scheme & syllabus for v and vi semesters b.e...

Scheme & Syllabus for V and VI semesters

B.E. – Instrumentation Technology

2015-16

V Semester

Course

Code

Course Title L T P C

IT501 Microcontrollers 3 1 0 4

IT502 Digital Signal Processing 3 1 0 4

IT503 Biomedical Instrumentation 4 0 0 4

IT504 Control systems 3 1 0 4

IT505 Data Converters and virtual Instrumentation 4 0 0 4

IT506 Process Instrumentation-II 3 0 0 3

IT507 Microprocessor lab 0 0 3 1.5

IT508 Control systems lab 0 0 3 1.5

HS005 Constitution of India and Professional Ethics(Audit

Course)

2 0 0 0

Total Credits 26

VI Semester

Course

Code

Course Title L T P C

IT601 Analytical Instrumentation 4 0 0 4

IT602 Embedded System Design 3 1 0 4

IT603 Process control 3 1 0 4

IT604 Advanced Control Systems 4 0 0 4

IT605 Microcontroller Lab 0 0 3 1.5

IT606 Data Acquisition and Virtual Instrumentation lab 0 0 3 1.5

IT607 Mini Project (Self Learning Component) 0 0 3 1.5

IT6XX

IT6XX

Elective I

Elective II

3

3

-

-

0

0

3

3

HS004 Communication Skill-2 (Summer Term Course) 0 0 2 1

HS006 Environmental Science(Audit Course) 0 0 2 0

Total Credits 27.5

Electives:

IT651-Computer Networks IT652 –Object Oriented Programming IT653 - Communication systems IT654 - Computer Organization

IT655 - Digital Image Processing

IT656 -Applied Numerical Methods

IT657-Concepts of Operating Systems IT691 - Control system Components

IT692 –Product Design Technology

SUBJECTCODE: IT501 CIE: 50

SUBJECT: MICROCONTROLLERS EXAM HOURS: 3

HOURS /WEEK: 4 SEE: 50 TOTAL SLOTS: 52

Objectives: Upon completion of this course, student should be able to:

Describe the internal architecture of microcontroller systems, including counters, timers,

ports, and memory.PO1,PO3

Program, build and test a microcontroller system. PO2,PO4

Interface a microcontroller system to user controls and other electronic

systems.PO5,PO6,PO9

Write report regarding system design and development.PO7

Part A 1. Introduction to Microcontrollers:Architecture,RISC and CISC processors. Harvard and

Von Neumann architecture.PIPO36F877 Architecture.

07Hours

2. PIPO36F877Instructions Set, addressing modes, Assembly language Programs.

07Hours

Part B

3. Memory organization, ports, Interrupts

06Hours

4. PIPO36F877 Peripherals: Timers, CCP modules, ADC modules, configuration word and

programming

07Hours

Part C

5. Serial communication module: UART, Interfacing of keys, Display - LEDs, 7-segment

LED (multiplexed display) & LCDs,

06Hours

6. DAC and ADC, generation of PWM with PIC microcontroller.

07Hours

Part D

7. Architecture, Instruction set of 8051 microcontrollers

06Hours

8. Programming 8051 microcontrollers.

06Hours

TEXT BOOKS:

1. Design with PIC microcontrollers, J.B.PEATMAN, Pearson Edication, 1998, 1st Edition.

2. The 8051 Microcontroller architecture programming &applications,KENNETH J

AYALA - penram International publishing, 1999,2nd' Edition (unit 7,8)

REFERENCE BOOKS:

1. Programming and Customizing 8051 Microcontroller, Mike Predko, PHI, 2000, 1st

Edition.

2. Microcontrollers theory and applications, Ajay V Deshmuk, TMH, 2007, 1st Edition.


SUBJECT: DIGITAL SIGNAL PROCESSINGEXAM HOURS: 3

Hours /Week: 4 SEE: 50 TOTAL SLOTS: 52 Prerequisites: Signals and systems


Know the fundamentals of signal properties and implementation of transforms.PO1,PO2

Design and implementation of digital filters.PO3,PO4,PO7

Study of applications of DSP. PO2,PO6

PART-A 1. Signal Transforms: DFT, Properties of DFT, and IDFT.

07Hours

2. Convolution and Correlation: Circular Convolution, Correlation, Correlation of

Discrete time signals, correlation coefficient computation.

06Hours

PART-B 3. Computation of FFT: Decimation in Time FFT, Decimation in Frequency FFT, IFFT, FFT

Algorithm for a composite numbers. DCT: Features, advantages, DCT-2(Exclude Signal flow

diagrams).

07Hours

4. System Realization: Direct, Parallel and Cascade form for FIR & IIR Systems

06Hours

PART-C 5. FIR filters: Properties, Filter Design using Windows (Rectangular, Hamming and Hanning), Filter

design using Frequency sampling technique.

07Hours

6. IIR Filters-I: Specification and design techniques, Design of digital Butterworth and Chebyshev low

pass filters using Analog filter design techniques, Transform of Low pass to High pass, Band pass and

Band rejection filters. Comparison of IIR and FIR filters

06Hours

PART-D 7. IIR Filters II: Design of digital Butterworth and Chebyshev low pass filters using Digital filter design

techniques: Impulse Invariant and Bilinear Transformation techniques

07Hours

8. Applications of DSP:Multirate signal processing-Introduction, Decimation process, Interpolation

process, Digital filter bank. Adaptive filters: LMS adaptive algorithm, applications of adaptive filters.

06Hours

TEXT BOOK:

Modern Digital Signal Processing, V. Udayashankara, Second Edition, PHI

REFERENCE BOOKS:

1. Digital Signal Processing, PROAKIS and MANOLAKIS, Prentice Hall of India /

Pearson, 3rd

Edition.2006 Reprint.

2. Digital Signal Processing, S K MITRA, McGraw-Hill 4th

Edition.2002 Reprint.


SUBJECT: BIOMEDICAL INSTRUMENTATION EXAM HOURS: 3


Prerequisites: Transducers and Instrumentation


Know the fundamentals of nature, behavior and acquisition of biomedical signals. PO1,PO2

Study of various lifesaving Biomedical Instruments PO4,PO6PO7

Understand safety aspects and working of critical care Instruments PO8,PO9

Part-A 1. Fundamentals: Sources of biomedical signals, basic medical instrumentation system,general

constraints in design of biomedical instrumentation systems. Bioelectric signals and

electrodes: Origin of bioelectric signals,recordingelectrodes,Electrode-tissue

interface,polarization, ,electrodes for ECG,EEG,EMG.

07Hours

2. Electrocardiograph: Electrical activity of heart,block diagram of electrocardiograph,ECG

Leads system,effects of artifacts on ECG recordings. Electroencephalograph: Typical EEG

signal waveform,block diagram of Electroencephalograph,Computerised EEG analysis.

07Hours

Part-B 3. Patient monitoring system: Bedside patient monitoring system,centralmonitors,heart rate

measurement-average heart rate meter,instantaneous heart rate meter,measurement of

pulserate.

06Hours

4. Blood pressure and respiration rate measurement: Direct method of BP

measurement(fluid filled system),Indirect methods-

Korotkoffmethod,Rheographicmethod,Oscillometricmethod,Ultrasonic Doppler shift

method. Measurement of respiration rate: Impedance pneumography,CO2 method,.

07Hours

Part-C 5. Blood flowmeters: Square wave Electromagnetic bloodflowmeter,Ultrasonic Doppler shift

blood flowmeter,NMR blood flowmeter,Laser Doppler blood flowmeter.

06Hours

6. Cardiac pacemakers: Need for cardiac pacemakers,Externalpacemakers,Types of

implantable pacemakers,programmablepacemaker,Ventricular synchronous demand

pacemakers,rate responsive pacemakers.

06Hours

Part-D

7. Cardiac Arrhythmia: Arrhythmia monitor, ST/AR Arrhythmia algorithim, data

compression and processing of ECG by AZTEC, detection of ventricular fibrillation, exercise

stress testing

06Hours

8. Patient safety: Electric shock hazards,Grossshock,effects of electric currents on human

body, micro current shock, electro physiology of ventricular fibrillation, types of leakage

currents, precautions to minimize electric shock hazards, testing of biomedical equipment.

07Hours

TEXT BOOK:

1. Handbook of Biomedical Instrumentation, -R S KHANDPUR- Tata Megrawhill

Co.2003 2nd

Edition

REFERENCE BOOKS:

1. Introduction to biomedical equipment technology-Joseph.J.Corr and John.M.Brown,,

Pearson education., 4th

Edition, 2001

2. Principles of applied biomedical Instruments-Leslie Cromwell and John M

Brown,Pearson education, 4th

Edition, 2004


SUBJECT: Control Systems EXAM HOURS: 3

Hours /Week: 4 SEE: 50 TOTAL SLOTS: 52 Prerequisites: Mathematics & Network Analysis


Know the fundamentals of various control systems and their ingredients(PO2,PO4)

To develop system modeling and determine the mathematical model of complex systems(PO1,

PO2, PO3)

Analyze the behavior of a system and its stability in time domain (PO2,PO4,PO6)

Analyze the behavior of a system and its stability using frequency domain tools(PO2, PO4,PO6)

Part-A 1. Introduction to Control systems and Modeling: The control system: Definition and its

Classifications, Types of feedback and its effects, Types of modeling of physical systems and

Differential equations of physical systems .

07 Hours

2. Modeling of systems: Mechanical systems: Translational systems (Mechanical

accelerometer, Levered systems excluded), Rotational systems, Gear trains, Electrical

systems: F-V and F-I Analogous systems

07Hours

Part-B

3. Block diagrams and signal flow graphs: Transfer functions, Block diagram algebra, Signal

Flow graphs (State variable formulation excluded),

07 Hours

4. Time Response of feedback control systems: Standard test signals, Unit step response of

First and second order systems, Time response specifications: Time response specifications

of second order systems: Transient specifications and steady – state errors and error

constants.

07 Hours

Part-C

5. Stability analysis: Concepts of stability, Necessary conditions for Stability, Routh- stability

criterion, Relative stability analysis; More on the Routh stability criterion

06 Hours

6. Root–Locus Techniques: Introduction, The root locus concepts, Construction of root loci.

06 Hours

Part-D

7. Stability in the frequency domain: Mathematical preliminaries, polar plot, Nyquist

Stability criterion, (Inverse polar plots excluded), Assessment of relative stability using

Nyquist criterion, (Systems with transportation lag excluded).

06 Hours

8. Frequency domain analysis: Introduction, Correlation between time and frequency

response, Bode plots, Assessment of relative stability using Bode Plots.

06Hours

TEXT BOOK :

Control Systems Engineering, J. Nagarath and M.Gopal, New Age International (P) Limited,

Publishers,– 4th

Edition, 2005

REFERENCE BOOKS:

1. Modern Control Engineering,K. Ogata, Pearson Education Asia/ PHI,2002,4th Edition.

2. Automatic Control Systems,Benjamin C Kuo, ,PHI,7rd

Edition,200


SUBJECT:DATA ACQUISITION AND VIRTUAL INSTRUMENTATIONEXAM HOURS: 3

Hours /Week: 4 SEE: 50 TOTAL SLOTS: 52

Prerequisites: Logic Design, Electronic Measurements.

Objectives: Upon completion of this course, student should be able to: • Know the fundamentals of analog and digital signal conversion, specification and

applications(PO2,PO4)

• Understand the working of various A-D and D-A converters(PO2,PO4)

• Understand basics of graphical programming language.(PO10,PO3,PO7)

• Know the basics of Lab VIEW software simulation tool.(PO10,PO3,PO7)

PART-A 1. General considerations and Converter Specifications:Introduction, basic converter

considerations, digital logic levels and control logic. Specifications: Accuracy, acquisition time,

aperture time, code skipping/code elongation, common mode range, conversion time, glitch and

de glitcher, droop rate, monotonicity, noise, quantization error, resolution, settling time, slew

rate, stability and switching time.

06 Hours 2. Digital to Analog Converters:D/A conversion techniques, DAC components and accuracy

considerations.Numerical examples on DAC.

07Hours

PART-B 3. Analog to Digital Converters:A/D conversion techniques, types of ADC and error sources in

ADC.Numerical examples on ADC.

07Hours 4. Applications of DAC: Data distribution, CRT displays, A/D converters, frequency

synthesizer, signal generator, digital to shaft position converter, liquid flow control and programmed power supplies.

06Hours PART C

5. Applications of ADC: Electronic weighing system, digital voltmeters, automatic calibrator for multi-channel signal conditioning system, digital micrometer, ratio-metric measurement, data acquisition system, plasma TV panel display and automotive diagnostic test systems.

07Hours

6. Introduction to Labview: Data flow and Graphical Programming Language,working of Lab view Examples- Temperature System and frequency response Virtual Instrumentation-usinglabviewin the real world,theevolution,DataAcquisition,GPIB,Communication using serial port,Real world Applications,PXI and VXILabview Add-on tool kits,Labviewreal-time,FPGA,PDA and Embedded.

06 Hours

PART D

7. Labview Environment-I:Front Panels ,block diagrams ,Labview projects ,Sub VIs, the Icon

and the Connector, Activity, Allignment Grid and Pull down Menu’s

07 Hours

8. Labview Environment-II: Floating Palettes,the Tool bar,PopupMenu’s,ExpressVis,Displaying

Sub VIs as expandablenodes,Activity-Front Panel and block diagram basics. 06 Hours

TEXT BOOKS: 1. Hand book of A/D & D/A converters. HNATEK,John Wiley,2

nd Edition,1985

2. Labview for Everyone :Graphical Programming made easy and Fun.(Third Edition)Author-Jeffrey Travis and Jim Kring.Publishers-Pearson Education.

REFERENCE BOOKS: 1. Principles of data conversion system design,Behzadrazavi IEEE press 1995. 2. Lab view manual- National Instruments


SUBJECT: PROCESS INSTRUMENTATION-II EXAM HOURS: 3


Prerequisites: Process Instrumentation-I Objectives: Upon completion of this course, student should be able to:

Understand the construction, working principle of various transducers. PO4

Study the behavior and applications of various process parameters.PO5

Familiar with bulk food and power process industries.PO6

Write Typical Instrumentation Flow plans.PO5,PO7

Part A 1. Humidity Measurement: introduction, Dry and wet bulb psychrometers, Hair hygrometers,

Dunmore cells, thin films capacitances humidity sensor; Dew point hygrometers: surface

conductivity method. 5 Hours

2. Moisture measurements: measurement of moisture in gases and liquids- electrolytic

hygrometer ,capacitance hygrometers, measurement of moisture in solids- infrared absorption

or reflection moisture gauge, resistance moisture gauge. 5 Hours

Part B

3. Viscosity measurement: efflux cup viscometers, capillary viscometers- Differential pressure

type, falling ball viscometer, float viscometers-single-float viscometer, rotational industrial

viscometers-magnetic coupling viscometer.

5 Hours

4. Introduction to industrial processes: classification by variables, classification by

measurement signals, basic measuring circuits, typical bridge circuits, balancing methods,

telemeters. 5 Hours

Part C

5. Instrumentation Practices in the process industries: Instrumentation department functions

and responsibilities, Project engineering, plant test and process analysis, maintenance records,

standardization of instruments 5 Hours

6. Steam power plant instrumentation: Selection of instrumentation, primary power plant

measurement-pressure, temperature, flows levels, combustion guides ,Secondary power plant

measurement-smoke density, PH, electrical conductivity &speed . 5 Hours

Part D

7. Brewery Instrumentation: Control of hot water tanks, control of ceneal cookers and mask

tubes, sparge –water control systems, brew-kettle control systems, wort cooling control systems,

fermenter control system. 5 Hours

8. Preparation of wiring diagrams for instrument applications: Objective, preparation of

schematic diagrams, symbols, panel board functions and types and basic arrangements. panel

materials, location of panels. 5 Hours

TEXT BOOKS:

1. Industrial Instrumentation –K.Krishnaswamy and S.Vijayachitra, new age international

publication (unit 1, 2 and 3)

2. Hand Book of Applied Instrumentation- Considine and Ross, McGraw Hill book company,1st

Edition,1985. (Units 4, 5, 6,7and 8)

REFERENCE BOOK:

Instrument Engineers Handbook - B G LIPTAK, CRC Press,3rd

Edition,2004.


SUBJECT: Microprocessor Lab EXAM HOURS: 3



Develop ALP for microprocessor applications PO2,PO5,PO6

Design and interface processor with various peripherals PO7,PO10,PO9

1.

a. Write an assembly language program for multi precision addition and subtraction operations

b. Generate a square wave on Pco pin of 8255.

2.

a. Write an assembly language program to sort a set of N 16 bit unsigned integer numbers in

ascending/ descending order using bubble sort algorithm. Length of the numbers N is in word memory

location Xand the integers start from word memory location X+l.

b. Interface a relay and write program for switching

3.

a. Write an assembly language program to find the G.C.D. of two 16 bit unsigned integers

b. Interface a 7-segment display and write program to display number from 0 to 9 in succession at a

regular interval.

4.

a. Write an assembly language program to find the average of N 16 bit unsigned integers,

b. Generate a sine wave of programmable amplitude using DAC interface

5.

a. Write an assembly language program to convert a BCD number to 7-segment Code using look-up table,

b. Interface a matrix key pad and write program to identify the key closed.

6.

a. Write an assembly language program to check whether the given number belongs to special code or

not(eg. 2 out of 5 code)

b. Generate a triangular wave using a DAC interface

7.

a. Write an assembly program to perform the following

If contents of X = 1, then determine Z = (Y+W)/V

If contents of X = 0, then determine Z = (Y* W) - V

For other values of X store 00 in location Z

Where Y, W, V are 16 bit unsigned integers.

b. Interface an 8-bit ADC and write program to store the converted data in memory location.

8.

a. Develop and execute assembly language program that implements Binary search algorithm. The

data consists of sorted 16 bit unsigned integers. The search key is also a 16 bit unsigned integer.

b. Interface a stepper motor and write program to rotate in clock-wise direction by N-steps.

9.

a. Write an ALP to count the number of 0’s & 1’s in a set of 16 bit unsigned numbers. Display the result

on screen.

b. Implement a programmable up/down 4bit binary/decade counter using the I/O lines in the Add-on card.

Provision for selecting up or down count, binary or decade counting and loading an initial value is to be

provided.

10.

a. Write an assembly language program to classify 16- bit unsigned numbers in to odd and even numbers

b. Using the 8255 in the ADD-ON card realize an 8 to 1 multiplexer.

11.

a. Write an ALP to generate FIBONACCI SERIES.

b. Develop and execute an assembly language program for rolling display using 4 digit seven segment

displays.

12.

a. Develop and execute an assembly language program to compute factorial of a positive integer number

using recursive procedure. The 16 bit binary result can be left in a memory word location. (Use n such

that n! do not exceed 16 bit number).

b. Develop and execute assembly language program to realize ALU. A&B arenl bit input binary to AEU

and Y is output. Two control lines XI, X2 decide the operation to be performed. XI X2 Operation XI

X2 Operation

0 0 ADD 1 0 AND 01 SUB 1 1XOR Realize this on an ADD - On card.


SUBJECT: Control systems Lab EXAM HOURS: 3


Prerequisites: Control system, Instrumentation

Objectives: Upon completion of this lab, student should be able to

Design and analyze time behavior and stability of system with test signals(PO1,d3,PO5)

Design and analyze the frequency response of compensators (PO2, PO4)

Design and implement the driving circuits for actuators and nonlinear functions (PO3,

PO4, PO5)

Realize the stability analysis for the given transfer function using MATLAB

(PO1,PO3,PO5,PO6)

1. Determine the step response of a 2nd order system, using RLC circuit and measure rise time,

peak time, maximum peak overshoot, and settling time for under damped, critically damped

and over damped, conditions. Verify using theoretically calculated values.

2. To analyse the stability of SOS for a step input by

a. Varying ζ,keepingωnconstant

b. Varying ωn ,keeping ζ constant

3. To determine the frequency response of a lead network and verify using Bode plot.

4. To determine the frequency response of a lag network and verify using Bode plot.

5. Determine the characteristics of synchro transmitter / receiver. Rig up a synchro position

control system.

6. Design of relay driving circuits using opto-couplers.

7. Design of relay driving circuits using LDR.

8. Realization of non-linear functions-Dead zone ,Hysterisis and saturation using op-amps.

9. Determine the response of P, PI and PID controller for step input.

10. Using MATLAB software, plot the root locus with and without compensation for a given

transfer functions and verify using theoretical analysis.

11. Using MATLAB software, plot the Bode-plot with and without compensation for a given

transfer functions and verify using theoretical analysis.

12. Using MATLAB software, plot the Nyquist diagram for the given transfer functions and

verify using theoretical analysis.

HS 004 - COMMUNICATION SKILLS - II (1-0-1) 1.5

The course is designed for 39 hours in a semester. This course is structured 3 hours per session

of 13 Sessions and will be conducted in the following comportment.

Session No. Topics No. of hours 39

Session 1 College to Corporate - Change management

Session 2 Etiquettes and behavior - General Professional Power of

Dressing and Grooming

Session 3 Meetings & Report writing

Session 4 Stress Management

Session 5 Aptitude and Analytical Skills/ practice papers

Session 6 Reading and interpreting advertisements

Session 7 Resume writing & writing covering letters

Session 8 Understanding types of Interviews

Session 09 The essence of Group Discussion in Interviews

Session 10 Mock Interviews - GD

Session 1 1 Mock Interviews - Panel Interviews

Session 12 Mock Interviews - Screening/Individual Interviews

Session 13 Recap and Feedback

Intellectual property & Proprietary of 1-Excel Consultancy Services


SUBJECT: ANALYTICAL INSTRUMENTATIONEXAM HOURS: 3



Know the fundamentals of sensors, transducers & instrument calibration techniques.PO1,PO5

Operate & working with different type of instruments related to absorption and emission of

radiation in UV & visible region of spectra.PO2,PO10

Select suitable spectrometer for Raman & Mass spectrometric technique.PO3,PO5

Identify&separate different components in complex compounds using qualitative and

quantitative methods.PO8

Part-A 1. Fundamentals of Analytical Instruments:

Elements of Analytical Instruments, Sensors and Transducers, Signal Conditioning in Analytical

Instruments, Read out systems, Intelligent Analytical Instrumentation Systems, PC based

Analytical Instruments, Performance requirements of Analytical Instruments, Instrument

calibration Techniques.

07Hours

2. Colorimeters and Spectrophotometers(Visible-UV)

Electromagnetic radiation, Laws relating to Absorption of Radiation, Absorption Instruments.

06Hours

Part-B 3. Colorimeters and Spectrophotometers(Visible-UV) Continued

Ultraviolet and Visible Absorption Spectroscopy, Colorimeters/Photometers,

Spectrophotometers, Source of Error in Spectrophotometric Measurements.

06Hours

4. Atomic Absorption Spectrophotometers

Atomic Absorption Spectroscopy, Atomic Absorption Instrumentation, Sources of Interference

07Hours

Part-C

5. Raman Spectrometer

Raman effect, Raman Spectrometer, PC based Raman Spectrometer, Infrared and Raman Micro

spectrometry.

06Hours

6. MassSpectrometer

Basic Mass Spectrometer, Principle of operation, Types of mass spectrometers, Components of

Mass spectrometers, Inductively Coupled Plasma-Mass Spectrometry, Trapped Ion Mass

Analyzers, Ion Cyclotron Resonance (ICR) Mass Spectrometry, Quadrupole Ion Mass Analyzers,

Resolution in Mass Spectrometer, Applications of Mass Spectrometry.

07Hours

Part-D

7. Gas Chromatographs

Chromatography, Basic Definitions of Chromatography, Gas Chromatography, Basic Parts of a

Gas Chromatograph, Methods of Measurement of Peak areas.

06Hours

8. Thermo-analytical Instruments

Thermo-analytical Methods, Thermogravimetric Analysis (TGA), Differential Thermal

Analysis(DTA), Differential Scanning Calorimetry, Simultaneous Thermal Analysis/Mass

Spectrometer.

07Hours

TEXT BOOK:

1. Hand book of Analytical Instrumentation: R.S. Khandpur, Second Edition,TMH, 2006.

REFERENCE BOOKS:

1. Instrumental Methods of Chemical Analysis: Gurdeep R. Chatwal, Sham K. Anand, Himalaya

Publishing House, 5th Edition,2005

SUBJECTCODE:IT602 CIE: 50

SUBJECT: Embedded System Design EXAM HOURS: 3

Hours /Week: 3 SEE: 50 TOTAL SLOTS: 40 Objectives: Upon completion of this course, student should be able to:

Compare embedded system design models using different processor technologies (single

purpose, general purpose & application specific processors).PO1,PO9

Describe and compare the various types of peripherals used in embedded systems.

PO3,PO4

Use modern engineering tools necessary for integrating software and hardware

components in embedded system designs.PO9,PO10

Design, implement and test an embedded system using ARM processor.PO2,PO4

Part A

1. Introduction: Embedded systems overview, design challenges, Processor technology-

General purpose processors, Single purpose processors and Application specific

processors.

5Hours

2. Design technology and Trade-offs.

Standard single-purpose processors: Design and applications of timers, counters,

watchdog timers& UART.

5Hours

Part B 3. Pulse width modulators, LCD controllers, Keypad controllers. Stepper motor controllers,

Analog to digital converters and Real time clocks.

5Hours

4. Memory: Introduction, Memory write ability & storage permanence, Common memory

types.Composing memory, Memory hierarchy & cache and Advanced RAM.

5Hours

Part C 5. Communication Protocols & Interfaces: Communication basics, Arbitration, Advanced

communication principles, Serial protocols, Parallel protocols and Wireless protocols.

6Hours

6. ARM Processor Fundamentals: Registers, Current program status register, Pipeline,

Exceptions, Interrupts, Vector table and Core extensions.

5Hours

Part D 7. Embedded C Programming: Overview of C Compilers and optimization, C looping

structures, Register allocation, Function calls, Pointer Aliasing.

5Hours

8. Structure arrangement, Bit fields, Unaligned data and Endianness, Division, Floating

point, Inline functions, Inline assembly and Portability issues.

4Hours

TEXT BOOKS:

1. Embedded System Design: A Unified Hardware/Software, Introduction-Frank Vahid,

Tony Givargis,John Wiley & Sons, Inc.2002.

2. ARM System Developer’s Guide,Andrew N. Sloss,DomonicSymes and Chris Wright,

Elsevier, Morgan Kaufmann Publishers, 2008.

REFERENCE BOOKS:

1. Embedded Systems:Architecture and Programming,RajKamal,TMH. 2008.

2. ARM Processor manual, ISM, Bangalore, 2005.


SUBJECT: Process Control EXAM HOURS: 3


Prerequisites: Logic design, Analog signal conditioning Circuits, Control system, Data

Converters

Objectives: Upon completion of this course, student should be able to: • Understand the different elements in a process control loop and different process control

principles(PO2,PO9)

• Understand the use of different standards and symbols of process industry(PO5,PO6,PO7)

• Design of Analog and Digital process controllers(PO2,PO4,PO10)

• Study control loop characteristics and annunciators(PO3,PO6,PO9)

Part-A 1. Introduction to Process Control: Process control block diagram, control system evaluation, units,

standards and definitions (Except1.6.4 of C D Johnson). Converters: Frequency based converters,

Data Acquisition Systems: DAS Hardware, DAS software.

07Hours

2. Final control: Introduction to final control operation, signal conversions, actuators, valve actuators,

valve positioner.Control drawings: P & ID symbols and diagrams: flow sheet symbols, inter logic

symbols, graphic symbols.

06 Hours

Part-B 3. Control Valves: Capacity of control valve, valve sizing, determining pressure drop across valve,

cavitation and flashing, valve range ability, selection factors, sequencing control valves, viscosity

corrections.

06Hours

4. Controller principles: Introduction, process characteristics, control system parameters,

discontinuous control modes, continuous control modes, and composite control modes.

07 Hours

Part-C 5. Analog controllers: Introduction, general features, electronic controllers, pneumatic controllers,

designs considerations.

07Hours

6. Digital controllers: Digital electronic methods, computers in process control, process control

networks, characteristics of digital data.

06Hours

Part-D 7. Combination control systems: Ratio controller, Cascade controller, saturation in cascade loops, feed

forward control, advantages, technique.

06Hours

8. Control-loop characteristics: Introduction, control system configuration, multivariable control

systems, control system quality, stability, and process loop tuning.

07 Hours

TEXT BOOKS:

1.Process Control Instrumentation Technology, C D Johnson PHI,8

th Edition, 2004

2.Instrumentation for Process Measurement and control, Norman.A.Anderson, CRC Press, Third

Edition

REFERENCE BOOK: 1. Instrument Engineers Handbook (Vol 1 & 2),B G Liptak ,Chilton Book Company, 3

rdEdition

2. Process Control, K Krishnaswamy, New age International India, 1st Edition, 2006.

3. Computer based Industrial Control, Krishna Kant, PHI.


SUBJECT: Advanced Control SystemsEXAM HOURS: 3


Prerequisites: Control system, Mathematics

Objectives: Upon completion of this course, student should be able to

Design and implement suitable compensators for control systems using time and

frequency domain tools (PO2,PO3).

Develop the model in various configurations which relates the terminal variables with

internal variables of Continuous and Discrete control systems (PO1,PO4,PO7)

Determine the response of complex Continuous and Discrete systems using state space

model(PO2, PO3)

Obtain the desired response of a system by placing poles in the desired locations in time

domain (PO2, PO3)

Part A

1

Design of Lag/Lead/Lag-lead compensators using Frequency domain(Bode plot)

technique: Lead, lag, lead lag network and compensator design using Bode techniques.

05Hours

2 Design of Lag/Lead/Lag-lead compensators using Root Locus technique :Lead, lag,

lead lag network and compensator design using Root locus techniques.

05Hours

Part B

3 Analysis of LTI continuous time systems using State space method: Introduction,

state space representation using physical variables, state diagram, Conversion of state

variable Models to Transfer functions, Conversion of Transfer functions to Canonical

state variable models, Similarity Transformation, Eigen values and Eigen vectors and

Invariance properties.

05Hours

4 Solution of state equations and Analysis of Continuous time systems :Solution of state

equations for homogeneous and non homogeneous systems, State transition matrix(STM)

and its properties, Computation of State Transition matrix( eAt

) using Laplace

Transformation , Similarity transformation and Caley-Hamilton theorem methods.

Problems on finding the Solution of state equations for both homogeneous and non

homogeneous systems by computing STM. Controllability and Observability.

05Hours

Part C

5 Z- Plane Analysis of Discrete Time Control Systems and its Stability Analysis:

Introduction, Impulse Sampling and Data Hold, Pulse Transfer Function, Mapping

between the s-plane and the Z- plane, Stability Analysis of Open loop and Closed loop

systems in the z-plane.

05Hours

Part D

6 Analysis of LTI discrete time systems using State space method: Introduction, state

space representation using physical variables, state diagram, Conversion of state variable

Models to Pulse Transfer functions, Conversion of Pulse Transfer functions to Canonical

state variable models, Similarity Transformation.

05Hours

7 Solution of state difference equations and Analysis of Discrete time systems :

Solution of state equations for homogeneous and non homogeneous systems, State

transition matrix(STM) and its properties, Computation of State Transition matrix(Z-k

)

using Z- Transformation method, Similarity transformation method and Caley-Hamilton

theorem method. Problems on finding the Solution of state equations for both

homogeneous and non homogeneous systems by computing STM. Controllability and

Observability.

05Hours

8 Pole placement Design and State Observers for both Continuous and Discrete Time

Systems:Introduction, Stability improvement by state feedback, Necessary and sufficient

conditions for arbitrary Pole – Placement, State regulator Design and Design of State

Observers.

05Hours

TEXTBOOKS:

1. Digital control and state variable methods, MadanGopal, PHI, 2nd

Edition, 2005.

2. Discrete time Control Systems, K.Ogata, PHI publication, 2nd

Edition,2005.

REFERENCE BOOKS:

1. Modern Control Engineering , K. Ogata, PHI publication, 3rd

Edition, 2002.

2. Modern Control Engineering, Roy Choudhury, PHI, 2nd

Edition , 2004.


SUBJECT: Microcontroller Lab EXAM HOURS: 3


Prerequisites: Microcontroller theory.

Objectives: Upon completion of this lab, student should be able to:

Understand assembler, debugger, and simulators.PO5

Develop ALP for Microcontroller applications.PO2,PO3

Interface controller with various peripherals.PO7

Able to design in the field of agricultural, automobiles and medical applications. PO3,PO9

Experiments are to be conducted using either PIC microcontroller or 8051

microcontroller.

1. Addition, subtraction, Multiplication and Division of 8-bit numbers.

2. Write an assembly language program to sort a set of N 16 bit unsigned integer numbers in

ascending/ descending order using bubble sort algorithm

3. Write an ALP to count the number of 0’s & 1’s in a set of 16 bit unsigned numbers.

4. Write an assembly language program to classify 8- bit unsigned numbers in to odd and even numbers

5. Write an ALP to generate FIBONACCI SERIES.

6. Write an ALP to convert a digit Hex number to ASCII and ASCII to Hex.

7. Write an ALP to convert a Binary to BCD and BCD to Binary.

8. LCD interfacing.

9. DC motor speed control

10. Stepper motor speed and direction control.

11. Traffic light simulation

12. DAC interface.


SUBJECT:DATA ACQUISITION AND VIRTUAL INSTRUMENTATIONLABEXAM HOURS: 3


Objectives: Upon completion of this lab, student should be able to:

Have the knowledge of the basics of data acquisition circuits and A to D and D to A

converters PO2,PO5,PO6

Study and stimulate transducer working in LabVIEW PO10,PO9

1. Sample and Hold Circuits with discrete components

2. Sample and Hold Circuits Using IC

3. Analog multiplexer.

4. Digital to analog converter (DAC-0800).

5. Programmable gain amplifier (PGA) using Analog multiplexer.

6. 8 bit Successive Approximation ADC using IC 0809 and 0800.

7. R-2R Ladder Network DAC

8. Binary weighted resistance DAC.

Experiments using Lab VIEW:

9. Basic programming and simulation experiments

10 Performance of switching operation using LDR and Phototransistor.

11 Measurement of temperature using Thermistor.

12. Measurement of temperature using Thermocouple.

13 Measurement of load using strain gauges.


SUBJECT: MINI PROJECT (SELF LEARNING COMPONENT)EXAM HOURS: N/A

Hours /Week: 3 SEE: N/A TOTAL SLOTS: 12

Guidelines:

1. The group of Students is expected to design and demonstrate working of a Mini project.

2. The Course Advisors will advise you on preparation of synopsis, design and implementation of

the undertaken project work.

3. The groups of students have to independently carryout the project work in the allotted time of 3

hours/week.

4. The Mini-project work is to be based the concepts and Hands-on experience in Laboratory

courses already studied.

5. A duly signed report consisting of salient features and results is to be submitted before final

Demonstration.

6. The pattern of evaluation is as follows:

Synopsis presentation - 10 Marks

Mid evaluation - 10 Marks

Final Demonstration - 30 Marks

7. The panel of evaluation consists of HOD, Course Advisor, coordinator and two senior faculties

(Nominated by HOD).


SUBJECT:Computer NetworksEXAM HOURS: 3



Familiarize with functions of different layers of computer network PO5,PO2,PO6

Study concepts of internet in transport layer protocols PO5,PO2

Know applications of computer networksPO8,PO3

Part-A 1. Review of Basic Concepts: Requirements- Connectivity, Cost-Effective Resource Sharing,

Support for Common Services; Network Architecture- Layering and Protocols, OSI Architecture,

Internet Architecture; Performance- Bandwidth and Latency.

5Hours

2. Direct link networks: Hardware Building Blocks-nodes, links; Error Detection- Two-

Dimensional Parity, Internet checksum Algorithm, cyclic Redundancy Check; Reliable

Transmission- Stop-and-Wait, Sliding Window: Algorithm and Finite Sequence numbers, Rings

(802.5, FDDI) –Token Ring Media Access Control, Token Ring Maintenance.

5Hours

Part-B 3. Packet Switching: Switching and forwarding – Datagrams, Virtual Circuit Switching, Source

Routing; Bridges and LAN Switches – Learning Bridges(excluding implementation), Spanning

Tree Algorithm, Broadcast and Multicast, Limitations of Bridges.

5Hours

4. Internetworking-1: Simple internetworking (IP) –Internetwork, IPv4, Service Model, Global

Address, Datagram Forwarding in IP, Address Translation(ARP), Host

Configuration(DHCP),Error Reporting(ICMP).

5Hours

Part-C 5. Internetworking-2: Routing – Network as a Graph, Distance Vector(excluding

implementation), Global Internet – Subnetting, Classless Routing(CIDR),

InterdomainRouting(BGP), Routing Areas, IP Version 6(IPv6) packet Header.

5Hours

6. End –to-End Protocols: Simple demultiplexer (UDP); Reliable byte stream (TCP) – End-to-

End Issues, Segment Format, Connection Establishment and Termination, Sliding Window

,Triggering Transmission, Adaptive Retransmission, Alternative Design Choices.

5Hours

Part-D 7. Congestion Control and Resource Allocation: Issues in resource allocation – Network

Model, Queuing discipline – FIFO, Fair Queuing; TCP Congestion Control – Additive

Increase/Multiplicative Decrease, Slow Start, Fast Retransmit and Fast Recovery; Congestion-

Avoidance mechanisms – DECbit, Random Early Detection (RED).

5Hours

8. Applications: Traditional applications – Electronic Mail (SMTP, MIME, IMAP), World Wide

Web (HTTP), Name Service (DNS), Network management (SNMP); Web services – Custom

APPLICATION Protocols (WSDL, SOAP).

5Hours

TEXT BOOK:

Computer Networks – A Systems Approach ,Larry L. Peterson and Bruce S. David,4th

Edition, Elsevier,2007.

REFERENCE BOOKS:

1. Data Communications and Networking, Behrouz A. Forouzan, 4th Edition, Tata

McGraw Hill, 2006.

2. Computer Networks, Andrews S.Tanenbaum, Pearson Education, 4th

Edition, 2004


SUBJECT:Object Oriented ProgrammingEXAM HOURS: 3



Differentiate procedure oriented and object-oriented programming

concepts.PO5,PO7,PO10

Perform object oriented programming to develop solutions to problems demonstrating

usage of objects, classes and overloaded operators and other standard language

constructs.PO3,PO5

Demonstrate adeptness of object oriented programming in developing solutions to

problems demonstrating usage of data abstraction, encapsulation, pointers and

inheritance.PO3,PO5

Understand fundamental concepts of data structure.PO4,PO10

Part-A 1. C++ programming Basics: Need for object oriented programming, procedural languages,

characteristics of OOP, preprocessor directives, data types, manipulators.

5Hours

2. Structures: Structures as user defined data types, enumerated data types, Functions: passing

arguments, returning values, reference arguments, overloaded functions, inline functions.

5Hours

Part B

3. Objects and classes: Objects as data types, constructors, destructors, overloaded

constructors. Arrays: Arrays as class member data types, passing arrays, arrays as objects,

strings.

5Hours

4. Operator overloading: Over loading of unary operators, binary operators and data

conversion.

5Hours

Part C

5. Inheritance: Derived and base class, levels of inheritance, multiple inheritance, Hybrid

inheritance and virtual base class.

5Hours

6. Pointers: Pointers in C++, pointers to objects, files and streams, input/output operations.

5Hours

Part D

7. Data structures-1: Data representation stacks and linked list.

5Hours

8. Data structures-2: Queues: Single ended, D-queue and Priority queues; binary trees and its

representation.

5Hours

TEXT BOOKS:

1.Object oriented programming in TURBO C++, Robert Lafore, Galgotia Publications, 2nd

Edition.

2.Data Structures, Algorithms and Applications in C++,SartajSahni, Tata McGraw Hill

Publications.

2nd

Edition.(Part-D)

REFERENCE BOOKS:

1.C++ Programming , BjrneStrounstrap, Addison-Wesley Publications, 3rd

Edition.

2.Object Oriented Programming with C++, E Balaguruswamy, , Tata McGraw Hill

Publications, 3rd

Edition.


SUBJECT: Communication SystemsEXAM HOURS: 3



Understand analog modulation techniques PO1,PO5

Know digital modulation techniques PO7,PO5,PO2

Study effects of noise in modulation PO1,PO4

Part A 1. Amplitude Modulation-1: Time-Domain Description, Frequency domain description,

Generation of AM waves, Detection of AM waves, AM/DSB, Time-Domain Description,

Frequency domain description Generation of DSBSC waves, Coherent Detection of DSBSC

Modulated waves. Costas loop, Quadrature Carrier multiplexing.

5Hours

2. Amplitude Modulation-2:AM-SSB/SC generation, Frequency-Domain Description,

Frequency discrimination method for generation an SSB Modulated wave, time domain

description, phase discrimination method for generating an SSB modulated wave,

Demodulation of SSB waves, Comparison of amplitude modulation techniques, frequency

translation, FDM.

5Hours

Part B

3. Angle Modulation: Basic Concepts, Frequency Modulation, Spectrum Analysis Of

sinusoidal FM wave, NBFM, WBFM, Constant Average power, Transmission bandwidth of

FM waves, Generation of FM waves, Direct FM, demodulation of FM waves, frequency

discriminator, ZCD, phase locked loop (1st order) of AM and FM

5Hours

4. Noise in Analog Modulation Systems: Signal-to-noise ratios, AM receiver model, Signal-

to -noise ratios for coherent reception, DSBSC receiver, SSB receiver, noise in AM

receivers using envelope detection, threshold effect, FM receiver model, noise in FM

reception, FM threshold effect, pre-emphasis and de-emphasis in FM systems

5Hours

Part C

5. Pulse Modulation-1: Sampling theorem for low-pass and band-pass signal, statement and

proof, PAM, Channel bandwidth for a PAM signal, natural sampling, flat-top sampling,

signal recovery though holding

5Hours

6. Pulse Modulation-2:quantization of signals, quantization error, PCM, electrical

representations of binary digits, PCM systems, DPCM, delta Modulation, Adaptive delta

modulation.

5Hours

Part D

7. Digital Modulation-1: Introduction, Binary Shift Keying, DPSK, QPSK, Type D flip-flop,

QPSK transmitter, non-offset QPSK, QPSK receiver.

5Hours

8. Digital Modulation-2: signal - space representation, BFSK, spectrum, receiver for BFSK,

geometrical representation of orthogonal BFSK, line codes, TDM.

5Hours

TEXTBOOKS:

1.Analog and Digital communication: Simon Haykin, John Willey, 3rd

edition 2005.

2.Principles of communication systems, Taub and Schilling, TMH, 2nd

edition, 2001.

REFERENCE BOOKS:

1.Electronic Communication Systems,Blake, Thomson publishers,2nd

Edition,2006

2.Electronic Communication Systems, George Kennedy,TMH, 2005, 2nd

Edition


SUBJECT: COMPUTER ORGANIZATIONEXAM HOURS: 3

HOURS /WEEK: 3 SEE: 50 TOTAL SLOTS: 40 Prerequisites: Logic Design

Objectives: Upon completion of this subject, student should be able to:

understand the basics of various subsystems of a computer.PO3,PO7

Know the working of RISC and CISC.PO5

Familiarize with various standard interfaces.PO9

PART-A

1. Basic Structures of Computers:Computer types : Functional units : Input unit, Memory

unit, Arithmetic &logic unit, Output unit, Control unit; Basic Operational

Concepts : Bus Structures : Performance : Processor clock, Basic

Performance equation, Pipelining & Superscalar operation, Clock rate,

Performance measurement; Multiprocessor &Multicomputers:

05 Hours

2. Machine Instructions &Programs:Numbers, Arithmetic operations and characters,

Memory Locations & Addresses : Byte addressability, Big-endian & Little-endian

assignments, Word Alignment, Accessing Numbers, Memory Operation : Instruction &

Instruction Execution & Straight-line sequencing, Branching, Condition Codes, Generating

Memory Addresses;

05 Hours

PART-B 3. Assembly Language : Assembler Directives, Number Notation; Basic Input/Output Operations :

Stacks & Queues : Subroutines : Subroutine Nesting & Processor Stack, Parameter Passing, The

Stack Frame; Additional Instructions : Logic Instruction, Shift & Rotate Instructions, Multiplication

& Division; General features of CISC & RISC. 05 Hours

4. Input/OutputOrganization:Accessing I/O devices : Interrupts : Interrupt Hardware, Enabling &

Disabling Interrupt, Handling Multiple devices, Controlling Device Requests, Exceptions; Direct

Memory Access : Bus Arbitration; Buses : Synchronous Bus, Asynchronous Bus; Interface Circuits :

Parallel Port, Serial Port.05 Hours

PART-C 5. The Memory System:Some Basic Concepts : Semiconductor RAM Memories: Internal

Organization of Memory Chips, Static Memories, Asynchronous DRAMs, Synchronous

DRAMs, Memory System Considerations, Rambus memory.

05 Hours

6. The Memory System:Read-onlyMemories : ROM, PROM, EPROM, EEPROM, Flash

memory; Speed, Size & Cost : Cache Memories : Mapping functions; Performance

considerations : Interleaving, Hit Rate & Miss Penalty; Virtual memories : Address

Translation;

05 Hours

PART-D 7. Arithmetic Unit:Addition& Subtraction of Signed Numbers .'Addition/Subtraction Logic Unit;

Signed-Operand Multiplication : Booth Algorithm; Fast Multiplication : Bit-pair Receding of

Multipliers; Integer division : Floating-Point Numbers & Operations : IEEE Standard for Floating-

Point Numbers, Arithmetic Operations on Floating-Point Numbers.

05 Hours

8. Basic Processing Unit:Some Fundamental Concepts: Register Transfers, Performing an Arithmetic

or Logic operation, Fetching a Word from Memory, Storing a Word in Memory; Execution of a

Complete Instruction : Branch instruction; Multiple-Bus Organization : Hardwired Control :A

CompleteProcessor.

05Hours

TEXT BOOK: Computer Organization, Carl Hamacher, Z Vranesic& S Zaky ,TMH, 5

th Edition., , 2002

REFERENCE BOOKS:

1. Computer System Architecture, Morris Mano, 2nd

Edition, PHI,1986. 2. Computer system Design & Architecture, V Heuring& H Jordan,,Addison-Wesley, 1

st

Edition., 1999.


SUBJECT: DIGITAL IMAGE PROCESSINGEXAM HOURS: 3



Know the fundamentals of Image Processing and Image transforms PO2,PO1

Familiarize with Image enhancement in various domains PO7

Know effect of noise and Denoising of images PO3,PO2

Understand boundary detection leading to area computation PO6

Part-A

1. Fundamentals:Introduction, Fundamental steps in digital image processing (DIP),

components of DIP system, A simple image formation model, Image sampling and

quantization, Basic relationship between pixels,

05Hours

2. Image Transforms:Mathematical preliminaries-Vector algebra, Linear operations, Fourier

transforms, Discrete sine and cosine transforms, Hartley transform, Walsh-Hadamard

transform, Harr transform, Slant transform, K-L transform.

05Hours

Part-B

3. Image Enhancement in Spatial Domain-1: Background, Point processing – Image

negatives, Log transformations, Power law transformations, Contrast stretching, Gray level

slicing, Bit plane slicing, Histogram processing – Histogram equalization, Histogram

matching (specification), Local enhancement,

05Hours

4. Image Enhancement in Spatial Domain-2: Arithmetic/Logic operations – Image

subtraction, Image averaging, Basics of spatial filtering, Smoothing spatial filters –

Smoothing linear filters, ordered statistics filters, Sharpening spatial filters – Foundation,

Laplacian and gradient.

05Hours

Part-C

5. Image Enhancement in Frequency Domain:Background, Basic properties of the frequency

domain, Basic filtering in the frequency domain, Basic filters and their properties, Smoothing

frequency domain filters – Ideal low-pass filters, Butterworth low-pass filters, Gaussian low-

pass filters, Sharpening frequency domain filters – Ideal high-pass filters, Butterworth high-

pass filters, Gaussian high-pass filters, Homomorphic filtering.

05Hours

6. Image Restoration: Image degradation and restoration models, noise models, restoration

using spatial filtering – mean filter, geometric mean filter, harmonic mean filter, median

filter, max & min filters, midpoint filter.

05Hours

Part-D

7. Noise filtering by frequency domain filtering – band reject filter, band pass filter, notch

filter, inverse filtering, minimum mean square error (Wiener) filtering.

05Hours

8. Detection of discontinuities- Point line edge detection, Gradient operators, Laplacian, edge

linking and boundary detection- local processing. Global processing through Hough

transform, Thresholding- Foundation, Illumination role, Basic global thresholding, Region

based separation- Region growing, Region splitting and merging.

05 Hours

TEXT BOOKS:

1. Digital Image Processing, Rafael C. Gonzalez & Richard E. Woods,. Pearson Education Inc.,2nd

Edition, 2004 ( units 1,3,4,5 and 6)

2. Digital Image Processing and Analysis, B.Chanda,D.DuttaMajumder, PHI, 6th

reprint,

2005

REFERENCE BOOKS:

1. Fundamentals of Digital Image Processing,A.K.Jain, PHI, 2nd

Edition, 2007

2. Image Processing, analysis and Machine Vision, Milan sonka, VaclarHlavac and

Roger boyle, Thomson, 2nd

Edition ,2003


SUBJECT: APPLIED NUMERICAL METHODSEXAM HOURS: 3



Know the fundamentals of numerical computationPO1,PO9

Familiarize with Linear algebra based techniquesPO10

Know the working of curve fitting & root finding techniquesPO3,PO2,PO9

Understand optimization methods PO1,PO10

Part-A

1. Numerical Computation: Motivation and objectives / Number Representation/ Machine

Precision/ Round off Error /Truncation Error / Random Number Generation.

05Hours

2. Linear Algebraic Systems: Motivation and objectives / Gauss-Jordan Elimination

05 Hours

Part-B

3. Linear Algebraic Systems: Gaussian Elimination/LU Decomposition/ III- Conditioned

systems/ Iterative Methods.

05 Hours

4. Eigen values And Eigenvectors: Motivation and objectives/ The Characteristic

polynomial/ Power methods/ Jacobs’s method/ householder transformation/ QR method/

Danilevskys Method/ Polynomial Roots.

05 Hours

Part-C 5. Curve Fitting: Motivation and objectives/ Interpolation/ Newtons Difference Formula/

Cubic Splines/ Least square/ Two- Dimensional Interpolation.

05 Hours

6. Root Finding-1: Motivation and objectives/ Bracketing methods/ contraction mapping

method/ secant method.

05 Hours

Part-D 7. Root Finding-2: Mullers Method/ Newton’s Method/ polynomial roots/ Nonlinear

systems of equations. 05 Hours

8. Optimization: motivation and objectives/ Local and Global minima/ Line searches/

steepest Descent method/ Conjugate- Gradient Method/ quasi-Newton Methods/ Penalty

Functions / Simulated Annealing

05 Hours

TEXT BOOK:

Applied Numerical Methods for Engineers using MATLAB and C,ROBERT J.SCHILING

&SANDRA HARRIS, Thomson Publishing, Singapore / Bangalore, 2002

REFERENCE BOOKS:

1. Applied Numerical Analysis, GERALD AND WHETELY, Pearson Education, New

Delhi, 2002.

2. Numerical Receipies in C, WILLIM PRESS ET.AL, Cambridge publishers, New Delhi.


SUBJECT:CONCEPTS OF OPERATING SYSTEMSEXAM HOURS: 3


Prerequisites: Higher Level Programming Language


• Understand the goals, operations and different classes of an Operating System(PO7,PO6,PO9)

• understand different memory management techniques in an operating system(PO7,PO6,PO9)

• Have knowledge of Windows and UNIX(PO7,PO6,PO9)

Part – A

1. Introduction: Abstract views of OS, Goals and operation of an OS, OS and the computer system,

Interrupt action and processing of interrupts and system calls

5Hours

2. Classes of OS: Batch processing OS, Multiprogramming OS, Time sharing OS, RTOS,

Distributed OS.

5Hours

Part – B

3. Processes And Threads: Processes and programs, OS view of processes, Threads:

User and kernel level threads, Hybrid thread model. 5Hours

4. Scheduling: Concepts and terminologies, Non-preemptive scheduling-FCFS and SRN policies,

Preemptive scheduling- RR, LCN and STG policies,Scheduling in practice : long, medium and

short term scheduling. 5 Hours

Part – C

5. Memory Management: Static and Dynamic Memory allocation, Memory allocation to a

process, Reuse of memory – Performing fresh allocations using a free

list,Memoryfragmentation,Merging free areas,Memory compaction, contiguous Memory

allocation-Handling memory fragmentation,Memorycompaction,Reuse of memory areas,

non-contiguous allocation. 5Hours

6. Virtual Memory: VM Basics, Demand paging-Overview of paging,demand paging

preliminaries,pagereplacement,optimal page size, Page replacement policies-FIFO, LRU and

optimal.

5Hours

Part - D

7. Structure of OS: Operation of OS, Structure of an OS, OS with monolithic structure, Layered

design of OS, Kernel based OS, Microkernel based OS, Architecture of UNIX and Windows.

5Hours

8. Distributed Operating System: Features and nodes of Distributed systems,Network OS,

Distributed OS, reliable inter-process communication, Distributed computation

paradigms-client server computing,remote procedure calls,remote evaluation

5Hours

TEXT BOOK:

Operating Systems: A Concept Based Approach – D.M Dhamdhere, 2nd

Edition, Tata McGraw- Hill,

2002.

REFERENCE BOOKS:

1. Operating System Principles – Abraham Silberschatz, Peter Baer Galvin, Greg Gagne, 7th

edition,

Wiley-India, 2006Operating Systems – P.C.P. Bhatt, 2nd

Edition, PHI, 2006. 2.Operating Systems – Harvey M Deital, 3

rd Edition, Addison Wesley, 1990.


SUBJECT:CONTROL SYSTEM COMPONENTSEXAM HOURS: 3

Hours /Week: 3 SEE: 50 TOTAL SLOTS: 40 Objectives: Upon completion of this course, student should be able to:

Know the fundamentals of motors PO1,PO2,PO8

Familiarize with working principle of different motors PO4

Know the difference between pneumatic and hydraulic actuated valves PO3,PO7

Part-A

1. A.C & D.C. Servomotors: Analysis, Transfer function and

Block Diagram load-torque speed torque characteristics. Electronic

drive circuits, Application in control.

05 Hours

2. Synchros: Principle, types, construction, errors and applications- error detection and error

transmission.

05 Hours

Part-B

3. Stepper Motors: Variable reluctance stepper motor (single stack & Multi stack) permanent

magnet stepper motor, hybrid stepper Motors, Drive circuits and High speed operations.

05 Hours

4. Induction Machines: Construction and working, speed control ( line voltage control and line

frequency control), Synchronous machines – Synchronous generator and motor, power and

torque characteristics, speed control(frequency control and self control)

05 Hours

PART-C

5. CONTROL VALVE AND SIZING: Principles, types, characteristics, Pneumatic &

hydraulic actuated valves, Solenoid operated valve.

05 Hours

6. Control valve positioners: The principle, type, characteristics and design

05 Hours

PART-D

7. Special control system components: Actuating magnets, Contactors and switches, Relays, Limit

switches, Miniature motors, electro-pneumatic circuits, Actuators for valves, I/P & P/I converters.

05Hours

8. Special Machines : Linear induction motor, reluctance motors,

brushless motors, Hysteresis motors, AC tachometers 05Hours

TEXT BOOKS :

1. Principles of Electrical Machines and Power Electronics, P.C Sen, John Wiley &

Sons, 2nd

Edition, 1997

2. Electrical Machines and power systems: Vincent Del Toro,TMH,2nd

Edition (Unit

5,6,7) , 1988,

REFERENCE BOOK:

Electrical machines, Drives & Power Systems,TheodoreWilde,Prentice -Hall International, 3rd

Edition, 1997


SUBJECT: Product Design Technology EXAM HOURS: 3



Know the preparation of layout of the product design PO2

Familiarize with identifying customer for new products PO8

Know the design and fabrication of PCB PO4,PO2

Part-A 1. Introduction, Development process and Organizations: characteristics of successful product

development, duration and cost of product development, challenges of product development.

05Hours

2. Generic development process, concept development – Front-end process, adapting the

generic product development process.

05 Hours

Part-B

3. Identifying Customer needs and Establishing Product specifications: defining scope,

gathering data from customers, establishing relative importance of needs. Target

specifications & refining specifications.

05Hours

4. Concept generation: five-step methodology of concept generation, with a case study of any

electronic instrument.

05Hours

Part-C

5. Human Engineering Considerations in product Design: anthropometry, the design of

controls, and the design of displays, man/machine information exchange.

05Hours

6. Concept Embodiment: overview, basic methods, advanced methods, case study-computer

monitor with reference to ergonomics and esthetics.

05 Hours

Part-D

7. PCB Technology: introduction, types, applications, base materials.

05Hours

8. PCB Technology: design methods and fabrication processes.

05Hours

TEXT BOOKS:

1.Product Design and Development by Karl T Ulrich, Steven D Eppinger, Tata McGraw,-3rd

Edition,2003

2.Printed Circuit board Design and Technologyby Walter C Boshart, McGraw International,

5th

reprint (Unit 7,8) , 2001

REFERENCE BOOKS

1.Product design and manufacturingby AK. Chitale and RC Gupta – Prentice Hall, 1st Edition,

2000

2.Product Design, Kevin Otto, Kristin Wood, Pearson Education, 2nd

Edition.

HS 006 - ENVIRONMENTAL SCIENCE (AUDIT COURSE) (2-0-0) 0

1. Environment - Definition, Eco system — Balanced ecosystem, Effects of human

activities on environment Agriculture Housing -Industry Mining and

Transportation

04 Hours

2. Natural Resources: - Water resources - Availability and Quality, Water borne

diseases, Water induced diseases, Fluoride problem in drinking water. Mineral

Resources - Forest Resources - Material Cycles - Carbon, Nitrogen and Sulphur

Cycles.

08 Hours

3. Pollution, effects of pollution - Water pollution - Air pollution Land pollution -

Noise pollution.

08 Hours

4. Current Environmental issues of importance: Acid Rain, Ozone layer depletion -

Population Growth, Climate change and Global warming. Environmental Impact

Assessment and Sustainable Development Environmental Protection - Legal

aspects. Water Act and Air Act.

06 Hours

TEXT BOOKS:

1. Environmental Studies - Dr. D.L Manjunath, Pearson Education -2006

2. Environmental Studies - Dr. S. M. Prakash - Elite Publishers - 2006

REFERENCE BOOKS:

1. Environmental Studies - Benny Joseph - Tata McGraw Hill- 2005

2. Principles of Environmental Science and Engineering P. Venugopala Rao, Prentice

Hall of India.

3. Environmental Science and Engineering - Meenakshi, Prentice Hall India.

scheme & syllabus for v and vi semesters b.e...

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