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Last update: T_AUUK (25.05.2006)
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Last update: prof. RNDr. David Vokrouhlický, DrSc. (11.06.2019)
Oral examination. |
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Last update: doc. Mgr. Miroslav Brož, Ph.D. (25.09.2020)
v případě distanční výuky, přes Zoom https://cesnet.zoom.us/j/6079238231
Brož M., Šolc M.: Fyzika sluneční soustavy. Praha: Matfyzpress, 2013. ISBN 9788073782368.
Wolf M. aj.: Astronomická příručka. Praha: Academia, 1992. ISBN 802000467X.
Murray, C. D., Dermott, S. F. Solar System Dynamics. Cambridge: Cambridge University Press, 2000. ISBN 0521575974.
Harmanec P., Brož M.: Stavba a vývoj hvězd. Praha: Matfyzpress, 2011. ISBN 9788073781651.
Carrol B.W., Ostlie D.A.: An Introduction to Modern Astrophysics, Pearson, Addison Wesley, San Francisco, 2007. ISBN 0321442849.
Bertotti, B., Farinella, P., Vokrouhlický, D. Physics of the Solar System. Dordrecht: Kluwer Academic Publishers, 2003. ISBN 1402014287.
de Pater, I., Lissauer, J. J. Planetary Sciences. Cambridge: Cambridge University Press, 2001. ISBN 0521482194.
Stix, M. The Sun: An Introduction. Berlin: Springer-Verlag, 1991. ISBN 3540207414.
Jones, M. H., Lambrourne, R. J. A. (Eds.) An Introduction to Galaxies and Cosmology. Cambridge: Cambridge University Press, 2004. ISBN 0521546230. |
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Last update: T_AUUK (31.03.2008)
Přednáška |
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Last update: doc. Mgr. Miroslav Brož, Ph.D. (04.01.2023)
Zkouška sestává ze dvou šířeji položených otázek, odpovídajících jednotlivým přednáškám. Jednu z nich si může zvolit student.
Požadavky odpovídají syllabu, resp. úvodním kapitolám v učebnici Brož a Šolc (2013), v tom rozsahu, který byl prezentován na přednášce. Známka se stanovuje dle správnosti nebo chybnosti odpovědí.
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Last update: T_AUUK (27.03.2015)
1. What is the time on sundials? Time in astronomy - universal time, sidereal time, true local and mean solar time, equation of time, Julian date; definitions and cardinal directions and planes of coordinate systems (azimuthal, equatorial, ecliptic, galactic, geographic).
2. How to construct a planisphere? Coordinate transformations, rotation in 2D, rotation matrices, spherical triangle, units of angles and distances.
3. Why planets orbit on ellipses? Kepler laws, Newton laws of motion and gravity law, two-body problem solution, orbital elements.
4. Where is asteroid (4) Vesta on the sky? Databases of orbits (MPC, AstOrb) and calculation of ephemerides (Horizons).
5. What forces act on small bodies? Gravitational perturbations by planets, resonances, Yarkovsky/YORP effect (an order of magnitude estimate), ...
6. How far are objects we see on the sky? Distance determination in the Universe. Moon eclipse, parallax, transits of Mercury and Venus, Cepheids, ...
7. Why the Sun shines? Observer phenomena on the Sun, structure of the Sun, thermonuclear reactions.
8. When and how planets were formed? Determination of ages in general, radiometric method, gravitational collapse, protoplanetary disk, planetesimals and embryos.
9. What asteroids tell us? Distribution of asteroids in the Solar System, Kirkwood gaps, a new scenario of planetary system evolution.
10. What can we read in stellar radiation? Spectroscopy, a spectrum of a progressively denser and hotter gas cloud, physical characteristics of stars, extrasolar planets.
11. How to use telescope and a CCD camera? Optical instruments, photometry and photometric quantities, brightness measurement of an eclipsing binary and its interpretation.
12. How do stars evolve? Hertzsprung-Russel diagram, equations of stellar structure, internal structure of stars, novae and supernovae.
13. Why there is dark during the night? Kepler-Olbers paradox, Big Bang, nucleosynthesis in early universe, dark matter and dark energy, black hole in the centre of our Galaxy. |