VL9213 SOLID STATE DEVICE MODELING AND SIMULATION ME VLSI DESIGN SYLLABUS

VL 9213 SOLID STATE DEVICE MODELING AND SIMULATION

UNIT I MOSFET DEVICE PHYSICS  

MOSFET capacitor, Basic operation, Basic modeling,Advanced MOSFET modeling, RF modeling of MOS transistors, Equivalent circuit representation of MOS transistor, High frequency behavior of MOS transistor and A.C small signal modeling, model parameter extraction, modeling parasitic BJT, Resistors,Capacitors, Inductors.

UNIT II NOISE MODELING  

Noise sources in MOSFET, Flicker noise modeling, Thermal noise modeling, model for accurate distortion analysis, nonlinearities in CMOS devices and modeling, calculation of distortion in analog CMOS circuits

UNIT III BSIM4 MOSFET MODELING  

Gate dielectric model, Enhanced model for effective DC and AC channel length and width, Threshold voltage model, Channel charge model, mobility model, Source/drain resistance model, I-V model, gate tunneling current model, substrate current models, Capacitance models, High speed model, RF model, noise model, junction diode models, Layout-dependent parasitics model.

UNIT IV OTHER MOSFET MODELS  

The EKV model, model features, long channel drain current model, modeling second order effects of the drain current, modeling of charge storage effects, Nonquasi- static modeling, noise model temperature effects, MOS model  , MOSAI model)

UNIT V MODELLING OF PROCESS VARIATION AND QUALITY ASSURANCE

Influence of process variation, modeling of device mismatch for Analog/RF

Applications, Benchmark circuits for quality assurance, Automation of the tests

REFERENCES:

1. Trond Ytterdal, Yuhua Cheng and Tor A. FjeldlyWayne Wolf, “Device Modeling for

Analog and RF CMOS Circuit Design”, John Wiley & Sons Ltd.

AP9212 ADVANCED DIGITAL SYSTEM DESIGN ME VLSI DESIGN SYLLABUS

AP9212 ADVANCED DIGITAL SYSTEM DESIGN

UNIT I SEQUENTIAL CIRCUIT DESIGN

Analysis of clocked synchronous sequential circuits and modeling- State diagram, state table, state table assignment and reduction-Design of synchronous sequential circuits-design of iterative circuits-ASM chart and realization using ASM

UNIT II ASYNCHRONOUS SEQUENTIAL CIRCUIT DESIGN

Analysis of asynchronous sequential circuit – flow table reduction-races-state assignment-transition table and problems in transition table- design of asynchronous sequential circuit-Static, dynamic and essential hazards – data synchronizers –mixed operating mode asynchronous circuits – designing vending machine controller

UNIT III FAULT DIAGNOSIS AND TESTABILITY ALGORITHMS 

Fault table method-path sensitization method – Boolean difference method-D algorithm -Tolerance techniques – The compact algorithm – Fault in PLA – Test generation-DFT schemes – Built in self test

UNIT IV SYNCHRONOUS DESIGN USING PROGRAMMABLE DEVICES

Programming logic device families – Designing a synchronous sequential circuit using PLA/PAL – Realization of finite state machine using PLD – FPGA – Xilinx FPGA-Xilinx 4000

UNIT V SYSTEM DESIGN USING VHDL

VHDL operators – Arrays – concurrent and sequential statements – packages- Data flow – Behavioral – structural modeling – compilation and simulation of VHDL code –Test bench - Realization of combinational and sequential circuits using HDL –Registers – counters – sequential machine – serial adder – Multiplier- Divider – Design of simple microprocessor

REFERENCES:
1 Charles H.Roth Jr “Fundamentals of Logic Design” Thomson Learning 2004
2 Nripendra N Biswas “Logic Design Theory” Prentice Hall of India,2001
3 Parag K.Lala “Fault Tolerant and Fault Testable Hardware Design” B SPublications,2002
4 Parag K.Lala “Digital system Design using PLD” B S Publications,2003
5 Charles H Roth Jr.”Digital System Design using VHDL” Thomson learning,2004
6 Douglas L.Perry “VHDL programming by Example” Tata McGraw.Hill - 2006

VL9211 DSP INTEGRATED CIRCUITS ME VLSI DESIGN SYLLABUS

VL 9211 DSP INTEGRATED CIRCUITS

UNIT I 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 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 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 ratioL/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 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 ARITHMETIC UNITS AND INTEGRATED 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. Cordic algorithm.

REFERENCES:

1. Lars Wanhammer, “DSP Integrated Circuits”, 1999 Academic press, New York

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”, Second Edition, Pearson Education, Asia.

4. Keshab K.Parhi, “VLSI Digital Signal Processing Systems design and

Implementation”, John Wiley & Sons, 1999.

MA9217 APPLIED MATHEMATICS FOR ELECTRONICS ENGINEERS ME VLSI DESIGN SYLLABUS

MA9217 APPLIED MATHEMATICS FOR ELECTRONICS ENGINEERS

UNIT I FUZZY LOGIC 

Classical logic – Multivalued logics – Fuzzy propositions – Fuzzy quantifiers.

UNIT II MATRIX THEORY 

Some important matrix factorizations – The Cholesky decomposition – QR
factorization – Least squares method – Singular value decomposition - Toeplitz
matrices and some applications

UNIT III ONE DIMENSIONAL RANDOM VARIABLES 

Random variables - Probability function – moments – moment generating
functions and their properties – Binomial, Poisson, Geometric, Uniform,
Exponential, Gamma and Normal distributions – Function of a Random
Variable

UNIT IV DYNAMIC PROGRAMMING 

Dynamic programming – Principle of optimality – Forward and backward
recursion – Applications of dynamic programming – Problem of dimensionality.

UNIT V QUEUEING MODELS
Poisson Process – Markovian queues – Single and Multi-server Models –
Little’s formula - Machine Interference Model – Steady State analysis – Self
Service queue.

REFERENCES:
1. George J. Klir and Yuan, B., Fuzzy sets and fuzzy logic, Theory and
applications, Prentice Hall of India Pvt. Ltd., 1997.
2. Moon, T.K., Sterling, W.C., Mathematical methods and algorithms for
signal processing, Pearson Education, 2000.
3. Richard Johnson, Miller & Freund’s Probability and Statistics for Engineers,
7th Edition, Prentice – Hall of India, Private Ltd., New Delhi (2007).
4. Taha, H.A., Operations Research, An introduction, 7th edition, Pearson
education editions, Asia, New Delhi, 2002.
5. Donald Gross and Carl M. Harris, Fundamentals of Queueing theory, 2nd
edition, John Wiley and Sons, New York (1985).

PR2404 DESIGN AND FABRICATION LAB PRODUCTION ENGINEERING SEVENTH SEMESTER SYLLABUS

PR2404 DESIGN AND FABRICATION LAB

The objective of this project is to provide opportunity for the students to implement their
skills acquired in the previous semesters to practical problems.
The students in convenient groups of not more than 4 members have to take one small
item for design and fabrication. Every project work shall have a guide who is the member
of the faculty of the institution and if possible with an industry guide also.
The item chosen may be small machine elements (Example-screw jack, coupling,
machine vice, cam and follower, governor etc), attachment to machine tools, tooling
(jigs, fixtures etc), small gear box, automotive appliances, agricultural implements,
simple heat exchangers, small pumps, hydraulic /pneumatic devices etc.
The students are required to design and fabricate the chosen item in the college and
demonstrate its working apart from submitting the project report. The report should
contain assembly drawing, parts drawings, process charts relating to fabrication.

ME2405 MECHATRONICS LAB PRODUCTION ENGINEERING SEVENTH SEMESTER SYLLABUS

ME2405 MECHATRONICS LAB

LIST OF EXPERIMENTS
1. Design and testing of fluid power circuits to control
(i) Velocity (ii) direction and (iii) force of single and double acting actuators
2. Design of circuits with logic sequence using Electro pneumatic trainer kits.
3. Simulation of basic Hydraulic, Pneumatic and Electric circuits using software
4. Circuits with multiple cylinder sequences in Electro pneumatic using PLC
5. Speed Control of AC & DC drives
6. Servo controller interfacing for DC motor
7. PID controller interfacing 16
8. Stepper motor interfacing with 8051 Micro controller
(i) full step resolution (ii) half step resolution
9. Modeling and analysis of basic electrical, hydraulic and pneumatic systems using
appropriate softwares
10. Computerized data logging system with control for process variables like pressure
flow and temperature.

ME2404 COMPUTER AIDED SIMULATION AND ANALYSIS LAB PRODUCTION ENGINEERING SEVENTH SEMESTER SYLLABUS

ME2404 COMPUTER AIDED SIMULATION AND ANALYSIS LAB

Simulation of Air conditioning system with condenser temperature and evaporator
temperatures as input to get COP using C /MAT Lab.
Simulation of Hydraulic / Pneumatic cylinder using C / MAT Lab.
Simulation of cam and follower mechanism using C / MAT Lab.
B. Analysis (Simple Treatment only) 37
Stress analysis of a plate with a circular hole.
Stress analysis of rectangular L bracket
Stress analysis of an axi-symmetric component
Stress analysis of beams (Cantilever, Simply supported, Fixed ends)
Mode frequency analysis of a 2 D component
Mode frequency analysis of beams (Cantilever, Simply supported, Fixed ends)
Harmonic analysis of a 2D component
Thermal stress analysis of a 2D component
Conductive heat transfer analysis of a 2D component
Convective heat transfer analysis of a 2D component