Walking with Terrain Reconstruction: Learning to Traverse Risky Sparse Footholds

Traversing risky terrains with sparse footholds presents significant challenges for legged robots, requiring precise foot placement in safe areas. Current learning-based methods often rely on implicit feature representations without supervising physically significant estimation targets. This limits the policy's ability to fully understand complex terrain structures, which is critical for generating accurate actions. In this paper, we utilize end-to-end reinforcement learning to traverse risky terrains with high sparsity and randomness. Our approach integrates proprioception with single-view depth images to reconstruct robot's local terrain, enabling a more comprehensive representation of terrain information. Meanwhile, by incorporating implicit and explicit estimations of the robot's state and its surroundings, we improve policy's environmental understanding, leading to more precise actions. We deploy the proposed framework on a low-cost quadrupedal robot, achieving agile and adaptive locomotion across various challenging terrains and demonstrating outstanding performance in real-world scenarios. Video at: http://youtu.be/ReQAR4D6tuc.