Human Demonstrations are Generalizable Knowledge for Robots
Abstract
Learning from human demonstrations is an emerging trend for designing intelligent robotic systems. However, previous methods typically regard videos as instructions, simply dividing them into action sequences for robotic repetition, which poses obstacles to generalization to diverse tasks or object instances. In this paper, we propose a different perspective, considering human demonstration videos not as mere instructions, but as a source of knowledge for robots. Motivated by this perspective and the remarkable comprehension and generalization capabilities exhibited by large language models (LLMs), we propose DigKnow, a method that DIstills Generalizable KNOWledge with a hierarchical structure. Specifically, DigKnow begins by converting human demonstration video frames into observation knowledge. This knowledge is then subjected to analysis to extract human action knowledge and further distilled into pattern knowledge compassing task and object instances, resulting in the acquisition of generalizable knowledge with a hierarchical structure. In settings with different tasks or object instances, DigKnow retrieves relevant knowledge for the current task and object instances. Subsequently, the LLM-based planner conducts planning based on the retrieved knowledge, and the policy executes actions in line with the plan to achieve the designated task. Utilizing the retrieved knowledge, we validate and rectify planning and execution outcomes, resulting in a substantial enhancement of the success rate. Experimental results across a range of tasks and scenes demonstrate the effectiveness of this approach in facilitating real-world robots to accomplish tasks with the knowledge derived from human demonstrations.
Cite
@article{arxiv.2312.02419,
title = {Human Demonstrations are Generalizable Knowledge for Robots},
author = {Te Cui and Tianxing Zhou and Zicai Peng and Mengxiao Hu and Haoyang Lu and Haizhou Li and Guangyan Chen and Meiling Wang and Yufeng Yue},
journal= {arXiv preprint arXiv:2312.02419},
year = {2025}
}
Comments
accepted for publication in lEEE/RSJ international Conference on Intelligent Robots and Systems (lROS 2025)