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SOLAPUR UNIVERSITY, SOLAPUR FACULTY OF ENGINEERING &
TECHNOLOGY
ELECTRONICS & TELECOMMUNICATION ENGINEERING
Syllabus Structure for
M.E. (Electronics & Telecommunication Engg.-Digital
Electronics & Communication System) w.e.f. Academic Year
2013-14
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SOLAPUR UNIVERSITY, SOLAPUR FACULTY OF ENGINEERING &
TECHNOLOGY
STRUCTURE OF M.E. (Electronics & Telecommunication
Engg.-Digital Electronics & Communication System)
With Effect from Academic Year 2013-14
Four Semester Course Semester-I
Sr. No.
Subject Teaching Scheme Credits L T P Total Credits
(L) Credits
(T) Credits
(P) Total
Credits 1 Communication
Networks
3 - 2 5 3.0 - 1.0 4.0
2 CMOS VLSI Design
3 - 2 5 3.0 - 1.0 4.0
3 Modern Digital Signal Processing
3 - 2 5 3.0 1.0 4.0
4 Probability & Random Process
3 1 - 4 3.0 1.0 - 4.0
5 Elective -I
3 1 - 4 3.0 1.0 - 4.0
6 Seminar-I
- - 2 2 - - 2.0 2.0
Total 15 2 8 25 15.0 2.0 5.0 22.0
Note Seminar-I shall be delivered on a topic related to students
broad area of interest for
dissertation work selected in consultation with the advisor
after compiling the information from the latest literature. Student
shall deliver seminar using modern presentation tools. A hard copy
of the report (as per format specified by the department) shall be
submitted to the Department before delivering the seminar. A PDF
copy of the report must be submitted to the advisor along with
other details if any.
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Semester-II
Sr. Subject Teaching Scheme Credits L T P Total Credits
(L) Credits
(T) Credits
(P) Total
Credits 1 RF & Microwave circuit
design
3 2 5 3.0 1.0 4.0
2 High Speed Digital Design
3 - 2 5 3.0 - 1.0 4.0
3 Advanced Embedded Systems
3 - 2 5 3.0 - 1.0 4.0
4 Wireless & Mobile Networks
3 1 4 3.0 1.0 - 4.0
5 Elective II
3 1 - 4 3.0 1.0 - 4.0
6 Seminar II
- - 2 2 - - 2.0 2.0
Total 15 2 8 25 15.0 2.0 5.0 22.0
Note Seminar-II shall be delivered on a topic related to
students particular area of interest
for dissertation work selected in consultation with the advisor
after compiling the information from the latest literature. Student
shall deliver seminar using modern presentation tools. A hard copy
of the report (as per format specified by the department) shall be
submitted to the Department before delivering the seminar. A PDF
copy of the report must be submitted to the advisor along with
other details if any.
List of Elective Subjects for semester I and II
Sr. Elective - I Elective - II 1 Multimedia Communication Image
& Video
Processing & broadcasting
2 DSP Processors Cryptography & Network Security
3 Optical Communication & Networks
Antenna Theory & Design
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Solapur University, Solapur M.E. (Electronics &
Telecommunication Engg.-Digital
Electronics & Communication System) Semester-I
COMMUNICATION NETWORKS
Teaching Scheme Examination Scheme Lectures 3 Hrs. /Week Theory
Credits 3.0 Practical 2 Hrs. /Week Practical Credit- 1.0
SECTION-I
Unit 1: Internet Technology (06 Hrs.) The TCP/IP Internet
,Internet Services , The Internet Architecture Board ,Internet
Request For Comments (RFCs) , Transition To IPv6 , Relationship
Between IPv4 And IPv6 , IPv6 Migration , IP address, ARP, RARP.
Unit 2: Datagram (08 Hrs.) Pinging, Datagram, ICMP, UDP, DHCP
and Mobile IP, Internet Routing Protocols, multicast Routing, IP
V6. 8
Unit 3: DNS Techniques (06 Hrs.) Flat Namespace, Hierarchical
Names, Delegation of Authority for names, TCP/IP Internet domain
names, official and unofficial Internet Domain names, items named
and syntax of names, mapping domain, names to addresses, domain
names resolution, efficient translation caching. The key to
efficiency, Domain mapping message format, compressed name format,
abbreviation of domain names, inverse mappings, pointer queries,
object types and resource record contents, obtaining authority for
a sub domain
SECTION-II
Unit 4: ATM Networks (08 Hrs.) Need of ATM, BISDN model, ATM
layer, ATM Adaptation Layer, ATM signals, PNNI Routing.
Unit 5: Advanced Network Architecture (06 Hrs.) IP forwarding
Architecture, Overlay model MPLS, RSVP, Differentiated Services
Unit 6: Giga Bit Ethernet (06 Hrs.) Architecture and overview of
Giga Ethernet, MAC, Physical layer, IEEE 802.32 Standard
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Term work: Term work shall consist of minimum eight experiments
based on above syllabus
Reference books:
1. Internet working with TCP/IP , D.E. Comer. Prentice-Hall
International 2. Communication Networks: Fundamental & concepts
and Key Architectures , Leon-
Garcia, widjaja .(Tata McGraw-Hill) 3. ATM by Rich Seifert 4.
Gigabit Ethernet: Technology and Applications for High Speed LANs,
(Addison
Wesley). 5. Gigabit Ethernet Networking by David Cunningham,
William G. Lane, Bill
Lane.(Pearson Higher Education ) 6. Data Communication &
Networking,- Behrmz Foruzan (TMH)
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Page 6 of 31
Solapur University, Solapur M.E. (Electronics &
Telecommunication Engg.-Digital
Electronics & Communication System) Semester-I
CMOS VLSI DESIGN
Teaching Scheme Examination Scheme Lectures 3 Hrs. /Week Theory
Credits 3.0 Practical 2 Hrs. /Week Practical Credit- 1.0
SECTION-I
Unit 1: MOS transistor theory: (06 Hrs.) Physical structure of
MOS transistor, accumulation, depletion & inversion modes, MOS
device design equations, second order effects, Technology
scaling
Unit 2: CMOS inverter: (06 Hrs.) Static and dynamic behavior of
CMOS inverter, power and energy delay, impact of technology scaling
on inverter
Unit 3: Combinational logic design in CMOS: (08 Hrs.) Static
CMOS design- complementary CMOS, Ratioed logic and pass transistor
logic; dynamic CMOS design- dynamic logic basic principle, speed
and power dissipation, issues in dynamic design, cascading dynamic
gates, comparison of static and dynamic designs in CMOS
SECTION-II
Unit 4: Sequential logic designs in CMOS: (06 Hrs.) Static
latches and registers- the bistability principle, multiplexer based
latches, Master-slave edge triggered register, low voltage static
latches, static SR flip flops, dynamic latches and registers-
dynamic transmission-gate edge triggered registers, C2MOS- A clock-
skew insensitive approach, true single-phase clocked register
(TSPCR)
Unit 5: Timing issues in digital circuits: (07 Hrs.) Timing
classification: synchronous interconnect, mesochronous
interconnect, plesiochronous interconnect, asynchronous
interconnect, synchronous design- clock skew, jitter, clock
distribution, latch based clocking, synchronizers and arbiters,
using PLL for clock synchronization
Unit 6: Designing arithmetic and memory building blocks: (07
Hrs.) Designing fast adders, designing fast multipliers, designing
other arithmetic building blocks, designing ROMs, DRAMs &
SRAMs
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Term work: Term work shall consist of minimum eight experiments
based on above syllabus using
any EDA software tool
Reference books:
1. Digital Integrated Circuits, Rabey, Chandrakasan, Nikolic,
Pearson Education 2. Principles of CMOS VLSI Design, Neil Weste,
Kamran Eshraghian, Addison
Wesley/Pearson Education 3. CMOS digital integrated circuits,
Analysis and Design, Sung-Mo Kang, Yusuf
Leblebici, TATA McGRAW Hill 4. CMOS VLSI design, Neil H. E.
Weste, David Harris, Ayan Banerjee, Pearson Education
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Solapur University, Solapur M.E. (Electronics &
Telecommunication Engg.-Digital
Electronics & Communication System) Semester-I
MODERN DIGITAL SIGNAL PROCESSING
Teaching Scheme Examination Scheme Lectures 3 Hrs. /Week Theory
Credits 3.0 Practical 2 Hrs. /Week Practical Credit- 1.0
SECTION-I
Unit 1: Design of digital filters: (06 Hrs.) Symmetric and
anti-symmetric FIR filters, design of linear phase FIR filters by
using Windows and frequency sampling method ,Design of optimum
equi-ripple linear phase FIR filters; Design of FIR differentiator,
Design of Hilbert transformers, comparison of design methods.
Unit 2: Linear prediction and optimal linear filters: (07 Hrs.)
Forward and backward linear prediction; the optimum reflection for
the forward and backward predictors; relationship of an AR process
to linear prediction; the Levinson Durbin algorithm; the Schur
algorithm; properties of the linear prediction error filters, FIR
Wiener filter.
Unit 3: Power spectrum estimation: (07 Hrs.) Estimation of
spectra from finite duration observation of signals; computation of
energy density function; estimation of auto-correlation and power
spectrum of random signals; the period gram; the use of DFT in
power spectrum estimation; parametric methods for power spectrum
estimation; AR model parameters for power spectrum estimation
SECTION-II
Unit 4: IIR filters: (07 Hrs.) Design of IIR filter using BLT
method,Characteristics of Commonly Used Analog Filter,Design of
digital filters based on least squares methods: Pade approximation
method; Least squares design methods; frequency transformation
Unit 5: Multirate DSP: (08 Hrs.) Decimation by a factor of D;
Interpolation by a factor of I; Sampling rate conversion by a
rational factor I/D; filter design & implementation for
sampling rate conversion, direct from FIR filter structure;
application of Multirate DSP ,Digital Filter bank
Unit 6: Wavelet transforms: (05 Hrs.) Introduction to wavelets,
wavelets and wavelet expansion systems, discrete wavelet transform
multi resolution formulation of wavelet systems, Haar wavelet and
other wavelet representations,
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Term work:
Term work shall consist of minimum eight experiments based upon
above syllabus
Reference books:
1. Digital signal processing- Principles, algorithms and
applications, John. G Proakis, PHI Publication 2. Advanced DSP,
Proakis, Rade, Ling, Mcmillan Publication 3. Discrete time signal
processing, A.V. Oppenheim, R.W. Schafer, PHI Publication 4. Theory
and application of digital signal processing, I.R. Rabiner, Gold 5.
Introduction to digital signal processing, Johnny R Johnson. PHI
Publication 6. Introduction to DSP, Roman Kuc, McGRAW Hill
Publication 7. Digital Signal Processing, A computer based
approach, Sanjit K. Mitra. McGraw-Hill Education
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Solapur University, Solapur M.E. (Electronics &
Telecommunication Engg.-Digital Electronics &
Communication System) Semester-I PROBOBALITY & RANDOM
PROCESS
Teaching Scheme Examination Scheme Lectures 3 Hrs. /Week Theory
Credits 3.0 Tutorial 1 Hrs. /Week Tutorial Credit- 1.0
SECTION- I
Unit 1: Introduction to Probability Theory: (04 Hrs.)
Experiments, sample space, Events, Axioms, Assigning probabilities,
Joint and conditional probabilities, Bayes Theorem, Independence,
Discrete Random Variables, Engg. Example.
Unit 2: Random Variables, Distributions, Density Functions: (10
Hrs.) CDF, PDF, Gaussian random variable, Uniform Exponential,
Laplace, Gamma, Erlang, Chi-Square, Raleigh, Rician and Cauchy
types of random variables Operations on a Single R V: Expected
value, EV of Random variables, EV of functions of Random variables,
Central Moments, Conditional expected values.
Unit 3: Characteristic functions, (06 Hrs.) Probability
generating functions, Moment generating functions, Engg
applications, Scalar quantization, entropy and source coding.
SECTION- II
Unit 4: Pairs of Random variables: (10 Hrs.) Joint CDF, joint
PDF, Joint probability mass functions, Conditional Distribution,
density and mass functions, EV involving pairs of Random variables,
Independent Random variables, Complex Random variables, Engg.
Application. Multiple Random Variables:Joint and conditional PMF,
CDF, PDF,.EV involving multiple Random variables, Gaussian Random
variable in multiple dimension, Engg. Application, linear
prediction. .
Unit 5: Random Process: (04 Hrs.) Definition and
characterization, Mathematical tools for studying Random Processes,
Stationary and Ergodic Random processes, Properties of ACF.
Unit 6: Example Processes: (06 Hrs.) Markov processes, Gaussian
Processes, Poisson Processes, Engg. application, Computer networks,
Telephone networks.
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Term work:
Term work shall consist of minimum six assignments based upon
above syllabus
Reference books:
1. Probability and random processes: application to Signal
processing and communication - S L Miller and D C Childers:
Academic Press / Elesivier 2004.
2. Probability, Random variables and stochastic processes - A.
Papoullis and S U Pillai: McGraw Hill 2002.
3. Probability, Random variables and Random signal principles -
Peyton Z Peebles: TMH 4th Edition 2007.
4. Probability, random processes and applications - H Stark and
Woods: PHI 2001
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Solapur University, Solapur M.E. (Electronics &
Telecommunication Engg.-Digital Electronics &
Communication System) Semester-I ELECTIVE-I : - MULTIMEDIA
COMMUNICATION
Teaching Scheme Examination Scheme Lectures 3 Hrs. /Week Theory
Credits 3.0 Tutorial 1 Hrs. /Week Tutorial Credit- 1.0
SECTION- I
Unit 1: (04 Hrs.) Definition, Elements and Need of multimedia,
Texture mapping,applications, image capture, compression,
standards.
Unit 2: Multimedia Communications: (06 Hrs.) multimedia
information representation, multimedia networks, network QoS and
application QoS., Case study of OpenGL .
Unit 3: Information Representation: (10Hrs.) text, images, audio
and video compression, compression principles, video compression
standards: H.261, H.263, P1.323, MPEG 1, MPEG 2, Other coding
formats for text, speech, image and video..
SECTION- II
Unit 4: Detailed Study of MPEG 4: (06 Hrs.) coding of
audiovisual objects, MPEG 4 systems, MPEG 4 audio and video,
profiles and levels. MPEG 7 standardization process of multimedia
content description, MPEG 21 multimedia framework, Significant
features of JPEG 2000, MPEG 4 transport across the Internet.
Unit 5: Synchronization: (07Hrs.) Notion of synchronization,
presentation requirements, reference model for synchronization,
Introduction to SMIL, Multimedia operating systems, Resource
management, process management techniques.
Unit 6: Multimedia Communication Across Networks: (07 Hrs.)
Layered video coding, error resilient video coding techniques,
multimedia transport across IP networks and relevant protocols such
as RSVP, RTP, RTCP, DVMRP, multimedia in mobile networks,
multimedia in broadcast networks.
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Term work:
Term work shall consist of minimum six assignments based upon
above syllabus
Reference books:
1. Multimedia Communications, Fred Halsall, Pearson education,
2001
2. Multimedia Communication Systems, K. R. Rao, Zoran S.
Bojkovic, Dragorad A. Milovanovic,Pearson education, 2004
3. Multimedia: Computing, Communications and Applications, Raif
Steinmetz, Klara Nahrstedt, Pearson education, 2002
4. Multimedia : An Introduction, John Billamil, Louis Molina,
PHI, 2002
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Solapur University, Solapur M.E. (Electronics &
Telecommunication Engg.-Digital Electronics &
Communication System) Semester-I
ELECTIVE-I :- DSP PROCESSORS Teaching Scheme Examination Scheme
Lectures 3 Hrs. /Week Theory Credits 3.0 Tutorial 1 Hrs. /Week
Tutorial Credit- 1.0
SECTION- I
Unit 1: Processors Fundamental (05 Hrs.) Digital signal
processing and DSP systems: Advantages of DSP, characteristics of
DSP systems, DSP applications. DSP processors, architecture and
instruction set. Speed of DSP Hardware, Resoultion
Unit 2: Floating point numbers: (05 Hrs.) Numeric
representations and arithmetic: floating point numbers, IEEE 754
standard for floating point numbers
Unit 3: Memory Architectures: (10Hrs.) Memory Architectures:
memory structures wait states, extended memory interfaces,
addressing mechanisms.
SECTION- II
Unit 4: TMS320C6x processor: (07 Hrs.) Architecture and
instruction set of DSP processor Introduction to TMS320C64
processor, architecture, pipelining, linear and circular addressing
modes, TMS320C64 instruction set, assembler directives, timers,
interrupts, serial I/O, DMA, fixed and floating point data format
.
Unit 5: Interrupt and Execution control: (06 Hrs.) Execution
control: Hardware looping, interrupts, stack, relative branch
support Pipelining: pipelining and performance, pipelining depth,
interlocking, branching effects, interrupt effects .
Unit 6: Peripherals: (07 Hrs.) Peripherals: serial / parallel
ports, timers, communication ports, on-chip A/D and D/A
converters,-external interrupts, on-chip debugging facilities,
power consumption, clocking.Application of DSP Processor-Adaptive
filtering.
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Term work:
Term work shall consist of minimum six assignments based upon
above syllabus
Reference books:
1. DSP Processor Fundamentals: architectures and Features, Phil
Lapsley, Wiley
2. DSP Applications using C and the TMS320C6x DSP, Rulph
Chassaing, Wiley
3. A practical Approach to DSP,K Padmanabhan, S.Ananthi. New AGE
Publishers
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Solapur University, Solapur M.E. (Electronics &
Telecommunication Engg.-Digital Electronics &
Communication System) Semester-I
ELECTIVE- I: -OPTICAL COMMUNICATION AND NETWORKS
Teaching Scheme Examination Scheme Lectures 3 Hrs. /Week Theory
Credits 3.0 Tutorial 1 Hrs. /Week Tutorial Credit- 1.0
SECTION- I
Unit 1: Fundamentals of Optical Communication: (08 Hrs.) The
basic optical communication system, communication components,
modulation methods, transmitters- receivers, repeaters.
Unit 2: Optical Amplifiers: (06 Hrs.) Basic concepts,
semiconductor Laser amplifier, Raman Amplifier, erbium-Doped Fiber
Amplifier
Unit 3: Multichannel Systems: (06 Hrs.) Wavelength division
multiplexing, time division multiplexing, channel multiplexing,
subcarrier multiplexing
SECTION- II
Unit 4: Optical Networks: (08 Hrs.) Basic networks, FDDI
networks, SONET/SDH, storage area networks, broadcast networks,
next generation networks.
Unit 5: Optical Fiber Measurements: (06 Hrs.) Fiber attenuation
measurement, fiber dispersion measurement, fiber Refractive index
profile measurement, Optical Time Domain Reflectometry (OTDR)
Unit 6: DIGITAL TRANSMISSION SYSTEM: (06 Hrs.) Point-to-Point
links System considerations -Link Power budget -Rise - time budget
-Noise Effects on System Performance-Operational Principles of WDM,
Solutions-Erbium-doped Amplifiers. Basic on concepts of SONET/SDH
Network.
.
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Term work:
Term work shall consist of minimum six assignments based upon
above syllabus
Reference books:
1. Optical Fiber Communications Principles and Practice, John M.
Senior, PHI 1992
2. Optical Fiber Communications Systems. Gerg Keiser,2nd Edition
PHI of India 1995
3. Fiber Optic Communications Systems, G.P.Agarwal, 3rd Edition,
Wiley, 2002
4. Optical communications Systems, John Gowar, 2nd Edition PHI
of India 1992
5. Optical and Wire-less Communications, Matthew N. O. Sadiku,
CRC Press
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Solapur University, Solapur M.E. (Electronics &
Telecommunication Engg.-Digital Electronics &
Communication System) Semester-II RF & MICROWAVE CIRCUIT
DESIGN
Teaching Scheme Examination Scheme Lectures 3 Hrs. /Week Theory
Credits 3.0 Practical 2 Hrs. /Week Practical Credit- 1.0
SECTION- I
Unit 1. Review of EM Theory : (10hrs) Introduction ,Maxwells
equations, Plane waves in dielectric & conducting media, Energy
& Power, Transmission lines and its parameters, planar
transmission lines, Lumped and Distributed Passive Elements .
Unit 2: RF and Microwave Circuit Design: (05hrs) Single &
multi port network, Basic definitions, Interconnecting networks,
network properties & applications, scattering parameters. RF
filter design, filter configurations, special filter realizations,
filter implementation, coupled filter.
Unit 3:Active components: (05hrs) Semiconductor basics, RF
diodes, bipolar junction transistor, RF field effect transistors,
High electron mobility transistors. Active RF components modeling :
Diodes models, transistor models, measurement of active devices,
scattering parametric device characterization.
SECTION- II Unit 4: Matching & biasing network: (04hrs)
Impedance matching using discrete components, micro strip line
matching networks, amplifier class of operation, biasing
networks.
Unit 5: RF transistor amplifier design: (06hrs) Amplifier power
relations, stability considerations, constant gain, noise figure
circles, constant VSWR circles, broadband, high power &
multistage amplifiers, Oscillators & Mixer: basic oscillator
model, High Frequency oscillator configuration, basic
characteristics of mixers.
Unit 6: Monolithic Microwave Integrated Circuits &
Technology: (10hrs) Introduction, History of Monolithic Microwave
Integrated Circuits, Materials, Fabrication techniques of MMIC
,Microwave field effect Transistor(MESFET) and High Electron
Mobility Transistors(HEMTS). Active & Passive Phase
shifters.
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Reference books:
1. Microwave engineering Annapurna Das and sisir K Das (TMH)
(Ref: Chapter1)
2. RF circuit design, theory & applications- Reinhold
Ludwig, Pavel Bretchko, (PearsonEducation
LPE)(Ref:4.1-4.4,5.1-5.4,6.1-6.5,7.1-7.4,8.1-8.3,9.1-9.7,10.1-10.3)
3. Microwave Devices and Circuits- Samuel Y. Liao, (PHI)
(Ref.12.0-12.2,6.2-6.3)
4. Microwave Engineering-David M. Pozar (John Wiley &
Sons)
5. Microwave Engineering- Sisodiya and Raghuvanshi, (PHI)
6. Microwave Devices & Circuit Design-Gupta &
Shrivastava(PHI)
Laboratory Experiments : (Minimum 8 experiments can be
conducted.)
(FEKO or Ansoft HFSS simulator can be used)
1. MATLAB Implementation to obtain radiation pattern of an
antenna
2. Experimental study of radiation pattern of antenna and
measurement of characteristics of antenna.
3. Survey on frequency independent antennas.
4. Simulation of RF filter for given specifications.
5. Measurement of unknown impedance using microwave bench.
6. Impedance matching of antenna using different methods.
7. Measurement of Phase shift of the wave in the waveguide.
8. Measurement of dielectric constant of a given dielectric.
9. Measurement of primary constants and transmission line
parameters of given transmission line.
(Any other experimets can be added to support the theory)
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Solapur University, Solapur M.E. (Electronics &
Telecommunication Engg.-Digital Electronics &
Communication System) Semester-II
HIGH SPEED DIGITAL DESIGN
Teaching Scheme Examination Scheme Lectures 3 Hrs. /Week Theory
Credits 3.0 Practical 2 Hrs. /Week Practical Credit- 1.0
SECTION- I
Unit 1.Introduction to high speed digital design. (7 Hrs)
Frequency, time and distance , Capacitance and inductance effects
,High speed properties of logic gates , Speed and power ,Modelling
of wires ,Geometry and electrical properties of wires , Electrical
models of wires ,transmission lines , lossless LC transmission
lines , lossy LRC transmission lines ,special transmission
lines.
Unit 2.Power distribution and noise (6 Hrs) Power supply network
, local power regulation , IR drops ,area bonding , on chip by pass
capacitors , symbiotic bypass capacitors , power supply isolation ,
Noise sources in digital system , power supply noise , cross talk ,
intersymbol interference.
Unit 3.Signalling convention and circuits (7 Hrs) Signalling
modes for transmission lines ,signalling over lumped transmission
media ,signaling over RC interconnect ,driving lossy LC lines ,
simultaneous bi-directional signalling, terminations , transmitter
and receiver circuits.
SECTION- II Unit 4. Design issues of high speed Electronics (5
Hrs) Simulation tools, Prototyping Circuits, Grounding in high
speed systems.
Unit 5.Power supply issues (6 Hrs) Power supply noise reduction
and filtering, Power supply conditioning, EMI/RFI considerations,
Shielding concepts
Unit 6. High Speed ADCs (9 Hrs) Fundamental of high speed
sampling, Base band antialiasing filters, Study of Harmonic
sampling and band pass sampling, Direct IF to digital conversion,
Distortion and noise in an ideal N bit ADC, AD9220 12 bit ADC,
Spurious free Dynamic Range, Measurement of Noise Power Ratio, Case
study of AD9066, Study of latency of ADCs.
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Term work: Term work shall consists of minimum eight experiments
based on syllabus using simulation tools.
Reference Books: 1. High-Speed Digital Design: A Handbook of
Black Magic by Howard Johnson
2. High Speed Signal Propagation: Advanced Black Magic by Howard
W. Johnson
3. Signal Integrity Issues and Printed Circuit Board Design by
Douglas Brooks. Prentice Hall Professional.
4. High-Speed Digital System Design: A Handbook of Interconnect
Theory and Design Practices by Stephen H. Hall
5. Signal Integrity - Simplified by Eric Bogatin. Prentice Hall
Professional.
6. Handbook of Digital Techniques for High-Speed Design : Design
Examples, Signaling and Memory Technologies, Fiber Optics,
Modeling, and Simulation to Ensure ... (Prentice Hall Modern
Semiconductor Design) by Tom Granberg
7. Noise Reduction Techniques in Electronic Systems, by Henry
Ott. Wiley
8. High Speed Design Techniques, Manual by analog Devices,
October 1996
9. High Speed Digital Circuits, Masakazu Shoji; Addison Wesley
Publishing Company, 1996
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Solapur University, Solapur M.E. (Electronics &
Telecommunication Engg.-Digital Electronics &
Communication System) Semester-II ADVANCED EMBEDDED SYSTEMS
Teaching Scheme Examination Scheme Lectures 3 Hrs. /Week Theory
Credits 3.0 Practical 2 Hrs. /Week Practical Credit- 1.0
SECTION- I
Unit 1: Embedded System Hardware: (7 hrs) Embedded systems
overview, Hardware components like microcontroller, GPP, ASSP,
AISP, SOC, Details of 32 bit ARM SOC architecture, Organization,
Analog, Digital & High speed I/O for embedded systems
Unit 2: Memory management (5 hrs) Interfacing SRAM, DRAM and
flash memories with microcontroller, memory management, allocation
of memory to program segments and blocks, memory maps.
Unit 3: Embedded System Software (8 hrs) Techniques of writing
efficient C code for microcontroller, C data types for ARM, Signed
& unsigned data types, limitation of char & data types,
storage class static & extern, volatile keyword, operation on
bits, functions, ARM Thumb procedural call standard, pointers &
arrays, conditional statements ifelse, switch, structure,
conditional loops for & while, preprocessing, compiling, cross
compiling, compiler driver, startup code and board support
packages, program segments calling assembly routines in C,
interrupt handling in C, interrupt latency
SECTION- II
Unit 4: Uniprocessor Real Time Scheduling (7 hrs) Real time
systems, tasks and its states, task assignment & scheduling,
scheduling algorithms rate monotonic and earliest deadline first,
inter-task communication, semaphore, priority inheritance protocol,
priority ceiling protocol, real time operating system features,
features of micro COS II, RTOS
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Unit 5: Embedded System Architecture & Design: (5 hrs)
Embedded system implementation aspects & estimation modeling,
embedded system architecture, validation and debugging of embedded
systems, hardware software codesign in an embedded system.
Unit 6: Embedded processor: (8 hrs) ARM 9 architecture,
instructions and data handling; interfacing with memory;
interrupts, timers, ARM bus, I/O devices, I/O controllers, simple
& autonomous I/O controllers, parallel, multiplexed, tristate,
and open-drain buses, bus protocols, serial transmission techniques
& standards, wireless protocol, CAN & advanced buses
Term work:
Term work shall consist of minimum eight experiments based upon
above syllabus
Reference Books :
1. Embedded Systems by Rajkamal, 2nd Ed, Tata McGraw Hill
2. Embedded Real-time Systems Programming by Iyer & Gupta,
Tata McGraw Hill
3. ARM System on Chip Architecture by Furber, 2nd Ed, Pearson
India
4. Intro. To Embedded Systems by K.V. Shibu, McGraw Hill
5. Scheduling in Real Time systems by Cottet, Delacroix &
Mammeri, John Wiley & Sons
6. Embedded system design A Unified Hardware/software approach
by Frank Valid & Tony Givangis, Publishing 1999
7. Embedded systems: World Class Designs- Jack Ganssle, Newness
Publication, Australia.
8. Embedded Microprocessor Systems: Real world design Stuart R
& Ball P.E., 3rd Ed., Newness, Imprint Elsevier Science.
9.ARM920T Technical Reference Manual (Rev 1) - ARM DDI 0151C,
Data books of ARM7/ARM9 J., ARM Company Ltd.
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Solapur University, Solapur M.E. (Electronics &
Telecommunication Engg.-Digital Electronics &
Communication System) Semester-II WIRELESS & MOBILE
NETWORKS
Teaching Scheme Examination Scheme Lectures 3 Hrs. /Week Theory
Credits 3.0 Tutorial 1 Hrs. /Week Tutorial Credit- 1.0
SECTION- I
Unit 1. (6 hrs) Wireless Communication Systems, Characteristics
of radio propagation, Fading, Multipath propagation .
Unit 2: (6 hrs) Detection in a Rayleigh fading channel, time
diversity, antenna diversity, frequency diversity, impact of
channel uncertainty
Unit 3: (8 hrs) RAKE Receiver, Interleaving, Fundamentals of
Channel Coding, Block Codes and Finite Fields, Convolution Codes,
Coding Gain, Trellis Coded Modulation, Turbo Codes
SECTION- II Unit 4: (8 hrs) MAC protocols for digital cellular
systems such as GSM. MAC protocols for wireless LANs such as
IEEE802.11 and HIPERLAN I and II. The near far effect. Hidden and
exposed terminals. Collision Avoidance (RTS-CTS) protocols
Unit 5: (8 hrs) Mobile Networking: Mobile-IP, Ad-Hoc Networks
and Ad-Hoc Routing, Wireless Protocols: Wireless TCP, Session
Mobility Mobile network layer protocols such as mobile-IP, Dynamic
Host Configuration Protocol (DHCP). Mobile transport layer
protocols such as mobile-TCP, indirect-TCP.
Unit 6: (4 hrs) Wireless Application Protocol (WAP). Mobile
Agents, Transcending and Proxy Architecture, Wireless Web and WAP,
Mobile Wireless Networks Simulation
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Term work:
Term work shall consist of minimum six assignments based upon
above syllabus
Reference books:
1. Wireless communications; Principle and Practice, T.S.
Rappaport, (Second Edition) Pearson
2. Fundamentals of Wireless Communication: David Tse,
Cambridge
3. Mobile communications, J.Schiller,ISBN: 0-321-12381-6,
Addison-Wesley, 2003
4. Computer Networks (Fourth Edition), A S. Tanenbaum,Publisher:
Prentice Hall PTR
5. Introduction to Wireless and Mobile Systems, Dharjma Agrawal,
An Zeng, Thomson Publication.
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Page 26 of 31
Solapur University, Solapur M.E. (Electronics &
Telecommunication Engg.-Digital
Electronics & Communication System) Semester-II
ELECTIVE-II :- IMAGE AND VIDEO PROCESSING & BROADCASTING
Teaching Scheme Examination Scheme Lectures 3 Hrs. /Week Theory
Credits 3.0 Tutorial 1 Hrs. /Week Tutorial Credit- 1.0
SECTION-I
Unit 1: Introduction: (8Hrs.) Introduction, 2D sampling theory,
Limitations in sampling & reconstruction, Quantization, Optimal
quantizer, Compander, Visual quantization, Optical & Modulation
transfer function, Spectral density function, fundamentals of Image
perception. Image Transforms: Applications of DCT, Slant, KLT, SVD,
DWT transforms in Image processing
Unit 2: Image Representation by Stochastic Models: (4Hrs.)
Introduction, one-dimensional Causal models, AR models, Non-causal
representations, linear prediction in two dimensions
Unit 3: Image Filtering & Restoration: (8Hrs.) Review of
spatial and frequency domain filtering, Image observation models,
Smoothing splines and interpolation, Least squares filters,
generalized inverse, SVD and Iterative methods, Maximum entropy
restoration, Bayesian methods, Coordinate transformation &
geometric correction, Blind de-convolution
SECTION-II
Unit 4: Image Analysis & Computer Vision: (7Hrs.) Spatial
feature extraction, Transform features, Edge detection, Boundary
Extraction, Boundary representation, Region representation, Moment
representation, Structure, Shape features, Texture, Scene matching
& detection, Image segmentation, Classification Techniques.
Unit 5: Image Reconstruction from Projections: (5Hrs.)
Introduction, Radon Transform, Back projection operator, Projection
theorem, Inverse Radon transform, Fourier reconstruction, Fan beam
reconstruction, 3D tomography
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Unit 6: Image & Video Broadcasting Standards: (8Hrs.)
Inter-frame coding, coding of two tone images, Image compression
standards. video
compression: Compression efficiency, MPEG-4 AVC/H.264. Scalable
video coding (SVC), Video over IPd video indexing
Term work:
Term work shall consist of minimum six assignments based upon
above syllabus
Reference books:
1. Fundamentals of Digital Image Processing, A. K. Jain, Pearson
Education (Asia) Pte. Ltd./Prentice Hall of India, 2004.
2. Fundamentals of Multimedia, Z. Li and M.S. Drew, Pearson
Education (Asia) Pte. Ltd., 2004.
3. Digital Image Processing, R. C. Gonzalez and R. E. Woods, 2nd
edition, Pearson Education (Asia) Pte. Ltd/Prentice Hall of India,
2004.
4. Digital Video Processing, M. Tekalp, Prentice Hall, USA,
1995.
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Page 28 of 31
Solapur University, Solapur M.E. (Electronics &
Telecommunication Engg.-Digital Electronics & Communication
System) Semester-II
ELECTIVE- II :- CRYPTOGRAPHY & NETWORK SECURITY
Teaching Scheme Examination Scheme Lectures 3 Hrs. /Week Theory
Credits 3.0 Tutorial 1 Hrs. /Week Tutorial Credit- 1.0
SECTION-I
Unit 1: Overview: (4 Hrs.) Services, Mechanisms, and attacks,
The OSI Security Architecture. A model for network security,
Classical Encryption Techniques: Symmetric Cipher
Model,Substitution Techniques, Transposition Techniques, Rotor
Machines, Steganography
Unit 2: Block Ciphers and the Data Encryption Standard: (8 Hrs.)
Simplied DES, Block Cipher Principles,The Data Encryption Standard,
The Strength of DES, Differential Linear Cryptanalysis,Block Cipher
Design Principles, Block Cipher Modes of Operation, Contemporary
symmetric Ciphers: Triple DES, Blowfish, RC5, And Characteristics
of Advanced Symmetric Block Ciphers, Confidentially using symmetric
Encryption: Placement of Encryption Function, Traffic
Confidentiality, Key Distribution, Random Number Generation
Unit 3: Public Key Cryptography and RSA: (8 Hrs.) Principles of
Public Key cryptosystems, The RSA Algorithm, Key Management, other
Public Key Cryptosystems key Management, Diffle- Hellman Key
exchange. Message Authentication and hash functions:Authentication
Requirements, F Authentication Function, Message Authentication
Codes, Hash Functions, Security of Hash Functions and MACs.
SECTION-II
Unit 4: Hash Algorithms: (10Hrs.) MD5 Message Digest Algorithm,
Secure Hash Algorithm Authentification Applications:Kerberos, X.
509 Authentication Service..
Unit 5: Electronic Mail Security: (5 Hrs.) Pretty Good Privacy,
S/MIME, IP Security Overview, IP Security Architecture,
Authentifications, Header, Encapsulating Security Payload,
Combining Security Associations, Key Management
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Unit 6: Web Security: ( 5 Hrs.) Web Security Considerations,
System Security: Intruders, Malicious Software, Viruses, Viruses
and Related Threats, Firewalls: Firewall Design Principles
Term work:
Term work shall consist of minimum six assignments based upon
above syllabus
Reference books:
1. Cryptography and Network Security, Willam Stallings, Third
Edition, Pearson Education
2. Network Security, Private Communication in a public world,
Cbarlie Kaufman, Radia Perlman, Mike Speciner, Second Edition,
Pearson Education Asia, 2002.
3. Cryptography and Network Security, Atul Kahate,Tata
McGrawhill, 2003. .
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Page 30 of 31
Solapur University, Solapur M.E. (Electronics &
Telecommunication Engg.-Digital Electronics & Communication
System) Semester-II
ELECTIVE- II : - ANTENNA THEORY & DESIGN
Teaching Scheme Examination Scheme Lectures 3 Hrs. /Week Theory
Credits 3.0 Tutorial 1 Hrs. /Week Tutorial Credit- 1.0
SECTION-I
Unit 1: Antenna Fundamentals and Definitions: (7Hrs.) Radiation
mechanism - over view, Electromagnetic Fundamentals, Solution of
Maxwells Equations for Radiation Problems, Ideal Dipole, Radiation
Patterns, Directivity and Gain, Antenna Impedance, Radiation
Efficiency. Antenna Polarization. Resonant Antennas: Wires and
Patches, Dipole antennas, Yagi - Uda Antennas, Micro strip
Antenna.
Unit 2: Arrays: (7 Hrs.) Array factor for linear arrays,
uniformly excited, equally spaced Linear arrays, pattern
multiplication, directivity of linear arrays, non- uniformly
excited -equally spaced linear arrays, Mutual coupling,
multidimensional arrays, phased arrays, feeding techniques,
perspective on arrays. Broad band Antennas: Traveling - wave
antennas, Helical antennas, Biconical antennas, sleave antennas,
and Principles of frequency - independent Antennas, spiral
antennas, and Log - Periodic Antennas.
Unit 3: Antenna: (6 Hrs.) Aperture Antennas: Techniques for
evaluating Gain, reflector antennas - Parabolic reflector antenna
principles, Axi -symmetric parabolic reflector antenna, offset
parabolic reflectors, dual reflector antennas, Gain calculations
for reflector antennas, feed antennas for reflectors, field
representations, matching the feed to the reflector, general feed
model, feed antennas used in practice.
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Page 31 of 31
SECTION-II
Unit 4: Antenna Synthesis: (6Hrs.) Formulation of the synthesis
problem, synthesis principles, line sources shaped beam synthesis,
linear array shaped beam synthesis Fourier Series, Woodward Lawson
sampling method,comparison of shaped beam synthesis methods, low
side lobe narrow main beam synthesis methods Dolph Chebyshev linear
array, Taylor line source method.
Unit 5: Moments: (7Hrs.) Method of Moments : Introduction to
method of Moments, Pocklingtons integral equation, integral
equations and Kirchoffs Networking Equations, Source Modeling
Weighted residuals formulations and computational consideration,
calculation of antenna and scatter characteristics.
Unit 6: CEM for Antennas: (7Hrs.) Finite Difference Time Domain
Method Geometrical Optics Wedge diffraction theory, ray fixed
coordinate system, uniform theory of wedge diffraction, E - Plane
analysis of Horn antennas. Cylindrical parabolic antenna, radiation
by a slot on a finite ground plane, radiation by a monopole on a
finite ground plane, equivalent current concepts, multiple
diffraction formulation, by curved surfaces, physical optics,
method of stationary phase, physical theory of diffraction,
cylindrical parabolic reflector antennas.
Term work:
Term work shall consist of minimum six assignments based upon
above syllabus
Reference books: 1.Antenna Theory Analysis and Design C. A.
Balanis, John Wiley, 2nd Edition, 1997
2.Antennas, John D. Kraus, McGraw Hill, TMH, 3rd/4th
Edition.
3.Antenna Theory and Design, Stutzman and Thiele, 2ndEd, John
Wiley and Sons Inc..
4. Antenna and Propagation, Sachidananda et. el, Pearson
Edu.