Download - 215195297 Revised Syllabus Microelectronics
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Master of Science-Technology in Microelectronics (Syllabus)
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Master of Science - Technology in Microelectronics
( For candidates admitted after April-2012 ) Sl No
Sub Code Sub Title Credits
Sem III
1 MEL651 Theory of MOS Devices 3-0-3-4
2 MEL653 Digital System Design Using HDL 3-0-3-4
3 MEL655 Process Technology 3-0-3-4
4 MEL657 Design of VLSI Systems 3-0-3-4
5 MEL659 CMOS Analog IC 3-0-3-4
6 MEL661 Elective-1 a. Nanotechnology b. MEMS c. EDA for IC Implementation
3-0-3-4
7 MEL613 Term Paper 1 1
Sem IV
8 MEL652 Synthesis and Optimisation of Digital Circuits 3-0-3-4
9 MEL654 Low Power VLSI 3-0-3-4
10 MEL656 Mixed IC 3-0-3-4
11 MEL658 High speed VLSI Design 3-0-3-4
12 MEL660 Testing of VLSI Circuits 3-0-3-4
13 MEL662 Elective 2 a. System on Chip b. Optical IC c. Design for Manufacturability and Yield Management
3-0-3-4
14 MEL614 Term paper 2 1
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MEL651 Theory of MOS Devices
3-0-3-4
Max Hrs: 36
UNIT I
Junction Field Effect Transistors : Introduction, Construction and operation, current voltage
characteristic equation, Secondary effects, Small-Signal equivalent circuit, Figure of merit of JFET,
High-frequency equivalent circuit of JFET, high frequency limitations.
Metal Semiconductor junctions and devices: Introduction ,Energy band diagrams of Metal and
N semiconductor before and after contact, Schottky barrier diode, Rectifying Metal-N
semiconductor junction, Rectifying Metal-P semiconductor junction, comparision of Schottky
barrier diode with PN diode.
UNIT II
MESFET: Fabrication and Modes of Operation, Threshold Voltage, I-V Characteristics of Depletion
and Enhancement devices, relations between the voltages .
Metal Oxide Silicon Systems: Introduction, Energy band diagrams, Band-bending and the effect
of bias voltages, Threshold Voltage, Oxide charges in MOS Capacitors.
UNIT III
MOS DEVICE PHYSICS: general considerations ,MOS IV characteristics, second order effects,
mos device models
UNIT IV
Metal Oxide Semiconductor FET: Introduction, Construction and basic operation, Fabrication of
N-type MOSFET (N-MOS) on an integrated circuit chip, Regions of operation: Cut-off, Linear, and
Saturation regions, current voltage analytical relations, types of MOSFETs, control of threshold
voltage, the MOSFET switch and CMOS Inverter, comparison between MOSFET & BJT
UNIT V
Small-Signal Models of the MOS: Trans conductance ,Intrinsic Gate-Source and Gate-Drain
Capacitance , Input Resistance, Output Resistance ,Basic Small-Signal Model of the MOS
Transistor, Body Trans conductance, Parasitic Elements in the Small-Signal Model , MOS
Transistor Frequency Response, Short-Channel Effects in MOS Transistors, Velocity Saturation
from the Horizontal Field, Trans conductance and Transition Frequency, Mobility Degradation from
theoretical Field, Weak Inversion in MOS Transistors, Drain Current in Weak Inversion, Trans
conductance and transitionFrequency in Weak Inversion , Substrate Current Flow in MOS
Transistors
Text Books:
1. microelectronic devices,deepank nagchoudary, Pearson Education, 2006.
2. Semiconductor Devices, Kanaan Kano, Pearson Education, 2001.
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References:
1. Physics of Semiconductor Devices, K. N. Bhat, Narosa Publications, 2004. 2. Semiconductor Devices: Physics and Technology, S. M. Sze, Second Edition, Wiley India,
2008.
3. Analog circuit design by Razavi
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MEL653 Digital System Design Using HDL
3-0-3-4
Max Hrs: 36
Digital Design using VHDL (or Verilog)
I. Introduction to Logic Circuits: Variables and Functions Inversion ,Truth Tables, Logic
Gates and Networks , Boolean Algebra, Sum-of-Products and Product-of-Sums
Forms, NAND and NOR Logic Networks,
II. Introduction to Verilog: Lexical conventions, data types, system tasks and
compilation, Modules and ports, Data-flow Modeling, Behavioral modeling
III. Optimization of Logic Functions: Karnaugh Map, Strategy for Minimization
Minimization of Product-of-Sums Forms, Incompletely Specified Functions Multiple-
Output Circuits, Multilevel Synthesis, Analysis of Multilevel Circuits, Cubical
Representation, Cubes and Hypercubes, A Tabular Method for Minimization.
IV. Number Representation and Arithmetic Circuits: Positional Number Representation ,
Addition of Unsigned Numbers, Signed Numbers, Fast Adders, Carry-Look ahead
Adder, Design of Arithmetic Circuits Using CAD Tools, Multiplication, Other number
representations. (special emphasis can be given to verilog programming)
V. Combinational Circuit Design: Multiplexers, Decoders, Encoders, Code Converters,
Arithmetic Comparison Circuits, Verilog for Combinational Circuits.
VI. Sequential Circuit Design: Basic Latch, Gated SR Latch, Master-Slave and Edge-
Triggered D Flip-Flops, T Flip-Flop, JK Flip-Flop, Summary of Terminology, Registers,
Counters, Reset Synchronization, Other Types of Counters, Using Storage Elements
with CAD Tools, Using Registers and Counters with CAD Tools, Design Examples.
References:
1. Fundamentals of Digital Logic with Verilog Design, Stephen Brown
and Vranesic, McGraw Hill Publications.
2. Verilog HDL, Samir Palnitkar, 2nd Edition, ISBN-10:0130449113,
Publisher: Prentice Hall Copyright: 2003
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MEL655 Process Technology
3-0-3-4
Max Hrs: 36
Review of semiconductors: Introduction to ICs, Process and Product Trends, Increasing chip
and wafer size, Increasing chip and wafer size, Chip cost, Stages of manufacturing,
Crystal Growth & Wafer Preparation: Semiconductor materials preparation, Crystalline
Materials, Crystal orientation, Crystal Growth, Crystal & Wafer quality, Wafer preparation.
Wafer Fabrication: Wafer Terminology, Basic Wafer Operations, Wafer fabrication process
example, Wafer sort, Packaging.
Contamination Control: The problems (classes of contaminants), Contamination sources,
Clean air strategies, Clean room construction, Clean room maintenance.
CMOS process technology: Basic n-well/p-well process, Twin-tub process.
Process Yields: Yield measurement points, Wafer-Fabrication Yield Limiters, Wafer-sort
Yield limiters, Overall process yield.
Oxidation: Silicon oxide layer uses, Thermal Oxidation mechanisms, Rapid Thermal
Processing, Oxidant sources, Post oxidation evaluation.
Photolithography: Overview of the patterning process, Ten step patterning process, Basic
photoresist chemistry, Photoresist performance factors, photomasking process, Soft brake,
Alignment and expose, Photoresist development, Hard bake, Etching methods, Resist
stripping, OPC, Pellicles.
Doping: Formation of a Doped Region, Diffusion process steps, Ion implantation: concept,
system, Dopant concentration in implanted regions, Future of Doping.
Deposition: Introduction, Film Parameters, CVD basics, CVD process steps, CVD systems:
LPCVD, PECVD, Molecular beam epitaxy (MBE) systems
Metallization: Conductor metals, Deposition Methods, Vacuum evaporation method,
Sputtering.
Wafer fabrication costs, Chip packaging options, Chip characteristics, Package functions and
Design, Overview of packaging operations, Packaging processes, Package/Bare Die
Strategies, Package design.
References:
1. Peter Van Zant, Microchip Fabrication, 3rd Edition, McGraw-Hill, International Edition.
2. S.M. Sze, VLSI Technology, 2nd Edition, McGraw-Hill International Edition.
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MEL657 Design of VLSI Systems
3-0-3-4
Max Hrs: 36
Unit 1: Text1 & Text2
Design Methodology: Y chart, Structured design techniques with examples, Programmable
logic, GA and SoG design, Cell-based design, Full custom design, SoC.
Design Flows: VLSI flow, Automated layout generation, Custom design flow, Programmed
behavioral synthesis.
Design Economics: Nonrecurring and recurring engineering Costs, Fixed Costs, Schedule,
Person power, Project management, Design Reuse. 9 Hours
Unit 2: Text2
CMOS Logic Structureies: CMOS, BiCMOS, Pseudo-nMOS, Transmission gate, Dynamic,
Domino, Zipper, C2MOS, CVSL, SFPL logic.
Chip Design Methods: Behavioral synthesis, RTL synthesis, Logic optimization.
Design Capture Tools: HDL Design, Schematic Design, Layout Design, Floor planning and
Chip Composition.
Design Verification Tools: Simulation, Timing Verifiers, Network isomorphism, Netlist
comparison, Layout Extraction, Back-annotation, Design Rule Verification, Pattern
generation, EDA Tools for the System.
Control Unit Design: Finite State Machine Design procedure with example. 9 Hours
Unit 3: Text1 & Text2
Datapath Sub-system Design: Introduction, Addition, Subtraction, One/Zero detectors,
Comparators, Counters, Shifters, Multiplication, Division, Parallel Prefix computations.
9 Hours
Unit 4: Text1
Array Subsystem Design: SRAM, DRAM, Read only memory, Content Addressable
memory, Serial access memories, Programmable logic arrays.
Special Purpose Subsystems: Packaging, Power distribution, I/O, Clock. 9 Hours
REFERENCE BOOKS:
1. Niel Weste, David Harris, Ayan Banerjee, CMOS VLSI Design 3rd edidtion, Pearson education.
2. Niel Weste, Kamran Eshraghian, Principles of CMOS VLSI Design 2rd edidtion,
Pearson education.
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MEL659 CMOS Analog IC Design
3-0-3-4
Max Hrs: 36
Introduction and Background: MOS Device Basics, MOS Device Models, active RC Layout, Design Rules. 3 hours Single Stage Amplifiers: Common Source Amplifiers, Source Follower Common Gate, Cascode Structures and Folded Cascode Structures. 4 hours Current Mirrors: Simple Current Mirrors/Sources, Cascode Current Mirrors/Sources, Differential Pair with Current Mirror Load. 3 hours Differential Amplifier: Introduction to Differential Pair Amplifier, Quantitative Analysis to Differential Pair Amplifier, Common Mode Response, Differential Amplifiers with Different Loads, Effects of Mismatches. 4 hours Operational Amplifiers: Op Amps Low Frequency Analysis, Telescopic Op Amps, Folded Cascode Op Amps, Two Stage Op Amps, Common Mode Feedback. 4 hours Frequency Response: Frequency Response of Common Source Amplifiers, Source Follower Common Gate, Cascode Structures and Folded Cascode Structures, Differential Amplifiers, Single Ended Differential Pair. 4 hours Feedback: Voltage-Voltage, Current -Voltage, Voltage-Current &Current-Current Feedback Loadingeffects. 3 hours Frequency Compensation & Stability: Frequency Compensation Techniques in Telescopic Op Amps, Folded Cascode Op Amps, Two Stage Op Amps. 4 hours Operational Amplifier Applications: Filters, Applications, ADCS&DACS 3 hours Text Book 1.Design of Analog CMOS Integrated Circuits, Behzad Razavi, McGraw-Hill, 2000. References 2.Analysis and Design of Integrated Circuits, Paul R. Gray, Paul J. Hurst, Stephen H. Lewis, Robert G. Meyer, 4th Ed., Wiley, 2001.
3.Phillip E. Allen and Douglas R. Holberg, CMOS Analog Circuit Design, 2nd
edition, Oxford
University Press, 2002
References
1.Operation and Modeling of the MOS Transistor, Y. Tsividis, McGraw-Hill, 2nd Edition, 1999. 2.Analog Integrated Circuit Design, D. Johns and K.Martin, Wiley, 1997. 3.The Designers Guide to SPICE & SPECTRE,K. S. Kundert, Kluwer Academic Press, 1995
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MEL661.1 Nanotechnology
3-0-3-4
Max Hrs: 36
Electronic transport in 1,2 and 3 dimensions: Quantum confinement, energy subbands, quantum
wells, quantum wires, quantum dots. Effective mass, drude conduction and mean free path in
3D, ballistic conduction, phase coherence length, and quantized conductance in 1D.
Compound semiconductor nanostructures: growth of compound semiconductors, superlattices,
self-assembled quantum dots.
Nanoparticles, nanotubes and nanowires, fullerenes (buckyballs, grapheme
Molecular electronics: optoelectronic properties of molecular materials, nanotechnology, devices:
OLEDs, OTFTs.
Nanofabrication and nanopatterning: Optical, X-ray, and electron beam lithography, self-
assembled organic layers, scanning tunnelling microscopy, atomic force microscopy
References
1. Vladimir V. Mitin, Viatcheslav A. Kochelap, Michael A. Stroscio: Introduction to
Nanoelectronics: Science, Nanotechnology, Engineering, and Applications, Cambridge University
Press, 2008.
2. Rainer Waser: Nanoelectronics and Information Technology: Advanced Electronic Materials
and Novel Devices, Wiley-VCH, 2003.
3. Edward L. Wolf: Nanophysics and Nanotechnology: An Introduction to Modern Concepts in
Nanoscience, 2nd ed., Wiley-VCH, 2006.
4. John H. Davies: The Physics of Low Dimensional Semiconductors: An Introduction,
Cambridge University Press, 1998.
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MEL661.2 MEMS
3-0-3-4
Max Hrs: 36
UNIT - 1
INTRODUCTION TO MICRO AND SMART SYSTEMS:
a) What are smart-material systems? Evolution of smart materials, structures and systems.
Components of a smart system. Application areas. Commercial products.
b) What are microsystems? Feynmans vision. Micromachined transducers. Evolution of micro-
manufacturing. Multi-disciplinary aspects. Applications areas. Commercial products.
UNIT - 2
MICRO AND SMART DEVICES AND SYSTEMS: PRINCIPLES AND
MATERIALS:
a) Definitions and salient features of sensors, actuators, and systems.
b) Sensors: silicon capacitive accelerometer, piezo-resistive pressure sensor, blood analyzer,
conductometric gas sensor, fiber-optic gyroscope and surface-acoustic-wave based wireless strain
sensor.
c) Actuators: silicon micro-mirror arrays, piezo-electric based inkjet printhead, electrostatic comb-
drive and micromotor, magnetic micro relay, shapememory-alloy based actuator, electro-thermal
actuator.
4. d) Systems: micro gas turbine, portable clinical analyzer, active noise controlin a helicopter
cabin.
UNIT - 3
MICROMANUFACTURING AND MATERIAL PROCESSING:
a. Silicon wafer processing, lithography, thin-film deposition, etching (wetand dry), wafer-bonding,
and metallization.
b. Silicon micromachining: surface, bulk, moulding, bonding based process flows.
c. Thick-film processing:
d. Smart material processing:
e. Processing of other materials: ceramics, polymers and metals
f. Emerging trends
UNIT - 4
MODELING:
a. Scaling issues. 69
b. Elastic deformation and stress analysis of beams and plates. Residual stresses and stress
gradients. Thermal loading. Heat transfer issues. Basic fluids issues.
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c. Electrostatics. Coupled electromechanics. Electromagnetic actuation. Capillary electro-phoresis.
Piezoresistive modeling. Piezoelectric modeling. Magnetostrictive actuators.
UNIT - 5
COMPUTER-AIDED SIMULATION AND DESIGN:
Background to the finite element element method. Coupled-domain simulations using Matlab.
Commercial software.
UNIT - 6
ELECTRONICS, CIRCUITS AND CONTROL:
Carrier concentrations, semiconductor diodes, transistors, MOSFET amplifiers, operational
amplifiers. Basic Op-Amp circuits. Charge-measuring circuits. Examples from microsystems. Transfer
function, state-space modeling, stability, PID controllers, and model order reduction. Examples
from smart systems and micromachined accelerometer or a thermal cycler. 8 Hours
UNIT - 7
INTEGRATION AND PACKAGING OF MICROELECTRO
MECHANICAL SYSTEMS:
Integration of microelectronics and micro devices at wafer and chip levels. Microelectronic
packaging: wire and ball bonding, flip-chip. Lowtemperature- cofired-ceramic (LTCC) multi-chip-
module technology. Microsystem packaging examples.
TEXT BOOKS
MEMS & Microsystems: Design and Manufacture, Tai-Ran Tsu,
REFERENCE BOOKS:
Analysis and Design Principles of MEMS Devices, Minhang Bao,
Elsevier, Amsterdam, The Netherlands, ISBN 0-444-51616-6.
Design and Development Methodologies,
1.Smart Material Systemsand MEMS: V. Varadan, K. J. Vinoy, S. Gopalakrishnan, Wiley.
2.. MEMS- Nitaigour Premchand Mahalik, TMH 2007
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MEL661.3 EDA for IC Implementation
3-0-3-4
Max Hrs: 36
EDA for Digital IC
Design Flows: Introduction to Digital design flow, Integration, future scaling challenges
Basics of Synthesis: Definition of Synthesis, Behavioral and RTL synthesis
Equivalence checking: Equivalence checking problem, Boolean reasoning, Combinational
equivalence checking, sequential equivalence checking
Placement: Placement problem, Global placement and detailed placement
Static timing analysis: Representation, Gate-delay models, Timing analysis of combinational
and sequential circuits, statistical STA.
Routing: Routing, Types of Routers, Common routing algorithms
EDA for Analog and RF IC
Simulation of Analog and RF Circuits: Differential Algebraic equations for circuits, Device
models, basic circuit simulations, steady state analysis, multi time analysis, Noise in RF
design.
EDA for Physical Verification
Design Rule Checking: Geometrical algorithms for physical verification, Hierarchical data
structures, Time complexity of hierarchical Analysis, Connectivity models.
References: (As of now one text is prescribed, few Journal papers will be added further)
EDA for IC Implementation, Circuit Design and Process Technology, Edited by
Louis Scheffer, Cadence Design Systems San Jose, California, U.S.A. Luciano Lavagno,
Cadence Berkeley Laboratories, Berkeley, California, U.S.A., Grant Martin Tensilica
Santa Clara, California, U.S.A. CRC- Taylor and Francis.
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MEL652 Synthesis and Optimisation of Digital Circuits
3-0-3-4
Max Hrs: 36
Introduction: Microelectronics, Semiconductor technologies and circuit taxonomy, Micro-
electronic design styles, Design of microelectronics circuits, Computer aided synthesis and
optimization. 4 Hours
Graphs: Notation, Graphs, Combinatorial optimization, Graph optimization problems and
algorithms, Boolean algebra and applications. 8 Hours
Hardware Modeling: Introduction, Abstract models, Compilation and Behavioral
optimization techniques.
3 Hours
Schedule Algorithms: A model for scheduling problems, Scheduling without resource
constraints (5.3.1, 5.3.2, 5.3.3), Scheduling with resource constraints, Scheduling algorithms
for extended sequencing models, Scheduling pipe lined circuits. 6 Hours
Two Level Combinational Logic Optimization: Logic optimization principles, Operation
on two level logic covers, Algorithms for logic minimization (7.4.1 -7.4.4), Symbolic
minimization and encoding property. 9 Hours
Multiple Level Combinational Optimizations: Models and transformations for
combinational networks (8.2.1 & 8.2.2), Algebraic model, Algorithm for delay evaluation
and optimization (8.6.1 & 8.6.3), Rule based system for logic optimization.
4 Hours
Sequential Circuit Optimization: Sequential circuit optimization using state based models
(State minimization and FSM decomposition). 2 Hours
REFERENCE BOOKS:
1. Giovanni De Micheli, Synthesis and Optimization of Digital Circuits, Tata McGraw-Hill, Edition 2003.
2. Srinivas Devadas, Abhijit Ghosh, and Kurt Keutzer, Logic Synthesis, McGraw-Hill, USA, 1994.
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MEL654 Low Power VLSI
3-0-3-4
Max Hrs: 36
Introduction top Low Power VLSI Design
Need for low power VLSI Design, Sources of power dissipation on Digital Integrated circuits. Physics of power dissipation in CMOS devices. Emerging Low power approaches.
Section:I (Technology and Devices):
Dynamic dissipation in CMOS, Transistor sizing & gate oxide thickness, Impact of technology Scaling, Technology & Device innovation, evolution of deep sub-micron bulk and SOI technologies, Leakage in CMOS nanometric technologies.
Section II (Low power Design Techniques):
Circuit level: Power consumption in circuits. Flip Flops & Latches design, high capacitance nodes, low
power digital cells library, low power very fast dynamic logic circuits, circuit techniques for dynamic
power reduction, circuit techniques for leakage reduction, Adiabatic and clock powered circuits.
Logic level: Gate reorganization, signal gating, logic encoding, state machine encoding, pre-computation logic, Verilog/VHDL for low power.
System level:Power & performance management, switching activity reduction, parallel architecture with voltage reduction, flow graph transformation, low power arithmetic components, low power memory design.
Low power Clock Distribution: Power dissipation in clock distribution, single driver Vs distributed buffers, Zero skew Vs tolerable skew, chip & package co design of clock network.
Section III (CAD tools for Low power):
Power estimation, Simulation Power analysis: SPICE circuit simulators, gate level logic simulation, capacitive power estimation, static state power, gate level capacitance estimation, architecture level analysis, data correlation analysis in DSP systems, Monte Carlo simulation. Probabilistic power analysis: Random logic signals, probability & frequency, probabilistic power analysis techniques, signal entropy. Synopsys tools for low power design, Magma tools for low power design.
Text Books:
1. Gary K. Yeap, Practical Low Power Digital VLSI Design, KAP, 2002 2. Rabaey, Pedram, Low power design methodologies Kluwer Academic, 1997 3. Kaushik Roy, Sharat Prasad, Low-Power CMOS VLSI Circuit Design Wiley, 2000 4. Low power CMOS circuits, Logic design and CAD tool. Christian Piguet, CRC Press, Taylor and Francis, 2006.
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MEL656 Mixed IC
3-0-3-4
Max Hrs: 36
1.Introduction to Mixed signal Circuit Design: Challenges and opportunities Need for mixed signal circuits
and systems, software tools, industry trends, Research in mixed signal and Road Map.
2. Advanced Continuous Time Filter
3. Design of MOSFET-C Filter& Gm-C Filters 4 Sample and Holds, Voltage References and Translinear Circuits 5 Advanced switched capacitor circuits Introduction, general consideration, sampling switches - speed and precision consideration, switched capacitor
amplifiers, switched capacitor integrators and switched capacitor filters.
6.Data converters Fundamental: Introduction, basic building blocks, analog versus discrete time signal,
sample and hold characteristics, DAC & ADC specifications- Differential Non Linearity (DNL), Integral Non
Linearity (INL), offset error, gain error, latency, dynamic range, Signal to Noise Ratio (SNR), Spurious Free
Dynamic Range (SFDR) and Effective Number of Bits (ENOB).
7.DAC Design: Introduction, transistor level design of sub circuits for ADCs and architecture level design of
resistor string DAC, mismatch errors related to the resistor string DAC, R-2R DAC- current mode, Voltage
mode, current steering DAC, mismatch errors related to the current steering DAC, charge scaling DACs, cyclic
DAC and pipeline DAC.
8.ADC Design: Introduction, transistor level design of sub circuits for ADCs and architecture level design of
Flash ADC, two steps flash ADC, pipeline ADC, integrated ADC, accuracy issues, successive approximation
ADC and over sampling ADC. 9. Phase Locked Loop (PLL) Design: Introduction, building blocks, Phase Frequency Detector (PFD), charge pump, Voltage Controlled Oscillators (VCO), loop filter. Non ideal effects in PLL, frequency multiplication and
synthesizers
Books
1. R. Jacob Baker, CMOS: Circuit Design, Layout and Simulation, 3rd
edition Wiley-IEEE, 2010
2. R. Jacob Baker, CMOS: Mixed Signal Circuit Design, Wiley-IEEE, 2002
3. Phillip E. Allen and Douglas R. Holberg, CMOS Analog Circuit Design, 2nd
edition, Oxford University Press,
2002
4. David Johns and Ken Martin, Analog Integrated Circuit Design, Wiley- India, 2008.
References R. Jacob Baker:CMOS Mixed Signal Circuits Design, Weslly-IEEE 2002
R. Gregorian and Ternes:Analog MOS integrated circuits for signal processing, JosseyBass, 1986.
R.Gregorian:Introduction to CMOS OP-AMPs and comparators, John-Wiley, 1999.
D.Johns and K.Martin:Analog integrated circuit design, John-Wiley, 1997.
Monolithic Phase-locked loops and clock recovery circuits: Theory and design, IEEE Press,
1996
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MEL658 High speed VLSI Design
3-0-3-4
Max Hrs: 36
Introduction to High Speed Digital Design: Frequency, time and distance, Capacitance and
Inductance Effects High speed properties of logical gates, Speed and power, modeling of wires,
Geometry and Electrical properties of wires, Electrical model of wires, transmission lines, lossless LC
transmission lines, lossy RLC transmission lines Special transmission lines, signal propagation on
interconnects in DSM .
Power Distribution and Noise: Power supply network, Local power regulation, IR drops, Area
Bonding, On chip bypass capacitors, Symbiotic bypass capacitors, Power supply isolation Noise
sources in digital system, Power supply Noise, Ground bounce, Cross talk, near end and far end cross
talk, Inter-symbol interference., managing noise in digital systems
Signaling convention and Circuits:, Signaling modes for transmission lines, Signaling over lumped
transmission media, Signaling over RC interconnects, driving lossy LC lines, simultaneous
Bidirectional Signaling, terminators in transmitter and receiver circuits.
Timing Convention and Synchronization:, Timing fundamentals, Timing properties of clocked storage
elements, signals and events, open loop Timing , level sensitive clocking, pipeline Timing , closed
loop Timing clock Distribution, Synchronization failure and meta stability, PLL and DLL based lock
aligners.
Pseudo-MOS logic, Pass transistors, Transmission gates, Dynamic and domino logic, single rail and
dual rail designs, MODL. NORA and ZIPPER logic, Flip Flop and Latch structures, TSPC and CCMOS
latches.
TEXT BOOKS
1. Digital System Engineering, William S.Dally & John W. Paulton, Cambridge University Press,1998. 2. High Speed Digital Circuits, Masakazu Shoji.,Addison Wesley Publishing Company, 1996 REFERENCES
1. Digital Integrated Circuits: A design Perspective, Jan M.Rabaey et al;2nd Edition 2003
2. Basic VLSI Design, Douglas A.Pucknell & Kamran Eshraghian, Prentice Hall,1994.
3. Design for Test for Digital ICs & Embedded core Systems, Alfred L Crouch; Prentice Hall.
4. High Speed Digital Design-A Hand book of Black Magic, Howard Johnson & Martin Graham,
Prentice Hall PTR,1993.
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MEL660 Testing of VLSI Circuits
3-0-3-4
Max Hrs: 36
Unit 1: 6 Hours
Introduction to Testing:
Introduction, Test economics and product quality, Fault modeling. 6 Hours
Unit 2: 18 Hours
Test Methods:
Logic and fault simulation, Testability measures. 6 Hours
Combinational circuit test generation, Sequential circuit test generation 6 Hours
Delay test, IDDQ test. 6 Hours
Unit 3: 12 Hours
Design for Testability:
Digital DFT and scan design. 3 Hours
Built-in self test. 6 Hours
Boundary scan 3 Hours
Reference:
1. M. L. Bushnell and V. D. Agrawal, Essentials for Testing of Digital, Memory and Mixed-Signal
VLSI Circuits, Springer, 2000.
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MEL662.3 System on Chip
3-0-3-4
Max Hrs: 36
System On Chip Design Process: A canonical SoC Design, SoC Design flow, waterfall vs spiral, top-
down vs Bottom up. Specification requirement, Types of Specification , System Design process,
System level design issues Soft IP Vs Hard IP, Design for timing closure, Logic design issues,
Verification strategy, On-chip buses and interfaces, Low Power, Manufacturing test strategies.
Macro Design Process: Top level Macro Design, Macro Integration, Soft Macro productization,
Developing hard macros, Design issues for hard macros, Design ,System Integration with reusable
macros., design examples
SoC Verification:, Verification technology options, Verification methodology, Verification languages,
Verification approaches, and Verification plans. System level verification, Block level verification,
Hardware/software co-verification and Static net list verification.
Design of Communication Architectures for SoCs: On chip communication architectures, System level
analysis for designing communication, Design space exploration, Adaptive communication
architectures, Communication architecture tuners, Communication architectures for energy/battery
efficient systems. Introduction to NOCs
MPSoCs:-What, Why and How of MPSoCs, Techniques for designing MPSoCs, Performance and
flexibility for MPSoCs design, MPSoCs performance modeling and analysis. System In Package (SIP)
design.
TEXT BOOKS
1. SoC VerificationMethodology and Techniques,Prakash Rashinkar Peter Paterson and Leena
Singh .Kluwer Academic Publishers,2001.
2. Reuse Methodology manual for SystemOnAChip Designs,Michael Keating, Pierre Bricaud,
Kluwer Academic Publishers, second edition,2001.
REFERENCES
1.Design Verification: Simulation and Formal Method based Approaches, William K. Lam, Prentice
Hall.
2. System on a Chip Design and Test, Rochit Rajsuman
3. Multiprocessor Systems on chips, A.A.Jerraya, W.Wolf, M K Publishers.
4. The EDA HandBook, Dirk Jansen, Kluwer Academic Publishers.
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MEL662.3 Optical IC
3-0-3-4
Max Hrs: 36
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MEL662.3 Design for Manufacturability and Yield Management
3-0-3-4
Max Hrs: 36
1. Design for Manufacturability of VLSI Course Objective
The course objectives are to give comprehensive coverage of the process and design
variables that determine the ease and feasibility of fabrication (or manufacturability)
of contemporary VLSI systems and circuits. This course progresses from
semiconductor processing to electrical design to system architecture. The material
provides a theoretical background as well as case studies, examining the entire
design for the manufacturing path from circuit to silicon. Each chapter includes
tutorial and practical applications coverage.
Course Outline I. Introduction II. Defect Monitoring and Characterization III. Digital CMOS Fault Modeling and Inductive Fault Analysis IV. Functional Yield Modeling V. Critical Area and Fault Probability Prediction VI. Statistical Methods of Parametric Yield and Quality Enhancement VII. Architectural Fault Tolerance VIII. Design for Test and Manufacturability IX. Testing Solutions for MCM Manufacturing
Books for Design for manufacturability & Yield management
1. Integrated Circuit Manufacturability: by Jose Pineda de Gyvez, IEEE Circuits and
Systems Society
2. Crouch, Alfred
Design-for-Test for Digital ICs and Embedded Core Systems
Prentice Hall PTR- Jun, 1995
3. Design for Manufacturability and Statistical Design: A Constructive Approach, Michael Orshansky,
Sani Nassif, Duane Boning, 2008, ISBN# 978-0-387-30928-6, Publisher: Springer