Regularity and Stability Properties of Selective SSMs with Discontinuous Gating

Abstract

Deep selective State-Space Models (SSMs), whose state-space parameters are modulated online by a selection signal, offer significant expressive power but pose challenges for stability analysis, especially under discontinuous gating. We study continuous-time selective SSMs through the lenses of passivity and Input-to-State Stability (ISS), explicitly distinguishing the selection schedule x(·) from the driving (port) input u(·). First, we show that state-strict dissipativity (β>0) together with quadratic bounds on a storage functional implies exponential decay of homogeneous trajectories (u 0), yielding exponential forgetting. Second, by freezing the selection (x(t) 0) we obtain a passive LTV input-output subsystem and prove that its minimal available storage is necessarily quadratic, Va,0(t,h)=12hH Q0(t)h, with Q0 ∈ AUCloc, accommodating discontinuities induced by gating. Third, under the strong hypothesis that a single quadratic storage certifies passivity uniformly over all admissible selection schedules, we derive a parametric LMI and universal kernel constraints on gating, formalizing an "irreversible forgetting" structure. Finally, we give sufficient conditions for global ISS with respect to the port input u(·), uniformly over admissible selection schedules, and we validate the main predictions in targeted simulation studies.