Branch Interference Sensing and Handling by Tactile Enabled Robotic Apple Harvesting

Hongyu Zhou; Hanwen Kang; Xing Wang; Wesley Au; Michael Yu Wang; Chao Chen

doi:10.3390/agronomy13020503

Branch Interference Sensing and Handling by Tactile Enabled Robotic Apple Harvesting

Hongyu Zhou, Hanwen Kang, Xing Wang, Wesley Au, Michael Yu Wang, Chao Chen

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

22 Citations (Scopus)

Abstract

In the dynamic and unstructured environment where horticultural crops grow, obstacles and interference frequently occur but are rarely addressed, which poses significant challenges for robotic harvesting. This work proposed a tactile-enabled robotic grasping method that combines deep learning, tactile sensing, and soft robots. By integrating fin-ray fingers with embedded tactile sensing arrays and customized perception algorithms, the robot gains the ability to sense and handle branch interference during the harvesting process and thus reduce potential mechanical fruit damage. Through experimental validations, an overall 83.3–87.0% grasping status detection success rate, and a promising interference handling method have been demonstrated. The proposed grasping method can also be extended to broader robotic grasping applications wherever undesirable foreign object intrusion needs to be addressed.

Original language	English
Article number	503
Pages (from-to)	1-16
Number of pages	16
Journal	Agronomy
Volume	13
Issue number	2
DOIs	https://doi.org/10.3390/agronomy13020503
Publication status	Published - Feb 2023
Externally published	Yes

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title = "Branch Interference Sensing and Handling by Tactile Enabled Robotic Apple Harvesting",

abstract = "In the dynamic and unstructured environment where horticultural crops grow, obstacles and interference frequently occur but are rarely addressed, which poses significant challenges for robotic harvesting. This work proposed a tactile-enabled robotic grasping method that combines deep learning, tactile sensing, and soft robots. By integrating fin-ray fingers with embedded tactile sensing arrays and customized perception algorithms, the robot gains the ability to sense and handle branch interference during the harvesting process and thus reduce potential mechanical fruit damage. Through experimental validations, an overall 83.3–87.0% grasping status detection success rate, and a promising interference handling method have been demonstrated. The proposed grasping method can also be extended to broader robotic grasping applications wherever undesirable foreign object intrusion needs to be addressed.",

keywords = "agricultural robots, branch sensing, interference handling, robotic harvesting, tactile-enabled grasping",

author = "Hongyu Zhou and Hanwen Kang and Xing Wang and Wesley Au and Wang, {Michael Yu} and Chao Chen",

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T1 - Branch Interference Sensing and Handling by Tactile Enabled Robotic Apple Harvesting

AU - Zhou, Hongyu

AU - Kang, Hanwen

AU - Wang, Xing

AU - Au, Wesley

AU - Wang, Michael Yu

AU - Chen, Chao

PY - 2023/2

Y1 - 2023/2

N2 - In the dynamic and unstructured environment where horticultural crops grow, obstacles and interference frequently occur but are rarely addressed, which poses significant challenges for robotic harvesting. This work proposed a tactile-enabled robotic grasping method that combines deep learning, tactile sensing, and soft robots. By integrating fin-ray fingers with embedded tactile sensing arrays and customized perception algorithms, the robot gains the ability to sense and handle branch interference during the harvesting process and thus reduce potential mechanical fruit damage. Through experimental validations, an overall 83.3–87.0% grasping status detection success rate, and a promising interference handling method have been demonstrated. The proposed grasping method can also be extended to broader robotic grasping applications wherever undesirable foreign object intrusion needs to be addressed.

AB - In the dynamic and unstructured environment where horticultural crops grow, obstacles and interference frequently occur but are rarely addressed, which poses significant challenges for robotic harvesting. This work proposed a tactile-enabled robotic grasping method that combines deep learning, tactile sensing, and soft robots. By integrating fin-ray fingers with embedded tactile sensing arrays and customized perception algorithms, the robot gains the ability to sense and handle branch interference during the harvesting process and thus reduce potential mechanical fruit damage. Through experimental validations, an overall 83.3–87.0% grasping status detection success rate, and a promising interference handling method have been demonstrated. The proposed grasping method can also be extended to broader robotic grasping applications wherever undesirable foreign object intrusion needs to be addressed.

KW - agricultural robots

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KW - interference handling

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Branch Interference Sensing and Handling by Tactile Enabled Robotic Apple Harvesting

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