References:

W.D. Stevenson, “Elements of Power Systems Analysis”, McGraw Hill. O.I. Elgerd, “Electric Energy Systems Theory: An Introduction”, Tata McGraw Hill. C. L. Wadhwa, “Electrical Power Systems”, New Age International Ltd. Ashfaq Hussain, “Power System”, CBS Publishers and Distributors.




62

EEEEEE330055:: CCOONNTTRROOLL SSYYSSTTEEMM


No. Content

Teaching Hours

I

The Control System: Open Loop & Closed Control; Servomechanism, Physical Examples. Transfer Functions, Block Diagram Algebra, Signal Flow Graph, Mason’s Gain Formula Reduction of Parameter Variation and Effects of Disturbance By Using Negative Feedback Control System Components: Constructional and Working Concept of Ac Servomotor, Synchros and Stepper Motor

12

II

Time Response Analysis: Standard Test Signals, Time Response of First and Second Order Systems, Time Response Specifications, Steady State Errors and Error Constants, Design Specifications of Second Order Systems: Derivative Error, Derivative Output, Integral Error and PID Compensations, Design Considerations for Higher Order Systems, Performance Indices Stability and Algebraic Criteria: Concept of Stability and Necessary Conditions, Routh-Hurwitz Criteria and Limitations. Root Locus Technique: The Root Locus Concepts, Construction of Root Loci

14

III

Frequency Response Analysis: Frequency Response, Correlation Between Time and Frequency Responses, Polar and Inverse Polar Plots, Bode Plots Stability in Frequency Domain: Nyquist Stability Criterion, Assessment of Relative Stability: Gain Margin and Phase Margin Introduction to Design: The Design Problem and Preliminary Considerations Lead, Lag and Lead-Lag Networks, Design of Closed Loop Systems Using Compensation Techniques in Time Domain and Frequency Domain. Review of State Variable Technique: Review of State Variable Technique, Conversion of State Variable Model to Transfer Function Model and Vice-Versa, Diagonalization, Controllability and Observability and Their Testing.

14

Text Books:

Nagrath & Gopal, “Control System Engineering”, New age International. References:

Norman S. Nise, “Control System Engineering”, Wiley Publishing Co. Ajit K Mandal, “Introduction to Control Engineering” New Age International. R.T. Stefani, B.Shahian, C.J.Savant and G.H. Hostetter, “Design of Feedback Control Systems”, Oxford

University Press. N.C. Jagan, “Control Systems”, B.S. Publications. K. Ogata, “Modern Control Engineering”, Prentice Hall of India. B.C. Kuo & Farid Golnaraghi, “Automatic Control System”, Wiley India Ltd. D.Roy Choudhary, “Modern Control Engineering”, Prentice Hall of India.




63

EECCEE330088:: AANNAALLOOGG && DDIIGGIITTAALL CCOOMMMMUUNNIICCAATTIIOONN

Module No.

Content Teaching

Hours

I

Elements of communication system and its limitations, Modulation, Need of Modulation Amplitude Modulation: Amplitude Modulation and detection, Generation and detection of DSB-SC, SSB-SC and vestigial side band modulation, carrier acquisition, AM transmitters and receivers Super heterodyne receiver, AGC circuits, Angle Modulation: Narrow band and wideband frequency modulation, transmission bandwidth of FM signals Generation and detection of frequency Modulation, Pre-emphasis & de-emphasis Noise : Sources of noise, Noise calculations, signal to noise ratio, Noise in AM and FM systems

15

II

Pulse Modulation: Introduction, sampling process, Analog Pulse Modulation Systems-Pulse Amplitude Modulation (PAM), Pulse width modulation(PWM) and Pulse Position Modulation (PPM). Multiplexing: Frequency Division multiplexing, Time Division Multiplexing, Electronic Commutator, Bit/byte interleaving, TI carrier system, synchronization and signaling of TI, TDM hierarchy, Synchronization techniques Waveform coding Techniques: Quantization process, quantization noise, Pulse code Modulation, Differential Pulse code Modulation, Delta Modulation and Adaptive Delta Modulation.

15

III

Digital Modulation Techniques: Types of digital modulation, waveforms for amplitude, frequency and phase shift keying, methods of generation of coherent and non coherent, ASK, FSK and PSK, comparison of ASK, FSK, PSK digital techniques. Introduction to Information Theory: Measure of information, Entropy & Information rate, channel capacity, Hartley Shannon law, Huffman coding, Shannon-Fano coding.

12

References:

Simon Haykin,“ Communication Systems” John Wiley & Sons 4th Edition G.Kennedy and B. Davis “Electronic Communication Systems” 4th Edition, Tata McGraw Hill B.P. Lathi, “Modern Analog & Digital Communication Systems” Oxford University Press. Taub& Schilling, “Communication System: Analog and Digital” Tata McGraw Hill Simon Haykin, “Digital Communications” John Wiley & Sons.

Credits: 04 L–T–P: 3–1–0 Semester VI




64

EEEEEE330066:: EELLEECCTTRRIICCAALL PPOOWWEERR GGEENNEERRAATTIIOONN


No. Content

Teaching Hours

I

Introduction: Importance of Electrical Energy, Comparison With Forms of Energy, Electrical Energy Sources. Power Plant Economics and Tariffs: Load Curve, Load Duration Curve, Different Factors Related to Plants And Consumers, Cost of Electrical Energy, Depreciation, Tariffs, Causes and Effects of Low Power Factor, Advantages of Power Factor Improvement, Different Methods for Power Factor Improvement. Power Plant Auxiliaries: Excitation System, Turbine and Governors, Storage Batteries, EHV Substation.

12

II

Thermal Power Plant: Location and Site Selection, General Layout and Working of Plant, Brief Description of Boilers, Economizers, Super Heaters, Draft Equipments, Fuel and Ash Handling Plant. Gas Turbine Power Plant: Operational Principle of Gas Turbine Plant & Its Efficiency, Fuels, Open and Closed-Cycle Plants, Regeneration, Inter-Cooling And Reheating. Nuclear Power Plant: Location, Site Selection, General Layout and Operation of Plant, Brief Description of Different Types of Reactors, Moderator Material, Fissile Materials, Control of Nuclear Reactors, Disposal of Nuclear Waste Material, Shielding. Hydro Electric Plants: Classifications, Location and Site Selection, Detailed Description of Various Components, General Layout and Operation of Plants, Brief Description of Impulse, Reaction, Kaplan and Francis Turbines, Advantages & Disadvantages.

15

III

Wind Energy: Basic Principles of Wind Energy Conversion, Wind Energy Power Calculation, Analysis of Aerodynamic Forces Acting on The Blades, Site Selection Considerations, Types of Wind Energy Collectors, Applications of Wind Energy. Solar Energy: Solar Radiation at The Earth’s Surface, Solar Radiation Measurement, Solar Energy Collectors, Solar Thermal Power Plant, Solar PV Cells, Applications of Solar Energy. Substation Automation: Basic Theory, Cost Justification, Risks/Benefits – Hard and Soft. SCADA System: Hardware, Software, Data Acquisition, Control and Features; RTU; PLC; IED; Types of Architecture; Equipment Monitoring for Reliability And Safety, Utility Integration of Communication, Control & Protection.

15

Text Books:

B. H. Khan, “Non-conventional Energy Resources”, Tata Mcgraw-Hill Education. B. R. Gupta, “Generation of Electrical Energy”, S. Chand Publication.

References:

W.D. Stevenson, “Elements of Power System Analysis”, McGraw Hill. S.L. Uppal, “Electrical Power”, Khanna Publishers. M.L. Soni, P.V. Gupta and U.S. Bhatnagar, “A Course in Electrical Power”, Dhanpat Rai & Sons.

Soni, Gupta & Bhatnagar, “A Text Book on Power System Engg.”, Dhanpat Rai & Co.

P.S.R. murthy, “Operation & Control of Power System”, BS Publications.

Brand K, Lohmann V and Wimmer, W, “Substation Automation Handbook”, Utility Automation

Consulting Lohman.




65

EEEEEE338855:: CCOONNTTRROOLL SSYYSSTTEEMM LLAABB

Module No.

Content Teaching

Hours

I

List of Experiments Hardware based

To determine response of first order and second order systems for step input for variousvalues of constant ’K’ using linear simulator unit and compare theoretical and practicalresults.

To study P, PI and PID temperature controller for an oven and compare their performance.

To study and calibrate temperature using resistance temperature detector (RTD)

To design Lag, Lead and Lag-Lead compensators using Bode plot. To study DC position control system To study synchro-transmitter and receiver and obtain output V/S

input characteristics To determine speed-torque characteristics of an ac servomotor. To study performance of servo voltage stabilizer at various loads

using load bank. To study behaviour of separately excited dc motor in open loop and

closed loop conditions atvarious loads. To study PID Controller for simulation proves like transportation lag.

Simulation Based Experiments To determine time domain response of a second order system for step

input and obtains performance parameters. To convert transfer function of a system into state space form and

vice-versa. To plot root locus diagram of an open loop transfer function and

determine range of gain ‘k’ fir stability. To plot a Bode diagram of an open loop transfer function. To draw a Nyquist plot of an open loop transfer functions and

examines the stability of the closed loop system.

24

Semester VI L–T–P: 0–0–2 Credits: 01




66

EEEEEE338844:: PPOOWWEERR SSYYSSTTEEMM LLAABB--IIII

Module

No. Content

Teaching Hours

I

List of Experiments

Hardware based To determine direct axis reactance (xd) and quadrature axis reactance

(xq) of a salient pole alternator. To study 3 phase short circuit fault. To test the various characteristics dielectric strength etc. for a given

insulator Simulation Based Experiments

2.Using MATLAB, determine the current response after closing the switch in a series R-L circuit for the following cases:

(i)No DC offset (ii)For maximum DC offset

To obtain steady state, transient and sub-transient short circuit currents of an 3 phase alternator.

To formulate Y-bus for a given power system network. To perform symmetrical fault analysis in a given power system To perform unsymmetrical fault analysis in a given power system for

LG, LL, LLG faults. To perform the load flow analysis for a given power system network

using Gauss Seidal method. To perform transient stability analysis for a single machine connected

to infinite bus.

24





67

EECCEE 338888:: CCOOMMMMUUNNIICCAATTIIOONN LLAABB

Module No.

Content Teaching

Hours

I

List of Experiments Realization of amplitude modulation using transistors and find modulation Index.

Realization of Linear envelop detector for demodulation of AM ware and observe diagonal peak clipping effect.

Realization of frequency modulation and determine its modulation index.

To study demodulation of FM wave. To study Pulse amplitude modulation and realize on bread board

using discrete components. To study Pulse width modulation and realize on bread board using

discrete components. To study transmission line and measure its characteristics impedance. To study Yagi-Uda, antenna. Plot radiation pattern and find beam

width. To study parabolic antenna. Plot radiation pattern and find beam

width. To study super heterodyne receiver and to analyze selectivity,

sensitivity and fidelity of analog communication system. To realize FM system using VCO and PLL.

24





68

EEEEEE338811:: EELLEECCTTRRIICCAALL MMAACCHHIINNEE LLAABB--IIII

Module

No. Content

Teaching Hours

I

To perform no load and blocked rotor tests on a three phase squirrel cage induction motor and determine equivalent circuit.

To perform load test on a three phase induction motor and draw: Torque -speed characteristics

To perform no load and blocked rotor tests on a single phase induction motor and determine equivalent circuit.

To study speed control of three phase induction motor byKeeping V/f ratio constant

To study speed control of three phase induction motor by varying supply voltage.

To perform open circuit and short circuit tests on a three phase alternator and determine voltage regulation at full load and at unity, 0.8 lagging and leading power factors by (i) EMF method (ii) MMF method.

To determine V-curves and inverted V-curves of a three phase synchronous motor.

To determine Xd and Xq of a three phase salient pole synchronous machine using the slip test and draw the power-angle curve.

To study synchronization of an alternator with the infinite bus by using (i)dark lamp method (ii) two bright and one dark lamp method

Software based experiments (Develop Computer Program in MATLAB) To determine speed-torque characteristics of three phase slip ring

induction motor and study the effect of including resistance, or capacitance in the rotor circuit.

To determine speed-torque characteristics of single phase induction motor and study the effect of voltage variation.

To determine speed-torque characteristics of a three phase induction by (i) keeping v/f ratio constant (ii) increasing frequency at the rated voltage.

24





69

AAHHEE338822:: SSOOFFTT SSKKIILLLLSS--IIVV

It is well recognized by the Industry that the soft skills are essential for entry level employees and they include articulation, competence in reading, writing, effective listening and oral communication skills; adaptability to cross cultural environment through creative thinking and problem solving; personal management with assertiveness and initiative; interpersonal skills; the ability to work in teams. Enterprises define the entrants to be ‘industry ready’ when they posses these soft skills. Course Objectives:

Understand what constitutes a professional environment. Develop positive group strategies & team spirit. Set specific measurable goals for themselves in their personal and/or professional life. Understand the skills and the intricacies involved in starting an entrepreneurial venture.

Module No.

Content Teaching

Hours

I

Campus to Company The Corporate Fit-Dressing and Grooming, Corporate Dressing - Dress for Success Business Etiquette, Basic Table Manners, Dealing with people Communication Media Etiquette Telephone and Email Etiquette

10

II

Group Discussions, Interviews and Presentations Group Discussions Group Discussions, Structured Group Discussions, Unstructured Group Discussions Interviewing Skills Interview Handling Skills An Effective Resume The Interview Process The Interview Preparation Check List At the Interview � Putting your best foot forward Common Interview Mistakes Presentation Skills Voice, Body Language, Content and Visual Aids, Audience Management, Practice

10

III

Entrepreneurial Skills Development Goal Setting, Understanding Entrepreneurship Studying Entrepreneurial Competencies What are the Entrepreneurial Competencies? Entrepreneurship in Daily Life Venture Project Planning & Entrepreneurship Cycles Planning the Project Case Studies in Entrepreneurship References and Links Entrepreneurship Courses in India Links to Venture capitalists

10

Reference Books:

Hornby, A.S. An Advanced Learners’Dictionary of Current English, OUP. Murphy, Raymond, Intermediate English Grammar, Cambridge University Press. Rizvi, Ashraf, M. Effective Technical Communication. New Delhi: Tata McGraw Hill. Infosys modules

L–T–P: 0–0–2 Credits: 04 Semester VI




70

PPT slides & videos provided by Infosys. Audio-Video Material available in the language Lab.




71

EEEEEE--440011:: SSWWIITTCCHHGGEEAARR && PPRROOTTEECCTTIIOONN

Text Books:

Y. G. Paithankar and S R Bhide, “Fundamentals of Power System Protection”, Prentice Hall of India. S. S. Rao, “Switchgear and Protection”, Khanna publishers

References: B. Ram and D. N. Vishwakarma, “Power System Protection and Switchgear”, Tata Mcgraw Hill Bhavesh Bhalja , R.P.Maheshwari & Nilesh Chothani, “ Protection & Switchgear”, Oxford university

press Nirmal-Kumar C Nair, Bhuvanesh A Oza, Vijay H Makwana, Rashesh P Mehta, “Power system

protection & switchgear”,Mcgraw Hill A.R. Van C. Warringtaon , “ Protective Relays- Their Theory and Practice, Vol. I & II” John Willey &

Sons.

Module No.

Content Teaching

Hours

I

Introduction to Protection system: Introduction to protection system & its elements, zone of protection, primary & back-up protection, desirable qualities of protective relaying, review of CT & PT. Relays: Electromagnetic attraction type relays, concept of time setting multiplier & plug setting multiplier, electromagnetic induction disc type relays, torque equation, Instantaneous over-current characteristics, Inverse definite minimum time characteristics (IDMT),Definite time over-current characteristics(DTOC),comparison between DTOC & IDMT relays, drawbacks of over-current protection, Universal Torque equation, Distance protection using simple impedance relay, drawbacks of simple impedance relay, directional protection & directional relay, concept of maximum torque angle ,characteristics on R-X diagram

13

II

Reactance relays & MHO relays- characteristics on R-X diagram, implementation, limitations, Simple differential protection, operation under external & internal fault condition, percentage bias differential protection , Bus – bar protection, auto reclosing, carrier current protection. Protection of Transformer, generator and motor

13

III

Circuit Breaking Arc formation, properties of arc, extinction theories, re-striking voltage, RRRV, current chopping, resistance switching, capacitive current interruption, short line interruption, circuit breaker ratings, Testing of circuit breakers-Direct & In-direct testing, Constructional features and operation of Bulk oil & minimum oil circuit breakers, Air blast circuit breakers,SF6 circuit breakers & HVDC circuit breakers. Static relays Amplitude comparator & phase comparator, synthesis of MHO relay using static phase comparator, synthesis of reactance relay using cosine type phase comparator, synthesis of simple impedance relay using amplitude comparator.

13

Credits: 04 Semester VII L–T–P: 3–1–0




72

EEEEEE--440022:: EELLEECCTTRRIICCAALL DDRRIIVVEESS

References:

G.K. Dubey, “Fundamentals of Electric Drives”, Narosa publishing House. S.K.Pillai, “A First Course on Electric Drives”, New Age International. P.S.Bimbhra, “Power Electronics”, Khanna Publishers. M.Chilkin, “Electric Drives”,Mir Publishers, Moscow. Mohammed A. El-Sharkawi, “Fundamentals of Electric Drives”, Thomson Asia, Pvt. Ltd.

Singapore. N.K. De and Prashant K.Sen, “Electric Drives”, Prentice Hall of India Ltd. V.Subrahmanyam, “Electric Drives: Concepts and Applications”, Tata McGraw Hill.

Module Content Teaching

Hour

I

Fundamentals of Electric Drives: Introduction, concept of electric drives, classification, multi-quadrant operations, types of load, load torque components and nature, constant torque and constant power operation, steady state and transient stability of electric drive. Selection of Motor Power Rating: Thermal model of motor for heating and cooling, classes of motor duty, determination of motor power rating for continuous duty, short time duty and intermittent duty and load equalization. Electric Braking: Purpose and types of electric braking, braking of dc, three phase induction and synchronous motors.

14

II

Dynamics During Starting and Braking: Calculation of acceleration time and energy loss during starting of dc shunt and three- phase induction motors and methods of reducing energy loss during starting. Power Electronic Control of DC Drives: Single-phase and three-phase controlled converter fed separately excited dc motor drives(continuous conduction only), dual converter fed separately excited dc motor drive and brushless dc motor, supply harmonics, power factor and ripples in motor current , chopper control of separately excited dc motor and dc series motor.

14

III

Power Electronic Control of AC Drives: Three Phase induction Motor Drives: stator voltage control & soft start, variable frequency control (voltage source inverter, current source inverter and cyclo-converter based), stator current control, rotor resistance control and slip power recovery control schemes. Three Phase Synchronous Motor Drives: Cylindrical rotor motors, salient pole motors, reluctance motor and permanent magnet synchronous motor.

13

Semester VII





73

EEE-403: ELECTRICAL INSTRUMENTATION AND PROCESS CONTROL


Hour

I

Introduction to Industrial Automation and control:Architecture of industrial automation systems. Introduction to Sensors and Measurement systems : Temperature measurement, pressure and force measurement, displacement and speed measurement, flow measurement techniques, measurement of level, humidity and ph. Signal conditioning and processing estimation of errors and calibration.

13

II

Introduction to Process Control: Process characteristics, proportional(P),integral(I),derivative(D),PI,PD and PID Control modes, controller tuning. Special Control Structures : Feed-forward and ratio control, predictive control, control of systems with inverse response cascade control, overriding control, selective control, split range control. Electronic, pneumatic anddigital controllers. Electrical Control elements: Construction and principle of operation of solenoids, stepper motor, AC/DC motor, limit switches, relays, auto transformer and magnetic amplifiers.

14

III

Introduction to Actuators:Flow control valves. Control valves: Principle of operation and constructional details of solenoid valves, diaphragmoperated valve, piston operated valve, valve positioners, control valve characteristics and their sizing, temperature switches flow switches, interlocking and sequencing circuits. Hydraulic Actuator systems: Principles, components and symbols, pumps and motors, proportional and servo valves. Pneumatic Control systems: System components, controllers and integrated control systems. Introduction to Sequence control: PLCs and relay ladder Logic.

13

References:

George Stephanopoulos, “Chemical Process Control: An Introduction to Theory and Practice”, Prentice-Hall, 1984.

Harrist P, “Process Control”, McGraw Hill. Johnson, Curtis D, “Process Control Instrumentation Technology”, John Wiley and Sons. B.C. Nakra & K.Chaudhry, “Instrumentation, Measurement and Analysis”, Tata McGraw Hill 2nd

Edition. A.K.Sawhney, “Advanced Measurements & Instrumentation”, DhanpatRai& Sons. E.O. Decblin, “Measurement System – Application & design”, McGraw Hill. Eckman D P , “Automatic Process Control”, Wiley Eastern, 1975. Liptak B. G., “Instrument Engineers Handbook”, CRC Press 3rd edition. Ronald P Hunta, PE, “Automated Process Control Systems: Concepts and Hadware”, Prentice Hall Inc.,

New Delhi. Eckman, Donal P, “Principles of Industrial Process Control”, John Wiley and Sons. Liptak Bila G, “Process Measurement and Analysis”CRC Press 3rd edition.

Semester VIII





74

EEEEEE--440044:: PPOOWWEERR SSYYSSTTEEMM OOPPEERRAATTIIOONN AANNDD CCOONNTTRROOLL

Text Books: D.P. Kothari & I.J. Nagrath, “Modern Power System Analysis” Tata Mc Graw Hill, 3rd Edition. P.S.R. Murty, “Operation and control in Power Systems” B.S. Publications. N. G. Hingorani & L. Gyugyi, “Understanding FACTS Concepts: and Technology of Flexible ac transmission

systems” IEEE press. A. J. Wood & B.F. Wollenburg, “Power Generation, Operation and Control “John Wiley & Sons.

References: O.I. Elgerd, “Electric Energy System Theory” Tata McGraw Hill Publishing Company Ltd. New Delhi,

Second Edition 2003. P. Kundur, “Power System Stability and Control” Mc Graw Hill Publishers, USA.

Module No.

Content Teaching

Hours

I

Introduction: Structure of power systems, power system control center and real time computer control, concept of energy control centre (or) load dispatch centre and the functions, system hardware configuration – SCADA and EMS functions, network topology, state estimation, security analysis and control. Various operating states: Normal, alert, emergency, in-extremis & restorative states, state transition diagram showing various state transitions and control strategies, power system voltage stability. System load variation: Load-duration curve (daily, weekly and annual), load factor & diversity factor, importance of load forecasting and simple techniques of forecasting.

13

II

Economic operation : Concept and problems of unit commitment, input-output characteristics of thermal and hydro-plants, system constraints, optimal operation of thermal units without and with transmission losses, Penalty factor, incremental transmission loss, transmission loss formula (without derivation). Load frequency control: Concept of load frequency control, load frequency control of single area system, turbine speed governing system and modeling, block diagram representation of single area system, steady state analysis, dynamic response, control area concept, P-I control, load frequency control and economic dispatch control. Load frequency control of two area system: Tie line power modeling, block diagram representation of two area system, static and dynamic response.

13

III

Automatic voltage control: Schematic diagram and block diagram representation, different types of Excitation system. Voltage and reactive power control: Concept of voltage control, methods of voltage control by tap changing transformer, shunt compensation, series compensation, and phase angle compensation. Flexible AC transmission systems: Concept and objectives of FACT’s controllers, structure & characteristics of following FACT’s controllers - TCR, FC-TCR, TSC, SVC, STATCOM, TSSC, TCSC, SSSC, TC-PAR, UPFC.

13

Semester VIII





75

EEEEEE--440055:: DIGITAL CONTROL SYSTEM

Text Books:

B.C.Kuo, “Digital Control System”,Saunders College Publishing. M.Gopal, “Digital Control and State Variable Methods”, Tata McGraw Hill.

Reference Books: R.Leigh, “Applied Digital Control”, Prentice Hall, International. C.H. Houpis and G.B.Lamont, “Digital Control Systems :Theory, hardware, Software”, McGraw Hill.


Hour

I

Signal Processing in Digital Control: Basic control system, advantages of digital control and implementation problems, basic discrete time signals, z-transform and inverse z-transform. Modeling of sample-hold circuit, pulse transfer function, solution of difference equation by z- Transform method.

14

II

Design of Digital Control Algorithms: Steady state accuracy, transient response and frequency response specifications, digital compensator design using frequency response plots and root locus plots. State Space Analysis and Design: State space representation of digital control system, conversion of state variable models to transfer functions and vice versa, solution of state difference equations, controllability and observability, design of digital control system with state feedback.

14

III

Stability of Discrete System: Stability on the z-plane and Jury stability criterion, bilinear transformation, Routh stability criterion on rth plane. Lyapunov’s Stability in the sense of Lyapunov, stability theorems for continuous and discrete systems, stability analysis using Lyapunov’s method. Optimal digital control : Discrete Euler Lagrange equation, max. min. principle, different types of problem and their solutions.

14

L–T–P

Semester VII





76

EEEEEE--440066:: PPOOWWEERR SSYYSSTTEEMM DDYYNNAAMMIICCSS AANNDD SSTTAABBIILLIITTYY

Text Books :

Peter W. Sauer and M.A.Pai , “ Power System Dynamics & Stability”, Prentice Hall. P. Kundur , “Power System Stability and Control” , Mc-Graw Hill.

Reference Books: K. R. Padiyar , “Power System Dynamics -Stability & Control”, BS Publications. E.W. Kimbark , “Power System Stability” , Wiley-IEEE Press. C.P.Taylor , “Power System Voltage Stability” , Mc- Graw Hill.


Hour

I

System Modeling and Dynamics of Machine: Modeling of synchronous machine: park’s transformation, equivalent circuit & phasor diagram of synchronous generator, dynamics of synchronous generator connected to infinite bus system, modeling of excitation system, prime mover and governing system; induction machine modeling.

15

II

Angular Stability: Review of stability concept, response to a step change in mechanical power input, equal area criterion and its application, swing equation, numerical solution of swing equation, factors affecting stability, multi-machine system stability, small signal stability of single machine system , introduction to power system stabilizers.

14

III

Voltage Stability: Introduction, classification of voltage stability, factors affecting voltage stability, voltage stability of a simple 2-bus system, tools for voltage stability analysis, voltage collapse and prevention of voltage collapse.

13

Semester VII





77

EEEEEE--440077:: DDIIGGIITTAALL SSIIGGNNAALL PPRROOCCEESSSSIINNGG

References:

John G Prokias, Dimitris G Manolakis, “Digital Signal Processing”, Pearson Education. Oppenheim & Schafer, “ Digital Signal Processing” PHI

Module No.

Content Teaching

Hours

I

Review of discrete time signals and systems, Sampling of CT signals: Periodic sampling, Frequency domain representation of sampling, Reconstruction of bandlimited signal from its samples, Discrete time processing of continuous time signals, Continuous time processing of discrete time signals, Changing the sampling rate using discrete time processing. Discrete time systems: Linear time invariant discrete time systems, Characterization of LTI systems.

13

II

Transform domain representation of signals and systems: The discrete time Fourier transform ,The frequency response ,The transfer function ,Discrete Fourier series ,Discrete Fourier transform ,Computation of DFT ,Linear convolution using DFT, FFT Algorithms, Direct Computation of the DFT Radix-2 FFT algorithms, Gortezel Algorithm, Chirp Z-transform The z-transform ,The region of convergence of z-transform

14

III

Structures for discrete time systems: Block diagram and signal flow representation of constant coefficient , linear difference equation, Basic structures for IIR systems, Basic structures for FIR systems ,Lattice structures, Effects of coefficient quantization, Effect of roundoff noise in digital filters, Zero-input limit cycles Filter design techniques: Design of discrete time IIR filters from continuous time filters, Design of FIR filters by windowing, Optimum approximation of FIR filters, Linear phase filters.

13

Semester VII





78

EEEEEE--440088:: SPECIAL ELECTRICAL MACHINES


Hour

I

Poly-Phase AC Machines: Construction and performance of double cage and deep bar three-phase induction motors, e.m.f. injection in rotor circuit of slip ring induction motor, effect of voltage and frequency variation, concept of constant torque and constant power controls, static slip power recovery control schemes. Single-Phase Induction Motors: Construction, double revolving field theory, equivalent circuit, no load and blocked rotor tests, starting characteristics and applications of split- phase, capacitor-start, capacitor-run, capacitor-start capacitor-run, and shaded -pole motors. Two-Phase AC Servomotors: Construction, torque-speed characteristic, performance and applications.

15

II

Single-Phase Synchronous Motor: Construction, operating principle, characteristics of reluctance and hysteresis motors. Stepper Motors: Principle of operation, variable reluctance, permanent magnet and hybrid stepper motors, characteristics, drive circuits and applications. Switched Reluctance Motors: Construction, principle of operation, torque production, modes of operation.

14

III

Single-Phase Commutator Motors: Construction, principle of operation, characteristics of universal and repulsion motors; linear induction motors: construction, principle of operation and applications. Permanent Magnet Machines: Types of permanent magnets, permanent magnet ac & dc motors, brushless dc motors and their important features and applications, PCB motors, introduction to permanent magnet generators.

13

Text Books:

P.S. Bimbhra, “Generalized Theory of Electrical Machines”,Khanna Publishers. P.C. Sen ,“Principles of Electrical Machines and Power Electronics”, John willey & Sons.

Reference Books: G.K.Dubey, “Fundamentals of Electric Drives”, Narosa Publishing House. Cyril G. Veinott , “Fractional and Sub-fractional horse power electric motors”, McGraw Hill. M.G. Say ,“Alternating current Machines”, Pitman & Sons.

Semester VII





79

EEEEEE--440099:: ADVANCE CONTROL SYSTEM

Text Books: M.Gopal, “Digital Control and State variable Methods”, Tata Mc Graw Hill. Ajit K.Madal, “Introduction to Control Engineering: Modelling, Analysis and Design”, New Age

International. D.Landau, “Adaptive Control”, Marcel Dekker Inc. S.Rajasekaran & G.A.Vjayalakshmi Pai, “Neural Networks,Fuzzy Logic and Genetic Alogorithms:

Synthesis and Applications”, Prentice Hall of India. Reference Books:

Donald E. Kiv, “Optimal Control Theory: An Introduction”, Prentice Hall. B.C. Kuo, “Digital Control Systems”, Sounders College Publishing. C.H.Houpis and G.B.Lamont,“Digital Control Systems:Theory,Hardware, Software”,Mc Graw Hill.

Hassan K. Khalil, “Nonlinear systems”, Prentice Hall.


Hour

I

State Space Analysis of Continuous System:

Review of state variable representation of continuous system, design of state

observer and controller.

Analysis of Discrete System:

Discrete system and discrete time signals, state variable model and transfer function

model of discrete system, conversion of state variable model to transfer function

model and vice-versa, modeling of sample hold circuit, solution of state difference

equations, steady state accuracy, stability on the z-plane and Jury stability criterion,

bilinear transformation, Routh-Hurwitz criterion on rth planes.

14

II

Stability:

Lyapunov’s stability theorems for continuous and discrete systems, methods for

generating Lyapunov function for continuous and discrete system.

Non linear System:

Types of non linearities, phenomena related to non-linear systems, analysis of non

linear systems, linearization method, second order non-linear system on the phase

plane, types of phase portraits, singular points, system analysis by phase-plane

method and describing function method.

13

III

Optimal Control:

Introduction, formation of optimal control problem, calculus of variations

minimization of functions, constrained optimization, Pontryagin’s minimum

maximum principle.

Adaptive Control:

Introduction, modal reference adaptive control systems, controller structure, self

tuning regulators. Introduction to neural network, fuzzy logic and genetic

algorithms.

13

L–T–P

Semester VII





80

EEEEEE--441100:: UUTTIILLIIZZAATTIIOONN OOFF EELLEECCTTRRIICC PPOOWWEERR AANNDD TTRRAACCTTIIOONN

Module

No. Content

Teaching Hours

I

Illumination engineering Nature of light, units, sensitivity of the eye, luminous efficiency, glares, production of light, incandescent lamps, arc lamps gas discharge lamps- fluorescent lamps-polar curves. Lightning Distribution and control of light, lighting calculations, solid angle, inverse square and cosine laws, methods of calculations, factory lighting, flood lighting and street lighting. Refrigeration Electrical circuits used in refrigeration and air conditioning and water coolers, principle of air conditioning, vapour pressure, refrigeration cycle, eco-friendly refrigerants.

13

II

Electric heating Electrical heating advantages, methods and applications, resistance heating, design of heating elements, induction heating, core type furnaces, core less furnaces and high frequency eddy current heating, dielectric heating, arc furnaces (direct arc furnaces, Indirect arc furnaces), electrodes, power supply and control. Welding Different methods of electrical welding, resistance welding, arc welding, laser welding, electron-beam welding and welding transformers. Electrolysis Review of electrolytic principles, laws of electrolysis, electroplating, anodizing, process of electro-deposition - clearing, operation, deposition of metals, polishing, buffing and extraction of refinery metals.

13

III

Traction system: Special features of traction motors, selection of traction motor, different system of electric traction and their advantages and disadvantages, mechanics of train movement, simplified speed time curves for train movement, crest, average and schedule speed, tractive effort, specific energy consumption, adhesive weight and coefficient of adhesion. Electric drives: Advantages and disadvantages of electric drives, types of motors used for electric drives, electrical braking (plugging, rheostat and regenerative braking), load equalization, use of fly wheel criteria for selection of motors for various industrial drives, intermittent loading and temperature rise curve. Applications: Tramways, trolley bus, diesel electric traction.

13

Text Books: H.Partab,“Art and Science of Electrical Energy” Dhanpat Rai & Sons publications. G.K.Dubey,“Fundamentals of Electric Drives” Narosa Publishing House. J. B. Gupta, “Electrical Power Utilization” S.K.Kataria & Sons publication. Soni, Gupta, Bhatnagar, A text book on “Power System Engineering”, Dhanpatrai & sons publications. S. Sivanagaraju, M. Balasubba Reddy & D. Srilatha, “Generation Utilization of Electrical Energy”, Pearson

Publications.

Semester VII





81

EEEEEE--441111:: BBIIOO--MMEEDDIICCAALL IINNSSTTRRUUMMEENNTTAATTIIOONN

Module No.

Content Teaching

Hours

I

The origin of biopotentials, bioelectric signals (ECG, EMG, EEG, EOG & ERG) and their characteristics, bioelectrodes, electrodes tissue interface, contact impedance, effects of high contact impedance, types of electrodes, electrodes for ECG, EEG and EMG. The origin, acquisition, processing, and analysis of electrical heart signals, recording and interpretation of electrocardiogram (ECG).

13

II

Blood pressure and sound, phonocardiography, pulse pickup, measurement of flow and volume of blood, electromagnetic and ultrasonic flowmeter, measurements of the respiratory System, lungs (spirometry, EIT), chemical biosensors. An introduction to therapeutic devices (cardiac pacemakers and defibrillators), An introduction to therapeutic devices for ears (hearing implants) and eyes (retinal implants).

13

III

Patient Monitoring System: Heart rate measurement pulse rate measurement, respiration, rate measurement, blood pressure measurement, microprocessor applications in patient monitoring. X- Ray Machine: Basic X-ray components and circuits, types of X-ray machines e.g. general purpose, dental image intensifier system, table shooting and maintenance of X- ray machine. Safety Aspect of Medical : Gross current, micro current shock, safety standards rays and considerations, safety testing instruments, biological effects of X-rays and precautions.

14

Text Book:

John. G. Webster, “Medical Instrumentation Application and Design”, Wiley India Pvt Ltd. L. A. Geddes, L. E. Baker, “Principles of Applied Biomedical Instrumentation”, John Wiley. Joseph J. Carr, John M. Brown , “Introduction to Biomedical Equipment Technology”, Pearson.

Reference Books:

Leslie Cromwell, “Biomedical Instrumentation and Measurements” , Prentice-Hall. R.S. Khandpur, “Handbook of Biomedical Instrumentation”, TMH, New Delhi. Sanjay Guha, “Medical Electronics and Instrumentation”, University Publication. Edwand J. Bukstein, “Introduction to Biomedical Electronics”, Bobbs-Merrill Co.

Semester VII





82

EEEEEE--441122:: SSMMAARRTT GGRRIIDD

Text Books: Ali Keyhani, Mohammad N. Marwali, Min Dai “Integration of Green and Renewable Energy in Electric

Power Systems”, Wiley Clark W. Gellings, “The Smart Grid: Enabling Energy Efficiency and Demand Response”,CRC Press Janaka Ekanayake, Nick Jenkins, Kithsiri Liyanage, Jianzhong Wu, Akihiko Yokoyama, “Smart Grid:

Technology and Applications”, Wiley Jean Claude Sabonnadière, Nouredine Hadjsaïd, “Smart Grids”, Wiley Blackwell Peter S. Fox Penner, “Smart Power: Climate Changes, the Smart Grid, and the Future of Electric Utilities”,

Island Press; 1 edition 8 Jun 2010 S. Chowdhury, S. P. Chowdhury, P. Crossley, “Microgrids and Active Distribution Networks.” Institution of

Engineering and Technology, 30 Jun 2009 Stuart Borlase, “Smart Grids (Power Engineering)”, CRC Press

References: Andres Carvallo, John Cooper, “The Advanced Smart Grid: Edge Power Driving Sustainability: 1”, Artech

House Publishers July 2011 James Northcote, Green, Robert G. Wilson “Control and Automation of Electric Power Distribution Systems

(Power Engineering)”, CRC Press Mladen Kezunovic, Mark G. Adamiak, Alexander P. Apostolov, Jeffrey George Gilbert “Substation

Automation (Power Electronics and Power Systems)”, Springer R. C. Dugan, Mark F. McGranghan, Surya Santoso, H. Wayne Beaty, “Electrical Power System Quality”, 2nd

Edition, McGraw Hill Publication Yang Xiao, “Communication and Networking in Smart Grids”, CRC Press

Module No.

Content Teaching

Hours

I

Introduction to Smart Grid Evolution of electric grid, concept of smart-grid, definitions, need of smart grid, functions of smart grid, opportunities & barriers of smart grid, difference between conventional & smart grid, concept of resilient & self healing grid, present development & international policies on smart grid. Smart Grid Technologies: Part 1 Introduction to smart meters, real time pricing, smart appliances, automatic meter reading(AMR), outage management system(OMS), plug in hybrid electric vehicles(PHEV), vehicle to grid, smart sensors, home & building automation, phase shifting transformers.

14

II

Smart Grid Technologies: Part 2 Smart-substations, substation automation, feeder automation. geographic information system(GIS), intelligent electronic devices(IED) & their application for monitoring & protection, smart storage like Battery, SMES, pumped hydro, compressed air energy storage, wide area measurement system(WAMS), phase measurement unit(PMU). Micro-grids and Distributed Energy Resources Concept of micro-grid, need & applications of micro-grid, formation of micro-grid, Issues of interconnection, protection & control of micro-grid. plastic & organic solar cells, thin film solar cells, variable speed wind generators, fuel cells, micro-turbines, captive power plants, integration of renewable energy sources.

13

III

Power Quality Management in Smart Grid Power Quality & EMC in Smart Grid, power quality issues of grid connected renewable energy sources, power quality conditioners for smart grid, web based power quality monitoring, power quality audit. Information and Communication Technology for Smart Grid Advanced metering infrastructure (AMI), home area network (HAN), neighborhood area network (NAN), wide area network (WAN). Bluetooth, zig-bee, GPS, Wi-Fi, Wi-Max based communication, wireless mesh network, basics of CLOUD Computing & cyber security for smart grid. Broad-band over power line (BPL). IP based protocols.

13

Semester VII





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References:

D.C.Reddy, “Biomedical Signal processing: Principle and technique,” TMH Gonzalez, R., and R. E. Woods. Digital Image Processing. Prentice-Hall,

3.F.M. Rangayyam, “Biomedical Signal Analysis: A case study approach,Wiley 2002.

Module No.

Content Teaching

Hours

I

Biomedical Signals and Images ECG: Cardiac electrophysiology, relation of electrocardiogram (ECG) components to cardiac events, clinical applications. Speech Signals: The source-filter model of speech production, spectrographic analysis of speech. Speech Coding: Analysis-synthesis systems, channel vocoders, linear prediction of speech, linear prediction vocoders. Imaging Modalities: Survey of major modalities for medical imaging: ultrasound, X-ray, CT, MRI, PET, and SPECT.

13

II

Fundamentals of Deterministic Signal and Image Processing Data Acquisition: Sampling in time, aliasing, interpolation, and quantization. Digital Filtering: Difference equations, FIR and IIR filters, basic properties of discrete-time systems, convolution. DTFT: The discrete-time Fourier transform and its properties. FIR filter design using windows. DFT: The discrete Fourier transform and its properties, the fast Fourier transform (FFT), the overlap-save algorithm, digital filtering of continuous-time signals. Sampling Revisited: Sampling and aliasing in time and frequency, spectral analysis.

14

III

Probability and Random Signals PDFs: Introduction to random variables and probability density functions (PDFs).Classification: Bayes' rule, detection, statistical classification. Estimating PDFs: Practical techniques for estimating PDFs from real data. Random signals I: Time averages, ensemble averages, autocorrelation functions, cross correlation functions. Random signals II: Random signals and linear systems, power spectra, cross spectra, Wiener filters.

13

Semester VIII





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Text Books:

M. S. Naidu and V. Kamaraju, “High Voltage Engineering”, Tata Mc-Graw Hill. References:

E. Kuffel and W. S. Zacngal, “High Voltage Engineering”, Pergamon Press. M. P. Chaurasia , “High Voltage Engineering”, Khanna Publishers. R. S. Jha, “High Voltage Engineering”, Dhanpat Rai & sons. C. L. Wadhwa, “High Voltage Engineering”, Wiley Eastern Ltd. M. Khalifa, ”High Voltage Engineering Theory and Practice”, Marcel Dekker. Subir Ray, “An Introduction to High Voltage Engineering”, Prentice Hall of India.

Module No.

Content Teaching

Hour

I

Level of high voltage, electrical insulation and dielectrics, importance of electric field intensity in the dielectrics. Break Down In Gases: Properties of atmospheric air, SF6 and vacuum ionization processes, Townsend’s criterion, breakdown in electronegative gases, time lags for breakdown, Streamer theory, Paschen’s law, break down in non-uniform field, breakdown in vacuum. Break Down In Liquid Dielectrics: Classification & Properties of liquid dielectric, characteristic of liquid dielectric, breakdown in pure liquid and commercial liquid.

14

II

Break Down In Solid Dielectrics: Classification & Properties of solid dielectrics, intrinsic breakdown, electromechanical breakdown, breakdown of solid, dielectric in Practice, breakdown in composite dielectrics. Generation of High Voltages and Currents: Generation of high direct current voltages, generation of high alternating voltages, generation of impulse voltages, generation of impulse currents, tripping and control of Impulse generator sources of overvoltage, standard lightning & switching wave shapes.

13

III

Measurement of High Voltages and Currents: Measurement of high direct current voltages, measurement of high alternating and impulse voltages, measurement of high direct, alternating and impulse currents, Cathode Ray Oscillographs for impulse voltage and current measurements. Non-Destructive Testing: Measurement of direct current resistively, measurement of dielectric constant and loss factor, partial discharge measurements. High Voltage Testing: Testing of insulators and bushings, testing of isolators and circuit breakers, testing of cables, testing of transformers, testing of surge arresters.

15

L–T–P

Credits: 4 L–T–P: 3–1–0 Semester VIII




85

EEE-415: ARTIFICIAL INTELLIGENCE & ITS APPLICATION TO POWER SYSTEM

Text Book: Timothy J. Ross, “Fuzzy Logic with Engineering Applications”, Wiley India. 2. Anupam Shukla, Ritu Tiwari, Rahul Kala, “Real Life Applications of Soft Computing”, CRC Press,

Taylor & Francis Group. Martin T Hagan, “Neural Network Design”, China Machine Press.

Reference Book: Kevin M. Passino and Stephen Yurkovich, “Fuzzy Control”, Addison Wesley Longman, Menlo Park, CA,

1998. Kevin Warwick, Arthur Ekwue and Raj Aggarwal, “Artificial Intelligence Techniques in Power

Systems”, Institution of Engineering and Technology, London, United Kingdom.

Module No.

Content Teaching

Hours

I

Artificial Neural Network Introduction of ANN, neuron model and network architecture, perceptron learning rules, signal and weight vector spaces, performance optimization, steepest decent algorithm, LMS algorithm, back-propagation algorithm, Chain rule, examples on back-propagation, Application of ANN on Power System ANN techniques for voltage control, ANN for power system protection system

15

II

Introduction to Fuzzy logic The case for imprecision, the utility of fuzzy systems, limitations of fuzzy systems, uncertainty and information, fuzzy sets and membership, chance versus fuzziness Classical Sets and Fuzzy Sets Classical sets, operations on classical sets, properties of classical (crisp) sets, fuzzy sets, fuzzy set operations, properties of fuzzy sets Classical Relations and Fuzzy Relations Cartesian product, crisp relations, cardinality of crisp relations, operations on crisp relations, properties of crisp relations, composition, fuzzy relations, cardinality of fuzzy relations, operations on fuzzy relations, properties of fuzzy relations, fuzzy cartesian product and composition, tolerance and equivalence relations, crisp equivalence relation, crisp tolerance relation, fuzzy tolerance and equivalence relations, value assignments, cosine amplitude, max–min method Application of Fuzzy Logic on Power System Fuzzy logic techniques for voltage control, fuzzy logic for power system protection system

15

III

Evolutionary Computation Evolutionary algorithms, Genetic algorithms (GA), solution, initial population genetic operators, fitness function, stopping condition, fitness scaling, rank scaling, proportional scaling, top scaling, selection, Roulette Wheel selection, stochastic universal sampling, rank selection, tournament selection, other selection methods, mutation, uniform mutation, Gaussian mutation, variable mutation rate, crossover, one-point crossover, two-point crossover, scattered crossover, intermediate crossover, heuristic crossover, other genetic operators, eliticism Application of GA on Power System GA for voltage control, GA for power system protection system

12

Semester VIII





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References:

Patranabis, D. “Telemetry Principles”, Tata Mc-Graw Hill. Schweber, W.L. “Data Communication” Mc-Graw Hill. Berder, M. “Telemetry Systems”.

Module No.

Content Teaching

Hours

I

Telemetry Principles: Introduction, classification, electrical telemetry systems, PLCC. Digital Modulation Techniques: Review of PCM, DPCM, DM, methods of binary data transmission, data formats, PSK, QPSK, FSK, probability of error, phase ambiguity resolution and differential encoding, error detection, error correction, error correction codes.

13

II

Data Handling System: Block schematic, Sensors, Signal conditioners, multiplexing, ADC- range and resolution, word Format, frame format, frame synchronizer codes, R.F. links, X24, RS422, RS423, RS232C interfaces, multi terminal configuration, multiplier & concentrator, data modems, data transmission over telephone lines. Data Acquisition Systems: Bit synchronizers, frame synchronizers, sub-frame synchronizers, PLL, SCADA.

14

III

Remote Control: Communication based processing control systems, operational security, pipeline control, power system control, Internet based tele-metering. Commands: Tone command system, Tone digital command system, ON/OFF command system. Satellite Telemetry: General considerations, TT&C services.

13

Semester VIII

Credits: 04 L–T–P: 3–1–0




87

EEE-417: INDUSTRIAL INSTRUMENTATION


Hour

I

Introduction to Industrial Instrumentation: Basic terminologies: Range, span, settling time dead zone, input impedance. Dynamic Characteristics: 1st order and second order instruments with step, ramp and sinusoidal input/ output characteristics. Strain Gauge: Derivation of gauge factor, strain gauge rosette, unbalanced wheat-stone bridge. Load Cell: Link type load cell, beam type load cell, ring type load cell and their sensitivities, Frequency response of link type load cell. Torque Measurements: Torquecell and its data transmission slip ring and radio telemetry. Temperature Measurements: Thermistor, resistance temperature detector (its construction, three wire and four wire method muller bridge), thermocouple, their relative comparison, cold junction compensation using AD590. LVDT: Phase compensation, phase sensitive demodulation.

13

II

Flow rate Measurements: General consideration of fluid flow rate meters, laminar flow, reynolds’s number, effect of temperature and pressure on flow rate measurement, calibration of flow meters. Head type: Orifice, venturi, flow nozzle, annubar analysis and calculation. Area flow meter: Rota meter and piston type. Mass flow meter: Coriolis, thermal, impeller type. electromagnetic type, ultrasonic type, vortex type, turbo magnetic type.

14

III

Pressure Measurement: Manometers:U-tube, well-type, inclined and dual tube manometers. Elastic Types: Bourdon gauge, diaphragm type, Bellows element type, pressure and D/P switches, D/P transmitters. Electronic Types: Capacitive, piezoresistive and resonator type. Vacuum Types: McLeod gauge, thermal conductivity gauge, ionization gauge. Level Measurement:Gauge glass, float, displacers and hydrostatic types ( their construction, errors and ranges, D/P type sensors and their installation arrangement), capacitive type, conductivity type magnetic level gauges ultrasonic type, microwave type, radiation type level gauges,level switches.

13

References: Alok Barua, “Fundamentals Of Industrial Instrumentation”, Wiley India Pvt Ltd. S K Singh, “Industrial Instrumentation And Control” 3 Edition, Tata McGraw - Hill Education (2008). K. Krishnamurthy, S Vijayachitra, K Krishnaswamy, “Industrial Instrumentation”, New Age International. D.Patranabis, “Principles of Industrial Instrumentation”, Tata McGraw Hill Publishing Ltd., New Delhi, 1999. Ernest O.Doebelin, “Measurement systems Application and Design, InternationalStudent Edition”, IV Edition,

McGraw Hill Book Company, 1999. R.K.Jain, “Mechanical and Industrial Measurements”, Khanna Publishers, New Delhi, 1999. B.C.Nakra and K.K.Chaudary, “Instrumentation Measurement and Analysis”, TataMcGraw Hill Publishing

Company Ltd., New Delhi, 1985. A.K.Sawhney, “A course in Electrical and Electronic Measurement andInstrumentation”, Dhanpat Rai and Sons,

New Delhi, 1999. Eckman D.P., ”Industrial Instrumentation” Wiley Eastern Limited, 1990. Liptak B.G.,“Instrument Engineers Handbook (Measurement)”, Chilton Book Co., 1994. P.Holman, “Experimental Methods for Engineers International Student Edition”,McGraw Hill Book Company,

1971. Considine; Douples M,“Process/Industrial Instruments and Control Handbook”, Magraw Hill. Becwith and Buch , “Mechanical Measurement”Pearson.

Semester VIII





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Module

No. Content

Teaching Hours

I

Introduction to Restructuring of power industry: Introduction, reasons for restructuring/deregulation of power industry, understanding the restructuring process-entities involved, levels of competition, market place mechanisms, introduction to issues involved in deregulation Fundamentals of Economics: Consumer behavior and its modeling, supplier behavior & its modeling, market equilibrium, short run & long run costs, market equilibrium, various costs of production Markets for electrical energy Market architecture, open electrical energy markets, managed spot market, comparison of various market models

13

II

Ancillary service management General description of some ancillary services, ancillary services management in various countries, reactive power management in some deregulated electricity markets Transmission congestion management Power wheeling, transmission open access, pricing of power transactions, transmission congestion management in deregulated environment

13

III

Transmission pricing Introduction, principle of transmission pricing, classification of transmission pricing methods, debated issues in transmission pricing Reliability analysis Generation, transmission and distribution reliability, Reliability and deregulation: conflict, reliability analysis, effects on the actual reliability, regulation of the market Reforms in Indian power sector Framework of Indian power sector, reforms initiative during 1990-1995, the availability based tariff (ABT), the electricity act 2003, open access issues, power exchange U.S. and European market evolution, Kyoto protocol

13

Text Books:

Daniel Kirschen, Goran Strbac, “ Fundamentals of power system economics” , John Wiley & sons limited

References: K. Bhattacharya, MHT Bollen and J.C Doolder, “Operation of Restructured Power Systems”, Kluwer

Academic Publishers, USA, 2001. Lei Lee Lai, “Power System restructuring and deregulation”, John Wiley and Sons, UK. 2001 Making competition work in electricity Sally Hunt, John Wiley & Sons, Inc., 2002.

Semester VIII





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Module

No. Content

Teaching Hours

I

Introduction to Power Quality Terms and definitions of power quality, long duration voltage variations, under voltage and sustained interruptions, short duration voltage variations, sag, swell, voltage imbalance; notching D C offset, waveform distortion; voltage fluctuation; power frequency variations. Voltage Sag: Sources of voltage sag: motor starting, arc furnace, fault clearing etc; estimating voltage sag, performance and principle of its protection; solutions at end user level- isolation transformer, voltage regulator, static UPS, rotary UPS, active series compensator.

13

II

Electrical Transients Sources of transient over voltages- atmospheric and switching transients- motor starting transients, power factor correction, power factor penalty, capacitor switching transients, ups switching transients, neutral voltage swing, devices for over voltage protection. Harmonics Causes of harmonics; current and voltage harmonics: measurement of harmonics; effects of harmonics on – transformers, AC motors, capacitor banks, cables, and protection Device, harmonic mitigation techniques.

13

III

Measurement and Solving of Power Quality Problems Power quality measurement devices- harmonic analyser , transient disturbance analyser, wiring and grounding tester, flicker meter, oscilloscope, multi-meter Introduction to Custom Power Devices Network reconfiguration devices, load compensation and voltage regulation using DSTATCOM, protecting sensitive loads using DVR, unified power quality conditioner (UPQC)

13

Text Books:

Roger C Dugan, McGrahan, Santoso & Beaty, “Electrical Power System Quality” McGraw Hill Arinthom Ghosh & Gerard Ledwich, “Power Quality Enhancement Using Custom Power Devices”,

Kluwer Academic publishers C. Sankaran, “ Power Quality” CRC Press. Alexander Kusko, Marc T.Thompson,”Power quality in electrical systems”, Mcgraw Hill

Semester VIII





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Hour

I

Indian Energy Scenario : Sectoral energy consumption; domestic, industrial and other sectors, energy needs of growing economy, energy intensity, long term energy scenario, energy pricing, Energy security, energy conservation and its importance, energy strategy for the future, energy conservation Act 2001 and its features. Basics of Energy- its various forms and conservation : Electricity basics; Direct current and alternative currents, electricity tariff, analysis of existing buildings setting up an energy management program and use management electricity saving techniques

13

II

Energy Management & Audit: Definition, energy audit, need, types of energy audit, energy management (audit) approach-understanding energy costs, bench marking, energy performance, matching energy use to requirement, maximizing system efficiencies, optimizing the input energy requirements, fuel and energy substitution, energy audit instruments and metering Financial Management : Investment-need, appraisal and criteria, financial analysis techniques; simple, payback period, return on investment, net present value, internal rate of return, cash flows, risk and sensitivity analysis; financing options, energy performance contracts and role of energy service companies (ESCOs)

14

III

Energy Monitoring and Targeting: Defining monitoring & targeting, elements of monitoring & targeting, data and information analysis techniques, production, cumulative sum of differences (CUSUM), energy management information systems (EMIS) Energy Efficiency in Utilities and systems: Energy efficiency pumps and fans, lighting system, motors belts and drives, refrigeration system.

13

References:

W. F. Kenny , ‘Energy Conservation In Process Industry Amlan Chakrabarti, ‘Energy Engineering and Management’,- Prentice hall India 2011 CB Smith, Energy Management Principles,- Pergamon Press, New York, Bureau of energy efficiency, Hand outs New Delhi . Handbook on Energy Efficiency , TERI, New Delhi, 2009

Semester VIII





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References:

Andra Gabdel, "A Handbook for Engineers and Economists". 2. A. Mani , "Handbook of Solar radiation Data for India". 3. Peter Auer, "Advances in Energy System and Technology". Vol. 1 & II Edited byAcademic Press. 4. F.R. the MITTRE, "Wind Machines" by Energy Resources and Environmental Series. 5. Frank Kreith, "Solar Energy Hand Book".

Module No.

Content Teaching

Hours

I

Introduction Various non-conventional energy resources- Introduction, availability, classification, relative merits and demerits. Solar Cells: Theory of solar cells. solar cell materials, solar cell power plant, limitations. Solar Thermal Energy: Solar radiation flat plate collectors and their materials, applications and performance, focussing of collectors and their materials, applications and performance; solar thermal power plants, thermal energy storage for solar heating and cooling, limitations.

13

II

Geothermal Energy: Resources of geothermal energy, thermodynamics of geo-thermal energy conversion-electrical conversion, non-electrical conversion, environmental considerations. Magneto-hydrodynamics (MHD): Principle of working of MHD Power plant, performance and limitations. Fuel Cells: Principle of working of various types of fuel cells and their working, performance and limitations. Thermo-electrical and thermionic Conversions: Principle of working, performance and limitations.

14

III

Wind Energy: Wnd power and its sources, site selection, criterion, momentum theory, classification of rotors, concentrations and augments, wind characteristics. performance and limitations of energy conversion systems. Bio-mass: Availability of bio-mass and its conversion theory. Ocean Thermal Energy Conversion (OTEC): Availability, theory and working principle, performance and limitations. Wave and Tidal Wave: Principle of working, performance and limitations. Waste Recycling Plants

13

Semester VII





92

EEE-462: INSTRUMENTATION

References:

Doeblin: Measurement system, Tata Mc Graw Hill Nakra: Instrumentation, Measurement and Analysis, TMH. Cromwek, etal: Biomedical Instrumentation and Measurement, PHI Patranabis: Sensors and Transducers, PHI

Module No.

Contents Teaching

Hours

I

Generalized measurement systems – Concept, Functional elements

Transducers – Classification, Basic requirements, Selection criteria

Principles of operation of resistive, Inductive, Capacitive, Piezoelectric, Ultrasonic,

Photoelectric transducers.

Signal conditioners and display devices – Bridges, Operational amplifier,

Instrumentation amplifier, Filters, LED, LCD, Nixie tube, Magnetic tape recorder,

Digital recorder.

14

II

Measurement of displacement, Force, Acceleration, Velocity and Torque – Strain

Gauge, Load cell, LVDT, Tachometer.

Measurement of flow, Level – Electromagnetic, Ultrasonic flow-meter, Hot wire

anemometer, Capacitive and Ultrasonic method of measuring level.

Measurement of pressure – Vacuum gauge, Bourdon tube

Measurement of temperature – RTD, Thermistor, Thermocouple, Digital

Oxygen analyzer, Measurement of pH, Humidity/Moisture, Gas-chromatography.

14

III

Bio-potentials and their Measurement – ECG and EEG, Ultrasonic imaging

Measurement of blood pressure, Body temperature, Dialyser

Recent improvements – Smart sensor, Fibre optic sensors

Introduction of microprocessor based instrumentation

12

Credits: 4 L–T–P: 3–1–0 Semester VII




93

EEE-481: ELECTRICAL DRIVES LAB

Module No.

Content Teaching Hours

I

1. To study speed control of separately excited dc motor by varying armature voltage using single-phase fully controlled bridge converter.

2. To study speed control of separately excited dc motor using single-phase dual converter (Static Ward-Leonard Control).

3. To study speed control of separately excited dc motor by varying armature voltage using single phase half controlled bridge converter.

4. To study closed loop control of separately excited dc motor. 5. To study speed control of separately excited dc motor using MOSFET/IGBT chopper. 6. To study speed control of single-phase induction motor using single phase ac voltage

controller. 7. To study speed control of three phase induction motor using three phase ac voltage

controller. 8. To study speed control of three phase induction motor using three phase current

source inverter. 9. To study speed control of three phase induction motor using three phase voltage

source inverter. 10. To study speed control of three phase slip ring induction motor using static rotor

resistance control using rectifier and chopper. Simulation Based Experiments (using MATLAB/ Simulink) 1. To study transient response of separately excited dc motor. 2. To study speed control of separately excited dc motor using single phase full / half

controlled bridge converter in discontinuous and continuous current modes. 3. To study speed control of separately excited dc motor using chopper control in

motoring and braking modes. 4. To study transient response of three phase induction motor. 5. To study speed control of three phase induction motor using (a) constant/V/F

control (b) constant voltage and frequency control.

Semester VII





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EEEEEE--448844:: EELLEECCTTRRIICCAALL IINNSSTTRRUUMMEENNTTAATTIIOONN LLAABB

Module No.

Content Lab

Hours

I

LIST OF EXPERIMENTS: Measurement of displacement using LVDT. Understand the features and hardware structure of an automation

controller. Create a ladder logic based digital control system with discrete

inputs, outputs. Create a ladder logic based digital control system with discrete

controls, timers and counters. Perform a lab to create a velocity algorithm based proportional

integral derivative control (PIDE control). Perform ratio control and feed forward control with a PIDE loop. Perform and understand a cascade based control with a PIDE loop. Perform position proportional control for a motorized valve

through simulation. Perform and simulate a split range proportional control for

heat/cool cycle. Create and simulate a ramp controlled temperature control system

with ramp soak control strategy. Create a Boolean logic and simulate a simple pump control system

in functional block diagram (FBD). Create a hardware based HMI and create visualization for a pump

control system. Create a Pc based visualization for a pump control system. Interfacing an automation controller with a human machine

interface.

24

Semester VIII


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