Document Details

Assessing the accuracy of OpenET satellite-based evapotranspiration data to support water resource and land management applications

John M. Volk, Justin L. Huntington, Forrest S. Melton, Richard Allen, Martha Anderson, Joshua B. Fisher, Ayse Kilic, Anderson Ruhoff, Gabriel B. Senay, Blake Minor, Charles Morton, Thomas Ott, Lee Johnson, Bruno Comini de Andrade, Will Carrara, Conor T. Doherty, Christian Dunkerly, MacKenzie Friedrichs, Alberto Guzmán, Christopher Hain, Gregory Halverson, Yanghui Kang, Kyle Knipper, Leonardo Laipelt, Samuel Ortega-Salazar, Christopher Pearson, Gabriel E.L. Parrish, Adam Purdy, Peter ReVelle, Tianxin Wang, Yun Yang | January 15th, 2024


Remotely sensed evapotranspiration (ET) data offer strong potential to support data-driven approaches for sustainable water management. However, practitioners require robust and rigorous accuracy assessments of such data. The OpenET system, which includes an ensemble of six remote sensing models, was developed to increase access to field-scale (30 m) ET data for the contiguous United States. Here we compare OpenET outputs against data from 152 in situ stations, primarily eddy covariance flux towers, deployed across the contiguous United States. Mean absolute error at cropland sites for the OpenET ensemble value is 15.8 mm per month (17% of mean observed ET), mean bias error is −5.3 mm per month (6%) and r2 is 0.9. Results for shrublands and forested sites show higher inter-model variability and lower accuracy relative to croplands. High accuracy and multi-model convergence across croplands demonstrate the utility of a model ensemble approach, and enhance confidence among ET data practitioners, including the agricultural water resource management community.

Keywords

agriculture water use and efficiency, ecosystem management, modeling, upper watershed management, water supply forecasting