Discrete Euler-Poincar\'e and Lie-Poisson Equations
Abstract
In this paper, discrete analogues of Euler-Poincar\'e and Lie-Poisson reduction theory are developed for systems on finite dimensional Lie groups G with Lagrangians L:TG R that are G-invariant. These discrete equations provide ``reduced'' numerical algorithms which manifestly preserve the symplectic structure. The manifold G × G is used as an approximation of TG, and a discrete Langragian L:G × G R is construced in such a way that the G-invariance property is preserved. Reduction by G results in new ``variational'' principle for the reduced Lagrangian :G R, and provides the discrete Euler-Poincar\'e (DEP) equations. Reconstruction of these equations recovers the discrete Euler-Lagrange equations developed in MPS,WM which are naturally symplectic-momentum algorithms. Furthermore, the solution of the DEP algorithm immediately leads to a discrete Lie-Poisson (DLP) algorithm. It is shown that when G=SO (n), the DEP and DLP algorithms for a particular choice of the discrete Lagrangian L are equivalent to the Moser-Veselov scheme for the generalized rigid body. %As an application, a reduced symplectic integrator for two dimensional %hydrodynamics is constructed using the SU(n) approximation to the volume %preserving diffeomorphism group of T2.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.