English

Interception-Driven Inverse Reachability for Engagement Zone Construction

Systems and Control 2026-07-03 v1

Abstract

In contested environments, autonomous vehicles may need to plan around adversarial pursuers whose launch locations are unknown. This paper presents an interception-driven inverse-reachability framework for inferring a feasible pursuer launch region directly from observed interception events for a single pursuer. Each interception induces a geometric constraint on the unknown launch location, and intersecting these constraints yields a bounded set guaranteed to contain the true origin under maximum-capability assumptions. Mapping this inferred set through the pursuer reachable region produces deterministic engagement zones with an explicit worst-case safety interpretation. A probabilistic extension models uncertainty in the pursuer launch location and yields graded engagement-risk fields for risk-aware planning. To accelerate localization, we introduce an information-driven planner for sacrificial agents that selects trajectories to maximize expected contraction of the feasible launch region. Monte Carlo simulations show that the proposed framework rapidly reduces launch-location uncertainty and enables substantially shorter safe trajectories after only a small number of sacrificial deployments.

Cite

@article{arxiv.2607.03554,
  title  = {Interception-Driven Inverse Reachability for Engagement Zone Construction},
  author = {Grant Stagg and Cameron K. Peterson and Alexander Von Moll and Isaac Weintraub},
  journal= {arXiv preprint arXiv:2607.03554},
  year   = {2026}
}