Three-dimensional motion analysis of upright bipedal walking android model

We previously developed a bipedal android model driven by trunk motion via psoas major contractions. A mechanically stabilized principle model was created to preserve gait mechanics, enabling autonomous bipedal walking and reliable center of pressure measurement by addressing knee and foot–ankle joi...

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Published in	Clinical biomechanics (Bristol) Vol. 129; p. 106620
Main Authors	Sanaka, Kouji, Sekiguchi, Yusuke, Kurosawa, Daisuke, Sugimura, Seiichi, Hashimoto, Ko, Takahashi, Kohei, Ebihara, Satoru, Murakami, Eiichi, Aizawa, Toshimi
Format	Journal Article
Language	English
Published	England Elsevier Ltd 01.10.2025
Subjects	3D motion analysis Android model Bipedal walking Center of pressure Physical Medicine and Rehabilitation Trunk movement Android model Center of pressure 3D motion analysis Bipedal walking Trunk movement
Online Access	Get full text
ISSN	0268-0033 1879-1271 1879-1271
DOI	10.1016/j.clinbiomech.2025.106620

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Abstract	We previously developed a bipedal android model driven by trunk motion via psoas major contractions. A mechanically stabilized principle model was created to preserve gait mechanics, enabling autonomous bipedal walking and reliable center of pressure measurement by addressing knee and foot–ankle joint instability. This study investigated whether the center of pressure trajectory generated by the trunk-driven model approximates that of humans using a three-dimensional gait analysis system. Thirty-five markers were attached to healthy subjects versus 24 markers to the principle model. Ground reaction force data were captured at 1200 Hz and analyzed using motion analysis and numerical software. The center of pressure trajectory of the right foot during the stance phase was compared between the principle model and healthy subjects. Center of pressure trajectories were generally similar during the double-limb stance and single-limb support phases. The principle model showed differences such as a backward deviation of the center of pressure in the direction opposite to walking progression during the single-limb support phase, especially between 47.5 % and 61.5 % of the phase. The trajectory did not extend toward the forefoot, likely due to the shorter stride length, slower walking speed, and prolonged single-limb support duration (0.91 ± 0.05 s vs. 0.41 ± 0.05 s in healthy subjects). Conventional gait analysis assumes passive trunk motion following lower-limb activity. In contrast, the principle model demonstrates trunk-driven motion with passive leg swing, partially replicating human center of pressure trajectories. This suggests a trunk-driven approach may offer insights for gait analysis. •The bipedal android model, driven by trunk motion, mimics human center of pressure.•The trunk is crucial in bipedal walking, not just passively following limb motion.•The model aids biomechanical studies post-treatment and predicts leg abnormalities.
AbstractList	We previously developed a bipedal android model driven by trunk motion via psoas major contractions. A mechanically stabilized principle model was created to preserve gait mechanics, enabling autonomous bipedal walking and reliable center of pressure measurement by addressing knee and foot–ankle joint instability. This study investigated whether the center of pressure trajectory generated by the trunk-driven model approximates that of humans using a three-dimensional gait analysis system. Thirty-five markers were attached to healthy subjects versus 24 markers to the principle model. Ground reaction force data were captured at 1200 Hz and analyzed using motion analysis and numerical software. The center of pressure trajectory of the right foot during the stance phase was compared between the principle model and healthy subjects. Center of pressure trajectories were generally similar during the double-limb stance and single-limb support phases. The principle model showed differences such as a backward deviation of the center of pressure in the direction opposite to walking progression during the single-limb support phase, especially between 47.5 % and 61.5 % of the phase. The trajectory did not extend toward the forefoot, likely due to the shorter stride length, slower walking speed, and prolonged single-limb support duration (0.91 ± 0.05 s vs. 0.41 ± 0.05 s in healthy subjects). Conventional gait analysis assumes passive trunk motion following lower-limb activity. In contrast, the principle model demonstrates trunk-driven motion with passive leg swing, partially replicating human center of pressure trajectories. This suggests a trunk-driven approach may offer insights for gait analysis. •The bipedal android model, driven by trunk motion, mimics human center of pressure.•The trunk is crucial in bipedal walking, not just passively following limb motion.•The model aids biomechanical studies post-treatment and predicts leg abnormalities. We previously developed a bipedal android model driven by trunk motion via psoas major contractions. A mechanically stabilized principle model was created to preserve gait mechanics, enabling autonomous bipedal walking and reliable center of pressure measurement by addressing knee and foot-ankle joint instability. This study investigated whether the center of pressure trajectory generated by the trunk-driven model approximates that of humans using a three-dimensional gait analysis system.BACKGROUNDWe previously developed a bipedal android model driven by trunk motion via psoas major contractions. A mechanically stabilized principle model was created to preserve gait mechanics, enabling autonomous bipedal walking and reliable center of pressure measurement by addressing knee and foot-ankle joint instability. This study investigated whether the center of pressure trajectory generated by the trunk-driven model approximates that of humans using a three-dimensional gait analysis system.Thirty-five markers were attached to healthy subjects versus 24 markers to the principle model. Ground reaction force data were captured at 1200 Hz and analyzed using motion analysis and numerical software. The center of pressure trajectory of the right foot during the stance phase was compared between the principle model and healthy subjects.METHODSThirty-five markers were attached to healthy subjects versus 24 markers to the principle model. Ground reaction force data were captured at 1200 Hz and analyzed using motion analysis and numerical software. The center of pressure trajectory of the right foot during the stance phase was compared between the principle model and healthy subjects.Center of pressure trajectories were generally similar during the double-limb stance and single-limb support phases. The principle model showed differences such as a backward deviation of the center of pressure in the direction opposite to walking progression during the single-limb support phase, especially between 47.5 % and 61.5 % of the phase. The trajectory did not extend toward the forefoot, likely due to the shorter stride length, slower walking speed, and prolonged single-limb support duration (0.91 ± 0.05 s vs. 0.41 ± 0.05 s in healthy subjects).FINDINGSCenter of pressure trajectories were generally similar during the double-limb stance and single-limb support phases. The principle model showed differences such as a backward deviation of the center of pressure in the direction opposite to walking progression during the single-limb support phase, especially between 47.5 % and 61.5 % of the phase. The trajectory did not extend toward the forefoot, likely due to the shorter stride length, slower walking speed, and prolonged single-limb support duration (0.91 ± 0.05 s vs. 0.41 ± 0.05 s in healthy subjects).Conventional gait analysis assumes passive trunk motion following lower-limb activity. In contrast, the principle model demonstrates trunk-driven motion with passive leg swing, partially replicating human center of pressure trajectories. This suggests a trunk-driven approach may offer insights for gait analysis.INTERPRETATIONConventional gait analysis assumes passive trunk motion following lower-limb activity. In contrast, the principle model demonstrates trunk-driven motion with passive leg swing, partially replicating human center of pressure trajectories. This suggests a trunk-driven approach may offer insights for gait analysis. AbstractBackgroundWe previously developed a bipedal android model driven by trunk motion via psoas major contractions. A mechanically stabilized principle model was created to preserve gait mechanics, enabling autonomous bipedal walking and reliable center of pressure measurement by addressing knee and foot–ankle joint instability. This study investigated whether the center of pressure trajectory generated by the trunk-driven model approximates that of humans using a three-dimensional gait analysis system. MethodsThirty-five markers were attached to healthy subjects versus 24 markers to the principle model. Ground reaction force data were captured at 1200 Hz and analyzed using motion analysis and numerical software. The center of pressure trajectory of the right foot during the stance phase was compared between the principle model and healthy subjects. FindingsCenter of pressure trajectories were generally similar during the double-limb stance and single-limb support phases. The principle model showed differences such as a backward deviation of the center of pressure in the direction opposite to walking progression during the single-limb support phase, especially between 47.5 % and 61.5 % of the phase. The trajectory did not extend toward the forefoot, likely due to the shorter stride length, slower walking speed, and prolonged single-limb support duration (0.91 ± 0.05 s vs. 0.41 ± 0.05 s in healthy subjects). InterpretationConventional gait analysis assumes passive trunk motion following lower-limb activity. In contrast, the principle model demonstrates trunk-driven motion with passive leg swing, partially replicating human center of pressure trajectories. This suggests a trunk-driven approach may offer insights for gait analysis. We previously developed a bipedal android model driven by trunk motion via psoas major contractions. A mechanically stabilized principle model was created to preserve gait mechanics, enabling autonomous bipedal walking and reliable center of pressure measurement by addressing knee and foot-ankle joint instability. This study investigated whether the center of pressure trajectory generated by the trunk-driven model approximates that of humans using a three-dimensional gait analysis system. Thirty-five markers were attached to healthy subjects versus 24 markers to the principle model. Ground reaction force data were captured at 1200 Hz and analyzed using motion analysis and numerical software. The center of pressure trajectory of the right foot during the stance phase was compared between the principle model and healthy subjects. Center of pressure trajectories were generally similar during the double-limb stance and single-limb support phases. The principle model showed differences such as a backward deviation of the center of pressure in the direction opposite to walking progression during the single-limb support phase, especially between 47.5 % and 61.5 % of the phase. The trajectory did not extend toward the forefoot, likely due to the shorter stride length, slower walking speed, and prolonged single-limb support duration (0.91 ± 0.05 s vs. 0.41 ± 0.05 s in healthy subjects). Conventional gait analysis assumes passive trunk motion following lower-limb activity. In contrast, the principle model demonstrates trunk-driven motion with passive leg swing, partially replicating human center of pressure trajectories. This suggests a trunk-driven approach may offer insights for gait analysis.
ArticleNumber	106620
Author	Sugimura, Seiichi Hashimoto, Ko Kurosawa, Daisuke Sanaka, Kouji Takahashi, Kohei Sekiguchi, Yusuke Ebihara, Satoru Aizawa, Toshimi Murakami, Eiichi
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Snippet	We previously developed a bipedal android model driven by trunk motion via psoas major contractions. A mechanically stabilized principle model was created to... AbstractBackgroundWe previously developed a bipedal android model driven by trunk motion via psoas major contractions. A mechanically stabilized principle...
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SubjectTerms	3D motion analysis Android model Bipedal walking Center of pressure Physical Medicine and Rehabilitation Trunk movement
Title	Three-dimensional motion analysis of upright bipedal walking android model
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