Vishwakarma Institute of Technology Issue 05 : Rev No. 1 : Dt. 30/03/15

Bansilal Ramnath Agarwal Charitable Trust’s

Vishwakarma Institute of Technology

(An Autonomous Institute affiliated to Savitribai Phule Pune University)

Structure & Syllabus of

B.Tech. (Instrumentation and Control Engineering)

Pattern ‘F-11_Revised’

Effective from Academic Year 2014-15

(S.Y. B.Tech. onwards)

Prepared by: - Board of Studies in Instrumentation& Control Engineering

Approved by:- Academic Board, Vishwakarma Institute of Technology, Pune

Signed by

Chairman – BOS Chairman – Academic Board

Content

Sr. No. / Title / Page No.
1 / Vision, Mission of Institute and Department / 4
2 / PEOs and POs / 5
3 / Course Structure / 6
4 / Course Syllabi for courses - Module V and VI / 6
5 / ‘Separator’ - Module V / 11
6 / Course Syllabi for courses - Module V / 12
6.1 / Theory Courses:
6.1a / IC30105 / Control System Components / 12
6.1b / IC31101 / Electronic Instrument and System Design / 14
6.1c / IC30103 / Microcontroller Based Systems / 16
6.1d / IC30107 / Digital Signal Processing / 18
6.1e / IC31107 / Unit Operations / 20
6.2 / Tutorial Courses:
6.2a / IC30205 / Control System Components / 21
6.2b / IC31201 / Electronic Instrument and System Design / 22
6.3 / Laboratory Courses:
6.3a / IC30305 / Control System Components Electronic Instrument and System Design / 23
6.3b / IC30307 / Microcontroller Based Systems / 24
6.3c / IC30309 / Digital Signal Processing / 25
6.4 / Professional Development Courses:
6.4a / IC33301 / Calibration and Standards / 26
6.4b / IC33311 / Graphical User Interface for Embedded Systems / 27
6.5 / IC30401 / Comprehensive Viva Voce / 28
6.6 / IC37301 / Seminar / 29
6.7 / IC37401 / Mini project / 30
7 / ‘Separator’- Module VI / 31
8 / Course Syllabi for courses - Module VI / 31
8 / Theory Courses:
8.1a / IC30102 / Process Loop Components / 31
8.1b / IC30110 / Industrial Automation / 34
8.1c / IC30106 / Biomedical Instrumentation / 36
8.1d / IC30108 / Modern Control Theory / 38
8.1e / IC31108 / Analytical Instrumentation / 40
8.2 / Tutorial Courses:
8.2a / IC30206IC30206 / Industrial Automation / 41
8.2b / IC30208 / Modern Control Theory / 43
8.3 / Laboratory Courses:
8.3a / IC30306 / Biomedical Instrumentation and Analytical Instrumentation / 44
8.3b / IC30310 / Industrial Automation / 45
8.3c / IC30308 / Process Loop Components / 47
8.4 / Professional Development Courses:
8.4a / IC33309 / Image Processing with Matlab / 48
8.4c / IC33319 / Water Engineering / 49
8.5 / IC30402 / Comprehensive Viva Voce / 50
8.6 / IC37302 / Project Stage - I / 51

Vision statement of Institute

To be globally acclaimed Institute in Technical Education and Research for holistic Socio-economic development

Mission statement of Institute

  • To impart knowledge and skill based Education in collaboration with Industry, Academia and Research Organization
  • To strengthen global collaboration for Students, Faculty Exchange and joint Research
  • To prepare competent Engineers with the spirit of Entrepreneurship
  • To Inculcate and Strength Research Aptitude amongst the Students and Faculty

Vision statement of Department

To be recognized as leading contributor in imparting technical education and research in Instrumentation & Control engineering and allied areas for development of the society.

Mission statement of Department

  • To deliver knowledge of Instrumentation and Control and allied areas by strengthening involvement of R&D institutions and industries in academics
  • To build conducive environment for advanced learning through participation of faculty and students in collaborative research, consultancy projects, student exchange programs and internships
  • To develop professionals for the benefit of society

Program Educational Objectives (PEO)

Programme : B. Tech. (Instrumentation and Control Engineering)

To develop graduates with

  1. Core competency in Instrumentation and Control to cater the industry and research needs.
  2. Multi-disciplinary skills, team spirit and leadership qualities with professional ethics to excel in professional career and/or higher studies.
  3. Preparedness to learn and apply contemporary technologies for addressing impending challenges for the benefit of organization/society.
  4. Knowledge of recommended guidelines/practices to design and implement the automation solutions considering its impact on global, economic and environmental context.

Programme Outcomes (PO)

Graduates shall have the ability to:

  1. Apply knowledge of mathematics, science and engineering fundamentals to instrumentation and control discipline. (GA1)
  2. Select suitable sensors/Process components/Electronic components for building complete automation system. (GA1,3)
  3. Analyze real-world engineering problems using fundamental concepts in Instrumentation and Control. (GA2)
  4. Conceptualize Design and Develop measurement/electronic/embedded and control system with computational algorithms to provide practical solutions to multidisciplinary engineering problems. (GA3)
  5. Identify and investigate complex engineering processes in the domain of Instrumentation and Control. (GA4)
  6. Use contemporary engineering technology to device a complete instrumentation and control system. (GA5)
  7. Demonstrate ability to address potential hazards associated with industrial equipments and processes considering safety standards. (GA6,7)
  8. Propose sustainable optimized solutions for addressing environmental and social issues. (GA 6,7)
  9. Demonstrate capabilities required for effectively leading / performing in multi-disciplinary teams with professional ethics. (GA8,9)
  10. Exhibit proficiency in oral/ written communication / soft-skills for preparing project proposals and other technical documents. (GA10)
  11. Understand and execute the life cycle of typical Instrumentation and control project and its financial budgetary aspects. (GA11)
  12. Develop necessary competencies for establishing as a professional and realize the need for continuous enrichment of knowledge. (GA12)

Structure and syllabus of T.Y. B.Tech. Instrumentation Engineering. Pattern F11-Revised, A.Y. 2015-16 Page No. 1 out of 51

Vishwakarma Institute of Technology Issue 05 : Rev No. 1 : Dt. 30/03/15

Bansilal Ramnath Agarwal Charitable Trust’s

VISHWAKARMA INSTITUTE OF TECHNOLOGY – PUNE

(An autonomous Institute affiliated to University of Pune)

666, Upper Indiranagar, Bibwewadi, Pune – 411 037.

FF No. 653Issue 05 : Rev No. 0 : Dt. 22/11/14

T.Y. B.Tech - Instrumentation and Control Engineering Structure Pattern F-11_Revised

Module 5

Code / Sub / Type / Subject / Teaching Scheme / Assessment Scheme / Credits
L / P / Tut. / ISA / ESA
Test 1 / Test 2 / HA / Tut. / CA / ESE
IC30105 / S1 / Theory core / Control System Components / 3 / - / 1 / 10 / 20 / 5 / 5 / - / 60 / 4
IC31101 / S2 / Theory core / Electronic Instrument and System Design / 3 / - / 1 / 10 / 20 / 5 / 5 / - / 60 / 4
IC30103 / S3 / Theory core / Microcontroller Based Systems / 3 / - / - / 15 / 20 / 5 / - / - / 60 / 3
IC30107 / S4 / Theory core / Digital Signal Processing / 3 / - / - / 15 / 20 / 5 / - / - / 60 / 3
IC31107 / S5 / Theory MD / Unit Operations / 2 / - / - / 15 / 20 / 5 / - / - / 60 / 2
IC30305 / Lab 1 / Lab Core / Control System Components Electronic Instrument and System Design / - / 2 / - / - / - / - / 70 / 30 / 1
IC30307 / Lab 2 / Lab Core / Microcontroller Based Systems / - / 2 / - / - / - / - / 70 / 30 / 1
IC30309 / Lab 3 / Lab Core / Digital Signal Processing / - / 2 / - / - / - / - / 70 / 30 / 1
IC33301 / Lab-4 / Lab-PD / Calibration and standards / - / 2 / - / - / - / - / 70 / 30 / 1
IC33311 / Graphical User Interface for Embedded Systems
IC30401 / CVV / oral / Comprehensive Viva Voce / - / - / - / - / - / - / - / - / 100 / 2
TOTAL / 14 / 8 / 2 / 22


Bansilal Ramnath Agarwal Charitable Trust’s

VISHWAKARMA INSTITUTE OF TECHNOLOGY – PUNE

(An autonomous Institute affiliated to University of Pune)

666, Upper Indiranagar, Bibwewadi, Pune – 411 037.

FF No. 653Issue 05 : Rev No. 0 : Dt. 22/11/14

T.Y. B.Tech - Instrumentation and Control Engineering Structure Pattern F-11_Revised

Module 6

Code / Sub / Type / Subject / Teaching Scheme / Assessment Scheme / Credits
L / P / Tut. / ISA / ESA
Test 1 / Test 2 / HA / Tut. / CA / ESE
IC30102 / S1 / Theory core / Process Loop Components / 3 / - / - / 15 / 20 / 5 / - / - / 60 / 3
IC30110 / S2 / Theory core / Industrial Automation / 3 / - / 1 / 10 / 20 / 5 / 5 / - / 60 / 4
IC30106 / S3 / Theory core / Biomedical Instrumentation / 3 / - / - / 15 / 20 / 5 / - / - / 60 / 3
IC30108 / S4 / Theory core / Modern Control Theory / 3 / - / 1 / 10 / 20 / 5 / 5 / - / 60 / 4
IC31108 / S5 / Theory MD / Analytical Instrumentation / 2 / - / - / 15 / 20 / 5 / - / - / 60 / 2
IC30306 / Lab 1 / Lab core / Biomedical Instrumentation & Analytical Instrumentation / - / 2 / - / - / - / - / 70 / 30 / 1
IC30310 / Lab 2 / Lab Core / Industrial Automation / - / 2 / - / - / - / - / 70 / 30 / 1
IC30308 / Lab 3 / Lab Core / Process Loop Components / - / 2 / - / - / - / - / 70 / 30 / 1
IC33309 / Lab 4 / Lab-PD / Image Processing with MATLAB / - / 2 / - / - / - / - / 70 / 30 / 1
IC33319 / Water Engineering
IC30402 / CVV / oral / Comprehensive Viva Voce / - / - / - / - / - / - / - / - / 100 / 2
TOTAL / 14 / 8 / 2 / 22

Bansilal Ramnath Agarwal Charitable Trust’s

VISHWAKARMA INSTITUTE OF TECHNOLOGY – PUNE

(An autonomous Institute affiliated to University of Pune)

666, Upper Indiranagar, Bibwewadi, Pune – 411 037.

FF No. 653Issue 05 : Rev No. 0 : Dt. 22/11/14

T.Y. B.Tech - Instrumentation and Control Engineering Structure Pattern F-11_Revised

Semester I – Irrespective of Module

Code / Sub
Type / Subject / Teaching Scheme / Assessment Scheme / Credits
L / P / Tut. / ISA / ESA
Test 1 / Test 2 / HA / Tut. / CA / ESE
IC37301 / Seminar / Seminar / - / 4 / - / - / - / - / - / 70 / 30 / 2
IC37401 / Mini Project / Project / - / 4 / - / - / - / - / - / 70 / 30 / 2
TOTAL / - / 8 / - / 4

T.Y. B.Tech - Instrumentation and Control Engineering Structure Pattern F-11_Revised

Semester II – Irrespective of Module

Code / Sub
Type / Subject / Teaching Scheme / Assessment Scheme / Credits
L / P / Tut. / ISA / ESA
Test 1 / Test 2 / HA / Tut. / CA / ESE
IC37302 / Major Project / Project-Stage-I / - / 4 / - / - / - / - / - / 70 / 30 / 2
TOTAL / - / 4 / - / 2

Structure and syllabus of T.Y. B.Tech. Instrumentation Engineering. Pattern F11-Revised, A.Y. 2015-16 Page No. 1 out of 51

Vishwakarma Institute of Technology Issue 05 : Rev No. 1 : Dt. 30/03/15

FF No. : 654A

IC30105 :: CONTROL SYSTEM COMPONENTS
Credits: 03 / Teaching Scheme: Theory 3 Hours/Week
Unit 1: Industrial Control Devices / (8+1Hours)
PartA: Switches:construction, symbolic representation, working, application of toggle switch, slide switch, DIP switch, rotary switch, thumbwheel switch, selector switch, push button, limit switch, emergency switch, micro-switches, review of process switches, switch specifications.
Relays:construction, working, specifications, terminologies and applications of Electro-mechanical relay, hermetically sealed relay, timing relay.
Contactors:construction, working, specifications and applications of contactors. Comparison between relay and contactor.
Development of wiring diagram for given application using above components.
PartB:construction and working ofrocker,drum switch,specifications of process switches, reed relay, solid-state relays, problems on development of wiring diagram.
Unit 2: Special Purpose Motors / (8+1Hours)
PartA: Stepper motor:principle, types, terminologies, half-stepping and micro-stepping techniques, characteristics, specifications, applications.
Servomotors:construction, working, features, advantages, disadvantages, characteristics of AC and DC servomotor, comparison with stepper motor. AC and DC position and speed control.Synchros for error detector, position measurement and control.
DC Micro motors: types, construction, working, characteristics and applications.
PartB: Stepper motor control circuits, Stepper motor interface with micro-controller.
Unit 3: Motor control circuits / (8+1 Hours)
PartA: Electrical wiring diagram: Standard symbols used for electrical wiring diagram, sequencing and interlocking for motors, wiring diagrams in relation to motors like starting, stopping, reversing direction of rotation, emergency shutdown, (direct on line, star delta),braking, starting with variable speeds, jogging / inching, Motor Control Center: concept and wiring diagram.
Mechanical components : springs (compression, extension, torsion, flat, leaf and motor spring), gears (spur, bevel, gear trains).
PartB: Protection of motors:short circuit protection, over load protection, low / under voltage protection, phase reversal protection, over temperature protection.
Unit 4: Hydraulic Components / (8+1Hours)
PartA: Hydraulics: principle, block diagram, advantages, disadvantages, applications, hydraulic fluiddesirable properties, Types of hydraulic oil and its selection.
Hydraulic components: hydraulic power pack, hydraulic pumps, actuators and valves.
Hydraulic circuits: Development of hydraulic circuits using standard symbols, hydraulic circuits like meter in, meter out, reciprocating, speed control, sequencing of cylinders, direction control, deceleration, regenerative circuit, etc. troubleshooting in hydraulic circuits. Introduction to circuit design.
PartB: hydraulic components likefilters, piping, heat exchangers and motors.
Unit 5: Pneumatic Components / (8+1 Hours)
PartA: Pneumatics: principle, block diagram, advantages, disadvantages, applications.
Pneumatic components: pneumatic power Supply, types of pneumatic relay, FRL unit, pneumatic actuator (cylinders and air motors), pneumatic valves,
Pneumatic circuits:development of pneumatic circuits using standard symbols,sequence diagram (step-displacement) for implementing pneumatic circuits,different pneumatic circuits like reciprocating, sequencing, block transfer, speed regulation, job sorting, electro-pneumatic circuits, etc.
PartB: Fluidic elements and its applications, development of pneumatic circuits, troubleshooting in pneumatic circuits.
Text Books
  1. Majumdar, “Pneumatic Systems: Principles and Maintenance”, TMH Publications.
2. F. D. Petruzella “Industrial Electronics”, , Glancor Publications.
3. B. L. Theraja, “Electrical Technology”, S. Chand and Company.
Reference Books
1. C. T. Kilian, “Modern Control Technology: Components & Systems”, Thomson
Learning Publications.
2. “Industrial Hydraulic Technology Parker Motion & Control, Training Department.
3. Festo Controls, “Fundamentals of Pneumatic Control Engineering”, Banglore.

Course Outcomes:

The students will be able to:

  1. Explain the working of electrical, mechanical, hydraulic and pneumatic components.
  2. Develop electrical wiring diagrams, hydraulic and pneumatic circuits for given application.
  3. Select and size the electrical, mechanical, hydraulic and pneumatic components to solve a problem.
  4. Identify, formulate and solve a problem using electrical, mechanical, hydraulic and pneumatic system
    FF No. : 654A

IC31101:: ELECTRONIC INSTRUMENTATION AND SYSTEM DESIGN
Credits: 03 / Teaching Scheme: - Theory 3 Hours/Week
Unit 1: Electromagnetic interference and minimization techniques / (8+1 Hours)
PartA.Introduction to EMI and EMC. Classification of noises in electronic systems. Noise coupling mechanisms, noise minimization techniques. Types of grounds and grounding techniques. Line filters. Electrostatic discharge (ESD), ESD coupling mechanism, effects of ESD on an electronic system. Protection of hardware and software.
from ESD.
PartB.Shielding materials and shielded cables.
Unit 2: Instrument testing & reliability / (8+1 Hours)
PartA. Various types of testing such as testing against EMI/EMC, environmental and mechanical Testing. Manufacturing cycle. Reliability concepts, bath tub curve, MTTF, MTBF etc., quality and reliability. Causes of failures. Availability and maintainability. Redundancy and redundant systems.
PartB. Problems on reliability.
Unit 3: Hardware and Software Techniques / (8+1 Hours)
PartA. Printed circuit board design guideline, layout scheme, grid systems, PCB size, Design rules for digital ckts, Design rules for analog circuits, single and multilayer PCB. Automation in PCB design artwork CAD package, Soldering techniques and component assembly techniques.
PartB.Object oriented design, software design methodology, Entity relationship diagram, Introduction to Virtual Instrumentation and Labview
Unit 4: Electronic Instruments for waveform generation, display & analysis / (8+1Hours)
PartA. Waveform generation methods. Function generators. Digital to analog and analog to digital converters. Digital multimeters, errors in DMM. Timer, Universal counter, Digital storage oscilloscopes (DSO), block schematic, sampling techniques, memory considerations, operating modes, specifications and applications. Operating principles, working and applications of spectrum analyzers, Distortion meter.
PartB. Comparison of DSO with analog oscilloscope and applications of DSO.Study of Logic Analyzer, Wave Analyzer, LCR meter.
Unit 5: Case Studies / (8+1 Hours)
PartA. This can contain study or some practical case studies regarding Electronic design or design aspects in some particular domain. e.g.
Designing radio frequency amplifier system:Differences in design consideration from LF to RF system with stress on PCBdesign, front-end RF preamplifier, mixer, impedance matching and insertion lossconcepts, neutralization and stability, detail design of IF amplifier and detectorstage, monolithic IC’s on mixer, IF amplifier ,detector with AGC.
ORState machines:State machines, Moore and Mealy Models, state diagram, ASM chartsimplementation of next state decoder, output decoder using MSI, LSI devices like
multiplexers decoders, PLDs, fuse map generation, steps in design using PLDs,assignment based on real life problems like traffic light control, elevator, drinkvending machine, design using HDL.
B.Features and applications of a virtual instrument (LabView).
Text Books
1. Nakra-Chaudhary, “Instrumentation Measurement and Analysis”, Tata McGraw Hill
Publications.
2. D. Patranabis, “Principles of Industrial Instrumentation”, Tata McGraw Hill Publications.
3. A. K. Sawhney, “Electrical and Electronic Measurements and Instrumentation”, Dhanpat Rai and Sons Publications.
4. R. K. Jain, “Mechanical and Industrial Measurement”, Khanna Publications.
5. E Balagurusamy, “Reliability engineering”, Tata McGraw Hill.
Reference Books
1. Andrew, Williams, “Applied Instrumentation in Process Industries”, Gulf Publications
Company.
2. E. O. Doebelin, “Measurement System Application and Design”, McGraw-Hill International Publications.
3. H. Ott, “Noise Reduction Techniques in Electronic System”, John Wiley & Sons.
Course Outcome:
The student will be able to:
  1. Articulate design considerations for instrumentation systems
  2. Understand the error in instrumentation systems associated with noise and effective noise minimization technique
  3. Understand the basic concepts of systems reliability
  4. Apply electronic instruments like DSO, Counters, Distortion meter, Spectrum Analyzer for testing the instruments
  5. Infer different instruments with design considerations.

FF No. : 654A

IC30103 :: MICROCONTROLLER BASED SYSTEMS
Credits: 03 / Teaching Scheme: - Theory 3 Hours/Week
Introduction to microcontrollers (MCS51 family) / (7+2Hours)
Part A.Overview and features, On chip and external memory map, Memory interfacing conceptsPort Structure, I/O interfacing concepts, I/O expansion Instruction Set Reset Circuit and Timing Details.
Part B. Programming Technique for MCS 51, Writing loops and Subroutines. Programming using ‘C’ cross compiler.
Unit 2: Architecture Details of MCS-51 / (7+2Hours)
Part A. Interrupt Structure, Timers and Counters, Generating Software and Hardware delays, Serial communication, Power down and Idle mode.
PartB. Writing programs for interrupts, timers, counters, generating delays, serial communication.
Unit 3: Interfacing of devices to MCS-51 / (7+2Hours)
Part A. Interfacing of Displays - LED (multiplexed and non-multiplexed)LCD.
Interfacing of keyboards - Matrix type, Micro switches, Thumbwheel, Interfacing of ADC and DAC, Relay Interface, Stepper motor interface, etc.
PartB. Writing programs for interfacing circuits.
Unit 4: Interfacing of devices to 89C51 / (8+1Hours)
Part A. Interfacing of serial devices to 89C51 - Serial ADC, Serial EPROM, Interfacing of RTC, RS 232 and RS 485 interface, System Development using MCS-51.
Part B. System development, writing the programs for the system.
Unit 5: 8086 Microcontroller / (8+1Hours)
PartA.8086 Micro Processor - Architecture, Minimum and Maximum modes of operation, Interfacing Memories with timing diagrams, Memory mapped memory, I/O mapped memory, Instruction set, Programming 8086.
Part B. Instruction set and programming of 8086.
Text Books
  1. M.Mazidi, “8051 Microcontroller and embedded systems”, Pearson Higher Education.
  2. Kenneth J. Ayala, “The 8051 microcontroller”, Penram International.
  3. Douglas Hall, “8086 Micro Processor and Interfacing”, Tata McGraw Hill Publishing Company Ltd.

Reference Books
  1. Myke Predko, “Programming and customizing the 8051 microcontroller”, Tata McGraw Hill Publishing Company Ltd.
  2. A.V. Deshmukh“Microcontroller Theory and Applications”, , Tata McGraw Hill Publishing Company Ltd.

Course Outcomes:

The student will be able to

  1. Select a microcontroller and other peripheral devices for given application
  2. Develop an algorithm for given application
  3. Interface various components to microcontroller
  4. Write a program in assembly language for given application for Microcontroller Microprocessor
  5. Write a program in assembly language for given application for Microprocessor

FF No. : 654A

IC30107:: DIGITAL SIGNAL PROCESSING
Credits: 03 / Teaching Scheme: Theory 3 Hours/Week

Unit 1:Linear systems(6+2 Hours)

PartA. Review of CT and DT Signals,Discrete Systems: Interconnections of Systems; Basic System Properties (Causality, Stability, Time-Invariance, Linearity, and Inevitability, systems with and without memory). Representation of Discrete Time Signals in Terms of impulse, Convolution

Sum, Properties of LTI Systems (Commutative, Distributive, Associative properties, Inevitability, Causality, Stability).

PartB. Time Shift and Time scaling operations on Discrete Time Signal

Unit 2: Fourier Transform (6+2 Hours)

PartA. Fourier series, convergence of Fourier series. CT Fourier transform, properties of CT Fourier transform, DT Fourier transform, properties of DT Fourier transform, system function and its analysis using CTFT and DTFT. Review of Z Transform, Relation of Z transform with Fourier transform. System function and its analysis using Z transform.

PartB. Computation of system function and analysis using Fourier transform. Sampling and

its significance with system analysis.

Unit 3: Discrete Fourier Transform and Fast Fourier Transform (7+1 Hours)

PartA. Discrete Fourier Transform and its inverse, Relationship between the DTFT and the DFT and their inverses, Discrete Fourier Transform properties, Computation of the DFT of real sequences, DFT as Linear Transformation

Fast Fourier Transform

(a) Decimation in time – Radix 2 FFT algorithm, butterfly structure for 8 point DFT, Computational advantages, Radix 2 Inverse FFT algorithm.