Controlling flat-foot limit cycle walkers with compliant joints based on local stability variation

Yan Huang; Yue Gao; Qiang Huang; Qining Wang

doi:10.1007/s00422-024-00987-y

Controlling flat-foot limit cycle walkers with compliant joints based on local stability variation

Yan Huang
, Yue Gao
, Qiang Huang
, Qining Wang

Beijing Institute of Technology
China Institute of Atomic Energy
Peking University

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

This study investigates local stability of a four-link limit cycle walking biped with flat feet and compliant ankle joints. Local stability represents the behavior along the solution trajectory between Poincare sections, which can provide detailed information about the evolution of disturbances. The effects of ankle stiffness and foot structure on local stability are studied. In addition, we apply a control strategy based on local stability analysis to the limit cycle walker. Control is applied only in the phases with poor local stability. Simulation results show that the energy consumption is reduced without sacrificing disturbance rejection ability. This study may be helpful in motion control of limit cycle bipedal walking robots with flat feet and ankle stiffness and understanding of human walking principles.

Original language	English
Pages (from-to)	111-126
Number of pages	16
Journal	Biological Cybernetics
Volume	118
Issue number	1-2
DOIs	https://doi.org/10.1007/s00422-024-00987-y
State	Published - Apr 2024
Externally published	Yes

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 7 Affordable and Clean Energy

Keywords

Ankle stiffness
Bipedal robots
Flat feet
Limit cycle walking
Local stability

Access to Document

10.1007/s00422-024-00987-y

Cite this

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title = "Controlling flat-foot limit cycle walkers with compliant joints based on local stability variation",

abstract = "This study investigates local stability of a four-link limit cycle walking biped with flat feet and compliant ankle joints. Local stability represents the behavior along the solution trajectory between Poincare sections, which can provide detailed information about the evolution of disturbances. The effects of ankle stiffness and foot structure on local stability are studied. In addition, we apply a control strategy based on local stability analysis to the limit cycle walker. Control is applied only in the phases with poor local stability. Simulation results show that the energy consumption is reduced without sacrificing disturbance rejection ability. This study may be helpful in motion control of limit cycle bipedal walking robots with flat feet and ankle stiffness and understanding of human walking principles.",

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AU - Huang, Yan

AU - Gao, Yue

AU - Huang, Qiang

AU - Wang, Qining

N1 - Publisher Copyright: © The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature 2024.

PY - 2024/4

Y1 - 2024/4

N2 - This study investigates local stability of a four-link limit cycle walking biped with flat feet and compliant ankle joints. Local stability represents the behavior along the solution trajectory between Poincare sections, which can provide detailed information about the evolution of disturbances. The effects of ankle stiffness and foot structure on local stability are studied. In addition, we apply a control strategy based on local stability analysis to the limit cycle walker. Control is applied only in the phases with poor local stability. Simulation results show that the energy consumption is reduced without sacrificing disturbance rejection ability. This study may be helpful in motion control of limit cycle bipedal walking robots with flat feet and ankle stiffness and understanding of human walking principles.

AB - This study investigates local stability of a four-link limit cycle walking biped with flat feet and compliant ankle joints. Local stability represents the behavior along the solution trajectory between Poincare sections, which can provide detailed information about the evolution of disturbances. The effects of ankle stiffness and foot structure on local stability are studied. In addition, we apply a control strategy based on local stability analysis to the limit cycle walker. Control is applied only in the phases with poor local stability. Simulation results show that the energy consumption is reduced without sacrificing disturbance rejection ability. This study may be helpful in motion control of limit cycle bipedal walking robots with flat feet and ankle stiffness and understanding of human walking principles.

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KW - Bipedal robots

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KW - Local stability

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Controlling flat-foot limit cycle walkers with compliant joints based on local stability variation

Abstract

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Keywords

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