Splitting methods

Robert I. McLachlan; G. Reinout W. Quispel

doi:10.1017/S0962492902000053

Abstract

I thought that instead of the great number of precepts of which logic is composed, I would have enough with the four following ones, provided that I made a firm and unalterable resolution not to violate them even in a single instance. The first rule was never to accept anything as true unless I recognized it to be certainly and evidently such …. The second was to divide each of the difficulties which I encountered into as many parts as possible, and as might be required for an easier solution. (Descartes)

We survey splitting methods for the numerical integration of ordinary differential equations (ODEs). Splitting methods arise when a vector field can be split into a sum of two or more parts that are each simpler to integrate than the original (in a sense to be made precise). One of the main applications of splitting methods is in geometric integration, that is, the integration of vector fields that possess a certain geometric property (e.g., being Hamiltonian, or divergence-free, or possessing a symmetry or first integral) that one wants to preserve. We first survey the classification of geometric properties of dynamical systems, before considering the theory and applications of splitting in each case. Once a splitting is constructed, the pieces are composed to form the integrator; we discuss the theory of such ‘composition methods’ and summarize the best currently known methods. Finally, we survey applications from celestial mechanics, quantum mechanics, accelerator physics, molecular dynamics, and fluid dynamics, and examples from dynamical systems, biology and reaction–diffusion systems.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Del Buono, Nicoletta and Lopez, Luciano 2003. Computational Science — ICCS 2003. Vol. 2658, Issue. , p. 111.

Hairer, Ernst and Hairer, Martin 2003. Frontiers in Numerical Analysis. p. 199.

Quispel, G.R.W. and McLaren, D.I. 2003. Explicit volume-preserving and symplectic integrators for trigonometric polynomial flows. Journal of Computational Physics, Vol. 186, Issue. 1, p. 308.

Sofroniou, Mark and Spaletta, Giulia 2003. Increment formulations for rounding error reduction in the numerical solution of structured differential systems. Future Generation Computer Systems, Vol. 19, Issue. 3, p. 375.

Moore, Peter K. 2003. An incomplete assembly with thresholding algorithm for systems of reaction–diffusion equations in three space dimensions IAT for reaction–diffusion systems. Journal of Computational Physics, Vol. 189, Issue. 1, p. 130.

McLachlan, R.I. Perlmutter, M. and Quispel, G.R.W. 2003. Lie group foliations: dynamical systems and integrators. Future Generation Computer Systems, Vol. 19, Issue. 7, p. 1207.

Omelyan, I.P. Mryglod, I.M. and Folk, R. 2003. Symplectic analytically integrable decomposition algorithms: classification, derivation, and application to molecular dynamics, quantum and celestial mechanics simulations. Computer Physics Communications, Vol. 151, Issue. 3, p. 272.

McLachlan, Robert I. and Ryland, Brett 2003. The algebraic entropy of classical mechanics. Journal of Mathematical Physics, Vol. 44, Issue. 7, p. 3071.

Araújo, A. 2004. A note on B-stability of splitting methods. Computing and Visualization in Science, Vol. 6, Issue. 2-3, p. 53.

Frank, Jason 2004. Geometric space–time integration of ferromagnetic materials. Applied Numerical Mathematics, Vol. 48, Issue. 3-4, p. 307.

Chin, Siu A. 2004. Quantum statistical calculations and symplectic corrector algorithms. Physical Review E, Vol. 69, Issue. 4,

McLaren, D I and Quispel, G R W 2004. Integral-preserving integrators. Journal of Physics A: Mathematical and General, Vol. 37, Issue. 39, p. L489.

Ascher, Uri M. and McLachlan, Robert I. 2004. Multisymplectic box schemes and the Korteweg–de Vries equation. Applied Numerical Mathematics, Vol. 48, Issue. 3-4, p. 255.

Araújo, A. 2004. A note on B-stability of splitting methods. Computing and Visualization in Science, Vol. 6, Issue. 2-3, p. 53.

Blanes, S. Casas, F. and Murua, A. 2004. On the Numerical Integration of Ordinary Differential Equations by Processed Methods. SIAM Journal on Numerical Analysis, Vol. 42, Issue. 2, p. 531.

Kozlov, Roman Kværnø, Anne and Owren, Brynjulf 2004. The behaviour of the local error in splitting methods applied to stiff problems. Journal of Computational Physics, Vol. 195, Issue. 2, p. 576.

Scuro, Sante R. and Chin, Siu A. 2005. Forward symplectic integrators and the long-time phase error in periodic motions. Physical Review E, Vol. 71, Issue. 5,

Chin, Siu A. and Krotscheck, Eckhard 2005. Fourth-order algorithms for solving the imaginary-time Gross-Pitaevskii equation in a rotating anisotropic trap. Physical Review E, Vol. 72, Issue. 3,

Vijalapura, Prashanth K. Strain, John and Govindjee, Sanjay 2005. Fractional step methods for index-1 differential-algebraic equations. Journal of Computational Physics, Vol. 203, Issue. 1, p. 305.

San Miguel, A. 2005. Numerical integration for the dynamics of the heavy magnetic top. Physics Letters A, Vol. 335, Issue. 2-3, p. 235.

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Splitting methods

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