Estrategias de adaptabilidad estáticamente estables al cambio de terreno para un robot caminante de seis extremidades

X. Yamile Sandoval Castro; Eduardo Castillo Castañeda

doi:10.4995/riai.2019.8979

Estrategias de adaptabilidad estáticamente estables al cambio de terreno para un robot caminante de seis extremidades

Translated title of the contribution: Terrain adaptability strategies statically-stable for a walking hexapod robot

X. Yamile Sandoval Castro, Eduardo Castillo Castañeda

Centro de Investigación en Ciencia Aplicada y Tecnología Avanzada (CICATA), Unidad Querétaro

Research output: Contribution to journal › Review article › peer-review

1 Scopus citations

Abstract

This article describes the forward and inverse kinematic model of position of the Hex-piderix robot, taking on account current attitude. Also three strategies to get terrain adaptability to the robot, guaranty statically stability are presented: constant orientation of the thorax, geometric strategy and emergency strategy. The designing of the adaptability strategies are considered geometric parameters and the weight of each of its components; both direct and inverse kinematics in position is essential for the robot could redirect. Statically stable is evaluated by using Normalized Energy Stability Margin. Adaptability strategies were simulated in MatLab and experimentally validated by using LabView.

Translated title of the contribution	Terrain adaptability strategies statically-stable for a walking hexapod robot
Original language	Spanish
Pages (from-to)	332-343
Number of pages	12
Journal	RIAI - Revista Iberoamericana de Automatica e Informatica Industrial
Volume	16
Issue number	3
DOIs	https://doi.org/10.4995/riai.2019.8979
State	Published - 2019

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title = "Estrategias de adaptabilidad est{\'a}ticamente estables al cambio de terreno para un robot caminante de seis extremidades",

abstract = "This article describes the forward and inverse kinematic model of position of the Hex-piderix robot, taking on account current attitude. Also three strategies to get terrain adaptability to the robot, guaranty statically stability are presented: constant orientation of the thorax, geometric strategy and emergency strategy. The designing of the adaptability strategies are considered geometric parameters and the weight of each of its components; both direct and inverse kinematics in position is essential for the robot could redirect. Statically stable is evaluated by using Normalized Energy Stability Margin. Adaptability strategies were simulated in MatLab and experimentally validated by using LabView.",

keywords = "Adaptability, Constant orientation of the thorax, Emergency strategy, Forward kinematics, Geometric strategy, Inverse kinematics, Stability",

author = "{Sandoval Castro}, {X. Yamile} and {Castillo Casta{\~n}eda}, Eduardo",

year = "2019",

doi = "10.4995/riai.2019.8979",

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AU - Sandoval Castro, X. Yamile

AU - Castillo Castañeda, Eduardo

PY - 2019

Y1 - 2019

N2 - This article describes the forward and inverse kinematic model of position of the Hex-piderix robot, taking on account current attitude. Also three strategies to get terrain adaptability to the robot, guaranty statically stability are presented: constant orientation of the thorax, geometric strategy and emergency strategy. The designing of the adaptability strategies are considered geometric parameters and the weight of each of its components; both direct and inverse kinematics in position is essential for the robot could redirect. Statically stable is evaluated by using Normalized Energy Stability Margin. Adaptability strategies were simulated in MatLab and experimentally validated by using LabView.

AB - This article describes the forward and inverse kinematic model of position of the Hex-piderix robot, taking on account current attitude. Also three strategies to get terrain adaptability to the robot, guaranty statically stability are presented: constant orientation of the thorax, geometric strategy and emergency strategy. The designing of the adaptability strategies are considered geometric parameters and the weight of each of its components; both direct and inverse kinematics in position is essential for the robot could redirect. Statically stable is evaluated by using Normalized Energy Stability Margin. Adaptability strategies were simulated in MatLab and experimentally validated by using LabView.

KW - Adaptability

KW - Constant orientation of the thorax

KW - Emergency strategy

KW - Forward kinematics

KW - Geometric strategy

KW - Inverse kinematics

KW - Stability

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SN - 1697-7912

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SP - 332

EP - 343

JO - RIAI - Revista Iberoamericana de Automatica e Informatica Industrial

JF - RIAI - Revista Iberoamericana de Automatica e Informatica Industrial

IS - 3

ER -

Estrategias de adaptabilidad estáticamente estables al cambio de terreno para un robot caminante de seis extremidades

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