Evaluating the benefits of chlorophyll fluorescence for in-season crop productivity forecasting

Remote sensing of solar-induced chlorophyll fluorescence (SIF) shows promise for monitoring the productivity of global agricultural systems. SIF-based primary productivity metrics have demonstrated higher fidelity to large-scale patterns of crop productivity than reflectance-based vegetation indices...

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Veröffentlicht in:	Remote sensing of environment 2021-07, Vol.260, p.112478, Article 112478
Hauptverfasser:	Sloat, Lindsey L., Lin, Marena, Butler, Ethan E., Johnson, Dave, Holbrook, N. Michele, Huybers, Peter J., Lee, Jung-Eun, Mueller, Nathaniel D.
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Sprache:	eng
Schlagworte:	Agricultural land Agricultural production agricultural productivity Chlorophyll Crop forecasting Crop production Crop productivity Crop yield Crop yield forecasting cropland Crops Drought Drought conditions environment Environmental impact Evaluation Fluorescence Forecasting GOME-2 Growing season MODIS Monitoring NDVI primary productivity Productivity Reflectance Remote sensing SIF Solar-induced fluorescence USDA Vegetation
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container_title	Remote sensing of environment
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creator	Sloat, Lindsey L. Lin, Marena Butler, Ethan E. Johnson, Dave Holbrook, N. Michele Huybers, Peter J. Lee, Jung-Eun Mueller, Nathaniel D.
description	Remote sensing of solar-induced chlorophyll fluorescence (SIF) shows promise for monitoring the productivity of global agricultural systems. SIF-based primary productivity metrics have demonstrated higher fidelity to large-scale patterns of crop productivity than reflectance-based vegetation indices when averaged across the growing season. In-season crop yield forecasting typically relies upon reflectance-based vegetation indices, raising the question of whether in-season monitoring could be improved by utilizing SIF. Here, we analyze patterns of US agricultural productivity from USDA surveys and their in-season relationships with coarse-resolution GOME-2 SIF, high-resolution downscaled SIF, SIF-based primary productivity metrics, MODIS NDVI, and MODIS GPP. We find that coarse-resolution SIF-based metrics and NDVI exhibit similar out-of-sample in-season (April–July and April–August) predictive ability, even when spatially filtering higher-resolution NDVI data to cropland areas. The downscaled SIF product performed more poorly than the coarse-resolution SIF, and MODIS GPP performed more poorly than MODIS NDVI. All forecasts are improved by incorporating county fixed effects to control for cross-sectional differences between counties. NDVI-based metrics allow for significantly better yield predictions during drought conditions than SIF-based metrics, suggesting limited added value of SIF for early warning of drought impacts. The benefits of SIF for crop monitoring should be continually evaluated as the frequency and quality of SIF measurements continue to improve. •GOME-2 SIF and MODIS NDVI are utilized for in-season crop productivity forecasting.•In-season, out-of-sample forecasts exhibit similar skill for SIF and NDVI metrics.•A downscaled SIF product did not improve in-season out-of-sample crop productivity forecasting.•Forecast error is significantly greater during drought for SIF-based indicators.
doi_str_mv	10.1016/j.rse.2021.112478
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Michele</creatorcontrib><creatorcontrib>Huybers, Peter J.</creatorcontrib><creatorcontrib>Lee, Jung-Eun</creatorcontrib><creatorcontrib>Mueller, Nathaniel D.</creatorcontrib><title>Evaluating the benefits of chlorophyll fluorescence for in-season crop productivity forecasting</title><title>Remote sensing of environment</title><description>Remote sensing of solar-induced chlorophyll fluorescence (SIF) shows promise for monitoring the productivity of global agricultural systems. SIF-based primary productivity metrics have demonstrated higher fidelity to large-scale patterns of crop productivity than reflectance-based vegetation indices when averaged across the growing season. In-season crop yield forecasting typically relies upon reflectance-based vegetation indices, raising the question of whether in-season monitoring could be improved by utilizing SIF. 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NDVI-based metrics allow for significantly better yield predictions during drought conditions than SIF-based metrics, suggesting limited added value of SIF for early warning of drought impacts. The benefits of SIF for crop monitoring should be continually evaluated as the frequency and quality of SIF measurements continue to improve. •GOME-2 SIF and MODIS NDVI are utilized for in-season crop productivity forecasting.•In-season, out-of-sample forecasts exhibit similar skill for SIF and NDVI metrics.•A downscaled SIF product did not improve in-season out-of-sample crop productivity forecasting.•Forecast error is significantly greater during drought for SIF-based indicators.</abstract><cop>New York</cop><pub>Elsevier Inc</pub><doi>10.1016/j.rse.2021.112478</doi><oa>free_for_read</oa></addata></record>
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subjects	Agricultural land Agricultural production agricultural productivity Chlorophyll Crop forecasting Crop production Crop productivity Crop yield Crop yield forecasting cropland Crops Drought Drought conditions environment Environmental impact Evaluation Fluorescence Forecasting GOME-2 Growing season MODIS Monitoring NDVI primary productivity Productivity Reflectance Remote sensing SIF Solar-induced fluorescence USDA Vegetation
title	Evaluating the benefits of chlorophyll fluorescence for in-season crop productivity forecasting
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