bansilal ramnath agarwal charitable trust’s vishwakarma … · 2018-07-04 · bipolar junction...

BRACT’S

Vishwakarma Institute of Technology, Pune – 411 037

Department of Electronics Engineering

Structure & Syllabus of B.E (Electronics and E&TC) Program – Pattern ‘A11/B11’, Rev01, dt.

2/4/2011

1

Bansilal Ramnath Agarwal Charitable Trust’s

Vishwakarma Institute of Technology (An Autonomous Institute affiliated to University of Pune)

Structure & Syllabus of

B.E. (Electronics) and

B.E. (E & TC) Pattern ‘A11 & B11’

Effective from Academic Year 2011-12

Prepared by: - Board of Studies in Electronics Engineering

Approved by: - Academic Board,

Vishwakarma Institute of Technology, Pune

Signed by,

Chairman – BOS Chairman – Academic Board

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Content

Sr. No. Title Page No.

Program Educational Objectives 5

Module III 6

Course Structure 7

Course Syllabi For Courses - Module III

Semiconductor Devices And Circuits 9

Semiconductor Devices And Circuits - Tutorial 11

Analog Communication 12

Analog Communication - Tutorial 14

Linear Algebra And Statistics 15

Signals And Systems 18

Practicals

Semiconductor Devices & Circuits* 20

Analog Communication 21

Department Specific Electives – SD3 22

Applied Electromechanics for Robotics 23

Electronics Measurement 24

MATLAB Fundamentals and Programming Technique 25

Module IV 26

Course Structure 27 Course Syllabi for courses - Module IV

Control Systems (MD) 29

Control Systems (MD) - Tutorial 31

Digital Electronics 32

Digital Electronics - Tutorial 34

Data Structures And Algorithm 35

Networks And Lines 37

Practicals

Digital Electronics 39

Data Structures And Algorithm 40

Department Specific Electives – SD4 42

Electronics Hardware Workshop 43

Electronic Software Workshop 44

C++ Programming 45

Open Electives 46

Applied Electronics (OE3) 47

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Analog Electronics (OE3) 49

Linear Circuit Analysis(OE3) 51 Module V 53

Course Structure 54

Course Syllabi For Courses - Module V Microcontroller & Applications 56 Microcontroller & Applications - Tutorial 58 Digital Communication 59 Digital Communication - Tutprial 61 Digital Signal Processing 62 Mechatronics (MD) 64 Practicals Microcontroller & Mechatronics Lab 66 Signal Processing And Communication Lab. 67 Institute Level Elective – PD1 68 Optimization Techniques 69 Simulation Of Power Circuits 70 Configurable And Reconfigurable Computing 71 Linux Operating System 73 Module VI 74

Course Structure 75 Course Syllabi For Courses - Module VI Electromagnetic Engineering 77 Electromagnetic Engineering -Tutorial 79 Analog Circuits 80 Analog Circuits - Tutorial 82 Power Electronics 83 Digital Integrated Circuits 86 Practicals Analog Circuits 88 Power & Integrated Circuits Lab 89 Institute Level Elective – PD2 90 Fourier Theory 91 PIC Microcontroller 92 Digital Signal And Image Processing Using Matlab 93 LATEX 94 Project And Seminar

Project And Seminar

Project And Seminar

95 Seminar – SM1 96 Project Stage-I – PS1 97 Module VII 99

Course Structure 100 Course Syllabi For Courses - Module VII Electronic Circuit Design / Microwave Engineering 102 Electronic Circuit Design / Microwave Engineering - Tutorial 105 Coding & Data Compression 109

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Elective I – Theory + Tutorial

111

Remote Sensing 112 Artificial Intelligence 115 Pattern Recognition 118 Elective II - Theory 121 Fibre Optic Communication 122 VLSI Design 124

Digital Image Processing 126 Practicals Coding & Data Compression 128 Elective II - Lab Fibre Optic Communication 129 VLSI Design 130 Digital Image Processing 131 Module VIII 132

Course Structure 133 Course Syllabi For Courses - Module VIII Computer Networks / Wireless Communication 135 Embedded Systems (MD) 141 Elective III - Theory + Tutorial 143 Microwave Engineering */ Computer Networks** 144 Electronic Automation 151 Artificial Neural Networks And Fuzzy Logic 154 Wireless Sensor Networks 157 Elective IV 160 Audio Video Engineering 161 Advanced Power Electronics 163 Biomedical Electronics 165 Practicals Embedded Systems 167 Audio Video Engineering 168 Advanced Power Electronics 169 Biomedical Electronics 170 Project Stage-III 172

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Program Educational Objectives (PEO)

(Electronics Engineering)

PEO No. Description of the Objective

1 Apply knowledge in Mathematics , Science and Engineering to solve

Electronics Engineering problems.

2 Ability to analyze and interpret data out of experimental findings.

3 Ability to understand professional & ethical responsibilities and

preparation to be a part of multidisciplinary team.

4 Ability to communicate effectively.

5 Knowledge of contemporary issues.

6 Ability to use the techniques, skills and modern Engineering tools

necessary for Engineering practice.

7 Provide students with a solid foundation in Electronics Engineering,

preparing them for career and professional growth.

8 To provide Engineering design experience, enabling students to explore

relationship between theory and practices.

9 Challenge traditional thinking and invent new approaches to solve

technical problems.

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SE MODULE III

Subject

No.

Subject Name Subject Code Teaching Scheme (Hrs. per week) Credits

Lecture Tutorial Practical

S1 Semiconductor

Devices & Circuits

EC 20101 3 0 0 3

Semiconductor

Devices & Circuits

EC 20201 0 1 0 1

S2 Analog

Communication

EC 20102 3 0 0 3

Analog

Communication

EC 20202 0 1 0 1

S3 Linear Algebra &

Statistics

EC20103 3 0 0 3

S4 Signals and

Systems

EC20104 3 0 0 3

P1 Semiconductor

Devices &

Circuits*

EC20301 0 0 2 1

P2 Analog

Communication

EC20302 0 0 2 1

SD3 Department

Specific Elective

EC243XX 0 0 2 1

GP3 Elective Soft skills -- 0 0 2 1

C V V1 Semiconductor

Devices & Circuits

+

Analog

Communication

EC20401 Comprehensive Viva Voce 1

Total 12 2 8 19

OE3 Institute Elective EC261XX 2 0 0 2

Total 2 0 0 2

List of Skill Development Electives(SD3)

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Subject

No.



SD3

Applied

Electromechanics

for Robotics

EC24301 0 0 2 1

SD3

Electronic

measurement

EC24302 0 0 2 1

SD3

Matlab

fundamentals and

programming

techniques

EC24303 0 0 2 1

List of Open Electives (OE3)

( Offered by Electronics Dept. for Computer students )

Subject

No.



OE3 Applied

Electronics

2 0 0 2

OE3 Analog Electronics 2 0 0 2

OE3 Linear Circuit

Analysis

2 0 0 2


(To be offered for Electronics/ E and TC students by other Departments )

Subject

No.



OE3 Computer

Architecture &

Operating System

EC26101 2 0 0 2

OE3 Business

Organization and

Management

EC26102 2 0 0 2

OE3 Database

Management

System

EC26103 2 0 0 2

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FF No. : 654

Credits: 03 Teaching Scheme: - Theory 3 Hrs/Week

Prerequisites: Nil

Objectives:

To make the students aware of following facets of semiconductor devices

Operation

Characteristics

Biasing (DC analysis)

Amplifier parameters (AC) analysis

Unit I (9 Hrs)

Semiconductor Diode

A) Intrinsic and extrinsic semiconductors, Conduction mechanism in extrinsic

semiconductors, density of states, E distance, Fermi Dirac probability function, Carrier

concentrations, Excess carriers, Recombination process, Drift, diffusion, Continuity,

Conductivity, Mobility, Mass action law, Einstein relationship.

Potential across Graded semiconductor, Open circuited step graded junction, Energy

Band diagram of p-n junction, Metallurgical junctions and Ohmic contacts, Depletion

region, Barrier potential, Forward and reverse biased diode operation, V-I characteristic

equation of diode, Temperature dependence of V-I characteristics, Forward and reverse

dynamic resistance, Small signal and large signal diode models, junction capacitances.

B) Diode data sheet specifications. Application of Diode as rectifier, clipper, clamper

and multiplier.

Unit II (9 Hrs)

Field Effect Transistor

A) JFET construction, Symbol, Basic operation, V-I Characteristics, Transfer

Characteristics (Shockley's Equation), Cut-off & Pinch-off voltages, Transconductance,

Input resistance & Capacitance. Drain to Source resistance, small signal JFET model.

MIS structures, two terminal structure: MOS capacitor, concept of accumulation,

depletion and inversion; four terminal structure: MOSFET, its I-V characteristics, drain

current equation in terms of W/L, Channel length modulation, brief introduction to MOS

scaling and scaling issues viz. short channel effects

B) Non ideal characteristics of MOSFET such as sub threshold conduction, body bias,

effect of temp.

EC20101: SEMICONDUCTOR DEVICES AND CIRCUITS

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Unit III (6 Hrs)

Bipolar Junction Transistor

A) BJT as a device, Construction, typical junction voltages for cutoff, active and

saturation regions, concept of amplification, BJT configurations(CE, CB, CC), Small

signal-low frequency h-parameter model, Variation of h-parameters with operating point,

small signal high frequency π model.

B) Small signal and DC data sheet specifications for BJT , Small signal ‘r’ model

Unit IV (8 Hrs)

DC analysis of Transistors

A) DC analysis of BJT circuits, Concept of DC load line, DC biasing of BJT, Fixed bias,

Voltage divider bias and its analysis for stability factors. DC analysis of MOSFET

circuits, DC biasing of FET/MOSFET, Voltage divider bias and Self bias.

B) Biasing of BJT collector to base bias. Biasing of JFET - Biasing against device

variation, biasing for zero current drift

Unit V (8 Hrs)

AC analysis of Transistors

A) Analysis of CE, CC configuration for performance parameters in terms of h

parameters, Comparison of performance parameters with CE,CC and CB configurations.

Analysis of CS, CD, amplifiers using small signal JFET model.

B) Analysis of CB amplifier using small signal BJT model, analysis of CG amplifier

using small signal JFET model

Text Books

1. Integrated Electronics, Millman Halkias, Tata McGraw Hill

2. Electronic Devices, Thomas L. Floyd, Pearson Education

Reference Books

1. Solid State Electronic Devices, B.G. Streetman, PHI, New Delhi.

2.Electronic Devices, Thomas L. Floyd, Pearson Education

3. Electronic Devices & Circuit Theory, R. L. Boylestad, L. Nashelsky, PHI, New Delhi.

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FF No. : 654

EC20201: SEMICONDUCTOR DEVICES AND CIRCUITS

Credits: 01 Teaching Scheme: - - Tutorial 1 Hr/Week

Prerequisites: : Nil

Objectives:

To make the students aware of following facets of semiconductor devices

Operation

Characteristics

Biasing (DC analysis)

Amplifier parameters (AC) analysis

List of Contents

1. Drift current, diffusion current, Continuity, Conductivity, Mobility

2. Drift current, diffusion current, Continuity, Conductivity, Mobility

3. Mass action law, Einstein relationship.

4. MOSFET

5. BJT DC Analysis

6. BJT DC analysis

7. MOSFET DC Analysis

8. MOSFET DC Analysis

9. BJT AC analysis

10. BJT AC Analysis

11. MOSFET AC Analysis

12. MOSFET AC Analysis

Text Books



Reference Books




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FF No. : 654


Prerequisites: Nil

Objectives:

To carry out mathematical analysis of analog modulation techniques

To evaluate performance of receiver characteristics, radiation pattern of

antenna

To learn problems in communication link and remedies available

To learn basics which is mandatory to understand advanced subjects

To learn design of useful circuits required in communication system

Unit I ( 8+1Hrs)

Introduction To Communication System

A) Analog Communication & Digital Communication basics; Communication System

Overview; The Electromagnetic & Optical Spectrum and its usage; Types of

Electronic Communication; Base band Communication – Merits, demerits,

applications; Communication Channels; Modulation- Need, Types

B) Spectrum Allocation & Management; Applications of Electronic Communication

Unit II (8+1Hrs)

Amplitude Modulation

A) AM Concepts; Mathematical Treatment for an AM signal; Spectral Analysis;

Modulation Index; Efficiency; Power Relations; DSB-SC and SSB-SC Modulation

Techniques – Generation Methods, BW requirements, merits, demerits & applications

B) Low level and high level AM Modulator; Frequency Division Multiplexing & its

applications

Unit III (8+1Hrs

Angle Modulation

EC 20102 :: ANALOG COMMUNICATION

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A) Basic principles of FM and PM; Mathematical Representation; Modulation Index and

Sidebands; Spectral Analysis; Noise Suppression Effects of FM; FM Generation Methods

and Demodulators; pre-emphasis and de-emphasis

B) NBFM and WBFM; Comparison – AM, FM, PM

Unit IV (8+1Hrs)

Communication Receivers

A) Basic Principles of Signal Reproduction; TRF Receivers; Super Heterodyne

Receivers; Intermediate Frequency and Image Frequency; Diode Detectors; DSB-SC and

SSB-SC Detectors; Expressing Noise Levels, Noise in Cascaded Stages

B) Dual Conversion Receivers; Noise Classification

Unit V (8+1Hrs)

Antennas and Wave Propagation

A) Antenna Fundamentals –Radio waves, Antenna operation, Antenna Reciprocity,

Basic Antenna; Common Antenna Types; Propagation Mechanisms - Ground Wave,

Sky Wave, Line of Sight; Calculating Received Power; Fading Mechanism

B) Common Propagation Problems – Multipath Fading, Shadow Fading, Rayleigh

Fading, remedies on these problems

Text Books

1. “Principles of Electronic Communication Systems”, Louis E Frenzel, Tata McGraw

Hill Publications, Third Edition

2. “Electronic Communication”, Kennedy & Devis, Tata McGraw Hill Publications

Reference Books

1. “Electronic Communication”, Dennis Roddy & Coolen, Tata McGraw Hill

Publications

2. “Electronic Communication Systems”, Wayne Tomasi, Fourth Edition

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EC20202:: ANALOG COMMUNICATION



Objectives:

To identify various communication channels

● To understand bandwidth requirement, power, modulation index of AM and FM

signals

● To realize performance of transmitters and receivers

● To know radiation & receiving pattern of an antenna

● To understand noise calculations in receiver circuits

List of Contents

1. Fourier Analysis of signals such as sine wave, triangular wave and square wave

2. Study of various communication channels (microwave, fiber optic cable etc)

3. To measure the attenuation of transmission line

4. Study of series and parallel resonant circuits

5. Comparison of Class A, B, AB, C amplifiers

6. Study of AM Transmitter

7. PAM Generation

8. FM modulation using reactance modulator

9. Design of pre-emphasis and de-emphasis circuit for a FM modulator. Plot the

necessary graphs.

10. Estimating the range of image frequency that can be interfered with commercial AM

broadcasting channel.

11. Calculating overall noise factor of a three stage cascaded amplifier system.

12. To study various Antenna types

13. Receiving pattern of an Antenna using field strength meter

Text Books

1. “Principles of Electronic Communication Systems”, Louis E Frenzel, Tata

McGraw Hill Publications, Third Edition


Reference Books


Publications


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Prerequisites: Engineering Mathematics I, Engineering Mathematics II.

Objectives:

To study basic concept of linear algebra.

To study basic concept of random process.

Unit I

(6+1 Hrs)

Vector Spaces

A) Vector spaces, Subspaces, Four Fundamental subspaces, Inner product, Inner

products , Cauchy – Schwarz inequality, Norms, Orthogonality, Gram – Schmidt,

Orthonormalization, Orthonormal basis, Expansion in terms of orthonormal basis –

Orthogonal complement, Eigen value – Eigenvector pairs Distinct real Eigen values,

Repeated Eigen values, Complex Eigen values

B) Fourier series, Decomposition of a vector with respect to a subspace and its

orthogonal complement – Pythagoras Theorem, Strategy for choosing the basis for the

four fundamental subspaces.

Unit II (6 +1 Hrs)

General Matrices

A) Real symmetric, Positive and Negative Definite and Semi definite matrix, Hermitian

Matrix and its properties, matrices TAA and AAT

,Pseudo inverse and Optimal solution

of a linear system of equations, Geometry of Pseudo inverse, Singular Values, Singular

Value Decomposition.

B) Properties of Eigen values and eigenvectors, Unitary/Orthogonal, Diagonalizbility of

Complex Matrix, Rank, Nullity, Range and Null Space of TAA and AAT

.

Unit III (9 +1 Hrs)

EC20103:LINEAR ALGEBRA AND STATISTICS

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Elements of Calculus and Vector Calculus

A) Sequences and Limits, Differentiabilty, The Derivative Matrix, Differentiation Rules,

Level sets and Gradients, Jacobian and Hessian Matrix.Vector function, Motion on a

curve, Curvature and Components of Acceleration, Partial Derivatives, Directional

Derivatives, Tangent Planes and Normal Planes, Divergence and Curl Line integrals,

independence of path, Double Integrals, Green’s Theorem, Surface Theorem, Stokes

Theorem, Triple integrals, Divergence Theorem.

B) Zeros and Poles, Residues and Residue Theorem, Evaluation of Real integrals.

Unit IV (9 +1 Hrs)

Probability and Random Variable

A) Relative frequency interpretation of probability; Axiomatic definition of probability

measure and its properties; Conditional probability; Theorem of total probability; Baye’s

theorem, Independence of events; Sequences of events and their limits; Continuity of

probability measures. Definition of random variables, continuous and discrete random

variables, cumulative distribution function (cdf) for discrete and continuous random

variables; probability mass function (pmf); probability density functions (pdf) and

properties, The Central Limit Theorem,distributions of the sample mean and the sample

variance for a normal population. Jointly distributed random variables, conditional and

joint density and distribution functions, independence; Bayes’ rule for continuous and

mixed random variables, Function of random a variable, pdf of the function of a random

variable; Function of two random variables; Sum of two independent random variables,

Expectation: mean, variance and moments of a random variable, Joint moments,

conditional expectation; covariance and correlation; independent, uncorrelated and

orthogonal random variables, Random vector: mean vector, covariance matrix and

properties Some special distributions: Uniform, Gaussian and Ray. leigh distributions;

Binomial, and Poisson distributions; Multivariate Gaussian distribution.

B) Chi-Square, Vector-space representation of random variables, linear independence,

inner product, Schwarz Inequality, Elements of estimation theory: linear minimum

mean-square error and orthogonality principle in estimation; Moment-moment generating

and characteristic functions and their applications, Bounds and approximations:

Chebysev inequality and Chernoff Bound

Unit V

(10 +1 Hrs)

Random process

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A) Random process: realizations, sample paths, discrete and continuous time processes,

Probabilistic structure of a random process; mean, autocorrelation and autocovariance

functions. Stationarity: strict-sense stationary (SSS) and wide-sense stationary (WSS)

processes Autocorrelation function of a real WSS process and its properties, cross-

correlation function, Ergodicity and its importance, Spectral representation of a real

WSS process: power spectral density, properties of power spectral density ; cross-power

spectral density and properties; auto-correlation function and power spectral density of a

WSS random sequence, linear shift-invariant discrete-time system with a WSS sequence

as input , Examples of random processes: white noise process and white noise sequence;

Gaussian process; Poisson process, Markov Process. Monte CarloTechnique.

B) Linear time-invariant system with a WSS process as an input: sationarity of the

output, auto-correlation and power-spectral density of the output; (examples with white-

noise as input);

Text Books

1. Erwin Kreyszig, ‘Advanced Engineering Mathematics’, John Wiley and sons, Inc.,

10th

Edition,Dec. 2010.(c)2011.

2. David C. Lay, ‘Linear Algebra and its applications’, Pearson Education, Inc.

(Indian Edition) (c) 2004.

3. Papoulis, A., ‘Probability, Random Variables and Stochastic Processes’,

McGraw Hill (3Prd P edition), 1991.

Reference Books

1. Dennis G. Zill, Michael Cullen, ‘ Advanced Engineering Mathematics’, Narosa

Publication.

2. Wozencraft, J. M. and Jacobs, I. J., ‘Principles of Communication

Engineering’, John Wiley, 1965.

3. M. Hays: Statistical Digital Signal Processing and Modelling, John Willey and

Sons, 1996.

4. Simon Haykin: Adaptive Filter Theory, Prentice Hall, 1996.

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FF No. : 654


Prerequisites: Calculus and Complex numbers.

Objectives

● Continuous-time and discrete-time concepts in an unified way

● Significance of LTI systems and its analysis

● Fourier series representation of different signals and its applications

● Solving differential equations using Laplace Transform

● Concept of correlation , ESD and PSD

Unit I (8+1Hrs)

Unit Name : Introduction To Signals And Systems

A) .Introduction, History, Application of embedded systems, Hardware and software

architecture ,Processor selection for Embedded System, Memory Architecture and IO

devices , Interrupt Service Mechanism ,Context switching, Device Drivers

B. Definition and classification of standard signals , Signal operations – Operations

performed on dependent and independent variables, Definition and classification of

systems

Unit II (8 +1Hrs)

Unit Name : Time domain representation of Linear Time-Invariant Systems

A.Introduction , Convolution : Impulse response of LTI systems ( Continuous and

discrete) properties of impulse response representation for LTI systems

B.Practice problems

Unit III (8 +1Hrs)

Unit Name : Fourier Analysis of Signals

EC20104:: SIGNALS AND SYSTEMS

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A. Continuous Time Fourier Series(CTFS), Symmetry properties of CTFS, Continuous

Time Fourier Transform (CTFT) , CTFT properties , Frequency response of LTI

systems, Ideal low pass filter, Sampling Theorem

B.Fourier transform of periodic signals

Unit IV (8 +1Hrs)

Unit Name : Correlation, Energy Spectral Density And Power Spectral Density

A.Energy Spectral density, Autocorrelation and Cross correlation of energy signals –

Properties and Applications, Power Spectral Density, Autocorrelation and Cross

correlation of power signals – Properties and Applications

B.Spectral characteristics of random signals and noise

Unit V (8 +1Hrs)

Unit Name : Laplace Transform

A.Unilateral and Bi-lateral Laplace Transform, The Region of convergence, Inverse

Laplace Transform using partial fraction expansion , Analysis of LTI systems.

B.Properties of the Laplace Transform

Text Books

1 Haykin Simon & Veen Barry Van, ‘Signals And Systems’ New York. John Wiley &

Sons, Inc,

2.Ramesh babu & Anand Natarajan , ‘Signals and Systems’, Scitech Publication

Reference Books

1. Oppenheim Alan V, Willsky Alan S & Nawab Hamid: Signals And Systems. (2) New

Delhi. Prentice Hall Of India, 2004

2. Roberts Michael J, ‘Signals and Systems’ New Delhi. Tata McGraw Hill Publishing

Company Limited, 2003.

3. Haykin Simon ,’An Introduction to analog and digital communications’ John

Wiley & Sons, Inc.

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FF No. : 654

EC20301:: SEMICONDUCTOR DEVICES AND CIRCUITS

Credits: 01 Teaching Scheme: - Laboratory 2 Hrs/Week

Prerequisites: Nil

Objectives:

Students should learn to verify experimentally

Transfer characteristics of device under study

Biasing of the device

Build and test amplifier circuit

Simulate amplifier circuit

List of Practical

1. BJT Characteristics

2. BJT Biasing

3. BJT as a switch

4. BJT CE Amplifier

5. BJT CC Amplifier

6. JFET characteristics

7. MOSFET characteristics

8. MOSFET as a switch

9. MINIPROJECT.

Text Books



Reference Books




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FF No. : 654

EC 20302:: ANALOG COMMUNICATION


Prerequisites: Nil

Objectives:

● To analyze different modulated signals in time domain and frequency domain ● To understand bandwidth requirement, power, modulation index of AM and FM signals ● To realize measurement of performance parameters of super heterodyne receiver ● To know radiation pattern of yagi antenna To simulate the performance of analog communication system in presence of noise in

MATLAB environment

List of Practical

1. Fourier Analysis of signals such as sine wave, triangular wave, square wave using

Digital Storage Oscilloscope (DSO)

2. Generation and detection of DSB-FC (AM) signal

3. Generation and detection of DSB-SC signal

4. Generation and detection of SSB-SC signal

5. FM Generation & demodulation

6. Measurement of Receiver Characteristics

7. Measurement of radiation pattern for an Antenna

8. Design and implementation of analog communication system in presence of noise in

MATLAB environment

a. Use any one modulation technique from DSF-FC, DSB-SC, SSB, FM.

b. For addition of noise Random noise, Gaussian noise, Rayleigh fading noise can be

considered

9. Mini-Project

Text Books

1. “Principles of Electronic Communication Systems”, Louis E Frenzel, Tata

McGraw Hill Publications, Third Edition


Reference Books


Publications


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Sr. No. Subject Name Subject Code

01 Applied Electromechanics for Robotics EC24301

02 Electronic measurement EC24302

03 Matlab fundamentals and programming techniques EC24303

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FF No. : 654

Prerequisites: NIL


Objectives:

To study basic electronic components in robotics, it’s assembly and testing

List of Practicals

1. Introduction to basic components- identification and selection

( IR sensors, Diodes, LEDs, Potentiometer, Controller, Driver)

2. In circuit operation of above components

3. Introduction to electromechanical devices- Relays, Position switches

DC Motors etc.

4. Introduction to power supplies- Rectifier module, filter, regulator

5. Speed control and direction reversal of motor

6. PCB soldering technique and PCB assembly

7. PCB soldering technique and PCB assembly

8. Algorithm for Robot maneuvering

9. Mechanical assembly and Testing

10. Mechanical assembly and Testing

EC24301:: APPLIED ELECTROMECHANICS FOR ROBOTICS

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Prerequisites: Nil Objectives:

● To identify, test the various electronic components & instruments.

● To analyze different signals in time domain and frequency domain.

● To understand specifications of various electronics instruments

● To realize measurement on CRO,DSO,Spectrum analyzer LCR-Q meter,DFM

● To develop the skills for various parameter measurements.

List of practicals

1. Voltage, current and resistance measurement using multimeters, component testing

using multimeters.

2. Observe & measure voltage by voltage source and waveforms by function generator

on CRO.

3. High frequency measurement using DSO, storing and retrieving of results, different

modes , mathematical operations on DSO.

4. LCR-Q meter a) Measure L , C & R b) Measure Q, Power factor of given component.

5. Measurement of THD using distortion factor meter.

6. Measurement by higher and lower range DMMs and compare accuracy.

7. Measurement on Frequency Counter. Principle of frequency counter, study of its different modes of measurement such as

Time, frequency ,ratio. 8. Observe & measure spectrum of sine, square and triangular waveform using

spectrum analyzer.

9. Filter & HF amplifier response analysis using spectrum analyzer.

EC 24302 :: ELECTRONIC MEASUREMENT

Text Books

1. H.S. Kalsi, “Digital Instrumentation”, Tata McGraw Hill “Electronic

Communication”, Kennedy & Devis, Tata McGraw Hill Publications

2. Cooper Helfric, “Electric Instrumentation & Measurement Techniques”, Prentice

Hall

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Prerequisites: Nil

Objectives:

Students should be acquainted with basic MATLAB Programming concepts

List of Practicals

1. Basic commands of Matlab

2. Various data types, storage & retrieval

3. Matrix manipulation

4. Matrices Generation

5. Basic Plotting

6. Various waveform Generators

7. String Handling

8. Control statements

9. Reading & storing Image Files

10. Operations on Images

11. GUI

12. GUI

Reference Books

1. Getting Started with MATLAB: Version 7 by Rudra Pratap

EC24303:: MATLAB FUNDAMENTALS AND PROGRAMMING

TECHNIQUES

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SE MODULE IV

Subject

No.



S5 Control Systems

(MD)

EC21101 3 0 0 3

Control Systems

(MD)

EC21201 0 1 0 1

S6 Digital Electronics EC20105 3 0 0 3

Digital Electronics EC20203 0 1 0 1

S7 Data Structure &

Algorithms

EC20106 3 0 0 3

S8 Networks and

Lines

EC20107 3 0 0 3

P3 Digital Electronics EC20303 0 0 2 1

P4 Data Structure &

Algorithms

EC20304 0 0 2 1

SD4 Department

Specific Elective

EC243XX 0 0 2 1

GP4 Elective-Hobby/

Health

-- 0 0 2 1

C V V2 Digital Electronics

+

Data Structure &

Algorithms


Total 12 2 8 19

OE3 Institute Elective EC261XX 2 0 0 2

Total 2 0 0 2

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Subject

No.



SD4 Electronic

Hardware

Workshop

EC24304 0 0 2 1

SD4 Electronic

Software

Workshop

EC24305 0 0 2 1

SD4 C++

Programming

EC24306 0 0 2 1


( Offered by Electronics Dept. for Computer students )

Subject

No.



OE3 Applied

Electronics

EC26101 2 0 0 2

OE3 Analog Electronics EC26102 2 0 0 2

OE3 Linear Circuit

Analysis

EC26103 2 0 0 2


( To be offered for Electronics/ E and TC students by other Departments )

Subject

No.



OE3 Computer

Architecture &

Operating System

CS26104 2 0 0 2

OE3 Business

Organization and

Management

IP26101 2 0 0 2

OE3 Database

Management

System

CS26104 2 0 0 2

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Prerequisites: Nil

Objectives:

To understand open loop and closed loop (feedback) systems.

To study of time domain and frequency domain analysis of control systems for

stability analysis.

To study compensation technique that can be used to stabilize control systems.

To understand concept of state, state variables and state model.

Unit I (8+1 Hrs)

Introduction

A) Definition of control system, Open loop, closed loop, Feedback and Feed-Forward

control, Mathematical modeling of a physical system, Laplace transforms, Differential

equations of a physical system and concept of transfer function. Block Diagram

Algebra, Signal flow graph – Mason’s Gain formula.

B) Study of different control system.

Unit II (8+1 Hrs)

Time Domain Analysis and Design

A) Standard test inputs, Time response of first order and second order systems,

Steady state analysis: steady state error and error constants, transient response

specifications. Introduction, Pole-Zero Plots, Hurwitz Criteria, Routh Array.

B) Effect of addition of Ploes and Zeros on Stability.

Unit III (8+1 Hrs)

Root Locus and Stability Analysis

A) Introduction, Root Locus: Definition and Properties, Rules for Constructing Root

Locus, stability Analysis, effect of adding poles and zeros on Root loci. Design of

compensators using Root Locus. Inverse Root Locus Technique.

B) Analysis of systems with Dead-time

EC21101:: CONTROL SYSTEMS

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Unit IV 9+1 Hrs)

Frequency Domain Analysis

A) Concept of frequency response, frequency domain specifications, Bode plots

gain margin, phase margin, design of lead/lag compensators using Bode plots.

Introduction to Polar Plots and Nyquist plots.

B) Correlation between time and frequency response, comparison of time domain and

frequency domain specifications.

Unit V (8+1 Hrs)

State Variable Analysis and Design

A) Concept of state, state variables and state model, State models for continuous time

systems(SISO, MIMO) – derivation of transfer function from state models and vice

versa, Solution of state equations – state transition matrix .

B) Controllability and Observability, State feedback controller using pole placement,

Observers

Text Books

“Control Systems Engineering”, Nagrath I. J. and M. Gopal, 5th

Edition New Age

International

“Modern Control Engineering”, Ogata Katsuhiko, 4th Edition, PHI

Reference Books

“Control System Engineering”, Norman S. Nise, 5th Edition, Wiley.

“Control System”, Les Frnical, CENGAGE Learning, India.

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EC21201: CONTROL SYSTEMS



Objectives:

To understand open loop and closed loop (feedback) systems.

To study of time domain and frequency domain analysis of control systems for

stability analysis.

To study compensation technique that can be used to stabilize control systems.

To understand concept of state, state variables and state model.

List of Contents

1. System representation

2. Block diagram reduction

3. Signal flow graph

4. Transient response

5. Hurwitz Criteria and Routh Array

6. Root locus

7. Root locus

8. Bode plot

9. Bode plot

10. Polar plot

11. Nyquist plot

12. State variable

Text Books

1. “Control Systems Engineering”, Nagrath I. J. and M. Gopal, 5th

Edition New Age

International

2. “Modern Control Engineering”, Ogata Katsuhiko, 4th Edition, PHI

Reference Books

1. “Control System Engineering”, Norman S. Nise, 5th Edition, Wiley.

2. “Control System”, Les Frnical, CENGAGE Learning, India.

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Prerequisites: Binary Logic, Number System

Objectives:

To introduce

Basics of digital circuits using building blocks such as logic gates and flip-flops.

Design of different combinational and sequential circuits and their applications.

Understanding basics of programmable logic devices.

Unit : I (8+1 Hrs)

BINARY ARITHMETIC & LOGIC SIMPLIFICATION

A) Binary, Hexadecimal number systems, Inter conversions, 1’s complement, 2’s

complement arithmetic, Binary Coded Decimal codes, Excess-3 Code, Gray code,

Standard logic gates, Universal logic gates, Derived gates, Simplification of logic

function using Boolean algebra, De Morgan’s Theorem, Sum-of-Products and Product-

of-Sums forms of Boolean function, NAND and NOR implementation, Canonical and

Standard forms, Karnaugh map up to 4 variables.

B) EBCDIC Code, ASCII code, problems on k-map

Unit II (8+1 Hrs)

COMBINATIONAL LOGIC DESIGN

A) Design procedure for combinational logic circuits, Code conversion, Half Adder,

Full Adder, IC-7483, Look Ahead Carry, BCD Adder, BCD Subtractor, Parity generator,

Parity checker, Digital Comparator, Multiplexer and Demultiplexer, their use in

combinational logic designs, multiplexer and demultiplexer trees, Encoder and Decoder,

Priority Encoder, Synthesis of combinational logic circuits.

B) Code conversion, Comparator IC-7485.

Unit III (8+1 Hrs)

SEQUENTIAL LOGIC DESIGN

A) Latches and Flip-flops: SR, D, JK, Master-Slave JK, and T, use of preset and clear

terminals, schematic symbol, truth table and excitation table, conversion of flip flops,

EC 20105: DIGITAL ELECTRONICS

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design and analysis of asynchronous and synchronous counters, up/down counters,

modulo counters, concept of propagation delay, set up time, hold time, Johnson and Ring

counters, application of counters, lock out condition, clock skew, clock jitter, sequence

generators, shift registers: SISO, SIPO, PISO, PIPO, bi-directional shift registers, Pseudo

Random Binary Sequence (PRBS) generator.

B) Counter IC7490, IC 7493, IC 74191, Shift Register IC 7495.

Unit IV (8+1 Hrs)

FINITE STATE MACHINES

A) Introduction to state machine, Basic Design steps for these sequential circuits using

state diagram, State Table, State assignment, finite state machine, Mealy machine and

Moore machine representation and implementation, sequence detector, Designing state

machine using state diagram.

B) Design problems based on finite state machine.

Unit V (8+1 Hrs)

PLD AND SEMICONDUCTOR MEMORIES

A) Programmable logic devices: architecture, Study of PAL, PLA, Designing

combinational circuits using PLDs, Introduction to CPLD and FPGA.

B) Classification and characteristics of memories RAM, SRAM and DRAM, ROM,

PROM, EPROM, EEPROM.

Text Books

1. Donald P Leach, Albert P Malvino, ‘Digital Principles and Applications’ (TMGH), 6th

Edition

2. M. Morris Mano, Digial Design - 3rd

Edition (Pearson)

Reference Books

1. Digital Systems :Principles and Applications – Ronald J Tocci, Neal S Widmer, 8th

Edition ( PHI- EEE)

2. Stephen Brown, “Fundamentals of digital logic design with VHDL” 1st edition, TMH

Publication

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Credits: 01 Teaching Scheme: - Tutorial 1 Hr/Week


Objectives:

To design combinational logic circuits & sequential logic circuits

List of Tutorials

1. Binary Arithmetic

2. Simplification and implementation of a Boolean function using canonical and

standard forms

3. Simplification and implementation of a Boolean functions using k-map

4. Multiplexer and Demultiplexer.

5. Encoder and decoder

6. Flip-flop conversion

7. Up/Down Counters

8. Pulse Train Generator

9. Mealy Machine

10. Mealy Machine

11. Moore Machine

12. Moore Machine

Text Books


Edition


Edition (Pearson)

Reference Books


Edition ( PHI- EEE)


Publication

EC 20203 :: DIGITAL ELECTRONICS

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Prerequisites: Basics of ‘ C’ Programming Language

Objectives:

To study efficient algorithms for a number of fundamental problems

To study techniques for designing algorithms using appropriate data structures,

To understand the correctness of an algorithms

To design an algorithm

To calculate the time complexity and space complexity of an algorithm

To optimize the algorithms

To apply the algorithm to find the solution of given problem..

To create data structures depending on the application.

Unit I

(8 +1 Hrs)

Analysis of Algorithms and Fundamentals of Data Structures

A) Analysis of algorithm, Performance Consideration, Time and Space Complexity,

Asymptotic notation, Data Type, Data Object and Data Structure, Abstract Data

Type (ADT). Types of Data Structures, Searching and Sorting Techniques:

merge, quick, radix, selection, heap. Hashing, concept of collision and analysis of

collision resolution techniques.

B) Analysis of all Sorting and searching methods.

Unit II (8 + 1 Hrs)

Linear Data Structures

A) Concept of sequential organization and Ordered List, Linear Data Structured using\

Linked organization: Dynamic Memory Management, Types of Linked List

Concept of stack, stack as ADT , Representation of Stack using Array and Linked List

Concept of queue, Queue as ADT, Representation of Queue using Array and Linked List

B) Dictionaries: skip-lists

EC20106: DATA STRUCTURES AND ALGORITHMS

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Unit III (6 + 1 Hrs)

Applications of Linear Data Structures

A) Generalized Linked List, Polynomial Manipulations, Infix to Postfix Conversion

and Evaluation, Validity of Parenthesis, Types of queue - Circular Queue,

B) Priority Queue

Unit IV (10 + 1 Hrs)

NonLinear Data Structures – Trees

A) Basic Terminology of Trees, Concept of Binary Tree, Concept of Binary Search Tree

,Construction and Traversal of BT, operations on BT, Threaded Binary Tree,

Hauffman tree. Priority Queue and Heap, heap sort.

B) Trees and red-black trees

Unit V (8 + 1 Hrs)

Graphs

A) Basic Terminology of Graphs, Types of Graphs, Graph Representation, Elementary

Graph Operation and Graph Traversal, Directed acyclic graphs: topological sort and

longest path, OBST, Spanning Tree – Kruskal’s and Prim’s Algorithm Shortest path

algorithm. – Dijksta’s Shortest Path Algorithm,

A)

B) Shortest and longest paths in directed acyclic graphs.

Text Books

1. Tenenbaum A M & Langsam Y: Data Structure Using C. Prentice Hall Of India

New Del

2. Horowits E & Sahni S: Fundamentals of Data Structures. Gurgaon. Galgotia

Book Source New Delhi.

Reference Books

1. Kruse R L, Leung B P & Tondo C L: Data Structure And Programming Design In C.

Prentice Hall Of

India Pvt.ltd.

2. Kakde O G & Deshpande ,” Data Structures And Algorithms”. Indian Society For

Technical E

3. Sahni S: Data Structures, Algorithms,& Applications In C++. Mcgraw Hill Boston.

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Prerequisites: Nil

Objectives:

To study various Networks Theorems.

To study Network topology and graph.

To study Two-port Networks, its functions and parameters with performance

To study system behavior using Pole zero plot.

To understand and implement filters.

To study variety of impedances and attenuators.

To study the concept of resonance.

To study concept transmission line.

Unit I (8+1 Hrs)

Networks Theorems and Network Topology

A) Network Theorems: Superposition, Thevenin’s, Norton’s and Maximum Power

transfer Theorems. Concept of Network Topology, Terms used in Topology,

Relation between Twigs and Links Properties of a Tree in a Graph, Formation

of Incidence Matrix [Ai], number of tree in Graph.

B) Cut –Set Matrix, Network Equilibrium Equation.

Unit II (8+1 Hrs)

Two Port Network Parameters and Functions

A. Terminal characteristics of network: Z, Y, h, ABCD Parameters; Reciprocity and

Symmetry conditions, Interrelation of Parameters, interconnection of parameters.

Network functions for one port and two port networks.

B. Pole-zeros of network functions and network stability.

Unit III (9+1 Hrs)

EC20107:: NETWORKS AND LINES

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Filters and Attenuators

C) Classifications: Symmetrical and Asymmetrical networks. Properties of two port

Network: Symmetrical Networks (T and Π only). Z0 and γ in terms of circuit

components, open and short circuit parameters. Filter fundamentals, Constant K-

LPF, HPF, BPF and BSF, m derived LPF and HPF. Introduction to Neper and

Decibel, Relation between Neper and Decibel, Symmetrical T and Π type

attenuators, Lattice attenuator, Bridge T-attenuator.

D) NBFM and WBFM; Comparison – AM, FM, PM

attenuators, Lattice attenuator, Bridge T-attenuator.

B. Asymmetrical Networks: Image Impedance and Iterative Impedance (L-Section

only). Terminating half sections. Asymmetrical L- type.

Unit IV (8+1 Hrs)

Resonance

C) Significance of Quality factor. Series Resonance: Impedance, Phase angle variations

with frequency, Voltage and current variation with frequency, Bandwidth, Selectivity

Resonant frequency and admittance variation with frequency, Bandwidth and

selectivity.

D) Series Resonance: Effect of Rg on BW & Selectivity. Magnification factor. Parallel

resonance: General case: Resistance present in both branches.

Unit V (7+1 Hrs)

Transmission Line Theory

A. Types of Transmission lines, Transmission Line Equation, Equivalent circuits,

Primary and Secondary line constants, Terminations of transmission lines.

B. VSWR and Reflection Coefficient.

Text Books

3. “Circuit Theory (Analysis and Synthesis )”,Chakrabarti, Dhanpat Rai and Co. 4th

Revised Edition

4. “Network Lines and Fields” John D.Ryder, PHI, 2nd

Edition

Reference Books

3. “Network Analysis”, Van Valkenberg, PHI

4. ”Electrical Networks “, Ravish R Singh, Tata Mc-Graw Hill

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Objectives:

To design and implement combinational logic circuits & sequential logic circuits

List of Practicals

1. Code Conversion using logic gates

2. Design & implement comparator using IC 7485

3. Design & implement BCD Adder using IC 7483

4. Design & implement combinational logic circuit using multiplexer & de-multiplexer

5. Design & implement 3 bit up-down ripple counter using flip-flop

6. Verification of mod-n counters using IC 7490, IC 7493 & IC 74191

7. Design & implement pulse train generator using IC 7495

8. Design & implement sequence detector using finite state machine.

9. Mini Project based on syllabus.

Text Books


Edition


Edition (Pearson)

Reference Books


Edition ( PHI- EEE)


Publication

EC 20303 :: DIGITAL ELECTRONICS

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Objectives: Learn techniques for implementing algorithms using appropriate data

structures.

List of Practicals

1. Implement the following searching algorithms

i. Binary Search

ii. Linear search

2. Implement the following sorting algorithms

i. Bubble Sort

ii. Insertion Sort

iii. Quick Sort

iv. Merge Sort.

3. Create and manipulate database using structures.

4. Create and manipulate database using Singly Linked List

5. Implement

i. Doubly Linked List

ii. Circular Linked List

6. Implement Stack

i. using array and

ii. linked list

7. Implement Queue

i. using array and

ii. linked list

8. Write a program to add two polynomials

9. Write a program to convert expression in infix form to postfix form

10. Write a program to create binary tree and perform operations on it.

11. Write a program to create graph using adjacency list/matrix

12. Write a program to find shortest path using Dijkstra’s Algorithm

EC20304::DATA STRUCTURES AND ALGORITHMS

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Text Books

1. Tenenbaum A M & Langsam Y: Data Structure Using C. Prentice Hall Of India

New Del

2. Horowits E & Sahni S: Fundamentals of Data Structures. Gurgaon. Galgotia

Book Source New Delhi.

Reference Books

Kruse R L, Leung B P & Tondo C L: Data Structure And Programming Design In C.

Prentice Hall Of

India Pvt.ltd.

Kakde O G & Deshpande ,” Data Structures And Algorithms”. Indian Society For

Technical E

Sahni S: Data Structures, Algorithms,& Applications In C++. Mcgraw Hill

Boston.

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List of Skill Development Electives ( SD4)

Subject

No.

Subject Name Subject Code

01 Electronic Hardware Workshop EC24304

02 Electronic Software Workshop EC24305

03 C++ Programming EC24306

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EC24304:: ELECTRONICS HARDWARE WORKSHOP


Prerequisites: Nil

Objectives: To make the students aware of

Different components

Different instruments

PCB manufacturing

List of Practical

1 Study of Passive and Active components

2 Study of Dual trace oscilloscope, Signal generator, power supply and

Digital multimeter

3 Soldering of circuit on general purpose PCB.

4 Artwork design for analog circuit

5 Preparation of PCB 1

6 Preparation of PCB 2

7 Drilling of PCB

8 Soldering of PCB

9 Mini Project

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FF No. : 654


Prerequisites: Basic electronics

Objectives:

To study design ,capture, simulation and verification of electronic circuits

List of practicals:

1. Design capture-electronic circuit 1

2. Functional simulation of electronic circuit 1

3. Functional verification of electronic circuit 1

4. Design capture-electronic circuit 2

5. Functional simulation of electronic circuit 2

6. Functional verification of electronic circuit 2

7. Design capture of electronic circuit 3

8. Simulation and verification of electronic circuit 3

9. Project

References

1) Mentor graphics higher education program manual

EC24305:: ELECTRONIC SOFTWARE WORKSHOP

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Prerequisites:

Objectives:

To study design ,capture, simulation and verification of electronic circuits

List of practicals:

References

1)

EC24306:: C ++ Programming

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(Offered by Electronics Dept. for Computer students )


01 Applied Electronics EC26101

02 Analog Electronics EC26102

03 Linear Circuit Analysis EC26103

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FF No. : 654


Prerequisites: Nil

Objectives:

To study the basic components like diode, BJT, Op-Amps and their applications.

To Study the basic working of active components and their implementation in

electronic circuits.

Unit I (8+1 Hrs)

Diodes

A. Overview of semiconductor theory: Intrinsic, Extrinsic, doping. Formation of P-N

Junction, working Principle, characteristics, Zener Diode working Principle,

characteristics, Application as a voltage regulator. Rectifier: - Half wave rectifier, analyze

these rectifiers w. r. t. ripple factor, efficiency, clipper and clamper circuits. Introduction

to BJT, BJT configuration, Characteristics of CE, Overview of Biasing, Fixed Bias,

Collector Base Bias, Self Bias, Transistor as a switch and amplifier

B. Full wave rectifier, Bridge rectifier and analyze these rectifiers w. r. t ripple factor,

efficiency.

Unit II (8+1 Hrs)

Operational Amplifiers

A. Block Diagram of an OP-Amp, Direct Coupled Differential Amplifier Circuit, Level

Shifter and the Output Stage. Op-Amp Parameters: Bias, Offset current; Bias, offset

voltage; CMRR, slew rate, PSRR Definitions, Significance. Op-Amp Applications –

Adder, Precision Rectifier, Zero Crossing Detector, Schmitt Trigger, Waveform

Generator (triangular), Integrator, Instrumentation Amplifier, Current to Voltage

Circuits.

B. Typical parameter values of Op-Amp (IC-μA741) Op-Amp Applications – Subtractor,

Differentiator, and Voltage to Current Circuits.

Unit III (8+1 Hrs)

Power Devices and Power Supplies

EC26101 :: APPLIED ELECTRONICS

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A. Power Devices: - Characteristics and Principle of Operation of SCR, Applications:

Half-wave and Full-wave Controlled rectifiers, Fan Regulator, UJT as relaxation

oscillator. Power supplies: - Introduction to SMPS, types of SMPS: Buck, Boost, Buck-

Boost SMPS, online UPS, off line UPS, Line interactive UPS

B. SCR Applications: Half-wave wave Controlled rectifiers, Introduction to DIAC and

TRIAC.

Unit IV (3 Hrs)

Comprises of part B of all above unit.

Text Books

1. “Integrated Electronics Analog and Digital Circuits and Systems”, J. Millman, C.

Halkias, McGraw Hill, 1988, ISBN 0 – 07 – Y85493 –9, 2nd

Edition.

2. “Op-Amp and Linear Integrated Circuits”, R. Gaikwad, Prentice Hall of India, 2002,

ISBN 81 – 203 – 2058 – 1, 4th

Edition.

Reference Books

1. “Electronic Devices”, Floyd, Pearson Education, 2001, ISBN 81– 7808–355-8, 5th

Edition.

2. “Electronic Devices and Circuit Theory”, R. Boylstad, L. Nashelsky, Pearson

Education, ISBN 81 – 7808 – 590 – 9, 2002, 8th Edition.

Additional Reading

1. “Microwave Devices and Circuits”, Liao, Prentice Hall of India, ISBN 81 – 203 –

0699 – 6, 3rd

Edition.

2. “Integrated Circuits and Semiconductor Devices”, G. Deboo, C. Burrous, Theory and

Applications”, McGraw Hill, 1987, ISBN 0 – 07 – 016246 – 8, 2nd

Edition.

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Prerequisites: Nil

Objectives:

To study the basic components like diode, BJT, FET, and their applications.

To study the basic working of active components and their implementation in

electronic circuits.

Unit I (8+1 Hrs)

Diodes

A. Overview of semiconductor theory: Intrinsic, Extrinsic, doping. Formation of P-N

Junction, working Principle, characteristics, Zener Diode working Principle,

characteristics, Application as a voltage regulator. Rectifier: - Half wave rectifier, analyze

these rectifiers w. r. t. ripple factor, efficiency, clipper and clamper circuits. Introduction

to BJT, BJT configuration, Characteristics of CE, Overview of Biasing, Fixed Bias,

Collector Base Bias, Self Bias.

B. Full wave rectifier, Bridge rectifier and analyze these rectifiers w. r. t. ripple factor,

efficiency.

Unit II (8+1 Hrs)

Transistor Biasing Circuits:

A. Definition and derivation for Stability Factors S, numerical for Self Bias Circuit only,

Comparison of the bias circuits, Need of and techniques for bias compensation, Thermal

run away, Derivation for Thermal Stability. Application of BJT: BJT as an amplifier,

Introduction to hybrid parameters, Approximate hybrid model of CE amplifier, Working,

Input output impendence concept, and current and voltage gain of an amplifier, BJT as a

switch. FET: Symbol, Operation, Construction, Drain and Transfer Characteristics and

Parameters

B. Numerical based on Approximate model of CE amplifier with Re and without Re.

Unit III (8+1 Hrs)

Power Devices and Power Supplies

EC26102: ANALOG ELECTRONICS

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A. Power Devices: - Characteristics and Principle of Operation of SCR, Applications:

Half-wave and Full-wave Controlled rectifiers, Fan Regulator, UJT as relaxation

oscillator.

Power supplies: - Introduction to SMPS, types of SMPS: Buck, Boost, Buck-Boost

SMPS, online UPS, off line UPS, Line interactive UPS.

B. SCR Applications: Half-wave wave Controlled rectifiers, Introduction to DIAC and

TRIAC.

Unit IV (3 Hrs)

Comprises of part B of all above unit.

Text Books

1. “Electronic Devices”, T. Floyd, Pearson Education, 2001, ISBN 81– 7808–355-8, 5th

Edition.

2. “Electronic Devices and Circuit Theory”, R. Boylstad, L. Nashelsky, Pearson

Education, ISBN 81 – 7808 – 590 – 9, 2002, 8th

Edition.

Reference Books

1. “Integrated Electronics Analog and Digital Circuits and Systems”, J. Millman, C.

Halkias, McGraw Hill, 1988, ISBN 0 – 07 – Y85493 –9, 2nd

Edition.

2. “Power Electronics, converters, applications and design”, N. Mohan, T. Undeland, W.

Robbins, John Wiley, 1995, ISBN 9971 – 51 – 177 – 0, 2nd

Edition.

Additional Reading

1. “Microwave Devices and Circuits”, Liao, Prentice Hall of India, ISBN 81 – 203 –

0699 – 6, 3rd

Edition.

2. “Integrated Circuits and Semiconductor Devices”, G. Deboo, C. Burrous, Theory and

Applications”, McGraw Hill, 1987, ISBN 0 – 07 – 016246 – 8, 2nd

Edition.

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Objectives:

To understand the fundamentals of electrical networks and its analysis

To study various network theorem and their applications

To understand Two port networks, its functions and

Unit I (8+1 Hrs)

Second Law of Thermodynamics

A. Basic Definitions: Passive Network, Active Network, Linear Element, non-linear

elements, Unilateral, bilateral, lumped & distributed elements. Representation of voltage

& current sources.(Ideal & practical) , source transformation, series &parallel connection

of passive elements(R,L,C), graph of network & its parts, loops & trees, linear graphs &

incidence matrix, cut sets, planner & non-planner graph loop matrix., reduction of

networks: Mesh analysis, Node analysis.

B. Star- Delta transformation and their numerical

nificance of First Law of Thermodynamics (Self Study Part of Individual Unit)

Unit II (8+1 Hrs)

Network Theorems

A. Superposition Theorem, Millman’s Theorem, Norton’s Theorem, Thevenin’s Theorem,

Maximum Power Transfer Theorem, Problems on theorem.

B. Reciprocity Theorem, Problems on above theorems

Unit III (8+1 Hrs)

Two port Network & Network Functions

A. Two port network: Open circuit impedance ( Z ) parameters, Short circuit admittance

( Y ) parameters , Hybrid ( H ) parameter, Transmission parameters(ABCD),Interrelation

of different parameters, Interconnections of two port network (Series, Parallel, Cascaded,

Series-Parallel) T & π representation.

Network Functions : Network functions for one port & two port networks, Driving point

impedance and admittance of one port network

B. Transfer function of two port networks (Z, Y, G & C parameters).

EC26103::LINEAR CIRCUITS ANALYSIS

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Text Books:

1. “Circuit and Networks: Analysis & Synthesis” A. Sudhakar, Shyammohan S.Palli

Tata McGraw Hill Publication, ISBN- 9780073404585, 3rd edition.

2. “Networks & Systems”, D. Roy Choudhury, New Age International Publisher,

ISBN-978-81-224-2767-7, 2nd

edition.

Reference Books :

1. “Network Analysis”, M.E.Van Valkenburg, Pearson Education, ISBN- ISBN:

0136110959 3rd

Editions.

2. “Electrical Circuit Analysis”, Soni Gupta, Dhanpat Rai & Co, ISBN-10:

8177582623, 2nd

edition.

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MO

DU

LE

- V

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TE MODULE V

Subject

No.



S1 Microcontroller &

Applications

EC30101 3 0 0 3

Microcontroller &

Applications

EC30201 0 1 0 1

S2 Digital

Communication

EC30102 3 0 0 3

Digital

Communication

EC30202 0 1 0 1

S3 Digital Signal

Processing

EC30103 3 0 0 3

S4 Mechatronics

(MD)

EC31101 3 0 0 3

P1 Microcontroller &

Mechatronics Lab.

EC30301 0 0 2 1

P2 Signal Processing

and

Communication

Lab.

EC30302 0 0 2 1

PD1 Institute Level

Elective

EC333XX 0 0 2 1

C V V3 Digital Signal

Processing

+

Microcontroller &

Applications


Total 12 2 8 18

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List of Professional Development Electives (PD1)

Subject

No.



PD1

Optimization

Techniques

EC33301 0 0 2 1

PD1

Simulation of

Power Circuits

EC33302 0 0 2 1

PD1 Configurable and

reconfigurable

computing

EC33303 0 0 2 1

PD1 Linux Operating

System

EC33304 0 0 2 1

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Prerequisites: Concepts of digital electronics, C language programming

Objectives:

To study

Architecture of 80C51microcontroller

Interfacing of peripherals to microcontroller

Assembly language and embedded C language programming.

Serial communication protocols.

RISC microcontrollers.

Unit I

(8+1 Hrs)

INTRODUCTION TO MICROCONTROLLER

A. Microprocessor and microcontroller, Features and architecture of 80C51

microcontroller, Addressing modes , Instruction set

B. Features and architecture of 89V51RD2 microcontroller

Unit II (8+1 Hrs)

ONCHIP PERIPHERALS OF 80C51

A. Port structure, Timers and counters, Serial port, Interrupt structure and simple

assembly language program

B. On chip peripherals of 89V51RD2( PCA with PWM, Timers and counters, Interrupts

etc)

Unit III (9+1 Hrs)

SERIAL AND PARALLEL PORT INTERFACING

A. Interfacing of display devices like LED, Seven segment, 2 x 16 character LCD (8bit

mode),serial communication protocols-RS232, RS485, Buses-I2C and its implementation

, SPI

B. Interfacing of 2 x 16 character LCD (4bit mode)

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Unit IV (8+1 Hrs)

INTERFACING AND PROGRAMMING USING EMBEDDED C

A. 4 X 4 matrix keypad, DAC( Binary weighted and R2R ladder), ADC(Dual slope and

Successive approximation type), Stepper motor( Unipolar, permanent magnet)

B. Interfacing of relay and DC motor

Unit V (7+1 Hrs)

RISC MICROCONTROLLERS

A. Memory interfacing, Features and Architecture of PIC 16F877A and AVR Atmega32,

Theoretical minimum system design.

B.Instruction set of PIC 16F877A

.

Outcomes

After studying the syllabus, students will be able to

1) Write Assembly and C language Program for 8051

2) Interface various peripheral devices to 8051

Text Books

1. ‘8051 and Embedded C programming’- Mazidi and Mazidi, Second edition, Pearson

education

2. ‘8051 microcontroller Architecture, programming and Applications- Kenath Ayala,

third edition, Peneram publication

References 1. Datasheets of 89C51RD2, ADC 0809,DAC 0808, PIC 16F877A, AVR Atmega32,

PCF 8591

2. ‘Serial port complete’- Jan Axelson, Peneram publication

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Credits: 1 Tutorials - 1 Hr/Week

List of Tutorials

1. Assembly language program for unsigned arithmetic operations.

2. Assembly language program for multibyte addition.

3. Assembly language program for block transfer.

4. Assembly language program to find Largest/smallest number from a given array

5. Implementation of Boolean expression

6. Interfacing switches and LEDs and its Assembly language program

7. PWM generation

8. Assembly language program using interrupts

9. Seven segment display interfacing and its programming in assembly language

10. 4 X 4 matrix keypad interfacing and its programming in embedded C language

11. Implementation of I2C protocol.

12. Stepper motor interfacing and its program in embedded C language

Text Books

3. ‘8051 and Embedded C programming’- Mazidi and Mazidi, Second edition, Pearson

education

4. ‘8051 microcontroller Architecture, programming and Applications- Kenath Ayala,

third edition, Peneram publication

References 3. Datasheets of 89C51RD2, ADC 0809,DAC 0808, PIC 16F877A, AVR Atmega32,

PCF 8591

4. ‘Serial port complete’- Jan Axelson, Peneram publication

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Prerequisites: Fourier series, Fourier transform, probability theory, Analog

communication

Objectives:

To study-

The basics of Sampling Theorem & Aliasing Effect

Digital Communication Techniques

Spread Spectrum Techniques

Unit I

(8+1 Hrs)

Sampling & Waveform Coding

A Introduction to digital communication, Sampling, reconstruction, ideal sampling, Flat

top & Natural Sampling Aliasing, Aperture effect. Pulse code modulation &

reconstruction, Quantization noise, Companded PCM, Delta modulation, Adaptive delta

modulation, Differential PCM, ISI and eye diagram.

B. LPC and Line Coding, equalizers.

Unit II (8+1 Hrs)

Digital modulation techniques

A. Digital modulation techniques such as Binary Phase Shift Keying, Quadrature Phase

Shift Keying, M-Ary PSK , Quadrature Amplitude Shift Keying, Binary Frequency Shift

Keying, M-Ary Frequency Shift Keying, Minimum Shift Keying

B. Differential Phase Shift Keying, Differentially encoded PSK , Gaussian Minimum

Shift Keying.

Unit III (8+1 Hrs)

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Detection & Performance Analysis Of Digital Signal

A.Base Band signal receiver ,Derivation for Error prob of int. & dump Filter, Optimum

Filter, white noise matched filter, probability error of match filter, correlation, FSK, PSK,

non- coherent detection of FSK, DPSK, QPSK, Calculation of error probability for BPSK &

BFSK , Signal Space to calculate Probability of error.

B Correlator receiver.

Unit IV

(8+1 Hrs)

Spread Spectrum

A. Pusedo-random Sequence, Direct Sequence Spread Spectrum Phase Shift Keying

block details & mathematical treatment , Power Spectrum Density curves, Jamming

margin and processing gain, Probability of error, Frequency Hop Spread Spectrum.

B. applications of DSSSPSK and FHSS

B. Geostationary satellites

Text Books

1. Taub Schilling, ‘Principles of communication system’, Tata McGraw Hill, 2nd

Edition

2 . B.Sklar , ‘Digital Communication’, Pearson, 2nd

edition …..

Reference Books

1. Simon Haykin , ‘Digital Communications’, Wiley Publications, 4th

edition

2. Carlson , ‘Communication System’, McGrawHill, 4th

edition

Unit V (8+1 Hrs)

Introduction to Link Design and Link Budget Analysis

A. CDMA,TDMA,FDMA, Kepler’s Laws, Satellite orbits, Satellite system link models,

models,

satellite system parameters , link equations and link Budget

Satellite system link models, satellite system parameters , link equations and link Budget

Satellite system parameters and link budget.

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Credits: 01 Tutorials - 1 Hr/Week

Prerequisites: Fourier series, Fourier transform, probability theory, Analog

communication

Objectives:

To study

The basics of Sampling Theorem & Aliasing Effect

Digital Communication Techniques

Spread Spectrum Techniques

List of Tutorials

1. PAM- TDM

2. Code Modulation.

3. Pulse Code Modulation Companding.

4. Differential PCM

5. Adaptive Delta Modulation

6. Study of data formats.

7. To Study BPSK

8. To Study QAM.

9. PN Sequence Generator

10. Study of FHSS

11. Study of Satellite Receiver.

12. GMSK

Text Books

1. Taub Schilling, ‘Principles of communication system’, Tata McGraw Hill, 2nd

Edition

2 . B.Sklar , ‘Digital Communication’, Pearson, 2nd

edition …..

Reference Books

3. Simon Haykin , ‘Digital Communications’, Wiley Publications, 4th

edition

4. Carlson , ‘Communication System’, McGrawHill, 4th

edition

EC30202 :: DIGITAL COMMUNICATION

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Prerequisites: Knowledge of signals and systems, Fourier Theory

Objectives:

To learn properties of discrete time signals and systems

To learn processing of signals in frequency domain using mathematical

transforms

To learn filter design based on approximations

To learn filter design based on truncation of impulse response

Unit I : Z Transform (10+1 Hrs.)

A. Discrete time signals & Systems, Z- transform and its properties, Inverse Z-transform,

analysis of LTI systems in Z domain, Unilateral Z-transform.

B. Sampling process, Convolution and Correlation

Unit II : Discrete Fourier Transform (12+ 1Hrs.)

A. Discrete time Fourier transform(DTFT), Discrete Fourier transform(DFT), Relation of

DFT to other transforms, Properties of DFT, Overlap_add and overlap_save methods,

FFT algorithms- Decimation in Time and Decimation in frequency

B. Goertzel algorithm, applications of DFT and FFT

Unit III : FIR Filters (6+1Hrs.)

A. FIR filter structures - Direct form structure, cascade form structure, Design of linear

phase FIR filters using windows , Design of linear phase FIR filters using frequency

sampling method.

B. Lattice Structure, Design of FIR filters using Fourier series method, applications of

FIR filters

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Unit IV : IIR Filters (6+1 Hrs.)

A. IIR filter structures - Direct form, Parallel form, cascade structure.

IIR Filter design methods - Bilinear transformation, Impulse invariance

B. IIR Filter design by Approximation of Derivatives.

Unit V : Finite Word Length Effects (6+1 Hrs.)

A. Rounding and Truncation errors, Coefficient Quantization effects in FIR and IIR

filters,Limit Cycle Oscillations, Product Quantization

B. Quantization Errors in DFT Computaions and FFT algorithms.

Text Books

1. Sanjit Mitra, ‘Digital Signal Processing’, TMH, 3rd

edition

2. John Proakis, Dimitri Manolakis, ‘Digital Signal Processing – Principles,

Algorithms & Applications’, PHI

Reference Books

1. Ramesh Babu, ‘Digital Signal Processing’ , Scitech publications, 2001

2. Shalivahanan, Vallavraj, Gnanapriya C., ‘Digital Signal Processing’, TMH, 2001

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Prerequisites: Basics of Op-Amp, Network theory, Control system

Objectives:

Understand the synergistic integration of multidisciplinary engineering.

Understand the key elements of measurement system.

Be able to design mechatronics system.

Unit I (8+1 Hrs)

Unit Name: Introduction to Mechatronics

A. Scope & importance of Mechatronics with respect to interdisciplinary approach Roll

of Electronics in Mechatronics, Mathematical Modeling of Physical Systems: -

Mechanical, Electrical, Thermal, and Fluid.

B. Study of automated systems- Industrial robots, Automatic weighing machine.

Unit II

(8+1 Hrs)

Unit Name: Sensors and Transducers

A. Static & dynamic Characteristics of Sensors and Systems, Performance Terminology

of sensors (Selection criteria of sensors), Study of Temperature, pressure and force,

motion, proximity, displacement, flow sensors.

B. Vibration, Range Sensors

Unit III (8+1 Hrs)

Unit Name: Signal Conditioning

A. Importance of signal conditioning, Use of AC and DC bridges, filters, Operational

Amplifier circuits, Overview of ADC and DAC, and its selection criteria.

B. Types of ADC & DAC

Unit IV (8+1 Hrs)

Unit Name: Actuators

A. Introduction to Pneumatic and Hydraulic systems, Linear and Rotary actuators,

Control valves, Electrical actuators – relay, solenoid, and stepper motor, servomotor.

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B. Mechanical Actuating Systems

Unit V (8+1 Hrs)

Unit Name: Data Acquisition and PLC

A. Elements of Data Acquisition, Types and selection criteria of key components in DAS.

Introduction to PLC-Basic Architecture, I/O Processing, Ladder Programming,

Interfacing of sensors and actuators to PLC.

B. Specification and selection of PLC, Microcontroller Interfacing, Development Tools.

Outcomes:

Upon completion of this course, students will be able to:

Design signal conditioning circuit.

Design Data Acquisition System.

Design Mechatronics system.

Text Books

1. W. Boltan, ‘Mechatronics’. Pearson education, 3rd

edition.

2. Devdas Shetty, ‘Mechatronics Systems Design’ Thomson publication.

Reference Books

1. Rangan,Mani,Sarma, ‘Instrumentation Devices & Systems’, Tata Mcgraw Hill,

2nd

edition.

2. A.K Sawhney, ‘Electrical and Electronic Measurement and Instrumentation’,

Dhanapat Rai and Co., 7th

edition.

3. K.P.Ramchandran, ‘Mechatronics- Integrated Mechanical Electronic Systems’,

Wiley India.

4. N.P. Mahalik, ‘Mechatronics Principles, Concepts & Applications’, Tata Mcgraw

Hill, 2nd

Edition

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Part A :: MICROCONTROLLER AND APPLICATIONS

Objectives:

To interface various peripherals and develop its assembly language and embedded

language program. To implement serial communication protocol

To study sensors and its characteristics.

To design signal conditioning circuits for sensors.

To study PLC and its applications.

List of practicals:

1. Arithmetic operations on signed numbers

2. 2 X 16 character LCD interfacing

3. Serial communication interfacing

4. DAC/ADC interfacing

5. Study of sensors – Temperature, LVDT, Encoder

6. Study pneumatic actuators.

7. Study of PLC – implementation of Ladder programming.

8. Study of Applications of PLC. / Simulation of Physical Systems.

9. Mini Project: - Signal conditioning of Sensors, Interfacing of Pneumatic

Components to PLC/ other semester – Sensor and Actuators interfacing to 8051

Microcontroller.

Text Books

1. ‘8051 and Embedded C programming’- Mazidi and Mazidi, Second

edition, Pearson education

2. ‘8051 microcontroller Architecture, programming and Applications-

Kenath Ayala, third edition, Peneram publication

3. W. Boltan, ‘Mechatronics’. Pearson education, 3rd

edition.

4. Devdas Shetty, ‘Mechatronics Systems Design’ Thomson publication.

EC 30301: MICROCONTROLLER & MECHATRONICS LAB

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Credits: 01 Teaching Scheme: - Practical 2 Hrs/Week

Prerequisites: Knowledge of programming language such as MATLAB, Fourier series,

Fourier transform, probability theory, Analog communication

Objectives:

Implementation of Decimation in Time/ Decimation in frequency FFT

To design FIR and IIR filters

Real time application on DSP Processor

List of Practicals

1. Magnitude and phase spectrum plot.

2. Decimation in Time/ Decimation in frequency FFT.

3. FIR/IIR Filter Design

4. Study of finite word length effects in FIR, IIR digital filters.

5. Verification of Sampling Theorem (PAM)

6. To Study PCM (Tr & Rx )

7. To Study DM (Tr & Rx )

8. To Study QPSK

9. To Study BFSK

10. To Study DS-SS PSK

11. Mini Project

Text Books

1. Sanjit Mitra, ‘Digital Signal Processing’, TMH, 3rd

edition

2. John Proakis, Dimitri Manolakis, ‘Digital Signal Processing – Principles,

Algorithms & Applications’, PHI

3. Taub Schilling, ‘Principles of communication system’, Tata McGraw Hill

4. B.Sklar , ‘Digital Communication’, Pearson, 2nd

edition …..

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Subject

No.

Subject Name Subject Code

01 Optimization Techniques EC33301

02 Simulation of Power Circuits EC33302

03 Configurable and reconfigurable computing EC33303

04 Linux Operating System EC33304

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Experiment List:

1. To implement algorithm to find the Eigen number and Eigen vector.

2. To implement data fitting algorithm.

3. Implement Polynomial interpolation methods.

4. To implement gradient and conjugate gradient type algorithm.

5. To implement Newton’s Method Type Algorithm.

6. To implement Golden section Rule.

7. To implement the iterative method.

8. To implement Fourier series( Orthogonality ).

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Credits: 01 Teaching Scheme: - PD Lab 2 Hrs/Week

EC33302:: MATLAB SIMULINK AND SIMULATION

TOOLS Credits: 01 Teaching Scheme: - Laboratory 2 Hrs/Week

Hrs/Week

Prerequisites: Knowledge of basic mathematics.

Objectives: To study basic building blocks of system simulation

To study system modeling and simulation.

Lab 1

Overview of MATLAB environment, Arrays and matrices

Lab 2

Graphics: Plots and appearances :Plots and subplots, multiple graphs.

Lab 3

Programming: Conditional control, program flow control ,loops ,

Lab 4

Data analysis and modeling, FFT, Ordinary differential equations, curve fitting. Symbolic

math toolbox.

Lab 5

Commonly used blocks in Simulink and CASPOC. Math blocks, Sink, sources, control

blocks.

Lab 6

Introduction to freeware SCILAB. Equivalent operations in SCILAB

Lab 7

To build small systems using commonly used blocks and components. Communicating

with workspace. Block parameters, symbolic math toolbox.

Lab 8

To build small systems with measurement and feedback blocks.

Mini Project:

Simulation of one complete system. Student will simulate a system for given problem

statement.

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Prerequisites: Knowledge of basic digital logic.

Objectives: To study hardware description language as EDA Tool

To write VHDL code for combinational and sequential circuits.

To appreciate concept of reconfigurable computing

Lab 1

General purpose computing with VLSI Technology

Comparison of ASIC and General purpose processors.

Architecture of FPGA and CPLD

Lab 2

Hardware Description language: VHDL basic Constructs.

Lab 3

Simulation of Combinational circuits using simple constructs

Lab 4

Modeling styles in VHDL. Combinational circuits simulation and verification

Lab 5

Implementation of Sequential circuits in VHDL

Lab 6

Implementation of state diagram. Based Sequential circuits in VHDL

Lab 7

Reconfigurable Techniques: reconfiguration architectures, Reconfiguration Architecture

comparisons, Time-Switched Field Programmable Gate Array (TSFPGA), Dynamically

Programmable Gate Arrays, rDPA.

Lab 8

Comparison of configuration: Temporal Spatial, Performance- Flexibility and Design

effort

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Mini Project:

Case study1 : Cellular phone supporting multiple communication and data protocols, with

automatically reconfigured hardware.

Case study2 : Reconfigurability for thermal management

3. Text Books A VHDL Primer Pearson,2000,J Bhaskar.

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Objectives:

To understand and utilize Linux operating system

List of Experiments

Sr No. Experiment

1 Installation of Linux

2 Consol and Vi Editor

3 File Related commands

4 Miscellaneous commands 1

5 Miscellaneous commands 2

6 Shell script 1

7 Shell script 2

8 C programming 1

9 C programming 2

10 Installation of software on Linux

Text Books

1. Any basic book on Linux or Unix

2. Neil Matthew,Richard Stones, Beginning Linux Programming ,Wilye.

EC33304 :: LINUX OPERATING SYSTEM

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MO

DU

LE

- V

I

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TE MODULE VI

Subject

No.



S5 Electromagnetic

Engineering

EC30104 3 0 0 3

Electromagnetic

Engineering

EC30203 0 1 0 1

S6 Analog Circuits EC30105 3 0 0 3

Analog Circuits EC30204 0 1 0 1

S7 Power Electronics EC30106 3 0 0 3

S8 Digital Integrated

Circuits

EC30107 3 0 0 3

P3 Analog Circuits EC30303 0 0 2 1

P4 Power &

Integrated

Circuits Lab

EC30304 0 0 2 1

PD2 Institute Level

Elective

EC333XX 0 0 2 1

C V V4 Power Electronics

+

Digital Integrated

Circuits


Total 12 2 8 18

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Subject

No.



PD2 Fourier Theory EC33305 0 0 2 1

PD2 PIC

Microcontroller

EC33306 0 0 2 1

PD2 Digital Signal and

Image Processing

using Matlab

EC33307 0 0 2 1

PD2 LATEX EC33308 0 0 2 1

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Objectives:

To study force experienced by a charge(s) in electrostatic, magnetostatic and

electromagnetic fields

To study power transmitted by electromagnetic waves in different media

Unit I

(4+1 Hrs)

Vectors and Coordinate Systems

A. Addition, subtraction, dot product and vector product of vectors, unit vectors,

position and displacement vectors, Cartesian, cylindrical and spherical coordinate

systems

Unit II (12+1 Hrs)

Electrostatics

A. Coulomb’s Law, Concept of Electric Field intensity, Electric Field Intensity due

to various charge distributions, Gauss’s law and its applications, Divergence

theorem, Work, Energy, Potential, Gradient, Electric Fields in conductors and

dielectrics, Continuity Equation, Boundary Conditions

B. Laplace, Poisson’s equations

Unit III (10+1 Hrs)

Applications of Linear Data Structures

A. Biot Savart law, Magnetic Field Intensity due to various current distributions,

Ampere’s circuital law and its applications, Curl, Stokes’ theorem, Magnetic Flux

and magnetic flux density, Scalar and vector magnetic potentials, Forces due to

magnetic fields, Magnetization and Permeability, Boundary conditions, Magnetic

Energy

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B. Magnetic circuits, Inductance and Mutual Inductance.

Unit IV (06+1 Hrs)

Maxwell’s Equations & Time Varying Fields

A. Faraday’s law, Displacement current, Maxwell’s equations, Time varying fields,

Time harmonic fields, Energy stored in electric and magnetic time varying field.

B. Retarded potentials

Unit V (8 +1Hrs)

Uniform Plane Wave And Propagation

A. Wave equation, Wave propagation in free space, dielectrics and conductors, Skin

Effect, Polarization, Reflection of uniform plane waves at normal and oblique

incidence, Standing wave ratio, Wave reflection from multiple interfaces

B. Wave propagation in dispersive media

Text Books

1. Sadiku Matthew N O, ‘Elements of Electromagnetics’, Oxford University Press,

3rd

edition, 2002/2003.

2. Hayt W H, ‘Engineering Electromagnetics’, Mc_graw Hill Book Co., 7th

edition,

1981

Reference Books

3. Kruse R L, Leung B P & Tondo C L: Data Structure And Programming Design In

C. Prentice Hall Of

India Pvt.ltd.

2. Kakde O G & Deshpande ,” Data Structures And Algorithms”. Indian Society For

Technical E

4. Sahni S: Data Structures, Algorithms,& Applications In C++. Mcgraw Hill

Boston.

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Credits: 01 Teaching Scheme: - Tutorial 1 Hrs/Week


Objectives:

To study force experienced by a charge(s) in electrostatic, magnetostatic and

electromagnetic fields

To study power transmitted by electromagnetic waves in different media

1. Coordinate Systems

2. Coulomb’s Law

3. Gauss’ Law

4. Work, Energy, Potential

5. Boundary Conditions

6. Ampere’s Law

7. Magnetization and Boundary Conditions

8. Maxwell’s Equation and Wave Equation

9. Polarization

10. Wave reflection (normal incidence)

11. Wave reflection (oblique incidence)

12. VSWR

Text Books

1. Sadiku Matthew N O, ‘Elements of Electromagnetics’, Oxford University Press,

3rd

edition, 2002/2003.

2. Hayt W H, ‘Engineering Electromagnetics’, Mc_graw Hill Book Co., 7th

edition,

1981

EC30203 :: ELECTROMAGNETIC ENGINEERING

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Prerequisites: Nil

Objectives:

To provide clear explanation to students regarding analysis of electronic circuits using

discrete transistors and operational amplifiers.

Unit I (9+1 Hrs)

Feedback Amplifiers and Oscillators

A. Concept of feedback, Negative feedback, Four Feedback topologies, Transfer gain

with feedback, Advantages and disadvantages of negative feedback, Effect of feedback

on input and output impedances and bandwidth of an amplifier. Analysis of one circuit

for each feedback topology.

OSCILLATORS: Positive feedback, Oscillator startup mechanism, need for amplitude

limiting. Study of LC oscillators - General form of LC oscillator. Hartley oscillator,

Colpitt,s oscillator, Clapp’s oscillator.

B. RC Oscillator, Wein Bridge Oscillator, Crystal oscillator.

Unit II (8 +1Hrs)

Large Signal AF Power Amplifiers

A. Classes of power amplifiers - Class A, Class B, Class AB, class C, class D. Class A

with resistive load, Transformer coupled class A amplifier, Class B Push-pull, Class AB,

Complementary symmetry. Efficiency analysis for all, Comparison of efficiencies,

Distortions in amplifiers, Nonlinearities and harmonics, Total Harmonic Distortion.

B. Quasi-complementary configurations Higher order harmonic generation

Unit III (8 +1Hrs)

OP-AMP Fundamentals

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A. Basic building blocks of operational amplifier, differential amplifier, current sources

like widlar, wilson and mosfet sources, voltage sources, active level shifters, output stage,

open loop and closed loop operation, inverting and non-inverting configurations of op-

amp, concept of virtual short and virtual ground. ideal op-amp parameters like input

offset voltage, output offset voltage, input offset current, bias current, CMRR, PSRR,

slew rate, open loop gain, input resistance, output resistance, frequency response, small

signal and power bandwidth, non-ideal op-amp behavior in terms of ac and dc parameters

and its effect on performance. offset nulling techniques.

B. Measurement of op-amp parameters, Frequency Compensation

Unit IV (6 +1 Hrs)

Linear Applications of OP-AMP

A. Summing amplifier, difference amplifier, voltage follower, Signal phase shifter, AC

amplifier, Instrumentation amplifier, Guard Shield circuits, Integrator and applications,

Integrator set, run and hold modes, Differentiator and applications, voltage to current and

current to voltage converters, Log Amplifier and Antilog amplifier with log ratio and

temperature compensation circuits.

B. Isolation Amplifier

Unit V (9 +1 Hrs)

Non Linear Applications of OP-AMP

A. Precision half wave and full wave rectifiers, True RMS converter, Comparators,

Limitations of op-amp as comparator, Comparator IC LM 339, Window Comparator,

Schmitt Triggers, Peak Detectors, Sample and Hold circuits, Astable, Mono-stable and

Bi-stable multi-vibrator and its applications, Design of sine, square, triangular, sawtooth

and ramp waveform generators, V to F and F to V converters.

B. Timer ICs 555/556, block diagram and applications.

Text Books

1. Integrated Electronics , Millman Halkias , Tata McGraw Hill1.

2. Design with opearational amplifiers and analog integrated circuits ,Sergio Franco,

TMH, Third edition

3. Op- amp and Integrated Circuits, Ramakant Gayakwad, PHI

Reference Books

1. Electronic circuit analysis & Design , Donald A. Neamen , Tata McGraw Hill 2. Operational Amplifiers, G. B. Clayton, Mc Graw hill International Edition

3. Opearational Amplifiers and Linear Integrated Circuits, Coughlin, Discroll, PHI,

4th edition

4. Linear Integrated Circuits, D. Roy Choudhary,

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EC30204 :: ANALOG CIRCUITS

Credits: 01 Teaching Scheme: - - Tuitorial 1 Hr/Week


Objectives: To provide clear explanation to students regarding analysis of electronic

circuits using discrete transistors and operational amplifiers.

List of Contents

1. Feedback amplifiers

2. Feedback amplifiers

3. Oscillators

4. Power amplifiers

5. Power Amplifiers

6. Opamp parameters

7. Opamp parameters

8. Instrumentation Amplifiers

9. Log Amplifier

10. Multivibrators

11. IC 555

12. IC 555

Text Books



TMH, Third edition


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Prerequisites: Basics of semiconductor devices, Fourier series analysis approach

Objectives:

To explain the necessity of power conversion.

To discuss physics & applications of various devices used for conversion

To explain techniques & control of power conversions

To apply analytical tools for performance evaluation

Unit I (10+1 Hrs)

POWER DEVICES

A. Structural modifications for power devices.

Structure, Characteristics, ratings of Power Diode SCR, GTO, IGBT

Comparison of above devices with Power MOSFET & Power BJT

Driver Circuits (isolated & non-isolated) for IGBT & SCR

Commutation circuits for SCR

Protection circuits for IGBT & SCR

B. Comparison of all power devices and suitability for applications.

Silicon Carbide (SiC), Gallium Nitride (GaN)-based power devices. Suitability of these

devices for high power circuits.

Unit II (8+1 Hrs)

CONTROLLED RECTIFIER

A. Concept of line commutation.

Single-phase half wave and full wave controlled rectifier: Circuit diagram, operation,

waveforms for resistive and level (highly inductive) loads.

Single phase semi and full bridge controlled rectifier: Circuit diagram, operation,

waveforms for R, L and RLE loads. Average and RMS expressions for o/p voltage.

Fourier analysis of supply current. Performance metrics : Fundamental power factor,

Current distortion factor, Active, reactive & apparent power.

EC30106: POWER ELECTRONICS

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B. Numericals based on converters.

Unit III (8+1 Hrs)

INVERTERS DC / AC

A. Half bridge and push pull type inverters : Circuit diagram, operation & waveforms.

Full bridge inverters: Circuit diagram, operation & waveforms for R & RL loads.

Switching techniques for obtaining square, quasi-square o/p waveforms.

Fourier analysis of square and quasi-square voltage waveform & harmonics.

Harmonic reduction techniques. Advantage of sine weighted PWM over single pulse

PWM techniques.

Inverter configuration for IM drive

B. Numericals based on Inverter performance.

Unit IV (8+1 Hrs)

SWITCHED & RESONANT DC/ DC CONVERTERS

A. Step Up / Down chopper: Circuit diagram, operation and waveforms for R and L load.

Load voltage calculations.

Two-quadrant, Four-quadrant chopper. Circuit diagram, operation and waveforms for R

and L load. Chopper DC motor drives.

SMPS : Circuit diagram, operation and waveforms, of Fly back converter and forward

converter.

Need for resonant converters. ZVS, ZCS Switches.

B. Comparison of linear, switched and resonant power supplies.

Unit V (6+1 Hrs)

APPLICATIONS OF POWER ELECTRONICS

A. Study of power circuits for Electronic ballast , HF induction heating, RF heating,

Welding.

ON-line and OFF line UPS, battery selection and design considerations.

HVDC transmission, twelve pulse converter, and advantages over HVAC transmission.

Stator voltage control for IM motors. B. Industrial applications of motor drives, Study of Cycloconverter.

Text Books

1. M. H. Rashid, “POWER ELECTRONICS circuits devices and applications”, PHI, 3rd

edition, 2004.

2. M D Singh, K B Khanchandani, “POWER ELECTRONICS”,2nd

Ed. TMH.

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Reference Books 1. N. Mohan, T. M. Undeland & W. P. Robbins, “POWER ELECTRONICS,

Converters Applications and Design” John Willey and sons, 3rd

edition,

Singapore

2. P. C. Sen,”MODERN POWER ELECTRONICS”, S Chand & Co., New Delhi

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Prerequisites: Nil

Objectives:

- To study behavior of CMOS inverter in detail.

- To draw NAND, NOR, XOR gates using CMOS logic.

- To study VHDL as EDA Tool.

Unit I : Introduction to HDL (8 + Hr)

A] What is HDL, VHDL, role of hardware description languages, motivation. Describing

Hardware in VHDL- data types, data objects data operators, Event and transactions,

attributes. Concurrency, Entity, Architecture, concurrent Signal assignments, resolved

signals, conditional signal assignment statement, selected signal assignment statement,

constructing VHDL models.

Delays- Inertial Delay, transport delay, Delta delay, waveform and timing.

B] predefined attributes.

Unit II: Modeling in VHDL (8 + 1Hr)

A] Behavior Modeling- Process construct, programming constructs-If –then else

statements, case statement, loop statements, more on process, wait statement, using signal

in process, state machine modeling. Structural modeling, component declaration,

instantiation, Generics, configuration and binding.

B] Generate statement.

Unit III: Advanced Topics (7+ 1 Hr)

A] Sub-programs and overloading -Functions, Procedures. Packages and libraries. Basic

principles of Synthesis,. Test benches-test bench for combinational and test bench for

sequential circuits.

B] Synthesizable and non-synthesizable statements.

EC30107 :: DIGITAL INTREGRATED CIRCUITS

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Unit IV: Static CMOS (8 + 1Hr)

A] Recap of I-V characteristics for MOS , CMOS inverter, VTC, detail analysis of VTC,

noise Margin, Regenerative property, performance, Power and energy consumption,

Power consumption and Power delay product, CMOS logic design, Transmission gate,

Ratioed logic, Pass transistor logic, power consumption in CMOS.

B] Resistive MOS Inverter.

Unit V: Dynamic CMOS design (9 + 1 Hr)

A] Dynamic logic –basic principles, Domino logic, Zipper CMOS, DCVSL logic, CMOS

Sequential circuit Design- CMOS flip-flops, dynamic sequential circuits- Pseudo static

Latch, C2MOS Latch, NORA CMOS, TSPCL, Non-Bistable.

B] Two phase Flip-flop, schmitt trigger

Text Books

1. “Digital Integrated Circuits: A Design Perspective”, J. Rabaey, Prentice Hall India, 1997.

2. “ VHDL Primer”, J Bhaskar , Addison Wesley Longman, 2000.

Reference Books

1. “Principles of CMOS VLSI Design”, N. Weste and K. Eshranghian, Addison

Wesley.

2.”CMOS Digital Integrated Circuits”, Kang S. M.,TMH, 3rd edition, 2003.

3. “VHDL”, D. Perry, 2nd Ed., McGraw Hill International, 1995.

4. “Introductory VHDL from simulation to synthesis”Sudhakar Yalamanchili, ,

Pearson education.

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EC30303:: ANALOG CIRCUITS


Prerequisites: Nil

Objectives:

Students should learn to verify analytical aspects of circuits using discrete transistors and

design operational amplifier based circuits.

List of Practical

1. Voltage Series Amplifier

2. Current Shunt amplifier

3. LC Oscillators

4. Design of Integrator and Differentiator circuit

5. Design of V to I and I to V converters

6. Design of Comparator and Schmitt Trigger

7. Design of Precision Rectifier

8. Design of Waveform Generator

9. Miniproject

Text Books



TMH, Third edition


Reference Books

1. Electronic circuit analysis & Design , Donald A. Neamen , Tata McGraw Hill 2. Operational Amplifiers, G. B. Clayton, Mc Graw hill International Edition

3. Opearational Amplifiers and Linear Integrated Circuits, Coughlin, Discroll, PHI,

4th ed

4. Linear Integrated Circuits, D. Roy Choudhary

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Part A :: Power Electronics

Objectives:

To study characteristics of Power devices

To study power circuits and control circuits.

To study Triggering circuits for SCR.

To study Driver circuits for IGBT / MOSFET.

To simulate power electronic conversion system (AC-DC/DC-DC/DC-AC), with

suitable load.

To study power electronic conversion system with R/L/E load (AC-DC/DC-

DC/DC-AC).

Course Project based on power electronic circuit design.

To write VHDL code, simulate and implement 1 bit full adder/

Multiplexer/decoder

To write VHDL code, simulate and implement D Flip flop/ Shift register/BCD

Counter

To write VHDL code, simulate and implement a state machine description

sequence detector / counter.

To study the characteristics of CMOS logic gate.

Course Project based on Hardware description language and simulation tool.

Text Books

1. M. H. Rashid, “POWER ELECTRONICS circuits devices and

applications”, PHI, 3rd

edition, 2004, New Delhi.

2. “A VHDL Primer”, J Bhaskar, Pearson,2000.

EC 30304: POWER & INTEGRATED CIRCUITS LAB

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01 Fourier Theory EC33305

02 PIC Microcontroller EC33306

03 Digital Signal and Image Processing using Matlab EC33307

04 LATEX EC33308

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Prerequisites: Basic knowledge of MATLAB Programming and signals and systems

Objectives:

Develop concepts of spectral analysis in signal processing and digital

communication.

Understand the fundamentals and implement the algorithms.

List of Practicals

1. Continuous time fourier series.

2. Continuous time fourier transform.

3. Discret time fourier series.

4. Discret time fourier transform.

5. Gibb’s phenomenon.

6. Design of Notch filter.

7. Speech encryption and decryption.

8. Applications of fourier transform- spectral analysis of noise.

9. Miniproject.

EC 33305 :: FOURIER THEORY

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Prerequisites: Basic Knowledge of Digital Electronics and Microprocessor

Objectives:

Understand the Architecture of PIC Microcontroller and On chip Peripherals

Understand the fundamentals and implement machine language programming.

Understand the fundamentals and implement C language programming.

List of Practicals

1. Signed and Unsigned Arithmetic Operations.

2. I/O PORT Programming

3. Delay using Timers

4. LED interfacing

5. LCD interfacing

6. Keyboard Interfacing

7. Serial Communication

8. ADC and PWM Programming.

9. Miniproject

EC 33306 :: PIC MICROCONTROLLER

Text Books

5. Ajay V. Deshmukh ‘Microcontrollers’(TMH)

References 5. Datasheets of PIC MICROCONTROLLER

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Prerequisites: Basic knowledge of MATLAB Programming

Objectives:

To implement various algorithms in the field of signal and image processing.

To develop applications in various fields like data compression, Image coding,

Biometrics etc.

List of Practicals

1. Review of MATLAB basics

2. Frequency domain analysis of signals.

3. Fundamental Image processing Techniques: negation, Binarization etc.

4. Histogram stretching and equalization

5. Image segmentation-Object Separation

6. Advanced Image processing Techniques: Smoothening, Sharpening etc.

7. Image Transforms- DCT, Hough Transform, Wavelet transform etc.

8. Introduction to Graphical user Interface(GUI)

9. Mini-project

Text Books

5. “Digital Image Processing using MATLAB”, Gonzalez and Woods

6. “MATLAB programming for Engineers”, Stephen J. Chapman, second Edition

Reference Books

5. “Digital Image Processing”, Gonzalez and Woods

6. “Getting started with MATLAB 7”, Rudra Pratap

EC 33307 :: DIGITAL SIGNAL AND IMAGE PROCESSING USING

MATLAB

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PD EC33308 :: LATEX


Prerequisites: Nil

Objectives: To make the students to write different document in presentable form.

List of Practical

1 Introduction to LaTex

2 Mathematics In LaTex

3 Formatting Environment in LaTex

4 Graphics Environment in Latex

5 Assignment (1) Conversion of Given PDF file into LaTex format (General)

6 Assignment (2) Conversion of Given PDF file into LaTex (Springer Verlag) format

7 Assignment (3) Conversion of Given PDF file into LaTex (Elsevier Science) format

8 Assignment (3) Conversion of Given PDF file into LaTex (IEEE) format F

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Project and Seminar

Subject

No/

Sem



SM1

TE I

Seminar EC37301 0 0 1 2

PS1

TE II

Project Stage-I EC37302 0 0 1 2

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Credits: 2 Teaching Scheme: - Lab 1 Hrs/Week

Prerequisites: Knowledge of Basic engineering subjects.

Objectives:

To evaluate student on the basis of

His / her performance in carrying out the seminar work.

Presentation skill

Guidelines for students

A seminar based on relevant disciplinary or inter disciplinary topic is to be

presented by every candidate during the semester. It consists of Literature

Survey , study of system and analysis.

The selection of the topic should be based on references from magazines,

transactions, reference books and other technical literature.

The approval of the Department Head/ Coordinator prior to

commencement of work and presentation is essential.

The student is expected to produce a report based on the work carried out.

The presentation, report, work done during the term supported by the

documentation, forms the basis of assessment.

Outcomes:

After completion of this course, student will be able to:

Carry out comparative study of the systems.

Improve soft skills.

Prepare and present technical seminar.

EC 37301:: Technical Seminar

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Objectives:

To select and work on real life application in the field of Electronics and

Telecommunication.

To support students’ learning and engagement with principles of undergraduate

education.

To apply and enhance the knowledge acquired in the related field.


1. The project work will be carried by a group of students. Optimum group

size is three students. However, if project complexity demands a

maximum group size of four students, the coordinating committee should

be convinced about such complexity and scope of the work

2. Topic of the project work should be in the field of Electronics and

Telecommunication related to real life application OR investigation of the

latest development OR Microcontroller based application OR Software

development project with the justification for techniques

used/implemented.

3. Interdisciplinary projects should be taken up only with the justification for

techniques used and the coordinating committee should be convinced

about such complexity and scope of the work

4. The abstract of the project should be submitted for approval. Students

should incorporate the modifications and changes prior to starting the

work.

5. Group should maintain a logbook of activities throughout the project

stages. It should have entries related to the work done, problems faced,

EC 37302: : Project (Stage I)

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solutions evolved, etc., duly signed by internal and external guides.

6. A approved copy of project progress report based on the work carried out

in stage should be submitted. It is required to be presented to internal

guide at the time of evaluation.

Outcomes:

Upon completion of this course student will be able to :

Appreciate various aspects of the curriculum which support students’ increasing

mastery of competencies in technicality.

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MO

DU

LE

- V

II

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BE MODULE VII

Subject

No.



S1 Electronic Circuit

Design /

Microwave

Engineering

EC40101/

EC40102

3 0 0 3

Electronic Circuit

Design /

Microwave

Engineering

EC40201/

EC40202

0 1 0 1

S2 Elective I EC421XX 3 0 0 3

Elective I EC422XX 0 1 0 1

S3 Coding & Data

Compression

EC40103 3 0 0 3

S4 Elective II EC421XX 3 0 0 3

P1 Coding & Data

Compression

EC40301 0 0 2 1

P2 Elective II EC423XX 0 0 2 1

Total 12 2 4 16

List of Elective 1

Subject

No.



S2 Remote Sensing EC42101 3 0 0 3

Remote Sensing EC42201 0 1 0 1

S2 Artificial

Intelligence

EC42102 3 0 0 3

Artificial

Intelligence

EC42202 0 1 0 1

S2 Pattern

Recognition

EC42103 3 0 0 3

Pattern

Recognition

EC42203 0 1 0 1

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List of Elective 2

Subject

No.



S4 Fibre Optic

Communication

EC42104 3 0 0 3

P2 Fibre Optic

Communication

EC42301 0 0 2 1

S4 VLSI Design EC42105 3 0 0 3

P2 VLSI Design EC42302 0 0 2 1

S4 Digital Image

Processing

EC42106 3 0 0 3

P2 Digital Image

Processing

EC42303 0 0 2 1

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Prerequisites: Basic knowledge of electronics.

Objectives:

1. To understand the design of basic electronics circuits like power supplies, audio

amplifiers etc.

2. To understand the effect of noise on electronics circuit performance.

3. To be able to design high frequency RF circuits.

4. To estimate the reliability of electronics circuits.

Unit I

Design of Power Supplies (8+1 Hrs)

A: Linear regulated power supply design, design of crowbar and foldback protection

circuits, line filter, fuse selection, Positive, negative and dual power supply, floating

power supply.

Switched mode power supplies, forward, flyback, buck & boost converters, design of

transformers and control circuits for SMPS.

B: Design of programmable power supply.

Unit II (8+1 Hrs)

Design of Audio Amplifier

A. Selection of microphone, Signal conditioning; grounding, shielding and guarding

techniques; design of multistage amplifier, power amplifier; impedance matching, biasing

and stability issues, interfacing with loudspeaker; Volume control, Bass boost design,

graphic equalizer.

B. Design of Class D audio amplifier

Unit III

Discrete Circuit Design

(8+1 Hrs)

EC 40101 :: ELECTRONICS CIRCUIT DESIGN

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A. Switched capacitors- design issues and applications like DC to DC converters,

filters, ADC etc. Phase Locked Loop, Voltage Controlled Oscillator, applications like FM

detector, FSK demodulator, frequency multiplier. PLL IC 565

B. AM Detector

Unit IV (8+1 Hrs)

Introduction to RF Design

A. RF behaviour of passive components, Chip components and circuit board

considerations, scattering parameters, Analysis of amplifier using scattering parameter.

RF filter – Basic resonator and filter configurations – Butterworth. Implementation of

microstrip filter design. Band pass filter and cascading of band pass filter elements,

stability issues. RF amplifier design- Broad band, high power amplifiers, RF oscillator

design- stability and phase noise, LNA design, Mixers and receiver design, Use of Smith

Chart.

B. ABCD parameters, Basic resonator and filter configurations – Chebyshev filters.

Receiver and transmitter design

Unit V (8+1 Hrs)

Reliability & Noise considerations in design of electronics circuits.

A. Introduction to reliability and quality, bath tub curve, MTBF, MTTR, failure rate,

causes of failure, maintainability, availability, techniques to enhance system reliability,

fault tree technique.

Noise: definition, noise reduction and interference eliminating methods, grounding,

shielding. Noise considerations in transistors and opamp.

B. EMI, EMC, ESD constraints in circuit design.

Text Books

1. “Reliability Engineering”, E.Balagurusamy, Tata McGraw Hill Publications

2. “Noise Reduction Techniques in Eletronics Circuits”, Henry Ott, John Wiley &

Sons

3. “SMPS Design”, Abraham Pressman,

4. “Audio amplifier design handbook” Philips

5. “Radio Frequency Transistors-Principles & Practical Applications”, Norman Dye,

Helge Granberg, Elsevier Science- Newnes

6. “Transistor Circuit Design”, Gerald Williams

7. “RF Circuit Design- Theory and Applications”, Reinhold Ludwig, Pavel Bretchko

http://www.indiastudychannel.com/resources/35378-EC-ADVANCED-ELECTRONIC-SYSTEM-DESIGN-Syllabus.aspx



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Reference Books

1. “High Frequency Switching Power Supplies: Theory & Design”, George

Chryssis,

2. “Solid State Radio Engineering”, Herbert Krauss, Charles Bostian, Frederick

Raab, John Wiley & Sons

3. Datasheets of regulated power supply IC, signal conditioning IC, graphic

equalizer IC, Tone control IC, RF transistor, PLL IC 565, etc

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EC 40201 :: ELECTRONICS CIRCUIT DESIGN


Prerequisites: Basic knowledge of electronics

Objectives:

To understand thoroughly and carry out design examples related to topics taught

in the class.

List of Tutorial Assignments

1. To design a Linear regulated power supply.

2. To design a Linear regulated power supply.

3. To design a SMPS.

4. To design a SMPS.

5. To design a multi-stage amplifier.

6. To design an Audio amplifier.

7. To design an Audio amplifier.

8. To design a circuit using switched capacitor.

9. To design a circuit using PLL.

10. To study Smith Chart.

11. To design an RF amplifier.

12. To design an RF amplifier.

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Prerequisites: Basic Communication Engineering concepts.

Objectives :

To study Basics of Microwave communication system.

To study different Waveguide components and applications.

To study Microwave Tubes.

To study Microwave solid state devices

Unit I

(6+1 Hrs)

MICROWAVE TRANSMISSION LINES

A. Overview of Microwave communication : Microwave communication system ,

Advantages and applications of Microwaves. Rectangular Waveguides – TE/TM mode

analysis, Expressions for Fields, Characteristic Equation and Cut-off Frequencies,

Dominant Modes. Mode Characteristics – Phase velocity and Group Velocity. Power

Transmission and Power Losses in Rectangular Waveguide.

B.Circular Waveguides : Introduction, Nature of fields, Characteristic Equation,

Dominant mode, Impossibility of TEM mode.

Unit II (8+1 Hrs)

WAVEGUIDE COMPONENTS AND APPLICATIONS

A. Cavity Resonators– Introduction, Rectangular and Cylindrical Cavities, Dominant

Modes and Resonant Frequencies, Q factor and Coupling Coefficients.

Waveguide Multiport Junctions – E plane Tee, Magic Tee.

Ferrite Components – Gyrator, Isolator. Scattering Matrix– Significance, Formulation

and Properties. S Matrix Calculations for E plane, Magic Tee, Gyrator& Isolator.

B. Study H-plane, Directional Coupler, Circulator & find out S Matrix Calculations for

H-plane, Directional Coupler, Circulator.

Unit III (10+1 Hrs)

MICROWAVE TUBES

EC40102 :: MICROWAVE ENGINEERING

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A. Limitations and Losses of conventional tubes at microwave frequencies.

Microwave tubes – O type and M type classifications.

i)O-type tubes : 2 Cavity Klystrons – Structure, Velocity Modulation Process and

Applegate Diagram, Bunching Process , Expressions for o/p Power and Efficiency.

HELIX TWTS: Significance, Types and Characteristics of Slow Wave Structures;

Structure of TWT , Expressions for o/p Power and Efficiency.

ii) M-type Tubes

Introduction, Cross-field effects, Magnetrons – Different Types, 8-Cavity Cylindrical

Travelling Wave Magnetron – Hull Cut-off, Modes of Resonance and PI-Mode

Operation, o/p characteristics.



B.Reflex Klystrons – Structure, Applegate Diagram and Principle of working,

Mathematical Theory of Bunching, Power Output, Efficiency, Oscillating Modes and o/p

Characteristics.

Unit IV (8+1 Hrs)

MICROWAVE SOLID STATE DEVICES

A. Principle, Construction, Characteristics and applications of Gunn Diode , Tunnel

Diode, PIN diode,Varactor diode, MASER.

B Principle, Construction, Characteristics and applications of PIN diode, IMPATT and

TRAPATT.

Unit V (8+1 Hrs)

REAL WORLD APPLICATIONS OF MICROWAVE ENGINEERING

A. Study of Microwave engineering such as in

i) Radars

ii) Communication

iii) Industrial applications

B. Microwave Power Measurement – Bolometer Method. Measurement of Attenuation,

Frequency, VSWR, Cavity Q. Impedance Measurements

.

Text Books

1. Microwave Devices and Circuits – Samuel Y. Liao, PHI, 3rd Edition .

2. Micro Wave and Radar Engineering – M. Kulkarni, Umesh Publications

Reference Books 1.Elements of Microwave Engineering – R. Chatterjee, Affiliated East-West Press Pvt.

Ltd., New Delhi, 1988.

2. Microwave Engineering Passive Circuits – Peter A. Rizzi, PHI, 1999.

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Credits: 01 Teaching Scheme: - Tutorials 1 Hrs/Week


Objectives :

Study Basic properties and characteristics of certain microwave sources and

microwave components.

1. Study of Microwave components.

2. Derive the expressions for Waveguide parameters.

3. Mathematical analysis of Reflex klystron.

4. Study the characteristics of Reflex klystron.

5. Study the domain formation in Gunn diode.

6. Study V-I characteristics of Gunn diode.

7. Calculate Scattering matrix for Magic Tee.

8. Study port parameters of Magic Tee.

9. Study construction details of Circulator.

10. Calculate port parameters of Circulator.

11. Calculate Directivity, Coupling factor and insertion loss for 10 dB / 20 dB

Directional Coupler.

12. Plot radiation pattern of Horn antenna.


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Prerequisites: Basic knowledge of Digital Communication , Matrix algebra

Objectives:

To give inputs regarding Information Theory & coding techniques. Understand

the structures of the codes through the practical and appreciate the applications in

signal processing.

To understand the basics of Data compression and quantization techniques

To know the transform coding basics

Unit I : Information Theory & Source Coding (8 Hrs.)

A. Introduction, Information & Entropy, Probability & Markov models; Uniquely

decodable codes, Prefix codes, Source Coding Theorem, Shannon Fanon, Huffman

codes, optimality of Huffman Codes, Extended Huffman codes, adaptive Huffman codes

B. Discrete Memory less Channel & Mutual Information

Unit II : Error Control Coding (8Hrs.)

A. Linear Block Codes, Trellis Codes, Cyclic codes, Convolution Codes, Viterbii

decoding.

B. Channel capacity and coding allocations

Unit III : Lossless Coding Techniques (10 Hrs.)

A. Golomb & Rice codes, Arithmetic Coding, adaptive arithmetic coding, Dictionary

Techniques- Static & Adaptive Dictionary, Lempel Ziv Approaches- LZ77, LZ78, LZW,

File Formats- Graphic Interchange Format(GIF), Portable Network Graphics (PNG)

B. Applications– Lossless image compression, text compression, Audio Compression

EC 40103 :: Coding and Data Compression

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Unit IV : Scalar & Vector Quantization (7 Hrs.)

A. Uniform Quantizer, Adaptive Quantizer – Forward & Backward adaptive quantizer,

Jayant quantizer, non-uniform quantizer, vector quantization, Trellis coded quantization

B. Advantages of vector quantization over scalar quantization, Linde-Buzo-Gray (LBG)

algorithm, application of LBG algorithm to image compression

Unit V : Transform coding (7 Hrs.)

A. Necessity of transforms, Discrete Cosine, Sine, Walsh, Hadamard transform, KL

transform, Quantization and coding of transform coefficients, JPEG image compression.

B. Applications– Lossy image compression, Audio & Video Compression, Modified

Discrete Cosine Transform (MDCT)

Text Books

5. Simon Hyakins , ‘Communication systems’, Wiley Publications, 4th

edition 6. Khalid Sayood , ‘Introduction to Data Compression’, Elsvier publication, 3rd edition,

7. Graham Wade, ‘Coding Techniques – Introduction to compression & Error

control’,

Palgrave Publications

Reference Books

1. Ranjan Bose, ‘Information Theory & cryptography’, Tata McGraw Hill, 2002/2006

2. Saloman D, ‘Data compression – Complete reference ‘ , springer verlag, 3rd edition

3. Levis W.J. , ‘Data compression ‘ . Springer , 2nd

edition

8. Nelson Mark . Gaily . Jean , Loup , ‘Data Compression book’ , BPB publication,

2nd

edition

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List of Elective 1

Subject No. Subject Name Subject Code

01 Remote Sensing EC42101

02 Artificial Intelligence EC42102

03 Pattern Recognition EC42103

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Prerequisites: Electromagnetics

Objectives:

1) To study remote sensing applications

2) To study radar technology

3) To study designing radar experiments

4) To study interpreting radar results

5) To study contemporary issues such as InSAR

Unit I

(6 + 1Hrs)

Foundations and Scope of Remote Sensing

A. History of remote sensing, Electromagnetic Spectrum, Energy sources and

Radiation Principles, Energy Interactions in the Atmosphere, Energy

Interactions with Earth Surface Features.

B. Civil applications of remote sensing.

Unit II (10 +1 Hrs)

Radar Basics

A. Interaction of EM waves with matter, Basic Radar Configurations, Basic Radar

Measurements, Doppler Shift, Radar Block Diagram, Radar Range Equation,

Antenna Parameters, Radar Cross Section, Pulse Repetition Frequency, Range

resolution, Time resolution, Pulse compression techniques, Design of radar

experiments

B. Radar Transmitters, Radar Receivers

EC42101:: REMOTE SENSING

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Unit III (8 + 1Hrs)

Practical Radar considerations

A. Detection of Signals in Noise, Information from Radar signals, Radar clutter – land,

sea, surface, weather clutter, propagation of radar waves.

B. Theoretical accuracy of radar measurements.

Unit IV (8+1 Hrs)

Remote Sensing Applications in Space Sciences

C. Study of High Power Large Aperture radars, Phased arrays, Coherent and

Incoherent Scattering, Effect of radio science on actual radar measurements,

Study of E-region of ionosphere and its effect on communications.

D. Study of latest radar systems such as modular design radar such as the Advanced

Modular Incoherent Scatter Radar.

Unit V (8 + 1Hrs)

Remote Sensing Applications in Natural Disaster Assessment and Land Cover

Mapping

A. Radar Interferometer, Synthetic Aperture Radars (SAR), Interferometric Synthetic

Aperture Radar (InSAR), Applications of SAR - polar research, mapping ocean

currents, seismic events, volcanic hazards

B. Study of Alaska SAR Facility

Text Books

1) Introduction to Radar Systems by Merrill Skolnik

2) Radar Principles by Peyton Z. Peebles

Reference Books

1) Synthetic Aperture Radar Interferometry by Richard Balmer and Philipp

Hartl(1998) Inverse Problems 14 R1.

2) Radar Interferometry: A new technique for studying plasma turbulence in the

ionosphere by Farley and Fejer (1981) Journal of Geophysical Research Vol. 86,

No. A3

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Prerequisites: Electromagnetics

Objectives:

To study remote sensing applications

To study radar technology

To study designing radar experiments

To study interpreting radar results

To study contemporary issues such as InSAR

1. Electromagnetic Wave Propagation

2. Interaction of Electromagnetic Waves with various media

3. Radar Range Equation

4. IPP, Time and Range Resolution

5. Pulse compression techniques

6. Antenna Parameters

7. Polarization and Antenna Arrays

8. Detection of signal in noise

9. Design of real world radar experiments – I

10. Design of real world radar experiments - II

11. Faraday Rotation

12. Radar Interferometry

Text Books:

3) Introduction to Radar Systems by Merrill Skolnik

4) Radar Principles by Peyton Z. Peebles

EC4220 :: REMOTE SENSING

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Prerequsit: NIL

OBJECTIVE:- • To provide a strong foundation of fundamental concepts in Artificial Intelligence

• To provide a basic exposition to the goals and methods of Artificial Intelligence

• To enable the student to apply these techniques in applications which involve

perception, reasoning and learning.

Unit 1 : Introduction To Artificial Intelligence (6+1Hrs)

A) AI task domain, problem representation in AI, Problem characteristics.

B) Game playing using AI.

Unit 2 : Searching Techniques (9+1Hrs)

A) A.I. search process, non-heuristic and heuristic search techniques, , constrain

satisfaction and their applications.

B) Min-max search procedure.

Unit 3 : Knowledge Representation (8+1Hrs)

A) Hierarchy of knowledge, types of knowledge, knowledge representation, methods for

knowledge representation, predicate logic, Problems on predicate logic.

B) Introduction to PROLOG.

Unit 4 : Planning (8+1Hrs)

A) Components of planning system, goal stack planning technique.

B) Nonlinear Planning using Constraint Posting.

Unit 5: AI Tools (9+1Hrs)

A) Expert System Shells, Explanation, and Knowledge Acquisition. Human expert

behaviors, Expert system components, structure of expert system, the production system,

how expert system work and Expert system development for particular application.

Natural language processing: Introduction, Syntactic Processing, Semantic Analysis,

Discourse and Pragmatic Processing.

Architectures and functions in ANN, various learning rules. Building an ANN.

B) Building an Expert System

EC42102 :: ARTIFICIAL INTELIGENCE

http://www.indiastudychannel.com/resources/33356-CS-ARTIFICIAL-INTELLIGENCE-Syllabus-Anna.aspx

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Text Books:-

1. Elain Rich and Kerin Knight, “Artificial Intelligance”

2. Elements of Artificial Neural Networks - by Kishan Mehrotra, Chilukurik. Mohan,

Sanjay Ranka Penram International Publishing (India) Pvt. Ltd. Second edition,

Reference Books:-

1. Eugane. Charniak, Frew, “Introduction to Artificial Intelligance”, McDermott

2. Kishan Mehrotra, Sanjay Rawika, K. Mohan, “Arificial Neural Network”

3. Rajendra Akerkar, “Introduction to Artificial Intelligance”, Prentice Hall

Publication

4. Relevant IEEE papers.

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EC42202 :: ARTIFICIAL INTELIGENCE


Objectives:-

To understand AI representations and applications

To get familiar with Statistical and Probabilistic Reasoning

To understand neural network architecture

To realize expert system using architecture and case studies

List

1. T o study of any game playing using non heuristic search technique.

2. T o study of Eight tile puzzle.

3. T o study of heuristic search technique like A*.

4. T o study of heuristic search technique like AO*.

5. T o study of heuristic search technique like Hill Climbing.

6. Neural network architecture for character recognition..

7. Neural network architecture for pattern classification or clustering application.

8. Build an Expert System.

9. Mini-project (Individual task).

Text Books

1. Elain Rich and Kerin Knight, “Artificial Intelligence”

2. Roberts, “Artificial Intelligence”

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Prerequisites: Digital Signal Processing, Digital Image Processing, Probability Theory.

Objectives: To familiarize the student with

Pattern recognition Techniques

Bayesian decision theory

Non parametric Techniques

Different clustering Techniques.

Unit I (5 +1 Hrs)

Basics of pattern recognition.

A) Machine perception, Pattern recognition systems, design cycle, learning and

adaptation.

B) Case studies of Pattern recognition

Unit II (10+1 Hrs)


A) Bayesian Decision theory continuous and discrete features, minimum error rate

classification, classification discriminant function, Parameter estimation methods

like Maximum-Likelihood estimation, Gaussian mixture models, Expectation-

maximization method, and Bayesian estimation.

B) Bayesian belief network

Unit III (8+1 Hrs)

Nonparametric Techniques

A) Parzen-window method, K-Nearest Neighbour method, metrics and Nearest-

Neighbor Classification.

B) Fuzzy Classification

Unit IV ( 8+ 1 Hrs)

Linear discriminant function based classifiers

A) Linear discriminant function and decision surface, Perceptron, Support vector

EC42103 :: PATTERN RECOGNITION

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machines

B) Multicategory generalization

Unit V (9+1 Hrs)

Unsupervised learning and clustering

A) Criterion functions for clustering, Algorithms for clustering: K-means,

Hierarchical and other methods, Cluster validation, component analysis.

B) Low dimensional representation and multidimensional scaling

Text Books

1. Pattern Classification, R.O.Duda, P.E.Hart and D.G.Stork, John Wiley, 2001

2. Pattern Recognition, S.Theodoridis and K.Koutroumbas, 4th Ed., Academic Press,

2009

Reference Books

7. Pattern Recognition and Machine Learning, C.M.Bishop, Springer, 2006

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EC42203 :: PATTERN RECOGNITION


Prerequisites:

Objectives: To familiarize the student with

Pattern recognition Techniques


Non parametric Techniques

Different clustering Techniques.

List of Contents

1. Concept of pattern recognition and Machine perception.

2. Analysis of Bayesian Decision theory continuous features

3. Analysis of Bayesian Decision theory discrete features

4. Analysis of Maximum-Likelihood estimation

5. Study of different Classification methods.

6. Analysis of Neighbour method-1

7. Analysis of Neighbour method- 2

8. Analysis of Linear discriminant function

9. Analysis of Support vector machines

10. Analysis of Algorithms for clustering-1

11. Analysis of Algorithms for clustering -2

12. Analysis of cluster validation

Text Books

1. Pattern Classification, R.O.Duda, P.E.Hart and D.G.Stork, John Wiley, 2001

2. Pattern Recognition, S.Theodoridis and K.Koutroumbas, 4th Ed., Academic Press,

2009

Reference Books

1. Pattern Recognition and Machine Learning, C.M.Bishop, Springer, 2006

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List of Elective 2

Subject No. Subject Name Subject Code

01 Fiber Optic Communication EC42104

02 VLSI Design EC42105

03 Digital Image Processing EC42106

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Objectives :

To study Basics of fiber optic communication system.

To study different fiber optic cable manufacturing techniques

To study Light sources and detectors.

To study losses in fiber optic communication system.

Unit I

(8+1 Hrs)

INTRODUCTION TO FIBER OPTIC COMMUNICATION

A. Overview of optical fiber communication: Fiber optic communication system,

Advantages of optical fiber communication, Ray theory transmission, total internal

reflection. Parameters of fiber optic cable: Acceptance angles, Numerical aperture, skew

rays, Mode, Index Profile, V number. Types of fiber optic cable.

B. Material of fiber optic cable, Manufacturing process of fiber optic cable.

Unit II (8+1 Hrs)

SIGNAL DEGRADATION IN FIBER OPTIC CABLE

A. Signal distortion in optical fibers : Attenuation ,Material absorption ,Scattering losses

(linear) , Bending losses ,Dispersion present in FOC, Fiber attenuation measurement ,

Optical Time Domain reflectometer ( Principle, concept & applications).

B. Nonlinear scattering losses , Fiber dispersion measurement

Unit III (10+1 Hrs)

OPTICAL SOURCES , DETECTORS AND SENSORS

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A. Light emitting diode: LED power and efficiency, LED structures, LED characteristics,

Modulation.

Light amplification by stimulated emission of Radiation : Basic concepts of LASER,

Injection LASER structures.

Optical detectors: Optical detection principles, Characteristics of optical detector,

photodiode, PIN diode, Avalanche photodiode.

Optical sensors : Phase and polarization fiber sensors, Intrinsic fiber sensors, Extrinsic

fiber sensors,

B. Optical Connectors & splices to connect Fiber optic cables..

Unit IV (8+1 Hrs)

FIBER OPTIC SYSTEM

A. Optical transmitter circuit, Optical receiver circuit, Link power budget, Rise time

budget , Analog system design.

B. Digital system design

Unit V (6+1 Hrs)

REAL WORLD APPLICATIONS OF FIBER OPTICS

A. Study of fiber optics such as in

i) Underwater communication

ii) Telephone system

iii) Military applications

B. Optical Networks: SONET/ SDH , Wavelength Division multiplexing

Text Books

1. Gerd Keiser , “Optical Fiber Communications”, Mc Graw Hill

2. John M. Senior, “Optical Fiber Communications”, Prentice Hall

Reference Books 1. D.K. Mynbaev , S.C. Gupta and Lowell L. Scheiner, “Fiber Optic

Communications” Pearson Education, 2005.

2.Govind P. Agarwal , John Wiley, “ Fiber Optic Communication Systems”,3rd

Edition,2004. .

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Prerequisites: Nil

Objectives:

-To study concepts of CMOS Analog & Digital Design.

- To be familiar with CMOS fabrication process.

Unit I: MOSFET SPICE modeling (8+1 Hrs)

A] Modeling of semiconductor devices, MOSFET modeling, small signal model for

MOS transistor, Modeling of secondary & short channel effects, sub threshold modeling,

understanding role of parameters in model, Introduction to industry standard models

like PSP, Bsim.

B] Surface potential and threshold voltage based model.

Unit II: Analog CMOS sub-circuits (8+1 Hrs)

A] MOS Switch, Calculation of charge feed through error, MOS diode, Current Sink and

Sources, Designing cascade current sink for a given Vmin, Designing the self biased high

swing cascade current sink for a given Vmin, Current Mirrors, Aspect ratio errors in

current amplifiers, Reduction of the aspect ratio error in current amplifier, Current and

voltage references, Bandgap reference.

B] Design of a Bandgap voltage reference.

Unit III: CMOS Amplifiers (8+1 Hrs)

A] CMOS Amplifiers, Inverters, Active load Inverter, Current Source Inverter, Push pull

inverter, Noise analysis of inverter, Differential amplifier, Large Signal analysis,

Calculation of the worst case input common mode range of the N channel input

differential amplifier, Small signal analysis of differential amplifier, Slew rate and noise,

Current source load differential amplifier, Design of a CMOS differential amplifier with

a current mirror as a load.

EC42105:: VLSI DESIGN

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B] Cascode amplifier.

Unit IV: Datapath and Memory Design (8 + 1 Hrs)

A] Adder- Single bit adder, bit parallel adder, carry save adder, carry-lookahead adder,

carry select adder, transmission adder, Parity generator, comparators, Multipliers- Array

multiplier, Radix n-multiplier, Wallace tree multiplier, serial multiplier, Shifters-Barrel

shifter, logarithemic shifter, Synchronizers and Arbiters, CMOS Memories-classification

of memories, Memory architecture, read only memories, Nonvolatile read write

memories, Read write memories, memory peripheral circuits, Booth’s Multiplier.

B] Manchester Carry Adder.

Unit V: Fabrication and Layout (8 +1 Hrs)

A] Basic CMOS fabrication flow, front end and back end fabrication steps, Self aligned

CMOS process, N well, Twin tub, Design rules, Layout of CMOS Inverter, Verification

of Layout.

B] P well

Text Books

1. “Digital Integrated Circuits: A Design Perspective”, J. Rabaey, Prentice Hall

India.

2. “CMOS analog circuit Design”, P.E. Allen and D.r. Holberg, second Edition,

Oxford.

3. “VLSI Technology”, S.M.Sze, , TMH.

Reference Books


Wesley.

2. “CMOS”, RJ Baker, Wiley IEEE Press, 2004.

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Prerequisites: Digital Signal Processing.

Objectives:

To familiarize the student with the basic concepts about image, its formation,

human visual system and its limitations

To understand various image enhancement approaches

To apply the basic morphology principles

To understand image segmentation

To learn basic ideas of image compression

To prepare the background for student to apply principles learnt to practical cases

Unit I (8 +1 Hrs)

Digital Image Fundamentals and Image Enhancement

A) Elements of visual perception, Image sampling & Quantization, colour

fundamentals, colour models, pseudo colour image processing. Basic grey level

transformations, histogram processing, enhancement using arithmetic and logic

operators, spatial filtering – smoothing and sharpening filters. Smoothing and

sharpening

B) frequency domain filters

Unit II (6+1 Hrs)

Morphological Image Processing

A) Neighbourhood concepts, adjacency and distance measures, dilation & erosion,

opening & closing operations, basic morphological operations such as region

filling, thinning, thickening, skeletons, pruning for binary and gray scale images.

B) Morphological operations for gray scale images.

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Unit III (8+1 Hrs)

Image Segmentation

C) Detection of discontinuities, edge linking and boundary detection, thresholding,

region based segmentation, use of watersheds, image representation- chain codes,

boundary descriptors & regional descriptors

D) Other segmentation techniques

Unit IV (10+1 Hrs)

Image Transforms

C) Coding, interpixel and image redundancy; 2-D Discrete Fourier Transform,

Discrete Cosine Transform – its application in Baseline JPEG , Walsh Hadamard

Transform, Fast Walsh Transform, sub band coding Haar Transform – it’s

application as a Wavelet, multi resolution expansions, 1-D Wavelet Transform,

Fast Wavelet Transform; Introduction to Gabor Transform, Introduction to Radon

Transform,

D) Multycategory generalization

Unit V (8+1 Hrs)

Image Processing Applications

C) Applications of transforms in fingerprinting, Medical applications, Morphological

applications. Study of IEEE reference papers covering basic ideas of Transforms

and their applications

D) Other applications of image processing

Text Books

1. Digital Image Processing, Gonzalez, Woods, PHI , 2nd

edition

2. Digital Image Processing, Pratt W.K., John Wiley, 2001

Reference Books

1. Fundamentals of Digital Image Processing, Jain A.K., PHI, 1997

2. Image Processing , Analysis & Machine Vision, Milan Sonka, Thomson

Publication .

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Prerequisites: Basic knowledge of MATLAB Programming

Objectives: To learn the theoretical concepts of various types of coding and data

compression techniques using a suitable programming platform.

List of Practicals

1. Linear Block Coding/ Convolution Coding

2. Unique Decodability Test

3. Huffman Coding.

4. Golomb Coding

5. Arithmetic Coding

6. Lempel Ziv-77

7. Uniform Quantizer/Jayant /Trellis coded Quantizer

8. Trellis Coded Quantizer

9. Miniproject

EC 40301 :: Coding and Data Compression

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Credits: 01 Teaching Scheme: - Laboratory 2Hrs /week


Objectives :

Study the parameters and losses in fiber optic cable.

Study the characteristics of optical source and optical detector.

Study transmission of signals through fiber optic cable.

List of Practicals

1. Study and Measurement of Numerical Aperture of a fiber.

2. Measurement of attenuation loss and bending loss for various lengths of fiber

optic cable.

3. Study of transmission of Analog and Digital signals through fiber optic cable.

4. Study and plot V-I characteristics of optical source.

5. Study and plot frequency response of optical receiver.

6. Study of transmission of Voice through fiber optic cable.

7. Study of transmission of FM signal through fiber optic cable.

8. Study of Optical Fiber Connectorization kit.

9. Mini Project.

Text Books

1. Gerd Keiser , “Optical Fiber Communications”, Mc Graw Hill

2. John M. Senior, “Optical Fiber Communications”, Prentice Hall

EC42301 :: FIBER OPTIC COMMUNICATION SYSTEM

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EC42302:: VLSI DESIGN


Prerequisites: Nil

Objectives:

Design and conduct experiments using SPICE to characterize and optimize

digital integrated circuits.

Design, Verify, Analyze and Evaluate the performance (speed, Power, Area,

Noise margins of different MOS digital integrated circuits for different design

specifications.

Use CAD tool in the design and verification of digital integrated circuits.

List of Practical

I-V characteristics of MOS using SPICE

To simulate MOS as a switch

To simulate Current mirror

To simulate Differential Amplifier

To simulate Adder.

To simulate Latch.

To draw the layout of CMOS inverter.

To draw the layout of two input logic gate.

Course project based on Spice and/or Layout tool

Text Books

1. “Digital Integrated Circuits: A Design Perspective”, J. Rabaey, Prentice Hall

India.

2. “CMOS analog circuit Design”, P.E. Allen and D.r. Holberg, second Edition,

Oxford.

3. “VLSI Technology”, S.M.Sze, , TMH.

Reference Books


Wesley.

2. “CMOS”, RJ Baker, Wiley IEEE Press, 2004.

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EC42303 :: Digital Image Processing


Prerequisites: Nil

Objectives:

To familiarize the student with the basic concepts about image file formats

To understand various image enhancement approaches

To apply the basic morphology principles

To understand image segmentation

List of Practical

1. Study of BMP file format

2. Conversion of 24 bit color image to 8 bit , 4 bit, 1 bit image

3. Image negation, power Law correction

4. Histogram mapping & equalisation, stretching

5. Image smoothing , sharpening

6. Edge detection – use of Sobel, Prewitt and Roberts operators

7. Morphological operations on binary images

8. Morphological operations on Gray scale images

9. Pseudo coloring

10. Chain coding

11. Image statistics

12. DCT/IDCT computation

13. Transform application assignment.

Text Books

1. Digital Image Processing, Gonzalez, Woods, PHI , 2nd

edition

2. Digital Image Processing, Pratt W.K., John Wiley, 2001

Reference Books

1. Fundamentals of Digital Image Processing, Jain A.K., PHI, 1997

2. Image Processing, Analysis & Machine Vision, Milan Sonka, Thomson

Publication .

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MO

DU

LE

- V

III

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BE MODULE VIII

Subject

No.



S5 Computer

Networks /

Wireless

Communication

EC40104/

EC40105

3 0 0 3

Computer

Networks /

Wireless

Communication

EC40203/

EC40204

0 1 0 1

S6 Elective III EC421XX 3 0 0 3

Elective III EC422XX 0 1 0 1

S7 Embedded

Systems (MD)

EC41101 3 0 0 3

S8 Elective IV EC421XX 3 0 0 3

P3 Embedded

Systems (MD)

EC41301 0 0 2 1

P4 Elective IV EC423XX 0 0 2 1

Total 12 2 4 16

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List of Elective3

Subject

No.



S6 Microwave

Engineering */

Computer

Networks**

EC42107/

EC42108

3 0 0 3

Microwave

Engineering */

Computer

Networks**

EC42204/

EC42205

0 1 0 1

S6 Electronic

Automation

EC42109 3 0 0 3

Electronic

Automation

EC42206 0 1 0 1

S6 Artificial Neural

networks and

Fuzzy Logic

EC42110 3 0 0 3

Artificial Neural

networks and

Fuzzy Logic

EC42207 0 1 0 1

S6 Wireless Sensor

networks

EC42111 3 0 0 3

Wireless Sensor

networks

EC42208 0 1 0 1

List of Elective 4

Subject

No.



S8 Audio Video

Engineering

EC42112 3 0 0 3

P4 Audio Video

Engineering

EC42304 0 0 2 1

S8 Advanced Power

Electronics

EC42113 3 0 0 3

P4 Advanced Power

Electronics

EC42305 0 0 2 1

S8 Biomedical

Electronics

EC42114 3 0 0 3

P4 Biomedical

Electronics

EC42306 0 0 2 1

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Prerequisites: NIL

Objectives:

To understand basics of computer networking

To study and implement various protocols.

To study and implement LAN, WAN.

To study Network management techniques.

Unit I (6+1 Hrs)

OSI Reference Model and Network Architecture

A. Introduction to Computer Networks, Topologies, Types of Networks, Layering

architecture of networks, OSI model, Functions of each layer, Services and Protocols of

each layer

B. Communication media.

Unit II (10+1 Hrs)

TCP/IP Protocol suit

A. Introduction, History of TCP/IP, Layers of TCP/IP, Protocols, Internet Protocol,

Transmission Control Protocol , User Datagram Protocol, IP Addressing, IP address

classes, Subnet Addressing, Internet Control Protocols, ARP, RARP, ICMP, Application

Layer, Domain Name System, Email – SMTP, POP, FTP, WWW, HTTP,

B. Overview of IP version 6.

Unit III (8+1 Hrs)

Local Area Networks

A : Introduction to LANs, Features of LANs, Components of LANs, Usage of LANs,

LAN Standards, IEEE 802 standards, Channel Access Methods, Aloha, CSMA,

CSMA/CD, Token Passing, Ethernet, Fast Ethernet and Gigabit Ethernet

Standards, IEEE 802 standards, Channel Access Methods, Aloha, CSMA, CSMA/CD,

Token Passing, Ethernet, Fast Ethernet and Gigabit Ethernet,, LAN Standards, IEEE 802

standards, Channel Access Methods, Aloha, CSMA, CSMA/CD, Token Passing,

Ethernet, Fast Ethernet and Gigabit Ethernet

B. Interconnecting devices: Hubs, Switches, Bridges, Routers, and Gateways.

Unit IV (8+1 Hrs)

Wide Area Networks

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A. Introduction of WANs, Routing, Congestion Control, WAN Technologies, Distributed

Queue Dual Bus (DQDB), Synchronous Digital Hierarchy (SDH)/ Synchronous Optical

Network (SONET), Asynchronous Transfer Mode (ATM), Frame Relay.

B. Routing and congestion control algorithms

Unit V (8+1 Hrs)

Introduction to Network Management:

A. Remote Monitoring Techniques: Polling, Traps, Performance Management, Class of

Service, Quality of Service, Security management, Firewalls, VLANs, Proxy Servers

B. Simple encryption and decryption algorithms.

Text Books

1. Computer Networks (3rd edition), Tanenbaum Andrew S., International edition,

2. Data communication and networking (4th

edition), Behrouz A Forouzan, McGraw

– Hill.

Reference Books

1. Data and computer communication by William Stallings.

2. Computer Networking , James kurose & Keith Ross. , Low Price Edition.

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EC40203 :: Computer Network



Objectives:

List of Contents

1. Basic media/ channel used in Computer networks.

2. Cable and connectors prepration

3. LAN/MAC card

4. Network components

5. LAN MAN architecture

6. Design of Network

7. Sliding window protocol

8. Dial up modems

9. Web Server FTP server

10. Mini projects based on course

Text Books




– Hill.

Reference Books



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Prerequisites: Knowledge of Analog Communication and Digital Communication

Objectives:

To understand Wireless Communication systems and standards across the globe.

To understand the current trends and technologies in wireless Communication

To understand wireless Networks

Unit I (7+1 Hrs)

Wireless Communication Systems

A.. Introduction to Wireless Communication Systems, Examples of Wireless

Communication Systems, Trends in Cellular Radio and Personal Communications.

Modern Wireless Communication Systems: Second Generation (2G) Cellular

Networks, 2.5G, Third Generation (3G) wireless Networks,

The Cellular Concept: Introduction, Frequency Reuse, Channel Assignment strategies,

Hand off Strategies, interference and system capacity, improving coverage and capability

in Cellular Systems.

B. 4G standard, effects of electromagnetic Radiation of mobile base stations on human

body.

Unit II (7+1 Hrs)

Mobile Radio Propagation

A. Large Scale Path Loss: Introduction to Radio wave propagation , free space

propagation model, propagation mechanisms, Practical Link Budget design using path

loss models, Out door propagation models, Indoor propagation models, signal penetration

into buildings, Ray tracing and site specific modeling.

Small Scale Path Loss: Small Scale Multi path propagation, small scale multi-path

measurements, parameters of mobile multi path channels, Types of small scale fading,

Examples of fading behaviour.

B. Raleigh and Racian distribution, Statistical models for multi path fading channels.

Unit III (7+1 Hrs)

EC 40105 :: WIRELESS COMMUNICATION

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Multiple Access Techniques for Wireless Communications

A. Introduction to multiple access, Frequency Division Multiple Access (FDMA), Time

Division Multiple Access (TDMA), Spread Spectrum Multiple Access, Space Division

Multiple Access (SDMA), Capacity of Cellular Systems.

B. Packet Radio Protocols, Carrier Sense Multiple Access Protocols. Reservation

protocols.

Unit IV (7+1 Hrs)

Wireless Networking

A. Introduction to Wireless Networks, differences between Wireless and fixed

Telephone Networks, Development of Wireless Networks, Traffic routing in Wireless

Networks, Wireless Data Services, Common Channel Signaling, Integrated Services

Digital Network (ISDN), Introduction to Signaling System No.7(SS7), Protocols for

network access. Personal Communication Services / Networks, Protocols for network

access.

Wireless LAN: Infrastructure and Adhoc Networks, IEEE 802.11 , HIPERLAN,

introduction to Bluetooth.

B. An example of SS7- Global Cellular Network inter operability, performance of SS7.

Unit V (7+1 Hrs)

Wireless Systems and Standards

A. AMPS and ETACS, United States Digital Cellular (IS-54 and IS-136), Global System

for mobile (GSM), CDMA, Digital Cellular Standard (IS-95), CT2 Standard for Cordless

Telephones, Digital European Cordless Telephone (DECT) Standard, Personal Access

Communication Systems (PACS).

B. TRAI Standards for GSM, DECT and GPRS.

Text Books

1. Wireless Communications- Principle and practice, Theodore S, Rappaport, Second

edition, PHI

2. Mobile Communications, Jochen Schiller, Second Edition, Pearson Education.

References

1. www. Trai.gov.in

2.Relevant IEEE Papers

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Credits: 01 Teaching Scheme: Tutorial 1 Hr/Week

Prerequisites: : Knowledge of Analog Communication and Digital Communication

Objectives:

To study Wireless Communication systems and standards across the globe.

To study the current trends and technologies in wireless Communication

To study wireless Networks

List of Contents

1. TRAI regulations on 3G and 4G Technologies

2. Study and discussion of IEEE papers on Frequency Re use , Channel assignment

3. Interference, Capacity improvement and Coverage improvement.

4. Large Scale Path Loss

5. Small Scale path loss

6. Multiple Access Techniques for wireless communication(CSMA)

7. Multiple Access Techniques for wireless communication( Packet Radio)

8. Wireless Networking Techniques

9. Traffic Routing in wireless Networks

10. Performance improvement of Wireless Networks

11. Network Access Protocols

12. Next Generation Networks.

Text Books

1. Wireless Communications- Principle and practice, Theodore S, Rappaport, Second

edition, PHI

2. Mobile Communications, Jochen Schiller, Second Edition, Pearson Education.

References

1. www. Trai.gov.in

2.Relevant IEEE Papers

EC 40204 :: WIRELESS COMMUNICATION

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Prerequisites: Digital Electronics and Microcontroller

Objectives:

To study Hardware and Software architecture of ES.

To study ARM7 architecture and learn its assembly language programming

To study wireless protocols

To study field bus protocols

To study architecture of Real Time Operating Systems (RTOS )

To study System Design Techniques

Unit I (8+1 Hrs)

Embedded System Architecture

A.Introduction, History, Application of embedded systems, Hardware and software

architecture ,Processor selection for Embedded System, Memory Architecture and IO

devices , Interrupt Service Mechanism ,Context switching, Device Drivers

B. Recent trends in embedded systems.

Unit II (8+1 Hrs)

Embedded processors

A.

ARM Processor: Architecture and Programming: RISC and CISC , ARM organization ,

ARM Programmers model , operating modes , Exception Handling , Nomenclature.

Introduction to ARM instruction set

B. ARM Core Extensions

Unit III (8+1 Hrs)

Unit Name : Protocols

EC41101 :: Embedded Systems

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A.

Bluetooth , Wireless Ethernet ,MODBUS, CAN and USB

B.

Applications of protocols

Unit IV (8+1 Hrs)

Unit Name : : Real Time Operating System

A.

Architecture of the kernel , Task scheduler , ISR , Semaphores , Mailbox , Message

queues , Pipes , Events , Timers , Memory Management .

B.

RTLinux architecture and specifications

Unit V (8+1 Hrs)

Unit Name : System Design Techniques

A.

Design goals ,Development strategies ,software development, crosss

compilation and code generation, porting to the final target system, generation

of test modules, Target hardware testing ,future techniques, relevance to more

complex design, the need for emulation

Examples- Burglar alarm system, Set Top box, Smart card

B.

Automobile electronic

Text Books

4. Raj Kamal ,”Embedded Systems “ TMH

5. Sloss etal ,”ARM Developers Guide”.

Reference Books

1 Dr. K.V.K.K. Prasad “Embedded / Real Time Systems” Dreamtech

2 Iyer , Gupta “ Embedded Real systems programming “ TMH.

3 Steve Heath “ Embedded System Design “ Neuwans.

4 Frank Vahid , “Embedded System Design.

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List of Elective3


01 Microwave Engineering */

Computer Networks**

EC42107/

EC42108

02 Electronic Automation EC42109

03 Artificial Neural networks and Fuzzy Logic EC42110

04 Wireless Sensor networks EC42111

*For Electronics Students

**For E and TC students

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Objectives :

To study Basics of Microwave communication system.

To study different Waveguide components and applications.

To study Microwave Tubes.

To study Microwave solid state devices

Unit I

(6+1 Hrs)

MICROWAVE TRANSMISSION LINES

A. Overview of Microwave communication : Microwave communication system ,

Advantages and applications of Microwaves. Rectangular Waveguides – TE/TM mode

analysis, Expressions for Fields, Characteristic Equation and Cut-off Frequencies,

Dominant Modes. Mode Characteristics – Phase velocity and Group Velocity. Power

Transmission and Power Losses in Rectangular Waveguide.

B.Circular Waveguides : Introduction, Nature of fields, Characteristic Equation,

Dominant mode, Impossibility of TEM mode.

Unit II (8+1 Hrs)

WAVEGUIDE COMPONENTS AND APPLICATIONS

A. Cavity Resonators– Introduction, Rectangular and Cylindrical Cavities, Dominant

Modes and Resonant Frequencies, Q factor and Coupling Coefficients.

Waveguide Multiport Junctions – E plane Tee, Magic Tee.

Ferrite Components – Gyrator, Isolator. Scattering Matrix– Significance, Formulation

and Properties. S Matrix Calculations for E plane, Magic Tee, Gyrator& Isolator.

B. Study H-plane, Directional Coupler, Circulator & find out S Matrix Calculations for

H-plane, Directional Coupler, Circulator.


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Unit III (10+1 Hrs)

MICROWAVE TUBES

A. Limitations and Losses of conventional tubes at microwave frequencies.

Microwave tubes – O type and M type classifications.

i)O-type tubes : 2 Cavity Klystrons – Structure, Velocity Modulation Process and

Applegate Diagram, Bunching Process , Expressions for o/p Power and Efficiency.

HELIX TWTS: Significance, Types and Characteristics of Slow Wave Structures;

Structure of TWT , Expressions for o/p Power and Efficiency.

ii) M-type Tubes

Introduction, Cross-field effects, Magnetrons – Different Types, 8-Cavity Cylindrical





B.Reflex Klystrons – Structure, Applegate Diagram and Principle of working,

Mathematical Theory of Bunching, Power Output, Efficiency, Oscillating Modes and o/p

Characteristics.

Unit IV (8+1 Hrs)

MICROWAVE SOLID STATE DEVICES

A. Principle, Construction, Characteristics and applications of Gunn Diode , Tunnel

Diode, PIN diode,Varactor diode, MASER.

B Principle, Construction, Characteristics and applications of PIN diode, IMPATT and

TRAPATT.

Unit V (8+1 Hrs)

REAL WORLD APPLICATIONS OF MICROWAVE ENGINEERING

A. Study of Microwave engineering such as in

i) Radars

ii) Communication

iii) Industrial applications

B. Microwave Power Measurement – Bolometer Method. Measurement of Attenuation,

Frequency, VSWR, Cavity Q. Impedance Measurements

.

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Text Books

1. Microwave Devices and Circuits – Samuel Y. Liao, PHI, 3rd Edition .

2. Micro Wave and Radar Engineering – M. Kulkarni, Umesh Publications

Reference Books 1.Elements of Microwave Engineering – R. Chatterjee, Affiliated East-West Press Pvt.

Ltd., New Delhi, 1988.

2. Microwave Engineering Passive Circuits – Peter A. Rizzi, PHI, 1999.

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Credits: 01 Teaching Scheme: - Tutorials 1 Hrs/Week


Objectives :

Study Basic properties and characteristics of certain microwave sources and

microwave components.

1. Study of Microwave components.

2. Derive the expressions for Waveguide parameters.

3. Mathematical analysis of Reflex klystron.

4. Study the characteristics of Reflex klystron.

5. Study the domain formation in Gunn diode.

6. Study V-I characteristics of Gunn diode.

7. Calculate Scattering matrix for Magic Tee.

8. Study port parameters of Magic Tee.

9. Study construction details of Circulator.

10. Calculate port parameters of Circulator.

11. Calculate Directivity, Coupling factor and insertion loss for 10 dB / 20 dB

Directional Coupler.

12. Plot radiation pattern of Horn antenna.


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Prerequisites: NIL

Objectives:

To understand basics of computer networking

To study and implement various protocols.

To study and implement LAN, WAN.

To study Network management techniques.

Unit I (6+1 Hrs)

OSI Reference Model and Network Architecture

A. Introduction to Computer Networks, Topologies, Types of Networks, Layering

architecture of networks, OSI model, Functions of each layer, Services and Protocols of

each layer

B. Communication media.

Unit II (10+1 Hrs)

TCP/IP Protocol suit

A. Introduction, History of TCP/IP, Layers of TCP/IP, Protocols, Internet Protocol,

Transmission Control Protocol , User Datagram Protocol, IP Addressing, IP address

classes, Subnet Addressing, Internet Control Protocols, ARP, RARP, ICMP, Application

Layer, Domain Name System, Email – SMTP, POP, FTP, WWW, HTTP,

B. Overview of IP version 6.

Unit III (8+1 Hrs)

Local Area Networks

A : Introduction to LANs, Features of LANs, Components of LANs, Usage of LANs,

LAN Standards, IEEE 802 standards, Channel Access Methods, Aloha, CSMA,

CSMA/CD, Token Passing, Ethernet, Fast Ethernet and Gigabit Ethernet





B. Interconnecting devices: Hubs, Switches, Bridges, Routers, and Gateways.

Unit IV (8+1 Hrs)

Wide Area Networks

A. Introduction of WANs, Routing, Congestion Control, WAN Technologies, Distributed

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EC 42108 :: COMPUTER NETWORK

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Queue Dual Bus (DQDB), Synchronous Digital Hierarchy (SDH)/ Synchronous Optical

Network (SONET), Asynchronous Transfer Mode (ATM), Frame Relay.

B. Routing and congestion control algorithms

Unit V (8+1 Hrs)

Introduction to Network Management:

A. Remote Monitoring Techniques: Polling, Traps, Performance Management, Class of

Service, Quality of Service, Security management, Firewalls, VLANs, Proxy Servers

B. Simple encryption and decryption algorithms.

Text Books



edition), Behrouz A Forouzan, McGraw –

Hill.

Reference Books



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EC42205 :: COMPUTER NETWORK



Objectives:

List of Contents

1. Basic media/ channel used in Computer networks.

2. Cable and connectors prepration

3. LAN/MAC card

4. Network components

5. LAN architecture

6. MAN architecture

7. Design of Network

8. Sliding window protocol

9. Dial up modems

10. Web Server

11. FTP server

12. Encryption /Decryption

13. Routing Algorithm

Text Books




– Hill.

Reference Books



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Prerequisites: Basics of control system, Op-Amp, and PLC

Objectives: To understand

- Hierarchy of automation

- Automation tools

- Controller principles

Unit I

(6+1 Hrs)

Unit Name: Introduction to Industrial Automation

A. Introduction and Architecture of automation, Types, pyramid of automation,

advantages and disadvantages, Advanced functions, Approach to automation, Manual

labor, and control levels.

B. Industrial Safety legislations and regulations, Safety by design.

Unit II

(8+1 Hrs)

Unit Name: Automation Tools

A. PLC- Architecture, Justification for use of PLC, Communication networking of PLC,

Ladder programming. HMI- Functions, alarming modes, type of display-graphic, trend,

group, detail. DCCS-advantages of decentralized control system, architecture, hierarchy,

SCADA- Architecture, functions of key elements of SCADA, applications.

B. Intelligent sensors in industrial and process automation, MEMS. Communication

networking protocols in automation.

Unit III (10+1 Hrs)

Unit Name: Controller Principles

A. Control system parameters, on-off, two position, and multi-position controllers,

Proportional, Derivative, and Integral controllers, PI, PD, PID controllers, analog

representation of composite controller, Stability concepts, Controller tuning, Controller

configurations, Fuzzy controller in control applications- concepts, membership

functions, fuzzy inference, defuzzfication methods, Fuzzy controller in automation.

B. Interacting and non-interacting PID controller.

EC 42109:: ELECTRONIC AUTOMATION

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Unit IV (8+1 Hrs)

Unit Name: Digital Controllers

A. Introduction of digital controllers, Models of A/D and D/A converters, Types of

digital controller- recursive, non-recursive, Realization of digital PID controller- digital

temperature control system, non-interacting velocity algorithm, digital position control

system.

B. Study of Model based controller, adaptive controller

Unit V (8+1 Hrs)

Unit Name: Automation Applications

A. Building automation system- Building management system, HVAC control, wireless

networking, Building control network. Railway signaling- Detection of trains, need of

signaling, release of locking, Implementation of railway signaling, PES in railway

signaling. High speed rail signaling system, Automotive Electronics- navigation/driver

guide system, ECU, vehicle communication standards, safety.

B. Networking protocols in BAS and vehicles.

Outcome: Students will be able to

- Design controller for automation application

- Design industrial automation system

Text Books

1. C. D. Johnson - Process Control Instrumentation

2. M. Gopal - Digital Control and state variable methods

Reference Books

1. Ogata - Modern Control Systems

2. Bela Liptak -Handbook of Process Control

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List of tutorials:

1. Discontinuous controllers

2. Continuous controllers

3. PLC programming

4. State variables

5. Stability analysis

6. Design of classical controller

7. Design of intelligent controller

EC 42206:: ELECTRONIC AUTOMATION

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Prerequisites: nil

Objectives: 1. To give overview of Neural network systems and standards across the globe.

2. To create awareness in the current trends and technologies in Neural networks

3. To learn different neural Networks.

Unit_1 Introduction to ANN :- (04Hrs)

PART ( A) History of Neural networks, Neural net architecture, Neural learning, Evaluation of

networks, Implementation.

PART (B)

Applications of neural networks.

Unit_2 Supervised Learning (10Hrs)

PART (A) Perceptions , Linear separability, preceptron training algorithms, modifications,

Support vector machines, Multilevel discrimination, back propagation algorithm.

Adaptive multilayer networks, predication networks, Polynomial Networks.

PART (B)

Radial basis functions, probabilistic networks.

UNIT _3 Unsupervised & Associative Learning (12Hrs)

PART (A) Winner-Takes –All network, Learning vector quantization, counter propagation

networks, Adaptive Resonance theory, Topological Organized networks ,Distance based

learning, Max Net, Competitive Net. Associative non iterative procedures for association,

Hop field networks ,Optimization, Learning using Hopfield networks, Brain state in a

box network.

PART (B)

Principal Component Analysis, Boltzman machines, Hetero-associators

UNIT _4 Evolutionary Optimization :- (08Hrs)

PART (A)

Optimization and search, Evolutionary Computation, Evolutionary Algorithms for

training neural networks, Learning connection weights, Learning architectures.

EC42110:: ARTIFICIAL NEURAL NETWORKS AND FUZZY LOGIC

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PART (B)

Hybrid evolutionary Approaches.

UNIT _5 Fuzzy Logic (06Hrs)

PART (A)

Fuzzy sets and fuzzy rules, Fuzzy relations, Properties of Fuzzy sets, Fuzzy graphs ,

Fuzzy numbers, Functions with Fuzzy arguments, Arithmetic operations on fuzzy

numbers.

PART(B)

Applications of fuzzy logic.

Text books

1. Elements of Artificial Neural Networks - by Kishan Mehrotra, Chilukurik.

Mohan, Sanjay Ranka Penram International Publishing (India) Pvt. Ltd. Second

edition,

2. Fuzzy Logic by John Yen,Reza Langari, Pearson Educations, First edition.

Reference books

1. Neural Network and Fuzzy system by Bart Kosko, John c. Burgess.

2. Fundamental of Artificial Neural Networks. By M.H. Hassoun.

3. Introduction to Artificial Neural Network system by M.Zurada.

4. Relevant IEEE Papers.

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Objectives:

To give overview of neural network systems and to built neural network systems.

To create awareness in the current trends and technologies in Neural networks

To learn different neural Networks.

To built and test following Neural Networks:

1) Perceptron Neural Network.

2) Hebbin Neural Network.

3) Hamming Neural Network.

4) Hanning Neural Network.

5) McCulloach Pitts Neural Network.

6) Back propagation Neural Network.

7) Max Net Neural Network.

8) Competitive Neural Network.

9) Mini project.

Text books

1. Elements of Artificial Neural Networks - by Kishan Mehrotra, Chilukurik. Mohan,

Sanjay Ranka Penram International Publishing (India) Pvt. Ltd. Second edition,

2. Fuzzy Logic by John Yen,Reza Langari, Pearson Educations, First edition.

Reference books

1. Neural Network and Fuzzy system by Bart Kosko, John c. Burgess.

2. Fundamental of Artificial Neural Networks. By M.H. Hassoun.

3. Introduction to Artificial Neural Network system by M.Zurada.

4. Relevant IEEE Papers.

EC42207:: ARTIFICIAL NEURAL NETWORKS AND FUZZY LOGIC

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Prerequisites: Students having basic knowledge of electronics.

Objectives:

1. To create awareness about the challenging field of Wireless Sensor Networks.

2. To introduce various basic principles of operation of a WSN.

3. To create a research attitude amongst the students.

4. To install network simulator ns-2 & simulate different wireless ad-hoc scenarios.

5. To become aware about the research avenues in WSN.

Unit I (8 + 1 Hrs)

Introduction and WSN Infrastructure

A. Introduction, Sensor Network Concept, WSN constraints and challenges, WSN

applications, WSN development stage – deployment, localization and tracking, data

communication. Design of sensor motes, low power WSN, Clustering, Topology control.

B. WSN applications

Unit II

(8+ 1 Hrs)

Localization and Sensor - Medium Access Control

A. Sensor management and Bayesian networks, Time synchronization, Types of

Localization, Key assumptions, Fundamentals of MAC protocols, Energy conservation

MAC protocols like S-MAC, P-MAC, Z-MAC, T-MAC, L-MAC etc, IEEE 802.15.4

standard.

B. Localization algorithms

Unit III (8+1 Hrs)

Routing protocols for WSN and Network simulators

A. Delaunay triangulation, Prim’s algorithm, Euclidean minimum spanning tree, DSR

algorithm, Network simulators – Introduction to TinyOS, Nes C, TOSSIM, NS-2.

EC 42111 :: WIRELESS SENSOR NETWORKS

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B. Simulations in ns-2

Unit IV (8+1 Hrs)

Security Issues

A. Attacks in WSN, Wormhole attack, DOS attack, Sybil attack, Methods for increasing

immunity to attacks, Effect of attacks on QoS

B. Comparison study of the various in WSN, Countermeasures to sustain the attacks.

Unit V (8+1 Hrs)

Performance and traffic management in WSN

A. Performance modeling – Traffic model, Energy model etc, Computation of WSN

system life span. Critical analysis of IEEE papers on ad-hoc wireless sensor networks.

B. Modification of energy models to suit the various operating environments of WSN.

Text Books

1. “Wireless Sensor Networks – Technology, Protocols & Applications”, Kazem

Sohraby, Daniel Minoli, Taieb Znati, Wiley Publication.

2. “Wireless Sensor Networks- An Information Processing Approach”, Feng Zhao,

Leonidas Guibas. Elsevier.

Reference Books

1. IEEE papers on MAC protocols.

2. IEEE papers on Attacks in WSN.

3. “Getting started with ns-2” http://nsnam.isi.edu

4. “NS by example” http://nile.wpi.edu/NS/menu.html

http://nsnam.isi.edu/

http://nile.wpi.edu/NS/menu.html

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EC 42208 ::WIRELESS SENSOR NETWORKS


Prerequisites: Students having basic knowledge of electronics.

Objectives:

1. To create awareness about the challenging field of Wireless Sensor Networks.

2. To introduce various basic principles of operation of a WSN.

3. To create a research attitude amongst the students.

4. To install network simulator ns-2 & simulate different wireless ad-hoc scenarios.

5. To become aware about the research avenues in WSN.

List of Contents

1. Installation of Linux Ubuntu.

2. Installation of Linux Ubuntu.

3. Installation of ns-2 network simulator.

4. Installation of ns-2 network simulator.

5. Simulation of 2-node topology.

6. Simulation of 2-node topology.

7. To generate a trace file & study its contents.

8. To generate a trace file & study its contents.

9. To create output files for XGraph.

10. To create output files for XGraph.

11. To generate node movement and traffic connection files for large wireless

scenarios.

12. To generate node movement and traffic connection files for large wireless

scenarios.

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List of Elective 4


01 Audio Video Engineering EC42112

02 Advanced Power Electronics EC42113

03 Biomedical Electronics EC42114

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Prerequisites: Communication Engineering & Digital Communication.

Objectives:

To study

Concepts of Color Television (CTV) Transmitter and Receiver.

Working Principle of Digital Television (DTV) and High Definition Television

(HDTV).

Compression Techniques.

Direct to Home (DTH) Receiver, Digital Video Disc (DVD) player, Digital

Satellite Radio (DSR).

Unit I (6+1Hrs)

Unit Name : Basics of Television

A) Scanning process, Composite Video Signal, Horizontal Blank and Sync standard,

Vertical Blank and Sync standard, Vestigial Sideband Transmission, TV Channels and

Bands, CCIR-B standards, Negative modulation, Inter-carrier Sound System.

B) Construction & working principle of CCD camera.

(Self Study Part of Individual Unit) Unit II (7+1Hrs)

Unit Name : TV Transmission and Reception

A) High Level modulated TV Transmitter , IF modulated TV Transmitter, Transmitting

Antenna, Receiving Yagi Antenna, Block Diagram of Monochrome Receiver, Pattern

Generator, Wobbuloscope .

B) Basic satellite theory ( Transponder), Cathode Ray Tube.

Unit III (9+1 Hrs)

Unit Name : Color TV Systems

A) Color fundamentals, Mixing of colors, Color perception, Color Characteristics,

Chromaticity diagram, Color TV camera, Frequency Interleaving Principle, Color

Bandwidth, Chroma Signal Generation, Color Burst, Simple PAL & PAL-D System,

PAL Encoder, PAL Decoder, CTV Receiver Block Diagram, Monochrome and Color

Picture Tubes, NTSC, PAL, SECAM systems.

EC42112:: AUDIO VIDEO ENGINEERING

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B) Chromaticity diagram, SAW filter.

Unit IV (9+1 Hrs)

Unit Name : Digital Television

A) Merits of DTV, Digitization formats, Source Coding : Compression of Video Signal

(JPEG&MPEG), Scrambling and Conditional Access, Channel Coding, Modulation by

Digital Signal, Reception of Digital TV Signal, Digital TV Receiver block diagram,

LCD and Plasma Displays, Types of digital TV ( SDTV, EDTV, HDTV), DTH system.

B) Closed Circuit Television (CCTV), Cable Television (CATV).

Unit V (9+1 Hrs)

Unit Name : Recording And Reproduction

A) A. Principle of MPEG Audio compression, MPEG audio layer III ( MPIII format),

MPEG-1 audio encoder & decoder, Methods of Recording and Reproduction : Magnetic

Recording, Optical Recording, CD/DVD/MP3 Player, Digital Satellite Radio.

B) Construction & working principle of camcorder.

Text Books

1. R.R.Gulathi, “Monochrome & color television”, New Age International.

2. Herve Benoit, “Digital Television”, Focal Press.

Reference Books

1. Bernard Grobb & Charles E., “Basic TV and Video Systems”, McGraw Hill.

2. Ranjan Parekh, “ Principles of multimedia”, Tata Mc-GrawHill

3. R.G. Gupta, “Audio Video Systems”, Technical Education.

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Prerequisites: Basics of Power devices, Basics of Power Conversion systems,

Basics of AC/DC Motors, Fourier series for analytical approach

Objectives:

To explain the necessity of power factor improvement & techniques.

To study the use of converters & inverters for speed control of motors.

To study harmonic control techniques in power conversion.

To discuss various measurement techniques in power electronics.

Unit I (8+1 Hrs)

3 Phase AC/DC Converters

A. Operation and Analysis of 3 phase Semi/ Full Converter with R and R-L load, Effect

of Source Impedance(Ls) on Single phase converter, Single phase and Three Phase Dual

Converters (Ideal and Practical), Control schemes for non circulating type dual converter,

Analysis of circulating current type dual converter.

B. Calculation of converter output with Ls, Microprocessor based firing scheme for dual

Converter converter.

converter.

Unit II (8+1 Hrs)

3 Phase Inverters

A. 3 Phase Transistorized Voltage Source Inverter(VSI)- 120° and 180° mode of

operation and analysis, PWM Inverters- Techniques and comparison, Voltage Control

and Harmonic Reduction in inverters, Introduction to Current Source Inverter.

B. Space Vector Modulation, Multilevel inverters

Unit III (8+1 Hrs)

PF Improvement and Instrumentation

A. Series and Parallel Operation of Power Devices- String Efficiency, Derating,

Triggering requirements, Need of equalizing Network.

Power Factor Improvement Techniques-PAC, Forced Commutation (SAC, EAC),

Sequence Control of Series Connected Converters.

Sensing and measurement of Sinusoidal and non-sinusoidal Voltage and Current, Speed,

Power Factor etc.

EC42113:: ADVANCED POWER ELECTRONICS

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B. Protection and Cooling of power switching devices

Unit IV (8+1 Hrs)

DC Motor Drives

A. Motor Performance Parameters, 1phase and 3phase converter drives for separately-

excited and series DC motors for continuous and discontinuous operation, Braking

techniques for DC and AC (IM) motors.

B. Suitability/ Selection of a drive based on process requirements (Matching of load,

Motor, and converter), Brushless dc motor and drive.

Unit V (8+1 Hrs)

AC Motor Drives and Power Quality

A. Motor Performance, Speed Control techniques of 1ph/3ph Induction Motor (Stator

Voltage, Frequency, V/F, Rotor resistance), Protection Circuit for AC/DC Motor drives-

Over/Under voltage and current, Phase failure, Field failure, soft start-stop, Effect of non-

sinusoidal supply on motor performance.

Power Quality- Types of Power line disturbances, Sources and Measurement of power

line disturbances, Preventive Techniques.

B. Slip Power Recovery control of Induction motors, Energy Audit

Text Books

1. M D Singh & Khanchandani,“Power Electronics”, Tata McGraw Hill, IInd

edition

2. M. H. Rashid, “Power Electronics”, 3 edition, Pearson Education, 2004

Reference Books

1. Mohan, Undeland & Robbins, “Power Electronics”, 3 edition, John Wiley, 2003

2. Dubey, Doralda, Joshi & Sinha, “Thyristorised Power Controllers”, New Age

International, 1986

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

4. B. K. Bose, “Modern Power Electronics & AC Drives”, Pearson Education, 2002

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Prerequisites: Nil

Objectives:

To understand basics of Biomedical Instrumentation

To study and understand ECG,EEG,AMG

To study and understand Laboratory equipments

To study and understand Radiology equipments

Unit I (9+1 Hrs)

Introduction to Biomedical System

A. Introduction to Biomedical System, Man Machine Interface, Bio-electric Signals,

Types of Electrodes, Electrodes for ECG, EMG, EEG, Cardiovascular System, Heart

Anatomy, ECG Amplifiers, ECG Machine. Electrocardiography.

B. Transducers and sensors related to biomedical measurements, Fiber Optic sensor for

temp.

Unit II (9+1 Hrs)

Cardiography

A. Heart Rate, Heart Sound, Blood pressure and Blood Flow Measurements.

Phonocardiography, Echocardiography, Vector Cardiography, Stress Testing System,

Beside Monitors, Central Monitoring System, Pacemakers, Defibrillators.

B. Grounding and Shielding, Patient Safety.

Unit III (7+1 Hrs)

Laboratory Equipments

EC 42114 :: BIOMEDICAL ELECTRONICS

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A. Basic working principle use calibration and maintenance of - Colorimeter,

Spectrophotometer, Flame photometer, PH/Blood Gas Analyzer, Pulse Oximeter,

Hemodialysis, Blood Cell Counter.





B. Autoanlyzer

Unit IV (8+1 Hrs)

Nervous System

A. Nervous system Anatomy, Human Brain Recording of EEG Signal, EEG Amplifier,

Electroencephalography, Electromyography.

B. Analysis of Diseases using EEG and EMG signals.

Unit V (7+1 Hrs)

Radiology equipments

A. Diagnostic Medical instruments: X – ray, CT scan, MRI, Ultrasonic Doppler Machine,

Lasers in Medicine.

B. Use of Laser in Vision Correction, Dermatological.

Text Books

1. Cromwell, “Biomedical Instrumentation and Measurement”, PHI.

2. Carr and Brown, “Biomedical Instrumentation”.

Reference Books

1. R. S. Khandpur, “handbook Biomedical Instrumentation”, by Tata MaGraw Hill

2. Webster, “Application and Design of Medical Instruments".

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Credits: 02 Teaching Scheme: - Practical 2 Hrs/Week

List of Practicals

Expt

No.

Experiment

01 Interfacing LED to LPC2294

02 Interfacing Seven Segment to LPC2294

03 Interfacing 4X4 Matrix Keyboard to LPC2294

04 Interfacing 2X16 LCD in 4bit Mode to 2294

05 LPC 2294 Serial Communication

06 LPC 2294 ADC

07 Power Down Mode of LPC2294

08 Interfacing LCD and Keyboard to LPC2294 with RTOS

09 Task scheduling with priority using RTOS functions

10 Implementation of semaphore for given task switching using RTOS

Subject Code EC41301 :: Embedded Systems

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Credits: 01 Teaching Scheme: - Laboratory 2 Hr/Week

Prerequisites: Communication Engineering & Digital Communication.

Objectives:

To Study

Equipment like Pattern Generator, Wobbuloscope which can be used for Color TV

servicing

To study different sections in Color TV receiver

To study TV transmitter, TV studio, DTV, HDTV, DTH, DVD player and DSR

block schematics

List:

1. Study of Video signal generation.

2. VIF amplifier response using Wobbuloscope

3. Voltage and Waveform Analysis of Color TV.

4. Video amplifier response testing

5. Sync separator

6. Video Compressing Technique.

7. Design of an Yagi antenna

8. Color spaces

9. Remote control circuit

10. Public address system

11. TV connectors

12. Video bandwidth calculation

13. Concept of IF & its choice

14. Design of a video detector

15. Horizontal output stage

16. Trouble shooting in a TV receiver

EC42304:: AUDIO VIDEO ENGINEERING

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Credits: 01 Teaching Scheme: - - Laboratory 2 Hr/Week

Prerequisites: Basics of Power devices, Basics of Power Conversion systems,

Basics of AC/DC Motors, Fourier series for analytical approach

Objectives:

To verify operations of power converter systems for different types of loads

To gain hands on experience on different AC / DC motor drives & it’s protection

Systems

Use of simulation software for analysis of power systems.

List of Practicals

1. Study of 3 Φ VSI (180º or 120º)

2. Study of Chopper fed / Converter fed DC Drive.

3. Study of Stator Voltage Control of IM Drive

4. Power factor improvement technique (SAC or EAC or PWM)

5. Study of VVVF 3 phase IM Drive.

6. Sensing and Protection circuits for AC and DC Drives

7. Simulations of 3 phase LCC (HCB or FCB or dual Converter).

8. Simulation of 3 phase VSI (180º or 120º) / Simulation of DC/AC drive.

9. Design and development of one power electronic control circuit.

Text Books

1 M D Singh & Khanchandani,“Power Electronics”, Tata McGraw Hill, IInd

edition

2 M. H. Rashid, “Power Electronics”, 3 edition, Pearson Education, 2004

Reference Books

1 Mohan, Undeland & Robbins, “Power Electronics”, 3 edition, John Wiley, 2003

2 Dubey, Doralda, Joshi & Sinha, “Thyristorised Power Controllers”, New Age

International, 1986

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

4 B. K. Bose, “Modern Power Electronics & AC Drives”, Pearson Education, 2002

EC42305 : ADVANCED POWER ELECTRONICS

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FF No. : 654

EC42306 :: BIOMEDICAL ELECTROINCS

Credits: 01 Teaching Scheme: - Laboratory 2 Hr/Week


Objectives:

To study and understand ECG,EEG,AMG Machine and signals

To study and understand Laboratory equipments

To study and understand Radiology equipments

To study and understand Equipments used in ICU/ICCU.

List of Contents

List of Practicals:

1. Recording and interpretation of ECG.

2. To Study Phonocardiography

3. To measure Blood Pressure using Sphygmomanometer.

4. Study of defibrillators

5. Study of EEG/EMG Machine.

6. Study of Bedside Monitor (ICU Monitor).

7. Study of Clinical Lab Instrumentation - COLORIMETER.

List of mini projects:

1. To design a Clinical Thermometer.

2. To design and record/monitor heart sounds using Electronic Stethoscope

3. To design Heart rate Meter.

Text Books

1. Cromwell, “Biomedical Instrumentation and Measurement”, PHI.

2. Carr and Brown, “Biomedical Instrumentation”.

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171

Project and Seminar

Subject

No/

Sem



PS2

BE I

Project Stage-II EC47301 0 0 2 4

PS3

BE II

Project Stage-III EC47302 0 0 2 6

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Objectives:


education.






2. Regular discussions should be carried out with project guide. Students

should refer Journal and transactions to keep themselves updated with the

cutting edge technology evolving in the respective area.

3. Project progress review report must be submitted in the prescribed format

only. No variation in the format will be accepted.

Subject Code :EC 47301: Subject Name : Project (Stage II)

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FF No. : 654



Objectives:

To select and work on real life application in the field of Electronics and

Telecommunication.


education.






2. Students are encouraged to participate various activities like project

competitions, Paper presentations, publications, Intellectual property -

patent registration or other suitable activities suggested by guide.

3. Regular discussions should be carried out with project guide. Students

should refer Journal and transactions to keep themselves updated with the

cutting edge technology evolving in the respective area.

4. Final project report must be submitted in the prescribed format only. No

variation in the format will be accepted. One guide will be assigned

maximum three project groups.

Subject Code :EC 47302: Subject Name : Project (Stage III)

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