Maize Characteristics Estimation and Classification by Spectral Data under Two Soil Phosphorus Levels

Baiyu Qiao,Wenxin Liu,Limin Liu,Joachim Müller,Yajia Liu,Hao Zhang,Alice-Jacqueline Reineke,Xiongkui He,Lanting Zhang

doi:10.3390/rs14030493

Baiyu Qiao, Wenxin Liu + Show 7 more

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https://doi.org/10.3390/rs14030493

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Abstract

As an essential element, the effect of Phosphorus (P) on plant growth is very significant. In the early growth stage of maize, it has a high sensitivity to the deficiency of phosphorus. The main purpose of this paper is to monitor the maize status under two phosphorus levels in soil by a nondestructive testing method and identify different phosphorus treatments by spectral data. Here, the Analytical Spectral Devices (ASD) spectrometer was used to obtain canopy spectral data of 30 maize inbred lines in two P-level fields, whose reflectance differences were compared and the sensitive bands of P were discovered. Leaf Area Index (LAI) and yield under two P levels were quantitatively analyzed, and the responses of different varieties to P content in soil were observed. In addition, the correlations between 13 vegetation indexes and eight phenotypic parameters were compared under two P levels so as to find out the best vegetation index for maize characteristics estimation. A Back Propagation (BP) neural network was used to evaluate leaf area index and yield, and the corresponding prediction model was established. In order to classify different P levels of soil, the method of support vector machine (SVM) was applied. The results showed that the sensitive bands of P for maize canopy included 763 nm, 815 nm, and 900–1000 nm. P-stress had a significant effect on LAI and yield of most varieties, whose reduction rate reached 41% as a whole. In addition, it was found that the correlations between vegetation indexes and phenotypic parameters were weakened under low-P level. The regression coefficients of 0.75 and 0.5 for the prediction models of LAI and yield were found by combining the spectral data under two P levels. For the P-level identification in soil, the classification accuracy could reach above 86%. These abilities potentially allow for phenotypic parameters prediction of maize plants by spectral data and different phosphorus contents identification with unknown phosphorus fertilizer status.

Highlights

IntroductionMaize is one of the most important and strongly expanding agricultural crops worldwide, having the potential for genetic adaptation to a wide climatic range
Notes: SD represents the standard deviation; Rd represents the relative reduction under low-P stress calculated by (mean (NP)-mean (LP))/mean (NP); CV represents the coefficient of variation; r represents the correlation coefficient, which is related to Leaf Area Index (LAI) and yields between low-P (LP) and normal-P treatment (NP); ** p < 0.01
This study focused on maize characteristics estimation and classification by spectral data under two soil phosphorus levels

Summary

Introduction

Maize is one of the most important and strongly expanding agricultural crops worldwide, having the potential for genetic adaptation to a wide climatic range. Global climate change may lead to abiotic stresses (such as low temperature, high temperature, drought, salinity, and so on), adversely affecting crop growth and reducing yields. Climate change causes corn yield to vary by approximately 30%, so it constitutes an important food security issue [1]. Maize is a cereal with a relatively high phosphate demand and a high sensitivity to phosphate-deficiency, in the early growth stage. Hyperspectral detection technology has become a hotspot of crop

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