Journal of Biosystems Engineering

Korean Society for Agricultural Machinery (한국농업기계학회)
권호 표지
DOI QR코드

DOI QR Code

Multi-functional Automated Cultivation for House Melon;Development of Tele-robotic System

시설멜론용 다기능 재배생력화 시스템;원격 로봇작업 시스템 개발

  • Im, D.H. (National Institute of Agricultural Engineering) ;
  • Kim, S.C. (National Institute of Agricultural Engineering) ;
  • Cho, S.I. (Seoul National University) ;
  • Chung, S.C. (Dept. of Biomechatronic Engineering, Sungkyunkwan University) ;
  • Hwang, H. (Dept. of Biomechatronic Engineering, Sungkyunkwan University)
  • Published : 2008.06.25
Download PDF
⟨ Previous Next ⟩

Abstract

In this paper, a prototype tele-operative system with a mobile base was developed in order to automate cultivation of house melon. A man-machine interactive hybrid decision-making system via tele-operative task interface was proposed to overcome limitations of computer image recognition. Identifying house melon including position data from the field image was critical to automate cultivation. And it was not simple especially when melon is covered partly by leaves and stems. The developed system was composed of 5 major modules: (a) main remote monitoring and task control module, (b) wireless remote image acquisition and data transmission module, (c) three-wheel mobile base mounted with a 4 dof articulated type robot manipulator (d) exchangeable modular type end tools, and (e) melon storage module. The system was operated through the graphic user interface using touch screen monitor and wireless data communication among operator, computer, and machine. Once task was selected from the task control and monitoring module, the analog signal of the color image of the field was captured and transmitted to the host computer using R.F. module by wireless. A sequence of algorithms to identify location and size of a melon was performed based on the local image processing. Laboratory experiment showed the developed prototype system showed the practical feasibility of automating various cultivating tasks of house melon.

Keywords

References

  1. Arima, S. and N. Kondo. 1994. Study on cucumber harvesting robot. J. of JSAM 56(6):69-76
  2. Hwang, H. and S. C. Kim. 2003. Multi-functional teleoperative modular robotic system for greenhouse watermelon. J. of KSAM 28(6):517-524
  3. Kim, S. C. and H. Hwang. 2003. Interface of tele-task operation for automated cultivation of watermelon in greenhouse. J. of KSAM 28(6):511-516
  4. Kim, S. C. and H. Hwang. 2004. Development of real time and robust feature extraction algorithm of watermelon for tele-robotic operation. J. of Biosystems Engineering 29(1): 71-78 https://doi.org/10.5307/JBE.2004.29.1.071
  5. Kondo, N., Y. Nishitsuji, P. P. Ling and K. C. Ting. 1996. Visual feedback guided robotic cherry tomato harvesting. Trans. of ASAE 39:2331-2338 https://doi.org/10.13031/2013.27744
  6. Kondo, N. and K. C. Ting, 1998. Robotics for Bioproduction Systems, ASAE
  7. Shirai, Y., N. Kondo and T. Fujiurab. 1998. Machine Vision in Robotics for Bioproduction Systems (N. Kondo and K. C. Ting (Ed), pp. 65-107. ASAE
  8. Umeda, M., M. Iida and S. Kubota, 1997. Development of Watermelon Harvesting Robot Stork, Bio-Robotics 97, Spain, 137-142