vi semester sl. no subject code subject credits sem... · information theory: introduction, measure...
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VI Semester
Sl. No Subject Code Subject Credits
1 UEC611C Field Theory 4.0
2 UEC612C Computer Networks 4.0
3 UEC613C Information theory and Coding 4.0
4 UEC614C CMOS Digital VLSI Design 4.0
5 UECXXXE Elective-III 3.0
6 UECXXXE Elective-IV 3.0
7 UEC621L Computer Network Lab 1.5
8 UEC622L VLSI Lab 1.5
Total 25
Elective-III
Sl. No Subject Code Subject Credits
1 UEC615E Bio Medical Engineering 3.0
2 UEC616E Operating System 3.0
3 UEC617E Advanced Microprocessors 3.0
Elective-IV
Sl. No Subject Code Subject Credits
1 UEC618E Applications of Signal Processing 3.0
2 UEC619E DSP Processors 3.0
3 UEC620E Mobile Communication 3.0
Course Title: Field Theory Course Code: UEC611C
Credits: 4 Teaching Hours: 52 Hrs (13 Hrs/Unit)
Contact Hours: 4 Hrs/Week
CIE Marks: 50 SEE Marks: 50 Total Marks: 100
Unit I
Vector analysis, Coulomb’s Law and electric field intensity: Experimental law of coulomb, coulomb’s
law, field intensity, field due to continuous volume charge distribution, Field of a line charge & field
of sheet charge, field of a volume charge, Electric flux density.
Gauss law and divergence: Electric flux density, Gauss law, Application of Gauss law to symmetrical
charge distribution & differential volume element, Divergence Maxwell’s first equation, vector
operator dell and divergence theorem.
Unit II
Energy and potential: Energy expended in moving a point charge in an electric filed, the line integral,
definition of potential difference and potential, the potential filed of a point charge and system of
charges, potential gradient, Energy density in an Electrostatics filed. Conductors, dielectrics and capacitance: Current and current density, continuity of current, metallic
conductors, conductor properties and boundary conditions, boundary conditions for perfect dielectrics,
capacitance and examples.
Unit III
Poisson’s and Laplace’s equations: Derivations of Poisson’s and Laplace’s equations. Uniqueness
theorem, examples of the solution of Laplace and Poisson’s equations.
The steady magnetic filed: Biot-savart law, Ampere’s circuital law, curl, stokes theorem, magnetic flux
density, scalar and vector magnetic potentials. Magnetic forces: Force on a moving charge and differential current element, force between differential
current elements, force and torque on a closed circuit.
Unit IV
Time varying fields and Maxwell’s equations: Faraday’s law, displacement current, Maxwell’s equation
in point and integral form, retarded potentials. Uniform plane wave: Wave propagation in free space and dielectrics, poynting’s theorem and wave
power, propagation in good conductors (skin effect), wave polarization Plane wave in boundaries and in dispersive media: Reflection of uniform plane waves at normal
incidence, SWR, wave reflection from multiple interfaces, plane wave propagation in general directions.
Text Book:
1) William H Hayt Jr, John A Buck, “Engineering Electronics”, Tata McGraw-Hill, 7th Edition, 2006.
Reference Books:
1) John Krauss and Daniel A Fleisch, “Electromangetics with Application”, McGraw-Hill, 5th edition,
1999.
2) David K Cheng, “Filed and Wave Electromagnetics” Pearson education Asia, 2nd edition, -1989,
Indian Reprint-2001.
Course Title: Computer Networks Course Code: UEC612C
Credits: 4 Teaching Hours: 52 Hrs (13 Hrs/Unit)
Contact Hours: 4 Hrs/Week
CIE Marks: 50 SEE Marks: 50 Total Marks: 100
Unit I
Layered tasks, OSI Model, Layers in OSI model, TCP/IP Suite, Addressing, Telephone and cable
networks for data transmission, Telephone networks, Dial up modem, DSL, Cable TV for data
transmission. Data Link Control: Framing, Flow and error control, Protocols, Noiseless channels and
noisy channels, HDLC.
Unit II
Multiple Access: Random access, Controlled access, Channelisation, Wired LAN, Ethernet, IEEE
standards, Standard Ethernet. Changes in the standards, Fast Ethernet, Gigabit Ethernet, Wireless LAN
IEEE 802.11,Connecting LANs, Backbone and Virtual LANs, Connecting devices, Back bone
Networks, Virtual LANs.
Unit III
Network Layer, Logical addressing, Ipv4 addresses, Ipv6 addresses, Ipv4 and Ipv6 Transition from Ipv4
to Ipv6, Delivery, Forwarding, Unicast Routing Protocols, Multicast Routing protocols.
Unit IV
Transport layer Process to process Delivery, UDP, TCP, Application Layer: Domain name system,
Name Space, Domain Name Space, Distribution of Name Space, DNS in the Internet, Resolution, DNS messages, Types of Records, Registrars, Dynamic Domain Name System, Encapsulation.
Text Book:
1) Data Communication and Networking, “Behrouz A. Forouzan”, 4th Edition, TMH, India, 2006.
Reference Books:
1) Andrew S. Tanenbaum, “Computer networks”, Prentice-Hall, 2010. 2) William Stallings, “Data and Computer Communications”, Prentice-Hall, 2007.
Course Title: Information Theory and Coding Course Code: UEC613C
Credits: 4 Teaching Hours: 52 Hrs (13 Hrs/Unit)
Contact Hours: 4 Hrs/Week
CIE Marks: 50 SEE Marks: 50 Total Marks: 100
Unit I
Information theory: Introduction, Measure of information, Average information content of symbols in
long independent sequences, Average information content of symbols in long dependent sequences,
Markov statistical model for information source, Entropy and information rate of Markov source,
Source Coding: Properties, Shannon’s encoding algorithm, Shannon-Fano encoding algorithm,
Huffman Coding, Shannon Fano Elias Coding, Arithmetic Coding, The Lempel -Ziv Algorithm, Run
Length Encoding and the PCX Format.
Unit II
Communication channels: Discrete communication channels, Entropy functions and equivocation,
Mutual information, Properties of mutual information, Rate of information transmission over a discrete
channel, Capacity of a discrete memory less channel, Shannon’s theorem on channel capacity, Channel
efficiency and Redundancy. Special channels: Symmetric/Uniform channels, Binary symmetric
channels, Binary erasure channel, Noiseless channel, Deterministic channel. Discrete channels with
memory. Continuous Channels: Differential entropy and Mutual information for continuous ensembles,
Shannon-Hartley law and its implications.
Unit III
Error control coding: Introduction, Types of errors, Examples of error control coding, and Methods for
controlling errors, Types of codes. Linear Block Codes: Matrix description of LBC, Encoding circuit
for (n, k) linear block codes, Syndrome and Error correction, Syndrome calculation circuit, Hamming
weight, Hamming distance and Minimum distance of LBC. Error detection and correction capability of
LBCs, Hamming codes, Standard array. Binary Cyclic Codes: Algebraic structure of cyclic codes,
Encoding using an (n, k) bit shift register, Syndrome calculation, Error detection and Correction.
Unit IV
Convolution codes: Connection Pictorial Representation, Time and Transform domain approach,
Systematic Convolution Codes, Structural Properties of Convolution Codes: State Diagram, Code tree,
Trellis Diagram, Maximum Likely-hood decoding of Convolution codes: The Viterbi Algorithm, Sequential Decoding: The Stack Algorithm, The Fano Algorithm.
Text Books:
1) K. Sam Shanmugam, “Digital and analog communication systems”, John Wiley, 1996.
2) P. S. Sathyanarayana, “Concepts of information theory and coding”, 2nd edition, Dynaram, 2004
Reference Book:
1) Bernard Sklar, “Digital Communication Fundamentals and Applications”, 2nd Edition, Pearson
Education, 2002.
2) Simon Haykin, “Digital communication”, John Wiley, 2003.
3) Ranjan Bose, “Information Theory, Coding and Cryptography”, McGraw-Hill 2nd edition, 2008.
Course Title: CMOS Digital VLSI Design Course Code: UEC614C
Credits: 4 Teaching Hours: 52 Hrs (13 Hrs/Unit)
Contact Hours: 4 Hrs/Week
CIE Marks: 50 SEE Marks: 50 Total Marks: 100
Unit I Introduction: A Brief History, Preview, MOS Transistors, CMOS Logic, CMOS Fabrication and
Layout, Design Partitioning. MOS Transistor Theory: Introduction, Long-Channel I-V Characteristics,
C-V Characteristics, Nonideal I-V Effects, DC Transfer Characteristics. CMOS Processing
Technology: Introduction, CMOS Technologies, Layout Design Rules, CMOS Process Enhancements,
Manufacturing Issues.
Unit II
Delay: Introduction, Transient Response, RC Delay Model, Linear Delay Model, Logical Effort of
Paths, Timing Analysis Delay Models. Power: Introduction, Dynamic Power, Static Power,
EnergyDelay Optimization, Low Power Architectures.
Unit III
Interconnect: Introduction, Interconnect Modeling, Interconnect Impact, Interconnect Engineering.
Combinational Circuit Design: Introduction, Circuit Pitfalls, More Circuit Families, Silicon-
OnInsulator Circuit Design, Sub threshold Circuit Design.
Unit IV
Sequential Circuit Design: Introduction, Sequencing Static Circuits, Circuit Design of Latches and Flip-
Flops, Static Sequencing Element Methodology, Sequencing Dynamic Circuits, Synchronizers, Wave
Pipelining. Array Subsystems: Introduction, DRAM, Read-Only Memory, Serial Access Memories, Content-Addressable Memory, Programmable Logic Arrays, Robust Memory Design.
Text Book:
1) Neil H. E. Weste, David Harris “CMOS VLSI Design A Circuits and Systems Perspective”
Addison-Wesley Fourth Edition.
Reference Books:
1) Jan M.Rabaey, Anantha Chandrakasan, Borivoje Nikolic, “Digital Integrated Circuits A
Design Perspective” Pearson Education Publisher, 2nd Edition.
2) John P Uyemura, “Introduction to VLSI Circuits and Systems” Wiley Publication 2002.
3) R Jcob Baker, Harry W. Li and David E Boyce, “CMOS Circuit Design, Layout, and
Simulation” PHI, 1998.
Course Title: Bio Medical Engineering Course Code: UEC615E
Credits: 3 Teaching Hours: 40 Hrs (10 Hrs/Unit)
Contact Hours: 3 Hrs/Week
CIE Marks: 50 SEE Marks: 50 Total Marks: 100
Unit I Introduction: Human body as an engineering system – physiological systems of the body. Medical and
physiological parameters. Fundamentals of Bio Signals: Bio-signal sources, man-instrument system,
general constraints in design of biomedical instrumentation systems. Origin of bioelectric signals, types
of bioelectric signals – ECG, EEG, EMG etc. Biopotential electrodes and physiological transducers for
biomedical applications, bio data acquisition. Biomedical amplifiers, principles of recorders for
recording bioelectric events
Unit II
Electrocardiograph: Electrical activity of the heart, characteristics of electrocardiogram (ECG), block
diagram description of an electrocardiograph, ECG lead system, multi-channel ECG machine. ECG
signal processing aspects. Cardiac pacemakers: Need for cardiac pacemaker, external pacemaker,
implantable pacemaker, programmable pacemaker, rate responsive pacemakers. Defibrillators: AC &
DC defibrillators. Electroencephalograph: Genesis of electroencephalogram (EEG), block diagram
description of an electroencephalograph, 10-20 electrode systems, and computerized analysis of EEG.
Electromyograph.
Unit III
Blood pressure measurement: Direct & indirect method, automatic blood pressure measuring apparatus
using Korotoff’s method, Rheographic method, oscillometric method, ultrasonic Doppler shift method,
measurement of respiration rate – thermistor method, impedance pnuemography. Blood Flow Meters:
Ultrasonic blood flow meters, NMR Blood flow meters. Patient monitoring system: Bedside patient
monitoring systems, measurement of heart rate: Average heart rate meter, instantaneous heart rate meter
(cardio tachometer), and measurement of pulse rate. ICU equipments.
Unit IV
Imaging Systems: X-rays: generation, imaging types, CAT. Ultrasound: properties, transducer, basics
of imaging, scanning modes, therapeutic ultrasound, MRI: principle, imaging, basic image processing
techniques. BioMetrics: Basics of biometrics. Patient safety: Physiological effects of electrical current, shock hazards, methods of accident prevention. Simple Telemedicine System.
Text Books:
1) Leslie Cromwell, Fred J Weibell, Erich A. Pfeiffer, “Biomedical Instrumentation and
Measurements”, PHI, 1999
2) R. S. Khandpur, “Hand book of Biomedical Instrumentation”, 2nd Edition, TMH, 2003.
3) J. G. Webster, “Medical Instrumentation, Application & Design”, 3rd Edition, John Wiley, 1998.
Reference Books:
1) S. K. Venkata Ram, “Bio-Medical Electronics and Instrumentation”, Galgotia Publications Pvt.
Ltd., 2000.
2) C. Raja Rao, S. K. Guha, “Principles of Medical Electronics and Biomedical Instrumentation”,
University Press, 2000.
3) Michael M. Domach, “Introduction to Biomedical Engineering”, Pearson Education Inc., 2004
4) Joseph J. Carr, John M. Browm, “Introduction to Biomedical Equipment Technology ”,
Pearson Education, 2007.
5) Welkowitz, Walter Deutsch Sid, “Biomedical Instruments: Theory and Design”, 2nd Edition,
Elsevier.
6) Enderle, “Introduction to Biomedical Engineering”, 2nd Edition Elsevier.
7) Nandini K. Jog, “Electronics in Medicine and Biomedical Instrumentation”, PHI, 2010.
Course Title: Operating Systems Course Code: UEC616E
Credits: 3 Teaching Hours: 40 Hrs (10 Hrs/Unit)
Contact Hours: 3 Hrs/Week
CIE Marks: 50 SEE Marks: 50 Total Marks: 100
Unit I Introduction and Overview of Operating Systems: Operating system, Goals of an O.S, Operation of an
O.S, Resource allocation and related functions, User interface related functions, Classes of operating
systems, O.S and the computer system, Batch processing system, Multiprogramming systems, Time
sharing systems, Real time operating systems, distributed operating systems. Structure of the Operating
Systems: Operation of an O.S, Structure of the supervisor, Configuring and installing of the supervisor,
Operating system with monolithic structure, layered design, Virtual machine operating systems, Kernel
based operating systems, and Microkernel based operating systems.
Unit II
Process Management: Process concept, Programmer view of processes, OS view of processes,
Interacting processes, Threads, Processes in UNIX, Threads in Solaris. Memory Management: Memory
allocation to programs, Memory allocation preliminaries, Contiguous and noncontiguous allocation to
programs, Memory allocation for program-controlled data, kernel memory allocation.
Unit III
Virtual Memory: Virtual memory basics, Virtual memory using paging, Demand paging, Page
replacement, Page replacement policies, Memory allocation to programs, Page sharing, UNIX virtual
memory. File Systems: File system and IOCS, Files and directories, Overview of I/O organization,
Fundamental file organizations, Interface between file system and IOCS, Allocation of disk space,
Implementing file access, UNIX file system.
Unit IV
Scheduling: Fundamentals of scheduling, Long-term scheduling, Medium and short term scheduling,
Real time scheduling, Process scheduling in UNIX. Message Passing: Implementing message passing, Mailboxes, Inter process communication in UNIX.
Text Book:
1) D. M. Dhamdhare, “Operating Systems - A Concept based Approach”, TMH, 3rd Edition, 2010.
Reference Books:
1) Silberschatz and Galvin, “Operating Systems Concepts”, John Wiley India Pvt. Ltd, 5th Edition,
2001.
2) Willaim Stalling, “Operating System – Internals and Design Systems”, Pearson Education, 4th
Edition, 2006.
3) Tennambhaum, “Design of Operating Systems”, TMH, 2001.
Subject : Advanced Microprocessors Subject code : UEC617E
Credits : 3(40Hours)
Unit I 10Hrs
8086/8088 processor: A historical background, the microprocessor-based personal computer
system. Architecture of 8086, Special functions of General purpose registers, Physical memory
organization, 8086 flag register, Addressing Modes of 8086,Instruction set of 8086, Assembly
language programs involving logical, branch and call instructions, Sorting, Evaluation of arithmetic
expressions, String manipulation etc.
Unit II 10Hrs
Assembler Directives, Procedures and macros, Pin Diagram of 8086: Minimum and
Maximum mode of operation, Timing Diagram, Memory interfacing to 8086(Static RAM
&EPROM), Need for DMA, DMA data transfer method, Interfacing with 8237/8257.
Unit III 10Hrs 8255 PPI: Various modes of operation and interfacing to 8086, Interfacing keyboard, Displays,
Stepper motor, Interrupt structure of 8086,Vector interrupt, Interrupt service routines,
Introduction to DOS and BIOS interrupts, 8259 PIC Architecture and interfacing cascading of
interrupt vector controller and its importance.
Unit IV
10Hrs 8251 USART architecture, control word formats, embedded processor architecture, IA32
architecture, Micro-architecture, IA-64 Itanium Processor architecture, study of ISA, ATA, SCSI, PCI
and USB buses. Introduction to i3,i5 and i7 processors.
Textbooks
1) Microcomputer systems-The 8086 / 8088 family – Y.C. Liu and G. A. Gibson, 2E PHI –2003.
2) Microprocessor and interfacing- programming & hardware, Douglas hall, 2e TMH, 1991 Reference books
1) Advanced microprocessors and peripherals – A.K.Ray and K.M. Bhurchandi, TMH, 2001. 2) The Intel microprocessor, architecture, programming and interfacing-Barry B. Brey, 6e,
Pearson education / PHI, 2003. 3) 8088 and 8086 microprocessors-Programming, Interfacing, Software, Hardware and
Applications-Trieble and Avtar Singh, 4e person education, 2003
Question paper pattern
1) Total of Eight Questions with two from each unit to be set uniformly covering the entire syllabus.
2) Each question can have a maximum of four subdivisions. Intermixing of questions within a unit is allowed and mixing up of the units is not allowed.
3) Any five full questions are to be answered choosing at least one from each unit.
Course Title: Applications of Signal Processing Course Code: UEC618E
Credits: 3 Teaching Hours: 40 Hrs (10 Hrs/Unit)
Contact Hours: 3 Hrs/Week
CIE Marks: 50 SEE Marks: 50 Total Marks: 100
Unit I
Analog to digital conversion and concept of digital frequency. Introduction to Z-transform, DFT and
its properties, DCT. Linear filtering of long sequence (overlap add and overlap-save methods). Review
of common signal processing operations: Convolution, autocorrelation, cross correlation, power
spectral density and their applications. Time dependent processing: short time energy and average
magnitude, short time average zero crossing detectors.
Unit II
Process of speech production and classification and basics of phonetics, digital models for speech –
vocal tract, radiation, excitation the complete model. Speech Vs silence discrimination, pitch period
estimation, short time autocorrelation function, short time average magnitude difference function,
spectrographic displays. Analysis – synthesis systems – phase vocoder, channel vocoder and Channel
vocoders. Homomorhic analysis-cepstrum and its applications.
Unit III
Fundamentals of Bio Signals: Bio-signal sources, man-instrument system, Origin of bioelectric signals,
types of bioelectric signals – ECG, EEG, and EMG. Electrocardiograph: Electrical activity of the heart,
characteristics of electrocardiogram (ECG), ECG signal processing aspects. Signal averaging, Signal
compression, Principal noise canceller model, 60 HZ adaptive canceling using a sine wave model, other
applications of adaptive filtering.
Unit IV
Introduction to Image processing: Image representation and Modeling, Image analysis: common signal
processing operations in image processing. Image enhancement: point operations, contast stretching,
clipping and thresholding, digital negative and bit extraction. Image filtering and restoration: image observation models and inverse filtering, and introduction to image data compression.
Text Books:
1) Proakis and Manolakis, “Digital Signal Processing”, Pearson , 4th Edition.
2) L. R. Rabiner and R. W. Schafer, “Digital Processing of Speech Signals", Pearson Education
(Asia) Pte. Ltd., 2004.
3)
Reference Books:
1) D. C. Reddy, “Biomedical Signal Processing: Principles and Techniques”, TMH, 2005. 2) Willis J. Tompkins, “Biomedical Digital Signal Processing: C Language Examples and
Laboratory Experiments for the IBM PC”, Printice Hall.
3) Anil K. Jain, “Fundamentals of Digital Image Processing”, PHI, 2003.
Course Title: DSP Processors Course Code: UEC619E
Credits: 3 Teaching Hours: 40 Hrs (10 Hrs/Unit)
Contact Hours: 3 Hrs/Week
CIE Marks: 50 SEE Marks: 50 Total Marks: 100
Unit I Introduction to Programmable DSPs: Multiplier and multiplier accumulator (MAC), Modified bus
structures and memory access Schemes in P-DSPs, Multiple access memory, Multi-ported memory,
VLIW architecture, Pipelining, Special addressing modes in P-DSPs. On-chip peripherals. Computational Accuracy in DSP Implementations: Introduction, Number formats for signals and
coefficients in DSP systems, Dynamic range and precision, Sources of error in DSP implementations.
Unit II
Architecture of DSP Processor-TMS320C5X: Bus structure, Central arithmetic and logic unit (CALU),
Auxiliary register ALU, Index register, Auxiliary register compare register, Block move address
register, Block repeat registers, Parallel logic unit, Memory mapped registers, Program controller, Flags
in the status registers. TMS320C5X Assembly Language Instructions: Assembly language syntax, Addressing modes,
Load/Store instructions, Addition/Subtraction instructions, Move instructions, Multiplication
instructions, The NORM instruction.
Unit III
Instruction Pipelining in TMS320C5X and Programming: Program control instructions, Peripheral
control, Pipeline structure, Pipeline operation, Normal pipeline operation, C50-based starter kit (DSK),
Programs for familiarization of addressing modes, Programs for familiarization of arithmetic
instructions.
Unit IV
Real Time Signal Processing Using TMS320C5X: On chip timer in C5X and programming its mode,
C5X Serial port block diagram and its operation, Analog interfacing circuit (AIC), Terminal functions,
Analog input and output, A/D and D/A filters, Internal timing configuration, AIC serial port modes and
its registers, AIC serial port operation and reset function, Interfacing the DSP and AIC, FIR filter implementation.
Text Books:
1) B Venkataramani and M Bhaskar, “Digital Signal Processors, Architecture, Programming and
Applications”, TMH Edition.
2) Avtar Singh and S Srinivasan, “Digital Signal Processing, Implementation using DSP
Microprocessors with examples from TMS 320C54XX”, Thomson Learning Edition.
Reference Book:
1) User Manual of TMS320C54XX of Texas Instruments Company.
Course Title: Mobile Communication Course Code: UEC620E
Credits: 3 Teaching Hours: 40 Hrs (10 Hrs/Unit)
Contact Hours: 3 Hrs/Week
CIE Marks: 50 SEE Marks: 50 Total Marks: 100
Unit I Introduction: Short history of wireless communication, Market for Mobile Communications Wireless
transmission, frequency for radio transmission, multiplexing, modulation, spread spectrum, cellular
systems.
Unit II
Medium axis: Motivation for specialized MAC, SDMA, FDMA, TDMA, CDMA. Tele communication
system: GSM, DECT, TETRA, UMPS and IMT2000.
Unit III
Satellite Systems: GEO, LIO, MEO, routing localization and handover, Broad cost system: Overview,
Cylicle repetition of data, Digital Audio Broadcasting, Digital Video Broadcasting. Mobile Network Layer: Mobile IP, Dynamic host configuration Protocol, Mobile Ad hoc networks.
Unit IV
Mobile Transport Layer: Traditional TCP, Classical TCP improvement, TCP over 2.5/3G wireless
network, performance enhancing proxies, support for mobility: 5 system, World wide web, Wireless
application protocol.
Text Books:
1) Jochen Schiller, “Mobile Communications”, 2nd Edition, Pearson Education, 2003.
2) William Stallings, “Wireless Communications and Networks”, Pearson Education, 2002.
Reference Books:
1) Kaveh Pahlavan, Prasanth Krishnamoorthy, “Principles of Wireless Networks”, 1st Edition,
Pearson Education, 2003.
2) Uwe Hansmann, Lothar Merk, Martin S. Nicklons and Thomas Stober, “Principles of Mobile
Computing”, Springer, 2003.
3) C. K. Toh, “AdHoc Mobile Wireless Networks”, 1st Edition, Pearson Education, 2002.
Course Title: Computer Networks Laboratory Course Code: UEC621L
Credits: 1.5 Contact Hours: 3 Hrs/Week
CIE Marks: 50 SEE Marks: 50 Total Marks: 100
List of Experiments
1) Network experiments using C (a) Simulate bit/ character stuffing and de-stuffing using HDLC. (b) Simulate the shortest path algorithm. (c) Encryption and decryption of a given message.
(d) Find minimum spanning tree of a subset. (e) Compute polynomial code checksum for CRC-CCITT
2) Network experiments using NS2 (a) To create a network topology for three nodes, To create a network topology for a star
topology of 12 nodes, to create a topology of 4 nodes for different link capacities and
observe the data flow in the network. (b) To simulate the network of 5 nodes and use the routing protocol dynamically and trace the
link up and down in between nodes.
(c) To simulate a network to perform shortest path routing for a network topology of 9 nodes. (d) To test the operation of multicast routing and trace the packet delivery.
(e) To create topology of 7 nodes and observe the data flow at different nodes.
3) Study of Network programming: (a) Client server programming using TCP. (b) Client server programming using UDP. (c) Client server programming using TCP and file sharing with semaphores.
4) Study of wireless LANs, Sensor networks and campus network
Course Title: VLSI Laboratory Course Code: UEC622L
Credits: 1.5 Contact Hours: 3 Hrs/Week
CIE Marks: 50 SEE Marks: 50 Total Marks: 100
List of Experiments
Design Simulation and Layout for the following
1) Inverter
2) Two input NAND Gate 3) Two input NOR gate 4) Two input XOR / XNOR gates 5) Two input OR gate
6) Two input AND gate 7) NMOS/PMOS transistor VI characteristics 8) NMOS / PMOS and TG as switch
9) D flip flop and T flip flop 10) 3-bit Counter 11) 3-bit Shift Register
12) Full adder 13) Parallel Adder