sathyabama university faculty of electrical · pdf fileb.e. / b. tech regular xxi regulations...

SATHYABAMA UNIVERSITY FACULTY OF ELECTRICAL AND ELECTRONICS

B.E. / B. Tech REGULAR xxi REGULATIONS 2015

PROGRAMME : B.E. ELECTRONICS AND INSTRUMENTATION

CURRICULUM SEMESTER 1

Sl. No. COURSE CODE COURSE TITLE L T P C PAGE No.

THEORY 1. SHS1101 / English for Science and Technology / 3 0 0 3 1 SCH1101 Environmental Science and Engineering 3 0 0 3 20

2. SMT1101 Engineering Mathematics - I 3 1 0 4 2

3. SPH1101 Physics of Engineering Materials 3 0 0 3 10

4. SCY1101 Engineering Chemistry 3 0 0 3 15

5. SCS1102 Fundamentals of Programming 3 0 0 3 22

6. SIC1102 Science of Measurements & Instrumentation 3 0 0 3 85

PRACTICAL 7. SPH4051 Engineering Physics Lab 0 0 2 1 105

8. SCY4051 Engineering Chemistry Lab 0 0 2 1 105

9. SCS4101 Programming in ‘C’ Lab 0 0 4 2 105

TOTAL CREDITS 23

SEMESTER 2


THEORY 1. SHS1101 / English for Science and Technology / 3 0 0 3 1 SCH1101 Environmental Science and Engineering 3 0 0 3 20

2. SMT1105 Engineering Mathematics - II 3 1 0 4 3

SPH1102 Physics of Electronic Devices / 3 0 0 3 12 3. SPH 1103 Engineering Physics / 3 0 0 3 13 SPH 1104 Applied Biophysics 3 0 0 3 14

4. SCY1102 Chemistry of Electronic Materials / 3 0 0 3 16 SCY1103 Chemistry of Industrial Materials / 3 0 0 3 17 SCY1104 Bio Organic Chemistry / 3 0 0 3 18 SCY1105 Physical Chemistry 3 0 0 3 19

5. SEE1105 Electrical Technology 3 0 0 3 65

6. SIC1101 Sensors and Transducers 3 0 0 3 84

PRACTICAL 7. SEE4051 Electrical Engineering Lab 0 0 4 2 127

8. SME4053 Engineering Graphics Lab 0 0 4 2 108

TOTAL CREDITS 23

L - LECTURE HOURS, T – TUTORIAL HOURS, P – PRACTICAL HOURS, C – CREDITS

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B.E. / B. Tech REGULAR xxii REGULATIONS 2015

SEMESTER 3


THEORY

1. SMT1201 Engineering Mathematics - III 3 1 0 4 4

2. SCS1202 Object Oriented Programming 3 0 0 3 23

3. SEE1107 Electrical Circuits & Networks 3 1 0 4 67

4. SME1210 Solid & Fluid Mechanics 3 0 0 3 27

5. SEC1204 Electronic Devices and Circuits 3 0 0 3 34

6. SEC1207 Digital Logic Circuits 3 0 0 3 37

PRACTICAL

7. SEC4077 Devices and Electric circuits Lab 0 0 4 2 122

8. SCS4201 Object Oriented Programming Lab 0 0 4 2 106

TOTAL CREDITS 24

SEMESTER 4


THEORY 1. SMT1204 / Engineering Mathematics – IV / 3 1 0 4 5 SMT1206 / Number Theory and Linear Algebra / 3 1 0 4 6 SMT1207 / Graph Theory / 3 1 0 4 7 SMT1208 / Applied Statistics / 3 1 0 4 8 SMT1209 Foundations of Mathematics 3 1 0 4 9

2. SEC1202 Discrete Electronic Circuits 3 0 0 3 32

3. SME1208 Applied Thermal Engineering 3 0 0 3 26

4. SEC1208 Signals and Systems 3 0 0 3 38

5. SIC1202 Electrical Measurements & Instrumentation 3 0 0 3 87

6. SIC1201 Industrial Instrumentation 3 0 0 3 86

PRACTICAL

7 SEC4079 Electronic Design Lab 0 0 4 2 123

8. SEC4080 Electronic Circuits Lab 0 0 4 2 124

9. S18PT1 Professional Training – 1 0 0 0 5

TOTAL CREDITS 28

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B.E. / B. Tech REGULAR xxiii REGULATIONS 2015

SEMESTER 5


THEORY

1. SEC1314 Digital Signal Processing 3 1 0 4 52

2. SEE1203 Control Systems 3 1 0 4 71

3. SIC1311 Biomedical Instrumentation 3 0 0 3 98

4. SIC1308 Industrial Unit Operations 3 0 0 3 96

5. SIC1305 Electronic Measurements & Instrumentation 3 0 0 3 93

6. SEC1302 Analog Integrated Circuits 3 0 0 3 43

PRACTICAL

7. SEC4082 Linear & Digital Integrated Circuits Lab 0 0 4 2 125

8. SIC4052 Measurements and Transducers Lab 0 0 4 2 131

TOTAL CREDITS 24

SEMESTER 6


THEORY

1. SIC1306 Control Engineering 3 1 0 4 94

2. SEC1309 Microcontrollers & Embedded Systems 3 0 0 3 48

3. SIC1307 Process Control Instrumentation Technology 3 0 0 3 95

4. SIC1310 Theory of Robotics 3 0 0 3 97

5. SEC1306 Data Communication & Networking 3 0 0 3 46

6. Elective – 1 3 0 0 3

PRACTICAL

7. SEC4084 Microprocessor and Microcontroller Lab 0 0 4 2 126

8. SIC4053 Process Control Lab 0 0 4 2 132

9. S18PT2 Professional Training – 2 0 0 0 5

TOTAL CREDITS 28

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B.E. / B. Tech REGULAR xxiv REGULATIONS 2015

SEMESTER 7


THEORY

1. SIC1404 Instrumentation in Industries 3 0 0 3 102

2. SIC1406 Process Control System Components 3 1 0 4 104

3. Elective – 2 3 0 0 3

4. Elective – 3 3 0 0 3

PRACTICAL

5. SIC4056 Industrial Instrumentation Lab 0 0 4 2 133

6. SIC4057 System Design Lab 0 0 4 2 134

Project Work (Phase 1)

TOTAL CREDITS 17

SEMESTER 8


THEORY

1. SIC1405 Logic and Distributed Control Systems 3 0 0 3 103

2. SBA1101 Principles of Management & Professional Ethics 3 0 0 3 28

3. Elective – 4 3 0 0 3

PRACTICAL

4. S18PROJ Project Work (Phase 1& 2) 0 0 30 15

TOTAL CREDITS : 24 TOTAL CREDITS FOR THE PROGRAM : 191

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B.E. / B. Tech REGULAR xxv REGULATIONS 2015

ELECTIVE COURSES (GROUP A)


THEORY

1. SCS1315 Computer Architecture and Operating System 3 0 0 3 24

2. SCS1611 Artificial Intelligence and Expert Systems 3 0 0 3 25

3. SEC1615 Nanoelectronics 3 0 0 3 149

4. SEC1618 Programming in MATLAB 3 0 0 3 152

5. SEC1619 Radar and Navigational Aids 3 0 0 3 153

6. SIC1601 Instrumentation in Aerospace & Navigation 3 0 0 3 165

7. SIC1602 Software for System Design 3 0 0 3 166

8. SIC1609 Satellite Instrumentation 3 0 0 3 173

9. SIC1611 Fundamentals of Mechatronics 3 0 0 3 175

10. SIC1613 Industrial Safety Management 3 0 0 3 177

11. SIC1614 Soft Computing Techniques 3 0 0 3 178

ELECTIVE COURSES (GROUP B)


1. SIC1304 Analytical Instrumentation 3 0 0 3 92

2. SIC1610 Ultrasonic Instrumentation 3 0 0 3 174

3. SIC1612 Adaptive Control System 3 0 0 3 176

4. SIC1605 Fiber Optics and Laser Instrumentation 3 0 0 3 169

5. SEC1617 Advanced Electronics Test Engineering 3 0 0 3 151

6. SEC1616 Pattern recognition and Image vision 3 0 0 3 150

7. SEE1305 Power Electronics 3 0 0 3 79

8. SEC1604 Biomedical Signal and Image Processing 3 0 0 3 139

9. SEC1612 MEMS and its Applications 3 0 0 3 146

10. SEC1316 CMOS VLSI Design 3 0 0 3 54

11. SEC1606 Digital Image Processing 3 0 0 3 141

12. SPR1307 Resource Management Techniques 3 0 0 3 29

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B. E. / B. Tech REGULAR 1 REGULATIONS 2015

SHS1101 ENGLISH FOR SCIENCE AND TECHNOLOGY (Common to ALL Branches of B.E/B.Tech)

L T P Credits Total Marks3 0 0 3 100

COURSE OBJECTIVE To equip the learners with English communicative skills to handle the present and future needs by exposing them to situations and tasks in the areas of LSRW, genre and register related to EST by following content based teaching.

UNIT 1 BASIC COMMUNICATION 9 Hrs. Listening for specific information, Self Introduction, Reading Comprehension, Kinds of Sentences, Parts of Speech, Tenses & its Types, Impersonal Passive, Elements of Effective Writing, Letter Writing, Concord, Prefixes & Suffixes

UNIT 2 NUANCES OF EST 9 Hrs. Listening for inference, Describing a process, Cloze Reading and its types, Transcoding - Encoding & Decoding, Flow Chart, Bar chart, Pie Chart, Tabular Column, Tree Diagram, Technical Definitions, Connectives & Discourse Markers, Word Association- connotations

UNIT 3 EST NOW AND THEN 9 Hrs. Listening and Note taking, Role-play, Reading and interpreting visual material (pictures/newspapers) Essay Writing - Note Making - WH questions - Question Tags - Types of sentences - Compound Nouns, Technical Definitions.

UNIT 4 APPLICATIONS OF EST 9 Hrs. Listening and Classifying information, Group discussion, Reading and identifying the topic sentence, - Writing a Project Proposal, Recommendations and Instructions - Manual Writing, Use of abbreviations and acronyms, Editing (Spelling, Grammar, Punctuation) Idioms & Phrases.

UNIT 5 PREPARING FOR FUTURE 9 Hrs. Listening and summarizing, Making presentations on given topics - Giving impromptu talks Reading and Summarizing, E-mail writing, Rearranging the Jumbled sentences Reported Speech, Homophones/Homonyms, Creative Writing & Poster making using similes/metaphors.

Max. 45 Hours TEXT / REFERENCE BOOKS 1. Sangeetha Sharma & Meenakshi Raman, Technical Communication: Principles and Practice. Oxford University Press, New

Delhi, 2011. 2. Sanjay Kumar & Pushp Lata, Communication Skills, 2nd Edition, Oxford University Press, New Delhi, 2011. 3. Nira Konar, Communication Skills for Professionals, PHI Publishers, Eastern Economy Edition, New Delhi, 2011. 4. Sharon J Gerson & Steven M Gerson, Technical Communication: Process and Product, 8th Edition, Orient Longman, 2013. 5. Tyagi Kavita and Misra Padma, Basic Technical Communication PHI Publishers, Eastern Economy Edition, New Delhi, 2011. 6. Nagini,P S et al. Excellence Through communication, Shri Jai Publications, Chennai, 2005.

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 questions of 2 marks each - No choice; with equal distribution to each unit -(10 x 2) 20 Marks

(Task types can include Multiple choice, open ended, gap filling, completion and rewriting the sentences, matching type etc.)

PART B : 2 questions from each unit with internal choice; each carrying 12 marks (5 X 10) 60 Marks (Questions types should testing vocabulary, grammar, reading and writing with equal

distribution to all. For example Reading Comprehension type can include skimming, scanning, comprehensive with evaluative, inferential and hypothetical question/ fixed type questions or cloze exercise , Academic paragraph writing based on Flow chart, Tree diagram, Bar diagram, Table and Pie chart to describe process, comparative and contrast, differentiate , Formal letter writing - Application for a Job & Resume Preparation/ Email- Letter inviting a dignitary-Accepting/Declining (or) Rearranging the jumbled sentences in the right order, (or) Requesting for Practical Training/ Letter to the Editor. Writing a Project Proposal / Project Report (or) Essay Writing- Writing an Essay on a given topic, Summary writing or Making notes in the standard format with title. Grammar Rearranging the jumbled sentences in the right order or editing the paragraph for errors based on syllabus)

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SCH1101 ENVIRONMENTAL SCIENCE AND ENGINEERING

(Common to ALL Branches of B.E/ B. Tech.) L T P Credits Total Marks3 0 0 3 100

COURSE OBJECTIVE To impart knowledge on the issues related to environment and to emphasize the importance of a clean environment

UNIT 1 INTRODUCTION TO ENVIRONMENTAL STUDIES AND NATURAL RESOURCES 10 Hrs. Definition, scope and importance, need for public awareness, forest resources: use and over-exploitation, deforestation, case studies. Timber extraction, mining, dams, floods, drought, conflicts over water, dams-benefits and problems, mineral resources: use effects on forests and tribal people. water resources: use and over-utilization of surface and ground water, exploitation, environmental effects of extracting and using mineral resources, case studies food resources: world food problems, changes caused by agriculture and overgrazing, effects of modern agriculture, fertilizer-pesticide problems, water logging, salinity, case studies. Energy resources: growing energy needs, renewable and non renewable energy sources, use of alternate energy sources: Case studies. Land resources: land as a resource, land degradation, man induced landslides, soil erosion and desertification, role of an individual in conservation of natural resources, equitable use of resources for sustainable lifestyles.

UNIT 2 ECOSYSTEMS AND BIODIVERSITY 10 Hrs. Concept of an ecosystem, structure and function of an ecosystem - producers, consumers and decomposers - energy flow in the ecosystem, ecological succession, food chains, food webs and ecological pyramids. Introduction, types, characteristic features, structure and function of the (a) forest ecosystem (b) grassland ecosystem (c) desert ecosystem (d) aquatic ecosystems (ponds, streams, lakes, rivers, oceans, estuaries). Introduction to biodiversity, definition: genetic, species and ecosystem diversity - biogeographical classification of India - value of biodiversity: consumptive use, productive use, social, ethical, aesthetic and option values, biodiversity at global, national and local levels. India as a mega-diversity nation, hot-spots of biodiversity, threats to biodiversity: habitat loss, poaching of wildlife, man-wildlife conflicts, endangered and endemic species of India, conservation of biodiversity, in-situ and ex-situ conservation of biodiversity.

UNIT 3 ENVIRONMENTAL POLLUTION 9 Hrs. Definition - causes, effects and control measures of: (a) air pollution (b) water pollution (c) soil pollution (d) marine pollution (e) noise pollution (f) thermal pollution (g) nuclear hazards. Solid waste management: causes, effects and control measures of urban and industrial wastes, role of an individual in prevention of pollution, pollution case studies, disaster management: floods, earthquake, cyclone and landslides.

UNIT 4 SOCIAL ISSUES AND THE ENVIRONMENT 8 Hrs. From unsustainable to sustainable development, urban problems related to energy, water conservation, rain water harvesting, watershed management, resettlement and rehabilitation of people; its problems and concerns, case studies, environmental ethics: issues and possible solutions, climate change, global warming, acid rain, ozone layer depletion, nuclear accidents and holocaust, case studies. Wasteland reclamation, consumerism and waste products - environment protection act: air (prevention and control of pollution) act - water (prevention and control of pollution) act, wildlife protection act; forest conservation act. Issues involved in enforcement of environmental legislation, Key initiatives of Rio declaration, Vienna convention, Kyoto protocol, Johannesburg summit and public awareness.

UNIT 5 HUMAN POPULATION AND THE ENVIRONMENT 8 Hrs. Population growth, variation among nations, population explosion, family welfare programme, environment and human health, human rights, value education, HIV / AIDS, women and child welfare, role of information

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SMT1101 ENGINEERING MATHEMATICS - I (Common to ALL branches except BIO Groups)


COURSE OBJECTIVE The ability to identify, reflect upon, evaluate and apply different types of information and knowledge to form independent judgments. Analytical, logical thinking and conclusions based on quantitative information will be the main objective of learning this subject.

UNIT 1 MATRICES 12 Hrs. Characteristic equation of a square matrix - Eigen values and Eigen vectors of a real matrix- properties of Eigen values- Cayley-Hamilton theorem (without proof) - verification , finding inverse and power of a matrix - Diagonalisation of a matrix using orthogonal transformation - Reduction of quadratic form to canonical form by orthogonal transformation.

UNIT 2 GEOMETRICAL APPLICATIONS OF DIFFERENTIAL CALCULUS 13 Hrs. Curvature -centre, radius and circle of curvature in Cartesian co- ordinates - Evolutes - Envelope of family of curves with one and two parameters. - Evolute as envelope of normals.

UNIT 3 FUNCTIONS OF SEVERAL VARIABLES 11 Hrs. Introduction to partial derivatives - Jacobians - Taylor’s expansion - Maxima and minima of functions of two variables - Constrained maxima and minima using Lagrange’s multiplier method.

UNIT 4 ORDINARY DIFFERENTIAL EQUATIONS 11 Hrs. First order exact differential equations - Second order linear differential equations with constant coefficients - Particular Integral for eax, sinax or cosax, xn, xneax, eaxsinbx or eaxcosbx - Equations reducible to linear equations with constant co-efficients using x = et - Simultaneous first order linear equations with constant coefficients - Method of Variation of Parameters

UNIT 5 THREE DIMENSIONAL ANALYTICAL GEOMETRY 13 Hrs. Direction cosines and ratios - Plane - Plane through intersection of two planes - Straight Line - Coplanar lines - Planes and Straight lines - Shortest distance between two Skew lines - Sphere -Plane section of a sphere - Great Circle.

Max. 60 Hours

TEXT / REFERENCE BOOKS 1. Veerarajan T, Engineering Mathematics for First Year, II Edition, Tata McGraw Hill Publishers, 2008. 2. Kandaswamy P & co., Engineering Mathematics for First Year, IX revised edition, S.Chand & Co Pub., 2010. 3. Moorthy M.B.K, Senthilvadivu K ,Engineering mathematics-I, Revised Edition, VRB Pub., 2010, 4. Arumugam S & co. Engineering Mathematics Vol-I , Revised Edition, SciTech Pub., 2010 5. Venkataraman M.K., Engineering Mathematics - First Year (2nd edition), National Publishing Co., 2000. 6. Kreyszig. E, Advanced Engineering Mathematics, 10th edition, John Wiley & Sons, Singapore, 2012. 7. Grewal B. S, Higher Engineering Mathematics, 41th Edition, Khanna Publications, Delhi,2011.

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 questions of 2 marks each - No choice 20 Marks PART B : 2 questions from each unit of internal choice, each carrying 12 marks 60 Marks

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SPH1101 PHYSICS OF ENGINEERING MATERIALS (Common to ALL Branches of B.E/ B. Tech.)


COURSE OBJECTIVE To expose the students to different classes of materials and present the fundamentals of materials science; to develop the understanding of the behaviour of materials, their properties and structures; to facilitate selection of suitable material for particular engineering application.

UNIT 1 CHARACTERIZATION OF MATERIALS 9 Hrs. Introduction, Structural characterization - X-ray diffraction, Bragg’s law, Determination of crystal structure - powder X-ray diffractometer (Debye Scherrer camera) and Single crystal XRD with principle, construction and working, Microstructural characterization - Introduction, electromagnetic lens system, Determination of surface morphology by Scanning Electron Microscope (SEM), Transmission Electron Microscope (TEM) and Atomic Force Microscope (AFM) with principle, construction and working. Microhardness testing -Determination of microhardness by Vickers hardness test, Knoop hardness test and Nanohardness test with principle, construction, and working.

UNIT 2 MAGNETIC MATERIALS 9 Hrs. Introduction, Origin of magnetic moment - orbital, spin and nuclear magnetic moments; Bohr magneton; Classification of magnetic materials based on spin- dia, para, ferro, antiferro and ferri- Curie temperature, Neel temperature.; Magnetic domains- Domain theory of Ferro magnetism (Weiss theory) - Observation of domain (bitter powder pattern), Energies involved in domain formation - magnetostatic energy, anisotropic energy, magnetostrictive energy and domain wall energy; Hysteresis Curve -based on domain theory; Types of magnetic materials - soft and hard magnetic materials; Magnetic bubbles - formation and propagation of magnetic bubbles-T-bar, read/write operation.

UNIT 3 SUPERCONDUCTING MATERIALS 9 Hrs. Introduction to superconductivity- Properties of superconductor - electrical resistance, Meissner Effect, effect of heavy magnetic field, effect of heavy current (Silsbee’s rule), effect of high pressure , isotope effect, entropy, specific heat capacity, energy gap, London Penetration depth, Coherence Length, Ginzburg Landau Parameter, Flux Quantization and thermal conductivity. Theory of superconductivity - London Theory (Macroscopic), Bardeen, Cooper and Schrieffer Theory (Microscopic) - explanation based on formation of Cooper pairs and existence of energy gap. Types of superconductors - Type I and Type II superconductors, D.C. and A.C Josephson Effect, I-V Characteristics and applications of Josephson junction. Applications - cryotron, magnetic levitation train and SQUIDS.

UNIT 4 OPTICAL MATERIALS 9 Hrs. Introduction, refractive index, absorption and dispersion, reflections. Classification of optical materials, absorption in metals, semiconductors and insulators (dielectrics), Excitons- Frenkel and Mott-Wannier excitons, Point detects -Frankel and Schottky defects, Traps - trapping and recombination centres - Colour Centres - types - F-Centre, R-Centre, V-Centre (V1 and V2), M -Centre. Luminescence - Principle and classification - Mechanism and working of Photo luminescence (Fluorescence and Phosphorescence).

UNIT 5 SEMICONDUCTING MATERIALS 9 Hrs. Introduction - Band theory (qualitative), types of semiconductors- intrinsic semiconductor - carrier concentration and Fermi level in intrinsic semiconductor - extrinsic semiconductor - carrier concentration and Fermi level in extrinsic semiconductor (p type and n type) - Experimental determination Band gap of semiconductor -Hall Effect - experimental determination of Hall Voltage, Applications of Hall effect.

Max. 45 Hours

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SCY1101 ENGINEERING CHEMISTRY (Common to ALL Branches of B.E/ B. Tech.)


COURSE OBJECTIVES To understand the properties and various synthetic methods for the preparation of nanomaterials and their applications. To know about the quality parameters of water and methods to estimate the toxic elements and softening methods. To give an overview about types of batteries and fuel cells, corrosion mechanisms and preventive methods. To have a basic idea about polymers and various moulding techniques.

UNIT 1 SYNTHESIS OF NANOMATERIALS 9 Hrs. Introduction: Nanomaterials: Definition - Classification based on dimensions - Size dependent properties. Types of nanomaterials: Nanoparticles: Synthesis by chemical reduction method. Nanoporous materials: Synthesis by sol-gel method. Nanowires: Synthesis by VLS mechanism. Carbon Nanotubes (CNTs): Single walled and multi walled nanotubes - Mechanical and electrical properties of CNTs - Applications of CNTs - Synthesis of CNTs by electric arc discharge method and laser ablation method.

UNIT 2 WATER TECHNOLOGY 9 Hrs. Introduction: Water quality parameters - Contamination of water by arsenic, lead, fluoride, mercury and their removal. Hardness: Types - Expression - Units. Estimation of hardness of water by EDTA method - Problems. Estimation of iron, calcium and magnesium: AAS method. Water softening: Zeolite process - Demineralization process. Desalination: Reverse osmosis - Electrodialysis.

UNIT 3 ELECTROCHEMICAL POWER SOURCES 9 Hrs. Electrochemistry: Galvanic cell - Electrochemical cell representation - EMF series and its significance. Batteries: Terminology - Lead-acid accumulator - Nickel-cadmium batteries. Lithium batteries: Li/SOCl2 cell - Li/I2 cell - Lithium ion batteries. Fuel Cells: Hydrogen-oxygen fuel cells - Solid oxide fuel cell (SOFC).

UNIT 4 CORROSION SCIENCE 9 Hrs. Introduction: Definition. Types: Dry corrosion: Mechanism - Pilling-Bedworth rule - Wet Corrosion: Mechanism. Types: Galvanic corrosion and differential aeration cell corrosion. Galvanic series and its significance. Factors influencing corrosion. Corrosion prevention: Material selection and design - Cathodic protection. Protective coatings: Paints - Constituents. Mechanism of drying of drying oils.

UNIT 5 POLYMER CHEMISTRY 9 Hrs. Introduction to polymers: Nomenclature - Functionality. Types of polymerization. Mechanism of polymerization: Free radical mechanism - Cationic mechanism - Anionic mechanism. Plastics: Types - Thermoplastics and thermosetting plastics. Properties: Strength - Crystalline and amorphous state - Average molecular weight - Polydispersity. Compounding of plastics. Moulding of plastics: Compression moulding - Injection moulding - Extrusion moulding- Introduction to conducting polymers. Max. 45 Hours TEXT / REFERENCE BOOKS 1. Jain P.C. and Monica Jain, Engineering Chemistry, 15th Edition Dhanpat Rai Publishing Co., 2009. 2. Dara S.S., Text Book of Engineering Chemistry, S. Chand & Co, 2008. 3. Sheik Mideen A., Engineering Chemistry (I & II),13th Edition, Shruthi Publishers, 2010. 4. Kuriakose J.C. and Rajaram J., Chemistry in Engineering and Technology". Vol.1 & 2, 5th reprint, Tata McGraw Hill

Publishing Company (P) Ltd., 2010. 5. Sharma B.K., Engineering Chemistry, 2nd Edition, Krishna Prakasam Media (P) Ltd., 2001. 6. Mars G Fontana, Corrosion Engineering, 3rd Edition, Tata McGraw Hill, 2008. 7. David Linden andThomas B Reddy, Handbook of Batteries, 4th Edition, McGraw-Hill, 2010.

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 Questions of 2 marks each-No choice 20 Marks PART B : 2 Questions from each unit of internal choice, each carrying 12 marks. 60 Marks (Out of 80 marks, maximum of 10% problems may be asked)

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SCS1102 FUNDAMENTALS OF PROGRAMMING (Common to ALL Branches of B.E/ B. Tech.)

L T P Credits Total Marks

3 0 0 3 100

COURSE OBJECTIVES To understand the basic programming concepts. To understand the concept of arrays, functions and pointers. To gain knowledge about memory management.

UNIT 1 INTRODUCTION 9 Hrs. Introduction: Algorithms, Pseudocodes & flowcharts, Overview of C, features of C, Structure of C program, Compilation & execution of C program. Identifiers, variables, expression, keywords, data types, constants, scope and life of variables, and local and global variables. Operators: arithmetic, logical, relational, conditional and bitwise operators. Special operators: sizeof () & comma (,) operator. Precedence and associativity of operators & Type conversion in expressions. Basic input/output and library functions: Single character input/output i.e. getch(), getchar(), getche() & putchar(). Formatted input/output: printf() and scanf().

UNIT 2 CONTROL STRUCTURES AND FUNCTIONS 9 Hrs. Control structures: Conditional control (if, nested if, switch case), Loop control (for, while, do while) and Unconditional control structures (goto) Functions: The Need of a function, user defined and library function, prototype of a function, calling of a function, function argument, passing arguments to function, return values, nesting of function, recursion. Library Functions: Concepts, mathematical and string functions.

UNIT 3 ARRAYS AND STRINGS 9 Hrs. Arrays: Single and multidimensional arrays, array declaration and initialization of arrays, array as function arguments. Strings: Declaration, initialization and string handling functions. Structure and Union: Defining structure, declaration of structure variable, accessing structure members, nested structures, array of structures, structure assignment, structure as function argument, function that returns structure, union.

UNIT 4 STORAGE CLASSES AND POINTERS 9 Hrs.

Storage class specifier - auto, extern, static & register, Pointers: The ‘&’ and ’*’ operators, pointers expressions, pointers vs arrays

UNIT 5 MEMORY MANAGEMENT 9 Hrs. Pointer to functions, Function returning pointers Direct Memory Access functions: malloc(), calloc(), sizeof(), free() and realloc(). Preprocessor directives. Command line arguments Max. 45 Hours TEXT / REFERENCE BOOKS 1. Balaguruswami. E., “Programming in C”, TMH Publications,1997 2. Yashavant P. Kanetkar., “Let us C”, Fifth Edition 3. Gottfried , “Programming with C”, Schaums Outline Series, TMH publications,1997 4. Mahapatra , “Thinking in C”, PHI publications,2nd Edition. 5. Subburaj . R , “Programming in C” , Vikas Publishing, First Edition, 2000

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 Questions of 2 marks each - No choice 20 Marks PART B : 2 Questions from each unit of internal choice, each carrying 12 marks 60 Marks

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SIC1102 SCIENCE OF MEASUREMENTS AND

INSTRUMENTATION (For EIE)

L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVES To create a strong base in the fundamentals of Instrumentation Engineering. To impart knowledge in the measurement and instrumentation systems and their characteristics To provide in-depth understanding of errors and calibration standards.

UNIT 1 MEASUREMENT AND MEASUREMENT SYSTEMS 9 Hrs. Measurements, Significance of Measurements, Methods of Measurements-Direct and Indirect methods, Measurement systems- Functions of Measurement systems, classification based on their functions, Applications of Measurement systems, Elements of a Generalized measurement system- primary sensing element, variable conversion element, variable manupulation element, data presentation element, generalized mathematical model of measurement systems.

UNIT 2 INSTRUMENTATION SYSTEMS 9 Hrs. Instrument systems - Mechanical, Electrical and Electronic Instruments, Classification of Instruments-absolute instruments and Secondary Instruments, Deflection and Null type Instruments, Analog and Digital modes of operation - Types of Instrumentation systems - Intelligent and dumb instrumentation systems, Generalized instrumentation system, Input-output configuration of measuring instruments - desired inputs, interfering inputs, modifying inputs, methods of correction for interfering and modifying inputs.

UNIT 3 ERRORS IN MEASUREMENTS AND CALIBRATION STANDARDS 9 Hrs. Classification of errors - Gross errors, systematic and random errors, Errors in Measuring Instruments, Sources of Errors, statistical evaluation of measurement data, Instrument error combination, probable error, limits of errors, methods of correction. Calibration and Standards - Process of calibration, theory and principles (absolute and secondary or comparison method), Calibration methods, classification of standards, standards for calibration

UNIT 4 CHARACTERISTICS OF MEASURING INSTRUMENTS 10 Hrs. Static and Dynamic characteristics - Static characteristics: Accuracy, precision, bias, sensitivity, linearity, resolution, hysteresis, dead zone, backlash, drift, threshold, input impedance and loading effect - Dynamic characteristics: speed of response, Lag, Fidelity, Dynamic Error. modelling of measuring instrument systems - operational transfer function - Dynamic Response of zero, first and second order instruments for impulse,step, ramp and frequency response of the above instruments.

UNIT 5 BASICS OF SENSORS AND TRANSDUCERS 8 Hrs. Introduction, Classification, Basic requirements and Selection of Sensors and Transducers, Human body as a sensor system, sensor as a part of measurement system, Characterization - Electrical, Mechanical and Thermal, Optical, Chemical / Biological characterization Max. 45 Hours TEXT / REFERENCE BOOKS 1. Sawhney A.K., “ A Course in Electrical, Electronic measurement & Instrumentation”, Dhanpat Rai & sons,18th Edition,

Reprint 2010 2. Doebelin E.O., “Measurement System Applications and Design”, McGraw Hill, 5th Edition, 2004. 3. Jain R.K., “Mechanical and Industrial Measurements”, Khanna Publishers, 11th edition,Reprint 2005. 4. Jones’ Instrument Technology, Instrumentation Systems, Edited by B.E.Noltingk, Vol 4, 4th edition, ELBS, 1987. 5. Murthy D.V.S., “Transducers and Instrumentation”, Printice Hall of India, 13th printing, 2006.

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration: 3 Hrs. PART A : 10 Questions of 2 marks each-No choice 20 Marks PART B : 2 Questions from each unit of internal choice, each carrying 12 marks 60 Marks

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B.E. / B. Tech REGULAR 105 REGULATIONS 2015

SPH4051 ENGINEERING PHYSICS LAB

(Common for ALL branches of B.E / B.Tech) (First Semester or Second Semester)

L T P Credit Total Marks

0 0 2 1 50

SUGGESTED LIST OF EXPERIMENTS (ANY SIX)

1. Quincke’s method – Determination of magnetic susceptibility of a liquid. 2. Semiconductor diode - Determination of the forbidden energy gap. 3. Optical Fibre – Determination of Numerical aperture and attenuation loss. 4. Torsional pendulum – Determination of Moment of inertia and Rigidity modulus of the wire. 5. Young’s modulus – non-uniform bending- Determination of Young’s modulus of the material of beam. 6. Spectrometer – Hallow prism – Determination of Refractive index of a liquid. 7. Copper Voltameter – determination of electrochemical equivalent of copper. 8. Lees Disc – Determination of thermal conductivity of bad conductor. 9. LASER grating – Determination of wavelength of laser light. 10. Newton’s Rings – Determination of Radius of Curvature of convex lens.

SCY4051 ENGINEERING CHEMISTRY LAB (Common to ALL Branches of First or

Second Semester B.E / B.Tech.)

L T P Credit Total Marks

0 0 2 1 50

SUGGESTED LIST OF EXPERIMENTS

1. Estimation of ferrous ion by potentiometric method. 2. Determination of pKa value of glycine using pH meter. 3. Estimation of mixture of acids by conductometric method, 4. Estimation of Nickel by using photocolorimeter. 5. Determination of viscosity of polymers by using Ostwald’s viscometer. 6. Estimation of total hardness of water sample by EDTA / AAS method.

SCS4101 PROGRAMMING IN C LAB (For ALL BE/ B.Tech)



1. Program to understand the basic data types and input/output functions. 2. Program for Looping and decision statements. 3. Program on Functions. 4. Program on Arrays. 5. Program on String Manipulations 6. Program on Structures and Union. 7. Program on Pointers. 8. Program to demonstrate the Command Line Arguments. 9. Program using Dynamic memory allocation. 10. Program to implement the Random Access in Files. 11. Program to implement math function. 12. Program to Implement sorting algorithms 13. Program to Implement searching algorithms 14. Programs to solve some of the Engineering applications.

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SHS1101 ENGLISH FOR SCIENCE AND TECHNOLOGY (Common to ALL Branches of B.E/B.Tech)


COURSE OBJECTIVE To equip the learners with English communicative skills to handle the present and future needs by exposing them to situations and tasks in the areas of LSRW, genre and register related to EST by following content based teaching.

UNIT 1 BASIC COMMUNICATION 9 Hrs. Listening for specific information, Self Introduction, Reading Comprehension, Kinds of Sentences, Parts of Speech, Tenses & its Types, Impersonal Passive, Elements of Effective Writing, Letter Writing, Concord, Prefixes & Suffixes

UNIT 2 NUANCES OF EST 9 Hrs. Listening for inference, Describing a process, Cloze Reading and its types, Transcoding - Encoding & Decoding, Flow Chart, Bar chart, Pie Chart, Tabular Column, Tree Diagram, Technical Definitions, Connectives & Discourse Markers, Word Association- connotations

UNIT 3 EST NOW AND THEN 9 Hrs. Listening and Note taking, Role-play, Reading and interpreting visual material (pictures/newspapers) Essay Writing - Note Making - WH questions - Question Tags - Types of sentences - Compound Nouns, Technical Definitions.

UNIT 4 APPLICATIONS OF EST 9 Hrs. Listening and Classifying information, Group discussion, Reading and identifying the topic sentence, - Writing a Project Proposal, Recommendations and Instructions - Manual Writing, Use of abbreviations and acronyms, Editing (Spelling, Grammar, Punctuation) Idioms & Phrases.

UNIT 5 PREPARING FOR FUTURE 9 Hrs. Listening and summarizing, Making presentations on given topics - Giving impromptu talks Reading and Summarizing, E-mail writing, Rearranging the Jumbled sentences Reported Speech, Homophones/Homonyms, Creative Writing & Poster making using similes/metaphors.

Max. 45 Hours TEXT / REFERENCE BOOKS 1. Sangeetha Sharma & Meenakshi Raman, Technical Communication: Principles and Practice. Oxford University Press, New

Delhi, 2011. 2. Sanjay Kumar & Pushp Lata, Communication Skills, 2nd Edition, Oxford University Press, New Delhi, 2011. 3. Nira Konar, Communication Skills for Professionals, PHI Publishers, Eastern Economy Edition, New Delhi, 2011. 4. Sharon J Gerson & Steven M Gerson, Technical Communication: Process and Product, 8th Edition, Orient Longman, 2013. 5. Tyagi Kavita and Misra Padma, Basic Technical Communication PHI Publishers, Eastern Economy Edition, New Delhi, 2011. 6. Nagini,P S et al. Excellence Through communication, Shri Jai Publications, Chennai, 2005.

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 questions of 2 marks each - No choice; with equal distribution to each unit -(10 x 2) 20 Marks

(Task types can include Multiple choice, open ended, gap filling, completion and rewriting the sentences, matching type etc.)

PART B : 2 questions from each unit with internal choice; each carrying 12 marks (5 X 10) 60 Marks (Questions types should testing vocabulary, grammar, reading and writing with equal

distribution to all. For example Reading Comprehension type can include skimming, scanning, comprehensive with evaluative, inferential and hypothetical question/ fixed type questions or cloze exercise , Academic paragraph writing based on Flow chart, Tree diagram, Bar diagram, Table and Pie chart to describe process, comparative and contrast, differentiate , Formal letter writing - Application for a Job & Resume Preparation/ Email- Letter inviting a dignitary-Accepting/Declining (or) Rearranging the jumbled sentences in the right order, (or) Requesting for Practical Training/ Letter to the Editor. Writing a Project Proposal / Project Report (or) Essay Writing- Writing an Essay on a given topic, Summary writing or Making notes in the standard format with title. Grammar Rearranging the jumbled sentences in the right order or editing the paragraph for errors based on syllabus)

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SCH1101 ENVIRONMENTAL SCIENCE AND ENGINEERING

(Common to ALL Branches of B.E/ B. Tech.) L T P Credits Total Marks3 0 0 3 100

COURSE OBJECTIVE To impart knowledge on the issues related to environment and to emphasize the importance of a clean environment

UNIT 1 INTRODUCTION TO ENVIRONMENTAL STUDIES AND NATURAL RESOURCES 10 Hrs. Definition, scope and importance, need for public awareness, forest resources: use and over-exploitation, deforestation, case studies. Timber extraction, mining, dams, floods, drought, conflicts over water, dams-benefits and problems, mineral resources: use effects on forests and tribal people. water resources: use and over-utilization of surface and ground water, exploitation, environmental effects of extracting and using mineral resources, case studies food resources: world food problems, changes caused by agriculture and overgrazing, effects of modern agriculture, fertilizer-pesticide problems, water logging, salinity, case studies. Energy resources: growing energy needs, renewable and non renewable energy sources, use of alternate energy sources: Case studies. Land resources: land as a resource, land degradation, man induced landslides, soil erosion and desertification, role of an individual in conservation of natural resources, equitable use of resources for sustainable lifestyles.

UNIT 2 ECOSYSTEMS AND BIODIVERSITY 10 Hrs. Concept of an ecosystem, structure and function of an ecosystem - producers, consumers and decomposers - energy flow in the ecosystem, ecological succession, food chains, food webs and ecological pyramids. Introduction, types, characteristic features, structure and function of the (a) forest ecosystem (b) grassland ecosystem (c) desert ecosystem (d) aquatic ecosystems (ponds, streams, lakes, rivers, oceans, estuaries). Introduction to biodiversity, definition: genetic, species and ecosystem diversity - biogeographical classification of India - value of biodiversity: consumptive use, productive use, social, ethical, aesthetic and option values, biodiversity at global, national and local levels. India as a mega-diversity nation, hot-spots of biodiversity, threats to biodiversity: habitat loss, poaching of wildlife, man-wildlife conflicts, endangered and endemic species of India, conservation of biodiversity, in-situ and ex-situ conservation of biodiversity.

UNIT 3 ENVIRONMENTAL POLLUTION 9 Hrs. Definition - causes, effects and control measures of: (a) air pollution (b) water pollution (c) soil pollution (d) marine pollution (e) noise pollution (f) thermal pollution (g) nuclear hazards. Solid waste management: causes, effects and control measures of urban and industrial wastes, role of an individual in prevention of pollution, pollution case studies, disaster management: floods, earthquake, cyclone and landslides.

UNIT 4 SOCIAL ISSUES AND THE ENVIRONMENT 8 Hrs. From unsustainable to sustainable development, urban problems related to energy, water conservation, rain water harvesting, watershed management, resettlement and rehabilitation of people; its problems and concerns, case studies, environmental ethics: issues and possible solutions, climate change, global warming, acid rain, ozone layer depletion, nuclear accidents and holocaust, case studies. Wasteland reclamation, consumerism and waste products - environment protection act: air (prevention and control of pollution) act - water (prevention and control of pollution) act, wildlife protection act; forest conservation act. Issues involved in enforcement of environmental legislation, Key initiatives of Rio declaration, Vienna convention, Kyoto protocol, Johannesburg summit and public awareness.

UNIT 5 HUMAN POPULATION AND THE ENVIRONMENT 8 Hrs. Population growth, variation among nations, population explosion, family welfare programme, environment and human health, human rights, value education, HIV / AIDS, women and child welfare, role of information

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SMT1105 ENGINEERING MATHEMATICS - II (Common to ALL branches except BIO Groups)


COURSE OBJECTIVE Analytical, logical thinking and conclusions based on quantitative information will be the main objective of learning this subject.

UNIT 1 MULTIPLE INTEGRALS 13 Hrs. Double integrals in Cartesian and polar co-ordinates - Change the order of integration - Change of variables from Cartesian to polar coordinates- Area of plane curves using double integrals- Triple integrals - Volume using triple integrals in Cartesian co-ordinates (simple applications).

UNIT 2 BETA AND GAMMA INTEGRALS 11 Hrs. Properties of definite Integrals and problems - Beta and Gamma integrals - Relation between them - Properties of Beta and Gamma integrals with proofs - Evaluation of definite integrals in terms of Beta and Gamma function - Simple applications (evaluation of double integrals).

UNIT 3 VECTOR CALCULUS 12 Hrs. Gradient, divergence and curl - Directional derivative - Irrotational and Solenoidal vector fields - Vector Integration - Simple problems on line, surface and volume Integrals, Green’s theorem in a plane, Gauss divergence theorem and Stoke’s theorem (without proofs)- Simple applications involving cubes and rectangular parallelopipeds.

UNIT 4 LAPLACE TRANSFORMS 14 Hrs. Laplace transform - Transforms of standard functions - properties- Transforms of derivatives and integrals - Transforms of the type eatf(t), tf(t), f(t)/t - Transform of periodic functions - Transform of unit step function and impulse function - Inverse Laplace transforms - Convolution theorem - Initial and final value theorems

UNIT 5 APPLICATIONS OF LAPLACE TRANSFORM 10 Hrs. Llinear ordinary differential equation with constant co-efficients - Integral equations - Integral equations of convolution type -simultaneous linear differential equations with constant co-efficients.

Max. 60 Hours

TEXT / REFERENCE BOOKS 1. Kreyszig. E, Advanced Engineering Mathematics, 10th edition, John Wiley & Sons, Singapore, 2012. 2. Grewal B. S, Higher Engineering Mathematics, 41th Edition, Khanna Publications, Delhi,2011. 3. Bali N.P and Manish Goyal, A Text book of Engineering Mathematics, Eigth Edition, Laxmi Publications Pvt Ltd., 2011. 4. Venkatraman M.K, Engineering Mathematics, National Publishing Company, 2000. 5. NarayananS., Manicavachagom Pillay T.K., and Ramanaiah G., Advanced Mathematics for Engineering students, Volume I,

2nd Edition, S. Viswanathan Printers and Publishers, 1992.


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SPH1102 PHYSICS OF ELECTRONIC DEVICES L T P Credits Total Marks3 0 0 3 100

COURSE OBJECTIVE To provide the students the fundamental knowledge in fibre optics, digital electronics and devices such as sensors devices, display devices and nano-devices to enable understanding of its applications.

UNIT 1 FIBRE OPTICS 9 Hrs. Introduction - principle of optical fibre transmission- fibre geometry - acceptance angle and numerical aperture - derivation, types of rays - Types of optical fibres -.Optical fibre materials - plastic and glass fibres- Manufacturing processes - Double crucible technique and vapour phase deposition technique. Transmission characteristics of optical fibres - attenuation and distortion. Fibre splicing - fusion and mechanical splicing. Fibre connectors - butt joint and expanded beam connectors. Optical fibre communication system (block diagram) - advantages and its general applications.

UNIT 2 DIGITAL ELECTRONICS 9 Hrs. Number systems - Binary, decimal, Hexadecimal and Octadecimal - Conversion from one number system to another. Binary addition, Subtraction - Subtraction by 1’s & 2’s complement, BCD addition, Excess 3 code and gray code, ASCII code.

UNIT 3 SENSOR DEVICES 9 Hrs. Introduction - voltage and current sensors, Light Dependent Resistor (LDR), photodiode, strain gauges, thermistor, pressure sensor - Bourdon tube, temperature sensor - thermocouple, magnetic sensor - Hall effect sensor, nanosensors and their applications.

UNIT 4 DISPLAY DEVICES 9 Hrs. Introduction, luminescence, electroluminescence, active display devices, cathode ray tube, light emitting diode, LED materials, passive display devices, liquid crystal displays-working, comparison LED and LCD, plasma display, dynamic scattering display, Touch screen.

UNIT 5 NANO DEVICES 9 Hrs. Definition, Fabrication-Top down approach and bottom up approach. Nanomagnets - Particulate Nanomagnets, Geometrical Nanomagnets, Magneto Resistance - Ordinary Magneto Resistance, Giant Magneto Resistance, Tunneling Magneto Resistance, Injection Laser - Quantum Cascade Laser - Optical Memories and Coulomb Blockade Devices. Max. 45 Hours TEXT / REFERENCE BOOKS 1. Gerd Keiser, Optical fibre communication, 4th Edition, Tata Mc Graw Hill, 2011. 2. John M. Senior, Optical fibre communications - Principle and Practice, 2nd Edition, Pearson Education, 2006. 3. Franz J.H, Jain V.K, Optical communication - Components and Systems, 1st Edition, Narosa Publications, 2001. 4. Rajagopal.K, Text book of Engineering Physics, Part-I, 1st Edition, Prentice Hall of India, 2008 5. Leach, Malvino and Goutam Saha, Digital Principles and applications, 7th Edition, McGraw Hill, 2011. 6. William H. Gothman, Digital electronics - An introduction to theory and practice, 2nd Edition, PHL of India, 2007. 7. Rajendran.V,.Marikani.A, Materials Science, 8th Reprint, Tata McGraw-Hill, 2008. 8. Avadhanulu. M.N. and. Kshirsagar. P.G, Engineering Physics, 2nd Edition, S. Chand & Company, 2007. 9. Neubert H.K.P, On Teaching Sensor Technology, Royal Aircraft Establishment, Great Britain, 1971. 10. Cooper W.D. and Helfrick A.P, Electronic measurement and Techniques, Prentice hall, 3rd Revised Edition, 1985. 11. Wilson J and Hawkers J F B, Optoelectronics - An introduction, 2nd Edition, Prentice-Hall of India, 2001. 12. Bhattacharya. P, Semiconductor optoelectronic devices, 2nd Edition, Prentice Hall of India, 1996. 13. Pole. Jr. C.P and Owens, F.J., Introduction to Nanotechnology, Wiley, 1st Edition, New York, 2003

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 questions of 2 marks each - No choice; 2 questions from each of the five units. 20 Marks PART B : 2 questions from each unit of internal choice; each carrying 12 marks. 60 Marks (Applications mentioned in the syllabus refer to the basic applications and not to any specific case.)

(Maximum of 20 % problems may be asked.)

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SPH1103 ENGINEERING PHYSICS L T P Credits Total Marks3 0 0 3 100

COURSE OBJECTIVE To provide the students with fundamental knowledge in Cryogenics and Acoustics, Properties of Matter such as Elasticity and Viscosity, and enable them to apply relevant principles to solve real world engineering problems.

UNIT 1 LOW TEMPERATURE PHYSICS 9 Hrs. Properties of cryogenic fluids- oxygen, nitrogen, helium and hydrogen - Joule Thomson effect - Porous plug experiment -Production of low temperatures- adiabatic demagnetisation of a paramagnetic salt - Cascade process - Practical applications of low temperatures -Refrigeration and Air conditioning machines - Super fluidity and its applications ( elementary ideas only)

UNIT 2 ELASTICITY 9 Hrs. Introduction-stress and strain diagram -Hooke’s law- types of elasticity- Young’s modulus, Bulk modulus, Rigidity modulus. Poisson ratio - Twisting couple on a cylinder (wire) - torsional pendulum - determination of rigidity modulus. Bending of beams - expression for bending moment of a beam - expression for the depression of the cantilever loaded at the free end - uniform and non-uniform bending-theory and experiment- I form of girders.

UNIT 3 VISCOSITY 9 Hrs. Streamline and turbulent motion, coefficient of viscosity - equation of continuity, Euler’s equation, critical velocity, Reynolds’s number, Poiseuille’s equation for flow of a liquid through a capillary tube - Stoke’s law (statement only)- terminal velocity, Bernoulli’s theorem and applications, Lift of an Aeroplane, Atomizer, Venturi meter, filter pump and Pitot’s tube.

UNIT 4 METAL ALLOYS 9 Hrs. Introduction, classification of metal alloys-Ferrous and Non Ferrous Alloys, Ferrous Alloys- classification, composition, properties and applications; Synthesization of alloy steels-Electric Arc Furnace process (Heroult furnace), Non-Ferrous Alloys - Aluminium, Copper, Titanium, Magnesium alloys - composition, properties and applications, Shape Memory Alloys - Shape memory effect, mechanism, transformation temperature, types of SMA - one way and two way shape memory effect, General applications of SMA.

UNIT 5 ACOUSTICS OF BUILDINGS 9 Hrs. Introduction - musical sound and noise, characteristics of musical sound - pitch, loudness, quality - Weber-Fechner law, decibel scale, sound intensity level and sound pressure level. Sound absorption-OWU, sound absorption coefficient and its measurements - Reverberation - Reverberation time - Standard Reverberation time - Sabine’s formula to determine the Reverberation time (Jaegar method), Factors affecting the acoustics of a building and the remedies, Principles to be followed in the acoustical design of a good auditorium.

Max. 45 Hours TEXT / REFERENCE BOOKS 1. Mathur D.S, Heat and Thermodynamics, Reprint, S. Chand and Co. 2004. 2. Christian Enss and Siegfried Hunklinger, Low temperature Physics, 1st Edition, Springer, 2005. 3. Mathur D.S, Elements of Properties of Matter, Reprint, S.Chand and Co. 2005. 4. Srinivasan M.R, Physics for Engineers, 2nd Edition, New Age international Publishers, 2005. 5. Gaur. R.K. and Gupta. S.L., Engineering Physics, 8th Edition, Dhanbat Rai Publications, 2007. 6. Avadhanulu. M.N. and. Kshirsagar. P.G, Engineering Physics, 2nd Edition, S. Chand and Company, 2007. 7. Willam D Callister, Materials Science and Engineering an introduction, 6th Edition, john-Wiley and Sons, 2004. 8. Rajendran.V, Marikani A., Materials Science, 8th Reprint, Tata McGraw-Hill, 2008. 9. Rajagopal.K, Text book of Engineering Physics, Part-I, 1st Edition, Prentice Hall of India, 2008 10. Kinsler L.E, Frey A.R., Coppens A.B. and Sanders J.V., Fundamentals of Acoustics, 4th Edition, John-Wiley and sons, 2005.

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 questions of 2 marks each - No choice; 2 questions from each of the five units. 20 Marks PART B : 2 questions from each unit of internal choice; each carrying 12 marks. 60 Marks (Applications mentioned in the syllabus refer to the basic applications and not to any specific case.) (Maximum of 20 % problems may be asked.)

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SPH1104 APPLIED BIOPHYSICS L T P Credits Total Marks3 0 0 3 100

COURSE OBJECTIVE To expose the students of biology to some fundamental physics required for study of the measurements of physical properties related to biological systems.

UNIT 1 PROPERTIES OF MATTER 9 Hrs. Viscosity-Newton’s formula-coefficient of viscosity-Factors affecting viscosity-capillary flow method-Stokes method-Biological significance of viscosity-Surface tension-Kinetic theory of surface tension-Factors affecting surface tension-Capillary rise method-Drop weight method-Interfacial surface tension-Biological significance of surface tension.

UNIT 2 LASER PHYSICS 9 Hrs. Absorption, spontaneous emission and stimulated emission-characteristics of laser light-Einstein’s A and B coefficients-principle of laser action-He-Ne laser-CO2 laser-Ruby laser-Nd-YAG Laser-semiconductor laser-applications of laser.

UNIT 3 MICROSCOPES 9 Hrs. Characteristics of light-magnification-Compound microscope-Phase contrast microscope-interference microscope-ultraviolet microscope-Fluorescent microscope-electron microscope-Transmission Electron microscope-Scanning electron microscope-Uses.

UNIT 4 RADIATION BIOLOGY 9 Hrs. Radioactivity-Natural radioactivity-induced radioactivity-Half life-mean life-Radioactive disintegration-units of radioactivity-GM counter-Proportional counter-Scintillation counter-uses of radio isotopes: diagnostic and therapeutic-archeological dating by C14 method-Biological effects of radiation.

UNIT 5 BIOLOGICAL TRANSDUCERS 9 Hrs. Bio-medical instrumentation-transducers-electrodes and bio amplifiers-physiological transducer-pressure transducer-temperature transducer-pulse sensors-respiration sensors-bio-chemical transducers.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. M. A. Subramaniam, Biophysics-principles and techniques, MJP publishers, 2005 2. S. Armugam, Biomedical instrumentation, Anuratha Agencies, 2ndEd., 2006 3. J. Kumar, S. Moorthy Babu, S. Vasudevan, Engineering Physics, Vijay Nicole Imprints Pvt. Ltd, 2006 4. Vasantha Pattabhi, N. Gautham, Biophysics, Narosa Publishing House, 2002 5. Vatsala Piramal, Biophysics, Dominant Publishers and Distributors, 2006 6. D.S.Mathur, Properties of matter, S.Chand Publishing, 11thEd.2005 7. P. Narayanan, Essentials of Biophysics, New Age International, 2ndEd. 2007

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 questions of 2 marks each - No choice; 2 questions from each of the five units. 20 Marks PART B : 2 questions from each unit of internal choice; each carrying 12 marks. 60 Marks (Applications mentioned in the syllabus refer to the basic applications and not to any specific case.) (Maximum of 20 % problems may be asked)

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SCY1102 CHEMISTRY OF ELECTRONIC MATERIALS L T P Credits Total Marks3 0 0 3 100

COURSE OBJECTIVES To know the nature of conducting polymer materials used in electronic industry and to understand the recent analytical techniques for their characterization. To give an idea on the application of computer science in chemistry and the importance of insulating materials in electrical and electronic industries.

UNIT 1 INTRODUCTION TO MOLECULAR ELECTRONICS 9 Hrs. Introduction: Charge transport carriers: Soliton - Polaron and bipolaron. Conducting polymers: Polyacetylene - Polyaniline. Applications of conducting polymers. Polymer Structures for LEDs: Polyphenylenes - Polythiophene. Photoresists for electronics. Molecular devices based on conducting polymers.

UNIT 2 INSTRUMENTAL METHODS OF ANALYSIS 9 Hrs. Introduction - Absorption of radiation. UV-Visible spectrophotometer: Instrumentation - Applications. IR spectrophotometer - Instrumentation - Applications. Thermal methods of analysis: Thermogravimetry (TGA) - Differential Thermal Analysis (DTA) - Differential Scanning Calorimetry (DSC). Sensors: Oxygen sensors - Glucose sensor. Cyclic Voltammetry for Redox systems.

UNIT 3 THIN FILM TECHNIQUES 9 Hrs. Introduction: Lithography. Thin-film deposition: Chemical vapour deposition - Physical vapour deposition: Pulsed laser and atomic layer deposition. Epitaxy: Vapour phase epitaxy - Liquid phase epitaxy - Molecular beam epitaxy. Evaporation: Thermal vaporation and e-beam evaporation. Sputtering techniques: Direct current (DC) sputtering and radio frequency (RF) sputtering. Preparation of Si/Ge semiconductors - Czochralski crystal growth technique: Doping of semiconductors by Ion implantation.

UNIT 4 INSULATING MATERIALS 9 Hrs. Electrical Insulating Materials: Introduction - Requirements. Classification based on substances: Gaseous, liquid and solid insulating materials. Preparation, properties and applications of SF6, Epoxy resin, ceramic products: white wares and glass - Transformer oil. Electrical resistivity: Factors influencing electrical resistivity of materials - Composition, properties and applications of high resistivity materials: Manganin - Constantan - Molybdenum disilcide - Nichrome.

UNIT 5 CHEMIN FORMATICS 9 Hrs. Introduction: Computer representation of chemical compounds: Line notations - Wiswesser line notation - ROSDAL notation - SMILES coding - Advantages and disadvantages of different types of notations. Standard structure exchange formats: Structure of Mol files and SD files. Chemical structure drawing softwares. Molecule editors: CACTVS molecule editor - Chemdraw - ChemSketch - Chemwindow. Searching chemical structure: Similarity search.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Ziaie B., Introduction to Micro/Nanofabrication, Springer, 2010. 2. Andrew Leach, An Introduction to Cheminformatics, Springer, 2009. 3. Johann Gasteiger and Thomas Engel (Ed.), Cheminformatics: A Textbook. Wiley-VCH, 2003. 4. Hagen Klauk, Organic Electronics: Materials, Manufacturing and Applications, Wiley, 2006. 5. Dara S.S., Text Book of Engineering Chemistry, S. Chand & Co, 2008. 6. Sheik Mideen A., Engineering Chemistry (I & II),13th Edition, Shruthi Publishers, 2010. 7. Douglas A. Skoog and Donald M. West, Principles of Instrumental Analysis, 6th Edition, Cengage Learning, 2006.

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 Questions of 2 marks each-No choice 20 Marks PART B : 2 Questions from each unit of internal choice, each carrying 12 marks 60 Marks (Out of 80 marks, maximum of 10% problems may be asked)

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SCY1103 CHEMISTRY OF INDUSTRIAL MATERIALS L T P Credits Total Marks3 0 0 3 100

COURSE OBJECTIVES To know the different types of coal, their analysis and gaseous fuels. To have a basic understanding about terms related to phase rule and its applications to various systems. To understand the requirements, classification of explosives and propellants used in aerospace industries. To provide an idea about lubrication mechanisms, properties and to learn the science of composites and abrasives.

UNIT 1 FUELS 9 Hrs. Fuels: Introduction - Classification of fuels - Characteristics of a fuel - Determination of calorific value of a fuel by Bomb calorimeter. Coal: Classification of coals based on energy content. Chemistry and analysis of coal: Proximate analysis and ultimate analysis. Manufacture of metallurgical coke: Otto-Hoffmann’s method. Cracking: Fluidized bed catalytic cracking. Knocking in compression ignition and spark ignition engines. Gaseous fuels: CNG - LPG - Producer gas. Ethanol as a fuel.

UNIT 2 PHASE EQUILIBRIA 9 Hrs. Introduction: Definition of phase rule - Terms involved in phase rule with examples. One component system: Water system. Two component alloy systems: Classification - Reduced phase rule - Thermal analysis. Simple eutectic system: Lead-silver system. Congruent system: Zinc-magnesium system. Incongruent system: Sodium-potassium system.

UNIT 3 EXPLOSIVES AND ROCKET PROPELLANTS 9 Hrs. Explosives: Requirements - Classification of explosives: Low explosives - Primary explosives - High explosives. Assessment of explosives: Sand bomb test - Drop height - Velocity of detonation. Rocket propellants: Types of rocket engines - Basic principle of rocket propulsion system - Specific impulse (ISP) - Thrust: Momentum thrust and pressure thrust. Requirements of a good propellant. Classification of chemical propellants - Liquid fuels - Liquid oxidizers - Solid fuels - Solid oxidizers.

UNIT 4 LUBRICANTS 9 Hrs. Introduction: Requirements and functions of lubricants. Mechanism of lubrication: Hydrodynamic lubrication - Boundary lubrication - Extreme pressure lubrication. Properties of lubricants: Viscosity index - Cloud point - Pour point - Flash point - Fire point - Oiliness - Sligh oxidation test - Aniline point. Classification of lubricants: Liquid lubricants - Semisolid lubricants - Solid lubricants.

UNIT 5 COMPOSITES AND ABRASIVES 9 Hrs. Introduction: Definition. Constituents of composites: Matrix phase and dispersed phase - Examples. Metal matrix composites: Al matrix; Mg matrix and Ti matrix composites. Ceramic matrix composites: SiC marix and Alumina matrix composites. Polymer matrix composites: Fiber reinforced plastics (FRP) and its types. Application of composites. Cermets: Oxide base cermets - Carbide base cermets - Properties and applications. Abrasives: Definition - Properties: Moh’s scale of Hardness. Classification: Natural and synthetic abrasives. Manufacture of abrasive paper and abrasive cloth.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Jain P. C., and Monica Jain, Engineering Chemistry, 15th Edition, Dhanpat Rai Publishing Co., 2009. 2. Sheik Mideen A., Engineering Chemistry (I & II), 13th Edition, Shruthi Publishers, 2010. 3. Dara.S.S., Text Book of Engineering Chemistry, S.Chand & Co, 2009. 4. Kuriakose J. C., and Rajaram. J, Chemistry in Engineering and Technology, Vol.1 & 2, Tata McGraw Hill Publishing

Company (P) Ltd., 2009. 5. Puri Br., Sharma Lr., Madhan S Pathania, Principles of Physical Chemistry, 41st Edition, Vishal Publishing Co., 2004. 6. Uppal M.M., Engineering Chemistry, 6th Edition, Khanna Publishers, 2006. 7. Agarwal O.P., Engineering Chemistry, 3rd Edition, Khanna Pubishers., 2003.


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SCY1104 BIO ORGANIC CHEMISTRY L T P Credits Total Marks3 0 0 3 100

COURSE OBJECTIVES To understand the fundamentals of classification, synthesis, properties and structural elucidation of carbohydrates, amino acids and proteins. To know the classification and properties of lipids and enzymes. To have overall idea about the structure and biological aspects of steroids, hormones, vitamins and nucleic acids.

UNIT 1 CARBOHYDRATES 9 Hrs. Introduction: Classification: Sugars and Non-sugars. Building up of the sugar series: Aldoses. Conversion of higher to lower homologue and vice versa: Ascending and descending series - Kiliani Fischer synthesis - Ruff degradation. Glucose: Physical properties - Chemical properties: Epimerization - Mutarotation. Structural elucidation of glucose: Open chain and closed chain structure. Structure and biological importance of disaccharides: Sucrose - Maltose - Lactose. Structure and biological importance of polysaccharides: Starch - Cellulose - Chitin - Heparin - Peptidoglycan. UNIT 2 AMINOACIDS AND PROTEINS 9 Hrs. Aminoacids: Classification - α, β, and γ aminoacid - acidic, basic and neutral amino acids - Essential and non essential amino acids. Preparation: HVZ reaction - Strecker synthesis - Gabriel Phthalimide synthesis. Physical properties: Isoelectric point. Chemical properties: Reaction of amino group - Carboxyl group and both. Proteins: Classification based on shape and solubility - Classification based on increasing complexity of structure. Structure of proteins: Primary - Secondary - Tertiary - Quaternary. UNIT 3 LIPIDS AND ENZYMES 9 Hrs. Lipids: Occurrence and classification of lipids - Simple lipids: Fats - Distinction between fats and oils - Occurrence - Properties: Hydrolysis - Auto oxidation - Addition reactions. Analysis of fats and oils: Saponification value and Iodine number. Compound Lipids and Derived lipids. Enzymes: Classification and nomenclature - Enzyme Kinetics: Michaelis-Menton equation. Enzyme activity - Mechanism of enzyme action. UNIT 4 STEROIDS, HORMONES AND VITAMINS 9 Hrs. Steroids: Introduction - Nomenclature. Cholesterol: Constitution (excluding synthesis) and biological importance. Hormones: Introduction - Difference between hormones and vitamins. Classification - Structure and functions of steroid hormones: Androsterone - Progesterone - Testosterone - Estrone. Adrenocortical hormones: Cortisone. Vitamins: Structure and importance of Vitamin D - Folic acid - Nicotinamide. UNIT 5 NUCLEIC ACIDS 9 Hrs. Introduction: Purines and Pyrimidines - Nucleosides and Nucleotides - Nitrogeneous bases - Structure of nucleic acids - DNA, RNA, m-RNA, t-RNA, r-RNA - 70s and 80s - Biological importance of nucleic acids - Sequencing of nucleic acids - Maxam-Gilbert’s method and Sanger’s method. Max. 45 Hours TEXT / REFERENCE BOOKS 1. Jain J. l., Nitin Jain, Sunjay Jain, Fundamentals of Biochemistry, 6th Edition, S. Chand and Sons, 2013. 2. David L. Nelson, Michael M. Cox, Lehninger Principles of Biochemistry, 6th Edition, W. H. Freeman, 2013. 3. Gurdeep R Chatwal, Organic Chemistry of Natural Products Vol II , 2nd Revised Edition, Himalaya Publishing House, 1986. 4. Tewari K.S., Vishnoi N.K. and Mehrotra S.N., A Text Book of Organic Chemistry, 2nd Revised Edition, Vikas Publications, 2004. 5. Rastogi S.C., Biochemistry, 6th Reprint, Tata McGraw Hill Publishing Limited, 2007. 6. Styer L., Biochemistry, . 4th Edition, W.H. Freeman & Co, 1995.


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SCY1105 PHYSICAL CHEMISTRY L T P Credits Total Marks3 0 0 3 100

COURSE OBJECTIVES To understand the fundamentals related to the phase diagrams and their applications. To know about the types and properties of solutions. To expose the students for various separation techniques for the purification of compounds. To provide an idea about the chemical kinetics in terms of order, molecularity and their derivations involved. To give an overview about the advanced electrochemical applications.

UNIT 1 PHASE RULE 9 Hrs. Phase diagram - Information from phase diagram - Terminology used in phase diagram. Gibb’s phase rule - Derivation. One component system: Water system. Two component alloy systems: Classification - Reduced phase rule - Thermal analysis. Simple eutectic system: Lead-silver system. Congruent System: Zinc-magnesium system. Incongruent system: Sodium-potassium system. Phase diagram of simple three component system.

UNIT 2 SOLUTIONS 9 Hrs. Introduction: Solid solution - Hume Rothery’s rule. Types of solid solutions: Liquid solutions: Solubility of partially miscible liquids - Phenol-water system. Colligative properties: Lowering of vapour pressure. Raoult’s law: Derivation - Osmotic pressure - Isotonic solution - Relationship between osmotic pressure and vapour pressure. Depression in freezing point - Derivation. Elevation in boiling point - Derivation - Problems.

UNIT 3 SEPARATION TECHNIQUES 9 Hrs. Distillation techniques: Fractional distillation - Steam distillation - Vacuum distillation. Chromatography: Elution analysis - Paper chromatography - Thin layer chromatography - Liquid chromatography - High performance liquid chromatography (HPLC) - Gas chromatography (GC).

UNIT 4 CHEMICAL KINETICS 9 Hrs. Introduction: First and second order reactions: Integration - Integration of nth order reaction. Methods of determining order and molecularity. Collision theory of bimolecular gaseous reactions - Activated complex of bimolecular reactions - Lindemann theory of unimolecular equation - Kinetics of complex reactions: Reversible reaction - Consecutive reaction - Chain reactions - Autocatalysis - Problems.

UNIT 5 ADVANCED ELECTROCHEMISTRY 9 Hrs. Introduction: Cell constant - Equivalent conductance - Molar conductance. Ionic mobility: Transport number - Moving boundary method - Hittorff’s method. Debye Huckel theory of strong electrolytes. Concentration cells: Types - Concentration cells without transference and with transference. Potentiometric tritrations: Redox titration. Polarography - Applications of polarography. Max. 45 Hours TEXT / REFERENCE BOOKS 1. Puri B.R., Sharma L. R., Madan. S.Pathania, Principles of Physical Chemistry, 41st Edition , Vishal Publishing co., 2004. 2. Keith J. Laidler, Chemical Kinetics, Third Edition, Pearson education limited, 2004. 3. Atkins P. W., Physical Chemistry, 6th edition, Oxford University press, 1998. 4. Barrow G. M., Physical Chemistry, 5th edition, McGraw-Hill, 1988. 5. Glasstone S., A Text book of Physical Chemistry, Macmillan Ltd, 1976. 6. Jayakumar V., Engineering Metallurgy, ARS publications, 2012.


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SEE1105 ELECTRICAL TECHNOLOGY (For ECE, E&C, EIE and ETCE)


COURSE OBJECTIVES To understand and analyze the magnetic circuit. To study the fundamental principle of electrical machines using the concepts of electro-mechanical energy conversion. To learn the principle of operation and performance characteristics of D.C/A.C. Machines and Transformers.

UNIT 1 MAGNETIC CIRCUITS 8 Hrs. Definition of MMF, Flux and Reluctance - Leakage Factor - Reluctances in Series and Parallel (Series and Parallel Magnetic Circuits) - Electromagnetic Induction - Fleming’s Rule - Lenz’s Law - Faraday’s laws - statically and dynamically induced EMF - Self and mutual inductance - Analogy of Electric and Magnetic Circuits.

UNIT 2 DC MACHINES 10 Hrs. Construction, Principles of operation of DC Machines - Types - EMF Equation - Performance Characteristics, of Series and Shunt Generators - DC Motor - Torque - Speed - Torque Characteristics of Series and Shunt Motors - Speed Control and Applications -Auto Transformer.

UNIT 3 TRANSFORMERS 10 Hrs. Constructional Details and Principle of operation of Single Phase Transformer - EMF Equation - Phasor Diagram on No Load and Loaded Transformer - Equivalent Circuit - Open Circuit and Short Circuit Test on Transformer - Regulation and Efficiency.

UNIT 4 INDUCTION MOTORS (QUALITATIVE TREATMENT ONLY) 8 Hrs. Constructional Details of Three Phase Induction Motor - Slip Ring and Squirrel Cage Rotor- Principle of operation- Torque Equation - Torque / Slip Characteristics - Starters - Applications Introduction to Single Phase Induction Motors - Capacitor Start Capacitor Run Motor -Shaded Pole Motor.

UNIT 5 SYNCHRONOUS MACHINES AND SPECIAL MACHINES (QUALITATIVE TREATMENT ONLY) 9 Hrs. Principles of Alternator - Construction Details - Types Special Machines: Stepper motor- AC and DC Servomotor -Universal Motor - Hysteresis Motor -Permanent Magnet Synchronous Motor - Switched Reluctance Motor - Brushless D.C Motor - Construction, Working And Applications.

Max. 45 Hours TEXT / REFERENCE BOOKS 1. B.L.Theraja & A.K.Theraja, “A Text Book of Electrical Technology, VOl II”, S.Chand & Company Ltd., 2009. 2. J.B. Gupta, “ Theory and Performance of Electrical Machines”, S.K.Kataria & Sons, 4th Edition, 2006. 3. R.K. Rajput, “Electrical Engineering” Lakshmi Publications Pvt Limited, 4th Edition, 2008. 4. S.K.Bhattacharya, “Electrical Machines” Tata Mc Graw Hill Company Ltd, 3rd Edition,2008. 5. D.P.Kothari & I.J.Nagrath, “Electrical Machines”, Tata Mc Graw Hill Company Ltd, 3rd Edition,2004, Twelfth Reprint.

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 Questions of 2 marks each - No choice 20 Marks PART B : 2 Questions from each unit of Internal choice, each carrying 12 marks 60 Marks (Distribution may be 80% Theory & 70 % Numerical)

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SIC1101 SENSORS AND TRANSDUCERS (For E&C and EIE)


COURSE OBJECTIVES To motivate the students to study the types and operational characteristics of basic sensors and transducers and their industrial applications. It also focuses to investigate various instrumentation technologies used in sensor and transducer systems. It intends to bring new ideas by introducing recently developed sensors.

UNIT 1 MEASUREMENTS 9 Hrs. General Configuration and functional description of measuring instruments-Characteristics of instrument - Static characteristics - Dynamic characteristics - Types of errors - sources of errors - methods of elimination - Analysis of data - Limiting errors - Relative limiting error - Combination of Quantities with limiting errors - Statistical treatment of data: Histogram, Mean, Measure of dispersion from the mean, Range, Deviation, Average deviation, Standard Deviation, variance.

UNIT 2 BASIC SENSORS 9 Hrs. Difference between Sensors and Transducers - Active and Passive transducers - Selection of Sensors - Sensor for Motion and Position Measurement, GPS, INS, Doppler, SONAR, Thermal Sensors - Gas Thermometric Sensors, Acoustic Temperature Sensor, Thermo-EMF Sensors, NQR Thermometry, Heat Flux Sensor.

UNIT 3 RESISTIVE TRANSDUCERS 9 Hrs. Classification of Transducers- Active and Passive Transducers - Characteristics - Basic Requirements of a Transducer -Mechanical Devices as Primary Detectors-Mechanical Springs, Proving Rings, Potentiometers, Strain Gauges -Theory, Types(includes Rossette), Temperature Compensation, Calibration - Resistance Hygrometer, Photoconductive cell, Hot wire anemometer.

UNIT 4 INDUCTIVE AND CAPACITIVE TRANSDUCERS 9 Hrs. Self inductive transducers, Mutual inductive transducer, Linear variable differential transformer - Eddy current gauge, Proximity sensors, Microsyn, Induction potentiometer, Capacitive displacement transducers - Desirable features of capacitive transducers -Practical capacitive pickups - Equibar differential pressure transducer -Feedback type capacitance proximity pickup - Capacitor microphone

UNIT 5 SMART SENSORS 9 Hrs. Smart sensors: Introduction-Primary sensors, Converters, Compensation, Recent trends in sensor technology - Film sensors - Semi conductor IC technology - Introduction to MEMS - Nano-sensors -SQUID Sensors

Max. 45 Hours TEXT / REFERENCE BOOKS 1. Sawhney A.K., “Electrical & Electronic Measurements and Instrumentation”, Dhanpat Rai Publications,2001 2. Patranabis D., ‘Sensors and Transducers’, Prentice Hall of India, 1999. 3. Doeblin E.O., “Measurement System Applications and Design”, TMH, 5th Edition, 2004. 4. Rangan C.S., Mani V.S.V: and Sharma G.R., “Instrumentation Devices and Systems” Tata McGraw Hill. 5. Renganathan S., “Transducer Engineering” -Allied Publishers Limited 6. Murthy D.V.S., -“Transducer and Instrumentation”, PHI, 1st Edition

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. Part A : 10 questions of 2 marks each - No Choice 20 Marks Part B : 2 Questions from each unit of internal choice, each carrying 12 marks 60 Marks

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SEE4051 ELECTRICAL ENGINEERING LAB (For ECE, ETCE, EIE and E&C)



1. Open circuit characteristics of separately excited dc shunt generator. 2. Load characteristics of self excited dc shunt generator 3. Load characteristics of dc Compound generator 4. Load characteristics of dc shunt motor 5. Speed control of dc shunt motor. 6. Load characteristics of dc series motor 7. Open circuit and short circuit test on single phase transformer. 8. Load test on single phase transformer 9. Brake load test on three phase squirrel cage induction motor 10. Load test on single phase Induction motor 11. Wiring circuits for

a) Calling Bell b) Stair Case c) Fluorescent Lamp d) Basic household wiring using switches, fuses, Indicator – lamps etc.,

SEE4052 ELECTRICAL CIRCUITS &

ELECTRONIC DEVICES LAB (For EEE)



ELECTRICAL CIRCUITS LAB 1. Verification of Kirchhoff’s laws 2. Verification of Theorems 3. Series and Parallel AC circuits 4. R-L and R-C Transients with DC Excitation 5. Series and Parallel Resonance 6. Clippers and Clampers

ELETRONIC DEVICES LAB 1. Characteristics of Semiconductor diode and Zener diodeto find static and dynamic resistance from the

characteristics 2. Characteristics of CB configuration 3. Characteristics of CE configuration 4. Drain and transfer characteristics of JFET. To obtain gain , transconductance and amplification factor 5. Characteristics of SCR find holding current ,break over voltage and holding voltage 6. Characteristics of UJT find intrinsic standoff ratio, Peak voltage and valley voltage 7. Characteristics of LDR with illumination and without illumination 8. Voltage multiplier

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SME4053 ENGINEERING GRAPHICS (Common to CSE, IT, BIO, Chemical & Circuit Branches)


COURSE OBJECTIVE • The student is expected to acquire the drafting proficiency depending on the operational function in order to

perform the day to day activity.

FUNDAMENTALS Use of drafting instruments – BIS – Letttering – Vertical and Inclined – Dimensioning – Aligned and Unidirectional systems – Scaling – Importance of graphics in engineering applications.

GEOMETRICAL CONSTRUCTIONS Dividing a given straight line into any number of equal parts – Bisecting a given angle – Trisecting a right angle – Drawing a regular pentagon and hexagon given one side – Conic sections – Construction of ellipse, parabola and hyperbola by Eccentricity method.

PROJECTION OF POINTS AND PLANE Types of projection - Introduction to orthographic projection – Orthographic projection of points lying in four quadrants – Projection of rectangular, square and circular planes.

PROJECTION OF LINES AND SOLIDS Orthographic projection of lines in first quadrant - Parallel to both the planes – Perpendicular to one plane – parallel to one plane and inclined to other plane – Inclined to both the planes - Orthographic projection of prisms, pyramids, cone and cylinder in first quadrant – Axis perpendicular to HP – Axis perpendicular to VP – Axis inclined to only one plane of projection – Change of position method only.

SECTION OF SOLIDS AND DEVELOPMENT OF SURFACES Sectioning of prisms, pyramids, cylinder and cone in simple vertical positions with cutting planes perpendicular to one plane and parallel or inclined to other plane - Need for development of surfaces – Development of prisms, pyramids, cylindrical and conical surfaces.

ISOMETRIC PROJECTION AND ORTHOGRAPHIC PROJECTION Isometric scale – Isometric View and Isometric Projection of simple solids and combination of solids - Drawing orthographic views (plan, elevation and profile) of objects from their isometric views.

TEXT / REFERENCE BOOKS 1. Natarajan, K.V., “A text book of Engineering Graphics”, Dhalakshmi Publishers, 2006 2. Bhatt, N.D. and Panchal, V.M., “Engineering Drawing”, Charotar Publishing House, 2010 3. Venugopal, K. and Prabhu Raja, V., “Engineering Drawing and Graphics + AutoCAD”, New Age International, 2009. 4. SP 46: “Engineering Drawing Practice for schools and colleges”, Bureau of Indian Standards.

END SEMESTER EXAMINATION QUESTION PAPER PATTERN

By using Mini Drafter 50 Marks (Note: Only after submission of all drawing sheets prescribed by staff member, the students will be allowed for

university practical examination.)

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SMT1201 ENGINEERING MATHEMATICS - III (Common to ALL Branches except BIO Groups, CSE and IT)



UNIT 1 COMPLEX VARIABLES 11 Hrs. Analytic functions - Cauchy- Riemann equations in cartesian and polar form - Harmonic functions - properties of analytic functions - Construction of analytic functions using Milne - Thompson method - Bilinear transformation.

UNIT 2 COMPLEX INTEGRATION 12 Hrs. Cauchy’s integral theorem - Cauchy’s integral formula - problems - Taylor’s and Laurent’s series - Singularities - Poles and Residues - Cauchy’s residue theorem and problems.

UNIT 3 FOURIER TRANSFORMS 12 Hrs. The infinite Fourier transform - Sine and Cosine transform - Properties - Inversion theorem - Convolution theorem - Parseval’s identity - Finite Fourier sine and cosine transform.

UNIT 4 PARTIAL DIFFERENTIAL EQUATIONS 13 Hrs. Formation of equations by elimination of arbitrary constants and arbitrary functions - Solutions of PDE - general, particular and complete integrals - Solutions of First order Linear PDE ( Lagrange’s linear equation ) - Solution of Linear Homogeneous PDE of higher order with constant coefficients.

UNIT 5 THEORY OF SAMPLING AND TESTING OF HYPOTHESIS 12 Hrs. Test of Hypothesis - test of significance - Large samples - Z test - single proportion - difference of proportions - Single mean - difference of means - Small samples - Student‘s t test - single mean - difference of means -Test of variance - Fisher’s test - Chi square test - goodness of fit - independence of attributes.

Max. 60 Hours

TEXT / REFERENCE BOOKS 1. Kreyszig, E., Advanced Engineering Mathematics (8th Edition), John Wiley and Sons (Asia)Pvt. Ltd., Singapore, 2001. 2. Grewal,B.S., Higher Engineering Mathematics, Tata Mcgraw Hill Publishing Co., New Delhi, 1999. 3. Kandasamy, P., Thilagavathy, K., and Gunavathy, K., Engineering Mathematics, (4th Revised Edition), S.Chand&Co., New

Delhi, 2001. 4. Veerarajan,T., Engineering Mathematics Tata Mcgraw Hill Publishing Co., NewDelhi, 1999. 5. S.C. Gupta, V.K. Kapoor, Fundamentals of Mathematical Statistics, S.Chand & Company, 2012.


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SCS1202 OBJECT ORIENTED PROGRAMMING (Common to ALL Branches of B.E/ B. Tech.)


COURSE OBJECTIVES To understand the fundamental concepts of object oriented programming. Be familiar with concepts like abstraction, inheritance, polymorphism. To understand the concept of Classes.

UNIT 1 INTRODUCTION TO OBJECT ORIENTED PROGRAMMING 9 Hrs. Object Oriented Programming Paradigms - Comparison of Programming Paradigms - Object Oriented Languages - Benefits of Object Oriented Programming - Comparison with C - Overview of C++ -Pointers- Functions - Scope and Namespaces - Source Files and Programs.

UNIT 2 CLASSES AND OBJECTS 9 Hrs. Working with classes - Classes and objects - Class specification-Class objects-Accessing class members-Defining class members-Inline functions-Accessing member functions within class-Data hiding-Class member accessibility-Empty classes,

UNIT 3 CONSTRUCTORS AND OVERLOADING 9 Hrs. Default constructors-Parameterized constructors-Constructor overloading-Copy constructors-new, delete operators-”this” pointer-friend classes and friend functions-Function overloading- Unary Operator overloading -Binary Operator overloading.

UNIT 4 INHERITANCE 9 Hrs. Base class and derived class relationship-Derived class declaration-Forms of inheritance-Inheritance and member accessibility- Constructors in derived class-Destructors in derived class-Multiple inheritance-Multi level inheritance-Hybrid inheritance-Virtual base classes-Member function overriding-Virtual functions-Abstract classes-Pure Virtual functions.

UNIT 5 I/O AND LIBRARY ORGANIZATION 9 Hrs. I/O Stream - File I/O - Exception Handling - Templates - STL - Library Organization and Containers - Standard Containers - Overview of Standard Algorithms-Iterators and Allocators.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Balagurusamy, ”Object Oriented Programming with C++”, Tata McGraw Hill,4th Edition,2010 2. Venu Gopal.K.R, Ravishankar.T, and Raj kumar, ”Mastering C++”, Tata McGraw Hill,1999. 3. Bjarne Stroustrup, ”The C++ programming language”, Addision Wesley, 3rd Edition,1998. 4. John R Hubbard, “Programming with C++”, Schaums Outline Series, McGraw Hill, 2nd edition, 2009. 5. James Martin & James J.Odell,”Object Oriented methods-A foundation”,Prentice Hall,1997.


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SEE1107 ELECTRICAL CIRCUITS AND NETWORKS

(For ECE, ETCE and EIE) L T P Credits Total Marks3 1 0 4 100

COURSE OBJECTIVES To impart knowledge on the fundamental principles on analysis of Electrical circuits and two port networks.

UNIT 1 D.C. AND AC CIRCUITS 12 Hrs. Electrical Quantities, Ohm’s Law, Resistors - Series and parallel Combinations, Kirchhoff’s Laws, Node and Mesh Analysis - Sinusoidal Functions - RMS(effective) and Average Values - Phasor Representation - J operator - Sinusoidal Excitation Applied to Purely Resistive - Inductive and Capacitive Circuits - RL - RC and RLC Series and Parallel Circuits.

UNIT 2 NETWORK THEOREMS (BOTH DC & AC) 12 Hrs. Superposition Theorem - Reciprocity Theorem - Thevenin’s Theorem - Norton’s Theorem - Maximum power transfer Theorem.

UNIT 3 NETWORK TOPOLOGY 12 Hrs. Network Topology - Basic concepts of Graph theory, Network Graph, Tree, Incidence & Reduced Incidence Matrices, Cut sets, Tie sets, Cut set schedule, Tie set schedule - Application to network solutions - Duality and Dual Networks.

UNIT 4 NETWORK FUNCTION AND ITS PARAMETERS 12 Hrs. Network Functions - Driving point Impedance - Transfer Functions- Network Parameters - Z,Y, h and ABCD-Parameter Conversion Parameters of Important Networks - Lattice Network - T Network and π Network - Twin Network -Network Conversions - Bartlett’s Bisection Theorem and its Application - Interconnection of Two Port Networks.

UNIT 5 TRANSIENTS AND RESONANCE CIRCUITS 12 Hrs. Time Domain Analysis - Transient Response of RL, RC & RLC networks with DC Input and Sinusoidal AC Input- Series and Parallel Resonance - Frequency Response - Quality Factor and Bandwidth.

Max. 60 Hours TEXT / REFERENCE BOOKS 1. Sudhakar and Shyam Mohan Palli, Circuits and Networks; Analysis and Synthesis, 3rd Edition, Tata McGraw Hill, 2008. 2. John.D.Ryder, Networks Lines and Fields, 2nd Edition, PHI Publications, 2003. 3. Hayt W. H, Jack Kemmerly, Steven Durbin‘”Engineering Circuit Analysis”, Tata McGraw Hill, 8th illustrated edition, 2011. 4. Kuo, ’Network Analysis and Synthesis’, 2nd Edition, PHI, 1995. 5. Soni and Gupta,’Electric Circuits and Analysis’, 5th Edition, Dhanpatrai and Sons, 1995. 6. Umesh Sinha, ‘Network Analysis and Synthesis’, 5th Edition, Sathya Prakashan Publishers, 1985.


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SME1210 SOLID AND FLUID MECHANICS (Common to EEE, E&C and EIE)


COURSE OBJECTIVES The subject of Mechanics of Solids cuts broadly across all branches of engineering profession. At the end of this course, the student will have knowledge about behavior of members To Understand Fluid Properties , flow characteristics and basic governing equations-mass , momentum , energy. To understand the analysis of roto dynamic machines and Velocity Triangles.

UNIT 1 STRESS STRAIN AND DEFORMATION OF SOLIDS, STATES OF STRESS 9 Hrs. Rigid bodies and deformable solids - stability, strength, stiffness - tension, compression and shear stresses - strain, elasticity, Hooke’s law, limit of proportionately, modules of elasticity, stress-strain curve, lateral strain - temperature stresses deformation of simple and compound bars - shear modulus, bulk modulus, relationship between elastic constants - bi axial state of stress - stress at a point - stress on inclined plane - principal stresses and principal planes - Mohr’s circle of stresses

UNIT 2 BENDING AND SHEAR STRESS DISTRIBUTION, TORSION & BEAMS 9 Hrs. Stresses in Beams - Simple bending theory - Composite Beams - Combined bending and Direct stress - Shear stress distribution for Rectangular and I section - Simple Torsion theory - Stresses and deformations in Solid and Hollow circular shafts- Double integration method - Macaulay’s method - Moment area method - Conjugate method for simply supported and cantilever beams, (only point loads & Uniformly distributed loads.)

UNIT 3 SLOPE AND DEFLECTION OF BEAMS 9 Hrs. Flow through orifices: Classification - Hydraulic co-efficient - Flow through rectangular orifice, Notches and weirs. Laminar and Turbulent flow: Reynolds experiment - Major and minor losses in pipes - Darcy Weisbach’s equation, Chezy’s formula - pipes in series and pipes in parallel - total energy line - hydraulic gradient line - Equivalent pipe

UNIT 4 FLUID PROPERTIES & EQUATIONS OF MOTION 9 Hrs. Fluid Properties: Density - Specific Weight - Specific Gravity - Viscosity - Surface tension - Capillarity -compressibility. Fluid Statics: Hydrostatic Law - Pressure Variation in static fluid - Hydrostatic force on a submerged plane-surfaces - Location of hydrostatic force. Manometers - Simple U tube and differential manometers - Buoyancy -Meta-centric height - determination of stability of floating bodies and submerged bodies- Basic equations of motion: Types of fluid flow - Continuity, momentum and energy equations - Euler’s and Bernoulli’s Equation and its applications.-Flow Measurement: Orifice meter, Venturi meter, Piezometer, Pitot Tube.

UNIT 5 PUMPS & TURBINES 9 Hrs. Centrifugal Pumps: Definition - Operations - Velocity Triangles - Performance curves - Cavitations - Multistaging. Reciprocating Pumps: Operation - Slip - indicator Diagram - Separation - Air vessels. Hydraulic Turbines: Classification of hydraulic turbines - Working principle of Pelton wheel, Francis and Kaplan turbines - velocity triangles - draft tube - hydraulic turbine characteristics. Dimensional Analysis: Buckingham’s Theorem, Non-Dimension Numbers, Similarities of Flow- Model studies Max. 45 Hours TEXT / REFERENCE BOOKS 1. Rajput.R.K. “Strength of Materials”4th Edition, S.Chand & co, New Delhi, 2002. 2. Khurmi, R.S, “Strength of Materials“, 23rd Edition,S.Chand & Co, 2008 3. Bansal.R.K,. “Fluid Mechanics & Hydraulics Machines”, 9th Edition,Laxmi Publications, 2005. 4. Kumar K. L., “Engineering Fluid Mechanics”, 8th Edition, Eurasia Publication.2009

END SEMESTER EXAM QUESTION PAPER PATTERN Max Mark: 80. Exam Duration : 3 Hrs. PART A : 10 Questions of 2 marks each- No choice 20 Marks PART B : 2 Questions from each unit of internal choice, each carrying 12 marks 60 Marks

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SEC1204 ELECTRONIC DEVICES AND CIRCUITS (For EIE,CSE and IT)


COURSE OBJECTIVE The objective of this course is to publicize the student with the analysis of Semiconductor diodes and regulators, Transistor biasing circuits, switching characteristics of FET and MOSFET devices, and knowledge on special semiconductor devices.

UNIT 1 SEMICONDUCTOR DIODES 8 Hrs. Intrinsic and Extrinsic semiconductor - charge density, Mobility and conductivity, Drift and diffusion current, Continuity equation, PN junction - Energy band diagram of PN junction, V-I characteristics, Current components in PN junction, Application of diode - Diode switch, Clipper, Clamper, Zener Diode-, V-I characteristics ,Zener Regulator

UNIT 2 TRANSISTORS 8 Hrs. Operation of NPN and PNP transistor - Current components in a transistor, Characteristics of CE,CB,CC configuration - Switching characteristics. JFET- Construction, Operation and Characteristics, Expression for pinch off voltage and drain current - MOSFET- Enhancement and Depletion mode operation and characteristics- Comparison of MOSFET and JFET - Comparison of BJT and JFET.

UNIT 3 BIASING CIRCUITS AND SMALL SIGNAL ANALYSIS 10 Hrs. Biasing Circuit Of BJT, Dc Equivalent Circuit Of BJT, DC And AC Load Lines, Stability Factor Analysis, Equivalent Circuits of transistor - Input-Output Characteristics - Small Signal Equivalent Circuit , Small signal model of JFET and MOSFET.

UNIT 4 SEMICONDUCTOR DEVICES 10 Hrs. SCR- UJT- Diac- Triac - Varactor diode - PIN diode - Tunnel diode - Gunn diode - Principle of photo electronic devices - Solar cell, Photo diode and Photo transistor - LED, LCD, LASER diode, CCD - Operation, Characteristics and Applications.

UNIT 5 RECTIFIERS AND POWER SUPPLIES 9 Hrs. Half Wave Rectifier - Full Wave Rectifier - Bridge Rectifier - Performance of Rectifiers - Filters - Types of Filters - L, C, LC, Filters - Ripple Factor Calculation for C, L, LC Filters - Regulators - Shunt and Series Voltage Regulator - IC Regulator - SMPS - Power Control using SCR.

Max. 45 Hours TEXT / REFERENCE BOOKS 1. Millman and Halkias, “Electronic devices and circuits”, 2nd Edition, McGraw Hill Publication, 2007. 2. G.K.Mithal, “Basic Electronic Devices and circuits”, 2nd Edition, G.K.Publishers Pvt. Ltd., 1998 3. David Bell, “Fundamentals of Electronic Devices and Circuits”, 5th Edition, Oxford University Press 2008. 4. Robert L. Boylestad, “Electronic Devices and Circuit Theory”, 6th Edition, PHI, 1998.. 5. Ben G Streetman and Sanjay Banerjee, “Solid State Electronic Devices”, 6th Edition, Pearson Education, 2005. 6. Gupta. J.B, “Electronic Devices and Circuits”, Katson Publishers, 2009. 7. Salivahanan. S, “Electronic Devices and Circuits”, TMH, 2008.

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A: 10 Questions of 2 marks each-No choice 20 Marks PART B: 2 Questions from each unit of internal choice, each carrying 12 marks 60 Marks

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SEC1207 DIGITAL LOGIC CIRCUITS (For ECE, EEE, EIE, ETCE and E&C)


COURSE OBJECTIVES To publicize the student with the design and analysis of Boolean algebra, logic gates, combinational circuits, sequential circuits, digital logic families and programmable logic devices.On completion of this course the student will recognize

Various number systems and to simplify the mathematical expressions using Boolean functions- simple problems. Implementation of combinational circuits and Design of various synchronous and asynchronous circuits. Expose to various digital logic families and the students to various memory devices and programmable logic devices

UNIT 1 BOOLEAN ALGEBRA AND LOGIC GATES 9 Hrs. Review of number systems - Binary arithmetic - Binary codes - Boolean algebra and theorems - Boolean functions -Minimization of Boolean functions-Sum of Products(SOP)-Product of Sums(POS)-Simplifications of Boolean functions using Karnaugh map and tabulation methods - Logic gates- NAND and NOR implementation.

UNIT 2 DESIGN OF COMBINATIONAL CIRCUITS 9 Hrs. Introduction to Combinational circuits - Analysis and design procedures - Half Adder, Full Adder-Half

Subtractor, Full Subtractor- Parallel binary Adder, Parallel binary Subtractor- Carry look ahead Adder- BCD Adder- Decoders- Encoders-Priority Encoder- Multiplexers- MUX as universal combinational modules- Demultiplexers- Code convertors- Magnitude Comparator.

UNIT 3 DESIGN OF SEQUENTIAL CIRCUITS 9 Hrs. Introduction to Sequential circuits - Flip flops - SR, JK, D and T flip flops, Master Slave flip flops, Characteristic and excitation table - Realization of one flip flop with other flip flops - Registers - Shift registers - Counters - Synchronous and Asynchronous counters - Modulus counters, Up/Down counters - Ring Counter - Johnson Counter - State diagram, State table, State minimization - Hazards.

UNIT 4 DIGITAL LOGIC FAMILIES 9 Hrs. Classification and characteristics of logic family - Bipolar logic family - Saturated logic family - RTL, DTL,DCTL, I2L,TTL, HTL - Non saturated family - Schottky TTL, ECL - Unipolar family - MOS, CMOS logic families. Tristate logic. Interfacing of CMOS and TTL families. Comparison of logic families.

UNIT 5 MEMORIES AND PROGRAMMABLE LOGIC DEVICES 9 Hrs. Classification of memories - ROM - ROM organization - PROM - EPROM - EEPROM - RAM - RAM organization - Write operation - Read operation - Memory decoding - Memory expansion - Static RAM - Dynamic RAM - Programmable Logic Devices - Programmable Logic Array (PLA) - Programmable Array Logic (PAL) - Field Programmable Gate Arrays (FPGA) - Implementation of combinational logic circuits using ROM, PLA, PAL.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Milos Ercegovac, Jomas Lang, “Introduction to Digital Systems”, Wiley publications, 1998. 2. John M. Yarbrough, “Digital logic: Applications and Design”, Thomas - Vikas Publishing House, 2002. 3. R.P.Jain, “Modern digital Electronics”,3rd Edition, TMH, 2003. 4. William H. Gothmann, “Digital Electronics”, Prentice Hall, 2001. 5. Morris Mano, “Digital design”, 3rd Edition, Prentice Hall of India, 2008.


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SEC4076 ELECTRIC CIRCUITS AND

DEVICES LAB (For E&C)



1. Verification of KVL and KCL 2. Verification of Thevenin and Norton Theorems. 3. Verification of Superposition Theorem. 4. Verification of Maximum power transfer and reciprocity theorems 5. Frequency response of series and parallel resonance circuits 6. Coupled Circuits 7. Characteristics of PN and Zener diode 8. Characteristics of CE configuration 9. Characteristics of CB configuration 10. Characteristics of UJT and SCR 11. Characteristics of JFET and MOSFET 12. Characteristics of DIAC and TRIAC 13. Characteristics of Photodiode and Phototransistor

SEC4077 DEVICES AND ELECTRIC CIRCUITS LAB (For EIE)



DEVICES LAB 1. Characteristics of semiconductor diode & Zener diode. 2. Characteristics of CE & CB Configuration. 3. Characteristics of JFET & UJT. 4. Characteristics of LDR & Phototransistor. 5. Characteristics of SCR. 6. Characteristics of Diac & Triac.

ELECTRIC CIRCUITS LAB 1. Verification of Thevenin’s Theorem. 2. Verification of Superposition Theorem. 3. Verification of Reciprocity Theorem. 4. Verification of Compensation Theorem. 5. Verification of Maximum Power Transfer Theorem.

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SCS4201 OBJECT ORIENTED PROGRAMMING LAB (For ALL branches of B.E / B.Tech except ETCE)



1. Develop a C++ program to implement a class, object creation, member function invocation concept. 2. Develop a C++ program to implement the various constructors and destructor concept. 3. Develop a C++ program to implement a friend function, Inline function. 4. Develop a C++ program to implement an operator (Unary & Binary) overloading concept. 5. Develop a C++ program to implement a function overloading concept. 6. Develop a C++ program to implement a run time polymorphism. 7. Develop a C++ program to implement the following inheritance types.

a). Single b). Multiple c). Multilevel d). Hierarchical e). Hybrid

8. Develop a C++ program to implement an Abstract class concept. 9. Develop a C++ program to implement a Virtual function. 10. Develop a C++ program to find the number of characters in a file. 11. Develop a C++ program to handle the exceptions.

Case Study 1. Categorization of living beings as humans, animals, birds, insects, etc.., using inheritance. 2. Develop user defined manipulator for the following named

a. Rupees for displaying Rs. and sets the precision to 2. b. Dollar for displaying $.

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SMT1204 ENGINEERING MATHEMATICS - IV (Common to ALL branches except BIO Groups, CSE & IT)



UNIT 1 FOURIER SERIES 13 Hrs. Definition- Dirichlets conditions- coefficients- Fourier series for the function defined in [c, c+2π],[c, c+2l] - Parseval’s identity ( without proof) - Half range cosine series and sine series of f(x) defined in [0,π],[0,l] - simple problems - Harmonic Analysis.

UNIT 2 APPLICATIONS OF PARTIAL DIFFERENTIAL EQUATIONS 13 Hrs. One dimensional wave equation - Transverse vibrating of finite elastic string with fixed ends- Boundary and initial value problems - Fourier solution - one dimensional heat equation - steady state problems with zero boundary conditions- Two dimensional heat equation - steady state heat flow in two dimensions- Laplace equation in Cartesian form( No derivations required).

UNIT 3 ALGEBRAIC AND TRANSCENDENTAL EQUATIONS 11 Hrs. Solution of Algebraic equation by Regula Falsi Method , Newton Raphson Method - Solution of simultaneous linear algebraic equations - Gauss Elimination Method , Gauss Jacobi & Gauss Seidel Method.

UNIT 4 INTERPOLATION , NUMERICAL DIFFERENTATION & INTEGRATION 11 Hrs. Interpolation- Newton forward and backward interpolation formula- Lagranges formula for unequal intervals- Numerical differentiation- Newton’s forward and backward differences to compute first and second derivatives- Numerical integration - Trapezoidal rule - Simpson’s one third rule and three eighth rule.

UNIT 5 NUMERICAL SOLUTIONS OF ORDINARY DIFFERENTIAL EQUATIONS AND PARTIAL DIFFERENTIAL EQUATIONS 12 Hrs.

Ordinary differential equations - Taylor series method - Runge Kutta method for fourth order- Partial differential equations - Finite differences - Laplace equation and its solutions by Liebmann’s process- Solution of Poisson equation - Solutions of parabolic equations by Bender Schmidt Method - Solution of hyperbolic equations.

Max. 60 Hours

TEXT / REFERENCE BOOKS 1. Kreyszig, E., Advanced Engineering Mathematics, (8th Edition), John Wiley and Sons (Asia)Pte Ltd., Singapore, 2001. 2. Grewal,B.S., Higher Engineering Mathematics, Tata Mcgraw Hill Publishing Co., New Delhi, 1999. 3. Kandasamy, P., Thilagavathy, K., and Gunavathy, K., Engineering Mathematics, (4th Revised Edition), S.Chand&Co., New

Delhi, 2001. 4. Veerarajan,T., Engineering Mathematics, Tata Mcgraw Hill Publishing Co., NewDelhi, 1999


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SMT1206 NUMBER THEORY AND LINEAR ALGEBRA (Common to ALL branches)



UNIT 1 NUMBER THEORY - I 12 Hrs. Divisibility theory in the integers - the division algorithm, the greatest common divisor, the Euclidean algorithm, the Diophantine equation ax + by = c. Primes and their distribution. The fundamental theorem of arithmetic. The sieve of Eratosthenes. The theory of congruences. Basic properties of congruence. Binary and decimal representation of integers. Linear congruences and Chinese remainder theorem. (Sections 2.2, 2.3, 2.4, 2.5, 3.1, 3.2, 4.2, 4.3 & 4.4 of Text 1).

UNIT 2 NUMBER THEORY - II 12 Hrs. Fermat's little theorem and pseudoprimes Wilson's theorem. The sum and number of divisors. The greatest integer function. Euler's phi-function. Euler's generalization of Fermat's theorem. Properties of the phi-function. (Sections 5.2, 5.3, 6.1, 6.3, 7.2, 7.3 and 7.4 of Text 1) (Theorems 7.6 and 7.7 only).

UNIT 3 MATRIX THEORY - I 12 Hrs. Rank of a matrix - Elementary transformation, reduction to normal form, row reduced echelon form. Computing the inverse of a non singular matrix using elementary row transformation. (Section 4.1 to 4.13 of Text 2)

UNIT 4 MATRIX THEORY - II 12 Hrs. System of linear homogeneous equations. Null space and nullity of matrix. Sylvester's law of nullity. Range of a matrix. Systems of linear non homogeneous equations. Characteristic roots and characteristic vectors of a square matrix.

UNIT 5 FUNDAMENTAL THEOREMS ON MATRIX THEORY 12 Hrs. Some fundamental theorem. Characteristic roots of Hermitian, Skew Hermitian and Unitary matrices. Characteristic equation of a matrix Cayley-Hamilton theorem.(Sections 6.1 to 6.6 and 11.1 to 11.3 and 11.11).

Max. 60 Hours

TEXT / REFERENCE BOOKS 1. David M. Burton : Elementary Number Theory, Sixth Edn., TMH. 2. Shanti Narayanan & Mittal : A Text Book of Matrices, Revised edn., S. Chand. 3. C.Y. Hsiung : Elementary Theory of Numbers. Allied Publishers. 4. Neville Robbins : Beginning Number Theory, Second Ed. Narosa. 5. George E. Andrews : Number Theory, HPC. 6. Kenneth Hoffman & Ray Kunze : Linear Algebra, Pearson Education.


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SMT1207 GRAPH THEORY (Common to ALL branches)


COURSE OBJECTIVE The ability to assess and interpret complex situations in mathematical methods of solution is the main objective of this subject.

UNIT 1 GRAPHS AND CONNECTIVITY 12 Hrs. Isomorphic graphs, Ramsey numbers, Independent sets and Coverings, Intersection graphs and line graphs, Operation on graphs, Walks, Trials and Paths, Connected components, Blocks, Connectivity sections 2.4, 2.5, 2.6, 2.7, 2.9, 4.0, 4.1, 4.2, 4.3, 4.4.

UNIT 2 EULER TOURS AND HAMILTON CYCLES 12 Hrs. Eulerian and Hamiltanian graphs (omit Fleury's Algorithm) Trees Sections : 5.0, 5.1, 5.2 (only upto and not including Theorem 5.5), 6.0, 6.1, 6.2.

UNIT 3 MATCHING AND PLANAR GRAPHS 12 Hrs. Matchings and Planarity Sections 7.0, 7.1, 7.2, 8.0, 8.1, 8.2

UNIT 4 GRAPH COLOURING 12 Hrs. Colourability, Chromatic numbers, Five colour theorem.

UNIT 5 DIRECTED GRAPHS 12 Hrs. Chromatic polynomials,Directed graphs, Paths and Connectedness. Sections: 9.0, 9.1, 9.2, 9.4, 10.0, 10.1, 10.2.

Max. 60 Hours

TEXT / REFERENCE BOOKS 1. S. Arumugam & S. Ramachandran, “ Invitation to Graph Theory”, Scitech Publications, Chennai-17. 2. R.J. Wilson, “Introduction to Graph Theory”, 4th ed., LPE, Pearson Education. 3. J.A. Bondy & U.S.R. Murty, “Graph Theory with Applications”. 4. J. Clark & D.A. Holton, “A First Look at Graph Theory”, Allied Publishers. 5. N. Deo, “Graph Theory with Application to Engineering and Computer Science”, PHI.


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SMT1208 APPLIED STATISTICS (Common to ALL branches)


COURSE OBJECTIVE Analytical, logical thinking and conclusions based on quantitative information will be the main objective of learning this subject.

UNIT 1 DESCRIPTIVE STATISTICS 12 Hrs. Univariate data : Skewness and kurtosis- Pearson's and Bowley's coefficient of skewness- moment measures of skewness and kurtosis.

UNIT 2 CORRELATION AND REGRESSION ANALYSIS 14 Hrs. Analysis bi-variate data: Curve fitting-fitting of straight lines,parabola,power curve and exponential curve. Correlation- Pearson's correlation coefficient and rank correlation coefficient - partial and multiple correlation-formula for calculation in 3 variable cases-Testing the significance of observed simple correlation coefficient. Regression-simple linear regression,the two regression lines, regression coefficients and their properties.

UNIT 3 TIME SERIES ANALYSIS 10 Hrs. Time series:Components of time series-measurement of trend by fitting polynomials-computing moving averages-seasonal indices-simple average-ratio to moving average.

UNIT 4 STATISTICAL QUALITY CONTROL 12 Hrs. Statistical Quality control: Concept of statistical quality control,assignable and chance causes,process control. Construction of control charts,3 sigma limits. Control chart for variables-X-bar chart and R chart. Control chart for attributes -p chart, d chart and c chart.

UNIT 5 DESIGN OF EXPERIMENTS 12 Hrs. Analysis of variance : One way and two wayclassifications. Null hypotheses , total, between and within sum of squares. Assumptions-ANNOVATable.

Max. 60 Hours

TEXT / REFERENCE BOOKS 1. Veerarajan. T., “Probability, Statistics and Random Processes”, Tata McGraw-Hill, New Delhi. 2. Goon A.M ,Gupta M.K.& Das Gupta:Fundementals of Statistics .Vol.I The World Press,Calcutta 3. S.C.Gupta & V.K.Kapoor:Fundementals of Applied Statistics Sultan Chand & Sons 4. S.P.Gupta:Statistical Methods, Sultan Chand, New Delhi.


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SMT1209 FOUNDATIONS OF MATHEMATICS (Common to ALL branches)


COURSE OBJECTIVE Understand the basic rules of logic, including the role of axioms or assumptions and appreciate the role of mathematical proof in formal deductive reasoning and able to distinguish a coherent argument from a fallacious one, both in mathematical reasoning and in everyday life.

UNIT 1 SET THEORY - I 13 Hrs. Pre-requisites: Sets, subsets, Set operations and the laws of set theory and Venn diagrams. Examples of finite and infinite sets. Finite sets and the counting principle. Empty set, properties of empty set. Standard set operations. Classes of sets. Power set of a set (Quick review). Cartesian product of two and more sets, relations. Difference and Symmetric difference of two sets. Set identities, Generalized union and intersections (As in section 1.7 of Text book 1).

UNIT 2 SET THEORY - II 12 Hrs. Relations: Product set, Relations (Directed graph of relations on set is omitted). Composition of relations, Types of relations, Partitions, Equivalence relations with example of congruence modulo relation, Partial ordering relations, n-ary relations. (As in Chapter 3 of text book 2 excluding 3.7).

UNIT 3 TYPES OF FUNCTION 13 Hrs. Functions Pre-requisites: Basic ideas such as domain, co-domain and range of functions. Equality of functions, Injection, Surjection and Bijection (Quick review). Syllabus: Identity function, constant functions, product (composition) of functions, theorems on one-one and onto functions, Mathematical functions, Recursively defined functions (As in Chapter 4 of text book 2). Indexed collection of sets, Operations on indexed collection of sets (As in 5.1, 5.2 and 5.3 of text book 2). Special kinds of functions, Associated functions, Algorithms and functions, Complexity of Algorithms (As in Chapter 5.7 of text book 2). Equipotent sets, Denumerable and countable sets, Cardinal numbers (Definitions and examples only as in 6.1, 6.2, 6.3 and 6.5 of text book 2).

UNIT 4 BASIC LOGIC - I 11 Hrs. Basic Logic-1 Introduction, propositions, truth table, negation, conjunction and disjunction. Implications, biconditional propositions, converse, contra positive and inverse propositions and precedence of logical operators. Propositional equivalence: Logical equivalences. Predicates and quantifiers: Introduction, Quantifiers, Binding variables and Negations. (As in Chapter 1 of Text book 1).

UNIT 5 BASIC LOGIC - II 11 Hrs. Basic Logic-2 Methods of proof: Rules of inference, valid arguments, methods of proving theorems; direct proof, proof by contradiction, proof by cases, proofs by equivalence, existence proofs, uniqueness proofs and counter examples. (As in Chapter 1 of Text book 1).

Max. 60 Hours

TEXT / REFERENCE BOOKS 1. K.H. Rosen, “Discrete Mathematics and its Applications” (fifth edition), Tata McGraw Hill Publishing Company, New Delhi. 2. S. Lipschutz, “Set Theory and related topics” (Second Edition), Schaum Outline Series, Tata McGraw-Hill Publishing

Company, New Delhi. 3. P.R. Halmos, “Naive Set Theory”, Springer. 4. E. Kamke, “Theory of Sets”, Dover Publishers.


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SEC1202 DISCRETE ELECTRONIC CIRCUITS (For EIE)


COURSE OBJECTIVES The objective of this course is to publicize the student with the design and analysis of Rectifiers and power supplies, Transistor biasing circuits, Small signal analysis of FET and MOSFET amplifiers, Frequency Response and Multistage amplifiers and Large Signal Amplifiers. On completion of this course the student will recognize.

Analysis of different types of Rectifiers and Power Supplies. Hybrid Model of BJT Amplifiers. Small Signal Model of FET and MOSFET Amplifiers. Frequency response and Multistage Amplifiers. Large Signal Amplifiers.

UNIT 1 SMALL SIGNAL AMPLIFIERS 9 Hrs. BJT amplifiers : CE, CB and CC amplifiers - multistage amplifiers - differential amplifier - designing BJT amplifier networks.(analysis using hybrid -π model) FET amplifiers : CS, CG and CD amplifiers -designing FET amplifier networks Frequency response : low frequency response of BJT and FET amplifiers - Miller effect capacitance - high frequency response of BJT and FET amplifiers.

UNIT 2 LARGE SIGNAL AMPLIFIERS 9 Hrs. Class A, B, C, AB and D type of operation - efficiency of class A amplifier with resistive and transformer coupled load, efficiency class B, complementary symmetry amplifiers - distortion in power amplifiers - Thermal stability of power amplifier.

UNIT 3 FEEDBACK AMPLIFIERS & OSCILLATORS 9 Hrs. Block diagram, Four types of negative feedback connections - voltage series feedback, voltage shunt feedback, current series feedback and current shunt feedback, Oscillators - Classification, Barkhausen Criterion - Analysis of LC oscillators - Hartley, Colpitts, Clapp, RC oscillators - phase shift – Wien bridge - Frequency range of RC and LC Oscillators, Miller and Pierce Crystal oscillators.

UNIT 4 TUNED AMPLIFIERS 9 Hrs. Small signal tuned amplifiers - Analysis of capacitor coupled single tuned amplifier & inductively coupled single tuned amplifier - double tuned amplifier - effect of cascading single tuned and double tuned amplifiers on bandwidth - Stagger tuned amplifiers - large signal tuned amplifiers - Class C tuned amplifier - Efficiency and applications of Class C tuned amplifier.

UNIT 5 WAVE SHAPING AND MULTIVIBRATOR CIRCUITS 9 Hrs. High Pass and Low Pass RC Circuits and their Response for Sine, Step, Pulse, Square, Ramp and Exponential Input. Multivibrators - Astable Multivibrators - Emitter and Collector Coupled - Monostable, Bistable Multivibrators, and Schmitt Trigger Circuits ,Blocking oscillator-Monostable & Astable blocking oscillator.

Max. 45 Hours TEXT / REFERENCE BOOKS 1. S. Salivahanan, N. Suresh Kumar and A. Vallavaraj, “Electronic Devices and Circuits”, 2nd Edition, TMH, 2007. 2. Mithal G.K, “Electronic Devices and Circuits”, Khanna Publishers, 23rd Edition, 2004. 3. David A., Bell, “Solid State Pulse Circuits”, PHI, 2002. 4. Venkatraman R., “Pulse, Digital Circuits and Computer Fundamentals”, Dhanpat Rai, (Paper Back), 2013. 5. Jacob Millman and C. Halkias, “Integrated Electronics, Analog and Digital Circuits and Systems”, McGraw Hill, 1997.

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 Questions of 2 marks each-No choice 20 Marks PART B : 2 Questions from each unit of internal choice, each carrying 12 marks 60 Marks

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SME1208 APPLIED THERMAL ENGINEERING (Common to EEE, EIE and E&C)


3 0 0 3 100

COURSE OBJECTIVE To study about the basic concepts in thermodynamics, compressors and internal combustion engines. To understand the Refrigeration and air conditioning concepts.

UNIT 1 FIRST LAW OF THERMODYNAMICS 9 Hrs. Concepts - concept of continuum, macroscopic approach, thermodynamic systems - closed, open and isolated. Property, state, path and process, quasi-static process, work, modes of work, Zeroth law of Basic thermodynamics - concept of temperature and heat. Concept of ideal gas. First law of thermodynamics - application to closed and open systems, internal energy, specific heat capacities, enthalpy, steady flow process with reference to various thermal equipments.

UNIT 2 SECOND LAW OF THERMODYNAMICS 9 Hrs. Second law of thermodynamics - Kelvin’s and Clausius statements of second law. Reversibility and irreversibility. Carnot theorem, Carnot cycle, reversed Carnot cycle, efficiency, COP, Clausius inequality, concept of entropy, entropy of ideal gas, principle of increase of entropy.

UNIT 3 POWER CYCLES AND INTERNAL COMBUSTION ENGINES 9 Hrs. Air standard cycles - Otto, Diesel and Dual cycles. Derivation of expression for air standard efficiency and mean effective pressure.IC Engines- Introduction-Classification, Comparison between four stroke and two stroke, Performance Testing on internal combustion engines, Performance curves.

UNIT 4 AIR COMPRESSORS 9 Hrs. Positive displacement compressor - reciprocating air compressor, work done, volumetric efficiency, Effect of clearance volume For qualitative treatment- rotary compressors - vane type, roots blower-centrifugal compressor

UNIT 5 HEAT TRANSFER & REGRIGERATION 9 Hrs. Heat transfer-Modes of heat transfer- Fourier law of conduction, one dimensional steady state conduction heat transfer in composite walls. For qualitative treatment- Convection and Radiation Vapour compression refrigeration cycle, Calculation of coefficient of performance. Max. 45 Hours

TEXT / REFERENCES BOOKS 1. Nag P.K, “Engineering Thermodynamics”, 4th Edition, Tata McGraw Hill, 2008 2. Rajput R.K, “Thermal Engineering”, 8th Edition, Lakshmi publications Ltd. New Delhi,2010 3. Rogers and Mayhew, “Engineering Thermodynamics”, 4th Edition, Addison Wesley 1999. 4. Manohar Prasad, “Refrigeration and Air Conditioning”, 2nd Edition, New Age International (P) Ltd, 2003. 5. Domkundwar S, Arora S.C, “A Course in Heat and Mass Transfer, Dhanpat Rai & Sons,2005 6. Ganesan.V., ”Internal combustion Engines”, 3rd Edition, Tata McGraw Hill, 2007

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 Questions of 2 marks each- No choice 20 Marks PART B : 2 Questions from each unit of internal choice, each carrying 12 marks 60 Marks (80% Problem and 20% Theory)

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SEC1208 SIGNALS AND SYSTEMS (For ECE, EIE, ETCE and E&C)


COURSE OBJECTIVES To introduce the concepts and techniques associated with the understanding of signals and systems. To impart Knowledge of time domain representation and analysis concepts as they relate to difference equations, impulse response and convolution, frequency domain representation and analysis concepts using Fourier analysis tools, Z-transform.etc. To Characterize and analyze the properties of CT and DT systems

UNIT 1 CLASSIFICATION OF SIGNALS 9 Hrs. Continuous time signals (CT signals) and Discrete time signals (DT signals) - Basic operations on signals-elementary signals- Step, Ramp, Pulse, Impulse, Exponential - Classification of CT and DT signals - Periodic, aperiodic signals-Deterministic and Random signals-even and odd signals - Real and Complex signals - Energy and power signals.

UNIT 2 ANALYSIS OF CONTINUOUS TIME SIGNALS 9 Hrs. Continuous time Fourier Transform -Properties of CTFT-Inverse Fourier transform- unilateral and bilateral Laplace Transform analysis with examples - Basic properties - Parseval’s relation - Convolution in time and frequency domain-Inverse Laplace transform using partial fraction expansion method - Relation between Fourier transform and Laplace transform-Fourier series analysis.

UNIT 3 LINEAR TIME INVARIANT CONTINUOUS TIME SYSTEMS 9 Hrs. Concept of CT systems - Linear Time invariant Systems - Basic properties of continuous time systems - Linearity, Invertilibity, Causality, Time invariance, Stability - Frequency response of LTI systems - Analysis and characterization of LTI systems using Laplace transform - Differential equation- Computation of impulse response, step response, natural response ,forced response and transfer function using Laplace transform --Convolution integral -Properties of convolution integral.

UNIT 4 ANALYSIS OF DISCRETE TIME SIGNALS 9 Hrs. Spectrum of DT signals, Discrete Time Fourier Transform (DTFT)- Properties of DTFT - z-transform -Basic properties of Z transform - Region of convergence - Properties of ROC - Poles and Zeros - Inverse z-transform using Contour integration - Residue Theorem, Power Series expansion and Partial fraction expansion-Relation between DTFT and Z transform.

UNIT 5 LINEAR TIME INVARIANT DISCRETE TIME SYSTEMS 9 Hrs. Concept of LTI-DT systems - Properties and types of LTIDT systems- causality, stability, invertibility, time invariant, linearity -interconnection of LTI Systems -Difference equation - Computation of Impulse response, Frequency response, step response, natural response, forced response and Transfer function using Z Transform, Convolution Sum using matrix, graphical and tabulation method-Properties of convolution sum.

Max. 45 Hours TEXT / REFERENCE BOOKS 1. Allan V. Oppenheim et al, ‘Signals and Systems, 2nd Edition., Prentice Hall of India Pvt. Ltd., 1997. 2. P.Ramesh Babu et al, ‘Signals and Systems’, 4th Edition, Scitech publishers, 2010. 3. Haykin. S and Van Been. B., ‘Signals and Systems’, 2nd Edition, John Wiley & Sons, 2003. 4. Rao.P, "Signals and Systems", 1st Edition, Tata McGraw Hill, 2008. 5. Lathi, B. P., "Linear Systems and Signals", 2nd Edition, Oxford University Press 2006. 6. Mrinal Mandal, Amir Asif, "Continuous and Discrete Time Signals and Systems", 1st Edition, Cambridge University Press, 2007. 7. Roberts, M.J., "Fundamentals of Signals and Systems", 1st Edition, Tata McGraw Hill, 2007. 8. S. Salivahanan et al., "Digital Signal Processing", 2nd Edition, Tata McGraw Hill, 2009. 9. H P Hsu, "Signals and Systems", 2nd Edition, Tata McGraw Hill, 2008.


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SIC1202 ELECTRICAL MEASUREMENTS AND INSTRUMENTATION (For EIE , E&C)


COURSE OBJECTIVES To equip the students to apply all the types of electrical instruments with the knowledge of construction and working of the instruments which are about to measure

voltage, current, resistance, inductance and capacitance, power and energy magnetic & potentiometeric measurement

UNIT 1 MEASUREMENT OF VOLTAGE AND CURRENT 7 Hrs. Units of voltage and current - principle of operation of D’Arsonval Galvanometer - principle, operation, constructional details and comparison of the following: permanent magnet moving coil, permanent magnet moving iron, Dynamometer, Induction, thermal and rectifier type instruments - Extension of ranges and calibration of voltmeter and ammeters - Errors and compensation.

UNIT 2 MEASUREMENT OF POWER AND ENERGY 7 Hrs. Power measurement - Voltmeter ammeter method, Ammeter voltmeter method, Electro-dynamic wattmeter Theory, errors and compensation methods - Low power factor wattmeter - Power measurement in poly-phase systems - Energy measurement - Single phase and poly phase induction type energy meter - theory and adjustments - DC energy meter - Testing of energy meters - Calibration of wattmeter and energy meter.

UNIT 3 MEASUREMENT OF RESISTANCE, INDUCTANCE AND CAPACITANCE 11 Hrs. Low Resistance: Kelvin's double bridge - Medium Resistance: Voltmeter Ammeter method - Substitution method - Wheatstone bridge method. High Resistance: Megger - Direct deflection method - Megohm bridge method, Loss of Charge method - Earth resistance measurement. Introduction to A.C bridges Sources and Detectors in A.C. bridges. Measurement of Self Inductance: Maxwell's bridge - Hay's bridge, and Anderson's bridge. Measurement of Mutual Inductance: Heavy side M.I bridge - Measurement of Capacitance: Schering's bridge - Sauty's bridge, Measurement of frequency using Wien's bridge.

UNIT 4 POTENTIOMETRIC MEASUREMENT 9 Hrs. DC Potentiometer: Laboratory type, Leeds and Northup potentiometer, Vernier potentiometer, Brooke’s deflection potentiometer -Working principle and applications. AC potentiometer: Dry-scale potentiometer, Gall potentiometer - Working principle and applications, Application of DC and AC potentiometer - Magnetic measurement: Flux meter -Testing of Ring specimen, B-H curve by method of reversal and step by step method, Testing of Bar specimen. Hopkinson’s permeameter - Iron loss measurement by Lloyd Fisher Square

UNIT 5 POLYPHASE METERING 11 Hrs. Blondel's Theorem for n-phase, p-wire system, Measurement of power and reactive kVA in 3-phase balanced and unbalanced systems: One-wattmeter, two-wattmeter and three-wattmeter methods. 3-phase induction type energy meter, Instrument Transformers: Construction and operation of current and potential transformers.

Max. 45 Hours TEXT / REFERENCE BOOKS 1. Sawhney A.K., “A Course in Electrical, Electronic Measurement & Instrumentation”, Dhanpat Rai & sons, 18th Edition, Reprint 2010. 2. Golding E.W. and Widdis. F.C., “Electrical Measurements and Measuring Instruments”, 5th Edition, Wheeler Publications 3. Stout M.B., “Basic Electrical Measurements”, PHI, 1981. 4. Harris F.K., Electrical Measurements”, Wiley Eastern Pvt. Ltd., 1974


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SIC1201 INDUSTRIAL INSTRUMENTATION

(For E&C and EIE) L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVES To make the student familiar with measurement techniques of force, torque and speed To make the student familiar with measurement techniques of acceleration, Vibration and density To make the student familiar with pressure measurement techniques To make the student familiar with temperature measurement techniques

UNIT1 INDUSTRIAL MEASUREMENTS 10 Hrs. Measurement of straightness, flatness, roundness and roughness. Force Measurement - Load cell, different types of load cells - elastic load cell-strain gauge load cell. Torque measurement-Using strain gauge and magneto elastic principle, Speed Measurement - Revolution counter-capacitive tacho-drag up type tacho,D.C and A.C tacho generators - stroboscopic methods. Acceleration Measurement- Elementary accelerometer, Seismic accelerometer, Practical accelerometers.

UNIT 2 TEMPERATURE MEASUREMENT & APPLICATION 9 Hrs. Definition & Standards, Temperature scales, Calibration of thermometers, Bimetallic thermometer, filled- in Thermometers, Vapour pressure thermometers, Resistance thermometers, Thermistors- color code testing and installation procedure, Thermostat, Thermocouples - types and ranges, characteristics, laws of thermocouples, cold junction compensation, IC temperature sensors AD 590, Pyrometers - radiation and optical pyrometers.

UNIT 3 PRESSURE MEASUREMENT 9 Hrs. Manometers - different types of manometers, Elastic pressure transducers, Dead weight Tester, Electrical types, Vacuum gauges - McLeod gauge, Knudsen gauge, Thermocouple gauge, Ionization gauge, Differential pressure Transmitter - electrical & pneumatic types, Complete air supply system for pneumatic control equipment and the different components and their function.

UNIT 4 MEASUREMENT OF FLOW & LEVEL 9 Hrs. Orifice, Venturi, Pitot tube, flow nozzle rotameter, Dahl tube, Positive displacement meter, Turbine flow meter, Electromagnetic flow meter, Ultrasonic flow meter, Open channel flow measurement, Solid flow measurement. Level: Sight glass, float gauge, displacer, torque tube, bubbler tube, diaphragm box, Differential Pressure methods, electrical methods- resistance type, capacitance type, ultrasonic level gauging.

UNIT 5 MEASUREMENT OF DENSITY, VISCOSITY, HUMIDITY 8 Hrs. Hydrometer - continuous weight measurement, liquid densitometer - float principle, air pressure balanced method, using gamma rays - gas density measurements - gas specific gravity measurements - Viscosity terms, saybolt viscometer, rotometer type viscometer, Industrial consistency meters. Humidity terms - dry & wet bulb psychrometers - hot wire electrode type hygrometer, electrolytic hygrometer, Dew point hygrometer.

Max. 45 Hours TEXT / REFERENCE BOOKS 1. Patranabis D., “Principles of Industrial Instrumentation”, Tata McGraw Hill, II Edition, New Delhi, Reprint 2009. 2. Singh. S.K., “Industrial Instrumentation & Control ” 3rd Edition, Tata McGraw Hill, Reprint 2009. 3. Krishnaswamy. K & Vijayachitra. S, “Industrial Instrumentation” New age International, Reprint 2008. 4. Ernest O. Doebelin, Dhanish. N. Manik, “Measurement Systems Application & Design”, TMH, 5th Edition, 2004. 5. Jain R.K, “Mechanical & Industrial Measurements”, Khanna Publishers, 11th Edition, 2004.


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SEC4078 ELECTRONIC CIRCUITS LAB (For E&C)



1. Design of Power Supply circuit with Half wave rectifier with simple capacitor filter.. 2. Design of Power Supply circuit with Full wave rectifier with simple capacitor filter 3. Class A Power Amplifier 4. Design of BJT /FET amplifier 5. Hartley and Colpitts Oscillators 6. Relaxation Oscillator 7. Shunt and Series Voltage Regulators 8. Single / Double tuned amplifier using BJT 9. Cascade / Cascode amplifier 10. Study of Switch mode power supply

SEC4079 ELECTRONIC DESIGN LAB (For EIE)



1. Analysis of transistor biasing circuits 2. Design and testing of half wave rectifier circuit without and with filter 3. Design and testing of full wave rectifier circuit without and with filter 4. Characteristics of series voltage regulator 5. Characteristics of shunt voltage regulator 6. Design and testing of RC coupled transistor amplifier

SIMULATION USING PSPICE (ORCAD) SOFTWARE

1. Simulation of transistor biasing circuits 2. Simulation of series voltage regulator 3. Simulation of shunt voltage regulator 4. Simulation of emitter follower 5. Simulation of FET amplifier 6. Simulation of class A power amplifier

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SEC4080 ELECTRONIC CIRCUITS LAB (For EIE)



1. Design and Testing of Hartley Oscillator. 2. Design and Testing of RC Phase Shift Oscillator. 3. Design and Testing of Colpitt’s Oscillator. 4. Design and Testing of Astable Multivibrator. 5. Design and Testing of Schmitt Trigger. 6. Design and Testing of Tuned Amplifier. 7. Design and Testing of Series Feedback Amplifier. 8. Design and Testing of Shunt feedback amplifiers. 9. Design and Testing of Monostable Multivibrator using PSPICE Simulation. 10. Design and Testing of Bistable Multivibrator using PSPICE Simulation. 11. Design and Testing of Feedback Amplifier using PSPICE Simulation. 12. Design and Testing of Class A Power Amplifier using PSPICE Simulation.

SEC4081 LINEAR AND DIGITAL INTEGRATED CIRCUITS LAB (For E&C)



1. Inverting and Non Inverting amplifier using IC UA741 2. Opamp linear applications (Adder, Subtractor, Differentiator and Integrator) 3. Active filters(Low pass and High pass) 4. Comparator and Schmitt trigger. 5. Wave generators (Square and triangular wave generator). 6. RC Oscillator 7. Study of Instrumentation amplifier. 8. Multivibrator using Timer IC 555 9. PLL as frequency multiplier 10. Study of A/D and D/A converters. 11. Instrumentation Amplifier.

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SEC1314 DIGITAL SIGNAL PROCESSING (For ECE, EIE, E&C and ETCE)


COURSE OBJECTIVES To impart knowledge of signal representation in time domain, Fourier transform, sampling theorem, linear time-invariant system, discrete convolution, z-transform, discrete Fourier transform, discrete filter design, finite word length effects and multi-rate signal processing To analyze signal processing and designing a signal processors (digital filters).

UNIT 1 INTRODUCTION TO SIGNALS AND SYSTEMS 12 Hrs. Representation, Characterization and Classifications of Continuous Time (CT) & Discrete Time (DT) signals, Sampling theorem - Aliasing effect, Operations on DT signals , Convolution, Advantages of DSP over ASP , Classification of CT & DT systems , properties of Discrete time systems-Linearity-Time invariance- causality -stability -Linear time Invariant systems, Difference equation representation of LTI systems-The Z transform- properties of Z transform- Inverse Z transform-System transfer Function.

UNIT 2 DISCRETE FOURIER TRANSFORM (DFT) AND FAST FOURIER TRANSFORM (FFT) 12 Hrs. DFT and its properties, Relation between DTFT and DFT, FFT computations using Decimation in time (DIT) algorithms and Decimation in frequency (DIF) algorithms, Auto correlation, Cross correlation, and their properties. Realization of Discrete Time System: introduction, Basic Realization block diagram and the signal flow graph, Realization of recursive and non recursive systems - Direct Form I and Form II - Cascade and parallel realization.

UNIT 3 DIGITAL FILTER DESIGN 12 Hrs. Design of Digital Filters: General considerations: causality and its implications, characteristics of practical frequency selective filter. Design of FIR filter using window method - Rectangular, Hanning and Hamming Windows. Design of IIR filters using Impulse invariant and Bilinear transformation method. Review of Butterworth and Chebyshev approximations, Frequency selective filters: Ideal filter characteristics, low pass, high pass and band pass filters, Properties of IIR and FIR filters

UNIT 4 FINITE WORD LENGTH EFFECTS 12 Hrs. Fixed point and floating point number representations - Comparison - Truncation and Rounding errors - Quantization noise - derivation for quantization noise power -coefficient quantization error - Product quantization error - Overflow error - Round off noise power - limit cycle oscillations due to product round off and overflow errors - signal scaling.

UNIT 5 MULTIRATE SIGNAL PROCESSING 12 Hrs. Introduction to Multirate signal processing-Decimation-Interpolation- Polyphase implementation of FIR filters for interpolator and decimator -Multistage implementation of sampling rate conversion- Design of narrow band filters - Applications of Multirate signal processing, Speech compression, Adaptive filter, Musical sound processing, Image enhancement.

Max. 60 Hours

TEXT / REFERENCE BOOKS 1. John C. Proakis & Dimities G. Manolakis, “Digital Signal Processing, Algorithm and Applications”, 4th Edition, PHI, 2009. 2. Sanjit K. Mitra, “Digital Signal Processing”, 2nd Edition, TMH, 1997. 3. B.P.Lathi, “Signal Processing & Linear systems”, Oxford, 2000. 4. Lyons, “Understanding Digital Signal Processing”, Addison Wesley, 1999. 5. Rabiner and Gold, “Theory and Application of Digital Signal Processing”, PHI, 1975. 6. Johny R. Johnson, “Introduction to Digital Signal Processing”, PHI, 7. Oppenhein & Schaffer, “Discrete Signal Processing”, PHI, 1975 8. Salivahanan, “Digital Signal Processing, 2nd Edition, TMH, 2010


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SEE1203 CONTROL SYSTEMS (For EEE, ETCE, ECE, EIE and E&C)


COURSE OBJECTIVES To study and familiarize the basic concepts of system design and analysis of system in different domains To analyse the time response of system in steady state To impart knowledge about stability analysis and design of compensators

UNIT 1 SYSTEM CONCEPTS 14 Hrs. Types of System - Open Loop Systems, Closed Loop Systems, Basic Elements in Control System - Mathematical Models of Physical System: Differential Equation- Transfer Functions of Single Input, Single Output and Multi Variable Systems - Simple Electrical Networks, Electrical Analogous of Mechanical Translational and Rotational System - D.C and A.C Servomotor - Mechanical System- Translational and Rotational System - Block Diagram Reduction Techniques - Signal Flow Graphs - Mason’s Gain Formula.

UNIT 2 TIME RESPONSE ANALYSIS OF CONTROL SYSTEMS 10 Hrs. Standard Test Signals -Time Response of First and Second Order System, Time Domain- Specifications - Generalized Error Series - Steady State Error - Static and Dynamic Error Constants.

UNIT 3 STABILITY OF CONTROL SYSTEM 12 Hrs. Characteristics Equation - Location of Roots in S Plane for Stability - Routh Hurwitz Criterion - Root Locus Analysis - Effect of Pole Zero Additions on Root Locus - Nyquist Stability Criterion.

UNIT 4 FREQUENCY RESPONSE ANALYSIS 12 Hrs. Frequency Response of the System - Correlation between Time and Frequency Response - Gain and Phase Margin - Bode Plot - Nyquist Plot (Polar Plot).

UNIT 5 COMPENSATION AND CONTROLLERS 12 Hrs. Introduction to compensation networks - Lag, Lead and Lag Lead networks - Effect of providing Lag, Lead and Lag-Lead compensation on system performance and design using bode plot - P, PI, PID Controllers design.

Max. 60 Hours TEXT / REFERENCE BOOKS 1. I.J.Nagarath and M.Gopal, “Control System Engineering” New Age International (p) Limited Publishers, 2nd edition, 2009. 2. Kausuhio Ogata, “Modern Control Engineering”, Prentice Hall of India PVT. Ltd, 5th edition. 3. Richard Dorf, “Modern Control Systems”, Pearson Education Ltd, 11th Edition 2009. 4. M.N. Bandyo padhyay, “Control Engineering, Theory and Practice” PHI, 4th print, 2006. 5. N.K.Sinha, “Control Systems”, New Age International Private Limited Publishers, 3rd Edition, 1998, reprint 2004. 6. A.Nagoorkani, “Control System”, RBA Publications, 2nd edition, repnit 1998. 7. U.A.Bakshi and S.C.Goyal, “Control System Engineering”, Technical Publication, 2nd Revised reprint 2007.


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SIC1311 BIOMEDICAL INSTRUMENTATION

(For ECE, ETCE, EEE, E&C and EIE) L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVES To familiarize use and requirements of medical instruments To give knowledge of the principle of operation and design of biomedical instruments. An attempt to render a broad and modern account of biomedical instruments. To give an introductory idea about human physiology system .

UNIT 1 ELECTRO PHYSIOLOGY 8 Hrs. Cell and Its Structure - Electrical, Mechanical and Chemical Activities - Action and Resting Potential- Organization of Nervous System - CNS - PNS - Neurons - Axons- Synapse - Propagation of Electrical Impulses along the Nerve-Sodium Pump - Cardio Pulmonary System- Physiology of Heart, Lung, Kidney.

UNIT 2 BIO POTENTIAL ELECTRODES AND TRANSDUCERS 8 Hrs. Design of Medical Instruments - Components of Biomedical Instrument System - Electrodes: Micro Electrodes, Needle Electrodes, Surface Electrodes -Instrumentation amplifier - Biomedical Measurements Like pH, PCO2, PO2 of Blood, Isolation Amplifier, Preamplifier, Current Amplifier, Chopper Amplifier.

UNIT 3 INSTRUMENTS USED FOR DIAGNOSIS 10 Hrs. ECG, Einthoven Triangle, Leads, Electrodes, Vector Cardiograph, Measurement of Cardiac Output, EEG, EMG ,Plethysmography, Blood Flow Measurements, Holter Monitor- Respiratory Rate Measurement - Oximeter, Patient Monitoring System, ICCU.

UNIT 4 MODERN IMAGING SYSTEM 10 Hrs. Ultrasonic Diagnosis, Ultrasonic Scanning, Isotopes in Medical Diagnosis- Pace Makers, Defibrillators, Doppler Monitor(colour), Medical imaging-X-ray generation, Radiographic & Fluoroscopic Techniques - Image Intensifiers-Computer Aided Tomography, PET, SPECT- Laser Applications-Echocardiography-CT Scan-MRI/ NMR-Endoscopy.

UNIT 5 RECENT TRENDS & INSTRUMENTS FOR THERAPY 9 Hrs. Dialysers - Surgical Diathermy - Electro Anaesthetic and Surgical Techniques. Sources of Electric Hazards and Safety Techniques. Single Channel Telemetry, Multi channel Telemetry, Implantable Telemetry, Wireless Telemetry,Telemedicine, Telemedicine Applications.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Khandpur, “Handbook of Biomedical Instrumentation” 2nd Edition, Tata McGraw Hill, 2003. 2. Arumugam M, “Biomedical Instrumentation”, Anuradha Publications, Reprint 2009. 3. Tompkins W J and Webster J G, "Design of Microcomputer Based Medical Instrumentation", Prentice Hall, 1991 4. Geddes L A and Baker L E, "Principle of Applied Biomedical Instrumentation" 3rd Edition, Wiley, 1989 5. Hill D.W, "Principle of Electronics for Medical Research", 2nd Edition, Butterworths, 1965.

END SEMESTER EXAM QUESTION PAPER PATTERN Max Marks : 80 Exam Duration: 3 Hrs. PART A : 10 Questions of 2 marks each-No choice 20 Marks PART B : 2 Questions from each unit of internal choice, each carrying 12 marks 60 MARKS

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SIC1308 INDUSTRIAL UNIT OPERATIONS

(For EIE) L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVES To impart knowledge pertaining to overview of unit operations, To give an idea about distillation and unit operations in transport of solids, liquids & gases and also various unit operations involved in chemical reactors, steam boilers, furnaces, pumps, compressors, extruders, blowers and centrifuges.

UNIT 1 OVERVIEW OF UNIT OPERATIONS 9 Hrs. Introduction to industrial processes - Concepts of unit operations and unit processes - Material balance and energy balance -Types of reactions - General idea of controlling operations

UNIT 2 TRANSPORT OF SOLIDS, LIQUIDS AND GASES 9 Hrs. Study of Unit operation in Transport of Solids, liquids and gases, Different crushers and grinders, Adjusting of particle size, Mixing, Separation, Leaching and extraction

UNIT 3 DISTILLATION, CHEMICAL REACTORS, STEAM BOILERS, FURNACES 9 Hrs. Study of Unit operation in Distillation: Flash distillation, Batch distillation, Continuous distillation, Operational features, construction and working principle of Chemical reactors, Steam boilers, Furnaces.

UNIT 4 DRYERS, CRYSTALLIZERS, EVAPORATORS 9 Hrs. Study of Unit operation in Dryers, Crystallization, Evaporators, Heat exchangers, Humidification, De-humidification - Different types - operational features, construction and working principle

UNIT 5 PUMPS, COMPRESSORS, EXTRUDERS, BLOWERS, CENTRIFUGES 9 Hrs. Study of Unit operation in Pumps, Compressors, Extruders, Blowers, Centrifuges - operational features, construction and working principle

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. McCabe W.L.Smith, J.C.Peter Harriot, Unit operation of chemical engineering, McGraw Hill Inc., 1993 2. Levrspel O, Chemical Reaction Engineering. Wiley, 1972 3. Robert H.Perry and Don Green Perry, Perry's Chemical Engineers' Handbook, 8th Edition, 2007 4. B.G.Liptak, Instrumentation Engineers Hand book: Process Measurement and Process control,


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SIC1305 ELECTRONIC MEASUREMENTS AND

INSTRUMENTATION (For EIE and E&C)


COURSE OBJECTIVES To provide in-depth understanding of operation, performance and applications of important measuring, monitoring and analyzing electronic instruments To impart knowledge on virtual instrumentation

UNIT 1 MEASURING INSTRUMENTS AND WAVEFORM GENERATORS 9 Hrs. Review of DC and AC voltmeter and Ammeter, Ohmmeter, Range Extension, Electronic Multimeters, Types of Voltmeters - Differential type, true RMS type, Vector voltmeter, Signal Generator - Audio and function generators - Pulse Generator, RF signal Generator, Frequency Synthesizer, Arbitrary Waveform Generator, Noise generators -- Pattern generator - Wobbluscope

UNIT 2 DATA CONVERTORS AND CONNECTORS 9 Hrs. ADC and DAC - Specifications, ADC Quantization Error, Types of ADC - Flash, Counter, Successive Approximation, Dual-Slope types and Introduction to Delta-Sigma, Types of DAC - Weighted-Resistor, R-2R ladder and PWM type, ADC and DAC Problems Probes and Connectors - Probes, Test Leads, Shielded Cables, Connectors, Low Capacitance Probes, High Voltage Probes, Current Probes, Special Probes for ICs.

UNIT 3 ANALYZERS AND DIGITAL INSTRUMENTS 9 Hrs. Wave Analyzer, Spectrum Analyzer and Distortion Analyzer, Measurement of Frequency and Time, Decimal Counting Assemblies, Frequency Counter, Period Counter, Counter Errors, Inherent errors, signal related errors, Digital Voltmeters, Digital Multimeters, Computer based digital instruments, IEEE 488 GPIB instruments

UNIT 4 DATA ACQUISITION AND OSCILLOSCOPES 9 Hrs. Data acquisition system, Data loggers, Problems in signal acquisition, Interference and screening, Grounding and Guarding Techniques Introduction- Oscilloscope Block Diagram, Cathode Ray Tube, CRT Circuits, Vertical Deflection System, Triggered sweep, CRO specifications, CRO controls, measurements on CRO, Storage CRO, Digital Storage Oscilloscope, Sampling Oscilloscope

UNIT 5 VIRTUAL INSTRUMENTATION 9 Hrs. Virtual instrumentation - Definition, flexibility - Block diagram and architecture of virtual instruments - Virtual instruments versus traditional instruments -LabVIEW software and Hardware, VI programming techniques - VI, sub VI, loops and charts, arrays, clusters and graphs, case and sequence structures, formula nodes, string and file input / output. LabVIEW applications in Electronic Instrumentation

Max. 45 Hours TEXT/ REFERENCE BOOKS 1. Sawhney A.K, “A Course in Electrical and Electronics Measurements and Instrumentation”, 18th Edition, Dhanpat Rai &

Company Private Limited, 2007. 2. Golding. E. W, and Widdis F.C, “Electrical Measurements and Measuring Instruments”, 5th Edition, A.H.Wheeler &

Company, 2003. 3. Kalsi.H.S, “Electronic Instrumentation”, 2nd Edition, Tata McGraw Hill Company, 2004. 4. Copper. W.D and Helfrick. A.D, “Modern Electronic Instrumentation and Measurement Techniques”, 5th Edition, Prentice Hall

of India, 2002


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SEC1302 ANALOG INTEGRATED CIRCUITS (For ECE, EEE, EIE, ETCE and E&C)


COURSE OBJECTIVES To comprehend the concepts of Op-Amp and its application To study the various Filters and signal generators To acquire knowledge about ADC and DAC To study the basic principles of PLL and Timer Circuit To understand the concept of Special function ICs

UNIT 1 INTRODUCTION TO OP- AMP AND ITS APPLICATIONS 9 Hrs. OP-AMP- DC and AC Characteristics- Input offset voltage- Input bias current-Input offset current- Total output offset voltage- Thermal drift- Slew rate- CMRR -Inverting amplifier- Non-inverting amplifier- Voltage follower- Summing and differential amplifier- Integrator- Differentiator- Logarithmic and Anti logarithmic amplifiers-Comparator and Schmitt trigger.

UNIT 2 FILTERS AND SIGNAL GENERATORS 9 Hrs. First order and Second order Butterworth filters- low pass, high pass, band pass and band reject filters -RC phase shift, Wein’s bridge oscillator- Astable and Monostable multivibrator-Precision half wave and full wave rectifiers.

UNIT 3 A/D AND D/A CONVERTERS 9 Hrs. Sample and Hold circuit - Digital to analog converters: R-2R ladder network and Binary weighted - Characteristics of D/A converters - Analog to digital converters: Flash converter - Successive approximation converter - Dual slope ADC.

UNIT 4 PLL AND TIMER CIRCUITS 9 Hrs. Phase Locked Loop IC 565- Block schematic - Applications of PLL: FM demodulator and Frequency synthesizer-

FSK Demodulator- VCO IC LM 566 - Timer IC LM 555 and its applications: Astable and Monostable multivibrator.

UNIT 5 SPECIAL FUNCTION ICS 9 Hrs. Integrated circuit Tuned amplifier, Instrumentation Amplifier, Series and shunt voltage regulator, Opto coupler, CMOS Operational Amplifier- Dc analysis- small signal analysis- specifications of IC MC 14573.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Ramakant A.Gayakwad, “OP-AMP and Linear ICs”, 4th Edition, Prentice Hall / Pearson Education, 1994. 2. D.Roy Choudary, Shail Jain, “Linear Integrated Circuits”, New Age International Pvt. Ltd., 2000. 3. Grey and Meyer, “Analysis and Design of Analog Integrated Circuits, 4th Edition, Wiley International, 2001. 4. Michael Jacob, “Applications and Design with Analog Integrated Circuits, 2nd Edition, Prentice Hall of India, 1993. 5. S. Salivahanan, V.S. Kanchana Bhaaskaran, “Linear integrated circuits”, 3rd Edition, McGraw-Hill, 2011. 6. William D.Stanely, “Operational Amplifiers with Linear Integrated Circuits”, 4th Edition, Pearson Education, 2004.


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SEC4082 LINEAR AND DIGITAL INTEGRATED CIRCUITS LAB (For EIE)



LINEAR INTEGRATED CIRCUITS

1. Characteristics of Operational amplifier 2. Applications of Operational amplifier: Integrator and Differentiator. 3. Design and testing of square and triangular waveform generators using Op-amps 4. Design and testing of Precision Rectifier. 5. Design and testing of Low pass and high Pass Filters. 6. Design and testing of a 4 bit D/A Converter.

DIGITAL INTEGRATED CIRCUITS

1. Design and testing of an half adder and full adder 2. Design and testing of 1 bit comparator using logic gates. 3. Design and testing of 4 bit shift register 4. Design and testing of 4 : 2 Encoder and 2 : 4 decoder 5. Design and testing of binary to gray and gray to binary code converter.

SEC4083 MICROPROCESSOR AND MICROCONTROLLER

LAB (For E&C)



1. Study of 8 bit Microprocessor and interfacing facilities 2. Programming with 8085 - 8-bit / 16-bit addition and subtraction 3. Programming with 8085 – 8-bit/16-bit multiplication/ division using repeated addition/subtraction 4. Programs for sorting ‘n’ number. 5. Programming with 8085-code conversion. 6. Programming with 8086 - addition, subtraction, multiplication and division 7. Interfacing of D/A and A/D converters using 8085. 8. Interfacing 8279 with 8085 Microprocessor 9. Stepper motor interfacing with 8085 Microprocessor 10. Traffic control interfacing with 8085 Microprocessor 11. 8051 Microcontroller based experiments – Simple assembly language programs 12. 8051 Microcontroller based experiments – simple control applications.

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SIC4051 TRANSDUCER LAB (For E&C)



1. Characteristics of RTD 2. Characteristics of Thermistor 3. Characteristics of Thermocouple 4. Characteristics of

a. Inductive Pickup b. LVDT

5. Characteristics of a. Capacitive Pickup b. DC Potentiometer

6. Characteristics of Strain Gauge 7. Characteristics of

a. Load Cell b. Measurement of Liquid Level Using Load Cell

8. Characteristics of Speed Measurement Sensors 9. Characteristics of LDR and Optocoupler 10. Study of Calibrators 11. Measurement of Resistance Using

a. Kelvin Double Bridge b. Wheatstone Bridge

SIC4052 MEASUREMENTS AND TRANSDUCERS LAB (For EIE)



1. Measurement of Medium Resistance Using Wheat stone’s Bridge 2. Measurement of Low Resistance Using Kelvin’s Double Bridge 3. Measurement of Capacitance Using Schering’s Bridge 4. Measurement of Inductance Using Anderson’s Bridge 5. Characteristics of Potentiometric transducer. 6. Strain Gauge characteristics 7. Load cell characteristics 8. Characteristics of LVDT 9. Characteristics of Thermocouple 10. Temperature measurement using resistive principle 11. Hall Effect Transducer 12. Measurement of speed by using stroboscope

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SIC1306 CONTROL ENGINEERING (For EIE)


COURSE OBJECTIVES To enable the students to learn the concepts of state variable analysis, nonlinear systems To realize the structure of discrete time system

UNIT 1 REVIEW OF MATRICES 12 Hrs. Review of matrices - co-ordinate transformation - Concept of State equation of Dynamic Systems - Eigen values and Eigen vectors - matrix diagonalization - Cayley Hamilton theorem - state transition matrix - Eigen Values and State transitions matrix

UNIT 2 STATE SPACE ANALYSIS 12 Hrs. State space analysis - state space formulation - state space representation of control systems described by scalar differential equation - state variable - transformation of state space equation, physical, phase & canonical variable, state space models - state space representation for discrete time system.

UNIT 3 PHASE VARIABLE MATRIX. 12 Hrs. Jordan and canonical forms, controllability and observability - condition for controllability and observability, Gilbert method and Kalman decomposition - design of state feedback by pole placement. Controllable phase variable form, observable phase variable form, reduced order observer - full order observer - reducibility, irreducibility, transfer function matrix, impulse response functions,Matlab programming Controllability and observability

UNIT 4 NON-LINEAR SYSTEM ANALYSIS 12 Hrs. Non-linear systems - properties of non linear system - describing function for simple non linearity’s like on-off, dead zone and saturation - describing function analysis of non linear systems - Limit cycles - phase plane method - basic concept - singular points - constructing phase plane trajectory for linear and nonlinear second order systems - Isocline method

UNIT 5 DESIGN OF DISCRETE TIME CONTROL SYSTEM (FOR DISCRETE SYSTEM) 12 Hrs. Sampled data theory - Sampling process - Sampling theorem, Sample and hold circuits - Zero Order Hold Z-Transform - Theorems on Z-Transforms - Inverse Z-Transforms - Discrete systems and solution of difference equation using Z transform - Pulse transfer function - Response of sampled data system to step and ramp input, Stability studies - Jury’s test, bilinear transformation, Schur Cohn Stability Max. 60 Hours

TEXT/ REFERENCE BOOKS 1. Gopal.M, “Modern Control Theory”, 2nd Edition, Wiley Eastern Publishers, 1993. 2. Tou.T.J. “Modern Control Theory”, McGraw Hill publications, 1964. 3. Ogata.K.H, “State Space Analysis of Control Systems”, Prentice Hall Publications, 1967. 4. Nagrath I.J. & Gopal.M, “Control Systems Engineering”, 2nd Edition, Wiley & Sons, 1985 5. Nagroor Kani “Advanced Control system”, McGraw Hill publications, 1964. 6. Deshpande P.B. & Ash R.H, “Elements of Computer Process Control”, Instrument Society of America 1981.


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SEC1309 MICROCONTROLLERS AND EMBEDDED SYSTEMS (For EIE)


COURSE OBJECTIVES To impart basic knowledge about 8051 and PIC microcontrollers. To introduce about microcontroller interfacing with external systems. To provide basics of 8051 and PIC programming with the knowledge of instructions and interfacing chips.

UNIT 1 ARCHITECTURE OF 8051 9 Hrs. Comparison of Microprocessor and Microcontroller - Block diagram of Microcontroller -Architecture of 8051- Pin details of 8051 - Memory Organization of 8051 - Special function registers - Interfacing of external Memory- I/O Ports- Oscillator and Clock - Timer - Interrupts - Serial Port.

UNIT 2 INSTRUCTION SET OF 8051 8 Hrs. Addressing modes of 8051- Instruction set of 8051 - Classification of 8051 Instructions - Data transfer instructions - Arithmetic Instructions - Logical instructions -Branching instructions - Bit Manipulation Instructions -Simple programs with 8051.

UNIT 3 PIC MICROCONTROLLER 10 Hrs. PIC Microcontrollers and Instruction Set: PIC Micro-controllers - overview; features, PIC-18Fxxx

architecture, file selection register, Memory organization, Addressing modes, Instruction set, Interrupt handling. PIC-18Fxxx - Reset, low power operations, oscillator connections, I/O ports - serial; parallel, Timers, Interrupts, ADC.

UNIT 4 INTRODUCTION TO EMBEDDED SYSTEM 10 Hrs. Embedded system- characteristics of embedded system- categories of embedded system- requirements of embedded systems- challenges and design issues of embedded system- trends in embedded system- system integration- hardware and software partition- applications of embedded system- control system and industrial automation-biomedical-data communication system-network information appliances- IVR systems- GPS systems.

UNIT 5 EMBEDDED SOFTWARE DEVELOPMENT AND TOOLS 8 Hrs. Software architectures, Round - Robin, Round-Robin with Interrupts, Function Queue Scheduling architecture, Introduction to assembler - Compiler -Cross compilers and Integrated Development Environment IDE, Linker/ Locators, Simulators, Getting Embedded software into target System- Debugging Strategies.

Max. 45 Hours TEXT / REFERENCE BOOKS

1. Mazidi & McKinlay, “The 8051 Microcontroller and Embedded Systems using Assembly and C”, PHI. 2. Myke Predko, “Programming and Customizing the 8051 Micro-controller”, Tata McGraw-Hill edition. 3. R A Gaonkar, “Fundamentals of Microcontrollers and Applications in Embedded Systems (with the PIC18 Microcontroller

Family)”, Penram Publishing India. 4. Kenneth Ayala ,”The 8051 Microcontroller”, 3rd Edition,Thomson Delmar Learning, 2004. 5. Kenneth J. Ayala, Dhananjay V. Gadre, “The 8051 Microcontroller & Embedded Systems Using Assembly and C”, Cengage

Learning India Publication. 6. Ajay V Deshmukh, “Microcontrollers: Theory and Applications”, Tata McGraw-Hill, 2005. 7. K.V. Shibu, “Introduction To Embedded Systems”, Tata McGraw, 2009. 8. Raj Kamal, “Embedded Systems Architecture, Programming, and Design”. (2/e), Tata McGraw Hill, 2008. 9. Technical references on www.mikroe.com. 10. Technical references on www.microchip.com.

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 Questions of 2 marks each-No choice 20 Marks PART B : 2 Questions from each unit with internal choice, each carrying 12 marks 60 Marks

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SIC1307 PROCESS CONTROL INSTRUMENTATION

TECHNOLOGY (For EIE)


COURSE OBJECTIVES To gain knowledge in modeling and characteristics of various processes and process controllers, controller tuning methods, complex control schemes, various instruments and their characteristics in process control To design digital control algorithms.

UNIT 1 MATHEMATICAL MODELING OF PROCESSES 9 Hrs. Introduction of Process control - Need for Process Control, Elements of process control system, Process variables, Degrees of Freedom, Process Lag - Mathematical model of first order Liquid level, pressure and thermal processes - Higher order process - Response of Interacting and Non-Interacting liquid level systems - Dynamic system with dead time and Inverse response - Concept of servo and regulator operation.

UNIT 2 CHARACTERISTICS OF PROCESS CONTROLLERS 9 Hrs. Basic control modes - Characteristics and Response of On-Off, Proportional, Integral, Derivative control modes - Composite control modes - Characteristics and Response of P+I, P+D and P+I+D control modes - Pneumatic and Electronic controllers to realize various control actions - Integral windup - Control Lag - Selection of Control modes for Different processes.

UNIT 3 CONTROLLER TUNING & ADVANCED CONTROL LOOP SCHEMES 9 Hrs. Evaluation criteria - IAE, ISE, ITAE and 1/4 Decay ratio - Types of Controller tuning - Process reaction curve method, Ziegler Nichols I and II method Control loop Schemes - Feed forward control, Cascade control, Ratio control, Split-range control, Adaptive control, Inferential control and Multivariable control - Interaction of control loops, Non interacting control loops, Relative gain array, Concepts of De-coupler.

UNIT4 PROCESS CONTROL INSTRUMENTS AND ITS CHARACTERICS 9 Hrs. I/P and P/I Converter - Final control element - Pneumatic, electric and hydraulic actuator - Valve positioner, Control valves -Characteristics of control valve - Inherent and installed characteristics - Types of control valve Globe, Butterfly valves, Diaphragm and Ball valve - Control valves sizing - Cavitations and flashing in control valves,Selection criteria.

UNIT5: DIGITAL CONTROL ALGORITHMS FOR PROCESS CONTROL 9 Hrs. Design of Deadbeat Algorithm, Dahlin’s Algorithm, Kalman’s Estimation - Predictive Controller - MPC - Linear and Nonlinear - Smith Predictor Algorithm. Max. 45 Hours TEXT / REFERENCE BOOKS 1. Stephanopoulos C, “Chemical Process Control”, Prentice Hall of India Pvt Ltd, 2005 2. Eckman. D.P, “Automatic Process Control”, Wiley Eastern Ltd, 1972. 3. Curtis D Johnson, “Process Control Instrumentation Technology”, John Wilsey & Sons, 2004. 4. Deshpande P.B. & Ash R.H, “Elements of Computer Process Control”, Instrument Society of America 1981. 5. Shanthi Sasidharan, “Computer Control of Process”, CBA Publishers, 2011. 6 Harriot. P., “Process Control”, Tata McGraw Hill, 1984. 7. B.G.Liptak, “Instrumentation in Process Industries”, Vol. 1 & 2, Chilton Book & Co. 1974. 8. Coughanowr. D.R., “Process System Analysis and Control”, 2nd Edition, John Wiley & Sons, 1991. 9. Shinskey. F.G., “Process Control System”, 3rd Edition, McGraw Hill, 1991. 10. Liptak. B.G., “Process Control”, Chilton Book & Co, 2001


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SIC1310 THEORY OF ROBOTICS

(For ECE, ETCE, EEE, E&C, EIE and BIO-MED) L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVES To introduce basic concepts of various dynamics processes To educate on the effect of various power sources and sensors. To impart knowledge on the manipulators , grippers and robot dynamics To introduce the evaluation criteria and tuning techniques of controllers To introduce the concept of multi loop control techniques

UNIT 1 BASIC CONCEPTS 9 Hrs. Origin & various generation of Robots - Robot definition - Robotics system components - Robot classification Coordinate frames - Asimov’s laws of robotics - degree of freedom - dynamic stabilization of robots.- work volume. Need for Automation - types of automation - fixed, programmable and flexible automation.

UNIT 2 POWER SOURCES AND SENSORS 9 Hrs. Hydraulic, pneumatic and electric drives - determination of HP of motor and gearing ratio - variable speed arrangements - path determination - micro machines in robotics - machine vision - ranging - laser - acoustic - magnetic, fiber optic and tactile sensors.

UNIT 3 MANIPULATORS, ACTUATORS, GRIPPERS and ROBOT DYNAMICS 9 Hrs. Construction of manipulators - manipulator dynamics and force control - electronic and pneumatic manipulator control circuits - end effectors - various types of grippers - design considerations. Introduction to Robot Dynamics - Lagrange formulation - Newton Euler formulation - Properties of robot dynamic equations.

UNIT 4 KINEMATICS AND PATH PLANNING 9 Hrs. Forward Kinematics - Denavit Hartenberg Representation. multiple solution jacobian work envelop, Inverse Kinematics - Geometric approach. Hill climbing techniques.

UNIT 5 PROGRAMMING LANGUAGES AND APPLICATIONS 9 Hrs. Robot programming - Fixed instruction, sequence control, General programming language, Specific programming languages. Robots for welding, painting and assembly - Remote Controlled robots - robots in manufacturing and non- manufacturing applications - Robots for nuclear and chemical plants.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Mikell P. Weiss G.M., Nagel R.N., Odraj N.G., “Industrial Robotics”, McGraw-Hill Singapore, 1996. 2. Ghosh, “Control in Robotics and Automation: Sensor Based Integration”, Allied Publishers, Chennai, 1998. 3. Deb.S.R., “Robotics technology and flexible Automation”, John Wiley, USA 1992. 4. Asfahl C.R., “Robots and Manufacturing Automation”, John Wiley, USA 1992. 5. Klafter R.D., Chimielewski T.A., Negin M., “Robotic Engineering - An integrated approach”, Prentice Hall of India,

New Delhi, 1994. 6. Mc Kerrow P.J. “Introduction to Robotics”, Addison Wesley, USA, 1991.


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SEC1306 DATA COMMUNICATION AND NETWORKING (For ECE, EIE and ETCE)


COURSE OBJECTIVES The aim of the course is to provide

The basic details about the data communication and networking A clear understanding of various IEEE networking standards An in depth knowledge about the various layers of ISO model data communication system

UNIT 1 DATA COMMUNICATION- BASICS 9 Hrs. Digital data - digital signals - Bit rate - Bit length - Data rate limits - noise less channels - Noisy channel - Shanon capacity - Performance - Bandwidth - throughput - latency - Bandwidth delay product - jitters. Circuit switched networks - Datagram networks - virtual circuit networks - connection oriented and connection less services - Structure of circuit switches and packet switches - OSI reference model - TCP/IP reference model - comparison of both models.

UNIT 2 NETWORKING 9 Hrs. Network Topologies - mesh, star, bus, and ring - hybrid topology - Network Standardization - De facto and De jure standards of networks - ITU - ISO - IETF - NIST - IEEE - Different IEEE802 working groups - internet- Architecture of the internet - Third generation mobile networks - UMTS Architecture - Wired Ethernet - Wireless LANs IEEE 802.11 - RFID - Different types - sensor networks - Multi hop topology of sensor networks.

UNIT 3 PHYSICAL LAYER AND DATALINK LAYER 9 Hrs. The Physical layer - Media - Twisted pair - coaxial cable - microwave - infrared - millimetre wave - PSTN - The local loop modem - ADSL - Switching - Internet over cable - cable modems The Data link layer - design issues - Error detection and control - data link protocols - HDLC - PPP - IEEE standards for data link layer.

UNIT 4 MAC SUB LAYER AND NETWORK LAYER 9 Hrs. MAC sub layer for Standard Ethernet, Fast Ethernet, Wireless LAN and broadband wireless.Design issues of network layer - Routing algorithm - shortest path routing - Distance vector routing - Broadcast routing - Congestion control algorithm - Congestion control in virtual circuit and datagram switches - The network layer in the internet - The IP protocol - IP Addresses - Mobile IP - IPv6.

UNIT 5 TRANSPORT LAYER AND APPLICATION LAYER 9 Hrs. The transport layer - service provided to the upper layer - Elements of transport protocols - Addressing - connection establishment - connection release - UDP - TCP TELNET - E mail - The user agent - Message transfer agent-SMTP - Message access agent: POP and IMAP - File Transfer Protocol - HTTP - SNMP - VOIP.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Andrew S Tanenbaum “Computer Networks” 5th Edition. Pearson Education/PHI/2011. 2. Behrouz A. Forouzan, “Data Communications and Networking” Fourth Edition, Mc GrawHill HIGHER Education 2007. 3. Michael A.Gallo, William Hancock.M, Brooks/Cole Computer Communications and Networking Technologies,2001 4. Richard Lai and Jirachief pattana, “Communication Protocol Specification and Verification”, Kluwer Publishers, Boston, 1998. 5. Pallapa Venkataram and Sunilkumar S.Manvi, “Communication protocol Engineering”, PHI Learning, 2008


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SEC4084 MICROPROCESSOR AND MICROCONTROLLER

LAB (For EIE)



1. Addition & Subtraction of 8 & 16 bit using 8085 using Indirect Addressing mode. 2. Multiplication & Division of 8 & 16 bit using 8085. 3. Interfacing of Stepper motor using 8085. 4. Interfacing of Traffic light using 8085. 5. Arithmetic operation of 16 bit data using 8086. 6. Largest number in an array using 8086. 7. Sorting using 8086. 8. Moving block of data using 8086. 9. Arithmetic operation of 8 bit data using 8051. 10. Code conversion using 8051: a. BCD to HEX b. HEX to BCD 11. Interfacing of ADC using 8051. 12. Interfacing of DAC using 8051.

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SIC4053 PROCESS CONTROL LAB (For EIE)



1. Characteristics of I/P converter and P/I converter. 2. Characteristics of Control valve. 3. Study and control of a Level process using ON-OFF, P, PI, PD, PID controllers. 4. Study and control of a Pressure process using ON-OFF, P, PI, PD, PID controllers. 5. Study and control of a Flow process using ON-OFF, P, PI, PD, PID controllers. 6. Study and control of a Temperature process using ON-OFF, P, PI, PD, PID controllers. 7. Verification of logic gates using PLC. 8. Study of DCS. 9. Cascade Control. 10. Ratio Control. 11. Interacting and Non-Interacting System. 12. Tuning of Controller using Ziegler- Nicholas Method.

SIC4054 MEASUREMENTS LAB (For E&C)



1. Measurement of Inductance using Anderson’s bridge 2. Measurement of Capacitance using Schering’s bridge 3. Calibration of ammeter, voltmeter and wattmeter using potentiometer 4. Calibration of wattmeter at different power factors 5. Calibration of Energy meter 6. Testing of current transformers 7. Design, construction and calibration of series and shunt type ohmmeters 8. Measurement of voltage, frequency using CRO 9. Measurement of phase difference by CRO using Lissajous figures 10. Measurement of angular displacement using potentiometer 11. AC servo motor speed torque characteristics 12. PC based data logging 13. Study of power measurement using VI or IV method.

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SIC1404 INSTRUMENTATION IN INDUSTRIES


COURSE OBJECTIVES To introduce the complete operation of various industries To provide an exposure to the process and instrumentation & control applications in various industries like paper, petrochemical, iron and steel, mining, pharmaceutical, nuclear and power plant industries.

UNIT 1 OVERVIEW DESCRIPTION OF INDUSTRIAL PROCESSESS 11 Hrs. Description of process in Paper Industries Description of process in petrochemical industries: Description of process in iron and steel and mining industries - Description of process in pharmaceutical and nuclear industries.

UNIT 2 INSTRUMENTATION IN PAPER INDUSTRIES 7 Hrs. Measurement of Basic weight, thickness, density, Porosity, smoothness, softness, hardness and compressibility; selection of suitable measurement hardware for flow, pressure, level, temperature, density, solids, consistency - moisture analyzers oxidation - reduction potential and pH.

UNIT 3 INSTRUMENTATION IN PETROCHEMICAL INDUSTRIES 7 Hrs. P & I diagram of petroleum refinery, measurement and control of absolute pressure, density, conductivity, differential pressure and flow of evaporators. Measurement and control of column pressure, liquid distillate, vapour distillate.

UNIT 4 INSTRUMENTATION IN IRON AND STEEL AND MINING INDUSTRIES 11 Hrs. Iron and steel: Selection of suitable measurement hardware for temperature, pressure, level, flow, weighing and proportioning - special gauges for measurement of thickness and shape Mining Industry: Weighing - conveyor belts - metal detectors - level sensors - nuclear density detectors - flow meters, Coal analyzer - thermogravimetri - gross calorific value - total sulphur analysis - ash analyser - online monitor- air quality monitoring- Sampling of ambient air - general air sampling system - Flue gas oxygen analyzer - analysis of impurities in feed water and steam - dissolved oxygen analyzer - chromatography - pH Meter - pollution monitoring instruments

UNIT 5 INSTRUMENTATION IN PHARMACUETICAL, NUCLEAR & POWER PLANT INDUSTRIES 9 Hrs. Pharmaceutical Industries: Flow measurement - pressure measurement - smoke detector Nuclear Industries: Radiation detection instruments - Area monitors and in-place detectors - Temperature measuring devices - level sensors Power Plant Industries: Metal temperature measurements, flow of feed water - fuel, air, steam with correction factor for temperature and pressure

Max. 45 Hours TEXT / REFERENCE BOOKS 1 Liptak B G, “Instrumentation in the processing industries”, Chilton book Company, 1973. 2. Considine D. M., “Process/Industrial Instruments and control Handbook”, McGraw Hill, 5th edition 1999. 3. Hower P. Kallen, “Hand Book of Instrumentation and Control”, Tata McGraw Hill, 1961. 4. Liptak B G, “Instrument Engineer’s Handbook, Vol. 2: Process Control and Optimization”, CRC Press, 2006. 5. BaskaraRao, “Petrochemicals”, Khanna Publishers, New Delhi, 1987. 6. Liptak B.G, “Process Measurement and Analysis”, Third Edition, Chilton Book Co., 2003 7. Considine D. M, “Hand Book of Applied Instrumentation”, Tata McGraw Hill, 1984


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SIC1406 PROCESS CONTROL SYSTEM COMPONENTS


COURSE OBJECTIVE To introduce the principles and design concepts of various control and instrumentation components applied to process control system

UNIT 1 FLOW AND TEMPERATURE SYSTEM 12 Hrs. Orifice meter - design of orifice for given flow condition - rotameter - design of rotameter - Transmitters Pneumatic transmitter, Electronic transmitter, intelligent transmitter - signal conditioning for RTD - Zero and span adjustment in D/P transmitters and temperature transmitters

UNIT 2 PRESSURE AND LEVEL SYSTEM 12 Hrs. Pressure Relieving devices Functions - Relief valve - safety valves - safety relief valves - Pilot operated relief valves - Bourdon gauges - design of Bourdon tube - Design of Air purge system for level measurement. Electronic P + I + D controllers - design - adjustment of set point, bias and controller settings.

UNIT 3 CONTROL VALVES 12 Hrs. Control valves -Necessity-Comparison with other final control elements- valve characteristics - Control valve parameters control valve capacity-valve range ability-valve size-valve gain - Selection criteria - Control valve sizing Procedure-Cavitations& flashing in control valve.

UNIT 4 PUMPS 12 Hrs. Types of pumps - pump - performance - pipe work calculation - characteristics of different pumps - pump operation maintenance - instruments used in pumping practice pump noise and vibration - selection of pumps.

UNIT 5 LOGIC CIRCUIT 12 Hrs. Design of logic circuits for alarm and annunciator circuits, interlocks - design of microprocessor based PID controller.

Max. 60 Hours TEXT / REFERENCE BOOKS 1. Anderson. N.A., “Instrumentation for Process Measurement and Control”, Chillton Company, 1980, 3rd Edition, 1997, CRC

Press 2. Considine D.M., “Process Instruments and Controls Handbook”, McGraw Hill Book Co. 1985, McGraw Hill Professional,

5th Edition, 1999 3. Warring. R.H., “Pumping Manual”, Gulf Publishing Co., 1984. 4. Johnson. C.D., “Process Control Instrumentation Technology”, Prentice Hall Inc. 7th Edition, 2002. 5. Terry Bartelt, “Instrumentation and Process Control”, Nov.28, 2006, Delmar Cengage Learning. 6. Donald. P. Eckman, “Automatic Process Control’, Wiley Eastern Ltd., New Delhi, 1993. 7. www.amiestudy.com,www.loremate.com


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SIC4055 INDUSTRIAL PROCESS CONTROL LAB (For E&C)



1. Characteristics of I/P Converter 2. Characteristics of Differential Pressure Transmitter 3. Characteristics of Valve with and without Positioner 4. Study and Control of Temperature Process 5. Study and Control of Level Process 6. Study and Control of Flow Process 7. Study and Control of Pressure Process 8. Control of a Process Using Ziegler Nichols Method 9. Control of a Process Using Process Reaction Curve Method 10. Characteristics of Control Valve 11. Study on Interacting System /Non Interacting System 12. Study of the response of ON-OFF, P,PI, PID Controllers 13. Study of Cascade Control 14. Study of Feed-Forward Control 15. Study of Ratio Control 16. Study on Decoupling Effect

SIC4056 INDUSTRIAL INSTRUMENTATION LAB (For EIE)


SUGGESTEDLIST OF EXPERIMENTS

1. Level Measurement using DPT. 2. Flow Measurement using Orifice and Venturimeter. 3. Calibration of Thermocouple. 4. Calibration of Pressure Transmitter. 5. Torque Measurement. 6. Viscosity Measurement. 7. UV Visible Spectrophotometer. 8. IR Spectrophotometer. 9. Vacuum Pressure Measurement. 10. Conductivity Meter Calibration and Measurements of conductivity of test solutions. 11. pH meter standardization and measurement of pH Values of test solutions. 12. Radiation Pyrometer and IR Thermometer.

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SIC4057 SYSTEM DESIGN LAB (For EIE)



MATLAB

1. Design of Digital Controller using Deadbeat Algorithm. 2. Design of Digital Controller using Dahlin’s Algorithm. 3. Design of Digital Controller using Kalman’s Algorithm. 4. Design of Fuzzy logic Controller . 5. Design of Neural Network . 6. Design of Model Predictive Controller.

LABVIEW

7. Building VI to demonstrate conversion of Centigrade to Fahrenheit and 8. Building VI o create a subroutine for conversion of Centigrade to Fahrenheit. 9. Building VI for analyzing and logging of data. 10. Building VI to demonstrate waveform generator. 11. Building VI to demonstrate error clusters and handling. 12. Building VI to design multimeter. 13. Building VI to demonstrate ON-OFF controller.

SIC4058 DIGITAL AND CONTROL LAB (For E&C)



1. Simulation of standard test signals 2. Step Response of First Order System 3. Ramp Response of First Order System 4. Step Response of Second Order System 5. Ramp Response of Second Order System 6. Sequential Control Using PLC 7. Control of Process Using Deadbeat Algorithm 8. Control of Process Using Dahlin’s Algorithm 9. Control of Process Using Kalman’s Algorithm 10. Design and Simulation of PID Controller 11. Study of Cascade Control 12. Study of Supervisory Control And Data Acquisition Systems (SCADA) 13. Study of Distributed Control Systems (DCS) 14. Study of frequency response analysis for first order and second order system.

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SIC1405 LOGIC AND DISTRIBUTED CONTROL SYSTEMS

(For EIE and E&C) L T P Credits Total Marks 3 0 0 3 100

COURSE OBJECTIVES To provide the Fundamentals of PLC, PLC programming concepts, PLC applications To provide in-depth understanding of DCS, SCADA, and Computer Controlled Systems which are used in automation of various machines, processes and systems in industries

UNIT 1 BASICS OF PROGRAMMABLE LOGIC CONTROLLER (PLC) 9 Hrs. Definition- overview of PLC systems - Input/ Output modules - Power supplies - I/O slots, General PLC programming procedures - programming on-off outputs, Auxiliary commands and functions - creating ladder diagrams from process control descriptions - Ladder logic for traffic light control system. PLC basic programming - digital logic Gates - Boolean algebra. Basic PLC functions-register basics - timer functions - counter functions.

UNIT 2 PLC INTERMEDIATE FUNCTIONS 11 Hrs. Arithmetic functions - number comparison functions - skip and MCR functions - data move systems. PLC Advanced intermediate functions- utilizing digital bits - sequencer functions - PLC Advanced functions: alternate-programming languages - operation. PLC-PID functions -PLC installation - trouble shooting and maintenance- controlling a robot - processes with PLC - design of inter locks and alarms using PLC. Use of PC as PLC - Application of PLC - Case Study of Bottle Filling System, Field Bus and HART Protocol

UNIT 3 DISTRIBUTED CONTROL SYSTEMS (DCS) 9 Hrs. Evolution of DCS - building blocks - different architectures-comparison of architectures- detailed descriptions and functions of local control units - basic elements & functions-operator stations - data highways - redundancy concepts.

UNIT 4 DISTRIBUTED CONTROL SYSTEMS: COMMUNICATION FACILITIES AND APPLICATIONS 9 Hrs. DCS communication Facilities - communication system requirements - architectural issues - protocol issues - communication system standards - operator interfaces - low level and high level operator interfaces - Operator Displays - Engineering interfaces - low level and high level engineering interfaces - Applications of DCS - oil and gas (extraction, production and storage)

UNIT 5 COMPUTER CONTROLLED SYSTEMS 7 Hrs. Basic building blocks of Computer controlled systems - SCADA - data acquisition System - supervisory Control - Direct digital Control - software - Velocity algorithm & Position algorithm

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. John Webb, W, Ronald Reis, A.,: “Programmable Logic Controllers Principles and Applications”, 3rd Edition, Prentice hall

Inc., New Jersey, 1995. 2. Krishna Kant, “Computer based Industrial Control”, Prentice Hall India. 1997. 3. Lucas, M.P.,: “Distributed Control Systems”, Van Nostrand Reinhold Co., New York, 2nd Edition, 1986 4. Petruzella., “Programmable Logic Controllers” 3rd Edition, Tata McGraw Hill, Newyork. 5. Hughes, T. “Programmable Logic Controllers”, ISA Press 1994. 4th Edition. 6. Mckloni, D.T. “Real Time Control Networks”, ISA Press 1994.


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COURSE OBJECTIVE To familiarize engineering students with the concepts of Management useful for Managing their own enterprise or to work in a professional organization in Managerial capacity and to provide them an ethical outlook.

UNIT 1 MANAGEMENT FUNCTIONS & STRUCTURE 9 Hrs. Management - Definition -Role of managers- Levels of management-Basic Function - Contribution of Taylor & Fayol. Types of structures - Line, staff, Functional, Committee and Project & Matrix - Structures. Departmentalization - Centralization - Decentralization - Span of control. Management by Objectives (MBO)- Management by Exception (MBE).

UNIT 2 MANAGEMENT OF ORGINASATION 9 Hrs. Forms of Business / Industrial Ownership - Sole Trader, Partnership, Joint stock Company, Performance Appraisal - Basic Principles - Pitfalls - Methods to Overcome. Industrial Safety - Causes of Accidents - Cost of Accidents - Measures to avoid Accidents. Plant Layout & Maintenance - Need, Types & Managerial Aspects.

UNIT 3 ORGANISATIONAL BEHAVIOUR 9 Hrs. Organisational Behaviour - Definition - Nature & Scope - Contributing Disciplines - Importance of OB to Managers. Personality - Definition - Theories - Factors Influencing Personality. Motivation - Definition - Theories. Transactional Analysis. Morale & Job Satisfaction - Factors Influencing Job Satisfaction.

UNIT 4 GROUP DYNAMICS 9 Hrs. Group - Definition - Types - Determinants of Group Cohesiveness. Communication - Process - Barriers - Effective Communication. Leadership-Definition- leadership styles- Theories of leadership - Factors Contributing to Effective Leadership. Trade Unions- Role of Trade Union in Organizations - Types and Functions of Trade Unions.

UNIT 5 PROFESSIONAL ETHICS 9 Hrs. Ethics in Workplace - Formulation of Ethics - Managerial Ethics - Managing Ethical Behaviour - Codes of Ethics - Encouraging Ethical Behaviour - Ethical Leadership - Ethical Decision making. Corporate Social Responsibility (CSR) - Intellectual Property Rights (IPR)- Meaning- Laws relating to Intellectual Property Rights (IPRs)

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Gupta C.B., “Management Theory and Practice”, 14th Edition, Sultan Chand & Sons, 2009. 2. Dr. Prasad L.M., “Principle & Practice of Management”, 7th Edition, Sultan Chand & Sons, 2008. 3. Aswathappa, “Organisational Behaviour”, 8th Edition, Himalaya Publishing House, 2010. 4. Dr. Prasad L.M., “Organisational Behaviour”, 4th Edition, Sultan Chand & Sons, 2008. 5. Harold Koontz, “Principles of Management”, 1st Edition, Tata McGraw Hill, 2004.


SBA1101 PRINCIPLES OF MANAGEMENT AND PROFESSIONAL ETHICS


3 0 0 3 100

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SCS1315 COMPUTER ARCHITECTURE AND

OPERATING SYSTEM (For ECE and EIE)


3 0 0 3 100

COURSE OBJECTIVES To understand the organization of a computer, and the hardware-software interface. To know about the various components of a computer and their internals. To have an overview of operating system and its functionality

UNIT 1 INTRODUCTION 9 Hrs. Central Processing Unit - Introduction - General Register Organization - Stack organization -- Basic computer Organization - Computer Registers - Computer Instructions - Instruction Cycle. Arithmetic ,Logic, Shift Microoperations- Arithmetic Logic Shift Unit -Example Architectures: MIPS, Power PC,RISC,CISC

UNIT 2 CONTROL UNIT DESIGN AND MULTIPROCESSORS 9 Hrs. Microprogrammed Control : Control memory - address sequencing - Microprogram Example- Design of Control unit -Example Processor design Multiprocessors: Characteristics- Interprocessor Arbitration- Interprocessor Communication

UNIT 3 MEMORY AND I/O SYSTEM 9 Hrs. Memory Organization : Memory Hierarchy - Main memory - auxiliary Memory - Associative Memory - Cache Memory - Virtual memory Input - Output Organization : Peripheral Devices - I/O Interface, Modes of transfer - Priority Interrupt - DMA - IOP - Serial Communication

UNIT 4 INTRODUCTION 9 Hrs. Introduction - Operating system structures - System components - OS services Process Management: Processes - Process concepts - Process schedulling-- CPU schedulling Scheduling algorithms - Preemptive strategies - Non-preemptive strategies.

UNIT 5 DEADLOCKS AND MEMORY MANAGEMENT 9 Hrs. `The critical section problem - Semaphores - Deadlocks - Deadlock characterization - Prevention - Avoidance - Detection - Recovery. Storage Management Strategies - Contiguous vs. non-contiguous storage allocation- Paging - Segmentation - Paging/Segmentation systems - Page replacement strategies

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. M.Morris Mano, ;Computer System Architecture”,Prentice-Hall Publishers,Third Edition. 2. John P Hayes , ‘Computer Architecture and Organization’, McGraw Hill international edition, Third Edition. 3. Kai Hwang and Faye A Briggs ,‘Computer Architecture and Parallel Processing’, McGraw Hill international edition,1995. 4. Abraham Silberschatz,Peter Galvin and Gagne, “Operating System Concepts”, 6th Edition, Addison Wesley, 2002. 5. Harvey M.Deitel, ”Operating System”, 2nd Edition, Addison Wesley, 2000.

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 Questions of 2 marks each- No choice 20 Marks PART B : 2 Questions from each unit of internal choice, each carrying 12 marks 60 Marks

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SCS1611 ARTIFICIAL INTELLIGENCE

AND EXPERT SYSTEMS (For EIE)


3 0 0 3 100

COURSE OBJECTIVE To impart adequate knowledge on the representation and structures of artificial intelligence and to study in depth about the expert systems and its tools

UNIT 1 AI & INTERNAL REPRESENTATION 9 Hrs. The AI problem - What is AI technology - Level of the Model - Criteria for Success problems, Problem Spaces & Searches & Heuristic Search Technology Problem as a State Space Search - Production Systems - Production System Characteristics - Generate & Test - Hill Climbing - Best First Search - Constraint Satisfaction - Means End Analysis.

UNIT 2 KNOWLEDGE REPRESENTATION 9 Hrs. Issues in Knowledge Representation - Using Predicate Logic - Representing Simple Facts in Logic, Representing Instance & Is a Relationship - Computable Functions & I Predicates - Representing Knowledge Using Rules: Procedural Vs. Declarative Knowledge - Forward Vs. Backward Reasoning.

UNIT 3 SLOT & FILLER STRUCTURES 9 Hrs. Weak Slot & Filler - Semantic Nets - Frames Strong & filler Structures - Scripts - CYC-CYCL

UNIT 4 EXPERT SYSTEMS 9 Hrs. What are Expert Systems - Knowledge Representation in Expert Systems - Symbolic Computation - Rule based Systems

UNIT 5 TOOLS FOR BUILDING EXPERT SYSTEMS 9 Hrs. Using Domain Knowledge - Knowledge Acquisition - Design for Explanation - Black Board Architecture - Truth Maintenance Systems - Machine Learning - Case based Reasoning

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Elaine Rich, Kevin Knight, “ Artifical Intelligence“ , 2nd Edition, Tata McGraw Hill, 1992. 2. Peter Jackson, “Introduction to Expert Systems“, 3rd Edition, Addison Wesley, 1st Indian Reprint 2000

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 Questions of 2 marks each- No choice 20 Marks PART B : 2 Questions from each unit of internal choice, each carrying 12 marks 60 Marks

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SEC1615 NANOELECTRONICS (For ECE, EIE and ETCE)


3 0 0 3 100

COURSE OBJECTIVES

To understand the evolution and basics of Nanoelectronics

To understand the different physical deposition techniques for thin film deposition

To learn the different types of chemical vapour decomposition techniques

To learn about the various characterization techniques

To understand the basics of elementary quantum devices

UNIT 1 FUNDAMENTALS OF NANOELECTRONICS 9 Hrs.

Moore‖s Law, Wave functions, wave packets, Schrodinger‖s wave equation, potential barriers and tunneling,

Fermi-Dirac statistics, Density of states, Limitations of conventional FET in nanoscales, Quantum Well, Quantum

wire, Quantum dot, current flow in two terminal Quantum dots, ballistic transport, Single Electron Transistor

UNIT 2 PHYSICAL DEPOSITION (THIN FILM) TECHNIQUES 9 Hrs.

Basics of physical methods, Glow discharge DC Sputtering, Triode sputtering, Getter sputtering, Radio

frequency sputtering, Magnetron sputtering, Ion beam sputtering, AC sputtering, Vacuum evaporation, Resistive heat

Evaporation, Flash Evaporation, Electron Beam Evaporation, LASER evaporation

UNIT 3 CHEMICAL DEPOSITION (THIN FILM) TECHNIQUES 9 Hrs.

Fundamentals of chemical methods, Chemical Vapour Deposition, LASER chemical Vapour Deposition,

Photo Chemical Vapour Deposition, Plasma enhanced Vapour Deposition, Metal Organo Chemical Vapour

Deposition, Chemical Bath Deposition, Electro less Deposition, Anodisation, Liquid Phase Epitaxy, Sol-Gel method,

Spin Coating, Spray-Pyrolysis Technique, Polymer Assisted Deposition

UNIT 4 THIN FILM CHARACTERIZATION TECHNIQUES 9 Hrs.

Cyclic Voltammetry and Linear Sweep Techniques, Thickness measurement Techniques, X-Ray Diffraction

Technique, Raman Spectral Study, Scanning Electron Microscopy, Energy Dispersive Analysis by X-rays

measurements, Atomic Force Microscopy

UNIT 5 NANOELECTRONIC DEVICES 9 Hrs.

Digital and Switching abstraction, Quantum Cellular Automata (QCA), Realization of logic gates using QCA,

Types and synthesis of molecular bundles, principle and types of spin wave devices, Array minimum/ maximum

computation with spin wave devices

Max. 45 Hours

TEXT / REFERENCE BOOKS

1. George W Hanson, “Fundamentals of Nanoelectronics”, Prentice Hall, 2008.

2. Karl Goser, “Nanoelectronics and Nanosystems: From Transistors to Molecular and Quantum Devices”, Springer, First

edition, 2005.

3. Rainer Waser (Ed), “Nanoelectronics and Information Technology”, Second Edition, Wiley VCH, 2003.

4. Mary Eshaghian-Wilner, “Bio inspired and Nano Scale Integrated Computing”, Wiley, 2009.

END SEMESTER EXAM QUESTION PAPER PATTERN

Max. Marks : 80 Exam Duration : 3 Hrs.

PART A : 10 Questions of 2 Marks each-No choice 20 Marks

PART B : 2 Questions from each unit of internal choice, each carrying 12 marks 60 Marks

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SEC1618 PROGRAMMING IN MATLAB

(For ECE, EEE, E&C, EIE and ETCE)


3 0 0 3 100

COURSE OBJECTIVES To understand basic representation of Matrices and vectors in MATLAB To learn various programming structures in MATLAB To study built in and user defined functions in MATLAB. To become conversant with 2D as well as 3D graphics in MATLAB To make a Graphical User Interface (GUI) in Matlab in order to achieve interactivity To Design simple Applications with Simulink (mdl files) and (M files) MATLAB.

UNIT 1 INTRODUCTION TO MATLAB 9 Hrs. Menus & Tool bars, Variables - Matrices and Vectors - initializing vectors - Data types- Functions - User defined functions - passing arguments - writing data to a file-reading data from a file - using functions with vectors and matrices- cell arrays & structures - Strings - 2D strings-String comparing - Concatenation - Input and Output statements - Script files .

UNIT 2 LOOPS & CONTROL STATEMENTS 9 Hrs. Introduction; Relational & Logical operations - Example programs - Operator precedence - Control & Decision statements- IF - IF ELSE - NESTED IF ELSE - SWITCH - TRY & CATCH - FOR -WHILE - NESTED FOR - FOR with IF statements, MATLAB program organization, Debugging methods - Error trapping using eval & lastern commands.

UNIT 3 PLOTS IN MATLAB & GUI 9 Hrs. Basic 2D plots, Labels, Line style, Markers, plot, subplot, LOG, LOG-LOG, SEMILOG-POLAR-COMET, Grid axis, labeling, fplot, ezplot, ezpolar, polyval, exporting figures, HOLD, STEM, BAR, HIST, Interactive plotting, Basic Fitting Interface – Polyfit - 3D plots – Mesh - Contour - Example programs. GUI - Creation Fundamentals - Capturing mouse actions

UNIT 4 MISCELLANEOUS TOPICS 9 Hrs. File & Directory management - Native Data Files - Data import & Export - Low Level File I/O - Directory management - FTP File Operations - Time Computations -Date & Time - Format Conversions - Date & Time Functions - Plot labels - Optimization - zero Finding - Minimization in one Dimension - Minimization in Higher Dimensions- Practical Issues. Differentiation & Integration using MATLAB, 1D & 2D Data Interpolation

UNIT 5 SIMULINK & APPLICATIONS 9 Hrs. How to create & run Simulink, Simulink Designing - Using SIMULINK Generating an AM signal & 2nd order systems - Designing of FWR & HWR using Simulink - Creating a subsystem in Simulink. Applications Programs - Frequency response of FIR & IIR filters. Open Loop gain of OPAMP, I/P characteristics of BJT, Plotting the graph between Breakdown voltage & Doping Concentration. PCM, DPCM


1. Rudra Pratap, “Getting Started with MATLAB 6.0” ,1st Edition, Oxford University Press-2004.

2. Duane Hanselman ,Bruce LittleField, “Mastering MATLAB 7” , Pearson Education Inc, 2005

3. William J.Palm, “Introduction to MATLAB 6.0 for Engineers”, Mc Graw Hill & Co, 2001

4. M.Herniter, “Programming in MATLAB”, Thomson Learning, 2001

5. John Okyere Altla, “Electronics and circuit analysis using MATLAB” - CRC press, 1999

6. K.K.Sharma, “MATLAB Demustifyied” -Vikas Publishing House Pvt Ltd.

7. K.C.Ravindaranath, “Systems Modelling & Simulation”

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 Questions of 2 Marks each-No choice 20 Marks PART B : 2 Questions from each unit of internal choice, each carrying 12 marks 60 Marks

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SEC1619 RADAR AND NAVIGATIONAL AIDS

(For ECE, ETCE and E&I)


3 0 0 3 100

COURSE OBJECTIVES

To acquaint the students with the concept of Radar, its basic principle and operation, its types.

On completion of this course, the students will

Acquire complete knowledge on RADAR and its various types

Acquire knowledge on different transmitters and receivers used in RADAR systems

Acquire knowledge on advanced RADAR concepts

UNIT 1 INTRODUCTION TO RADAR 9 Hrs. Origin of Radar, Block diagram of Radar, Radar frequencies, simple form of Radar equation and considerations, applications of Radar. Integration of Radar Pulses-Radar Cross Section of Targets and its fluctuations, Prediction of Range Performance, Minimum Detectable Signal, Radar Clutter-surface clutter, sea clutter and Land clutter ,weather clutter. Pulse Repetition Frequency and Range ambiguities.

UNIT 2 BASIC AND MTI RADAR, TRACKING 9 Hrs. Principle of basic radar, simple block diagram of radar, radar range equations, basic pulsed radar, CW radar, Doppler Effect, FMCW radar, factors affecting the radar operation. Delay line canceller, blind speed, types of MTI radars, Digital MTI Processing - Moving Target Detector - Limitations to MTI Performance - MTI from a Moving Platform.

UNIT 3 RADAR TRANSMITTERS AND RECEIVERS 9 Hrs. Types of Radar transmitters - Radar Modulators, Linear Beam Power Tubes - Solid State RF Power Sources - Magnetron - Crossed Field Amplifiers - Other RF Power Sources - Radar transmitter monitoring and testing Noise Figure of Radar receivers - Super heterodyne Receiver - Duplexers and Receiver Protectors- Radar Displays.

UNIT 4 DETECTION OF SIGNALS IN NOISE 9 Hrs. Introduction - Matched Filter Receiver - Detection Criteria - Detectors - Automatic Detector - Integrators - Constant-False-Alarm-Rate Receivers - The Radar operator - Signal Management - Propagation of Radar Waves - Atmospheric Refraction - Standard propagation - Nonstandard Propagation - The Radar Antenna - Reflector Antennas - Electronically Steered Phased Array Antennas - Phase Shifters - Frequency-Scan Arrays

UNIT 5 ADVANCED RADARS AND RADAR NAVIGATION 9 Hrs. Pulse Doppler Radar, mono-pulse radar, sequential lobbing radar, conical scan radars, MST radars, Synthetic Aperture Radars (SAR) - Principle of operation and characteristic parameters. Phased array radars - salient features, advantages and limitations of Phased Array Radars. Elementary ideas of Navigation Aids : VOR, DME, DVOR, TACAN, ILS and MLS, GPS, Automatic Direction finder, Hyperbolic Navigation (LORAN, DECA, OMEGA).


1. Merrill I.Skolnik, “Introduction to Radar Systems”, Tata McGraw-Hill (3rd Edition) 2003.

2. N.S.Nagaraja, “Elements of Electronic Navigation Systems”, 2nd Edition, TMH, 2000.

3. Peyton Z. Peebles:, "Radar Principles", John Wiley, 2004

4. J.C Toomay, " Principles of Radar", 2nd Edition -PHI, 2004

5. Dr.A K Sen and Dr. AB Bhattacharya, “Radar Systems and Radio Aids to Navigation”, Khanna Publishers, 1988.

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 Questions of 2 Marks each-No choice 20 Marks PART B : 2 Questions from each unit of internal choice, each carrying 12 marks 60 Marks

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SIC1601 INSTRUMENTATION IN AEROSPACE & NAVIGATION

(For EIE and E&C)


3 0 0 3 100

COURSE OBJECTIVES

To describe the principle and working of aircraft and aerospace vehicle systems and instruments, their related

sensors and navigation aids

To provide knowledge on flight simulation, instrumentation and control concepts with their major faults.

UNIT 1 AIR CRAFT AND AEROSPACE VEHICLE INSTRUMENTATION 9 Hrs.

Air data instruments: altimeter, air speed rate of climb - gyroscopic instruments - turn and back indicator -

artificial horizon - directional Gyro Schuler Tuning, Stable Platform - Introduction to Auto pilots - integrated flight

instruments - altitude compensation.

UNIT 2 GPS AND SENSORS 7 Hrs.

GPS - propulsion controls - Sun sensors - Horizon sensors - Star tracker - Stabilization controls

UNIT 3 RADIO NAVIGATION AIDS AND FLIGHT INSTRUMENTATION AND CONTROL 10 Hrs.

Automatic direction finder - distance measuring equipments -instruments landing system - visual omni range

- radar - optical instruments - engine instruments and control - pressure measurements - thermal meter control -

tachometer - accelerometer - smoke and fire detection - propeller controls - twin blade control - cabin pressure

and temperature.

UNIT 4 AIR CRAFT FLIGHT SIMULATION INSTRUMENTATION 9 Hrs.

Basic description of a flight simulator - Solution of Aerodynamics equations - simulation of abnormal

conditions - Jet engine power plant troubles - Flight controls and auto pilot troubles, Simulation - Simulation o f

difficult conditions - Weapons sys tem tra iner - Need for realism - Instrumentation.

UNIT 5 FAULTS IN AEROSPACE VEHICLE 10 Hrs.

Hydraulic systems troubles - landing gear troubles - cabin conditioning troubles - indication of unsafe

canopy - Boeing condition - Radio troubles - Separate generator - System troubles - Trouble indicator light -

Advantages of instrumentated flight - Black box and its use.

Max. 45 Hours


1. Pallett E.G.H., "Aircraft Instrumentation and Integrated Systems", Longman Scientific and Technical‖, 1992

2. Nagaraja N.S., "Elements of Electronic Navigation", Tata Mcgraw Hill Publishing Ltd., New Delhi, 1975.

3. Douglas M. Considine and Ross. S.D. Handbook of Applied Instrumentation, McGraw Hill, 1965.



PART A : 10 Questions of 2 marks each-No choice 20 Marks


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SIC1602 SOFTWARE FOR SYSTEM DESIGN

(For EIE and E&C)


3 0 0 3 100

COURSE OBJECTIVES

To impart knowledge on Software packages for control system design. It focuses the basic concepts of

MATLAB, MAPLE, PSPICE and Lab VIEW software.

The students can also familiar with the basic programming techniques .

UNIT 1 INTRODUCTION OF MATLAB 9 Hrs.

MATLAB fundamentals: function description, data types, arrays, conditional, decision making and loop

statements, I/O- graphics and plotting: two dimensional, three dimensional - Data import and export - Numerical

solution: Integration and differentiation- Euler‖s method -Rungekutta method - Adam bash forth technique- solution of

ordinary differential equation

UNIT 2 MATLAB PROGRAMMING 9 Hrs.

Programs for solution of State Space Methods for Controller Design - simple control application programs:

P.PI and PID controller.-simulation of first order, second order and lead-lag transfer function- Matlab routine for step

and impulse response -development of dynamic model and Laplace domain model using MATLAB

UNIT 3 SIMULINK 9 Hrs.

Introduction-graphical user interface- starting - selection of objects- blocks-lines- simulation-application

programs-limitations- Steps for creating fuzzy logic tool box -GUI editor-rule view-membership function editor- rule

editor.

UNIT 4 INTRODUCTION TO VIRTUAL INSTRUMENTATION 9 Hrs.

Introduction to virtual instrumentation-VI‖s and sub VI‖s,-running and debugging VI‖s -loops and structures-

event driven programming-grouping data using strings, arrays, clusters-local and global variables -charts and graphs-

file I/O -formulas and equations

UNIT 5 INSTRUMENT INTERFACE AND USE OF ANALYSIS TOOLS 9 Hrs.

DIO, RS232/RS485, GPIB,USB & PCMCIA - VISA - networking basics for office & industrial applications - VI

applications in signal processing: Fourier transform, power spectrum, correlation methods, windowing and filtering- VI

applications in instrumentation and control, robotics, image acquisition and processing.

Max. 45 Hours


1. Sokoloff, “Basic Concepts of Lab View 4”, Prentice Hall, 1998.

2. Katsuhiko Ogata, “Modern Control Engineering”, Fourth Edition, PHI, New Delhi, 2006.

3. MATLAB user manual

4. SIMULINK user manual

5. Gary Johnson, “Lab View Graphical Programming”, Ide, McGraw Hill, 1997

6. Lisa. Kewell & Jeffery Travels, “Lab View for Every One”, Prentice Hall, 1997.

7. Gupta. S, Gupta. J.P, “PC Interfacing for Data Acquisition & Process Control”, 2nd Edition, Instrument Society of America,

1994.

8. Lab view User manual





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SIC1609 SATELLITE INSTRUMENTATION

(For EIE and E&C)


3 0 0 3 100

COURSE OBJECTIVES

To illuminate the depth knowledge of satellite orbit & access,.

To investigate its link calculation and design

To acquire knowledge on the satellite instrumentation and to understand the control system in satellite

communication

To focus on the application of satellite system

UNIT 1 SATELLITE ORBIT AND ACCESS 9 Hrs. Introduction to Kepler‖s Laws, orbital parameters, orbital perturbations, station keeping, geo stationary and non geostationary orbits - Look Angle Determination - Limits of visibility - eclipse - Sub satellite point - Sun transit outage - Launching Procedures - launch vehicles and propulsion. Interference between satellite circuits, satellite access, single access, pre-assigned FDMA, SCPC (spade system), TDMA, pre-assigned TDMA, demand assigned TDMA, down link analysis, and comparison of uplink power requirements for TDMA & FDMA, on board signal processing satellite switched TDMA

UNIT 2 LINK CALCULATIONS AND DESIGN 9 Hrs. Space craft configuration, payload and supporting subsystems, satellite uplink - downlink power budget equation - System noise - Antenna noise - Amplifier noise temperature - Amplifiers in cascade - Noise factor - Noise temperature of absorptive networks - Overall system noise temperature - Carrier to Noise ratio - Uplink - Saturation flux density - Input back off - The earth station HPA - Downlink - Output back off - Satellite TWTA output - Effects of rain - Uplink rain - Fade margin - Downlink rain - Fade margin - Combined uplink and downlink C/N ratio - Inter modulation noise.

UNIT 3 SATELLITE CONTROL 9 Hrs. Attitude control of satellites, Reaction wheel, Momentum wheel, Thrusters, Stabilization satellites, Spin stabilization, Gravity gradient stabilization, control moment gyros, orbit determination of satellites, sensors in satellite ADCS. Dual spinners, navigation of satellites, ascent guidance, satellite rendezvous. Tethered satellite systems, satellite services, space stations and docking of spacecrafts.

UNIT 4 SATELLITE INSTRUMENTATION 9 Hrs. Advanced very high resolution radiometer, Magnetometer, Torque coil, high-resolution infrared radiation sounder, Microwave sounding unit, stratospheric sounding unit, advanced microwave sounding unit, solar backscatter ultraviolet radiometer, GOES imager and sounder.

UNIT 5 SATELLITE APPLICATIONS 9 Hrs. INTELSAT series, INSAT, VSAT, Remote sensing, Mobile satellite Service: GSM, GPS, INMARSAT, LEO, MEO, Satellite navigation system, Direct Broadcast satellites(DBS), Direct to home broad cast (DTH), Digital audio broadcast (DAB) , World space services , Business TV(BTV), GRAMSAT, Specialized services - E-mail, Video conferencing and internet connectivity. Max. 45 Hours TEXT / REFERENCE BOOKS 1. Dennis Rody, “Satelite communication”, Regents/Prentice Hall, Eaglewood Cliff, New Jersey, 1983 2. Marshall. H Kalpan, ―Modern Spacecrafts Dynamics and Control‖, John Wiley & sons, 1976 3. Wilbur L. Pritchard and Joseph A. Sciulli, “Satellite Communication Systems Engineering”, prentice hall, New Jersey, 1986 4. Timothy Pratt and Charles W. Bostain, “Satellite Communications”, John Wiley and sons, 1986 5. Tri T Ha, “Digital Satellite Communication”, 2nd edition, McGraw Hill, New york, 1990. 5. Wilbur L. Pritchard, Hendri G. Suyderhood, Robert A. Nelson, “Satellite Communication Systems Engineering”. 2ndEdition,

Prentice Hall, New Jersey, 1993 6. Feher.K, “Digital Communication Satellite / Earth Station Engineering”, Prentice Hall Inc. New Jersey, 1983


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SIC1611 FUNDAMENTALS OF MECHATRONICS

(For EIE, E&C and EEE)


3 0 0 3 100

COURSE OBJECTIVES

To create a strong base on the various sensors and transducers in mechanical system, interdisciplinary

applications of Electronics, Electrical, Mechanical and Computer Systems for the Control of Mechanical and

Electronic Systems

To design control system for computer application like CNC.

UNIT 1 INTRODUCTION 9 Hrs.

Mechatronics: Definition & Key Issues - Evolution - Elements - Mechatronics Approach to Modern

Engineering, Industrial design and safety Design.

UNIT 2 SENSORS AND TRANSDUCERS 9 Hrs.

Introduction and background, difference between transducer and sensor, transducers types, transduction

principle, photoelectric transducers- thermistors, thermodevices, thermocouple, inductive transducers capacitive

transducers, piezoelectric transducers, piezoelectric transducers. Hall Effect transducers, Fiber optic transducers,

Signal Processing - Data Display.

UNIT 3 ACTUATION SYSTEMS 9 Hrs.

Introduction to Mechanical Types and Electrical Types - Pneumatic & Hydraulic Systems - Applications -

Selection of Actuators, Kinematics of robot manipulator links.

UNIT 4 DIGITAL AND CONTROL SYSTEMS 9 Hrs.

Digital logic neuron system, Types of Controllers - Programmable Logic Controllers - applications - ladder

diagrams - Microprocessor Applications in Mechatronics: Temperature measurement system, Domestic washing

machine - Programming Interfacing - Computer Applications: CNC drilling machine

UNIT 5 RECENT ADVANCES 9 Hrs.

Manufacturing Mechatronics - Automobile Mechatronics - Medical Mechatronics - Office Automation - Case

Studies

Max. 45 Hours


1. Bolton. W “Mechatronics: Electronic Control System for Mechanical & Electrical Engineering”, 2nd Edition Pearson

Education, 2004.

2. Ramachandran. K.P,Vijaya Raghavan. G.K, Mechatronics, A.R.S. Publications, Second Edition, 2008.

3. Bradly.D.A, Dawson.D, Burd. N.C, Loader. A.J “Mechatronics: Electronics in Products and Processes” Nelson Publisher,

2004.

4. Michael B. Histand & David G. Alciators, “Introduction to Mechatronics & Measurement systems”, McGraw- Hill International

Editions, 1998

5. Dan Necsulescu, “Mechatronics”, Pearson Education, 2005.Bishop, Robert H, "Mechatronics Hand book", CRC Press, 2002.





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SIC1613 INDUSTRIAL SAFETY MANAGEMENT

(For EIE)


3 0 0 3 100

COURSE OBJECTIVES

To educate on the safety, safety considerations and safety management systems in industries and to handle

the complex industrial environment

To prevent accidents and pollution

UNIT 1 FIRE AND EXPLOSION 9 Hrs.

Introduction - Industrial processes and hazards potential, mechanical, thermal and process hazards. Shock

wave propagation, vapor cloud and boiling liquid expanding vapors explosion (VCE and BLEVE), mechanical and

chemical explosion, multiphase reactions, transport effects and global rates.

UNIT 2 RELIEF SYSTEMS 9 Hrs.

Preventive and protective management from fires and explosion - inerting, ventilation, and sprinkling,

proofing, relief systems -relief valves, flares, scrubbers.

UNIT 3 TOXICOLOGY 9 Hrs.

Hazards identification - toxicity, fire, static electricity, noise and dust concentration-Material safety data sheet,

-hazards indices - Dow and Mond indices, hazard operability (HAZOP) and hazard analysis (HAZAN).

UNIT 4 ELECTRICAL SAFETY 9 Hrs.

Primary and secondary hazards, shocks, burns, falls, human safety, capacity and protection of conductor -

joints and connections, overload and short circuit protection - no load protection - earth fault protection - system

grounding - equipment grounding maintenance of ground - ground fault circuit interrupter - safety in handling hand

held electrical appliances tools and medical equipments.

UNIT 5 SAFETY MANAGEMENT 9 Hrs.

Evaluation of modern safety concepts - safety management functions - safety Organization, safety

department - safety committee - safety audit - general safety considerations in power plants, pressure vessels and

pressurized pipe lines - operation and inspection of extinguishers - preventing the spread of fire - emergency exit

facilities.

Max. 45 Hours


1. Fordham Coper, W. “Electrical Safety Engineering” Buterworth and Company, London, 1986

2. Blake Roland.P, “Industrial safety”, Prentice Hall of India, 1973.

3. John.V.Grimaldi and Rollin. H Simonds, “Safety Management”, All India traveler book seller, New Delhi - 1989.

4. Krishnan N.V, “Safety in Industry”, Jaico Publisher House, 1996.

5. Crowl D.A. and Louvar J.F., “Chemical Process Safety: Fundamentals with Applications”, 2nd Ed., Prentice Hall.2001.

6. John V Grimaldi, “Safety Management”, AITB publishers, 2003.

7. Mannan S., “Lee‖s Loss Prevention in the Process Industries”, Vol. I, 3rd Edition, Butterworth - Heinemann, 2004

8. Noel de Nervers, “Air Pollution Control Engineering”, McGraw Hill Book Co., 2000.





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SIC1614 SOFT COMPUTING TECHNIQUES

(For EIE and E&C)


3 0 0 3 100

COURSE OBJECTIVES

To learn the key aspects of Neural networks, Fuzzy logic components and building block hypothesis of

Genetic algorithm

To adopt these techniques in solving problems in the real world.

UNIT 1 INTRODUCTION TO SOFT COMPUTING AND ARTIFICIAL NEURAL NETWORKS 9 Hrs.

Evolution of Computing - Soft Computing Constituents - From Conventional AI to Computational Intelligence -

Machine Learning Basics, Fundamentals of ANN - Biological Neurons and Their Artificial Models - Types of ANN -

Properties - Different Learning Rules - Types of Activation Functions - Training of ANN - Hebb learning - Perceptron

Model (Both Single & Multi Layer) - Training Algorithm - Problems Solving Using Learning Rules and Algorithms -

Linear Separability – Limitation.

UNIT 2 DETERMINISTIC & STATISTICAL NETWORKS 11 Hrs.

Back Propagation Training Algorithm - Practical Difficulties - Counter Propagation Network - Structure &

Operation - Training of Kohonen and Grossberg Layer - Applications of BPN & CPN - Statistical Method - Training

Application - Boltzman Training - Cauchy Training - Hop Field Network and Boltzman Machine - Speed Energy

Function - Network Capacity - RBF Network, BAM, Architecture of SOM, ANN based water level controller.

UNIT 3 FUZZY LOGIC 9 Hrs.

Introduction to Fuzzy Set Theory - Basic Concepts of Fuzzy Sets - Classical Set Vs Fuzzy Set - Properties of

Fuzzy Set - Fuzzy Logic Operation on Fuzzy Sets - Fuzzy Logic Control Principles - Fuzzy Relations - Fuzzy Rules -

Defuzzification - Fuzzy Inference Systems - Fuzzy Expert Systems - Fuzzy Decision Making.

UNIT 4 FUZZY LOGIC CONTROLLER & ITS APPLICATION 9 Hrs.

Fuzzy Logic Controller - Fuzzification Interface - Knowledge Base - Decision Making Logic - Defuzzification,

Interface - Application of Fuzzy Logic to Water Level Controller - Temperature Controller - Control of Blood Pressure

during Anesthesia. Introduction to Neuro - Fuzzy Systems - Fuzzy System Design Procedures - Fuzzy Sets and

Logic Background - Fuzzy / ANN Design and Implementation.

UNIT 5 GENETIC ALGORITHMS 9 Hrs.

Introduction - Robustness of Traditional Optimization and Search Techniques - The goals of optimization -

Survival of the Fittest - Fitness Computations - Cross over - Mutation -Reproduction - Rank method - Rank space

method.

Max. 45 Hours


1. Laurene Fausett, "Fundamentals of Neural Networks", Pearson Education, 2003

2. Timothy J. Ross , “Fuzzy Logic with Engineering Applications”, McGraw- Hill International Editions,1995

3. George J. Klir and Bo Yuan, "Fuzzy sets and Fuzzy Logic", Prentice Hall, USA 1995.

4. Jang J.S.R., Sun C.T. and Mizutani E, "Neuro-Fuzzy and soft computing", Pearson Education 2003

5. David E. Goldberg, “Genetic Algorithms in Search, Optimization and Machine Learning”, Addison Wesley, 1997. 27

6. Rajasekaran. S, Pai. G.A.V. “Neural Networks, Fuzzy Logic and Genetic Algorithms”, Prentice-Hall of India, 2003





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SIC1304 ANALYTICAL INSTRUMENTATION (For EIE and E&C)


COURSE OBJECTIVES The subject aims to provide the basic principles of various instrument analysis and its applications. This subject brings comprehensive analysis of various gas analyser and chromatography. It aims in thorough study of spectro photometers analysis and applications.

UNIT 1 pH CONDUCTIVITY & DISSOLVED COMPONENT ANALYSER 9 Hrs. Conductivity meters - pH meters - dissolved oxygen hydrogen analyser -sodium analyser - silica analyser and Sampling systems.

UNIT 2 GAS ANALYSER 9 Hrs. Thermal conductivity - thermal analyser - type Oxygen analyser - CO monitor - NOx analyser - H2S analyser - dust and smoke measurement.

UNIT 3 CHROMATOGRAPHY 9 Hrs. Gas chromatography - liquid chromatography -- high-pressure liquid chromatography - principles, types and applications detectors.

UNIT 4 SPECTRO PHOTOMETERS 9 Hrs. Spectral methods of analysis - Beer’s law UV - visible spectrophotometers - single beam and double beam instruments - source and detectors - IR spectrophotometers - sources and detectors - FTIR spectrometers - atomic absorption spectrophotometer - flame emission spectrophotometers - sources of flame photometry - applications ESR, EPR spectroscopy - TOF spectrometer -Introduction to x-ray spectroscopy

UNIT 5 PRINCIPLE Of NUCLEAR MAGNETIC RESONANCE 9 Hrs. NMR - basic principle - NMR spectrometers - Applications - Introduction to mass spectrophotometer - Nuclear radiation detectors - GM counter - proportional counter - solid state detectors -.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Hobart H. Willard, Lynne.L. Merrit, John A. Dean, Frank A.Settle, “Instrumental Methods of Analysis”, 7th Edition,CBS

Publishing & Distribution, 1986. 2. Jain R.K, “Mechanical &Industrial Measurements”, Khanna Publishers, 11th Edition, 2004 3. Khandpur R.S, “Handbook of Analytical Instruments”, II Edition, Tata McGrawHill, New Delhi, 2006. 4. Gurdeep R. Chatwal, Sham.K. Anand, “Instrumental methods of Chemical Analysis” Himalaya Publishing house, Reprint

2006. 5. Robert D. Braun, “Introduction to Instrumental Analysis”, Pharma Book Syndicate, Hydrabad, Reprint 2006. 6. Douglas.A. Skoog, F. James Holker, Stanley R. Gouch, “Instrumental Analysis”, CEngage Learning India , India Edition

2008.


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SIC1610 ULTRASONIC INSTRUMENTATION

(For EIE and E&C)


3 0 0 3 100

COURSE OBJECTIVES To expose the student to ultrasound and its interaction with environment, generation of ultrasonic waves and its various test methods To focus on the measurement of ultrasound and its display modes, artifacts and the characteristics of the resolution in ultrasound imaging and also the applications of ultrasound in the field of medicine, power and quality assurance.

UNIT 1 PHYSICS OF ULTRASOUND AND ITS CHARACTERISTICS 9 Hrs.

Basic principle of Ultrasound - Pulse echo Technique - Producing beam of ultrasound, Interaction of

ultrasound with matter, properties of ultrasonic transmission, reflection and transmission coefficients, intensity and

attenuation of sounds beam, attenuation, power level, medium parameters.

UNIT 2 ULTRASONIC WAVE GENERATION AND TEST METHODS 9 Hrs.

Generation of ultrasonic waves: magneto-strictive and piezoelectric effects, search unit types, construction

and characteristics Test methods: Ultrasonic test methods: pulse echo, transit time, resonance, direct contact and

immersion type and ultrasonic methods of flaw detection.

UNIT 3 ULTRASOUND MEASUREMENT AND DISPLAY MODES 9 Hrs.

Ultrasound measurement: measuring thickness, depth and flow, variables affecting ultrasonic testing in

various applications Ultrasonic Display modes: A-mode, B-mode, Time position mode, Ultrasonic Probe construction.

UNIT 4 ARTIFACTS AND RESOLUTION IN ULTRASOUND IMAGING 9 Hrs.

Display of false echoes - Reverberation between Probe and structure, omission of echoes from display -

Acoustic Shadowing, Off-Normal incidence, Distortion of echoes. Beam width and lateral resolution, factors affecting

lateral and longitudinal resolution, Hazardous effects of ultrasound.

UNIT 5 ULTRASONIC APPLICATIONS 9 Hrs.

Ultrasound quality assurance, Acoustic power and bio-effects: Acoustic power and intensity of pulsed

ultrasound, Applications in medicine: Echo-Cardiography, Obstetrics and Gynaecology, Liver, Biliary systems,

Kidneys and Adrenals.

Max. 45 Hours


1. David J Cheeke. N “Fundamentals And Applications of Ultrasonic Waves”, CRC Press 2002.

2. Dale Ensminger, Ultrasonic: “Fundamentals, Technology, Applications”, CRC press, 1988, Second Edition.

3. Baldev Raj, Palanichamy P., Rajendran. V, “Science and Technology of Ultrasonic”, Alpha Science, 2004

4. David.J.Farman and Isabel M Shirley, "A Users guide to diagnostic Ultrasound", Pitman Medical Publishing Co Ltd, 1978.

5. Brown Y.H.W and Dickson J.F., "Advances in Medical Engineering" Volume II and V, Academic Press, London, 1972

6. Jerold T. Bushhery, J. Antony Siebert, Edwin M. Leidholdt, John M Boone, “The Essential Physics of Medical Imaging”,

Lippincott Williams & Wilkins, 3rd Edition 2011.

7. Flower. M.A “Webh‖s Physics of Medical Imaging”, Taylor & Francis, 2nd Edition, 2012

8. Perter Hoskins, Kevin Martin and Abigail Thrush, “Diagnostic ultrasound: Physics and Equipment”, Cambridge University

Press, 2nd Edition, 2010.





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SIC1612 ADAPTIVE CONTROL SYSTEMS

(For EIE and E&C)


3 0 0 3 100

COURSE OBJECTIVES

To make the student familiarize with adaptive control schemes and MRAS

To identify the techniques of linear and nonlinear systems with unknown parameters

To introduce stability robustness concepts with protection systems.

UNIT 1 INTRODUCTION TO ADAPTIVE CONTROL SYSTEM 9 Hrs.

Definition of adaptive control system - functions of adaptive control - Different approaches to Adaptive Control

- gain scheduling - Relay feedback

UNIT 2 IDENTIFICATION OF ADAPTIVE CONTROL 9 Hrs.

Conventional methods of Identifications - step response, impulse response, Bode plot - Identification of linear

time-invariant systems - Adaptive observers - Sufficient richness condition for parameter convergence - Equation

error and output error methods

UNIT 3 MODEL REFERENCE ADAPTIVE SYSTEMS (MRAS) 9 Hrs.

The need for MRAS - An over view of adaptive control systems - Mathematical description of MRAS - Design

hypothesis - Equivalent representation of MRAS.

UNIT 4 CLASSIFICATION OF ADAPTIVE CONTROL 9 Hrs.

Definitions - Auto tuning - Types of adaptive control - Recent trends in self-tuning - Robustness studies -

Multivariable systems - Model updating - General-purpose adaptive regulator

UNIT 5 ADAPTIVE PROTECTION 9 Hrs.

Need of Adaptive Protection in the system - Techniques for adaptive strategies in distance protection -

Synchro-phasor based adaptive protection schemes - protection schemes - SCADA based protection systems - FTA

- Testing of Relays.

Max. 45 Hours


1. Astrom K.J, Wittenmark B, Adaptive Control, Addison-Wesley, 2nd edition, 1995

2. Shankar Sastry, Marc Bodson, "Adaptive Control", Prentice Hall of India (P) Ltd., 1993.

3. Chalam V.V “Adaptive Control Systems - Techniques & Applications” - Marcel Dekker Inc

4. Chang C. Hong, Tong H. Lee and Weng K. Ho, Adaptive Control, ISA press, Research Triangle Park, 1993.





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SIC1605 FIBRE OPTICS AND LASER INSTRUMENTATION

(For ECE, ETCE, EEE, EIE and E&C)


3 0 0 3 100

COURSE OBJECTIVES

To expose the students to the basic concepts of optical fibres and their properties.

To provide adequate knowledge about the Industrial applications of optical fibres.

To expose the students to the Laser fundamentals.

To provide adequate knowledge about Industrial application of lasers.

To provide adequate knowledge about holography and Medical applications of Lasers.

UNIT 1 OPTICAL FIBRES AND THEIR CHARACTERISTICS 9 Hrs.

Quantum nature of light, optical laws and definitions- Principles of light propagation through a fiber -optical

fiber modes, configurations and their properties-fiber materials-fiber fabrication vapor phase oxidization - fiber

characteristics - Absorption losses - Scattering losses - Dispersion - Connectors and splicers -fiber termination .

UNIT 2 OPTICAL SOURCES, DETECTORS AND SENSORS 9 Hrs.

LED characteristics -LED structures: surface LED, edge emitting LED-Double heterojunction LED-Basic

concepts of Laser. Optical Detectors: PN Photo diode , Avalanche photo diode ,PIN diode, Photo transistor ,Photo

thyristors ,Photo thermistor, opto-couplers ,optrodes, modulators.Fibre optic sensors - Fiber optic instrumentation

system - Interferometric method of measurement of length - Moire-fringes - Measurement of pressure and

temperature.

UNIT 3 LASER FUNDAMENTALS 9 Hrs.

Laser Diode Rate Equation - External Quantum Efficiency- Resonant Frequencies - Three level and four level

lasers - Properties of laser -Laser modes - Resonator configuration - Q-switching and mode locking - Cavity damping

- Types of lasers - Gas lasers, Solid lasers, Liquid lasers, Semiconductor lasers, Non-semiconductor lasers- The

Nd:YAG laser and glass fiber lasers.

UNIT 4 LASER APPLICATIONS 9 Hrs.

Optical transmitter and Receiver designs - Laser for measurement of distance, length, velocity, acceleration,

current, voltage and atmospheric effect - material processing - Laser heating, welding, melting and trimming of

materials - Removal and vaporization.

UNIT 5 HOLOGRAM AND MEDICAL APPLICATION 9 Hrs.

Holography- Basic principle - methods - Holographic Interferometer and application - Holography for non-

destructive testing - Holographic Components - Medical applications of lasers, laser and tissue interactive - Laser

instruments for surgery, tumor, vocal chords, brain surgery, plastic surgery, gynecology and oncology.

Max. 45 Hours


1. Senior J.M, “Optical Fibre Communication - Principles and Practice”, Prentice Hall of India,1985.

2. Wilson J and Hawkes J.F.B, “Introduction to Opto Electronics”, Prentice Hall of India, 2001.

3. Keiser G, “Optical Fibre Communication”, McGraw Hill, 1995.

4. Arumugam M, “Optical Fibre Communication and Sensors”, Anuradha Agencies, 2002.

5. John F. Read, “Industrial Applications of Lasers”, Academic Press, 1978.

6. Monte Ross, “Laser Applications”, McGraw Hill, 1968.





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SEC1617 ADVANCED ELECTRONIC TEST ENGINEERING

(For ECE, EIE, ETCE and EEE)


3 0 0 3 100

COURSE OBJECTIVES

The primary goal of the course is to introduce the concepts of automated test engineering techniques applied

for testing complex printed circuit board assemblies. On completion of the course the students will learn

Analog/Digital/Mixed signal devices testing and Functional model development.

PCBA functional testing methods

Testing of BGAs/Boundary Scan components in PCBs

Test pattern generation

UNIT 1 INTRODUCTION TO PCB TECHNOLOGY 9 Hrs.

Printed Circuit Boards(PCB) - Construction - Types of PCB - Multilayer - Surface Mount technology - PCB

Manufacturing process - PCB Inspection methods - Bare Board Testing - Optical and X-Ray Inspection - Electrical tests -

Text fixtures - Bed of nails fixtures - Cross talk test - Mock up test - In circuit test – Burn-in-test - Fault diagnostic methods.

Electromagnetic compatibility testing of electronic components, subassemblies, Measuring Instruments and systems

UNIT 2 PCB TROUBLE SHOOTING PROCESS 9 Hrs.

Symptom Recognition - Bracketing Technique - Component failure Analysis - Fault types and causes in

circuits - during manufacturing - Manual trouble shooting technique - Tools and Instruments DMM - CRO - PCO -

Logic probes - Logic pulsar - Logic Analyzer.

UNIT 3 AUTOMATED TROUBLE SHOOTING TECHNIQUES 9 Hrs.

ATE Techniques - CPU Emulator technique - ROM amd ROM Emulators - In circuit Comparator - In Circuit

Functional test - Trouble shooting digital gates - Testing Linear Integrated Circuits - Guarding Technique - VI trace

Technique - Bus Cycle Signature System - Board functional test methods - Boundary scan test basics.

UNIT 4 ATE SYSTEM ARCHITECTURE 9 Hrs.

ATE System Components - Digital Pin Electronics - Drive data formats - Digital High way - Analog Highway -

Test Vector Generation - Creating test patterns - Fault Simulations.

UNIT 5 DESIGN FOR TESTABILITY (DFT) 9 Hrs.

MDA test systems - Boundary scan test with I/O pin compatibility - Automatic optical inspection systems -

Combinational ATE Systems - Design for testability - Observability and Controllability - Testing Flow diagram - Stuck

at fault model - Fault simulation - Ad Hoc technique - Scan design technique - Basics of ATPG - BIST-Test pattern

generation for built in self test - Exhaustive pattern generation and deterministic testing - Output response Analysis -

Transition count syndrome checking - Signature Analysis - Circular BIST.

Max. 45 Hours


1. Michael L.Bushnell et al., “Essentials of Electronic testing for digital, memory and mixed signal VLSI circuit”,1st edition,

Academic Press, 2002.

2. Randall L Geiger, Pillip E Allen, “VLSI design techniques for analog and digital circuits”, MGH,1990.

3. Parag.K.lala, “Digital circuit Testing and Testability”, 1st edition, Academic press, 2001.

4. Alfred L.Crouch, “Design for test for Digital ICs and Embedded core systems”, 2nd edition, PHI, 1999

5. Sabapathy S.R., “Test Engineering for electronic hardware”, Qmax publishers, 1st Edition, 2007.





(Distribution may be 20% Theory & 80% Numerical)

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SEC1616 PATTERN RECOGNITION AND IMAGE VISION

(For ECE, EIE and ETCE)


3 0 0 3 100

COURSE OBJECTIVES To comprehend the concepts of pattern recognition To study the various methodologies of object detection in pattern recognition To acquire knowledge about pattern classifications To study the various classifiers like fuzzy and neural classifiers To understand the concept of image extraction through computer vision and boundary analysis

UNIT 1 PRINCIPLES OF PATTERN RECOGNITION 9 Hrs. Patterns and features, training and learning in pattern recognition approach, different types of pattern recognition. Statistical pattern recognition, feature selection, syntactic pattern recognition, clustering and non-supervised learning methods.

UNIT 2 OBJECT DETECTION METHODOLOGIES 9 Hrs. Combined detection method, edge detection, edge linking, gradient. Laplacian, line detection, method based, point detection, snake methods. Boundary description detection, matching, merges segmentation, smoothing, splitting of boundaries syntactic, analysis of region boundaries, study of shape by region analysis.

UNIT 3 PATTERN CLASSIFICATION 9 Hrs. Distance Functions - Pattern classification by distance functions - Minimum distance classification - Cluster and cluster seeking algorithms - Pattern classification by likelihood functions. Statistical Functions - Pattern classification using Statistical classifiers - Bayes‖ classifier - Classification performance measures - Risk and error probabilities.

UNIT 4 PATTERN RECOGNITION 9 Hrs. Fuzzy Classifiers- Fuzzy and crisp classification - Fuzzy clustering - Fuzzy pattern recognition - Syntactic pattern recognition - Selection of primitives - Syntax analysis for pattern recognition.

Neural Classifiers - Introduction - Neural network structures for PR, Neural network based pattern

associators - Feed forward networks trained by back propagation - ART networks.

UNIT 5 IMAGE EXTRACTION CONCEPTS 9 Hrs. Introduction of Computer Vision, Computer Imaging System, Image Formation and sensing CVIP tools Software, Image representation. Area Extraction, Concepts, Data-structures, Edge, Line- Linking, Hough transform, Line fitting, Curve fitting. Introduction - Boundary Analysis and Matching Region Analysis: Region properties, External points, spatial moments, mixed spatial gray-level moments, Boundary analysis- Signature properties, Shape numbers. General Frame Works for Matching, Distance relational approach,


1. Dude, Hart, and Stock, "Pattern Classification", John Wiley and Sons, 2nd Edition, 2001.

2. Gose, Johnsonbaugh and Jost, "Pattern Recognition and Image Analysis", Prentice Hall; Har/Dsk Edition, 1996.

3. D. Forsyth and J. Ponce , “Computer Vision - A modern approach”, Pearson, 2012.

4. B. K. P. Horn , “Robot Vision”, McGraw-Hill, 1986.

5. Milan Sonka,Vaclav Hlavac, Roger Boyle, "Image Processing, Analysis, and Machine Vision" , 2007.

6. Robert Haralick and Linda Shapiro, "Computer and Robot Vision", Vol I & II, Addison-Wesley, 1993.

7. Christoper M Bishop, “Neural Network for pattern recognition”, Oxford university press, 2008.

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 Questions of 2 Marks each-No choice 20 Marks PART B : 2 Questions from each unit of internal choice, each carrying 12 marks 60 Marks (Distribution may be 20% Theory & 80% Numerical)

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SEE1305 POWER ELECTRONICS (For EEE, ECE, EIE and E&C)


COURSE OBJECTIVES To understand the various applications of electronic devices for conversion and control of the electrical power.

UNIT 1 POWER SEMICONDUCTOR DEVICES 9 Hrs. Overview of V-I characteristics of switching devices - Switching characteristics of Power Diode, BJT power MOSFETS, IGBT and Thyristor - SCR Protection circuits - Thyristor Turn-ON methods - firing circuits - Commutation techniques.

UNIT 2 PHASE CONTROLLED RECTIFIERS 10 Hrs. Principle of phase controlled converter operation - single phase half wave converter, semi converter & full converter with R, RL & RLE load - Freewheeling diode - Inverter operation of full converter - Three phase Semi converter & full converter with RL load.

UNIT 3 DC & AC CHOPPERS 9 Hrs. DC - DC Chopper: Principle of operation of Step down and step up choppers - Control Strategies - One, Two and Four quadrant operation. AC - AC Chopper: Single phase AC voltage controllers with R & RL load - Multistage sequence control. Single phase step up and step down cycloconverters.

UNIT 4 INVERTERS 9 Hrs. Principle of operation: Single phase half bridge & full bridge voltage source inverters - Three phase Voltage source inverters (120° and 180° mode) - Single phase current source inverter. PWM techniques: Single pulse PWM, Sinusoidal PWM, Modified sinusoidal PWM and multiple PWM

UNIT 5 APPLICATIONS 8 Hrs. SMPS: Flyback and Push Pull - UPS: Redundant and Non-Redundant - HVDC Transmission systems -Single phase full converter fed DC drives - Inverters for standalone photovoltaic systems.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Rashid M.H., “Power Electronics circuits Devices and Applications”, Prentice Hall, 3rd Edition, New Delhi, 2013 2. P.S.Bimbhra, “Power Electronics”, Khanna Publishers, 4rd Edition, 2003 3. P.C.Sen, “ Power Electronics”, Tata Mc Graw Hill Company, New Delhi, 1987. 4. M.D.Singh and K.B.Khanchandani, “Power Electronics” TMH, New Delhi, 2nd Edition, 2008. 5. Dubey G.K., Doradla S.R., Joshi A and Sinha R.M., “Thyristorised Power Controllers” - Wiley Eastern Limited 1986. 6. Ned Mohan, “ Power Electronics”, 2nd Edition, 2001. 7. Rashid M.H , Power electronics hank book, Academics press publications., 2nd Edition, 2007

END SEMESTER EXAM QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. PART A : 10 Questions of 2 marks each - No choice 20 Marks PART B : 2 Questions from each unit of Internal choice, each carrying 12 marks 60 Marks (Distribution may be 90% Theory & 10% Numerical)

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SEC1604 BIOMEDICAL SIGNAL AND IMAGE PROCESSING

(For ETCE and EIE)


3 0 0 3 100

COURSE OBJECTIVES To acquaint the students with the basics about Biomedical Signals and Images, Knowledge about ECG, EEG, XRAY Images, CT Scanners, MRI Images and PET images and applications of same On completion of this course the student will recognize Acquire knowledge about the basics of Biomedical signals and Images Acquire knowledge about the ECG, EEG, X-RAY and CT Scanner Acquire knowledge about the Applications of biomedical Signals and Images

UNIT 1 INTRODUCTION OF BIOMEDICAL SIGNALS 9 Hrs.

Bio medical Signal, Types of biomedical signals - ECG, ENG, EMG, ERG - Characteristics of some dynamic

biomedical signals - Acquisition of physiological signal, characteristics, frequency domain representation; stationary

and non-stationary bio-signals, Waveform detection and Pattern Recognition, Computation of diagnostic signal

parameters.

UNIT 2 INTRODUCTION OF BIOMEDICAL IMAGES 9 Hrs.

Overview of medical imaging technology, systems, and modalities. characteristics of biomedical Images,

Medical Image Formation Principles, Medical Image Storage, Archiving and Communication Systems and Formats:

PACS, DICOM, TIFF, RIS and HIS.

UNIT 3 PROCESSING OF BIOMEDICAL SIGNALS 9 Hrs.

Electrical Activities of Cell - Ion Transport in Biological Cells - Electrical Characteristics of Cell Membranes

Hodgkin-Huxley Model Electrical Data Acquisition, Electrocardiogram - Function and Structure of the Heart -

Electrocardiogram: ECG Processing and Feature Extraction of ECGs, Electroencephalogram - Signal of the Brain

Evoked Potentials, EEG Feature Extraction of EEGs

UNIT 4 PROCESSING OF BIOMEDICAL IMAGES 9 Hrs.

X-Ray Imaging and Computed Tomography, Biomedical CT Scanners, Magnetic Resonance Imaging

(MRI),Physical and Physiological Principles of MRI, Ultrasound Imaging Generation and Detection of Ultrasound

Waves, Physical and Physiological Principles of Ultrasound, Positron Emission Tomography - Physical and

Physiological, Principles of PET

UNIT 5 APPLICATIONS OF BIOMEDICAL SIGNALS AND IMAGES 9 Hrs.

Neurological Applications - The electroencephalogram EEG rhythms & waveform categorization of EEG

activity, recording techniques EEG, applications - Epilepsy, sleep disorders, brain computer interface. Modelling

EEG, linear stochastic models, Non linear modelling of EEG, Applications - Applications of Medical Imaging:

Validation, Image Guided Surgery, Image Guided Therapy, Computer Aided Diagnosis/Diagnostic Support Systems

Max. 45 Hours


1. Kayvan Najarian and Robert Splinter ,“Biomedical signal and image processing”, Second edition,2012

2. Atam P.Dhawan, “Medical Image Analysis”, Wiley Interscience Publication, NJ, USA 2003.

3. D.C.Reddy,”Biomedical Signal Processing Principles and Techniques”, Tata McGraw-Hill, 2005.

4. L. Yaroslavsky. Lecture notes. http://www.eng.tau.ac.il/~yaro





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SEC1612 MEMS AND ITS APPLICATIONS

(For ECE and EIE)


3 0 0 3 100

COURSE OBJECTIVES

To learn and design concepts of Micro electronics

To learn and design the micro sensors and its operations

UNIT 1 OVERVIEW OF MEMS AND MICROSYSTEMS 8 Hrs.

Definition - historical development - Fundamentals - Properties, Introduction to Design of MEMS and NEMS,

MEMS and Microsystems, Microsystems and microelectronics, Microsystems and miniaturization, Working principle

of micro system - Micro sensors, Micro actuators, Micro accelerometers and Micro fluidics, MEMS materials: Silicon,

silicon compounds, silicon Piezo- resistors, Gallium Arsenide, Quartz, Piezoelectric crystals, Polymers, Metals.

UNIT 2 MEMS FABRICATION & PACKAGING 10 Hrs.

Micro-system fabrication processes: Photolithography, Ion Implantation, Diffusion, and Oxidation. Thin film

depositions: LPCVD, Sputtering, Evaporation, Electroplating; Etching techniques: Dry and wet etching,

electrochemical etching; Micromachining: Bulk Micromachining, Surface Micromachining, High Aspect-Ratio (LIGA

and LIGA-like) Technology; Micro-Stereo lithography for polymer MEMS.

UNIT 3 MICRO SENSORS AND ACTUATORS 9 Hrs.

Micro-sensing for MEMS: Piezo-resistive Pressure Sensor, Capacitive sensor, Piezoelectric sensing,

Resonant sensing, Surface Acoustic Wave sensors Vibratory gyroscope, Electromechanical transducers:

Piezoelectric transducers, Electrostrictive transducers, Magnetostrictive transducers, Electrostatic actuators,

Electromagnetic transducers, Electro-dynamic transducers, Electro-thermal actuators, comparison of electro-thermal

actuation process.

UNIT 4 MEMS DESIGN AND INTRODUCTION TO OPTICAL RF MEMS 9 Hrs.

Micro system Design - Design consideration, process design, Mechanical design, Mechanical design using

MEMS. Optical MEMS,- System design basics - Gaussian optics, Matrix operations, Resolution. MEMS scanners

and retinal scanning display, Digital Micro mirror devices. RF Memes - Design basics, case study - Capacitive RF

MEMS switch, Performance issues.

UNIT 5 MEMS PACKAGING AND APPLICATIONS 9 Hrs.

MEMS packaging: Role of MEMS packaging, Types of MEMS packaging, selection of packaging materials,

flip-chip and multichip Unit packaging, RF MEMS packaging issues. Micro-machined transmission line and

components, micro-machined RF Filters, Micro-machined Phase shifters, and Micro-machined antenna, Gyros and

Bio-MEMS.

Max. 45 Hours


1. Vijay K. Varadan, K. J. Vinoy and K. A. Jose , “RF MEMS & Their Applications”, John Wiley & Sons, 2003.

2. Tai - Rai Hsu, “MEMS and Microsystems Design and Manufacturing”, Tata MC Graw Hill, New Delhi, Edition 2002.

3. Gabriel M Rebeiz, “RF MEMS - Theory Design and Technology”, John Wiley and Sons, 2003.

4. Nadim Maluf, “An introduction to Micro electro mechanical system design”, Artech House ,2000





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SEC1316 CMOS VLSI DESIGN

(For ECE, EEE, E&C, EIE and ETCE) L T P Credits Total Marks3 0 0 3 100

COURSE OBJECTIVES To focus on Key elements of semiconductor physics, Predominant CMOS technology and circuit style.

To study challenges of digital VLSI design, Conceptual thinking and design methodology over detailed circuit analysis techniques.

UNIT 1 MOS TRANSISTOR THEORY 9 Hrs. The MOS transistor-Current Voltage Relations-Threshold Voltage-Second order effects-Capacitances in

MOSFET - Scaling of MOS circuits -Review of CMOS - DC characteristics - Dynamic behavior- Power consumption .

UNIT 2 COMBINATIONAL LOGIC DESIGN 9 Hrs. nMOS depletion load and Static CMOS design - Determination of Pull-up and Pull-down ratio-Design of Logic gates- Sizing of transistors -Stick diagrams-Lay out diagram for static CMOS - Pass transistor logic - Dynamic CMOS design - Noise considerations - Domino logic, np CMOS logic - Power consumption in CMOS gates - Multiplexers - Transmission gates design.

UNIT 3 SEQUENTIAL LOGIC DESIGN 9 Hrs. Introduction - Static sequential circuits- CMOS static flip-flop - Dynamic sequential circuits -Pseudo static latch- Dynamic two phase flip-flop - clocked CMOS logic - Pipelining - NORA CMOS logic -True single phase clocked logic - Realization of D-FF in TSPC logic.

UNIT 4 SUBSYSTEM DESIGN 9 Hrs. Introduction-Designing Static and Dynamic Adder circuits - The Array Multiplier - Multiplier structures-Baugh-Wooly - Booth Multiplier - Barrel shifter - Memory structures - SRAM and DRAM design - Design approach of Programmable logic devices - PLA,PAL and FPGA.

UNIT 5 ASIC CONSTRUCTION 9 Hrs. Physical design - Goals and Objectives - Partitioning methods - Kernighan Lin algorithm - Hierarchical Floor planning - Floor planning tools -input, output and power planning -Min-cut placement, Force directed placement algorithm -Placement using simulated annealing - Greedy channel routing.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1. Jan M.Rabaey ,“Digital Integrated Circuits” , 2nd edition, September,PHl Ltd. 2000 2. M.J.S.Smith ,“Application Specific Integrated Circuits “, Ist edition,Pearson education. 1997 3. Douglas A.Pucknell,”Basic VLSI design”, PHI Limited, 1998. 4. E.Fabricious, “Introduction to VLSI design”, Mc Graw Hill Limited, 1990. 5. Neil Weste , “Principles of CMOS VLSI design”, Addison Wesley 1998. 6. Wayne Wolf,”Modern VLSI design ‘2nd Edition, Pearson education. 2003 7. Sung-Mo Kang & Yusuf,”CMOS Digital Integrated Circuits- Analysis & Design”, 2nd Edition, MGH.


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SEC1606 DIGITAL IMAGE PROCESSING

(For EEE, EIE, E&C, ETCE and CSE)


3 0 0 3 100

COURSE OBJECTIVES

To understand the basic principles and methods of digital image processing

To have a comprehensive background in image filtering

To develop analytic skill to process images

UNIT 1 DIGITAL IMAGE FUNDAMENTALS 9 Hrs.

Elements of Visual Perception; Image Sensing and Acquisition; Image Sampling and Quantization; Basic

Relationships between Pixels; Monochromatic Vision Models; Colour Vision Models; Colour Fundamentals; Colour

Models

UNIT 2 IMAGE ENHANCEMENT 9 Hrs.

Introduction; Point Processing - Image Negatives, Log transformations, Power Law Transformations,

Piecewise-Linear Transformation Functions; Arithmetic/Logic Operations - Image Subtraction, Image Averaging;

Histogram Processing - Histogram Equalization, Histogram Matching; Spatial filtering - Smoothing, Sharpening;

Smoothing Frequency Domain Filters - Ideal Low Pass, Butterworth Low Pass, Gaussian Low Pass; Sharpening

Frequency Domain Filters - Ideal High Pass, Butterworth High Pass, Gaussian High Pass.

UNIT 3 IMAGE RESTORATION 9 Hrs.

A Model of Image Degradation/Restoration Process; Noise Models; Inverse Filtering, Minimum Mean Square

Error Filtering, Constrained Least Square Filtering; Geometric Mean Filter; Geometric Transformations - Spatial

Transformations, Gray-Level Interpolation.

UNIT 4 MORPHOLOGICAL PROCESSING & SEGMENTATION 9 Hrs.

Morphological Image Processing - Logic Operations involving Binary Images; Dilation and Erosion; Opening

and Closing; Basic Morphological Algorithms - Boundary Extraction, Region Filling, Thickening, Thinning; Image

Segmentation - Detection of Discontinuities; Edge Linking; Boundary Detection; Thresholding - Global and Adaptive;

Region based Segmentation.

UNIT 5 COLOUR IMAGE PROCESSING & APPLICATIONS 9 Hrs.

Conversion of Colour Models; Basic of Full-Colour Image Processing; Colour Transformations; Smoothing;

Sharpening; Segmentation; Applications of Image Processing - Motion Analysis, Image Fusion, Image Classification.

Max. 45 Hours


1. Rafael C. Gonzalez, Richard E. Woods, “Digital Image Processing”, 2nd Edition, Pearson Education, Inc., 2004.

2. Anil K. Jain, “Fundamentals of Digital Image Processing”, PHI Learning Private Limited, New Delhi, 2002.

3. William K. Pratt, “Digital Image Processing”, 3rd Edition, John Wiley & Sons, Inc., 2001.

4. Rafeal C.Gonzalez, Richard E.Woods and Steven L. Eddins, “Digital Image Processing using Matlab”, Pearson Education,

Inc., 2004.

5. Bernd Jähne, “Digital Image Processing”, 5th Revised and Extended Edition, Springer, 2002.





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SPR1307 RESOURCE MANAGEMENT TECHNIQUES L T P C Total. Marks 3 0 0 3 100

COURSE OBJECTIVE To develop in a student efficient and effective deployment of an organization's resources when they are needed. Such resources may include financial resources, inventory, human skills, production resources, or information technology.

UNIT 1 INTRODUCTION AND LINEAR PROGRAMMING 9 Hrs. Operations Research(OR)- Nature – Characteristics – Phases - Role of OR in Decision making - Outline of OR Models Linear Programming – Formulation of L.P.problems –Solution by graphical method, simplex method, Two Phase Method, Big M methods, Dual Simplex method

UNIT 2 TRANSPORTATION AND ASSIGNMENT MODEL 9 Hrs. Transportation problem – Initial Basic feasible solution- Northwest corner method, Least Cost method, Vogel’s approximation method – Test for optimality-MODI method. Assignment problems- Hungarian assignment models- Travelling salesman problems

UNIT 3 RESOURCE SCHEDULING AND NETWORK ANALYSIS 9 Hrs. Problem of Sequencing – Problem with N jobs and 2 machines N Jobs 3 machines N Jobs and m machines and 2 Jobs m machines (Graphical method). Project Management -Basic concepts–Network construction and scheduling Critical Path Method (CPM) & Program Evaluation Review Technique (PERT) and resource leveling by network techniques, time – Cost trade off.

UNIT 4 INVENTORY CONTROL 9 Hrs. Inventory Control – Various Types of inventory models – deterministic inventory models – Production model, Purchase model– with and without shortage- Economic Order Quantity (EOQ) – Buffer stock – Shortage quantity, Probabilistic inventory models – Quantity Discount and Price Breaks

UNIT 5 QUEUEING THEORY AND REPLACEMENT MODELS 9 Hrs. Queuing theory – Poisson arrivals and exponential service times, Single channel models only, Replacement policy for items whose maintenance cost increases with time- Consideration of time value of money - Replacement policy- Individual, Group replacement of items that fail completely and suddenly.

Max. 45 Hours

TEXT / REFERENCE BOOKS 1.. R.Panneerselvam, “Operation Research”, 2nd Edn., Prentice Hall, 2001. 2. S.D Sharma, “Operation research Theory, Methods and Application”, 17th Edn., Kedar Nath Ram Nath Publication, 2010. 3. Nita H Shah, Ravi M Gor & Hardik Soni, “Operation Research”, 4th Edn., PHI, 2010. 4. Hamdy A.Taha, “Operation Research”, 8th Edn, PHI, 2008 5. Hiller & Liberman., “Introduction to Operations Research”, 5th Edition, Mc Graw Hill, 2001 6. Ravindran,Phillips &Solberg, “Operations Research: Principles and practice”, 2nd Edn., Wiley India Lts, 2007 7. Ronald L. Rardin, “Optimization in Operations Research”, Prentice Hall, 1998

END SEMESTER EXAMINATION QUESTION PAPER PATTERN Max. Marks : 80 Exam Duration : 3 Hrs. Part A : 10 Questions of 2 marks each - No choice 20 Marks Part B : 2 Questions from each unit of internal choice; each carrying 12 marks 60 Marks

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