ANNA UNIVERSITY TIRUNELVELI
M.E. APPLIED ELECTRONICS
CURRICULUM 2005 - FULL TIME MODE
SEMESTER – I
Code No. Course Title L T P M
Theory
MA1616A Applied Mathematics for Electronics Engineers
3 1 0 100
AN1601 Advanced Digital Signal Processing
3 1 0 100
AN1602 Advanced Digital System Design
3 1 0 100
AN1603 VLSI Design Techniques
3 0 0 100
AN1604 Advanced Microprocessors and Micro Controllers
3 0 0 100
E1*** Elective I 3 0 0 100
Practical
AN1605 Electronics Design Lab I
0 0 4 100
SEMESTER – II
Code No. Course Title L T P M
Theory
AN1651 Analysis and Design of Analog Integrated Circuits
3 0 0 100
AN1652 Computer Architecture and Parallel Processing
3 0 0 100
AN1653 Digital Control Engineering
3 0 0 100
AN1654 Embedded Systems
3 0 0 100
E2*** Elective II 3 0 0 100
E3*** Elective III 3 0 0 100
Practical
AN1655 Electronic Design Lab II
0 0 4 100
SEMESTER – III
Code No. Course Title L T P M
Theory
E4*** Elective IV 3 0 0 100
E5*** Elective V 3 0 0 100
E6*** Elective VI 3 0 0 100
Practical
AN1751 Project Work (Phase I) 0 0 12 *
SEMESTER – IV
Code No. Course Title L T P M
AN1751 Project Work (Phase II) 0 0 24 *
* As per Regulations 2005
LIST OF ELECTIVES
M.E. APPLIED ELECTRONICS
Code No. Course Title L T P M
AN1621 Digital Image Processing
3 0 0 100
AN1622 Neural Networks and Applications
3 0 0 100
AN1623 Robotics
3 0 0 100
VL1601 DSP Integrated Circuits
3 0 0 100
AN1625 ASIC Design
3 0 0 100
AN1626 Design and Analysis of Algorithms
3 0 0 100
AN1627 Reliability Engineering
3 0 0 100
AN1628 Internetworking Multimedia
3 0 0 100
AN1629 Electromagnetic Interference and Compatibility in System Design
3 0 0 100
AN1630 High Performance Communication Networks
3 0 0 100
CO1621 RF system Design
3 0 0 100
VL1622 Low Power VLSI Design
3 0 0 100
VL1623 VLSI Signal Processing
3 0 0 100
VL1625 Analog VLSI Design
3 0 0 100
VL1651 Computer Aided Design of VLSI Circuits
3 0 0 100
AN1645 Special Elective 3 0 0 100
MA1616A APPLIED MATHEMATICS FOR ELECTRONICS ENGINEERS
(With effect from 2006-2007)
3 1 0 100
UNIT I (9) Linear Algebraic equation and Eigen Value Problem
System of Equations – Solution by Gauss Elimination, Gauss – Jordan and LU decomposition method – Jacobi, Gauss – Seidal iteration method – Eigen Values of a matrix by Jacobi and Power methods.
UNIT II (9) Wave Equation
Solution of initial and boundary value problems – Characteristics – D’Alembert’s Solution – Significance of characteristic curves – Laplace transform solutions for displacement in a long string – a long string under its weight – Longitudinal vibration of a elastic bar with prescribed force on one end – free vibrations of a string.
UNIT III (9) Special Functions
Bessel’s equation – Bessel Functions – Legendre’s Equation – Legendre Polynomials – Rodrigue’s formula – Recurrence relations – generating function and orthogonal property of Bessel functions and Legendre polynomials.
UNIT IV (9) Random Variables
One dimensional Random Variables – Moments and MGF – Binomial, Poisson, Geometrical, Uniform, Exponential, Normal and Welbull distributions – Two dimensional Random Variables – Marginal and Conditional distribution – Covariance and correlation coefficient – Functions of one dimensional and Two dimensional Random Variables.
UNIT V (9) Queuing Theory
Single and Multiple server Markovian queuing models – Steady state system size probabilities – Little’s formula – customers impatience – priority queues – M/G/1 queuing system – P.K formula.
L – 45, T – 15, Total - 60
References:
1. Jain M.K., Iyengar. S.R.K. & Jain. R.K, “Numerical Methods for Scientific and Engineering Computation”, New Age International (P) ltd, Publishers, 2003.
2. Sankara Rao K, “Introduction to Partial Differential” , Prentice Hall of India, 1997.
3. Grewai B.S, “Higher Engineering Mathematics”, Khanna Publishers, 2005.
4. Kapur J.N & Saxena. H.C, “Mathematics Statistics”, S.Chand & Company Limited, New Delhi,2003.
5. Taha H.A, “Operations Research- An Introduction”, Prentice Hall of India, 2001.
6. Gross D & Harris C.M, “Fundamentals of Queuing Theory” , John Wiley & Sons, 1985.
AN1601 ADVANCED DIGITAL SIGNAL PROCESSING 3 1 0 100
[Review of discrete-time signals and systems- DFT and FFT, Z-Transform, Digital Filters is recommended]
UNIT I 9
DISCRETE RANDOM SIGNAL PROCESSING
Discrete Random Processes- Ensemble averages, stationary processes, Autocorrelation and Auto covariance matrices. Parseval's Theorem, Wiener-Khintchine Relation- Power Spectral Density-Periodogram Spectral Factorization, Filtering random processes. Low Pass Filtering of White Noise. Parameter estimation: Bias and consistency.
UNIT II 9
SPECTRUM ESTIMATION
Estimation of spectra from finite duration signals, Non-Parametric Methods-Correlation Method , Periodogram Estimator, Performance Analysis of Estimators -Unbiased, Consistent Estimators- Modified periodogram, Bartlett and Welch methods, Blackman –Tukey method. Parametric Methods - AR, MA, ARMA model based spectral estimation. Parameter Estimation -Yule-Walker equations, solutions using Durbin’s algorithm
UNIT III 9
LINEAR ESTIMATION AND PREDICTION
Linear prediction- Forward and backward predictions, Solutions of the Normal equations- Levinson-Durbin algorithms. Least mean squared error criterion -Wiener filter for filtering and prediction , FIR Wiener filter and Wiener IIR filters ,Discrete Kalman filter
UNIT IV 9
ADAPTIVE FILTERS
FIR adaptive filters -adaptive filter based on steepest descent method-Widrow-Hoff LMS adaptive algorithm, Normalized LMS. Adaptive channel equalization-Adaptive echo cancellation-Adaptive noise cancellation- Adaptive recursive filters (IIR). RLS adaptive filters-Exponentially weighted RLS-sliding window RLS.
UNIT V 9
MULTIRATE DIGITAL SIGNAL PROCESSING
Mathematical description of change of sampling rate - Interpolation and Decimation , Decimation by an integer factor - Interpolation by an integer factor, Sampling rate conversion by a rational factor, Filter implementation for sampling rate conversion- direct form FIR structures, Polyphase filter structures, time-variant structures. Multistage implementation of multirate system. Application to sub band coding - Wavelet transform and filter bank implementation of wavelet expansion of signals.
L-45 T-15 Total-60
REFERENCES:
1. Monson H.Hayes, Statistical Digital Signal Processing and Modeling, John Wiley and Sons, Inc., Singapore, 2002.
2. John G. Proakis, Dimitris G.Manolakis, Digital Signal Processing Pearson Education, 2002.
3. John G. Proakis et.al.’Algorithms for Statistical Signal Processing’, Pearson Education, 2002.
4. Dimitris G.Manolakis et.al.’ Statistical and adaptive signal Processing’, McGraw Hill, Newyork, 2000.
5. Rafael C. Gonzalez, Richard E.Woods, ‘Digital Image Processing’, Pearson Education, Inc., Second Edition, 2004.( For Wavelet Transform Topic)
AN1602 ADVANCED DIGITAL SYSTEM DESIGN 3 1 0 100
UNIT I 9
SEQUENTIAL CIRCUIT DESIGN
Analysis of Clocked Synchronous Sequential Networks (CSSN) Modeling of CSSN – State Stable Assignment and Reduction – Design of CSSN – Design of Iterative Circuits – ASM Chart – ASM Realization.
UNIT II 9
ASYNCHRONOUS SEQUENTIAL CIRCUIT DESIGN
Analysis of Asynchronous Sequential Circuit (ASC) – Flow Table Reduction – Races in ASC – State Assignment – Problem and the Transition Table – Design of ASC – Static and Dynamic Hazards – Essential Hazards – Data Synchronizers – Designing Vending Machine Controller – Mixed Operating Mode Asynchronous Circuits.
UNIT III 9
FAULT DIAGNOSIS AND TESTABILITY ALGORITHMS
Fault Table Method – Path Sensitization Method – Boolean Difference Method – Kohavi Algorithm – Tolerance Techniques – The Compact Algorithm – Practical PLA’s – Fault in PLA – Test Generation – Masking Cycle – DFT Schemes – Built-in Self Test.
UNIT IV 9
SYNCHRONOUS DESIGN USING PROGRAMMABLE DEVICES
EPROM to Realize a Sequential Circuit – Programmable Logic Devices – Designing a Synchronous Sequential Circuit using a GAL – EPROM – Realization State machine using PLD – FPGA – Xilinx FPGA – Xilinx 2000 - Xilinx 3000
UNIT V 9
SYSTEM DESIGN USING VHDL
VHDL Description of Combinational Circuits – Arrays – VHDL Operators – Compilation and Simulation of VHDL Code – Modeling using VHDL – Flip Flops – Registers – Counters – Sequential Machine – Combinational Logic Circuits - VHDL Code for – Serial Adder, Binary Multiplier – Binary Divider – complete Sequential Systems – Design of a Simple Microprocessor.
L -45 T-15 Total - 60
REFERENCES:
1. Donald G. Givone “Digital principles and Design” Tata McGraw Hill 2002.
2. John M Yarbrough “Digital Logic applications and Design” Thomson Learning, 2001
3. Nripendra N Biswas “Logic Design Theory” Prentice Hall of India, 2001
4. Charles H. Roth Jr. “Digital System Design using VHDL” Thomson Learning, 1998.
5. Charles H. Roth Jr. “Fundamentals of Logic design” Thomson Learning, 2004.
6. Stephen Brown and Zvonk Vranesic “Fundamentals of Digital Logic with VHDL Design” Tata McGraw Hill, 2002.
7. Navabi.Z. “VHDL Analysis and Modeling of Digital Systems. McGraw International, 1998
8. Parag K Lala, “Digital System design using PLD” BS Publications, 2003
9. Peter J Ashendem, “The Designers Guide to VHDL” Harcourt India Pvt Ltd, 2002
10. Mark Zwolinski, “Digital System Design with VHDL” Pearson Education, 2004
11. Skahill. K, “VHDL for Programmable Logic” Pearson education, 1996
AN1603 VLSI DESIGN TECHNIQUES 3 0 0 100
UNIT I 9
MOS TRANSISTOR THEORY AND PROCESS TECHNOLOGY.
NMOS and PMOS transistors, Threshold voltage- Body effect- Design equations- Second order effects. MOS models and small signal AC characteristics. Basic CMOS technology.
UNIT II 9
INVERTERS AND LOGIC GATES.
NMOS and CMOS Inverters, Stick diagram, Inverter ratio, DC and transient characteristics , switching times, Super buffers, Driving large capacitance loads, CMOS logic structures , Transmission gates, Static CMOS design, dynamic CMOS design.
UNIT III 9
CIRCUIT CHARACTERISATION AND PERFORMANCE ESTIMATION
Resistance estimation, Capacitance estimation, Inductance, switching characteristics, transistor sizing, power dissipation and design margining. Charge sharing .Scaling.
UNIT IV 9
VLSI SYSTEM COMPONENTS CIRCUITS AND SYSTEM LEVEL PHYSICAL DESIGN.
Multiplexers, Decoders, comparators, priority encoders, Shift registers.
Arithmetic circuits – Ripple carry adders, Carry look ahead adders, High-speed adders, Multipliers. Physical design – Delay modelling ,cross talk, floor planning, power distribution. Clock distribution. Basics of CMOS testing.
UNIT V 9
VERILOG HARDWARE DESCRIPTION LANGUAGE
Overview of digital design with Verilog HDL, hierarchical modelling concepts, modules and port definitions, gate level modelling, data flow modelling, behavioral modelling, task & functions, Test Bench.
Total: 45
REFERENCES:
1. Neil H.E. Weste and Kamran Eshraghian, Principles of CMOS VLSI Design, Pearson Education ASIA, 2nd edition, 2000.
2. John P.Uyemura “Introduction to VLSI Circuits and Systems”, John Wiley & Sons, Inc., 2002.
3. Samir Palnitkar, “Verilog HDL”, Pearson Education, 2nd Edition, 2004.
4. Eugene D. Fabricius, Introduction to VLSI Design McGraw Hill International Editions, 1990.
5. J.Bhasker, B.S.Publications, “A Verilog HDL Primer”, 2nd Edition, 2001.
6. Pucknell, “Basic VLSI Design”, Prentice Hall of India Publication, 1995.
7. Wayne Wolf “Modern VLSI Design System on chip. Pearson Education.2002.
AN1604 ADVANCED MICROPROCESSORS AND MICRO CONTROLLERS
3 0 0 100
UNIT I 9
MICROPROCESSOR ARCHITECTURE
Instruction set – Data formats – Instruction formats – Addressing modes – Memory hierarchy – register file – Cache – Virtual memory and paging – Segmentation – Pipelining – The instruction pipeline – pipeline hazards – Instruction level parallelism – reduced instruction set – Computer principles – RISC versus CISC – RISC properties – RISC evaluation – On-chip register files versus cache evaluation .
UNIT II 9
HIGH PERFORMANCE CISC ARCHITECTURE – PENTIUM
The software model – functional description – CPU pin descriptions – RISC concepts – bus operations – Super scalar architecture – pipe lining – Branch prediction – The instruction and caches – Floating point unit –protected mode operation – Segmentation – paging – Protection – multitasking – Exception and interrupts – Input /Output – Virtual 8086 model – Interrupt processing -Instruction types – Addressing modes – Processor flags – Instruction set -programming the Pentium processor.
UNIT III 9
HIGH PERFORMANCE RISC ARCHITECTURE: ARM
The ARM architecture – ARM assembly language program – ARM organization and implementation – The ARM instruction set - The thumb instruction set – ARM CPU cores.
UNIT IV 9
MOTOROLA 68HC11 MICROCONTROLLERS
Instructions and addressing modes – operating modes – Hardware reset – Interrupt system – Parallel I/O ports – Flags – Real time clock – Programmable timer – pulse accumulator – serial communication interface – A/D converter – hardware expansion – Assembly language Programming
UNIT V 9
PIC MICRO CONTROLLER
CPU architecture – Instruction set - Interrupts – Timers – I/O port expansion –I2C bus for peripheral chip access – A/D converter – UART
Total - 45
REFERENCES :
1. Daniel Tabak , ‘’ Advanced Microprocessors” McGraw Hill.Inc., 1995
2. James L. Antonakos, “The Pentium Microprocessor ‘’ Pearson Education, 1997.
3. Steve Furber, ‘’ ARM System –On –Chip architecture “Addison Wesley, 2000.
4. Gene .H.Miller.” Micro Computer Engineering,” Pearson Education, 2003.
5. John .B.Peatman, “Design with PIC Microcontroller, Prentice hall, 1997.
6. James L.Antonakos,” An Introduction to the Intel family of Microprocessors ‘’ Pearson Education 1999.
7. Barry.B.Breg,” The Intel Microprocessors Architecture , Programming and
Interfacing “, PHI, 2002.
8. Valvano "Embedded Microcomputer Systems" Thomson Asia PVT LTD first reprints 2001.
Readings:
Web links
www.ocw.nit.edu
www.arm.com
AN1605 ELECTRONICS DESIGN LABORATORY I 0 0 4 100
1. System design using PIC Microcontroller.
2. Implementation of Adaptive Filters, periodogram and multistage multirate system in DSP Processor
3. Simulation of QMF using Simulation Packages
4. Modeling of Sequential Digital system using VHDL.
5. Modeling of Sequential Digital system using Verilog.
6. Design and Implementation of ALU using FPGA.
7. Simulation of NMOS and CMOS circuits using SPICE.
8. System design using 16- bit Microprocessor.
AN1651 ANALYSIS AND DESIGN OF ANALOG INTEGRATED CIRCUITS
3 0 0 100
UNIT I 9
MODELS FOR INTEGRATED CIRCUIT ACTIVE DEVICES
Depletion region of a PN junction – large signal behavior of bipolar transistors- small signal model of bipolar transistor- large signal behavior of MOSFET- small signal model of the MOS transistors- short channel effects in MOS transistors – weak inversion in MOS transistors- substrate current flow in MOS transistor.
UNIT II 9
CIRCUIT CONFIGURATION FOR LINEAR IC
Current sources, Analysis of difference amplifiers with active load using BJT and FET, supply and temperature independent biasing techniques, voltage references. Output stages: Emitter follower, source follower and Push pull output stages.
UNIT III 9
OPERATIONAL AMPLIFIERS
Analysis of operational amplifiers circuit, slew rate model and high frequency analysis, Frequency response of integrated circuits: Single stage and multistage amplifiers, Operational amplifier noise
UNIT IV 9
ANALOG MULTIPLIER AND PLL
Analysis of four quadrant and variable trans conductance multiplier, voltage controlled oscillator, closed loop analysis of PLL, Monolithic PLL design in integrated circuits: Sources of noise- Noise models of Integrated-circuit Components – Circuit Noise Calculations – Equivalent Input Noise Generators – Noise Bandwidth – Noise Figure and Noise Temperature
UNIT V 9
ANALOG DESIGN WITH MOS TECHNOLOGY
MOS Current Mirrors – Simple, Cascode, Wilson and Widlar current source – CMOS Class AB output stages – Two stage MOS Operational Amplifiers, with Cascode, MOS Telescopic-Cascode Operational Amplifier – MOS Folded Cascode and MOS Active Cascode Operational Amplifiers
TOTAL: 45
REFERENCES
1. Gray, Meyer, Lewis, Hurst, “Analysis and design of Analog IC’s”, Fourth Edition, Willey International, 2002.
2. Behzad Razavi, “Principles of data conversion system design”, S.Chand and company ltd, 2000
3. Nandita Dasgupata, Amitava Dasgupta,”Semiconductor Devices, Modelling and Technology”, Prentice Hall of India pvt. ltd, 2004.
4. Grebene, Bipolar and MOS Analog Integrated circuit design”, John Wiley & sons,Inc.,2003.
5. Phillip E.Allen Douglas R. Holberg, “CMOS Analog Circuit Design”, Second Edition-Oxford University Press-2003
AN1652 COMPUTER ARCHITECTURE AND PARALLEL PROCESSING 3 0 0 100
UNIT I 9
PRINCIPLES OF PARALLEL PROCESSING
Multiprocessors and Multicomputers – Multivector and SIMD Computers- PRAM and VLSI Models- Conditions of Parallelism- Program Partitioning and scheduling-program flow mechanisms- parallel processing applications- speed up performance law.
UNIT II 9
PROCESSOR AND MEMORY ORGANIZATION
Advanced processor technology – Superscalar and vector processors- Memory hierarchy technology- Virtual memory technology- Cache memory organization- Shared memory organization.
UNIT III 9
PIPELINE AND PARALLEL ARCHITECTURE
Linear pipeline processors- Non linear pipeline processors- Instruction pipeline design- Arithmetic design- Superscalar and super pipeline design- Multiprocessor system interconnects- Message passing mechanisms.
UNIT IV 9
VECTOR, MULTITHREAD AND DATAFLOW ARCHITECTURE
Vector Processing principle- Multivector Multiprocessors- Compound Vector processing- Principles of multithreading-fine grain multicomputers- scalable and multithread architectures – Dataflow and hybrid architectures.
UNIT V 9
SOFTWARE AND PARALLEL PROCESSING
Parallel programming models- parallel languages and compilers- parallel programming environments- synchronization and multiprocessing modes- message passing program development- mapping programs onto multicomputers- multiprocessor UNIX design goals- MACH/OS kernel architecture- OSF/1 architecture and applications.
TOTAL : 45
REFERENCES
1. Kai Hwang, “Advanced Computer Architecture”, TMH 2001.
2. William Stallings, Computer Organization and Architecture, McMillan Publishing Company, 1990.
3. M.J. Quinn, “Designing efficient Algorithms for parallel computer”, McGraw Hill International, 1994.
AN1653 DIGITAL CONTROL ENGINEERING 3 0 0 100
UNIT I 9
Review of frequency and time response analysis and specifications of control systems, need for controllers, continues time compensations, continues time PI, PD, PID controllers, digital PID controllers.
UNIT II 9
SIGNAL PROCESSING IN DIGITAL CONTROL
Sampling, time and frequency domain description, aliasing, hold operation, mathematical model of sample and hold, zero and first order hold, factors limiting the choice of sampling rate, reconstruction.
UNIT III 9
MODELING AND ANALYSIS OF SAMPLED DATA CONTROL SYSTEM
Difference equation description, Z-transform method of description, pulse transfer function, time and frequency response of discrete time control systems, stability of digital control systems, Jury's stability test, state variable concepts, first companion, second companion, Jordan canonical models, discrete state variable models, elementary principles.
UNIT IV 9
DESIGN OF DIGITAL CONTROL ALGORITHMS
Review of principle of compensator design, Z-plane specifications, digital compensator design using frequency response plots, discrete integrator, discrete differentiator, development of digital PID controller, transfer function, design in the Z-plane.
UNIT V 9
PRACTICAL ASPECTS OF DIGITAL CONTROL ALGORITHMS
Algorithm development of PID control algorithms, software implementation, implementation using microprocessors and microcontrollers, finite word length effects, choice of data acquisition systems, microcontroller based temperature control systems, microcontroller based motor speed control systems.
TOTAL : 45
REFERENCES
1. M.Gopal, "Digital Control and Static Variable Methods", Tata McGraw Hill, New Delhi, 1997.
2. John J. D'Azzo, "Constantive Houpios, Linear Control System Analysis and Design", Mc Graw Hill, 1995.
3. Kenneth J. Ayala, "The 8051 Microcontroller- Architecture, Programming and Applications", Penram International, 2nd Edition, 1996.
AN1654 EMBEDDED SYSTEMS 3 0 0 100
UNIT I 9
EMBEDDED ARCHITECTURE
Embedded Computers, Characteristics of Embedded Computing Applications, Challenges in Embedded Computing system design, Embedded system design process- Requirements, Specification, Architectural Design, Designing Hardware and Software Components, System Integration, Formalism for System Design- Structural Description, Behavioral Description, Design Example: Model Train Controller
UNIT II 9
EMBEDDED PROCESSOR AND COMPUTING PLATFORM
ARM processor- processor and memory organization, Data operations, Flow of Control, SHARC processor- Memory organization, Data operations, Flow of Control, parallelism with instructions, CPU Bus configuration, ARM Bus, SHARC Bus, Memory devices, Input/output devices, Component interfacing, designing with microprocessor development and debugging, Design Example : Alarm Clock.
UNIT III 9
NETWORKS
Distributed Embedded Architecture- Hardware and Software Architectures, Networks for embedded systems- I2C, CAN Bus, SHARC link pports, Ethernet, Myrinet, Internet, Network-Based design- Communication Analysis, system performance Analysis, Hardware platform design, Allocation and scheduling, Design Example: Elevator Controller.
UNIT IV 9
REAL-TIME CHARACTERISTICS
Clock driven Approach, weighted round robin Approach, Priority driven Approach, Dynamic Versus Static systems, effective release times and deadlines, Optimality of the Earliest deadline first (EDF) algorithm, challenges in validating timing constraints in priority driven systems, Off-line Versus On-line scheduling.
UNIT V 9
SYSTEM DESIGN TECHNIQUES
Design Methodologies, Requirement Analysis, Specification, System Analysis and Architecture Design, Quality Assurance, Design Example: Telephone PBX- System Architecture, Ink jet printer- Hardware Design and Software Design, Personal Digital Assistants, Set-top Boxes.
TOTAL : 45
REFERENCES
1. Wayne Wolf, Computers as Components: Principles of Embedded Computing System Design, Morgan Kaufman Publishers, 2001.
2. Jane.W.S. Liu Real-Time systems, Pearson Education Asia, 2000
3. C. M. Krishna and K. G. Shin , Real-Time Systems, ,McGraw-Hill, 1997
4. Frank Vahid and Tony Givargi Embedded System Design: A Unified Hardware/Software Introduction, s, John Wiley & Sons, 2000.
AN1655 ELECTRONIC DESIGN LAB II 0 0 4 100
1. System design using PLL
2. System design using CPLD
3. Alarm clock using embedded micro controller
4. Model train controller using embedded micro controller
5. Elevator controller using embedded micro controller
6. Simulation of Non adaptive Digital Control System using MAT LAB control system toolbox
7. Simulation of Adaptive Digital Control System using MAT LAB control system toolbox
AN1621 DIGITAL IMAGE PROCESSING 3 0 0 100
UNIT I 9
DIGITAL IMAGE FUNDAMENTALS
Elements of digital image processing systems, Elements of visual perception, psycho visual model, brightness, contrast, hue, saturation, mach band effect, Color image fundamentals -RGB,HSI models, Image sampling, Quantization, dither, Two-dimensional mathematical preliminaries.
UNIT II 9
IMAGE TRANSFORMS
1D DFT, 2D transforms – DFT, DCT, Discrete Sine, Walsh, Hadamard, Slant, Haar, KLT, SVD, Wavelet Transform.
UNIT III 9
IMAGE ENHANCEMENT AND RESTORATION
Histogram modification and specification techniques, Noise distributions, Spatial averaging, Directional Smoothing, Median, Geometric mean, Harmonic mean, Contraharmonic and Yp mean filters, Homomorphic filtering, Color image enhancement. Image Restoration – degradation model, Unconstrained and Constrained restoration, Inverse filtering – removal of blur caused by uniform linear motion, Wiener filtering, Geometric transformations – spatial transformations, Gray-Level interpolation,
UNIT IV 9
IMAGE SEGMENTATION AND RECOGNITION
Edge detection. Image segmentation by region growing, region splitting and merging, edge linking.. Image Recognition – Patterns and pattern classes, Matching by minimum distance classifier, Matching by correlation, Back Propagation Neural Network, Neural Network applications in Image Processing.
UNIT V 9
IMAGE COMPRESSION
Need for data compression, Huffman,. Run Length Encoding, Shift codes, Arithmetic coding, Vector Quantization, Block Truncation Coding. Transform Coding – DCT and Wavelet. JPEG, MPEG. Standards, Concepts of Context based Compression.
Total: 45
REFERENCES:
1. Rafael C. Gonzalez, Richard E.Woods, ‘Digital Image Processing’, Pearson Education, Inc., Second Edition, 2004.
2. Anil K. Jain, ‘Fundamentals of Digital Image Processing’, Prentice Hall of India, 2002.
3. David Salomon : Data Compression – The Complete Reference, Springer Verlag New York Inc., 2nd Edition, 2001
4. Rafael C. Gonzalez, Richard E.Woods, Steven Eddins, ‘ Digital Image Processing using MATLAB’, Pearson Education, Inc., 2004.
5. William K.Pratt, ‘ Digital Image Processing’, John Wiley, NewYork, 2002.
6. Milman Sonka, Vaclav Hlavac, Roger Boyle, ‘Image Processing, Analysis, and Machine Vision’, Brooks/Cole, Vikas Publishing House, II ed., 1999.
7. Sid Ahmed, M.A., ‘Image Processing Theory, Algorithms and Architectures’, McGraw-Hill, 1995.
AN1622 NEURAL NETWORKS AND APPLICATIONS 3 0 0 100
UNIT I 9
BASIC LEARNING ALGORITHMS
Biological Neuron – Artificial Neural Model - Types of activation functions – Architecture: Feedforward and Feedback – Learning Process: Error Correction Learning –Memory Based Learning – Hebbian Learning – Competitive Learning - Boltzman Learning – Supervised and Unsupervised Learning – Learning Tasks: Pattern Space – Weight Space – Pattern Association – Pattern Recognition – Function Approximation – Control – Filtering - Beamforming – Memory – Adaptation - Statistical Learning Theory – Single Layer Perceptron – Perceptron Learning Algorithm – Perceptron Convergence Theorem – Least Mean Square Learning Algorithm – Multilayer Perceptron – Back Propagation Algorithm – XOR problem – Limitations of Back Propagation Algorithm.
UNIT II 9
RADIAL-BASIS FUNCTION NETWORKS AND SUPPORT VECTOR MACHINES:
RADIAL BASIS FUNCTION NETWORKS:
Cover’s Theorem on the Separability of Patterns - Exact Interpolator – Regularization Theory – Generalized Radial Basis Function Networks - Learning in Radial Basis Function Networks - Applications: XOR Problem – Image Classification.
Support Vector Machines:
Optimal Hyperplane for Linearly Separable Patterns and Nonseparable Patterns – Support Vector Machine for Pattern Recognition – XOR Problem - -insensitive Loss Function – Support Vector Machines for Nonlinear Regression
UNIT III 9
COMMITTEE MACHINES:
Ensemble Averaging - Boosting – Associative Gaussian Mixture Model – Hierarchical Mixture of Experts Model(HME) – Model Selection using a Standard Decision Tree – A Priori and Postpriori Probabilities – Maximum Likelihood Estimation – Learning Strategies for the HME Model - EM Algorithm – Applications of EM Algorithm to HME Model
NEURODYNAMICS SYSTEMS:
Dynamical Systems – Attractors and Stability – Non-linear Dynamical Systems- Lyapunov Stability – Neurodynamical Systems – The Cohen-Grossberg Theorem.
UNIT IV 9
ATTRACTOR NEURAL NETWORKS:
Associative Learning – Attractor Neural Network Associative Memory – Linear Associative Memory – Hopfield Network – Content Addressable Memory – Strange Attractors and Chaos - Error Performance of Hopfield Networks - Applications of Hopfield Networks – Simulated Annealing – Boltzmann Machine – Bidirectional Associative Memory – BAM Stability Analysis – Error Correction in BAMs - Memory Annihilation of Structured Maps in BAMS – Continuous BAMs – Adaptive BAMs – Applications
ADAPTIVE RESONANCE THEORY:
Noise-Saturation Dilemma - Solving Noise-Saturation Dilemma – Recurrent On-center –Off-surround Networks – Building Blocks of Adaptive Resonance – Substrate of Resonance Structural Details of Resonance Model – Adaptive Resonance Theory – Applications
UNIT V 9
SELF ORGANISING MAPS:
Self-organizing Map – Maximal Eigenvector Filtering – Sanger’s Rule – Generalized Learning Law – Competitive Learning - Vector Quantization – Mexican Hat Networks - Self-organizing Feature Maps – Applications
PULSED NEURON MODELS:
Spiking Neuron Model – Integrate-and-Fire Neurons – Conductance Based Models – Computing with Spiking Neurons.
Total: 45 REFERENCES:
1. Satish Kumar, “Neural Networks: A Classroom Approach”, Tata McGraw-Hill Publishing Company Limited, New Delhi, 2004.
2. Simon Haykin, “Neural Networks: A Comprehensive Foundation”, 2ed., Addison Wesley Longman (Singapore) Private Limited, Delhi, 2001.
3. Martin T.Hagan, Howard B. Demuth, and Mark Beale, “Neural Network Design”, Thomson Learning, New Delhi, 2003.
4. James A. Freeman and David M. Skapura, “Neural Networks Algorithms, Applications, and Programming Techniques, Pearson Education (Singapore) Private Limited, Delhi, 2003.
AN1623 ROBOTICS 3 0 0 100
UNIT I 9
INTRODUCTION TO ROBOTICS
Motion - Potential Function, Road maps, Cell decomposition and Sensor and sensor planning. Kinematics. Forward and Inverse Kinematics - Transformation matrix and DH transformation. Inverse Kinematics - Geometric methods and Algebraic methods. Non-Holonomic constraints.
UNIT II 9
COMPUTER VISION
Projection - Optics, Projection on the Image Plane and Radiometry. Image Processing - Connectivity, Images-Gray Scale and Binary Images, Blob Filling,
Thresholding, Histogram. Convolution - Digital Convolution and Filtering and Masking Techniques. Edge Detection - Mono and Stereo Vision.
UNIT III 9
SENSORS AND SENSING DEVICES
Introduction to various types of sensor. Resistive sensors. Range sensors - Ladar (laser distance and ranging), Sonar, Radar and Infra-red. Introduction to sensing - Light sensing, Heat sensing, Touch sensing and Position sensing.
UNIT IV 9
ARTIFICIAL INTELLIGENCE
Uniform Search strategies - Breadth first, Depth first, Depth limited, Iterative and deepening depth first search and Bidirectional search. The A* algorithm . Planning - State-Space Planning , Plan-Space Planning, Graphplan/SatPlan and their Comparison, Multi-agent planning 1, and Multi-agent planning 2, Probabilistic Reasoning - Bayesian Networks, Decision Trees and Bayes net inference .
UNIT V 9
INTEGRATION TO ROBOT
Building of 4 axis or 6 axis robot - Vision System for pattern detection - Sensors for obstacle detection - AI algorithms for path finding and decision making
Total: 45 REFERENCES
1. Duda, Hart and Stork, Pattern Recognition. Wiley-Interscience, 2000.
2. Mallot, Computational Vision: Information Processing in Perception and Visual Behavior. Cambridge, MA: MIT Press, 2000.
3. Artificial Intelligence-A Modern Approach By Stuart Russell and Peter Norvig, Pearson Education Series in Artificial Intelligence, 2004
4. Fundamentals of Robotics, Analysis and control By Robert Schilling and Craig, Hall of India Private Limied, New Delhi, 2003.
5. Computer Vision, A modern Approach By Forsyth and Ponce, Person Education, 2003.
CO1621 RF SYSTEM DESIGN 3 0 0 100
UNIT I 9
RF ISSUES
Importance of RF design, Electromagnetic Spectrum, RF behaviour of passive components, Chip components and Circuit Board considerations, Scattering Parameters, Smith Chart and applications.
UNIT II 9
RF FILTER DESIGN
Overview , Basic resonator and filter configuration, Special filter realizations, Filter implementations, Coupled filter.
UNIT III 9
ACTIVE RF COMPONENTS & APPLICATIONS
RF diodes, BJT, RF FETs, High electron mobility transistors; Matching and Biasing Networks – Impedance matching using discrete components, Microstripline matching networks, Amplifier classes of operation and biasing networks.
UNIT IV 9
RF AMPLIFIER DESIGNS
Characteristics, Amplifier power relations, Stability considerations, Constant gain circles, Constant VSWR circles, Low Noise circuits, Broadband , high power and multistage amplifiers.
UNIT V 9
OSCILLATORS, MIXERS & APPLICATIONS
Basic Oscillator model, High frequency oscillator configuration, Basic characteristics of Mixers ; Phase Locked Loops ; RF directional couplers and hybrid couplers ; Detector and demodulator circuits.
Total: 45 Hours
REFERENCES:
1. Reinhold Ludwig and Powel Bretchko, RF Circuit Design – Theory and Applications, Pearson Education Asia, First Edition, 2001.
2. Joseph . J. Carr, Secrets of RF Circuit Design , McGraw Hill Publishers, Third Edition, 2000.
3. Mathew M. Radmanesh, Radio Frequency & Microwave Electronics, Pearson Education Asia, Second Edition, 2002.
4. Ulrich L. Rohde and David P. NewKirk, RF / Microwave Circuit Design, John Wiley & Sons USA 2000.
5. Roland E. Best, Phase - Locked Loops: Design, simulation and applications, McGraw Hill Publishers 5TH edition 2003.
VL1601 DSP INTEGRATED CIRCUITS 3 0 0 100
UNIT I 9
DSP INTEGARTED CIRCUITS AND VLSI CIRCUIT TECHNOLOGIES
Standard digital signal processors, Application specific IC’s for DSP, DSP systems, DSP system design, Integrated circuit design. MOS transistors, MOS logic, VLSI process technologies, Trends in CMOS technologies.
UNIT II 9
DIGITAL SIGNAL PROCESSING
Digital signal processing, Sampling of analog signals, Selection of sample frequency, Signal-processing systems, Frequency response, Transfer functions, Signal flow graphs, Filter structures, Adaptive DSP algorithms, DFT-The Discrete Fourier Transform, FFT-The Fast Fourier Transform Algorithm, Image coding, Discrete cosine transforms.
UNIT III 9
DIGITAL FILTERS AND FINITE WORD LENGTH EFFECTS
FIR filters, FIR filter structures, FIR chips, IIR filters, Specifications of IIR filters, Mapping of analog transfer functions, Mapping of analog filter structures, Multirate systems, Interpolation with an integer factor L, Sampling rate change with a ratio L/M, Multirate filters. Finite word length effects -Parasitic oscillations, Scaling of signal levels, Round-off noise, Measuring round-off noise, Coefficient sensitivity, Sensitivity and noise.
UNIT IV 9
DSP ARCHITECTURES AND SYNTHESIS OF DSP ARCHITECTURES
DSP system architectures, Standard DSP architecture, Ideal DSP architectures, Multiprocessors and multicomputers, Systolic and Wave front arrays, Shared memory architectures. Mapping of DSP algorithms onto hardware, Implementation based on complex PEs, Shared memory architecture with Bit – serial PEs.
UNIT V 9
NUMBER SYSTEMS , ARITHMETIC UNITS AND INTEGARTED CIRCUIT DESIGN
Conventional number system, Redundant Number system, Residue Number System .Bit-parallel and Bit-Serial arithmetic, Basic shift accumulator, Reducing the memory size, Complex multipliers, Improved shift-accumulator. Layout of VLSI circuits, FFT processor, DCT processor and Interpolator as case studies
TOTAL : 45
REFERENCES
1. Lars Wanhammer, “DSP INTEGRATED CIRCUITS”, Academic press, New York 1999.
2. A.V.Oppenheim et.al, ‘Discrete-time Signal Processing’ Pearson education, 2000.
3. Emmanuel C. Ifeachor, Barrie W. Jervis, “Digital signal processing – A practical
approach”, 2nd edition, Prentice Hall, 2001.
4. Keshab K.Parhi, ‘VLSI digital Signal Processing Systems design and Implementation’
John Wiley & Sons, 1999.
AN1625 ASIC DESIGN 3 0 0 100
UNIT I 9
INTRODUCTION TO ASICS, CMOS LOGIC AND ASIC LIBRARY DESIGN
Types of ASICs - Design flow - CMOS transistors CMOS Design rules - Combinational Logic Cell – Sequential logic cell - Data path logic cell - Transistors as Resistors - Transistor Parasitic Capacitance- Logical effort –Library cell design - Library architecture .
UNIT II 9
PROGRAMMABLE ASICS, PROGRAMMABLE ASIC LOGIC CELLS AND PROGRAMMABLE ASIC I/O CELLS
Anti fuse - static RAM - EPROM and EEPROM technology - PREP benchmarks - Actel ACT - Xilinx LCA –Altera FLEX - Altera MAX DC & AC inputs and outputs - Clock & Power inputs - Xilinx I/O blocks.
UNIT III 9
PROGRAMMABLE ASIC INTERCONNECT, PROGRAMMABLE ASIC DESIGN SOFTWARE AND LOW LEVEL DESIGN ENTRY
Actel ACT -Xilinx LCA - Xilinx EPLD - Altera MAX 5000 and 7000 - Altera MAX 9000 - Altera FLEX –Design systems - Logic Synthesis - Half gate ASIC -Schematic entry - Low level design language - PLA tools -EDIF- CFI design representation.
UNIT IV 9
LOGIC SYNTHESIS, SIMULATION AND TESTING
Verilog and logic synthesis -VHDL and logic synthesis - types of simulation -boundary scan test - fault simulation - automatic test pattern generation.
UNIT V 9
ASIC CONSTRUCTION, FLOOR PLANNING, PLACEMENT AND ROUTING
System partition - FPGA partitioning - partitioning methods - floor planning - placement - physical design flow –global routing - detailed routing - special routing - circuit extraction - DRC.
TOTAL : 45
REFERENCES
1. M.J.S .Smith, "Application Specific Integrated Circuits, Addison -Wesley Longman Inc., 1997.
2. Farzad Nekoogar and Faranak Nekoogar, From ASICs to SOCs: A Practical Approach, Prentice Hall PTR, 2003.
3. Wayne Wolf, FPGA-Based System Design, Prentice Hall PTR, 2004.
4. R. Rajsuman, System-on-a-Chip Design and Test. Santa Clara, CA: Artech House Publishers, 2000.
5. F. Nekoogar. Timing Verification of Application-Specific Integrated Circuits (ASICs). Prentice Hall PTR, 1999.
AN1626 DESIGN AND ANALYSIS OF ALGORITHMS 3 0 0 100
UNIT I 9
INTRODUCTION
Polynomial and Exponential algorithms, big "oh" and small "oh" notation, exact algorithms and heuristics, direct / indirect / deterministic algorithms, static and dynamic complexity, stepwise refinement.
UNIT II 9
DESIGN TECHNIQUES
Subgoals method, working backwards, work tracking, branch and bound algorithms for traveling salesman problem and knapsack problem, hill climbing techniques, divide and conquer method, dynamic programming, greedy methods.
UNIT III 9
SEARCHING AND SORTING
Sequential search, binary search, block search, Fibonacci search, bubble sort, bucket sorting, quick sort, heap sort, average case and worst case behavior, FFT.
UNIT IV 9
GRAPH ALGORITHMS
Minimum spanning, tree, shortest path algorithms, R-connected graphs, Even's and Kleitman's algorithms, ax-flow min cut theorem, Steiglitz's link deficit algorithm.
UNIT V 9
SELECTED TOPICS
NP Completeness Approximation Algorithms, NP Hard Problems, Strasseu's Matrix Multiplication Algorithms, Magic Squares, Introduction To Parallel Algorithms and Genetic Algorithms, Monti-Carlo Methods, Amortised Analysis.
TOTAL : 45
REFERENCES
1. Sara Baase, "Computer Algorithms : Introduction to Design and Analysis", Addison Wesley, 1988.
2. T.H.Corman, C.E.Leiserson and R.L.Rioest, "Introduction to Algorithms", Mc Graw Hill, 1994.
3. E.Horowitz and S.Sahni, "Fundamentals of Computer Algorithms", Galgotia Publications, 1988.
4. D.E.Goldberg, "Genetic Algorithms : Search Optimization and Machine Learning", Addison Wesley, 1989.
AN1627 RELIABILITY ENGINEERING 3 0 0 100
UNIT I 9
PROBABILITY PLOTTING AND LOAD-STRENGTH INTERFERENCE
Statistical distribution , statistical confidence and hypothesis testing ,probability plotting techniques – Weibull, extreme value ,hazard, binomial data; Analysis of load – strength interference , Safety margin and loading roughness on reliability.
UNIT II 9
RELIABILITY PREDICTION, MODELLING AND DESIGN
Statistical design of experiments and analysis of variance Taguchi method, Reliability prediction, Reliability modeling, Block diagram and Fault tree Analysis ,petric Nets, State space Analysis, Monte carlo simulation, Design analysis methods – quality function deployment, load strength analysis, failure modes, effects and criticality analysis.
UNIT III 9
ELECTRONICS AND SOFTWARE SYSTEMS RELIABILITY
Reliability of electronic components, component types and failure mechanisms, Electronic system reliability prediction, Reliability in electronic system design; software errors, software structure and modularity, fault tolerance, software reliability, prediction and measurement, hardware/software interfaces.
UNIT IV 9
RELIABILITY TESTING AND ANALYSIS
Test environments, testing for reliability and durability, failure reporting, Pareto analysis, Accelerated test data analysis, CUSUM charts, Exploratory data analysis and proportional hazards modeling, reliability demonstration, reliability growth monitoring.
UNIT V 9
MANUFACTURE AND RELIABILITY MAQNAGEMENT
Control of production variability, Acceptance sampling, Quality control and stress screening, Production failure reporting; preventive maintenance strategy, Maintenance schedules, Design for maintainability, Integrated reliability programmes , reliability and costs, standard for reliability, quality and safety, specifying reliability, organization for reliability.
TOTAL: 45
REFERENCES
1. Patrick D.T. O’Connor, David Newton and Richard Bromley, Practical Reliability Engineering, Fourth edition, John Wiley & Sons, 2002
2. David J. Klinger, Yoshinao Nakada and Maria A. Menendez, Von Nostrand Reinhold, New York, "AT & T Reliability Manual", 5th Edition, 1998.
3. Gregg K. Hobbs, "Accelerated Reliability Engineering - HALT and HASS", John Wiley & Sons, New York, 2000.
4. Lewis, "Introduction to Reliability Engineering", 2nd Edition, Wiley International, 1996.
VL1623 VLSI SIGNAL PROCESSING 3 0 0 100
UNIT I 9
INTRODUCTION TO DSP SYSTEMS
Introduction To DSP Systems -Typical DSP algorithms; Iteration Bound – data flow graph representations, loop bound and iteration bound, Longest path Matrix algorithm; Pipelining and parallel processing – Pipelining of FIR digital filters, parallel processing, pipelining and parallel processing for low power.
UNIT II 9
RETIMING
Retiming - definitions and properties; Unfolding – an algorithm for Unfolding, properties of unfolding, sample period reduction and parallel processing application; Algorithmic strength reduction in filters and transforms – 2-parallel FIR filter, 2-parallel fast FIR filter, DCT algorithm architecture transformation, parallel architectures for rank-order filters, Odd- Even Merge- Sort architecture, parallel rank-order filters.
UNIT III 9
FAST CONVOLUTION
Fast convolution – Cook-Toom algorithm, modified Cook-Took algorithm; Pipelined and parallel recursive and adaptive filters – inefficient/efficient single channel interleaving, Look- Ahead pipelining in first- order IIR filters, Look-Ahead pipelining with power-of-two decomposition, Clustered Look-Ahead pipelining, parallel processing of IIR filters, combined pipelining and parallel processing of IIR filters, pipelined adaptive digital filters, relaxed look-ahead, pipelined LMS adaptive filter.
UNIT IV 9
BIT-LEVEL ARITHMETIC ARCHITECTURES
Scaling and roundoff noise- scaling operation, roundoff noise, state variable description of digital filters, scaling and roundoff noise computation, roundoff noise in pipelined first-order filters; Bit-Level Arithmetic Architectures- parallel multipliers with sign extension, parallel carry-ripple array multipliers, parallel carry-save multiplier, 4x 4 bit Baugh- Wooley carry-save multiplication tabular form and implementation, design of Lyon’s bit-serial multipliers using Horner’s rule, bit-serial FIR filter, CSD representation, CSD multiplication using Horner’s rule for precision improvement.
UNIT V 9
PROGRAMMING DIGITAL SIGNAL PROCESSORS
Numerical Strength Reduction – sub expression elimination, multiple constant multiplications, iterative matching. Linear transformations; Synchronous, Wave and asynchronous pipelining- synchronous pipelining and clocking styles, clock skew in edge-triggered single-phase clocking, two-phase clocking, wave pipelining, asynchronous pipelining bundled data versus dual rail protocol; Programming Digital Signal Processors – general architecture with important features; Low power Design – needs for low power VLSI chips, charging and discharging capacitance, short-circuit current of an inverter, CMOS leakage current, basic principles of low power design.
TOTAL : 45
REFERENCES
1. Keshab K.Parhi, “VLSI Digital Signal Processing systems, Design and implementation”, Wiley, Inter Science, 1999.
2. Gary Yeap, “Practical Low Power Digital VLSI Design”, Kluwer Academic Publishers, 1998.
3. Mohammed Isamail and Terri Fiez, “Analog VLSI Signal and Information Processing”, Mc Graw-Hill, 1994.
4. S.Y. Kung, H.J. White House, T. Kailath, “VLSI and Modern Signal Processing”, Prentice Hall, 1985.
5. Jose E. France, Yannis Tsividis, “Design of Analog - Digital VLSI Circuits for Telecommunication and Signal Processing”, Prentice Hall, 1994.
AN1628 INTERNETWORKING MULTIMEDIA 3 0 0 100
UNIT I 9
MULTIMEDIA NETWORKING
Digital sound, video and graphics, basic multimedia networking, multimedia characteristics, evolution of Internetservices model, network requirements for audio/ video transform, multimedia coding and compression for text, image, audio and video.
UNIT II 9
BROAD BAND NETWORK TECHNOLOGY
Broadband services, ATM and IP, IPV6, High speed switching, resource reservation, Buffer management, traffic shaping, caching, scheduling, and policing, throughput, delay and jitter performance. Storage and media services, voice and video over IP, MPEG-2 over ATM/IP, indexing synchronization of requests, recording and remote control.
UNIT III 9
RELIABLE TRANSPORT PROTOCOL AND APPLICATIONS
Multicast over shared media network, multicast routing and addressing, scaping multicast and NBMA networks, Reliable transport protocols, TCP adaptation algorithm, RTP, RTCP. MIME, Peer- to-Peer computing, shared application, video conferencing, centralized and distributed conference control, distributed virtual reality, light weight session philosophy.
UNIT IV 9
MULTIMEDIA COMMUNICATION STANDARDS
Objective of MPEG- 7 standard, Functionalities and systems of MPEG-7, MPEG-21 Multimedia Framework Architecture, - Content representation, Content Management and usage, Intellectual property management, Audio visual system- H322: Guaranteed QOS LAN systems; MPEG_4 video Transport across internet.
UNIT V 9
MULTIMEDIA COMMUNICATION ACROSS NETWORKS
Packet Audio/video in the network environment, video transport across Generic networks- Layered video coding, error Resilient video coding techniques, Scalable Rate control, Streaming video across Internet, Multimedia transport across ATM networks and IP network, Multimedia across wireless networks.
TOTAL : 45
REFERENCES
1. Jon Crowcroft, Mark Handley, Ian Wakeman, Internetworking Multimedia,
Harcourt Asia Pvt. Ltd. Singapore, 1998.
2. B.O. Szuprowicz, Multimedia Networking, McGraw Hill, NewYork. 1995
3. Tay Vaughan, Multimedia making it to work, 4ed, Tata McGraw Hill , New Delhi, 2000.
4. K.R.Rao, Zoran S. Bojkovic and Dragorad A. Milovanovic, Multimedia Communication systems, PHI , 2003 ( Unit 4 and Unit 5)
AN1629 ELECTROMAGNETIC INTERFERENCE AND COMPATIBILITY IN SYSTEM DESIGN 3 0 0 100
UNIT I 9
EMI ENVIRONMENT
EMI/EMC concepts and definitions, Sources of EMI, conducted and radiated EMI, Transient EMI, Time domain Vs Frequency domain EMI, Units of measurement parameters, Emission and immunity concepts, ESD.
UNIT II 9
EMI COUPLING PRINCIPLES
Conducted, Radiated and Transient Coupling, Common Impedance Ground Coupling, Radiated Common Mode and Ground Loop Coupling, Radiated Differential Mode Coupling, Near Field Cable to Cable Coupling, Power Mains and Power Supply coupling.
UNIT III 9
EMI/EMC STANDARDS AND MEASUREMENTS
Civilian standards - FCC,CISPR,IEC,EN,Military standards - MIL STD 461D/462, EMI Test Instruments /Systems, EMI Shielded Chamber, Open Area Test Site, TEM Cell, Sensors/Injectors/Couplers, Test beds for ESD and EFT, Military Test Method and Procedures (462).
UNIT IV 9
EMI CONTROL TECHNIQUES
Shielding, Filtering, Grounding, Bonding, Isolation Transformer, Transient Suppressors, Cable Routing, Signal Control, Component Selection and Mounting.
UNIT V 9
EMC DESIGN OF PCBs
PCB Traces Cross Talk, Impedance Control, Power Distribution Decoupling, Zoning, Motherboard Designs and Propagation Delay Performance Models.
TOTAL : 45
REFERENCES
1. Henry W.Ott, "Noise Reduction Techniques in Electronic Systems", John Wiley and Sons, NewYork. 1988.
2. C.R.Paul, “Introduction to Electromagnetic Compatibility” , John Wiley and Sons, Inc, 1992
3. V.P.Kodali, "Engineering EMC Principles, Measurements and Technologies", IEEE Press, 1996.
4. Bernhard Keiser, "Principles of Electromagnetic Compatibility", Artech house, 3rd Ed, 1986.
AN1630 HIGH PERFORMANCE COMMUNICATION NETWORKS 3 0 0 100
UNIT I 9
PACKET SWITCHED NETWORKS
OSI and IP models, Ethernet (IEEE 802.3), Token ring (IEEE 802.5), Wireless LAN (IEEE 802.11) FDDI, DQDB, SMDS: Internetworking with SMDS
UNIT II 9
ISDN AND BROADBAND ISDN
ISDN - overview, interfaces and functions, Layers and services - Signaling System 7 - Broadband ISDN architecture and Protocols.
UNIT III 9
ATM AND FRAME RELAY
ATM: Main features-addressing, signaling and routing, ATM header structure-adaptation layer, management and control, ATM switching and transmission.
Frame Relay: Protocols and services, Congestion control, Internetworking with ATM, Internet and ATM, Frame relay via ATM.
UNIT IV 9
ADVANCED NETWORK ARCHITECTURE
IP forwarding architectures overlay model, Multi Protocol Label Switching (MPLS), integrated services in the Internet, Resource Reservation Protocol (RSVP), Differentiated services
UNIT V 9
BLUE TOOTH TECHNOLOGY
The Blue tooth module-Protocol stack Part I: Antennas, Radio interface, Base band, The Link controller, Audio, The Link Manager, The Host controller interface; The Blue tooth module-Protocol stack Part I: Logical link control and adaptation protocol, RFCOMM, Service discovery protocol, Wireless access protocol, Telephony control protocol.
TOTAL : 45
REFERENCES
1. William Stallings,”ISDN and Broadband ISDN with Frame Relay and ATM”, 4th edition, Pearson education Asia, 2002.
2. Leon Gracia, Widjaja, “Communication networks ", Tata McGraw-Hill, New Delhi, 2000.
3. Jennifer Bray and Charles F.Sturman,”Blue Tooth” Pearson education Asia, 2001.
4. Sumit Kasera, Pankaj Sethi, “ATM Networks ", Tata McGraw-Hill, New Delhi, 2000.
5. Rainer Handel, Manfred N.Huber, Stefan Schroder,”ATM Networks”,3rd edition, Pearson education asia,2002.
6. Jean Walrand and Pravin varaiya, “High Performance Communication networks”, 2nd edition, Harcourt and Morgan Kauffman, London 2000.
7. William Stallings,”High-speed Networks and Internets”, 2nd edition, Pearson education Asia, 2003.
VL1625 ANALOG VLSI DESIGN 3 0 0 100
UNIT I 9
BASIC CMOS CIRCUIT TECHNIQUES, CONTINUOUS TIME AND LOW-VOLTAGESIGNAL PROCESSING:
Mixed-Signal VLSI Chips-Basic CMOS Circuits-Basic Gain Stage-Gain Boosting Techniques-Super MOSTransistor- Primitive Analog Cells-Linear Voltage-Current Converters-MOS Multipliers and Resistors-CMOS,Bipolar and Low-Voltage BiCMOS Op-Amp Design-Instrumentation Amplifier Design-Low Voltage Filters.
UNIT II 9
BASIC BICMOS CIRCUIT TECHNIQUES, CURRENT -MODE SIGNAL PROCESSING AND NEURAL INFORMATION PROCESSING
Continuous-Time Signal Processing-Sampled-Data Signal Processing-Switched-Current Data Converters-Practical Considerations in SI Circuits Biologically-Inspired Neural Networks - Floating - Gate, Low-Power Neural Networks-CMOS Technology and Models-Design Methodology-Networks-Contrast Sensitive Silicon Retina.
UNIT III 9
SAMPLED-DATA ANALOG FILTERS, OVER SAMPLED A/D CONVERTERS AND
ANALOG INTEGRATED SENSORS
First-order and Second SC Circuits-Bilinear Transformation - Cascade Design-Switched-Capacitor Ladder Filter-Synthesis of Switched-Current Filter- Nyquist rate A/D Converters-Modulators for Over sampled A/D Conversion-First and Second Order and Multibit Sigma-Delta Modulators-Interpolative Modulators –Cascaded Architecture-Decimation Filters-mechanical, Thermal, Humidity and Magnetic Sensors-Sensor Interfaces.
UNIT IV 9
DESIGN FOR TESTABILITY AND ANALOG VLSI INTERCONNECTS
Fault modelling and Simulation - Testability-Analysis Technique-Ad Hoc Methods and General Guidelines-Scan Techniques-Boundary Scan-Built-in Self Test-Analog Test Buses-Design for Electron -Beam Testablity-Physics of Interconnects in VLSI-Scaling of Interconnects-A Model for Estimating Wiring Density-A Configurable Architecture for Prototyping Analog Circuits.
UNIT V 9
STATISTICAL MODELING AND SIMULATION, ANALOG COMPUTER-AIDED DESIGN AND ANALOG AND MIXED ANALOG-DIGITAL LAYOUT
Review of Statistical Concepts - Statistical Device Modeling- Statistical Circuit Simulation-Automation Analog Circuit Design-automatic Analog Layout-CMOS Transistor Layout-Resistor Layout-Capacitor Layout-Analog Cell Layout-Mixed Analog -Digital Layout.
TOTAL : 45
REFERENCES
1. Mohammed Ismail, Terri Fiez, “Analog VLSI signal and Information Processing ", McGraw-Hill International Editons, 1994.
2. Malcom R.Haskard, Lan C.May, “Analog VLSI Design - NMOS and CMOS ", Prentice Hall, 1998.
3. Randall L Geiger, Phillip E. Allen, " Noel K.Strader, VLSI Design Techniques for Analog and Digital Circuits ", Mc Graw Hill International Company, 1990.
4. Jose E.France, Yannis Tsividis, “Design of Analog-Digital VLSI Circuits for Telecommunication and signal Processing ", Prentice Hall, 1994
VL1651 COMPUTER AIDED DESIGN OF VLSI CIRCUITS 3 0 0 100
UNIT I 9
Introduction to VLSI Design methodologies - Review of Data structures and algorithms - Review of VLSI Design automation tools - Algorithmic Graph Theory and Computational Complexity - Tractable and Intractable problems - general purpose methods for combinatorial optimization.
UNIT II 9
Layout Compaction - Design rules - problem formulation - algorithms for constraint graph compaction - placement and partitioning - Circuit representation - Placement algorithms - partitioning
UNIT III 9
Floorplanning concepts - shape functions and floorplan sizing - Types of local routing problems - Area routing - channel routing - global routing - algorithms for global routing.
UNIT IV 9
Simulation - Gate-level modeling and simulation - Switch-level modeling and simulation - Combinational Logic Synthesis - Binary Decision Diagrams - Two Level Logic Synthesis.
UNIT V 9
High level Synthesis - Hardware models - Internal representation - Allocation ¬assignment and scheduling - Simple scheduling algorithm - Assignment problem – High level transformations.
TOTAL : 45
REFERENCES
1. S.H. Gerez, "Algorithms for VLSI Design Automation", John Wiley & Sons,2002.
2. N.A. Sherwani, "Algorithms for VLSI Physical Design Automation", Kluwar Academic Publishers, 2002.
3. Drechsler, R., Evolutionary Algorithms for VLSI CAD, Kluwer Academic Publishers, Boston, 1998.
4. Hill, D., D. Shugard, J. Fishburn and K. Keutzer, Algorithms and Techniques for VLSI Layout Synthesis, Kluwer Academic Publishers, Boston, 1989.
VL1622 LOW POWER VLSI DESIGN 3 0 0 100
UNIT I 9
POWER DISSIPATION IN CMOS
Hierarchy of limits of power – Sources of power consumption – Physics of power dissipation in CMOS FET devices- Basic principle of low power design.
UNIT II 9
POWER OPTIMIZATION
Logical level power optimization – Circuit level low power design – Circuit techniques for reducing power consumption in adders and multipliers.
UNIT III 9
DESIGN OF LOW POWER CMOS CIRCUITS
Computer Arithmetic techniques for low power systems – Reducing power consumption in memories – Low power clock, Interconnect and layout design – Advanced techniques – Special techniques
UNIT IV 9
POWER ESTIMATION
Power estimation techniques – Logic level power estimation – Simulation power analysis – Probabilistic power analysis.
UNIT V 9
SYNTHESIS AND SOFTWARE DESIGN FOR LOW POWER
Synthesis for low power –Behavioral level transforms- Software design for low power - TOTAL : 45
REFERENCES
1. K.Roy and S.C. Prasad , LOW POWER CMOS VLSI circuit design, Wiley,2000
2. Dimitrios Soudris, Chirstian Pignet, Costas Goutis, DESIGNING CMOS CIRCUITS FOR LOW POWER, Kluwer,2002
3. J.B. Kuo and J.H Lou, Low voltage CMOS VLSI Circuits, Wiley 1999.
4. A.P.Chandrakasan and R.W. Broadersen, Low power digital CMOS design, Kluwer,1995.
5. Gary Yeap, Practical low power digital VLSI design, Kluwer,1998.
6. Abdellatif Bellaouar,Mohamed.I. Elmasry, Low power digital VLSI design,s Kluwer, 1995.
7. James B. Kuo, Shin – chia Lin, Low voltage SOI CMOS VLSI Devices and Circuits. John Wiley and sons, inc 2001
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