Syllsbus of Sst

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M.Tech.SensorSystemsTechnology

Curriculum(Regular)

(2008-09onwards)

UniversityCore

Course Code CourseTitle L T P CEEE 698 Seminar 1

EEE 699 StudentProject 20

Totalcredits 21

ProgrammeCore

Course Code CourseTitle L T P CEEE

557

Physical

Sensors

3

0

2

4

EEE 558 DataAcquisitionandHardwareInterfaces 3 0 2 4

EEE 559 MicrocontrollersandApplications 3 0 4 5

EEE 560 ControlSystems 3 0 2 4

EEE 561 MicroandSmartSystemsTechnology 3 0 2 4

EEE 562 SensorNetworks 3 0 0 3

EEE 563 OpticalSensors 2 0 2 3

EEE 564 ChemicalSensors 3 0 0 3

EEE 601 TechnicalCommunications 1 0 4 3

Total credits 33


2/33

ProgrammeElective

Creditstobetaken:16

Course Code CourseTitle L T P CEEE 565 RFandMicrowaveSensors 3 0 0 3

EEE566

Sensors

for

Transportation

3

0

0

3

EEE 567 BiomedicalSensors 3 0 0 3

EEE 568 BioSensors 3 0 0 3

MGT 501 CreativityandInnovationinManagement 3 0 0 3

EEE 556 NeuralNetworksandFuzzyLogic 3 0 0 3

EEE 539 ElectronicHardwareSystemDesign 2 0 2 3

EEE 540 EmbeddedSystemDesign 3 0 0 3

EEE 551 EmbeddedCandLinux 1 0 4 3

ForeignLanguage 2 0 0 2

EEE Characterization,CalibrationandPackagingofSensors 3 0 0 3

EEE SensorsforHarshEnvironment 3 0 0 3

UniversityElectiveinsteadofProgrammeElectivecanbetaken

CreditSummary

MinimumQualifyingcredits 70

TotalcreditsOffered(UC+PC+PE) 70

UC 21

PCOffered 33

PENeeded 16

UCUniversityCore

PCProgrammeCore

PEProgrammeElective


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M.Tech.SensorSystemsTechnology

Curriculum(Dualdegree)

(2008-09onwards)

Dualdegree

Programme

with

the

University

of

Applied

Sciences,

Karlsruhe,Germany

ProgrammeCore

Course Code CourseTitle L T P CEEE 557 PhysicalSensors 3 0 2 4

EEE 558 DataAcquisitionandHardwareInterfaces 3 0 2 4

EEE 559 MicrocontrollersandApplications 3 0 4 5

EEE 560 ControlSystems 3 0 2 4

EEE 562 SensorNetworks 3 0 0 3

EEE 563 OpticalSensors 2 0 2 3

Total credits 23

ProgrammeElective

Creditstobetaken:17

Course Code CourseTitle L T P CEEE 565 RFandMicrowaveSensors 3 0 0 3

EEE 566 SensorsforTransportation 3 0 0 3

EEE567

Biomedical

Sensors

3

0

0

3

EEE 568 BioSensors 3 0 0 3

MGT 501 CreativityandInnovationinManagement 3 0 0 3

EEE 556 NeuralNetworksandFuzzyLogic 3 0 0 3

EEE 539 ElectronicHardwareSystemDesign 2 0 2 3

EEE 540 EmbeddedSystemDesign 3 0 0 3

EEE 551 EmbeddedCandLinux 1 0 4 3

ForeignLanguage 2 0 0 2

EEE Characterization,CalibrationandPackagingofSensors 3 0 0 3

EEE

Sensors

for

Harsh

Environment

3

0

0

3UniversityElectiveinsteadofProgrammeElectivecanbetaken


4/33

CreditSummary

MinimumQualifyingcredits 70

Totalcredits

Offered

(PC+PE+CreditTransferred)70

PCOffered 23

PENeeded 17

CreditTransferredfromUAS,Karlsruhe,

Germany

30

DualdegreestudentsareexemptedfromdoingthetwoUCcourses,viz.EEE601andEEE698.TheFirst

semesterwillbecommonforbothRegularandDualdegreestudents.ThesecondsemesteratVITwillbe

carriedout

through

fast

track,

in

two

phases.

The

first

phase

for

the

Dual

degree

students

will

be

commonwiththeRegularstudentsandthesecondphasewillbeonlyfortheRegularstudentsatVIT.

TheDualdegree studentswillearn the remaining30creditsatUAS,Karlsruhe,Germanyduring their

stay of one year duration. The Student Project ofDual degree studentswill be carried out atUAS,

Karlsruhe,Germany

PCProgrammeCore

PEProgrammeElective


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M.Tech.SensorSystemsTechnology(Regular&Dual)CoursesOffered

No. Course Code CourseTitle L T P C CourseOfferedby

335 EEE 557 PhysicalSensors 3 0 2 4 SES336 EEE 558 DataAcquisitionandHardwareInterfaces 3 0 2 4 SES337 EEE 559 MicrocontrollersandApplications 3 0 4 5 SES338 EEE 560 ControlSystems 3 0 2 4 SES339 EEE 561 MicroandSmartSystemsTechnology 3 0 2 4 SES340 EEE 562 SensorNetworks 3 0 0 3 SES341 EEE 563 OpticalSensors 2 0 2 3 SES342 EEE 564 ChemicalSensors 3 0 0 3 SES334 EEE 601 TechnicalCommunications 1 0 4 3 SES232 EEE 698 Seminar 1 SES233 EEE 699 StudentProject 20 SES343 EEE 565 RFandMicrowaveSensors 3 0 0 3 SES344 EEE 566 SensorsforTransportation 3 0 0 3 SES345 EEE 567 BiomedicalSensors 3 0 0 3 SES346 EEE 568 BioSensors 3 0 0 3 SES347 MGT 501 CreativityandInnovationinManagement 3 0 0 3 VITBS

277 EEE 556 NeuralNetworksandFuzzyLogic 3 0 0 3 SES260 EEE 539 ElectronicHardwareSystemDesign 2 0 2 3 SES261 EEE 540 EmbeddedSystemDesign 3 0 0 3 SES272 EEE 551 EmbeddedCandLinux 1 0 4 3 SES

ForeignLanguage 2 0 0 2 SSHEEE Characterization,CalibrationandPackagingofSensors 3 0 0 3 SESEEE SensorsforHarshEnvironment 3 0 0 3 SES


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M.Tech.SensorSystemsTechnology(Regular&Dual)CoursesOffered

CreditSummary

(Regular)

CreditSummary

(Dualdegree)

MinimumQualifyingcredits 70 MinimumQualifyingcreditsTotalcreditsOffered(UC+PC+PE) 70 TotalcreditsOffered

(PC+PE+CreditTransferred)UC 21 UCPCOffered 33 PCOfferedPENeeded 16 PENeeded

CreditTransferredfromUAS,Karlsruhe,Germany

UCUniversityCorePCProgrammeCorePEProgrammeElective


7/33

EEE539 Electronic Hardware System Design

L T P C

2 0 2 3

Version No.: 1.00

Prerequisites: Digital and Analog ElectronicsAim:

To teach the fundamental possibilities and limitations of different technology platforms (FPGA,and PCB), and specifically describe some FPGA families, architectures and capabilities.

To provide knowledge in some current and relevant DSP applications for FPGAsLearning Outcome:

Ability to demonstrate proficiency in implementing designs using hardware description languagesand EDA tools such as HDL simulators and synthesizers.

Ability to describe the steps required for the design, implementation, verification and test of acomplex new electronic product of today, and how these steps are related to each other.

Programmable Logic Devices & FPGAs

Introduction to FPGAs FPGA technologies FPGA Architectures FPGA Design Flow Prototyping withXilinx FPGAs FPGA based Testing

Applications on FPGA

DSP Algorithms on FPGAs Wireless applications -FPGAs for automotive applications -Use of Lab viewfor real time simulations

PCB design

Signal integrity - High speed PCB design -EMI/EMC analysis -System level design of electronic hardwarefor automotive applications -System level testing and validation of automotive electronics systems for

reliability

Case studies

References

1. Gajski, Principles of Digital Design, Prentice- Hall International, 1997.2. Samir Palnitker, A guide to Digital Design and Synthesis, Pearson Education, 2003.3. Stephen Brown and Zvonko Vranesic, Fundamentals of Digital Logic with Verilog Design, TATA

McGraw Hill, 2002

4. Charles Roth, Digital Systems Design using VHDL, Thomson Books, 1998.5. J Bhasker, A Verilog Premier, 20016. Lionel Bening, Harry Foster, Principles of Verifiable RTL Design, Computers, 20017. Howard. W. Johnson & Martin Graham, High speed Digital Design, Prentice Hall, 2004.Mode of evaluation:Written examination, Seminar, Assignments

Recommended by the Board of studies on : 21.11.2008Date of Approval by the Academic Council: 25.11.2008


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Electronic Hardware System Design Lab

List of Experiments

1. Design a Half & Full Adder using Verilog codes for a general purpose Spartan kit and verifythe outputs by simulation using ISE / ModelSim Simulator.

2. Design a 8 : 1 Multiplexer using Verilog codes for a general purpose Spartan kit and verify theoutputs by simulation using ISE / ModelSim Simulator.

3. Design a 8 bit parity encoder using verilog code for a general purpose Spartan kit and verifythe RTL level abstraction using synthesis tools.

4. Design a 4 binary to gray code encoder using verilog code for a general purpose Spartan kitand verify the RTL level abstraction using synthesis tools.

5. Design a Verilog codes for different logic gates, translate and place the netlist in a generalpurpose Spartan Kit to verify the time delay. Back annotate the above design to reduce the

time delay.

6. Design a Verilog codes for 4:2 decoder and translate and place the netlist in a general purposeSpartan Kit to verify the time delay. Back annotate the above design to reduce the time delay.

7. Using Schematic level abstraction, develop a design for 4-bit Asynchronous UpCounter toimplement for general purpose Spartan Kit and verify the simulated output of the counter.

8. Using Schematic level abstraction, develop a design for 4-bit Johnson Counter to implementfor general purpose Spartan Kit and verify the simulated output of the counter.

9. Design a Finite state machine using verilog for coin vending machine and implement the samefor a general purpose Spartan kit

10. Design a Finite state machine using verilog for Video player machine and implement the samefor a general purpose Spartan kit.

11. Using a general purpose Spartan kit, verify the input and outputs using on-board Switches andleds using any of the above example.


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EEE540 Embedded System Design

L T P C3 0 0 3

Version No.: 1.00

Introduction to Embedded System: An embedded system, processor, hardware unit, soft ware embedded

into a system, Example of an embedded system, OS services, Embedded Design life cycle; Modelingembedded systems

Processor and Memory Organization: Structural unit in as processor, processor selection for an embeddedsystems. Memory devices, memory selection for an embedded system, allocation of memory to programstatements and blocks and memory map of a system. Direct memory accesses.

Devices and Buses for Device Networks: I/O devices, serial communication using FC, CAN devices,device drivers, parallel port device driver in a system, serial port device driver in a system, device driver forinternal programmable timing devices, interrupt servicing mechanism, V context and periods for switchingnetworked I/O devices using ISA, PCI deadline and interrupt latency and advanced buses.

Programming Concepts and embedded programming in C: Languages, Firmware developmentenvironment, Start up code or Boot loader, Abstraction Layers, Application Layer, build download debugprocess of firmware.

Program Modeling Concepts in Single and Multiprocessor Systems: software development process,modeling process for software analysis before software implementation, programming model for the eventcontrolled or response time constrained real time programs, modeling of multiprocessor system.

Inter-Process Communication and Synchronization of Processors Tasks: and threads; multiple process inan application, problems of sharing data by multiple tasks and routines, inter process communications.

RTOS task scheduling models interrupt literacy and response times, performance metric in schedulingmodels, standardization of RTOS, list of basic functions, synchronization.

Reference Books:1. Frank Vahid and Tony Givargis, Embedded System Design: A Unified Hardware / Software

Approach, John Wiley, 2002.2. Steve Heath , Embedded Systems Design, EDN Series ,2003.3. David E simon, An Embedded Software Primer, 1st edition, Addison Wesley 1999.4. Wayne Wolf Computers as components: Principles of Embedded Computing System Design, The

Morgan Kaufmann Series in Computer Architecture and Design, 20085. Jane W. S., Liu, Real time systems, Pearson Education, 2000.6. Raj Kamal, Embedded systems Architecture, Programming and design, Second Edition, 2008.



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Embedded C and Linux Lab

Linux Lab

1. File Handling Using SHELL Scripting2. Print the Environmental variables in Linux using Ca. Printing the environmental variables or the execution environment

b. Printing the System uptime, CPU time and System idle time.3. To create Process in Linux using C

a. To create and terminate a processb. To print the process ID of various Processes in Linux environment

4. MultithreadingTo create a multithreaded application in Linux using C. Two threads are created. One thread forgiving the input from the keyboard and another thread is helpful in converting to upper caseletters.

5. SemaphoresTo initialize the semaphore in Linux. Two threads are working under a binary semaphore in whichone thread is locking the semaphore while the other thread is waiting for the semaphore to bereleased.

6. Shared MemoryCreate a memory block of 1024 bytes and make the memory block shared. One program will readthe contents from this memory and another program will take input from keyboard and write thedate to be memory.

7. PipesCommunication between the parent process and child process using pipes.

C Lab

1. To write a C-Program to accept N integers elements into an arrays and sort them using BUBBLE-SORT Algorithm.

2. Counting Vowels and cousonants program to accept a string of data and cpunt the no of vowelsand cousonants in the input string.

3. Program to implement a Linked List and perform insertion, deletion and display operations on it.4. Program to perform all Arithmatic operations on two nos using LINUX5. Program to SWAP two numbers using LINUX6. Program to Evaluate an ALGEBRIAC EXPRESSION Using LINUX7. 7. Program to find sum and average of N numbers using FOR loop in Linux.8. Program to determine whether entered number is EVEN OR ODD and count them.9. Program to find sum of digits in a no and count them using SWITCH-CASE10. Program to find whether the entered number is an AMSTRONG number.11. Program to print the series in given format12. 12. Program to find the sum of squares of number in series.


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EEE556 Neural Networks and Fuzzy LogicL T P C3 0 0 3

Version No.: 1.00Aims:

To teach the various neural network and fuzzy systems models and the applications of these models tosolve engineering problems.

Learning Outcomes:

To apply the concepts of neural networks, fuzzy logic for practical applicationIntroduction to Artificial Neural Networks: Hours-3

Artificial neural networks and their biological motivation Terminology Models of neuron Topology characteristics of artificial neural networks types of activation functions

Learning Laws: Hours-7learning methods error correction learning Hebbian learning Perceptron XOR Problem Perceptron learning rule convergence theorem Adaline

Feedforward networks: Hours-6Multilayer Perceptron BackPropagation learning algorithm Universal function approximation

Associative memory: autoassociation, heteroassociatio, recall and cross talk

Recurrent neural networks: Hours-4Linear auto associator Bi-directional associative memory Hopfield neural network TravellingSalesman Problem

Unsupervised Learning: Hours-3Competitive learning neural networks Max net Mexican Hat Hamming net

Self Organising networks: Hours-5

Kohonen Self organizing Feature Map Counterpropagation Learning Vector QuantizationAdaptive Resonance Theory

Hours-2Applications of neural networks in image processing, signal processing, modeling and control.

Fuzzy Sets and Fuzzy Relations: Hours-6Introduction classical sets and fuzzy sets classical relations and fuzzy relations membership functions fuzzy to crisp conversion,fuzzy arithmetic, numbers, vectors, and extension principle

Fuzzy Decision Making: Hours-8Classical logic and fuzzy logic fuzzy rule based systems fuzzy nonlinear simulation fuzzy decisionmaking fuzzy control systems fuzzy optimization one-dimensional optimization.

Neuro Fuzzy: Hours-2Mathematical formulation of adaptive neuro-fuzzy inference systems.

Reference books:1. Laurene Fausett, Fundamentals of Neural Networks-Architectures, algorithms and applications,

Pearson Education Inc., 2004.2. Timothy J. Ross, Fuzzy Logic with Engineering Applications, John Wiley and sons, 2004.3. S. Haykin, Neural Networks, A Comprehensive Foundation, Pearson Education Inc., 2004.4. Jacek. M. Zurada, Introduction to Artificial Neural Systems, Jaico Publishing House, 2001.5. J.S.R. Jang, C.T. Sun, E. Mizutani,, Neuro Fuzzy and Soft Computing - A computational Approach to

Learning and Machine Intelligence, Pearson Education Inc., 2002.

Mode of evaluation:Written examination, Seminar, Assignments.



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EEE557 Physical SensorsL T P C3 0 2 4

Version No.: 1.00Prerequisite: None

Aim:

To develop a basic understanding of different sensor types. To teach the principles of various sensors and their characteristics. To teach how fundamental principles can be applied to develop present and future sensor systems.

Learning Outcomes:

The students will have knowledge of different types of mechanical and electrical sensors They will have knowledge of characterization (static and dynamic) of sensors

Sensor fundamentals and characteristicsBasic sensor technology -sensor characteristics static and dynamic Principles of sensing- capacitance-magnetic and electromagnetic induction resistance piezoelectric effect Pyroelectric effect -Hall effect-Seebeck and Peltier effect-heat transfer-light

Analysis of experimental data: causes and types of experimental errors statistical analysis of experimentaldata method of least squares correlation coefficient, multivariable regression graphical analysis and

curve fitting.Strength of materialsStress, strain, Hooks law, Poissons ratio, tensile strength, yield strength, bending stress and yielding

vibration definitions and terminologyPosition, Displacement and Level sensorsPotentiometric and capacitive sensors-inductive and magnetic sensors-LVDT, RVDT, eddy current,transverse inductive, magneto-resistive, Hall effect ultrasonic sensors-thickness and level sensors-ablation,thin film, liquid level sensor

Velocity and Acceleration sensorsLinear velocity sensors Doppler shift, light interference method, seismic devices, -angular velocity sensors

dc and ac tachometer, counter types, hall effect, wiegand effect, absolute angular rate sensors Gyroscopes magnetic speed and direction sensor

Accelerometer dynamics -capacitive, piezoresistive, piezoelectric accelerometers- thermal accelerometer-heated plate, heated gas accelerometers-force balance accelerometerForce, Strain and Tactile sensorsStrain gages, tactile sensor, piezoelectric force sensor torque sensor thrust measurementPressure and Flow sensorsBellows, membranes, thin plates piezo-resistive, capacitive sensors vacuum sensors thermalconductivity gages pirani gage, thermistor gage, thermocouple gage, convection gage ionization gage gasdrag gageFlow sensors -Pressure gradient technique, turbine and vane flow meter, thermal mass flow sensors,ultrasonic sensors, electromagnetic flow sensors, micro flow sensors, Breeze sensors, coriolis mass flowsensors, drag force flow sensors, Laser Doppler Anemometer

Acoustic Sensors

Resistive Microphones Condenser Microphones Fiber -Optic Microphone Piezoelectric Microphones Electret Microphones Solid -State Acoustic Detectors Surface Acoustic Wave sensor Bulk AcousticWave sensor acoustic resonance

Temperature SensorsThermo-resistive thermoelectric -semiconductor PN junction optical acoustic piezoelectrictemperature sensors

References1. Jacob Fraden, Hand Book of Modern Sensors: physics, Designs and Applications, 3rd ed., Springer,

2003.2. Jon. S. Wilson, Sensor Technology Hand Book, Elsevier Inc., 20053.

John G Webster, Measurement, Instrumentation and sensors Handbook, CRC Press, 1999.

Mode of evaluation:Written examination, Seminar, Assignments



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Physical Sensors Lab

Strain, Force, pressure, and torque measurement

i. Strain measurement with Bridge Circuitii. Beam force sensor using Strain Gauge Bridgeiii. Beam deflection sensing with Strain Gauge Bridgeiv. Diaphragm pressure sensor using Strain Gauge Bridge

v. Shear strain and angle of shift measurement of hollow shaftDisplacement measurement

i. Inductive transducer (LVDT)ii. Hall effect sensor

Temperature measurement

i. Thermocouple principlesii. Thermistor and linearization of NTC Thermistoriii. Resistance Temperature Detectoriv. Semiconductor Temperature sensor

v. Current output absolute temperature sensorForce measurement using piezoelectric transducer

Fundamental aspects of error estimation in measurements

-computer aided exercises


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EEE558 Data Acquisition and Hardware InterfacesL T P C3 0 2 4

Version No.: 1.00Prerequisite: Analog and Digital Circuits

Aim:

To impart an in-depth knowledge in sensor signal conditioning, signal conversion, data acquisition,signal processing, transmission and analysis.

To provide a comprehensive coverage of data acquisition methods for sensor systems andhardware interface cards available commercially.

To introduce the students to pSpice and LabView through practical sessions.Learning outcomes:

The students shall be able to gain sufficient practice in sensor signal conditioning, and signalconversion, acquisition, signal processing and analysis using Lab view.

Sensor Signal conditioning circuits:Amplifiers -Instrumentation amplifiers-isolation-chopper and low drift amplifier -Lock-in amplifiers-electrometer and trans-impedance amplifiers-modulation-filters-signal conditioning for resistive sensors,reactive variation sensors and self generating sensors-preamplifier-noise analysis-low noise charge amplifier-cold junction compensation-linearization-conditioning RTD -lead wire compensation, Error budgetanalysis.Power supplies: Constant voltage and constant current regulators, DC-DC converter, SMPS.Basic signal conversion and communication:Converters for different variables to frequency-time parameters of the electrical signals, Sampling concepts,D/A converters, ADC conversion techniques, Serial data communication transmission modes, RS232interface standard, RS485 interface standard. Distributed and stand alone data loggers, IEEE488 standard.Methods of frequency-to-code conversion- standard, indirect and combined counting method, method forfrequency-to-code conversion based on Discrete Fourier transformations. Two wire transmission-four wire,six wire sensing - noise in sensors and circuits-magnetic, capacitive and optical isolation-isolationtransformer-signal averaging.

Data acquisition methods for multi channel sensor systems:Data acquisition method with time-division channeling, data acquisition with space-division channeling, andmain errors of multi channel data-acquisition systems, data transmission and error protection.

Hardware Interface cards:NI DAQ cards - Field point I/O, PCI, PXI, Compact RIO I/O, USB, PCMCIA cards; Agilent dataacquisition unit 34970A.

Virtual Instrumentation (Through Lab sessions):LabVIEW - Graphical user interfaces - Controls and Indicators - 'G' programming - Data type, Functionsand Libraries. FOR loops, WHILE loops, CASE structure, formula nodes, Sequence structures - Arraysand Clusters - Array operations strings and file I/O-graphs and charts.

Introduction to pSpice(Through Lab sessions):Circuit design and simulation.

References:

1. Jacob Fraden, Hand Book of Modern Sensors: physics, Designs and Applications, 3rd ed., Springer,2003.

2. Jon. S. Wilson, Sensor Technology Hand Book, Elsevier Inc., 20053. Pallas Areny. R , Webster. J. G, Sensors and Signal conditioning, 2nd ed. John Wiley and Sons, 2001.4. Taylor H Rosemary, Data Acquisition for Sensor Systems, Kluwer Academic Publishers Group, 1997.

Mode of evaluation: Written examination, Seminar, Assignments



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Data Acquisition and Hardware Interfaces Lab

1. Wheatstone Bridge

2. Signal Conditioning Circuit

3. Digital to Analog Converter

4. Analog to Digital Converter

5. Labview Programming

i. Temperature Conversionii. Debugging and Sub-VI Creationiii. Loops and Waveform Chartsiv. Case statements, Arrays and Clusters

v. Strings and File Input/Output6. Data Acquisition Systems and Lab view

i. Strain Measurement Systemii. Temperature measurement Systemiii. Pressure measurement system


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EEE559 Microcontrollers and Applications

L T P C3 0 4 5

Version No.: 1.00Prerequisite: Digital electronics, microprocessors, C programming

Aim:

To provide knowledge on the basic architecture and the programming concepts of 8051,PIC16F877A microcontroller, free scale HCS12 and ARM processor.

To develop an understanding of basic communication protocols.Learning Outcomes:

Ability to apply timer and A/D subsystems to solve measurement and control tasks. Ability to interface microcontrollers and external circuitry to a variety of sensors and actuators. Develop a Microcontroller based system to interact with real-world systems.

8051 MicrocontrollerIntroduction to Microcontrollers and system design, Assembly and High, Level language programming,

System Development Environment: assembler, compiler and integrated development environment.

8051 Micro controller Hardware, CPU, Registers, features, I/O Ports, Counters and Timers, Serial dataI/O, Interrupts, External Memory Interfacing.

PIC microcontrollerIntroduction to PIC microcontroller Family, PIC16F877A 8 bit microcontroller features, CPU

Architecture, Memory Architecture, Instruction Set, Addressing Modes, Assembly Language Programming,Introduction to MPLAB IDE, Cross compilers, In Circuit Emulators, In circuit Debuggers.PIC microcontroller Hardware PeripheralsPorts, Interrupt Mechanism, RESET mechanism, Timers and Counters, Watchdog Timer, SynchronousSerial Port, LCD Interfacing, ADC module, Capture/Compare/PWM(CCP) module, USART,MSSPmodule

Free scale HCS12 MicrocontrollerMicrocontroller HCS12 architectures, instruction set, addressing modes, memory map, CPU registers,features, interrupt system, Ports, Timers, PWM module, ADC module Programming using Assembly/CLanguageCommunication interfaceSynchronous Serial Interface SPI - description Serial Communication Interface (SCI) -Expansion of I / Ospace -I2C Bus - Principle - Data Transfer on the I2C Bus - Software Implementation RS232 -Parallelport USB; LED, LCD, Keypad-Relays-Solenoids-DC motor- Stepper motor-Case Study- Communicationbetween Multiple Processors.

ARM microcontrollerIntroduction to ARM processor design approaches RISC Vs CISC ARM approach towards RISC.

References:1. Han way Huang, HCS12 / 9s12: An introduction to software and Hardware interfacing

Thomson Learning, 20062. Stevan F. Barrett, Daniel J. Pack, Embedded systems: design and applications with 68HC12 &

HCS12, Prentice Hall, 20043. John B. Peatman , Design with PIC Microcontrollers, Pearson Education Asia, 1997.4. Martin P. Bates, PIC Microcontrollers: An Introduction to Microelectronics, newnes press, 2004.5. Steve Furber, ARM System-on-Chip Architecture (2nd Edition), Addison-Wesley, 2000.6. J. D. Greenfield, W.C. Wray, Using Microprocessors and Micro controllers The Motorola family,

Prentice Hall 4th Ed., 1999.

Mode of evaluation:Written examination, Seminar, Assignments.

Recommended by the Board of studies on : 21.11.2008Date of Approval by the Academic Council : 25.11.2008
http://mail.vit.ac.in/exchweb/bin/redir.asp?URL=http://www.newnespress.com/http://mail.vit.ac.in/exchweb/bin/redir.asp?URL=http://www.newnespress.com/


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Microcontrollers and Applications Lab

8051 Microcontroller

1.Wave generation using 8051micro controllera) Saw tooth wave generation using 8051micro controllerb) Triangular wave generation using 8051micro controllerc) Square wave generation

2. Timer Programming3. Sine wave Generation using 8051 microcontroller4. Serial communication using 8051 microcontroller5. Finding the largest Number using 8051 microcontroller6. Transfer a block of data using 8051 microcontroller

PIC 16F877A Microcontroller

7. Timer interrupta) Timer 0 Interrupt with polling using PIC16F877A microcontrollerb) Timer 0 Interrupt with ISR using PIC16F877A microcontroller

8 . Generation of PWM wave using PIC16F877A microcontroller9. Analog to digital conversion using PIC16F877A microcontroller10. Serial port communication using PIC16F877A microcontroller11. LCD interfacing using PIC16F877A microcontroller12.Waveform generation using PIC16F877A microcontroller

MC68HCS12 Microcontroller

13. Block Move and Block Transfer using MC68HCS12 micro controller

14. ADC programming with MC68HCS12 micro controllera) Without Triggerb) With External Trigger

15. PWM using MC68HCS12 micro controllersa) Edge Alignedb) Center Aligned

16. Square wave Generation using MC68HCS12 microcontrollers17. Pulse Accumulator in Event Count Mode using MC68HCS12


19/33

EEE560 Control SystemsL T P C3 0 2 4


Aim:

To develop an understanding the elements of classical control theory as applied to the control ofsensor systems.

To present concepts related to modeling and control of sub systems To introduce the students to the fundamentals of control theory as applied to the discrete-time

control systems.

Learning Outcomes: Examine sensor systems and subsystems with regard to operation, modeling and control and

develop an appreciation for the design of controller

System Modeling:Mathematical modeling of physical systems- differential equation, difference equation, State variable

representations, examples of modeling different systems(electrical, mechanical, etc.,) Introduction toSimulink.

Performance of Feedback control system:First order, Second order control system response for step, ramp and impulse inputs. Error Analysis - Typenumber -characteristic equation -Poles and Zeroes concept -Error Analysis and performance indices.Frequency response plots -frequency domain specifications -stability analysis- Routh Hurwitz stabilitycriteria Root Locus stability in the frequency domain gain and phase margins Nyquist stabilitycriterion

Controller design:Proportional, Integral, Derivative controllers, P, PI, and PID control actions and mathematical models

(Simulink). Classical design in the frequency domain- lead, lag compensator design.

Introduction to Digital Control System:Discrete Time systems, Sampling and aliasing considerations, System time response, characteristics -Jurys

stability test -mapping s to z plane -Digital controller design: from analog to digital design, State spacedesign methods.

Mat lab Control systems tool box and Simulink:Computer-aided design of compensators using frequency domain methods, simulation of closed loopcontrol systems.

References

1. Katsuhiko Ogata, Modern Control Engineering, Prentice Hall, (4th Edition), 20012. K. Ogata, Discrete-Time Control Systems, Prentice-Hall, Inc., 19943. I.J. Nagrath and M. Gopal, "Control Systems Engineering", New Age International(p) Limited, 4th

Edition, 2006




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Control Systems Lab

1. Mathematical modeling of linear and nonlinear SISO process2. Transfer function and state-space modeling of SISO process3. Frequency response and stability analysis of SISO process4. Designing of controllers using frequency response analysis techniques5. Designing of P, PI, PID controllers using performance criteria6. Designing of lag-lead compensators7. Modeling of Discrete-time system8. Designing of digital controller9. Closed loop control of a DC motor10. Modeling of sensor11. a)Temperature sensor12. b)Flow sensor


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EEE561 Micro and Smart Systems TechnologyL T P C3 0 2 4

Version No.: 1.00Prerequisite: Physical Sensors

Aim:

To teach different methods of micro machining and how these methods can be used to produce avariety of MEMS, including microstructures, micro sensors, and micro actuators Expose the students to design, simulation and analysis software. In addition to this the course covers the various applications of MEMS in different field.Learning Outcomes:

Design of MEMS based systemsIntroduction to smart materials and their applications:Examples aeronautics (control surfaces) aerospace, automobiles engineering9tire pressure sensor),structural health monitoring, biomedical engineering and consumer products (smart shoes, purses, etc).

Smart Materials:Introduction and basic properties of piezo electric, magnetic, polymers shape memory alloys, ferroelectricand rheological materials.

Introduction to Sensors, Actuators and mathematical models:Various domains and classification of transducers: electrostatic, piezoelectric, thermal. Sensing principles:electrostatic, resistive, chemical etc. SAW devices.

Evolution of Microsystems:Benefits of micro systems, concept of micro machines/ micro systems. Scaling laws, nano machines.

Surface Bulk micro machining:Overview of silicon processes techniques, micro machining techniques and special processes for MEMS,polymer MEMS. Recent advances in MEMS fabrication.

Case Studies:Pressure, strain, acceleration and vibration sensors, and micro fluidics: chemical and bio medical sensors.

Electronics for Microsystems:Control in smart systems, signal conditioning in sensors, integration and packaging to Microsystems,System level simulations.

Computer methods in MEMS and micro systems design:MEMS CAD software, coupled models, dynamics.

MEMS and micro systems applications:Details of application in actual systems, introduction to RF- MEMS, MOMS, MOEMS, future of smartstructures and MEMS leading to NEMS.

Packaging, test and calibration of MEMS.Simulation and analysis of the following:

Electrothermal actuator with resistive pad and wax Piezoelectric plate on a thin sheet: vibration, resonance Demonstration of SMA Pressure Sensor Spice design on simple pre amplifiers Mat lab Comsol modeling of transduction principles Design of Micro pumps Simulation of dynamic response of micro systems


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References:1. Tai-Ran Hsu, MEMS & Microsystem, Design and Manufacture, McGraw Hill, 20022. Banks H.T. Smith R.C. and Wang Y.Smart, Material Structures Modeling, Estimation and Control, John

Wiley & Sons, New York, 1996.

3. Massood Tabib Arar, Microactuators Electrical, Magnetic Thermal, Optical, Mechanical, Chemical andSmart structures, Klumer Academic publishers, New York , 1997.4. M.Eluenspoek, R.Wiegerink, Mechanical Microsensors, Springer, 2001.



Micro and Smart Systems Technology Lab

1. RPM Measurement Usinga. Hall Effect Sensor (Bosch)b. Inductive Type Sensor(Bosch)

2. Absolute Pressure measurement using Bosch Pressure Sensor3. Measurement of Engine vibration Using Bosch Piezo electric Sensor4. Measurement of Oil temperature using Bosch Fluid temperature sensor5. Measurement of High pressure (200MPa) Using Bosch High pressure Sensor6. Break Pedal Position measurement using Hall Eeffect sensor7. Simulation of Humidity Sensor using Coventorware8. Simulation of Pressure sensor using Comso Multi physics.


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EEE562 Sensor NetworksL T P C3 0 0 3


Aim:

To teach the basic and advanced concepts in sensor networking architectures and protocols. To expose the students to the recent advances in various wireless networks.Learning Outcomes:

The students will be able to understand the fundamentals and basic features of wireless sensornetworking.

IntroductionAdvantages of Sensor Networks, Habitat Monitoring, Tracking Chemical Plumes, Smart transportation,Collaborative Processing

Localization and TrackingCollaborative Localization, Bayesian state estimation, State space decomposition, data association, Sensormodels

Networking SensorsMedium access control the S-MAC protocol, IEEE 802.15.4 Standard and ZigBee,Energy aware routing Unicast geographic routing, routing on a curve, energy minimizing broadcast,energy aware routing to a region, Attribute based routing directed diffusion, rumor routing, geographichash tables.

Sensor Tasking and ControlTask driven sensing, roles of sensor nodes and utilities, information based sensor tasking IDSQ, clusterleader based protocol, sensor tasking in tracking relations, joint routing and information aggregation multistep information directed routing, sensor group management.

Sensor Network DatabasesQuery interfaces, High level database organization, In-Network aggregation, data-centric storage, dataindices and range queries, distributes hierarchical aggregation, temporal data

Wireless Sensor NetworkingIntroduction, characteristics, applications, technical challenges and design directions.

Local area networks:Ethernet and WLAN.

Reference books:1. Wireless Sensor Networks, Feng Zhao, Leonidas. J.Guibas, Morgan Kaufamann Publishers 2000.2. Introduction to wireless and mobile systems, Dharma Prakash Agarwal, Quing- AnZeng, Vikas

Publishing House.3. Handbook of Sensor Networks: Algorithms and Architectures, Ivan Stojmenovi & Cacute, October

20054. William Stallings, Wireless Communications and Networks, Prentice Hall, 2000.




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EEE563 Optical SensorsL T P C2 0 2 3


Aim: To provide the students with suitable background knowledge to understand the principles underlying

the theory, principles and the wide application of fiber optic sensing.

To teach different types of optical sensors and different optoelectronic sources, detectors, and variousapplication

Learning Outcomes:

The students will be equipped with basic skills required in the design and development of fiberoptic sensor systems.

Optical RadiationElectromagnetic Spectrum, Snells Law and Total internal reflection, Diffraction principles, Generation offree carriers in semiconductors by absorption of electromagnetic radiations

Optical Detectors and SourcesPhototransistors and Photo-darlington pairs, Photoconductive sensors, Photomultiplier Tubes, Photodiodes, APD, Wavelength Sensors, CCD sensors, CMOS active pixel Sensor Technology, Solid state lightsources, LED , Diode lasers, Semiconductor laser optical cavity resonator, Distributed Feedback lasers(DFB),Vertical cavity surface emitting Lasers (VCSELs), Radiometry and photometry, Black-bodyradiation,

Optical FibersMultimode Step Index Fibers, Multimode graded index fibers, Pulse spreading/dispersion in single modeOptical fibers, Material dispersion, Waveguide dispersion, Chromatic Dispersion, Attenuation in opticalfiber-Absorption, Scattering, Polarization Modes in single mode fibers, h parameter and beat Length,

Polarization maintaining fibers, Intensity modulated .

Fiber-Optic sensorsEvanescent Field fiber Optic sensors, Reflection Coefficient Fiber-optic sensors, Moving Grating Fiber-optic Sensors, Micro Bend Fiber-optic Sensors, Fiber Bragg Grating Sensors, FBG fabrication methods,Fiber-optics Temperature and Refractive index sensors, Fiber-optic Curvature Sensors, Integrated Opticalsensors, PMT, Optical sensors used in Satellites.

Interferometric Fiber-Optic SensorsIntensity Interferometry -Basic principles, The Michelson Interferometer, Mach-Zehnder Interferometer,Sagnac Interferometer, Fabry Perot Interferometer, interferometer Sensitivity, Polarization in OpticalFibers, Acousto-Optic devices,-Acousto optic modulators, Analog Acousto optic modulators, Magneto

optic devices, Optical radar, Triangulation methods, Autofocus Methods, Laser Doppler Measurement

References:1. S.O Kasap, Optoelectronics and Photonics , Prentice Hall, 2001.2. Optoelectronics , J.Watson, Van Nostrand Reinhold, 19893. Essence of optoelectronics, K Booth, S.Hill, Prentice hall, 19984. Optical fiber Sensor technology, Grattan K.T.V5. Udd, Eric, Fiber Optic Sensors : An introduction for engineers and scientists ,Wiley, New York ,19916. Agarwal, Govind P, fiber Optic Communication Systems, 2nd edition, Wiley, NewYork,1997




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Optical Sensors Lab

1. (a) To study the Characteristics of Photoelectric Sensor (LDR)(b) Displacement measurement using LDR

2. Characteristics of OPTO Coupler IC3. Study of Bar Code Scanner using transmissive technique.4. Measurement of Absorption Coefficient for Turbulent liquid using optical fiber sensor5. Displacement measurement using triangulation method6. Frequency measurement using optical fiber sensor7. Proximity measurement using optical fiber sensor8. Force measurement using Microbending method of optical fiber9. Gas pressure measurement using reflective type fiber optic sensor.10. Lateral displacement measurement using optical fiber sensor.


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EEE564 Chemical Sensors

L T P C3 0 0 3

Version No.1.00Pre requisite: None

Aim: To teach the students the basic principles of chemical and biosensors and their applications. To keep the students abreast of the technological advancements in the field of chemical and bio-

sensors

Learning Outcomes:

The students will gain knowledge about the state-of-the -art Chemical and Bio-sensors and theirapplications.

Chemical sensor characteristicsSpecific difficulties, Classification of chemical sensing Mechanism, Direct Sensors-Metal oxide chemical

sensors, Chem-FET, Electrochemical sensors, Potentiometric sensors, Conductometric Sensors,Amperometric Sensors, Enhanced Catalytic gas Sensors, Elastometer, Chemi resistors.

Complex sensorsThermal sensors, Pellister Catalytic Sensors, Optical Chemical Sensors, Mass Detector, Bio Chemicalsensors, Enzyme sensors, Chemo-metric multisensor arrays, Electronic Noise , (Oil factory sensors).

Thick film and Hybrid techniques in Sensor production:Examples of thick film and hybrid sensors, introduction to thick film technology, pastes and substrates-basic material, components, manufacturing layer systems, production, quality control, circuit layout, designrules, print cycles, screen manufacturing, screen printing, parameters, drying, and sintering.Comparison: thick film Vs thin film technologies, structure devices, assembly, packaging. SMT, active and

passive devices SMD, connection technology, soldering process, adhesive employment, chip on boardprocess, die and wire bonding, welding process, packaging.

Reference:1. Biosensor Principles and Applications, Edited by Loc J.Blum, Pierre R. Coulet2. W.Gopal,J Hesse, J N Zemel, Sensors A comprehensive study, VCH Press, 1989.3. Sabree Soloman, Sensors Hand Book, McGraw Hill, 1998.

Mode of Evaluation :Written examination, Seminar, Assignments.

Recommended by the Board of studies on : 21.11.2008

Date of Approval by the Academic Council: 25.11.2008


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EEE565 RF and Microwave Sensors

L T P C3 0 0 3

Version No.: 1.00Pre requisite: Electromagnetic field Theory

Aim: To introduce to the students the different RF and Microwave sensors, their parameters and their

applications

To also introduce to them the RFID technologyLearning Outcomes:

To select a proper sensor in the RF and microwave range depending on the environment andapplication.

To gain knowledge about the RFID technology.

RF Sensors:Microwave Antenna-Introduction, types of Antenna, fundamental parameters of antennas, radiationmechanism. Proximity sensors, Motion sensors.

Radar:Introduction to RADAR, RADAR range equation, pulse RADAR, applications of RADAR, factorsaffecting the performance of RADAR, RADAR transmitters, Receivers, RADAR antennas, CW RADAR,applications, MTI and pulse Doppler RADAR, Tracking RADAR, SAR, LIDAR.Radiometers:Radiative transfer theory, SMMR, Types of radiometers - Applications IR thermometers, Pyrometers, andBolometers.

Microwave Power Sensors:Diode Sensors: Diode detector principles, dynamic range average power sensors, signal waveform effectson the measurement uncertainty of diode sensors.

Thermistor Sensors: Principles, coaxial thermistor sensors, waveguide thermistor sensor, thermistors aspower transfer standards.

Thermocouple Sensors: Principles of Thermocouple sensor, power meters for thermocouple sensors.

RFID Technology:Introduction, Components of RFID systems, hardware and software components, RFID standards, RFIDapplications.

References:1. Constantine A. Balanis, Antenna Theory Analysis and Design, John Wiley & Sons Third Edition,

2005.2. Lillesand & Kiefer, Remote Sensing and Image Interpretation, John Wiley & Sons, 2000.3. Finkenzeuer Klous, RFID Handbook, 2nd edition, Chicesten, England, John Wiley and Sons, 2004.4. B.Hoffman - Wellenhof, H.Lichtenegger and J.Collins, "GPS: Theory and Practice ". 4th revised edition,

Springer, Wein, New York, 1997




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EEE566 Sensors for TransportationL T P C3 0 0 3

Version No.: 1.00Prerequisite: Physical Sensors

Aim:

To give an overview of automotive sensors of different types, their principles and applications. To bring an awareness of a variety of challenges that automotive environment presents to the sensor

designer.Learning Outcomes:

The students will be well aware of the future technologies in the automotive field and be made capableof handling the challenges.

Introduction to Automotive EngineeringPower-train, Combustion Engines, Transmission, Differential Gear, Braking Systems

Automotive Management systemsIntroduction to Modern Automotive Systems and need for electronics in Automobiles, Application areas ofelectronics in the automobiles, Possibilities and challenges in the automotive industry, Enabling

technologies and Industry trends.Power train Sensors: sensors, exhaust temperature sensor, Nox sensor, PM sensor, fuel quality sensor, level sensor, torquesensor, speed sensor, mass flow sensor, manifold pressure sensor.Sensors for Chassis management:

Wheel speed sensors/direction sensors, steering position sensor(multi turn), acceleration sensor(inertiameasurement), brake pneumatic pressure sensor, ABS sensor, electronic stability sensor.Sensors for Vehicle body management:Gas sensors (CO2), temperature/humidity sensor, air bag sensor, key less entering sensor, radar sensors.Sensors for Automotive Vehicle Convenience and Security Systems

Tire pressure monitoring systems, Two wheeler and Four wheeler security systems, parking guide systems,anti lock braking system, future safety technologies. Vehicle diagnostics and health monitoring, Safety and

Reliability, Traction Control, Vehicle Dynamics Control,accelerators and tilt sensors for sensing skiddingand anti collision - anti collision techniques using ultrasonic Doppler sensors.

Air Bag and Seat Belt Pre tensioner SystemsPrincipal Sensor Functions, Distributed Front Air Bag sensing systems, Single-Point Sensing systems, Side-Impact Sensing, and Future Occupant Protection systems.Passenger Convenience Systems:- Electromechanical Seat, Seat Belt Height, Steering Wheel, and Mirror

Adjustments, Central Locking Systems, Tire Pressure Control Systems, Electromechanical Window Drives,etc.Modern Trends and Technical SolutionsEnabling Connectivity by Networking:-In vehicle communication standards, Telematic solutions, Portableor embedded connectivity, Endorsing Dependability in Drive-by-wire systems :- Terminology andconcepts, Why by-wire?, Requirements on cost and dependability, Drive-by-wire case studies and

prototypes , System Architecture Trends:-Topologies, ECUs and three levels of concerns , Distribution ofcontrol in cluster networks Software and functional architectures, Future dominating industry standards

References:1. Automotive Electrics, Automotive Electronics 4th Edition: Systems & Components , BOSCH. 20052. Automotive Sensors, BOSCH. 20023. Ronald K.Jurgen, Sensors and Transducers, 2nd Edition, SAE, 2003.4. Ernest O. Doebelin, Measurement Systems Application and Design, 4 th Edition, McGraw-Hill,

20005. Tai-Ran Hsu, MEMS & Microsystem, Design and Manufacture, McGraw Hill, 2002Mode of evaluation:Written examination, Seminar, Assignments



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EEE567 Biomedical Sensors

L T P C3 0 0 3


Aim: To impart basic understanding of different types of bio-medical sensors. To teach how fundamental principles can be applied to develop present and future biomedical sensor

systems.

Learning Outcomes:

The students will be able to understand the conduction techniques of bioelectric signals and thevarious measurement methods.

Origin and Transmission of bioelectrical SignalsThe Nervous System and the Nerve Cells (Neurons), Electrical Potentials and Propagation of NerveSignals, Resting Potential across the Membrane , Propagation of Nerve Signal ,Electrodes ,The Electrode-Skin Interface and Motion Artifact ,Conduction Techniques of bioelectrical Signals

The Electromyogram (EMG) & the Electrocardiogram (ECG)The Electromyogram (EMG),Anatomical and physiological Basics, Creation and Description of the ECG,Derivation Methods, Einthoven Derivations ,Goldberger Derivations, Wilson-Chest Wall Derivations,Diagnostic Evaluation of the ECG, Cardiac Pacemakers

The Electroencephalogram (EEG) & Blood pressure measurementBioelectric Potentials from the Brain, The Derivation Technique, The electrical signals from the Brain,Normal EEG, Abnormal EEG, Evoked Potentials, Blood Pressure-, The Cardiovascular System,Measurement of the Blood Pressure, Indirect, noninvasive blood pressure measurement, DirectMeasurement of the Blood Pressure

Determination of the Arterial O2-Saturation of the Blood: The Pulse OxymetryOxygen Supply of the Organism, Optical Properties of the Hemoglobin, Arterial Oxygen Concentration ,Principle of the Pulse-oxymetry, Layer-Model ,measurement Method of the O2-Saturation, Calculation ofthe partial Oxygen Saturation ,Limitations of the pulse oxymeters, Technical Aspects ,Light Source,Measurement Method and Sensor System ,Signal Evaluation , Calibration and measurement stability

References:1. Medical Instrumentation; Application and Design; J. G. Webster, Editor, 3. Edition, 1998; John Wiley

& Sons, Inc., New York2. Medical Physics; J. R. Cameron, J, G, Skofronick; 1978; John Wiley & Sons, Inc.; New York3. Bioelectricity and Biomagnetism; John Wiley & Sons, Inc. 1998, ISBN 0-471-24852-(RG)




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EEE568 Bio-Sensors

L T P C3 0 0 3

Version No.: 1.00Prerequisite: Chemical Sensors

Aim: The objective of this course is to provide a solid foundation and to help the students to understand

the modern biological sensor principles and application technology.

It also aims in providing the student with the ability to operate with existing biosensor systems andtransducers.

Learning outcomes:

The student will be able to understand the biosensing and the transduction principle. They will be aware of the technological advancements in the field of biosensors.

Introduction:

A historical perspective, signal transduction, physio-chemical and biological transducers: sensor types andtechnologies, Overview of Biosensors, Fundamental elements of biosensor devices, Fundamentalengineering aspects of biosensors, Signal processing for biosensors.

Physio-chemical transducers:Electrochemical transducers (amperometric, potentiometric, conductometric), semiconductor transducers(ISFET, ENFET), optical transducers (absorption, fluorescence, bio-chemiluminescences, SPR), thermaltransducers, piezoelectric and acoustic wave transducers, limitations and problems, an overview ofperformance and applications.

Biosensors:Catalytic biosensors, mono-enzyme electrodes, bi-enzyme electrodes, enzyme sequence electrodes and

enzyme competition electrodes, affinity-based biosensors, inhibition based biosensors, cell basedbiosensors, biochips and biosensor arrays, problems and limitations.

Biosensor Engineering:Methods for biosensors fabrication, self assembled monolayers, screen printing, photolithography, microcontact printing, MEMS, concepts for mass production.

Applications:Clinical chemistry- test strips for glucose monitoring, urea determination, implantable sensors for long termmonitoring, drug development and detection, environmental monitoring, technological process control,food quality control, forensic science benefits.

References:1. Alice Cunningham, Introduction to Bioanalytical Sensors, John Wiley, 2000.2. Brian Eggins, Chemical Sensors and Biosensors, John Wiley and Sons, 2002.3. Graham Ramsay, Commercial Biosensors, John Wiley and Sons, 1998.




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EEE601 Technical communications

L T P C1 0 4 3

Version No.: 1.00

Aim:To introduce the learners to the nuances of various genres of technical communication, both oral andwritten

To guide students through self-study and assignments, in performing their communicative tasks in real-life work environment.

Learning Outcome:

The students oral and written communication skills will be strengthened, so that they can achieve theirprofessional goals more effectively.

Role and importance of communication:

Effectiveness in oral and written communication; technical reports; technical proposals; Research Papers,Interpersonal Communication; business correspondence; prcis writing; memorandum; notices, agenda andminutes; oral communication related to meetings, seminars, conferences, group discussions, etc.; use ofmodern communication aids.

Process of Communication:Barriers to Communication, Technology in Communication, Active Listening, Effective Presentation,Fundamentals of Writing, Letters, Group communications, Job interviews, Report writing, draftingproposals, research papers writing, dissertation and thesis writing, drafting instruction manuals andtechnical descriptions

References:

1. Raman Meenakshi and Sangeeta Sharma. 2004. Technical Communication: Principles and Practice.Oxford University Press, 20042. Stevenson, Susan and Steve Whitmore, Strategies for Engineering Communication, Wiley Singapore

Edition .20023. Gerson, Sheron J and Steven M. Gerson, Technical Writing, 3rd Edition, 2000 Delhi Addison Wesley

Longman Pte. Ltd.




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GER501 German for Beginners

L T P C2 0 0 2

Aims and objectives

The course aims at basic written and oral skills (comprehension and expression) in German which willenable the students to have the know-how in the target language. As a whole, it will bring an idea about theGerman culture and society.

Learning OutcomeThe learners will get the required training in the target language which will enable them to practice it in dayto day life, in higher education and in career too.

Lektion IDie Einleitung, Gren, Personalpronomen, Konjugation von Verben

Lektion II

Possessivpronomen, Verb- Sein, Singular, Plural, Wortbildung, Ja/ Nein Frage und Fragewoerter, Tempus-Praesens, Dialoge.

Lektion IIINegation, Zahlen, Maskulin, Feminin und Neutrum. Kasus, Das Essen und Leben in Deutschland.

Lektion IVDie Zeit, Starke Verben, Praepositionen, Bestimmter und Unbestimmter Artikel

Lektion VModal Verben, Dialoge mit Kontext: Freizeit und Arbeit

Text BooksHartmut Aufderstrae, Heiko Bock, Jutta Mller, Themen Aktuell-1, Deutsch als Fremdsprache: 2007.

Reference Books1. Gick, Cornelia, Momentmal, Grundstufenlehrwerk Deutsch als Fremdsprache.M: 20052. Maria Dallapiazza, Eduard von Jan, Til Schonherr.Tangram, Deutsch als Fremdsprache.Berlin: 20053. Griesbach, Schulz. Deutsche Sprachlehre fr Auslnder.Mnchen: 2005Mode of evaluation1. Written examinations/quiz/Assignments/seminars2. Term End Examination.


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MGT501 Creativity and Innovation in ManagementL T P C3 0 0 3

Course Objectives :

To understand techniques of being creative and inculcating creative culture in the organization. To know the different types and forms of innovation and techniques adopted for effective

innovation.

To apply the knowledge gained in a practical situation and prepare a case.Learning Outcome :

Students will be aware of various creative problem solving methodologies and be able to apply thesame in day to day life.

Students will know the factors influencing innovation and be able to suitably apply to create aninnovative culture in an organization.

Students will be equipped to demonstrate process innovation.1. Creativity for Managers : 15 hrs

Creativity - Creative thinking Theories of creativity Creativity Map Creative Personality -Creative Intelligence Creative Environment Blocks to creativity Techniques of creativity

Creative problem solving process Evaluation Methods Case Study.

2. Innovation in Management : 15 hrsInnovation Types of Innovation Application in Management Different Models of innovation Role of knowledge Management in Innovation Strategic Innovation Building Innovative Culture

Leadership for innovation ICT enabled Innovation Learning organizations Metrics andMeasurement of Innovation Case Studies.

3. Managing Innovation in Organization : 15 hrsProduct Innovation Process Innovation Market Innovation Strategies -Sustaining Innovation inorganization Organizational Structure for Managing Innovation Change Management Models Models of Technology Transfer Role of Technology Transfer in Innovation Organizational

Factors Managing Intellectual property Case Studies.

Text Books :1. Creative Problem Solving for Managers

By Tony ProctorII Edition, Routledge Publishers, UK, 2005

2. Innovation Management and New Product DevelopmentBy Paul TrottII Edition, Prentice Hall,UK,2002

3. Innovation Driving Product, Process and Market ChangeEdition : Edward B RobertsMIT Sloan Management Review

Jossey Bass; John Wiley & Sons Inc, USA, 2002

Reference Books :1. Fourth eye, Excellence thro creativity

By Pradip N.KhandwallaII Edition, Wheeler Publishing, New Delhi, 1992

2. Creativity at Work; Developing the right practices to make Innovation happenBy Jeff Degraft & Katherine A. LawrenceUniversity of Michigan Business School, Johnailey , USA, 2006

3. Effective InnovationBy John AdairRupa.Co, New Delhi, 2002

4. InnovationBy W.R. Spence

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