Timescale Limits of Linear-Threshold Networks
William Retnaraj, Simone Betteti, Alexander Davydov, Francesco Bullo, Jorge Cortes
TLDR
This paper explores global stability in linear-threshold networks by analyzing fast and slow limits, revealing key stability mechanisms.
Key contributions
- Introduces a one-parameter family of Linear-Threshold Networks (LTNs) preserving Lyapunov diagonal stability.
- Shows LTNs converge to a Projected Dynamical System (PDS) in the fast limit and a Hard-Selector System (HSS) in the slow limit.
- Proves global exponential stability for the fast PDS and global asymptotic stability for the slow HSS under LDS.
- Suggests resolving stability at fast/slow limits provides a path to global stability for LTNs.
Why it matters
Understanding Linear-Threshold Network (LTN) stability is vital for neural modeling and control theory. This paper simplifies stability analysis by showing that fast and slow limiting systems capture essential mechanisms. This offers a new, structurally grounded path to establish global stability for complex LTNs.
Original Abstract
Linear-threshold networks (LTNs) capture the mesoscale behavior of interacting populations of neurons and are of particular interest to control theorists due to their dynamical richness and relative ease of analysis. The aim of this paper is to advance the study of global asymptotic stability in LTNs with asymmetric neural interactions and heterogeneous dissipation under the structural Lyapunov diagonal stability (LDS) condition. To this end, we introduce a one-parameter family of LTNs that preserves the LDS condition and has a parameter-independent equilibrium set. In the fast limit, this family converges to a projected dynamical system (PDS), while in the slow limit, it converges to a discontinuous hard-selector system (HSS). Under LDS, we prove that the fast PDS limit is globally exponentially stable and that the HSS limit is globally asymptotically stable. This alignment suggests that the limiting systems capture essential mechanisms governing stability across the entire LTN family. Together with numerical evidence, these findings indicate that resolving stability at the fast and slow endpoints provides a promising and structurally grounded path toward establishing global stability for LTNs with biologically plausible recurrence and diagonal dissipation.
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