Device for Measuring Contact Reaction Forces during Animal Adhesion Landing/Takeoff from Leaf-like Compliant Substrates

A precise measurement of animal behavior and reaction forces from their surroundings can help elucidate the fundamental principle of animal locomotion, such as landing and takeoff. Compared with stiff substrates, compliant substrates, like leaves, readily yield to loads, presenting grand challenges...

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Bibliographic Details
Published in:Biomimetics (Basel, Switzerland) Switzerland), 2024-02, Vol.9 (3), p.141
Main Authors: Wang, Zhouyi, Feng, Yiping, Wang, Bingcheng, Yuan, Jiwei, Zhang, Baowen, Song, Yi, Wu, Xuan, Li, Lei, Li, Weipeng, Dai, Zhendong
Format: Article
Language:English
Subjects:
Accuracy
Adhesion
Adhesives
Animal behavior
Animals
Behavior
Biomechanics
Biosensors
Compliance
contact reaction force
Design
Environmental aspects
Force
force measurement device
Geckos
Growth
Health aspects
landing
leaf-like compliant substrate
Leaves
Load
Locomotion
Observations
Research methodology
Sensors
Simulation
Structure-function relationships
takeoff
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Summary:A precise measurement of animal behavior and reaction forces from their surroundings can help elucidate the fundamental principle of animal locomotion, such as landing and takeoff. Compared with stiff substrates, compliant substrates, like leaves, readily yield to loads, presenting grand challenges in measuring the reaction forces on the substrates involving compliance. To gain insight into the kinematic mechanisms and structural-functional evolution associated with arboreal animal locomotion, this study introduces an innovative device that facilitates the quantification of the reaction forces on compliant substrates, like leaves. By utilizing the stiffness-damping characteristics of servomotors and the adjustable length of a cantilever structure, the substrate compliance of the device can be accurately controlled. The substrate was further connected to a force sensor and an acceleration sensor. With the cooperation of these sensors, the measured interaction force between the animal and the compliant substrate prevented the effects of inertial force coupling. The device was calibrated under preset conditions, and its force measurement accuracy was validated, with the error between the actual measured and theoretical values being no greater than 10%. Force curves were measured, and frictional adhesion coefficients were calculated from comparative experiments on the landing/takeoff of adherent animals (tree frogs and geckos) on this device. Analysis revealed that the adhesion force limits were significantly lower than previously reported values (0.2~0.4 times those estimated in previous research). This apparatus provides mechanical evidence for elucidating structural-functional relationships exhibited by animals during locomotion and can serve as an experimental platform for optimizing the locomotion of bioinspired robots on compliant substrates.
ISSN:2313-7673
2313-7673
DOI:10.3390/biomimetics9030141