Proving periodic solutions and branches in the 2D Swift Hohenberg PDE with hexagonal and triangular symmetry

Abstract

In this article, we enforce space group symmetries in Fourier series to rigorously prove the existence of smooth, periodic solutions in partial differential equations (PDEs) with hexagonal and triangular symmetries. In particular, we provide the necessary analytical and numerical tools to construct Fourier series of functions on the hexagonal lattice. This allows one to build approximate solutions that are periodic. Moreover, to generate the periodic tiling, we can use one symmetric hexagon for D6 symmetry and two symmetric triangles for D3 symmetry. We derive a Newton-Kantorovich approach based on the construction of an approximate inverse around an approximate solution, u. More specifically, we verify a condition based on the computation of explicit bounds. The strategy for constructing u, the approximate inverse, and the computation of these bounds will be presented. We demonstrate our approach on the 2D Swift-Hohenberg PDE by proving the existence of D3 and D6 periodic solutions. We then perform proofs of branches of solutions by using Chebyshev series. The algorithmic details to perform the proof can be found on Github.