Abstract
The detection of rice leaf folder (RLF) infestation usually depends on manual monitoring, and early infestations cannot be detected visually. To improve detection accuracy and reduce human error, we use push-broom hyperspectral sensors to scan rice images and use machine learning and deep neural learning methods to detect RLF-infested rice leaves. Different from traditional image processing methods, hyperspectral imaging data analysis is based on pixel-based classification and target recognition. Since the spectral information itself is a feature and can be considered a vector, deep learning neural networks do not need to use convolutional neural networks to extract features. To correctly detect the spectral image of rice leaves infested by RLF, we use the constrained energy minimization (CEM) method to suppress the background noise of the spectral image. A band selection method was utilized to reduce the computational energy consumption of using the full-band process, and six bands were selected as candidate bands. The following method is the band expansion process (BEP) method, which is utilized to expand the vector length to improve the problem of compressed spectral information for band selection. We use CEM and deep neural networks to detect defects in the spectral images of infected rice leaves and compare the performance of each in the full frequency band, frequency band selection, and frequency BEP. A total of 339 hyperspectral images were collected in this study; the results showed that six bands were sufficient for detecting early infestations of RLF, with a detection accuracy of 98% and a Dice similarity coefficient of 0.8, which provides advantages of commercialization of this field.
Highlights
Rice leaf folder (RLF), Cnaphalocrocis medinalis Guenée, is widely distributed in the rice-growing regions of humid tropical and temperate countries [1], and the developmental time of RLF decreases with an increase in temperature [2]
To obtain different levels of damage caused by RLF, e.g., lineal white stripes (LWSs) and ocher patches (OPs), 1st, 2nd, 3rd, 4th, or 5th-instar larvae of RLF were manually introduced to infest 40-day-old healthy rice for seven days, and three replicates were conducted for each treatment
The LWSs are enlarged into a patch; the color of the patch gradually turns from white to ocher; and the images and spectral signatures of these patches change during this process, as shown in Figure 7a,b, respectively
Summary
Rice leaf folder (RLF), Cnaphalocrocis medinalis Guenée, is widely distributed in the rice-growing regions of humid tropical and temperate countries [1], and the developmental time of RLF decreases with an increase in temperature [2]. RLF has become one of the most important insect pests of rice cultivation [3]. The larvae of RLF fold the leaves longitudinally and feed on the mesophyll tissue within the folded leaves. The feeding of RLF generates lineal white stripes (LWSs) in the early stage and enlarge into ocher patches (OPs) and membranous OPs [4]. As the infestation of RLF increases, the number and area of OPs will increase. The feeding of RLF reduced the chlorophyll content and photosynthesis efficiency [4] and provided a method for fungal and bacterial infection [5]. The severe damage caused by RLF may cause
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
