Estimating Global Gross Primary Production from Sun-Induced Chlorophyll Fluorescence Data and Auxiliary Information Using Machine Learning Methods

Remote. Sens. Pub Date : 2021-01-01 DOI:10.3390/rs13050963

Yu Bai, S. Liang, W. Yuan

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引用次数: 16

Abstract

The gross primary production (GPP) is important for regulating the global carbon cycle and climate change. Recent studies have shown that sun-induced chlorophyll fluorescence (SIF) is highly advantageous regarding GPP monitoring. However, using SIF to estimate GPP on a global scale is limited by the lack of a stable SIF-GPP relationship. Here, we estimated global monthly GPP at 0.05° spatial resolution for the period 2001–2017, using the global OCO-2-based SIF product (GOSIF) and other auxiliary data. Large amounts of flux tower data are not available to the public and the available data is not evenly distributed globally and has a smaller measured footprint than the GOSIF data. This makes it difficult to use the flux tower GPP directly as an input to the model. Our strategy is to scale in situ measurements using two moderate-resolution satellite GPP products (MODIS and GLASS). Specifically, these two satellite GPP products were calibrated and eventually integrated by in situ measurements (FLUXNET2015 dataset, 83 sites), which was then used to train a machine learning model (GBRT) that performed the best among five evaluated models. The GPP estimates from GOSIF were highly accurate coefficient of determination (R2) = 0.58, root mean square error (RMSE) = 2.74 g C·m−2, bias = –0.34 g C·m−2) as validated by in situ measurements, and exhibited reasonable spatial and seasonal variations on a global scale. Our method requires fewer input variables and has higher computational efficiency than other satellite GPP estimation methods. Satellite-based SIF data provide a unique opportunity for more accurate, near real-time GPP mapping in the future.

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利用机器学习方法从太阳诱导的叶绿素荧光数据和辅助信息估计全球初级总产量

初级生产总值(GPP)对调节全球碳循环和气候变化具有重要意义。最近的研究表明，太阳诱导的叶绿素荧光(SIF)在GPP监测中具有很高的优势。然而，由于缺乏稳定的SIF-GPP关系，使用SIF在全球范围内估计GPP受到限制。本文利用基于oco -2的全球SIF产品(GOSIF)和其他辅助数据，在0.05°空间分辨率下估算了2001-2017年全球月度GPP。公众无法获得大量通量塔数据，可用数据在全球分布不均匀，测量足迹比GOSIF数据小。这使得很难直接使用通量塔GPP作为模型的输入。我们的策略是使用两种中等分辨率卫星GPP产品(MODIS和GLASS)进行现场测量。具体来说，这两个卫星GPP产品通过原位测量(FLUXNET2015数据集，83个站点)进行校准并最终整合，然后用于训练机器学习模型(GBRT)，该模型在五个评估模型中表现最好。实测数据表明，GOSIF估算的GPP具有较高的精度，决定系数(R2) = 0.58，均方根误差(RMSE) = 2.74 g C·m - 2，偏差= -0.34 g C·m - 2，在全球尺度上具有合理的空间和季节变化。与其他卫星GPP估计方法相比，该方法所需的输入变量更少，计算效率更高。基于卫星的SIF数据为未来更精确、接近实时的GPP制图提供了独特的机会。

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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Remote. Sens.

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