蝗虫跳跃过程中的翻滚控制。

Control of tumbling during the locust jump.

机构信息

Department of Biology, Georgia State University, Atlanta, GA 30303, USA.

出版信息

J Exp Biol. 2010 Oct 1;213(Pt 19):3378-87. doi: 10.1242/jeb.046367.

DOI:10.1242/jeb.046367

PMID:20833932

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2936971/

Abstract

Locust can jump precisely to a target, yet they can also tumble during the trajectory. We propose two mechanisms that would allow the locust to control tumbling during the jump. The first is that prior to the jump, locusts adjust the pitch of their body to move the center of mass closer to the intended thrust vector. The second is that contraction of the dorsolongitudinal muscles during the jump will produce torques that counter the torque produced by thrust. We found that locusts increased their take-off angle as the initial body pitch increased, and that little tumbling occurred for jumps that observed this relationship. Simulations of locust jumping demonstrated that a pitch versus take-off angle relationship that minimized tumbling in simulated jumps was similar to the relationship observed in live locusts. Locusts were strongly biased to pitch head-upward, and performed dorsiflexions far more often than ventral flexions. The direction and magnitude of tumbling could be controlled in simulations by adjusting the tension in the dorsolongitudinal muscles. These mechanisms allowed the simulations to match the data from the live animals. Control of tumbling was also found to influence the control of jump elevation. The bias to pitch head-upwards may have an evolutionary advantage when evading a predator and so make control of tumbling important for the locust.

摘要

蝗虫可以精确地跳跃到目标，但它们在飞行过程中也会翻滚。我们提出了两种机制，这两种机制可以让蝗虫在跳跃过程中控制翻滚。第一种是在跳跃之前，蝗虫调整身体的俯仰角度，将质心移动到更接近预期的推力矢量。第二种是在跳跃过程中，背纵肌的收缩会产生与推力产生的扭矩相反的扭矩。我们发现，随着初始身体俯仰角的增加，蝗虫增加了起飞角度，并且观察到这种关系的跳跃很少翻滚。对蝗虫跳跃的模拟表明，在模拟跳跃中最小化翻滚的俯仰角与起飞角度关系与在活体蝗虫中观察到的关系相似。蝗虫强烈地偏向于仰头向上倾斜，并进行背屈运动的次数远多于腹屈运动。在模拟中，通过调整背纵肌的张力，可以控制翻滚的方向和幅度。这些机制使模拟能够与活体动物的数据相匹配。翻滚的控制也被发现会影响跳跃高度的控制。仰头向上倾斜的倾向在躲避捕食者时可能具有进化优势，因此控制翻滚对蝗虫很重要。

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本文引用的文献

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J Comp Physiol A Neuroethol Sens Neural Behav Physiol. 2005 Oct;191(10):965-75. doi: 10.1007/s00359-005-0023-3. Epub 2005 Sep 29.

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