From constants of motion to superposition rules for Lie-Hamilton systems

A Lie system is a nonautonomous system of first-order differential equations possessing a superposition rule, i.e. a map expressing its general solution in terms of a generic finite family of particular solutions and some constants. Lie-Hamilton systems form a subclass of Lie systems whose dynamics is governed by a curve in a finite-dimensional real Lie algebra of functions on a Poisson manifold. It is shown that Lie-Hamilton systems are naturally endowed with a Poisson coalgebra structure. This allows us to devise methods to derive in an algebraic way their constants of motion and superposition rules. We illustrate our methods by studying Kummer-Schwarz equations, Riccati equations, Ermakov systems and Smorodinsky-Winternitz systems with time-dependent frequency.

Article: 
From constants of motion to superposition rules for Lie-Hamilton systems
Authors: 
A. Ballesteros, J.F. Cariñena, F.J. Herranz, J. de Lucas, C. Sardón
Journal: 
Arxiv
Year: 
2013
URL: 
http://arxiv.org/abs/1305.6272