IJPAA

Abstract: Aiming at solving drawbacks of traditional spraying systems such as uniform spraying mode which is prone to waste of chemical pesticides and cannot be mounted on UAV, this paper designed a machine vision based system to identify crop coverage for target spraying by UAV.  This research built a hardware device of the system using Raspberry Pie as the main controller, and then analyzed the grayscale processing effect of the ultra-green method, ultra-green and Ultra-red method, standard deviation index method in sunny and cloudy days.  The result is that the Ultra-green and Ultra-red method has a better grayscale effect.  Therefore, a spraying decision model based on rice canopy coverage calculation was constructed in this research.  According to the rice canopy coverage, the system adjusts the spray nozzles to full, half, and no-spray states.  The rice canopy identification model is evaluated in this paper based on four indicators: relative error of coverage, grayscale time, segmentation time, and total time.  The experimental results show that the comprehensive performance of the ultra-green and ultra-red-maximum entropy is excellent, with the performance indexes of 5.43ms, 11.356ms, 11.356ms, 4.409ms, and 15.765 ms.  Water-sensitive paper droplet distribution experiments show that the system can reduce unnecessary agent waste and provide a reference for the application of machine vision technology to target spraying by plant protection UAV.

Keywords: plant protection UAV, target spraying, raspberry pie, rice canopy coverage, threshold segmentation

DOI: 10.33440/j.ijpaa.20200303.92

 

Citation: Jinbao Hong, Yubin Lan, Xuejun Yue, Zhenzhao Cen, Linhui Wang, Wen Peng, Yang Lu.  Adaptive target spray system based on machine vision for plant protection UAV.  Int J Precis Agric Aviat, 2020; 3(3): 65–71.

 

Zhao Q, Yu M, Xiao XH. A review of the research on China's agricultural innovation development model. Scientific Research Management, 2020, 41(03): 256–263. doi: 10.19571/j.cnki.1000-2995.2020.03.026. (in Chinese)

Wang J X, Li Y, Wang X D, et al. Status Quo of Pesticide Use in China and Its Outlook. Agricultural Outlook, 2017, 13(02): 56–60.(in Chinese)

Lu A. Analysis on the application status of plant protection UAV. Agricultural equipment technology, 2020, 46(02): 8–9. (in Chinese)

He X K. Plant protection precision pesticide application technology equipment. Agricultural Engineering Technology, 2017, 37(30): 22–26. doi: 10.16815/j.cnki.11-5436/s.2017.30.002. (in Chinese)

Giles D K, Slaughter D C. Precision band spraying with machine-vision guidance and adjustable yaw nozzles. Transactions of the ASAE, 1997, 40(1): 29–36. doi: 10.13031/2013.21240.

Zhou W. Research of variable spray device and control system for the target. Master dissertation. Zhejiang University, 2013. (in Chinese)

Wang L H, Gan H M, Yue X J, et al. Design of a precision spraying control system with unmanned aerial vehicle based on image recognition. Journal of South China Agricultural University, 2016, 37(6): 23–30. doi: 10.7671/j.issn.1001-411X.2016.06.004. (in Chinese)

Tian L. Development of a sensor-based precision herbicide application system. Computers and electronics in agriculture, 2002, 36(2-3): 133–149. doi: 10.1016/S0168-1699(02)00097-2.

Miranda-Fuentes A, Godoy-Nieto A, Gonzalez-Sanchez E J, et al. Reducing spray drift by adapting the spraying equipment to the canopy shape in olive orchards with isolated trees. Aspects of Applied Biology, 2018(137): 325–332.

Wu Y Q, Zhu Z D. 30 years (1962-1992) progress of threshold selection methods in image processing (1). Data collection and processing, 1993(03): 193–201. doi: 10.16337/j.1004-9037.1993.03.005. (in Chinese)

Yan J C. Technology on remote automatic monitoring of crop canopy coverage and height. Master dissertation. Zhejiang Sci-Tech University, 2016. (in Chinese)

Otsu N. A Threshold Selection Method from Gray-Level Histograms. IEEE Transactions on Systems Man & Cybernetics, 2007, 9(1): 62–66. doi: 10.1109/TSMC.1979.4310076.

Davis L S. A survey of edge detection techniques. Computer Graphics and Image Processing, 1975, 4(3): 248–270. doi: 10.1016/ 0146-664X(75)90012-X.

Adams R, Bischof L. Seeded region growing. IEEE Trans on Pattern Analysis and Machine Intelligence, 1994, 16(6): 641–647. doi: 10.1109/ 34.295913.

Meyer F. Skeletons and watershed lines in digital spaces. Proc of International Society for Optics and Photonics, 1990: 85–102. doi: 10.1117/12.23578.

Zhao D S. Real-time weed identification technology for precise spraying intelligent weeding device based on machine vision. Master dissertation. Jiangsu University, 2009. (in Chinese)

Liu Y Y, Wang Y Y, Yu H Y, et al. Detection of straw coverage rate based on multi-threshold image segmentation algorithm. Transactions of the Chinese Society for Agricultural Machinery, 2018, 49(12): 27–35. doi: 10.6041/j.issn.1000-1298.2018.12.004.(in Chinese)

Hu P C. High-throughput field morphological phenotyping using UAV-based proximal sensing. Ph.D. dissertation. China Agricultural University, 2018. (in Chinese)

Chen L J. Study on automatic control system of variable spraying based on machine vision. Ph.D. dissertation. Shenyang Agricultural University, 2009. (in Chinese)

He Y, Wu J J, Fang H, et al. Research on deposition effect of droplets based on plant protection unmanned aerial vehicle: A review. Journal of Zhejiang University (Agric. & Life Sci.), 2018, 44(04): 392–398+515. doi: 10.3785/j.issn.1008-9209.2018.07.020.(in Chinese)