On the Existence and Stability of Fast Traveling Waves in a Doubly-Diffusive FitzHugh-Nagumo System

TL;DR

This paper proves the existence and stability of fast traveling waves in a symmetric doubly-diffusive FitzHugh-Nagumo system using geometric singular perturbation theory and the Maslov index, revealing unique non-monotonic behavior.

Contribution

It introduces a novel stability analysis of fast traveling pulses in a symmetric FitzHugh-Nagumo system using the Maslov index and geometric singular perturbation theory.

Findings

Existence of stable fast traveling pulses established.

The Maslov index tracks unstable eigenvalues and reveals non-monotonicity.

The transition from fast to slow dynamics is carefully analyzed.

Abstract

The FitzHugh-Nagumo equation, which was derived as a simplification of the Hodgkin-Huxley model for nerve impulse propagation, has been extensively studied as a paradigmatic activator-inhibitor system. We consider the version of this system in which two agents diffuse at an equal rate. Using geometric singular perturbation theory, we prove the existence and stability of fast traveling pulses. The stability proof makes use of the Maslov index--an invariant of symplectic geometry--to count unstable eigenvalues for the linearization about the wave. The calculation of the Maslov index is carried out by tracking the evolution of the unstable manifold of the rest state using the timescale separation. This entails a careful consideration of how the transition from fast to slow dynamics occurs in the tangent bundle over the wave. Finally, we observe in the calculation that the Maslov index lacks monotonicity in the spatial parameter, which distinguishes this application of the Maslov index from similar analyses of Hamiltonian systems.