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arxiv: 2508.17547 · v1 · pith:P6IV7O7Vnew · submitted 2025-08-24 · 💻 cs.RO · cs.AI· cs.LG

LodeStar: Long-horizon Dexterity via Synthetic Data Augmentation from Human Demonstrations

classification 💻 cs.RO cs.AIcs.LG
keywords long-horizonmanipulationtasksdatasetsdexteritylearningskillsapproach
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Developing robotic systems capable of robustly executing long-horizon manipulation tasks with human-level dexterity is challenging, as such tasks require both physical dexterity and seamless sequencing of manipulation skills while robustly handling environment variations. While imitation learning offers a promising approach, acquiring comprehensive datasets is resource-intensive. In this work, we propose a learning framework and system LodeStar that automatically decomposes task demonstrations into semantically meaningful skills using off-the-shelf foundation models, and generates diverse synthetic demonstration datasets from a few human demos through reinforcement learning. These sim-augmented datasets enable robust skill training, with a Skill Routing Transformer (SRT) policy effectively chaining the learned skills together to execute complex long-horizon manipulation tasks. Experimental evaluations on three challenging real-world long-horizon dexterous manipulation tasks demonstrate that our approach significantly improves task performance and robustness compared to previous baselines. Videos are available at lodestar-robot.github.io.

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  1. EgoEngine: From Egocentric Human Videos to High-Fidelity Dexterous Robot Demonstrations

    cs.RO 2026-06 unverdicted novelty 7.0

    EgoEngine transforms egocentric human videos into high-fidelity robot data enabling zero-shot visuomotor dexterous policy learning without real-robot demonstrations.