BEGIN:VCALENDAR VERSION:2.0 PRODID:Linklings LLC BEGIN:VTIMEZONE TZID:Asia/Tokyo X-LIC-LOCATION:Asia/Tokyo BEGIN:STANDARD TZOFFSETFROM:+0900 TZOFFSETTO:+0900 TZNAME:JST DTSTART:18871231T000000 END:STANDARD END:VTIMEZONE BEGIN:VEVENT DTSTAMP:20250110T023312Z LOCATION:Hall B7 (1)\, B Block\, Level 7 DTSTART;TZID=Asia/Tokyo:20241204T145600 DTEND;TZID=Asia/Tokyo:20241204T150800 UID:siggraphasia_SIGGRAPH Asia 2024_sess120_papers_739@linklings.com SUMMARY:PC-Planner: Physics-Constrained Self-Supervised Learning for Robus t Neural Motion Planning with Shape-Aware Distance Function DESCRIPTION:Technical Papers\n\nXujie Shen, Haocheng Peng, and Zesong Yang (State Key Laboratory of CAD&CG, Zhejiang University); Juzhan Xu (Shenzhe n University (SZU)); Hujun Bao (State Key Laboratory of CAD&CG, Zhejiang U niversity); Ruizhen Hu (Shenzhen University (SZU)); and Zhaopeng Cui (Stat e Key Laboratory of CAD&CG, Zhejiang University)\n\nMotion Planning (MP) i s a critical challenge in robotics, especially pertinent with the burgeoni ng interest in embodied artificial intelligence. Traditional MP methods of ten struggle with high-dimensional complexities. Recently neural motion pl anners, particularly physics-informed neural planners based on the Eikonal equation, have been proposed to overcome the curse of dimensionality. How ever, these methods perform poorly in complex scenarios with shaped robots due to multiple solutions inherent in the Eikonal equation. %local minima of their solutions. To address these issues, this paper presents \pcplann er, a novel physics-constrained self-supervised learning framework for rob ot motion planning with various shapes in complex environments. To this en d, we propose several physical constraints, including monotonic and optima l constraints, to stabilize the training process of the neural network wit h the Eikonal equation. Additionally, we introduce a novel shape-aware dis tance field that considers the robot's shape for efficient collision check ing and Ground Truth (GT) speed computation. This field reduces the comput ational intensity, and facilitates adaptive motion planning at test time. Experiments in diverse scenarios with different robots demonstrate the sup eriority of the proposed method in efficiency and robustness for robot mot ion planning, particularly in complex environments.\n\nRegistration Catego ry: Full Access, Full Access Supporter\n\nLanguage Format: English Languag e\n\nSession Chair: Hao (Richard) Zhang (Simon Fraser University, Amazon) URL:https://asia.siggraph.org/2024/program/?id=papers_739&sess=sess120 END:VEVENT END:VCALENDAR