Fold singularities of nonsmooth and slow-fast dynamical systems -- equivalence by the hidden dynamics approach

TL;DR

This paper reveals a deep connection between two-fold singularities in nonsmooth systems and folded singularities in slow-fast systems, showing they are equivalent through hidden dynamics when smoothing or blowing up the discontinuity.

Contribution

It demonstrates that two-fold and folded singularities are related via hidden dynamics, requiring nonlinear terms for structural stability and the equivalence to hold.

Findings

Two-fold and folded singularities are equivalent through hidden dynamics.

Nonlinear 'hidden' terms are essential for the structural stability of the transformation.

The approach unifies nonsmooth and smooth slow-fast dynamical systems analysis.

Abstract

The {\it two-fold singularity} has played a significant role in our understanding of uniqueness and stability in piecewise smooth dynamical systems. When a vector field is discontinuous at some hypersurface, it can become tangent to that surface from one side or the other, and tangency from both sides creates a two-fold singularity. The flow this creates bears a superficial resemblance to so-called {\it folded singularities} in (smooth) slow-fast systems, which arise at the intersection of attractive and repelling branches of slow invariant manifolds, important in the local study of canards and mixed mode oscillations. Here we show that these two singularities are intimately related. When the discontinuity in a piecewise smooth system is blown up or smoothed out at a two-fold singularity, the resulting system can be mapped onto a folded singularity. The result is not obvious, however, since it requires the presence of nonlinear or `hidden' terms at the discontinuity, which turn out to be necessary for structural stability of the blow up (or smoothing), and necessary for mapping to the folded singularity.