这篇论文把仿人机器人控制的缩放问题拆解清楚了:Humanoid Transformer配合特定训练范式,让MPKPE直接降了82%,比现有控制器强一大截。
该论文提出行为基础模型(BFM)的缩放配方,核心包括运动跟踪学习范式、策略同步量与参考动作多样性的协同、以及可扩展的Humanoid Transformer架构。在仿真和真实世界部署中,Humanoid Transformer将局部模式下的平均关键点位置误差(MPKPE)降低10%以上,全局模式下降低82%。相比现有仿人控制器,该方法显著提升了控制保真度和任务泛化能力。论文验证了BFM作为通用仿人控制基础的有效性。
Scaling Behavior Foundation Model for Humanoid Robots
Humanoid control requires natural whole-body coordination, precise real-time responses to control signals, and robust generalization across diverse environmental contexts, making it a cornerstone for generalist embodied agents. Behavior Foundation Models (BFMs) have recently emerged as a promising solution to address these challenges by leveraging large-scale behavioral data to achieve superior expressiveness, versatility and generalization. However, despite growing interest in scaling BFMs to further improve their capabilities, it remains unclear how key factors, including the learning paradigm, behavioral data and model architecture should be coordinated to enable effective scaling. In this work, we revisit the scaling recipe for BFMs and demonstrate that substantial performance gains can be achieved through the coordination of three core components: 1) the learning paradigm of motion tracking that reformulates diverse humanoid control problems as the reproduction of integrated whole-body behaviors in the global frame; 2) the strategic synergy between on-policy rollout quantity and reference motion diversity; and 3) the expressive and scalable model architecture termed Humanoid Transformer that facilitates the natural emergence of structured behavioral representations. Through extensive experiments in both simulation and real-world deployment, we demonstrate that our approach yields significant improvements in control fidelity and task generalization, reducing Mean Per-Keypoint Position Error (MPKPE) on the test set by over 10% in local mode and 82% in global mode compared with existing humanoid controllers. These results establish BFM as a principled and effective foundation for scalable and general-purpose humanoid control.