{"ID":5937756,"CreatedAt":"2026-07-07T03:14:33.014478982Z","UpdatedAt":"2026-07-08T17:29:38.726141074Z","DeletedAt":null,"paper_url":"https://arxiv.org/abs/2607.04426","arxiv_id":"2607.04426","title":"ACE-Brain-0.5: A Unified Embodied Foundational Model for Physical Agentic AI","abstract":"Embodied AI is moving from isolated perception or action modules toward physical agents that understand, plan under goals, act through robot bodies, monitor progress, and improve from experience. Existing systems address this loop only in parts: end-to-end policies generate actions but often lack spatial reasoning, planning, and execution assessment, while robot-agent systems orchestrate tools or specialists but do not learn a shared representation. This fragmentation limits general Physical Agentic AI. We present ACE-Brain-0.5, a unified embodied foundation model that organizes robot intelligence into five coupled functions: spatial perception, decision making, embodied interaction, self-monitoring, and self-improvement. Built on ACE-Brain-0, which established spatial intelligence as a shared scaffold across robot platforms, ACE-Brain-0.5 extends an understanding-centric model into a closed-loop foundation model. A single 8B backbone instantiates the first four functions: grounding objects and affordances, reasoning over 3D and egocentric spatial relations, decomposing instructions into subgoals, generating navigation and manipulation actions, and estimating progress for verification and recovery. To unify these capabilities without cross-task interference, we introduce SSR+, which extends Scaffold-Specialize-Reconcile with a Reactivate stage after task-vector merging. The fifth function, self-improvement, is realized by a companion framework that updates external execution state, including task schemas, spatial memory, and failure-recovery cases, from rollouts. Across fifteen benchmarks, ACE-Brain-0.5 improves over ACE-Brain-0 on 14 of 18 spatial perception and grounding benchmarks, achieves competitive navigation and manipulation performance, and provides strong progress estimation in ID and OOD settings. Together, these results mark an early step toward general Physical Agentic AI.","short_abstract":"Embodied AI is moving from isolated perception or action modules toward physical agents that understand, plan under goals, act through robot bodies, monitor progress, and improve from experience. Existing systems address this loop only in parts: end-to-end policies generate actions but often lack spatial reasoning, pla...","url_abs":"https://arxiv.org/abs/2607.04426","url_pdf":"https://arxiv.org/pdf/2607.04426v1","authors":"[\"ACE-Brain Team\",\":\",\"Ziyang Gong\",\"Haoming Gu\",\"Zehang Luo\",\"Tianyi Zhang\",\"Tao Tao\",\"Yixiao Chi\",\"Zhe Liu\",\"Lingsi Zhu\",\"Jingyuan Liu\",\"Anke Tang\",\"Songze Li\",\"Yilun Kong\",\"Ningjing Liu\",\"Tianyu Zhu\",\"Yunpeng Qing\",\"Shuang Luo\",\"Xiang Liu\",\"Shi Fu\",\"Dawei Nie\",\"Sixiang Liu\",\"Zhexi Wen\",\"Feng Pan\",\"Xiaofeng Wang\",\"Zhi Hou\",\"Chunxiao Liu\",\"Xue Yang\",\"Junchi Yan\",\"Hengshuang Zhao\",\"Dacheng Tao\",\"Xiaogang Wang\"]","published":"2026-07-05T17:43:06Z","proceeding":"cs.RO","tasks":"[\"cs.RO\"]","methods":"[\"Generative Adversarial Network\"]","has_code":false}
