Curriculum and Syllabi

1

Pondicherry Engineering College, Puducherry – 605014

(An Autonomous Institution of Government of Puducherry, affiliated to Pondicherry University)

Curriculum and Syllabi for

B.Tech. (Electronics and Instrumentation Engineering) (Effective from Academic year 2018-19)

(Approved in Fifth Academic Council Meeting held on 6th May 2019)

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CURRICULUM

The Curriculum of B.Tech. (Electronics and Instrumentation Engineering) is designed to fulfil the Program Educational Objectives (PEO) and the Program Outcomes (PO) listed below.

PROGRAM EDUCATIONAL OBJECTIVES (PEO)

PEO1 Our graduates acquire strong foundation in the mathematical, science and all engineering fundamentals necessary to formulate solutions to engineering problems that are technically sound.

PEO2 Our graduates possess technical knowledge in Electronics, Instrumentation and Control related fields that can address current technical issues and develop as potential entrepreneur.

PEO3 Our graduates expertise in carrying design and development projects using modern methodologies and hence are able to pursue higher education and research activities.

PEO4 Our graduates emphasize on high degree of ethics with good communication skill to work collaboratively in groups, thus contributing immensely to the growth and development of our society.

PROGRAM OUTCOMES (PO) : The graduates will have the ability to

a. have the ability to apply knowledge of mathematics, science, and engineering.

b. Identify and formulate Instrumentation Engineering problems from research literature and be able to analyze the problem using first principles of Mathematics and Engineering Sciences.

c. Come out with solutions for the complex problems and to design system components orprocess that fulfill the particular needs taking into account public health and safety and the social, cultural and environmental issues

d. Draw well-founded conclusions applying the knowledge acquired from research and research methods including design of experiments, analysis and interpretation of data and synthesis of information and to arrive at significant conclusion

e. Form, select and apply relevant techniques, resources and Engineering and IT tools for Engineering activities like electronic prototyping, modeling and control of systems/processes and also being conscious of the limitations.

f. Understand the role and responsibility of the Professional Instrumentation Engineer and to assess societal, health, safety issues based on the reasoning received from the contextual knowledge.

g. Be aware of the impact of professional Engineering solutions in societal and Environmental contexts and exhibit the knowledge and the need for sustainable Development.

h. Apply the principles of Professional Ethics to adhere to the norms of the engineering practice and to discharge ethical responsibilities

i. Function actively and efficiently as an individual or a member/leader of different teams and multidisciplinary projects.

j. Communicate efficiently the engineering facts with a wide range of engineering community and others, to understand and prepare reports and design documents; to make effective presentations and to frame and follow instructions

k. Demonstrate the acquisition of the body of engineering knowledge and insight and Management Principles and to apply them as member / leader in teams and multidisciplinary environments.

l. Recognize the need for self and life-long learning, keeping pace with technological challenges in the broadest sense

PEO/PO a b c d e f g h i j k l

PEO1

PEO2

PEO2

PEO4

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PROGRAM SPECIFIC OUTCOMES (PSO)

PSO1 Graduates possess an ability to recognize, adapt and to apply the knowledge of electronics and Instrumentation to optimize Measurement systems to various applications.

PSO2 Graduates learn latest tools and apply them in the design and analysis of modern control systems.

PSO3 Graduates can function in a Multidisciplinary Environment by being able to associate and integrate their domain knowledge with other disciplines.

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Credit Distribution

Distribution of total 160 credits among the subjects grouped under various categories is as follows:

Sl. No.

Category Credits

Course Category

Code (CCC)

1 Humanities, Social Sciences and Management Courses 6 HSM

2 Basic Science Courses (Mathematics, Physics, chemistry and Biology)

25 BSC

3 Engineering Science Courses (Workshop, Drawing, Basics of Electrical/Mechanical/Computer etc.,)

19 ESC

4 Professional Core Courses 69 PCC

5 Professional Elective Courses (from chosen discipline) 15 PEC

6 Open Elective Courses (from other technical/ emerging disciplines)

10 OEC

7 Professional Activity Courses (Project Work, Entrepreneurship, Seminar, Internship, Comprehensive Test)

16 PAC

8 Mandatory non-Credit Courses (Environmental Sciences, Induction, Indian Constitution, Essence of Indian Traditional Knowledge, Professional Ethics)

Non-credit

MCC

Total 160

*included in open elective courses

5

Semester-wise Courses and Credits

Semester I

Course Code

Course CCC SET Periods

Credits L T P

FY201 Induction Programme MCC - - - - 0

MA201 Mathematics I BSC TY 3 1 0 4

PH201 Physics BSC TY 3 1 0 4

CY201 Chemistry BSC TY 3 1 0 4

HS201 English for Communication HSM TY 2 0 2 3

ME201 Workshop and Manufacturing Practice ESC LB 0 0 3 1.5

PH202 Physics Laboratory BSC LB 0 0 3 1.5

CY202 Chemistry Laboratory BSC LB 0 0 3 1.5

Total 11 3 11

19.5 25

Semester II

Course Code


Credits L T P

MA202 Mathematics II BSC TY 3 1 0 4

EE201 Basic Electrical Engineering ESC TY 3 1 0 4

CS201 Programming for Problem Solving ESC TY 3 0 0 3

ME202 Engineering Graphics and Computer Aided Drawing

ESC TY

2 0 4 3

CE201 Environmental Science MCC - 3 0 0 0

EE202 Basic Electrical Engineering Laboratory ESC LB 0 0 3 1.5

CS202 Programming Laboratory ESC LB 0 0 3 1.5

Total 14 2 10

17 26

CCC - Course Category Code, SET – Semester Exam Type, TY – Theory, LB – Laboratory, PR - Project

6

III Semester:

Course Code


Credits L T P

EIOXX Open Elective OEC TY 3 - - 3

EIH01 Measurement data Analysis PCC TY 3 1 - 4

EIM01 Transducer Engineering PCC TY 3 1 - 4

IV Semester:

Course Code


Credits L T P

SH202 Indian Constitution MCC - 2 - - 0

EI207 Linear Integrated Circuits PCC TY 3 - - 3

EI208 Electrical and Electronics Instruments PCC TY 3 - - 3

EI209 Transducers and Measurements System PCC TY 3 - - 3

CS234 Data Structures and OOPS ESC TY 3 - - 3

EIYXX Professional Elective Course -I PEC TY 3 - - 3

EI210 Linear and Integrated Circuits Lab PCC LB - - 3 1.5

CS235 Data structures and OOPS Lab ESC LB - - 3 1.5

EI211 Transducers and Measurements System Lab

PCC LB

- - 3 1.5

Total 17 9 -

26 19.5

Course Code


Credits L T P


EIH02 Design Of Sensors And Transducers PCC TY 3 1 - 4

EIM02 Measuring Instruments And Testing PCC TY 3 1 - 4

Course Code


Credits L T P

MA204 Transforms, Partial Differential Equations and Statistics

BSC TY

3 1 - 4

SH201 Biology for Engineers BSC TY 3 - - 2

EI201 Circuit Theory PCC TY 3 1 - 4

EI202 Electronic Circuits PCC TY 3 - - 3

EI203 Electronic Design and fabrication PCC TY 3 1 - 4

EI204 Digital Logic Theory and Design PCC TY 3 - - 3

EI205 Electronic Circuits Lab PCC LB - - 3 1.5

EI206 Electronic Design and fabrication lab PCC LB - - 2 1

Total 18 3 5 -

26 22.5

7

V Semester:

Course Code


Credits L T P

EI213 Industrial Instrumentation PCC TY 3 1 - 4

EI214 Microprocessors and Applications PCC TY 3 - - 3

EI215 Control Systems PCC TY 3 1 - 4

EP201 Entrepreneurship PAC TY 3 - - 2

EIYXX Professional Elective Course -II PEC TY 3 - - 3

EI216 Instrumentation System design Lab PCC TY - - 3 1.5

EI217 VLSI Lab PCC LB - - 3 1.5

EI218 Microprocessors and Applications Lab PCC LB - - 3 1.5

SH203 Essence of Indian Traditional Knowledge MCC - 2 - - 0

Total 17 2 9 -

28 20.5

Course Code


Credits L T P


EIH03 Field Instruments for Process Control PCC TY 3 1 - 4

EIM03 Measurements In Process Industries PCC TY 3 1 - 4

VI Semester:

Course Code


Credits L T P

EI219 Process Control PCC TY 3 1 - 4

EI220 Embedded System Design PCC TY 3 1 - 4

EI221 Robotics and Automation PCC TY 3 3

HS202 Industrial Economics and Management HSM TY 3 - 3

EIYXX Professional Elective Course -III PEC TY 3 - - 3

EI222 Process Control Lab PCC LB - - 3 1.5

EI223 Virtual Instrumentation Lab

PCC LB

- 3 1.5

EI224 Embedded System Design Lab PCC LB - - 3 1.5

Total 15 2 9 -

26 21.5

Course Code


Credits L T P


EIH04 Advanced control engineering PCC TY 3 1 - 4

EIM04 Essentials of control engineering PCC TY 3 1 - 4

8

VII Semester:

Course Code


Credits L T P

EI225 PLC and DCS PCC TY 3 1 - 4

EI226 Analytical Instruments PCC TY 3 1 - 4

EIYXX Professional Elective Course -IV PEC TY 3 - - 3

EIYXX Professional Elective Course -V PEC TY 3 - - 3

EI227 Industrial Measurements and Control Lab PCC TY - - 3 1.5

EI228 Seminar PAC LB 3 - - 1

EI229 Mini Project PAC LB - - 3 2

EI230 Professional Ethics MCC - 2 - - 0

Total 17 2 3 -

22 18.5

Course Code


Credits L T P


EIH05 Cyber Security in Industrial Automation PCC TY 3 1 - 4

EIM05 Internet of things for automation PCC TY 3 1 - 4

VIII Semester:

Course Code


Credits L T P

SWO01 Open Elective through SWAYAM OEC - - - - 2

SWO02 Open Elective through SWAYAM OEC - - - - 2

EI231 Comprehensive Test PAC - - - - 1

EI232 Internship PAC - - - - 2

EI233 Project Work PAC - - - - 8

Total - - - -

15

9

List of Professional Elective Courses (PEC)

Professional Electives Course Code

Course Semester

Professional Elective – I/II

EIY01 Signals and Systems

VI

EIY02 Visual Programming for Instrumentation Engineers

EIY03 Industrial Electronics

EIY04 Virtual Instrumentation

Professional Elective –III/IV/V

EIY05 Digital Signal Processing

EIY06 Applied Soft Computing

EIY07 VLSI Design

EIY08 Biomedical Instrumentation

EIY09 Instrumentation System Design

EIY10 Digital Image Processing

VII

EIY11 Design of Process Control System Components

EIY12 Power Plant Instrumentation

EIY13 Fiber Optics and Laser Instrumentation

EIY14 MEMS

EIY15 Instrumentation In Petrochemical Industry

List of Open Elective Courses (OEC)

Course Code

Course

EIO01 Measurements and Instrumentation

EIO02 Process Instrumentation

EIO03 Principles of Medical Electronics

EIO04 Microcontroller based system Design

EIO05 Fundamentals of MEMS

10

Courses offered under various categories:

CCC Course Code

Course Semester Credit Total Credit

BSC

MA201 Mathematics – I I 4

25

PH201 Physics I 4

CY201 Chemistry I 4

PH202 Physics laboratory I 1.5

CY202 Chemistry Laboratory I 1.5

MA202 Mathematics –II II 4

SH201 Biology for Engineers III 2


III 4

ESC

ME201 Workshop and Manufacturing Practice I 1.5

19

EE201 Basic Electrical Engineering II 4

CS201 Programming for Problem Solving II 3

ME202 Engineering Graphics & Computer Aided Drawing

II 3

EE202 Electrical Engineering Laboratory II 1.5

CS202 Programming Laboratory II 1.5

CS234 Data Structures and OOPS IV 3

CS235 Data Structures and OOPS Lab IV 1.5

PCC

EI201 Circuit Theory III 4

69

EI202 Electronic Circuits III 3

EI203 Electronic Design and fabrication III 4

EI204 Digital Logic Theory and Design III 3

EI205 Electronic Circuits Lab III 1.5

EI206 Electronic Design and fabrication lab III 1

EI207 Linear Integrated Circuits IV 3

EI208 Electrical and Electronics Instruments IV 3

EI209 Transducers and Measurements System IV 3

EI210 Transducers and Measurements System lab

IV 1.5

EI211 Linear and Integrated Circuits Lab IV 1.5

EI213 Industrial Instrumentation V 4

EI214 Microprocessors and Applications V 3

EI215 Control Systems V 4

EI216 Instrumentation System design Lab V 1.5

EI217 VLSI Design Lab V 1.5

EI218 Microprocessors and Applications Lab V 1.5

EI219 Process Control VI 4

EI220 Embedded System Design VI 4

EI221 Robotics and Automation VI 3

EI222 Process Control Lab VI 1.5

EI223 Virtual Instrumentation Lab VI 1.5

EI224 Embedded System Design Lab VI 1.5

EI225 PLC and DCS VII 4

EI226 Analytical Instruments VII 4

EI227 Industrial Measurements and Control Lab VII 1.5

PEC

- Professional Elective – I IV 3

15

- Professional Elective – II V 3

- Professional Elective – III VI 3

- Professional Elective – IV VII 3

- Professional Elective – V VII 3

OEC ZZOXX Open Electives offered by other III - VII 6 10

11

Departments

SWOXX Open Electives offered under SWAYAM - 4

PAC

EP201 Entrepreneurship V 2

16

EI228 Seminar VII 1

EI229 Mini Project VII 2

EI231 Comprehensive Test VIII 1

EI232 Internship VIII 2

EI233 Project Work VIII 8

HSM

HS201 English for Communication I 3

6 + 3*/ 2*

HS202 Industrial Economics & Management VI 3

HSOXX Humanities Open Elective offered by HSS Department

- 3*

SWOXX Humanities Open Elective offered under SWAYAM

- 2*

160

*included in the 10 credits under Open Elective category

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Department : Mathematics Programme : B.Tech - Mech, EEE, E&I, CHEMICAL ENGG.

Semester : Third Subject Category: BSC Exam Type: TY

Course Code Course Name Hours / Week Credit Maximum Marks

L T P C CA SE TM


3 1 - 4 40 60 100

Prerequisite: Basic Integration and Probability

Outcome:

CO1 Understands Transform Calculus

CO2 Understands how to form partial differential equations

CO3 Solve the Partial Differential Equations

CO4 Gain knowledge on solving Boundary Value Problems

CO5 Understand basic statistics and distributions

UNIT-I LAPLACE TRANSFORMS Hours: 12

Definition of Laplace Transform, Inverse Laplace Transform, Linearity property, Laplace transform of unit step function, Unit impulse function and some elementary functions, Change of scale and first shifting property, Derivatives and integrals of Laplace transform, Transform of derivatives and integrals, Application: Solution of single ordinary linear differential equation with constant coefficients-Laplace transform of Periodic functions.

CO1

UNIT-II PARTIAL DIFFERENTIAL EQUATIONS Hours: 12

General and Singular solution of PDE, Complete Solution of First order Non-linear PDE, Lagrange's linear equation of first order, Solution of the simultaneous equations by the method of grouping and multipliers.

CO2

UNIT-III HIGHER ORDER PDE AND BOUNDARY VALUE PROBLEMS Hours: 12

Homogeneous linear PDE of higher order with constant coefficients. Solution of partial differential equation by the method of separation of variables. Application of PDE: Variable separable solutions of the one dimensional wave equation, Transverse vibration of a stretched string.

CO3

UNIT-IV ONE DIMENSIONAL AND TWO DIMENSIONAL HEAT FLOW Hours: 12

Heat Equation, Variable and separable solution of one dimensional heat equation, Temperature distribution with zero and non-zero boundary values, Two dimensional heat flow under steady state conditions(Cartesian).

CO4

UNIT-V PROBABILITY AND STATISTICS Hours: 12

Probability, Events, Sample space, Axioms of probability, Random variable(Discrete and Continuous), Expectation, Probability Distribution: Binomial, Poisson & Normal distribution and statistical parameters of these distributions, Correlation and Regression, Rank correlation.

CO5

Total contact Hours: 45 Total Tutorials: 15 Total Practical Classes:- 00 Total Hours: 60

Reference Books:

1. Veerarajan T, Engineering Mathematics II, McGraw-Hill Education(India) Private Limited, 2014 2. Veerarajan T, Transforms and Partial Differential Equations, Third Edition, McGraw-Hill Education(India)

Private Limited, 2016. 3. Venkataraman M.K., Engineering Mathematics, Third Year, Part-B, The National Publishing Company,

Chennai, 2008. 4. S.C.Gupta and V.K.Kapoor, Fundamentals of Mathematical Statistics, 10th Edition, Sultan Chand &Sons, New

Delhi, 2000. 5. Erwin Kreyszig, Advanced Engineering Mathematics (9 th Ed), John Wiley & Sons, New Delhi, 2011. 6. Ramana B.V., Higher Engineering Mathematics, Tata McGraw Hill New Delhi, Eleventh Reprint, 2010. 7. Bali N. and Goyal M., Advanced Engineering Mathematics, Laxmi Publications Pvt. Ltd., New Delhi, 9thEdition,

2011.

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Department: Electronics and Instrumentation Engineering Programme : B.Tech.(EI)

Semester : Third Subject Category: BSC Semester Exam Type: TY

Course Code Course Name Periods /

Week Credit Maximum Marks

L T P C CA SE TM

SH201 Biology for Engineers 3 - - 2 40 60 100

Prerequisite -

Outcomes

After studying the course, the student will be able to:

CO1 Convey that classification per se is not what biology is all about but highlight the underlyingcriteria, such as morphological, biochemical and ecological

CO2 Highlight the concepts of recessiveness and dominance during the passage of genetic materialfrom parent to offspring

CO3 Convey that all forms of life have the same building blocks and yet the manifestations are asdiverse as one can imagine

CO4 Gain a basic understanding of enzyme action and factors affecting their activity.

CO5 Identify and classify microorganisms.

UNIT-I Classification Periods: 9

Classification outline based on (a) cellularity- Unicellular or multicellular (b) ultrastructure prokaryotes or eukaryotes (c) Energy and Carbon utilisation -Autotrophs, heterotrophs, lithotropes (d) Ammonia excretion – aminotelic, uricoteliec, ureotelic (e) Habitats- acquatic or terrestrial (e) Molecular taxonomy three major kingdoms of life.

CO1

UNIT-II Genetics Periods: 9

Mendel’s laws, Concept of segregation & independent assortment. Concept of allele. Recessiveness, and dominance. Single gene disorders in humans – Sickle cell disease, Phenylketonuria.

CO2

UNIT-III Biomolecules Periods: 9

Carbohydrates: Types, Structural & functional importance. Lipids: Classification - Simple, compound, & derived, Importance of lipid soluble vitamins. Amino acids – general structure, essential amino acids. Proteins - Levels of protein structure, structural & functional importance of proteins, Enzymes- Definition, Enzyme Activity & Units, Specific Activity, Specificity, Factors affecting enzyme activity. Nucleic acids: Types and importance.

CO3

UNIT-IV Metabolism Periods: 9

Introduction: Food chain & energy flow. Definitions - Anabolism & Catabolism. Photosynthesis: Reaction and importance. Glycolysis & TCA cycle. ATP – the energy currency of cells

CO4

UNIT-V Microbiology Periods: 9

Concept of single celled organisms. Concept of species & strains. Identification & classification of microorganisms. Virus – Definition, types, examples.

CO5

Lecture Periods: 45 Tutorial Periods: Practical Periods: Total Periods: 45

Reference Books:

1. Biology: A global approach: Campbell, N. A.; Reece, J. B.; Urry, Lisa; Cain, M,L.; Wasserman, S. A.; Minorsky, P. V.; Jackson, R. B. Pearson Education Ltd

2. Outlines of Biochemistry, Conn, E.E; Stumpf, P.K; Bruening, G; Doi, R.H. John Wiley and Sons 3. Principles of Biochemistry (V Edition), By Nelson, D. L.; and Cox, M. M.W.H. Freemanand Company 4. Molecular Genetics (Second edition), Stent, G. S.; and Calender, R. W.H. Freeman andcompany, Distributed by

Satish Kumar Jain for CBS Publisher 5. Microbiology, Prescott, L.M J.P. Harley and C.A. Klein 1995. 2nd edition Wm, C.Brown Publishers.

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Department: Electronics and Instrumentation Engineering Programme : B.Tech.

Semester : Course Category Code: PCC Semester Exam Type:TY

Course Code Course Name Periods / Week Credit Maximum Marks

L T P C CA SE TM

EI201 CIRCUIT THEORY 3 1 0 4 40 60 100

Prerequisite:

Course Outcome

CO1 Analyse Electric circuits using network theorems

CO2 Understand the resonance phenomenon and its significance.

CO3 Analyse electric circuits for transient response using Laplacetransform

CO4 Understand the concepts network function and network parameters

CO5 Design passive filters for the given application

UNIT-I NETWORK THEOREMS FOR DC AND AC CIRCUITS Periods12:

Review of loop and nodal methods of analysis, star-to-delta or delta-to-star transformation, Source transformation, Superposition theorem, Thevenin’s theorem, Norton’s theorem, reciprocity theorem, compensation theorem, Maximum power transfer theorem, Millman’s theorem and Tellegen’s theorem applied to dc and ac circuits.

CO1

UNIT-II RESONANCE AND COUPLED CIRCUITS Periods: 12

Resonance – Series and parallel resonance circuits- Concept of band width and Q factor. Coupled Circuits: Faraday’s laws of electromagnetic induction – Concept of self and mutual inductance – dot convention – coefficient of coupling.

CO2

UNIT-III TRANSIENT ANALYSIS Periods:12

Initial conditions in elements, Transient response of R-L, R-C, R-L-C circuits (Series combinations only) for step and sinusoidal excitations -Solution using Laplace transform

CO3

UNIT-IV NETWORK FUNCTIONS AND NETWORKPARAMETERS

Periods: 12

Network functions: The concept of complex frequency- concept of transformed network- driving point impedance and admittance-transfer function- Properties of driving point impedance -poles and zeros. Z, Y, ABCD, hybrid parameters and their relations– 2-port network parameters using transformed variables.

CO4

UNIT-V PASSIVE FILTERS Periods: 12

Classification of filters - Analysis of a proto type low pass filter and High pass filters- Analysis of a proto type Band pass and Band stop filters- constant K filters - m-derived filters – BPF and BSF-Lowpass filter with RL and RC sections-High pass filter with RC and RL Sections-Band pass filter with RLC circuits

CO5

Lecture Periods: 45 Tutorial Periods:15 Practical Periods: -- Total Periods:60

Reference Books:

1. William Hayt and Jack E. Kimmerly, Engineering circuit analysis, McGraw Hill Company, 8th edition, 2013. 2. P. Ramesh Babu, Circuit theory, Second Edition, Scitech Publications Pvt. Ltd, 2017. 3. N.C. Jagan&C.Lakshminarayana, Network Theory, B.S Publications, 2006. 4. Kuriakose, Circuit Theory, PHI Learning, 2005

15

Department: Electronics and Instrumentation Engineering Programme: B.Tech.

Semester : Third Course Category Code: PCC Semester Exam Type: TY


L T P C CA SE TM

EI202 Electronic Circuits 3 - 0 3 40 60 100

Prerequisite: Basic knowledge of electronics engineering

Course Outcome

CO1 To understand the working of simple circuits using diodes

CO2 To understand the operation of transistor as amplifier and switch and to design various biasing circuits

CO3 To understand the models of transistor and its frequency response

CO4 To understand concept of positive feedback and negative feedback in amplifier and oscillator

CO5 To understand the operation FET and its biasing and study the SCR, UJT, DIAC, TRIAC

UNIT-I SEMICONDUCTOR DIODES Periods: 9

The PN Diode- VI Characteristics of a Diode- Diode Models- Testing a Diode. Applications of Diodes:Half-wave and Full-wave rectifiers-Power Supply Filters and Regulators-Clipping and Clamping Circuits- Zener Diode- Applications of Zener Diode. Special Diodes: Tunnel Diode-PIN Diode- Varactor Diode- Light Emitting diode-Photo Diode.

CO1

UNIT-II BIPOLAR JUNCTION TRANSISTORS (BJT) Periods: 9

BJT Operation-Transistor Characteristics- Applications of Transistor as a switch, as an amplifier. The DC and AC Load Line and operating point, Types of BJT Biasing, analysis and Design, Biasing stability, Temperature compensation, Thermal runway. Basic Amplifier Operation, Amplifier AC and DC equivalent circuits, Characteristics of common Emitter Amplifier, Common Collector Amplifier, Common Base amplifier.

CO2

UNIT-III TRANSISTOR AMPLIFIERS AND FREQUENCY RESPONSE Periods: 9

Small signal transistor amplifier circuits: r-parameter and h-parameter representation of a transistor, Analysis of single stage transistor amplifier using r parameter and h-parameters: voltage gain, current gain, Input impedance and Output impedance. BJT Amplifier Frequency Response: The Decibel, Low Frequency Amplifier Response, High Frequency Amplifier Response, Total frequency response of Amplifier, Multistage Amplifier , Frequency response of multistage amplifiers.

CO3

UNIT-IV FEEDBACK AND POWER AMPLIFIERS Periods: 9

Concept of feedback, Classification of Negative feedback amplifiers - the oscillator- Barkhausen criteria for oscillations -RC phase shift oscillator, Wien bridge oscillator, Colpitt’s oscillator, Hartley oscillator, crystal oscillator. Multivibrators – Astable, Monostable ,Bistable modes of operation, Schmitt trigger.Class A power amplifier, maximum value of efficiency of Class A amplifier, transformer coupled amplifier, Class B and Class AB Push-Pull amplifiers, complimentary symmetry circuits (transformerless class B power amplifier), class C operation.

CO4

UNIT-V FIELD EFFECT TRANSISTORS (FET) Periods: 9

The JFET- Characteristics and Parameters - JFET Biasing-JFET amplifiers - common source, common Drain, common Gate amplifiers - The MOSFET-Enhancement and Depletion mode MOSFETs - MOSFET characteristics and Parameters - Basic Four Layer Device - Silicon Controlled Rectifier (SCR)-Applications of SCR- The DIAC and TRIAC, Uni-junction Transistor(UJT).

CO5

Lecture Periods: 45 Tutorial Periods: Practical Periods: Total Periods:45

Reference Books:

1. Floyd, Electronic Devices, Pearson Education, 7thEdition , 2008 2. Millman, C.C.Halkias, and SatyabrathaJit, Electronic Devices and Circuits, Tata McGraw Hill, 2nd Ed., 2007. 3. R.L. Boylestad and Louis Nashelsky , Electronic Devices and Circuits ,Pearson/Prentice Hall, 9th Edition,2006. 4. P. Ramesh Babu, Electronic Devices and Circuits, Scitech Publications Pvt,Ltd., 2008 5. Nagrath, Electronic Devices and Circuits, PHI Learning, 2006

16


Semester : Third Course Category Code: PCC Semester Exam Type:TY


L T P C CA SE TM

EI203 Electronic Design and Fabrication 3 1 0 4 40 60 100

Prerequisite:

Course Outcome

CO1 The student will gain conceptual understanding of Arduino Platform

CO2 The students will become knowledgeable about firmware development using arduino platform

CO3 The students will gain knowledge about sensors and peripheral devices.

CO4 The students will learn about design of real time electronic systems using arduino.

CO5 Student will get understanding of PCB designing and fabrication.

UNIT-I Introduction to Electronic System Design Periods: 9

Building blocks of electronic system design– Key Design Metrices- Introduction to AnalogI/O - Digital I/O – Introduction to Arduino platform- Hardware features – Types of Arduino boards – Features of Arduino Uno - pin details - Arduino IDE – configuration settings - basic sketch in Arduino – compiling and downloading sketches.

CO1

UNIT-II Arduino Firmware Development Periods: 9

Data types, operators, Decision Making statements, Looping statements, Arrays, Functions, Classes, Arduino Libraries, debugging. Built in I/O Functions, Programming digital I/O, analog I/O, UART communication, PWM and Interrupt programming - Intel Hex File format.

CO2

UNIT-III Peripherals and Sensors Periods: 9

Peripherals: LEDs, switches, Relays, Buzzers, Seven segment displays, keypads, Character LCDs, graphical LCDs, SD card memory, DC and Servomotors. Sensors: Temperature, Infrared, Moisture and Humidity sensor, Pressure, Light, Gas Sensor, Motion Sensor, Speed, PIR Sensor, Accelerometer.

CO3

UNIT-IV Design of Electronic systems. Periods: 9

Study of temperature control system – Robotic system using DC motors – Ultrasonic Range system – Security system using sensors – weather monitoring system – Street light control system – GSM based systems – WiFi and Bluetooth based systems – PC based Measurement and Control.

CO4

UNIT-V PCB Design and Fabrication Periods: 9

Introduction to PCB Designing - Steps in PCB Designing and Manufacturing- Electronics Components and their Packaging- Schematic Editor - Schematic Diagram - Board/Layout Editor- Converting Schematic into Board - Layers - Routing - Important Guidelines and standards - Gerber file generation.

CO5

Lecture Periods: 45 Tutorial Periods: 0 Practical Periods: 0 Total Periods:45

Reference Books:

1. Simon Monk, Programming Arduino Next Steps: Going Further with Sketches, Mc Graw Hill Education-2019. 2. Michael Margolis, Arduino CookBook, Oreilly-2011. 3. Jeremy Blum, Exploring Arduino, Wiley-2012. 4. Mark Geddes, Arduino Project Handbook: Volume one: Complete Guide to Creating with the Arduino, Sketch

Publishing-2014. 5. Muhammad Ali Mazidi, Shujen Chen, Eshragh Ghaemi, Arduino Programming From Beginning to Advanced, Micro

Digital-Ed-2018.

17




L T P C CA SE TM

EI204 Digital Logic Theory and Design 3 0 0 3 40 60 100

Prerequisite: -

Course Outcome

CO1 The students will be able to understand the digital Logic families and relevant ICs and its usages

CO2 The students will be able to understand the design of digital circuit and its principle

CO3 The students will be able to design sequential circuits by understanding the working of various sequential circuits

CO4 The student will understand asynchronous sequential circuits and algorithmic state machines

CO5 The students will be able to distinguish between different memory devices

UNIT-I Minimization Techniques and Logic Gates Periods: 12

Number System and Boolean algebra: Review of Number systems and codes – Error detecting codes –Hamming Code- Boolean postulates and laws – De-Morgan’s Theorem - Principle of Duality -Boolean expression - Minimization of Boolean expressions –– Minterm – Maxterm - Sum of Products (SOP) –Product of Sums (POS) – Karnaugh map Minimization – Don’t care conditions - Quine-McCluskey method of minimization. Logic Gates: AND, OR, NOT, NAND, NOR, Exclusive–OR and Exclusive–NOR Implementations of Logic Functions using gates, NAND–NOR implementations - TTL and CMOS Logic and their characteristics –Tristate gates.

CO1

UNIT-II Combinational Circuits Periods: 12

Design procedure – Half adder – Full Adder – Half subtractor – Full subtractor - Parallel binary adder, Parallel binary Subtractor – Fast Adder - Carry Look Ahead adder –- BCD adder – Multiplexer/ Demultiplexer – Decoder - Encoder – Parity checker – Parity generators - Code converters - Magnitude Comparator.

CO2

UNIT-III Sequential Circuits Periods: 12

Latches, Flip-flops - SR, JK, D, T, and Master-Slave – Characteristic table and equation –Edge triggering – Level Triggering – Realization of one flip flop using other flip flops –Asynchronous Ripple or serial counter – Asynchronous Up/Down counter - Synchronous counters – Synchronous Up/Down counters –Design of Synchronous counters: State diagram- State table – State minimization –State assignment -Excitation table and maps-Circuit implementation - Modulo–N counter, Registers – Shift registers -Universal shift registers – Shift register counters – Ring counter – Shift counters - Sequence generators.

CO3

UNIT-IV Synchronous and Asynchronous Sequential Circuits Periods: 12

Synchronous Sequential Circuits: General Model – Classification – Design – Use of Algorithmic State Machine – Analysis of Synchronous Sequential Circuits - Asynchronous Sequential Circuits: Design of fundamental mode and pulse mode circuits – Incompletely specified State Machines– Problems in Asynchronous Circuits – Design of Hazard Free Switching circuits.

CO4

UNIT-V Memory Devices Periods: 12

Classification of memories –ROM organization - PROM – EPROM – EEPROM – EAPROM, RAM organization – Write operation – Read operation – Memory cycle - Timing wave forms – Memory decoding – memory expansion – Static RAM Cell- Bipolar RAM cell – MOSFET RAM cell – Dynamic RAM cell– Programmable Logic Devices – Programmable Logic Array (PLA) - Programmable Array Logic (PAL) –Complex Programmable Logic Device (CPLD)- Field Programmable Gate Arrays (FPGA) - Implementation of combinational logic circuits using ROM, PLA, PAL.

CO5

Lecture Periods: 45 Tutorial Periods: 15 Practical Periods: Total Periods:60

Reference Books:

1. R.Ananda Natarajan , Digital Design, 1st Edition, PHI Learning Pvt. Limited, New Delhi 2015. 2. M. Morris Mano, M.MichaelCiletti , Digital Design, 5th Edition, Pearson Education(Singapore) Pvt. Ltd., New Delhi,

2013. 3. John F.Wakerly, Digital Design, Fourth Edition, Pearson/PHI, 2006 4. John.M Yarbrough, Digital Logic Applications and Design, Thomson Learning, 2002. 5. Charles H.Roth. Fundamentals of Logic Design, Thomson Learning, 2003. 6. Donald P.Leach and Albert Paul Malvino, Digital Principles and Applications, 6th Edition, TMH, 2003.

18

7. William H. Gothmann, Digital Electronics, 2nd Edition, PHI, 1982. 8. Thomas L. Floyd, Digital Fundamentals, 8th Edition, Pearson Education Inc, New Delhi, 2003 9. Donald D.Givone, Digital Principles and Design, TMH, 2003.

19

Department:Electronics and Instrumentation Engineering Programme : B.Tech.

Semester : Third Course Category Code: PCC Semester Exam Type:LB


L T P C CA SE TM

EI205 Electronic Circuits Lab 0 0 3 1.5 40 60 100

Prerequisite - knowledge of diode and basics

Course Outcome

CO1 The students will be able to design simple circuits using diodes, transistors

CO2 The students will be able to analyze the given circuit using their models

CO3 The students will be able to design biasing circuits using transistors.

CO4 The students will be able to design and construct amplifiers.

CO5 The students will be able to design and construct oscillators, rectifiers and multivibrators.

1. PN Junction diode and zener diode characteristics 2. BJT and FET characteristics 3. SCR, UJT, DIAC and TRIAC characteristics

CO1

4. Clippers and clampers CO2

5. Measurement of h-parameters of transistors in CB, CE, CC configurations 6. Biasing Circuits

CO3

7. CE , CB and CC Amplifier 8. Single stage R-C coupled Amplifier 9. Power Amplifiers 10. FET amplifier (Common Source)

CO4

11. Astablemultivibrator, Monostablemultivibrator using transistors 12. Rectifier with and without filters (Full wave and Half wave) 13. RC oscillators using transistor 14. LC Oscillators

CO5

Lecture Periods: Tutorial Periods: Practical Periods: 45 Total Periods: 45

Reference Books

1. J.Millman, C.C.Halkias, and SatyabrathaJit, Electronic Devices and Circuits, Tata McGraw Hill, 2nd Ed., 2007. 2. Floyd, Electronic Devices, Pearson Education, 7th Edition , 2008

20

Department : Electronics and Instrumentation Engineering Programme :B.Tech.

Semester : Third Course Category Code : PCC Semester Exam Type:LB


L T P C CA SE TM

EI206 Electronic Design and Fabrication Lab - - 2 1 40 60 100

Prerequisite:

Course Outcome

CO1 The student will gain conceptual understanding of using Arduino Uno.

CO2 The students will become knowledgeable about Digital and Analog I/O of Arduino Uno

CO3 The students will gain knowledge about Sensor Interfacing with Arduino.

CO4 The students will learn about design of communication interfaces with Arduino.

CO5 Student will understand of PCB Designing and Fabrication.

List of Experiments

PART-A 1. Parallel Port Interfacing using Arduino - LEDs, switches, Relays, Buzzers, Seven segment displays. 2. UART communication using Arduino. PC based control systems. 3. Sensor Interfacing with Arduino. Design of real world systems. 4. Character and Graphical LCD display interfacing with Arduino. 5. Interfacing DC and Servo motors with Arduino.

List of Experiments

PART-B 6. SPI and I2C communication using Arduino 7. Interfacing GSM and Bluetooth systems with Arduino. 8. Design of Internet of Things (IoT) using Arduino. 9. Single layer PCB design of Arduino based system. 10. Multi Player PCB design and Gerber generation.

Total contact Hours: - Total Tutorials: - Total Practical Classes: 45 Total Hours:45

21




L T P C CA SE TM

EIH01 MEASUREMENT DATA ANALYSIS 3 1 - 4 40 60 100

Prerequisite:

Course Outcome

CO1 To review basics of measurements

CO2 Will be exposed to the methods for estimating errors and uncertainties of real measurements: measurements that are performed in industry, commerce and experimental research.

CO3 Will understand the errors in direct measurement

CO4 Will clarify on the importance of indirect measurements

CO5 To introduce the fundamental techniques of measurement and data analysis and to report the results of an experiment

UNIT-I Periods: 12

Sample Spaces- Events - Axioms – Counting - Conditional Probability and Bayes’ Theorem – The Binomial Theorem – Random variable and distributions: Mean and Variance of a Random variable-Binomial-Poisson-Exponential and Normal distributions. Curve Fitting and Principles of Least Squares- Regression and correlation

CO1

UNIT-II Periods:

The Central Limit Theorem, distributions of the sample mean and the sample variance for a normal population, Sampling distributions (Chi-Square, t, F, z). Test of Hypothesis- Testing for Attributes – Mean of Normal Population – One-tailed and two-tailed tests, F-test and Chi-Square test - - Analysis of variance ANOVA – One way and two way classifications.

CO2

UNIT-III Periods: 12

PRESENTATION AND CLASSIFICATION OF DATA : Methods of collection of primary data, Discrete and Continuous Variables, Frequency Distributions, Cumulative Frequency distribution and gives, Bivariate Frequency Distributions; Tabulation of data. MEASURES OF LOCATION AND DISPERSION: Arithmetic mean: The Arithmetic mean of grouped Data, The Median: The mode; The variance and standard deviation: Interpretation of SD, Chebyshev's Lemma or Rule (for sample),

CO3

UNIT-IV Periods: 12

GRAPHICAL REPRESENTATION: Line graphs, Geometric Forms, Pictorial Diagrams, Control Charts, Radar charts, Parteto Diagrams, Histograms, Pie Charts, Histogram, Scatter diagram, Flow charts TIME SERIES ANALYSIS: Characteristics Movements in a time series; Time series models; Measurement of Trend; Secular Trend; Seasonal Movements; Cyclical Movements; Irregular Movements; Long Cycles

CO4

UNIT-V Periods: 12

Introduction to R- Packages- Scientific Calculator- Inspecting Variables- VectorsMatrices and Arrays- Lists and Data Frames- Functions- Strings and Factors- Flow Control and Loops- Advanced Looping- Date and Times. Introduction to PythonPackages- Fundamentals of Python- Inserting and Exporting Data- Data CleansingChecking and Filling Missing Data- Merging Data- Operations- Joins.

CO5

Lecture Periods: 45 Tutorial Periods: 15 Practical Periods: - Total Periods:60

Reference Books:

1. Richard Cotton, “Learning R”, O’Reilly, 2013. 2. Dalgaard, Peter, “Introductory statistics with R”, Springer Science & Business Media, 2008. 3. Brain S. Everitt, “A Handbook of Statistical Analysis Using R”, Second Edition, 4 LLC, 2014. 4. Samir Madhavan, “Mastering Python for Data Science”, Packt, 2015. 5. Sheldon M. Ross,”Introduction to Probability and Statistics for Engineers and Scientists”, 4 th edition, Academic Press; 2009. 6. Paul Teetor, “R Cookbook, O’Reilly, 2011. 7. Mark Lutz ,”Learning Python”, O’Reilly,5th Edition,2013

22

Department : Electronics and Instrumentation Engineering Programme : B.Tech.


Course Code

Course Name Periods / Week Credit Maximum Marks

L T P C CA SE TM

EIM01 TRANSDUCER ENGINEERING 3 1 0 4 40 60 100

Prerequisite:

Course Outcome

CO1 To expose the students to various sensors and transducers for measuring mechanical quantities.

CO2 To study the basic ofResistive, Inductive and capacitive transducers

CO3 To make the students familiar with

CO4 To teach the basic

CO5 To make the students familiar with Intelligent and smart transducers

UNIT-I Basic of transducers Periods: 9

General concepts and terminology of measurement systems, transducer classification, general input-output configuration, static and dynamic characteristics of a measurement system, Statistical analysis of measurement data.

CO1

UNIT-II Resistive, Inductive and capacitive transducers Periods: 9

Resistive transducers: Potentiometers, metal and semiconductor strain gauges and signal conditioning circuits, strain gauge applications: Load and torque measurement, Digital displacement transducer. Self and mutual inductive transducers- capacitive transducers, eddy current transducers, proximity sensors, tacho-generators and stroboscope.

CO2

UNIT-III Piezoelectric transducers Periods: 9

Piezoelectric transducers and their signal conditioning, Seismic transducer and its dynamic response, photoelectric transducers, Hall effect sensors, Magnetostrictive transducers,

CO3

UNIT-IV MISCELLANEOUS TRANSDUCERS Periods: 9

Eddy current transducers. Hall effect transducers – Optical sensors, IC sensor for temperature – signal conditioning circuits, Introduction to Fiber optic sensors – Temperature, pressure, flow and level measurement using fiber optic sensors.

CO4

UNIT-V Intelligent and smart transducers Periods: 9

Intelligent and smart transducers- principle- design approach, interface design, configuration support, communication in smart transducer networks. SQUID sensors, Film sensors, MEMS – Nano sensors. Basics of Gyroscope. Introduction to semiconductor sensor, materials, scaling issues and basics of micro fabrication.

CO5


Reference Books:

1. John P.Bentley, Principles of Measurement Systems, Pearson Education, 4th Edition, 2005. 2. Doebelin E.0, Measurement Systems -Application and Design, McGraw-Hill, 4thEdition, 2004. 3. S.M. Sze, Semiconductor sensors, John Wiley & Sons Inc., 1994. 4. Murthy D. V. S, Transducers and Instrumentation, Prentice Hall, 2ndEdition, 2011. 5. James W.Dally, Instrumentation for Engineering Measurements, Wiley, 2ndEdition, 1993. 6. John G.Webster, Sensors and Signal Conditioning, Wiley Inter Science, 2ndEdition, 2008.

23

Department : HSS Programme : B.Tech

Semester : Fourth Subject Category: MCC Semester Exam Type: -


L T P C CA SE TM

SH202 Indian Constitution 3 - - - - - -

Prerequisite -

Outcome

The course will enable the students to:

CO1 understand the essence and significance of the constitution

CO2 recognize ones fundamental duties and rights

CO3 appreciate the structure and functions of legislature, executive and judiciary

CO4 understand the functioning of state governments and union territories

CO5 understand the centre-state relations and functioning of constitutional bodies

UNIT-I Introduction of Indian Constitution Periods: 09

The Making of Indian Constitution - The Constituent Assembly - Sources of Indian Constitution - Preamble and the Supreme Court’s Judgments on Preamble.

CO1

UNIT-II State, Rights and Duties Periods: 09

State and Union Territories – Citizenship - Fundamental Rights - Directive Principles of State Policy - Fundamental Duties.

CO2

UNIT-III Union Government Periods: 09

Union Government - The Powers and Functions of the President, Vice–President, Council ofMinisters, Prime Minister, Judiciary, Supreme Court - Judicial Review - Judicial Activism- Public InterestLitigation - Power and Functions of the Parliament -Budget Power and Functions of Parliament, Speaker of Lok Sabha.

CO3

UNIT-IV State Governments Periods: 09

State Governments – Governor - State Council of Ministers - Chief Minister- Legislative Assembly- HighCourts - Union Territories - Panchayati Raj Institutions - 73th and 74th Constitutional Amendment - GramPanchayats - Block Panchayats - Municipalities.

CO4

UNIT-V Union- State Relations, Constitutional Bodies Periods: 09

Centre – State Relations - Public Service - Election Commission - NITI Ayog, Emergency Powers of the President- Constitution Amendment Procedure- Right to Information Act - Right to Education. Major Constitutional Amendments and their impact on Indian Political System.

CO5


Reference Books: 1. Austin, Granville. The Indian Constitution: Cornerstone of a Nation. Oxford University Press, 1999. 2. Basu, Durga Das, et al. Introduction to the Constitution of India. 20th ed., Thoroughly Rev, Lexis Nexis

Butterworths Wadhwa Nagpur, 2008. 3. Choudhry, Sujit, et al., editors. The Oxford Handbook of the Indian Constitution. Oxford University Press, 2016. 4. Bakshi, Parvinrai Mulwantrai, and Subhash C. Kashyap, The Constitution of India (Universal Law Publishing, 2016) 5. Bhargava, Rajeev, ‘Politics and Ethics of the Indian Constitution’, 2009 6. Rajeev Bhargava - ‘The Promise of India’s Secular Democracy’, 2010 7. Chakrabarty, Bidyut, India’s Constitutional Identity: Ideological Beliefs and Preferences (Routledge, 2019) 8. Jayal, Niraja Gopal, and Pratap Bhanu Mehta, The Oxford Companion to Politics in India, Oxford University Press,

2010 9. Kashyap, Subhash C., Our Constitution: An Introduction to India’s Constitution and Constitutional Law (NBT India,

1994) 10. Kashyap, Subhash C. Our Parliament: An Introduction to the Parliament of India. Revised edition, National Book

Trust, India, 2011. 11. Subhash C. Kashyap Our Constitution Paperback –. (NBT India, 2012). 12. Laxmikanth, M. "INDIAN POLITY". McGraw-Hill Education "Constitution of India". Ministry

of Law and Justice, Govt. of India.

24


Semester : Fourth Course Category Code: PCC Semester Exam Type:TY


L T P C CA SE TM

EI207 Linear Integrated Circuits 3 - - 3 40 60 100

Prerequisite: Knowledge of electronic circuits

Course Outcome

CO1 To understand the features of IC and fabrication methodology To understand the basic operation of op-amp

CO2 To understand the different applications of op-amp and their design

CO3 Able to design first order and second order active filter , oscillator

CO4 Able to design timer IC in astable and monostable mode To understand the basics of PLL, VCO and its application

CO5 To design ADC and DAC using op-amps and ADC 0804 and DAC 0800

UNIT-I Integrated Circuits and Operational Amplifier Periods:9

INTEGRATED CIRCUITS: Classification, chip size and circuit complexity, Fundamentals of Monolithic IC technology, basic planar processes, Fabrication of a typical circuit, Active and passive components of ICs, fabrication of FET, Thin and thick film technology, Micromachining technology. OPERATIONAL AMPLIFIER: Basic information of Op-amp, ideal and practical Op-amp, Op-amp characteristics, 741 op-amp and its features, modes of operation-inverting, non-inverting, differential mode.

CO1

UNIT-II OP-Amp Applications Periods: 9

Basic application of Op-amp, instrumentation amplifier, ac amplifier, V to I and I to V converters, Precision rectifiers, log and antilog amplifiers, sample & hold circuits, multipliers and dividers, Differentiators and Integrators, Comparators, Schmitt trigger, Multivibrators, Triangular wave generator.

CO2

UNIT-III Active Filters, Oscillators and Regulators Periods: 9

Introduction-Low pass and High pass filters- Design of first and second order Butterworth lowpass and high pass filters Band pass, Band reject and all pass filters- Oscillator types and principle of operation – RC phase shift and Wien bridge oscillators - triangular, saw-tooth, square wave generators - Introduction to voltage regulators, features of 723, Three Terminal IC regulators – Fixed and variable - DC to DC Converter- Switching Regulators-SMPS.

CO3

UNIT-IV Timers & Phase Locked Loops Periods: 9

Introduction to 555 timer, functional diagram, monostable, astable operations and applications, Schmitt Trigger. VCO and PLL - introduction, block schematic, principles and description of individual blocks of 565-PLL applications, Analog and digital phase detectors. Programmable timers - XR2240

CO4

UNIT-V D-A AND A- D Converters Periods: 9

Introduction, basic DAC techniques, weighted resistor DAC, R-2R ladder DAC, Different types of ADCs - parallel comparator type ADC, counter type ADC, successive approximation ADC, dual slope ADC and Sigma delta ADC. DAC and ADC specifications. DAC 0800 and ADC 0804 pin diagram and applications.

CO5


Reference Books:

1. Ramakanth A. Gayakwad, Op-Amps & Linear ICs –PH I, 4th Edition 2004. 2. D. Roy Chowdhury, Linear Integrated Circuits, New Age International (p) Ltd, 2011. 3. R.F. Coughlin & Fredrick F. Driscoll. Operational Amplifiers & Linear Integrated Circuits, PHI, 6th Edition, 2003 . 4. B.Guptha, Linear Integrated Circuits, S.K.Kataria& sons, 2013

25



Course Code Course Name: Periods / Week Credit Maximum Marks

L T P C CA SE TM

EI208 Electrical and Electronics Instruments 3 - - 3 40 60 100

Prerequisite:

Course Outcome

To study about

CO1 The students will be able to acquire knowledge about electrical instruments and measurements

CO2 The students will be able to acquire knowledge about resistance and impedance measuring methods.

CO3 The students will be able to acquire knowledge about Potentiometers, Instrument Transformers & Magnetic Measurements

CO4 The students will be able to acquire knowledge about signal generators

CO5 The students will be able to acquire knowledge about cathode ray oscilloscope, recorders and displays

UNIT-I Measurement of Voltage, Current, Power And Energy Periods: 10

Galvanometers – Ballistic, D’Arsonval galvanometer – Theory, calibration, application –Principle, construction, operation and comparison of moving coil, moving iron meters, dynamometer, induction type & thermal type meter, rectifier type – Extension of range of voltmeter and ammeter– Errors and compensation Electrodynamometer type wattmeter – Theory & its errors – Methods of correction – LPF wattmeter – Phantom loading – Induction type KWH meter – Calibration of wattmeter, energy meter

CO1

UNIT-II Potentiometers, Instrument Transformers & Magnetic Measurements

Periods: 10

Calibration of ammeter and voltmeter using potentiometer – AC potentiometer – Drysdale (polar type) type – Gall-Tinsley (coordinate) type – Limitations & applications – Magnetic measurements –step by step method – Hopkinson’s permeameter – Iron loss measurement by Lloyd Fisher square. Current Transformer and Potential Transformer construction, theory, operation, phasor diagram, characteristics, testing, error elimination – Applications.

CO2

UNIT-III Resistance and Impedance Measurement Periods: 10

Measurement of low, medium & high resistance – Ammeter, voltmeter method – Wheatstone bridge – Kelvin double bridge – Series and shunt type ohmmeter –High resistance measurement – Megger – Direct deflection methods – guard wire method – Loss of charge method – Earth resistance measurement. A.C bridges–Measurement of inductance, capacitance – Q of coil – Maxwell Bridge – Wein’s bridge – Hay’s bridge – Schering bridge – Anderson bridge – Campbell bridge to measure mutual inductance –Introduction to cable fault and eddy current measurement.

CO3

UNIT-IV Signal Generators and Analyzers Periods: 10

Sine wave generator – Frequency synthesized sine wave generator – Sweep frequency generator, pulse and square wave generator – Function generator- XR2206 monolithic IC function generator.

CO4

UNIT-V Cathode Ray Oscilloscope, Recorders and Displays Periods: 10

General purpose oscilloscope – Vertical & horizontal deflection systems – Delay line –Multiple trace – Dual beam & dual trace – Probes –Oscilloscope techniques – Special oscilloscopes – Storage oscilloscopes – Sampling oscilloscope-XY plotters-Data acquisition system-7 segment LED display- LCD display.

CO5

Lecture Periods: 50 Tutorial Periods:0 Practical Periods:0 Total Periods:50

Reference Books:

1. E.W.Golding&F.C.Widdis, Electrical Measurements & Measuring Instruments, A.H.Wheeler& Co, 1994. 2. Albert D.Helfrick& William D. Cooper, Modern Electronic Instrumentation & Measurement Techniques, Prentice

Hall of India, 2002. 3. A.K. Sawhney, Electrical & Electronic Measurements and Instrumentation, Dhanpath Rai & Co (P) Ltd, 2004. 4. Patranabis, Principles of Electronic Instrumentation - PHI, 2007 5. B.M.Oliver and J.M.Cage, Electronic Measurements & Instrumentation, McGraw Hill International Edition, 1975. 6. Joseph. J. Carr, Elements of Electronic Instrumentation & Measurements, III edition, Pearson Education, 2003.

26




L T P C CA SE TM

EI209 Transducers and Measurements System

3 - - 3 40 60 100

Prerequisite:

Course Outcome

CO1 To get the basic idea of measurements and the errors associated with measurement.

CO2 To differentiate between the Static and Dynamic Characteristics

CO3 To gain information Active and Passive Transducers

CO4 To study about Inductive, Capacitive and Piezoelelctric Transducers

CO5 To have basic knowledge in smart transducer and other important transducers

UNIT-I Introduction Periods:9

Generalized scheme of a measurement system – basic methods of measurements- Errors in measurements –types of errors- Statistical analysis of measurement data, mean, standard deviation – probability of errors – probable error, limiting errors. Propagation of Limiting Errors. Reliability of measurement systems – failure rate – reliability improvement, Availability, redundancy.

CO1

UNIT-II Static and Dynamic Characteristics Periods: 9

Static characteristics of instruments –generalized mathematical model of measurement systems – dynamic characteristics – Modelling of Transducers( RTD, Thermocouple) – operational transfer function – zero, first and second order instruments – impulse, step, ramp and frequency response of the above instruments.

CO2

UNIT-III Active and Passive Transducers Periods: 9

Resistance potentiometer – loading effect – strain gauges – gauge factor – types of strain gauges – rosettes –semiconductor strain gauges – installation of strain gages – strain measuring circuits - quarter bridge, half bride and full bridge circuits– Resistance thermometers, materials, construction, characteristics – Thermistors and photo resistors (LDR) – hot wire anemometer – constant current and constant temperature operation – Humidity sensors. Signal conditioning circuits for RTD, Thermistor and Thermocouple – Cold junction compensation.

CO3

UNIT-IV Inductive, Capacitive and Piezoelelctric Transducers Periods: 9

Inductive transducers – variable reluctance transducers – Inductive proximity pick up and Capacitive proximity pickup– Synchros operation and applications – LVDT construction –Equivalent Circuit- signal conditioning circuit, Phase sensitive demodulator circuit – applications. Capacitive transducers – variable area type – variable air gap type –variable permittivity type – signal conditioning circuit – Blumlein bridge – Capacitor microphone – frequency response. Piezoelectric transducers – piezoelectric crystals – charge amplifier.

CO4

UNIT-V MISCELLANEOUS AND SMART TRANSDUCERS Periods: 9

Hall effect transducers – Photo electric detector, different types and characteristics –Magneto-strictive Transducer, Optical sensors, IC sensor for temperature – signal conditioning circuits, Introduction to Fiber optic sensors: Temperature, pressure, flow and level measurement using fiber optic cable. Intelligent and smart transducers- principle- design approach, interface design, configuration support, communication in smart transducer networks. SQUID sensors, HART devices .Film sensors, MEMS – Nano sensors.

CO5


Reference Books:

1. S. Renganathan, Transducers Engineering, Pearson Education, Third Edition, 2008. 2. John. P. Bentley, Principles of Measurement systems, Longman Publishers, 1983. 3. J.W. Dally.W.F. Riley and K.G. Mc Connell, Instrumentation for Engineering measurements, John Wiley & sons Inc.,

1993. 4. H.K.P.Nubert, Instruments Transducers: An Introduction to their performance and Design, 1st Edition, 2003. 5. C.D. Johnson, Process Control Instrumentation Technology, PHI, 7th Edition. 6. R.K.Jain, Mechanical measurements, Khanna Publishers, 2002.

27

Department : Computer Science and Engineering Programme: B.Tech. EI

Semester : Fourth Course Category Code: ESC Semester Exam Type:TY


L T P C CA SE TM

CS234 Data Structures and Object- Oriented Programming

3 - - 3 40 60 100

Prerequisite Nil

Course Outcome

CO1 Select appropriate Searching and Sorting techniques.

CO2 Compare and Demonstrate Linear and Non-linear data structures.

CO3 Apply Linear and Non-linear data structures for a given problem.

CO4 Define Object-Oriented Programming Concepts.

CO5 Develop C++ programs with the concepts Inheritance and Polymorphism.

UNIT-I Arrays, Searching and Sorting Periods: 9

Algorithm: Characteristics –Representation – Efficiency of Algorithms– Data Structures: Characteristics –Types –Arrays: Introduction – Types – Representation –Operations – Applications: Sparse Matrix – Searching: Linear Search and Binary Search– Sorting techniques: Insertion Sort, Selection Sort, Bubble Sort, Quick Sort and Heap Sort.

CO1

UNIT-II Linear Data Structures Periods: 9

Stacks: Introduction – Operations – Applications: Evaluation of Expressions – Queues: Introduction – Operations– Circular queues – Priority queues – Double ended queues – Applications: Job Scheduling– Linked List: Introduction – Singly Linked List –Circularly Linked List and Doubly Linked List–Applications: Polynomial Addition.

CO2, CO3

UNIT-III Non-Linear Data Structures Periods: 9

Trees: Introduction –Terminology – Binary tree –Representation – Traversals– Graph: Introduction – Terminology – Representation – Traversals – Single Source and All Pairs Shortest path algorithms.

CO2, CO3

UNIT-IV Introduction to Object-Oriented Programming Periods: 9

Basics Concepts of Object-Oriented Programming – Structure of C++ – Tokens-Expressions-Control Structures – Functions in C++: Inline Functions – Recursion– Function Overloading – Classes and Objects– Constructors and Destructors– Friend Functions.

CO4

UNIT-V Concepts of Object-Oriented Programming Periods: 9

Operators Overloading: Unary and Binary Operators– Type Conversions – Inheritance–Types – Polymorphism– Virtual Functions – Exception Handling: Basics and Mechanism.

CO5

Lecture Periods: 45 Tutorial Periods: - Practical Periods: - Total Periods: 45

Reference Books

1. E Balagurusamy, Data Structures, McGraw Hill Education (India) Private Limited, 2018. 2. G A VijayalakshmiPai, Data Structures and Algorithms: Concepts, Techniques and Applications, McGraw Hill

Education (India) Private Limited, 2008. 3. Ellis Horowitz, SartajSahni and Susan Anderson Freed, Fundamentals of Data Structures in C, Second Edition,

Universities Press (India) Private Limited,2018. 1. E. Balagurusamy, Object Oriented Programming with C++, Seventh Edition, McGraw Hill Education (India) Private

Limited,2017.

28


Semester : Fourth Course Category Code: PCC Semester Exam Type:LB


L T P C CA SE TM

EI210 Linear and Integrated Circuits Lab 0 0 3 1.5 40 60 100

Prerequisite - Knowledge of electronic circuits

CO1 Able to design application circuits using IC 741 required for control applications

CO2 Able to design instrumentation amplifier for measuring physical variables and design of waveform generators using op-amp

CO3 Able to design signal conditioning circuits necessary for instrumentation, PLL, VCO

CO4 Able to learn the design converter such as ADC, DAC and voltage regulators

CO5 Able to design oscillators, Multivibrators

1. OPAMP applications, Inverting and Non-inverting Amplifiers, Summer, Differential amplifier, Differentiator and Integrator

2. Comparator, Zero crossing detector and Window detector

CO1

3. Design of instrumentation amplifier 4. Waveform generation using op-amp 5. Astable and Schmitt trigger using 741 IC

CO2

6. First order active filters (LPF, HPF and BPF). 7. IC 565 PLL Applications.

CO3

8. 4 bit DAC using OP AMP, ADC using op-amp, ADC 0809 9. Voltage Regulator using IC 723, Three Terminal Voltage Regulators – 7805, 7809, 7912.

CO4

10. MonostableMultivibrators design using 741 IC. 11. 555 timer Applications. 12. Design of oscillator using 741 op-amp

CO5


Reference Books

1. Ramakanth A. Gayakwad, Op-Amps & Linear ICs –PH I, 4th Edition 2004. 2. D. Roy Chowdhury, Linear Integrated Circuits, New Age International (p) Ltd, 2011.

29

Department : Computer Science and Engineering Programme: B.Tech. (EI)

Semester : Fourth Course Category Code: ESC Semester Exam Type: LB


L T P C CA SE TM

CS235 Data Structures and Object - Oriented Programming Laboratory

- - 3 1.5 40 60 100

Prerequisite Nil

Course Outcome

CO1 Choose and implement appropriate Searching/sorting algorithms for an application

CO2 Implement data structures using C

CO3 Apply Linear and Non-linear data structures for a given problem

CO4 Develop and implement C++ programs using of classes and objects, constructors and destructors.

CO5 Design C++ programs with inheritance and run time polymorphism.

Experiments for Cycle 1

1. Implementation of Linear search and binary search. 2. Implementation Insertion sort, Selection sort, Bubble sort, Quick sort and Heap Sort.

CO1

3. Array implementation of Stacks and Queues. 4. Implementation of Singly and Doubly Linked List. CO2, CO3

5. Implementation of Binary Tree Traversals. 6. Implementation of Graph Traversals and shortest path Algorithms.

CO2, CO3

Experiments for Cycle 2

7. Programs to implement classes and objects. 8. Programs to implement constructors and destructors.

CO4, CO5

9. Programs to implement different types of inheritance. 10. Programs to implement virtual functions to demonstrate the use of run time polymorphism.

CO5

Lecture Periods: - Tutorial Periods: - Practical Periods: 45 Total Periods: 45

Reference Books

1. Ellis Horowitz, SartajSahni and Susan Anderson Freed, Fundamentals of Data Structures in C, Second Edition, Universities Press (India) Private Limited, 2018.

2. E. Balagurusamy, Object Oriented Programming with C++, Seventh Edition, McGraw Hill Education (India) Private Limited, 2017.

30

Department : Electronics and Instrumentation Engineering Programme: B.Tech.

Semester : Fourth Course Category Code: PCC Semester Exam Type:LB


L T P C CA SE TM

EI211 Transducers and Measurements Laboratory

- - 3 1.5 40 60 100

Prerequisite Nil

Course Outcome

CO1 To study the characteristics of different transducers

CO2 To measure torque, strain and load using strain gauge

CO3 To know the applications of hall effect, optical, ,

CO4 To model RTD and thermocouple

CO5 To study magnetic and electric pickup transducers

(Any 10 Experiments) Characteristic of Temperature transducers (LDR, thermistor and thermocouple). Characteristics of Optical Transducers (LDR, Phototransistor, Photovoltaic and photoconductive cells) Characteristics of P/I and I/P converters.

C01

Measurement of strain, Load and Level using strain gauges Measurement of torque and Pressure using strain gauges Measurement of pH using single glass electrode.

CO2

Measurement of speed using Magnetic and photo electric pickup transducers. Measurement of Voltage, current and power using Hall Effect transducer Measurement of Position using synchro Transmitter and receiver

CO3

Ramp response characteristic of filled in system thermometer. Online Modeling of RTD and thermocouple using Data loggers. Measurement of Pressure and Temperature using ICs (LM 35,LM 335 and AD 590) Measurement of Flow, Level and Temperature.

CO4

Measurement of Displacement using capacitive transducer, LVDT, inductive transducer and potentiometric transducer.

CO5


31



Course Code Course name Periods / Week Credit Maximum Marks

L T P C CA SE TM

EIH02 DESIGN OF SENSORS AND TRANSDUCERS 3 1 - 4 40 60 100

Prerequisite:

Course Outcome

CO1 To provide fundamentals of various types of diaphragm design

CO2 To familiarize with design of strain gauge and its applications.

CO3 To familiarize with design of capacitive and inductive based transducers and its applications.

CO4 To furnish the knowledge on design of accelerometer and gyroscope

CO5 To provide the basics of various chemical sensors and its design criterion

UNIT-I Periods: 12

Introduction to diaphragm; Diaphragm performance and materials, Design of flat diaphragms, flat diaphragms with rigid centre – Design of convex diaphragms, semiconductor diaphragms and rectangular diaphragms – Design of corrugated diaphragms.

CO1

UNIT-II Periods: 12

Design of strain gauge based load cells, torque sensors, force sensors and pressure sensors CO2


Design of capacitance based displacement, pressure and level sensors; Design of self and mutual inductance transducers for measurement of displacement and other parameters; Design of capacitive and inductive proximity sensors

CO3

UNIT-IV Periods: 12

Accelerometer and Gyroscopic design and its applications. Design of Hall Effect sensors, Electromagnetic sensors, Magneto-elastic sensors

CO4

UNIT-V Periods: 12

Introduction to chemical Sensors, characteristics. Design of direct and complex chemical sensors.

CO5

Lecture Periods: 45 Tutorial Periods: 15 Practical Periods: Total Periods: 60

Reference Books:

1. Karl Hoffmann, An introduction to stress analysis and transducer design using strain gauges, HBM, 1989. 2. James W. Dally, William F. Riley, Kenneth G. McConnell, Instrumentation for Engineering Measurements,

Wiley, 1993. 3. Di Giovanni, Flat and Corrugated Diaphragm Design Handbook, CRC Press, 1982. 4. Fraden, Jacob, Handbook of Modern Sensors: Physics, Designs, and Applications, Springer, 3rd Editions, 1993.

32




L T P C CA SE TM

EIM02 MEASURING INSTRUMENTS AND TESTING 3 1 0 4 40 60 100

Prerequisite:

Course Outcome

CO1 To give an overview of electro mechanical instruments..

CO2 To study the importance of power measurements

CO3 To expose the students to the design of bridges for the measurement of resistance, capacitance and inductance.

CO4 To study the Digital Measurement of Electrical Quantities

CO5 To expose the Wave form generation and analysis

UNIT-I Electrical measurements: Periods: 12

General features and Classification of electro mechanical instruments. Principles of Moving coil, moving iron instruments. Extension of instrument range: shunt and multipliers, CT and PT.

CO1

UNIT-II Measurement of Power Periods: 12

Electrodynamic wattmeter’s, Low Power Factor (LPF) wattmeter, errors, calibration of wattmeter. Single and three phase power measurement, Hall effect wattmeter, thermal type wattmeter.

CO2

UNIT-III Measurements of RLC Periods: 12

Different methods of measuring low, medium and high resistances, measurement of inductance & capacitance with the help of AC Bridges, Q Meter.

CO3

UNIT-IV Digital Measurement of Electrical Quantities: Periods: 12

Concept of digital measurement, block diagram Study of digital voltmeter, Digital multimeter, Digital LCR meter, Digital wattmeter and energy meters. CO4

UNIT-V Wave form generation and analysis Periods: 12

DSO, Function generator, Audio frequency signal generation, Waveform analyzers, Spectrum analyzers.

CO5


Reference Books:

Text Books: 1. Golding, E.W. and Widdis, F.C., Electrical Measurements and Measuring Instruments, A.H.Wheeler and Co, 5thEdition,

2011. 2. David A. Bell, Electronic Instrumentation and Measurements, Oxford University Press, 3rd Edition, 2013. 3. Shawney A K, A course in Electrical and Electronic Measurements and Instrumentation, Dhanpat Rai and Sons.

19threvised edition, 2013. 4. Cooper, W.D. and Helfric, A.D., Electronic Instrumentation and Measurement Techniques, Prentice Hall, 1stEdition,

2009. 5. Kalsi.H.S, Electronic Instrumentation, Tata Mcgraw Hill Education Private Limited, 3rdEdition, 2012.

33


Semester : Fifth Course Category Code: PCC Semester Exam Type:TY


L T P C CA SE TM

EI213 Industrial Instrumentation 3 1 - 4 40 60 100

Prerequisite:

Course Outcome

CO1 The students will understand the role of instrumentation engineer by studying different instruments used in industries for pressure measurement.

CO2 The students will understand the role of instrumentation engineer by studying different instruments used in industries for level and flow measurement.

CO3 The students will understand the role of instrumentation engineer by studying different instruments used in industries for temperature measurement.

CO4 The students will understand the role of instrumentation engineer by studying different instruments used in industries for acceleration, density and viscosity measurement

CO5 The students will be able to interpret process flow diagrams and will be able to prepare diagram for any projects.

UNIT-I Pressure Measurement Periods: 12

manometers – different types – elastic type pressure gauges –Bourdon tube - bellows – diaphragms –Electrical methods – elastic elements with LVDT and strain gauges– piezo resistive pressure sensor – measurement of vacuum – McLeod gauge – thermal conductivity gauges – Ionization gauge– flapper nozzle system – testing and calibration of pressure gauges – dead weight tester.

CO1

UNIT-II Level & Flow Measurement Periods: 12

Level: float gauges - level switches – bubbler system- differential pressure method –electrical types of level gauges using resistance, capacitance and ultrasonic sensors. Flow: Orifice plate, Venturi tube, Pitot tube-Rotameter-Positive displacement meter - electromagnetic flow meter- ultrasonic flow meter– coriolis mass flow meters –ultrasonic flow meter- solid flow measurement -calibration of flow meters – dynamic weighing method- selection factors for flow meters.

CO2

UNIT-III Temperature Measurement Periods: 12

Different types of filled in system thermometer – sources of errors in filled in systems and their compensation – Bimetallic thermometers – Resistance thermometer– 3 lead wire and 4 lead wire RTDs –Thermocouples – law of thermocouple –cold junction compensation –total radiation and selective radiation pyrometers– optical pyrometer.

CO3

UNIT-IV Measurement of Acceleration, Density, Viscosity Periods: 12

Accelerometers – LVDT, Piezo-Electric, Strain gauge and Variable reluctance type accelerometers – Seismic instrument as an accelerometer and vibrometer. Pressure head type densitometer – Float type densitometer – Ultrasonic densitometer -Bridge type gas densitometer. Saybolt viscometer – Rotameter type viscometer - Industrial consistency meters

CO4

UNIT-V Industrial Safety and Specification Periods: 12

EMC: Introduction, Interference coupling mechanism, Basics of circuit layout and grounding, Concepts of Interfaces, Filtering and Shielding. Safety: electrical hazards, fuses and circuit breakers, protection methods: purging, explosion proofing and Intrinsic safety. Introduction to Piping and Instrumentation Diagram- process flow sheet-Instrument index sheet.

CO5

Lecture Periods: 45 Tutorial Periods: 15 Practical Periods: 0 Total Periods: 60

Reference Books:

1. Ernest O.Doebelin, “Measurement systems Application and Design”, International Student Edition, IV Edition, McGraw Hill Book Company, 1998.

2. R.K.Jain, “Mechanical and Industrial Measurements”, Khanna Publishers, New Delhi, 1999. 3. Bela.G.Liptak,” Process Measurement and Analysis”, Instrument Engineers handbook, fourth Edition, 2003. 4. D.Patranabis, “Principles of Industrial Instrumentation”, Tata McGraw Hill Publishing Ltd., New Delhi, 1999. 5. K. Krishnaswamy And S. Vijayachitra, “Industrial Instrumentation”, New Age International Publishers,, 2014.

34




L T P C CA SE TM

EI214 MICROPROCESSOR AND APPLICATIONS 3 - - 3 40 60 100

Prerequisite:

Course Outcome

CO1 Know the fundamentals of microprocessor

CO2 Write simple assembly language programs in 8085

CO3 Interface any i/o device to 8085

CO4 Write assembly language programs using 8086.

CO5 Design a microprocessor based system for the given application

UNIT-I Introduction to 8085 Periods: 9

Generic-8-bit microprocessor and its architecture-8085 functionalblock diagram-Architecture-functions of different sections-Memory mapping-Memory interfacing-Instruction format-addressing modes-instruction set of 8085 CPU-instruction cycle-timing diagram-different machine cycles-fetch and execute operations-estimation of execution time.

CO1

UNIT-II Programming 8085 Periods: 9

Data transfer instructions-arithmetic operations-logic and branchoperations-writing assembly language programmes-looping, count indexing-16 bit arithmetic instructions-arithmetic operations related to memory-logical operations, rotate compare, counter and time delays-debugging techniques. Stack- subroutine- call and return instructions-parameter passing techniques-nested subroutine. Parallel input-output and interfacing applications-peripheral and memory mapped I/O. 8085 interrupts-Restart as software instructions

CO2

UNIT-III Interfacing Devices Periods: 9

8255 programmable peripheral interface-8253 programmableinterval timer-8259 programmable interrupt controller-direct memory access(DMA) and 8257 DMA controller-8155 multipurpose programmable devices-8279 programmable keyboard display interface-serial I/O and data communication-8251 USART-Interfacing data converters ADC and DAC.

CO3

UNIT-IV Introduction to 8086 Periods: 9

Architecture of 8086 Microprocessor- Special functions of Generalpurpose registers- 8086 flag register and function of 8086 flags- Addressing modes of 8086-Instruction set of 8086-, Assembly language programs involving logical, Branch & Call instructions, sorting, evaluation of arithmetic expressions, string manipulation- Pin diagram of 8086-Minimum mode and maximum mode of operation- Timing diagram- Memory interfacing to 8086 (Static RAM & EPROM).

CO4

UNIT-V Applications of Microprocessors Periods: 9

Typical application of microprocessors: Sevensegment display interface, LCD interface, stepper motor control, temperature control, frequency measurement., phase angle and power factor measurement, Measurement of strain, deflection and water level measurement, Microprocessor based traffic control

CO5


Reference books:

1. Ramesh S Gaonkar, Microprocessor Architecture, Programming and application with 8085, 6th Edition, Penram International Publishing, New Delhi, 2017.

2. A.K. Ray and K.M.Burchandi, and A.K.Ray, Advanced Microprocessor and Peripherals, McGraw Hill International Edition, 3rd Edition, 2012 .

3. B.Ram, Fundamentals of Microprocessors and Microcomputers, Dhanpat Rai Publications, 2001.

35




L T P C CA SE TM

EI215 CONTROL SYSTEMS 3 1 - 4 40 60 100

Prerequisite:

Course Outcome

CO1 Performtimedomainandfrequencydomainanalysisofcontrolsystemsrequiredfor stabilityanalysis.

CO2 Designthecompensationtechniquethatcanbeusedtostabilizecontrolsystems.

CO3 To understand the frequency domain specifications

CO4 To appreciate the stability analysis

CO5 To develop state variable models

UNIT-I Introduction to Systems Periods: 12

Basicelementsincontrolsystems–OpenandClosedloopsystems–Feedbackcharacteristics–Effectsoffeedback –Mathematicalmodelingofphysicalsystems:-Mechanical,Thermal,HydraulicandPneumaticsystems-Transfer function–ACandDCservomotors–Blockdiagramreductiontechniques–Signalflowgraph–Controlsystem components–Computersimulation(Forassignmentsonly).

CO1

UNIT-II Time Response Analysis Periods: 12

Timeresponse–Typesoftestinputs-IandIIordersystemresponses–Errorcoefficients–Generalizederror series-Steadystateerror-Timedomainspecifications-PIDandON/OFFcontrollers-Performancecriteria-Selection of controller modes - Computer simulation

CO2

UNIT-III Frequency Response Analysis Periods: 12

Frequencyresponse-Frequencydomainspecifications-Bodeplot-Polarplot-Determinationofphasemarginand gainmargin-ConstantMandNcircles–Nicholschart-Determinationofclosedloopresponsefromopenloop response–Computersimulation

CO3

UNIT-IV Stability of Control System Periods: 12

Conceptsofstability–Locationofrootsins-planeforstability–RouthHurwitzcriterion–Rootlocustechniques– Construction – Nyquist stability criterion -Computer simulation - Lag, Lead, andLag-Lead networks – Compensator design for desired response using Root locus and Bode diagrams.

CO4

UNIT-V State-Variable Analysis Periods: 12

Introduction of state, state variables and state model, derivation of state models from block diagrams, Relationship between state equations and transfer functions-Characteristic equation, eigenvalues, eigenvectors, canonical forms Diagonalization-solving the time invariant state equations-State Transition Matrix. Controllability and observability. Computer simulation

CO5


Reference books:

1. R.Anandanatarajan, P.Ramesh Babu, ControlSystemsEngineering, Scitech Publications, India, Fifth Edition, 2014. 2. I.J.Nagrath,M.Gopal,ControlSystemEngineering,New-ageInternational(P),4thEditionLtd.,NewDelhi,2009. 3. M.Gopal, Control Systems, Principles and Design, Tata McGraw-Hill Pub. Co., 2nd Edition, New Delhi, 2006. 4. K.Ogata,ModernControlEngineering,PHI.,5thEdition,NewDelhi,2010. 5. B.C.Kuo,AutomaticControlSystems,PHI.,NewDelhi,2003.

36

Department : Humanities & Social Sciences Programme : B.Tech.

Semester : Fifth Course Category code : PAC Semester Exam Type:TY


L T P C CA SE TM

EP201 Entrepreneurship 3 0 - 2 40 60 100

Prerequisite: -

Course Outcome

CO1 The student will gain conceptual understanding of Entrepreneurship and design thinking.

CO2 The students will become knowledgeable about business model development and MVP

CO3 The students will gain knowledge about costing and revenue.

CO4 The students will learn about marketing and sales.

CO5 Student will get understanding of team formation and compliance requirements.

UNIT – I Problem and Customer Periods: : 12

Effectuation, Finding the flow. Entrepreneurial style, business opportunity, problems worth solving, methods for finding problems, problem interviews. Design Thinking, Consumer and customer, market types, segmentation and targeting, early adopters, Gains, Pains and “Jobs-To be done, Value Proposition Canvas (VPC), Identifying Unique Value Proposition (UVP).

CO1

UNIT – II Business Model and Validation Periods: : 12

Types of Business Models, Lean Canvas, Risks. Building solution demo, solution interviews, problem-solution test, competition, Blue Ocean Strategy. MVP- Build-Measure-Learn feedback loop, MVP Interviews, MVP Presentation.

CO2

UNIT – III Revenue and Cost Periods: : 12

Revenue Streams-Income, costs, gross and net margins - primary and secondary revenue streams- Different pricing strategies - product costs and Operations costs; Basics of unit costing. Financing New Venture- various sources - investor expectation- Pitching to Investors.

CO3

UNIT – IV Marketing and Sales Periods: : 12

Difference between product and brand - positioning statement. Building Digital Presence, Social media- company profile page – Sales Planning - buying decisions, Listening skills, targets. Unique Sales Proposition (USP), sales pitch, Follow-up and closing a sale.

CO4

UNIT – V Team and Support Periods: : 12

Team Building - Shared leadership - role of a good team - team fit - defining roles and responsibilities - collaboration tools and techniques- project management, time management, workflow, delegation of tasks. Business regulations - starting and operating a business - compliance requirements.

CO5

Total contact Hours: 60 Total Tutorials: - Total Practical Classes: Total Hours: 60

Reference Books:

1. Nandan H,"Fundamentals of Entrepreneurship",Prentice Hall India,2013. 2. LearnWISE–Digital learning platform by Wadhwani Foundation, www.learnwise.org 3. Khanka S.S,"Entrepreneurial Development",S Chand & Company,2007. 4. Sangeetha Sharma,"Entrepreneurship Development"– Prentice Hall India,2017. 5. Anil Kumar.S,"Entrepreneurship Development"– New Age Publishers, 2003.

37


Semester : Fifth Course Category Code: PCC Semester Exam Type: LB


L T P C CA SE TM

EI216 Instrumentation System Design Lab - - 3 1.5 40 60 100

Prerequisite:

Course Outcome

CO1 The students will be able to design, test and calibrate the industrial instruments.

CO2 The students will become knowledgeable about Analog circuit design for instrumentation

CO3 Student will be able to implement in Real time systems and applications.

List of Experiments

Design, Testing and calibration of 3½ Digit Digital Voltmeter using ICL 7107. Design, Testing and calibration of Monolithic Function Generator using XR 2206 and LM566 Design, Testing and calibration of Regulator Power supplies. Design, Testing and calibration of Batch counter using TTL ICs. Design ,Testing and calibration of DAC and ADC (both passive and digital)

CO1,CO2

Design, Testing and calibration of Electronic P, PI, PID & ON/OFF controllers. Design, Testing and calibration of Programmable Timers. Design, Testing and calibration of pH meter using single glass electrode. Design, Testing and calibration of Digital Thermometer. Design, Testing and calibration of F to V and V to F converters. Design and testing of advanced measurement circuits.

CO3,CO4

Total contact Hours: - Total Tutorials: - Total Practical Classes: 45 Total Hours: 45

Reference Books 1. C. D. Johnson, “Process Control Instrumentation Technology”, 8th Edition, Prentice Hall, 2006. 2. Control Valve Handbook, 4th Edition, Emerson Process Management, Fisher Controls International, 2005. 3. R.W. Miller, “Flow Measurement Engineering Handbook”, Mc-Graw Hill, New York, 1996.

38


Semester : Fifth Course Category Code: PCC Semester Exam Type:LB


L T P C CA SE TM

EI217 VLSI Design Lab - - 3 1.5 40 60 100

Prerequisite:

Course Outcome

CO1 The student will gain conceptual understanding of using a FPGA.

CO2 The students will become knowledgeable about Combinational logic circuits implementation

CO3 The students will gain knowledge about Sequential logic implementation

CO4 The students will learn about design of data acquisition and LCD systems using FPGA

CO5 Student will get understanding of Real time systems and applications using FPGA.

List of Experiments

1. Implementation of Basic Logic Gates, Half and Full Adders in FPGA and logic synthesis. 2. Implementation of Combinational logic circuits-Encoders, Decoders , Multiplexors , Demultiplexors , Comparators in FPGA 3. Implementation of Sequential logic Circuits - Flips Flops, Registers , Counters in FPGA. 4. Implementation of ALU in Structural , Behavioral and Dataflow modes. Validation of Logic outputs. 5. Peripheral Interfacing using FPGA - Switches, LEDs , Segment Displays.

CO1, CO2

List of Experiments

6. Design of Motor Controller using FPGA/CPLD. 7. Design of Display controllers using FPGA/CPLD. 8. Design of Data Acquisition controllers using FPGA/CPLD. 9. Design of Programmable Signal generators using FPGA/CPLD. 10. Design of UART communication controller using FPGA/CPLD

CO3,CO4,CO5


39


Semester : Fifth Course Category Code: PCC Semester Exam Type:LB


L T P C CA SE TM

EI218 Microprocessor and Applications lab -- -- 3 1.5 40 60 100

Prerequisite -

Course Outcome

CO1 Write simple assembly language program in 8085

CO2 Write simple assembly language program in 8086

CO3 Will be able to interface I/O devices to 8085 microprocessor

CO4 Will be able to interface I/O devices to 8086 microprocessor

CO5 Know about 8254 timer, PPI and 8259 programmable interrupt controller

LIST OF EXPERIMENTS

Assembly language programming in 8085 CO1

Assembly language programming in 8086 CO2

Interfacing I/O Devices to 8085 Microprocessor CO3

Interfacing I/O Devices to 8086 Microprocessor CO4

Study of 8253, 8255 and 8259 ICs CO5


Reference Books:

1. Ramesh S Gaonkar, Microprocessor Architecture, Programming and application with 8085, 6th Edition, Penram International Publishing, New Delhi, 2017.

2. A.K. Ray and K.M.Burchandi, and A.K.Ray, Advanced Microprocessor and Peripherals, McGraw Hill International Edition, 3rd Edition, 2012 .

3. B.Ram, Fundamentals of Microprocessors and Microcomputers, Dhanpat Rai Publications, 2001.

40

Department : HSS Programme : B.Tech

Semester : Fifth Subject Category: MCC Semester Exam Type: -


L T P C CA SE TM

SH203 Essence of Indian Traditional Knowledge

3 - - - - - -

Prerequisite -

Outcome The course will enable the student to:

CO1 understand connect up and explain basics of Indian traditional knowledge in modern scientific perspective

UNIT-I Periods: 12

Basic structure of Indian knowledge system, Modern science and Indian knowledge system, Yoga and holistic health care.

CO1 UNIT-II Periods: 12

Philosophical tradition, Indian linguistic tradition, Indian artistic tradition.

Lecture Periods: Tutorial Periods: Practical Periods: Total Periods:

Reference Books:

1. N. Sivaramakrishnan (Ed.) Culteral Heritage of India – Course Materal, BharatiyaVidyaBhavan, Mumbai 5th edition, 2014.

2. Swami Jitatmanand, Modern Physics and Vedanta, BharatiyaVidyaBhavan. 3. Fritzof Capra, Tao of Physics. 4. Yoga Sutra of Patanjali, Ramakrishna Mission, Kolkatta. 5. R.N. Jha, Science of Conciousness Psychotherapy and yoga Practices, VidyanidhiPrakashan, Delhi 2016. 6. S.C Chaterjee and D.M Datta, An Introduction to Indian Philosophy, University of Calcutta, 1984. 7. Krishna Chaitanya, Arts of India, Abhinav Publications, 1987

41




L T P C CA SE TM

EIH03 FIELD INSTRUMENTS FOR PROCESS CONTROL

3 1 - 4 40 60 100

Prerequisite:

Course Outcome

CO1 Learner will be able to learn the Industrial Automation and various communication busses

CO2 Learner will be able to learn the terminologies of Instrumentation, Measurement Techniques and concepts of control system environment

CO3 Able to understand the importance of Field instruments

CO4 Able to perceive the Automation protocols, Instrumentation and Industrial Engineering

CO5 Able to suitable P&ID for industrial process

UNIT-I INDUSTRIAL AUTOMATION Periods: 12

Orientation to Industrial Automation - Overview of the Process Plant – Refineries – Petrochemicals - Fertilizers, Chemical – Pharmaceuticals - Overview of the Process Plant - Crude Oil Distillation - Power generation – Reactors - Boiler Unit - Cracker unit - Introduction to various Industrial Automation - Single Loop Controllers - Programmable Logic Controllers - Distributed Control Elements - Introduction to various Communication Protocols – HART – BRAIN - Ethernet - Serial Communication - Modbus Communication - Fieldbus Communication

CO1

UNIT-II INSTRUMENTATION BASICS Periods: 12

Introduction to Instrumentation Basics - Introduction to Industrial Measurement techniques - Pressure Measurement - Temperature Measurement - Flow Measurement - Level Measurement - Basic Control Loops and Tuning

CO2

UNIT-III FIELD INSTRUMENTS Periods: 12

Introduction to Field Instruments - Principle and Operation of Transmitters - Principle and Operation of Flow meters - Principle and Operation of Control Valves - Single Loop Controllers and Operation - Principle and Operation of Data acquisition System

CO3

UNIT-IV INDUSTRIAL ENGINEERING Periods: 12

Project Engineering - Panel Engineering - Nest loading - Process Wiring – Industrial Safety CO4

UNIT-V DIAGRAMS AND SCHEMES Periods: 12

Process Diagrams - Process flow diagrams - Process Flow Schemes - P&ID CO5


Reference Books:

1. Terry L. M. Bartelt, Instrumentation and Process Control, Delmar Cengage Learning, 1st edition, 2006. 2. Gregory K. Mcmillan, Douglas M. Considine, Process/Industrial Instruments and Controls Handbook, McGraw-Hill

Education; 5 edition, 1999.

42

Department :Electronics and Instrumentation Engineering Programme : B.Tech.



L T P C CA SE TM

EIM03 MEASUREMENTS IN PROCESS INDUSTRIES

3 1 - 4 40 60 100

Prerequisite:

Course Outcome

CO1 familiar with the different temperature measurement techniques used in process industries

CO2 able to select and make measurements of pressure in any process industry.

CO3 able to identify or choose level measuring device for specific process.

CO4 able to identify flow measuring devices used in industries for specific process

CO5 able to select flow meter for specific applications

UNIT-I Temperature Measurement Periods: 12

Temperature measurement: Introduction to temperature measurements, Thermocouple, Resistance Temperature Detector, Thermistor and its measuring circuits, Radiation pyrometers and thermal imaging.

CO1

UNIT-II Pressure Measurement Periods: 12

Pressure measurement: Introduction, definition and units, Mechanical, Electro-mechanical pressure measuring instruments. Low pressure measurement, Transmitter definition types, I/P and P/I Converters.

CO2

UNIT-III Level Measurement Periods: 12

Level measurement: Introduction, Capacitance pickup, Ultrasonic pickup. CO3

UNIT-IV Flow Measurement Periods: 12

Flow measurement: Introduction, definition and units, classification of flow meters, differential pressure and variable area flow meters, Positive displacement flow meters, Electro Magnetic flow meters.

CO4

UNIT-V Selection of Flow Meters. Periods: 12

Hot wire anemometer and ultrasonic flow meters. Calibration and selection of Flow meters. CO5


Reference books:

1. Ernest.O.Doebelin and Dhanesh.N.Manik, Doebelin’s Measurement Systems, McGraw Hill Education, 6th Edition, 2011.

2. B.G.Liptak, Process Measurement and Analysis, CRC Press, 4th Edition, 2003. 3. Patranabis D, Principles of Industrial Instrumentation, Tata McGraw Hill, 3rd Edition, 2010. 4. B.E.Noltingk, Instrumentation Reference Book, Butterworth Heinemann, 2nd Edition, 1995. Douglas M.

Considine, Process / Industrial Instruments & Controls Handbook, McGraw Hill, Singapore, 5th Edition, 1999. 5. Andrew W.G, Applied Instrumentation in Process Industries – A survey, Vol I &Vol II, Gulf Publishing Company,

Houston, 2001 . 6. Spitzer D. W., Industrial Flow measurement, ISA press, 3rd Edition, 2005. 7. Tony.R.Kuphaldt, Lessons in Industrial Instrumentation, Version 2.02, April 2014

43

Department : Electronics and Instrumentation Engineering Programme: B.Tech.

Semester : Sixth Course Category Code :PCC Semester Exam Type:TY


L T P C CA SE TM

EI219 Process Control 3 1 - 4 40 60 100

Prerequisite -

Outcome

CO1 Canunderstandcharacteristicsofvariousprocesses

CO2 KnowthefunctionsofprocessControlelements

CO3 Candesignacontrollerforaselectedprocess.

CO4 Cananalyzeanydiscrete-timesystemanddesignadigitalcontrol.

CO5 Able design digital PID controller

UNIT – I Introduction Hours: 12

Needforprocesscontrol–Mathematicalmodeloflevel,pressureandthermalprocesses–higherorderprocess– interactingandnon-interactingsystems–continuousandbatchprocesses–self-regulation–servoandregulatoryoperations.

CO1

UNIT – II Controllers and FCE Hours: 12

Basiccontrolactions–characteristicsofON/OFF,proportional,single-speedfloating,integralandderivative controlmodes–P+I,P+DandP+I+Dcontrolmodes–Automanualtransfer–Finalcontrolelements-VFD-TPC-Control valves: Characteristics – inherent and installed – cavitation and flashing.

CO2

UNIT – III Controller Tuning and Multiloop Control Hours: 12

Determinationofoptimumsettingsforprocessmodelsusingtimeresponseandfrequencyresponse–Tuning– Processreactioncurvemethod–ZieglerNicholsmethod-Evaluationcriteria–IAE,ISE,ITAEand¼decayratio– Dampedoscillationmethod.Feed-forwardcontrol–ratiocontrol-cascadecontrol–inferentialcontrol–split- rangecontrol–introductiontomultivariablecontrol:Distillationcolumnandboilersystems.

CO3

UNIT – IV Analysis of Discrete Data Systems Hours: 12

State-spacerepresentationofdiscretedatasystems–Selectionofsamplingperiod–Reviewofz-transform–Basic buildingblocksofcomputercontrolsystem–Pulsetransferfunction–Modifiedz-transform-Stabilityofdiscrete data system – Jury’s stability test.

CO4

UNIT – V Design of Digital Controller Hours: 12

DigitalPIDcontroller–Positionandvelocityform–Deadbeat’salgorithm–Dahlin’salgorithm–Kalman’salgorithm - Pole placement controller – Predictive controller.

CO5

Total contact Hours: 45 Total Tutorials: -15 Total Practical: - Total Hours: 60

Reference Books: 1. G.Stephanopoulis,ChemicalProcessControl,PHIlearning,NewDelhi,2008. 2. D.P.Eckman, Automatic Process Control, Wiley Eastern Ltd., New Delhi,2008. 3. Donald R.Coughanowr,Steven E.Leblanc, Process System Analysis Control, 3rd edition, 2013.

44


Semester : Sixth Course Category Code: PCC Semester Exam Type:TY


L T P C CA SE TM

EI220 Embedded System Design 3 1 - 4 40 60 100

Prerequisite: Microprocessor and Applications

Course Outcome

CO1 The student will gain conceptual understanding of using a generic microcontroller and activation circuit.

CO2 The students will become knowledgeable about 8051 microcontroller architecture and programming.

CO3 The students will gain knowledge about LPC2148 microcontroller and programming.

CO4 The students will learn about design of simple real time embedded systems.

CO5 Student will get understanding of Real time operating systems (RTOS)

UNIT – I REVIEW OF EMBEDDED SYSTEMS Hours: 12

Introduction to embedded system, embedded system architecture, classifications of embedded systems, challenges and design issues in embedded systems, fundamentals of embedded microcontrollers, CISC vs. RISC, fundamentals of Vonneuman/ Harvard microcontrollers. Steps for activating a Microcontroller- Development Tools–Firmware Development options – Assembly Language Vs High level Language Programming- Intel Hex File Format.

CO1

UNIT – II MCS51 MICROCONTROLLER Hours: 12

Pin Diagram of MCS51 microcontroller – Internal Memory Map - Special Function Registers (SFR)- Instruction set, Addressing Modes, Stack Operation, Assembly Language Programming, Parallel port operation - Timer and Counter, UART Communication, Interrupts, Power Management - External Memory interfacing.

CO2

UNIT – III LPC2148 MICROCONTROLLER Hours: 12

Features of LPC2148 microcontroller – 8051 Vs LPC2148 Microcontroller - Pin diagram - Activating LPC2148 microcontroller - LPC2148 Bus Architecture – Programming GPIO, PLL, Timer/Counter, UART, ADC ,DAC and Interrupts in LPC2148. Firmware development using Embedded C – introduction to data types – conditional statements – loops – simple programs using embedded ‘C’

CO3

UNIT – IV SYSTEM DESIGN USING MCU Hours: 12

Design of Simple I/O systems using Switches, LEDs, Buzzers - Relays – Keypads - Current source and sink concepts - Interfacing Character and Graphical LCD Displays – RTC interfacing - Interfacing External ADC and DAC - DC Motor Speed Control System – Speed Measurement – Design of Digital Frequency meter - PC based Control systems

CO4

UNIT – V REAL TIME OPERATING SYSTEMS Hours: 12

Introduction to RTOS- Types of Real time systems - Concept of Scheduling – Cooperative and Preemptive scheduling –Components of RTOS – Kernel services – Task management - Task States, task and resource synchronization, semaphores, inter task communication , Dynamic Memory Allocation, Interrupt handling - RTOS implementation of a multi task application.

CO5

Total contact Hours: 45 Total Tutorials: -15 Total Practical Classes: Total Hours: 60

Reference Books:

1. David E Simon, " An embedded software primer ", Pearson education Asia, 2001. 2. Mohammed Ali Mazidi and Janice Gillispie Mazidi, “The 8051 Microcontroller and Embedded System”, Pearson

Education Asia, New Delhi, 2006. 3. Trevor Martin,”The Insider's Guide to the Philips ARM7-Based Microcontrollers”,Hitex Pubications(UK), 2005. 4. Michael J Pont,"Patterns for Time-Triggered Embedded Systems",Addison-Wesley Professional,2001. 5. Burns, Alan and Wellings, Andy, " Real-Time Systems and Programming Languages ", Second Edition. Harlow:

Addison-Wesley-Longman, 1997. 6. Raymond J.A. Bhur and Donald L.Bialey, " An Introduction to real time systems: Design to networking with

C/C++ ", Prentice Hall Inc. New Jersey, 1999. 7. Grehan Moore, and Cyliax, " Real time Programming: A guide to 32 Bit Embedded Development. Reading "

Addison-Wesley-Longman, 1998. 8. Heath, Steve, " Embedded Systems Design ", Newnes 1997. 9. John B Peat man " Design with Microcontroller ", Pearson education Asia, 1998.

45




L T P C CA SE TM

EI221 Robotics and Automation 3 - - 3 40 60 100

Course Outcome

CO1 Students will be able to design a robot starting with the conceptual design

CO2 The students will become knowledgeable about the design of sensor and gripper.

CO3 The students will gain manipulator dynamics of robots

CO4 Develop the concept into a model, analyze the model on computer using engineering software packages

CO5 Student will get understanding of Robotic applications also to Develop an engineering report and demonstrate the robot’s performance

UNIT-I Introduction Periods: 9

Robotics – Basic components – Classification – Performance characteristics – Actuators- Electric actuator- DC motor horse power calculation, magnetostrictive hydraulic and pneumatic actuators. Sensors and vision systems: Different types of robot transducers and sensors – Tactile sensors – Proximity and range sensors – ultrasonic sensor-touch sensors-slip sensors-sensor calibration- vision systems – Image processing and analysis – image data reduction – segmentation feature extraction – Object recognition

CO1

UNIT-II End Effectors Periods: 9

End effectors and tools– types – Mechanical grippers – Vacuum cups – Magnetic grippers – Robot end effectors interface, work space analysis work envelope workspace fixtures-pick and place operation- continuous path motion-interpolated motion straight line motion.

CO2

UNIT-III Robot Motion Analysis Periods: 9

Robot motion analysis and control: Manipulator kinematics –forward and inverse kinematics- arm equation-link coordinates-Homogeneous transformations and rotations and Robot dynamics .

CO3

UNIT-IV Robot control Periods: 9

Control of robot manipulators- state equations-constant solutions-linear feedback systems-single axis PID control- PD gravity control- computed torque control- variable structure control- Impedance control.

CO4

UNIT-V Robot Applications Periods: 9

Industrial and Non industrial robots, Robots for welding, painting and assembly – Remote Controlled robots – Robots for nuclear, thermal and chemical plants – Industrial automation – Typical examples of automated industries

CO5


Reference Books:

1. Mikel P. Grover , et. Al. , Industrial Robots – Technology Programming and Applications, McGraw Hill, 1980. 2. Robert J.Schilling, Fundamentals of Robotics-Analysis and Control, PHI, 2007. 3. K.S.Fu,R.C.Gonzalez, CSG. Lee, Robotics,control sensing vision and Intelligence, Tata Mcgraw-Hill, 2008.

46

Department : HSS Programme : B.Tech.

Semester : Sixth Course Category Code: HSM Semester Exam Type: TY


L T P C CA SE TM

HS202 Industrial economics and management 3 - - 3 40 60 100

Prerequisite:

To familiarize the prospective engineers with elementary principles of economics and management To enable the students with standard management concepts and tools that is likely to be useful in their profession. To create awareness about the current status of economic parameters/indicators/policy debates.

Course Outcome

CO1 Assess the knowledge of mathematics to understand industrial micro economics/macroeconomics.

CO2 Implement various management techniques based on the needs.

CO3 Implement various investment evaluation based on the needs

CO4 Apply formula and workout problem

CO5 Case studies on General, Production and Financial management.

UNIT-I MICRO AND MACRO ECONOMICS AND ITS APPLICATIONS Periods: 12

Nature and Scope of Economic science: Micro – Macro Economics, Economic decisions and Technical decisions. Demand and Supply concepts: Types of Demand, Determinants of Demand and Supply, concept of Equilibrium, Elasticity of Demand, cost components, Concepts of ISO-Quant – Break Even Analysis – Market structure – Price of Product Nature of pricing in different types of competition Small Scale Industries – Role of SSI in Indian Economy. Macro Economics: Nature and functions of Money – National Income – GNP and Savings – Inflation and Deflation concept – Business Cycle – Foreign Trade and Balance of payment.

CO1

UNIT-II MANAGEMENT TECHNIQUES Periods: 12

Types and Principles of Management – Elements of Management – Planning, Organising, Staffing, Directing, Coordinating Controlling - Scope of Management – Types of Organization Merits and Demerits – Types of (Ownership) of a firm Merits and Demerits.

CO2

UNIT-III INDUSTRIAL FINANCE Periods: 12

Need for Finance – Types of finance – Sources of finance – Types of Investment – Evaluation of Investment – Preparation of Trading, Profit and loss Account and Balance Sheet – types of accounting and significance of each types.

CO3

UNIT-IV PRODUCTION MANAGEMENT Periods: 12

Theory of Production Function – Types of Production Merits and Demerits – Process Planning – Routing – Scheduling – Material Control Concepts of Productivity – Measurement of Productivity – Inspection and Dispatches.

CO4

UNIT-V MARKETING MANAGEMENT Periods: 12

Core Concepts of Marketing -0 Needs – Wants – Demand, Marketing Vs Selling – Products and Markets – Pricing and related factors – Channels of Distribution – Promotion Advertising – Market Research Vs Marketing Research

CO5

Lecture Periods: 60 Tutorial Periods: Practical Periods:- Total Periods: 60

Reference Books:

1. Varshney Maheswari “Managerial Economics” S Chand & Co, New Delhi 2011 2. Dutt & Sundaram, “Indian Economy” S Chand & Co New Delhi 2015 3. Pandey I.M, “Elements of Financial Management” Wiley Eastern Ltd New Delhi 2015 4. H.L. Ahuja, “Macro Economics for Business and Management, S Chand & Company Ltd 2011 5. O.P Khanna, “Industrial Engineering and Management, Dhanpat Rai and Sons, 2009. 6. Philip B Kotler, “Marketing Management, Mac Millan, New York 2011.

47


Semester : Sixth Course Category Code: PCC Semester Exam Type: LB

Course Code Course Name Hours /Week Credit Maximum Marks

L T P C CA SE TM

EI222 Process Control Lab - - 3 1.5 40 60 100

Prerequisite

Outcome

CO1 Tounder standtheprocessplantandPipingandInstrumentationdiagrams.

CO2 Thestudentswillbeabletodesignandimplementdifferentclosedloopcontrolschemes for differentprocesses

CO3 Togetadequateknowledgeaboutpracticalissuesofvariouscontrollermodesandmethods oftuningofPIDcontroller.

CO4 Togetadequateknowledgeaboutpracticalissuesofclosedloopcontrolofprocesses.

CO5 To design an embedded PID controller

List of Experiments

StudyofProcessControlTrainingSystemandPipingandInstrumentationdiagramofa plant. StudyofInherentandInstalledCharacteristicsof Control Valves.

CO1

Tuning and Closed loopcontrolofLevelProcess. TuningandClosedloopcontrolofFlowProcess. TuningandClosedloopcontrolofTemperatureProcess. TuningandClosedloopcontrolofPressureProcess.

CO2

DesignandimplementationofON/OFFControllerfortheTemperatureProcess.PIDImplementationIssuesandconfiguringIndustrialPIDController.

CO4

Tuning PID Controller for soft processes. (Mathematically described processes) Design and simulation of Digital Controllers (Dead Beat, Dhalin’s,Kalman’s)

CO4

TuningandclosedloopcontrolofElectronicProcesses. Design and implementation Embedded PID Controller

CO5

Totalcontact Hours:- Total Tutorials: - Total Practical Classes: 45 Total Hours: 45

Reference Books:

1. G.Stephanopoulis,ChemicalProcessControl,PHIlearning,NewDelhi,2008. 2. D.P.Eckman, Automatic Process Control, Wiley Eastern Ltd., New Delhi,2008. 3. Donald R.Coughanowr,Steven E.Leblanc, Process System Analysis Control, 3rd edition, 2013.

48

Department: Electronics and instrumentation Engineering Programme : B.Tech.

Semester : Sixth Course Category Code: PCC Semester Exam Type: LB


L T P C CA SE TM

EI223 VIRTUAL INSTRUMENTATION LAB - - 3 1.5 40 60 100

Prerequisite -

Course Outcome

CO1 Apply concepts of VI for programming structures and loops

CO2 Design of VI using serial communication

CO3 Design of VI systems using GPIB, Ethernet, ARDUINO & DAQ

CO4 Apply concepts of VI in specialised Control Design and Computer vision applications

CO5 Explore other VI tools for designing GUI’s

Basic LabView Programming - Controls and indicators- Labels and Text –Shape, size and color- – Data type, Format, Precision and representation – Data types - Concept of subVI - FOR Loops, WHILE Loops, CASE Structure, Formula nodes, Sequence structures- Attribute modes Local and Global variables Arrays and Clusters– Array Operations – Bundle – Bundle/Unbundle by name, graphs and charts – String and file I/O

CO1

Implementing Serial Communication using Programmable Dual Axis stage controller Design of Virtual Programmable Digital Voltmeter & Function generator

CO2

GPIB based instrument control, Distributed Instrument control using Ethernet DAQ & ARDUINO Interfacing

CO3

Control Systems and Image Processing Toolkits for custom applications CO4

Serial Communication using Text based Programming – Development of GUI CO5


Reference Books

1. Jovitha Jerome, ―Virtual Instrumentation using LabVIEW‖, PHI Learning Pvt. Ltd., 2010. 2. Steve Mackay, Edwin Wright, John Park, and Deon Reynders, ―Industrial Data Networks, Elsevier, 2004. 3. Gary Johnson and Richard Jennings, ―LabVIEW Graphical Programming, McGraw Hill Inc., Fourth Edition, 2006. 4. Sanjay Gupta and Joseph John, ―Virtual Instrumentation using LabVIEW, Tata McGraw-Hill Inc., 2005. 5. William Buchanan, ―Computer Buses Design and Application, CRC Press, 2000.

49


Semester : Sixth Course Category Code: PCC Semester Exam Type:LB


L T P C CA SE TM

EI224 Embedded System Design Lab - - 3 1.5 40 60 100

Prerequisite:

Course Outcome

CO1 The student will gain conceptual understanding of using a 8051 microcontroller and parallel ports.

CO2 The students will become knowledgeable about 8051 microcontroller timer and interrupts

CO3 The students will gain knowledge about LPC2148 microcontroller and programming.

CO4 The students will learn about design of data acquisition and LCD systems using LPC2148

CO5 Student will get understanding of Real time operating systems (RTOS)

List of Experiments

1.Parallel Port Interfacing Using MCS51. 2.Design of Real Time Clock using MCS 51 using segment Displays. 3.Design of PC interface Hardware with MCS51 4.Interfacing LCD Display using MCS51 5.Design of Single Channel Data Acquisition System Using MCS51.

CO1, CO2

6.Implementation of GPIO and Timer using ARM LPC2148. 7.Implementation of UART features of ARM LPC2148. 8. Implementation of Data Acquisition and Signal Generation using LPC2148. 9.Interfacing SD card and Graphical LCD using LPC2148. 10. Implementation of RTOS using LPC2148.

CO3, CO4, CO5


Refernce Books: 1. David E Simon, " An embedded software primer ", Pearson education Asia, 2001. 2. Mohammed Ali Mazidi and Janice Gillispie Mazidi, “The 8051 Microcontroller and Embedded System”, Pearson

Education Asia, New Delhi, 2006. 3. Trevor Martin,”The Insider's Guide to the Philips ARM7-Based Microcontrollers”,Hitex Pubications(UK),2005. 4. Michael J Pont,"Patterns for Time-Triggered Embedded Systems",Addison-Wesley Professional,2001. 5. Burns, Alan and Wellings, Andy, " Real-Time Systems and Programming Languages ", Second Edition. Harlow:

Addison-Wesley-Longman, 1997. 6. Raymond J.A. Bhur and Donald L.Bialey, " An Introduction to real time systems: Design to networking with C/C++ ",

Prentice Hall Inc. New Jersey, 1999. 7. Grehan Moore, and Cyliax, " Real time Programming: A guide to 32 Bit Embedded Development. Reading " Addison-

Wesley-Longman, 1998. 8. Heath, Steve, " Embedded Systems Design ", Newnes 1997. 9. John B Peat man " Design with Microcontroller ", Pearson education Asia, 1998.

50




L T P C CA SE TM

EIH04 ADVANCED CONTROL ENGINEERING 3 1 - 4 40 60 100

Prerequisite:

Course Outcome

CO1 will be able to Analyze the digital system design.

CO2 will be able to Derive state models for LTI continuous systems

CO3 will be able to Estimate the solution for LTI system and its performance indices.

CO4 will able to Analyze the nonlinear system using phase plane and describing function methods.

CO5 will be able to Evaluate the stability of non-linear systems and state model design

UNIT-I SAMPLED DATA SYSTEM Periods: 12

Sampled data theory – Sampling process – Sample and hold circuits – Signal reconstruction –Pulse transfer function-Response of Sampled data system to step and Ramp inputs- Stability analysis of sampled data systems

CO1

UNIT-II STATE SPACE MODEL Periods: 12

I Introduction to generalized state model – state diagram - state variable analysis for physical variable – mechanical and electrical systems – state model for armature and field controlled dc motor - phase variable and canonical variables model for continuous time systems – state model to transfer function.

CO2

UNIT-III STATE VARIABLE ANALYSIS Periods:12

Decomposition techniques – Direct, cascade and parallel forms - Solution of homogeneous state equations – state transition matrix – Laplace transformation and cayley hamiltan methods - Eigen values and eigen vector - Controllability and Observability.

CO3

UNIT-IV NON LINEAR SYSTEM ANALYSIS Periods: 12

Types of non-linearity – Phase plane analysis – Singular points – Limit cycle – jump resonance - construction of phase trajectories – analytical method and isoclines method – Describing function analysis – Saturation, Dead zone, saturation-dead zone , Relay and Backlash.

CO4

UNIT-V STABILITY ANALYSIS Periods: 12

Definiteness of scalar functions –quadratic forms – Basics of stability theorems – Liapunov functions – Direct method liapunov – constructing of liapunov functions using kravskii‟s method.

CO5


Reference Books:

1. Gopal M., Modern Control Systems Theory, 3rd Edition, New Age International Publishers, New Delhi, 2015 2. Robert H Bishop and Richard C Dorf, Modern Control Systems, 12th Edition, Pearson Education, 2010 3. K.K.Agarwal, “Control system analysis and Designs”, Khanna Publishers, 2003.

51

Department:Electronics and Instrumentation Engineering

Programme : B.Tech.



L T P C CA SE TM

EIM04 ESSENTIALS OF CONTROL ENGINEERING

3 1 - 4 40 60 100

Prerequisite:

Course Outcome

CO1 Able to appreciate the importance of feedback control system.

CO2 Able to analyze and design the system performance using time domain and frequency domain techniques.

CO3 Able to use simulation software for classical control system design and analysis.

CO4 Able to design compensator using simulation software

CO5 Able to understand case studies with different applications

UNIT-I Periods: 12

Introduction to control system – Open loop and Closed loop system – Feedback system characteristics – Block diagram reduction techniques – Signal flow graph.

CO1

UNIT-II Periods: 12

Order and type of system – time domain and frequency domain response of different system characteristics using simulation software – Introduction of stability – Routh Hurwitz stability criteria.

CO2


Introduction to root locus – plotting of root locus and stability analysis using simulation software. Introduction to bode and Nyquist plot – Plotting of bode and Nyquist plot using simulation software - Gain Margin and Phase margin calculation.

CO3

UNIT-IV Periods: 12

Introduction to different compensator design – the design of different compensator design using simulation software. PID controller design using simulation software.

CO4

UNIT-V Periods: 12

Application of control system for different domain with case studies. CO5


Reference Books:

1. Dorf, R.C., & Bishop, R.H., Modern Control Systems, Prentice Hall, 13th Edition, 2016. 2. Katsuhiko Ogata Modern Control Engineering, Pearson, 5th Edition, 2009. 3. Franklin G.F., Powell J.D., Emami-Naeini A., Feedback Control of Dynamic Systems, Pearson, 7th Edition, 2015. 4. B. C. Kuo, F. Golnaraghi, Automatic Control Systems, Wiley Publishers, India, 8th Edition, 2003. 5. Ramakalyan A., Control Engineering- A comprehensive foundation, Vikas Publication, New Delhi, 2004. 6. Norman S. Nise, Control Systems Engineering, Wiley India publications, 4th Edition, 2003.

52


Semester : Seventh Course Category Code: PCC Semester Exam Type:TY


L T P C CA SE TM

EI225 PLC& DCS 3 1 - 4 40 60 100

Prerequisite:

Course Outcome

CO1 The students will be able to understand the basics of PLC Architecture

CO2 The students will become familiar with PLC programming and can do their own programming

CO3 The students will be able to understanddifferent data networking protocols

CO4 The students will become familiar with Industrial DCS systems

CO5 The students will understand HART & Field Bus and its role in building DCS systems

UNIT-I PLC Architecture and Interface Modules Periods: 12

PLC Architecture -comparative study of industrial PLC’s- Interface modules-ac and dc input and output modulesanalog and discrete input and output modules, BCD and TTL input and output modules - communication modules - PID-Thermocouple-stepper motor, Encoder/Counter, servo and language modules.

CO1

UNIT-II PLC Programming Periods: 12

Ladder logic - Boolean language - sequential function instruction set-program counter, data manipulation, chartArithmetic, shift registers and sequencers – Structured Text Programming

CO2

UNIT-III Data Network Fundamentals Periods: 12

Network hierarchy and switching-ISO/OSI Reference model-Data link control protocol: HDLC-SDLC-Multiple access protocols-Token ring Token bus and CSMA/CD, Polling, reservation, FDMA, TDMA, CDMA, Addressing concepts: class full, classless addressing and network address translation. TCP/IP-Bridges-routers-gateways-standard Ethernet and ARCNET configuration

CO3

UNIT-IV Distributed Control System Periods: 12

Evolution – Different architecture – Local control unit functions – Operator Interface – LLOI and HLOI – redundancy concepts – Displays – Communication networks and communications standards in DCS – Engineering Interface – Factors to be considered in selecting a DCS

CO4

UNIT-V Hart and Fieldbus Periods: 12

Introduction HART communication protocol – communication modes - HART networks – HART commands – HART application – Fieldbus: Introduction – fieldbus architecture, Basic requirements of field bus standard – fieldbus topology – Interoperability and Interchangeability. Smart Transmitters – MAP protocol.

CO5


Reference Books:

1. Frank. D.Petrezuella , Programmable logic controllers, McGrewhill, Third edition. 2. Lucas. M.P., Distributed control systems ,Van Nostrand and Reinholdcompany, NY,1986. 3. Hughes.T., Programmable controllers, ISA Press, 2000 4. M. Chidambaram , Computer control of process, Narosa publishing house. 5. D.M.Considine, Process Instruments and Controls Handbook, McGraw-Hill., 1985. 6. Moore, Digital control devices, ISA press, 1986. 7. B.G.Liptak, Instrumentation in process industries, Vol. I and II, Chilton books co,1973.

53

Department : Electronics and Instrumentation Engineering

Programme : B.Tech.



L T P C CA SE TM

EI226 ANALYTICAL INSTRUMENTS 3 1 - 4 40 60 100

Course Outcome

CO1 Understand the importance of Spectral methods & identify its measurement in UV range

CO2 Acquire knowledge about the FLAME &IR spectroscopy and the impact of its measurement in environmental context.

CO3 Acquire knowledge about the MASS, NMR spectroscopy & RADIATION measurement and the impact of its measurement in environmental context.

CO4 Identify the process behind CONDUCTIVITY, pH and OXYGEN analysisin real time industrial environments.

CO5 Identify techniques and modern engineering tools for monitoring different pollutants in air and water and Chromatography techniques

UNIT-I Periods: 12

Electromagnetic radiation and its interaction with matter – Beer's law – Spectral methods of analysis –Absorption spectroscopy – Radiation sources – Monochromators – Filters – Prisms – Diffraction gratings – Detectors – Choice of solvents. UV-Visible spectrometers – single-beam and double-beam instruments

CO1

UNIT-II Periods: 12

Infrared spectrophotometer – IR sources – Cells – detectors – sample preparation. Analysis using Attenuated Total Reflectance (ATR). Atomic absorption spectrometry (AAS) – Wavelength choice –Sources – Cells – Detectors. Flame emission spectrometry. Atomic fluorescence spectrometry.

CO2


Single focusing and double focusing mass spectrometers – Time of Flight – Quadrupole Mass Spectrometers – principles and application - X-ray spectroscopy – X-ray absorption methods – X-ray fluorescence methods – X-ray diffraction. Radioactive measurement – Units of radioactivity – Radioactivity detectors. Nuclear magnetic Resonance (NMR) spectroscopy – Basic principles and applications.

CO3

UNIT-IV Periods: 12

Sampling – Sample collection for gas, liquid, and solid analysis. pH measurement – Basic principles –Ion selective electrodes – Glass and reference electrodes – pH meter and its calibration. Electrical conductivity measurement – Water and steam purity measurement using electrical conductivity. Oxygen measurement – Paramagnetic oxygen analyzers – Ceramic electrode for high temperature oxygen measurement – Dissolved oxygen measurement

CO4

UNIT-V Periods: 12

Flue gas analysis for pollution control – Measurement of CO, carbon di-oxide, NOX and SOX, dust and smoke measurement. Chromatography – Basic principles of liquid and gas chromatography – Column details – Detectors for chromatography – Thermal conductivity detector – Flame ionization detector – Flame photometric detector – Electron capture detector – Effect of temperature programming – High pressure liquid chromatography (HPLC)

CO5

Lecture Periods: 45 Tutorial Periods: 15 Practical Periods:0 Total Periods:60

Reference Books:

1. Braun, Robert D., Introduction to Instrumental Analysis, Pharma Book Syndicate, Hyderabad. 2006. 2. 2. Ewing, G.W., Instrumental Methods of Analysis, 5th Edition, McGraw Hill, Singapore, 1992. 3. 3. Jain, R.K., Mechanical and Industrial Measurements, Khanna Publishers, Delhi,1999. 4. Liptak, B.G. Process Measurement and Analysis, 4th Edition, CRC Press, Washington, 2003. 5. Considine, D.M. Process/Industrial Instruments and Controls Handbook, 4th Edition, McGraw Hill, Singapore, 1993. 6. Sherman, R.E. and Rhodes L.J., Analytical Instrumentation, ISA Press, New York, 1996.

54


Semester : Seventh Course Category Code: PCC Semester Exam Type:LB


L T P C CA SE TM

EI227 Industrial Measurements and Control Lab

0 0 3 1.5 40 60 100

Course Outcomes

CO1 To understand practical issues of applications of PLC hardware and programming a PLC.

CO2 To get adequate knowledge about practical issues of implementations of PLC and DCS.

CO3 To get adequate knowledge about practical issues of calibration of Process instruments

CO4 To get adequate knowledge about practical issues of various digital controllers.

CO5 To get adequate knowledge about practical issues of closed loop control of processes

(Any 10 Experiments) . Study of basic programming of PLC . Analog operation in PLC . Arithmetic operation, Timer, Counter operation using PLC . Annunciator design using PLC PLC based control of Level Process , Temperature Process.

CO1

DCS based control of Level Process , Pressure , Flow Process. CO2

Calibration of Pressure gauge using Dead weight Tester. Calibration of manometers and Control valves Calibration of Control valves, I to P and P to I converters Calibration of Pressure Switch, RTD and Thermocouple.

CO3

Design of PID Controller and Auto tuning of PID Controller Analysis of Multi-input Multi-output System(Four-tank System) Design of Multi-Loop PID Controller and Multivariable PID Controller. Design of Gain scheduling controller Design of Self-Tuning Controller Design of Deterministic/stochastic State Observer b) Design of State Feedback

CO4

Design and simulation of digital controller using Dahlin's algorithm Design and simulation of digital controller using Dead beat algorithm Parameter estimation of process from input output data Control of a real time process using ADC/DAC interface between Simulink and Process hardware. Design and simulation of digital controller using Kalman's algorithm PC based PID Control of 4th order electronic process using C program PC based Cascade control of level process PC based control of interacting level process

CO5

LecturePeriods: 0 Tutorial Periods: 0 Practical Periods: 45 Total Periods: 45

55


Semester : Seventh Course Category Code: PAC Semester Exam Type:TY

Course Code


L T P C CA SE TM

EI228 Seminar 3 0 0 1 100 - 100

This one credit course is meant to give students practice speaking in front of a scientific audience and to explore topics in detail. Students will research topics and organize presentations for faculty and other students. The topics may be any aspect of the instrumentation applications not covered in regular curriculum and must be approved by the instructor in advance. Attendance at each seminar is mandatory for all students enrolled. It is expected that students will actively participate by asking questions of the speaker. The effort by students to meet these expectations will be considered in the determination of your final grade. The curriculum of all engineering disciplines will have a compulsory ‘Seminar’ course offered in sixth or seventh semester. The student will present a Seminar on a topic in an emerging area in his discipline of engineering. The student will make the presentation for a duration of 20 to 25 minutes and also submit a brief report running to 15 or 20 pages for the purpose of evaluation.

LecturePeriods: 3 Tutorial Periods: 0 Practical Periods: 0 Total Periods: 3

56


Semester : Seventh Course Category Code: PAC Semester Exam Type:LB


L T P C CA SE TM

EI229 Mini Project 0 0 3 2 100 - 100

Individual Student should select a problem which addresses some basic home, office or other real life applications. Students should develop solutions for the same and see that final circuit submitted by them is in working condition. A 5-10 pages report to be submitted by students. Department may arrange demonstration with poster presentation of all mini projects developed by the students at the end of semester. It is desirable that the project developed by the student have some novel features. The evaluation will be made for the continuous internal assessment for the Project by a committee nominated by the Head of the Department

LecturePeriods: 0 Tutorial Periods: 0 Practical Periods3 Total Periods: 3

57


Semester : Seventh Course Category Code: MCC Semester Exam Type: TY


L T P C CA SE TM

EI230 Professional Ethics 2 0 0 0 100 - 100

The course should cover the following topics by way of Seminars, Expert Lectures and Assignments: 1. Engineering Ethics – Moral issues, Ethical theories and their uses 2. Engineering as Experimentation – Code of Ethics 3. Engineer’s responsibility for safety 4. Responsibilities and rights 5. Global issues of engineering ethics


58

Department: Electronics and Instrumentation Engineering

Programme : B.Tech.



L T P C CA SE TM

EIH05 Cyber Security in Industrial Automation

3 1 0 4 40 60 100

Prerequisite:

Course Outcome

CO1 Describe in detail about cyber security for Industrial Control System

CO2 Discuss about treats in Industrial Control System

CO3 Explain in detail about Industrial Control System vulnerabilities

CO4 Discuss about cyber security in SCADA system

CO5 Explain about Industrial Sectors Cyber Security.

UNIT-I CYBER SECURITY FOR INDUSTRIAL CONTROL SYSTEM Periods: 9

Industrial Control System-Industrial control system security different than regular IT security-ICS-ICS compare to safety instrument system-Components of Typical ICS/SCADA systems-SCADA system-Supervisory Control and Data Acquisition-Remote Terminal Unit (RTU)-Distributed Control System (DCS)-Programmable Logic Controller (PLCs)-Human Machine Interface (HMI)

CO1

UNIT-II THREATS TO ICS Periods: 9

Threats to ICS: Threat treatment in ICS and IT-Threats to ICS-Threat –to and threat-from-most series treat to ICS-Hi-jacking malware-The reproductive cycle of modern malware- A socks 4/sock 5/HTTP connect proxy-SMTP spam engine-porn dialers

CO2

UNIT-III ICS VULNERABILITIES Periods: 9

ICS Vulnerability versus IT vulnerability-Availability, Integrity and Confidentiality-Purdue Enterprise Reference Architecture-PERA levels-Levels 5- level 4-level 3-level 2-level1-level 0- an ironic comment on PERA

CO3

UNIT-IV CYBER SECURITY FOR SCADA SYSTEMS Periods: 9

SCADA security architecture: Commercial hardware and software vulnerabilities-Operating system-TCP/IPFirewalls-Traditional security feature of SCADA system-Eliminating the vulnerabilities of SCADA system

CO4

UNIT-V INDUSTRIAL SECTORS CYBER SECURITY Periods: 9

ICS Application security: Application security-Application security testing_ ICS application patching-ICS secure SDLC-Case Studies: Water/waste water industry specific cyber security-Piping Industry-specific cyber security issues-Emerging cyber threat to SCADA system

CO5


Reference Books:

1. Pascal Ackerman “Industrial Cyber Security Efficiently secure critical infrastructure systems”, Packt publisher,2017 2. William T.Shaw, “Cyber security for SCADA systems”, Pennwel publisher,2006 3. R.A.Kisner, W.W.Manges, “Cyber security through Real-time Distributed Control Systems”, UT-Battelle publisher,

2010 4. Eric D. Knapp, Joel Thomas Langill “Industrial Network Security: Securing Critical Infrastructure”, Syngress

publisher,2014 5. B.R. Mehta, Y. Jaganmohan Reddy “Industrial Process Automation Systems”, Butterworth-Heinemann publisher,

2014.

59

Department :Electronics and Instrumentation Engineering

Programme : B.Tech.

Semester : VIII Course Category Code: PAC Semester Exam Type: TY

Course Code

Course Name Periods /

Week Credit Maximum Marks

L T P C CA SE TM

EI231 Comprehensive Test 0 0 0 1 100 - 100

i) The student is required take a ‘Comprehensive Test’ on a scheduled date in the beginning of the this semester. ii) Comprehensive Test is meant for testing the higher order and critical thinking of thestudent in the respective domain. This test will have the standard of GATE examination.

Lecture Periods: 0 Tutorial Periods: 0 Practical Periods Total Periods:

60


Semester : Eighth Course Category Code: PAC Semester Exam Type:


L T P C CA SE TM

EI232 Internship 0 0 0 2 100 - 100

i) The student is required to undergo ‘internship’ in industry / research laboratory / higher learning institution for a period of at least 6 weeks in a maximum of 3 spells during vacations.

ii) Each spell of internship shall be for a period of not less than 2 weeks. iii) The main purpose of internship is to enhance the general professional outlook and capability of the student to

advance his chances of improving the career opportunities. The student should get prior approval from the Head of the Department before undertaking the internship and submit a detailed report after completion for the purpose of assessment.

iv) The assessment of the internship will appear only in the eighth semester grade card irrespective of the semester vacation in which the internship is completed.

Lecture Periods: 0 Tutorial Periods: 0 Practical Periods3 Total Periods:

61


Semester : Eighth Course Category Code: PAC Semester Exam Type: PR

Course Code


L T P C CA SE TM

EI233 Project Work 0 0 0 8 100 - 100

The student is given an option to carry out this project work either in the college or in an industry / research laboratory / higher learning institution. The project work will be carried out under the supervision of a project guide from the department. In the case of student carrying out the project work outside the college, an external guide from the relevant organization shall be assigned in addition to the internal guide from the department. On completion of the work, a project report should be prepared and submitted to the department. The project work and the report will be evaluated by an internal assessment committee. The external university examination will have report evaluation and viva voce examination conducted by a committee of one external examiner and one internal examiner.

Lecture Periods: 0 Tutorial Periods: 0 Practical Periods Total Periods:

62

PROGRAM ELECTIVE COURSES

63


Semester : Course Category Code: PEC Semester Exam Type:TY


L T P C CA SE TM

EIY01 Signals and Systems 3 0 -- 3 40 60 100

Prerequisite:

Course Outcome

CO1 Understand about signals, systems and their classification

CO2 Will be able to analyze the signals and systems in frequency domain

CO3 Analyze continuous and discrete-time systems in time-domain

CO4 Analyse Continuous systems using Laplace transform

CO5 Analyse discrete-time systems using z-transform

UNIT-I Introduction to signals and systems Periods: 9

Classification of signals – Continuous-time signal and discrete-time signals – periodic and aperiodic signals – even and odd signals – energy and power signals – deterministic and random signal. Basic operations on signals-. Types of signals – exponential, sinusoidal, step, impulse and ramp. System –Classification of systems : Linear, Nonlinear, static, dynamic, time –invariant, time variant, causal and non-causal, stable and unstable systems.

CO1

UNIT-II Fourier Series and Fourier transform Periods: 9

Trigonometric Fourier series and Exponential Fourier series, Dirichlet’s conditions, Complex Fourier spectrum -properties of Fourier series, Fourier transform of standard signals, properties of Fourier transforms, frequency response of a system, Sampling theorem. Aliasing effect, Discrete-Fourier series-Properties-DTFT-propertiesfrequency response –transfer function.

CO2

UNIT-III Analysis of continuous-time and discrete-time systems Periods: 9

Analysis of continuous-time and discrete-time systems-: Linear system, -representation of an arbitrary CT and DT signals- impulse response of CT and DT systems -convolution –properties convolution integral- convolution sum-causality and stability - Cross correlation and auto correlation of functions, properties of correlation function, Energy density spectrum, Parseval’s theorem, Power density spectrum, Relation between convolution and correlation

CO3

UNIT-IV Laplace transform Periods: 9

Review of Laplace transforms, Concept of region of convergence (ROC) for Laplace transforms, Properties of Laplace transform-relation between lapalce transform and Fourier transform, Laplace transform of certain signals using waveform synthesis. Inverse Laplace transform, Partial fraction expansion, Solutions of differential equation using Laplace transform, Transfer function-stability-State space representation

CO4

UNIT-V Z.transform Periods: 9

Concept of Z- Transform of a discrete sequence. Distinction between Laplace, Fourier and Z transforms. Region of convergence in Z-Transform, constraints on ROC for various classes of signals, properties of z-transform-Inverse Z-transform, Solution of difference equations using z- transform, system function-stability- State space representation

CO5


Reference Books:

1. Allan V.Oppenheim, “Signals and systems”, Prentice Hall of India, 2011. 2. Roger E.Ziemer, “Signals and Systems Continuous and discrete”, McMillan, 2008. 3. P.Ramesh Babu & R.Ananda Natrajan, Signals and Systems, Fourth Edition, Scitech Publications (India) Pvt. Ltd.,2014 4. Signals and Systems- Narayan Iyer and K Satya Prasad , Cenage Learning, 2011.

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L T P C CA SE TM

EIY02 Visual Programming for Instrumentation Engineers

3 0 0 3 40 60 100

Prerequisite: C Programming

Course Outcome

CO1 The student can understand fundamentals of .net, vb.c# and vb.net

CO2 The student can understand advanced concepts in c# and vb in .net

CO3 The student can able to choose a platform and language for developing instrumentation software

CO4 The student can create database applications

CO5 The student can create sample applications for instrument control.

UNIT-I Net Frame Work and C# Basics Periods: 9

.Net Frame work : Introduction – Components of .NET architecture –Principal Design features-web services C# basics: Introduction –Data Types-Access Modifiers- Variables and Constants –Statements –OO concepts-arrays –strings-System collections-delegate and events –indexer-properties-versioning

CO1

UNIT-II C# Using Libraries Periods: 9

Name space System-Input and output- Multithreading-Windows Forms –data handling and Exception handling

CO2

UNIT-III Advanced Features Using C# Periods: 9

Web services –Window services-Messaging, Reflection and COM- Localization and Globalization- - XML- Unsafe Model- Graphical Device Interface

CO3

UNIT-IV Introduction to VB.Net Periods: 9

Concepts and Simple Applications- variables, constants and Functions – processing decisions- Loop Structure and List File and Database Application: File access-Dialog Boxes –exception handling , Menus in Vb.net- Connecting to databases.

CO4

UNIT-V Advanced Programming Constructs Periods: 9

Sub Procedures –Functions –Modules-Arrays-Structure –Collection .Net Architecture and Advanced Tools: OOP with VB.net – Creating Distributed Web applications –Graphics, Printing ,Reporting Case Study: Case studies in developing applications for Instrumentation

CO5


Reference Books:

1. ISRD Group, Application of .net Technology, Tata Mcgraw Hill Education Private Limited, 2011. 2. Balagurusamy E, Programming with C#., Tata Mcgraw Hill 2008. 3. Chappell D , Understanding .NET , Pearson Edition 2007.

65




L T P C CA SE TM

EIY03 Industrial Electronics 3 0 0 3 40 60 100

Prerequisite: -

Course Outcome

CO1 Employ safety procedures presently being used in local manufacturing environments.

CO2 Communicate effectively using the appropriate written or oral techniques.

CO3 Modify or repair currently used manufacturing systems to operate in accordance with industry requirements and standards

CO4 Perform maintenance and troubleshooting functions

CO5 Apply industrial electronics in Industrial Heating Applications

UNIT-I Regulated Supplies and SCR Periods: 9

Switched Mode Voltage Regulator, Comparison of Linear and Switched Mode Voltage Regulators, Servo Voltage Stabilizer, monolithic voltage regulators, Fixed and Adjustable IC Voltage regulators, 3-terminal Voltage regulators, Current boosting. Principles of operation and characteristics of SCR, Triggering of Thyristors, Commutation Techniques of Thyristors, Classes A, B, C, D, E and F, Ratings of SCR

CO1

UNIT-II Applications of SCR-I Periods: 9

Static circuit breaker, Protection of SCR, Inverters, Classification, Single Phase inverters, Converters , single phase Half wave and Full wave. Chopper circuits, Principle, methods and Configurations, Diac and Triac – Triggering modes, Firing Circuits, Commutation

CO2

UNIT-III Applications of SCRS-II Periods: 9

Voltage compensator – solid state DC voltage regulation – DC shunt motor – armature control and field control of motor speed – electronic control of DC motor – speed regulator action – full wave motor speed regulation by one SCR

CO3

UNIT-IV Industrial Timers Periods: 9

Industrial timers -Classification, types, Electronic Timers, Classification, RC and Digital timers, Time base Generators. Electric Welding , Classification, types and methods of Resistance and ARC wielding

CO4

UNIT-V Industrial Heating Applications Periods: 9

High Frequency heating, principle, merits, applications, High frequency Source for Induction heating. Dielectric Heating, principle, material properties, Electrodes and their Coupling to RF generator, Thermal losses and Applications. Ultrasonics, Generation and Applications.

CO5


Reference Books:

1. G.K. Mithal and Maneesha Gupta, Industrial and Power Electronics, Khanna Publishers, 19th Ed., 2003. 2. M. Ramamurthy, Thyristors and applications, East-West Press, 1977. 3. S.K. Bhattacharya and Chatterjee, Industrial electronics and control, Tata Mc Graw Hill, 1995. 4. Frank D. Petruzella, Industrial Electronics, McGraw Hill International Editions, 1996.

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Semester : Course Category Code: PEC Semester Exam Type: TY


L T P C CA SE TM

EIY04 VIRTUAL INSTRUMENTATION 3 0 0 3 40 60 100

Prerequisite: Electrical and Electronic Instruments

Course Outcome

CO1 Paraphrase the basics of VI & Identify the importance of Graphical System design

CO2 Exploring the basic programming tools and understanding different data types

CO3 Apply concepts of VI for programming structures and loops

CO4 Identifying the different interfaces that can be employed

CO5 Identification of specialized application areas of VI

UNIT-I INTRODUCTION Periods: 9

Evolutions of VI, advantages, block diagram and architecture of a virtual Instrument-Graphical programming, and comparison with conventional programming

CO1

UNIT-II VI PROGRAMMING BASICS Periods: 9

Controls and indicators- Labels and Text –Shape, size and color- – Data type, Format, Precision and representation – Data types – Data flow Programming-Editing – Debugging and Running a Virtual Instrument – Concept of subVI.

CO2

UNIT-III PROGRAMMING STRUCTURES Periods: 9

FOR Loops, WHILE Loops, CASE Structure, Formula nodes, Sequence structures- Attribute Modes Local and Global Variables Arrays and Clusters– Array Operations – Bundle – Bundle/Unbundle by name, graphs and charts – String and file I/O

CO3

UNIT-IV INTERFACE STANDARDS AND DAQ Periods: 9

DAQ hardware configuration, sampling methods and grounding techniques, analog I/O, digital I/O, counter/timer, DAQ software architecture, RS232, RS485, GPIB. Interface Buses: USB, Firewire Backplane buses: PCI, PCI-Express, PXI, PXI – Express; Communication protocol overview - Industrial Ethernet, CAN.

CO4

UNIT-V APPLICATION MODULES AND TOOLKITS Periods: 9

Machine vision, motion control, data logging and supervisory control, control design and simulation tools – control design tool, system identification and simulation interface tool.

CO5


Reference Books:

1. Jovitha Jerome, ―Virtual Instrumentation using LabVIEW‖, PHI Learning Pvt. Ltd., 2010. 2. Steve Mackay, Edwin Wright, John Park, and Deon Reynders, ― Industrial Data Networks, Elsevier, 2004. 3. Gary Johnson and Richard Jennings ―LabVIEW Graphical Programming, McGraw Hill Inc., Fourth Edition, 2006. 4. Sanjay Gupta and Joseph John, ―Virtual Instrumentation using LabVIEW, Tata McGraw-Hill Inc., 2005. 5. William Buchanan, ―Computer Buses Design and Application, CRC Press, 2000. 6. Clyde F Coombs, ―Electronic Instruments Handbook, McGraw Hill Inc., Third Edition, 1999.

67




L T P C CA SE TM

EIY05 Digital Signal Processing 3 0 -- 3 40 60 100

Prerequisite: signals and system

Course Outcome

CO1 Analyze the response of a discrete-time system for different inputs

CO2 Plot the frequency response of a discrete-time system and analyze the discrete-time systems using z-transform

CO3 Analyse the frequency spectrum of discrete-time signals using FFT

CO4 Design IIR and FIR digital filters for the given application

CO5 Analyse finite word length effects in digital filter

UNIT-I Discrete-Time Signals and Linear Systems Periods: 9

Classification of signals: continuous and discrete, energy and power -representation of discrete-time signals, elementary discrete-time signals, classification of discrete-time signals, Classification of systems, Representation of a system with difference equation, impulse response and step response, FIR and IIR systems, Convolution sum and correlation, sampling techniques, quantization, quantization error, Nyquist rate, aliasing effect, reconstruction of analog signal from its samples..

CO1

UNIT-II DTFT and Z-Transform Periods: 9

Discrete-time Fourier series, Frequency range, Discrete-time Fourier transform-properties, Frequency response, ideal filters, Z-transform and its properties- inverse z-transforms- system function- stability criterion- Solving difference equations using Z-transform. Realization of IIR systems- direct form-I, direct form –II, cascade form and parallel forms. Realization of FIR systems-direct form, linear phase realization, cascade and parallel forms.

CO2

UNIT-III DFT and FFT Periods: 9

Discrete Fourier Transform, Relationship of the DFT to other transforms, Properties of DFT, circular convolution, filtering long duration sequences, parameter selection to calculate DFT. Computation of DFT using FFT algorithm – DIT & DIF - FFT using radix 2 – Butterfly structure- FFT applications.

CO3

UNIT-IV Design of Digital Filters Periods: 9

FIR filter design: Linear phase characteristics- Windowing technique of designing FIR filter–Need and choice of windows, frequency sampling method. IIR filter design: Analog filter design - Butterworth and Chebyshev filters, digital design usingimpulse invariant and bilinear transformation – War ping effect, prewarping.

CO4

UNIT-V Finite Word Length Effects in Digital Filters Periods: 9

Number representation, quantization, roundingtruncation. Input quantization error, Product quantization error, Coefficient quantization error, Overflow limit cycle oscillations, Zero input limit cycle oscillation, Scaling. Finite word length effects in computation of DFT using direct evaluation and FFT algorithms.

CO5

Lecture Periods: 45 Tutorial Periods: Practical Periods: - Total Periods:45

Reference Books:

1. P. Ramesh Babu, Digital Signal Processing, Seventh edition, Scitech publications, 2017. 2. Alan V. Oppenheim, Ronald W. Schafer and John R. Buck, Discrete – Time Signal Processing, Pearson Education,

New Delhi, 2003. 3. Johny R. Johnson : Introduction to Digital Signal Processing, Prentice Hall, 2004. 4. J.G Proakis and D.G.Manolakis, Digital Signal Processing Principles, Algorithms and Applications, Pearson

Education/ PHI, New Delhi, 2011.

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L T P C CA SE TM

EIY06 Applied Soft Computing 3 0 0 3 40 60 100

Prerequisite:

Course Outcome

CO1 To expose the students to the concepts of feed forward neural networks.

CO2 To provide adequate knowledge about feedback neural networks

CO3 To provide adequate knowledge about fuzzy and neuro-fuzzy systems

CO4 To provide comprehensive knowledge of fuzzy logic control to real time systems.

CO5 To provide adequate knowledge of genetic algorithms and its application to economic

UNIT-I Artificial Neural Network Periods: 9

Review of fundamentals – Biological neuron, Artificial neuron, activation function, single layer perceptron limitation – multilayer perceptron- Back propagation algorithm –recurrent network- adaptive resonance theory based network – radial base function network- online learning algorithms, BP through time- RTRL algorithm reinforce learning

CO1

UNIT-II Neural Networks for Modeling And Control Periods: 9

Modeling of non-linear systems using ANN- generation of training data – optimal architecture – model validation – control of nonlinear systems using ANN – direct and indirect neuro control schemes – adaptive neuro controller – familiarization with neural network toolbox

CO2

UNIT-III Fuzzy Set Theory Periods: 9

Fuzzy set theory- fuzzy sets- operation on fuzzy sets- Scalar cardinality, fuzzy cardinality, union and intersectioncomplement (Yeger and sugeno), equilibrium points, aggregation, projection, composition, cylindrical extension, fuzzy relation- fuzzy membership functions

CO3

UNIT-IV Fuzzy Logic For Modeling And Control Periods: 9

Modeling of non linear systems using fuzzy models – TSK model – fuzzy logic controller- fuzzification – knowledge base- decision making logic – defuzzification – adaptive fuzzy systems – Familiarization with fuzzy logic toolbox

CO4

UNIT-V Hybrid Control Schemes Periods: 9

Fuzzification and rule base using ANN – Neuro fuzzy systems ANFIS – Fuzzy neuron – Introduction to GA –Optimization of membership function and rule base using Genetic algorithm – Introduction to support vector machine – particle swarm optimization – case study – familiarization with ANFIS toolbox

CO5


Reference Books:

1. Laurene V.Fausett, Fundamentals of Neural Networks, Architecture, Algorithms, and Applications, Pearson Education, 2008.

2. Timothy J.Ross, Fuzzy Logic with Engineering Applications, Wiley, Third Edition, 2010. 3. David E.Goldberg, Genetic Algorithms in Search, Optimization and Machine Learning, Pearson Education, 2009. 4 George J.Klir and Bo Yuan, Fuzzy Sets and Fuzzy Logic: Theory and Applications,PHI, First Edition, 1995. 5. W.T.Miller, R.S.Sutton and P.J.Webrose, Neural Networks for Control, MIT Press, 1996. 6. C.Cortes and V.Vapnik, Support-Vector Networks, Machine Learning, 1995.

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L T P C CA SE TM

EIY07 VLSI Design 3 0 - 3 40 60 100

Prerequisite: Digital Logic Theory Design

Course Outcome

CO1 The student will gain foundational skill set in CMOS technology and logic implementation using CMOS.

CO2 The students will become knowledgeable about basics of VHDL language and VHDL levels of abstraction.

CO3 The students will gain knowledge about Working knowledge of VHDL programming using concurrent architecture

CO4 The students will learn about basics of VERILOG language and VERILOG levels of abstraction.

CO5 Student will get understanding of System implementation using VERILOG and test bench development.

UNIT – I REVIEW OF IC TECHNOLOGIES Hours: 9

Introduction to IC Technology Fabrication Process of MOSFETs - MOS, PMOS, NMOS, CMOS technologies- Design of CMOS inverter, pull ups, CMOS inverter analysis- design of CMOS logic gates using Microwind - Gate realization using CMOS- Hardware Description Languages- Introduction to Reconfigurable Hardware -FPGA and CPLD basics- Applications of VLSI.

UNIT – II INTRODUCTION TO VHDL Hours: 9

VHDL basics - VHDL levels of abstraction – Structural , Behavioral and dataflow modes of implementation- The VHDL design flow - VHDL design entities - Entity declarations - Architectures –Concurrent signal assignments - Signal assignments with delays – Signal and variable assignments -Sequential statements - VHDL processes - Process sensitivity lists - Conditional statements – loops – Examples.

UNIT – III SYSTEM IMPLEMENTATION USING VHDL Hours: 9

Component declarations - Component instantiation - named association – positional association – Packages: declaration and body. Test Bench development in VHDL - Simple Test Benches. Use of Procedures and functions - Modeling hardware in VHDL - VHDL models for multiplexers, Encoders, Decoders, Parity Generators – sequential circuit implementation - VHDL Synthesis.

UNIT – IV INTRODUCTION TO VERILOG Hours: 9

Introduction to VERILOG - Levels of Abstraction- Module description - Description of data types – Operators - Net – Register – scalar and vector data description - Dataflow and Behavioral Modeling –procedural statements- always and initial statements - conditional statements – loops - Examples

UNIT – V SYSTEM IMPLEMENTATION USING VERILOG Hours: 9

Structural design modeling - Test Bench Implementation – Implementation of combinational and sequential circuits in VERILOG - Examples – Logic Synthesis and physical implementation using VERILOG.

Total contact Hours: 45 Total Tutorials: - Total Practical Classes: - Total Hours: 45

Reference Books:

1. J. Bhasker ,VHDL Primer, Prentice Hall, 2006. 2. Bhasker,Verilog HDL Synthesis-A Practical Primer,Star Galaxy Publications,1998. 3. Chip Design for Submicron VLSI: CMOS Layout & Simulation, - John P.Uyemura, Thomson Learning. 4. Introduction to VLSI Circuits and Systems - John .P. Uyemura, JohnWiley,2003. 5. Digital Integrated Circuits - John M. Rabaey, PHI, EEE, 1997. 6. Modern VLSI Design - Wayne Wolf, Pearson Education, 3rd Edition, 1997

70




L T P C CA SE TM

EIY08 BIOMEDICAL INSTRUMENTATION 3 0 0 3 40 60 100

Prerequisite: Basic Electronics , Transducers & Measurements

Course Outcome

On successful completion of the course students will be able to:

CO1 Understand the importance of Physiology & identify challenges in its measurement

CO2 Acquire knowledge about the different biomedical system components.

CO3 Identify the process behind measurement of Physiological parameters as well to analyse and interpret data.

CO4 Understand the functioning of Imaging System, Telemetry and its role in multidisciplinary fields.

CO5 Usage of techniques and modern engineering tools for diagnostic and therapeutic requirements.

UNIT-I Basic Human Physiology Periods: 9

Cell Structure, Basic Cell functions, Sources of Biomedical signals, Physiology of Cardiovascular, Nervous system & Respiratory system. Special senses: Auditory & Vision System, Engineering Analogy of Physiological system, Challenges in measuring signals from living system

CO1

UNIT-II Basic Components Of Biomedical System Periods: 9

Bio potential electrodes, Electrode-electrolyte interface, Half-cell Potential, Electrodes-Micro, needle and surface electrodes. Various biomedical transducers. Bio-signal Amplifiers - Differential amplifiers, Chopper amplifiers, Notch Filters - Electrical Safety of Medical Equipment and Patients.

CO2

UNIT-III Measurement of Physiological Parameters Periods: 9

ECG – Einthoven triangle – 12 Lead ECG recording system – EEG – Types of brain waves - 10/20 EEG recording methods - EMG – Role of Actin & Myosin - Measurement of blood Pressure - Cardiac output - Heart sounds - Respiratory rate - Lung Volumes and Capacities – Pneumotachography, Total Body Plethysmography (BOD)

CO3

UNIT-IV Imaging System and Telemetry Periods: 9

Ultrasound scanner – X-Ray Imaging - CAT / CT scan – MRI Imaging – PET scan. Basic elements of a Biotelemetry system - Single / Multi channel Telemetry Systems – Implanted transmitters – Telemedicine.

CO4

UNIT-V Assisting and Therapeutic Equipment’s Periods: 9

Electrotherapy – Diathermy – Pacemakers - Defibrillators – Heart Lung Machine - Audiometry - Hearing aid – Dialysis Machine -Ventilators - Endoscopes.

CO5

Lecture Periods: 45 Tutorial Periods:- Practical Periods: - Total Periods: 45

Reference Books:

1. R. Anandanatarajan, “Biomedical Instrumentation and Measurements”, PHI Learning, 2011. 2. John Webster, “Medical Instrumentation: Application and Design”, 3rd Edition, Wiley Publishing, 2009. 3. Leslie Cromwell, Fred. J. Weibell, “Biomedical Instrumentation and Measurements”, 2nd Edition, PHI, 2003.

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L T P C CA SE TM

EIY09 Instrumentation System Design 3 0 0 3 40 60 100

Prerequisite: Sensor and Transducer

Course Outcome

CO1 Capable of Design and developing the Instrumentation design to cater the industrial requirements

CO2 The students will become knowledgeable about the design of sensor and gripper.

CO3 The students will gain manipulator dynamics of robots

CO4 Develop the concept into a model, analyze the model on computer using engineering software packages

CO5 Student will get understanding of Robotic applications also to Develop an engineering report and demonstrate the robot’s performance

UNIT-I Design of Signal Conditioning Circuits Periods: 9

Design of V/I Converter and I/V Converter- Analog and Digital Filter design – Signal conditioning circuit for pH measurement –Compensation circuit - Signal conditioning circuit for Temperature measurement - Cold Junction Compensation – Thermocouple Linearization – Software and Hardware approaches

CO1

UNIT-II Design of Transmitters Periods: 9

Design of Temperature Transmitters – using RTD, Thermocouple - Design of Capacitance based Level Transmitter – Air-purge Level Measurement – Design of Smart Flow Transmitters

CO2

UNIT-III Design of Data Logger and Controller Periods: 9

Design of Electronic Controllers: ON / OFF and PID Controller – Microcontroller Based Digital PID Controller and Data Logger – Design of PC based Data Acquisition Cards

CO3

UNIT-IV Flow meters and Control Valve Sizing Periods: 9

Orifice Sizing and design: - Liquid, Gas and steam services - Rotameter Design. Control Valves – types – Valve body:- Commercial valve bodies – Control valve sizing – Liquid, Gas and steam Services – Cavitation and flashing –Selection criteria.

CO4

UNIT-V Design of Alarm and Annunciation Circuit Periods: 9

Alarm: Fire alarm circuit, Fire alarm control panel- annunciator control panel. Alarm and Annunciation circuits using Analog and Digital Circuits – Design Alarm and annunciator circuits using Relays and Programmable Logic Controller.

CO5

Lecture Periods: 45 Tutorial Periods: - Practical Periods: - Total Periods: 45

Reference Books:

1. C. D. Johnson, “Process Control Instrumentation Technology”, 8th Edition, Prentice Hall, 2006. 2. Control Valve Handbook, 4th Edition, Emerson Process Management, Fisher Controls International, 2005. 3. R.W. Miller, “Flow Measurement Engineering Handbook”, Mc-Graw Hill, New York, 1996.

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L T P C CA SE TM

EIY10 DIGITAL IMAGE PROCESSING 3 0 0 3 40 60 100

Prerequisite:

Course Outcome

On successful completion of the course students will be able to:

CO1 Interpret about the elements of digital image processing

CO2 Illustrate various methodology for smoothening and sharpening of the image.

CO3 Explore the image segmentation using edge detection, thresholding and region-based approach

CO4 Explore the image compression using lossy and lossless compression techniques.

CO5 Discuss the methods for used for image representation


Elements of Digital Image processing – Elements of visual perception: light - luminance – brightness, contrast, hue, saturation – Mach band effect – simultaneous contrast. Colour image fundamentals – RGB model and HIS model – converting colours from HIS to RGB.

CO1

UNIT-II Image Enhancement Periods: 9

Image enhancement - Point operations - contrast stretching - clipping and thresholding - digital negative intensity level slicing - bit extraction. Histogram processing - histogram equalisation -modification. Spatial operations – smoothing spatial filters, sharpening spatial filters. Transform operations. Colour image enhancement.

CO2

UNIT-III Image Segmentation Periods: 9

Point, line and edge detection –Image segmentation based on thresholding-the role of Illumination-Basic global thresholding-Optimal global and adaptive thresholding-use of boundary characteristics for histogram improvement and local thresholding– Region based segmentation – region growing – region splitting and merging.

CO3

UNIT-IV Image Compression Periods: 9

Image Compression – Need for data compression – Run length encoding – Huffman coding – Arithmetic coding – predictive coding- transform based compression, Image compression standards – JPEG 2000, MPEG 4.

CO4

UNIT-V Image Representation Periods: 9

Representation: chain codes – polynomial approximations – signatures –boundary segment-skeletons– boundary descriptors: shape numbers – Regional descriptors: topological descriptors CO5

Lecture Periods: 45 Tutorial Periods: - Practical Periods: - Total Periods:45

Reference Books:

1. Gonzalez, Rafel C. and Woods, Richard E, “Digital Image Processing”, Second Edition, Prentice Hall, New York, 2006.

2. Anil K.Jain, “Fundamentals of Digital Image Processing”, Pearson Education 2013. 3. K.P.Soman and R.Ramanathan, “Digital Signal and Image Processing”, ISA publishers, Amrita University,

Coimbatore, 2012. 4. NPTEL Course, Digital Image Processing by Prof. P.K. Biswas, IIT Kharagpur.

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L T P C CA SE TM

EIY11 DESIGN OF PROCESS CONTROL SYSTEM COMPONENTS

3 0 0 3 40 60 100

Prerequisite:

Course Outcome

CO1 The student gain the knowledge about design of signal conditioning circuits required for selected sensors.

CO2 The students will become knowledgeable about electronic PID controller design

CO3 The students will gain knowledge about flow measuring and design

CO4 To familiarize the student with the methods of selecting control valve and design the required sizing of control valve given flow condition

CO5 Student will get understanding of alarm and interlock design

UNIT-I DESIGN OF SIGNAL CONDITIONING CIRCUITS Periods: 9

Design of V/I Converter and I/V Converter - Signal conditioning circuit for Thermocouple and RTD- Cold Junction Compensation circuit for thermocouple using RTD - Transmitters – Design of RTD based Temperature Transmitter, Thermocouple based Temperature Transmitter -zero and span adjustment in and temperature transmitters.

CO1

UNIT-II AIR PURGE SYSTEM AND PID CONTROLLER DESIGN Periods: 9

Bourdon gauges - factors affecting sensitivity - design aspect 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.

CO2

UNIT-III DESIGN OF FLOW METER Periods: 9

Orifice meter - design of orifice for given flow condition - Liquid, Gas and steam services- rotameter-design of rotameter for the given flow condition-zero and span adjustment in differential pressure transmitter.

CO3

UNIT-IV CONTROL VALVE SIZING Periods: 9

Control valves - characteristics of control valves - types of valve bodies - valve characteristics - materials for body and trim - sizing of control valves - cavitations, flashing in control valves- selection of body materials and characteristics of control valves for typical applications

CO4

UNIT-V DESIGN OF ALARM AND ANNUNCIATION CIRCUIT Periods: 9

Interlocks and alarms: Interlock design principles, fail-safe design - alarms and their types. Design of logic circuits for alarm and annunciator circuits, interlocks design.

CO5


Reference Books:

1. N.A.Anderson, Instrumentation for Process Measurement and Control, Chilton Company, 1980. 2. D.M.Considine, Process Instruments and Controls Handbook,McGraw-Hill., 1985. 3. J.P.Bentley, Principles of Measurment Systems, Longman Inc., 1983. 4. C.D. Johnson, Process Control Instrumentation Technology, Prentice Hall of India, 1998. 5. Bela G. Liptak, “Instrument Engineers Handbook - Process Control and Optimization”, CRC Press, 4th Edition, Vol.2, 2008.

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L T P C CA SE TM

EIY12 Power Plant Instrumentation 3 0 0 3 40 60 100

Prerequisite: Industrial Instrumentation

Course Outcome

CO1 The student will gain knowledge about thermal power generation and also to familiarize the drawing of P&I diagrams of different power plant and various measurements involved in power plants.

CO2 The students will become knowledgeable about the combustion process and temperature control loops in thermal power plants to improve the efficiency

CO3 The students will gain knowledge about drum level, boiler draft and safety system for boiler .

CO4

To familiarize the student with the methods of monitoring different parameters like speed, vibration of turbines and their control along with flue gas analysis and trimming of gases to reduce emissions in order to sensitize students to the environmental impact of these systems.

CO5 Student will get understanding of nuclear power generation, radiation detector and various instruments used in nuclear power plant.


Piping and instrumentation diagram of a thermal power plant, basic process on a boiler, - measurement of non electrical parameters –flow of feed water, fuel, air and steam with correction factor for temperature, steam pressure and steam temperature , drum level measurement –water level gauge for boiler drums, closed circuit television instrument

CO1

UNIT-II Boiler Control-I Periods: 9

Boiler control objectives-combustion of fuels (gaseous liquid, and solid), excess air, combustion chemistry and products of combustion, requirement for excess combustion, air-circulation of efficiency of boiler: input/output method-stream temperature control systems super heaters and de-super heaters.

CO2

UNIT-III Boiler Control-II Periods: 9

Feed water supply and boiler water circulation system-drum level control systems-boiler draft systems-measurement and control of furnace draft-measurement and control of combustion-draft and air flow control related functions, control techniques and safety interlocks in boiler operation.

CO3

UNIT-IV Flue Gas Analysis Trimming of Combustion Control Systems

Periods: 9

Flue gas analysis and its importance, combustion control for liquid and gaseous fuel boilers coal or solid fuel strokes-combustion control for stoker-fired boilers- pulverised coal-fired boilers and trimming of combustion control systems. Turbine monitoring and control: speed, vibration, shell temperature monitoring, lubricant oil temperature control and cooling system.

CO4

UNIT-V Nuclear Power Plant Instrumentation Periods: 9

Piping and instrumentation diagram of different types of nuclear power plants--process sensors for nuclear power plants-spectrum analyzers-nuclear reactor control systems and allied instrumentation.

CO5


Reference Books:

1. B.G.Liptak, Instrumentation in process industries, Vol. I and II, Chilton books co, 1973. 2. Sam G. Dukelow. The control of boilers, Instrument Society of America press, 1991. 3. A.Sherryet. Al. (Editors), Modern power station practice, Vol.6 (Instrumentation controls and testing), Pergamon

Press, 1971 4. R.K.Jain, Mechanical and Industrial Measurements, Khanna publishers, New Delhi, 1995. 5. Elonka. S.M and Kohal. A.L., Standard Boiler Operations, Mc Graw Hill, New Delhi, 1994.

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L T P C CA SE TM

EIY13 Fibre Optics and Laser Instrumentation 3 0 - 3 40 60 100

Prerequisite:

Course Outcome

CO1 Students will be able to understand the concept of signal transfer through fibre

CO2 The students will be able to apply fibre optics for industrial applications

CO3 The students will understand the concept and properties of laser

CO4 The students will be able to apply laser for industrial applications

CO5 The students will be know how to apply for holography and medical application

UNIT – I Optical Fibres and Their Properties Hours: 9

Principles of light propagation through a fibre - Different types of fibres and their properties, fibre characteristics - Absorption losses - Scattering losses - Dispersion - Connectors & Splices - Optical Sources - Optical detectors.

CO1

UNIT – II Industrial Applications of Optical Fibres Hours: 9

Fibre Optic Sensors - Fibre Optic Instrumentation System – Electro optic, Acousto-optic and Travelling Wave Modulators - Interferometric Method of Measurement of Length – Moire fringes – Measurement of Pressure, Temperature, Current, Voltage, Liquid level and Strain.

CO2

UNIT – III Laser Fundamentals Hours: 9

Fundamental Characteristics of Lasers – Three level and Four level Lasers - Properties of Lasers - Laser Modes - Resonator Configuration – Q-Switching and Mode locking – Cavity dumping - Types of Lasers – Gas lasers, Solid lasers, Liquid lasers, Semiconductor lasers.

CO3

UNIT – IV Industrial Applications of Lasers Hours: 9

Laser for measurement of Distance, Length, Velocity, Acceleration, Current, Voltage and Atmospheric Effect - Material Processing - Laser heating, Welding, Melting and Trimming of Material - Removal and Vaporization.

CO4

UNIT – V Hologram and Medical Applications Hours: 9

Holography - Basic Principle - Methods - Holographic interferometry and applications, Holography for nondestructive testing - Medical Applications of Lasers, Lasers and Tissue interaction - Laser Instrumentations for surgery, Removal of Tumours of Vocal cords, Brain surgery, Plastic surgery.

CO5


Reference Books:

1. G.Keiser, Optical Fibre Communication, McGrawHill, 1995. 2. Ajoyghatak K.Thyagarajan, Optical Electronics, Cambrige University Press, 2009. 3. J.M.Senior, OFC – Principles and Practice,PH1,1985. 4. J.Wilson and J.F.Bhawkes, Introduction to Optical Electronics, PH1, 2001. 5. Dr.Manjeet Singh, Lasers – Theory, Principles and Applications, VEI, Vayn Education India, 2011. 6. Mr.Gupta, Fibre Optics Communication, PH1, 2004.

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L T P C CA SE TM

EIY14 MEMS 3 0 0 3 40 60 100

Prerequisite: Transducers and measurements

Course Outcome

CO1 Ability to understand the basic characteristics of MEMS sensors and materials operation of micro devices, micro systems and their applications

CO2 Able to understand the micromachining methodology such bulk, surface and LIGA

CO3 Able to design the MEMS sensors and actuators-I using basic concepts

CO4 Able to understand and design piezoresitive and piezo electric mems devices

CO5 Ability to design the optical MEMS devices and polymer mems devices

UNIT-I INTRODUCTION Periods: 9

Intrinsic Characteristics of MEMS – Energy Domains and Transducers- Sensors and Actuators – Introduction to Micro fabrication – Silicon based MEMS processes – New Materials – Review of Electrical and Mechanical concepts in MEMS – Semiconductor devices – Stress and strain analysis – Flexural beam bending- Torsional deflection.

CO1

UNIT-II MICROMACHINING Periods: 9

Bulk Micro Machining , Silicon Anisotropic Etching – Anisotrophic Wet Etching – Dry Etching of Silicon – Plasma Etching – Deep Reaction Ion Etching (DRIE) – Isotropic Wet Etching – Gas Phase Etchants – Case studies – Basic surface micro machining processes – Structural and Sacrificial Materials – Acceleration of sacrificial Etch – Striction and Antistriction methods – LIGA Process – Assembly of 3D MEMS – Foundry process.

CO2

UNIT-III SENSORS AND ACTUATORS-I Periods: 9

Electrostatic sensors – Parallel plate capacitors – Applications – Interdigitated Finger capacitor – Comb drive devices – Micro Grippers – Micro Motors – Thermal Sensing and Actuation – Thermal expansion – Thermal couples – Thermal resistors – Thermal Bimorph – Applications – Magnetic Actuators – Micromagnetic components – Case studies of MEMS in magnetic actuators- Actuation using Shape Memory Alloys.

CO3

UNIT-IV SENSORS AND ACTUATORS-II Periods: 9

Piezoresistive sensors – Piezoresistive sensor materials – Stress analysis of mechanical elements – Applications to Inertia, Pressure, Tactile and Flow sensors – Piezoelectric sensors and actuators – piezoelectric effects – piezoelectric materials – Applications to Inertia , Acoustic, Tactile and Flow sensors.

CO4

UNIT-V POLYMER AND OPTICAL MEMS Periods: 9

Polymers in MEMS– Polimide – SU-8 – Liquid Crystal Polymer (LCP) – PDMS – PMMA – Parylene – Fluorocarbon – Application to Acceleration, Pressure, Flow and Tactile sensors- Optical MEMS – Lenses and Mirrors – Actuators for Active Optical MEMS.

CO5


Reference Books:

1. Nadim Maluf,“ An Introduction to Micro Electro Mechanical System Design”, Artech House, 2000. 2. Mohamed Gad-el-Hak, editor, “ The MEMS Handbook”, CRC press Baco Raton, 2001. 3. Julian w. Gardner, Vijay K. Varadan, Osama O.Awadelkarim, Micro Sensors MEMS and Smart Devices, John Wiley

& Son LTD, 2002. 4. James J.Allen, Micro Electro Mechanical System Design, CRC Press Publisher, 2005. 5. Thomas M.Adams and Richard A.Layton, “Introduction MEMS, Fabrication and Application,” Springer, 2010.

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L T P C CA SE TM

EIY15 INSTRUMENTATION IN PETROCHEMICAL INDUSTRY

3 0 0 3 40 60 100

Prerequisite: Transducers and measurements

Course Outcome

CO1 Gain knowledge on oil gas production process and important unit operations in a refinery

CO2 Having gained the process knowledge, ability to develop and analyze mathematical model of selective processes.

CO3 Able to develop, analyze and select appropriate control strategy for selective unit operations in a refinery.

CO4 Gain knowledge on the most important chemical derivatives obtained from petroleum products.

CO5 Understand safety instrumentation followed in process industries

UNIT-I OIL EXTRACTION AND OIL GAS PRODUCTION Periods: 9

Techniques used for oil discovery – Oil recovery methods – oil rig system - Overview of oil gas production – oil gas separation – Gas treatment and compression – Control and safety systems

CO1

UNIT-II IMPORTANT UNIT OPERATIONS IN REFINERY Periods: 9

Distillation Column – Thermal cracking – Catalytic Cracking – Catalytic reforming – mathematical Modeling and selection of appropriate control strategy – Alkylation – Isomerization

CO2

UNIT-III DERIVATIVES FROM PETROLEUM Periods: 9

Derivatives from methane – Methanol Production – Acetylene production - Derivatives from acetylene –Derivatives from ethylene – Derivatives from propylene..

CO3

UNIT-IV IMPORTANT PETROLEUM PRODUCTS & MEASUREMENTS Periods: 9

BTX from Reformate – Styrene – Ethylene oxide/Ethylene glycol – polyethylene – Polypropylene – PVC production. Parameters to be measured in refinery and petrochemical industry – Selection and maintenance of measuring instruments.

CO4

UNIT-V SAFETY IN INSTRUMENTATION SYSTEMS Periods: 9

Hazardous zone classification – Electrical and Intrinsic safety – Explosion suppression and Deluge systems – Flame, fire and smoke detectors – leak detectors – Guidelines and standards – General SIS Design Configurations – Hazard and Risk Assessment – Failure modes – Operation and Maintenance.

CO5


Reference Books:

1. Waddams, A.L., “Chemicals from Petroleum”, Wiley, 1973. (digitized in 2007). 2. Balchen, J.G., and Mumme K.I., “Process Control Structures and Applications”, Von Nostrand Reinhold Company,

New York, 1988. 3. Liptak, B.G., “Instrumentation in Process Industries”, Chilton Book Company, 2005. (Digitizedin 2008.) 4. Austin, G.T. and Shreeves, A.G.T., “Chemical Process industries”, McGraw-Hill, 2012. 5. Havard Devold, “Oil and Gas Production Handbook”, ABB, 2006. 6. Paul Gruhn and Harry Cheddie, “Safety Instrumented Systems: Design, Analysis, and Justification”, 2nd Edition,

ISA Press, 2006.

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SYLLABI OF THE OPEN ELECTIVE COURSES

79


Semester : - Course Category Code: OEC Semester Exam Type:TY


L T P C CA SE TM

EIO01 Measurement and Instrumentation 3 0 0 3 40 60 100

Prerequisite:

Course Outcome

CO1 The student will gain conceptual understanding of measurements and instrumentation

CO2 The students will become knowledgeable about electrical and electronic measuring devices

CO3 The students will gain knowledge about signal generators and signal analyzers

CO4 The students will learn about oscilloscopes and data loggers and hence know how to rectify any error in such instruments

CO5 Student will get understanding of the evolving virtual instrumentation concepts and will be able to design their own program for computerized testing and measurement system

UNIT-I Introduction to Measurement Periods: 9

Elements of Generalized measurement system - Methods of measurement - Classification of instruments – Static & Dynamic characteristics of instruments - Mean, Standard deviation. Probability of errors - Types of error Accuracy, Precision, Sensitivity, Linearity, Resolution, Hysteresis, Threshold, Input impedance, loading effects

CO1

UNIT-II Electrical Measuring Instruments Periods: 9

Principle of operation and comparison of moving coil, moving iron meters, dynamometer, induction type & thermal type meter, rectifier type – Extension of range of voltmeter and ammeter. Principle of operation of electrodynamometer type wattmeter, induction type KWH meter – Calibration of wattmeter, energy meter. Power factor meter – Frequency meter.

CO2

UNIT-III Signal Generators and Analyzers Periods: 9

Sine wave generator – Frequency synthesized sine wave generator – Sweep frequency generator, pulse and square wave generator – Function generator – Wave analyzer –Applications – Harmonic distortion analyzer – Spectrum analyzer – Applications – Audio Frequency generator – Noise generator

CO3

UNIT-IV Cathode Ray Oscilloscope and Data Logging Periods: 9

General purpose oscilloscope – Screens for CRT graticules – Vertical & horizontal deflection systems – Delay line – Multiple trace – Dual beam & dual trace – Probes –Oscilloscope techniques – Special oscilloscopes – Storage oscilloscopes – Sampling oscilloscope. Data loggers.

CO4

UNIT-V Virtual Instrumentation Periods: 9

Historical perspective, advantages, blocks diagram and architecture of a virtual instrument, data-flow techniques, graphical programming in data flow, comparison with conventional programming. Development of Virtual Instrument using GUI. VI programming techniques: VIS and sub-VIS, loops and charts, arrays, clusters and graphs, case and sequence structures, formula nodes, local and global variables, string and file I/O, Instrument Drivers, Publishing measurement data in the web.

CO5


Reference Books:

1. E.W.Golding& F.C.Widdis, Electrical Measurements and Measuring Instruments, A.H.Wheeler & Co, 1994. 2. Albert D. Helfrick and William D. Cooper, Modern Electronic Instrumentation and Measurement Techniques,

Prentice Hall of India, 2002. 3. Jovitha Jerome, Virtual Instrumentation using LabVIEW, PHI Learning Pvt. Ltd., New Delhi, 2010 4. Patranabis, Principles of Electronic Instrumentation - PHI, 2008 5. Kalsi H.S, Electronic Instrumentation, 2nd edition, TMH, 2004. 6. Joseph.J.Carr, Elements of Electronic Instrumentation & Measurement, III edition, Pearson Education, 2003. 7. A.K.Sawhney, A course of in Electrical and Electronics measurement and instrumentation, Dhanpat Rai & sons,

2010. 8. Gary Johnson and Richard Jennings, LabVIEW Graphical Programming, McGraw Hill Inc., 2006

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Semester : -- Course Category Code: OEC Semester Exam Type:TY


L T P C CA SE TM

EIO02 Process Instrumentation 3 0 0 3 40 60 100

Course Outcome

CO1 The students will be able to understand the working of process control Systems

CO2 The students will to able to correlate instrumentation and its role in such industry by studying in detail about measurement system

CO3 The students will understand the role of instrumentation engineer by studying different instruments used in industries for temperature and pressure measurement

CO4 The students will understand the role of instrumentation engineer by studying different instruments used in industries for flow measurement

CO5 The students will understand the role of instrumentation engineer by studying different instruments used in industries for level measurement

UNIT-I Process Control Periods: 9

Process Characteristics Introduction to control aspects, their needs & application in industries, Classification of variables. Process Equation, Process variables, Degrees of freedom. Characteristics of liquid system, gas system, thermal system. Mathematical modelling of processes. Self regulating-Servo and Regulatory, control aspects of a chemical plant, stirred tank heater, flow in tank & their control aspects-– Inverse response. Process Control Elements: Signal conversion - I/P, P/I Converters, Pneumatic and Electric actuators, Valve Positioner-Control Valve – Characteristics of Control Valves-Types of control valves- Control valve sizing- cavitation and flashing.

CO1

UNIT-II Measurement System Periods: 9

Generalized scheme of measurement systems – Basic method of measurements –Errors in measurements – Types of Errors. Transducers – definition – classification – Static characteristics of instruments – Dynamic characteristic. Transmitter –definition – different types.

CO2

UNIT-III Temperature & Pressure Measurement Temperature measurements:

Periods: 9

Temperature measurements: Introduction – Temperature scale – Conventional methods of temperature sensing. Resistance Thermometer Detector (RTD)- Thermistors – Temperature sensing using thermistor – Semiconductor temperature sensor. Thermocouple –Basics of thermocouple – Thermocouple types – Cold junction compensation Pressure measurements: Introduction – Units of pressure – Types of pressure measurement – Bourdon tube and bellows – SG based pressure sensors –Capacitance type pressure transducers. Low pressure measurements.

CO3

UNIT-IV Flow Measurements Periods: 9

Basics of fluid flow – Flow meters – Quantum flow measurements, Differential pressure measurement – Principle of the differential pressure flowmeter, Orifice plate, Venturi meter, Flow nozzle, Dall tube, Pitot tube. Variable area flow meter – Electro Magnetic Flowmeter – Different type of ultrasonic Flowmeter.

CO4

UNIT-V Level Measurements Periods: 9

Level transducer with differential pressure sensing –Capacitance based level sensors – Capacitance sensors for conducting liquids –Capacitance sensors for Nonconducting liquids, other liquid sensors –Displacement type level sensor – Ultrasonic type level sensor – Gamma ray level sensor. pH measurements – Basic ideas of pH value – Measurement of electrode potentials.

CO5


Reference Books:

1. Tattamangalam R. Padmanaban , Industrial Instrumentation Principles and Design, Springer, 2000. 2. P. Harriott, Process Control, Tata McGraw Hill, 1984. 3. S. Renganathan, Transducer Engineering, Allied Publishers, 1999. 4. C. Stephanopoulos, Chemical Process Control, Prentice Hall of India, 1990. 5. Donald P. Eckman, Industrial Instrumentation, CBS Publishers, New Delhi, 2002. 6. C.D. Johnson, Process Control Instrumentation Technology, Prentice Hall of India, 1998.

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L T P C CA SE TM

EIO03 Principles of Medical Electronics 3 0 0 3 40 60 100

Course Outcome

CO1 Understand the basics of Electrophysiology

CO2 Understand the principle of Physiological parameters

CO3 Learn the working principle of Assist devices and Biotelemetry

CO4 Understand the principles of Medical imaging

CO5 Identify modern instruments used in Medical field

UNIT-I ELECTRO-PHYSIOLOGY AND BIO-POTENTIAL RECORDING Periods: 9

The origin of Bio-potentials; biopotential electrodes, biological amplifiers, ECG, EEG,EMG, PCG, EOG, lead systems and recording methods, typical waveforms and signalcharacteristics.

CO1

UNIT-II BIO-CHEMICAL AND NON ELECTRICAL PARAMETER Periods: 9

PH, PO2, PCO2, Electrophoresis, colorimeter, photometer, Auto analyzer, Blood flow meter, cardiac output, respiratory measurement, Blood pressure, temperature, pulse, Blood cell counters.

CO2

UNIT-III ASSIST DEVICES AND BIO-TELEMETRY Periods: 9

Cardiac pacemakers, DC Defibrillator, Haemodialysis - Telemetry principles, FM/FM Biotelemetry,radio-pill and tele-stimulation.

CO3

UNIT-IV MEDICAL IMAGING Periods: 9

Diagnostic x-ray equipments – Fluoroscopy - use of Radio Isotope in diagnosis, Ultrasound Scanner - CT scanner

CO4

UNIT-V RECENT TRENDS IN MEDICAL INSTRUMENTATION Periods: 9

Thermograph, endoscopy unit, Laser in medicine, Diathermy units, Electrical safety inmedical equipment CO5


Reference Books:

1. R.Ananda Natarajan, “Biomedical instrumentation and Measurements”, PHI Learning, 3rd edition 2019 2. J.G. Webster, Medical Instrumentation: Application and Design, John Wiley and Sons, New York, 2010 3. Leslie Cromwell, Biomedical Instrumentation and measurement, Tata McGraw Hill, 2007

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L T P C CA SE TM

EIO04 Microcontroller based system Design 3 0 0 3 40 60 100

Prerequisite: Microprocessor and Applications

Course Outcome

CO1 To introduce ARM Architecture and LPC2148 microcontroller

CO2 To study the LPC2148 Microcontroller Operation

CO3 To understand the Advanced Peripherals for LPC2148

CO4 To design the System Using LPC2148

CO5 To introduce Real time operating systems and its implications

UNIT-I Introduction to LPC2148 Microcontroller Periods: 9

Background of ARM Architecture – LPC2148 microcontroller introduction – Peripheral features - Bus Structure –Memory Map - Memory Accelerator Module – Boot Loader – In application programming – PLL and VLSI Bus Divider – Power Control - Software development using Embedded ‘C’ – Development Tools

CO1

UNIT-II LPC2148 Microcontroller Operation Periods: 9

General Purpose IO – Timer Operation – Prescalar – Timer Capture and Compare modes – PWM Modulator – Real Time Clock – Watch Dog Timer – Interrupt Structure – FIQ Interrupt – Vectored IRQ – Non–Vectored Interrupts –ISR.

CO2

UNIT-III LPC2148 Advanced Peripherals Periods: 9

UART operation – I2C operation – SPI Interface - Analog to Digital Converter – Digital to Analog Converter – CAN Controller – USB Interface.

CO3

UNIT-IV System Design Using LPC2148 Periods: 9

Design of Simple I/O systems using Switches, LEDs, Buzzers - Current source and sink concepts - Interfacing Character and Graphical LCD Displays – DC Motor Speed Control System – Speed Measurement – Design of Digital Frequency meter - Stepper Motor Interfacing – Relays – Keypads - Interfacing SD cards and touch screens–PC based Control systems

CO4

UNIT-V Real Time Operating Systems Periods: 9

Concept of Scheduling – Round Robin and Preemptive scheduling – Implementing a simple scheduler in ‘C’ - Task and Task States, tasks and data, semaphores and shared Data Operating system Services-Message queues- EventsMemory Management, Interrupt Routines in an RTOS environment, Implementing SD card – Graphical LCD system using RTOS

CO5


Reference Books:

1. David E Simon, An embedded software primer, Pearson education Asia, 2001. 2. Trevor Martin, The Insider's Guide to the Philips ARM7-Based Microcontrollers, Hitex Pubications(UK), 2005. 3. Michael J Pont, Patterns for Time-Triggered Embedded Systems, Addison-Wesley Professional,2001. 4. Burns, Alan and Wellings, Andy, Real-Time Systems and Programming Languages, Second Edition. Harlow: Addison-

Wesley-Longman, 1997. 5. Raymond J.A. Bhur and Donald L.Bialey, An Introduction to real time systems: Design to networking with C/C++ ,

Prentice Hall Inc. New Jersey, 1999. 6. Grehan Moore, and Cyliax, Real time Programming: A guide to 32 Bit Embedded Development. Reading , Addison-

Wesley-Longman, 1998. 7. Heath, Steve, Embedded Systems Design, Newnes, 1997. 8. John B Peat man, Design with Microcontroller, Pearson education Asia, 1998.

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L T P C CA SE TM

EIO05 Fundamental of MEMS 3 0 0 3 40 60 100

Prerequisite: Nil

Course Outcome

CO1 Ability to understand the basic characteristics of MEMS sensors and materials

CO2 Able to understand the micromachining methodology such bulk, surface and LIGA

CO3 Able to design the MEMS sensors and actuators-I using basic concepts

CO4 Able to understand and design piezoresitive and piezo electric mems devices

CO5 Ability to design the optical MEMS devices and polymer mems devices

UNIT-I Introduction to MEMS Periods: 9

Introduction to MEMS and Microsystems, Materials and Substrates for MEMS, Sensors/Transducers, Sensors characterization and classifications, microactuators, Application of MEMS.

CO1

UNIT-II Material Properties Periods: 9

MEMS materials, structural and sacrificial materials, properties of silicon, mechanical, electrical and thermal properties of materials, Basic modeling of elements in electrical and mechanical systems.

CO2

UNIT-III MEMS Fabrication Periods: 9

MEMS Fabrication Technologies, single crystal growth, micromaching, photolithography, microsterolithography, thin film deposition, impurity doping, diffusion, etching, bulk and surface micromaching, etch stop technique and microstructure, LIGA.

CO3

UNIT-IV Mechanical Sensors & Actuators Periods: 9

Stress and Strain, Hooke's Law. Stress and Strain of Beam Structures, Cantilever, Pressure sensors, Piezoresistance Effect, Piezoelectricity, Piezoresistive Sensor, capacitive sensors, Inductive sensors, MEMS inertial sensors, micromachined microaccelerometer for MEMS, Parallel-plate Actuator, piezoactuators.

CO4

UNIT-V Thermal Sensors: Periods: 9

Temperature coefficient of resistance, Thermo-electricity, Thermocouples, Thermal and temperature sensors, heat pump, micromachined thermocouple probe, thermal flow sensors, shape memory allloy.

CO5


Reference Books:

1. R.S. Muller, Howe, Senturia and Smith, “Microsensors”, IEEE Press. 2. 2. S. M. Sze, Semiconductor Sensors, Willy –Interscience Publications 3. Nadim Maluf,“ An Introduction to Micro Electro Mechanical System Design”, Artech House, 2000.

Curriculum and Syllabi

Documents

Transcript of Curriculum and Syllabi