PROSPECT-GPR: Exploring spectral associations among vegetation traits in wavelength selection for leaf mass per area and water contents

IF 5.7 Q1 ENVIRONMENTAL SCIENCES Science of Remote Sensing Pub Date : 2023-09-12 DOI:10.1016/j.srs.2023.100100
Chunmei He , Jia Sun , Yuwen Chen , Lunche Wang , Shuo Shi , Feng Qiu , Shaoqiang Wang , Jian Yang , Torbern Tagesson
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Abstract

Leaf mass per area (LMA) and equivalent water thickness (EWT) are key indicators providing information on plant growth status and agricultural management, and their retrieval is commonly done through radiative transfer models (RTMs) such as the PROSPECT model. However, the PROSPECT model is frequently hampered by the ill-posed problem as a consequence of measurement and model uncertainties. Here, we propose a wavelength selection method to improve the inversion of EWT and LMA by integrating PROSPECT with a machine learning algorithm (Gaussian process regression (GPR); PROSPECT-GPR for short). The GPR model conducted sorting of wavelengths and the PROSPECT-D was used to determine the optimal number of characteristic wavelengths. The results demonstrated that the estimation of EWT (R2 = 0.80; RMSE = 0.0021) and LMA (R2 = 0.71; RMSE = 0.0021) using the proposed wavelengths and PROSPECT inversion all exhibited superior accuracy in comparison with those from previous studies. The efficacy of PROSPECT-GPR in exploring the spectral linkage among vegetation traits was demonstrated by selecting wavelengths associated with leaf structure parameter N and EWT (1368 nm) that turn out to contribute to the estimation of LMA. The findings lay a strong foundation for understanding the spectral linkage among vegetation traits, and the proposed wavelength selection method provides valuable insights for selecting informative spectral wavelengths for RTMs inversion and designing future remote sensors.

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展望-探地雷达:探索植被性状在叶面积质量和含水量波长选择中的光谱关联
每面积叶质量(LMA)和等效水厚(EWT)是反映植物生长状况和农业管理的关键指标,它们的反演通常通过辐射转移模型(RTMs)实现,如PROSPECT模型。然而,由于测量和模型的不确定性,PROSPECT模型经常受到不适定问题的阻碍。在这里,我们提出了一种波长选择方法,通过将PROSPECT与机器学习算法(高斯过程回归(GPR))相结合来改进EWT和LMA的反演;探地雷达(简称gpr)。探地雷达模型对波长进行分类,利用PROSPECT-D确定最佳特征波长数。结果表明,EWT的估计(R2 = 0.80;RMSE = 0.0021)和LMA (R2 = 0.71;RMSE = 0.0021),与以往的研究相比,使用所提出的波长和PROSPECT反演均显示出更高的精度。通过选择与叶片结构参数N和EWT (1368 nm)相关的波长来估算LMA, PROSPECT-GPR在探索植被性状之间的光谱联系方面的有效性得到了验证。研究结果为理解植被特征之间的光谱联系奠定了坚实的基础,提出的波长选择方法为rtm反演选择信息光谱波长和设计未来的遥感器提供了有价值的见解。
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