6.  edition, 1991.
                   7.  Microprocessor Architecture, programming and Applications with 8085/8086 by
                   8.  Ramesh S. Gaonkar, Wiley – Eastern Let. 1987 ( for unit v)
                   9.  Microwaves by K.L. Gupta, Wiley Eastern Ltd. New Delhi, 1983.


               Phys.323                   Astronomy and Astrophysics                                     3+1

               LEARNING OBJECTIVES:

               The primary aim of this course is to:
                     provide a pedagogical introduction to astronomy and astrophysics both on the galactic and
                       extragalactic scale at the graduation level along with the brief introduction to astronomical
                       techniques.
                     provide hands-on experience of the astronomy lab.

               LEARNING OUTCOMES:

               After completing the course satisfactorily, a student will be able:
                     To understand the technique in observational astronomy
                     To understand the distance ladder in the context of the size of the Universe
                     Sun and stellar synthesis. Interstellar medium
                     Galaxies and their morphology
                     Smooth  and  clumpy  universe.  The  basic  mathematical  machinery  of  the  background
                       Universe.
                     To understand the technique used to analyze the astronomy data
                     To analyze the data from the astronomy archive
                     To get familiar with the night sky
                     To learn to use the astronomical software in the various electromagnetic bands.

               THEORY (45 Hours)


               UNIT 1                                                                             (15 Hours)
               Astronomical Scales: Astronomical Distance, Mass and Time, Scales, Brightness, Radiant Flux
               and Luminosity, Measurement of Astronomical Quantities Astronomical Distances, Stellar Radii,
               Masses of Stars, Stellar Temperature. Basic concepts of positional astronomy: Celestial Sphere,
               Geometry  of  a  Sphere,  Spherical  Triangle,  Astronomical  Coordinate  Systems,  Geographical
               Coordinate  Systems,  Horizon  System,  Equatorial  System,  Diurnal  Motion  of  the  Stars,
               Conversion of Coordinates. Measurement of Time, Sidereal Time, Apparent Solar Time, Mean
               Solar Time, Equation of Time, Calendar. Basic Parameters of Stars: Determination of Distance by
               Parallax Method;  Brightness,  Radiant  Flux and  Luminosity, Apparent  and Absolute magnitude
               scale, Distance Modulus; Determination of Temperature and Radius of a star; Determination of
               Masses from Binary orbits; Stellar Spectral Classification, Hertzsprung-Russell Diagram.
               Astronomical  techniques:  Basic  Optical  Definitions  for  Astronomy  (Magnification  Light
               Gathering  Power,  Resolving  Power  and  Diffraction  Limit,  Atmospheric  Windows),  Optical
               Telescopes (Types of Reflecting Telescopes, Telescope Mountings, Space Telescopes, Detectors
               and Their Use with Telescopes (Types of Detectors, detection Limits with Telescopes).
               Physical  principles:  Gravitation  in  Astrophysics  (Virial  Theorem,  Newton  versus  Einstein),
               Systems in Thermodynamic Equilibrium.
               UNIT 2                                                                             (15 Hours)

               The sun (Solar Parameters, Solar Photosphere, Solar Atmosphere, Chromosphere. Corona, Solar
               Activity, Basics of Solar Magneto-hydrodynamics. Helioseismology).


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