Sylabus of Ec

8/11/2019 Sylabus of Ec

1/61

B.Tech (EC)

w.e.f. Session: 2012-2013

DEPARTMENT OF ELECTRONICS & COMMUNICATION ENGINEERING

Institute of Engineering & Technology

COURSE STRUCTURE


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B.Tech. (Electronics & Communication Engineering) (w.e.f. Session-2012-13)

DEPARTMENT OF ELECTRONICS & COMMUNICATION ENGINEERING, Institute of Engineering & Technology

First Semester

S.

NO.CODE SUBJECT

TEACHING SCHEMECREDITS

CONTACT HRS

/WEEKL T P

THEORY

1. AHM101 Mathematics - I 3 1 0 4 42. AHP101 Engineering Physics - I 2 1 0 3 3

3. CSE101Fundamentals of Computer

& Programming2 0 0 2 2

4.MEE102/

EEE101

Basic Thermodynamics/

Electrical Engineering3 1 0 4 4

5.AHC101/

MEE101

Engineering Chemistry/

Manufacturing Process3 1 0 4 4

6.MEE103/

ECE101

Applied

Mechanics/Electronics

Engineering

3 1 0 4 4

PRACTICALS

7. AHE181 Communication Skills - I 0 0 3 2 3

8.MEE182/MEE181

Engineering Drawing/EWSPractice Lab

0 0 3 2 3

9.AHC181/

AHP181Chemistry Lab/Physics Lab 0 0 2 1 2

10. CSE181Computer Programming

Lab0 0 2 1 2

11.MEE183/

EEE181

Applied Mechanics Lab/

Electrical & Electronics Lab0 0 2 1 2

12. ECE197 General Proficiency 0 0 0 1 0

TOTAL 16 5 12 29 33

Second Semester

S.

NO.CODE SUBJECT


CONTACT HRS

/WEEKL T P

THEORY

1. AHM102 Mathematics - II 3 1 0 4 4

2. AHP102 Engineering Physics - II 2 1 0 3 3

3. CSE102Problem Solving using

Computers2 0 0 2 2

4.EEE101/

MEE102

Electrical Engineering/

Basic Thermodynamics3 1 0 4 4

5.MEE101/

AHC101

Manufacturing Process/

Engineering Chemistry3 1 0 4 4

6. ECE101/MEE103

Electronics Engineering/Applied Mechanics

3 1 0 4 4

PRACTICALS

7. AHE182 Communication Skills - II 0 0 3 2 3

8.MEE181/

MEE182

EWS Practice Lab

/Engineering Drawing0 0 3 2 3

9.AHP181/

AHC181Physics Lab/Chemistry Lab 0 0 2 1 2

10. CSE182 Problem Solving Lab 0 0 2 1 2

11.EEE181/

MEE183

Electrical & Electronics

Lab/Applied Mechanics Lab0 0 2 1 2

12. ECE198 General Proficiency 0 0 0 1 0

TOTAL 16 5 12 29 33


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Third Semester

S.

NO.CODE SUBJECT


CONTACT HRS

/WEEKL T P

THEORY

1 AHM 201 Mathematics III 3 1 0 4 42 CEE 201/

AHE 201

Environmental Studies /

Ethics & Values

2 0 0 2 2

3 ECE 201 Electro Magnetic Field

Theory

3 1 0 4 4

4 ECE 202 Digital Electronics 3 1 0 4 4

5 ECE 205 Semiconductor Materials &

Devices

3 1 0 4 4

6 EEE 201 Network Analysis &

Synthesis

3 1 0 4 4

PRACTICALS

1 AHE 281 Soft Skills I 0 0 2 1 2

2 ECE 281 Digital Electronics Lab 0 0 2 1 2

3 ECE 282 Electronics Lab 0 0 2 1 2

4 EEE 281 Network Lab 0 0 2 1 2

5 ECE 297 GP 0 0 0 1 0

TOTAL 27 30

Fourth Semester

S.

NO.CODE SUBJECT


CONTACT HRS

/WEEKL T P

THEORY

1 AHM 202 CBNST 3 1 0 4 4

2AHE 201/

CEE 201

Ethics & Values/

Environmental Studies2 0 0 2 2

3 ECE 204 Signals & Systems 3 1 0 4 4

4 ECE 203Electronic Devices &

Circuits3 1 0 4 4

5 ECE 208Electronic Measurement &

Instrumentation3 1 0 4 4

6 ECE 206Microprocessors &

Applications3 1 0 4 4

PRACTICALS

1 AHE 282 Soft Skills II 0 0 2 1 2

2 ECE 283 Electronics Workshop & PCBLab 0 0 2 1 2

3ECE 288

Electronic Measurement &

Instrumentation Lab0 0 2 1 2

4 ECE 286 Microprocessor Lab 0 0 2 1 2

5 ECE 298 GP 0 0 0 1 0

TOTAL 27 30


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Fifth Semester

S.

NO.CODE SUBJECT


CONTACT HRS

/WEEKL T P

THEORY

1 AHS 301/AHS 302 Industrial Psychology/Industrial Economics 2 0 0 2 2

2 AHE 301/

AHS 303

Technical Writing

/Principle of Management

2 1/0 0 3/2 3/2

3 ECE 301 Communication

Engineering

3 1 0 4 4

4 ECE 302 Linear Integrated Circuit 3 1 0 4 4

5 ECE 303 Antenna & Wave

Propagation

3 1 0 4 4

6 ECE 304 Control System 3 1 0 4 4

PRACTICALS

1 AHE 381 Soft Skills III 0 0 2 1 2

2 ECE 381 Communication Lab 0 0 2 1 2

3 ECE 382 Integrated Circuit Lab 0 0 2 1 2

4 ECE 383 Control System Lab 0 0 2 1 2

5 CSE 389 Advance Programming Lab 0 0 2 1 2

6 ECE 397 GP 0 0 0 1 0

TOTAL 27/26 31/30

Sixth Semester

S.

NO.CODE SUBJECT


CONTACT HRS

/WEEKL T P

THEORY

1AHS 302/

AHS 301

Industrial Economics/

Industrial Psychology 2 0 0 2 2

2AHS 303/

AHE 301

Principle of Management /

Technical Writing 2 0/1 0 2/3 2/3

3 ECE 305 Digital Communication 3 1 0 4 4

4 CSE 371Computer Architecture and

Application 3 1 0 4 4

5 ECE 306 Microwave Engineering. 3 1 0 4 4

6 ECE 307 VLSI Technology & Design 3 1 0 4 4

PRACTICALS

1 AHE 382 Soft Skills IV 0 0 2 1 2

2 ECE 384 Digital Communication Lab 0 0 2 1 23 ECE 385 Simulation Lab 0 0 2 1 2

4 ECE 386 Microwave Lab 0 0 2 1 2

5 ECE 387 CAD Lab 0 0 2 1 2

6 ECE 388 Colloquium 0 0 2 1 2

7 ECE 398 GP 0 0 0 1 0

TOTAL 27/28 32/33

Note: At the end of sixth semester, each student has to undergo an industrial training of minimum

04 weeks, which will be evaluated as ECE 483 in the seventh semester.


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Seventh Semester

S.

NO.

CODE SUBJECT TEACHING SCHEME CREDITS CONTACT HRS

/WEEKL T P

THEORY

1 ECE 401 Data Networks 3 1 0 4 42 ECE 402 Digital Signal Processing 3 1 0 4 4

3 Elective-I 3 1 0 4 4

4 Elective-II 3 1 0 4 4

5 Open Elective 3 1 0 4 4

PRACTICALS

1 ECE 481 Digital Signal Processing Lab 0 0 2 1 2

2 ECE 482 Project-I 0 0 6 3 6

3 ECE 483 Industrial Training 0 0 2 1 2

4 ECE 497 GP 0 0 0 1 0

TOTAL 26 30

Eight Semester

S.

NO.CODE SUBJECT


CONTACT HRS

/WEEKL T P

THEORY

1 ECE 403 Optical Communication &

Networks

3 1 0 4 4

2 ECE 404 Wireless Communication 3 1 0 4 4

3 Elective-III 3 1 0 4 4

4 Elective-IV 3 1 0 4 4

PRACTICALS

5 ECE 484 Optical Communication Lab 0 0 2 1 2

6 ECE 485 Wireless Communication

Lab

0 0 2 1 2

7 ECE 486 Project-II 0 0 14 7 14

8 ECE 498 GP 0 0 0 1 0

26 34


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Subject Code Elective-I

ECE 406 Artificial Neural Network

ECE 407 TV & Satellite Communication

ECE 408 Radar Engineering

Subject Code Elective-II

ECE 409 Tele-communication Switching

ECE 410 Multimedia Communication

ECE 411 Mobile Computing

Subject Code Elective-III

ECE 413 Digital System Design

ECE 414 MEMS

ECE 415 Embedded Systems

Subject Code Elective-IV

ECE 416 Speech Processing

ECE 417 Multi Carrier Communication

ECE 418 Digital Image Processing


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DDDEEETTTAAAIIILLLEEEDDDSSSYYYLLLLLLAAABBBUUUSSS


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AAHHMM110011::MMAATTHHEEMMAATTIICCSSII

Module

No.Content

Teaching

Hours

I

Differential Calculus: Successive Differentiation, Leibnitz theorem, Partial

Differentiation, Eulers 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, Lagranges method ofUndetermined multipliers.

14

II

Ordinary Differential Equations: Introduction, variables separable & linear

form of I order and I degree ODEs, Linear differential equations of nthorder

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:

Behrouz A. Forouzan and Richard F. Gilberg , Computer Science A structured Programming

Approach Using C, Cengage Learning, 2007.

K. N. King, C Programming - A Modern Approach, 2nd Edition, W. W. Norton, 2008.

Kernighan and Ritche, The C programming Language, PHI , 1996.

P. Dey, M. Ghosh, Programming in C, Oxford University Press ,2009 .

Credits: 04 LTP: 310Semester I


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AAHHPP110011::EENNGGIINNEEEERRIINNGGPPHHYYSSIICCSS--II

Module

No.Content

Teaching

Hours

I

1. Relativistic Mechanics: Basic Concepts, Inertial & non-inertial frames,

Galilean Transformations, Michelson- Morley experiment, Einsteins postulates,

Lorentz transformation equations, Length contraction, Time dilation, Addition

of velocities, Variation of mass with velocity, Mass energy equivalence.

2. Solid State Physics : Bands in solids, Insulators, conductors and

semiconductors, electron and hole conduction, the band structure of

semiconductors, Donor and acceptor impurities, Fermi level and Fermi energy,

impurity level in N and P type semiconductors, p-n junction fabrication, effective

mass, electron and hole concentration at equilibrium, temperature dependence

of carrier concentration, conductivity and mobility, Hall effect insemiconductors.

10

II

1. Interference: Light Fundamentals, Interference of light, Principle of

superposition and coherence of light, Interference due to division of wavefront

and division of amplitude, Theory of biprism experiment, Interference in

parallel thin films, wedge shaped films, Newtons rings and MichelsonsInterferometer.

2. Diffraction: Diffraction of light, Fresnel and Fraunhofer diffraction,

diffraction due to single slit and N-slits, Plane diffraction grating, absent spectra

with grating and dispersive power of grating, Rayleighs criterion and resolving

power of grating and application.

10

III

1. 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, Fresnels theory ofoptical activity, Specific rotation, Lorentz half shade and Biquartz polarimeters.

2. Laser: Spontaneous and stimulated emission of radiation, Einsteinscoefficients, Principle of laser, Ruby laser, Semiconductor laser, coherence,

characteristics of laser beam and coherence property, laser applications.

3. FiberOptics:Introduction, Principle of optical fiber, Classification of fibers,

acceptance angle and acceptance cone, Numerical aperture, Propagation

mechanism and attenuation in optical fiber.

10

References:

Aurthur Beiser, Concepts of Modern Physics, TMH. Robert Resnick , Introduction to Special theory of relativity, Wiely & Sons

Ajoy Ghatak , Optics, TMH

Brijlal and Subramaniam , Optics, S. Chand

Anuradha De. , Optical Fibre & Laser, New Age

Resnick, Halliday and Walker , Fundamental of Physics, Wiely

S.O. Pillai , Solid State Physics, New Age International Publication , 5thedition

C. Kittel : Solid State Physics, Wiley Eastern, 7thedition.

M.A.Wahab : Solid State Physics, Narosa Publication



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CCSSEE110011::FFUUNNDDAAMMEENNTTAALLSSOOFFCCOOMMPPUUTTEERRSS&&PPRROOGGRRAAMMMMIINNGG

Module

No.Content

Teaching

Hours

I

Introduction: Digital & Analog Computers, Major components of a digital

computer, Word length, processing speed, Computer classification, Batch

processing, Multiprogramming & Multi user systems, Computer network.

Number System: Binary number system, Conversion from binary number to

decimal & vice versa, Addition & subtraction of binary numbers, Use of

complements to represent negative numbers, Binary Fraction to decimal

fraction & vice versa, Hexadecimal and Octal number systems. Decimal, Binary,

Octal, Hexadecimal numbers and their inter-conversions; Representation of

information inside the computers. Integer representation, Signed 1's and signed

2's complement representation, Floating point representation.

Introduction to Programming: Programming languages: Generations oflanguages, machine level, assembly and high level languages, compiler,

assembler, interpreter, Programming fundamentals, Algorithm and flow charts .

7

II

Introduction to the C Language: Structure of a C program; Standard Input-

Output in C, Data Types ,Storage classes. Operators and Expressions, Type

conversion, .Non-formatted Input and Output and Formatted Input and Output

functions.

Control Statements: Conditional Operator, The switch statement, while

Construct, Looping or iteration using for loop, do-while construct, goto

statement, special control statements, Nested loops.

7

III

Array: Representation of Single and Multidimensional Arrays, Address

calculation, Operations on arrays, Application of arrays.

Functions:Function Declaration and definition, call by value and by reference,

Scope Rules, Types: User defined and system defined, passing array to functions.

7

References:

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

Approach Using C,C Language Learning ,2007

K. N. King: C Programming A Modern Approach, W. W. Norton, 2ndEdition, 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



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EEEEEE110011::EELLEECCTTRRIICCAALLEENNGGIINNEEEERRIINNGG

Module

No.

Content Teaching

Hours

I

1. D C Circuit Analysis and Network Theorems:

Circuit Concepts, Active and passive elements, Electrical energy sources, linear

& non-linear network, unilateral and bilateral elements, source transformation.

Kirchhoffs laws, loop and nodal methods of analysis, star-delta transformation,

Network Theorems: Superposition Theorem, Thevenins Theorem, NortonsTheorem, Maximum Power Transfer Theorem.

2. Steady- State Analysis of Single Phase AC Circuits:

AC Fundamentals: waveforms or wave shapes, average and effective values,

form and peak factors, concept of phasor, phasor algebra & phasor

representation. Analysis of series, parallel and series-parallel RLC Circuits:

complex power, power triangle, power factor, introduction to resonance in

series and parallel circuits (numerical problems).

13

II

1. Three Phase AC Circuits & Measuring Instruments:Generation & advantages of three phase system, phase sequence, star and delta

connections, balanced supply and balanced load, line and phase voltage/current

relations, three-phase power and its measurement (simple numerical

problems). Classification of instruments, construction and working principles of

PMMC and MI type instruments and their range extension, single phase

dynamometer wattmeter and induction type energy meter.

2. Magnetic Circuit & Single Phase Transformer

Analogy between electric & magnetic circuits, magnetic leakage & fringing, B-H

curve, hysteresis and eddy current losses, concept of mutual and self induction

Principle of operation, construction, e .m. f. equation, equivalent circuit, power

losses, efficiency, introduction to auto transformer

13

III

Introduction to electro mechanical energy conversion, DC machines:

Construction & working principle, types, e.m.f. equation and torque equation,

applications of dc motors.

Three Phase Induction Motor: Construction & working principle, types, Principle

of operation, Concept of slip, applications. Single Phase Induction motor:

Principle of operation and introduction to methods of starting, applications.

Three Phase Synchronous Machines: Principle of operation of alternator and

synchronous motor and their applications.

2. Introduction to Power Generation & Power System:

Introduction to generation of Electrical Power (conventional and non-

conventional sources), Introduction to Wind energy and solar energy, layout of

thermal & hydro power plant, General layout of electrical power system and

functions of its elements, standard transmission and distribution voltages,

concept of grid (elementary treatment only)

14

References:

V. Del Toro , Principles of Electrical Engineering, Prentice Hall International

I.J. Nagarath , Basic Electrical Engineering,TMH

D.E. Fitzgerald and A. Grabel Higginbotham, Basic Electrical Engineering, TMH

T.K. Nagsarkar and M.S. Sukhija, Basic Electrical Engineering, Oxford University Press.

H. Cotton , Advanced Electrical Technology , Wheeler Publishing

W.H. Hayt and J.E. Kennely, Engineering Circuit Analysis, TMH.

S.N.Singh, Electrical power generation, transmission & distribution , Eastern Economy

Edition.



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MMEEEE110011::MMAANNUUFFAACCTTUURRIINNGGPPRROOCCEESSSS

Module

No.

ContentTeaching

Hours

I

Engineering materials, composition, properties and their applications:

Materials composition, mechanical properties & their applications of

engineering materials-plane carbon steel, alloy steel-tool steel and stainless

steel, various non ferrous metals and alloys e.g. Cu alloy-brass, bronze, , Al alloy-

Duralumin.

Introduction to Rubber, Plastics, Composite materials and their applications.

Machining Processes: Working principles and applications of machining

processes-Lathe Machine, Drilling Machine and Grinding Machine, various tools

used in the operations of these machines.

14

II

Metal Forming Processes: Introduction to Hot & Cold working processes, eg.

Forging, Rolling, Extrusion and Drawing.

Casting Processes: Introduction to various patterns and their allowances.

Molding sand and their properties, preparation of sand moulds, basic conceptsof core, gating, runner & riser system, defects in sand casting & their remedies.

17

III

Fabrication processes: Basic concept of Welding and its classification /

operations. Introduction to Arc welding & Gas welding, types of flames.

Introduction to Soldering, Brazing and their applications.

Advanced Machining Processes: Introduction to advanced machining

processes: Ultrasonic machining, Electrochemical machining, Electric Discharge

machining, Laser Beam machining and their applications.

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, PHI, New Delhi

Jain RK, Production Technology, Khanna Publishers, New Delhi.

Richard L and Little, Welding and Welding Technology, TMH, 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, TMH, 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 , New Delhi.



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EECCEE110011::EELLEECCTTRROONNIICCSSEENNGGIINNEEEERRIINNGG

Module

No.

ContentsTeaching

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; Photo-

diode 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 JFET; Shockleys 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; 1s and 2s complement ,

Subtraction using 2s 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 varia bles with dont carecondition; 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.



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AAHHEE118811::CCOOMMMMUUNNIICCAATTIIOONNSSKKIILLLLII

Module

No.

ContentTeaching

Hours

I

1. Hurdles of the Path and Route Map

Language Drills :

Singular & Plural, countable & uncountable, Parts of speech, Tense-shift

Routine Expressions :

Greeting, Introducing yourself and others, Query formal/ Informal, Replies

Positive, Neutral and Negative, Expressing surprise, regret, apology, seeking

information.

Tenses through simple presentations :

For Example:

Present : Introduction, Routine, My City, My Value System etc.

Past : Describing events marriage party, picnic, conference etc.

Experience, Process, Movie etc.

Future : Goal of my life, India of my dreams etc.We will have to return to our roots

Cloning will make us immortal

Technological Advancement : Man is on the verge of becoming Machine/God.

2.

Virtual Speaking

Extempore : 1 minute description of objects in the room.

Picture Description :

Flow of the idea, organization of the message.

Crowded Pictures

Abstract Pictures

Open ended relationship based:(i) Mother(in Business suit) rushing outside while child is

crying, goods in home are scattered

(ii) Sibling Fight

(iii) Joint family having fun

Bars, Pie-charts, Tables

Cook a Story : Ways of developing paragraph in prose

Jumbled Pictures

One Person One Sentence

Tie up the loose threads

3.

Rapid Vocabulary & its Usage:

Roots & word formation, commonly misused words, words with shades of

meaning, Phrasal Verbs, Terms used as Noun & Verb, Noun & Adjectives.

4. Speak Well

Ambiguity in conversation/ comment, Reason & ways to root it out, commonly

mispronounced words Phonetic symbols / Pronunciation Drills

5.

Comprehension and Conversation

Listening: Active & Passive listening; listening with Empathy, Listening

Comprehension

Reading Comprehension (pre-discussion and post discussion)

(From Everyday English Pg. 99 103)Telephonic Conversation :

Greetings, putting the phone on hold, inquiry about the caller.

Simple Role Play

Credits: 2 LTP: 0-0-3Semester I


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MMEEEE118811::EEWWSSPPRRAACCTTIICCEELLAABB

Module

No.

ContentTeaching

Hours

I

Machine Shop

1. To make a step turning job from mild steel round bar as per drawing.

2. To make a job for taper turning, grooving & threading from mild steel round

bar as per drawing.

3. Study of practices on Shaper.

4. Demonstration of CNC Lathe operation.

5. Demonstration of Milling Machine operation

Sheet Metal Shop

6. To make a rectangular tray as per drawing

7. To make a funnel with soldering

Carpentry Shop

8. To make a flat wooden block by using jack plane as per drawing.

9. To make a half lap corner joint as per drawing.10. To make a wooden round block by using wood working lathe.

Welding Shop

11. To prepare a Butt-joint by electric arc welding.

12. To prepare a Lap-joint by electric arc welding.

13. To prepare a joint by gas welding.

Fitting Shop

14. To make a rectangular M.S. flat job as per drawing.

15. To make a simple and tapped hole in M.S. plate as per drawing.

16. To make a male-female joint as per drawing.

Black-smithy Shop

17. To make a nail as per sketch.

Foundry Shop

18. To make a pattern from wood for a hollow cylinder as per drawing.

19. To make a casting using a core as per given pattern.



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AAHHPP118811::PPHHYYSSIICCSSLLAABB

Module

No.

ContentTeaching

Hours

I

1. To determine the wavelength of monochromatic light by Newtons rings.

2. To determine the wavelength of monochromatic light with the help of

Fresnels biprism.

3. To determine the focal length of two lenses by nodal slide and to locate the

position of cardinal points.

4. To determine the specific rotation of cane sugar solution using polarimeter.

5. To determine the wavelength of spectral lines using plane transmission

/diffraction grating.

6.Measurement of wavelength of laser (He- Ne) light using single slit

diffraction.

7. To determine the specific resistance of the material of a given wire usingCarey Fosters bridge.

8. To study the variation of magnetic field along the axis of current carrying

circular coil and then to estimate the radius of the coil.

9. To calibrate the given ammeter and voltmeter by potentiometer.

10. To study the Hall effect and determine Hall coefficient, carrier density and

mobility of a given semiconductor.

11. To determine the energy band gap of a given semiconductor material.

12 To determine E.C.E. of copper using Tangent or Helmholtz galvanometer.

13. To draw hysteresis curve of a given sample of ferromagnetic material and

then to determine the magnetic susceptibility and permeability of the given

specimen.14. To determine the ballistic constant of a ballistic galvanometer.

15. Measurement of fiber attenuation and aperture of optical fiber.

16. To determine high resistance by leakage method.



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CCSSEE118811::CCOOMMPPUUTTEERRPPRROOGGRRAAMMMMIINNGGLLAABB

Module

No.

ContentTeaching

Hours

I

(1) Arithmetic operations

a. WAP to perform arithmetic operation over the variables.

b. WAP to calculate area of the circle.

c. WAP to find the sum of digits of a number.

d. WAP to find the reverse of a string..

e. WAP to implement perimeter of a rectangle

(2) Function

a. WAP to call a function by reference.

b. WAP to call a function by value.

c. WAP to calculate factorial of a number.

d. WAP to print a table of a user define number.

e. WAP to generate Fibonacci Series

(3) Pointer

a. WAP to display the contents of 2D array using pointer.

b. WAP to sort an array in ascending order using dynamic

memory allocation and pointers.

(4) Microsoft office

a. MS Word Introduction.

b. MS Excel Introduction

c. MS PowerPoint Introduction.

d. MS Paint brush Introduction.

(5) pattern

a.

WAP to design the following pattern

* * * * * * * * * *

* * * * * * * *

* * * * * *

* * * *

* *

24



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EEEEEE118811::EELLEECCTTRRIICCAALL&&EELLEECCTTRROONNIICCSSLLAABB

Module

No.Content

Teaching

Hours

I

1. To verify the Thevenins theorem (DC circuits).

2. To verify the maximum power transfer theorem (DC circuits). Also draw

graph between power and load resistance.

3. To verify the Superposition Theorem (DC circuits).

4. 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.

5. To determine the V-I characteristics of a semiconductor diode. Also

calculate forward and reverse static and dynamic resistances.

6. 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).

7. To study single phase (induction type) energy meter.

8. To study various logic gates such as OR, AND, NOT, NAND, NOR.

9. Study of CRO and measurement of voltage and frequency using CRO.

10.V-I characteristics of Zener diode.

11.Identification of active and passive components.

12.V-I characteristics of bipolar junction transistor in common base mode.



19/61



AAHHMM110022::MMAATTHHEEMMAATTIICCSS--IIII

Module

No.

ContentTeaching

Hours

I

Multiple Integrals: Double and Triple Integrals, Change of order of

integration, Change of variables, Beta and Gamma functions. Applications to

Dirichlet integrals.

Vector Calculus: Gradient, Divergence and curl ; their geometrical and

physical significance, Vector Identities, Line, surface and volume integrals,

Independence of path, Green, Gauss divergence and Stokes theorem (withoutproof).

15

II

Partial Differential Equations : Solution of I order Lagranges linear PDEs,Linear PDEs with constant coefficients, Classification of II order PDEs, Method

of separation of variables, One dimensional wave equation, DAlemberts

solution, Heat conduction equations up to two dimensions.

11

III

Laplace Transform: Properties of Laplace transform, Existence theorem,

Laplace transform of derivatives and integrals, Unit step and Dirac deltafunction, periodic functions, Partial Fractions, Properties of inverse Laplace

transform, convolution theorem. Application to ODEs and integral equations.

13

References:

E. Kreyszig ,Advanced Engg. Mathematics, John Wiley & Sons, 9thEdition.

Peter V.ONeil,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, New Delhi.

Credits: 04 LTP: 310Semester II


20/61



AAHHPP110022::EENNGGIINNEEEERRIINNGGPPHHYYSSIICCSSIIII

Module

No.Content

Teaching

Hours

I

1. Wave Mechanics: Wave model, Wave- particle duality, Photoelectric effect,

de-Broglie hypothesis, Phase and group velocities: wavepacket, Heisenbergsuncertainty principle and its applications, Wave function and its normalisation,

Schrdingers wave equation : time dependent and time independent wave

equations, particle in one dimensional potential box.

2. X-ray Diffraction: Diffraction of X-rays by crystal planes, Braggs law, Braggs

spectrometer, Comptons effect.

10

II

1. Superconductivity: Temperature dependence of resistivity in

superconducting materials, Meissner effect, Type I and Type II superconductors,

Temperature dependence of critical field, BCS theory (qualitative), Londons

equation, Landon penetration depth, Properties and applications of

superconductors.

2. Science and Technology of Nanomaterials:Basic principle of nanoscienceand nanotechnology, Nanomaterials, creation and uses of Buckyballs. structure,

properties and uses of carbon nano-tubes (CNT), Tools to make nano-structures,

Applications of nanotechnology.

8

III

1. Electromagnetics : Inconsistency in Amperes law, Displacement current,

Equation of continuity, Maxwells equations (Integral and Differential forms),

Propagation of E-M waves in free space and in conducting media, Poynting

theorem and Poynting vector.

2. Electric Field in Matter: Dielectric materials, Dielectric polarization,

Dielectric constant, Types of Polarization, Polarizability, Clausius- Mosotti

equation, Ferro and Piezo electricity (qualitative), Dielectric losses, Applications

of dielectric materials.

3. Magnetic Field in Matter: Magnetisation, dia, para and ferromagnetism,Langevins theory for dia and para-magnetic materials, Phenomenon ofhysteresis and its applications.

12

References:

Beiser , Concept of Modern Physics, TMH , New Delhi.

C. Kittel , Solid State Physics, Wiley Eastern, 7th edition

V. Raghavan , Materials Science and Engineering, PHI , New Delhi.

S.O. Pillai , Solid State Physics, New Age International Publication, 5th edition.

Rechard Booker and Earl Boysen, Nanotechnology, Wiley International.

David J. Griffith, Introduction to Electrodynamics, PHI, New Delhi

C.S.Liu and V.K.Tripathi , Electromagnetic Theory for Telecommunications, Cambridge

University press India.



21/61



CCSSEE110022::PPRROOBBLLEEMMSSOOLLVVIINNGGUUSSIINNGGCCOOMMPPUUTTEERRSS

Module

No.

ContentTeaching

Hours

I

Recursion: Mechanics of a recursive call, How recursion is implemented,

definition of recursion, Key concepts. Comparing recursion and iteration.

Structures: Declaration, initialization of. Structure, Nested structures, user

defined data types, Enumerated data types, Unions. Difference between

structure and Union.

7

II

Pointers: Introduction, Pointer variables, pointer and arrays, array of pointers,

pointers and structures, dynamic allocation.

Strings: Introduction, Declaring & Initializing string variables, String

Input/output Functions, String Manipulation Functions.

File handling in C: Data and information, File concepts, File organization, Files

in C, Files and streams, stream I/O, Sequential and Direct File organization.

Problems based on Files.

7

III

Introduction Stack, Queue & Linked List: Array Representation andImplementation, Insertion, Deletion. Empty, Underflow.

Declarations: Storage Classes- Auto, Static, Extern, Register etc.

Low Level Programming such as Bit-level

Writing Large Programs: A simple file Program, Program by using two

Source Files, Program based on separate compilation of functions.

7

References:

Behrouz A. Forouzan and Richard F. Gilberg, Computer Science A structured Programming

Approach Using C , C Languages Learning, 2007.

K. N. King and W. W. Norton , C Programming A Modern Approach , 2nd Edition, 2008. Kernighan and Ritchie,The C programming Language , PHI , 1996.

P. Dey, and M. Ghosh, Programming in C, Oxford University Press ,2009 .



22/61



MMEEEE110022::BBAASSIICCTTHHEERRMMOODDYYNNAAMMIICCSS

Module

No.

ContentTeaching

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, Energy equations for closed systems and open

systems under steady flow conditions, Application of first law to various

thermodynamic systems such as boiler, turbine compressor, nozzle, pump etc.

13

II

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 ofentropy of universe, Entropy change during various processes, Concept of

Third Law of Thermodynamics.

Properties of Steam or pure substance

Definition of pure substance, Phase change, p-T diagram and pV-T surfaces,

Formation of Steam, Classification of steam generators, Construction and

working of boilers, Concept and determination of dryness fraction of steam,

Thermodynamic properties of steam, Steam table and Mollier diagram, Various

thermodynamic processes with steam as a working medium.

Rankine cycle, layout and working of steam power plant

14

III

Gas power cycle and IC engine

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.

Refrigeration & Air Conditioning

Elementary concept of Refrigeration & Air conditioning, Working principle and

schematic diagrams of refrigerators, air coolers, air conditioners and ice plants,

Vapour compression cycles.

13

References:

Van Wylen G.J. and 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, Central Publishing House Allahabad, Vol I, 2nd

Edition.

Ballaney P.L. , Thermal Engineering, Khanna Publisher.

Arora C.P. , Engineering Thermodynamics, TMH, New Delhi.



23/61



AAHHCC110011::EENNGGIINNEEEERRIINNGGCCHHEEMMIISSTTRRYY

ModuleNo.

Content TeachingHours

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

& CO2system), 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 hydroxy butyrate), vulcanization of rubber.

Water Treatment: Introduction, Hardness and its units, , L-S Process, Calgonprocess, 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

Laidler , Chemical Kinetics



24/61



MMEEEE110033::AAPPPPLLIIEEDDMMEECCHHAANNIICCSS

Module

No.Content

Teaching

Hours

I

Introduction: Engineering Mechanics, Idealization of Bodies, concept of Rigid

Body, External Forces (Body forces & surface forces), 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: Introduction to friction, Dry friction, Laws of friction and its

application to wedge, ladder, screw, rolling friction, belt-pulley system.

14

II

Distributed Forces And Moment Of Inertia: Centroid of Composite figures,

Area Moment of Inertia, Polar Moment of Inertia, Parallel axes theorem,

Perpendicular axes 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

Diagram.

Analysis Of Plane Trusses: Engineering structures, Perfect Truss,

Determination of axial forces in the members, Method of Joints, Method of

Section.

17

III

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, DAlemberts Principle and dynamicequilibrium.

Principle Of Virtual Work: Principle and application of Virtual work, Stability

of equilibrium.

17

References:

I.H. Shames , Engineering Mechanics, PHI., New Delhi.

F.P. Beer and E.R. Johnston , Mechanics for Engineers (Statics and Dynamics),TMH New

Delhi.

Dr. A.K. Tayal , Engineering Mechanics Statics & Dynamics, Umesh Publications, Delhi.

V.S. Mokashi , Engineering Mechanics Statics Vol.I & Dynamics Vol-II, TMH.

J.L. Marriam and L.G. Kraig , Engineering Mechanics Statics & Dynamics, John Wiley &

Sons Ltd.



25/61



AAHHEE118822::CCOOMMMMUUNNIICCAATTIIOONNSSKKIILLLLSSIIII

Module

No.Content

Teaching

Hours

I

Communication Games(as per the level and requirement of the class) 2 truth

and 1 lie, psychological tests through pictures, Building Blind, Blind obstacle

course.

II

Discussion on Newspaper/Magazines/Comics(Underlying process), dividing

the class into small teams as per their choice- after a week one group is to ask

questions about the happenings of last week- continuing on different sides,

debate based upon counterview, narrate all the seven activities of a particular

cartoon and which one do you like the most, most important happening of the

week, analyzing headlines- appeal and attractiveness, cover pages of

magazines- comparison, upgrading vocabulary- noticing phases and popular

acronyms, Quiz from Sunday column, analyzing advertisements and their

appeal

III

Presentation Skills: Analyzing locale, audience orientation, organizingcontent- Effective beginning, Development of thought and forceful/emphatic

conclusion, Visual aids- Usage of PPT- Theory & practice;

Non-Verbal clues: Significance and awareness of basics- posture & gestures,

i.e. eye contact, hand movement, gap from the audience, assessing the mood

and response of the audience.

Model presentation, Presentation on long story, Novel, Drama, Poetry e.g.- Who

moved my cheese by Spencer Johnson, The Barber's Trade Union by Mulk Raj

Anand, Jonathan Livingstone Seagull- Richard Bach, To Kill a Mockingbird-

Harper Lee, Miracles on the water- Tom Nagasaki.

IV

Debate and group discussion:Basic Theory- Difference between debate and

GD, Why GDs, Skills gauged during GD, major kinds of GDs, Dos and don'ts of

GD.

Practice of debate-Famous controversial topics to simulate the logic and free

flow of communication;

GDs- on simple factual topics, argumentative/controversial topics, Current

topics; Group Discussion/Case study on the topics with perceptual variety.

V

Role play: Simple role play- from student life(involving friends, teachers,

parents);

Advanced role plays -creating business related situations, Famous speeches

from epics(if the class is comfortable with it);

Enacting a drama popular one act play, Theme enactment (the theme is

provide to the team 1 week back, One theme to the whole batch- competition)



26/61



MMEEEE118822::EENNGGIINNEEEERRIINNGGDDRRAAWWIINNGG

Module

No.

ContentTeaching

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 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.

References:

Bhatt N.D. and Panchal V.M. , Elementary Engineering Drawing , Charothar Publishing,

Gujarat.

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. and Duff John M. , Fundamentals of Engineering Drawing with an

introduction to Interactive Computer Graphics for Design and Production, PHI, New

Delhi. Singh Ajit , Machine Drawing,TMH, New Delhi.



27/61



AAHHCC118811::CCHHEEMMIISSTTRRYYLLAABB

Any TEN Experiments are to be performed

Module

No.Content

Teaching

Hours

I

1. Preparation and Standardization of solutions.

2. To determine the constituents and amount of alkalinity of the supplied

water sample.

3. To determine the percentage of available chlorine in given sample of

bleaching powder.

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

solution pH-metrically.

5. Determination of free CO2in a given sample of water.

6. To determine the Ferrous ion content in given iron ore by titrimetricanalysis against standard K2Cr2O7solution using K3[Fe(CN)]6as an external

indicator.

7. 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 480nm.

8. To determine the viscosity of an addition polymer like polystyrene sample

by using Ostwald viscometer relative to water.

9. To determine the temporary and permanent hardness of water by using

EDTA or complexometry.

10. To determine the equivalent weight of iron by chemical displacement

method. The equivalent weight of copper is 63.5.11. To determine chloride ion in a given water sample by Argentometric

method (Mohrs Method).

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

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

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

polarimeter.



28/61



CCSSEE118822::PPRROOBBLLEEMMSSOOLLVVIINNGGLLAABB

Module

No.Content

Teaching

Hours

I

(1) Recursion

a. WAP to calculate factorial of a number.

b. WAP to generate table of any number.

c. WAP to find GCD of two numbers.

d. WAP to calculate nth term of Fibonacci Series 1,1,2,3,5,8

e. WAP to find the sum of digits of a number.

f. WAP to find the reverse of a string.

g.

(2) Structure

a. WAP to enter 10 records of student .Structure fields are Name, Roll no,

Marks. Calculate the average of their marks.

b. 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.

c. WAP to demonstrate, how structure is passed to a function.

d. WAP to perform arithmetic operations using functions and switch

case and enumeration.

(3) Pointera. WAP to display the contents of 2D array using pointer.

b. WAP to sort an array in ascending order using dynamic memory

allocation and pointers.

(4) File handling

a. WAP to copy the contents of a given file into another file.

b. WAP to read the characters from a file and display the uppercase on a

console.

(5) Introduction to Data Structure

a. WAP to demonstrate various operations (create, push, pop, overflow,

underflow, peek, display) of STACK using array implementation.

b. WAP to demonstrate various operations (create, enqueue, dequeue,

overflow, underflow, peek, display) of Queue using array

implementation.

c. 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.

d. WAP to demonstrate various operations (create, Traversing,

Searching, Inserting an element at beginning, Deleting an element

from end) of a doubly linked List.

24



29/61



MMEEEE118833::AAPPPPLLIIEEDDMMEECCHHAANNIICCSSLLAABB

Module

No.

ContentTeaching

Hours

I

1. To conduct the tensile test and determine the ultimate tensile strength,

percentage elongation for a steel specimen.

2. To determine the compression test and determine the ultimate compressive

strength for a specimen.

3. To conduct the Impact-tests (Izod/Charpy) on Impact-testing machine to

find the toughness.

4. To determine the hardness of the given specimen using Brinell/Rockwell

hardness testing machine.

5. Friction experiment on inclined plane.

6. Simple & compound gear-train experiment.

7. Worm & worm-wheel experiment for load lifting.

8. Belt-Pulley experiment.

9. Bending of simply-supported beams for theoretical & experimental

deflection.

10. Torsion of rod/wire experiment.

11. Experiment on Trusses.

12. Experiment on Moment of Inertia.



30/61



AAHHMM220011::MMAATTHHEEMMAATTIICCSSIIIIII

Module

No.

ContentTeaching

Hours

I

Solution Of Cubic and Biquadratic Equations : Cardons Method of solving

Cubic equations, Descartes and Ferraris 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, Partialfractional and Residue method, applications of Z transform in solving

difference equations.

13

III

Functions of a complex variable: Analytic functions, Cauchy - Reimannequations , Harmonic function, Milnes Thomson method, Cauchy integraltheorem, Taylors, Maclaurins and Laurents series (without proof ), 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.ONeil , 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 LTP: 310Semester III


31/61



CCEEEE220011::EENNVVIIRROONNMMEENNTTAALLSSTTUUDDIIEESS

Module

No.

ContentTeaching

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 andMajor 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 Anisha Singh , Environmental Science & Ecology.

Agarwal and Sangal , Environment & Ecology.



32/61



EECCEE220011::EELLEECCTTRROOMMAAGGNNEETTIICCFFIIEELLDDTTHHEEOORRYY

Module

No.

ContentTeaching

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 , Stokess Theorem.

Electrostatics-I

Coulombs law & field intensity, Electric fields due to continuous chargedistributions. Electric flux density, Gausss 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, Poissons and Laplaces equation, Capacitance, Method of Images.

Magnetostatics

Biot-savarts law, Amperes Circuit law, Magnetic flux density, The scalar andvector magnetic potential, Maxwells equations for static field, Forces due to

magnetic field, Magnetic torque and moment, Magnetization in materials,

Magnetic boundary conditions, Inductance, Magnetic energy.

14

III

Maxwells Equations

Faradays law, Displacement current, Maxwells 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:

1. Jordan E.C. and Balmain K.G., Electromagnetic wave and radiating Systems, PHI Second

edition.

2.

W.H. Hayt and J.A. Buck, Electromagnetic Field Theory, 7th TMH.Reference Books:

1. M.N.O. Sadiku, Elements of Electromagnetics, 4th Ed, Oxford University Press

2. Kraus, F Electromagnetics Tata Mc Graw Hill fifth edition.

3. Ramo S, Whinnery T.R. and Vanduzer T, Field and Waves in communication

electronics John Wiley and sons third edition.



33/61



EECCEE220022::DDIIGGIITTAALLEELLEECCTTRROONNIICCSS

Module

No.

ContentTeaching

Hours

I

Logic Families, Diode, BJT & MOS as a switching element, concept of transfer

characteristics, Input characteristics and output characteristics of logic gates,

Fan-in, Fan-out, Noise margin, circuit concept and comparison of various logic

families: TTL, CMOS Tri-state logic, open collector output, packing density,

power consumption & gate delay.

Digital system and binary numbers: Signed binary numbers, binary codes,

Cyclic Codes, Error Detecting and Correcting Codes, Hamming Codes. Floating

point representation.

Gate-level minimization : Five variable K-Map, dont care conditions, POS

simplification, NAND and NOR implementation, Quine Mc- Clusky method

(Tabular method)

13

II

Combinational Logic : Combinational circuits, analysis procedure, designprocedure, Binary Adder-Subtractor, Decimal Adder, Binary Multiplier,

Magnitude Comparator, Decoders, Encoders, Multiplexers

Synchronous sequential logic: Sequential Circuits, Storage Elements : Latches,

Flip Flops, Analysis of Clocked Sequential Circuits, State Reduction and

Assignments, Design Procedure

Register and counters: Shift Registers, Ripple Counter, Synchronous Counter,

Other Counters.

14

III

Registers and Counters: Shift Registers, Ripple Counter, Synchronous Counter,

Other Counters.

Memory and programmable logic : RAM, ROM, PLA, PAL, FPGA, PROM, EPROM,

EEPROM

Asynchronous Sequential Logic : Analysis procedure, circuit with latches, Design

procedure, Reduction of state and flow table, Race free state assignment,

hazards.

14

Text Book:

1. M. Morris Mano and M. D. Ciletti, Digital Design 4th Edition, Pearson Education

2. S. Salivahanan & S. Asivazhagan, Digital Circuit & Design, IInd Edition



34/61



EECCEE220033::EELLEECCTTRROONNIICCDDEEVVIICCEESS&&CCIIRRCCUUIITTSS

Module

No.

ContentTeaching

Hours

I

Review of transistors: all configurations of BJTs and FETs with their

characteristics. High frequency equivalent circuits of BJTs, MOSFETs, Miller

effect, Short circuit current gain, s-domain analysis and amplifier transfer

function. Low and high frequency response of BJTs and FETs in all

configurations.

12

II

Feedback Amplifiers: Classification of amplifiers, the feedback concept, The

transfer gain with feedback, General characteristics of negative feedback

amplifiers, input resistance, output resistance, Method of analysis of feedback

amplifier, voltage series feedback, voltage shunt feedback, current series,

current shunt feedback.

Oscillators: Conditions for oscillations, Sinusoidal oscillators, the phase shiftoscillators, resonant circuit oscillators, a general form of oscillator circuit, the

Wein Bridge oscillators, crystal oscillators, frequency stability

14

III

Output stages and Power amplifiers: Power amplifiers, Power Transistors,

Class A, Class B, Class AB, Class C operation, Design Application.

Power Devices: The p-n-p-n Diode, Semiconductor Controlled Rectifier,

Insulated Gate Bipolar Transistor, DIAC, TRIAC.

14

Text Books:

1. Neamen D A, Electronics Circuits, 3rd Ed TMH

2. Ben G. Streetman, Sanjay Banerjee, Solid State Electronic Devices , 5th Ed.PHI

Reference Books:

1. Jacob Millman,Christos Halkias, Satyabrata Jit, Electronic Devices and Circuits, TMH

2. Sedra S., Smith K., Micro-electronics ,5th edition, OXFORD

http://www.tatamcgrawhill.com/cgi-bin/same_author.pl?author=Jacob+Millmanhttp://www.tatamcgrawhill.com/cgi-bin/same_author.pl?author=Christos+Halkiashttp://www.tatamcgrawhill.com/cgi-bin/same_author.pl?author=Satyabrata+Jithttp://www.tatamcgrawhill.com/cgi-bin/same_author.pl?author=Satyabrata+Jithttp://www.tatamcgrawhill.com/cgi-bin/same_author.pl?author=Satyabrata+Jithttp://www.tatamcgrawhill.com/cgi-bin/same_author.pl?author=Christos+Halkiashttp://www.tatamcgrawhill.com/cgi-bin/same_author.pl?author=Jacob+Millman


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EEEEEE220011::NNEETTWWOORRKKAANNAALLYYSSIISS&&SSYYNNTTHHEESSIISS

Module

No.

ContentTeaching

Hours

I

A1: Network Theorems (Applications to ac networks):

Super-position theorem, Thevenins theorem, Nortons theorem, Maximum

power transfer theorem, Millmans theorem, Compensation theorem,

Tellegens 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 & 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:1 D.Roy Choudhary, Networks and Systems 2ndEd., New Age International (P) Ltd. Publishers.2 C.L Wadhwa, Network Analysis and Synthesis(Including Linear System Analysis) 3rdEd., New

Age International Publishers.

3 A.Chakrabarti, Network Analysis & Synthesis, Dhanpat Rai & Co.

Reference Books:4 M.E. Van Valkenburg, An Introduction to Modern Network Synthesis,Wiley Eastern Ltd.

5 Sudhakar, Circuits & Networks: Analysis and Synthesis, TMH Education Pvt. Ltd.

6 K.S. Suresh Kumar, Electric Circuits and Networks Pearson Education.



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EECCEE228811::DDIIGGIITTAALLEELLEECCTTRROONNIICCSSLLAABB

List of Experiments

1. Realization of 4-bit even / odd parity checkers using Ex-OR gate.

2. Realization of 4-bit binary decoder/ demultiplexer.

3. Realization of 4-bit / 3-bit multiplexer.

4. Realization of full-adder & full subtractor using logic gates and using Boolean

expression.

5. Realization of decimal to BCD encoder using IC 74147.

6. Realization and implementation of RS, JK, T and D flip-flop using logic gates.

7. Realization and implementation serial in parallel out and parallel in serial out

shift register.

8. Realization and implementation 4-bit binary ripple counter using JK flip-flop.

9. Realization and implementation of 2-bit up/down synchronous counter.

10. Realization and implementation of Arithmetic logic unit.



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EECCEE228822::EELLEECCTTRROONNIICCSSLLAABB

List of Experiments

1. To study application of CRO and function generator.

2. To study application of diode as (a) clipper ckt (b) clamper ckt.

3. To study application of Zener diode as a voltage regulator.

4. To study V-I characteristic of JFET and MOSFET.

5. Realization of BJT as a buffer amplifier.

6. Realization of multistage amplifier using BJT and calculation of current gain

7. Realization of JFET as amplifier and determine various parameters.

8. Realization of MOSFET as a switch.

9. Realization of Op-Amp as integrator & differentiator.

10.Realization of tuned amplifier and its application in Hartley and Collpit oscillator.

11.Realization of Wien Bridge oscillator.

12.Realization of crystal oscillator.



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EEEEEE228811::NNEETTWWOORRKKLLAABB

List of Experiments

1. Verification of principle of superposition with dc sources.

2. Verification of Thevenin, Norton and Maximum power transfer theorems in ac

circuits.

3. Verification of Tellegins theorem for two networks of the same topology.

4. Determination of transient response of current in RL and RC circuits with step

voltage input.

5. Determination of transient response of current in RLC circuit with step voltage input

for underdamp, critically damp and overdamp cases.

6. Determination of frequency response of current in RLC circuit with sinusoidal ac

input.

7. Determination of z and h parameters (dc only) for a network and computation of Y

and ABCD parameters.

8. Determination of driving point and transfer functions of a two port ladder networkand verify with theoretical values.

9. Determination of frequency response of a Twin T notch filter.

10.To determine attenuation characteristics of a low pass / high pass active filters.

11.Implementation of Pre-emphasis and De-emphasis circuits.



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EECCEE220066::MICROPROCESSORS AND APPLICATIONS

Module

No.

ContentTeaching

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, Assember

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:

1. Gaonkar, Ramesh S, Microprocessor Architecture, programming and applications with the 8085 Pen ram International

Publishing 5th Ed.

2. Ray, A.K. & Burchandi, K.M., Advanced Microprocessors and Peripherals: Architecture, Programaming and

Interfacing Tata Mc. Graw Hill.

Reference Books:

3. Uffenbeck, John, Microcomputers and Microprocessors PHI/ 3rd Edition 5. Brey, Barry B. INTEL Microprocessors

Prentice Hall ( India)

4. M. Rafiquzzaman, Microprocessors- Theory and applications PHI

5. B. Ram, Advanced Microprocessor & Interfacing Tata McGraw Hill

6. Renu Singh & B.P. Singh, Microprocessor and Interfacing and applications New Age International

7. Hall D.V., Microprocessors Interfacing Tata Mc Graw Hill

8. Liu and Gibson G.A., Microcomputer Systems: The 8086/8088 Family Prentice Hall (India)

Credits: 04 LTP: 310Semester IV


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EECCEE220055::SEMICONDUCTOR MATERIALS AND DEVICES

Module

No.

ContentTeaching

Hours

I

EXCESS CARRIERS IN SEMICONDUCTORS.

Optical Absorption. Luminescence. Photoluminescence. Electroluminescence.

Carrier Lifetime and Photoconductivity. Direct & Indirect Band gap Semiconductor,

Direct & Indirect Recombination, Steady State Carrier Generation, Quasi-Fermi

Levels. Photoconductive Devices. Diffusion & Drift of Carriers. The Continuity

Equation. Steady State Carrier Injection. The Haynes-Shockley Experiment.

Gradients in the Quasi-Fermi Levels.

JUNCTIONS.

Equilibrium Conditions. The Contact Potential. Equilibrium Fermi Levels. Space

Charge at a Junction. Steady State Conditions. Reverse Bias. Reverse-Bias

Breakdown. Transient and A.C. Conditions. Time Variation of Stored Charge. The

Varactor Diode. Effects of Contact Potential on Carrier Injection. Graded Junction.

13

II

Type of Junctions

Metal-Semiconductor Junctions. Schottky Barriers. Rectifying Contacts. Ohmic

Contacts. Typical Schottky Barriers. Heterojunctions.

OPTOELECTRONIC DEVICES.

Photodiodes. Solar Cells. Photodetectors. Light-Emitting Diodes. Light-Emitting

Materials. Multilayer Heterojunctions for LEDs. Lasers. Semiconductor Lasers.

Population Inversion at a Junction. Emission Spectra for p-n Junction Lasers..

Heterojunction Lasers. Materials for Semiconductor Lasers.

HIGH FREQUENCY AND HIGH POWER DEVICES.

Tunnel Diodes: Degenerate Semiconductors. Tunnel diode Operation. Circuit

Applications. Transit Time Devices: The IMPATT Diode. Gunn Effect and

Related Devices:Transferred Electron Mechanism. Formation and Drift of Space

Charge Domains. Fabrication.

13

III

BIPOLAR JUNCTION TRANSISTORS.

Solution of the Diffusion Equation in the Base Region. Charge Control Analysis.

The Switching Cycle. Drift in the Base Region. Base Narrowing. Avalanche

Breakdown. Injection Level; Thermal Effects. Base Resistance and Emitter

Crowding.

Gummel-Poon Model. Kirk Effect. High-Frequency Transistors. Heterojunction

Bipolar Transistors.

FIELD-EFFECT TRANSISTORS

The Metal-Semiconductor FET. The GaAs MESFET. The High Electron Mobility

Transistor (HEMT). Short Channel Effects. The Metal-Insulator-SemiconductorFET. Basic Operation. The Ideal MOS Capacitor. Threshold Voltage. MOS

Capacitance-Voltage Analysis. Time-dependent Capacitance Measurements.

13

Text Books:1. Ben.G.Streetman & Sanjan Banerjee Solid State Electronic Devices (5th Edition) PHI Private

Ltd, 2003



41/61



EECCEE220044::SIGNALS AND SYSTEMS

Module

No.Content

Teaching

Hours

I

Signals:

Definition, types of signals and their representations, commonly usedsignals (in continuous-time as well as in discrete-time), operations oncontinuous-time and discrete-time signals (including transformations ofindependent variables).

Systems:

Classification, linearity, time-invariance and causality, impulse response,characterization of linear time-invariant (LTI) systems, unit sampleresponse, convolution summation, step response of discrete time systems,

stability.convolution integral, co-relations, signal energy and energy spectral density,

signal power and power spectral density, properties of power spectral

density.

13

II

Fourier series

Trigonometric & Exponential Fourier Series Analysis, Sampling Theorem,Nyquist criteria for sampling theorem

Fourier Transforms (FT):(i) Definition, conditions of existence of FT, properties, magnitude and

phase spectra, Some important FT theorems, Parsevals theorem, InverseFT, relation between LT and FT(ii) Discrete time Fourier transform (DTFT), inverse DTFT, convergence,properties and theorems, Comparison between continuous time FT andDTFT

13

III

Laplace-Transform (LT) and Z-transform (ZT):(i) One-sided LT of some common signals, important theorems andproperties of LT, inverse LT, solutions of differential equations using LT,Bilateral LT, Regions of convergence (ROC)(ii) One sided and Bilateral Z-transforms, ZT of some common signals,ROC, Properties and theorems, solution of difference equations using one-

sided ZT, s- to z-plane mappingApplication of Signals and Systems in MATLAB

13

Text Books:P. Ramakrishna Rao, `Signal and Systems 2008 Edn., Tata MGH, New Delhi

Reference Books:

1. Chi-Tsong Chen, `Signals and Systems, 3rd

Edition, Oxford University Press,20042. V. Oppenheim, A.S. Willsky and S. Hamid Nawab, signals & System, PEARSON Education,Second Edition, 2003.



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EEEEEE220022::EELLEECCTTRROONNIICCMMEEAASSUURREEMMEENNTTSSAANNDDIINNSSTTRRUUMMEENNTTAATTIIOONN

Module

No.

ContentTeaching

Hours

I

Theory of Measurement

Introduction, Performance Characteristics: Static & Dynam

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