English

Distill-Belief: Closed-Loop Inverse Source Localization and Characterization in Physical Fields

Artificial Intelligence 2026-04-30 v1

Abstract

{Closed-loop inverse source localization and characterization (ISLC) requires a mobile agent to select measurements that localize sources and infer latent field parameters under strict time constraints.} {The core challenge lies in the belief-space objective: valid uncertainty estimation requires expensive Bayesian inference, whereas using fast learned belief model leads to reward hacking, in which the policy exploits approximation errors rather than actually reducing uncertainty.} {We propose \textbf{Distill-Belief}, a teacher--student framework that decouples correctness from efficiency. A Bayes-correct particle-filter teacher maintains the posterior and supplies a dense information-gain signal, while a compact student distills the posterior into belief statistics for control and an uncertainty certificate for stopping. At deployment, only the student is used, yielding constant per-step cost.} {Experiments on seven field modalities and two stress tests show that Distill-Belief consistently reduces sensing cost and improves success, posterior contraction, and estimation accuracy over baselines, while mitigating reward hacking.}

Keywords

Cite

@article{arxiv.2604.26095,
  title  = {Distill-Belief: Closed-Loop Inverse Source Localization and Characterization in Physical Fields},
  author = {Yiwei Shi and Zixing Song and Mengyue Yang and Cunjia Liu and Weiru Liu},
  journal= {arXiv preprint arXiv:2604.26095},
  year   = {2026}
}
R2 v1 2026-07-01T12:40:07.877Z