dtu ep syllabus.pdf

1

DELHI TECHNOLOGICAL UNIVERSITY

COURSE CURRICULUM & SCHEME OF EXAMINATION

for

B.TECH. (Engineering Physics) Engineering Physics(Majors in Electronics & Communication)

Semester I Examination November, 2009

Semester II Examination May, 2010

Semester III Examination November, 2010

Semester IV Examination May, 2011

Semester V Examination November, 2011

Semester VI Examination May, 2012

Semester VII Examination November, 2012

Semester VIII Examination May, 2013

istudys.in

(Internet study made easy)

2

ENGINEERING PHYSICS

Summary of Revised Scheme of Examination

Total Credits for B.TECH. Degree: 240

Semester wise: I-30, II-30, III-30, IV-30, V-30, VI-30, VII-30, VIII-30

Classification of Subjects:

Subjects H A C

I 19 11 00

II 14 16 00

III 03 04 23

IV 00 04 26

V 00 06 24

VI 00 14 16

VII 00 07 23

VIII 00 00 30

Total Credits 240 36 64 142

Percentage

Contents of H, A, C

15% 25.83% 59.16%

H Humanities, Social Studies and Basic Sciences

A Allied Engineering

C Core (include major project and practical training also)

Note:

Industrial training of 10 weeks durations during summer vacations after 6th

semester and 4 weeks after 7th semester.

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SUGGESTED SCHEME FOR B.TECH. FIRST SEMESTER (ENGINEERING PHYSICS)

S.No. Course No. Subject LTP Evaluation

Sessional End Total

Marks Credit

Type TH1 MA 101 Mathematics-1 310 30 70 100 4H

TH2 HU 102 Communication skills 210 30 70 100 3H

TH3 EP 103 Applied Physics-I 400 30 70 100 4H

TH4 CH 104 Applied Chemistry 310 30 70 100 4H

TH5 EE 105 Electrical sciences 310 30 70 100 4A

TH6 IT 106 Fundamentals of Information Technology

210 30 70 100 3A

PR1 EP 107 Applied Physics Lab 002 30 70 100 2H

PR2 CH 108 Applied Chemistry Lab 002 30 70 100 2H

PR3 EE 109 Electrical Sciences Lab 002 30 70 100 2A

PR4 IT 110 Information Technology Lab

002 30 70 100 2A

TOTAL 30 hrs 1000 30

SUGGESTED SCHEME FOR B.TECH. SECOND SEMESTER (ENGINEERING PHYSICS) S.No. Course No. Subject LTP Evaluation

Sessional End

Total

Marks Credit

Type TH1 MA 111 Mathematics-II 310 30 70 100 4H

TH2 EN 112 Environmental Sciences 200 30 70 100 2H

TH3 EP 113 Applied Physics-II 400 30 70 100 4H

TH4 AS 114 Engineering Materials 400 30 70 100 4H

TH5 ME 115 Basic Mechanical Engineering

400 30 70 100 4A

TH6 COE 116 Programming Fundamentals 200 30 70 100 2A

PR1 ME 117 Engineering Graphics 003 30 70 100 3A

PR2 ME 118 Mechanical workshop 003 30 70 100 3A

PR3 COE 119 Programming Lab 002 30 70 100 2A

PR4 PE 120 Applied Physics Lab 002 30 70 100 3A

TOTAL 30 hrs 1000 30

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SUGGESTED SCHEME FOR B.TECH. THIRD SEMESTER (ENGINEERING PHYSICS)

SUGGESTED SCHEME FOR B.TECH. FOURTH SEMESTER (ENGINEERING PHYSICS)

S.No. Course

No.

Subject L T P Evaluation

Sessional End

Total

Marks

Credit

Type

TH1 EP 201 Introduction to computing 3 1 0 30 70 100 4C

TH2 EP 202 Mathematical Physics 3 1 0 30 70 100 4C

TH3 EP 203 Thermal Physics 3 1 0 30 70 100 4C

TH4 EP 204 Digital Electronics 3 1 0 30 70 100 4C

TH5 EP 205 Engineering Mechanics 3 1 0 30 70 100 4A

TH6 EP 206 Basic Engineering

Economics

3 0 0 30 70 100 3H

PR1 EP207 Thermal Physics Lab 0 0 2 30 70 100 2C

PR2 EP 208 Digital Electronics Lab 0 0 2 30 70 100 2C

PR3 EP 209 Computing Lab 0 0 2 30 70 100 2C

VS1 EP 210 Self study 0 1 0 30 70 100 1C

Total 30 hrs 1000 30

S.No. Course

No.

Subject L T P Evaluation

Sessional End

Total

Marks

Credit

Type

TH1 EP 211 Classical & Quantum

Mechanics

3 1 0 30 70 100 4C

TH2 EP 212 Optics 3 1 0 30 70 100 4C

TH3 EP 213 Signals and systems 3 1 0 30 70 100 4A

TH4 EP 214 Microprocessor & Interfacing 3 0 0 30 70 100 3C

TH5 EP 215 Computational Methods 3 1 0 30 70 100 4C

TH6 EP 216 Condensed Matter Physics 3 1 0 30 70 100 3C

PR1 EP 217 Optics Lab 0 0 2 30 70 100 2C

PR2 EP 218 Solid State Physics Lab 0 0 2 30 70 100 2C

PR3 EP 219 Microprocessor & Interfacing

Lab

0 0 2 30 70 100 2C

VS2 EP 220

Self study 0 1 0 30 70 100 1C


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SUGGESTED SCHEME FOR B.TECH.FIFTH SEMESTER (ENGINEERING PHYSICS)

SUGGESTED SCHEME FOR B.TECH. SIXTH SEMESTER (ENGINEERING PHYSICS)

S.NO Course

No

Subject LTP Evaluation Total Credit

type Sessional End

TH1 EP 311 Instrumentation and Control 3 1 0 30 70 100 4A

TH2 EP 312 Fiber optics and optical

communication

3 1 0 30 70 100 4C

TH3 EP 313 Quantum Information and

Computing

3 1 0 30 70 100 4C

TH4 EP314 Microwave Engineering 3 1 0 30 70 100 4A

TH5 EP 315 Fabrication and Characterization

of Nanostructures

3 1 0 30 70 100 4C

PR1 EP316 Fiber optics and optical

communication lab

0 0 2 30 70 100 2C

PR2 EP 317 Microwave Engineering Lab 0 0 2 30 70 100 2A

PR4 EP 318 Minor Project-II 0 0 6 50

150 200 4C

PR3 EP 319 Industrial Training - 100 100 2C

Total 30 Hrs 1000 30

S.NO Course

No


type Sessional End

TH1 EP 301 Atomic and Molecular Physics 3 1 0 30

30

30

30

30

30

30

30

70

70

70

70

70

70

70

70

100 4C

TH2 EP 302 Communication systems 3 1 0 100 4C

TH3 EP 303 Electromagnetic theory, Antennas

and Propagation 3 1 0 100

4C

TH4 EP 304 Semiconductor Devices 3 1 0 100 4C

TH5 EP 305 Biophysics 3 1 0 100 4A

PR1 EP 306 Advanced Physics Lab 0 0 2 100

2C

PR2 EP 307 Electromagnetic theory, Antenna

and Propagation Lab 0 0 2 100 2C

PR3 EP 308 Communication Systems Lab 0 0 2 100

2A

PR4 EP 309 Minor Project-I 0 0 4 50 150 200 4C


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SUGGESTED SCHEME FOR B.TECH. SEVENTH SEMESTER (ENGINEERING PHYSICS)

SUGGESTED SCHEME FOR B.TECH. EIGHTH SEMESTER (ENGINEERING PHYSICS)

S.NO Course

No


type Sessional End

TH1 EP 401 Computer Networking 3 1 0 30 70 100 4A

TH2 EP 402 Alternate Energy Storage and

conversion devices

3 1 0 30 70 100 4C

TH3 EP 403 Mobile and Satellite

Communication

3 1 0 30 70 100 4C

TH4 EP 404 Elective I 3 1 0 30 70 100 4C

TH5 EP 405 Open Elective 3 0 0 30 70 100 3C

PR1 EP 406 Energy Storage and conversion

lab

0 0 2 30 70 100 2C

PR2 EP 407 Mobile and Satellite

Communication Lab

0 0 2 30 70 100 2C

PR3 EP 408 Major Project (Part-I) 0 0 8 50

150 200 4C

PR4 EP 409 Industrial Training 100 100 4C


S.NO Course

No


type Sessional End

TH1 EP 411 VLSI and FPGA Design Synthesis 3 1 0 30 70 100 4C

TH2 EP 412 Elective II 3 1 0 30 70 100 4C

TH3 EP 413 Open Elective 3 1 0 30 70 100 4C

PR1 EP 414 Elective Lab 0 0 3 30 70 100 3C

PR2 EP 415 FPGA Design Lab 0 0 3 30 70 100 3C

PR3 EP 416 Seminar 0 0 2 100 100 2C

PR4 EP 417 Major project (Part II) 0 0 10 100

300 400 10C


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List of Electives

MINORS:

A. Nano Science and Technology

B. Photonics

C. Robotics and Intelligent Systems

D. Nuclear Engineering

(A) MATERIAL SCIENCE AND TECHNOLOGY

A1. Nano Science and Technology

A2. Introduction to Spintronics

A3. Selected topics in Nano Science and Technology

AP3.Materials Growth and Characterization Lab

(B) PHOTONICS

B1. Photonics

B2.Integrated Optics

B3. Selected topics in photonics

BP3. Photonics Lab

(C) ROBOTICS AND INTELLIGENT SYSTEMS

C1. Introduction to Automation and Motion Control

C2. Robotic Engineering

C3. Selected topics in robotics and intelligent systems

CP3. Robotics Lab

(D) NUCLEAR ENGINEERING

D1. Principles of Nuclear Engineering

D2. Nuclear Materials for Engineering Applications

D3. Selected topics in nuclear engineering

DP3. Nuclear Applications Lab

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The course structure is designed to award the degree as

B.Tech. (Engg. Physics) with majors in Electronics and

Communication Technology and minors in any one of the

following:

Nano Science and Technology

Photonics

Robotics and Intelligent Systems

Nuclear Engineering

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Course Curriculum

B.TECH. I- Year, I Semester Examination

Theory Paper I (Common to all Branches)

EE/COE/EC/IC/ME/PE/MPA/CE/ENE/PT/IT/BT

L T P Credits

3 1 0 4

MA-101 Mathematics I

UNIT I: Infinite series: Tests for convergence of series (comparison, ratio, root, integral, Raabes, logarithmic), Alternating series, Absolute convergence, Conditional convergence. (5L)

UNIT II: Calculus of single variable: Taylors & Maclaurins expansion, Radius of curvature, applications of definite integral to area, arc length, surface area and volume (in Cartesian, parametric and

polar co-ordinates). (8L)

UNIT III: Calculus of several variables: Partial differentiation, Eulers theorem, total differential, Taylors theorem, Maxima-Minima, Lagranges method of multipliers, Application in estimation of error and

approximation. (7L)

UNIT IV: Multiple Integrals: Double integral (Cartesian and polar co-ordinates), change of order of integration, triple integrals (Cartesian, cylindrical and spherical co-ordinates), Gamma and Beta functions.

Applications of multiple integration in area, volume, centre of mass, and moment of inertia. (8L)

UNIT V: Vector Calculus: Continuity and differentiability of vector functions, Scalar and vector point function, Gradient, Directional Derivative, divergence, curl and their applications. Line integral, surface

integral and volume integral, applications to work done by the force . Applications of Greens, Stokes and

Gauss divergence theorems. (8L)

UNIT VI: Function of Complex Variable: Definition of complex function. Circular, Hyperbolic, and

Logarithmic functions. Inverse of Circular, and Hyperbolic functions. (4L)

Text Books/Reference Books:

1. Advanced Engineering Mathematics by Alan Jeffery ; Academic Press

2. Calculus and Analytic Geometry by Thomas/Finney; Narosa.

3. Advanced Engineering Mathematics by Kreyszig; Wiley.

4. Advanced Engineering Mathematics by Taneja ; I K international

5. Advanced Engineering Mathematics by Jain/Iyenger; Narosa.

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Course Curriculum B.TECH. I- Year, I Semester Examination

Theory Paper II (Common to all Branches)


L T P Credit

2 1 0 3

HU-102 Communication Skills

UNIT I: Functional English:

(A) Parts of speech; Tense and concord; Conditional clauses; Question tags & short responses;

Punctuation; Common errors.

(B) Vocabulary and Usage: Synonyms & Antonyms; One word substitutions; Words often

confused; Idioms / Idiomatic expressions.

UNIT II: Basics of Writing:

(A) Presentation of Technical Information: Technical description of simple objects, tools,

appliances; Processes and operations; Scientific Principles; Definitions ; Interpretation of Visual

Data (graph, charts etc)

(B) Writing of: Paragraph; Summary and Abstract; Taking and Making Notes.

(C) Comprehension of Unseen Passages based on reading exercises like Skimming, Scanning and

Inference making.

UNIT III: Oral Communication:

Phonetics: Speech Sounds and their articulation; Phonemes, syllable, Stress, Transcription of Words

and Simple Sentences; Presentation and Seminar; Language Lab Practice for Oral Communication.

UNIT IV: Texts for Appreciation and Analysis:

(A) Wings of Fire by APJ Abdul Kalam

(B) The Fortune at the Bottom of the Pyramid by C.K. Prahalad.

(C) The Branded (Uchalya) by Laxman Gaikwad

(D) Geetanjali by Ravindranath Tagore.


1. Day, Robert A. Scientific English: A Guide for Scientists and Other Professionals. UP.

2. Maison Margaret , Examine Your English, New Delhi: Orient Longman.

3. Tikoo M.L., A.E. Subramaniam and P.R. Subramaniam. Intermediate Grammar Usage and

Composition. Delhi: Orient Longman.

4. Weiss, Edmond H. Writing Remedies: Practical Exercises for Technical Writing.

University Press.

5. Lesikar and Flatley. Business Communications. New Delhi, Biztantra Press.

6. OConnor, Better English Pronunciation, Cambridge: Cambridge University Press.

7. Gaikwad, Laxman, The Branded, Delhi: Sahitya Akademi.

8. Kalam, APJ Abdul, Wings of Fire, Delhi: University Press.

9. C.K. Prahalad, The Fortune at the Bottom of the Pyramid, Wharton School Publishing.

10. Rabindranath Tagore, Gitanjali, Filiquarian Publishing, LLC.

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Course Curriculum B.TECH.I year, I- Semester Examination

Theory Paper III (Common to all Branches)


L T P Credits

3 1 0 4

EP 103 Applied Physics

UNIT I: Relativity: Review of concepts of frames of reference and Galilean transformation equation, Michelson Morley

experiment and its implications, Einsteins special theory of relativity, Lorentz transformation

equations, Law of addition of velocities, Mass variation with velocity, Concept of energy and

momentum, Mass energy relation.

UNIT II: Oscillations, waves: Damped and forced oscillations, Resonance (amplitude and power), Q factor, Sharpness of resonance.

Equations of longitudinal and transverse waves and their solutions, Impudence, Reflection and

transmission of waves at a boundary, Impedance matching between two medium.

UNIT III: Physical optics: Interference by division of wave front and amplitude, Multiple beam interference and Fabry-Perot

interferometer, Fresnel diffraction through a straight edge, Fraunhoffer diffraction, Zone plate, single

slit and N-slit / grating, Resolving power of telescope, prism and grating. Polarization by reflection and

by transmission, Brewsters law, Double refraction, elliptically and circularly polarized light, Nichol

prism, Quarter and half wave plates.

UNIT IV: Optical Instruments: Cardinal points of co-axial lens systems, spherical and chromatic aberrations and their removal,

Huygens and Ramsdens eyepiece.

UNIT V: Laser optics: Coherence and coherent properties of laser beams, Brief working principal of lasers, Spontaneous and

stimulated emission, Einsteins co-efficient, Ruby laser, He-Ne laser.

UNIT VI: Optical Fiber: Classification of optical fibers, Refractive index profile, Core cladding refractive index difference,

Numerical aperture of optical fiber, Pulse dispersion in optical fiber (ray theory).


1. Physics of Vibrations and Waves by H.J. Pain.

2. Vibrations and Waves by A.P. French.

3. Perspective of Modern Physics by Authors Beiser.

4. Optics by A. Ghatak.

5. Berkley Physics Course Vol 1.

12

Course Curriculum

B.TECH. I year, I- Semester Examination

Theory Paper IV (Common to all Branches)

EE/COE/EC/IC/ MPA/CE/ENE/PT/IT/BT ME/PE

L T P Credits

3 1 0 4

CH-104 Applied Chemistry

UNIT I: (a) Conventional Analysis: Volumetric Analysis, Types of titrations, Theory of indicators. 2L

(b) Spectral Analysis: Electromagnetic radiation, Lambert-Beers Law, UV-VIS, IR,

instrumentation & applications. 4L

UNIT II: Thermal Methods of Analysis: principle, working and applications of Thermogravimetry, Differential thermal analysis and Differential scanning calorimetry. 4L

UNIT III: (a) Polymers: Monomer & polymer, functionality and Degree of Polymerization. Mechanism of polymerization. Molecular weights of polymers. Methods of polymerization. Industrial

production of PE and PF resins. Industrial applications of polymers. 6L

(b) Bio-molecules: Classification, Structure, physical and chemical properties of Amino-acids,

Peptides and Proteins, Carbohydrates, Cellulose and its derivatives, RNA, DNA. Introduction to Bio-

degradable Polymers. 6L

UNIT IV: Electrochemistry: Electrochemical cells: components, characteristics of batteries. Primary and Secondary battery systems: Zinc-Carbon cells, Lead storage and lithium batteries. Fuel Cells,

Electro-deposition: Electrical and chemical requirements. Electroplating bath and linings. Agitation,

Circulation and filteration equipment. Plating of copper, gold and rhodium. 8L

UNIT V: Phase Equilibrium: Definitions of Phase, component and degree of freedom, Gibbs phase rule. One component systems: Water and sulphur. Two component systems: Pb-Ag and Cu-Ni system.

6L

Univ VI: Green Chemistry: Introduction, Goals & Significance of Green Chemistry. Reagents, solvents and catalysts for green synthesis. Principles of Green Chemistry, Evaluation of feedstocks,

reaction types and methods. Future trends in Green Chemistry. 4L

Text Books/Reference Books: 1. Thermal Analysis by T. Hatakeyama, F.X. Quinn; Wiley.

2. Inorganic Quantitative Analysis by A.I. Vogel.

3. Instrumental Method of Analysis by Skoog D.A.; HRW International.

4. Green Chemistry: Theory & Practice by P.T. Anastas & JC Warner; Oxford Univ Press.

5. Polymer Science and Technology by Billmeyer; John Wiley.

6. Polymer Science and Technology by Fried; Prentice Hall.

13

Course Curriculum B.TECH.I year, I Semester Examination

Theory Paper-V (Common to all Branches)


L T P Credits

3 1 0 4

EE 105 Electrical Sciences

UNIT I: Introduction: Role and importance of circuits in Engineering, concept of fields, charge, current, voltage, energy and

there interrelationship. V-I characteristics of ideal voltage and ideal current sources, various types of

controlled sources. Passive circuit components: V-I characteristics and ratings of different types of R, L,

C elements.

UNIT II: DC Network: Series circuits and parallel circuits, power and energy, Kirchoffs Laws. Delta-star conversion,

Superposition Theorem, Thevenins Theorem, Nortons theorem, Maximum Power Transfer Theorem,

Tellgen Theorem.

UNIT III: Single Phase AC Circuits: Single phase EMF generation, average and effective values of sinusoids, complex representation of

impedance, series and parallel circuits, concept of phasor, phasor diagram, power factor, power in

complex notation, real power, reactive power and apparent power. Resonance in series and parallel

circuits, Q-factor, bandwidth and their relationship, half power points.

UNIT IV: Three-Phase AC Circuits: Three phase EMF generation, delta and Y connection, line and phase quantities. Solution of three phase

circuits: balanced supply voltage and balanced load, phasor diagram, measurement of power in three

phase circuits.

UNIT V: Magnetic Circuits & Transformers: Amperes circuital law, B-H curve, concept of reluctance, flux, MMF, analogies between electrical and

magnetic quantities solution of magnetic circuits. Hysteresis and eddy current losses, application of

magnetic force, mutual inductance and dot convention. Single phase Transformer construction, principle

of working, auto transformer and their applications.

UNIT VI: Three Phase Induction Motor: Construction, Principle of operation, types of motors applications.

UNIT VII: Equipment and Machine Power supply basics: Electric wiring, power distribution and utilization: Neutral, grounding & phase definitions, colour

coding, of cable, IS standards for domestic and industrial cable/wiring, conduct and cable wiring, MCB,

ELCB, industrial and domestic sockets, plug, etc. Fuses, their types characteristics, introduction to

energy efficient lighting and energy conservation.

UNIT VIII: Measuring Instruments: Analog indicating instruments, devices, Damping devices, PMMC ammeters and voltmeters, shunt and

multipliers, Moving iron ammeter and voltmeters, dynamometer type wattmeters, multimeters, AC watt-

hour meters. Digital electronic voltmeters, digital electronic ammeters and wattmeters.


1. Basic electrical Engineering by C.L. Wadhwa, 4

th Edition; New Age International.

2. Basic Electrical Engineering by Fitzereld, Higgenbotham & Grabel; McGraw Hill

International.

3. Electrical Engineering Fundamentals by Vincent Deltoro; Prentice Hall International (EEI).

4. Relevant Indian Electricity Supply rules & BIS codes.

14


Theory Paper-VI (Common to all Branches)


L T P Credits

2 1 0 3

IT 106 Introductions to Information Technology

UNIT I : Fundamental Concepts of Information: Definition of information, Data Vs Information, Introduction to Information representation in Digital Media, Text, image, graphics,

Animation, Audio, Video etc., Need, Value and Quality of information

UNIT II : Concepts in Computer & Programming: Definition of Electronic Computer, History, Generations, Characteristic and Application of Computers, Classification of Computers,

Memory, different types of memory, Computer Hardware - CPU, Various I/O devices, Peripherals,

Firmware and Humanware.

UNIT III : Programming Language Classification & Program Methodology: Computer Languages, Generation of Languages, Translators, Interpreters, Compilers, Flow Charts, Dataflow

Diagram, Assemblers, Introduction to 4GL and 5GL.

UNIT IV : Digital Devices and Basic Network Concepts: Digital Fundamentals: Various codes, decimal, binary, hexa-decimal conversion, floating numbers gates, flip flops, adder, multiplexes,

Introduction to Data Transmission.

UNIT V : Data Communication & Networks: Computer Networks- Introduction of LAN, MAN and WAN. Network Topologies, Client-server Architecture.

UNIT VI : Internet and Web Technologies: Hypertext Markup Language, DHTML, WWW, HTTP, Gopher, FTP, Telnet, Web Browsers, Net Surfing, Search Engines, Email, Safety of Business

Transaction on web. Elementary Concepts of E-Learning and E-Commerce, Electronic Payment

Systems, Digital Signatures, Firewall.

Text Books/Reference Books: 1. Using Information Technology: A Practical Introduction to Computers &

Communications by William Sawyer & Hutchinson; Publisher: Tata McGraw-Hill.

2. Introduction to Computers by Peter Norton; Tata McGraw-Hill.

3. Introduction to Computers by Rajaraman; EPI.

4. Data Compression by Nelson; BPB.

5. Internet, An introductionby CIS Tems; Tata McGraw Hill.

6. Information Technology: Breaking News by Curtin; TMH.

7. Fundamentals of Information Technology by Leon & Leon; Vikas.

8. Internet 101 by Lehngart; Addison Wesley.

15


Practical Paper I (Common to all Branches)


EP-107 Physics Lab

Based on course work corresponding EP-103

L T P Credits

0 0 2 02


Practical Paper II (Common to all Branches)


CH-108 Chemistry Lab

Based on course work corresponding CH-104

` L T P Credits

0 0 2 02


Practical Paper III (Common to all Branches)


EE-109 Electrical Sciences Lab

Based on course work corresponding EE-105

L T P Credits

0 0 2 02


Practical Paper IV (Common to all Branches)


IT-110 Fundamental of IT Lab

Based on course work corresponding IT-106

L T P Credits

0 0 2 02

16

Course Curriculum B.TECH.I year, II Semester Examination

Theory Paper-I (Common to all Branches)


L T P Credits

2 1 0 3

MA- 111 Mathematics-II

Matrices: Rank of a matrix, inverse of a matrix using elementary transformations, consistency of linear system of equations; Eigen-values and eigenvectors of a matrix, Cayley Hamilton theorem, diagonalization

of matrix. (8L)

Ordinary differential equations: Bernoullis equation, Second & higher order linear differential equations with constant coefficients, General solution of homogenous and non- homogenous equations,

method of variation of parameters, Euler-Cauchy equation, simultaneous linear equations, power series

method, Frobenious method, Legendre equation, Legendre polynomials, Bessel equation. (16L)

Laplace Transforms: Basic properties, Laplace transform of derivatives and integrals, Inverse Laplace transform, Differentiation and Integration of Laplace transform, Convolution theorem, UNIT step function,

Periodic function, Laplace transform solution of IVP and system of linear differential equations. (6L)

Fourier series and Transforms: Fourier series, Dirichlet conditions, Even and odd functions, half range series, harmonic analysis, Fourier Transforms, Sine and Cosine Transforms, Transforms of derivatives and

integrals, Applications to boundary value problem in ordinary differential equations (simple cases only).

(10L)


1. Advanced Engineering Mathematics by Greenberg; Pearson Education.

2. Advanced Engineering Mathematics by Kreyszig; Wiley.

3. Advanced Engineering Mathematics by Taneja; I K international.

4. Advanced Engineering Mathematics by Jain/Iyenger; Narosa.

17


Theory Paper-II (Common to all Branches)


L T P Credits

2 0 0 2

EN 112 Environmental Science

UNIT I: Introduction to Environment: Origin & evolution of earth, segments of environment- lithosphere, hydrosphere, atmosphere & biosphere, Biogeochemical cycles- geologic, hydrological, oxygen, nitrogen,

carbon & phosphate cycles.

UNIT II: Ecosystems: Concept of ecosystem biotic & abiotic components, types of ecosystems, functional components of ecosystem- biodiversity, productivity, food chains & food webs, material cycling and energy

flow, different ecosystems- forest, grassland, desert, aquatic.

UNIT III: Water Pollution: Water quality, physical, chemical & biological characteristics of water & waste water, ground water pollution, water borne diseases.

UNIT IV : Air & Noise Pollution: Primary & secondary air pollutants, sources, effects & control of- carbon monoxide, nitrogen oxides, hydrocarbons, sulphur dioxide & particulates, Air quality standards,

global warming, acid rain, El Nino, ozone hole. Classification and measurement of noise, effects of noise

pollution on human, control of noise pollution.

UNIT V: Energy & Solid Waste Management: Conventional energy resources- coal, thermal, petroleum, hydroelectricity, nuclear power, wood, non conventional sources- solar, biogas, wind, ocean & tidal energy,

geothermal energy. Hazardous and non hazardous solid waste management. Environmental laws and acts.


1. Environmental Studies by De Anil Kumar & De Arnab Kumar; New Age International (P) Ltd.

2. Environmental Studies by Basak Anindita; Pearson Education South Asia.

3. A Text Book of Environmental Science by Subramanian. V; Narosa Publishing House.

4. Essentials of Ecology & Environment Science by Rana. S.V.S.; EPI Publications.

18

Course Curriculum

B.TECH. I- Year, II- Semester Examination

Theory Paper- III, (Common to all Branches)


L T P Credits

4 0 0 4

EP 113 Applied Physics II

UNIT I: Quantum Physics.

Failure of classical physics ,Compton effect , Pair production de-broglie relation, wave function, Probability

density, Schrodinger wave equation operators, expection values and eigen value equation, particle in a box,

simple harmonic oscillator problem, concept of degeneracy.

UNITII: Clasical Statistic.

Statistical physics : Microscopic macroscopic systems, concept of phase space basic postulates of statistical

mechanics, MaxwellBoltzmann distribution law.

UNITIII: Quantum statistic.

Quantum Statistics: FermiDirac and Bose Einstein Distribution, Fermi- Dirac probability function, Fermi

energy level.

UNITIV: Nuclear Physics.

Nuclear properties, constituent of the nucleus, binding energy, stable nuclei, radioactive decay law (alpha

and beta spectrum), Q-value of nuclear reaction , nuclear models-liquid drop and shell model, nuclear fission

and fusion, elementary ideas of nuclear reactors.

UNITV: Electrodynamics.

Maxwells equations, concept of displacement current, Derivation of wave equation for plane

electromagnetic wave, Pointing vector. Pointing theorem, Energy density, wave equation in dielectric &

conducting media.


1. Nuclear Physics by Erwin Kaplan.

2. Concept of Nuclear Physics by Cohen.

3. Electrodynamics by Griffith.

4. Electricity & magnetism by Rangawala & Mahajan.

5. Perspective of Modern Physics by Arthur Beiser.

19

Course Curriculum


Theory Paper- IV, (Common to all Branches)


L T P Credits

4 0 0 4

AS- 114 Engineering Materials

SECTION A (Physics)

Crystal Structure: Bravis lattices; Miller indices, simple crystal structures, Different kind of bending.

Metallic Conduction: Energy distribution of electrons in a metal, Fermi level, Conduction process.

Semi Conductors: Band theory of solids , P and N type of semiconductors , Statistics of holes and electrons , Hall effect , Effect of temperature on conductivity , Life time and recombination ,draft and

diffusion in PN junction .

Dielectric and Optical properties of Materials: Dielectric polarization and dielectric constant, optical absorption process.

Magnetism and Superconducting Materials: Dia-para , Ferro-magnetism , Antiferro , Ferro-magnetism ferrites, Superconducting materials , Properties , Type of superconducting materials ,

Meissner effect , High- Tc superconductor , application.

SECTION B (CHEMISTRY)

Water treatment: Impurities in water, hardness of water, determination and removal of hardness, boiler feed water, boiler troubles and prevention, numerical based on hardness removal.

Composite materials: Introduction, limitations of conventional engineering materials, role of matrix in composites, classification, matrix materials, reinforcements, metal-matrix composites, polymer-

matrix composites, fiber-reinforced composites, environmental effects on composites, applications of

composites.

Speciality Polymers: Conducting polymers-Introduction, conduction mechanism, polyacetylene, polyparaphenylene and polypyrole, applications of conducting polymers, Ion-exchange resins and their

applications.

Ceramic & Refractory: Introduction, classification, properties, raw materials, manufacturing and applications.

NOTE: Two hrs per week load for Applied Physics Department. Two hrs per week load for Applied Chemistry Department.

Text Books/Reference Books (PHYSICS):

1. Solid State Physics, 7th edition by Kittel; J. W .& Sons Publication.

2. Solid State Physics by Wahab M.A.; Narosa Publishing House.

3. Solid State Physics by Ali OmerM; Pearson Education (Singapore) pvt. Ltd. India branch,

New delhi.

4. Engineering Materials: Properties and Selection, 7th edition by Kenneth G. Budinski,

Budinshi; Pearson Singapor (Prentice Hall).

5. Solid State Physics by Pillai S.O.; New Age International Publication.

Text Books/Reference Books (CHEMISTRY)

1. Essentials of Material Science and Engineering by Donald R. Askeland, Pradeep P. Phule;

Thomson.

2. Speciality Polymers by R.W.Dyson,; USA: Chapman and Hall, New York.

3. Polymer Composites by A.P.Gupta, M.C.Gupta; New Age publication.

4. Engineering Chemistry by R.N.Goyal, H.Goel; Ane Books India.

5. Engineering Chemistry by S.S.Dara; S.Chand.

6. Engineering Chemistry by Raghupati Mukhopadhyay, Sriparna Datta; New Age International.

7. Engineering Chemistry by P.C.Jain, Monica Jain; Dhanpat Rai.

20

Course Curriculum


Theory Paper- V, (Common to all Branches)


L T P Credits

4 0 0 4 ME 115 Basic Mechanical Engineering

(PART A)

UNIT I: Introduction to Thermodynamics, Concepts of systems, control volume, state, properties, equilibrium, quasi-static process, reversible & irreversible process, cyclic process. Zeroeth

Law and Temperature, Ideal Gas. Heat and Work.

UNIT II: First Law of Thermodynamics for closed & open systems. Non Flow Energy Equation. Steady State, Steady Flow Energy Equation.

Second Law of Thermodynamics Kelvin and Planks Statements, Clausius inequality, Definition of

Head Engines, Heat pumps, Refrigerators. Concept of Energy and availability. Carnot Cycle; Carnot

efficiency, Otto, Diedel, Dual cycle and their efficiencies.

UNIT III: Properties & Classification of Fluids, Ideal & real fluids, Newtons law of viscosity, Pressure at a point, Pascals law, Pressurevariation in a static fluid, Introduction to Bio-fluid Mechanics

General description of fluid motion, stream lines, continuity equation, Bernoullis equation, Steady and

unsteady flow.Turbines and pumps.

(PART-B)

UNIT IV: Introduction to engineering materials for mechanical construction. Composition, mechanical and fabricating characteristics and applications of various types of cast irons, plain carbon and alloy

steels, copper, aluminum and their alloys like duralumin, brasses and bronzes cutting tool materials,

super alloys thermoplastics, thermosets and composite materials.

UNIT V: Introduction to Manufacturing processes for various machine elements. Introduction to Casting & Welding processes. Fabrication of large & small components and assemblies- example Nuts

and Bolts, Water turbine rotors, Large Electric Generators, introduction to turning milling, shaping,

drilling & boring processes.

UNIT VI: Introduction to quality measurement for manufacturing processes; standards of measurements, line standards and, end standards, precision measuring instruments and gauges: vernier

calipers, height gauges, micrometers, comparators, dial indicators, and limit gauges.

Text Books/Reference Books

1. Engineering Thermodynamics by P. K. Nag.

2. Fundamentals of Classical Thermodynamics by G. J. Van Wyle and R. E. Santag.

3. Introduction to Fluid Mechanics and Fluid Machines by S. K. Som and G. Biswas.

4. Fluid Mechanics by V. L. Streeter and E. B. Wylie.

5. Fluid Mechanics and Hydraulic Machines by R. K. Bansal.

6. Manufacturing Processes by Kalpakjian.

7. Fluid Mechanics by Modi and Seth.

8. Workshop Practics by A. K. Hazara Chowdhary.

9. Workshop Technology by W. A. J. Chapman.

10. Production Engineering by P.C. Sharma.

11. Production Engineering by R. K. Jain.

21

Course Curriculum B.TECH. I- Year, II- Semester Examination

Theory Paper- VI, (Common to all Branches)


L T P Credits

2 0 0 2

COE 116 Programming Fundamentals

UNIT I: Introduction: Concepts of algorithm, flow chart, Introduction to different Programming Languages like

C, C++, Java etc.

Elementary Programming: Data types, assignment statements, conditional statements and input/output

statements. Iterative programs using loops.Concept of subprograms. Coding style: choice of names,

indentation, documentation, etc. [8 hrs]

UNIT II: Arrays: Array representation, Operations on array elements, using arrays, multidimensional arrays.

Structures& Unions: Declaration and usage of structures and Unions.

Pointers: Pointer and address arithmetic, pointer operations and declarations, using pointers as function

argument,

File: Declaration of files, different types of files. File input/output and usage. [8 hrs]

UNIT III: Object Oriented Programming: Functional and data decomposition, Characteristics of Object-

Oriented Languages: Abstraction, Encapsulation, Information hiding, abstract data types,

Classes and Objects: Concept of Object & classes, attributes, methods, C++ class declaration, private

and public memberships, Constructors and destructors, instantiation of objects. Introduction to Class

inheritance and operator overloading. [10 hrs]

UNIT IV: Files: Streams and files, error handling, over view of Standard Template Library.

[2 hrs]


1. Problem Solving and Program Design in C by Jeri R. Hanly, Elliot B. Koffman; Pearson

Addison-Wesley, 2006.

2. A Structured Programming Approach Using C by Behrouz A.Forouzan, Richard F. Gilberg;

Thomson Computer Science- Third Edition [India Edition], 2007.

3. C++: The Complete Reference by Schildt Herbert; Wiley DreamTech, 2005.

4. Object Oriented Programming using C++ E. Balagurusamy, TMH. R. Lafore; BPB

Publications, 2004.

5. Object Oriented Programming with C++ by D . Parasons; BPB Publication, 1999.

6. The Art of Programming Computer Science with C++ Steven C. Lawlor; Vikas Publication,

2002.

22

Course Curriculum B.TECH. I- Year, II- Semester Examination

Practical Paper- I, (Common to all Branches)


L T P Credits

0 0 3 03

ME 117 Engineering Graphics

General: Importance, Significance and scope of engineering drawing Lettering, Dimensioning, Scales,

Sense of Proportioning, Different types of Projections, B.I.S. Specification, line symbols, rules of

printing.

Projections of Points and Lines: Introduction of planes of projection, Reference and auxiliary planes, projections of points and

lines in different quadrants, traces, inclinations, and true lengths of the lines, projections on auxiliary

planes, shortest distance, intersecting and non-intersecting lines.

Planes Other than the Reference Planes: Introduction of other planes (perpendicular and oblique), their traces, inclinations etc.,

projections of points lines in the planes, conversion of oblique plane into auxiliary plane and solution

of related problems.

Projections of Plane Figures: Different cases of plane figure (of different shapes) making different angles with one or both

reference planes and lines lying in the plane figures making different given angles (with one or both

reference planes). Obtaining true shape of the plane figure by projection.

Projection of Solids: Simple cases when solid is placed in different positions, Axis, faces and lines lying in the faces

of the solid making given angles.

Isometric and Orthographic:

First and Third angle of system of projection sketching of Orthographic views from pictorial

views and vice versa principles and type of sectioning.

Development of Surface

Suggested Readings:

1. Engineering Graphics by Narayana, K.L. and Kannaiah, P.; Tata McGraw Hill, New

Delhi

2. Elementary Engineering Drawing by Bhatt N.D.; Charotar Book Stall, Anand

3. Engineering Graphics by Lakshminarayaan, V. and Vaish Wanar, R.S.; Jain Brothers, New

Delhi

4. Engineering Graphics by Chandra, A.M. and Chandra Satish; Narosa

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23


Practical Paper II (Common to all Branches)


COE 118 Programming Lab

Laboratory Practical Based on course work corresponding COE-116

L T P Credits

0 0 2 02

Course Curriculum B.TECH.I year, II Semester Examination Practical

Paper III (Common to all Branches)


EP 119 Applied Physics Lab

Laboratory Practical Based on course work corresponding EP-119

L T P Credits

0 0 2 02


Practical Paper IV (Common to all Branches)


PE 120 Mechanical Workshop L T P Credits

0 0 3 03

Fitting shops: Introduction to various fitting tools- fabrication methods & job work assigned by workshop

superintendent.

Welding shops: Introduction to welding shop-welding principles & classifications, arc welding processes &

related tools/equipments.

Foundry Shops: Introduction to molding sands, molding tools-pattern making, miscellaneous work.

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24

Course Curriculum

B.TECH. (EP) II-Year, III-Semester

Theory Paper I

EP201 Introduction to computing

L T P Credits

3 1 0 04

UNIT I

Introduction to Matlab: Advantages and disadvantages, Matlab environment: Command window, Figure window, Edit

window, Variables and Arrays: Initializing variables in Matlab, Multidimensional arrays, Subarrays.

UNIT II

Special values, Displaying output data, Data file, Scalar and array operations, Hierarchy of operations, Built-in-Matlab

functions, Introduction to plotting: 2D and 3D plotting. Branching Statement and Program design: Introduction to top-

Down design Technique, Use of pseudo code, Relational and logical operators, Branches, additional plotting features

of Matlab

UNIT III

Loops: The while loop, for loop, details of loops operations, break and continue statement, nesting loops, Logical

arrays and vectorization, User Defined Functions: Introduction to Matlab functions.

UNIT IV

Variable passing in Matlab, Optional arguments, Sharing data using global memory, preserving data between calls to a

function, function functions, Subfunction and private function.

UNIT V

Complex Data and Character Data: Complex data, String functions, Multidimensional arrays, Additional 2D plots,

three dimensional plots. Input/Output Function: Textread function, load and save commands.

UNIT VI

An introduction to Matlab file processing, file opening and closing, Binary I/O functions, Formatted I/O functions,

comparing binary and formatted functions, file positioning and Status functions, Numerical methods and developing

the skills of writing the program.


1. Stephen J. Chapman, MATLAB Programming for Engineers, CL-Engineering; 4 edition (November 8, 2007)

2. Rudra Pratap, Getting Started with MATLAB: A Quick Introduction for Scientists and Engineers, Oxford

University Press, USA (November 16, 2009)

3. Duane C. Hanselman, Mastering MATLAB 7, Prentice Hall; 1 edition (November 1, 2004)

4. Stormy Attaway, Matlab: A Practical Introduction to Programming and Problem Solving, Butterworth-

Heinemann; 1 edition (February 16, 2009)

5. Amos Gilat, MATLAB: An Introduction with Applications, Wiley; 3 edition (January 2, 2008

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25

Theory Paper II

EP202 Mathematical Physics

L T P Credits

3 1 0 04 UNIT I:

Review of Vector Analysis: Scalar and vector fields, Differentiations, divergence and curl, Integrations,

Applications of Greens, Gausss and stokes theorem, Equation of continuity and its applications.

UNIT II:

Tensors: Definition- Contravariant and Covariant tensors-Dummy suffix notation-Addition, substraction,

Contraction, inner product, outer product, Quotient law, symmetric and anti-symmetric tensors-application of

tensor theory to strain, thermal expansion, piezo-electricity and converse piezo-electric effect

UNIT III:

Complex Variables: Introduction, Functions of complex variables, limit, continuity, Analytic function,

Cauchy-Reimann equations, Harmonic function, Singular points and classification, Cauchy theorem, Cauchys

integral formula, Taylors and Laurents series, Residues, Calculations of residues, Residue theorem-evaluation

of definite integrals.

UNIT IV:

Partial Differentiatial Equations: Laplace equation Method of separation of variables- Solution of Laplace

Equation in two dimensions- Application of Laplace equation to two dimensional steady state of heat flow in a

thin rectangular plate- Dalemberts solution of vibrating string-application to the vibration of a rectangular

membrane.

UNIT V:

Numerical analysis: Introduction to Numerical analysis, Forward and backward differences, Relation between

the operators, Concept of Interpolation and Extrapolation

UNIT VI:

Numerical analysis: Newton-Gregory formula for forward and backward interpolation, Solution of ordinary

differential equations of first order using Runge-Kutta Method


1. M. R. Spiegel, Vector Analysis, Schaums outline series Tata McGraw Hill

2. Harry Lass, Vector and Tensor analysis, International Student edition, McGraw-Hill

3. I.S. Sokolnikof, Tensor Analysis, John Wiley & Sons, Inc.

4. Physical properties of crystals, J.F. Nye, Schaums outline series, Oxford University Press

5. M. J. Ablowitz, A.S. Fokas, Complex variables, Cambridge University Press, First South Asian

paperback edition.

6. J.W. Brown and R.V. Churchill, Complex variable and applications, 6th ed., McGraw Hill International

7. Erwin Kreyszig, Advanced Engineering Mathematics, New Age International (p) Limited.

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26

Theory Paper III

EP 203 Thermal Physics L T P Credits

3 1 0 04

UNIT I

Thermal equilibrium, zeroth law and concepts of temperature. First law and its

consequences, reversible, irreversible and quasi-static processes. Path Dependence

and Heat capacities,

UNIT II

Calculations of Work and heat; Isothermal, adiabatic, Isobaric, Isochoric, Enthalpy.

Second law: heat engines, basic inequality, Extension to Non-Isolated systems,

Carnots cycle, concept of entropy and its statistical interpretation, thermodynamic

potentials, Maxwell's relations.

UNIT III

Gibbs free energy, Helmholtz free energy.Chemical equilibrium, stability, elements

of chemical thermodynamics. Thermodynamic functions, Clausius-Clapeyron

equation..

UNIT IV

Maxwell-Boltzmanns molecular speed distribution and heat capacities, Canonical

ensemble: Boltzmanns factor, partition function

UNIT V

Phase transition: Joule Kelvin effect, first order and continuous transitions, critical

exponents, applications to magnetism, super fluidity and superconductivity

UNIT VI

Chemical potentials; grand canonical ensembles; gas-liquid phase transition, photon

gas: Black body radiation.


1. M.W. Zemansky and R. H. Dittman, Heat and Thermodynamics (7th ed.),

McGraw Hill

2. H. B. Callen, Thermodynamics and an Introduction to Thermostatistics (2nd

ed.), John Wiley

3. ter Haar and H. Wergeland, Elements of Thermodynamics, Addison- Wesley

4. H. E. Stanley, Phase Transition and Critical Phenomenon, Cambridge

University Press

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Theory Paper IV

EP-204: Digital Electronics

L T P Credits

3 1 0 04 UNIT I Minimization Techniques: Boolean postulates and laws De-Morgans Theorem-Principle

of Duality - Boolean expression - Minimization of Boolean expressions Minterm

Maxterm - Sum of Products (SOP) Product of Sums (POS) Karnaugh map Minimization

Dont care conditions, Implementation of Logic Functions using gates, NANDNAND and

NOR-NOR implementations. BCD and XS3 Addition, Gray Codes, 1s complement and 2s

complement subtraction.

UNIT II Introduction to the circuits for Arithmetic UNIT: Design procedure Half adder Full Adder

Half subtractor Full subtractor - Parallel binary Adder/Subtractor Serial

Adder/Subtractor - BCD adder 2s complement adder/subtractor, Multiplexer,

Demultiplexer, Decoder, Encoder, Latches, Flip-flops - SR, JK, D, T, and Master-Slave

Characteristic table and equation Edge triggering Level Triggering Realization of one

flip flop using other flip flops. Registers shift registers - Bidirectional shift registers, serial

and parallel configurations.

UNIT III Shift register counters Ring counter, Johnson counter, Asynchronous Ripple or serial

counter Asynchronous Up/Down counter - Synchronous counters Synchronous Up/Down

counters Programmable counters

UNIT IV Design of Synchronous counters: state diagram- State table State minimization State

assignment - Excitation table and Circuit implementation - Modulon counter, Non-

Sequential Counter Design using JK, D and T-design. Introduction to VHDL-Behavioural

Modeling, Dataflow Modeling, Structural Modeling, Application in Digital System Designs.

UN IT V

Digital to analog converter: Binary Weighted Resistors, Analog to digital converter-Successive

Approximation Method, Logic gates, DTL, TTL, ECL, I2L, CMOS Gates and their

parameters and comparisons.

UNIT V I Classification of memories ROM - ROM organization - PROM EPROM EEPROM

EAPROM, RAM RAM organization Write operation Read operation, memory

expansion Static RAM Cell-Bipolar RAM cell MOSFET RAM cell Dynamic RAM cell

Text Books/Reference Books 1. Thomas L. Floyd , Digital Fundamentals, Pearson Education Asia (1994)

2. Digital Integrated Electronics by H.Taub & D. Schilling(TMH).

3. Digital Principles and Application by Malvino & Leach (TMH).

4. Digital Electronics And Logic Design by M.Mano (EPI)

5. Switching And Finite Automata Theory by Z. Kohavi (TMH).

6. Modern Digital Electronics by R. P. Jain (TMH).

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Theory Paper V

EP 205 : Engineering Mechanics L T P Credits

3 1 0 04

UNIT I

Rigid body static: Equivalent force system. Equations of equilibrium, Free body

diagram, Reaction, Static indeterminacy and partial constraints, Two and three force

systems.

UNIT II

Structures: 2D truss, Method of joints, Method of section. Frame, Beam, types of loading

and supports, Shear Force and Bending Moment diagram, relation among load-shear

force-bending moment.

UNIT III

Friction: Dry friction (static and kinematics), wedge friction, disk friction (thrust

bearing), belt friction, square threaded screw, journal bearings (Axle friction), Wheel

friction, Rolling resistance.

UNIT IV

Center of Gravity and Moment of Inertia: First and second moment of area and mass,

radius of gyration, parallel axis theorem, product of inertia, rotation of axes and principal

M. I., Thin plates, M.I. by direct method (integration), composite bodies.Virtual work

and Energy method: Virtual Displacement, principle of virtual work, mechanical

efficiency, work of a force/couple (springs etc.), Potential Energy and equilibrium,

stability.

UNIT V

Kinematics of Particles: Rectilinear motion, curvilinear motion rectangular, normal

tangential, polar, cylindrical, spherical (coordinates), relative and constrained motion,

space curvilinear motion.

UNIT VI

Kinetics of Rigid Bodies: Translation, fixed axis rotation, general planner motion, work-

energy, power, potential energy, impulse-momentum and associated conservation

principles, euler equations of motion and its application.


1. I. H. Shames, Engineering Mechanics: Statics and dynamics, 4th Ed, EPI, 2002.

2. P. Beer and E. R. Johnston, Vector Mechanics for Engineers, Vol I - Statics, Vol II

3. Dynamics, 3rd Ed, Tata McGraw Hill, 2000.

4. R. C. Hibbler, Engineering Mechanics, Vol I and II, Pearson Press, 2002.

5. Andy ruina and Rudra Pratap, Introduction to Statics and Dynamics

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Theory Paper VI

EP 206 : Basic Engineering Economics

L T P Credits

3 0 0 03

Syllabus shall be provided by Humanities Department

I

30

B.TECH. (EP) II-Year, III-Semester Practical Papers

EP 207: Thermal Physics Lab

L T P

0 0 2

Laboratory experiments will be set in consonance with the material covered in introduction to

thermal physics course

EP 208: Digital Electronics Lab

L T P

0 0 2

Laboratory experiments will be set in consonance with the material covered in digital electronics

course

EP 209: Computing Lab

L T P

0 0 2

Laboratory experiments will be set in consonance with the material covered in introduction to

computing course

EP 210 Self Study/cum Seminar

L T P

0 1 0

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31

Course Curriculum

B.TECH. (EP) II-Year, IV-Semester

Theory Paper I

EP 211 Classical Mechanics and Quantum Mechanics

L T P Credits

3 1 0 4

Classical Mechanics

UNIT I

Basic Principles of classical dynamics: Central forces: Definition and properties, The equations

of motion, the equivalent one dimensional problem and classification of orbits.

UNIT II

Constraints of motion : Generalised coordinates : Hamiltons variational principle: DAlmbert

Principle : The Lagrangian function,Lagranges equations of motion: derivation and

applications , Conservation theorems

UNIT III

The Hamiltonian (H), Hamiltons Canonical equations of motion, Physical Significance of H,

Cyclic coordinates Derivation of Hamiltons equations from a variational principle,

Applications of Hamiltons equations of motion

Quantum Mechanics UNIT IV

Review of Schrdinger equation. Simple potential problems- peneteration of a potential barrier,

Bra and ket notations, Angular momentum algebra

UNIT V

Approximation techniques in quantum mechanics : Variational Method, Applications of

variation method (i) Ground state of hydrogen atom and (ii) helium atom.

UNIT VI

Wentzel Kramers Brillouin (WKB) approximation, Principle of WKB

approximation, connection formulae for penetration of barrier.

Application of WKB Approximation method (i) Transmission through a barrier (ii)

Theory of alpha decay.

Time dependent perturbation theory, perturbation theory for non degenerate case,

stark effect of the plane rotator


1. H. Goldstein, Classical Mechanics, Addison Wesley, 2nd ed.

2. S. Gasiorowicz, Quantum Physics, John Wiley , Asia

3. P.W. Mathews and K. Venkatesan, A textbook of Quantum Mechanics, Tata

McGraw Hill

4. Schwabl, Quantum Mechanics, Narosa

5. L.I. Schiff, Quantum Mechanics, McGraw Hill

6. Merzbacher, Quantum Mechanics,John Wiley , Asia

7. B.H. bransden and C. J. joachain,Introduction to Quantum Mechanics, Longman

ParthPencil

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Theory Paper II

EP 212 Optics L T P Credits

3 1 0 04

UNIT I

Wave nature of light, Coherence: Spatial and temporal coherence, spectral resolution of a finite wave

train, Optical Beats, Coherence time and line width via fourier analysis, Fourier transform

spectroscopy.

UNIT II

Theory of interference and interferometers: Interference of two monochromatic waves, two beam

interference, multiple beam interference, fabry perot interferometer, chromatic resolving power,

Channeled spectra

UNIT III

Theory of diffraction: Introduction, The Huygens Fresnel principle, Kirchhoffs diffraction theory,

the integral theorem of Kirchhoff, Fraunhofer and Fresnel diffraction.

UNIT IV

Spatial frequency filtering, resolving power of prism and grating, diffraction patterns with sound and

microwaves.

UNIT V

Optics of crystals: the dielectric tensor of an anisotropic medium, the structure of a monochromatic

plane wave in an anisotropic medium, Optical properties of uniaxial and biaxial crystals.

UNIT VI

Measurements in crystal optics, Stress birefringence and form birefringence, Absorbing crystals,

Introduction to Lasers


1. G. B. Fowles, Introduction to Modern Optics, Holt Reinhart and Winston

2. A.Ghatak, Introduction to Optics, Tata McGraw Hill.

3. M. Born and E. Wolf, Principles of Optics, McMillan

4. S. C. Lipson and H. Lipson, Optical Physics, Cambridge University Press

ParthPencil

ParthPencil

ParthPencil

ParthPencil

ParthHighlight

ParthHighlight

ParthHighlight

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Theory Paper III

EP 213 Signals and Systems

L T P Credits

3 1 0 04

UNIT I Basic signal in continuous and discrete form, linearity, causality, stability, linear time-invariant (LTI)

systems, convolution integral for continuous-time systems, convolution sum for discrete time systems,

properties of linear time-invariant systems, system described by differential and difference equations.

UNIT II Fourier series representation of periodic signals: Representation of periodic signals

by trigonometric and exponential series, properties of continuous time Fourier series, discrete time Fourier

series and its properties, continuous and discrete time filtering.

UNIT III Continuous time Fourier transform: Definition of Fourier transform and its inverse, properties of the transform, common transform pairs, convolution and multiplication theorems.

Discrete time Fourier transform: Definition and properties, Convolution theorem, frequency response

corresponding to difference equations.

UNIT IV

Laplace Transform: Definition, region of convergence, properties, analysis of LTI systems, solution of differential equations, system functions, poles and zeros, stability.

UNIT V Z Transform: definition, region of convergence, inversion, basic properties, solution of difference

equations, system functions, poles and zeros and stability.

UNIT VI Discrete Fourier transform: Properties of discrete Fourier transform, relation between discrete Fourier

transform, Z and Laplace transform. Convolution of sequences, circular convolution theorem, overlap

add and overlap save methods of convolution.

Sampling: Uniform sampling, sampling theorem, aliasing, decimation, interpolation.


1. Signals & Systems by Oppenheim, Willsky and Nawab.

2. Signal & systems by Simon Haykins; PHI

3. Fundamentals of Signal & Systems using the Web and Matlab, By Kamen : Pearson

4. Digital Signal Processing, by Proakis : Pearson.

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Theory Paper IV

EP-214- Microprocessors and Interfacing

L T P Credit

3 0 0 03

UNIT I : Basic Concepts of Microprocessors, Introduction to 8086 Microprocessor, its internal

architecture, Concept of address, data and control buses, 8086 hardware specifications: pin-outs and

the pin-functions, Real Mode Memory Addressing, Introduction to protected mode memory

addressing, Memory Address Space Organization, Minimum and Maximum mode.

UNIT II : Programming model of 8086-general purpose registers, special purpose registers and

segment registers. Physical address generation, data addressing modes, program memory addressing

modes, stack memory addressing modes, data transfer instructions, arithmetic and logic instructions,

flag control instructions, program control instructions, Input/Output instructions, Bus Cycle Timing

Diagrams.

UNIT III : Types of Interrupts, interrupt instructions, hardware interrupt interface, software

interrupts, NMI interrupt.

UNIT IV

Programmable Interrupt Controller 8259, Programmable Peripheral Interface (PPI) - 8255,

Programmable Direct Memory Access (DMA) Controller - 8237/8257, Programmable Interval Timer

- 8253.

UNIT V : Introduction to PIC Microcontrollers, PIC microcontroller overview and features, PIC

16F877: ALU, CPU registers, pin diagram, PIC reset actions, PIC oscillator connections, PIC memory

organization, PIC 16F877 instructions, Addressing modes, I/O ports.

UNIT VI

Interfacing applications of Microcontroller-interfacing of 7 segment display, LCD interfacing, ADC

and DAC interfacing.

Texts/References :

1. Y. Liu and G. A. Gibson, Microcomputer Systems: The 8086/8088 Family, 2nd Ed., Prentice Hall

of India.

2. Douglas Hall, Microprocessors Interfacing, Tata McGraw Hill.

3. Barry B. Brey, The Intel Microprocessors, 7th Ed., Prentice Hall of India.

4. Walter A. Treibel and Avtar Singh, The 8088 and 8086 Microprocessors, Prentice Hall of India.

5. Rafiquzzaman, Microprocessors, Prentice Hall of India.

6. A.K.Ray, K.M.Bhurchandi, Advanced Microprocessors and Peripherals (Second edition), TMH.

7. Microcontroller and Embedded systems- M.A.Mazadi, J.G.Mazadi & R.D.McKinlay - Pearson

PHI.

8. Embedded Design with Microcontrollers by Martin Bate

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Theory Paper V

EP 215 Computational Methods

L T P Credits

3 1 0 04 UNIT I Errors in numerical calculations: Introduction, Number and their accuracy, Errors and their

analysis, Absolute, Relative, Percentage and Maximum probable error, Physical significance

of errors, General error formula, Error in series approximation, Interpolation: Introduction,

Errors in polynomial Interpolation, Finite differences, Detection of errors by use of

difference tables, Differences of a polynomial, Newtons formulae for interpolation, Central

difference interpolation formulae, Practical interpolation, Divided differences and their

property, Inverse interpolation, Double Interpolation.

UNIT II

Solution of numerical algebraic and transcendental equation: Roots of equations, Direct

method and iteration method, Bisection method, Regula Falsi Method or Method of False

position, Secant or Chord method, Newton-Raphson method, Solution of simultaneous linear

algebraic equation: Gauss-elimination method, Gauss-Jordon elimination method, Power

method, Jacobi method for finding eigen values, Rotation Matrix, Method of

triangularization, Relaxation Method

UNIT III Curve fitting: Introduction, Least square curve fitting procedures, fitting a straight line,

nonlinear curve fitting, curve fitting by a sum of exponentials, Data fitting with cubic

splines, governing equations and end condition, errors in the cubic Spline derivatives, error

analysis of the cubic Spline, Approximation of function, Chebyshev polynomials,

Economization of power series

UNIT IV

Numerical Differentiation and Integration: Cubic Spline method, maximum and minimum

values of a tabulated data, Numerical integration, trapezoidal method, Simpsons 1/3-rule,

Simpsons 3/8-rule, Booles and Weddles Rule, Romberg integration, Newton-cotes

integration formulae, Euler-Maclaurin formula, Gaussian integration, Numerical double

integration

UNIT V Numerical solution of ordinary differential equations: Introduction, solution by Taylors

series, Picards method of successive approximation methods, Eulers method, modified

Eulers method, Runge-Kutta method, predictor-corrector method, Cubic Spline method,

Boundary value problem.

UNIT VI Numerical solution of partial differential equation: Introduction, Finite difference

approximations to derivatives, Laplaces equation, Jacobis method, Iterative method for

solution of equation.


1. Steven C. Chapra and Raymond P Canale, Numerical Methods for Engineers,

McGraw New York

2. T.R. McCalla, Introduction to Numerical Methods and Fortran Programming, John

Wiley, N.Y.

3. William Press et al, Numerical Recipes in Fortran/C, Cambridge University Press

4. Tao Pang, An Introduction to Computational Physics, Cambridge University Press

5. S.E. Koonin, Computational Physics, Benjamin

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36

Theory Paper VI

EP 216 Condensed Matter Physics

L T P Credits

3 1 0 04

UNIT I

Introduction to crystal physics, Symmetry operations; Bravais lattices; Point and Space groups; Miller

indices and reciprocal lattice; Brillouin zones; Defects in crystals; Point and line defects. Interplanar

spacing, Ionic bonding, Bond dissociation energy, Calculation of lattice energy of ionic crystals,

Madelung constant of ionic crystals, Covalent, Metallic and Intermolecular bonds; X-ray diffraction;

UNIT II

Lattice vibration and thermal properties: Einstein and Debye models; continuous solid; linear lattice;

acoustic and optical modes; dispersion relation; attenuation; density of states; phonons and

quantization; thermal conductivity of metals and insulators.

UNIT III

Free electron theory of metals; Electronic motion in a one and three dimensional potential well; Fermi

energy, total energy, Density of states, Wave equation in a periodic potential and Bloch theorem;

Kronig-Penny model; band theory; Distinction between metal, semiconductor and insulators; band

gap.

UNIT IV

Dielectrics: Polarization mechanism and types, dielectric constant, Polarizability, Clausius Mossoti

equation, Behaviour of polarization under impulse, Dielectric loss, ferroelectric and piezoelectric

materials, application of dielectric materials.

UNIT V

agnetism: concept of magnetism, classification of dia-, para-, ferro-, antiferro magnetism and

ferrimagnetism (Ferrites), Hysteresis, Hard and Soft magnetic materials, magnetic storage and

surfaces, Application of magnetic materials, GMR.

UNIT VI

Superconductivity: Introduction and historical developments; Meissner effect and its contradiction to

the Maxwells equation; Critical parameters; Thermal properties, energy gap, Isotope effect, London

equations, Penetration depth, Coherence length; BCS theory; Cooper pair, ground state, Josephson

effect and tunnelling, Applications of superconductors.


1. H. P. Myers, Introduction to Solid State Physics, Viva books (1998).

2. M. A. Omar, Elementary Solid State Physics, Addison-Wesley (1975).

3. C. Kittel, Introduction to Solid State Physics, John Wiley (1996).

4. A. J. Dekker, Solid State Physics, Macmillan (1986).

5. N. W. Ashcroft and N. D. Mermin, Solid State Physics, HBC Publ. (1976).

6. S. O. Pillai, Soild State Physics, New Age International publication.

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B.TECH. (EP) II-Year, IV-Semester Practical Papers

EP 217 Optics Lab

L T P

0 0 2

Laboratory experiments will be set in consonance with the material covered in optics course

EP 218 Microprocessor & Interfacing Lab

L T P

0 0 2

Laboratory experiments will be set in consonance with the material covered in microprocessor

course

EP 219 Solid State Physics Lab

L T P

0 0 1

Laboratory experiments will be set in consonance with the material covered in optics course

EP 220 Self Study/cum Seminar

L T P

0 1 0

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38

Course Curriculum

B.TECH. (EP) III-Year, V-Semester

Theory Paper I

EP301 Atomic and Molecular Physics L T P Credits

3 1 0 04 UNIT I

Bohr-Sommerfeld theory of Hydrogen Atom, Quantum mechanics of Hydrogen atom: Angular momentum &

parity, Magnetic dipole moments, Electron spin and vector atom model, Spin orbit Interaction: Hydrogen fine

structure, identical particles & Paulis principle.

UNIT II

Helium Atom & its spectrum, Multielectron atoms; Hartrees field: Atomic ground states & periodic table,

Spectroscopic terms: L-S & j-j couplings, spectra of alkali elements, spectra of alkaline earth elements, The

Zeeman effect, The stark effect, Hyperfine structure of spectral lines, The Breadth of Spectral lines, X-ray

spectra.

UNIT III

Rotational spectroscopy:Rigid rotor, Rotational spectra of diatomic Molecules, Rotation levels of polyatomic

molecules: spherical, symmetric, and asymmetric tops. Angular momentum couplings Hunds cases

UNIT IV

Vibrational spectroscopy: Vibration of diatomic molecules. Harmonic and anharmonic oscillator, Vibrational-

rotational couplings,Vibration of polyatomic molecules, Solvent effects on vibration spectra.

UNIT V

Electronic spectroscopy of molecules: Electronic absorption specta of diatomic molecules. Molecular orbital

and term, symbols, Dissociation and pre-dissociation in the spectra of diatomics.

UNIT VI

Electronic absorption spectra of polyatomic molecules, fluorescence. Raman spectroscopy. Solvent effects.


1. Molecular Spectra and Molecular Structure by G. Herzberg

2. B. H. Bransden and C. J. Joachain, Physics of Atoms and Molecules, Pearson Education

3. H. Haken and H. C. Wolf, The Physics of Atoms and Quanta, Springer

4. E. U. Condon and G. H. Shortley, The Theory of Atomic Spectra, Cambridge

5. J. M. Blatt and V. F. Weisskopf, Theoretical Nuclear Physics, John Wiley

6. H. E. White, Introduction to Atomic Spectra, McGraw-Hill

I

39

Theory Paper II

EP 302 Communication Systems L T P Credits

3 1 0 04 UNIT I

Introduction: Block diagram of an electronic communication system, electromagnetic spectrum-band

designations and applications, need for modulation.Concept of Noise: External noise, internal noise, signal to

noise ratio, noise factor, noise temperature, Friss formula.

UNIT II

Amplitude modulation: modulation index, frequency spectrum, generation of AM (balanced modulator),

Amplitude Demodulation (diode detector), Other forms of AM: Double side band suppressed carrier, DSBSC

generation (balanced modulator), Single side band suppressed carrier, SSBSC generation (filter method), SSB

detection, Introduction to other forms of AM (Pilot Carrier Modulation, Vestigial Side Band modulation).

UNIT III

Angle modulation: Frequency and Phase modulation, modulation index and frequency spectrum, equivalence

between FM and PM, Generation of FM (direct methods), FM detector (slope detector, PLL). .

UNIT IV

Pulse Analog Modulation: Sampling theorem, Errors in Sampling. Pulse Amplitude Modulation (PAM), Time

Division Multiplexing (TDM). Pulse Width Modulation (PWM) and Pulse Position Modulation (PPM).

Generation and detection of PAM, PWM, PPM.

UNIT V

Pulse Code Modulation: Need for digital transmission, Quantizing, Uniform and Non-uniform Quantization,

Quantization Noise, Companding, Coding, Decoding, Regeneration, Transmission noise and Bit Error Rate.

Differential Pulse Code Modulation, Delta Modulation, Adaptive Delta Modulation.

UNIT VI

Digital Carrier Modulation Techniques: Information capacity, Bit Rate, Baud Rate and M-ary coding.

Amplitude Shift Keying (ASK), Frequency Shift Keying (FSK), Phase Shift Keying (PSK), Binary Phase Shift

Keying (BPSK) and Quadrature Phase Shift Keying (QPSK). QPSK, Amplitude modulation, bandwidth

efficiency, carrier recovery squaring loop, Costas loop, DPSK.


1. Electronic Communications: Modulation and Transmission by Robert J. Schoenbeck, Prentice Hall of

India

2. Electronic Communications by D.Roddy and J.Coolen, Pearson Education

3. Electronic Communications by Kennedy, Pearson Education

4. Digital and Analog Communication Systems by L.W.Couch, Pearson Education

5. Communication Systems by Haykins, Prentice Hall of India

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40

Theory Paper III

EP 303: Electromagnetic theory, Antennas and Propagation L T P Credits

3 1 0 04 UNIT I

Transmission lines: transmission line equation in time and frequency domain, losses and dispersion, reflection

from an unknown load; quarter wavelength, single stub and double stub matching; Smith Chart and its

applications. distortion distortion less transmission line The telephone cable Inductance loading of

telephone cables.Input impedance of lossless lines reflection on a line not terminated by Zo - Transfer

impedance reflection factor and reflection loss.

UNIT II

Maxwells equations, constitutive relations, wave equation, plane wave functions, rectangular waveguide,

circular waveguide, dielectric slab waveguide, surface guided waves. Characteristics of TM and TE Modes,

Impossibility of TEM waves in waveguides, Wave impedances, characteristic impedance, Excitation of modes,

Cutoff wavelength and phase velocity.

UNIT III:

Introduction to Antennas, Antenna parameters: Radiation intensity. Directive gain. Directivity. Power gain.

Beam Width. Band Width. Gain and radiation resistance of current element, radiation from simple dipole and

aperture, horn antenna, microstrip antenna, parabolic disc antenna.

UNIT IV

Concept of antenna arrays, end fire and broadside arrays, Expression for electric field from two and three

element arrays. Uniform linear array. Method of pattern multiplication. Binomial array. Use of method of

images for antennas above ground.

UNIT V

Basic types of propagation; ground wave, space wave and sky wave propagation.

Sky wave propagation: Structure of the ionosphere. Effective dielectric constant of ionized region. Mechanism

of refraction. Refractive index. Critical frequency. Skip distance. Maximum usable frequency. Fading and

Diversity reception.

UNIT VI

Space wave propagation: Reflection from ground for vertically and horizontally polarized waves. Reflection

characteristics of earth. Resultant of direct and reflected ray at the receiver. Duct propagation. Ground wave

propagation: Attenuation characteristics for ground wave propagation. Calculation of field strength at a

distance.


1. Advanced Engineering and Electromagnetics By C.A.Balanis.

2. Antennas and Wave Propagation by J.D.Kraus, R.J.Marhefka and A.S.Khan

3. Electromagnetics for Engineers by S.E.Schwarz

4. Introduction to Electrodynamics by David J.Griffiths

5. Electromagnetic Waves and Radiating Systems by E.C. Jordan & K.G. Balmain

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41

Theory Paper IV

EP 304 Semiconductor Devices

L T P Credits

3 1 0 04 UNIT I

Introduction to the Quantum theory of solids: Allowed and forbidden Energy bands, Electrical conduction in

solids, density of state function, Semiconductor in Equilibrium: Equilibrium carrier concentration, Intrinsic

semiconductor, Extrinsic semiconductor, Position of Fermi energy level.

UNIT II

Carrier transport phenomenon: Random motion, Drift and diffusion, Graded Impurity distribution, Excess

carriers: Injection level, Lifetime, Direct and indirect semiconductors, P-N Junction: Device structure and

fabrication, Equilibrium picture, DC forward and reverse characteristics, Small-signal equivalent circuit,

Generation Recombination currents, Junction Breakdown, Tunnel diode

UNIT III

Bipolar Junction Transistor: History, Device structures and fabrication, Transistor action and amplification, low

frequency, common- base current gain, Small-signal Equivalent circuit.

UNIT IV

Ebers-Moll model MOS Junction: C-V characteristics, threshold voltage, body effect Metal Oxide Field Effect

Transistor: History, Device structures and fabrication, Common source DC characteristics

UNIT V

Small-signal equivalent circuit, Differences between a MOSFET and a BJT Junction FET and MESFET: Basic

pn JEFT & MESFET operation, Device characteristics.

UNIT VI

Recent Developments: Hetero-junction FET, Hetro-junction bipolar transistor Optical Devices: Solar Cells,

Photodectectors, LEDs


1. Physics of Semiconductor Devices by Ben G. Streetman

2. Physics of Semiconductor Devices by M.Shur

3. Semiconductor Devices by Kittel

4. Integrated Electronics by Millman and Helkias

I

42

Theory Paper V

EP 305 Biophysics L T P Credits

3 1 0 04

UNIT I

Background of membrane biophysics, Basic structure and composition of membrane, Donnan equilibrium,

GHK, Ion transport system overview.

UNIT II

Whole cell behavior: cardiac, Integration: from channels to whole cell, Whole cell behavior: currents,

gating, kinetics, control, Measurement approaches, Automaticity and pacemakers, Excitation-contraction

coupling (cardiac and neuro), Cardiac EC coupling, structure and function, NMJ

UNIT III

Ion channel structure and gating function, Common elements organized to make specific function, Protein

structure, pore formation, charge field, Control of channel function, voltage activation, ligand activation,

signaling, gating kinetics.

UNIT IV

Ion selectivity, Ion channel types and characterization, Channel types, structure, function, Same channels in

different cell types, Molecular biology in ion channels, Sample channelopathies

UNIT V

Modeling and simulation of channels, Stochastic processes, State transition mechanics and modeling,

Examples of disease modeling, Whole cell behavior: neuron, Integration, Propagation, saltatory conduction,

Neuron synapse, synaptic plasticity, Structure of the synapse, Electrochemical transduction, Postsynaptic

integration and information processing.

UNIT VI

Modeling and simulation of whole cell EP, Review of HH formalism; modern extensions, Mathematical

formulation, numerical implementation, examples of software, Strengths and limitations of simulation,

Cardiac cell-to-cell communication, Gap junction structure, function


1. Biophysics: An Introduction by Roland Glaser

2. Molecular and Cellular Biophysics by Meyer B. Jackson

3. Introductory Biophysics: Perspectives on the Living State by J.R. Claycomb and Jonathan Quoc P.

Tran

4. Quantitative Understanding of Biosystems: An Introduction to Biophysics by Thomas M.

Nordlund

I

43

B.TECH. (EP) III-Year, V-Semester Practical Papers

EP 306 Advanced Physics Lab

L T P

0 0 2

Laboratory experiments will be set in consonance with the material covered in theory courses 1

and 4.

EP 307 Electromagnetic theory, Antenna and Propagation Lab

Laboratory experiments will be set in consonance with the material covered in Electromagnetic Antennas and Propagation course

L T P

0 0 2

EP 308 Communication Systems Lab

L T P

0 0 2 Laboratory experiments will be set in consonance with the material covered in communication

systems course

EP 309 Minor Project -I

L T P

0 0 4

I

44

Course Curriculum

B.TECH. (EP) III-Year, VI-Semester

Theory Paper I EP 311 Instrumentation and Control

L T P Credits

3 1 0 04 UNIT-I Instrumentation: Transducers, classification & selection of transducers, strain gauges, inductive

& capacitive transducers, piezoelectric and Hall-effect transducers, thermisters, thermocouples,

photo-diodes & photo-transistors, encoder type digital transducers, signal conditioning and

telemetry, basic concepts of smart sensors and application.

UNIT II

Control System:Linear, Non Linear, Time Varying and Linear Time Invariant System,

Servomechanism, Historical Development of Automatic Control and Introduction to Digital

Computer Control, Mathematical Models of Physical Systems, Differential Equations of Physical

Systems, Transfer Functions, Block Diagram Algebra and Signal Flow Graphs.

UNIT III Feedback and Non-feedback Systems Reduction of Parameter Variations By Use of Feedback Control

Over System Dynamics By Use of Feedback Control of Effects of Disturbance Single By Use of Feedback

and Regenerative Feedback.

UNIT IV

Time and frequency response Analysis: Standard test signals, Time response of First order Systems,

Time Response of Second-Order Systems, Steady-State Error and Error Constants, Effect of Adding a Zero

to a System, P, PI and PID Control Action and Their Effect.

UNIT V

Design Specifications of Second-Order Systems and Performance Indices.Correlation Between Time and

Frequency Response, Polar Plots, Bode Plots, and All Pass and Minimum-Phase Systems.

UNIT V

The Concept of Stability, Necessary Conditions for Stability, Hurwitz Stability Criterion, Routh Stability

Criterion and relative Stability Analysis. The Root Locus Concept, Construction of Root Loci, Root

Contours.

UNIT VI

Systems with Transportation Lag, Sensitivity of the Roots of the Characteristic equation,

Mathematical Preliminaries, Nyquist Stability Criterion, Definition of Gain Margin and Phase Margin,

Assessment of Relative Stability Using Nyquist Criterion and Closed-Loop Frequency Response.

Text Books/Reference Books 1. Modern Electronic Instrumentation and Measurement Techniques by Helfrick and Cooper; Prentice- Hall

of India, Reprint1988.

2. Electrical Measurement and Measuring Instruments by Golding, E.W., 3rd Edition; Sir Issac Pitman and

Sons, 1960.

3. Control Systems Engineering by Nagrath & Gopal; New Age International. Publishers

4. Instrumentation Measurement and Feedback by Jones, B.TECH.; Tata McGraw-Hill, 1986.

5. Modern Control Engineering by Ogata

6. Linear Control Systems by Scheultz & Melsa.

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45

Theory Paper II

EP 312 Fiber optics and optical communication

L T P Credits

3 1 0 04

UNIT I

Introduction to vector nature of light, propagation of light, propagation of light in a cylindrical dielectric rod,

Ray model, wave model. Different types of optical fibers, Modal analysis of a step index fiber..

UNIT II

Signal degradation on optical fiber due to dispersion and attenuation, Pulse dispersion in graded index optical

fibers, Material dispersion.

UNIT III

Propagation characteristics of step index fiber, Propagation characteristics of graded index fibers, Waveguide

dispersion and design considerations

UNIT IV

Fabrication of fibers and measurement techniques like OTDR. Optical sources - LEDs and Lasers, Photo-

detectors - pin-detectors, detector responsivity, noise, optical receivers.

UNIT V

dtu ep syllabus.pdf

Documents

semester engineering

h th3 ep

applied physics lab

semester iv examination

semester v examination

c total

c pr2 ep

c th5 ep