STEAM: Self-Supervised Temporal Ensemble Advantage Modeling for Real-World Robot Learning
摘要
Real-world robot learning increasingly relies on heterogeneous data, but demonstrations and rollouts often mix useful progress with stalls, corrections, and suboptimal behavior. Effective policy learning therefore requires frame-level advantages that distinguish reliable local progress from failures and regressions. We propose Self-supervised Temporal Ensemble Advantage Modeling (STEAM), a label-free method that learns such advantages from expert demonstrations. STEAM trains an ensemble of temporal-offset predictors on frame pairs within expert trajectories, using the normalized temporal offset between two frames as a self-supervised signal. Each predictor maps a frame pair to a distribution over temporal offsets, which is converted into a scalar advantage. STEAM then takes the minimum advantage across the ensemble to score mixed-quality rollout data conservatively. Across real-world bimanual towel folding, chip checkout, cola restocking, and single-arm pick-and-place tasks, STEAM identifies stalls, failures, and recoveries. When combined with CFGRL, STEAM further improves policy success rate by 59%, 54.3%, 23% and 16.2% over baselines, respectively.
引用
@article{arxiv.2606.29834,
title = {STEAM: Self-Supervised Temporal Ensemble Advantage Modeling for Real-World Robot Learning},
author = {Zhihao Liu and Qiuyi Gu and Yitao Wang and Dongming Qiao and Yixian Zhang and Shuaihang Chen and Liangzhi Shi and Tianxing Zhou and Zefang Huang and Kang Chen and Zhen Guo and Quanlu Zhang and Jincheng Yu and Xiaodan Liang and Guoliang Fan and Yu Wang and Feng Gao and Xinlei Chen and Chao Yu},
journal= {arXiv preprint arXiv:2606.29834},
year = {2026}
}