Celestial Mechanics I - NAST005
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Last update: prof. RNDr. David Vokrouhlický, DrSc. (07.06.2019)
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Last update: prof. RNDr. David Vokrouhlický, DrSc. (07.06.2019)
Oral examination preceded by a short written exercise. |
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Last update: prof. RNDr. David Vokrouhlický, DrSc. (04.01.2019)
W.M. Smart, Celestial Mechanics, Longmans, Green and Co., 1953 (nebo ruský překlad)
D. Brouwer, and G. Clemence, Methods of Celestial Mechanics, Academic Press, New York, 1961
C.D. Murray, and S.F. Dermott, Solar System Dynamics, Cambridge University Press, 2008
V. Szebehely, Theory of Orbits, Academic Press, 1961
B. Bertotti, P. Farinella, and D. Vokrouhlicky, Physics of the Solar System, Kluwer Academic Press, 2003 |
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Last update: T_AUUK (31.03.2008)
Přednáška. |
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Last update: prof. RNDr. David Vokrouhlický, DrSc. (06.10.2017)
Zkouška sestává z písemné a ústní části. Písemná část obvykle představuje vyřešení příkladu. Nesplnění písemné části však nevylučuje úspěšné složení zkoušky. |
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Last update: prof. RNDr. David Vokrouhlický, DrSc. (07.06.2019)
A brief overview of analytical mechanics: Lagrange and Hamiltonian approach; Lagrange equations of the second kind; Hamilton equations; canonical transformations; Poisson and Lagrange brackets; symplectic matrix; Hamilton-Jacobi equation; particle in one-diemnsional potential. Two-body problem: Basic formulation; transformation of barycenter; relative coordinate; momentum and angular momentum integrals; Binet equation; Kepler equation and variants for parabolic and hyperobolic motions; orbital and non-singular orbital elements; solution of the two-body problem using Hamilton-Jacobi equation; Delaunay variables; elliptic expansions (Bessel functions; Hansen functions). Circular restricted problem of three bodies: Equations of motion in the inertial and synodic reference systems; Jacobi integral; Tisserand criterion; Hill's planes of zero velocity; stationary solutions (Lagrange points); stability of stationary solutions. Elliptic restricted problem of three bodies: Nechvile's transformation to rotating and pulsating coordinate system; non-integrability; stationary solutions and their stability; Hill's problem: Jacobi coordinates; equations of motion in synodic reference system; Hill's surfaces of zero velocity; lunar origin; theory of lunar motion; variational solution. |