Saved in:
Bibliographic Details
Main Authors: Zheng, Ziang, Zhan, Guojian, Liu, Shiqi, Lyu, Yao, Zhang, Tao, Li, Shengbo Eben
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2507.01243
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866913922181758976
author Zheng, Ziang
Zhan, Guojian
Liu, Shiqi
Lyu, Yao
Zhang, Tao
Li, Shengbo Eben
author_facet Zheng, Ziang
Zhan, Guojian
Liu, Shiqi
Lyu, Yao
Zhang, Tao
Li, Shengbo Eben
contents Reinforcement learning (RL) has shown great potential in enabling quadruped robots to perform agile locomotion. However, directly training policies to simultaneously handle dual extreme challenges, i.e., extreme underactuation and extreme terrains, as in monopedal hopping tasks, remains highly challenging due to unstable early-stage interactions and unreliable reward feedback. To address this, we propose JumpER (jump-start reinforcement learning via self-evolving priors), an RL training framework that structures policy learning into multiple stages of increasing complexity. By dynamically generating self-evolving priors through iterative bootstrapping of previously learned policies, JumpER progressively refines and enhances guidance, thereby stabilizing exploration and policy optimization without relying on external expert priors or handcrafted reward shaping. Specifically, when integrated with a structured three-stage curriculum that incrementally evolves action modality, observation space, and task objective, JumpER enables quadruped robots to achieve robust monopedal hopping on unpredictable terrains for the first time. Remarkably, the resulting policy effectively handles challenging scenarios that traditional methods struggle to conquer, including wide gaps up to 60 cm, irregularly spaced stairs, and stepping stones with distances varying from 15 cm to 35 cm. JumpER thus provides a principled and scalable approach for addressing locomotion tasks under the dual challenges of extreme underactuation and extreme terrains.
format Preprint
id arxiv_https___arxiv_org_abs_2507_01243
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Jump-Start Reinforcement Learning with Self-Evolving Priors for Extreme Monopedal Locomotion
Zheng, Ziang
Zhan, Guojian
Liu, Shiqi
Lyu, Yao
Zhang, Tao
Li, Shengbo Eben
Robotics
Machine Learning
Reinforcement learning (RL) has shown great potential in enabling quadruped robots to perform agile locomotion. However, directly training policies to simultaneously handle dual extreme challenges, i.e., extreme underactuation and extreme terrains, as in monopedal hopping tasks, remains highly challenging due to unstable early-stage interactions and unreliable reward feedback. To address this, we propose JumpER (jump-start reinforcement learning via self-evolving priors), an RL training framework that structures policy learning into multiple stages of increasing complexity. By dynamically generating self-evolving priors through iterative bootstrapping of previously learned policies, JumpER progressively refines and enhances guidance, thereby stabilizing exploration and policy optimization without relying on external expert priors or handcrafted reward shaping. Specifically, when integrated with a structured three-stage curriculum that incrementally evolves action modality, observation space, and task objective, JumpER enables quadruped robots to achieve robust monopedal hopping on unpredictable terrains for the first time. Remarkably, the resulting policy effectively handles challenging scenarios that traditional methods struggle to conquer, including wide gaps up to 60 cm, irregularly spaced stairs, and stepping stones with distances varying from 15 cm to 35 cm. JumpER thus provides a principled and scalable approach for addressing locomotion tasks under the dual challenges of extreme underactuation and extreme terrains.
title Jump-Start Reinforcement Learning with Self-Evolving Priors for Extreme Monopedal Locomotion
topic Robotics
Machine Learning
url https://arxiv.org/abs/2507.01243