Recent Progress in the Physical Principles of Dynamic Ground Self-Righting.

IF 2.2 3区 生物学 Q1 ZOOLOGY
Chen Li
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引用次数: 0

Abstract

Animals and robots must self-right on the ground after overturning. Biology research has described various strategies and motor patterns in many species. Robotics research has devised many strategies. However, we do not well understand the physical principles of how the need to generate mechanical energy to overcome the potential energy barrier governs behavioral strategies and 3D body rotations given the morphology. Here, I review progress on this which I led studying cockroaches self-righting on level, flat, solid, low-friction ground, by integrating biology experiments, robotic modeling, and physics modeling. Animal experiments using three species (Madagascar hissing, American, and discoid cockroaches) found that ground self-righting is strenuous and often requires multiple attempts to succeed. Two species (American and discoid cockroaches) often self-right dynamically, using kinetic energy to overcome the barrier. All three species use and often stochastically transition across diverse strategies. In these strategies, propelling motions are often accompanied by perturbing motions. All three species often display complex yet stereotyped body rotation. They all roll more in successful attempts than in failed ones, which lowers the barrier, as revealed by a simplistic 3D potential energy landscape of a rigid body self-righting. Experiments of an initial robot self-righting via rotation about a fixed axis revealed that the longer and faster appendages push, the more mechanical energy can be gained to overcome the barrier. However, the cockroaches rarely achieve this. To further understand the physical principles of strenuous ground self-righting, we focused on the discoid cockroach's leg-assisted winged self-righting. In this strategy, wings propel against the ground to pitch the body up but are unable to overcome the highest pitch barrier. Meanwhile, legs flail in the air to perturb the body sideways to self-right via rolling. Experiments using a refined robot and an evolving 3D potential energy landscape revealed that, although wing propelling cannot generate sufficient kinetic energy to overcome the highest pitch barrier, it reduces the barrier to allow small kinetic energy from the perturbing legs to probabilistically overcome the barrier to self-right via rolling. Thus, only by combining propelling and perturbing can self-righting be achieved when it is so strenuous; this physical constraint leads to the stereotyped body rotation. Finally, multi-body dynamics simulation and template modeling revealed that the animal's substantial randomness in wing and leg motions helps it, by chance, to find good coordination, which accumulates more mechanical energy to overcome the barrier, thus increasing the likelihood of self-righting.

地面动态自整定物理原理的最新进展。
动物和机器人在翻车后必须在地面上自我扶正。生物学研究描述了许多物种的各种策略和运动模式。机器人研究设计了许多策略。然而,我们并不十分清楚,需要产生机械能以克服势能障碍的物理原理是如何支配行为策略和三维身体旋转形态的。在此,我回顾了我领导的研究蟑螂在水平、平坦、坚固、低摩擦地面上自我扶正的进展情况,将生物实验、机器人建模和物理建模融为一体。使用三种蟑螂(马达加斯加嘶嘶蠊、美洲大蠊和盘状蟑螂)进行的动物实验发现,在地面上自我扶正非常吃力,往往需要多次尝试才能成功。有两种蟑螂(美洲大蠊和盘形蟑螂)经常利用动能来克服障碍,进行动态自转。所有这三种蟑螂都使用并经常随机转换不同的策略。在这些策略中,推进运动往往伴随着扰动运动。这三个物种都经常表现出复杂而刻板的身体旋转。它们在成功的尝试中都比失败的尝试中滚动得更多,这降低了障碍,正如刚体自动扶正的简单三维势能图所示。通过围绕固定轴线旋转来实现初始机器人自动扶正的实验表明,附肢推得越长、越快,就能获得越多的机械能来克服障碍。然而,蟑螂很少能做到这一点。为了进一步了解地面剧烈自转的物理原理,我们重点研究了盘状蟑螂的腿辅助翼自转。在这种策略中,翅膀推动地面使身体向上俯仰,但无法克服最高俯仰障碍。与此同时,腿部在空中甩动,扰动身体侧向,通过滚动实现自我扶正。使用改进后的机器人和不断变化的三维势能图进行的实验表明,虽然机翼推进无法产生足够的动能来克服最高俯仰障碍,但它能降低障碍,使扰动腿的小动能有可能克服障碍,通过滚动实现自右。因此,只有将推进和扰动结合起来,才能在如此吃力的情况下实现自右;这种物理限制导致了定型的身体旋转。最后,多体动力学模拟和模板建模显示,动物翅膀和腿部运动的随机性很大,这有助于它偶然找到良好的协调,从而积累更多的机械能来克服障碍,从而增加自右的可能性。
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来源期刊
CiteScore
4.70
自引率
7.70%
发文量
150
审稿时长
6-12 weeks
期刊介绍: Integrative and Comparative Biology ( ICB ), formerly American Zoologist , is one of the most highly respected and cited journals in the field of biology. The journal''s primary focus is to integrate the varying disciplines in this broad field, while maintaining the highest scientific quality. ICB''s peer-reviewed symposia provide first class syntheses of the top research in a field. ICB also publishes book reviews, reports, and special bulletins.
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