Estimation of Aboveground Biomass of Potatoes Based on Characteristic Variables Extracted from UAV Hyperspectral Imagery

Remote. Sens. Pub Date : 2022-10-13 DOI:10.3390/rs14205121
Yang Liu, Haikuan Feng, Jibo Yue, Zhenhai Li, Xiuliang Jin, Yiguang Fan, Zhihang Feng, Guijun Yang
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引用次数: 6

Abstract

Aboveground biomass (AGB) is an important indicator for crop-growth monitoring and yield prediction, and accurate monitoring of AGB is beneficial to agricultural fertilization management and optimization of planting patterns. Imaging spectrometer sensors mounted on unmanned aerial vehicle (UAV) remote-sensing platforms have become an important technical method for monitoring AGB because the method is convenient, rapidly collects data and provides image data with high spatial and spectral resolution. To confirm the feasibility of UAV hyperspectral remote-sensing technology to estimate AGB, this study acquired hyperspectral images and measured AGB data over the potato bud, tuber formation, tuber growth, and starch-storage periods. The canopy spectrum obtained in each growth period was smoothed by using the Savitzky–Golay filtering method, and the spectral-reflection feature parameters, spectral-location feature parameters, and vegetation indexes were extracted. First, a Pearson correlation analysis was performed between the three types of characteristic spectral parameters and AGB, and the spectral parameters that reached a significant level of 0.01 in each growth period were selected. Next, the spectral parameters reaching a significance of 0.01 were optimized and screened by moving window partial least squares (MWPLS), Monte Carlo uninformative variable elimination (MC-UVE), and random frog (RF) methods, and the final model parameters were determined according to the thresholds of the root mean square error of cross-validation (RMSEcv), the reliability index, and the selected probability. Finally, the three optimal characteristic spectral parameters and their combinations were used to estimate the potato AGB in each growth period by combining the partial least squares regression (PLSR) and Gaussian process regression (GPR) methods. The results show that, (i) ranked from high to low, vegetation indexes, spectral-location feature parameters, and spectral-reflection feature parameters in each growth period are correlated with the AGB, and these correlations all first improve and then degrade in going from the budding period to the starch-storage period. (ii) The AGB estimation model based on the characteristic variables screened by the three methods in each growth period is most accurate with RF, less so with MC-UVE, and least accurate with MWPLS. (iii) Estimating the AGB with the same variables combined with the PLSR method in each growth period is more accurate than the corresponding GPR method, but the estimations produced by the two methods both show a trend of first improving and then worsening from the budding period to the starch-accumulation period. The accuracy of the estimation models constructed by PLSR and GPR from high to low is based on comprehensive variables, vegetation indexes, spectral-location feature parameters and spectral-reflection feature parameters. (iv) When combined with the RF-PLSR method to estimate AGB in each growth period, the best R2 values are 0.65, 0.68, 0.72, and 0.67, the corresponding RMSE values are 167.76, 162.98, 160.77, and 169.24 kg/hm2, and the corresponding NRMSE values are 19.76%, 16.01%, 15.04%, and 16.84%. The results of this study show that a variety of characteristic spectral parameters may be extracted from UAV hyperspectral images, that the RF method may be used for optimizing and screening, and that PLSR regression provides accurate estimates of the potato AGB. The proposed approach thus provides a rapid, accurate, and nondestructive way to monitor the growth status of potatoes.
基于无人机高光谱影像特征变量的马铃薯地上生物量估算
地上生物量(AGB)是作物生长监测和产量预测的重要指标,准确监测地上生物量有利于农业施肥管理和种植模式优化。安装在无人机遥感平台上的成像光谱仪传感器具有方便、快速采集数据、提供高空间和光谱分辨率的图像数据等优点,已成为监测AGB的重要技术手段。为了验证无人机高光谱遥感技术估算AGB的可行性,本研究采集了马铃薯芽、块茎形成、块茎生长和淀粉贮藏期的高光谱图像和AGB数据。利用Savitzky-Golay滤波方法对各生长期的冠层光谱进行平滑处理,提取光谱反射特征参数、光谱定位特征参数和植被指数。首先,对3类特征光谱参数与AGB进行Pearson相关分析,选取各生育期达到0.01显著水平的光谱参数。其次,采用移动窗口偏最小二乘法(MWPLS)、蒙特卡罗无信息变量消去法(MC-UVE)和随机青蛙法(RF)对显著性达到0.01的光谱参数进行优化筛选,并根据交叉验证均方根误差阈值(RMSEcv)、可靠性指标和选择概率确定最终模型参数。最后,采用偏最小二乘回归(PLSR)和高斯过程回归(GPR)相结合的方法,利用3个最优特征光谱参数及其组合估算马铃薯各生育期的AGB。结果表明:(1)各生育期植被指数、光谱定位特征参数和光谱反射特征参数与AGB的相关性由高到低,且从出芽期到淀粉贮藏期,这些相关性都先提高后降低。(ii)基于三种方法筛选的各生长期特征变量的AGB估计模型,RF估计精度最高,MC-UVE估计精度较低,MWPLS估计精度最低。(iii)在相同变量下,结合PLSR法估算各生育期的AGB比对应的GPR法更准确,但从出芽期到淀粉积累期,两种方法估算的AGB均呈现先提高后下降的趋势。PLSR和GPR构建的估算模型从高到低的精度是基于综合变量、植被指数、光谱定位特征参数和光谱反射特征参数。(iv)结合RF-PLSR法估算各生长期AGB时,最佳R2值分别为0.65、0.68、0.72和0.67,对应RMSE值分别为167.76、162.98、160.77和169.24 kg/hm2,对应NRMSE值分别为19.76%、16.01%、15.04%和16.84%。研究结果表明,无人机高光谱图像可提取多种特征光谱参数,射频方法可用于优化筛选,PLSR回归可准确估计马铃薯AGB。因此,提出的方法提供了一种快速、准确和无损的方法来监测马铃薯的生长状况。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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