English

Solving Linearized Equations of the $N$-body Problem Using the Lie-integration Method

Astrophysics 2009-11-13 v1
Authors: Andras Pal , Aron Suli
View on arXiv PDF DOI

Abstract

Several integration schemes exits to solve the equations of motion of the NN-body problem. The Lie-integration method is based on the idea to solve ordinary differential equations with Lie-series. In the 1980s this method was applied for the NN-body problem by giving the recurrence formula for the calculation of the Lie-terms. The aim of this works is to present the recurrence formulae for the linearized equations of motion of NN-body systems. We prove a lemma which greatly simplifies the derivation of the recurrence formulae for the linearized equations if the recurrence formulae for the equations of motions are known. The Lie-integrator is compared with other well-known methods. The optimal step size and order of the Lie-integrator are calculated. It is shown that a fine-tuned Lie-integrator can be 30%-40% faster than other integration methods.

Keywords

differential equations n-body problem partial differential equations

Cite

@article{arxiv.0707.3454,
  title  = {Solving Linearized Equations of the $N$-body Problem Using the Lie-integration Method},
  author = {Andras Pal and Aron Suli},
  journal= {arXiv preprint arXiv:0707.3454},
  year   = {2009}
}

Comments

accepted for publication in MNRAS (13 pages, 4 figures); see http://cm.elte.hu/lie (cm.elte.hu/lie) for software

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