SPIRAL WAVE MEANDER AND SYMMETRY OF THE PLANE

Abstract

We present a general group-theoretic approach that explains the main qualitative features of the meander of spiral wave solutions on the plane. The approach is based on the well-known space reduction method and is used to separate the motions in the system into superposition of those ‘along’ orbits of the Euclidean symmetry group, and ‘across’ the group orbits. It can be interpreted as passing to a reference frame attached to the spiral wave’s tip. The system of ODEs governing the tip movement is obtained. It is the system that describes the movements along the group orbits. The motions across the group orbits are described by a PDE which lacks the Euclidean symmetry. Consequences of the Euclidean symmetry on the spiral wave dynamics are discussed. In particular, we explicitly derive the model system for bifurcation from rigid to biperiodic rotation, suggested earlier by Barkley [1994] from a priori symmetry considerations.