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Main Authors: Liu, Yan, Yu, Tao, Song, Haolin, Zhu, Hongbo, Hu, Nianzong, Hao, Yuzhi, Yao, Xiuyong, Zang, Xizhe, Chen, Hua, Zhao, Jie
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2601.10365
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author Liu, Yan
Yu, Tao
Song, Haolin
Zhu, Hongbo
Hu, Nianzong
Hao, Yuzhi
Yao, Xiuyong
Zang, Xizhe
Chen, Hua
Zhao, Jie
author_facet Liu, Yan
Yu, Tao
Song, Haolin
Zhu, Hongbo
Hu, Nianzong
Hao, Yuzhi
Yao, Xiuyong
Zang, Xizhe
Chen, Hua
Zhao, Jie
contents Running up stairs is effortless for humans but remains extremely challenging for humanoid robots due to the simultaneous requirements of high agility and strict stability. Model-free reinforcement learning (RL) can generate dynamic locomotion, yet implicit stability rewards and heavy reliance on task-specific reward shaping tend to result in unsafe behaviors, especially on stairs; conversely, model-based foothold planners encode contact feasibility and stability structure, but enforcing their hard constraints often induces conservative motion that limits speed. We present FastStair, a planner-guided, multi-stage learning framework that reconciles these complementary strengths to achieve fast and stable stair ascent. FastStair integrates a parallel model-based foothold planner into the RL training loop to bias exploration toward dynamically feasible contacts and to pretrain a safety-focused base policy. To mitigate planner-induced conservatism and the discrepancy between low- and high-speed action distributions, the base policy was fine-tuned into speed-specialized experts and then integrated via Low-Rank Adaptation (LoRA) to enable smooth operation across the full commanded-speed range. We deploy the resulting controller on the Oli humanoid robot, achieving stable stair ascent at commanded speeds up to 1.65 m/s and traversing a 33-step spiral staircase (17 cm rise per step) in 12 s, demonstrating robust high-speed performance on long staircases. Notably, the proposed approach served as the champion solution in the Canton Tower Robot Run Up Competition.
format Preprint
id arxiv_https___arxiv_org_abs_2601_10365
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle FastStair: Learning to Run Up Stairs with Humanoid Robots
Liu, Yan
Yu, Tao
Song, Haolin
Zhu, Hongbo
Hu, Nianzong
Hao, Yuzhi
Yao, Xiuyong
Zang, Xizhe
Chen, Hua
Zhao, Jie
Robotics
Running up stairs is effortless for humans but remains extremely challenging for humanoid robots due to the simultaneous requirements of high agility and strict stability. Model-free reinforcement learning (RL) can generate dynamic locomotion, yet implicit stability rewards and heavy reliance on task-specific reward shaping tend to result in unsafe behaviors, especially on stairs; conversely, model-based foothold planners encode contact feasibility and stability structure, but enforcing their hard constraints often induces conservative motion that limits speed. We present FastStair, a planner-guided, multi-stage learning framework that reconciles these complementary strengths to achieve fast and stable stair ascent. FastStair integrates a parallel model-based foothold planner into the RL training loop to bias exploration toward dynamically feasible contacts and to pretrain a safety-focused base policy. To mitigate planner-induced conservatism and the discrepancy between low- and high-speed action distributions, the base policy was fine-tuned into speed-specialized experts and then integrated via Low-Rank Adaptation (LoRA) to enable smooth operation across the full commanded-speed range. We deploy the resulting controller on the Oli humanoid robot, achieving stable stair ascent at commanded speeds up to 1.65 m/s and traversing a 33-step spiral staircase (17 cm rise per step) in 12 s, demonstrating robust high-speed performance on long staircases. Notably, the proposed approach served as the champion solution in the Canton Tower Robot Run Up Competition.
title FastStair: Learning to Run Up Stairs with Humanoid Robots
topic Robotics
url https://arxiv.org/abs/2601.10365