We present an algorithm for the rapid numerical integration of a time-periodic ODE with a small dissipation term that is C1 in the velocity. Such an ODE arises as a model of spin–orbit coupling in a star/planet system, and the motivation for devising a fast algorithm for its solution comes from the desire to estimate probability of capture in various solutions, via Monte Carlo simulation: the integration times are very long, since we are interested in phenomena occurring on timescales of the order of 10 6–10 7 years. The proposed algorithm is based on the high-order Euler method which was described in Bartuccelli et al. (Celest Mech Dyn Astron 121(3):233–260, 2015), and it requires computer algebra to set up the code for its implementation. The payoff is an overall increase in speed by a factor of about 7.5 compared to standard numerical methods. Means for accelerating the purely numerical computation are also discussed.

Bartuccelli, M., Deane, J., Gentile, G. (2017). Fast numerics for the spin orbit equation with realistic tidal dissipation and constant eccentricity. CELESTIAL MECHANICS & DYNAMICAL ASTRONOMY, 128(4), 453-473 [10.1007/s10569-017-9760-1].

Fast numerics for the spin orbit equation with realistic tidal dissipation and constant eccentricity

Gentile, Guido
2017-01-01

Abstract

We present an algorithm for the rapid numerical integration of a time-periodic ODE with a small dissipation term that is C1 in the velocity. Such an ODE arises as a model of spin–orbit coupling in a star/planet system, and the motivation for devising a fast algorithm for its solution comes from the desire to estimate probability of capture in various solutions, via Monte Carlo simulation: the integration times are very long, since we are interested in phenomena occurring on timescales of the order of 10 6–10 7 years. The proposed algorithm is based on the high-order Euler method which was described in Bartuccelli et al. (Celest Mech Dyn Astron 121(3):233–260, 2015), and it requires computer algebra to set up the code for its implementation. The payoff is an overall increase in speed by a factor of about 7.5 compared to standard numerical methods. Means for accelerating the purely numerical computation are also discussed.
2017
Bartuccelli, M., Deane, J., Gentile, G. (2017). Fast numerics for the spin orbit equation with realistic tidal dissipation and constant eccentricity. CELESTIAL MECHANICS & DYNAMICAL ASTRONOMY, 128(4), 453-473 [10.1007/s10569-017-9760-1].
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11590/327640
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