English

Physics-Based Communication Compression via Lyapunov-Weighted Event-Triggered Control

Systems and Control 2025-12-04 v1 Systems and Control

Abstract

Event-Triggered Control (ETC) reduces communication overhead in networked systems by transmitting only when stability requires it. Conventional mechanisms use isotropic error thresholds (eσx\|e\| \le \sigma \|x\|), treating all directions equally. This ignores stability geometry and triggers conservatively. We propose a static directional triggering mechanism that exploits this asymmetry. By weighting errors via the Lyapunov matrix PP, we define an anisotropic half-space scaling with instantaneous energy margins: larger deviations tolerated along stable modes, strict bounds where instability threatens. We prove global asymptotic stability and exclusion of Zeno behavior. Monte Carlo simulations (N=100N=100) show 43.6\% fewer events than optimally tuned isotropic methods while achieving 2.1×2.1\times better control performance than time-varying alternatives. The mechanism functions as a runtime safety gate for learning-based controllers operating under communication constraints.

Keywords

Cite

@article{arxiv.2512.03604,
  title  = {Physics-Based Communication Compression via Lyapunov-Weighted Event-Triggered Control},
  author = {Abbas Tariverdi},
  journal= {arXiv preprint arXiv:2512.03604},
  year   = {2025}
}
R2 v1 2026-07-01T08:07:25.169Z