Quadruped Rotary Galloping Gait Pattern within a Constant Radius Bend Using Accelerometry

IF 1.9 Q3 ENGINEERING, MECHANICAL
Vibration Pub Date : 2023-09-20 DOI:10.3390/vibration6030044
David Eager, Imam Hossain, Callan Brook
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引用次数: 0

Abstract

This paper provides an initial investigation of quadruped rotary galloping gait patterns using data from racing greyhounds as they navigate their way around a constant radius bend. This study reviewed actual race data collected over a five month period from 2986 racing greyhounds. Using numerical dynamics modelling and value range analysis important factors were identified and analysed. By cleaning and synthesising simple X and Y data and also processing data for accuracy greyhound motion path dynamics results were produced for analysis. The results show that the galloping path greyhounds took going into the bend was different from the path coming out of the bend. It also shows that more than 50% of the greyhounds naturally optimised their path for a longer transition while minimising jerk when entering and exiting the bend. This research verified that individual greyhounds naturally chose different path transition lengths for accommodating their dynamic conditions. Finally, it was found that the greyhound galloping path dynamics state is less intense during the second half of the bend.
使用加速度计在恒定半径弯曲内的四足旋转疾驰步态模式
本文提供了一个四足旋转奔驰步态模式的初步调查使用数据从赛灰狗,因为他们导航的方式在一个恒定的半径弯曲。这项研究回顾了2986只赛狗在5个月的时间里收集的实际比赛数据。通过数值动力学建模和数值范围分析,识别和分析了重要的影响因素。通过对简单的X和Y数据进行清洗和综合,并对数据进行精确处理,得出灰狗运动路径动力学结果以供分析。结果表明,灰狗进入弯道时的奔跑路径与出弯道时的奔跑路径不同。研究还显示,超过50%的灰狗会自然地优化它们的路径,以便在进入和离开弯道时,在最短的时间内过渡。本研究证实,个体灰狗自然选择不同的路径转换长度以适应其动态条件。最后,发现灰狗在弯道后半段的动态状态较弱。
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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来源期刊
CiteScore
3.20
自引率
0.00%
发文量
0
审稿时长
10 weeks
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