Course Structure and Syllabus for
Engineering Physics (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 |
ME 110/ 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 |
|
PH202 |
Electromagnetics |
3 |
1 |
0 |
8 |
EE220 |
Signals,
Systems and Networks |
3 |
1 |
0 |
8 |
|
PH204 |
Quantum Mechanics |
3 |
1 |
0 |
8 |
PH201 |
Advanced
Classical Mechanics |
3 |
1 |
0 |
8 |
|
PH206 |
Analog
& Digital Electronics |
3 |
0 |
0 |
6 |
PH203 |
Semiconductor
Devices |
3 |
0 |
0 |
6 |
|
BT205 |
Biophysics |
2 |
1 |
0 |
6 |
PH205 |
Heat
& Thermodynamics |
2 |
1 |
0 |
6 |
|
HS2xx |
HSS
Elective - II |
3 |
0 |
0 |
6 |
HS2xx |
HSS
elective - I |
3 |
0 |
0 |
6 |
|
PH210 |
Electronics
Lab-I |
0 |
0 |
4 |
4 |
SA
201 |
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 |
|
17 |
4 |
0 |
42 |
|
|
|
14 |
3 |
4 |
38 |
||
Semester 5 |
|
Semester 6 |
||||||||||
PH301 |
Microprocessor
architecture and Programming |
3 |
0 |
0 |
6 |
|
PH302 |
Solid State Physics |
2 |
1 |
0 |
6 |
PH303 |
Atomic
and Molecular Spectroscopy |
3 |
0 |
0 |
6 |
|
PH304 |
Engineering
Optics |
3 |
0 |
0 |
6 |
PH305 |
Computational
Physics |
2 |
0 |
2 |
6 |
|
PH306 |
Nuclear
Science & Engineering |
3 |
0 |
0 |
6 |
PH307 |
Statistical
Mechanics |
2 |
1 |
0 |
6 |
|
PH308 |
Measurement
Techniques |
2 |
0 |
2 |
6 |
HS3xx |
HSS
Elective - III |
3 |
0 |
0 |
6 |
|
XXxxx |
Open
Elective - I |
3 |
0 |
0 |
6 |
PH311 |
Electronics
Lab-II |
0 |
0 |
6 |
6 |
|
PH320 |
General
Physics Lab |
0 |
0 |
6 |
6 |
13 |
1 |
8 |
36 |
|
|
|
13 |
1 |
8 |
36 |
||
Semester 7 |
|
Semester 8 |
||||||||||
PH413 |
Materials
Science & Engineering |
3 |
0 |
0 |
6 |
|
PH414 |
Nanoelectronics & Nanophotonics |
3 |
0 |
0 |
6 |
PH415 |
Lasers
& Photonics |
3 |
0 |
0 |
6 |
|
PH4XX |
Department
Elective - II |
3 |
0 |
0 |
6 |
PHxxx |
Department
Elective-I |
3 |
0 |
0 |
6 |
|
PH4XX |
Department
Elective - III |
3 |
0 |
0 |
6 |
XXxxx |
Open
Elective - II |
3 |
0 |
0 |
6 |
|
XX4XX |
Open
Elective - III |
3 |
0 |
0 |
6 |
PH417 |
Advanced
Physics Lab |
0 |
0 |
6 |
6 |
|
HS4XX |
HSS
Elective - IV |
3 |
0 |
0 |
6 |
PH498 |
Project
- I |
0 |
0 |
6 |
6 |
|
PH499 |
Project
- II |
0 |
0 |
6 |
6 |
12 |
0 |
12 |
36 |
|
|
|
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. |
PH 201 Advanced
Classical Mechanics (3-1-0-8) Generalized coordinates. Lagrangian
formulation of dynamical systems. D’Alemberts
Principle. calculus of variations; Principle of least action:
Hamilton’s principle, Symmetry and conservation theorems, Hamiltonian
Formulation, Legendre transformation, Poisson brackets; Two body central
force problem: conservation of angular momentum and energy, motion in
gravitational potential, equation for the orbit, stability of orbits;
Conserved quantities : angular momentum and Runge
Lenz Vector; Orthogonal transformation: rigid body
rotation about a fixed axis, moment of Inertia tensor, Eigen values and
principal axis transformations; Euler angles, Euler equations of a rigid
body, precession of heavy symmetrical top; Small oscillations: dynamical
matrix, normal modes. Continuum
mechanics: Transverse motion of a Taut String, the wave equation, boundary
conditions, waves on a finite string, three-dimensional wave equation, volume
and surface forces; Stress and Strain: the elastic moduli,
the stress tensor, the strain tensor for a solid; Relation Between Stress and
Strain: Hooke's law, the equation of motion for an elastic solid,
longitudinal and transverse waves in a solid; Fluids: description of the
motion, waves in a Fluid. Texts: 1.
N.C. Rana and P.S. Joag, Classical
Mechanics, Tata McGraw-Hill, New Delhi, 1991. 2.
H. Goldstein, Classical Mechanics, Narosa,
New Delhi, 1998. References: 1.
J. R. Taylor, Classical Mechanics, University Science Books, 2003. 2.
L.D. Landau and E.M. Lifshitz, The
Classical Theory of Fields, Elsevier, 2005. |
PH 203 Semiconductor
Devices (3-0-0-6) Energy bands in solids and Charge carriers. Semiconductors: Elemental and compound semiconductors,
intrinsic and extrinsic materials, Direct and indirect band-gap semiconductors ,Heavily doped semiconductors. Charge carrier in semiconductors: mobility , impurity band conduction, nonlinear
conductivity, excess carriers in semiconductors. Semiconductor Bloch equation,
transport properties. P-N junctions: fabrication, static and
dynamic behavior of p-n junction diodes, Junction breakdown in p-n junctions,
tunnel diode, Schottky diode. Bipolar Junction Transistor: fundamentals of BJT operation, BJT
fabrication, carrier distribution and terminal current, generalized biasing,
switches, frequency limitations of transistors. Field Effect Transistors: JFET, MOSFET. Metal Semiconductor junctions: Schottky effect, rectifying and Ohmic
contacts. Integrated circuits,
fabrication methods. Power
devices: p-n-p-n diode, Silicon controlled rectifiers. Optoelectronic Devices: photodiodes, light emitting diodes,
semiconductor lasers, photovoltaic cells. Texts:
References:
|
PH
205 Heat and Thermodynamics (2-1-0-6) Kinetic
theory and Transport phenomena: Equation of state of a perfect gas, Maxwell
velocity distribution, real gases and Vander Wall’s equation, Brownian
motion, mean free path, viscosity and thermal conductivity. Laws of
thermodynamics and applications: Review of thermodynamic systems, state
variables, intensive and extensive parameters, thermodynamic processes, Zeroth and first law of thermodynamics; State functions, internal energy and
enthalpy, Joule Thomson effect, Carnot process and entropy, second law of thermodynamics,
refrigerators and thermodynamic engines; Otto and diesel engines, TdS equations, Third law of thermodynamics; Thermodynamic potentials:
Entropy and internal energy as thermodynamic potentials, Legendre
transformation, Helmholtz and Gibbs potentials, enthalpy, grand potential,
transformation of variables Maxwell relations; Phase equilibria:
Gibb’s phase rule, Clausius-Clapeyron
equation, phase equilibrium and Maxwell construction, first order phase
transitions. Texts: 1.
W. Pauli, Thermodynamics and kinetic theory of gases, Dover Publications,
2010 2.
M. W. Zeemansky
and R. H. Dittman, Heat and thermodynamics, McGraw Hill, 1997 References: 1.
F. W. Sears
and G. L. Salinger, Thermodynamics, Kinetic Theory and
Statistical Thermodynamics,
Narosa, New Delhi, 1975. 2.
C. Kittel
and H. Kroemer, Thermal
Physics, W. H. Freeman & Co., 1980. 3.
F.
Mandl, Statistical Physics, John
Wiley, 1978. 4.
W. Greiner, L. Neise
and H. Stocker, Thermodynamics and
Statistical Mechanics, Springer,1995. |
PH 202 Electromagnetics (3-1-0-8) Electrostatics:
Green function, Dirichlet and Neumann boundary
conditions, Green function for the sphere. Laplace Equation: Separation of variables in spherical
and cylindrical coordinates and general solution (Legendre polynomials,
Spherical harmonics, Bessel function, etc.). Expansion of Green function in
spherical and cylindrical coordinates.
Multipole expansion. Dielectrics: Boundary value problem, Clausius Mossotti
equation. Electrostatic
energy. Anisotropy and susceptibility
tensor. Magnetism: Green function method for vector
potential,
Magnetic materials,
Boundary value problems. Magenetic field in conductors.Maxwell equations: Time varying fields,
conservation laws, Plane waves, propagation in nonconducting
and conducting media.
Reflection and refraction, Fresnel relations. Kramers-Kronig
relations. Gauge transformation and gauge conditions. Green function method for wave
equation. Retarded
potentials. Poynting
theorem – for harmonic fields – in dispersive medium. Transformation properties of the EM
field. Wave guides &
Cavities: Fields within a
conductor. Rectangular and
cylindrical geometries. Orthonormal modes.
Energy flow and attenuation.
Power loss and Q-value.
Schumann resonances.
Radiation: Oscillating
source. Electric dipole, magnetic
dipole, and electric quadrupole fields. Centre-fed linear antenna. Multipole
expansion and multipole radiation. Scattering of electromagnetic waves. Texts:
References:
|
PH 204 Quantum
Mechanics (3-1-0-8) Review
of wave mechanics: Young’s double slit, de Broglie relation, wave
packets, Schroedinger equation; Observable, eigen values and eigen
functions; Simple applications:
particle in a box; potential well; potential barrier, delta function
potential, linear harmonic oscillator; Matrix formulation: Dirac’s bra
and ket notation, matrix representation of vectors
and operators, expectation values; Angular momentum: spherical harmonics, L2 and Lz
operators, commutation relations, spin of electron; 3-dimensional problems:
Hydrogen atom, energy levels, wave function; Time independent perturbation:
non-degenerate and degenerate cases; applications to Zeeman effect. Texts: 1. E.
Merzbacher, Quantum
Mechanics, 3rd Ed., John Wiley & Sons, 1998. 2. S.
Gazierowicz,
Quantum Physics,, John Wiley, 2000 References: 1. P.
W. Mathews and K. Venkatesan, A
Textbook of Quantum Mechanics, Tata McGraw Hill, 1995. 2. J.J.
Sakurai, Modern Quantum Mechanics, Pearson
Education, 2002. 3. R.
Shankar, Principle of Quantum
Mechanics, 2nd Ed., Springer, 2008. 4. B.H.
Bransden and C.J. Joachain, Quantum Mechanics, 2nd
Ed., Pearson Education, 2007. |
PH 206 Analog
and Digital Electronics (3-0-0-6
) Physics
of junction devices; BJT/FET amplifiers; Feedback: effect of negative and
positive feedback, basic feedback topologies; Feedback amplifiers: sinusoidal
oscillators. different classes of power amplifiers; differential
amplifiers; Operational amplifiers: arithmetic circuits, active
filters, voltage controlled oscillators, A/D and D/A converters, sample
and hold circuits and other applications of Op-amps; SE/NE 555 timer IC, multivibrators.Review of number systems and their inter
conversion, logic gates and logic families; MOSFET as switch; CMOS
inverter; Combinational logic modules; flip-flops; registers; counters;
sequential circuits, decoders, encoders, multiplexers, demultiplexers
and their applications; comparators; Different types of semiconductor
memories and their architectures; Programmable logic devices. Texts: 1. A. S. Sedra
and K. C. Smith, Microelectronic
Circuits, Oxford University Press, 2008. 2.
R. A. Gaykwad, Op-Amps
and Linear Integrated Circuits, Prentice- Hall of India, 2002. 3.
D. P. Leach, A. P. Malvino and G Saha, Digital
Principles and Applications, Tata McGraw Hill, 2007. References: 1.
J. F. Wakerly, Digital Design - Principles and Practices,
3rd Ed., Prentice Hall of India, 2005. 2.
J. Millman and C. C. Halkias, Integrated
Electronics, Tata McGraw Hill, 1995. 3.
R. L. Boylestad and L. Nashelsky, Electronic
Devices and Circuit Theory, Pearson Education, 2007. 4.
P. Horowitz and W. Hill, The Art of Electronics, Cambridge University Press, 1995. 5.
M. Mano, Digital Design, 2nd Ed., Prentice Hall of India, 1997. |
PH 210 Electronic
Lab - I (
0-0-4-4 ) Amplifiers: single- and multi-stage amplifiers,
frequency response,
Fourier transform, various classes of amplifiers and their
frequency response, various modulation schemes. Multivibrators
and wave function generators, filters.
Measurement of depletion layer capacitance and effect of
temperature. Controller circuits. References:
1.
P. B. Zbar and A. P. Malvino, Basic electronics: A text-lab manual,
Tata McGraw Hill, 1983. 2.
P.
Horowitz and W. Hill, The Art of Electronics, Cambridge
University Press, 1995. 3.
R. A. Gayakwad, Op-Amps
and Linear Integrated Circuits, Prentice Hall of India, 2002. |
PH
301 Microprocessor
Architecture and Programming (3-0-0-6
) Introduction
to Microprocessors. The 8085
Architecture, Bus organization, Registers, Memory, I/O devices. Control signals, Machine cycles and
Bus timings. Memory
Interfacing: Memory Read cycle,
Address decoding, Interfacing the 8155 memory section. I/O Interfacing: I/O Instructions and executions,
Device selection, Interfacing with input and output devices. Memory mapped I/O. 8085 Instructions and Assembly
Language: Arithmetic operations,
Logic operations, Branch operations.
Controls and time delays.Flowchart and
Programming techniques, Stack and Subroutines, Restart, Conditional Call, and
Return instructions.
Nesting. Code
Conversions: BCD-Binary,
BCD-seven segment LED, Binary-ASCII.
BCD Arithmetic and 16-bit data operations. Operating System: Assembler and programming using an
Assembler. Interrupts: Instructions, Restart, Trap.
Programmable interrupt controller 8259A. Interfacing: with D/A and
A/D converter. Interfacing I/O
ports using 8155. The 8279
keyboard/display interfacing. The
8255 programmable peripheral interface.
Serial I/O and Data communication. Microprocessor applications. Texts:
References:
|
PH
303 Atomic and Molecular
Spectroscopy (3-0-0-6) Review
of single electron systems; Multi-electron
atoms: central-field and Hartree - Fock approximations, Thomas Fermi model, angular momentum, LS and jj coupling,
Pauli exclusion principle, alkali spectra, Helium atom, complex
atoms; Zeeman effect, Paschen-Back effect and Stark
effect. Rotational
spectra of diatomic molecules, infra-red spectra, diatomic vibrating rotator,
vibration-rotation spectra; electronic spectra of diatomic molecules, vibrational coarse structure, Franck-Condon principle,
dissociation energy, rotational fine structure; Spectroscopic Techniques:
Interferometers and spectrometers, FTIR, Raman, NMR and ESR spectroscopy. Texts: 1.
B H Bransden and
C J Joachain, Physics of atoms
and molecules, 2nd Ed.,
Pearson Education, 2007. 2.
A N Banwell and E
M McCash, Fundamentals
of molecular spectroscopy, 4th Ed., Tata McGraw Hill, 1995. References: 1.
H E White, Introduction
to atomic spectra, 1st Ed., McGraw Hill, 1934. 2.
H. Haken and H.
C. Wolf, The Physics of Atoms and Quanta: Introduction
to experiment and theory, 7th Ed., Springer, 2010. 3.
S. Svanberg, Atomic and molecular spectroscopy: basic
aspects and practical applications, 4th Ed., Springer,
2004. 4. W. Demtroder, Laser Spectroscopy, 4th Ed., Springer, 2008. |
PH 305 Computational
Physics
(2-0-2-6) Matrices: System of linear equations,
Gauss and Gauss-Jordan elimination, Matrix Inversion, LU decomposition, eigenvalue and eigenvector problems, Power and Jacobi
method, application to physics
problems; Ordinary and Partial Differential Equations: Euler, Runge-Kutta and finite difference methods; solution to initial and boundary value
problems, Finite difference solutions to hyperbolic, parabolic and elliptic
partial differential equations, application to physics problems; Monte Carlo
Simulation: Markov process and Markov chain, random numbers, simple and importance sampling, Metropolis algorithm, 2D-Ising model. Texts: 1.
S. S. M. Wong, Computational
Methods in Physics and Engineering, World Scientific, 1997. 2.
T. Pang, An Introduction to
Computational Physics, Cambridge University Press, 1997. References: 1.
R. H. Landau, M. J. Paez and
C. C. Bordeianu, Computational Physics: Problem Solving with Computer, Wiley Vch Verlag Gmbh
& Co. KGaA, 2007. 2.
D. Frenkel and B. Smit, Understanding Molecular Simulation,
Academic Press, 1996. 3.
M. E. J. Newman and G. T. Barkema,
Monte Carlo Methods in Statistical
Physics, Clarendon Press, Oxford, 2001. 4.
M. P. Allen
and D. J. Tildesley, Computer Simulation of Liquids, Clarendon Press, Oxford, 1991. 5.
W. H. Press, S. A. Teukolsky,
W. T. Verlling and B. P. Flannery, Numerical Recipes in C/Fortran,
Cambridge, 1998. |
PH 307 Statistical Mechanics (2-1-0-6) Ensemble theory: Phase space, Ergodic
hypothesis, Liouville's theorem, micro-canonical,
canonical and grand canonical ensembles, equipartition
and virial theorems, formulation of quantum
statistics, quantum mechanical ensemble theory. Quantum gases: Ideal Bose
gas, Bose Einstein condensation, blackbody radiation, phonons; ideal Fermi
gas, Pauli para-magnetism, thermionic emissions,
white dwarfs. Non-equilibrium
statistical mechanics: Boltzmann transport equation, master equations, Markov
processes, diffusion and Brownian motion. Texts: 1. R.K. Pathria, Statistical Mechanics, Butterworth Heinemann, 1996. 2. N. Pottier, Nonequilibrium Statistical Physics, Oxford University Press, 2010.
References: 1. K. Huang, Statistical Mechanics, John Wiley, Asia, 2000. 2. L.D. Landau and E.M. Lifshitz, Statistical Physics-1, Pergamon, 1980. 3. L. Couture and R. Zitoun, Statistical Thermodynamics and Properties of Matter, Gordon & Breach Science Publishers, 1998. |
PH 311 Electronics
Lab - II (0-0-6-6) Experiments using Small
Scale Integration and Medium Scale Integration digital integrated circuits:
logic gates, flip-flops, counters, multiplexers, demultiplexers,
shift registers, seven-segment decoders, monostable
multivibrators, latches, memories, etc. Assembly
language programming for 8085 microprocessor, interfacing 8085 microprocessor
with memory and I/O devices, 8085 microprocessor kit based interfacing
experiments using peripheral programmable interface such as LED and 7-segment
display, Temperature controller, stepper motor control, A/D and D/A
converters, etc. References: 1. P. B. Zbar and A. P. Malvino, Basic electronics: A text-lab manual, Tata McGraw Hill, 1983. 2.
A. P. Malvino and D. P Leach, Digital Principles and Applications. McGraw-Hill,1996. 3.
R. S. Gaonkar, Microprocessor
Architecture, programming & application with 8085/8080A, 2nd
Ed., New Age, 1995. |
PH 302
Solid
State Physics (2-1-0-6) Crystallography: crystal lattices and symmetry
groups, reciprocal lattice, Brillouin zone, Miller
indices, crystal structure by X-ray diffraction, crystal defects; Thermal
properties: crystal potentials, harmonic theory of lattice vibrations,
optical and acoustic modes, density of states, Einstein and Debye theory of
specific heat; Electronic properties: free electron theory, electrons in a
periodic potential, Bloch's theorem, Kronig-Penny
model, formation of bands, effective mass, holes, classification of metal,
insulator and semiconductor, intrinsic and extrinsic semiconductors, law of
mass action, Hall effect; Magnetic properties: classical and quantum models
of diamagnetism, quantum theory of para-magnetism, Lande g factor, Hund's rule,
electronic configurations, crystal field, Curie law, concepts of ferro, ferri, and anti-ferro magnetism; Superconductivity: Meissner
effect, London equations, BCS ground state, flux quantization in
superconducting ring, type-II superconductors, Josephson tunnelling,
high temperature superconductors. Texts: 1. H. P. Myers, Introduction to Solid State Physics, CRC press, 1997. 2. C. Kittel,
Introduction to Solid State Physics,
John Wiley & Sons, 2005. References: 1. N.W.
Ashcroft and N.D. Mermin, Solid State Physics, HBC Publication, 1976. 2. J. R.
Christman, Fundamentals
of Solid State Physics, John Wiley & Sons, 1988. 3. A.J. Dekker, Solid State Physics, Mcmillan, 1986. |
PH 304
Engineering
Optics (3-0-0-6) Geometrical
optics: Matrix formulation for lens and mirrors and
combinations, Aberrations.
Diffraction Theory: Kirchoff integrals, Fraunhoffer and Fresnel diffraction, Propogation
of Gaussian beam, derivation of lens making formula, Fourier optics, Spatial
frequency filtering, image processing, Holography. Interference
Phenomena: Two and Multiple beam interference, effect of line width, fringe
contrast, coherence, Optical properties of single and multilayer thin films,
matrix formulation, applications of interferometer. Polarization: Polarization of
radiation, polarization calculus (matrix formulation and Poincare
representation, Pancharatnam phase), birefringence,
crystal optics, Ellipsometry and application of
polarization based devices.
Optical designing and testing, optical devices and their applications. Texts: 1. M. Born and E. Wolf, Principles of Optics, 6th Ed., Cambridge
University Press, 1997. 2. B. H. Walker, Optical engineering fundamentals,
SPIE Optical Engineering Press, 1998. References: 1. R. D. Gunther, Modern Optics, John Wiley, 1990. 2. K. Iizuka, Elements of Photonics, John Wiley,
2002. 3. R. M. A. Azzam and N. M. Bashara, Ellipsometry and
Polarized light, Elsevier, 1996. 4. W. J. Smith, Modern optical engineering, McGraw Hill, 1991. |
PH 306
Nuclear Science and Engineering (3-0-0-6) Review of nuclear physics: general nuclear properties, models
of nuclear structure, nuclear reactions, nuclear decays and fundamental
interactions; Nuclear radiation: radioactivity, radiation dosimetry,
dosimetry units and measurement; radiation
protection and control; applications of radiation: medical applications,
industrial radiography, neutron activation analysis, instrument
sterilization, nuclear dating; Nuclear fission: nuclear energy, fission
products, fissile materials, chain reactions, moderators, neutron thermalization, reactor physics, criticality &
design; nuclear power engineering; energy transport and conversion in reactor
systems, nuclear reactor safety; nuclear fusion: controlled fusion, nuclear
fusion reactions, fusion reactor concepts, magnetic confinement, tokamak, inertial confinement by lasers; Nuclear waste
management: components and material flow sheets for nuclear fuel cycle, waste
characteristics, sources of radioactive wastes, compositions, radioactivity
and heat generation; waste treatment and disposal technologies; safety
assessment of waste disposal; Particle accelerators and detectors:
interactions of charged particles, gamma rays and neutrons with matter,
electrostatic accelerators, cyclotron, synchrotron, linear accelerators,
colliding beam accelerators, gas-filler counters, scintillation detectors,
and semiconductor based particle detectors. Texts: 1.
K. S. Krane,
Introductory Nuclear Physics, John Wiley, 1987. 2.
R. J. Blin-Stoyle,
Nuclear and Particle
Physics, Springer,
1991. References: 1. J.
K. Shultis and R. E. Faw,
Fundamentals of Nuclear Science and Engineering, Marcel Dekker, 2007. 2. J.
E. Turner, Atoms, Radiation, and Radiation Protection, Wiley-VCH,
2007. 3. R.
L. Murray, Nuclear Energy, 6th
Ed., Butterworth-Heinemann, 2008. 4. J.
J. Duderstadt and L. J. Hamilton, Nuclear Reactor
Analysis, Wiley, 1976. 5. D.
H. Perkins, Introduction to High Energy Physics, Cambridge University
Press, 2000. 6. J.
R. Lamarsh and A. J. Baratta,
Introduction to Nuclear Engineering, Prentice Hall, (2001 7. G.
Chmielewski, C. M. Kang, C. S. Kang, and J. L. Vujic, Radiation Technology: Introduction to
Industrial and Environmental Applications, Seoul National University
Press, 2006. |
PH 308 Measurement
Techniques (2-0-2-6) Sensors:
Resistive, capacitative, inductive, electromagnetic,
thermoelectric, elastic, piezoelectric, piezoresistive,
photosensitive and electrochemical sensors; interfacing
sensors and data acquisition using serial and parallel ports. Low Pressure: Rotary, sorption, oil
diffusion, turbo molecular, getter and cryo pumps; Mcleod, thermoelectric (thermocouple, thermister
and pirani), penning, hot cathode and Bayard Alpert
gauges; partial pressure measurement; leak detection; gas flow through pipes
and apertures; effective pump speed; vacuum components. Low Temperature: Gas liquifiers; Cryo-fluid baths;
liquid He cryostat design; closed cycle He
refrigerator; low temperature measurement. Analytical Instruments: X-ray diffractometer; Spectrophotometers; FT-IR; DSC; lock-in
amplifier; spectrum analyzer, fluorescence and Raman spectrometer, scanning
electron microscope, atomic force microscope, interferometers. Laboratory Component: physical
parameter measurement using different sensors; low pressure generation and
measurement; calibration of secondary gauges; cryostat design; CCR operation;
data collection from analytical instruments in the department. Texts:
1. A.
D. Helfrick and W. D. Cooper, Modern Electronic
Instrumentation and Measurement Techniques, Prentice-Hall of India, 1996.
2. J.
P. Bentley, Principles of Measurement Systems, Longman, 2000. References:
1.
G. K. White, Experimental Techniques
in Low Temperature Physics, Clarendon, 1993. 2.
A. Roth, Vacuum Technology,
Elsevier, 1990. 3.
D. A. Skoog, F.
J. Holler and T. A. Nieman, Principles of
Instrumental Analysis, Saunders Coll. Publ., 1998. |
PH 320 General
Physics Lab (0-0-6-6) Experiments based
on general physics, optics, and condensed matter physics. References:
|
PH 413 Materials
Science & Engineering (3-0-0-6) Classification
of engineering materials; equilibrium and kinetics; structure of crystalline
and non-crystalline solids; imperfections in solids; phase diagrams: phase
rule, phases, binary phase diagram and eutectic, eutectoid and peritectic systems, microstructural
changes, the lever rule, examples and application of phase diagram; phase transformation: time scale of
phase changes, nucleation and growth, transformation in steel, precipitation
processes, solidification and crystallization, re-crystallization and grain
growth; diffusion in solids: Fick’s laws and
their applications, Kirkendall effect, atomistic
model of diffusion; Mechanical properties of metals: elastic, anelastic and viscoelastic
behaviors, plastic deformation and creep in crystalline materials, hardness,
mechanical testing of metals;
failure: fracture, fatigue and creep; thermal processing of metal
alloys: annealing processes, heat treatment of steels, precipitation
hardening; oxidation and corrosion, oxidation resistant materials, protection
against corrosion; electrical and optical properties of the materials;
ceramics, polymers and composites materials, selection and design
consideration; environmental issues in material science. Texts: 1.
V. Raghavan, Material Science and Engineering : A First Course, 5th Ed, Prentice-Hall of India, 2004. 2. W.D.
Callister (Jr.), Materials Science and Engineering : An
Introduction, 6th Ed., 2003. References: 1.
J. B. Watchman, Characterization of Materials, Butterworth-Heinenmann,
1992. 2.
L.H. Van Valck,
Elements of Materials Science and
Engineering, 6th Ed., Addision-Wesley,
1998. |
PH
415 Lasers
and Photonics (3-0-0-6) Laser Physics: The
Einstein coefficients, light amplification, the threshold condition, laser
rate equations, line broadening mechanisms, cavity modes, optical resonator,
quality factor, mode selection, Q-switching, mode locking in lasers; gas
lasers, solid state lasers, semiconductor lasers and dye lasers. Photonics: optical properties of anisotropic media, wave
refractive index, optical activity and Faraday effect, liquid crystals; principles of electro-optics, magneto-optics,
photo refractive materials, acousto-optics and
related devices; Nonlinear optical susceptibilities, second harmonic
generation, self-focussing and Kerr effect; basic
principles and applications of holography; Step index and graded index optical
fibers, attenuation and dispersion; fiber optic communications; optical
detectors. Texts: 1.
W. T. Silfvast,
Laser Fundamentals, 2nd
Ed., Cambridge University Press, 2004. 2.
B.E.A. Saleh
and M.C.Teich, Fundamentals
of Photonics, 2nd Ed., Wiley, 2007. References: 1.
A. Ghatak
and K. Thyagarajan, Optical Electronics, Cambridge University Press, 2009. 2.
A. Yariv
and P. Yeh, Photonics,
6th Ed., Oxford University Press, 2007. 3.
O. Svelto
and D. C. Hanna, Principles of Lasers,
Springer, 1998. 4. R.W. Boyd, Nonlinear Optics,
3rd Ed., Academic Press, 2007. 5. A. Yariv and P. Yeh, Photonics: Optical Electronics in Modern Communications, 6th Ed., Oxford
University Press, 2006. |
PH 417 Advanced
Physics Lab (0-0-6-6) Experiments
based on modern optics, lasers, solid state physics, microwave, nuclear
physics and
advanced measurement techniques. References:
|
PH 414 Nano Electronics and Nanophotonics (3-0-0-6) Nanoelectronics:
Energy levels, Density of states. Bond structure, coulomb blockade, quantum
wire, electron phase correlation, single electron tunneling, quantum dot,
molecular motors, nano-transistors and FET and NEMS
and sensors.Nanophotonics: nano
scale field interaction, nanoconfinement, near
field microscopy, plasmonics, nonlinear optical
phenomena, nano-scale dynamics, quantum well laser,
photonic crystal and wave guide. Growth method and characterization of
material, nanolithography, nanphotonics for
biotechnology. Texts: 1.
Charles P. Poole and Frank J. Owens, Introduction to Nanotechnology, Wiley-Interscience, 2003. 2.
P. N. Prasad, Nanophotonics, Wiley Interscience,
2004. References:
|