Generalizing kinematic skill learning to energy efficient dynamic motion planning using optimized Dynamic Movement Primitives

IF 11.4 1区计算机科学 Q1 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS

Robotics and Computer-integrated Manufacturing Pub Date : 2025-02-18 DOI:10.1016/j.rcim.2025.102983

Tian Xu , Siddharth Singh , Qing Chang

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Abstract

In manufacturing, automating the generation of dynamic trajectories for diverse robots and loads in response to kinematic task requirements presents a significant challenge. Previous research has primarily addressed kinematic trajectory generation and dynamic motion planning as separate endeavors, with integrated solutions rarely explored. This paper presents a novel methodology that combines reinforcement learning (RL)-based kinematic skill learning, dynamic modeling and an enhanced version of Dynamic Movement Primitives (DMP). Utilizing a pre-established skill library, the RL-enabled method generates multiple kinematic trajectories that fulfill the specific task requirements. These trajectories are further refined by dynamic modeling, selecting paths that minimize energy consumption tailored to specific robot types and loads. The newly proposed Optimized Normalized Dynamic Motion Primitive (ON-DMP) enhances obstacle avoidance with minimal energy consumption, remaining effective in novel environments. Validated through both simulated and real-world experiments, this methodology shows robust results in improving task completion in dynamic real-world environments without the need of reprogramming.

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利用优化的动态运动原语将运动学技能学习推广到节能动态运动规划中

在制造业中，根据运动学任务要求，自动化生成不同机器人和负载的动态轨迹是一项重大挑战。以前的研究主要是将运动学轨迹生成和动态运动规划作为单独的努力，很少探索集成的解决方案。本文提出了一种结合了基于强化学习（RL）的运动学技能学习、动态建模和增强版动态运动原语（DMP）的新方法。利用预先建立的技能库，rl方法生成满足特定任务要求的多个运动轨迹。这些轨迹通过动态建模进一步细化，选择适合特定机器人类型和负载的最小化能耗路径。新提出的优化归一化动态运动原语（ON-DMP）以最小的能量消耗增强避障能力，在新环境中保持有效。通过模拟和现实世界的实验验证，该方法在不需要重新编程的情况下提高了动态现实环境中的任务完成度。

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来源期刊

Robotics and Computer-integrated Manufacturing 工程技术-工程：制造

CiteScore

24.10

自引率

13.50%

发文量

160

审稿时长

50 days

期刊介绍： The journal, Robotics and Computer-Integrated Manufacturing, focuses on sharing research applications that contribute to the development of new or enhanced robotics, manufacturing technologies, and innovative manufacturing strategies that are relevant to industry. Papers that combine theory and experimental validation are preferred, while review papers on current robotics and manufacturing issues are also considered. However, papers on traditional machining processes, modeling and simulation, supply chain management, and resource optimization are generally not within the scope of the journal, as there are more appropriate journals for these topics. Similarly, papers that are overly theoretical or mathematical will be directed to other suitable journals. The journal welcomes original papers in areas such as industrial robotics, human-robot collaboration in manufacturing, cloud-based manufacturing, cyber-physical production systems, big data analytics in manufacturing, smart mechatronics, machine learning, adaptive and sustainable manufacturing, and other fields involving unique manufacturing technologies.