昆虫学报 ›› 2024, Vol. 67 ›› Issue (4): 572-581.doi: 10.16380/j.kcxb.2024.04.013

• 研究论文 • 上一篇    下一篇

基于水稻冠层多信息融合的监测褐飞虱种群大小的BP神经网络方法

熊志强, 王嘉汉, 刘向东*   

  1. (南京农业大学植物保护学院昆虫学系, 南京 210095)
  • 出版日期:2024-04-20 发布日期:2024-05-24

BP neural network method for monitoring the population size of Nilaparvata lugens (Hemiptera: Delphacidae) based on multi-source data collected from rice canopy

XIONG Zhi-Qiang, WANG Jia-Han, LIU Xiang-Dong*    

  1. (Department of Entomology, College of Plant Protection, Nanjing Agricultural University, Nanjing 210095, China)
  • Online:2024-04-20 Published:2024-05-24

摘要: 【目的】褐飞虱 Nilaparvata lugens种群监测的自动化和智能化尚未实现。本研究旨在探究水稻受褐飞虱危害后冠层光谱和温度以及叶片叶绿素相对含量与为害虫量的关系,建立基于高光谱、热成像和叶绿素等多信息融合的误差反向传播(back propagation,BP)神经网络监测褐飞虱的方法,为田间褐飞虱种群监测向自动化与智能化方向发展提供方法支持。【方法】在可控条件下利用方形塑料框培育水稻,并在分蘖期接入雌雄1∶1配对的不同对数(0, 1, 2, 3, 4, 5, 6和7对)的褐飞虱雌、雄成虫,然后连续多次(接虫后16, 27, 32, 44和60 d时)调查接虫区水稻上褐飞虱虫量(每4穴稻上个体数),并采用高光谱仪和热成像仪分别测定水稻冠层光谱反射率和冠层温度,利用土壤和植物分析仪器开发(soil and plant analyzer development, SPAD)叶绿素仪测定叶片叶绿素的相对含量(SPAD值);采用Pearson相关法分析各测量指标与褐飞虱虫量的相关性;采用多元散射校正对光谱反射率数据进行降噪处理;采用连续投影算法对高光谱反射率数据进行降维和敏感波段筛选;分别以光谱反射率单一信息及其与冠层温度和SPAD值融合后的多源信息为输入量,采用普通和加入粒子群算法优化的BP神经网络建模,构建褐飞虱为害不同时段后种群大小的神经网络监测模型。【结果】褐飞虱为害后水稻冠层光谱在近红外的730-930 nm波段反射率、水稻冠层温度与气温的差值(冠气温差)和叶片的SPAD值均与褐飞虱虫量呈显著负相关。利用连续投影算法筛选出的冠层光谱敏感波段处反射率并降噪后建立的BP神经网络监测5个危害时段褐飞虱虫量的预测集决定系数R2在0.504~0.892之间;融合冠层光谱、冠气温差和叶片SPAD值等多信息建立的BP神经网络监测褐飞虱虫量的预测集R2提升到0.640~0.975;在多源信息基础上再选用粒子群优化(particle swarm optimization, PSO)算法优化BP神经网络后监测褐飞虱虫量的精度提高,预测集R2提升到0.931~0.991,模型预测效果好。【结论】基于水稻冠层高光谱与热成像和叶片SPAD值等多信息融合的PSO-BP神经网络方法监测褐飞虱虫量的精度高、效果好,有望用于田间褐飞虱种群的自动监测。

关键词: 褐飞虱, 冠层光谱反射率, 冠层温度, 叶绿素SPAD, BP神经网络, 粒子群优化

Abstract: 【Aim】 The automation and intelligence of population monitoring of the brown planthopper, Nilaparvata lugens, have not been resolved now. The aim of this study is to explore the relationship of canopy spectrum and temperature, and leaf chlorophyll content with the number of N. lugens on rice plants, and to establish a back propagation (BP) neural network to monitor the population size of N. lugens based on multi-source information fusion of hyperspectral, thermal imaging, and chlorophyll, so as to provide a new method for the development of automation and intelligence in monitoring N. lugens populations. 【Methods】 Under controlled conditions, rice was cultivated using the square plastic box, and different pairs (0, 1, 2, 3, 4, 5, 6 and 7 pairs) of female and male adults of N. lugens (female to male ratio=1∶1) were released onto rice plants at the tillering stage. Then, the number of N. lugens on rice (number of individuals per 4 hills of rice) was investigated on day 16, 27, 32, 44 and 60 post original infestation, and the spectral reflectance and temperature of rice canopy were measured using a hyperspectral spectrometer and a thermal imager, respectively. The relative content of chlorophyll in leaves was measured using a chlorophyll meter (soil and plant analyzer development, SPAD) as SPAD readings. The Pearson correlation method was used to analyze the correlations between these measured indexes and the number of N. lugens. The multivariate scattering correction was used to process the spectral reflectance data to reduce noise. The successive projection algorithm was adopted for dimensionality reduction and screening the sensitive band of hyperspectral reflectance. Using single source of spectral reflectance information and its multi-source information fusion with canopy temperature and SPAD readings as inputs, the modeling methods, the general (BPNN) and optimized BP neural networks by particle swarm optimization (PSO-BPNN) were used to establish the neural network models to monitor the population sizes of N. lugens damaging different periods. 【Results】 The reflectance from rice canopy at the near-infrared band 730-930 nm was significantly negatively correlated with the number of N. lugens damaging rice plants, and the temperature difference between rice canopy and air (TDC) and the SPAD readings of leaves were also significantly negatively correlated with the number of N. lugens. The coefficient of determination R2 of the prediction set for monitoring the population size of N. lugens using the BPNN based on the noise reduction value of reflectance at the sensitive band of rice canopy screened by the successive projection algorithm could reach up to 0.504-0.892. The R2 of the predication set for monitoring the number of N. lugens by the BP neural network based on multi-source information fusion of canopy reflectance, TDC, and leaf SPAD readings could reach up to 0.640-0.975. Further, on the basis of multi-source information, the BP neural network optimized by particle swarm optimization (PSO) algorithm improved the accuracy for monitoring the number of N. lugens, and the R2 value of the predication set was up to 0.931-0.991. 【Conclusion】 The PSO-BP neural network method based on multi-source information fusion of rice canopy hyperspectral and thermal imaging, as well as leaf SPAD readings, has high accuracy and good effectiveness in monitoring the number of N. lugens, and is expected to be applied for automatic monitoring of N. lugens populations in paddy fields.

Key words: Nilaparvata lugens; canopy spectral reflectance, canopy temperature, chlorophyll SPAD, BP neural network, particle swarm optimization