机器人
适应(眼睛)
计算机科学
适应性
任务(项目管理)
人机交互
人工智能
模仿
一般化
可扩展性
具身认知
复制
运动(物理)
任务分析
空格(标点符号)
范围(计算机科学)
人机交互
基于行为的机器人学
机器人学习
自然语言
认知机器人学
自然语言理解
机器人学
机器人运动学
作者
Xi Chen,Yuan Gao,Hangxin Liu,Fangkai Yang,Ali Ghadirzadeh,Jun Yang,Bo Liang,Chongjie Zhang,Tin Lun Lam,Song-Chun Zhu
出处
期刊:Science robotics
[American Association for the Advancement of Science]
日期:2026-03-18
卷期号:11 (112): eadv2250-eadv2250
标识
DOI:10.1126/scirobotics.adv2250
摘要
Imitation learning (IL) has succeeded in enabling robots to perform new tasks by learning from demonstrations. However, its success is often constrained by the need for direct skill mappings between a learner and a demonstrator under identical conditions, limiting its adaptability to diverse environments and generalization across robots with different physical embodiments. To address these challenges, we introduce the Intention-Aligned Imitation Learning (IAIL) framework, a behavior adaptation approach that extends the conventional scope of IL by enabling robots to reproduce motions demonstrated by heterogeneous peers, even in previously unseen situations. Inspired by human cultural learning, IAIL aligns and adapts robot motions on the basis of high-level intentions annotated in natural language rather than by directly copying motor movements. This alignment is achieved by constructing a shared intention space that connects robot-generated motions with linguistic annotations, enabling inference-time behavior adaptation across diverse embodiments and environmental contexts. The framework further supports scalable task allocation in heterogeneous robot teams by leveraging differences in capabilities and constraints. We validated IAIL through real-world experiments involving seven distinct robots performing multistep collaboration tasks across 30 scenarios. Our results demonstrate that IAIL enables robust intention-aligned behavior adaptation across variations in embodiment, motion modality, and task configuration. These capabilities enable flexible behavior transfer across heterogeneous robots and support resilient, autonomous multirobot systems for reliable real-world collaboration.
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