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Foot placement modification for a biped humanoid robot with narrow feet.

Hashimoto K, Hattori K, Otani T, Lim HO, Takanishi A - ScientificWorldJournal (2014)

Bottom Line: And a foot-landing point is also changed laterally to inhibit the robot from falling to the outside.To reduce a foot-landing impact, a virtual compliance control is applied to the vertical axis and the roll and pitch axes of the foot.Verification of the proposed method is conducted through experiments with a biped humanoid robot WABIAN-2R.

View Article: PubMed Central - PubMed

Affiliation: Waseda Research Institute for Science and Engineering, Waseda University, No. 41-304, 17 Kikui-cho, Shinjuku-ku, Tokyo 162-0044, Japan.

ABSTRACT
This paper describes a walking stabilization control for a biped humanoid robot with narrow feet. Most humanoid robots have larger feet than human beings to maintain their stability during walking. If robot's feet are as narrow as humans, it is difficult to realize a stable walk by using conventional stabilization controls. The proposed control modifies a foot placement according to the robot's attitude angle. If a robot tends to fall down, a foot angle is modified about the roll axis so that a swing foot contacts the ground horizontally. And a foot-landing point is also changed laterally to inhibit the robot from falling to the outside. To reduce a foot-landing impact, a virtual compliance control is applied to the vertical axis and the roll and pitch axes of the foot. Verification of the proposed method is conducted through experiments with a biped humanoid robot WABIAN-2R. WABIAN-2R realized a knee-bended walking with 30 mm breadth feet. Moreover, WABIAN-2R mounted on a human-like foot mechanism mimicking a human's foot arch structure realized a stable walking with the knee-stretched, heel-contact, and toe-off motion.

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Related in: MedlinePlus

Modification value of a swing foot along the lateral axis with 90 mm breadth feet.
© Copyright Policy - open-access
Related In: Results  -  Collection


getmorefigures.php?uid=PMC3926377&req=5

fig8: Modification value of a swing foot along the lateral axis with 90 mm breadth feet.

Mentions: Figure 8 shows the modification value of a swing foot along the lateral axis. We can find that a foot-landing point is also modified according to the modified foot angle about the roll axis and a waist trajectory is modified by changing the foot positions of both legs during the double support phase.


Foot placement modification for a biped humanoid robot with narrow feet.

Hashimoto K, Hattori K, Otani T, Lim HO, Takanishi A - ScientificWorldJournal (2014)

Modification value of a swing foot along the lateral axis with 90 mm breadth feet.
© Copyright Policy - open-access
Related In: Results  -  Collection

Show All Figures
getmorefigures.php?uid=PMC3926377&req=5

fig8: Modification value of a swing foot along the lateral axis with 90 mm breadth feet.
Mentions: Figure 8 shows the modification value of a swing foot along the lateral axis. We can find that a foot-landing point is also modified according to the modified foot angle about the roll axis and a waist trajectory is modified by changing the foot positions of both legs during the double support phase.

Bottom Line: And a foot-landing point is also changed laterally to inhibit the robot from falling to the outside.To reduce a foot-landing impact, a virtual compliance control is applied to the vertical axis and the roll and pitch axes of the foot.Verification of the proposed method is conducted through experiments with a biped humanoid robot WABIAN-2R.

View Article: PubMed Central - PubMed

Affiliation: Waseda Research Institute for Science and Engineering, Waseda University, No. 41-304, 17 Kikui-cho, Shinjuku-ku, Tokyo 162-0044, Japan.

ABSTRACT
This paper describes a walking stabilization control for a biped humanoid robot with narrow feet. Most humanoid robots have larger feet than human beings to maintain their stability during walking. If robot's feet are as narrow as humans, it is difficult to realize a stable walk by using conventional stabilization controls. The proposed control modifies a foot placement according to the robot's attitude angle. If a robot tends to fall down, a foot angle is modified about the roll axis so that a swing foot contacts the ground horizontally. And a foot-landing point is also changed laterally to inhibit the robot from falling to the outside. To reduce a foot-landing impact, a virtual compliance control is applied to the vertical axis and the roll and pitch axes of the foot. Verification of the proposed method is conducted through experiments with a biped humanoid robot WABIAN-2R. WABIAN-2R realized a knee-bended walking with 30 mm breadth feet. Moreover, WABIAN-2R mounted on a human-like foot mechanism mimicking a human's foot arch structure realized a stable walking with the knee-stretched, heel-contact, and toe-off motion.

Show MeSH
Related in: MedlinePlus