Fuzzy Control Design for Table Tennis Robot to Strike Spinning Balls

Chung Hsun Sun; Ying Shu Chuang; Wen Jia Wu; Hsiang Chieh Chen

doi:10.18494/SAM4724

Fuzzy Control Design for Table Tennis Robot to Strike Spinning Balls

Chung Hsun Sun, Ying Shu Chuang, Wen Jia Wu, Hsiang Chieh Chen

Department of Mechanical Engineering

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

1 Scopus citations

Abstract

In this study, we propose a fuzzy control design for a table tennis robot to accurately strike ping-pong balls, regardless of whether they are topspinning or backspinning. The classification of topspin and backspin is determined through a comparison of ball trajectories measured by binocular vision with that of an ideal flying model derived from aerodynamics. By inputting trajectory features into the corresponding model, the striking signal, including contact position and hitting time, can be predicted. A fuzzy inference system is then utilized to derive the face angle of the racket at the hitting moment, which ultimately controls the robot to strike topspinning or backspinning balls. With an average error of approximately 3 cm for contact position prediction and less than 13.5 ms for hitting time prediction, our proposed fuzzy control design has demonstrated its effectiveness in striking spinning balls.

Original language	English
Pages (from-to)	2063-2074
Number of pages	12
Journal	Sensors and Materials
Volume	36
Issue number	5
DOIs	https://doi.org/10.18494/SAM4724
State	Published - 2024

Keywords

fuzzy control
table tennis robot
topspinning/backspinning ball

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10.18494/SAM4724

Cite this

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abstract = "In this study, we propose a fuzzy control design for a table tennis robot to accurately strike ping-pong balls, regardless of whether they are topspinning or backspinning. The classification of topspin and backspin is determined through a comparison of ball trajectories measured by binocular vision with that of an ideal flying model derived from aerodynamics. By inputting trajectory features into the corresponding model, the striking signal, including contact position and hitting time, can be predicted. A fuzzy inference system is then utilized to derive the face angle of the racket at the hitting moment, which ultimately controls the robot to strike topspinning or backspinning balls. With an average error of approximately 3 cm for contact position prediction and less than 13.5 ms for hitting time prediction, our proposed fuzzy control design has demonstrated its effectiveness in striking spinning balls.",

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AU - Sun, Chung Hsun

AU - Chuang, Ying Shu

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N1 - Publisher Copyright: © MYU K.K.

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N2 - In this study, we propose a fuzzy control design for a table tennis robot to accurately strike ping-pong balls, regardless of whether they are topspinning or backspinning. The classification of topspin and backspin is determined through a comparison of ball trajectories measured by binocular vision with that of an ideal flying model derived from aerodynamics. By inputting trajectory features into the corresponding model, the striking signal, including contact position and hitting time, can be predicted. A fuzzy inference system is then utilized to derive the face angle of the racket at the hitting moment, which ultimately controls the robot to strike topspinning or backspinning balls. With an average error of approximately 3 cm for contact position prediction and less than 13.5 ms for hitting time prediction, our proposed fuzzy control design has demonstrated its effectiveness in striking spinning balls.

AB - In this study, we propose a fuzzy control design for a table tennis robot to accurately strike ping-pong balls, regardless of whether they are topspinning or backspinning. The classification of topspin and backspin is determined through a comparison of ball trajectories measured by binocular vision with that of an ideal flying model derived from aerodynamics. By inputting trajectory features into the corresponding model, the striking signal, including contact position and hitting time, can be predicted. A fuzzy inference system is then utilized to derive the face angle of the racket at the hitting moment, which ultimately controls the robot to strike topspinning or backspinning balls. With an average error of approximately 3 cm for contact position prediction and less than 13.5 ms for hitting time prediction, our proposed fuzzy control design has demonstrated its effectiveness in striking spinning balls.

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Fuzzy Control Design for Table Tennis Robot to Strike Spinning Balls

Abstract

Keywords

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