Activation Saturation and Floquet Spectrum Collapse in Neural ODEs

Abstract

We prove that activation saturation imposes a structural dynamical limitation on autonomous Neural ODEs h=fθ(h) with saturating activations (, sigmoid, etc.): if q hidden layers of the MLP fθ satisfy |σ'|δ on a region~U, the input Jacobian is attenuated as Dfθ(x) C(U) (for activations with x|σ'(x)| 1, e.g.\ and sigmoid, this reduces to CWδq), forcing every Floquet (Lyapunov) exponen along any T-periodic orbit γ⊂ U into the interval [-C(U),\;C(U)]. This is a collapse of the Floquet spectrum: as saturation deepens (δ 0), all exponents are driven to zero, limiting both strong contraction and chaotic sensitivity. The obstruction is structural -- it constrains the learned vector field at inference time, independent of training quality. As a secondary contribution, for activations with σ'>0, a saturation-weighted spectral factorisation yields a refined bound C(U) C(U) whose improvement is amplified exponentially in~T at the flow level. All results are numerically illustrated on the Stuart--Landau oscillator; the bounds provide a theoretical explanation for the empirically observed failure of -NODEs on the Morris--Lecar neuron model.