electronics and communication syllabus

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JAIN University Regulations, Scheme & Syllabi B.E (Electronics & Communication Engineering). 2009-10

JAIN UNIVERSITYEstd u/s 3 of the UGC Act, 1956

Ref: No. JU/Notification for Institution of Programmes/1/2009-10

24th July 2009

Notification

Subject: Institution of B.E Degree Programme under JAIN University

Reference: Meeting of the Academic Council held on 31st May 2009

Pursuant to the approval by the Academic Council, it is hereby notified that JAIN University

has instituted Bachelor of Engineering (B.E) Programme from the academic year 2009-2010.

The regulations, scheme of study and syllabi for the same are enclosed.

By Order

Dr. N Sundararajan

Vice Chancellor

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Contents

REGULATIONS of JAIN University:

Page Nos.

1) Scope and Content 03

2) Course Content 04

3) Eligibility for admission and mode of selection 04

4) Attendance requirement 04

5) Assessment Procedure 04

6) Eligibility for Pass 05

7) Summer Term 05

8) Classification of successful students 06

9) Graduation Requirements 07

10) Maximum period for the completion of the Programme 07

11) Code of Conduct 07

CURRICULUM & SYLLABUS

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JAIN UNIVERSITYEstd u/s 3 of the UGC Act, 1956

BACHELOR OF ELECTRONICS AND COMMUNICATION ENGINEERING

(B.E.)

REGULATIONS

Introduction:

The Bachelor of Engineering (B.E) gained prominence with the growth in Indian Economy and entry of

Multinationals. The University shall offer undergraduate programmes in eight disciplines leading to Bachelors

Degree in Engineering (B.E). The duration of the B.E. program is four years (Eight semesters). The objective

of the B.E. program at the Jain University is to provide highest level of education in technology and science

and to produce competent engineers, entrepreneurs, and scientists at global level.

Obtaining a Bachelors degree in Engineering widens the choice of careers among the young minds in the

frontier science areas of technology, marketing, consultancy, education, public administration.

The Engineering curriculum at Jain University extends a comprehensive training in the emerging areas of

Research and new Technologies. We provide students with the best of hands on training, knowledge in

computational methods and standard software. The programme is designed to meet the needs of Global

Industry.

The curriculum fosters inter-disciplinary approaches and inter-departmental involvement in the educationalprogramme. It also promotes contact with, and give service to industries, government and civic organizations

through research efforts, consultations, conferences and short term courses on current developments in

technology.

Over the years, the Institution has developed a network of expert academic and professional faculty which

enables the curriculum to go beyond the present programmes offered by a standard graduation course. The

faculty is a blend of young and experienced minds with academic, industrial & research experience.

The Board of Studies for these programmes consists of academic and corporate personnel with vast

experience. The curriculum is designed in a way to cater to the requirements of higher education, industry

and R & D. Therefore, the programme proposes class room learning in the form of Case Studies, Group

Discussions, Presentations and mandatory practical training at industries through internship, industrial visits

and projects.

1) Scope and Content:

1.1) The regulation and policies documented here are applicable for B.E programme offered by Jain

University.

1.2) The applicability of the Regulations and Policies must be understood in the context of the given Course

Matrix and Syllabus of each programme.

1.3) The Regulations and policies given here are in addition to the rules and regulations notified at the time of

admission.

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1.4) The authorities of University may modify, add, delete, expand or substantiate any part of the

Regulations and policies, at any time.

2) Course Content:

The programme shall for a duration of eight semesters, spread over four years. Each semester of the

programme shall consist of the following components:

a) Core Subjects

b) Professional Subjects

c) Electives (Departmental & Inter-Departmental)

d) Laboratory classes

2.1) Core subjects: A Core subject comprises of that form the back bone for the professional courses. These

subjects provide a strong back ground in basic disciplines of study.

2.2) Electives: Students will be required to choose electives from among those on offer.

3) Eligibility for admission and mode of selection:

3.1) A candidate should have passed (10+2) course or equivalent course recognized by State or Central

board and secured minimum marks as prescribed by State Government for the admission year 2009-10.

3.2) The method of selection for the course shall be normally through merit, based on performance in the

qualifying exam. However, for some programmes, the admission might also be by means of an entrance test

in addition, there to.

4) Attendance requirement:

4.1) A student should have attended a minimum of 85% of the classes conducted in each subject. In case

student fails to fulfill the 85% attendance requirement, then with the permission of board the candidate may

be condoned to the maximum extent of 10% provided the candidate has a minimum of 75% attendance in

that subject of the semester.

4.2) In case the candidates attendance falls below 75% in a subject he/she may be permitted to register for

the summer term with permission of the board but no candidate is permitted to take the end semester

examination in the subject in which the candidate does not fulfill the attendance requirement.

4.3) If a student is absent from all the classes without prior permission his/her name will be removed from

the rolls of the university.

5) Assessment Procedure:

5.1) Credit Based System: Assessment procedure follows a model of credit system wherein each subject

depending upon the number of contact hours is assigned with an integer called Credit. A candidate will have

to register for around 25 credits every semester as prescribed by the department.

5.2) Course Credits: Each course shall have an integer number of credits, which reflects its weightage. The

number of credits of each subject in a semester shall ordinarily be calculated as under: -

Lectures: One lecture hour per week shall be assigned one credit

Practical: Three Laboratory hours per week shall be assigned one credit

Tutorials: One tutorial hour per week shall be assigned one credit. Special courses like project, industrial

training shall be treated as another course and shall be assigned such number of credits as may beapproved by the board.

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5.3) Evaluation System: The evaluation of the performance of students shall follow the continuous evaluation

system, which means that evaluation proceeds along side with the progress of the course.

5.3 1) Evaluation of Theory Subjects:

The theory subjects will carry maximum marks of 100 with a pass mark of 40. A weightage of 30% will be

given for continuous internal assessment and 70% weightage for the end semester examination.

Internal assessment is carried out based on two internal written tests for 10 marks each. Ten marks allotted

for un-announced quizzes and assignments. A student has to score a minimum of 12 marks out of 30 in

internal assessments to qualify for end semester examination. The end semester examination is conducted

for 70 marks and a candidate will have to score a minimum of 28 marks to pass end semester examination.

To pass a subject the candidate will have to score a total of forty marks out of the total 100 marks.

5.3 2) Laboratory Courses: The Laboratory and practical work will carry maximum marks of 100 with passing

marks of 40. A weightage of 50% will be given for continuous internal assessment and a weightage of 50% is

given for the End Semester Laboratory Examination.

The internal assessment is carried out based on continuous evaluation of the work carried out in laboratory

with a weightage of 30 marks and internal laboratory test of 20 marks. A candidate will have to score a

minimum of 20 marks in the internal assessment to quality end semester laboratory examination. The end

semester laboratory examination is conducted for 50 marks and candidate will have to score a minimum of

20 marks to pass the examination. To pass the laboratory course the candidate will have to score a minimum

of forty marks out of the total 100 marks. No student will be allowed to have any make up examination for

the laboratory internal test.

5.4Make-up test for internal assessments:

a) A candidate will be permitted to take only one make-up test per subject due to unforeseen or

unavoidable circumstance

b) The make-up test will be held at the end of the semester after completion of the regular classes

c) The duration and weightage of the make-up test will be the same as that of regular internal test

d) The marks obtained in the Make-up test will be reduced to 75% of the total marks obtained in that

subject

6) Eligibility for Pass:

6.1) The CGPA for a candidate will be calculated at the end of each academic year provided the candidate has

passed in all the subjects

6.2) To pass an year he should have to obtain a minimum CGPA of 2.0

6.3) A student is permitted to carry a maximum of two backlog subjects from an odd semester to next even

semester otherwise he has to rejoin the odd semester in next academic year by losing one year. No candidate

is permitted to carry any subject from an odd semester to the next odd semester6.4) A candidate is permitted to carry not more than two subjects from an even semester to the next odd

semester provided he has scored the minimum requirement in the internals. Otherwise the candidate has to

rejoin that even semester in the next academic year.

7) Summer Term:

Summer term is organized to help the candidate to study and clear a subject in case.

7.1 A candidate does not satisfy the attendance requirement but has been permitted by the board to undergo

the summer term based on valid reasons

7.2 A candidate is unable to fulfill the minimum requirement in the internal assessment and not permitted to

write the end term examination

Note: No candidate is permitted to undergo the summer term program for more than two subjects at a time

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8) Classification of successful students:

8.1) On successful completion of the programme, the students will be classified as below:

Grade A+ A B C D E+ E* F

Corresponding grade point 5 4 3.5 3 2.0 1.0 0 0

Percentage of Marks 90-100 75-90 60-75 50-60 40-50 25-40 Less than 25

Class DISTINCTION FIRST SECOND PASS FAIL

* Summer / winter to be repeated program

8.2) Inadequate Academic Performance: The academic performance of every student is carefully assessed at

the end of every semester. The following table gives the deficient grades and the actions to be taken by thestudents.

He/She is permitted to Grade Reasons Grade Points Not to

End term supplementary exams E+ 25-39 1.0Attend the classes,redo the internal

Summer / winter to be repeatedprogram

E Less than 25 0 Redo the internal

Repeat the entire course FAbsent, attendance,indiscipline andpunishment

0 ___

8.2.1 Semester grade point average:

The Semester Grade Point Average (SGPA) is the weighted average of all the grade points earned by a

student in all the courses credited and describes his/her academic performance in a semester. SGPA is

computed by dividing the total grade points earned with the total number of credits registered in that

semester.

SGPA = CjGj / Cj

Where, Cj denotes credit assigned to the j th course taken by the student in the concerned semester and Gj

indicates the grade point equivalent obtained by the student in Jth course.

8.2.2 Cumulative Grade Point Average:

The Cumulative Grade Point Average (CGPA) indicates the over all academic performance of a student in all

the courses up to and including the latest completed semester/ summer semester. CGPA is computed as

follows:

CGPA = CiGi / Ci

Where, Ci denotes credit assigned to the ith course and Gi indicates the grade point equivalent obtained by the

student in ith course.

8.2.3 Ranks:

Only Students, who have passed each of the semester examination at the first attempt, shall be eligible for

award of Ranks. The first three ranks (in respective branch) shall be notified.

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9) Graduation Requirements:

A student shall be deemed to be eligible for the award of the B.E. degree if he/she has completed all the

prescribed courses.

9.1 At the end of 8th Semester, student should attain at least 2.0 CGPA.

9.2 Registered and Successfully earned credits in all the courses within the stipulated duration of

programmes.

9.3 Successfully earned the credits in the different categories as specified in the curriculum corresponding to

the discipline (branch) of his/her study with in the stipulated time.

9.4 Clear all the dues in all sections of the institute including Hostels.

9.5 Has no disciplinary action pending against him/her

10) Maximum period for the completion of the Programme

The maximum period for the completion of the B.E. Degree shall be six years from the date of joining the

programme.

11) Code of Conduct:

11.1 Academic Integrity and Ethics

a) A student who has committed an act of academic dishonesty will be deemed to have failed to meet the

basic requirement of satisfactory academic performance. Thus, academic dishonesty is not only a basis for

disciplinary action but also is relevant to the evaluation of students level of performance and progress.

b) Where there has been violation of the basic ethos and principles of academic integrity and ethics, the

Director/Board of Examiners/ Course coordinator may use their discretion in terms of disciplinary action to be

taken.

c) He/She is expected not to indulge in any activity which is likely to bring down the prestige of the

Institution.

d) He/She should also show due respect and courtesy to teachers, administrators, officers and the employees

of the Institution.

e) Ragging in any form what so ever is strictly prohibited and is considered as a serious offence.

f) Academic dishonesty includes, but is not necessarily limited, to the following-

i) Cheating or knowingly assisting another student in committing an act of cheating;

ii) Unauthorized possession of examination materials, destruction or hiding of relevant materials;

iii) Act of plagiarism;

iv) Unauthorized changing of marks or marking on examination records.

11.2Generala) The students are expected to spend a considerable amount of time in research, reading and practice.

b) All students are expected to develop and maintain a positive professional attitude and approach

throughout the programme and in conduct of all other activities.

c) Attendance alone is not sufficient. Students are expected to participate, to help the class learn and

understand the topics under the consideration.

d) Food and drinks are not permitted in the classroom/ conference hall.

e) All students are expected to dress as per prescribed dress code.

f) Cell phones are strictly prohibited in the campus.

11.3 Medium of Instruction: The medium of instruction and examination shall be in English only.

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Curriculum & Syllabus

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Faculty of Engineering Sciences

I/II Semester Subject List

(Common to all branches Physics Cycle)

Semester Subject Sub. Code Credits

I / II semester B.E. 26 Credits

I/II

Engineering Mathematics I / II MA11/21 04

Engineering Mechanics CE12/22 04

Basics of Electrical Engineering EE13/23 04

Engineering Physics PH14/24 04

Engineering Graphics ME15/25 04

Basics of Environmental Engineering CE16/26 02

Mind Management & Human Values SH17/27 02

Engineering Physics Laboratory PHL1/2 01

Basic Engineering Laboratory MEL1/2 01

I/II Semester Subject List(Common to all branches - Chemistry Cycle)

Semester Subject Sub. Code Credits

I / II semester B.E. 28 Credits

I/II

Engineering Mathematics I / II MA11/21 04

Basics of Mechanical Engineering ME12/22 04

Basics of Electronics Engineering EC13/23 04

Engineering Chemistry CH14/24 04

Introduction to Computers, Software Systems and Internet CS15/25 04

Basics of Material Science ME16/26 04

Communication Skills SH18/28 02

Engineering Chemistry Laboratory CHL1/2 01

Computer Fundamentals and Programming Laboratory CSL1/2 01

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III and IV SEMESTER SUBJECT LIST

(DEPARTMENT OF ELECTRONICS & COMMUNICATION ENGINEERING)

Sl.No. Name of the Subject Sub. Code Credits

III semester B.E. (ECE) 26 Credits

1 Mathematics-3* (*-Common to all Branches of Engineering) MA 31 04

2 Analog Electronics EC 32 04

3 Network Analysis EC 33 04

4 Digital System Design EC 34 04

5 Signals and Systems EC 35 04

6 Electronics Measurement EC 36 04

7 Electronics Laboratory - I ECL 37 01

8 Electronics Laboratory - II ECL 38 01

IV semester B.E. (ECE) 26 Credits

1 Mathematics-4* (*-Common to all Branches of Engineering) MA 41 04

2 Linear Integrated Circuits EC 42 04

3 Power Electronics EC 43 04

4 Control Engineering EC 44 04

5 Computer Organization EC 45 04

6 Microprocessors and Microcontrollers EC 46 04

7 Electronics Laboratory - III ECL 47 01

8 Electronics Laboratory - IV ECL 48 01

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V and VI SEMESTER SUBJECT LIST


Sl.No.

Name of the Subject Sub. Code Credits

V semester B.E. (ECE) 26 Credits

1 Analog Communication EC 51 04

2 Electromagnetic Theory EC 52 04

3 Digital system Design with HDL EC 53 04

4 Digital Signal Processing EC 54 04

5 Embedded System Design EC 55 04

6 Elective I 04

7 Electronics Laboratory - V ECL 57 01

8 Electronics Laboratory - VI ECL 58 01

VI semester B.E. (ECE) 26 Credits

1 Digital Communication EC 61 04

2 Microwave Engineering EC 62 04

3 Information Theory and Coding EC 63 04

4 Digital VLSI Design EC 64 04

5 Antenna and Wave Propagation EC 65 04

6 Elective II 04

7 Electronics Laboratory - VII ECL 67 01

8 Electronics Laboratory VIII ECL 68 01

Elective I Elective II

Data Structures with C Digital Signal processors

Digital Switching Systems Simulation & Modeling

FPGA, FPAA & FPMA Fault Tolerant System Design

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VII and VIII SEMESTER SUBJECT LIST


Sl.No.

Name of the Subject Sub. Code Credits

VII semester B.E. (ECE) 25 Credits

1 Mobile Communication EC 71 04

2Computer Communication andNetwork

EC 72 04

3 Engineering Economics and Management EC 73 04

4 Elective III 04

5 Elective IV 04

6 Mini Project 04

7 Lab IX ECL 74 01

VIII semester B.E. (ECE) 24 Credits

1 ARM Processors EC 81 04

2 Operation Research and Management EC 82 04

3 Elective V 04

4 Elective VI 04

5 Project 08

Elective III Elective V

Image Processing Statistical Signal Processing

Optical Fiber communication Wireless Networks

ANN & Fuzzy Systems Advanced CMOS VLSI Design

-- Data Compression Techniques

Elective IV Elective VI

Wavelet Transforms Adaptive Signal Processing

Multimedia communicationHigh Performance ComputingNetworks

CAD for VLSI Low Power VLSI Design

TCP/IP (with focus on ITU standards) Operating Systems & RTOS

Parallel Processing RF Systems

Total Credits = 6*26 + 25 + 24 = 156 + 28 + 19 = 205

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Semester I/IIEngineering Mechanics

Course Outline(Common to Physics Cycle)

Subject Code: CE12/ 22 Total Hours: 48

Credits: 04 Hrs per week: 04

Fundamental principles and concepts:

System of Units, Scalar and Vector Quantities, Fundamental Laws of Mechanics Concept offorce, Moment of a force about a point and about an axis, Couple, System of forces, Reso-lution and compositions of coplanar and non-coplanar force systems.

Equilibrium:Free body diagrams, Types of supports and reactions, Equations of equilibrium, LamisTheorem, Varignons Theorem, Problems of equilibrium involving co-planer force systemsacting on particle, rigid body and system of rigid bodies, Principle of virtual work, Efficiency

of simple machines.

Trusses And Frames:

Perfect, Deficient and Redundant Frames, Nature of forces in members, Analysis of simpleplane trusses- method of joints, method of sections.

Friction:Laws of Friction, Angle of Friction, Angle of Repose, Cone of Friction, Ladder, Wedge, Ropeand Belt Friction.

Properties of Plane Areas and Solids:

Centroid, Second moment of area and product of inertia, Radius of gyration, Transfer

theorems, Polar moment of inertia, Principal axes and principal moment of inertia, Centre ofGravity, Ixx, Iyy, and Izz for solids like sphere, cylinder and parallelopiped.

Kinematics of Particles and Rigid bodies:

Particles: Definitions of displacement, velocity and acceleration and their relations,Rectilinear motion under constant and variable accelerations, Motion curves, Curvilinearmotion using rectangular coordinates, normal and tangential components of acceleration.Rigid body: Rotation about a fixed axis.

Kinetics of Particles:

Equations of Motion, DAlemberts principle, Concept of dynamic equilibrium, Kinetics ofrectilinear motion of a particle acted upon by constant and variable force system, rectilinear

motion of several interconnected particles. Work Energy equation of particles, Impulse andmomentum, Direct and Oblique Central impact

Text Books:

1. Engineering Mechanics by J. L. Meriam & L. G. Kraige, Wiley India Pvt. India Ltd.2006 (Vol. 1 and Vol. 2).

2. Engineering Mechanics, Statics and Dynamics by F. L. Singer, Houperde Rowpublication house Nee-Delhi 1988

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Semester I/IIBasics of Electrical Engineering


Subject Code: EE13/ 23 Total Hours: 48


Electrostatics

Charge, voltage, Electric field intensity, electric flux density, Permittivity, capacitance, series

and parallel circuits & analysis, Energy stored in capacitor. Simple Problems.

Electromagnetism

Electromagnetic Induction, Faradays & Lenzs Law, Flemings Right hand rules. Statically

and dynamically induced EMFs, Concept of self and Mutual inductance. Coefficient of

coupling, Energy stored in a Magnetic field. Problems.

D.C. Circuits

Application of Ohms Law and Kirchoffs Laws: Analysis of series, parallel and series-parallel

resistive circuits excited by independent voltage sources. Power and Energy in resistive

circuits for independent DC voltage sources. Source transformation; Star-Delta

transformation.

Super position theorem and Thevenins theorem for simple DC circuits.

Measuring Instruments

Indicating Instruments: Ammeter, Voltmeter, Wattmeter; Energy meter: Measurement of

single-phase power using Wattmeter. Different type of wirings, specifications of wires.

Working of Flourcent Lamp. Two-way and three-way control of lamps. Necessity and types of

earthing. Elementary discussion on fuses. Safety measures against electrical shock.

AC Circuits

Single Phase AC circuits

Generation of sinusoidal AC voltage, Concept of Average and RMS values. Form factor, Peak

factor of sinusoidal varying voltage and current. Voltage, current, power & power factor

analyses with phasor diagrams of circuits with R, L & C. and series circuits with RL, RC and

RLC. .Parallel circuits. Problems.

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Three Phase AC Circuits

Necessity and advantages of three phase systems. Phase sequence, balanced and

unbalanced supply. Star and Delta wound connection, relationship between line and phase

values.

Measurement of 3 phase power by two wattmeters methods. Expression of power factor in

terms of wattmeters reading. Problems.

DC Machines

Working Principle of DC machine as generator and motor, constructional features. EMF

equation of generator, Types of generators & applications; Simple problems. Back emf and

torque equations of DC motors. Types of DC motors. Characteristics and applications.

Necessity of 3 point starter. Problems.

Transformers

Principle of operation and construction of single phase transformers (core and Shell types).

Emf equations and simple problems. Power losses of a transformer and problems; Efficiency

and voltage regulation, Auto transformer. Problems.

Three Phase Induction Motors

Concept of rotating magnetic field, Principle of operation of 3 phases induction motor.

Constructional features of 3 phase motors, Application of squirrel cage and slip ring motors.Problems only on slip calculations.

Synchronous Generators Principle of operation of an alternator, Types & constructional

features of an alternator, EMF equation, Voltage regulation, Problems.

Text Books:

1. T1 - E.HUGES; Electrical Technology, Intl. student seventh edition, AWL Press,

1998. Revised by I.M.Smith2. T2 - H. COTTON, Electrical Technology, Oxford Press.

Reference Books:

1. Rajendra Prasad; Fundamentals of Electrical Engineering, PHI, 2005.

2. B.L. Theraja; Electrical Technology, Khanna Publishers, 2005.

3. N.N. Parker Smith; Problems in Electrical Engineering, 19th edition, CBS publishers.

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Semester I/IIEngineering Physics


Subject Code: PH14/ 24 Total Hours:48


Introduction to Physics

Why do engineers study physics?

Basic Physics

Mechanics: Kinematics and dynamics of point particles; Work, Energy and Power;

Conservation Laws; Rigid body dynamics; Fluid dynamics; Newtons law of gravitation and

Keplers laws.

Waves and Oscillations: Simple harmonic motion; wave motion; superposition and

resonance.

Heat and Thermodynamics: Concept heat and temperature, thermal expansion; Specific and

latent heat capacities; Kinetic Theory of Gases; Laws of thermodynamics.

Electricity and Magnetism: Electrostatics; Gauss law, Current electricity, Electromagnetism;

Electromagnetic induction; Alternating current; Series LCR circuit and Electrical resonance;

Electromagnetic radiation.

Optics: Geometrical optics; Physical optics- interference, diffraction and polarization.

Quantum Physics

Blackbody distribution of energy in the spectrum of Blackbody Weins displacement law,

Weins law, Rayleigh-Jeans law Quantum theory of radiation - Plancks law deduction of

Weins law, Rayleigh-Jeans law, from Plancks law

Photoelectric effect Einstiens photoelectric equation. Comptons effect- experimental

verification. Stability of an atom Bohrs atomic theory. Limitations of old quantum theory.

de Broglies hypothesis wavelength of matter waves, properties of matter waves. Phase

and group velocities. Davisson and Germer experiment. Double slit experiment. Standing

de Brogile waves of electron in Bohr orbits.

Heisenbergs uncertainty principle. Gamma ray microscope. Diffraction by a single slit.

Position of electron in a Bohr orbit. Particle in a box. Complementary principle of Bohr.

The concept of the wave function, physical significance of wave function, Max Borns

interpretation of the wave function. Schrodinger time independent and time dependent wave

equations. Basic postulates of quantum mechanics. Operators, eigen functions and eigen

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values, expectation values. Application of Schrodinger wave equation to particle in one and

three dimensional boxes, potential step and potential barrier.

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Elementary principle of Laser, basic steps required to form a Laser

absorption, spontaneous emission, stimulated emission, optical pumping, popular inversion,

metastable state, Types of Laser He-Ne Laser, Ruby Laser, Applications of Laser;

Holography-Obtaining hologram, viewing the object, Applications of holography

Solid State Physics

Crystalline nature of matter. Cystal lattice, Unit Cell, Elements of symmetry. Crystal

systems, Bravais lattices. Miller indices. Simple crystal structures, reciprocal lattice,

Diffraction of X rays by crystals, Braggs law, elementary ideas about point defects and

dislocations. Lattice vibrations, Phonons, specific heat of solids.

Classical free electron theory--drawbacks of classical theory-- relaxation time--collision time

and mean free path--electrons scattering and source of resistance in metals- electron

scattering mechanisms and variation or resistivity with temperaturedistinction between

metals, insulators and semiconductors on the basis of Band theory.

Quantum free-electron theory. Fermi - Dirac Statistics. Fermi-energy Fermi factor. Density

of states (with derivation). Expression for electrical resistivity / conductivity. Temperature

dependence of resistivity of metals. Effect of magnetic fields--Hall effect--Hall coefficient

Low Temperature Physics

Properties of materials at low temperatures. Phase transition; liquefactions of gases-(i) Joule

Kelvin porous plug experiment (Thomson effect) (ii) adiabatic demagnetization (thermo

magnetic effect). Applications of low temperature physics

Superconductivity - introduction Experimental facts Zero resistivity The critical field

The critical current density Meissner effect Type I and type II superconductors Cooper

pair BCS Theory persistent currents superconducting magnets magnetie levitation

isotope effect temperature dependence of specific heat and thermal conductivity.

Text Books:

R A Serway, J W Jewett,Physics for Scientists and Engineers6th Edition, Thomson,

2004

1. D J Griffiths.Introduction to Quantum Mechanics Prentice-Hall, NJ, 2nd ed, 2004

2. C Kittel, Introduction to Solid State PhysicsSeventh Edition, John Wiley & Sons,

New York, Chichester, 1996

3. M W Zemansky and R H Dittman, Heat and ThermodynamicsAn Intermediate

Textbook7th edition, McGraw-Hill Higher education

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Semester I/II

Engineering GraphicsCOURSE OUTLINE

(Common to all branches)

Subject Code: ME15 / 25 Total No of Hrs: 48

Credits: 4 Hours per week: 04

Introduction Language of Engineers Principles of Engineering Graphics - Importance of

Precision - Drawing Instruments and their uses - Conventions in Drawing Lettering - BIS

Conventions Advantages of orthographic projections - Three views - Objects needing two

views - Single views Curves used in Engineering Practice & their Construction - Ellipse,

Parabola and Hyperbola, Cycloid, Epicycloid and Hypocycloid. Construction of regularpolygons - Two views of prisms and pyramids.

Freehand sketching: conversion of pictorial to orthographic by using grid sheets -Problems on

missing lines and missing views; Dimensioning and construction of dimensioned views

Sectional and half sectional views: sectioning conventions.

Assembly drawings: assembly drawings of simple appliances.

Pictorial Drawings : Principles of Isometric Projection - Isometric Scale - Isometric Views -Freehand sketching on isometric grid paper - Oblique and perspective Projection

Development - Cylinder to cylinder, cylinder to cone, funnel. Transition piece (circle to

square, rectangular to circle only)

Descriptive geometry: PROJECTIONS OF SOLIDS: Projections of regular solids inclined to one

plane. - Freehand sketching exercises only

Computer graphics

REFERENCES:

1. N.D. Bhatt and V M Panchaal, Engineering Drawing Plane and Solid Geometry, 47th Edition,

Charotar Publishing House, Anand, 2004

2. Luzadder, Duff, Fundamentals of Engineering Drawing, 11th Edition, EEE Publication

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Semester I/IIBasics of Environmental Engineering


Subject Code: CE16/ 26 Total Hours: 24Credits: 02 Hrs per week: 02

Introduction: Scope and Importance of Environmental Engineering

Eco system and Natural Resources: Concept of an ecosystem, Energy flow in theecosystem,Forest ecosystem, Grassland ecosystem, Desert ecosystem, Aquatic ecosystems(ponds, lakes, streams, rivers, estuaries, oceans), Natural resources, Types of resources,forest, air, water, soil, minerals and biodiversity, Biodiversity at Global, National and Locallevels, Threats to biodiversity, Impact of development activities - Impacts of agriculture,mining, traditional sources of energy, population, industrialization, transportation structures,

big dams etc.

Environmental Pollution and Control: Causes, Effects and control measures of air, water,soil, marine, noise, thermal, nuclear pollution, solid waste, hazardous waste, e-waste,biological waste, Control measures, Global warming and climate change.

Sustainable Development: Introduction, Renewable energy sources, Life cycle analysisand clean technologies.

Environmental legislations and international treaties: Global and regionalenvironmental issues, Environmental toxicology, Environment protection act, Air (preventionand control of pollution) act, Water (prevention and control of pollution) act, Wildlife

protection act, Forest conservation act, Environment Impact Assessment (EIA), Riskassessment in environmental management, Introduction to ISO and ISO 14000.

Text Books:

1. Environmental Science by Anil Kumar D Gupta, 5th edition, New Age Internationalpublications, 2003.2. Principles of Environmental Engineering by Mackenzie L Davis and Susan J Masten,Tata Mc Graw Hill India, 2007.3. Environmental Science for engineering undergraduates by Dr. Sushmita Baskar,Unicorn Books Publications 2008.4. Textbook for Environmental Studies For Undergraduate Courses of all Branches of

Higher Education by Erach Bharucha, distributed by University Grants Commission, NewDelhi. 2004.

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Semester I/IIMind Management & Human Values


Subject Code: SH17/ 27 Total Hours: 24


A course based on the concept of Character-building, Man-making and Life-enhancing

education. This personality development course will be conducted under the name Vishva

Chaitanya which means universal consciousness emphasizing the entire mankind as one

family.

Unit -1

Objectives: Interactive sessions to enable the students to learn life-skills and to create

awareness about our national history, culture, social responsibilities and human values.

Students are encouraged to have clear professional goals as well as transpersonal goals that

take them beyond selfish aspirations to nation-building and social service.

Topics:

SWOT analysis of the Indian Nation

Concept of Self-Psychometric Test

Positive Mental Attitude

Relationships

Time Management

Goal Setting

Memory Techniques

Universal Message of the Bhagavadgita

References:

Colombo to Almora Lectures by Swami Vivekananda, Published by Sri Ramakrishna Math

You can Win, Living with Honor Shiv Khera

Success through a Positive Mental Attitude Napolean Hill and W Clement Stone.

Interpersonal Skills Training Burnard.

Unit-2

A) Analysis of short silent educational films to develop independent critical thinking.These films are produced by Human Networking Academy, a division of JGI.

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Themes of the films: -Proactive style of life, dedication to and efficiency in work. Social

obligations and sharing. Integrating the best of the Eastern & Western cultures, Mindfulness

and importance of meditation.

B) Practical Session on Managing Emotions for (internal assessment)

To discuss the role of emotions in our lives. Learn about the importance of expressing them

in a right way. To discuss different techniques of managing these emotions to achieve

emotional stability.

Unit 3

Practical experiential sessions integrating modern psychological insights with Yoga practices

that enable the students to develop strong positive personalities, and to be proud of our

ancient yet modern multi-cultural heritage.

A) Yogasanas

a) Breathing Exercises

b) Loosening Exercises

c) Asanas

1) Suryanamaskara, an effective set of asanas that energizes both body and mind.

2)Ardhakati chakraasana

3) Trikonaasana

4) Parivrita Trikonaasana

5) Veerabhadraasana

6) Vakraasana

7) Gomukhaasana

8) Padmaasana

9) Shashaankaasana

d) Pranayama

1) Kapalabhati kriya

2) Vibhaagiya Svasana & full yogic breathing

3) Nadi shodhana pranayama

B) Mind Managementa) Effect of music on mind

b) Discussion on the concepts of personality and character on the basis of modern

Humanistic psychology (Growth Psychology) and Yoga psychology

c) The three dimensions of the personal identity Intelligence Quotient, Emotional Quotient

and Spiritual Quotient

d) Meditation as a life-skill.

Mind Management through right postures,

Prana-anusandhana,

Purification of mind,

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Nada-anusandhana

Concentration exercises like Trataka

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Semester I/IIEngineering Physics Laboratory


Subject Code: PHL1/ 2 Total Hours: 36


1. Error Analysis

2. Graph Drawing

3. Torsion Pendulum

4. Radiation from a Black Body: Stefan-Boltzmann Law

5. Resonance in LCR circuits

6. B-H loop of a ferromagnetic material7. Plancks constant

8. Determination of wavelength of a source - Diffraction Grating

9. Energy gap of a material of p-n junction

10. Newtons law of cooling

11. Dielectric constant by charging and discharging of a capacitor

12. Fermi energy of copper

References:

1. Smith E. V. -Manual of Experiments in Applied Physics, London

2. Workshop B.L., and Flint H.P. -Advanced Practical Physics for Students, Methuen and

Co. Ltd. London.

3. Jerrad H.G. and Mc Neil D.B. -Theoretical and Experimental Physics.

4. Fretter W.B. -Introduction to Experimental Physics, Blackiee

5. M. Nelkon and J.rlJl. Ogborn -Advanced Level Practical Physics, English Language

Book Society, 1955.

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Semester I/IIBasic Engineering Laboratory


Subject Code:MEL1/ 2 Total Hours: 36Credits: 01 Hrs per week: 03

Exercise-1: Introduction of tools and devices in various Workshop trades

Exercise-2: Use of hand tools for sheet metal fabrication

Exercise-3: Use of Conventional and Non conventional tools used in shop floor

Exercise-4: Soldering and Brazing

Exercise-5: Welding

Exercise-6:. Study of Electronic components and equipments Resistor, colour codingmeasurement of AC signal parameter (peak-peak, RMS period, frequency) using CRO.

Exercise-7:. Study of logic gates AND, OR, NOT and Universal Gates.

Exercise-8:. Operation of Electromagnetic Relay using phototransistor

Exercise-9: Measurement of ripple factor of HWR and FWR (Rigup of circuits using general

purpose PCB).

Exercise-10:. Astable multivibrator using IC.

Exercise-11: Fluorescent lamp wiring.

Exercise-12: Stair-case wiring

Exercise-13: Measurement of electrical quantities voltage, current, power & power factor

in RLC circuit and verification of Kirchoffs laws

Exercise-14: Measurement of energy using single phase energy meter.

Exercise-15: Verification of Kirchoffs Laws in DC Circuits

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Semester IIEngineering Mathematics - II

Course Outline(Common to all branches)

Subject Code: MA21 Total Hours: 48Credits: 04 Hrs per week: 04

ORDINARY DIFFERENTIAL EQUATIONS

Linear differential equations of First order: Exact differential equations, integrating

factors, Leibnizs form, reducible to Leibnizs form, Bernoullis form. LCR circuit, Orthogonal

trajectories of curves.

Linear differential equations of second and higher order: homogeneous equations of

second order, with constant coefficients. Case of complex roots, complex exponential

functions, solution by inverse Differential operator.

Modeling with free oscillations (Mass spring system), Euler-Cauchy Equation, Existence and

Uniqueness Theory, Wronskian, Non homogeneous equations, Solution by undetermined

coefficients, Solution by variation of parameters, solution of simultaneous first and second

order differential equations ,Modeling of electric circuits.

INFINITE SERIES

Concept of Convergence and divergence

Integral test, Comparison test, p series, Ratio test, Raabes test-Cauchys root test, log test,

Test for alternating series conditional convergence and Absolute convergence

COMPLEX ANALYSIS

Function of a complex variable, limit, continuity and differentiability of a function , Analytic

functions, Cauchy-Riemann Equations, Laplace equation, Conformal mapping(Bilinear, ez,

sinz, cosz, z+1/z, z2).

Complex integration:

Line integrals, Cauchy integral theorem, Cauchy Integral formula, Power series, Taylors

series and Laurents series, Singularities and zeros of an analytic function, Residue theorem.

Reference Book: 1. Ervin Kreyszig, Advanced Engg Mathematics, Wiley Eastern

2. K A Stroud, Advanced engineering mathematics, MacMillan

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3. Thomas, Calculus, 11th edition, Pearson Education.

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Semester I/IIBasics of Mechanical Engineering

Course Outline(Common to Chemistry Cycle)

Subject Code: ME12/22 Total Hours: 48


General introduction of an IC Engine, Types, Typical Applications, Major parts, associated

terms, Fuels & Cycles, Performance indicators, simple numerical examples, major

manufacturers, pollution & threat to environment, modern trends

Necessity of Refrigeration & Air conditioning, types, refrigerants, processes, COP,

applications, simple numerical examples, major manufacturers, pollution & threat to

environment, modern trendsNecessity of power, types, power generation units, general layout with block diagram,

applications, simple numerical examples, major power producers, pollution & threat to

environment, modern trends

Conventional Machines and their working principles, types of tools, Machinability Parameters,

Numerical Examples, Automation, Modern trends and Major industries

Soldering & Brazing: Soldering in Micro and Macro applications, types and major industries

Welding: Types, Tools, Applications, Automation and numerical examples and major

industries

Power Transmission Devices with typical examples and major industries

Text Books:

1. Workshop Technology Vol. 1 Hajra and Choudary, Publications2. Thermal Engineering, Rajput Laxmi Publications

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Semester I/IIBasics of Electronics Engineering


Subject Code: EC13/23 Total Hours: 48


Semiconductor diodes and applications

P-N junction diode, Characteristics and Parameters, Diode approximations, DC load line,

Effect of temperature on junction characteristics, AC equivalent circuits, Zener diodes Half-

wave diode rectifier, Ripple factor, Full-wave diode rectifier, Other full-wave circuits, Shunt

capacitor - Approximate analysis of capacitor filters, Power supply performance, Zener diode

voltage regulators, Numerical examples as applicable.

Transistors

Bipolar Junction transistor, Transistor Voltages and currents, amplification, Common Base,

Common Emitter and Common Collector Characteristics, DC Load line, AC load line and

operating Point.

Biasing methods

Base Bias, Collector to Base Bias, Voltage divider Bias, Comparison of basic bias circuits, Bias

circuit design, Thermal Stability of Bias Circuits (Qualitative discussions only).

Other devices

Silicon Controlled Rectifier (S.C.R), SCR Control Circuits, More S.C.R applications; Unijunction

transistor, UJT applications, Junction Field effect Transistors(Exclude Fabrication and

packaging), JFET Characteristics, FET Amplifications, Numerical examples as applicable

Amplifiers & Oscillators

Transistor as an Amplifier, Single Stage CE Amplifier and Capacitor coupled two stage CE

amplifier(Qualitative discussions only), Frequency response of an amplifier, Decibels, Half

power points, Bandwidth of an Amplifier, Series voltage negative feedback and Additional

effects of Negative feed back(Qualitative discussions only), The Barkhausen Criterion for

Oscillations, BJT RC phase shift oscillator, Hartley, Colpitts and crystal oscillator ( Qualitative

discussions only) Numerical problems as applicable.

Introduction to operational amplifiers

Block diagram, Ideal characteristics of an operational amplifier, Applications of operational

amplifier, Inverting and non inverting OPAMP circuits, need for OPAMP, Characteristics and

applications voltage follower, adder, subtractor, integrator, differentiator.

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Communication systems

Block diagram, Modulation, Radio Systems, Superhetrodyne Receivers, Numerical examples

as applicable.

Number systems and Digital logic

Introduction, decimal system, Binary, Octal and Hexadecimal number systems, addition and

subtraction, fractional number, Binary Coded Decimal numbers

Boolean algebra, Logic gates, Half-adder, Full-adder, Parallel Binary adder.

Text Books:

1. Electronic Devices and Circuits: David. A. Bell; PHI, New Delhi, 2004

2. Digital systems by Ronald Tocci.

3. Electronics Communication Systems by George Kennedy, 4e, TMH

Reference Books:

1. Electronic Devices and Circuits: Jacob Millman, Christos C. Halkias, TMH, 1991

Reprint 2001

2. Digital Logic and Computer Design, Morris Mano, PHI, EEE

3. Digital Fundamentals by Floyad.

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Semester I/IIEngineering Chemistry

Course Outline

(Common to Chemistry Cycle)

Subject Code: CH14/24 Total Hours: 48


Fuels and Combustion

Definition and classification of fuels, Importance of hydrocarbon as fuels, Calorific value

Gross and Net calorific values, Units (SI).Experimental determination of calorific value of

solid / liquid fuel using Bomb calorimeter, numerical problems. Coal-analysis of coal

numerical problems, conversion of coal into liquid fuels.Petroleum-Refining, cracking,

reforming of Petrol. Octane number, Cetane number, Knocking,anti-knocking agents,

aviation gasoline, non-petroleum fuels. Combustion-calculation of air quantities-industrial

stoichiometry, energy balance, Numerical Problems.

Electrode Potential and Cells

Redox reactions, origin of electrode potential, single electrode potential with unit (SI)

Determination of single electrode potential, electrochemical cell construction and working

of Daniel cell.EMF of single electrode Derivation of Nernst equation-Numerical problems onEMF measurements. Electrochemical conventions, Types of electrodes (explanation and

representation ),Reference electrodes-Primary standard, Secondary reference electrodes

(Calomel electrode and glass electrodes).Concentration cells - EMF determination and

Numerical problems.

Corrosion and its Control

Definition, Chemical and Electrochemical or wet corrosion. Mechanism of electrochemical

corrosion taking iron as an example. Types of corrosion-(Galvanic corrosion, Differentialaeration corrosion, Stress corrosion and Bio corrosion), Factors affecting the rate of

corrosion. Testing and measurement of corrosion.

Corrosion Control Objectives -Inhibition of corrosion (Modification of environment,

Modification of properties of metal, electrochemical protection), Protective coatings (metal

and non-metal inorganic coatings).

Metal Finishing

Technological importance of metal finishing, Polarisation, Decomposition and Over voltage.

Electroplating-purpose of electroplating, application of electroplating, Effect of plating

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variables on the properties of electro deposit Current density, Plating bath Throwing power

of the plating bath,Temperature,pH),Surface preparation-Removal of organic and inorganic

substances, rinsing with water. Electroplating of Chromium and Nickel, Electroless plating-

Distinction between electroplating and electrolessplating.

Electroless plating of copper on PCB.

Polymers

Definition and classification of polymers, Polymerisation,types of polymerization, Methods of

polymerization, Glass transition temperature (Tg),parameters affecting Tg,Structure and

property, Resins and plastics, Engineering plastics Characterization,

synthesis, properties and uses of polyamide,polycarbonates,polyurethane,Teflon,

Elastomers-advantages of synthetic elastomers, synthesis, properties and uses of neoprene

and butyl rubber, Adhesives- Synthesis and applications of epoxy resin, Speciality polymers-

polymers in biotechnology, environmental and other applications.

Liquid crystals and their applications

Definition, comparision of liquid crystalline phase with solid and liquid phase(positional

order,orientational order, mobility)structural classification (thermotropic and lyotropic liquid

crystals with examples). Types of mesophases,Liquid crystalline behavior in homologous

series (PAA and MBBA), Applications of liquid crystals in display system.

Chemical and Instrumental methods of analysis

Chemical methods Introduction, principles of volumetry (redox and complexometric

titrations) and Gravimetry.Instrumental methods of analysis - Theory, Instrumentation and

applications of Visible spectrophotometry,Potentiometry,Conductometryand Flame

photometry.

New Engineering materials

Memory metals, organic electronics, Refractories and materials for communication.

Text Books

1. Engineering chemistry M.M.Uppal, Khanna Publishers

2. Engineering Chemistry,Jain & Jain Dhanpat Rai & Co. Publications

3. Engineering Chemistry, O.P.AggrawalThird edition. 2007, Khanna Publishers

4. Engineering Chemistry B SivsankarTata Mc Graw Hill publications

5. A Text Book of Engineering Chemistry,Shashi Chawla, Dhanpat Rai & Co.

Publications

Reference Books

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1. Text Book of Engineering Chemistry R.Gopalan,D.Venkappayya,Sulochana

Nagarajan, Vikas Publishing House Pvt. Ltd

2. Engineering Chemistry,Abhijit Mallick, Viva Books Pvt. Ltd., New Delhi

3. Elements of fuels, furnaces and refractories, O.P.Gupta, Khanna Publishers

4. Instrumental Methods of Analysis,Williard Merit Dean Settle, Wadsworth Publishingcompany USA

Semester I/IIIntroduction to Computers, Software Systems & Internet


Subject Code: CS15/25 Total Hours: 48


Algorithms, Bits and Bytes

Hardware, Software, Problems & their Solution Using Computers.

Data Representation and Binary Arithmetic

Binary & Hexadecimal, Representation of characters, integers, fractions & floating Point

numbers, Binary Arithmetic.

Basic Computer Hardware & Software

Processor, Memory, IO Devices, Storage. Motherboards, Hard-disk drives other temporary

storage devices, Monitors, Graphics cards, Sound cards, Network cards, Wireless cards, Data

& Other Ports.

Basic Elements of Software

Why software? Software stack on a typical computer OS, Infrastructure software

Application programs. Other Utility software.

Computer Organization

CPU, Memory, Internal Clock & Machine Cycles, Bus Architecture, Interrupt Structures,

Virtual Memory. Modern CPUs, RISC, Multi-core CPUs and parallel processing, Specialized

Expansion Boards (SCSI / USB / ForeWire / MIDI).

Basics of OS

Why OS? Types of OS, Interfaces graphical, command line, Elements of common desktop

OSs Windows XP/Vista, Linux/UNIX. Network OSs Windows 2003/NT, Linux/Unix.

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Basic Networking

Network Media & other hardware, Network topologies & protocols, Types of networks,

Characteristics of cellular networks.

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Internet

Standard internet services (FTP, Search, Instant Messaging, Peer-to-Peer, Web2.0 and

Mashups, Software as a Service, Web Services), IP Addresses- Domain Names-URLs.

Accesses to Internet ISDN, DSL, Cable Modem, Wireless - Data Cards, Wifi, and WIMAX.

Computer Security Concerns and Precautions

Vulnerabilities, Privacy Issues, Viruses, Backup and Recovery, Preventive Tips Firewalls,

right use of passwords, cookies, etc. Open Source, Freeware and Licensing.

Programming Languages and the Programming Process

What is a program? Code, Machine Code, Compilers & Interpreters, Categories & Generations

of programming languages, SDLC. Compilation and Execution of Programs. Fundamentals

Data types, Variables, Operators, Selection Statements, Iteration Statements, Arrays,

Pointers, Functions and Structures.

Classes and Objects

Constructors, Destructors, Scope Resolution operators. Inheritance- Types of Inheritance,

ambiguities in inheritance. File I/O File classes, Opening and Closing of file, reading and

writing text files, binary files and random access of files.

References:

1. Introduction to computers, Peter Norton, Sixth Edition, McGraw Hill

2. Fundamentals of Computers, V Rajaraman, 4th Edition, Prentice Hall India

3. The Complete Reference C++, Herbert Schildt, 4th Edition, McGraw Hill.

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Semester I/II

Basics of Material ScienceCourse Outline


Subject Code: ME16/26 Total Hours: 48


Introduction- Types of materials, Solidification, Grain structure and texture, Processing ofmetals, Stress and strain, Mechanical testing, Plastic deformation in metals, Recovery and re-crystallization, Fracture and fatigue, Creep and stress rupture, Ceramics and their structure,Processing and properties, Glasses.

Brick, Stone, Tiles, Sand, Lime, Cement, Mortar, Concrete, Steel, Timber, PVC, Polymers,Geo-synthetic materials, Utilization of waste (Fly ash and Building waste), preservation ofstones in monuments, Paints and varnishes, Water proofing, anti-corrosive, fire and heatresistant materials, Fluorescent materials.

Electronic structure of atoms and types of bonding between atoms, Crystallography anddiffraction, Optical and electron microscopy, Common engineering alloys.

Electrical properties, the energy band model of metals, semiconductors & insulators,Magnetic materials, permeability, susceptibility and six types of magnetism, Polymers andcomposite materials.

Text Books:

1. Material Science & EngineeringWilliam J Callister, John Wiley Publications

2. Foundations of Materials Science and Engineering, 4th Ed. W.F. Smith & J.Hashemi, McGraw Hill.

3. Engineering materials, Rajput R.K. 3rd Edition, S. Chand & Company LTD NewDelhi,2008

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Semester I/II

Communication SkillsCourse Outline


Subject Code: SH18/28 Total Hours: 24


1. Concept of Communication

Attributes of Communication Process of Communication Feedback

2. Objectives of Communication

Objectives of upward communication Information and Persuasion Instruction andOrder Education and Training Motivation Raising Morale Advice and Counseling

Warning Appreciation. Objectives of downward communication Request Application

Appeal Demand Representation Complaint Suggestion Objectives of

Horizontal Communication.

3. Channels of Communication

External Outward and Inward. Internal Formal Channels Vertical Horizontal

Consensus Informal Channel Grapevine

4. Barriers to Communication

Physical Barriers Language (Semantic) Barriers Socio-psychological Barriers Cross-

cultural Barriers How to overcome Barriers

5. Listening

Listening Skills Blocks of Effective Listening Improving Listening Skills Use of

Silence in Communication

6. Group Communication

Problems of Group Communication Types of Meetings Conference Committees

Advantages and Disadvantages of Meetings Preparations for a Meeting Conduct of a

Meeting Chairmans Functions Participants Responsibilities

7. Interviews

Purpose of Interviews Types of Interview Promotion Appraisal

Exit Problem Stress Employment Interview Technique of Interviewing

Candidates Preparation Interviewers Role and Preparation

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8. Public Relations

Objectives of Public Relations Internal Public Relations Suggestion Schemes

Counseling and Advice Publications House Organs Bulletins External Public

Relations Image Building Open house Exhibitions, Fairs, Shows Conferences and

Seminars Visits. Use of Mass Media Press Release and Press Handouts Newsletters

Other Media Crisis Management

9. Writing Effectively

Planning Beginning and Ending of a Letter Tactful use of Language Asking for Action

Handling Negatives Talking about Errors Active Voice and Passive Voice

Techniques of Emphasis

10.Job Applications

Covering Letter Bio-data Letters to Applicants

11.Enquiries and Replies

Asking for Information Asking for Help Quotations Bargaining Getting back Lost

Customers

12.Reports

Types of Reports Structure of a Report Individual and Committee Reports

13.Summarization

Uses of Summarizing Skills Making a Precis Drafting Telegrams

14.Literary Aspects

Communication in Life Situations

Recommended Books:

1. Business Communication Urmila Rai & SM Rai

Himalaya Publishing House

2. Footprints II An Anthology of prose, poetry and fiction

by Nandini Nayar Foundation Publication

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Semester I/II

Engineering Chemistry LaboratoryCourse Outline


Subject Code: CHL1/2 Total Hours: 36


1. Determination of total hardness of water by complexometric titration

2. Determination of CaO in the given Cement sample (Rapid EDTA method)

3. Determination of Chemical Oxygen Demand (COD) of the given industrial waste water

sample

4. Colorimetric determination of Iron5. Electrogravimetry of Copper

6. Determination of Dissolved Oxygen in the given water sample by Winkler Method

7. Determination of molecular mass of given polymer by Viscometric method

8. Potentiometric estimation of FAS using standard K2Cr2O7 solution

9. Conductometric estimation of an acid (HCl) using standard NaOH solution

10. Flamephotometric estimation of Sodium in the given sample of water

11.Determination of calorific value of a solid/liquid fuel using Bomb calorimeter

12.Electroless plating of Copper

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Semester I/IIComputer Fundamentals and Programming Laboratory


Subject Code: CSL1/2 Total Hours: 36


Subject:Computer Fundamentals and Programming Lab

1. Identification of various Components of a Computer RAM Cards, Hard Disk Drive,CPU and others.

2. Formatting and Partitioning of Hard Disks.

3. Changing System Configurations RAM, Additional Plug and Play Cards and others.

4. Install/Reinstall OS on a System. Demonstrations on different OSs Linux, WindowsXP and Vista

5. Getting to know various types of Servers Windows 2003 Server, Linux Server andMail Servers. Exploration of college LAN Physical Connections, Routers, Switches,Gateway and Firewalls.

6. Create a document using a suitable word processing package, like MS-WORD andimplement the following:

i) Basic formatting features.ii) Creating tables, merging cells, splitting cells etc.iii) Creating hyperlinks.iv) Embed pictures.v) Using drawing tools.vi) Explore other options available in Word.

7. Create a work sheet using Microsoft MS-Excel and implement the following:

i) Basic formatting features.ii) Show all types of Cell references.iii) Using formulas in worksheetsiv) Customizing Excel Auto fill.

v) Use of data tables in worksheets.vi) Customize tool bars and menus.vii) Automate entering and editing.viii) Plot graphs.

8. Develop and demonstrate a HTML document that illustrates the use of Hyperlinks andTables.

9. Develop and demonstrate a HTML document that illustrates the use of HTML Forms.

10.Develop and demonstrate a HTML document that illustrates the use of HTML withCSS.

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11.Write a C++ program to input N integer numbers into a single dimension array. Sortthem in ascending order using bubble sort technique. Print both the given array andthe sorted array with suitable headings.

12.Write a C++ program to input N real numbers in ascending order into a singledimension array. Conduct a binary search for a given key number and reportsuccess or failure in the form of a suitable message.

13.Write a C++ program to read two matrices A(M x N) and B(P x Q ) and compute theproduct of A and B after checking compatibility for multiplication. Output the inputmatrices and the resultant matrix with suitable headings and format.

14.Given that an EMPLOYEE class contains following members:Datamember: Employee_Number, Employee_Name, Basic, DA, IT, Net_Sal.Member functions: to read the data to calculate Net_Sal and to print data members.Write a C++ program to read the data of N employees and compute Net_Sal of eachemployee (DA=52% of Basic and Income Tax(IT)=30% of the gross salary.

15. Implement a String class. Each object of this class will represent a character string.Data members are the length of the string and the actual character string. In addition

to constructors, destructor, access function and the print function, include asubscript function.

16.Create a class called Numbers consisting of a set of integers and doubles. Useappropriate functions to accept data and print the sum of integers and doubles.Overload the sum () to illustrate function polymorphism.

17.Create a class publication that stores the title(string) and price(float) of a publication.From this class derive two classes book, which adds a page count(int) and tape whichadds a playing time in minutes (float). Each of these classes should have a getdata()function to get its data from the user at the keyboard, and a putdata function todisplay its data. Write a main() program to test the book and tape classes by creating

instances of them, asking the user to fill in their data with getdata() and thendisplaying the data with putdata.

18.Write a program that emulates the dos copy command. That is should copy thecontents of a character file to another file. Invoke the program with two commandline arguments the source file & destination file.

19. Programming Project development using c++.

20.Web development project.

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Semester IIIEngineering Mathematics - III

Course Outline(Common to Non-IT branches)

Subject Code: MA31 Total Hours: 48


LAPLACE TRANSFORMS

Laplace Transforms- Elementary Functions- Properties - Inverse Transforms, Linearity,

Shifting, Transforms of Derivatives and Integrals, differential equations, Unit-Step Function,

second shifting theorem, Diracs Delta Function, differentiation and Integration ofTransforms, Convolution, Integral Equations. Differential Equations, Systems of Differential

Equations, Application of Laplace transforms to engineering problems-LCR circuit, bending of

beams.

FOURIER ANALYSIS

Periodic Functions, Trigonometric Series, Fourier series. Functions of any Period p=2L, Even

and Odd functions, Half-range Expansions, Complex Fourier series. Forced Oscillations,

Practical Harmonic analysis.Fourier integrals, Fourier sine and cosine transforms, Fourier Transform, Inverse Fourier

transforms, Convolution theorem, Parsevals identity.

Z-TRANSFORMS

Introduction, Properties, Inverse Z Transform. Solution to difference equations.

PARTIAL DIFFERENTIAL EQUATIONS

Basic concepts, Formation of partial differential equations, solution of first order PDEs,

equations solvable by direct integration, linear equations of first order, Non linear equations

of first order, Charpits method, separation of variables, vibrating string wave equation, D

Alemberts solution of wave equation, Heat equation: solution by Fourier series, Heat

equation: solution by Fourier integrals and transforms, series, Modeling two dimensional

wave equation.

Reference Books: 1. Ervin Kreyszig, Advanced Engg Mathematics, Wiley Eastern2. Higher Engineering Mathematics by Grewal, Khanna Publishers.3. K A Stroud, Advanced engineering mathematics, MacMillan

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Semester IIIAnalog Electronics

Subject Code: EC 32 Total No. of Hrs: 48


Semi conductor diodes

Semiconductor diode, Ideal Vs Practical, Diode equivalent Circuit, Transition and DiffusionCapacitance, Reverse Recovery TimeDiode Applications: Load line analysis, AND, OR gate, Rectifiers, Capacitor Filter, Clippers,clampers, Zener diodes, Voltage multiplier circuits.

DC Biasing of BJTs

Introduction, Load line analysis, Fixed Bias Circuit, Emitter Bias, Voltage Divider bias, DC biaswith voltage Feedback, PNP Transistors, Bias Stabilization, Transistor switching Networks,

BJT AC Analysis

BJT modeling, Hybrid equivalent model, Common Emitter Fixed Bias con figuration, voltagedivider bias, CE Emitter Bias configuration, Emitter Follower, Common Base Configuration,Collector DC feedback Configuration, Determining the current gain, effect of RL and RS.

BJT Frequency Response

Introduction, Logarithm, Decibels, General Frequency considerations, Low frequencyresponse, Miller effect capacitance, high frequency response, multistage frequency effects

FET Biasing

Construction and Characteristics of JFET, Transfer characteristics, Depletion andenhancement type MOSFETs, Fixed Bias Circuit, Self bias circuit, Voltage Divider bias circuit,

FET Amplifiers

FET Small signal model, fixed bias, self bias, JFET Voltage divider bias, JFET source follower,JFET common gate configuration, MOSFET drain feedback configuration, MOSFET voltagedivider configuration

Feedback and Oscillator Circuits

Feedback concepts, connection types, +ve and ve feedback and its advantages feedbackcircuits, Oscillator operation, Phase shift oscillator, Wein bridge oscillator, Hartley andColpitts oscillator circuit, crystal oscillator

Power Amplifiers

Definition and amplifier types, series fed class A amplifier transformer coupled class Aamplifier, Class B amplifier operation, Class B amplifier circuit, Class C and Class D amplifier,amplifier distortion.

Reference Books:

1. Electronic Devices and Circuit Theory Robert L. Boylestad Louis Nashesky-

PHI 9th Edition.

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2. Electronic Devices and Circuits David A. Bell Prentice Hall Publications.

Semester IIINetwork Analysis

Subject Code: EC33 Total No. of Hrs: 48


Basic Circuit Elements and Waveforms

Introduction, circuit components, assumptions for circuit analysis, definitions, conservation ofenergy, sources of electrical energy, standard input signals, sinusoidal signal

Mesh and Node analysis

Introduction, Kirchhoffs laws, source transformation, mesh and node analysis, networkequations for RLC networkGraph theory and network equation

Introduction, Graph of a network, trees, cotrees and loops, incidence matrix, cutest matrix,cut-set matrix, tieset matrix and loop currents, number of possible trees of a graph

Network theorems

Introduction, Superposition theorem, Norton theorem, Thevinin theorem, Maximum powertransfer theorem, Reciprocity theorem, Millmans theorem

Resonance

Introduction, Series resonance, parallel resonance

The Laplace transform

Introduction, Lapalce transformation, Some basic theorems, Gate function, impulse function,Laplace transform of periodic functions.

Application of Laplace transform

Introduction, Solution of linear differential equation, Heavisides partial fraction expansion,kirchhofs laws, Solution of network problems.

Two port network

Introduction, characterization of linear time invariant two port networks, z parameters, yparameters, h parameters, transmission parameters, interrelationship between theparameters transistors as 2 port active network

Reference Books

1. Roy Chowdhary, Networks and Systems, 2nd Edition, 2006 Reprint, New AgeInternational Publications

2. M.E. Van Valkenburg, Network Analysis, PHI/Pearson Education, 3rd Edition, R

Hayt, Kemmerly and Durbin,

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3. Engineering Circuit Analysis, THM, 6th Edition, 2002.

Semester IIIDigital System Design

Subject Code: EC34 Total No. of Hrs: 48Credits: 4 Hours per week: 4

Boolean algebra and its Design by gates

Principal of duality, Boolean formulas and functions, Normal formulas, Minterm and Maxterm

canonical formulas, m- notation and M-notation. Expansion about a variable, equation

simplification. Reduction theorems, Minterm, Maxterm canonical formula. Complements of

canonical formulas.Gates and combinational networks, Analysis and synthesis procedure.

Incomplete and dont care functions in logic design. Basic and universal gates.

Simplification of Boolean Expression

Karnaugh maps for 1, 2, 3 & 4 variables, POS and SOP forms. Karnaugh map for complete

Boolean function and incomplete Boolean functions.Quine McCluskey method for solving

complete and incomplete Boolean functions. For generating prime imlicants and essential

prime implicants, prime implicates.Map entered variables.

Logic Design with MSI components and PLDs

Binary adders, sub tractors, carry Look Ahead Adder, decimal adder.Comparators, decoders:

logic design using decoders, decoders with enable input. Encoders, Multiplexers, logic design

using multiplexers.

Programmable logic devices (PLDs) : notation, PROMS, Programmable logic array(PLA),

Programmable array logic(PAL) devices.

Flip flops and their Applications

The basic Bistable element: Latches: SR latch, application of SR latch: a switch debouncer

gated SR latch, gated D latch.Master slave SR flip flops, Master Slave JK flip flop, edge

triggered flip flops, Positive and negative edge triggered flip flops, characteristic equation.

Registers, ripple counter, synchronous binary counter, design of mod-6 counter using clocked

JK flip flops, D, T or SR flip flops. Counters based on shift registers.

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Synchronous sequential Networks

Structure, analysis and operation of clocked synchronous sequential networks, excitation and

output expressions, Transition equations, transition tables, excitation tables, state tables,

state diagrams, network terminal behavior.

Logic Families

Logic levels, parameter of logic gates: propagation delay, fan in, fan out, speed power

product. Extension to other logic gates, logic cascades.

Circuit symbols, The MOSFET as a resistor; NMOS and PMOS logic. NMOS as a inverter, NOR

and NAND gate. The CMOS inverter, NOR, NAND gate. Comparison of above logic.

Reference Books:

1. Digital principles and design by Donald D Givone2. Digital logic applications by John M Yarbrough

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Semester IIISignals & Systems

Subject Code: EC35 Total No. of Hrs: 48Credits: 4 Hours per week: 4

Analog Signals

Signals, Classifications, Operations on Signals, Signal Symmetry, Harmonic Signals andSinusoids, Commonly Encountered Signals, The Impulse Function, The Doublet, Moments,Problems.

Discrete Signals

Discrete Signals, Operations on Discrete Signals, Decimation and Interpolation, CommonDiscrete Signals, Discrete-Time harmonics and Sinusoids, Aliasing and the SamplingTheorem, Random Signals, Problems.

Analog Systems

Introduction, System Classification, Analysis of LTI Systems, LTI Systems Described byDifferential Equations, The Impulse Response of LTI Systems, Systems Stability, Application-Oriented Examples, Problems.

Discrete-Time Systems

Discrete-Time Operators, System Classification, Digital Filters, Digital Filters Described byDifference Equations, Impulse Response of Digital Filters, Stability of Discrete-Time LTISystems, Connections: System Representation in Various Forms, Application-OrientedExamples, Problems.

Continuous Convolution

Introduction, Convolution of Some Common Signals, Some Properties of Convolution,Convolution by Ranges (Graphical Convolution), Stability and Causality, The response toPeriodic Inputs, Periodic Convolution, Connections: Convolution and Transform Methods,Convolution Properties Based on Moments, Correlation, Problems.

Discrete Convolution

Discrete Convolution, Convolution Properties, Convolution of Finite Sequences, Stability andCausality, of LTI Systems, System Response to Periodic Inputs, Periodic Convolution,connections: Discrete Convolution and Transform Methods, Deconvolution, DiscreteCorrelation, Problems.

Fourier Series

Fourier Series: A First Look, Simplifications Through Signal Symmetry, Parsevals Relationand the Power in Periodic Signals, The Spectrum of Periodic Signals, Properties of FourierSeries, Signal Reconstruction and the Gibbs Effect, System Response to Periodic Inputs,Application-Oriented Examples, The Dirichlet Kernel and the Gibbs Effect, The Fourier Series,

Orthogonality, and Least Squares, Existence, Convergence and Uniqueness, A historicalPerspective Problems.

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Z Transforms

Introduction, Z-transforms, properties of ROC, properties of Z-transforms, inversion of Z-transforms, transforms analysis of LTI systems, transfer function, stability and causality,unilateral Z-transform and its application to solve difference equations.

Reference Books:1. Simon Haykin & Barry Van Veen, Signals and Systems, John Wiley & Sons, 2001.

2. Ashok Ambardar, Analog and Digital Signal Processing, Thomson Learning, 2/e,2001.

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Semester IIIElectronics Measurements

Subject Code: EC36 Total No. of Hrs: 48


Units and dimensions

Review of fundamental and derived units, SI Units, dimensional equations, problems.

Measurement of resistance, inductance and capacitance

Wheatstones bridge, sensitivity analysis, limitations; Kelvin double bridge; earth resistancemeasurement using Megger Andersons bridge Wiens bridge; Schering bridge; sources anddetectors, shielding of bridge problem.

Extension of instrument rangesShunts and multipliers, construction and theory of instrument transformers, ratio and phaseangle errors of CT and PT, turns compensation; problems.

Measurement of power and related parameters

Wattmeter; LPF Wattmeter ; Induction type energy meter: construction, theory , errorsadjustments and calibration; principle of electronic energy meter; construction and operationof electrodynamometer single-phase PF meter, Weston frequency meter and phase sequenceIndicator; problems.

Electronic InstrumentsIntroduction, True RMS voltmeter, Electronic multi-meters, Digital voltmeters, Q meter,Phase meter and vector impedance meters.

TransducersClassification, selection, strain gauges, LVDT, Selsyn, Photoconductive and Photovoltaic cellsinterfacing resistive transducers to electronic circuits. Thermo-couple & Thermistors.

Special TransducersHall Effect Transducers, Principles & Applications. Magnetostrictive Transducers:Characteristics & applications. OptoElectronic Transducers: Photo Voltaic & Photoconductive Cells, Photo Diode & Photo Transistor - Characteristics & applications. Digitaltransducers and Smart transducers: Principles & Applications.

OscilloscopesIntroduction, Basic principles, CRT features, Block diagram and working of each block,Typical CRT co

Documents

electronics and communication syllabus