Course
Structure and Syllabus for BTech in Electronics and
Electrical Engineering (to
be applicable from 2010 batch onwards) |
||||||||||||
Course No. |
Course Name |
L |
T |
P |
C |
|
Course No. |
Course Name |
L |
T |
P |
C |
Semester - 1 |
|
Semester -2 |
||||||||||
CH101 |
Chemistry |
3 |
1 |
0 |
8 |
|
BT101 |
Modern
Biology |
3 |
0 |
0 |
6 |
CH110 |
Chemistry
Laboratory |
0 |
0 |
3 |
3 |
|
CS
101 |
Introduction
to Computing |
3 |
0 |
0 |
6 |
EE101 |
Electrical
Sciences |
3 |
1 |
0 |
8 |
|
CS110 |
Computing
Laboratory |
0 |
0 |
3 |
3 |
MA101 |
Mathematics
- I |
3 |
1 |
0 |
8 |
|
EE102 |
Basic
Electronics Laboratory |
0 |
0 |
3 |
3 |
ME110/ PH 110 |
Workshop
/Physics Laboratory |
0 |
0 |
3 |
3 |
|
MA102 |
Mathematics
- II |
3 |
1 |
0 |
8 |
ME
111** |
Engineering
Drawing |
0 |
0 |
3 |
3 |
|
ME101 |
Engineering
Mechanics |
3 |
1 |
0 |
8 |
PH101 |
Physics
- I |
2 |
1 |
0 |
6 |
|
PH102 |
Physics
- II |
2 |
1 |
0 |
6 |
SA
101 |
Physical
Training -I |
0 |
0 |
2 |
0 |
|
PH
110/ ME
110 |
Physics
Laboratory/Workshop |
0 |
0 |
3 |
3 |
NCC/NSO/NSS |
0 |
0 |
2 |
0 |
|
SA
102 |
Physical
Training -II |
0 |
0 |
2 |
0 |
|
11 |
4 |
9 |
39 |
|
|
NCC/NSO/NSS |
0 |
0 |
2 |
0 |
||
** For 2010 batch the credit structure is 0-0-3-3 |
|
|
|
14 |
3 |
9 |
43 |
|||||
Semester 3 |
|
Semester 4 |
||||||||||
MA201 |
Mathematics
- III |
3 |
1 |
0 |
8 |
|
EE203 |
Analog
Integrated Circuits |
3 |
0 |
0 |
6 |
EE200 |
Semiconductor
Devices and Circuits |
3 |
0 |
0 |
6 |
|
EE221 |
Probability
and Random Processes |
3 |
1 |
0 |
8 |
EE201 |
Digital
Circuits and Microprocessors |
3 |
0 |
0 |
6 |
|
EE230 |
Principles
of Communication |
3 |
1 |
0 |
8 |
EE220 |
Signals,
Systems and Networks |
3 |
1 |
0 |
8 |
|
EE270 |
Measurement
and Instrumentation |
3 |
0 |
0 |
6 |
HS2xx |
HSS
Elective - I |
3 |
0 |
0 |
6 |
|
HS2xx |
HSS
Elective - II |
3 |
0 |
0 |
6 |
EE202 |
Digital
Circuits Laboratory |
0 |
0 |
3 |
3 |
|
EE
204 |
Analog
Circuits Laboratory |
0 |
0 |
3 |
3 |
SA201 |
Physical
Training - III |
0 |
0 |
2 |
0 |
|
SA
202 |
Physical
Training - IV |
0 |
0 |
2 |
0 |
NCC/NSO/NSS |
0 |
0 |
2 |
0 |
|
|
NCC/NSO/NSS |
0 |
0 |
2 |
0 |
|
15 |
2 |
3 |
37 |
|
|
|
15 |
2 |
3 |
37 |
||
Semester 5 |
|
Semester 6 |
||||||||||
EE320 |
Digital
Signal Processing |
3 |
0 |
0 |
6 |
|
EE340 |
Electromagnetic
Theory |
3 |
0 |
0 |
6 |
EE350 |
Control
Systems |
3 |
0 |
0 |
6 |
|
EE351 |
Advanced
Control Systems |
3 |
0 |
0 |
6 |
EE380 |
Electrical
Machines |
3 |
0 |
0 |
6 |
|
EE360 |
Embedded Systems |
3 |
0 |
0 |
6 |
EE382 |
Electrical
Power Systems |
3 |
0 |
0 |
6 |
|
EE385 |
Power
Electronics and Drives |
3 |
0 |
0 |
6 |
HS3xx |
HSS
Elective - III |
3 |
0 |
0 |
6 |
|
XXxxx |
Open
Elective - I |
3 |
0 |
0 |
6 |
EE331 |
Communication
Laboratory |
0 |
0 |
3 |
3 |
|
EE304 |
Design
Laboratory |
0 |
0 |
3 |
3 |
EE381 |
Electrical
Machines Laboratory |
0 |
0 |
3 |
3 |
|
EE371 |
Control
and Instrumentation Lab |
0 |
0 |
3 |
3 |
15 |
0 |
6 |
36 |
|
|
|
15 |
0 |
6 |
36 |
||
Semester 7 |
|
Semester 8 |
||||||||||
EE480 |
Electrical
Power Systems Operation and
Control |
3 |
0 |
0 |
6 |
|
EExxx |
Dept.
Elective -III |
3 |
0 |
0 |
6 |
EExxx |
Dept.
Elective - I |
3 |
0 |
0 |
6 |
|
EExxx |
Dept.
Elective - IV |
3 |
0 |
0 |
6 |
EExxx |
Dept.
Elective - II |
3 |
0 |
0 |
6 |
|
EExxx |
Dept.
Elective - V |
3 |
0 |
0 |
6 |
XXxxx |
Open
Elective - II |
3 |
0 |
0 |
6 |
|
HS4xx |
HSS
Elective - IV |
3 |
0 |
0 |
6 |
EE482 |
Advanced
Electrical Engineering Laboratory |
0 |
0 |
3 |
3 |
|
XXxx |
Open
Elective - III |
3 |
0 |
0 |
6 |
EE498 |
Project
- I |
0 |
0 |
6 |
6 |
|
EE499 |
Project
- II |
0 |
0 |
6 |
6 |
12 |
0 |
9 |
33 |
|
|
|
15 |
0 |
6 |
36 |
CH 101 Chemistry (3-1-0-8) Structure
and Bonding; Origin of quantum theory, postulates of quantum mechanics; Schrodinger
wave equation: operators and observables, superposition theorem and
expectation values, solutions for particle in a box, harmonic oscillator,
rigid rotator, hydrogen atom; Selection rules of microwave and vibrational spectroscopy; Spectroscopic term symbol;
Molecular orbitals: LCAO-MO; Huckel
theory of conjugated systems; Rotational, vibrational
and electronic spectroscopy; Chemical Thermodynamics: The zeroth
and first law, Work, heat, energy and enthalpies; The relation between Cv and Cp; Second law:
entropy, free energy (the Helmholtz and Gibbs) and chemical potential; Third
law; Chemical equilibrium; Chemical kinetics: The rate of reaction,
elementary reaction and chain reaction; Surface: The properties of liquid
surface, surfactants, colloidal systems, solid surfaces, physisorption
and chemisorption; The periodic table of elements;
Shapes of inorganic compounds; Chemistry of materials; Coordination
compounds: ligand, nomenclature, isomerism,
stereochemistry, valence bond, crystal field and molecular orbital theories;
Bioinorganic chemistry and organometallic
chemistry; Stereo and regio-chemistry of organic
compounds, conformers; Pericyclic reactions;
Organic photochemistry; Bioorganic chemistry: Amino acids, peptides,
proteins, enzymes, carbohydrates, nucleic acids and lipids; Macromolecules
(polymers); Modern techniques in structural elucidation of compounds (UV-vis, IR, NMR); Solid phase synthesis and combinatorial
chemistry; Green chemical processes. Texts:
1. P. W. Atkins, Physical Chemistry, 5th Ed., ELBS, 1994. 2. C.
N. Banwell, and E. M. McCash,
Fundamentals of Molecular Spectroscopy,
4th Ed., Tata McGraw-Hill, 1962. 3. F.
A. Cotton, and G. Wilkinson, Advanced
Inorganic Chemistry, 3rd Ed., Wiley Eastern Ltd., New Delhi, 1972,
reprint in 1988. 4. D. J. Shriver, P. W. Atkins, and C. H.
Langford, Inorganic Chemistry, 2nd
Ed., ELBS ,1994. 5. S. H. Pine, Organic Chemistry, McGraw-Hill, 5th Ed., 1987 References: 1. I. A. Levine, Physical Chemistry, 4th Ed., McGraw-Hill, 1995. 2. I. A. Levine, Quantum Chemistry, EE Ed., prentice Hall, 1994. 3. G. M. Barrow, Introduction to Molecular Spectroscopy, International Edition,
McGraw-Hill, 1962 4. J.
E. Huheey, E. A. Keiter
and R. L. Keiter, Inorganic Chemistry: Principle, structure and reactivity, 4th
Ed., Harper Collins, 1993 5. L. G. Wade (Jr.), Organic Chemistry, Prentice Hall, 1987. |
CS 101
Introduction to Computing (3-0-0-6)
Introduction:
The von Neumann architecture, machine language, assembly language, high level
programming languages, compiler, interpreter, loader, linker, text editors,
operating systems, flowchart; Basic features of programming (Using C): data
types, variables, operators,
expressions, statements, control structures, functions; Advanced
programming features: arrays and pointers, recursion, records (structures),
memory management, files, input/output, standard library functions,
programming tools, testing and debugging; Fundamental operations on data:
insert, delete, search, traverse and modify; Fundamental data structures:
arrays, stacks, queues, linked lists; Searching and sorting: linear search,
binary search, insertion-sort, bubble-sort, selection-sort, radix-sort,
counting-sort; Introduction to object-oriented programming Texts:
1. A Kelly and I Pohl, A Book on C, 4th Ed.,
Pearson Education, 1999. 2. A M Tenenbaum,
Y Langsam and M J Augenstein,
Data Structures Using C, Prentice
Hall India, 1996. References: 1.
H Schildt, C:
The Complete Reference, 4th Ed., Tata Mcgraw
Hill, 2000 2. B Kernighan and
D Ritchie, The C Programming Language,
4th Ed., Prentice Hall of India, 1988. |
CS 110 Computing
Laboratory (0-0-3-3)
Programming
Laboratory will be set in consonance with the material covered in CS101. This
will include assignments in a programming language like C. References: 1.
B. Gottfried and J. Chhabra, Programming With C,
Tata Mcgraw Hill, 2005 MA
102 Mathematics
- II (3-1-0-8) Vector
functions of one variable – continuity and differentiability; functions
of several variables – continuity, partial derivatives, directional
derivatives, gradient, differentiability, chain rule; tangent planes and normals, maxima and minima, Lagrange multiplier method;
repeated and multiple integrals with applications to volume, surface area,
moments of inertia, change of variables; vector fields, line and surface
integrals; Green’s, Gauss’ and Stokes’ theorems and their
applications. First
order differential equations – exact differential equations,
integrating factors, Bernoulli equations, existence and uniqueness theorem,
applications; higher-order linear differential equations – solutions of
homogeneous and nonhomogeneous equations, method of
variation of parameters, operator method; series solutions of linear
differential equations, Legendre equation and Legendre polynomials, Bessel
equation and Bessel functions of first and second kinds; systems of
first-order equations, phase plane, critical points, stability. Texts: 1.
G. B. Thomas (Jr.) and R. L. Finney, Calculus and Analytic Geometry, 9th
Ed., Pearson Education India, 1996. 2.
S. L. Ross, Differential Equations, 3rd Ed., Wiley India,
1984. References: 1. T.
M. Apostol, Calculus
- Vol.2, 2nd Ed., Wiley India, 2003. 2. W.
E. Boyce and R. C. DiPrima, Elementary Differential Equations and Boundary Value Problems, 9th
Ed., Wiley India, 2009. 3. E.
A. Coddington, An Introduction to Ordinary Differential Equations, Prentice Hall
India, 1995. 4. E.
L. Ince, Ordinary
Differential Equations, Dover Publications, 1958. ME
101 Engineering
Mechanics (3-1-0-8) Basic principles:
Equivalent force system; Equations of equilibrium; Free body diagram;
Reaction; Static indeterminacy. Structures: Difference between trusses,
frames and beams, Assumptions followed in the analysis of structures; 2D
truss; Method of joints; Method of section; Frame; Simple beam; types of loading and supports; Shear Force and bending Moment diagram
in beams; Relation among load, shear force and bending moment. Friction: Dry
friction; Description and applications of friction in wedges, thrust bearing
(disk friction), belt, screw, journal bearing (Axle friction); Rolling
resistance. Virtual work and Energy method: Virtual Displacement; Principle
of virtual work; Applications of virtual work principle to machines;
Mechanical efficiency; Work of a force/couple (springs etc.); Potential
energy and equilibrium; stability. Center of Gravity and Moment of Inertia:
First and second moment of area; Radius of gyration; Parallel axis theorem; Product of inertia, Rotation of axes
and principal moment of inertia;
Moment of inertia of simple and composite bodies. Mass moment of
inertia. Kinematics of Particles: Rectilinear motion; Curvilinear motion; Use
of Cartesian, polar and spherical coordinate system; Relative and constrained
motion; Space curvilinear motion. Kinetics of Particles: Force, mass and
acceleration; Work and energy; Impulse and momentum; Impact problems; System
of particles. Kinematics and Kinetics of Rigid Bodies: Translation; Fixed
axis rotational; General plane
motion; Coriolis acceleration; Work-energy; Power; Potential energy; Impulse-momentum and associated
conservation principles; Euler
equations of motion and its application. Texts 1. I. H. Shames, Engineering Mechanics:
Statics and Dynamics, 4th Ed., PHI, 2002. 2.
F. P. Beer and E. R. Johnston, Vector Mechanics for Engineers, Vol I - Statics, Vol
II – Dynamics, 3rd Ed., Tata McGraw Hill, 2000. References 1. J.
L. Meriam and L. G. Kraige,
Engineering Mechanics, Vol I –
Statics, Vol II – Dynamics, 5th
Ed., John Wiley, 2002. 2. R. C. Hibbler,
Engineering Mechanics, Vols. I
and II, Pearson Press, 2002. PH 102 Physics
- II
(2-1-0-6) Vector Calculus: Gradient, Divergence and
Curl, Line, Surface, and Volume integrals, Gauss's divergence theorem and
Stokes' theorem in Cartesian, Spherical polar, and
Cylindrical polar coordinates, Dirac Delta function. Electrostatics: Gauss's law and its
applications, Divergence and Curl of Electrostatic fields, Electrostatic
Potential, Boundary conditions, Work and Energy, Conductors, Capacitors,
Laplace's equation, Method of images, Boundary value problems in Cartesian
Coordinate Systems, Dielectrics, Polarization, Bound Charges, Electric
displacement, Boundary conditions in dielectrics, Energy in dielectrics,
Forces on dielectrics. Magnetostatics: Lorentz force, Biot-Savart and Ampere's laws and their applications,
Divergence and Curl of Magnetostatic fields, Magnetic
vector Potential, Force and torque on a magnetic dipole, Magnetic materials,
Magnetization, Bound currents, Boundary conditions. Electrodynamics: Ohm's law, Motional EMF,
Faraday's law, Lenz's law, Self and Mutual inductance, Energy stored in
magnetic field, Maxwell's equations, Continuity Equation, Poynting
Theorem, Wave solution of Maxwell Equations. Electromagnetic waves: Polarization, reflection
& transmission at oblique incidences. Texts:
References:
EE 102 Basic Electronics Laboratory (0-0-3-3) Experiments using diodes
and bipolar junction transistor (BJT): design and analysis of half -wave and
full-wave rectifiers, clipping circuits and Zener
regulators, BJT characteristics and BJT amplifiers; experiments using
operational amplifiers (op-amps): summing amplifier, comparator, precision
rectifier, astable and monostable
multivibrators and oscillators; experiments using
logic gates: combinational circuits such as staircase switch, majority
detector, equality detector, multiplexer and demultiplexer;
experiments using flip-flops: sequential circuits such as non-overlapping
pulse generator, ripple counter, synchronous counter, pulse counter and
numerical display.
3.
R.J. Tocci, Digital Systems, 6th Ed.,
2001. |
EE 200
Semiconductor Devices and Circuits
(3-0-0-6) Energy bands; semiconductors; charge
carriers: electrons and holes, effective mass, doping. Carrier concentration:
Fermi level, temperature dependence of carrier concentration. Drift and
diffusion of carriers: excess carriers; recombination and life time, Five
equations of carrier transport. p-n Junction:
depletion region, forward and reverse-bias, depletion and diffusion
capacitances, switching characteristics; breakdown mechanisms; SPICE model.
BJT: carrier distribution; current gain, transit time, secondary effects;
SPICE model. Metal-semiconductor junctions: rectifying and ohmic contacts. MOSFET: MOS capacitor; Cv-Iv characteristics; threshold voltage; SPICE model.
Single stage amplifiers: CE-CB-CC and CG-CD-CS modes of operation, large
signal transfer characteristics of BJT and MOSFET, Different types of biasing for BJT and
MOSFET, Small signal parameters, Body effect in MOSFET, Parasitic elements,
frequency response of CE and CS amplifiers. Analog ICs: DAC, ADC, VCO, PLL
and 555-timer. 1. R. F. Pierret, Semiconductor
Device Fundamentals, PHI, 2006 2. P. R. Gray, P.Hurst,
S.H. Lewis and R. G. Meyer, Analysis
and Design of Analog Integrated Circuit, John Wiley, 2001. References: 1. S. Sedra and K. C. Smith, Microelectronic Circuits, Oxford University Press, 1997. 2. M. S. Tyagi, Introduction
to Semiconductor Materials and Devices, John Wiley & Sons Inc, 1991. 3. M. Shur, Introduction
to Electronic Devices, John Wiley & Sons Inc., 2000 4. R. T. Howe and
C. G. Sodini, Microelectronics:
An Integrated Approach, Prentice-Hall Inc. 1997. 5. B. G. Streetman,
Solid State Electronic Devices, 5th
Ed., PHI, 2001. 6. J. Singh, Semiconductor Devices - Basic Principles,
John Wiley & Sons Inc., 2001 |
EE 201 Digital
Circuits And Microprocessors
(3-0-0-6) Digital logic families:
TTL, MOS, interfacing between logic families; Combinational circuits:
multiplexer/ demultiplexer, encoder/ decoder,
adder/ subtractor, comparator and parity
generators; Sequential circuits: latches and flip-flops (RS, JK, D, T, and
Master Slave); Registers; Counters: ripple, ring, and shift register
counters; Design and analysis of synchronous sequential finite state machine;
Programmable logic devices; Introduction to HDL. Microprocessors: 8085
addressing modes, memory interfacing, interrupts, instructions, timing
diagram; Introduction to 8086; Peripheral chips: I/Os, timer, interrupt
controller, USART, DMA.
Penram International Publishing (India), 2000.
Prentice-Hall, 1995. |
EE 220
Signals, Systems and Networks
(3-1-0-8) Signals: classification of signals;
signal operations: scaling, shifting and inversion; signal properties:
symmetry, periodicity and absolute integrability;
elementary signals. Systems: classification of systems; system properties:
linearity, time/shift-invariance, causality, stability; continuous-time
linear time invariant (LTI) and discrete-time linear shift invariant (LSI)
systems: impulse response and step response; response to an arbitrary input:
convolution; system representation using differential and difference
equations; Eigen functions of LTI/ LSI systems, frequency response and its
relation to the impulse response. Signal representation: signal space and
orthogonal bases; Fourier series representation of continuous-time and
discrete-time signals; continuous-time Fourier transform and its properties; Parseval's relation, time-bandwidth product; discrete-time
Fourier transform and its properties; relations among various Fourier
representations. Sampling: sampling theorem; aliasing; signal reconstruction:
ideal interpolator, zero-order hold, first-order hold; discrete Fourier
transform and its properties. Laplace transform and Z-transform: definition,
region of convergence, properties; transform-domain analysis of LTI/LSI
systems, system function: poles and zeros; stability. Review of network
theorems: superposition, Thevenin’s,
Norton’s, reciprocity, maximum power transfer, Millman’s
and compensation theorems; Network topology: definition of basic terms,
incidence matrix, tie-sets, cut-sets; Two port networks: characterization in
terms of impedance, admittance, transmission, hybrid parameters and their
relationships, interconnection of two port networks; Symmetrical two port
network: T and π equivalents, image impedance, characteristic impedance
and Propagation constant. Texts:
4th
Ed., Prentice Hall, 1998. |
EE 202
Digital
Circuits Laboratory
(0-0-3-3) Combinational Logic design using
decoders and multiplexers; design of arithmetic circuits using adder ICs;
Flip flop circuit (RS latch, JK & master slave) using basic gates; Asynchronous
Counters, Johnson & Ring counters; Synchronous counters; Sequential
Circuit designs (sequence detector circuit), DAC circuit; Assembly language
programming of 8085: a) sorting and code conversion, b) matrix
multiplication; 8085 interfacing: a) parallel port interface (square wave
generation), b) counter and timer interface (polling and using interrupts);
ADC/DAC interfacing with 8085.
8085,
Penram International Publishing (India), 2000. |
EE 203
Analog Integrated Circuits
(3-0-0-6) Frequency response of amplifiers: high
frequency device models, frequency response, GBW, methods of short circuit
and open circuit time constants, dominant pole approximation; Feedback
amplifiers: basic feedback topologies and their properties, analysis of
practical feedback amplifiers, stability; Power amplifiers: class A, B, AB,
C, D, E stages, output stages, short circuit protection, power transistors
and thermal design considerations; Differential amplifiers: DC and small
signal analysis, CMRR, current mirrors, active load and cascode
configurations, frequency response; case study: 741 op-amp – DC and small
signal analysis, frequency response, frequency compensation, GBW, phase
margin, slew rate, offsets; CMOS realizations: current source, sink and
mirrors, differential amplifiers, multistage amplifiers; Signal generation
and waveform shaping: sinusoidal oscillators- RC, LC, and crystal
oscillators, Schmitt trigger; Analog subsystems: analog switches, voltage
comparator, voltage regulator, switching regulator, bandgap
reference voltage source, analog multiplier, filter approximations:
Butterworth, Chebyshev and elliptic, first order
and second order passive/active filter realizations. Texts:
References:
|
EE 221
Probability and Random Processes
(3-1-0-8) Introduction to probability:
mathematical background - sets, set operations, sigma and Borel
fields; classical, relative-frequency and axiomatic definitions of
probability; conditional probability, independence, total probability, Bayes’ rule; repeated trials; random variables:
cumulative distribution function, continuous, discrete and mixed random
variables, probability mass function, probability density functions;
functions of a random variable; expectation - mean, variance and moments;
characteristic and moment-generating functions; Chebyshev,
Markov and Chernoff bounds; special random
variables-Bernoulli, binomial, Poisson, uniform, Gaussian and Rayleigh; joint
distribution and density functions; Bayes’
rule for continuous and mixed random variables; joint moments, conditional
expectation; covariance and correlation- independent, uncorrelated and
orthogonal random variables; function of two random variables; sum of two
independent random variables; random vector- mean vector and covariance
matrix, multivariate Gaussian distribution; sequence of random variables:
almost sure and mean-square convergences, convergences in probability and in
distribution, laws of large numbers, central limit theorem; elements of
estimation theory- linear minimum mean-square error and orthogonality
principle; random process: discrete and continuous time processes;
probabilistic structure of a random process; mean, autocorrelation and autocovariance functions; stationarity-
strict-sense stationary and wide-sense stationary (WSS) processes:
autocorrelation and cross-correlation functions; time averages and ergodicity; spectral representation of a real WSS
process-power spectral density, cross-power spectral density, linear
time-invariant systems with WSS process as an input- time and frequency
domain analyses; spectral factorization theorem; examples of random
processes: white noise, Gaussian, Poisson and Markov processes. Texts: 1.
A. Papoulis and S.U. Pillai, Probability Random Variables and Stochastic Processes, 4th
Ed.,
McGraw-Hill, 2002. 2. A. L. Garcia, Probability and Random Processes for Electrical Engineering, 2nd
Ed., Addison-Wesley, 1993. References:
2000.
Processing,
Prentice Hall, 2002.
Introduction to Mathematical Finance, 4th Ed., Springer-Verlag, 2003. |
EE 230
Principles of Communication
(3-1-0-8) Basic blocks in a communication
system: transmitter, channel and receiver; baseband and passband
signals and their representations; concept of modulation and demodulation.
Continuous wave (CW) modulation: amplitude modulation (AM) - double sideband
(DSB), double sideband suppressed carrier (DSBSC), single sideband suppressed
carrier (SSBSC) and vestigial sideband (VSB) modulation; angle modulation -
phase modulation (PM) & frequency modulation (FM); narrow and wideband
FM. Pulse Modulation: sampling process; pulse amplitude modulation (PAM);
pulse width modulation (PWM); pulse position modulation (PPM) ; pulse code
modulation (PCM); line coding; differential pulse code modulation; delta
modulation; adaptive delta modulation. Noise in CW and pulse modulation
systems: Receiver model; signal to noise ratio (SNR); noise figure; noise
temperature; noise in DSB-SC, SSB, AM & FM receivers; pre-emphasis and
de-emphasis, noise consideration in PAM and PCM systems. Basic digital
modulation schemes: Phase shift keying (PSK), amplitude shift keying (ASK),
frequency shift keying (FSK) and Quadrature
amplitude modulation (QAM); coherent demodulation and detection; probability
of error in PSK, ASK, FSK & QAM schemes. Multiplexing schemes: frequency
division multiplexing
and time division multiplexing. Texts:
2002. 2. R. E. Ziemer
and W. H. Tranter, Principles of
Communications: Systems, Modulation,
and Noise, 5th Ed., John Wiley & Sons, 2001.
1998. |
EE
270
Measurement and Instrumentation
(3-0-0-6) Introduction
to instrumentation; Static characteristics of measuring devices; Error
analysis, standards and calibration; Dynamic characteristics of instrumentation
systems; Electromechanical indicating instruments – AC/DC current and
voltage meters, ohmmeter; Loading effect; Measurement of power and energy;
Instrument transformers; Measurement of resistance, inductance and
capacitance; AC/DC bridges; Transducers classification; Measurement of
non-electrical quantities – displacement, strain, temperature,
pressure, flow, and force; Signal conditioning; Instrumentation amplifier,
isolation amplifier, and other special purpose amplifiers; Electromagnetic compatibility;
Shielding and grounding; Signal recovery; Data transmission and telemetry;
Data acquisition system; Modern electronic test equipment –
oscilloscope, DMM, frequency counter, wave/ network/ harmonic distortion/
spectrum analyzers, logic probe and logic analyzer; programmable logic
controller; Virtual instrumentation. Texts: 1. E. O. Deobelin, Measurement Systems – Application and Design, Tata McGraw-Hill, 2004. 2. M. M. S. Anand,
Electronic Instruments and Instrumentation Technology, Prentice-Hall
of India, 2006. 3. A. D. Helfrick
and W. D. Cooper, Modern Electronic Instrumentation and Measuring
Techniques, Pearson Education, 2008. References:
1. R. A. Witte, Electronic Test Instruments, Pearson Education, 2002. 2.
B. E. Jones, Instrumentation, Measurement, and Feedback, Tata
McGraw-Hill, 2000. 3.
R. P. Areny and T. G. Webster, Sensors and
Signal Conditioning, Wiley-Interscience, 2000. 4.
C. F. Coombs, Electronic Instruments Handbook, McGraw-Hill,
2000.
2003. |
EE 204
Analog Circuits Laboratory
(0-0-3-3) Experiments using BJTs, FETs, op-amps
and other integrated circuits: Multistage amplifiers, automatic gain controlled
amplifiers, programmable gain amplifiers; frequency response of amplifiers;
voltage regulator with short circuit protection; phase locked loop; waveform
generators; filters.
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EE 320 Digital
Signal Processing (3-0-0-6)
Review of discrete time signals,
systems and transforms: Discrete time signals, systems and their
classification, analysis of discrete time LTI systems: impulse response,
difference equation, frequency response, transfer
function, DTFT, DTFS and Z-transform. Frequency selective filters: Ideal
filter characteristics, lowpass, highpass, bandpass and bandstop filters, Paley-Wiener criterion, digital
resonators, notch filters, comb filters, all-pass filters, inverse systems,
minimum phase, maximum phase and mixed phase systems. Structures for
discrete-time systems: Signal flow graph representation, basic structures for
FIR and IIR systems (direct, parallel, cascade and polyphase
forms), transposition theorem, ladder and lattice structures. Design of FIR
and IIR filters: Design of FIR filters using windows, frequency sampling, Remez algorithm and least mean square error methods;
Design of IIR filters using impulse invariance, bilinear transformation and
frequency transformations. Discrete Fourier Transform (DFT): Computational
problem, DFT relations, DFT properties, fast Fourier transform (FFT)
algorithms (radix-2, decimation-in-time, decimation-in-frequency), Goertzel algorithm, linear convolution using DFT. Finite wordlength effects in digital filters: Fixed and floating
point representation of numbers, quantization noise in signal
representations, finite wordlength effects in
coefficient representation, roundoff noise, SQNR computation
and limit cycle. Introduction to multirate signal
processing: Decimation, interpolation, polyphase
decomposition; digital filter banks: Nyquist
filters, two channel quadrature mirror filter bank
and perfect reconstruction filter banks, subband
coding. Texts:
2004.
Applications,
4th Ed., Pearson Education, 2007. References:
2006.
India, 2005.
2003. |
EE 350
Control Systems
(3-0-0-6) Modeling of physical systems:
time-domain, frequency-domain and state-variable models; block diagram,
signal flow graph and Mason’s gain formula; time and frequency response
of first and second order systems; control system characteristics: stability,
sensitivity, disturbance rejection and steady-state accuracy; stability
analysis: Routh-Hurwitz test, relative stability,
root locus, Bode and Nyquist plots; controller
types: lag, lead, lag-lead, PID and variants of PID; controller design based
on root-locus and frequency response plots; modern design techniques:
canonical state-variable models, equivalence between frequency and
time-domain representations, diagonalisation,
controllability and observability, pole placement
by state feedback, state feedback with integral control, observer and
observer based state feedback control.
References:
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EE 380 Electrical
Machines
(3-0-0-6) Magnetic circuits and transformer
including 3-phase transformers; modeling of D.C. machines; phasor diagram of cylindrical rotor and salient pole
machines- electromagnetic and reluctance torque, response under short circuit
conditions; modeling of induction machines- derivation of equivalent
circuits, dynamics under load change, speed reversal and braking, unbalanced and asymmetrical
operation; single phase induction motor and applications in domestic appliances;
modeling of synchronous machines – equivalent circuit, d-q
transformations, short circuit studies in synchronous machines; variable
reluctance, permanent magnet, stepper motors and their applications.
Press, 2003. |
EE 382
Electrical Power Systems
(3-0-0-6) Generation of electrical energy: Basic
structure of power system; demand of electrical system – base load,
peak load; controlling power balance between generator and load, advantages
of interconnected system; Thermal power plant – general layout,
turbines, alternators, excitation system, governing system, efficiency; Hydel power plant – typical layout, turbines,
alternators; Nuclear power plant – principle of energy conversion,
types of nuclear reactors; brief overview of renewable energy sources.
Transmission of electrical energy: Evaluation of Transmission line
parameters- types of conductors, representation of transmission line,
inductance calculation of single/three phase lines, concept of GMD and GMR,
transposition of lines, bundled conductors, skin effect, proximity effect,
capacitance calculation of single/three phase lines, effect of earth on
calculation of capacitance, line resistance, line conductance; Analysis of
transmission lines – representation, short/ medium/long transmission
lines, nominal T/π network, ABCD parameters, surge impedance, Ferranti
effect, power flow through a transmission line, reactive power compensation
of transmission line; corona loss; Insulators for overhead transmission lines
– types of insulators, string efficiency, methods to improve string
efficiency; Insulated cables – insulating material, grading of
cables, capacitance of single/three core cable, dielectric loss; methods of
grounding; Transient analysis – travelling waves, reflection and
refraction, lattice diagram; mechanical design of transmission line. Distribution
of Electrical Energy: D.C and A.C. distribution, radial and ring main
distribution, medium voltage distribution network, low voltage distribution
network, single line diagram, substation layout, substation equipments. Texts:
References:
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EE 331
Communication Laboratory
(0-0-3-3) Amplitude modulation and
demodulation (AM with carrier & DSBSC AM); frequency modulation and
demodulation (using VCO & PLL); automatic gain control (AGC); pulse width
modulation (PWM); pulse code modulation (PCM); pseudo-random (PN) sequence
generation; binary phase shift keying (BPSK); binary frequency shift keying
(BFSK). Texts/References:
Pearson, 2003. |
EE 381
Electrical Machines Laboratory
(0-0-3-3) Open circuit and short circuit tests
of single phase transformer, three phase transformer connections, open
circuit test and load characteristics of DC generator, speed control and
output characteristics of DC motor, no load, blocked rotor and load tests on
induction motor, open circuit and short circuit tests of an alternator. Texts/References: |
EE 340
Electromagnetic Theory
(3-0-0-6) Static fields:
Coulomb’s and Gauss’ laws for electrostatics, Poisson’s and
Laplace’s equations, Method of images and boundary value problems; Equation
of continuity, Kirchoff’s voltage and current
laws, Boundary conditions for current density; Biot-Savart’s
law, Gauss’s and Ampere’s laws for magnetostatics,
Magnetic vector potential; Magnetic dipoles, Magnetization and behavior of
magnetic materials. Maxwell’s equations: Faraday’s law of
electromagnetic induction, Maxwell’s discovery, Maxwell’s
equations and boundary conditions, Time-harmonic fields. Wave equation and
plane waves: Helmholtz wave equation, Solution to wave equations and plane
waves, Wave polarization, Poynting vector and power
flow in em fields. Plane waves at a media
interface: Plane wave in different media, Plane wave reflection from a media
interface, Plane wave reflection from a complex media interface.
Finite-difference time-domain method: 1-, 2- and 3-dimensional simulations,
Absorbing boundary conditions and perfectly matched layer, Applications.
Antennas & radiating systems: Radiation fundamentals, Antenna patterns
and parameters, Hertz dipole, Wire antennas, Loop antennas, Antenna arrays.
Method of moments: Introductory example from electrostatics, Basic steps of
the method of moments, Linear operator equation, Applications. Texts:
References:
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EE 351
Advanced Control Systems (3-0-0-6) Frequency response design: Design of
lag, lead, lag-lead and PID controllers, the Nyquist
criterion, analysis and design, relative stability and the Bode diagram,
closed-loop response, sensitivity, time delays; Root locus design:
construction of root loci, phase-lead and phase-lag design, PID controller
design; Modern design: controllability and observability,
state feedback with integral control, reduced order observer; Optimal control
design: Solution-time criterion, Control-area criterion, Performance indices,
Zero steady state step error systems; Modern control performance index:
Quadratic performance index, Ricatti equation;
Digital controllers: Use of z-transform for closed loop transient response,
stability analysis using bilinear transform and Jury method, deadbeat
control, Digital control design using state feedback; On-line identification
and control: On-line estimation of model and controller parameters. Texts:
References:
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EE 360
Embedded Systems
(3-0-0-6) Introduction: Introduction
to embedded systems with examples, embedded system design & modeling with
unified markup language (UML). ARM processor fundamentals: Introduction
to microprocessors and microcontrollers, 8-bit and 16- bit, von Neumann and
Harvard architectures, CISC and RISC architectures, open source core
(LEOX), ARM versions, ARM instruction set: programming model, assembly
language, Thumb instruction set, memory organization, data operations and
flow control. CPUs: Input/output mechanisms, isolated and memory mapped IO;
interrupts and real time operations, ARM interrupts vectors, priorities and
latency; supervisor modes, exceptions, traps, co-processors; cache memory and
memory management. Embedded Platforms: CPUs: bus protocols, system bus
configuration, USB and SPI buses, DMA, ARM bus; memory devices: memory device
configuration, ROM, RAM, DRAM; I/O devices: timers, counters, ADC & DAC, keyboards, displays and touch screens.
Processes and Operating Systems: multiple tasks and multiple processes;
process abstraction; context switching: cooperative multitasking, preemptive
multitasking, process and object-oriented design; operating systems and RTOS;
scheduling polices; inter-process communication. Networks: distributed
embedded architectures: networks abstractions, hardware and software
architectures; networks for embedded systems: I2C bus, CAN bus; examples.
Case studies: Inkjet printer, telephone exchange,
etc.
Texts:
References:
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EE 385
Power Electronics and Drives
(3-0-0-6) Power Semiconductor Devices: Diode,
BJT, MOSFET, SCR, Triac, GTO, IGBT, MCT and their
V-I characteristics, ratings, driver circuits, protection and cooling; AC-DC
Converters (Rectifiers): Diode rectifier, thyristor
based rectifier, effect of source inductance, single/three phase rectifiers,
semi/full rectifiers, power factor, harmonics; DC-AC Converters (Inverters):
Concept of switched mode inverters, PWM switching, voltage and frequency
control of single/ three phase inverters, harmonics reduction, other switching
schemes - square wave pulse switching, programmed harmonic elimination
switching, current regulated modulation switching - tolerance band control,
fixed frequency control; voltage source inverter (VSI), current source
inverter (CSI); DC-DC Converters (Chopper): Principle; buck, boost and
buck-boost converters; AC Voltage Controllers: Principle of ON-OFF control
and phase control, single/three phase controllers, PWM AC voltage controller,
cycloconverters; Electric drives: introduction and
classification. DC motor drives: speed-torque characteristics of shunt,
series, PMDC motors; dynamic models; speed and position control methods; AC
motor drives: d-q model of induction motor; constant flux speed control
structure; vector control model; vector control structure. Texts:
References:
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EE 304
Design Laboratory
(0-0-3-3) A student has to do an electronic hardware
mini-project in broad areas like communication, electronic systems design,
control and instrumentation, computer, power systems and signal processing.
The project involves laying down the specifications, design, prototyping and
testing. The project must have major hardware modules involving active
discrete components and integrated circuits. Texts/References:
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EE 371 Control and
Instrumentation Laboratory
(0-0-3-3) Development of circuits
for signal conditioning, signal recovery, telemetry; PC based
instrumentation; Computer controlled test systems; Experiments using modern
electronic test equipment, Programmable logic controller. Modeling of
physical systems, open-loop and closed-loop control of systems, design of
classical controllers, closed loop control of servo systems and regulatory
systems, state-feedback based design of modern controllers. Texts/References:
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EE 480 Electrical
Power Systems Operation and Control (3-0-0-6) Power system analysis: modeling of
power system components - integrated operation of power systems, load flow studies,
economic load dispatch, load frequency control, automatic generation control
(AGC), power system stability; Power system protection: Symmetrical
components, fault analysis, switchgear, fuses, circuit breakers and relays.
Economics of power supply systems: Economic choice of conductor size and
voltage level, maximum demand and diversity factor, tariffs, power factor
correction; Introduction to high voltage DC transmission (HVDC), flexible AC
transmission system (FACTS), supervisory control and data acquisition
(SCADA). Texts:
References:
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EE 482 Advanced Electrical
Engineering Laboratory
(0-0-3-3) Reactive power compensation,
synchronization of alternators, load angle characteristics of transmission
line, ABCD parameters of transmission lines, fault analysis based on
over-current and differential relays, design of simple inverters and voltage
controllers, speed control of electric drives. Texts/References:
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