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Main Authors: Mark, Max Sobol, Liang, Jacky, Attarian, Maria, Fu, Chuyuan, Dwibedi, Debidatta, Shah, Dhruv, Kumar, Aviral
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2602.15010
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author Mark, Max Sobol
Liang, Jacky
Attarian, Maria
Fu, Chuyuan
Dwibedi, Debidatta
Shah, Dhruv
Kumar, Aviral
author_facet Mark, Max Sobol
Liang, Jacky
Attarian, Maria
Fu, Chuyuan
Dwibedi, Debidatta
Shah, Dhruv
Kumar, Aviral
contents Many robot tasks require attending to the history of past observations. For example, finding an item in a room requires remembering which places have already been searched. However, the best-performing robot policies typically condition only on the current observation, limiting their applicability to such tasks. Naively conditioning on past observations often fails due to spurious correlations: policies latch onto incidental features of training histories that do not generalize to out-of-distribution trajectories upon deployment. We analyze why policies latch onto these spurious correlations and find that this problem stems from limited coverage over the space of possible histories during training, which grows exponentially with horizon. Existing regularization techniques provide inconsistent benefits across tasks, as they do not fundamentally address this coverage problem. Motivated by these findings, we propose Big Picture Policies (BPP), an approach that conditions on a minimal set of meaningful keyframes detected by a vision-language model. By projecting diverse rollouts onto a compact set of task-relevant events, BPP substantially reduces distribution shift between training and deployment, without sacrificing expressivity. We evaluate BPP on four challenging real-world manipulation tasks and three simulation tasks, all requiring history conditioning. BPP achieves 70% higher success rates than the best comparison on real-world evaluations. Videos are available at https://bigpicturepolicies.github.io/
format Preprint
id arxiv_https___arxiv_org_abs_2602_15010
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle BPP: Long-Context Robot Imitation Learning by Focusing on Key History Frames
Mark, Max Sobol
Liang, Jacky
Attarian, Maria
Fu, Chuyuan
Dwibedi, Debidatta
Shah, Dhruv
Kumar, Aviral
Robotics
Machine Learning
Many robot tasks require attending to the history of past observations. For example, finding an item in a room requires remembering which places have already been searched. However, the best-performing robot policies typically condition only on the current observation, limiting their applicability to such tasks. Naively conditioning on past observations often fails due to spurious correlations: policies latch onto incidental features of training histories that do not generalize to out-of-distribution trajectories upon deployment. We analyze why policies latch onto these spurious correlations and find that this problem stems from limited coverage over the space of possible histories during training, which grows exponentially with horizon. Existing regularization techniques provide inconsistent benefits across tasks, as they do not fundamentally address this coverage problem. Motivated by these findings, we propose Big Picture Policies (BPP), an approach that conditions on a minimal set of meaningful keyframes detected by a vision-language model. By projecting diverse rollouts onto a compact set of task-relevant events, BPP substantially reduces distribution shift between training and deployment, without sacrificing expressivity. We evaluate BPP on four challenging real-world manipulation tasks and three simulation tasks, all requiring history conditioning. BPP achieves 70% higher success rates than the best comparison on real-world evaluations. Videos are available at https://bigpicturepolicies.github.io/
title BPP: Long-Context Robot Imitation Learning by Focusing on Key History Frames
topic Robotics
Machine Learning
url https://arxiv.org/abs/2602.15010