Multi-functional foot use during running in the zebra-tailed lizard (<i>Callisaurus draconoides</i>)

Li, Chen; Hsieh, S. Tonia; Goldman, Daniel I.

doi:10.1242/jeb.061937

Cited by 74 publications

(99 citation statements)

References 76 publications

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“…First, an improved understanding of foot contact mechanics is needed to provide insight into the complexities of thrust generation beyond simple coulomb friction-type attachments that include interlocking (14,54,55), adhesion (56)(57)(58), and resistive forces in granular media (7,59). Second, a leg actuation model that more effectively captures dependence of force production on such factors such as leg morphology, lever and transmission systems, and muscle mechanics (21).…”

Section: Resultsmentioning

confidence: 99%

“…Studies of locomotion over rough terrain (3), compliant surfaces (4), mesh-like networks (5), and sand (6)(7)(8), and through cluttered, 3D terrain (9) have resulted in the discovery of new behaviors and novel theory characterizing environments (10). The study of climbing has led to undiscovered templates (11) that define physical interactions through frictional van der Waals adhesion (12,13) and interlocking with claws (14) and spines (5).…”

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confidence: 99%

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Cockroaches traverse crevices, crawl rapidly in confined spaces, and inspire a soft, legged robot

Jayaram

Full

2016

Proc. Natl. Acad. Sci. U.S.A.

153

112

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Jointed exoskeletons permit rapid appendage-driven locomotion but retain the soft-bodied, shape-changing ability to explore confined environments. We challenged cockroaches with horizontal crevices smaller than a quarter of their standing body height. Cockroaches rapidly traversed crevices in 300-800 ms by compressing their body 40-60%. High-speed videography revealed crevice negotiation to be a complex, discontinuous maneuver. After traversing horizontal crevices to enter a vertically confined space, cockroaches crawled at velocities approaching 60 cm·s −1 , despite body compression and postural changes. Running velocity, stride length, and stride period only decreased at the smallest crevice height (4 mm), whereas slipping and the probability of zigzag paths increased. To explain confined-space running performance limits, we altered ceiling and ground friction. Increased ceiling friction decreased velocity by decreasing stride length and increasing slipping. Increased ground friction resulted in velocity and stride length attaining a maximum at intermediate friction levels. These data support a model of an unexplored mode of locomotion-"body-friction legged crawling" with body drag, friction-dominated leg thrust, but no media flow as in air, water, or sand. To define the limits of body compression in confined spaces, we conducted dynamic compressive cycle tests on living animals. Exoskeletal strength allowed cockroaches to withstand forces 300 times body weight when traversing the smallest crevices and up to nearly 900 times body weight without injury. Cockroach exoskeletons provided biological inspiration for the manufacture of an origami-style, soft, legged robot that can locomote rapidly in both open and confined spaces.T he emergence of terradynamics (1) has advanced the study of terrestrial locomotion by further focusing attention on the quantification of complex and diverse animal-environment interactions (2). Studies of locomotion over rough terrain (3), compliant surfaces (4), mesh-like networks (5), and sand (6-8), and through cluttered, 3D terrain (9) have resulted in the discovery of new behaviors and novel theory characterizing environments (10). The study of climbing has led to undiscovered templates (11) that define physical interactions through frictional van der Waals adhesion (12, 13) and interlocking with claws (14) and spines (5). Burrowing (15, 16), sand swimming (17), and locomotion in tunnels (18) have yielded new findings determining the interaction of bodies, appendages, and substrata.Locomotion in confined environments offers several challenges for animals (18) that include limitations due to body shape changes (19,20), restricted limb mobility (21), increased body drag, and reduced thrust development (22). Examining the motion repertoire of soft-bodied animals (23), such as annelids (19), insect larvae (24), and molluscs (25), has offered insight into a range of strategies used to move in confined spaces. Inspiration from softbodied animals has fueled the explosive growth in soft robo...

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Section: Resultsmentioning

confidence: 99%

mentioning

confidence: 99%

Cockroaches traverse crevices, crawl rapidly in confined spaces, and inspire a soft, legged robot

Jayaram

Full

2016

Proc. Natl. Acad. Sci. U.S.A.

153

112

View full text Add to dashboard Cite

show abstract

“…The authors obtained a remarkable match between experimental data and the model, for instance in terms of the interaction forces of rotating legs of different shapes with the granular media, and in terms of locomotion speeds of the robot with different leg shapes and different stride frequencies. Such a terradynamics model can be useful to understand how lizards run in the sand (55) and to design leg shapes and control laws for robots that move in sand and gravel.…”

Section: Crawling and Terradynamicsmentioning

confidence: 99%

Biorobotics: Using robots to emulate and investigate agile locomotion

Ijspeert

2014

Science

392

220

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Abstract:The graceful and agile movements of animals are difficult to analyze and emulate because locomotion is the result of a complex interplay of many components: the central and peripheral nervous systems, the musculoskeletal system, and the environment. The goals of biorobotics are to take inspiration from biological principles to design robots that match the agility of animals, and to use robots as scientific tools to investigate animal adaptive behavior. Used as physical models, biorobots contribute to hypothesis testing in fields such as hydrodynamics, biomechanics, neuroscience, and prosthetics. Their use may contribute to the design of prosthetic devices that more closely take human locomotion principles into account.

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“…The distribution of plantar pressure sensors is shown in Figure 9. In walking, the upper part of the body exhibits a slight swing with the swing of the feet [21]. We installed sensors to acquire upper body swinging data to more accurately reproduce the process of walking.…”

Section: Sensor Data Acquisition System and Experimentmentioning

confidence: 99%

Design and Voluntary Motion Intention Estimation of a Novel Wearable Full-Body Flexible Exoskeleton Robot

Chen

Wang

Liu

et al. 2017

Mobile Information Systems

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The wearable full-body exoskeleton robot developed in this study is one application of mobile cyberphysical system (CPS), which is a complex mobile system integrating mechanics, electronics, computer science, and artificial intelligence. Steel wire was used as the flexible transmission medium and a group of special wire-locking structures was designed. Additionally, we designed passive joints for partial joints of the exoskeleton. Finally, we proposed a novel gait phase recognition method for full-body exoskeletons using only joint angular sensors, plantar pressure sensors, and inclination sensors. The method consists of four procedures. Firstly, we classified the three types of main motion patterns: normal walking on the ground, stair-climbing and stair-descending, and sit-to-stand movement. Secondly, we segregated the experimental data into one gait cycle. Thirdly, we divided one gait cycle into eight gait phases. Finally, we built a gait phase recognition model based on -Nearest Neighbor perception and trained it with the phase-labeled gait data. The experimental result shows that the model has a 98.52% average correct rate of classification of the main motion patterns on the testing set and a 95.32% average correct rate of phase recognition on the testing set. So the exoskeleton robot can achieve human motion intention in real time and coordinate its movement with the wearer.

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Multi-functional foot use during running in the zebra-tailed lizard (Callisaurus draconoides)

Cited by 74 publications

References 76 publications

Cockroaches traverse crevices, crawl rapidly in confined spaces, and inspire a soft, legged robot

Cockroaches traverse crevices, crawl rapidly in confined spaces, and inspire a soft, legged robot

Biorobotics: Using robots to emulate and investigate agile locomotion

Design and Voluntary Motion Intention Estimation of a Novel Wearable Full-Body Flexible Exoskeleton Robot

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