Position-Tracking Controller for Two-Wheeled Balancing Robot Applications Using Invariant Dynamic Surface

Seok Kyoon Kim; Choon Ki Ahn; Ramesh K. Agarwal

doi:10.1109/TSMC.2018.2882868

Position-Tracking Controller for Two-Wheeled Balancing Robot Applications Using Invariant Dynamic Surface

Seok Kyoon Kim
, Choon Ki Ahn
, Ramesh K. Agarwal

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

17 Scopus citations

Abstract

This paper suggests a position-tracking algorithm for the outer-loop through the invariant dynamic surface approach for balancing robot applications. The main feature is to devise a dynamic surface representing the target position-tracking performance with variable cut-off frequency. The proposed controller makes the dynamic surface invariant while updating the closed-loop cut-off frequency accordingly with the self-tuner. The closed-loop properties are rigorously analyzed. The experimental verification result shows that the proposed controller establishes the 48% enhancement of the circular tracking performance in comparison with the feedback linearization method, where the LEGO Mindstorms EV3 is used.

Original language	English
Article number	8567957
Pages (from-to)	705-711
Number of pages	7
Journal	IEEE Transactions on Systems, Man, and Cybernetics: Systems
Volume	51
Issue number	2
DOIs	https://doi.org/10.1109/TSMC.2018.2882868
State	Published - Feb 2021

Keywords

Performance recovery
position-tracking
robot balancing
self-tuner

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10.1109/TSMC.2018.2882868

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title = "Position-Tracking Controller for Two-Wheeled Balancing Robot Applications Using Invariant Dynamic Surface",

abstract = "This paper suggests a position-tracking algorithm for the outer-loop through the invariant dynamic surface approach for balancing robot applications. The main feature is to devise a dynamic surface representing the target position-tracking performance with variable cut-off frequency. The proposed controller makes the dynamic surface invariant while updating the closed-loop cut-off frequency accordingly with the self-tuner. The closed-loop properties are rigorously analyzed. The experimental verification result shows that the proposed controller establishes the 48\% enhancement of the circular tracking performance in comparison with the feedback linearization method, where the LEGO Mindstorms EV3 is used.",

keywords = "Performance recovery, position-tracking, robot balancing, self-tuner",

author = "Kim, \{Seok Kyoon\} and Ahn, \{Choon Ki\} and Agarwal, \{Ramesh K.\}",

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AU - Kim, Seok Kyoon

AU - Ahn, Choon Ki

AU - Agarwal, Ramesh K.

PY - 2021/2

Y1 - 2021/2

N2 - This paper suggests a position-tracking algorithm for the outer-loop through the invariant dynamic surface approach for balancing robot applications. The main feature is to devise a dynamic surface representing the target position-tracking performance with variable cut-off frequency. The proposed controller makes the dynamic surface invariant while updating the closed-loop cut-off frequency accordingly with the self-tuner. The closed-loop properties are rigorously analyzed. The experimental verification result shows that the proposed controller establishes the 48% enhancement of the circular tracking performance in comparison with the feedback linearization method, where the LEGO Mindstorms EV3 is used.

AB - This paper suggests a position-tracking algorithm for the outer-loop through the invariant dynamic surface approach for balancing robot applications. The main feature is to devise a dynamic surface representing the target position-tracking performance with variable cut-off frequency. The proposed controller makes the dynamic surface invariant while updating the closed-loop cut-off frequency accordingly with the self-tuner. The closed-loop properties are rigorously analyzed. The experimental verification result shows that the proposed controller establishes the 48% enhancement of the circular tracking performance in comparison with the feedback linearization method, where the LEGO Mindstorms EV3 is used.

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KW - robot balancing

KW - self-tuner

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JF - IEEE Transactions on Systems, Man, and Cybernetics: Systems

IS - 2

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ER -

Position-Tracking Controller for Two-Wheeled Balancing Robot Applications Using Invariant Dynamic Surface

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