Evaluation of precipitation measurement methods using data from a precision lysimeter network
-
Published:2023-09-11
Issue:17
Volume:27
Page:3265-3292
-
ISSN:1607-7938
-
Container-title:Hydrology and Earth System Sciences
-
language:en
-
Short-container-title:Hydrol. Earth Syst. Sci.
Author:
Schnepper TobiasORCID, Groh JannisORCID, Gerke Horst H.ORCID, Reichert Barbara, Pütz ThomasORCID
Abstract
Abstract. Accurate precipitation data are essential for assessing the water balance of ecosystems. Methods for point precipitation determination are influenced by wind, precipitation type and intensity and/or technical issues. High-precision weighable lysimeters provide precipitation measurements at ground level that are less affected by wind disturbances and are assumed to be relatively close to actual precipitation. The problem in previous studies was that the biases in precipitation data introduced by different precipitation measurement methods were not comprehensively compared with and quantified on the basis of those obtained by lysimeters in different regions in Germany. The aim was to quantify measurement errors in standard precipitation gauges
as compared to the lysimeter reference and to analyze the effect of
precipitation correction algorithms on the gauge data quality. Both correction methods rely on empirical constants to account for known external influences on the measurements, following a generic and a site-specific approach. Reference precipitation data were obtained from high-precision weighable lysimeters of the TERrestrial ENvironmental Observatories (TERENO)-SOILCan lysimeter network. Gauge types included tipping bucket gauges (TBs), weighable gauges (WGs), acoustic sensors (ASs) and optical laser disdrometers (LDs). From 2015-2018, data were collected at three locations in Germany, and 1 h aggregated values for precipitation above a threshold of 0.1 mm h−1 were compared. The results show that all investigated measurement methods underestimated
the precipitation amounts relative to the lysimeter references for long-term
precipitation totals with catch ratios (CRs) of between 33 %–92 %. Data from ASs had overall biases of −0.25 to −0.07 mm h−1, while data from WGs and LDs showed the lowest measurement bias (−0.14 to −0.06 mm h−1 and −0.01 to −0.02 mm h−1). Two TBs showed systematic deviations with biases of −0.69 to −0.61 mm h−1, while other TBs were in the previously reported range with biases of −0.2 mm h−1. The site-specific and generic correction schemes reduced the hourly measurement bias by 0.13 and 0.08 mm h−1 for the TBs and by 0.09 and 0.07 mm h−1 for the WGs and increased long-term CRs by 14 % and 9 % and by 10 % and 11 %, respectively. It could be shown that the lysimeter reference operated with minor uncertainties in long-term measurements under different site and weather
conditions. The results indicate that considerable precipitation measurement
errors can occur even at well-maintained and professionally operated stations equipped with standard precipitation gauges. This generally leads
to an underestimation of the actual precipitation amounts. The results
suggest that the application of relatively simple correction schemes, manual
or automated data quality checks, instrument calibrations, and/or an adequate
choice of observation period can help improve the data quality of
gauge-based measurements for water balance calculations, ecosystem modeling, water management, assessment of agricultural irrigation needs, or
radar-based precipitation analyses.
Publisher
Copernicus GmbH
Subject
General Earth and Planetary Sciences,General Engineering,General Environmental Science
Reference100 articles.
1. Adirosi, E., Roberto, N., Montopoli, M., Gorgucci, E., and Baldini, L.:
Influence of Disdrometer Type on Weather Radar Algorithms from Measured DSD:
Application to Italian Climatology, Atmosphere, 9, 360, https://doi.org/10.3390/atmos9090360, 2018. 2. Alter, J. C.: Shielded storage precipitation gages, Mon. Weather Rev., 65, 262–265,
https://doi.org/10.1175/1520-0493(1937)65<262:SSPG>2.0.CO;2, 1937. 3. Bárdossy, A., Kilsby, C., Birkinshaw, S., Wang, N., and Anwar, F.: Is
Precipitation Responsible for the Most Hydrological Model Uncertainty?, Front. Water, 4, 836554, https://doi.org/10.3389/frwa.2022.836554, 2022. 4. Bloemink, H. I. and Lanzinger, E.: Precipitation type from the Thies
disdrometer, WMO, Bukarest, https://cdn.knmi.nl/system/data_center_publications/files/000/068/578/original/teco2005_paper_bloemink.pdf?1495621277 (last access: 1 September 2022), 2005. 5. Bogena, H. R., Montzka, C., Huisman, J. A., Graf, A., Schmidt, M., Stockinger, M., von Hebel, C., Hendricks-Franssen, H. J., van der Kruk, J.,
Tappe, W., Lücke, A., Baatz, R., Bol, R., Groh, J., Pütz, T., Jakobi, J., Kunkel, R., Sorg, J., and Vereecken, H.: The TERENO-Rur Hydrological Observatory: A Multiscale Multi-Compartment Research Platform
for the Advancement of Hydrological Science, Vadose Zone J., 17, 180055, https://doi.org/10.2136/vzj2018.03.0055, 2018.
|
|