TY - JOUR
T1 - Agricultural Robot under Solar Panels for Sowing, Pruning, and Harvesting in a Synecoculture Environment
AU - Otani, Takuya
AU - Itoh, Akira
AU - Mizukami, Hideki
AU - Murakami, Masatsugu
AU - Yoshida, Shunya
AU - Terae, Kota
AU - Tanaka, Taiga
AU - Masaya, Koki
AU - Aotake, Shuntaro
AU - Funabashi, Masatoshi
AU - Takanishi, Atsuo
N1 - Funding Information:
This study was conducted with the support of the Research Institute for Science and Engineering, Waseda University; Future Robotics Organization, Waseda University. Further, it was supported in part by SolidWorks Japan K.K. This work was also supported by Sustainergy Company. The sponsor had no control over the interpretation, writing, or publication of this study. We thank all these organizations for the financial and technical support provided. Synecoculture ™ is a trademark of Sony Group Corporation.
Publisher Copyright:
© 2022 by the authors.
PY - 2023/1
Y1 - 2023/1
N2 - Currently, an agricultural method called SynecocultureTM has been receiving attention as a means for multiple crop production and recovering from environmental degradation; it helps in regreening the environment and establishing an augmented ecosystem with high biodiversity. In this method, several types of plants are grown densely, and their management relies mainly on manual labor, since conventional agricultural machines and robots cannot be applied in complex vegetation. To improve work efficiency and boost regreening by scaling-up Synecoculture, we developed a robot that can sow, prune, and harvest in dense and diverse vegetation that grows under solar panels, towards the achievement of compatibility between food and energy production on a large scale. We adopted a four-wheel mechanism with sufficient ability to move on uneven terrain, and a two orthogonal axes mechanism with adjusted tool positioning while performing management tasks. In the field experiment, the robot could move straight on shelving slopes and overcome obstacles, such as small steps and weeds, and succeeded in harvesting and weeding with human operation, using the tool maneuver mechanism based on the recognition of the field situation through camera image.
AB - Currently, an agricultural method called SynecocultureTM has been receiving attention as a means for multiple crop production and recovering from environmental degradation; it helps in regreening the environment and establishing an augmented ecosystem with high biodiversity. In this method, several types of plants are grown densely, and their management relies mainly on manual labor, since conventional agricultural machines and robots cannot be applied in complex vegetation. To improve work efficiency and boost regreening by scaling-up Synecoculture, we developed a robot that can sow, prune, and harvest in dense and diverse vegetation that grows under solar panels, towards the achievement of compatibility between food and energy production on a large scale. We adopted a four-wheel mechanism with sufficient ability to move on uneven terrain, and a two orthogonal axes mechanism with adjusted tool positioning while performing management tasks. In the field experiment, the robot could move straight on shelving slopes and overcome obstacles, such as small steps and weeds, and succeeded in harvesting and weeding with human operation, using the tool maneuver mechanism based on the recognition of the field situation through camera image.
KW - agricultural robots
KW - harvesting
KW - pruning
KW - sowing
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U2 - 10.3390/agriculture13010018
DO - 10.3390/agriculture13010018
M3 - Article
AN - SCOPUS:85146679410
SN - 2077-0472
VL - 13
JO - Agriculture (Switzerland)
JF - Agriculture (Switzerland)
IS - 1
M1 - 18
ER -