The Lagrange reduction of the N-body problem, a survey
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THE LAGRANGE REDUCTION OF THE N-BODY PROBLEM, A SURVEY Alain Chenciner Dedicated with admiration to the memory of Ta Quang Buu and Lê V˘an Thiêm. ˙ Received: 10 December 2012 / Published online: 6 March 2013 © Institute of Mathematics, Vietnam Academy of Science and Technology (VAST) and Springer Science+Business Media Singapore 2013
Abstract In his fundamental “Essai sur le problème des trois corps” (Oeuvres, vol. 6, pp. 229–324, 1772), Lagrange, well before Jacobi’s “reduction of the node”, carries out the first complete reduction of symmetries in this problem. Discovering the so-called homographic motions (Euler had treated only the collinear case), he shows that these motions necessarily take place in a fixed plane, a result which is simple only for the “relative equilibria”. In order to understand the true nature of this reduction—and of Lagrange’s equations—it is necessary to consider the n-body problem in an euclidean space of arbitrary dimension. The actual dimension of the ambient space then appears as a constraint, namely the angular momentum bivector’s degeneracy. I describe in detail the results obtained in a joint paper with Alain Albouy published in French in 1998 (Albouy and Chenciner in Invent. Math. 131:151–184, 1998): for a non-homothetic homographic motion to exist, it is necessary that the motion takes place in an even-dimensional space. Two cases are possible: either the configuration is “central” (that is, we have a critical point of the potential among configurations with a given moment of inertia) and the space where the motion takes place is endowed with a hermitian structure, or it is “balanced” (that is, we have a critical point of the potential among configurations with a given inertia spectrum) and the motion is a new type, quasi-periodic, of relative equilibrium. Only the first type is of Kepler type and hence corresponds to the absolute minimum in Sundman’s inequality. When the space of motion is odd-dimensional, one can look for a substitute to the non-existing homographic motions: a candidate is the family of Hip-Hop solutions, which are “simple” periodic solutions naturally related to relative equilibria through Lyapunov families of quasi-periodic solutions (see Chenciner and Féjoz in Regul. Chaotic Dyn. 14(1):64–115, 2009). Finally, some words are said on the bifurcation of periodic central relative equilibria to quasi-periodic balanced ones. Keywords N-body problem · Reduction · Homographic solutions
Part of this survey is adapted from [7], a course given in Ravello in 1997.
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A. Chenciner ( ) IMCCE, 77 avenue Denfert-Rochereau, 75014 Paris, France e-mail: [email protected]
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Mathematics Subject Classification (2000) 70F10 · 70H33 · 70H12 · 37J15 Contents 1 From the side of ambient space to the side of the bodies . . . . . . . . . . . . . . 1.1 The shape of N points in an euclidean space . . . . . . . . . . . . . . . . . . 1.2 Masses as an euclidean structure on the dispositions . . . . . . . . . . . . . . 2 The n-body problem and its symmetries . . . . . .
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