In order to meet the actual operation demand of visual navigation during cotton field management period, image detection algorithm of visual navigation route during this period was investigated in this research. Firstly, for the operation images under natural environment, the approach of color component difference, which is applicable for cotton field management, was adopted to extract the target characteristics of different regions inside and outside cotton field. Secondly, the median filtering method was employed to eliminate noise in the images and realize smoothing process of the images. Then, according to the regional vertical cumulative distribution graph of the images, the boundary characteristic of the cotton seedling region was obtained and the central position of the cotton seedling row was determined. Finally, the detection of the candidate points cluster was realized, and the navigation route was extracted by Hough transformation passing the known point. The testing results showed that the algorithms could rapidly and accurately detect the navigation route during cotton field management period. And the average processing time periods for each frame image at the emergence, strong seedling, budding and blooming stages were 41.43 ms, 67.83 ms, 68.80 ms and 74.05 ms, respectively. The detection has the advantage of high accuracy, strong robustness and fast speed, and is simultaneously less vulnerable to interference from external environment, which satisfies the practical operation requirements of cotton field management machinery.
Keywords: visual navigation, route detection, Hough transformation passing the known point, cotton field management period
DOI: 10.25165/j.ijabe.20181106.3976

Citation: Li J B, Zhu R G, Chen B Q. Image detection and verification of visual navigation route during cotton field management period. Int J Agric & Biol Eng, 2018; 11(6): 159–165.

visual navigation, route detection, Hough transformation passing the known point, cotton field management period

Reid J F, Searcy S W. Detecting crop rows using the Hough transform. American Society of Agricultural Engineers. Microfiche collection (USA), 1986.

Søgaard H T, Olsen H J. Determination of crop rows by image analysis

without segmentation. Computers and Electronics in Agriculture, 2003; 38(2): 141–158.

Kaizu Y, Yokoyama S, Imou K, Nakamura Y. Vision-based navigation of a rice transplanter. Collection of Extent Abstracts of 2004 CIGR International Conference, 2004.

Marchant J A, Brivot R. Real-time tracking of plant rows using a Hough transform. Real-time Imaging, 1995; 1(5): 363–371.

Marchant J A. Tracking of row structure in three crops using image analysis. Computers and Electronics in Agriculture, 1996; 15(2): 161–179.

Yuan Z Y, Mao Z H, Wei Q. Crop rows positioning technology based on computer vision. Journal of China Agricultural University, 2005; 1(3): 69–72. (in Chinese)

Zhang Q, Huang X G, Li B. Centerline detection based on color model and nearest neighbor method paddy seedlings columns clustering. Transactions of the CSAE, 2012; 28(17): 163–171. (in Chinese)

Ding Y C, Wang S M, Chen H. Navigation path detection algorithm based on image rotation projection. Transaction of the CSAM. 2009; 40(8): 155–160. (in Chinese)

Si Y S, Jiang G Q, Liu G, Gao R, Liu Z X. Early crop row center line detection method based on least squares method. Transaction of the CSAM, 2010; 41(7): 163–167. (in Chinese)

Cao Q, Wang K, Li H. Dry multi-target line detection method based on machine vision. Transactions of the CSAE, 2010; (Supp): 187–191. (in Chinese)

Chen B Q, Tojo S, Watanabe K, Ai F, Huang B K. Studies on the Computer-eye of Rice Transplant Robot. Journal of the Japanese Society of Agricultural Machinery, 1997; 59(3): 23–28. (in Janpanese)

Chen B Q, Tojo S, Watanabe K. Machine vision based algorithmic guiding system for automatic rice transplanters. Applied Engineering in Agriculture, 2003; 19(1): 40–46.

Chen B Q, Tojo S, Watanabe K. Detection Algorithm for traveling route in paddy field for automated managing machines. Transaction of the ASAE, 2002; 45(1): 239–246.

Chen B Q, Tojo S, Watanabe K. Study on Machine Vision for Micro Weeding Robot in Paddy Field. Biosystems Engineering, 2003; 85(4): 393–404.

Zhao Y, Chen B Q, Wang S M, Dai F Y. Fast detection of furrows based on machine vision on autonomous mobile robot. Transactions of the CSAM, 2006; 37(4): 81–86. (in Chinese)

Zhang L, Wang S M, Chen B Q, Zhang H X. Crop-edge detection based on machine vision. New Zealand Journal of Agricultural Research, 2007; 50(5): 1367–1374.

Zhang H, Chen B Q, Zhang L. Detection algorithm for crop multi-centerlines based on machine vision. Transactions of the ASABE, 2008; 51(3): 1089–1097.

Li J B, Chen B Q, Liu Y. Study on image detection method of navigation route of the cotton plastic film mulch planter. Transactions of the CSAM, 2014; 45(1): 40–45. (in Chinese)

Li J B, Chen B Q, Liu Y, Cha T. Detection for navigation route for cotton harvester based on machine vision. Transactions of the CSAE, 2013; 29(11): 11–19. (in Chinese)

Haw C L, Ismail W I W, Kairunniza-Bejo S, Putih A, Shamshiri R. Colour vision to determine paddy maturity. Int J Agric & Biol Eng, 2014; 7(5): 55–63.