03.801 DIGITAL CONTROL SYSTEMS (A) 2-1-0

Module I (Quantitative analysis)

Introduction to Digital control system. Z plane analysis of discrete control systems – Impulse sampling and data hold - pulse transfer function - Realization of digital controllers. Design of discrete time control systems by conventional methods - Mapping between the S plane and the Z plane. Stability analysis in the Z plane. Transient and steady state response analysis. Design based on the root locus and frequency response methods.

Module II (Quantitative analysis)

State space analysis – State space representations – Solving discrete time state space equations – pulse transfer function matrix – Discretization of continuous time state space equations – Liapunov stability analysis. Pole placement and observer design – Introduction – controllability – observability – Transformations in state space analysis and design – design via pole placement – state observers – servo systems.

Module III (Quantitative analysis)

Polynomial equation approach to control systems design - Introduction – Diophantine equation – Design – Design of model matching control systems. Optimal control – Introduction – Discrete Euler – Lagrange equation – Time optimum control with energy constraint - Design of optimal linear digital regulator – Principle of optimality and dynamic programming – Solution of the discrete Riccati equation – Sampling period sensitivity. Quadratic optimal control systems – Introduction – Steady state quadratic optimal control.

Text Books:

1. Ogata K., Discrete-time Control Systems, 2/e , Pearson Education.

2. Kuo B. C , Digital Control Systems , Second edition , Saunders College Publishing, Japan, 1992.

References:

1. Phillips C. L. and Nagle H. T, Digital Control System Analysis and Design, 3/e Prentice-Hall.

2. Astrom K. J and Wittenmark, Computer Controlled Systems Theory and Design, Second edition, Prentice Hall, New Delhi , 1990.

3. Gopal M., Digital Control and State Variable Methods, Tata McGraw Hill, New

Delhi, 1997.

4. Charles L. Phillips, H. Troy Nagle, Digital Control System Analysis and Design, ISA Press, New York,

1995.

5. Gene F. Franklin and David Powell, Digital Control of Dynamic Systems, 3/e , Pearson Education

Question Paper

The question paper shall consist of two parts. Part I is to cover the entire syllabus, and carries 40 marks. This shall contain 10 compulsory questions of 4 marks each. Part II is to cover 3 modules, and carries 60 marks. There shall be 3 questions from each module (10 marks each) out of which 2 are to be answered.

Assignment for Sessional marks shall be problems based on Matlab / any other software packages covering the syllabus above.

03.802 COMPUTERISED PROCESS CONTROL (A) 2-1-0

Module I (Quantitative Approach)

Fundamentals of automatic process control – Building blocks of automation system – Multiprocessor systems – Local Area Networks – SCADA – Remote Terminal Unit – Direct Digital Control – DDC structure – DDC Software. Display systems – Real-Time programming – Distributed Digital Control – Functional requirements of distributed process control system – System architecture – Popular distributed control systems.

Module II (Quantitative Approach)

Logic Controllers – Combinational – Sequential – Synchronous Asynchronous – Logic controllers using PLDs – Combinational PLDs – Sequential PLDs – PLCs – Hardware – i/p modules – o/p modules – PLC programming and operation – Relay logic – Ladder diagram – Timers – Counters – PLC processors, Advantages of PLC control – Microprocessor based PLCs - Micro PLCs – Analog interfacing – Standards for PLC programming – Commercially available PLCs.

Module III (Quantitative Approach)

Field bus – Protocols – MODBUS – PROFIBUS – FIPBUS. Applications of SCADA systems, PLC controllers and Distributed control systems in - Cement plant – Thermal plant – Water treatment plant – Steel plant – Irrigation canal. Intelligent controllers – Model based controllers – Artificial Intelligent based systems. Fuzzy systems – Fuzzy controller, Fuzzy Logic Tools. Neural controllers. Artificial Neural Network – Classification, Learning rules, Multilayer ANN.

Text Books:

1. B G Liptak : Process Control Handbook

2. Krishnakant : Computer based Industrial Control : PHI

3. E A Parr : Programmable Controllers : 2/e, Newnes publications

4. Enrique Mandado, Jorge Marcos: Programmable Logic Devices and Logic Controllers, Prentice Hall

5. Gray Dunning : Introduction to PLCs, Delmar Thomson learning pub

References:

1. George L Batten : Programmable Controllers , 2/e, MGH

2. Christopher T Kilian : Modern Control Technology : Components and Systems, 2/e, Thomson

Delmar Pub.

Question Paper

03.803 INDUSTRIAL INSTRUMENTATION (A) 2-1-0

Module I

Atomic Spectroscopy – Properties of EM Radiation – spectrochemical measurements. Atomic absorption and Atomic fluorescence spectrometry. Atomic emission spectrometry. Atomic Mass spectrometry. Atomic X-Ray spectrometry.

Module II

Molecular spectroscopy – Ultraviolet / visible molecular absorption spectrometry – Introduction and applications. Molecular Luminescence spectrometry. Infrared spectrometry – Introduction and applications. Raman spectroscopy.

Module III

Nuclear magnetic resonance and Molecular mass spectrometry. Chromatography – Introduction to chromatographic separations. Gas and Liquid chromatography. Supercritical fluid chromatography and capillary electrochromatography.

Text Book:

1) Skoog, Holler, Nieman, Principles of Instrumental Analysis, 5^th edn., Harcourt Asia

References:

1) R S Khandpur, Handbook of Analytical Instruments

2) Doebelin, Measurement Systems, 5^th edn., Mc Graw Hill

3) Patranabis, Principles of Industrial Instrumentation, 2^nd edn., TMH

Question Paper

03.804 OPTICAL INSTRUMENTATION (A) 2-1-0

Module I

Optical fiber measurements : Cylindrical fiber – Transmission characteristics –Attenuation, Material absorption losses, Intermodal and intramodal dispersion - Attenuation measurements, Absorption and scattering loss measurement, Fiber dispersion measurements, Time domain & frequency domain measurements, fiber refractive index profile measurements, Fiber cutoff wavelength and numerical aperture measurements, Fiber diameter measurements, refletana and optical return loss, Field measurements, OTDR.

Module II

Holography & Interferometry: Principles of Holography, Gabor’s hologram, Leith’s and Upatneik’s techniques in holography, Point holograms, Fourier transform holograms, various types of holography, acoustic holography, holographic interferometry, Applications of holography with emphasis on instrumentation. Interferometry, Youngs experiments, Fresnels Biprism, Michelson, Jamin, Mach-Zender & Fabry Perot interferometers, Applications of interferometers such as testing of optical components.

Module III

Optical fiber sensors : Intensity modulated optical fiber sensors, Reflective Evanescent wave and microbend fiber optic sensors, Fiber optic refractometers & thermometers, Chemical analysis, Distributed sensing with fiber optic sensors, Principles and applications of interferometric optical fiber sensors.

fiber sensor for current measurement, Fiber optic pressure sensors, Fiber optic flow meter, Fluoro optic temperature sensors, fluid level detection, displacement sensors.

References:

1) Wilson J F B Hawkes – Optoelectronics An Introduction – Second edition , Prentice Hall of India Pvt. Ltd.

2) John M Senior, Optical Fiber Communications, Prentice Hall, 1996

3) B P Pal – Fundamentals of Fiber Optics in Telecommunication & Sensor Systems – Wiley Eastern Ltd. 1991

Question Paper

03.805 (1) MULTIRATE Systems & WAVELETS (Ta) 3-1-0

(Elective V)

Module I (Quantitative Approach)

Review of Multirate Signal Processing. Maximally decimated filter banks – QMF banks – M-channel filter Banks – polyphase representation – PR Systems - Alias-free filter banks – Structures – Trans- multiplexers. Para unitary PR filter banks – Properties – QMF banks and structures – Transform coding and the LOT. Linear phase PR QMF banks and structures. Cosine modulated filter Banks and its structures. Sub band and orthogonal transform coder.

Module II (Quantitative Approach)

Brief review of Linear algebra and vector spaces – Vector spaces – Subspace – Linear transformations – Orthogonal projection – Hilber space - L²(R) space. Continuous wavelet Transform. Discrete wavelet Transform – Introduction – Nested Linear vector sub spaces – Definition of an MRA – Example – construction – A wavelet basis for the MRA – Digital filtering Interpretation – Examples – Interpreting orthogonal MRAs for discrete time signals. Biorthogonal wavelet bases and examples. Two dimensional wavelets and examples.

Module III (Quantitative Approach)

Wavelet Transform Applications – Data compression – Transform Coding – DTWT for Image compression – Audio compression – Video coding – Wavelet de noising – Speckle removal – Edge detection – Image fusion – Object detection – Scaling functions – Multi tone modulation. CWT and DWT – Operations and algorithms – Regularity and convergence – Daubechies construction – Band limited bi-orthogonal decomposition – Design and selection of wavelets – Reconstruction circular convolution filter banks – interpolators matched to the input process.

References :

1. P. P. Vaidyanathan: Multirate Systems & Filter Banks , PTR, PH, 1993

2. Gilbert Strong : Linear Algebra and its Applications.

3. Reghuveer M Rao, Ajit S Bopardikar: Wavelet Transforms – Introduction to Theory and Applications, Pearson Education Asia, 1998.

4. Strang G S, T Q Nguyen: Wavelets and Filter Banks, Wellesley – Cambridge Press 1996.

5. Burrus C S, R A Gopinath and H. Gao: Introduction to Wavelets and Wavelet Transforms: A Primer, Prentice Hall, 1998.

Question Paper

Assignment for Sessional marks shall be problems based on MATLAB / any other software packages covering the syllabus above.

03.805 (2) INTEGRATED OPTICS & PHOTONIC SYSTEMS (Ta) 3-1-0

(Elective v)

Module I

Integrated photonics: history and characteristics, integrated photonics technology, basic

Integrated photonics components, IP devices, electromagnetic waves, Maxwell’s equations, wave equation in dielectric media, monochromatic waves in dielectric media, polarization of EM waves, light propagation in absorbing media, EM waves at planar dielectric interface, boundary conditions at the interface, reflection and transmission coefficients, total internal reflection

Module II

Integrated optic waveguides, optical waveguides, modes in planar waveguides, wave equation in planar waveguides, guided modes in step index planar waveguide and channel waveguides, Marcatili’s method and effective index method, graded index planar waveguides, multilayer and ray approximations, reconstruction of index profiles, inverse WKB method, modal coupling, coupled mode equations, co directional and contra directional coupling, diffraction gratings in waveguides, coupling coefficients in modulation index and relief diffraction gratings

Module III

Light propagation in wave guides: beam propagation method, paraxial propagation method, fresnel equation, Fast Fourier transform method based on finite differences, boundary conditions, transparent boundary conditions, spatial frequencies filtering, modal description based on BPM, modal field calculation using BPM

Textbooks:

1. G. Lifante - Integrated Photonics: Fundamentals - John Wiley & Sons 2003

2. P Battacharya - Semiconductor Optoelectronic Devices – 2/e– Pearson Education - 2001

Question Paper

03. 805 (3) SOFTWARE ARCHITECTURE & SYSTEMS (TA) 3-1-0

(Elective V)

Module I (Quantitative Approach)

Software process and the role of modeling and analysis, Software architecture, and software design.

Software Modeling and Analysis : analysis modeling and best practices, Traditional best practice diagrams such as DFDs and ERDs, UML disgrams and UML analysis modeling, Analysis case studies, Analysis tools, Analysis patterns.

Module II (Quantitative Approach)

Software Architecture : Architectural styles, Architectural patterns, Analysis of architectures, Formal descriptions of software architectures. Architectural description lnguages and tools, Scalability and interoperability issues, Web application architectures, Case studies.

Module III (Quantitative Approach)

Software Design: Design best practices, Design patterns, Extreme programming, Design case studies, Component technology, Object oriented frame works, distributed object request brokers, case studies.

Reference:

1. Booch G, Rumbaugh, J. Jacobson : The Unified modelling Language User Guide, Addison-Wesley,

1999

2. Gamma, E. Helm, R. Johnson, R. Vissides : Design Patterns, Elements of Reusable Object-Oriented Software Architecture, Volume I: A System of Patterns. John Wiley & Sons, 1996

3. Shaw M, Garlan D: Software Architecture : Perspectives on an Emerging Discipline, Prentice Hall, 1996

4. Len Bass et al: Software Architecture in Practice – Addison Wesly, 1998.

Question Paper

03.805 (4) ARTIFICIAL NEURAL NETWORKS (Ta) 3-1-0

(Elective V)

Module I

Introduction – uses of neural networks, Biological neural networks- neuro physiology, models of a neuron-Mc Culloch & Pitts model, Activation functions- types, multiple input neurons.

Learning processes- learning paradigms- supervised and unsupervised learning.

Single layer perceptrons-Architecture-learning rule- Perceptron convergence theorem.

Performance learning-Quadratic functions-performance optimization-steepest descent algorithm, learning rates, Widrow-Hoff learning- ADALINE networks, LMS algorithm, linear separability- The XOR problem, Multilayer Perceptrons (MLPs)- Backpropagation algorithm.

Module II

RBF networks- Cover’s theorem on separability of patterns, comparison of RBF networks and MLPs.

Associative learning- Unsupervised Hebb rule, Instar and outstar rules.

Competitive learning- Winner –Take-All networks, Learning Vector Quantizers, Counter propagation networks, Adaptive Resonance Theory (ART)- ART1 clustering algorithm, ART1 network architecture.

Module III

Self Organizing Maps (SOM), Principal Component Analysis (PCA) networks.

Hopfield networks – Discrete Hopfield networks- energy function- storage capacity of Hopfield networks, Optimization using Hopfield networks- Travelling salesperson problem, solution of simultaneous linear equations, character retrieval. Boltzmann machines. Simulated Annealing.

References:

1. Martin T. Hagan, Howard B. Demuth & Mark Beale : Neural Network Design, Vikas Thomson learning.

2. Simon Haykin : Neural Networks- A Comprehensive Foundation, Pearson Education.

3. Kishan Mehrotra, Chilukuri K. Mohan, Sanjay Ranka: Elements of Artificial Neural Networks, Penram International Publishing(India).

4. James A Freeman, David M. Skapura: Neural Networks- Algorithms, Applications and Programming Techniques , Pearson Education.

5. Bose & Liang : Neural Network Fundamentals, Mc Graw Hill.

Question Paper

03.805 (5) CDMA SYSTEMS (Ta) 3-1-0

(Elective V)

Module I (Quantitative Approach)

Introduction to CDMA. Multiple access using spread spectrum. PN Codes. Link analysis- Shadowing, Multipath Rayleigh Fading, Multipath Delay Spread. Principles- Capacity, Power control, Hands off. Link Structure - Asymmetric link - Forward link - Reverse Link. Call Processing - states. CDMA Design Engineering.

Module II (Quantitative Approach)

Direct Sequence and Frequency Hopped Spread Spectrum, Spreading sequences and their correlation functions, Acquisition and tracking of spread spectrum signals, Error probability for DS-CDMA on AWGN channels. DS-CDMA on frequency selective fading channels, Performance analysis of cellular DS-CDMA.

Module III (Quantitative Approach)

Effect of imperfect power control on DS-CDMA performance, Spreading/Coding trade offs. Multi-carrier CDMA, IS-95A CDMA system. Third generation CDMA systems, Multi-user Detection-Optimum receiver, MMSE, Decorrelation, SIC, PIC receivers and performance.


References:

1. Samuel C Yang, CDMA RF System Engineering, 1998, ARTEC HOUSE Inc,

2. Andrew J Viterbi, CDMA: Principles of spread spectrum Communication, Addison-Wesley, 1996

3. Sergio Verdu, Multiuser Detection, Cambridge University Press, 1998

Question Paper

03.806 (1) ADAPTIVE SIGNAL PROCESSING (Ta) 3-1-0

(Elective VI )

Module I (Quantitative Approach)

Optimum linear filters – Optimum Signal Estimation – LMS error estimation – solution of the Normal Equations – Optimum FIR filters – Linear Prediction – optimum IIR filters – Inverse filtering and deconvolution – channel equalization in data transmission systems – matched filters and Eigen filters.

Algorithms for optimum Linear filters – order recursive algorithms for optimal FIR filters – Levinson and Levinson Durbin algorithms.

Module II (Quantitative Approach)

Structures for optimum linear filters – Lattice structures – Algorithm of schiir – Triangularization and inversion of Toeplitz Matrices – Kalman Filter algorithm. Least squares filtering and prediction – Principles – Error estimation – LS FIR filters – Linear LS signal estimation – LS computations using Normal equations, orthogonalization techniques and singular value decomposition.

Module III (Quantitative Approach)

Adaptive filters – principles – typical applications – Method of Steepest Descent – LMS adaptive filters - Recursive LS adaptive filters. Array fundamentals – RLS algorithms for Array processing – Spatial filtering – Adaptive spatial filtering – Space time adaptive processing. Performance of adaptive algorithms.

Text Books:

1) Dimitris G. Manolakis, Vinay K Ingle, Stephan M Krgon : Statistical and Adaptive Signal Processing, Mc Graw Hill, 2000.

2) Simon Haykin: Adaptive Filter Theory, 3^rd edn., Prentice Hall International Editions, 1996.

Reference:

Windrow, Stearns: Adaptive Signal Processing, Pearson Education, 2001

Question Paper

Assignment for Sessional marks shall be problems based on MATLAB / any other software packages covering the syllabus above.

03.806 (2) EMBEDDED SYSTEMS (Ta) 3-1-0

(Elective VI)

Module I (Quantitative Approach)

Introduction to Microprocessors and Embedded RISC processors, Architecture of the MPC 860 processor and Power PC core, Instruction set, Programming model, Exception handling and processing, MMU, Instruction and Data Cache, Memory controller, Communication Processors Module and Serial Interface, Serial Management Controller and Serial Communication Controller.

Module II (Quantitative Approach)

UART, HDLC and Ethernet Protocol, SDMA channels and IDMA emulation, CPM interrupt controller and CPM timers, SPI, I2C and Parallel ports, Reset, Clock, Power control External bus interface, System Development and Debugging. Real Time System concepts, Kernel structure, Task management, Time management, Inter task communication & synchronization, Memory management.

Module III (Quantitative Approach)

8096 processor architecture – High speed registers, Serial output ports, Programmable timers, PW registers. Instruction set, Assembly language programming, Hardware interfacing, Memory. Architecture of 68C11, Instruction set, Programming.

Text Book:

1. Cathy May and Ed Silha, The Power PC Architecture, Morgan Kauffman, 1998

References:

1. 16 bit embedded Controller Hand book - Intel 1990.

2. The Programming Environment for 32-Bit Microprocessors, Motorola

3. MPC860 User’s Manual, Motorola

4. David L Ripps, An Implementation guide to Real Time Programming, Yourdon Press, 1990

Question Paper

03.806 (3) MICROCONTROLLER BASED SYSTEM DESIGN (Ta) 3-1-0

(Elective VI)

Module I (Quantitative Approach)

History of microcomputers, Application of embedded controllers, Over view of 8051, 8096, 6811, 6812. 6812 architecture, 68HC12 Hardware system, Modes of operation, Hardware pin assignments, 68HC12 sub system.

Module II (Quantitative Approach)

Programming model, Assembly language, instruction execution cycle, Instruction set, Addessing modes, Advanced assembly programming. Interrupts, General interrupts, concept of ISR, Writing an ISR for 68HC812, Advanced interrupt topics.

Module III (Quantitative Approach)

Clock Module – Background theory, clock module, Clock drivider chain, 68HC12 Timer Module, Components of the timer module. The Real Time Interrupt (RTI). Programming Input Capture, Output Compare and the Pulse Accumulator Features of the TIM. 68HC12 memory system, 68HC12 ADC (ATD) , 68HC12 Communication System.

References:

1. Daniel J Pack & Steven F Barett – 68HC12 Microcontroller

2. Han – Way Huang – MC 68HC12 An Introduction : Software & Hardware

3. Jonathan W Valvano – Introduction to Embedded Microcomputer System : Motorola 6811/6812

Simulator.

Question Paper

03.806 (4) COMMUNICATION PROTOCOLS (TA) 3-1-0

(Elective VI)

Module I (Quantitative Approach)


TCP/IP Protocol suite overview. Protocol structure. Error and Flow Control. Protocol Specification and Modeling: Validation Models. Correctness requirements. Protocol design. Finite state machines.

Module II  (Quantitative Approach)

Conformance testing, Protocol Synthesis, Protocol Validation, Introduction to Estelle. Implementation and verification of  Protocols in Estelle. SDL,  Introduction to security Protocols. Security Properties, Encryption modes, Security protocol vulnerabilities

Module III (Quantitative Approach)

The CSP approach, Limits of formal analysis. CSP - building blocks, parallel operators, hiding and renaming, process behavior, discrete time. Modeling security protocols in CSP. Expressing protocol goals.  Overview of FDR. Encoding protocols and intruder in FDR. Theorem proving, Simplifying transformations. Case studies.

Text Books:

1. Gerard J Holzmann: Design and Validation of Computer Protocols, Prentice Hall.

2. Peter Ryan,Steve Schneider,Michael Goldsmith,Gavin Lowe, Bill Roscoe: The Modeling and

    Analysis of Security Protocols: The CSP Approach -  Addison Wesley

References:

1. Kenneth J Turner,   : Using Formal Description Techniques : An Introduction to Estelle, Lotos, and

    Sdl -   John Wiley & Sons Inc

2. Richard Lai Ajin Jirachiefpattana, Kluwer : Communication Protocol Specification and Verification -     Academic Press

3.  R. Stevens : TCP/IP Illustrated Vol. 1 and Vol 2, A-W

Question Paper

Assignment for Sessional marks shall be problems based on MATLAB / any other software packages covering the syllabus above.

03.806 (5) DESIGN OF INDUSTRIAL CONTROL SYSTEMS (a) 3-1-0

(ELECTIVE VI)

Module I

Switches. Relays – Electromechanical and solid state. Mechanical Systems – Friction, Springs, Mass and Inertia, Levers, Energy conversion and Heat Transfer, Damping and Resonance, Gears, Clutches and brakes. Power transmitting techniques. DC motor control circuits – Analog drive, PWM drive, Reversing and Braking, An application of a small DC Motor. Brushless DC Motors. AC motor control – Start stop, Jogging, Reduced voltage starting, Variable frequency and vector drives.

Module II

Actuators – Electric linear actuators – Hydraulic, Pneumatic actuators and systems. Flow control valves. Stepper Motors – Permanent Magnet, Variable reluctance and Hybrid stepper motors. Stepper motor control circuits – 2 and 4 phase control, Microstepping, High torque. Positioning a disk drive head. Microcomputer based scale. Microcomputer and 8086 based Industrial Process control system. Developing a prototype microcomputer based Instrument. Robotics and Embedded Control.

Module III

Microcontrollers - Instruction set of Intel 8051(over view) - brief description of instruction set - addressing modes. Real time controller - interrupt structure - priority - masking of interrupts - global disabling of interrupts - programmable timers & counters - real time clock. Introduction to Intel / MCS 8096 microcontrollers (any 16 bit micro controller) Architecture memory mapping - instruction set - interrupts - timers and high speed I/O etc. Application of microcontroller - PWM generation for DC motor controller - stepper motor control - CRT controller - data acquisition systems - distributed motor control – Aircraft Control demonstration – Light sensors for robots – Ultrasonic distance measuring.

Text Books :

Module I – Ref (1)

Module II – Ref (1) & Ref (2)

Module III – Ref (3), Ref (4) & Ref (5)

References:

1. Kilian, Modern Control Technology Components and Systems, 2/e, Thomson & Delmar

2. Douglas V Hall, Microprocessors and Interfacing, 2/e, Mc Graw Hill

3. Kenneth I Ayala. The 8051 Microcontroller - Architecture Programming & Applications, Penram International India.

4. Kenneth Hentz & David Tabech. Microcontroller Architecture Implementing & Programme, McGraw Hill

5. Peatman. Designing with Microcontroller , McGraw Hill.
6. Douglas M Considine, Process/ Industrial Instruments and Controls Hand book, 4/e, Mc. Graw Hill

7. Intel Embedded Applications Vol. 1 & 2

Question Paper

03.807 PROCESS CONTROL LAB ( A) 0-0-4

1. ON-OFF controller & ON-OFF controller with and without neutral zone.

5. PID Controller

6. Controller tuning using continuous cycling methods

7. Controller tuning using Process Reaction curve

8. Study of P, PI, PD & PID modes of Temperature, Flow, Level and Pressure control systems

9. Calibration of pressure guage using dead weight tester and calibration of level transmitter

10. Input converter and PI converter

11. PLC controlled bottle filling system

12. Computer controlled lathe machine

13. Control valves with and without positioner

14. RTD based temperature transmitter

15. Cold junction compensator, thermocouple based temperature transmitter

16. PC based data acquisition using ADC/DAC add-on cards

17. Computer interface for PID controller

18. Differential pressure transmitter characteristics

Note

For University examination, the following guidelines should be followed regarding award of marks

(a) Circuit and design -25%

(b) Result & Performance -50%

Practical examination to be conducted covering entire syllabus given above.

03.808 PROJECT & VIVA VOCE ( TA ) 0-0-5

Project & Viva-voce – Internal Evaluation (150 marks)

Each student is expected to prepare a report on the project work done by him/her and present a paper highlighting the work done by him/her in a seminar. The student is expected to complete the project work assigned to him/her and submit the project report by the end of semester. This report shall be of a hard bound type and consist of design phase report as volume one and other part as volume two.

Marks shall be awarded by continuous evaluation of minimum two times in this semester. (25 marks for evaluation of the report, 25 marks for presentation, 50 marks for viva and 50 marks for results / product)

Evaluation of report, results, presentation and viva will be conducted by a committee consisting of the guide, project coordinator and a senior faculty.

Project & Viva - Voce – University Examination (100 Marks)

(Examiners shall be senior staff members)

The students shall prepare for an oral examination based on Electronics, Communication, Electronic Instrumentation, other related and advanced topics. Viva-Voce examination shall also be based on Project and Seminar.

Students shall submit their Seminar Report (Certified during 7^th Semester) and Project Report (consists of design phase report, Implementation and results report) for viva-voce. Marks for Project shall have weightage for valid results only.

Marks shall be awarded as

General Topics : 50 Marks

Project (Results) : 25 Marks

Seminar : 25 Marks

03.801 DIGITAL CONTROL SYSTEMS (A) 2-1-0

Module I (Quantitative Approach)

Module II (Quantitative Approach)

References:

Question Paper

Module I

Module II

Module III

Question Paper

03.804 OPTICAL INSTRUMENTATION (A) 2-1-0

Module I

Module II

Module III

Question Paper

Question Paper

03.805 (2) INTEGRATED OPTICS & PHOTONIC SYSTEMS (Ta) 3-1-0

Module I

Module II

Module III

Question Paper

03. 805 (3) SOFTWARE ARCHITECTURE & SYSTEMS (TA) 3-1-0

Module I (Quantitative Approach)

Module II (Quantitative Approach)

Module III (Quantitative Approach)

1. Booch G, Rumbaugh, J. Jacobson : The Unified modelling Language User Guide, Addison-Wesley,

1999

Module II

Question Paper

03.805 (5) CDMA SYSTEMS (Ta) 3-1-0

Question Paper

Question Paper

03.806 (2) EMBEDDED SYSTEMS (Ta) 3-1-0

Module I (Quantitative Approach)

Module II (Quantitative Approach)

Module III (Quantitative Approach)

8096 processor architecture – High speed registers, Serial output ports, Programmable timers, PW registers. Instruction set, Assembly language programming, Hardware interfacing, Memory. Architecture of 68C11, Instruction set, Programming. Text Book:

References:

1. 16 bit embedded Controller Hand book - Intel 1990.

2. The Programming Environment for 32-Bit Microprocessors, Motorola

3. MPC860 User’s Manual, Motorola

4. David L Ripps, An Implementation guide to Real Time Programming, Yourdon Press, 1990

Question Paper

03.806 (3) MICROCONTROLLER BASED SYSTEM DESIGN (Ta) 3-1-0

Question Paper

Question Paper

Module I

Module II

Question Paper

Note

8096 processor architecture – High speed registers, Serial output ports, Programmable timers, PW registers. Instruction set, Assembly language programming, Hardware interfacing, Memory. Architecture of 68C11, Instruction set, Programming.

Text Book: