Research on Cotton Chemical Topping System Based on Apical Bud Intelligent Recognition

A cotton chemical topping system based on top bud intelligent recognition was designed to achieve precise operation, rational and efficient use of cotton chemical topping agents, and reduce environmental pollution caused by excessive use of chemical topping agents. The system mainly consisted of cotton top bud recognition system, control system, and spraying system. A cotton top bud recognition model was constructed by using the YOLO v5s algorithm. The control system adopted STM32F407 microcontroller, which was responsible for receiving signals from the recognition system and controlling various cotton topping agent pipelines. At the same time, the display interface can display real-time parameters such as the driving speed of the equipment, the flow rate of the medicine, and the liquid level of the topping agent. The experimental results showed that in the field all day light experiment, the morning and afternoon time periods had the best recognition performance. At a speed of 0.4m/s, the average recognition rate was about 94%. When the signal transmission interval was 100mm, the success rate of successfully sending signals to the lower computer reached 92%. The field target spraying experiment showed that the effective spraying rate was 94%, which met the spraying requirements.

Keywords: cotton; chemical topping; control system; YOLO v5s; apical bud recognition

 

LIU Haitao, YI Lili, LAN Yubin, et al. Research progress in the application of machine vision in the field of cotton intelligent topping [J]. Journal of Chinese Agricultural Mechanization, 2021 , 42(6) ; 159 - 165. (in Chinese)

HAN Changjie, V AN Changhui, QIU Shilong, et al. Design and experiment of double disc cotton topping device based on machine vision [ J ]. Transactions of the Chinese Society for Agricultural Machinery, 2023, 54(5) : 36 -46. (in Chinese)

PENG Qiangji, KANG Jianming, SONG Yuinin, et al. Design of 3MDZ— 4 self-propelled cotton topping and spraying combined machine [ J ]. Transactions of the CSAE,2019, 35( 14) : 30 -38. (in Chinese)

ZHOU Haiyan, YIN Suzhen, ZHU Licheng, et al. Design of3WDZ—6 self-propelled cotton top cutting [J ]. Transactions of the Chinese Society for Agricultural Machinery, 2010, 41(Supp. ) : 86 -89. (in Chinese)

HE Lei, LIU Xiangxin, ZHOU Yali, et al. Verticallift type single profiling cotton topping machine [J ]. Transactions of the Chinese Society for Agricultural Machinery, 2013, 44(Supp.2) : 62 -67. (in Chinese)

QI Haikun, WANG Sai, XU Dongyong, et al. Cotton chemical topping by applying DPC in different cotton-growing regions [J]. Cotton Science, 2020, 32(5) : 425 -437. (in Chinese)

BOURLAND F M, OOSTERHUIS D M, TUGWELL N P. Concept for monitoring the growth and development of cotton plants using main-stem node counts [J] . Journal of Production Agriculture, 1992(5) : 532 -538.

MCCONNELL J S, GLOVER R E, VORIES E D, et al. Nitrogen fertilization and plant development of cotton as determined by nodes above white flower [ J ]. Journal of Plant Nutrition, 1995, 18(5) ; 1027 - 1036.

ANG Chengxun, ZHANG Wangfeng, XU Shouzhen, et al. Effects of spraying chemical topping agents on canopy structure and canopy photosynthetic production in cotton [ J ]. Scientia Agriculture Sinica, 2016, 49(9) ; 1672 - 1684. (in Chinese)

GRAVALOS I, ZIAKAS N, LOUTRIDIS S, et al. A mechatronic system for automated topping and suckering of tobacco plants [J]. Computers and Electronics in Agriculture, 2019, 166: 104986.

TUFAIL M, IQBALL J, TIWANA M I, et al. Identification of tobacco crop based on machine learning for a precision agricultural sprayer [J] . IEEE Access, 2021 , 9: 23814 -23825.

ZHENG Shenyu, ZHAO Xueguan, ZHANG Xinwei, et al. Design of an intermittent herbicide spray system for open-field cabbage and plant protection effect experiments[ J ]. Agronomy, 2023, 13(2) ; 286.

DAMMER К H. Real-time variable-rate herbicide application for weed control in carrots [ J]. Weed Research, 2016, 56(3) : 237 -246.

ROCHA F C, OLIVEIRA NETO A M, BOTTEGA E L, et al. Weed mapping using techniques of precision agriculture[ J ]. Planta Daninha, 2015(33) ; 157 - 164.

LIU Junqi. The research of automatic recognition of cotton’s top [ D ]. Shihezi: Shihezi University, 2009. (in Chinese)

SHEN Xiaochen. The height of the cotton plant identification technology for cotton top-cutting machine[ D]. Shihezi; Shihezi University, 2018. (in Chinese)

LIU Haitao. Research on cotton top buds recognition system based on deep learning [D]. Zibo; Shandong University of Technology, 2022. (in Chinese)

RAYKAR V C, SAHA A. Data split strategies for evolving predictive models [ С ] // Machine Learning and Knowledge Discovery in Databases, Springer, 2015: 3 - 19.

ZHAO Xinlong, GU Zhenqi, LI Jun. Larvae of black soldier fly counting based on YOLO v5s network and improved SORT aigorithm J . Transactions of the Chinese Society for Agricultural Machinery, 2023, 54(7) ; 339 -346. (in Chinese)

LU Wei, ZOU Mingxuan, SHI Haonan, et al. Technology of visual identification — measuring — location for brown mushroom picking based on YOLO v5 — TL J . Transactions of the Chinese Society for Agricultural Machinery, 2022, 53( 11) : 341 - 348. (in Chinese)

ZHAI Changyuan, FU Нао, ZHENG Kang, et al. Establishment and experimental verification of deep learning model for on¬line recognitior of field cabbage [j]. Transactions of the Chinese Society for Agricultural Machinery, 2022, 53(4); 293 - 303. (in Chinese)