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Autori principali: Rusiecki, Szymon, Morales, Cecilia, Störy, Pia, Elenberg, Kimberly, Weiss, Leonard, Dubrawski, Artur
Natura: Preprint
Pubblicazione: 2026
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Accesso online:https://arxiv.org/abs/2604.21568
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author Rusiecki, Szymon
Morales, Cecilia
Störy, Pia
Elenberg, Kimberly
Weiss, Leonard
Dubrawski, Artur
author_facet Rusiecki, Szymon
Morales, Cecilia
Störy, Pia
Elenberg, Kimberly
Weiss, Leonard
Dubrawski, Artur
contents Autonomous robots deployed in mass casualty incidents (MCI) face the challenge of making critical decisions based on incomplete and noisy perceptual data. We present an autonomous robotic system for casualty assessment that fuses outputs from multiple vision-based algorithms, estimating signs of severe hemorrhage, visible trauma, or physical alertness, into a coherent triage assessment. At the core of our system is a Bayesian network, constructed from expert-defined rules, which enables probabilistic reasoning about a casualty's condition even with missing or conflicting sensory inputs. The system, evaluated during the DARPA Triage Challenge (DTC) in realistic MCI scenarios involving 11 and 9 casualties, demonstrated a nearly three-fold improvement in physiological assessment accuracy (from 15\% to 42\% and 19\% to 46\%) compared to a vision-only baseline. More importantly, overall triage accuracy increased from 14\% to 53\%, while the diagnostic coverage of the system expanded from 31\% to 95\% of cases. These results demonstrate that integrating expert-guided probabilistic reasoning with advanced vision-based sensing can significantly enhance the reliability and decision-making capabilities of autonomous systems in critical real-world applications.
format Preprint
id arxiv_https___arxiv_org_abs_2604_21568
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle A Bayesian Reasoning Framework for Robotic Systems in Autonomous Casualty Triage
Rusiecki, Szymon
Morales, Cecilia
Störy, Pia
Elenberg, Kimberly
Weiss, Leonard
Dubrawski, Artur
Robotics
Autonomous robots deployed in mass casualty incidents (MCI) face the challenge of making critical decisions based on incomplete and noisy perceptual data. We present an autonomous robotic system for casualty assessment that fuses outputs from multiple vision-based algorithms, estimating signs of severe hemorrhage, visible trauma, or physical alertness, into a coherent triage assessment. At the core of our system is a Bayesian network, constructed from expert-defined rules, which enables probabilistic reasoning about a casualty's condition even with missing or conflicting sensory inputs. The system, evaluated during the DARPA Triage Challenge (DTC) in realistic MCI scenarios involving 11 and 9 casualties, demonstrated a nearly three-fold improvement in physiological assessment accuracy (from 15\% to 42\% and 19\% to 46\%) compared to a vision-only baseline. More importantly, overall triage accuracy increased from 14\% to 53\%, while the diagnostic coverage of the system expanded from 31\% to 95\% of cases. These results demonstrate that integrating expert-guided probabilistic reasoning with advanced vision-based sensing can significantly enhance the reliability and decision-making capabilities of autonomous systems in critical real-world applications.
title A Bayesian Reasoning Framework for Robotic Systems in Autonomous Casualty Triage
topic Robotics
url https://arxiv.org/abs/2604.21568