Climbing control of autonomous mobile robot with estimation of wheel slip and wheel-ground contact angle

Nabih Pico; Hong ryul Jung; Juan Medrano; Meseret Abayebas; Dong Yeop Kim; Jung Hoon Hwang; Hyungpil Moon

doi:10.1007/s12206-022-0142-6

Climbing control of autonomous mobile robot with estimation of wheel slip and wheel-ground contact angle

Nabih Pico
, Hong ryul Jung
, Juan Medrano
, Meseret Abayebas
, Dong Yeop Kim
, Jung Hoon Hwang
, Hyungpil Moon

Department of Mechanical Engineering

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

29 Scopus citations

Abstract

The objective of this work is to control a delivery robot equipped with a passive bogie that can successfully climb up steps of various sizes and move on uneven terrain in outdoor environments. The kinematic model of a six-wheel mobile robot is described in detail. Jacobian matrices and inverse kinematics are obtained to get the velocity of each wheel based on the desired velocity of the robot center of mass in conjunction with the terrain information obtained by the onboard sensors according to the contact angle estimation between the wheel and ground. A slip control is implemented based on slip ratio to adjust the wheel velocity when the slip is detected. Simulation and experimental results verify the effectiveness of the approach that enables the robot autonomously climbing up on different steps and uneven terrain.

Original language	English
Pages (from-to)	959-968
Number of pages	10
Journal	Journal of Mechanical Science and Technology
Volume	36
Issue number	2
DOIs	https://doi.org/10.1007/s12206-022-0142-6
State	Published - Feb 2022

Keywords

Autonomous mobile robot
Contact angle estimation
Kinematic analysis
Slip control

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10.1007/s12206-022-0142-6

Cite this

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title = "Climbing control of autonomous mobile robot with estimation of wheel slip and wheel-ground contact angle",

abstract = "The objective of this work is to control a delivery robot equipped with a passive bogie that can successfully climb up steps of various sizes and move on uneven terrain in outdoor environments. The kinematic model of a six-wheel mobile robot is described in detail. Jacobian matrices and inverse kinematics are obtained to get the velocity of each wheel based on the desired velocity of the robot center of mass in conjunction with the terrain information obtained by the onboard sensors according to the contact angle estimation between the wheel and ground. A slip control is implemented based on slip ratio to adjust the wheel velocity when the slip is detected. Simulation and experimental results verify the effectiveness of the approach that enables the robot autonomously climbing up on different steps and uneven terrain.",

keywords = "Autonomous mobile robot, Contact angle estimation, Kinematic analysis, Slip control",

author = "Nabih Pico and Jung, \{Hong ryul\} and Juan Medrano and Meseret Abayebas and Kim, \{Dong Yeop\} and Hwang, \{Jung Hoon\} and Hyungpil Moon",

note = "Publisher Copyright: {\textcopyright} 2022, The Korean Society of Mechanical Engineers and Springer-Verlag GmbH Germany, part of Springer Nature.",

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AU - Pico, Nabih

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AU - Medrano, Juan

AU - Abayebas, Meseret

AU - Kim, Dong Yeop

AU - Hwang, Jung Hoon

AU - Moon, Hyungpil

PY - 2022/2

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N2 - The objective of this work is to control a delivery robot equipped with a passive bogie that can successfully climb up steps of various sizes and move on uneven terrain in outdoor environments. The kinematic model of a six-wheel mobile robot is described in detail. Jacobian matrices and inverse kinematics are obtained to get the velocity of each wheel based on the desired velocity of the robot center of mass in conjunction with the terrain information obtained by the onboard sensors according to the contact angle estimation between the wheel and ground. A slip control is implemented based on slip ratio to adjust the wheel velocity when the slip is detected. Simulation and experimental results verify the effectiveness of the approach that enables the robot autonomously climbing up on different steps and uneven terrain.

AB - The objective of this work is to control a delivery robot equipped with a passive bogie that can successfully climb up steps of various sizes and move on uneven terrain in outdoor environments. The kinematic model of a six-wheel mobile robot is described in detail. Jacobian matrices and inverse kinematics are obtained to get the velocity of each wheel based on the desired velocity of the robot center of mass in conjunction with the terrain information obtained by the onboard sensors according to the contact angle estimation between the wheel and ground. A slip control is implemented based on slip ratio to adjust the wheel velocity when the slip is detected. Simulation and experimental results verify the effectiveness of the approach that enables the robot autonomously climbing up on different steps and uneven terrain.

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KW - Contact angle estimation

KW - Kinematic analysis

KW - Slip control

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Climbing control of autonomous mobile robot with estimation of wheel slip and wheel-ground contact angle

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Keywords

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