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一种利用可重构运动策略实现陆地、水上和空中移动的双足机器人平台。

A Bipedal Robotic Platform Leveraging Reconfigurable Locomotion Policies for Terrestrial, Aquatic, and Aerial Mobility.

作者信息

Sun Zijie, Li Yangmin, Teng Long

机构信息

Department of Industrial and Systems Engineering, The Hong Kong Polytechnic University, Hong Kong, China.

出版信息

Biomimetics (Basel). 2025 Jun 5;10(6):374. doi: 10.3390/biomimetics10060374.

DOI:10.3390/biomimetics10060374
PMID:40558343
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12191364/
Abstract

Biological systems can adaptively navigate multi-terrain environments via morphological and behavioral flexibility. While robotic systems increasingly achieve locomotion versatility in one or two domains, integrating terrestrial, aquatic, and aerial mobility into a single platform remains an engineering challenge. This work tackles this by introducing a bipedal robot equipped with a reconfigurable locomotion framework, enabling seven adaptive policies: (1) thrust-assisted jumping, (2) legged crawling, (3) balanced wheeling, (4) tricycle wheeling, (5) paddling-based swimming, (6) air-propelled drifting, and (7) quadcopter flight. Field experiments and indoor statistical tests validated these capabilities. The robot achieved a 3.7-m vertical jump via thrust forces counteracting gravitational forces. A unified paddling mechanism enabled seamless transitions between crawling and swimming modes, allowing amphibious mobility in transitional environments such as riverbanks. The crawling mode demonstrated the traversal on uneven substrates (e.g., medium-density grassland, soft sand, and cobblestones) while generating sufficient push forces for object transport. In contrast, wheeling modes prioritize speed and efficiency on flat terrain. The aquatic locomotion was validated through trials in static water, an open river, and a narrow stream. The flight mode was investigated with the assistance of the jumping mechanism. By bridging terrestrial, aquatic, and aerial locomotion, this platform may have the potential for search-and-rescue and environmental monitoring applications.

摘要

生物系统可以通过形态和行为的灵活性,自适应地在多地形环境中导航。虽然机器人系统越来越多地在一两个领域实现了运动的多功能性,但将陆地、水上和空中移动性集成到一个单一平台仍然是一项工程挑战。这项工作通过引入一个配备可重构运动框架的双足机器人来解决这一问题,该框架实现了七种自适应策略:(1) 推力辅助跳跃,(2) 腿部爬行,(3) 平衡滚动,(4) 三轮滚动,(5) 划桨式游泳,(6) 空气推进漂移,以及(7) 四旋翼飞行。现场实验和室内统计测试验证了这些能力。该机器人通过抵消重力的推力实现了3.7米的垂直跳跃。一个统一的划桨机构实现了爬行和游泳模式之间的无缝过渡,允许在河岸等过渡环境中进行两栖移动。爬行模式展示了在不平坦的地面(如中密度草地、软沙地和鹅卵石地)上的通行能力,同时为物体运输产生足够的推力。相比之下,滚动模式在平坦地形上更注重速度和效率。通过在静水、开阔河流和狭窄溪流中的试验验证了水上运动能力。借助跳跃机制对飞行模式进行了研究。通过连接陆地、水上和空中运动,该平台可能具有在搜索救援和环境监测应用方面的潜力。

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