Chandra S. Pathak John R. Mecikalski Simon J. Paech Qinglong Wu Taiye Sangoyomi Roger W. Babcock Jr. Raymond Walton David M. Sumner 2008 <p><span>Solar radiation data are critically important for the estimation of evapotranspiration. Analysis of visible-channel data derived from Geostationary Operational Environmental Satellites (GOES) using radiative transfer modeling has been used to produce spatially- and temporally-distributed datasets of solar radiation. An extensive network of (pyranometer) surface measurements of solar radiation in the State of Florida has allowed refined calibration of a GOES-derived daily integrated radiation data product. This refinement of radiation data allowed for corrections of satellite sensor drift, satellite generational change, and consideration of the highly-variable cloudy conditions that are typical of Florida. To aid in calibration of a GOES-derived radiation product, solar radiation data for the period 1995&ndash;2004 from 58 field stations that are located throughout the State were compiled. The GOES radiation product was calibrated by way of a three-step process: 1) comparison with ground-based pyranometer measurements on clear reference days, 2) correcting for a bias related to cloud cover, and 3) deriving month-by-month bias correction factors. Pre-calibration results indicated good model performance, with a station-averaged model error of 2.2 MJ m</span>^&ndash;2<span>&nbsp;day</span>^&ndash;1<span>&nbsp;(13 percent). Calibration reduced errors to 1.7 MJ m</span>^&ndash;2<span>&nbsp;day</span>^&ndash;1<span>&nbsp;(10 percent) and also removed time- and cloudiness-related biases. The final dataset has been used to produce Statewide evapotranspiration estimates.</span></p> application/pdf 10.1061/40976(316)95 en American Society of Civil Engineers Calibration of GOES-derived solar radiation data using a distributed network of surface measurements in Florida, USA text