Continuous and discrete damping reduction for systems with quadratic interaction (1809.05532v1)

Abstract: We study the connection between Lagrangian and Hamiltonian descriptions of closed/open dynamics, for a collection of particles with quadratic interaction (closed system) and a sub-collection of particles with linear damping (open system). We consider both continuous and discrete versions of mechanics. We define the Damping Reduction as the mapping from the equations of motion of the closed system to those of the open one. As variational instruments for the obtention of these equations we use the Hamilton's principle (closed dynamics) and Lagrange-d'Alembert principle (open dynamics). We establish the commutativity of the branches Legendre transform + Damping Reduction and Damping Reduction+Legendre transform, where the Legendre transform is the usual mapping between Lagrangian and Hamiltonian mechanics. At a discrete level, this commutativity provides interesting insight about the resulting integrators. More concretely, Discrete Damping Reduction yields particular numerical schemes for linearly damped systems which are not symplectic anymore, but preserve some of the features of their symplectic counterparts from which they proceed (for instance the semi-implicitness in some cases). The theoretical results are illustrated with the examples of the heat bath and transmission lines. In the latter case some simulations are displayed, showing a better performance of the integrators with variational origin.