Energy and time optimal trajectories in exploratory jumps of the spider Phidippus regius

Energy and time optimal trajectories in exploratory jumps of the spider Phidippus regius

Abstract Jumping spiders are proficient jumpers that use jumps in a variety of behavioural contexts. We use high speed, high resolution video to measure the kinematics of a single regal jumping spider for a total of 15 different tasks based on a horizontal gap of 2–5 body lengths and vertical gap of...

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Main Authors: Mostafa R. A. Nabawy, Girupakaran Sivalingam, Russell J. Garwood, William J. Crowther, William I. Sellers
Format: Article
Language:English
Published: Nature Publishing Group 2018-05-01
Series:Scientific Reports
Online Access:https://doi.org/10.1038/s41598-018-25227-9
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spelling doaj-e27cd7e3c6af4f5fbbdb7612bb465e9c2020-12-08T03:50:56ZengNature Publishing GroupScientific Reports2045-23222018-05-018111510.1038/s41598-018-25227-9Energy and time optimal trajectories in exploratory jumps of the spider Phidippus regiusMostafa R. A. Nabawy0Girupakaran Sivalingam1Russell J. Garwood2William J. Crowther3William I. Sellers4School of Mechanical, Aerospace and Civil Engineering, The University of ManchesterSchool of Mechanical, Aerospace and Civil Engineering, The University of ManchesterSchool of Earth and Environmental Sciences, The University of ManchesterSchool of Mechanical, Aerospace and Civil Engineering, The University of ManchesterSchool of Earth and Environmental Sciences, The University of ManchesterAbstract Jumping spiders are proficient jumpers that use jumps in a variety of behavioural contexts. We use high speed, high resolution video to measure the kinematics of a single regal jumping spider for a total of 15 different tasks based on a horizontal gap of 2–5 body lengths and vertical gap of +/−2 body lengths. For short range jumps, we show that low angled trajectories are used that minimise flight time. For longer jumps, take-off angles are steeper and closer to the optimum for minimum energy cost of transport. Comparison of jump performance against other arthropods shows that Phidippus regius is firmly in the group of animals that use dynamic muscle contraction for actuation as opposed to a stored energy catapult system. We find that the jump power requirements can be met from the estimated mass of leg muscle; hydraulic augmentation may be present but appears not to be energetically essential.https://doi.org/10.1038/s41598-018-25227-9
collection DOAJ
language English
format Article
sources DOAJ
author Mostafa R. A. Nabawy
Girupakaran Sivalingam
Russell J. Garwood
William J. Crowther
William I. Sellers
spellingShingle Mostafa R. A. Nabawy
Girupakaran Sivalingam
Russell J. Garwood
William J. Crowther
William I. Sellers
Energy and time optimal trajectories in exploratory jumps of the spider Phidippus regius
Scientific Reports
author_facet Mostafa R. A. Nabawy
Girupakaran Sivalingam
Russell J. Garwood
William J. Crowther
William I. Sellers
author_sort Mostafa R. A. Nabawy
title Energy and time optimal trajectories in exploratory jumps of the spider Phidippus regius
title_short Energy and time optimal trajectories in exploratory jumps of the spider Phidippus regius
title_full Energy and time optimal trajectories in exploratory jumps of the spider Phidippus regius
title_fullStr Energy and time optimal trajectories in exploratory jumps of the spider Phidippus regius
title_full_unstemmed Energy and time optimal trajectories in exploratory jumps of the spider Phidippus regius
title_sort energy and time optimal trajectories in exploratory jumps of the spider phidippus regius
publisher Nature Publishing Group
series Scientific Reports
issn 2045-2322
publishDate 2018-05-01
description Abstract Jumping spiders are proficient jumpers that use jumps in a variety of behavioural contexts. We use high speed, high resolution video to measure the kinematics of a single regal jumping spider for a total of 15 different tasks based on a horizontal gap of 2–5 body lengths and vertical gap of +/−2 body lengths. For short range jumps, we show that low angled trajectories are used that minimise flight time. For longer jumps, take-off angles are steeper and closer to the optimum for minimum energy cost of transport. Comparison of jump performance against other arthropods shows that Phidippus regius is firmly in the group of animals that use dynamic muscle contraction for actuation as opposed to a stored energy catapult system. We find that the jump power requirements can be met from the estimated mass of leg muscle; hydraulic augmentation may be present but appears not to be energetically essential.
url https://doi.org/10.1038/s41598-018-25227-9
work_keys_str_mv AT mostafaranabawy energyandtimeoptimaltrajectoriesinexploratoryjumpsofthespiderphidippusregius
AT girupakaransivalingam energyandtimeoptimaltrajectoriesinexploratoryjumpsofthespiderphidippusregius
AT russelljgarwood energyandtimeoptimaltrajectoriesinexploratoryjumpsofthespiderphidippusregius
AT williamjcrowther energyandtimeoptimaltrajectoriesinexploratoryjumpsofthespiderphidippusregius
AT williamisellers energyandtimeoptimaltrajectoriesinexploratoryjumpsofthespiderphidippusregius
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