EC010 601
DIGITAL COMMUNICATION TECHNIQUES
Teaching scheme Credits:
4
2 hours lecture
and 2 hour tutorial per week
Objectives:
To develop ability to analyze communication engineering problems and also to
design and develop different communication and electronics systems for
processing signals and data.
MODULE
I (12 hrs)
Random
Signal Theory: Random process: stationarity,ergodicity, mean, auto
correlation, cross correlation, covariance, random process transmission through
linear filters, power spectral density, cross correlation functions, cross spectral
densities, Gaussian process, Discrete Time Random Process, White Process
Signal Space Representation of Waveforms: Vector
Space Concept, Signal Space Concepts, Orthogonal Expansion, Gram- Schmidt
Orthogonalization Procedure
MODULE II (12 hrs)
Detection
and Estimation: Model of digital communication system, response of bank of
correlators to noisy input. Detection of known signals in noise:-ML Receiver.
Probability of error calculation, erf, Correlation Receiver, Matched Filter
Receiver, properties, detection of signals with unknown phase in noise,
Estimation concepts: ML Estimate.
MODULE III (12 hrs)
Pulse
Modulation Techniques: Sampling and pulse modulation: Sampling theorem, Ideal
sampling and reconstruction, practical sampling and Aliasing, PAM, PWM, PPM,
Quantizing, Quantization Noise, Companding, PCM generation and reconstruction,
DPCM, Delta Modulation, Adaptive Delta Modulation, digital multiplexing
MODULE IV (12 hrs)
Baseband
shaping for Data Transmission: Binary signaling format, Inter Symbol
Interference, Nyquist criterion for distortion less base band binary
transmission: Ideal solution, practical solution, correlative coding: Duobinary
signaling, modified duobinary, generalized form of correlative coding, eye
pattern, equalization ,adaptive equalization, synchronization techniques: bit
synchronization, frame synchronization
MODULE V (12 hrs)
Bandpass
Digital Transmission: Digital CW Modulation: ASK, BFSK, BPSK, MSK, Coherent
binary system, timing and synchronization, Non coherent binary system,
Differentially coherent PSK, Quadrature carrier and M-ary systems: quadrature
carrier system, MPSK, M-ary QAM, Trellis coded modulation
References:
1. Simon Haykin
, Introduction To Analog
And Digital Communications, Wiley India Edition
2. Proakis& Salehi,
Digital Communications, Mc
Graw Hill International Edition.
3.
Herbert
Taub, Schilling Donald L.,“Principles of Communication Systems,3rd e/d, Tata
Mc Graw Hill,2007.
4. Carlson,
Crilly, Rutledge, “Communication
Systems” 4th Edition, McGraw Hill
5. Simon Haykin
, Digital Communications,
Wiley India Edition
6. Sklar,Kumar Ray,
Digital Communications,
Pearson Education
7. Glover,Grant, Digital
Communications, Pearson Education
EC010 602
DIGITAL SIGNAL PROCESSING
Teaching
scheme Credits: 4
2
hours lecture and
2 hours tutorial per
week
Objectives
• To
study the fundamentals
of discrete-time system
analysis, digital filter
design and the
DFT
Module I
(12 hrs)
Advantages of DSP – Review of discrete time
signals and systems – Discrete time LTI systems – Review of DTFT – Existence –
Symmetry properties – DTFT theorems – Frequency response-Review of Z transform
– ROC – Properties
Sampling
of Continuous time signals – Frequency domain representation of sampling –
Aliasing - Reconstruction of the analog signal from its samples – Discrete time
processing of continuous time signals – Impulse invariance – Changing the
sampling rate using discrete time processing – Sampling rate reduction by an
integer factor – Compressor – Time and frequency domain relations – Sampling
rate increase by an integer factor – Expander – Time and frequency domain
relations – Changing the sampling rate by a rational factor.
Module II
(12 hrs)
Transform
analysis of LTI systems – Phase and group delay – Frequency response for
rational system functions – Frequency response of a single zero and pole –
Multiple poles and zeros - Relationship between magnitude and phase – All pass
systems – Minimum phase systems – Linear phase systems – Generalised linear
phase – 4 types – Location of zeros.
Module III
(12 hrs)
Structures
for discrete time systems – IIR and FIR systems – Block diagram and SFG
representation of difference equations – Basic structures for IIR systems –
Direct form - Cascade form - Parallel form - Transposed forms – Structures for
FIR systems – Direct and Cascade forms - Structures for Linear phase systems –
Overview of finite precision numerical effects in implementing systems
Analog filter design: Filter specification
– Butterworth approximation – Pole locations – Design of analog low pass
Butterworth filters – Chebyshev Type 1 approximation – pole locations – Analog
to analog transformations for designing high pass, band pass and band stop
filters.
Module IV
(12 hrs)
Digital
filter design: Filter specification – Low pass IIR filter design – Impulse
invariant and Bilinear transformation methods – Butterworth and Chebyshev –
Design of high pass, band pass and band stop IIR digital filters – Design of
FIR filters by windowing – Properties of commonly used windows – Rectangular,
Bartlett, Hanning, Hamming and Kaiser.
Module V
(12 hrs)
The
Discrete Fourier Transform - Relation with DTFT – Properties of DFT – Linearity
– Circular shift – Duality – Symmetry properties – Circular convolution –
Linear convolution using the DFT – Linear convolution of two finite length
sequences – Linear convolution of a finite length sequence with an infinite
length sequence – Overlap add and overlap save – Computation of the DFT –
Decimation in time and decimation in frequency FFT – Fourier analysis of
signals using the DFT – Effect of windowing – Resolution and leakage – Effect
of spectral sampling.
References
1.
A V
Oppenheim, R W Schaffer, Discrete Time Signal Processing , 2nd Edition
Pearson Education.
2.
S K Mitra, Digital Signal
Processing: A Computer
Based Approach ,Tata Mc.Graw Hill.
3.
J G
Proakis, D G Manolakis, Digital Signal Processing: Principles, Algorithms
and Applications, Prentice Hall of India..
4.
L C
Ludeman, Fundamentals of
Digital Signal Processing, Wiley
5.
J R
Johnson, Introduction to Digital
Signal Processing, Prentice
Hall of India.
EC010
603 RADIATION AND
PROPAGATION
Teaching Schemes Credits:
4
3 hours
lecture and 1
hour tutorial per
week.
OBJECTIVES
•
To impart
the basic concepts
of radiating structures
and their arrays
•
To give
understanding about analysis
and synthesis of
arrays
•
To give
idea about basic
propagation mechanisms
MODULE 1
( 13 hours)
Retarded
potentials: Concept of vector potential- Modification for time
varying- retarded case- Fields associated with
Hertzian dipole- Power radiated and radiation resistance of current
element-Radiation from half-wave dipole and quarter-wave monopole antennas.
Antenna Parameters: Introduction, Isotropic
radiators, Radiation pattern, Gain -radiation intensity-Directive gain,
Directivity, antenna efficiency- antenna field zones. Reciprocity theorem & its applications, effective
aperture, Effective height,
radiation resistance, terminal impedance, front-to-back ratio, antenna beam
width, antenna bandwidth, antenna beam efficiency, antenna beam area or beam
solid angle, polarization, antenna temperature.
MODULE 2
(13hours)
Antenna
Arrays: Introduction, various forms of antenna arrays, arrays of point sources,
non isotropic but similar point sources, multiplication of patterns, arrays of
n-isotropic point sources, Grating lobes, Properties and Design of Broadside,
Endfire, Binomial and Dolph Chebyshev arrays, Phased arrays, Frequency-
Scanning arrays- Adaptive arrays and Smart antennas.
MODULE 3
(13hours)
Antenna Types:- Horizontal and Vertical
Antennas above the ground plane. Loop Antennas: Radiation from small loop and
its radiation resistance- Radiation from a loop with circumference equal to a
wavelength-Helical antenna: Normal mode and axial mode operation-Yagi uda
Antenna- Log periodic antenna- rhombic antenna- Horn antenna-Reflector antennas
and their feed systems- Micro strip antenna-Selection of antenna based on
frequency of operation – Antennas for special applications: Antenna for
terrestrial mobile communication systems, Ground Penetrating Radar(GPR),
Embedded antennas, UWB,
,Plasma antenna.
MODULE 4
(13hours)
Ground wave
propagation: Attenuation characteristics for ground wave
propagation-Calculation of field strength at a distance –
Space wave propagation: Reflection
characteristics of earth- Resultant of direct and reflected ray at the receiver- LOS distance
– Effective earth‘s radius – Field strength of space wave - duct propagation
Sky wave propagation: Structure
of the ionosphere- effect of earth‘s magnetic field Effective dielectric constant of ionized
region- Mechanism of refraction- Refractive index- Critical frequency- Skip
distance- Effect of earth’s magnetic field- Attenuation factor for ionospheric
propagation- Maximum usable frequency(MUF) – skip
distance – virtual height – skip distance, Fading and Diversity reception.
MODULE 5
(8 hours)
Antenna Measurements: Reciprocity in
Antenna measurements – Measurement of radiation pattern – Measurement of ranges
- Measurement of different Antenna parameters- Directional pattern, Gain,
Phase, Polarization, Impedance, and Efficiency, Effective gain,SAR.
REFERENCES
- John D. Krauss, Ronald
J Marhefka: “Antennas and Wave Propagation”, 4th
Edition, Tata Mc Graw Hill
- Jordan & Balman. “Electromagnetic
waves & Radiating Systems”– Prentice Hall India
- Constantine.
A. Balanis: “Antenna Theory- Analysis and Design”, Wiley India, 2nd
Edition, 2008
- R.E Collin: “Antennas &
Radio Wave Propagation”, Mc Graw Hill. 1985.
- Terman: “Electronics &
Radio Engineering”, 4th Edition,
McGraw Hill.
- Kamal Kishor: “Antenna and
Wave propagation” , IK International
Mahatma
Gandhi University
EC010 604:
COMPUTER ARCHITECTURE AND
PARALLEL
PROCESSING
Teaching scheme Credits: 4
3 hours lecture and 1 hour tutorial per week
Objectives
•
To
impart the basic
concepts of architecture
and organisation of
computers
•
To develop
understanding about pipelining
and parallel processing
techniques.
•
To
impart knowledge about
the current PC
hardware
Pre-requisites: Digital
Electronics and Microprocessors
Module
I (12 hours)
Introduction
:
Difference between Architecture, Organisation and Hardware, Review of basic
operational concepts – Stored program concept, Instruction sequencing, bus structure,
Software support- translating and executing a program- assembler, linker,
loader, OS, Instruction types and Addressing modes.
CPU Performance and its factors, Performance
evaluation, The Power wall, Switch from uniprocessors to multiprocessors, Basic
concepts of pipelining, superscalar architecture and multithreading,
Instruction level parallelism (basic idea only).
Module
II (12 hours)
Processor Organisation: Control
Unit design: Execution of a complete instruction, Single bus and multibus organisation,
Sequencing of control signals, Hardwired control unit, Microprogrammed control
unit.
Arithmetic and logic design – review of signed and
unsigned binary arithmetic, fast adders, Array multiplier, sequential
multiplier, Booth’s algorithm, fast multiplication methods, integer division –
restoring and non restoring methods, floating point numbers.
Module
III (12 hours)
Memory
and I/O Organisation Memory hierarchy, Memory characteristics,
Internal organization
of semiconductor RAM memories, Static and Dynamic RAM memories, flash memory,
Cache memory – mapping function, replacement algorithm, measurement and
improvement of cache performance, Virtual memory and address translation, MMU.
Secondary
memories – magnetic and optical disks, I/O accessing – Programmed, Interrupt
driven and DMA , Buses- synchronous and asynchronous, bus standards.
Module
IV (12 hours)
Parallel
Processing :Enhancing performance with pipelining-overview,
Designing instruction
set for pipelining, pipelined datapath, Hazards in pipelining.
Flynn’s classification, Multicore processors and
Multithreading, Multiprocessor systems-Interconnection networks, Multicomputer
systems, Clusters and other message passing architecture.
Syllabus -
B.Tech. Applied Electronics & Instrumentation Engg.
Mahatma
Gandhi University
Module V
(12 hours)
PC Hardware: Today’s PC architecture – block
diagram, Familiarisation of PC hardware components.
Processor - Pentium series to higher processors -
single core, hyperthreading, dual core, multi core and many core processors
(brief idea about evolution and improvements in performance)
Motherboard – Typical architecture , Essential
Chipsets, Sockets, Slots and ports – serial, parallel, USB, RAM , Brief idea
about buses, Subsystems (Network, Sound and Graphics, Ethernet port),
Storage
devices : Hard Disks-Types and Classification based on interface- Optical
Storage – CD, DVD, BLURAY
SMPS – Functions, power connectors. Typical
specifications for a computer
Reference
Books
- Carl Hamacher : “Computer Organization ”, Fifth
Edition, Mc Graw Hill.
- David A. Patterson and John L.Hennessey, “Computer
Organisation and Design”, Fourth Edition, Morgan Kaufmann.
- William Stallings :
“Computer Organisation and Architecture”, Pearson Education.
- John P Hayes : “Computer Architecture and Organisation”, Mc Graw Hill.
- Andrew S Tanenbaum :
“Structured Computer Organisation”, Pearson Education.
- Craig Zacker : “PC
Hardware : The Complete Reference”, TMH.
- Nicholas P Carter : “Computer Architecture and
Organization”, Mc Graw Hill.
- Pal Chaudhari: “Computer Organisation and Design”,
Prentice hall of India.
Syllabus -
B.Tech. Applied Electronics & Instrumentation Engg.
Mahatma
Gandhi University
EC010
605 MICROCONTROLLERS AND
APPLICATIONS
Teaching scheme Credits: 4
3 hours lecture
and 1
hour tutorial per week
Objectives
•
To
study the architecture
of 8051, PIC18
microcontrollers
•
To
understand the instruction
set and programming
of 8051.
•
To
know the Interfacing
methods and programming
using 8051.
Module
I (9hours)
Introduction
to Microcontrollers: Comparison with Microprocessors – Harvard and Von Neumann
Architectures - 80C51 microcontroller – features - internal block schematic -
pin descriptions, I/O ports.
Module
II (9 hours)
Memory organization – Programming model -
Program status word - register banks - Addressing modes - instruction set
–Programming examples.
Module
III (9 hours)
Interrupts - interrupt sources - interrupt
handling – programming examples. Timers operation-different modes –waveform
generation- programming examples - Serial communication-different modes -
programming examples.
Module
IV (9 hours)
Interfacing of DIP switch- LED -7 segment
displays -alphanumeric LCD – relay interface – Stepper motor –ADC-DAC-interfacing
programs using assembly language.
Module
V(9 hours)
Overview of PIC 18, memory organisation, CPU,
registers, pipelining, instruction format, addressing modes, instruction set,
interrupts, interrupt operation, resets, parallel ports, timers, CCP.
References
1.
Muhammad
Ali Mazidi, The 8051 Microcontroller and embedded sytems, Pearson
Education 2nd edition, 2006
2.
Kenneth J
Ayala, The 8051 Microcontroller, Penram International, 3rd edition
2007
3.
Myke
Predko, “Programming and customizing the 8051 microcontroller” Tata
Mc.Graw Hill, 2004
4.
Han Way
Huang, “PIC microcontroller An introduction to software and hardware
interfacing”, Cenage learning 2007
5.
Muhammad
Ali Mazidi “PIC microcontroller and embedded systems using assembly
and C for PIC 18” , Pearson 2009
Syllabus
- B.Tech. Electronics & Communication
Engg.
Mahatma Gandhi University
EC010
606 L01: DATA STRUCTURES
AND ALGORITHMS
Teaching scheme Credits: 4
3 hours lecture
and 1 hour
tutorial per week
Objectives
•
To
impart the basic
concepts of data
structures and algorithms.
•
To develop understanding about writing
algorithms and solving problems with the help of fundamental data structures
using object oriented concepts.
Module
I (10 hours)
Introduction
to Data Structures, arrays, records, stacks, queue, linked list, linked stacks
and queues, doubly linked list. Polynomial representation using arrays and
lists.
Module
II (12hours)
Trees, binary
tree, traversals, binary search tree, creation insertion, deletion, searching.
Graph:-representation, depth first search, breadth first search, path finding.
Module
III (12hours)
Search
algorithms, sequential binary interpolation, sorting, insertion, bubble, radix,
quick sort, merge sort, and heat sort.
Module
IV (14 hours)
Analysis of algorithms: - Time and space
complexity, complexity notations, best, worst, average cases.
Algorithmic
techniques-brute force, greedy, divide and conquer, dynamic programming
Module
V (12 hours)
Analysis
of search algorithms, sort algorithms. P and NP problems, travelling sales man
problems.
Reference
Books
1.
Horowitz
,Sahni & Anderson Freed,
Fundamentals of Data Structures in C, 2nd ed., Universities
Press, Hyderabad, 2009
2.
Sartaj Sahni , Data Structures,
Algorithms and Applications in C++ , 2nd ed., Universities Press, Hyderabad, 2009
3.
Michael T Goodrich, Roberto Tamassia, David
Mount, Data Structures and Algorithms in C++, Wiley India
Edition, New Delhi, 2009
4.
B.M. Harwani, Data Structures and
Algorithms in C++, Dreamtech Press, New Delhi, 2010
5.
Langsam,
Augenstein ,Tanenbaum, Data Structures in C & C++ , 2nd Edition,
Pearson Education.
6.
John
Hopcroft, Rajeev Motwani & Jeffry Ullman, Introduction to Automata Theory,
Languages & Computation, Pearson Education.
7.
Tremblay
& Sorenson, Introduction to Data Structures with Applications, Tata
Mc Graw Hill
8.
Sara Baase
& Allen Van Gelder ,Computer Algorithms – Introduction to Design and
Analysis , Pearson Education
9.
Sahni, Data
Structures algorithms and
applications , Tata
Mc GrHill
Syllabus -
B.Tech. Computer Science
& Engg.
Mahatma Gandhi University
10. K.L.P. Mishra, N.
Chandrashekharan, Theory of Computer Science , Prentice
Hall of India
Syllabus -
B.Tech. Computer Science
& Engg.
Mahatma
Gandhi University
EC010
606 L602: DATABASE
MANAGEMENT SYSTEMS
Teaching scheme Credits: 4
3 hours lecture and 1 hour tutorial per week
Objectives
•
To
impart an introduction
to the theory
and practice of
database systems.
•
To develop
basic knowledge on
data modelling and
design of efficient
relations.
•
To
provide exposure to
oracle database programming.
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Module
I
|
(10
hours)
|
|
|
|
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Basic Concepts -
Purpose
|
of
|
Database
|
Systems-
|
3
|
Schema
|
Architecture
|
and
|
Data
|
Independence- Components of DBMS –Data Models,
Schemas and Instances-Data Modeling using the Entity Relationship Model-Entity
types, Relationship Types, Weak Entity Types .
Module II (14 hours)
Relational Model
Concepts –Constraints –
Entity Integrity and
Referential Integrity,
Relational
Algebra -Select, Project, Operations from Set Theory, Join, OuterJoin and
Division - Tuple Relational Calculus.
SQL- Data Definition with SQL - Insert,
Delete and Update Statements in SQL, Defining Domains, Schemas and Constraints,
Constraint Violations - Basic Queries in SQL - Select Statement, Use of
Aggregate functions and Group Retrieval, Nested Queries, Correlated Queries –
Views.
Module III (12 hours)
Oracle Case Study : The Basic Structure of
the Oracle System – Database Structure and its Manipulation in Oracle- Storage
Organization in Oracle.- Programming in PL/SQL- Cursor in PL/SQL - Assertions –
Triggers.
Indexing and
Hashing Concepts -: Ordered Indices, Hash Indices, Dense and Sparse Indices,
Multi Level Indices, Cluster Index, Dynamic Hashing.
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Module IV
|
(11
hours)
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|
|
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Database
|
Design–
|
Design
|
Guidelines–
|
Relational
|
Database
|
Design
|
–
|
Functional
|
|
|
|
|
|
|
|
|
|
Dependency- Determination of Candidate
Keys, Super Key, Foreign Key, Normalization using Functional Dependencies,
Normal Forms based on Primary keys- General Definitions of First, Second and
Third Normal Forms. Boyce Codd Normal Form– Multi-valued Dependencies and Forth
Normal Form – Join Dependencies and Fifth Normal Form – Pitfalls in Relational
Database Design.
Module V (13 hours)
Introduction to Transaction Processing-
Transactions- ACID Properties of Transactions-Schedules- Serializability of
Schedules- Precedence Graph- Concurrency Control – Locks and
Timestamps-Database Recovery
Query
processing and Optimization- Translating SQL Queries into a Relational Algebra
Computing Select, Project and Join
Object
Relational Databases-Distributed Databases-Different Types-Fragmentation and
Replication Techniques-Functions of DDBMS.
Syllabus -
B.Tech. Computer Science & Engg.
Mahatma
Gandhi University
Reference
Books
1.
Elmsari and Navathe, Fundamentals of
Database System, Pearson Education Asia, 5th Edition, New Delhi, 2008.
- Henry F Korth, Abraham Silbershatz , Database System
Concepts, Mc Graw Hill
6td Edition, Singapore, 2011.
3.
Elmsari and Navathe, Fundamentals of
Database System, Pearson Education Asia, 3rd Edition, New Delhi, 2005, for oracle
- Alexis Leon and Mathews Leon, Database
Management Systems, Leon vikas Publishers, New Delhi.
- Narayanan S, Umanath and Richard W.Scamell, Data
Modelling and Database Design,Cengage Learning, New Delhi,
2009.
- S.K Singh,Database Systems
Concepts,Design and Applications, Pearson Education Asia, New Delhi,
2006.
- Pranab Kumar Das Gupta, Database management System
Oracle SQL And
PL/SQL, Easter Economy Edition, New Delhi, 2009
|
8.
C.J.Date , An
Introduction to Database
Systems,
|
Pearson
|
Education
|
Asia,
|
7th
|
|
Edition, New Delhi.
|
|
|
|
|
- Rajesh Narang, Database Management Systems, Asoke
K ghosh , PHI Learning, New Delhi, 2009.
- Ramakrishnan and Gehrke, Database Management Systems,
Mc Graw Hill, 3rd Edition , 2003.
Syllabus -
B.Tech. Computer Science & Engg.
Mahatma Gandhi University
EC010
606L03 HIGH SPEED
DIGITAL DESIGN
Teaching scheme Credits: 4
3 hours lecture
and 1 hour tutorial
per week
Objectives
•
To develop the skills for analyzing
high-speed circuits with signal behaviour modelling.
•
To demonstrate proficiency in understanding
signal integrity concepts and terminology and to understand the signal
integrity on circuit design.
•
To be able to perform and analyze signal
measurements and to be able to make trade off decisions based on signal budget
and design requirements.
Pre-requisites: Digital
Electronics, Digital system design
Module
I (12hours)
High
Speed Digital Design Fundamentals: Frequency and time, Time and distance,
Lumped vs distributed, four kinds of reactance- ordinary capacitance and
inductance, mutual capacitance and inductance, Relation of mutual capacitance
and mutual inductance to cross talk.
High
Speed properties of Logic gates: Power, Quicent vs active dissipation, Active
power driving a capacitive load, Input power, Internal dissipation, drive
circuit dissipation, Totem pole and open circuit, speed, Sudden change in
voltage and current.
Module
II (12 hours)
Measurement Techniques; Rise time and bandwidth of
oscilloscope probes, self inductance of probe ground loop, Effects of probe
load on a circuit, special probing fixtures.
Transmission Lines;
Problems of point
to point wiring,
signal distortion, EMI,
cross talk.
Module
III (12 hours)
Transmission
Lines at High frequency: Infinite uniform transmission line, Lossy transmission
line, Low loss transmission line, RC transmission line, Skin effect, Proximity
effect, and Dielectric loss.
Module
IV (12 hours)
Termination:
End termination, rise time, dc biasing, power dissipation, Source termination,
Resistance value, Rise time, Power dissipation, Drive current, Middle
terminators,
Vias:
mechanical properties, capacitance and inductance Connectors: mutual, series
and parasitic capacitance.
Module
V (12 hours)
Power system: Stable voltage reference,
Uniform voltage distribution, choosing a bypass capacitor,
Clock
Distribution: Timing margin,
Clock skew, delay
adjustments, Clock jitter.
Reference
1.
Howard Johnson,
High-Speed Digital Design:
A Handbook of
Black Magic ,
Prentice Hall
2.
Dally W.S.
& Poulton J.W., “Digital
Systems Engineering”, Cambridge
University Press.
3.
Masakazu Shoji,
“High Speed Digital
Circuits”, Addison Wesley
Publishing Company
4.
Jan M,
Rabaey, Digital Integrated
Circuits: A Design
perspective, Second Edition,
2003.
Syllabus
- B.Tech. Electronics
& Communication Engg.
EC
010 606 L04
MEDICAL ELECTRONICS
Teaching
Scheme
3
hours lecture and
1 hour tutorial
per week. Credits: 4
Objectives:-
• To
study the working
of different medical
equipments.
Module 1
(12 hrs)
Introduction
to the physiology of cardiac, nervous & muscular and respiratory systems.
Transducers and Electrodes: Different types of transducers & their
selection for biomedical applications. Electrode theory, selection criteria of
electrodes & different types of electrodes such as, Ag - Ag Cl, pH, etc
Module 2
(12 hrs)
Cardiovascular
measurement: The heart & the other cardiovascular systems. Measurement of
Blood pressure-direct and indirect method, Cardiac output and cardiac rate. Electrocardiography-waveform-standard
lead systems typical ECG amplifier, phonocardiography, Ballisto cardiography,
Cardiac pacemaker –defibrillator –different types and its selection.
Module 3
(12 hrs)
EEG
Instrumentation requirements –EEG electrode –frequency bands – recording
systems EMG basic principle-block diagram of a recorder –pre amplifier. Bed
side monitor –block diagram- measuring parameters-cardiac
tachometer-Alarms-Lead fault indicator-central monitoring. Telemetry –
modulation systems – choice of carrier frequency – single channel telemetry
systems.
Module 4
(12 hrs)
Instrumentation
for clinical laboratory: Bio electric amplifiers-instrumentation
amplifiers-isolation amplifiers-chopper stabilized amplifiers –input guarding -
Measurement of pH value of Blood-blood cell counting, blood flow, Respiratory
transducers and instruments.
Module 5
(12hrs)
Medical Imaging: Computer tomography – basic
principle, application –advantage, X ray tubes, collimators, detectors and
display - Ultra sound imaging
References
1.
J J
Carr, “Introduction to
Biomedical Equipment Technology” :
Pearson Education 4th e/d.
2. K S
Kandpur, “Hand book
of Biomedical instrumentation”, Tata
McGraw Hill 2nd
e/d.
3. John G
Webster, “Medical
Instrumentation application and
design”, John Wiley
3rd e/d.
4. Richard Aston, “Principle of
Biomedical Instrumentation and
Measurement”.
EC010 606
L05 SOFT COMPUTING
Teaching scheme Credits: 4
3 hour lecture
and 1 hour
tutorial per week.
Objectives
•
To develop
basic knowledge about
neuron and neural
networks.
•
To develop
basic knowledge about
fuzzy stems.
•
To be able
to understand basic concepts of soft computing frame work and neuro
fuzzysystems
Module 1
(12 hrs)
Introduction- artificial neuron - activation
functions - Single layer & multi-layer networks - Training artificial
neural networks - Perception - Representation - Linear separability - Learning
- Training algorithms.
Module 2
(12 hrs)
Back Propagation - Training algorithm -
Applications - network configurations - Local minima -. Hopfield nets -
Recurrent networks - Adaptive resonance theory - Architecture classification -
Implementation
Module 3
(12 hrs)
Introduction to Fuzzy sets
and systems: Fuzzy operations-support of a fuzzy set, height - normalised fuzzy
set, α – cuts- The law of the excluded middle and law of
contradiction on fuzzy sets. Properties of fuzzy set operations.
Module 4
(12 hrs)
Operations on fuzzy relations - projection,
max-min. and min and max-compositions. Fuzzy membership functions- Fuzzy logic
controller: fuzzification - Rule base – Defuzzififaction-case study for
engineering applications.
Module 5
(12hrs)
Soft
computing frame work – comparisons- evolutionary algorithm/Genetic Algorithm:
basic structure – Neuro fuzzy controller – Applications – case study.
Reference
1.
C.T lin
& C S George Lee, Neural
Fuzzy Systems, Prentice Hall
of India, 1996
2.
Lawrence
Fausset, Fundamentals of Neural
Networks, Prentice Hall
3.
Timmoty J. Rose, Fuzzy Logics
& Applications,
Willey publications, 2010
4.
Bart Kosko. Fuzzy Engineering, Prentice Hall.
5.
A.R.Alive,
Soft Computing &
its applications
6.
Fakhreddine
O, Karray Clarence W De Silva, Soft Computing and Intelligent Systems Design:
Theory, Tools and Applications, Pearson India
7.
Christina
Ray, Artificial neural networks, Tata Mc.Graw Hill, 1997
8.
J.S.R.Jang,
C.T. Sun and E.Mizutani, Neuro-Fuzzy and Soft Computing, Prentice hall
of India, 2004,
EC010
606L06– TELEVISION AND
RADAR ENGINEERING
Teaching
Scheme:
3 hours
lecture and 1
hour tutorial. Credit
4
Objective
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To familiarise the
students with the
fundamentals of TV
Engineering and its
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applications
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•
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T
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o familiarise
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the
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students with
the fundamentals of
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Radar
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Engineering
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and
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its
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applications
Module 1 (12
hrs)
Principles of television - image continuity -
interlaced scanning - blanking - synchronizing – composite video signal - video
and sound signal modulation - channel bandwidth - vestigial sideband
transmission – television signal propagation
Television
receiver circuits – IF section, video detector-video amplifiers-AGC,Sync
processing and AFC-Horizontal and vertical deflection circuits –sound
section-tuner .
Module 2 (12
hrs)
Colour
TV - Colour perception - luminance, hue and saturation - colour TV camera and
picture tube(working principle only) - colour signal transmission - bandwidth -
modulation - formation of chrominance signal - principles of NTSC, PAL and
SECAM coder and decoder.
Module 3(12 hrs)
Digital TV - composite digital standards - 4 f sc
NTSC standard - general specifications - sampling structure - digital
transmission, Flat panel display TV receivers-LCD and Plasma screen
receivers-3DTV-EDTV.
Cable TV - cable frequencies - co-axial cable for
CATV - cable distribution system - cable decoders - wave traps and scrambling
methods, Satellite TV technology-Geo Stationary Satellites-Satellite
Electronics
Module
4(12hrs)
Introduction- Radar Equation- Block diagram- Radar
frequencies- Applications- Prediction of range performance –Pulse Repetition
Frequency and Range ambiguities –Antenna parameters- System losses.
CW Radar-The Doppler Effect- FM-CW radar- Multiple
frequency radar – MTI Radar-Principle- Delay line cancellors- Noncoherent
MTI-Pulse Doppler Radar- Tacking Radar – Sequential lobing-Conical Scan-
Monopulse – Acquisition- Comparison of Trackers.
Module 5(12 hrs)
Radar
Transmitters- Modulators-Solid state transmitters, Radar Antennas-
Parabolic-Scanning feed-Lens- Radomes, Electronically steered phased array
antenna-Applications, Receivers-Displays-Duplexers.
Special
purpose radars-Synthetic aperture radar- HF and over the horizon radar- Air
surveillance radar- Height finder and 3D radars – Bistatic radar-Radar Beacons-
Radar Jamming and Electronic Counters .
References:-
1.
Gulati R.R., Modern Television
Engineering, Wiley Eastern Ltd.
2.
Dhake A.M., Television Engineering, Tata McGraw Hill, 2001 .
3.
R.P.Bali, “Color Television,
Theory and Practice”, Tata
McGraw-Hill, 1994
4. R.G Gupta., “ Television Engineering
and Video System”,
Tata McGraw-Hill, 2005
5.
Bernard
Grob & Charles E. Herndon, “Basic Television and Video Systems”,
McGraw Hill International
6.
Damacher P., “Digital Broadcasting”, IEE Telecommunications Series
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7.
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Merrill I. Skolnik, “Introduction to
Radar Systems”– 3rd Edition, McGraw Hill, 2001.
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rd
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8.
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Merril I.Skolnik , “Radar Handbook”-, 3
Edition, McGraw Hill
Publishers,2008.
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9.
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J. C.
Toomay, Paul Hannen,
“Radar Principles for
the Non-Specialist”, Printice
hall
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of India,2004
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EC010
607 MICROPROCESSOR &
MICROCONTROLLER LAB
Teaching
scheme Credits: 2
3
hours practical per
week.
Objectives:-
•
To provide
experience on programming
and testing of
few electronic circuits
using 8086
•
. To provide experience on programming and
testing of few electronic circuits using 8051simulator.
•
To understand
basic interfacing concepts
between trainer kit
and personal computers.
A. Programming
experiments using 8086
(MASM)
1. Sum of
N Numbers.
2. Display message
on screen using
code and data
segment.
3. Sorting, factorial
of a number
4. Addition /Subtraction
of 32 bit
numbers.
5. Concatenation of
two strings.
6. Square, Square
root, & Fibonacci
series.
B. Programming
experiments using 8051
simulator (KEIL).
1. Addition and
subtraction.
2. Multiplication and
division.
3. Sorting, Factorial
of a number.
4. Multiplication by
shift and add
method.
5. Matrix addition.
6. Square, Square
root, & Fibonacci
series.
C.
Interface experiments using Trainer kit / Direct down loading the programs from
Personal computer.
1. ADC /
DAC interface.
2. Stepper motor
interface.
3. Display (LED,
Seven segments, LCD)
interface.
4. Frequency measurement.
5. Wave form
generation.
6. Relay interface.
EC 010 608 MINI PROJECT LAB
Teaching Scheme
3 hours
practical per week. 2 credits
The
mini project will involve the design, construction, and debugging of an
electronic system approved by the department. There will be several projects
such as intercom, SMPS, burglar alarm, UPS, inverter, voting machine etc. The
schematic and PCB design should be done using any of the standard schematic
capture & PCB design software. Each student may choose to buy, for his
convenience, his own components and accessories. Each student must keep a
project notebook. The notebooks will be checked periodically throughout the
semester, as part of the project grade.
In addition
to this, the
following laboratory experiments
should also be
done in the
lab.
1.
555 applications
2.
Light activated
alarm circuit
3.
Speed control
of electric fan
using TRIAC
4.
Illumination control
circuits
5.
Touch control
circuits
6.
Sound operated
circuits
7.
Relay driver
circuit using driver
IC
8.
Interfacing using
Opto coupler
9.
Schematic capture
software (OrCAD or
similar) familiarization.
10. PCB design
software (OrCAD Layout
or similar) familiarization.
A
demonstration and oral examination on the mini project also
should be done at the end of the semester. The university examination will
consist of two parts. One of the lab experiments will be given for examination
to be completed within 60 to 90 minutes with a maximum of 30% marks. 70% marks
will be allotted for the demonstration and viva voce on the mini project.
