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Hauptverfasser: Kamimura, Tomoya, Oshita, Yuya, Adachi, Mau, Ambe, Yuichi, Sano, Akihito, Wada, Naomi, Matsuno, Fumitoshi, Aoi, Shinya
Format: Preprint
Veröffentlicht: 2026
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Online-Zugang:https://arxiv.org/abs/2604.00329
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author Kamimura, Tomoya
Oshita, Yuya
Adachi, Mau
Ambe, Yuichi
Sano, Akihito
Wada, Naomi
Matsuno, Fumitoshi
Aoi, Shinya
author_facet Kamimura, Tomoya
Oshita, Yuya
Adachi, Mau
Ambe, Yuichi
Sano, Akihito
Wada, Naomi
Matsuno, Fumitoshi
Aoi, Shinya
contents Cheetahs are characterized by large spinal flexion and extension during high-speed running, yet the dynamical role of the phase relationship between spinal motion and limb support remains unclear. We aimed to clarify how this phase relationship affects running performance, focusing on the effect of asymmetric spinal stiffness. Using a simple planar cheetah model with asymmetric torsional spinal stiffness, we numerically searched for periodic bounding solutions over a range of stiffness parameters and compared their ground reaction forces, horizontal velocities, and stability. We obtained both cheetah-like solutions, in which the spine extends after hindlimb liftoff and flexes after forelimb liftoff, and non-cheetah-like solutions, in which the spine flexes after hindlimb liftoff and extends after forelimb liftoff. Under asymmetric spinal stiffness, cheetah-like solutions reduced ground reaction forces while maintaining horizontal velocity more effectively than non-cheetah-like solutions. The phase relationship between spinal motion and stance timing is a key determinant of high-speed running performance. These findings provide a dynamical understanding of cheetah locomotion and suggest design principles for spined legged robots.
format Preprint
id arxiv_https___arxiv_org_abs_2604_00329
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Phase Relationship between Spinal Motion and Limb Support Determines High-speed Running Performance in a Cheetah Model with Asymmetric Spinal Stiffness
Kamimura, Tomoya
Oshita, Yuya
Adachi, Mau
Ambe, Yuichi
Sano, Akihito
Wada, Naomi
Matsuno, Fumitoshi
Aoi, Shinya
Systems and Control
Cheetahs are characterized by large spinal flexion and extension during high-speed running, yet the dynamical role of the phase relationship between spinal motion and limb support remains unclear. We aimed to clarify how this phase relationship affects running performance, focusing on the effect of asymmetric spinal stiffness. Using a simple planar cheetah model with asymmetric torsional spinal stiffness, we numerically searched for periodic bounding solutions over a range of stiffness parameters and compared their ground reaction forces, horizontal velocities, and stability. We obtained both cheetah-like solutions, in which the spine extends after hindlimb liftoff and flexes after forelimb liftoff, and non-cheetah-like solutions, in which the spine flexes after hindlimb liftoff and extends after forelimb liftoff. Under asymmetric spinal stiffness, cheetah-like solutions reduced ground reaction forces while maintaining horizontal velocity more effectively than non-cheetah-like solutions. The phase relationship between spinal motion and stance timing is a key determinant of high-speed running performance. These findings provide a dynamical understanding of cheetah locomotion and suggest design principles for spined legged robots.
title Phase Relationship between Spinal Motion and Limb Support Determines High-speed Running Performance in a Cheetah Model with Asymmetric Spinal Stiffness
topic Systems and Control
url https://arxiv.org/abs/2604.00329