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Main Authors: Cui, Tiehan, Liu, Peipei, Mao, Yanxu, Liu, Congying, Xing, Mingzhe, You, Datao
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2605.09387
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author Cui, Tiehan
Liu, Peipei
Mao, Yanxu
Liu, Congying
Xing, Mingzhe
You, Datao
author_facet Cui, Tiehan
Liu, Peipei
Mao, Yanxu
Liu, Congying
Xing, Mingzhe
You, Datao
contents While Large Language Models (LLMs) have catalyzed progress in embodied intelligence, a fundamental gap between their inherent probabilistic uncertainty and the strict determinism and verifiable safety required in the physical world. To mitigate this gap, this paper introduces NEXUS, a modular framework designed for continual learning in embodied agents. Different from prior works that treat symbolic artifacts merely as static interfaces, NEXUS leverages them for symbolic grounding and knowledge evolution. The framework explicitly decouples physical feasibility from safety specifications: capability of agents is improved through closed-loop execution feedback, while probabilistic risk assessments are grounded into deterministic hard constraints to establish a rigorous pre-action defense. Experiments on SafeAgentBench demonstrate that NEXUS achieves superior task success rates while effectively refusing unsafe instructions, exhibiting robust defense against adversarial attacks, and progressively improving planning efficiency through knowledge accumulation.
format Preprint
id arxiv_https___arxiv_org_abs_2605_09387
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle NEXUS: Continual Learning of Symbolic Constraints for Safe and Robust Embodied Planning
Cui, Tiehan
Liu, Peipei
Mao, Yanxu
Liu, Congying
Xing, Mingzhe
You, Datao
Artificial Intelligence
Robotics
While Large Language Models (LLMs) have catalyzed progress in embodied intelligence, a fundamental gap between their inherent probabilistic uncertainty and the strict determinism and verifiable safety required in the physical world. To mitigate this gap, this paper introduces NEXUS, a modular framework designed for continual learning in embodied agents. Different from prior works that treat symbolic artifacts merely as static interfaces, NEXUS leverages them for symbolic grounding and knowledge evolution. The framework explicitly decouples physical feasibility from safety specifications: capability of agents is improved through closed-loop execution feedback, while probabilistic risk assessments are grounded into deterministic hard constraints to establish a rigorous pre-action defense. Experiments on SafeAgentBench demonstrate that NEXUS achieves superior task success rates while effectively refusing unsafe instructions, exhibiting robust defense against adversarial attacks, and progressively improving planning efficiency through knowledge accumulation.
title NEXUS: Continual Learning of Symbolic Constraints for Safe and Robust Embodied Planning
topic Artificial Intelligence
Robotics
url https://arxiv.org/abs/2605.09387