New families of symplectic splitting methods for numerical integration in dynamical astronomy

New families of symplectic splitting methods for numerical integration in dynamical astronomy

We present new splitting methods designed for the numerical integration of near-integrable Hamiltonian systems, and in particular for planetary N-body problems, when one is interested in very accurate results over a large time span. We derive in a systematic way an independent set of necessary and s...

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Bibliographic Details
Published in:Applied numerical mathematics Vol. 68; pp. 58 - 72
Main Authors: Blanes, S., Casas, F., Farrés, A., Laskar, J., Makazaga, J., Murua, A.
Format: Journal Article
Language:English
Published: Elsevier B.V 01-06-2013
Subjects:
Accuracy
Astronomy
Dynamical systems
Mathematical analysis
Mathematical models
N-body problems
Near-integrable systems
Numerical integration
Polynomials
Splitting
Splitting methods
Symplectic integrators
N-body problems
Splitting methods
Symplectic integrators
Near-integrable systems
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Summary:We present new splitting methods designed for the numerical integration of near-integrable Hamiltonian systems, and in particular for planetary N-body problems, when one is interested in very accurate results over a large time span. We derive in a systematic way an independent set of necessary and sufficient conditions to be satisfied by the coefficients of splitting methods to achieve a prescribed order of accuracy. Splitting methods satisfying such (generalized) order conditions are appropriate in particular for the numerical simulation of the Solar System described in Jacobi coordinates. We show that, when using Poincaré Heliocentric coordinates, the same order of accuracy may be obtained by imposing an additional polynomial equation on the coefficients of the splitting method. We construct several splitting methods appropriate for each of the two sets of coordinates by solving the corresponding systems of polynomial equations and finding the optimal solutions. The experiments reported here indicate that the efficiency of our new schemes is clearly superior to previous integrators when high accuracy is required.
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ISSN:0168-9274
1873-5460
DOI:10.1016/j.apnum.2013.01.003