Spring 2013

NATIONAL INSTITUTE OF TECHNOLOGY MEGHALAYA

List of Spring Semester Courses

SPRING SEMESTER 2013

B. Tech I 2nd Semester

Sr. No. Subject Code Scheme Credit

1 Engg. Mathematics-II ASM 201 3-1-0 04

2 Engg. Physics ASP 202 3-0-2 04

3 Engg. Chemistry ASC 203 3-0-2 04

4 Engg. Mechanics AMD 204 3-0-2 04

5 Engg. Drawing CIME 205 2-0-4 04

6 Basic of Civil & Environmental Engg. CICH 206 4-0-2 05

Total 18-1-12=31 25

B. Tech. II (CSE) Fourth Semester (4th)

Sr. No.

Course Code L-T-P Credit

L

1. CS-1: Theoretical Computer Science CO202 3-1-0 4

2. CS-2: Computer Organization CO204 3-1-2 5

3.CS-3: Principles of Programming

LanguagesCO206 3-0-2 4

4.IS-1: Communication Systems

EC208 3-1-2 5

5.IS-2: Engineering Mathematics-III

MH210 3-1-0 4

Total 25 22

B. Tech. II (EEE) Fourth Semester (4th)

Sr. No.


L

1. Applied Thermodynamics & Thermal Engineering

ME 212 3-0-0 3

2. Digital Circuits EC212 3-0-2 4

3. Network and Systems EE 202 4-1-0 5

4. Electrical Machines-II

EE 204 3-1-2 5

5. Computer Applications for

Electrical Engineering EE 206 3-1-2 5

Total 25 22

http://svnit.ac.in/deptt/coed/coed_curr/co202.html

http://svnit.ac.in/deptt/coed/coed_curr/mh210.html



http://svnit.ac.in/deptt/coed/coed_curr/ec208.html








B. Tech. II (ECE) Fourth Semester (4th)

Sr. No.


L

1. Electronic Circuits EC 202 3-1-2 5

2. Microprocessors EC 204 3-1-2 5

3. Principles of Communication EC 206 3-1-2 5

4. Electrical Technology

EE 208 3-0-2 4

5. Control Systems

EE 216 3-0-0 3

Total 25 22

B. Tech. III (CSE) Sixth Semester (6th)

Sr. No.


L

1. Operating Systems CO 302 3-1-2 5

2. Unix Programming CO 304 3-1-2 5

3. System Software CO 306 3-1-2 5

4. IS-I: Economics and Business

ManagementMH 308 3-0-0 3

5. EIS-II - 3-0-0 3

Total 24 21

B. Tech. III (ECE) Sixth Semester (6th)

Sr. No.


L

1. Data Communication and Networks EC 302 4-0-2 5

2. Digital Integrated Circuits EC 304 3-0-2 4

3. Embedded Systems EC 306 3-1-2 5

4. Fiber Optic Communication

EE 308 4-0-2 5

5. EIS-II

- 3-0-0 3

Total 26 22

B. Tech. III (EEE) Sixth Semester (6th)

Sr. No.


L

1. Microcontroller and Embedded System EE 302 3-1-2 5

2. Communication System EC 326 3-1-2 5





http://www.svnit.ac.in/deptt/coed/coed_curr/3rdyear.php





3. Power Electronic Converters EE 306 3-1-2 5

4. Measurement and Instrumentation EE 332 3-1-2 5

5.EIS-II

- 3-0-0 3

Total 27 23

ELECTIVE INTERDISCIPLINARY SUBJECTS (EIS-II)EE 314 Industrial Automation and Process ControlEE 316 State Variable AnalysisEE 318 Energy Audit and ManagementEE 322 Power System Planning and ManagementEE 324 Power Quality Issues and Remedial MeasuresCO312 Wireless NetworksCO314 Parallel Processing and ArchitectureEC 312 NanotechnologyEC 314 Multimedia Communication TechnologyEC 316 Image Processing & Computer VisionEC 318 Process InstrumentationEC 322 MEMSEC 326 Scientific Computing




SyllabusASP 202 Engineering Physics CH: 3-0-2 CR: 4

WAVE OPTICS: Interference : Introduction to waves, Coherence (Spatial and Temporal), Principle of Superposition,

Visibility of the fringes, principles of production of coherent sources, YDSE, Interference due to thin parallel films and anti reflecting coatings, Interference due to wedge shaped film and colors of the films, Newton’s rings, fringes of equal thickness and fringes of equal inclination.

Diffraction: Fresnel and Fraunhofer diffracting, Fraunhofer diffraction due to double slits, Fraunhofer diffraction due to circular aperture and Rayleigh criterion of image resolution, Introduction to Electron Microscopes, Diffraction grating and its usages.

Polarization: Introduction, Malus’ law, Polarization by reflection and Brewster’s law, Polarization in Anisotropic materials and birefringence, Production of elliptically polarized light and plane polarized light, Quarter wave plate and Half wave plate, Analysis and detection of state of polarization of unknown light, polarization by scattering and blue of sky.

LASER PHYSICS: Introduction Lasers, Mechanisms of production of Laser viz., Spontaneous and Stimulated emissions,

Generation of metastable states, Population Inversion, Amplification, etc., Einstein’s coefficients, Different kinds of lasers and their working, latest developments in Laser Physics.

ELECTROMAGNETISM: Amperes theorem and its applications to determine magnetic induction (B) in case of (i) a straight

conductor carrying current, (ii) Solenoid and (iii) Toroid. Lorentz force, Hall effect in metals. High Energy particle accelerators. Gauss’s law for magnetism, Types of matter magnetism, Diamagnetism, Paramagnetism,

Ferromagnetism, Nuclear Magnetism, three magnetic vectors.

MODERN PHYSICS: Sources of light, cavity radiators, spectrum power distribution, Wien’s Rayleigh, Jean’s and Plank’s

laws, Dual nature of matter and radiation, photoelectric effect, Einstein’s photoelectric equation, compton’s scattering, De Broglies waves, wave and group velocity, uncertainly principle.

X-rays, X-ray diffractions and Bragg’s law, Quantum physics of hydrogen atom, Bohr’s postulates and applications in explanation of hydrogen spectrum, Bohr’s correspondence principle, Frank and Hertz experiment.

LIST OF PRACTICALS:(1) To study He-Ne Laser (Demo)(2) To study the adjustment of a Spectrometer and to measure the angle of a Prism.(3) To study the variation of Magnetic filled of circular coil carrying current.(4) To verify Malus’ law of plane polarized light.(5) To find wavelength of emission lines of mercury source using plane transmission grating.(6) Determination Planck’s constant (h) by Photovoltaic Cell.(7) To find radius of curvature of a convexlense/wavelength of monochromatic light by Newton’s Rings

method.(8) Verification of Stefan’s fourth power law of Black body radiation.

References :1. Resnick and Haliday, Physics Part-I and II, Wiley Eastern publication.2. A. Beiser, Concept of the Modern Physics, Wiley Eastern.3. A. Ghatak, Introduction to Modern Optics, TMG Pbbl.4. D.N. Vasudeva, Electricity and Magnetism, S. Chand & Co.5. S. Tolansky, Atomic Physics, Orient Publications.

ASC 203 Engineering Chemistry CH: 3-0-2 CR: 4

1. Water: Raw water Treatment-Filtration, Coagulation, Hard water, Estimation and Calculation of Hardness, Scales and Sludge, Internal and External treatment methods, Boiler feed water, Caustic Embrittlement, Municipal water and its Sterilization, Desalination methods.

2. Pollution: Two methods Air sampling, effect of the air pollutants and their permissible limits, Global warming, Green house effects, Ozone hole, Smog, El Nino effect, Cottrell electrostatic precipitator and Cyclone collector, effects of the water pollutants and their permissible limits, COD, BOD, and DO, Primary and Secondary waste water treatments.

3. Polymers: Biopolymers, Elastomers, Number and Weight Average Molecular Weight and calculation, Structures and uses of Polystyrene, Teflon, PMMA, Nylon, Vulcanization of rubber, Moulding methods, Copolymers and their importance.

4. Introduction: Biomolecules, Nanomaterials, Fullerenes, Super conductors, Brass Alloys, Dyes (Vat & Acid), Drugs (Antimalarial, Antibiotics & Vitamic-C), Composites (RCC & Plywood).

5. Instrumental methods: Theoretical & Experimental : pH-metry, Potentiometry, Conducometry, Colorimetry. Introduction to Chromatography.

6. Corrosion: Galvanic Series, Electrochemical Theory, Galvanic Corrosion; Crevice Corrosion & Pitting Corrosion and its Control, General Methods of Corrosion Control.

7. New Approach in Chemistry: Introduction to Electrochemical Cells, Introduction to Non-Conventional Sources of energy and Basics of Green Chemistry.

References :

1. Engg. Chemistry (15th Ed.), P.C. Jain & M. Jain, Dhanpat Rai Publication Co. New Delhi.2. A Text Book of Engg. Chemistry (Latest Ed.), S.S. Dara, S. Chand & Co. Ltd. New Delhi (2004)3. Engg. Chemistry (Latest Ed.) by Gopalan R, Vikas Publishing House Pvt. Ltd.4. Engg. Chemistry (Latest Ed.), B.K. Sharma, Krishna Prakashan Media (P) Ltd., Meerut.5. Corrosion Engineering (Latest Ed.), Fontana M.G. Mc. Graw Hill Book Co. Inc. New Delhi.

LIST OF EXPERIMENTS

(1) Potentionmetric Redox Titration of Fe2+ by Standard Ce4+

(2) pH metric Titration of Acidic water by standard Base(3) Complexometric determination of Hardness of water(4) Iodometric determination of Cu in Brass

(5) Titrimetric determination of Ascorbic acid (Vitamin-C)(6) Estimation of COD of wastewater(7) Determination of DO in wastewater(8) Viscometric determination of Molecular Weight of water soluble Polymer(9) Demonstration of Electrodepostion(10)Demonstration of Co as a pollutant by Spectrophotometer

AMD 204 Engineering Mechanics CH: 3-0-2 CR: 4

THEORY:1. Introduction, Force, Praticle, Rigid Body, Systems of Forces.2. Coplanar Concurrent Forces, Determination of Resultant, Equilibrium, Equilibrant, Forces in Space

and their equilibrium.3. Coplanar Non-concurrent Force Systems, Moments about Points & Axes. Equilibrium, Non-coplanar

Non-concurrent Forces.4. Determination of Reaction of Beams for Points Loads, Uniformly distributed Loads and Uniformly

Varying Loads.5. Centroids and Moment of Inertia.6. Method of Joints and Method of Sections of Truss Analysis.7. Friction, Wedge, Ladder and Belt Friction.8. Work Energy Principle, D’Alembert’s Principle, Impulse momentum, Impact of Elastic Bodies.9. Vibrations, Equation of Motion of Single Degree of Freedom, Introduction to Free and Forced

Vibrations, Earthquake Induced Waves.

PRACTICALS:

Based on the theory course prescribed above.

References:

1. Bear F.P. and Johnston E.R., “Vector Mechanics for Engineers”, Tata McGraw-Hill In. Delhi.2. Desai J.A. and Mistry B.B., “Engineering Mechanics – Statics & Dynamics”, Popular Prakashan, Surat.3. Shah H.J. and Junarkar S.B., “Applied Mechanics”, Charotar Publication, Anand.4. Bhavikatti S.S. and Rajashekarappa K.G., “Engineering Mechanics”, Wiley Eastern Ltd.5. Hibbeler R.C., “Engineering Mechanics – Statics & Dynamics”, Macmillan Publication Co.

CIME 205 Engineering Drawing CH: 2-0-4 CR: 4

THEORY:

1. Introduction : Importance of Engineering Drawing, Drawing instruments and materials, B.I.S. and ISO conventions, lines lettering and dimensioning.

2. Plane Geometry : Geometrical Construction : line, arc and angle, divisions of straight line and circumference, construction of polygon, Scales : types of scales – plane scale, diagonal scale, vernier

scale, functional scale, concept of conversion scale and nomogram Conic Sections : Ellipse, conjugate diameters, parabola, hyperbola, rectangular hyperbola.

3. Orthographic Projection : Principle of first and third angle projection, projection of points, projection of straight lines, projection of planes.

4. Building Drawing : Building components and terminology, building plans, elevation & sections.5. Solid Geometry : Projection of solids : polyhedral, prisms, pyramids, cylinder, cone, auxiliary

projection method, one view, two view and three view drawings. Missing view, rules for selection of views.

6. Section of Solids : Sectional view, section plane perpendicular to the HP & VP and other various positions, true shape of sections.

7. Intersection : Classification, line of interaction, line/generator method and section plane method; intersection of two prisms, two cylinders, interaction of cone and cylinder.

8. Development of Surface : Method of development, parallel line development, radial line development, developments of cylinder, cone, prism, pyramid, true length of edges – oblique surface.

9. Isometric Projections : Terminology, isometric scale, isometric view and isometric projection, isometric axes and lines, missing view.

PRACTICAL: Based on above theory course.

References:

1. K.L. Gopal Krishna, “Engineering Drawing”, Subhas Publications, 1995.2. N.D. Bhatt, “Engineering Drawing”, Chrotar Publishing House, 1989.3. K. Venugopal, “Engineering Drawing made Easy” Wiley Eastern Ltd., 1993.4. M.L. Agrawal, R.K. Garg, “Engineering Drawing Vol-I”, Dhanpatrai & Co., 1997.

CICH 206 Basics of Civil & Environmental Engineering CH: 4-0-2 CR: 5

THEORY:1. Introduction to Civil Engineering, relation of Civil Engineering to other branches of Engineering.2. Principles of surveying, linear measurement, compass surveying, principles of leveling.3. Basic building materials, properties of building materials, different types of building materials like

stone, brick, cement, lime, mortar, cement concrete etc.4. Different building components, their types and construction techniques – foundation, masonary

(stone/brick), floors, roofs, staircase, doors/windows etc.5. Different types of road, bridges, dams etc.6. Importance of Environmental Engineering, component of environment and their interaction, man &

the biosphere, impact of development on environment, natural resources, environmental pollution (air, water, soil, noise).

PRACTICAL: Based on above theory course.

References:

1. G.S. Birdi, “Basic Civil Engineering”, Dhanpat Rai & Sons Publication (1994)2. Dr. J.N. Patel & Dr. M.B. Gohil, “Basic Civil Engineering”, Atul Prakashan, Ahmedabad, Gujarat

(1999).3. Shamnugam and Palaniswamy, “Basic Civil Engineering”, TMG Publication (1995).4. Basak, “Surveying & Leveling”, TMG Publication, (1994).5. S.C. Rangwala, “Engineering Materials”, Charotar Publishers, Anand, Gujarat (1999).6. Benny Joseph, “Environmental Studies”, Tata McGrow Hill Publication Co. Ltd., New Delhi (2005).7. Dr. Suresh K. Dhameja, “Environmental Studies”, S.K. Kataria & Sons, New Delhi (2006).

ASM 201 Engineering Mathematics-II CH: 3-1-0 CR: 4

Unit I: Differential Calculus: Partial differentiation, Euler’s theorem for homogeneous function, Modified Euler’s theorem, Taylor’s and Maclaurins series for two variables.

Unit II: Applications of Partial differentiation: Tangent plane and Normal line Error and Approximation, Jacobians with properties, Extreme values of function of two variables, Lagrange’s methods of undetermined multipliers.

Unit III: Differential Equation of higher order: Solution of homogenous equations, complementary functions, Particular Integrals, Linear differential equation with variable coefficient, Cauchy’s Euler and Legendre’s equation with variable coefficient, Method of variation of parameters, application to Engg. Problem (without proof).

Unit IV: Mathematical Models: Electrical network models, Detection of diabetes model and Bending beam models.

Unit V: Series solution and special functions : Regular point, Singular point, series solution of ODE of 2nd order with variable coefficient with special emphasis to differential equation of Legendre’s and Bessel’s for different cases of roots of indicial equations.

Unit VI: Laplace Transform: Laplace transform, Existance theorem, Laplace transform of derivatives and integrals, Inverse Laplace transform, Unit step function, Dirac–delta functions, Laplace transform of periodic functions, Convolutions theorem, Application to solve simple linear and simultaneous differential equations.

Reference Books:

1. E. Kreyszig, Advanced Engg. Mathematics, 8th Ed, John Wiley & Sons, New York.2. Jain and Iyenger, Advanced Engg. Mathematics, Narosa Publications, New Delhi.3. B.S. Grewal, Higher Engg. Mathematics, Khanna Publications, New Delhi.4. J.N. Kapur, Mathematical Models in Biology and Medicine, East West Press.5. F.B. Hilderbrand, Methods of Applied Mathematics, McGraw Hill, New York.

SEMESTER-IV

MH 210: ENGINEERING MATHEMATICS III (IS-III) 3 1 0 4

Calculus, Multiple Integrals (08 Hours)

Reorientation of concepts of integrals, Double and Triple integrals, evaluation techniques, change of order of Integration, change of variable, Application of double and triple integrals for evaluation of area, volume and mass.

Basic concepts of vector calculus (08 Hours)

Line Integrals, scalar and vector point function, differential operator, gradient, directionalDerivative, physical meaning of gradient, divergence, curl and Laplacian with their properties, Surface Integral, Volume integral, Green’s ,Gauss and Stoke’s theorem & application.

Fourier Series (06 Hours)

Definition, Fourier series with arbitrary period, in particular periodic function with period 2 . Fourier series of even and odd function, Half range Fourier series.

Fourier Integral & transform (06 Hours)

Fourier Integral theorem, Fourier sine and cosine integral complex form of integral, Inversion formula for Fourier transforms, Fourier transforms of the derivative of a function.

Partial differential equation (06 Hours)

Second order PDE of mathematical physics (Heat, wave and Laplace equation, one dimensional with standard boundary conditions, solution by separation of variable method using Fourier series,Solution by Separation of variables & transformation techniques.

Complex variables (10 Hours)

Basic mathematical concept, Analytic function, C – R equations, Harmonic functions, its applications, Linear transformation of complex domain, some special transformation, bilinear transformations, conformal mapping and its application, complex integration including contour Integration.

Tutorials will be based on the coverage of the above topics separately (14 Hours)

(Total Contact Time: 44 Hours + 14 Hours = 58 Hours)

BOOKS RECOMMENDED

1) Kreyszing E., “Advanced Engineering Mathematics”, John Wiley, Int. Student Ed, 1995.2) Wiley C. R., “Advanced Engineering Mathematics”, MGH Int. Student Ed, 1993.3) O’Neil Peter, “Advanced Egg. Mathematics”, Thompson, Singapore, Ind. Ed, 2002.4) Greenberg Michael D., “Advanced Engg. Mathematics”, Pearson, Singapore, Ind. Ed, 2007.5) Ramana B. V., “Higher Engg. Mathematics”, MGH Inc., New Delhi, 2007.

CO 202 THEORETICAL COMPUTER SCIENCE (CS-I) 3 1 0 4

Introduction (02 Hours)

Basic Mathematical Objects: Sets, Logic, Functions, Relations, Strings, Alphabets, Languages; Mathematical Induction: Inductive proofs, Principles; Recursive Definitions; Set Notation.

Finite Automata and Regular Expressions (12 Hours)

Finite State systems, Regular Languages & Regular Expressions, Deterministic Finite Automata; Nondeterministic Finite Automata, Kleene’ Theorem; Two-way Finite Automata, Finite Automata with output, Properties of Regular Sets: The Pumping Lemma for Regular sets, Closure properties, Decision properties of regular languages, Equivalence and minimization of Automata.

Context Free Grammars (14 Hours)

Definition, Derivation trees & Ambiguity, Inherent ambiguity, Parse tree, Application of CFG, Simplification of CFG, Normal form of CFG, Chomsky Normal form and Chomsky Hierarchy, Unrestricted grammars, Context-sensitive languages, Relations between classes of languages, Properties of Context Free Languages: The Pumping Lemma, Closure properties, Decision properties of CFL.

Pushdown Automata (04 Hours)

Definitions, Languages of PDA, Equivalence of PDA and CFG , Deterministic PDA

Turing Machines (06 Hours)

Turing Machine Model, Language of a Turing Machine, Programming techniques of the TM, Variations of TM (Multiple TM, One-tape and Multi-tape TM etc), Deterministic and Non deterministic TM, Universal TM, Churche thesis, Recursively Enumerable Languages.

Computational Complexity (04 Hours)

Time and Space Complexity, Growth Rate, Complexity classes, Tractable and Non tractable Problems: P and NP, Cooks’s theorem.



BOOKS RECOMMENDED

1). John E. Hopcroft, Rajeev Motwani, Jeffrey Ullman: “Introduction to Automata theory, languages computation “, 2/E, Pearson India, Last Indian, Reprint 2005.2). John C Martin : “Introduction to Languages & the Theory of Computation”, McGraw-Hill International ed, 20023). Daniel I A Cohen : “Introduction to Computer Theory”, John Wiley & Sons, 1990 Ed, Reprint 19944). A.M. : “Theory of computation”, New Age Publication, 1/E, 2003.5). Sushil Kumar Azad : “Theory of Computation, An introduction to /automata, Formal Languages And Computability”, Dhanpat Ray & Co., New Delhi, 2005.

CO204 : Computer Organization 3 1 2 5

CENTRAL PROCESSING UNIT (25 Hours)

Computer system and its sub modules, Number System and Representation of information, Arithmetic and Logical operation and hardware implementation, Software implementation of some complex operation. Arithmetic and Logic Unit, Introduction to memory Unit, control unit and Instruction Set , Working with an ALU, Concepts of Machine level programming, Assembly level programming and High level programming, Various addressing modes and designing of an Instruction set, Concepts of

subroutine and subroutine call, Use of stack for handling subroutine call and return, Introduction to CPU design, Instruction interpretation and execution.

Memory (06 Hours)

Concepts of semiconductor memory, CPU-memory interaction, organization of memory modules, Cache memory and related mapping and replacement policies, Virtual memory.

Input - Output (07 Hours)

Introduction to input/output processing, working with video display unit and keyboard and routine to control them, Programmed controlled I/O transfer, Interrupt controlled I/O transfer, DMA controller, Secondary storage and type of storage devices, Introduction to buses and connecting I/O, devices to CPU and memory.

Introduction to ASIC, FPGA, VHDL, HDL concepts (04 Hours)



PRACTICALS

1. Design and simulation of CPU.2. Simulation of Memory management techniques.3. Simulation of I/O device management4. Mini project based on CPU design using advanced tools.

BOOKS RECOMMENDED

John L. Hannessy, David A. Patterson, Computer organization and Design, 3/E, Morgan Kaufmaan Tanenbaum, Structured Computer Organization, PHI EEE Stallings, Computer Organization & Architecture: Designing For Performance, 4/E,PHI EEE Hamacher, Computer Organization, McGraw-Hill Morris Mano, Computer Systems Architecture, PHI

CO 206: PRINCIPLE OF PROGRAMMING LANGUAGES (CS-III) 3 1 2 5

Logic programming pardigms (14 Hours)

Introduction to Prolog, Prolog Programs Models, Types Of Logic, WFF, Symbolic Logic, Facts, Clauses, Predicates, Unification, Backtracking, Cut, Fail & Built-In Predicates, Recursion in Prolog, Arithmetic Operators & Relational Operators ,LIST Processing, String manipulation & Built-In Predicates, Compound objects, Dynamic Database.

Object oriented programming pardigms (15 Hours)

Introduction to Object Oriented Programming, Token, Expression & control Structure, Classes & Objects, Constructors & Destructors, Operator Overloading & Type Conversion, Inheritance, Pointers, Virtual Functions and Polymorphism, I/O Operations, Working With Files.

Language design issue and Implmentation (13 Hours)

Why Study Programming Language?, A History Of Programming Language, Role Of programming Language, Programming Environments ; Implicit and Explicit Sequence Control, Sequencing with Arithmetic Expressions, Sequence Control between Statements ; Subprogram Sequence Control Attributes of Control, Parameter Transmission ; Storage Management.



PRACTICALS

1) Implement Prolog Programs for Recursion, Arithmetic Operators & Relational Operator.

2) Implement Various Prolog Programs for LIST.

3) Prolog Program for String Manipulation.

4) Implement Various Programs of Compound objects.

5) Implement Prolog Program for Dynamic Database.

6) Implement C++ Program for Class & Object, Constructor & Destructor.

7) Implement C++ Programs for Operator Overloading, Inheritance, and Polymorphism, file Operation.

BOOKS RECOMMENDED

1) Bjarne Stroustrup, The C++ Programming Language, Addison-Wesley Professional

2) E Balagurusamy, Object Oriented Programming C++, Tata Mcgraw Hill.

3) Terrence W. Pratt, Programming Languages: Design and Implementation, Pearson Education.

4) Kenneth Louden, Programming Languages-Principles and Practices, Thomson.

5) I. Bratko, Prolog Programming for Artificial Intelligence, Addison-Wesley.

EC208: COMMUNICATION SYSTEM (IS-I) 3 1 2 5

Introduction (02 Hours)

History, Concept of Transmitter, Receiver, Channel, Noise, Modulation, need for modulation, Types of Modulation, Different communication systems based on Input and Output.

Amplitude Modulation (AM) (08 Hours)

AM, AM Index, Frequency spectrum, Average Power for Sinusoidal AM, Effective Voltage and Current, Non sinusoidal Modulation, DSBFC & DSBSC Modulation, Amplitude modulator and Demodulator Circuits, AM Transmitters.

Single-Sideband (SSB) Modulation (06 Hours)

SSB Principles, Balanced Modulators, SSB Generation and Reception.

Angle Modulation (06 Hours)

Frequency Modulation (FM), Frequency spectra, Average power, Deviation Ratio, Measurement of Modulation Index, Phase Modulations (PM), Sinusoidal PM, Digital PM, Angle Modulator Circuits, FM Transmitters, Angle Modulations Detectors.

Pulse Modulation (08 Hours)

Pulse Amplitude Modulation, Pulse Code Modulation, Delta Modulation, Pulse Frequency Modulation, Pulse Time Modulation, Pulse Position modulation and Pulse Width Modulation.

Digital Communication (06 Hours)

Introduction, Digital Carrier Systems ASK, FSK, QAM, BPSK, QPSK Transmitter and receiver block diagrams.

Fiber-Optic Communications (06 Hours)

Principles of Light Transmission in Fiber Losses in Fibers, Dispersion, Light Sources and Detectors for Fiber Optics.



PRACTICALS

1) AM modulation/demodulation2) SSB & DSBSC modulation3) FM modulation4) PAM,PTM,PPM5) PCM modulation6) Delta modulation7) ASK,FSK8) BPSK,QPSK

BOOKS RECOMMENED

1) Dennis Roddy & John Coolen: “Electronic Communications”, PHI, 4/E, 1995.2) George Kennedy : “Electronic Communication Systems”, 3/E, McGraw Hill Book Co., 1993.3) Simon Haykin : “Communication Systems”, 2/E, Wiley Eastern Ltd, 1994. 4) Taub and Schilling: “Principles of communication Systems”. Mc, Graw Hill Publication, 1992.5) B.P.Lathi :”Modern digital and analog communication systems”. Holt, Sounders Pub. 1998

B. Tech III (CSE) Semester-VI

CO 302: OPERATING SYSTEMS CH:3-1-2 CR: 5

INTRODUCTION & OVERVIEWOperating Systems Objectives - Formal Definition - Evolution - Types - DMA & OS - Multiprogramming - OS Interfaces - The Command-less command interpreter systems - Device drivers & unification of the concept of files & devices. Introduction to the examples of contemporary operating systems.

PROCESS MANAGEMENTThe process concept - Programs, Processes & Threads - Process Hierarchy - Process Management System Calls - CPU Scheduling & algorithms with examples - Evaluation - Concurrent processes - The critical Section problem - Algorithms for mutual exclusion - Semaphores, Critical Region,

Monitors, Messages. Examples of IPC in Contemporary Operating Systems - Classical Process Co-ordination Problems.

DEADLOCKSCharacterization - Prevention - Avoidance - Detection - Recovery - Combined Approach to Deadlock handling & Deadlock Handling in contemporary operating systems.

MEMORY MANAGEMENTOverview of Swapping - Multiple Partitions - Paging - Segmentation - Virtual Memory - Demand paging - Performance - Fragmentation & Compaction. Page replacement algorithms - Allocation algorithms - Memory Protection - Memory Management System Calls.

DEVICE MANAGEMENTTerminals & Capability Databases - Emulators - Virtual Terminals - Disk Devices - Device Independence - RAID devices - Device Driver Interface. Disk Drive Access Techniques - Free space management - Performance and Reliability improvements - Storage hierarchy.

FILE SYSTEMS: LEVELSFile Systems in Disk Partitions - File-naming & File Access - File Meta-data - Allocation strategies - Directory systems & their implementations - System Calls; Connecting File Systems to device drivers - File Systems Reliability - File protection - Implementation issues. Modern Operating Systems: Thread scheduling - Client Server architecture - Ordinary File Sharing vs. Network Operating Systems - Real-time systems - Comparative survey/study of architectures of contemporary Operating Systems - Introduction to Micro-kernel based operating system - The development towards a Distributed Operating system.

PRACTICALS:

1) Shell programming exercises (a) without using any of the filters (b) using filters like sed, awk, grep, find.

2) Implementation of the Classical Process Coordination & Synchronization Problems like Bounded Buffer Producer-Consumer, Readers-Writers etc using System V IPC constructs.

3) Implementation of the Classical Process Coordination & Synchronization Problems as above using Java’s concurrent programming support.

BOOKS RECOMMEDED:

1. Stallings: Operating Systems: Internals and Design Principles, 5/E, 2007, Pearson Prentice-Hall2. Silberschatz A & Galvin: Operating System Concepts, 7/E, 2004, John Wiley & Sons.

3. Andrew S Tanenbaum: Operating Systems - Design and Implementation, 3/E, 2006, PHI EEE.

4. Crawley: Operating Systems - An Object oriented Approach, 1998, McGraw Hill.

5. Kernighan & Pike: UNIX programming Environment, 2/E, 1995 reprint, PHI-EEE.

CO 304: UNIX PROGRAMMING (CS-II) CH:3-1-2 CR: 5

INTRODUCTION TO THE LINUX SYSTEMS Review of the basic concepts of Files & Directories , Logggin in, Input & Output ,Programs & Processes;

VARIOUS UNIX/LINUX STANDARDS AND IMPLEMENTATIONS

FILES, DIRECTORIES & I/O RELATED CONCEPTS AND SYSTEM CALLSInternal Structure & Representation of files in Linux – the Standard I/O Library – System Data files;

THE ENVIRONMENT OF A LINUX/UNIX PROCESS AND THE RELATED SYSTEM CALLS;

PROCESS CONTROL creation, termination, scheduling, changing the size of a process, invoking other programs, race conditions and the related system calls;

PROCESSING SCHEDULING & TIME RELATED SYSTEM CALLS IN LINUX/UNIX;

PROCESS RELATIONSHIPS Daemon processes, Interprocess Communication techniques viz pipes, FIFOs, semaphores, shared memory, sockets & the related system calls;

STREAMS AND I/O MULTIPLEXING AND THE RELATED SYSTEM CALLS.

INTRODUCTION TO THE LINUX/UNIX KERNEL.

PRACTICALS:1) Implement cat command. 2) Implement link, unlink, and rename, symlink, readlink system calls.3) Implement who command.4) Print all environment variables.5) Write a program that creates a zombie and verify that the process is zombie.6) Send a data from parent to child over a pipe.

BOOKS RECOMMEDED:

1. W Richard Stevens, Stephen A Rago; Advanced Programming in the UNIX Environment; 2/E, Addison Wesley Professional, 2005.

2. Kernighan & Pike: UNIX programming Environment, 2/E, 1995 reprint, PHI-EEE.

3. Marc J Rochkind; Advanced UNIX Programming, 2/E; Addison-Wesley Professional;2004

4. Eric S. Raymond; The Art of Unix Programming; Addison Wesley Professional, 2004

5. Terence Chan; UNIx Programming using C++; Prentice-Hall ECS Professional, 2004

CO306: SYSTEM SOFTWARE (CS-III) CH:3-1-2 CR: 5

COMPILER STRUCTUREAnalysis-synthesis model of compilation, various phases of a compiler, tool based approach to compiler construction.

LEXICAL ANALYSISInterface with input, parser and symbol table, token, lexeme and patterns, difficulties in lexical analysis, error reporting, and implementation. Regular definition, Transition diagrams, LEX.

SYNTAX ANALYSISContext free grammars, ambiguity, associativity, precedence, top down parsing, recursive descent parsing, transformation on the grammars, predictive parsing, Bottom up parsing, operator precedence grammars, LR parsers(SLR,LALR,LR),YACC.

INTERMEDIATE CODE GENERATIONIntermediate representations, Code generation and instruction selection: issues, basic blocks and flow graphs, register allocation, code generation, Code optimization, source of optimizations, optimization of basic blocks, loops, global dataflow analysis, solution to iterative dataflow equations.

PRACTICALS:1) Implement a symbol table routine to determine whether an identifier lexeme has previously seen

& store a new lexeme into symbol table2) Implement a lexical analyzer that reads the input one character at a time and returns to the parser

the token it has found. 3) Implement recursive descent, predictive, operator precedence & LR parsers.

BOOKS RECOMMEDED:1. John J. Donovan : System Programming. 2. D. M. Dhamdhere : System Software and Operating System. 3. Leland L. Black : System Software -An Introduction to System Programming, Addision Wesley.4. A.V. Aho, R. Sethi and J D. Ullman : Compilers-Principles, Techniques and Tools. Pearson

Education5. Louden , Kenneth C : Compiler Construction-Principles and Practice,1/e. Thomson

MH 308: ECONOMICS AND BUSINESS MANAGEMENT CH: 3-0-0 CR: 3

ECONOMICS:Introduction to Economics, Micro & Macro Economics, Applications & Scopes of Economics, Demand Analysis, Demand Forecasting, Factors of Production, Types of Cost, Market structures, Break Even Analysis, Concept of Supply, National Income

MANAGEMENT:Introduction to Management, Features of Management, Nature of Management, Development of Management thoughts – Scientific Management by Taylor & Contribution of Henry Fayol, Coordination & Functions of Management, Centralization & Decentralization, Decision Making

Fundamentals of Planning

Objectives & MBO

Types of Business organizations: Private Sector, Public Sector & Joint Sector

Organizational Behavior: Theories of Motivation, Individual & Group Behavior, Perception, Value, Attitude, Leadership

FUNCTIONAL MANAGEMENT:

Marketing Management: Core concepts of Marketing, Marketing Mix (4P), Segmentation – targeting – Positioning, Marketing Research, Marketing Information System, Concept of International Marketing, Difference between Domestic Marketing & International Marketing

Operations Management: Introduction to Operations Management, Types of Operation Systems, Types of Layouts, Material Handling, Purchasing & Store System, Inventory Management

Personnel Management: Roles & functions of Personnel Manager, Recruitment, Selection, Training, Industrial Dispute, Collective Bargaining

Financial Management: Goal of Financial Management, Key activities in Financial Management, Organization of Financial Management, Financial Institutions, Financial Instruments, Sources of Finance

MODERN MANAGEMENT ASPECTS:Introduction to ERP, e-CRM, SCM, Re-engineering, WTO, IPR etc.

OPERATIONS RESEARCH:Introduction to OR, Approaches, Applications & Scope of OR; Linear Programming: Basic concepts, formulation of LP Models, Limitations of LP, Graphical & Simplex methods, Assignment Problems, Transportation Problems – Initial Basic Solution; Decision Theory; Queuing System; Simulation

BOOKS RECOMMEDED:

1. L. M. Prasad, “Principles & Practices of Management”, Sultan Chand & Sons2. T.R. Banga & S.C. Shrama “Industrial Organization and Engineering Economics”, Khannna Pub.3. S. Robbins ,”Organizational Behavior”, PHI (Pearson).4. Philip Kotler,Keller, Koshi & Jha “Marketing Management”, A South Asian Perspective, Pearson.5. S.D. Sharma “Operations Research”, Kedar Nath Ram Nath & Company.

CO312: WIRELESS NETWORK (EIS-II) CH: 3-0-0 CR: 3

OVERVIEW OF WIRELESS TECHNOLOGIES AND COMMUNICATIONS STANDARDS

MEDIUM ACCESS CONTROL IN WIRELESS LANS, MULTIPLE ACCESS SCHEMES IN WIRELESS COMMUNICATIONS Time Division Multiple Access (TDMA), Frequency Division Multiple Access (FDMA), Code Division Multiple Access (CDMA),

WIRELESS ACCESS PROTOCOLS

CASE STUDIES OF 802.11, Hiperlan, Bluetooth, Performance analysis and quality of service, Single and multi-hop ad-hoc networks, Mobility Management in Wireless Network, Routing issues

CASE STUDIES OF Mobile IP, IPv6, DSR, AODV and other protocols, Transport issues: TCP adaptations for wireless and mobility, Research papers, Relevant RFCs, Standards

BOOKS RECOMMEDED:

1. M. S. Gast, O'Reilly, “802.11 wireless networks” 20022. J.Schiller, “Mobile Communications”, Addison Wesley, 2000

3. Charles Perkins, ”Adhoc Networks”, Addison Wesley, 2000 4. WCY Lee,” Mobile Cellular Telecommunications Systems”, 2/E,TMH, 2006 5. J. W. Mark and W. Zhuang, “Wireless Communications and Networking”, PHI, Reprint 2005

CO314 : PARALLEL PROCESSING AND ARCHITECTURE (EIS – II) CH: 3-0-0 CR: 3

PARALLEL COMPUTER MODELThe state of Computing, Multiprocessors and Multicomputers, Multivector and SIMD Computers, Architectural Development Tracks.

PROGRAM AND NETWORK PROPERTIESConditions of parallelism, Program Partitioning and scheduling, Program Flow Mechanism, System Interconnect Architecture.

PRINCIPLES OF SCALABLE PERFORMANCEPerformance Metrics and Measures, Parallel Processing Applications, Speedup Performance Laws, Scalability Analysis and Approaches.

PROCESSORS AND MEMORY HIERARCHYAdvanced Processor Technology, Superscalar and vector Processors, Memory Hierarchy Technology, Virtual Memory Technology.

MULTIPROCESSORS AND MULTICOMPUTERSMultiprocessor system Interconnects, Cache Coherence and synchronization, Message Passing Mechanism.

MULTIVECTOR AND SIMD COMPUTRSVector Processing Principles, Multivector Multiprocessors, Compound Vector Processing, SIMD Computer Organization, The Connection Machine CM-5.

SCALABLE, MULTITHREADED AND DATAFLOW ARCHITECTURELatency-Hiding Techniques, Principles Of Multithreading, Fine-Grain MultiComputers, Scalable and Multithreaded Architecture, dataflow and Hybrid Architectures.

MULTICORE PROGRAMMINGSingle-Core Processor Fundamentals, Introduction to Multi Core Architecture, System Overview of Threading, Fundamental Concepts of Parallel Programming, Threading and Parallel Programming.

BOOKS RECOMMEDED:

1. Kai Hwang, F. Briggs, “Computer Architecture and Parallel Processing”, McGraw Hill International Edition, Reprint 2006.

2. M. Flynn, “Computer Architecture: Pipelined and Parallel Processor Design”, 1/E, Jones and Bartlett, 1995

3. Harry F. Jordan, “ Fundamentals of Parallel Processing”, 1/E, 2002

4. Hesham El-Rewini and Mostsfa Abd-El-Barr, “Advanced Computer Architecture and Parallel Processing, Wiley-Interscience”, 2005.

5. Shameem Akhter & Jason Roberts, “Multi-Core Programming”, Intel Press, 2006.

B.Tech. (Electrical), Semester – IV

ME212: APPLIED THERMODYNAMICS AND THERMAL ENGINEERING L-3 T-0 P-0 CR-3

BASIC CONCEPTS OF THERMODYNAMICS (06 Hours)Basic concepts of thermodynamics, system & surroundings, Heat and Work, Reversible and Irreversible process.

FIRST LAW OF THERMODYNAMICS (07 Hours)The first law for a closed system undergoing a cycle and change of state, Internal energy, enthalpy, specific heat at constant volume and constant pressure. First law of thermodynamics for a control volume, Application of first law to boiler, turbines, compressors.

SECOND LAW OF THERMODYNAMICS (05 Hours)Heat engines and refrigerators, statements of second law of thermodynamics, and corollaries.

INTERNAL COMBUSTION ENGINES (06 Hours)Different types study of various systems like cooling, ignition, lubrication etc and numericals.

STEAM NOZZLE (05 Hours)Different types – condition for maximum discharge – effect of friction-numericals.

STEAM TURBINES & CONDENSER (07 Hours)Classification: - compounding – Rankin cycle- velocity triangles – blade efficiency, condition for maximum blade efficiency, Governing of turbine – losses in steam turbine – types of condenser – quantity of cooling water required for condenser & Condenser efficiency.

GAS TURBINE (04 Hours)Different types, working of open & closed type gas turbine Methods used for improving efficiency of turbine.

HEAT TRANSFER (05 Hours)Basic modes of Heat transfer, conduction in solids, thermal conductivity, Insulating materials, one dimensional steady state conduction problems, free and forced convection, laws of radiation.

Total Hours: 45

BOOKS RECOMMENDED:1. Wylen Van, Sonntag & Borgnakke, “Fundamentals of Classical thermodynamics” 6th ed. John Wiley &

Sons, New York 2003.2. CENGEL Yunus A. & BOLES MICHAEL A., “Thermodynamics” 4th Ed., Tata Mc Graw Hill, New Delhi,

20043. Gorden Rogers & Yon Mayhew “Engineering Thermodynamics” 4th Ed., ADDISON WESLEY, 2004.4. Simonson John, “Thermodynamics” 4th Ed., Mac Millan 1997.5. Rajput, “Thermal Engineering”, Laxmi Publication, Dariya Ganj, New Delhi, Edition 2005.

EC212: DIGITAL ELECTRONICS L-3 T-0 P-2 CR-4

NUMBER SYSTEMS AND CODES (05 Hours)Addition, Subtraction, Multiplication and Division using Different Number Systems; Representation of Binary Number in Sign-Magnitude, Sign 1's Complement and Sign 2's Complement Notation; Rules for Addition and Subtraction with Complement Reprsentation; BCD, EBCDIC, ASCII, Extended ASCII, Gray and other Codes.

BOOLEAN FUNCTION AND ITS MINIMIZATION (06 Hours)

Simplification of Boolean Function using Boolean theorems; Canonical and Standard Forms(SOP and POS) for Boolean Functions; Objectives of the Minimization Procedures; Karnaugh Map Method;Don't Care Conditions;

COMBINATIONAL LOGIC CIRCUITS USING DISCRETE LOGIC GATES (10 Hours)Half Adder and Full Adder; Half Subtractor and Full Subtractor; Parity Generator and Checker; CodeConverters; Carry look ahead generator; Binary Multiplier; Majority Circuits, Magnitude Comparator.

COMBINATIONAL LOGIC USING MSI CIRCUITS (10 Hours)Binary Parallel Adder; BCD Adder; Encoder, Priority Encoder, Decoder; Multiplexer and DemultiplexerCircuits; Programmable Logic Array (PLA) and Programmable Array Logic (PAL).

INTRODUCTION TO FLIP-FLOP CIRCUITS (06 Hours)Basic Concepts of Sequential Circuits; Cross Coupled SR Flip-Flop Using NAND or NOR Gates; D-Type and Toggle Flip-Flops JK Flip-Flop & race Condition; Clocked Flip-Flops; Master Slave Configuration; Edge triggered D flip-flop; Elimination of Switch Bounce Using Flip-Flops; Flip-Flops With Preset and Clear.

SEQUENTIAL LOGIC CIRCUIT DESIGN & COUNTERS (08 Hours)Sequential circuit; state table and state diagram; Design procedure; Basic Concepts of Counters andRegisters; Shift Left and Right Register; Registers With Parallel Load; Serial-In-Parallel-Out(SIPO) andParallel-In-Serial-Out(PISO); Register Using Different Type of Flip-Flops; Ripple(asynchronous) counters; Up Down and Mod-N ripple counters; Design of Synchronous Counter Using State Diagrams and State Table; BCD Counters; Modulo-N Counter; Up Down Counter; Ring counter; Johnson Counter, Sequence Generators

Total Hours: 45

Practical:1. Half-Adder/Half-Subtractor Circuit using a select input.2. Full -adder/Full-Subtractor circuit using a select input.3. 4-Bit Gray to Binary/Binary to Gray code converter using a select input.4. Logic expression with the help of MUX. IC 74153.5. Flip-flops using NAND/NOR gate.6. Modulo-7 ripple counter.7. 4-bit shift left/right register.8. Sequence generator.

BOOKS RECOMMENDED:1. Morris Mano, “Digital Logic And Computer Design”, Prentice Hall Of India, 2005.2. Jain and Anand : “Digital Electronics”, Practice Using Integrated Circuits, TMH, 20043. Charles Kime: “”Logic and Computer Design Fundamentals”, Pearson Education, 2004.4. Sandige Richard, “Modern Digital Design”, McGraw-Hill, 1990.

B.Tech. (Electrical), Semester – IVME 212: APPLIED THERMODYNAMICS AND THERMAL ENGINEERING 3-0-0 CR-3

BASIC CONCEPTS OF THERMODYNAMICS (06 Hours)Basic concepts of thermodynamics, system & surroundings, Heat and Work, Reversible and Irreversible process.

FIRST LAW OF THERMODYNAMICS (07 Hours)The first law for a closed system undergoing a cycle and change of state, Internal energy, enthalpy, specific heat at constant volume and constant pressure. First law of thermodynamics for a control volume, Application of first law to boiler, turbines, compressors.

SECOND LAW OF THERMODYNAMICS (05 Hours)Heat engines and refrigerators, statements of second law of thermodynamics, and corollaries.

INTERNAL COMBUSTION ENGINES (06 Hours)Different types study of various systems like cooling, ignition, lubrication etc and numericals.

STEAM NOZZLE (05 Hours)Different types – condition for maximum discharge – effect of friction-numericals.

STEAM TURBINES & CONDENSER (07 Hours)Classification: - compounding – Rankin cycle- velocity triangles – blade efficiency, condition for maximum blade efficiency, Governing of turbine – losses in steam turbine – types of condenser – quantity of cooling water required for condenser & Condenser efficiency.

GAS TURBINE (04 Hours)Different types, working of open & closed type gas turbine Methods used for improving efficiency of turbine.

HEAT TRANSFER (05 Hours)Basic modes of Heat transfer, conduction in solids, thermal conductivity, Insulating materials, one dimensional steady state conduction problems, free and forced convection, laws of radiation.

Total Hours: 45

BOOKS RECOMMENDED:1. Wylen Van, Sonntag & Borgnakke, “Fundamentals of Classical thermodynamics” 6th ed. John Wiley &

Sons, New York 2003.2. CENGEL Yunus A. & BOLES MICHAEL A., “Thermodynamics” 4th Ed., Tata Mc Graw Hill, New Delhi,

20043. Gorden Rogers & Yon Mayhew “Engineering Thermodynamics” 4th Ed., ADDISON WESLEY, 2004.4. Simonson John, “Thermodynamics” 4th Ed., Mac Millan 1997.5. Rajput, “Thermal Engineering”, Laxmi Publication, Dariya Ganj, New Delhi, Edition 2005.

EC 212: DIGITAL ELECTRONICS 3-0-2 CR-4

NUMBER SYSTEMS AND CODES (05 Hours)Addition, Subtraction, Multiplication and Division using Different Number Systems; Representation of Binary Number in Sign-Magnitude, Sign 1's Complement and Sign 2's Complement Notation; Rules for Addition and Subtraction with Complement Reprsentation; BCD, EBCDIC, ASCII, Extended ASCII, Gray and other Codes.

BOOLEAN FUNCTION AND ITS MINIMIZATION (06 Hours)Simplification of Boolean Function using Boolean theorems; Canonical and Standard Forms(SOP and POS) for Boolean Functions; Objectives of the Minimization Procedures; Karnaugh Map Method;Don't Care Conditions;

COMBINATIONAL LOGIC CIRCUITS USING DISCRETE LOGIC GATES (10 Hours)Half Adder and Full Adder; Half Subtractor and Full Subtractor; Parity Generator and Checker; CodeConverters; Carry look ahead generator; Binary Multiplier; Majority Circuits, Magnitude Comparator.

COMBINATIONAL LOGIC USING MSI CIRCUITS (10 Hours)Binary Parallel Adder; BCD Adder; Encoder, Priority Encoder, Decoder; Multiplexer and DemultiplexerCircuits; Programmable Logic Array (PLA) and Programmable Array Logic (PAL).

INTRODUCTION TO FLIP-FLOP CIRCUITS (06 Hours)Basic Concepts of Sequential Circuits; Cross Coupled SR Flip-Flop Using NAND or NOR Gates; D-Type and Toggle Flip-Flops JK Flip-Flop & race Condition; Clocked Flip-Flops; Master Slave Configuration; Edge triggered D flip-flop; Elimination of Switch Bounce Using Flip-Flops; Flip-Flops With Preset and Clear.

SEQUENTIAL LOGIC CIRCUIT DESIGN & COUNTERS (08 Hours)Sequential circuit; state table and state diagram; Design procedure; Basic Concepts of Counters andRegisters; Shift Left and Right Register; Registers With Parallel Load; Serial-In-Parallel-Out(SIPO) andParallel-In-Serial-Out(PISO); Register Using Different Type of Flip-Flops; Ripple(asynchronous) counters; Up Down and Mod-N ripple counters; Design of Synchronous Counter Using State Diagrams and State

Table; BCD Counters; Modulo-N Counter; Up Down Counter; Ring counter; Johnson Counter, Sequence Generators

Total Hours: 45

Practical:1. Half-Adder/Half-Subtractor Circuit using a select input.2. Full -adder/Full-Subtractor circuit using a select input.3. 4-Bit Gray to Binary/Binary to Gray code converter using a select input.4. Logic expression with the help of MUX. IC 74153.5. Flip-flops using NAND/NOR gate.6. Modulo-7 ripple counter.7. 4-bit shift left/right register.8. Sequence generator.

BOOKS RECOMMENDED:1. Morris Mano, “Digital Logic And Computer Design”, Prentice Hall Of India, 2005.2. Jain and Anand : “Digital Electronics”, Practice Using Integrated Circuits, TMH, 20043. Charles Kime: “”Logic and Computer Design Fundamentals”, Pearson Education, 2004.4. Sandige Richard, “Modern Digital Design”, McGraw-Hill, 1990.

EE 202: NETWORK AND SYSTEMS 4-1-0 CR-5

FOURIER SERIES AND TRANSFORM (11 Hours)Dirichlet’s conditions, Properties of Fourier series, Trigonometrical and complex exponential forms, thefrequency spectra of periodic wave forms, plot of discrete magnitude and phase spectrum, Steady state response to periodic signals, Fourier transforms and its properties, application of Fourier transforms.

NETWORK FUNCTIONS AND TWO PORT PARAMETERS (11 Hours)Poles and zeros of a function, physical and analytical concepts, terminals and terminal pairs, driving point immittances, transfer functions, restrictions on locations of poles and zeros in S-plane. time domain behaviour from pole zero locations in the S plane, procedure for finding network functions for general two terminal pair network, transfer immitances, two port and N-port networks, Ladder, Lattice, Pie, and Tee networks. Definitions, calculations and interrelationships of impedance, admittance, hybrid, and transmission line parameters for two port networks and their interrelations

ONE TERMINAL PAIR NETWORKS (03 Hours)Reactive networks and their properties, external and internal critical frequencies, separation property for reactive functions and its proof

TWO TERMINAL PAIR REACTIVE NETWORKS (FILTERS) (11 Hours)Ladder network and its decomposition into tee, pie, and L sections, image impedance, image transfer function and applications to LC networks, attenuation and phase shift in symmetrical Tee and Pie networks, constant K-filters, m-derived filters, composite filters, , lattice filters, Bartlett’s bisection theorem. Introduction to the active filters

SINUSOIDAL STEADY STATE ANALYSIS (08 Hours)Radian frequency and sinusoid, magnitude and phase of network functions, sinusoidal network functions in terms of poles and zeros, resonant circuits, bandwidth and circuit Q, asymptotic change of magnitude and phase of network functions in light of poles and zeros, polar plots and Bode plots of network functions, analysis and applications of symmetrical lattice network.

SIGNALS AND SYSTEMS (12 Hours)Continuous time and discrete time signals, periodic signals, even & odd signals, exponential and sinusoidal signals, Unit impulse and Unit step functions, Continuous time and Discrete time systems, Basic system properties, Discrete time LTI system, continuous time LTI system, properties of LTI systems, Causal LTI systems described by differential and Difference equations.

Total Hours: 56

BOOKS RECOMMENDED:1. Van Valkenburg M.E., Network Analysis, Prentice Hall, India.2. Oppenheimetal Alan, Signals & Systems, Prentice Hall India.3. Edminister Joseph A., Electrical circuits, Schaum’s outline series, McGraw hill.4. Hayt W. H., Kemmerly J. E, Durbin S. M., Engineering Circuit Analysis, Tata McGraw Hill.5. Wadhwa C.L., Network Analysis & Synthesis, New Age International.6. Chakarabati A. circuit theory (analysis &synthesis), Danpat Rai & Co.

EE 204: ELECTRICAL MACHINES-II 3-1-2 CR-5

DIRECT CURRENT MACHINES (09 Hours)Construction, armature windings, simple lap and wave windings, armature reaction, demagnetizing and cross magnetizing ampere-turns, compensating winding, commutation, commutation time and type, reactance voltage, inter-poles, ampere-turns for inter-poles, self and separate excitations, shunt, series and compound motors and generators, magnetization characteristics, performance characteristics of DC generators and motors.

STARTING, SPEED CONTROL AND BRAKING OF DC MACHINES (06 Hours)Starting problems, methods of starting, starters, methods of speed control, methods of braking.

ANALYSIS OF STEADY STATE PERFORMANCE OF DC MACHINE (03 Hours)Losses and efficiency calculations.

TESTING OF DC MACHINES (04 Hours)Swinburn’s test, Hopkinson’s test, separation of core losses, retardation test, series field test.

BRUSHLESS D.C. MACHINES (03 Hours)Construction, equivalent circuit, performance analysis.

SYNCHRONOUS MACHINES (20 Hours)Construction, cylindrical and salient pole type, basic principles, armature windings, distributed winding, full pitched windings, chording, EMF equation, distribution and pitch factors, excitation system, armature reaction, synchronous machine impedance, SCR, equivalent circuit, phasor diagram, voltage regulations, synchronous impedance method, MMF method, ZPF method, operating characteristics, ‘V’ and inverted ‘V’ curves, power angle characteristics, power flow equation for salient and non salient pole type synchronous machines, salient pole synchronous machine - two reaction model, phasor diagram, power angle characteristic, hunting, damper winding, parallel operation of alternators, starting methods of synchronous motors, synchronous condenser, synduction machines

Total Hours: 45

PRACTICALS:1. Speed control of dc shunt motor.2. Swinburn’s test3. Speed torque characteristic of a D. C. Shunt motor.4. D. C. Series motor, Speed -torque characteristic.5. External & Internal characteristics of D. C. separately excited and Shunt generator.6. Regulation of an alternator by synchronous impedance method7. 'V' and 'inverted v' curves of a synchronous motor.8. Regulation of an alternator By zero power factor method9. Synchronisation of an alternator with infinite busbar.10. Power factor improvement using synchronous motor.11. Hopkinson’s Test on DC machines.12. Retardation Test on DC shunt motor.

BOOKS RECOMMENDED:1. Clayton A. E., The performance and design of direct current machines, Pitman and sons, London.2. Say M. G., The performance and design of alternating current machines, CBS Publishers and

Distributors, Delhi.

3. Fitzgerald, Kingsley and Umans, Electric Machinery, TMH, New Delhi.4. Mukherjee and chakravorty, Electrical Machines, Dhanpat Rai Pub., New Delhi.5. Nagrath and Kothari, “Electric Machines”, TMH, New Delhi.6. P. S. Bimbhra, “Electrical Machinery”, Khanna Pub., Delhi.

EE 206: COMPUTER APPLICATIONS FOR ELECTRICAL ENGINEERING 3-1-2 CR-5

The topics given below shall be taught along with stress on computer programming in C language.

ERRORS (02 Hours)Errors in Numerical Computation, their types and estimation.

SOLUTION OF TRANSCENDENTAL AND POLYNOMIAL EQUATIONS (08 Hours)Bisection method, Secant Method, Newton Raphson method for Polynomial equation.

SOLUTION TO SYSTEM OF LINEAR ALGEBRAIC EQUATIONS (08 Hours)Gauss elimination method, Gauss Jordon Method, Gauss Seidal Iteration method.

INTERPOLATION (10 Hours)Linear interpolation and high order interpolation using Lagrange’s and Newton Interpolation methods, Finite difference operators and difference tables.

NUMERICAL INTEGRATION (06 Hours)Trapezoidal rule, Simpson’s 1/3 and 3/8 rules.

SOLUTION TO ORDINARY DIFFERENTIAL EQUATIONS (10 Hours)Taylor series, Euler’s method, Euler’s predictor corrector method, Runge Kutta method of Second and Fourth order.

Total Hours: 44

PRACTICALS:Practice Exercises based on above syllabus.

BOOKS RECOMMENDED:1. Shastri S. S., Introductory Methods of Numerical Analysis, Prentice Hall Ltd.2. Bajpai A. C., Numerical Methods for Engineers and Scientists, John Wiley.3. Salaria R. S., Numerical methods : A computer oriented approach, BPB Publications.4. Teukolsky, S. A., Vetterling, W. T. & Flannery, B. P., Numerical recipes in C, Foundation Books Pvt.

Ltd.5. Balagurusamy E., Numerical methods, Tata McGraw-Hill, New Delhi.

B.Tech. III (Electrical), Semester – VIEE 302: MICROCONTROLLERS AND EMBEDDED SYSTEMS 3-1-2 CR-5

REVIEW OF 8051 ARCHITECTURE (05 Hours)General purpose registers, on-chip RAM, timers-counters, special function registers, 8051 interrupt system, input/output ports and circuits

ADDITIONAL FEATURES OF 8051 ARCHITECTURE ( 08 Hours)UART, concept of SPI & I2C serial interface, programmable counter array (PCA), PWM signal generation, watchdog timers.

INTRODUCTION TO EMBEDDED ‘C’ PROGRAMMING ( 05 Hours)Variables and constants, storage classes, enumerations and definitions, I/O operations, control statements, functions, pointers and arrays, structure and unions, interrupt service routines.

INTERFACING AND PROGRAMMING OF 8051 WITH EXTERNAL HARDWARE ( 07 Hours)External memory, ADC and DAC, matrix keyboard, LCD, 7 segment display.

INTRODUCTION TO 32-BIT TO ARM PROCESSOR ARCHITECTURE (05 Hours)32-Bit Arm 7 and Cortex M-3 core, Harvard and Von-Neuman Architecture, AHB and Bus Matrix, Register Structure

INTRODUCTION TO EMBEDDED SYSTEMS ( 03 Hours)Embedded systems description, definition, design considerations & requirements, embedded processor selection & tradeoffs, embedded design life cycle, product specifications, hardware/software partitioning, Co-Design concept..

EMBEDDED SOFTWARE ARCHITECTURE ( 06 Hours)Concept of real time systems, concept of real-time task scheduling, scheduling methods, and introduction to real time operating systems (RTOS).

APPLICATIONS OF EMBEDDED SYSTEMS ( 05 Hours)Measurement of analog and electrical variables, control of electrical devices, user interface in embedded systems, data communication in embedded systems.

Total Hours:43

LIST OF EXPERIMENTS:1 Timer driven clock2 Study of External Hardware Interrupts3 Measurement of frequency of External waveform4 Parallel A/D & D/A Converter5 Study of high speed A/D Converter6 Study of Synchronous Serial Protocol ( I2C & SPI)7 Interfacing of Stepper Motor8 Interfacing of PMDC Motor9 Firing of Traic10 Measurement of Electrical Quantity.11 A Synchronous Serial Communication (UART)

REFERENCES:1. Kenneth J. Ayala, “The 8051 Microcontroller”, Penram International 3rd edition2. M. Mazidi and others, “The 8051 Microcontroller and Embedded Systems”, PRENTICE Hall Of India,

3rd Edition3. David Seal, “ARM Architecture Reference Manual”4. Trevor Martin, "The Insider's Guide To The Philips ARM7-Based Microcontrollers", Published by Hitex

(UK) Ltd., April 2005.5. Barnett & others, “Embedded C Programming and Microchip PIC”, Thomson Learning Inc, 1e.6. David E. Simon, “An Embedded Software Primer”, Addision Wesley Pearson Education, 1999.

B.Tech. III (Electrical & Electronics), Semester – VI L T P C

EC 326 : COMMUNICATION SYSTEMS 3 1 2 5

INTRODUCTION (02 Hours)

History, Concept of Transmitter, Receiver, Channel, Noise, Modulation, need for modulation, Types of Modulation, Different communication systems based on Input and Output.

AMPLITUDE MODULATION (AM) (08 Hours)AM, AM Index, Frequency spectrum, Average Power for Sinusoidal AM, Effective Voltage and Current, Non sinusoidal Modulation, DSBFC & DSBSC Modulation, Amplitude modulator and Demodulator Circuits, AM Transmitters.

SINGLE-SIDEBAND (SSB) MODULATION (06 Hours)SSB Principles, Balanced Modulators, SSB Generation and Reception.

ANGLE MODULATION (06 Hours)Frequency Modulation (FM), Frequency spectra, Average power, Deviation Ratio, Measurement of Modulation Index, Phase Modulations (PM), Sinusoidal PM, Digital PM, Angle Modulator Circuits, FM Transmitters, Angle Modulations Detectors.

PULSE MODULATION (08 Hours)Pulse Amplitude Modulation, Pulse Code Modulation, Delta Modulation, Pulse Frequency Modulation, Pulse Time Modulation, Pulse Position modulation and Pulse Width Modulation.

DIGITAL COMMUNICATION (06 Hours)Introduction, Digital Carrier Systems ASK, FSK, QAM, BPSK, QPSK Transmitter and receiver block diagrams.

FIBER-OPTIC COMMUNICATION (06 Hours)Principles of Light Transmission in Fiber Losses in Fibers, Dispersion, Light Sources and Detectors for Fiber Optics Tutorials will be based on the coverage of the above topics separately

Tutorial based on the above topics: 14 hrs

Lecture 42 Hour + Tutorial 14 Hour =Total Hours: 56

LIST OF EXPERIMENTS:

1. AM modulation/demodulation2. SSB & DSBSC modulation3. FM modulation4. PAM,PTM,PPM5. PCM modulation6. Delta modulation7. ASK,FSK8. BPSK,QPSK

REFERENCES:1. Dennis Roddy & John Coolen: “Electronic Communications”, PHI, 4/E, 1995.2. George Kennedy : “Electronic Communication Systems”, 3/E, McGraw Hill Book Co., 1993.

3. Simon Haykin : “Communication Systems”, 2/E, Wiley Eastern Ltd, 1994.

4. Taub and Schilling: “Principles of communication Systems”. Mc, Graw Hill Publication, 1992. B.P.Lathi :”Modern digital and analog communication systems”. Holt, Sounders Pub. 1998

EE 306: POWER ELECTRONIC CONVERTERS 3-1-2 CR-5

INTRODUCTION (06 Hours)Power Electronics Scope and Applications, Interdisciplinary Nature of Power Electronics, Types of power electronics circuits, Thyristor Characteristics, Two transistor analogy, Gate Characteristics, Methods of triggering and commutation, Ratings and protection of devices, Introduction to power electronic devices like Power BJT, MOSFET, GTO, IGBT, MCT etc.

PHASE CONTROLLED RECTIFIERS (12 Hours)Principle of phase control, half wave controlled rectifiers, half wave controlled rectifiers with R, R-L, R-L-E load, single phase full wave controlled converters, 2-pulse mid-point converters, 2-pulse half and fully controlled bridge converters with R, R-L, R-L-E load, Three phase converter system with diodes, 3 phase half and fully controlled bridge converters, triggering scheme, Effect of source impedance on the performance or the converters, Dual converters.

CHOPPERS (08 Hours)Basic principle of chopper operation, Control strategies – Duty Ration Control and Frequency Control, Types of idealized chopper circuits, Steady state time domain analysis of Type A choppers, Step up chopper.

INVERTERS (10 Hours)Forced commutated inverters, Single phase voltage source inverters, Half bridge inverters, full bridgeinverters, Steady state analysis, Voltage control in single phase inverters, 3-phase bridge inverters, Pulse width modulated inverters, Reduction of harmonics in Inverter.

AC VOLTAGE CONTROLLERS (08 Hours)Principle of AC Voltage Controllers – Integral Cycle Control and Phase Control, Types of AC voltage controllers, Analysis of 1-phase Integral Cycle Control AC controllers with R load, Analysis of 1-phase Phase Control AC controllers with R and R-L load.

Total Hours: 44

LIST OF EXPERIMENTS:1. Study Of Igbt, Mosfet, Scr, Triac, Diac Characteristics.2. Study Of Different Scr Triggering Circuit Trainer – Dc, R, R-C, Ujt.3. Study Of Single Phase Half Controlled Bridge Converter With R, R-L Load.4. Study Of Single Phase Fully Controlled Bridge Converter With R, R-L Load.5. Study Of Single Phase Scr Full Bridge Inverter Circuit.6. Study Of High Voltage Thyristorised Chopper7. Study Of Single Phase Ac Voltage Controller Using Scr.8. Study Of Single Phase Ac Voltage Controller Using Triac.9. Study Of Single Phase Dual Converter Circuit.10. Study Of Scr Dc Circuit Breaker Circuit.11. Study Of Three Phase Scr Triggering Circuit Using Tca785 Ic.12. Study Of Ac Solid State Relay Using Ic 555, Opto Coupler & Triac.13. Simulation Of Power Ec CIRCUITS IN PSIM AND SIMULINK.

REFERENCES:1. Bimbhra, P. S., Power electronics, Khanna Publishers, New Delhi.2. Rasid, M. H., Power Electronics Circuits, Devices, and Applications, Prentice-Hall of India Pvt. Ltd.3. Singh, M. D., Khanchandani, K. B., Power electronics, Tata McGraw-Hill Publishing Co. Ltd.4. Ned Mohan, Tore M. Undeland and William P. Robbins, Power Electronics Converters, Applications,

and Design, John Willey & Sons, Inc.5. Agrawal, J. P., Power electronic systems: Theory and design, Addison Wesley Longman Pte. Ltd.

B. Tech.III (Electrical & Electronics), Semester – VI L T P CEE 332: MEASUREMENT AND INSTRUMENTATION 3 1 2 5_____________________________________________________________________________________________

MEASUREMENT OF RESISTANCE , INDUCTANCE AND CAPACITANCE (07 Hours)General four arm bridge network, Kelvin bridge, Maxwell, Anderson, Schering bridge networks, Wagner earthling device,

INDICATING AND INTEGRATING INSTRUMENTS (09 Hours)Classification, operating principles, general construction details of indicating instruments, balancing, control and damping method, theory and construction of PMMC, moving iron electrostatic and rectifier instruments, electrodynamics wattmeter , induction energy meter

INSTRUMENT TRANSFORMERS (07 Hours) Theory of current and voltage transformer, ratio error and phase angle ,burden, turns compensation performance characteristics , testing and applications of CT and PT

PERFORMANCE CHARACTERISTICS OF MEASUREMENT SYSTEMS (06 Hours)Elements of generalized measurement system, input-output configuration of instruments and measurement systems, methods of correction for interfering and modifying inputs, static performance characteristics of measurement system, noise, signal to noise ratio, errors in measurement

TRANSDUCERS (08 Hours)Classification of transducers, passive transducers: resistive, inductive and capacitive transducers, active transducers: thermocouple, piezoelectric transducer, taco-generator, pH cell, basic signal conditioning circuits for transducers

ELECTRONIC METERS AND OSCILLOSCOPE (07 Hours)DC amplifier voltmeter, AC voltmeter using rectifiers, true RMS responding voltmeter, Hall effect wattmeter, Oscilloscope block diagram, CRT and its circuits, vertical deflection systems, delay line, multiple trace, horizontal deflection system, oscilloscope probes. Special Oscilloscopes: Sampling oscilloscope, storage oscilloscopeTutorial based on the above topics 14 Hours

Lecture 42 Hour + Tutorial 12 Hour =Total Hours: 56_______________________________________________________________________________________________

LIST OF EXPERIMENTS:1. Calibration of LVDT2. Instrumentation Amplifier and Measurement of temperature using Thermocouple3. Measurement of liquid level4. LCR-Q Meter5. Strain Gauge6. CRO and Function generator7. Anderson bridge8. Kelvin bridge9. Calibration of energy meter

REFERENCES:1. A. K. Sawhney, “Electrical and electronic Measurements and Instrumentation”, Dhanpat Rai & Co.2. Helfrick A D; Cooper W. D., “Modern electronic Instrumentation and Measurement techniques”, PHI 3. Rangan; Sarma; Mani, “Instrumentation devices and systems”,TMH, 2nd edition4 Doebelin E.O and Manik D N, “Measurement Systems, McGraw hill,Edition ,2007

EE 314: INDUSTRIAL AUTOMATION AND PROCESS CONTROL 3-0-0 CR-3

INTRODUCTION OF INDUSTRIAL PROCESSES (04 Hours)Process with analog variables , discrete state sequential process, hybrid process, overview of automation.

SENSORS (06 Hours )

Mechanical sensors: strain ; motion; pressure ; flow: Thermal sensors: RTD; thermistors, thermocoupleOptical sensors: photo detectors ;pyrometers; optical sourcesACTUATORS (05 Hours)Final control operation :signal conversions ;actuators ;control elements, signal conversions: analog electrical signals; digital signals; pneumatic signals, actuators: electrical ;pneumatic ;hydraulic, fluid valves : control valve principle ;types ;sizingCONTROL SYSTEM CONFIGURATIONS (05 Hours)Feedback control, Feed Forward Control, Ratio Control, cascade Control, over-ride control, optimizing control systemCONTROLLER PRINCIPLES (06 Hours)Controller modes, electronic controller, pneumatic controller, digital controllers, controller software.PROGRAMMABLE LOGIC CONTROLLERS (12 Hours)Advantages & disadvantages of PLC with respect to relay logic, PLC architecture, Input Output modules, PLC interfacing with plant, ladder diagramCASE STUDY OF INDUSTRIAL AUTOMATION (04 Hours)Boiler, conveyor belt system, Heat Exchanger

Total Hours:42

REFERENCES:1. JOHN WEBB, Programmable Logic Controllers Principles & applications, PHI2. T. A. HUGHES, Programmable Controllers.3. C. D. JOHNSON, Process Control Instrumentation Technology, PHI.4. ANDREWS, Applied Instrumentation in Process Industries (Volume-IV).5. D. PATRANABIS, Principles of Process Control, TMH6. LIPTAK, Process Control7. S. K. Singh, Computer aided process control, PHIEE 316: STATE VARIABLE ANALYSIS 3-0-0 CR-3

MATHEMATICAL BACKGROUND-MATRICES: (03 Hours)Definition of Matrices; Matrix Algebra; Matrix Multiplication and Inversion; Rank of a Matrix; Differentiation and Integration of Matrix.

STATE SPACE ANALYSIS OF CONTROL SYSTEMS: (16 Hours)State Variables; State-Space Representation of Electrical and Mechanical and Electromechanical Systems; State Space Representation of Nth Order, Linear Differential Equation; Transformation to Phase Variable Canonical Form; Relationship Between Transfer Functions and State Equations; Characteristic Equation; Eigen Values and Eigen Vectors; Transformation to Diagonal Canonical Form; Jordan Canonical Form.

SOLUTION OF THE TIME-INVARIANT SYSTEMS: (06Hours)Solution of the Time-Invariant State Equation; State Transition Matrix and its Properties; Transfer Matrix; Transfer Matrix of Closed Loop Systems.

CONTROLLABILTY AND OBSERVABILITY: (08 Hours)Concept of Controllability and Observability; Kalman’s Theorems on Controllability; and Observability, Alternative Tests (Gilbert’s Method) of Controllability and Observability; Principle of Duality; Relationship among Controllability, Observability and Transfer Function, Decomposition of Transfer Function-Direct, Cascade and Parallel Decomposition; State Diagram.

LIOPUNOV STABILITY ANALYSIS: (09 Hours)Stability of Equilibrium State in the Sense of Liopunov; Graphical Representation of Stability; Asymptotic Stability and Instability; Sign-Definiteness of Scalar Function; Second Method of Liopunov; Stability Analysis of Linear Systems; Krasovskii’s Theorem; Liopunov Function Based on Variable Gradient Method.

Total Hours: 42

References:1. Nagrath & Gopal, Control system engineering, New Age International Publishers.2. K. Oggata, Modern control system engineering, Pearson Education Asia.

3. B.C.Kuo, Automatic control system, Prentice Hall of India.4. Richard C Dorf & Robert H Bishop, Modern control system, Pearson Education Asia.5. Nise N. S., Control System Engineering, John willey & sons.

EE 318: ENERGY AUDIT AND MANAGEMENT 3-0-0 CR-3

ENERGY SCENARIO (02 Hours)Commercial and non-commercial energy, primary energy resources, commercial energy production, final energy consumption, energy needs of growing economy, long term energy scenario, energy pricing, energy sector reforms, energy and environment, air pollution, climate change, energy security, energy conservation and its importance, energy strategy for the future, energy conservation act 2001 and its features.

BASICS OF ENERGY & ITS VARIOUS FORMS (02 Hours)Electricity basics – DC and AC currents, electricity tariff, load management and maximum demand control, power factor. Thermal basics – fuels, thermal energy content of fuels, temperature and pressure, heat capacity, sensible & latent heat, evaporation, condensation, steam, moist air, humidity and heat transfer, units and conversion.

ENERGY MANAGEMENT AND AUDIT (02 Hours)Definition, energy audit – need, types of energy audit, energy management (audit) approach – understanding energy costs, benchmarking, energy performance, matching energy use to requirement, maximising system efficiencies, optimising the input energy requirements, fuel and energy substitution, energy audit instruments.

MATERIAL AND ENERGY BALANCE (02 Hours)Facility as an energy system, methods for preparing process flow, material and energy balance diagrams.

ENERGY ACTION PLANNING (03 Hours)Key elements, force field analysis, energy policy purpose, perspective contents, formulation, ratification, organising, location of energy management, top management support, managerial function, roles and responsibilities of energy manager, accountability, motivating – motivation of employees, information system designing barriers, strategies, marketing and communicating, training & planning.

FINANCIAL MANAGEMENT (02 Hours)Investment – need, appraisal and criteria, financial analysis techniques – simple pay back period, return on investment, net present value, internal rate of return, cash flow, risk and sensitivity analysis, financing options, energy performance contracts and role of ESCOs.

PROJECT MANAGEMENT (03 Hours)Definition and scope of project, technical design, financing, contracting, implementation & performance monitoring, implementation plan for top management, planning budget, procurement procedures, construction, measurement & verification.

ENERGY MONITORING AND TARGETING (02 Hours)Defining monitoring and targeting, elements of monitoring and targeting, data and information analysis, techniques – energy consumption, production, cumulative sum of differences (CUSUM)

GLOBAL ENVIRONMENTAL CONCERNS (02 Hours)United nations framework convention on climate change (UNFCC), Kyoto protocol, conference of parties (COP), clean development mechanism (CDM), prototype carbon fund (PCF), sustainable development.

ELECTRICAL SYSTEM (04 Hours)Electricity billing, electrical load management & maximum demand control, power factor improvement & it’s benefits, selection & location of capacitors, performance assessment of pf capacitors, distribution & transformer losses.

ELECTRIC MOTORS (03 Hours)Types, losses in induction motors, motor efficiency, factors affecting motor performance, rewinding & motor replacement issues, energy saving opportunities with energy efficient motors.

FANS AND BLOWERS (02 Hours)

Types and applications, fan characteristics and performance curves, fan laws, performance evaluation, efficient system operation, flow control strategies, energy conservation opportunities.

PUMPS AND PUMPING SYSTEM (02 Hours)Types of pumps, significance of head flow curve & operating point of a pump, factors affecting pump performance, performance evaluation, efficient pumping system operation, various flow control strategies, energy conservation opportunities in pumping system.

LIGHTING SYSTEM (03 Hours)Light source, choice of lighting, luminance requirements, terminologies used in lighting systems, recommended illuminance standards, methodology of energy efficiency audit in lighting systems, good practices, energy conservation avenues.

DG SET SYSTEM (04 Hours)basics of internal combustion engines, factors affecting selection & performance, waste heat recovery to enhance cost effectiveness of DG sets, energy performance assessment, energy conservation avenues and troubleshooting.

ENERGY EFFICIENT TECHNOLOGIES IN ELECTRICAL SYSTEM (04 Hours)Maximum demand controllers, automatic power factor controllers, energy efficient motors, soft starters with energy saver, variable speed drives, energy efficient transformers, electronic ballast, occupancy sensors, energy efficient lighting controls, energy saving potential of each technology.

Total Hours:42

REFERENCES:1. Encyclopedia of Energy, McGraw Hill Publication.2. Albert Thumann, Handbook of Energy Engineering, The Fairmont Press Inc.3. Wayne C. Turner, Energy management Handbook, John Wiley and sons.4. Cleaner Production, Energy Efficiency Manual for GERIAP, UNEP, Bangkok prepared by National

Productivity Council.5. Prasanna Chandra, Financial management, Tata Mc-Graw Hill.6. S. Choudhury, Projects: Planning, Analysis, Selection, Implementation and Review, Tata McGraw Hill.

EE 322: POWER SYSTEM PLANNING AND MANAGEMENT 3-0-0 CR-3

FORECASTING-NEEDS & USES (11 Hours)Current Status Of Forecasting, Fundamentals Of Quantitative Forecasting, Explanatory And Time Serious Forecasting, Least Square Estimates, Peak Load Forecasting, Accuracy Of Forecasting Methods, Regression Methods, Box Jenkins Time Serious Methods.

SHORT AND LONG TERM FORECASTING TECHNIQUES (11 Hours)Problems facing electricity industry, Long term forecasting techniques, Methods of long term forecasting, Spatial load forecasting, Multivariate procedures, Short term forecasting techniques

FORECASTING AND PLANNING (10 Hours)The role of forecasting in planning, Comparison and selection of forecasting methods, The accuracy of forecasting methods, Pattern of the Data and its effects on individual forecasting methods, Time horizon effects on forecasting methods.

GENERATION PLANNING (10 Hours)Fundamental economic analysis, Generation planning optimized according to generating unit categories, distribution & Transmission system planning.Total Hours:42

REFERENCES:1. Makridakis, Spyros, Forecasting methods and application, John Wiley.2. X.Wang & J.R. Mc Donald, Modern Power system planning, McGraw. Hill3. A.S Pabla, Electrical Power system planning, Mac Millan.4. Sullivan, Power system planning, McGraw. Hill.5. Lakervi E, E J Holmes, Electricity distribution network design, IEE.

EE 324: Power Quality Issues and Remedial Measures 3-0-0 CR-3

Power quality: (04 Hours)Understanding power quality, types of power quality disturbance, power quality indices, causes and effects of power quality disturbances.

TRIGGERING & SEGMENTATION: (06 Hours)Basic concepts, Overview of existing method, triggering method: changes in RMS waveforms, detecting singular point form wavelet transforms, segmentation.

HARMONICS: SOURCES & ITS EFFECT (07 Hours)Causes and effect of harmonics, converter configuration and their contribution to supply harmonics and other sources of harmonics, standards-IEEE guides, standards and recommended practices, effect of power system harmonics on power system equipment and loads.

POWER FACTOR CORRECTION & MITIGATION OF HARMONICS: (13 Hours)Modeling of networks and components under non-sinusoidal conditions: transmission and distributionsystems, power quality problems created by drives and its impact on drives, Power factor improvement, Passive Compensation, Active Power Factor Correction -Single Phase APFC, Three Phase APFC and Control Techniques, static VAR compensators-SVC and STATCOM - Active Harmonic Filtering, Dynamic Voltage Restorers for sag ,swell and flicker problems. Grounding and bonding-introduction.

ELECTROMAGNETIC INTERFERENCE: (06 Hours)Electromagnetic Interference: frequency classification, electric and magnetic field, EMI terminology, EMT Mitigation, Health concern of EMI.

POWER QUALITY MEASUREMENT: (06 Hours)Measuring and solving power quality problems, Power Quality measurement device and its measurement, test: Location, Duration, Instrument set-up and its guide lines.

Total Hours:42

REFERENCES:1. Bollen Math H.J, Understanding Power quality Problems: Voltage Sags and Interruptions, IEEE Press.2. Sankaran C., Power Quality, CRC Press.3. Padiyar K.R. FACTS controller in power transmission and Distribution, New Age international.4. Bollen math H.J.,GU Irene Y.H., Signal processing of power quality Disturbances, Wilely Inter-science

publication.5. Recent Publications on power system and Power Delivery.

Spring 2013

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Transcript of Spring 2013