Moving Frames and Noether's Finite Difference Conservation Laws I

TL;DR

This paper develops a framework using discrete moving frames and difference invariants to compute Euler-Lagrange equations and Noether's conservation laws for invariant difference equations, simplifying solutions and aiding geometric integrator design.

Contribution

Introduction of difference moving frames and invariants for invariant difference equations, enabling direct calculation of Euler-Lagrange equations and conservation laws, with applications to geometric integrators.

Findings

Difference moving frames simplify solving invariant difference equations.

Conservation laws can be expressed using difference invariants and frames.

Application to discretized Euler's elastica demonstrates the method's effectiveness.

Abstract

We consider the calculation of Euler--Lagrange systems of ordinary difference equations, including the difference Noether's Theorem, in the light of the recently-developed calculus of difference invariants and discrete moving frames. We introduce the difference moving frame, a natural discrete moving frame that is adapted to difference equations by prolongation conditions. For any Lagrangian that is invariant under a Lie group action on the space of dependent variables, we show that the Euler--Lagrange equations can be calculated directly in terms of the invariants of the group action. Furthermore, Noether's conservation laws can be written in terms of a difference moving frame and the invariants. We show that this form of the laws can significantly ease the problem of solving the Euler--Lagrange equations, and we also show how to use a difference frame to integrate Lie group invariant difference equations. In this Part I, we illustrate the theory by applications to Lagrangians invariant under various solvable Lie groups. The theory is also generalized to deal with variational symmetries that do not leave the Lagrangian invariant. Apart from the study of systems that are inherently discrete, one significant application is to obtain geometric (variational) integrators that have finite difference approximations of the continuous conservation laws embedded \textit{a priori}. This is achieved by taking an invariant finite difference Lagrangian in which the discrete invariants have the correct continuum limit to their smooth counterparts. We show the calculations for a discretization of the Lagrangian for Euler's elastica, and compare our discrete solution to that of its smooth continuum limit.