@misc{753d51be3c4e4b9ab42e32c44b4f7e9f,
title = "Evaluating the Sources of Uncertainties in the Measurements from Multiple Pyranometers and Pyrheliometers",
abstract = "Traceable radiometric data sets are essential for validating climate models, validating satellite-based models for estimating solar resources, and validating solar radiation forecasts. The current state-of-the-art radiometers have uncertainties in the range from 2% - 5% and sometimes more [1]. The National Renewable Energy Laboratory (NREL) and other organizations are identifying uncertainties and improving radiometric measurement performance and developing a consensus methodology for acquiring radiometric data. This study analyzes the impact of differing specifications -- such as cosine response, thermal offset, spectral response, and others -- on the accuracy of radiometric data for various radiometers. The study will also provide insight on how to perform a measurement uncertainty analysis and how to reduce the impact of some of the sources of uncertainties.",
keywords = "measurement, radiometer, radiometric data, solar radiation, uncertainties",
author = "Aron Habte and Manajit Sengupta and Afshin Andreas and Ibrahim Reda and Mark Kutchenreiter",
year = "2017",
language = "American English",
series = "Presented at the 2017 Atmospheric Radiation Measurement (ARM) / Atmospheric System Research (ASR) Principal Investigator Meeting, 13-16 March 2017, Vienna, Virginia",
type = "Other",
}