Stride frequency or length? A phylogenetic approach to understand how animals regulate locomotor speed.

M. Granatosky, E. McElroy
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引用次数: 6

Abstract

Speed regulation in animals involves stride frequency and stride length. While the relationship between these variables has been well documented, it remains unresolved whether animals primarily modify stride frequency or stride length to increase speed. In this study, we explored the interrelationships between these three variables across a sample of 103 tetrapods and assessed whether speed regulation strategy is influenced by mechanical, allometric, phylogenetic or ecological factors. We observed that crouched terrestrial species tend to regulate speed through stride frequency. Such a strategy is energetically costly, but results in greater locomotor maneuverability and greater stability. In contrast, regulating speed through stride length is closely tied to larger arboreal animals with relatively extended limbs. Such movements reduce substrate oscillations on thin arboreal supports and/or helps to reduce swing phase costs. The slope of speed on frequency is lower in small crouched animals than in large-bodied erect species. As a result, substantially more rapid limb movements are matched with only small speed increases in crouched, small-bodied animals. Furthermore, the slope of speed on stride length was inversely proportional to body mass. As such, small changes in stride length can result in relatively rapid speed increases for small-bodied species. These results are somewhat counterintuitive, in that larger species, which have longer limbs and take longer strides, do not appear to gain as much speed increase out of lengthening their stride. Conversely, smaller species that cycle their limbs rapidly do not gain as much speed out of increasing stride frequency as do larger species.
步幅的频率还是长度?一种了解动物如何调节运动速度的系统发育方法。
动物的速度调节涉及步频和步长。虽然这些变量之间的关系已经被很好地记录下来,但动物是否主要通过改变步频或步长来提高速度仍未得到解决。在这项研究中,我们在103个四足动物样本中探索了这三个变量之间的相互关系,并评估了速度调节策略是否受到机械、异速生长、系统发育或生态因素的影响。我们观察到,蹲伏的陆生物种倾向于通过步频来调节速度。这种策略在能量上是昂贵的,但结果是更大的运动机动性和更大的稳定性。相比之下,通过步幅调节速度与四肢相对较长的大型树栖动物密切相关。这样的运动减少了基板在薄树支架上的振荡和/或有助于降低摆相成本。小的蹲伏动物的速度对频率的斜率比大的直立动物要低。因此,在蹲伏的小体型动物中,更快的肢体运动只与较小的速度增加相匹配。此外,速度对步幅的斜率与体重成反比。因此,对于体型较小的物种来说,步幅的微小变化可以导致相对较快的速度增加。这些结果在某种程度上是违反直觉的,因为体型较大的物种,四肢更长,步幅更大,似乎并没有因为延长步幅而获得那么多的速度提升。相反,那些四肢快速循环的小型物种并没有像大型物种那样通过增加跨步频率获得那么多的速度。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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