Estimation of refractivity uncertainties and vertical error correlations in collocated radio occultations, radiosondes, and model forecasts
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Published:2022-10-28
Issue:20
Volume:15
Page:6243-6256
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ISSN:1867-8548
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Container-title:Atmospheric Measurement Techniques
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language:en
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Short-container-title:Atmos. Meas. Tech.
Author:
Nielsen Johannes K.ORCID, Gleisner HansORCID, Syndergaard Stig, Lauritsen Kent B.ORCID
Abstract
Abstract. Random uncertainties and vertical error correlations are estimated for
three independent data sets. The three collocated data sets are
(1) refractivity profiles of radio occultation measurements retrieved
from the Metop-A and B and COSMIC-1 missions, (2) refractivity derived
from GRUAN-processed RS92 sondes, and (3) refractivity profiles derived
from ERA5 forecast fields. The analysis is performed using
a generalization of the so-called three-cornered hat method to include
off-diagonal elements such that full error covariance matrices can be
calculated. The impacts from various sources of representativeness
error on the uncertainty estimates are analysed. The estimated
refractivity uncertainties of radio occultations, radiosondes, and
model data are stated with reference to the vertical representation of
refractivity in these data sets. The existing theoretical estimates of
radio occultation uncertainty are confirmed in the middle and upper
troposphere and lower stratosphere, and only little dependence on
latitude is found in that region. In the lower troposphere,
refractivity uncertainty decreases with latitude. These findings have
implications for both retrieval of tropospheric humidity from radio
occultations and for assimilation of radio occultation data in numerical weather prediction models and reanalyses.
Funder
European Organization for the Exploitation of Meteorological Satellites
Publisher
Copernicus GmbH
Subject
Atmospheric Science
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