TY - JOUR
T1 - Analysis of single-Alter-shielded and unshielded measurements of mixed and solid precipitation from WMO-SPICE
AU - Kochendorfer, John
AU - Nitu, Rodica
AU - Wolff, Mareile
AU - Mekis, Eva
AU - Rasmussen, Roy
AU - Baker, Bruce
AU - Earle, Michael E.
AU - Reverdin, Audrey
AU - Wong, Kai
AU - Smith, Craig D.
AU - Yang, Daqing
AU - Roulet, Yves Alain
AU - Buisan, Samuel
AU - Laine, Timo
AU - Lee, Gyuwon
AU - Aceituno, Jose Luis C.
AU - Alastrué, Javier
AU - Isaksen, Ketil
AU - Meyers, Tilden
AU - Brækkan, Ragnar
AU - Landolt, Scott
AU - Jachcik, Al
AU - Poikonen, Antti
N1 - Publisher Copyright:
© 2017 Author(s).
PY - 2017/7/14
Y1 - 2017/7/14
N2 - Although precipitation has been measured for many centuries, precipitation measurements are still beset with significant inaccuracies. Solid precipitation is particularly difficult to measure accurately, and wintertime precipitation measurement biases between different observing networks or different regions can exceed 100 %. Using precipitation gauge results from the World Meteorological Organization Solid Precipitation Intercomparison Experiment (WMO-SPICE), errors in precipitation measurement caused by gauge uncertainty, spatial variability in precipitation, hydrometeor type, crystal habit, and wind were quantified. The methods used to calculate gauge catch efficiency and correct known biases are described. Adjustments, in the form of "transfer functions" that describe catch efficiency as a function of air temperature and wind speed, were derived using measurements from eight separate WMO-SPICE sites for both unshielded and single-Alter-shielded precipitation-weighing gauges. For the unshielded gauges, the average undercatch for all eight sites was 0.50 mm h-1 (34 %), and for the single-Alter-shielded gauges it was 0.35 mm h-1 (24 %). After adjustment, the mean bias for both the unshielded and single-Alter measurements was within 0.03 mm h-1 (2 %) of zero. The use of multiple sites to derive such adjustments makes these results unique and more broadly applicable to other sites with various climatic conditions. In addition, errors associated with the use of a single transfer function to correct gauge undercatch at multiple sites were estimated.
AB - Although precipitation has been measured for many centuries, precipitation measurements are still beset with significant inaccuracies. Solid precipitation is particularly difficult to measure accurately, and wintertime precipitation measurement biases between different observing networks or different regions can exceed 100 %. Using precipitation gauge results from the World Meteorological Organization Solid Precipitation Intercomparison Experiment (WMO-SPICE), errors in precipitation measurement caused by gauge uncertainty, spatial variability in precipitation, hydrometeor type, crystal habit, and wind were quantified. The methods used to calculate gauge catch efficiency and correct known biases are described. Adjustments, in the form of "transfer functions" that describe catch efficiency as a function of air temperature and wind speed, were derived using measurements from eight separate WMO-SPICE sites for both unshielded and single-Alter-shielded precipitation-weighing gauges. For the unshielded gauges, the average undercatch for all eight sites was 0.50 mm h-1 (34 %), and for the single-Alter-shielded gauges it was 0.35 mm h-1 (24 %). After adjustment, the mean bias for both the unshielded and single-Alter measurements was within 0.03 mm h-1 (2 %) of zero. The use of multiple sites to derive such adjustments makes these results unique and more broadly applicable to other sites with various climatic conditions. In addition, errors associated with the use of a single transfer function to correct gauge undercatch at multiple sites were estimated.
UR - http://www.scopus.com/inward/record.url?scp=85024389652&partnerID=8YFLogxK
U2 - 10.5194/hess-21-3525-2017
DO - 10.5194/hess-21-3525-2017
M3 - Article
AN - SCOPUS:85024389652
SN - 1027-5606
VL - 21
SP - 3525
EP - 3542
JO - Hydrology and Earth System Sciences
JF - Hydrology and Earth System Sciences
IS - 7
ER -