Evaluating Parsivel2's raindrop data: A comparative study of different terminal drop velocity models on simulated and natural rain events

Rainfall measurement inherently contains uncertainty in the accuracy of the collected data. Theoretical terminal velocity models are used to filter drop size distributions (DSDs) collected by measurement devices to remove physically unlikely data. This filtration process decreases the number of drop...

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Vydané v:Atmospheric environment (1994) Ročník 362; s. 121548
Hlavní autori: Yuan, Lifeng, Mikelonis, Anne M., Sawyer, Jonathan
Médium: Journal Article
Jazyk:English
Vydavateľské údaje: Elsevier Ltd 01.12.2025
Predmet:
Microphysical characteristics
Optical disdrometer
Rain rate
Rainfall simulator
Terminal velocity models
Terminal velocity models
Microphysical characteristics
Rainfall simulator
Rain rate
Optical disdrometer
ISSN:1352-2310
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Shrnutí:Rainfall measurement inherently contains uncertainty in the accuracy of the collected data. Theoretical terminal velocity models are used to filter drop size distributions (DSDs) collected by measurement devices to remove physically unlikely data. This filtration process decreases the number of drops and further influences the calculation of bulk rain parameters. This study compared the impact of different drop velocity models on the DSD and rain parameter calculations for both natural and artificial rain. A total of ten natural rainfall events were observed with a Parsivel2 disdrometer on the U.S. Environmental Protection Agency (EPA) Research Triangle Park (RTP) campus in Durham, North Carolina, during June–July 2024. In addition, 732 min of artificial rainfall were generated using four nozzles at the U.S. EPA Fluid Modeling Facility (FMF) in Durham, North Carolina. The results showed that for artificial rainfall, the rain rate calculated from the instruments' ‘raw’ DSD data (terminal output %93) was on average 38.73 % higher across four nozzles compared to the Parsivel2's rain rate calculation. The rain rate calculated directly from ‘raw’ data more closely matched the volume of water collected in a bin than the Parsivel2's rain rate calculation. For natural rainfall, the research found that the investigated terminal velocity models performed similarly. The average reduction in drop count across the six drop velocity models tested was 0.14 %, with the highest reduction observed in the Atlas (1977) model at 0.36 %. For the accumulated DSD of ten rainfall events, the ranking of models by the number of filtered drops, from highest to lowest, was: Atlas (1977) > Uplinger (1981) > Atlas et al. (1973) > Beard (1976) > Van Dijk et al. (2002) > Gunn and Kinzer (1949). In contrast to artificial rain, both rain intensity and kinetic energy measured by Parsivel2 were higher than those calculated from the ‘raw’ DSD, and applying a filter reduced these values. The study also identified the microphysical characteristics of the natural precipitation, with peak values of liquid water content (W) and radar reflectivity factor (Z) observed at 0.6–0.7 g m−3 and 30 dBz, respectively. The average mass-weighted diameter Dm (normalized intercept parameter log10Nw) values for convective, mixed, and stratiform rain were 1.81 mm (5.40), 1.15 mm (4.18), and 1.35 mm (4.53), respectively. Filters had a more pronounced effect on the Dm values compared to the log10Nw values and appeared to have a larger influence on convective rain compared to stratiform rain. The study illustrated how various theoretical terminal drop velocity models used to filter the number of raindrops in a DSD affect the calculation of bulk rain parameters and how they are applicable to natural rainfall but not artificially produced rainfall. This research is valuable for gaining a deeper understanding of precipitation microphysics and improving the accuracy of rainfall assessments. [Display omitted] •Determined drop velocity filters applied to simulated rain cause underestimation of rain rate.•Found different drop velocity filters reduced the total drop count to similar degrees.•Identified filters had more impact on the calculation of Dm compared to log10Nw.•Recognized filters had a larger influence on convective rain compared to stratiform rain.
ISSN:1352-2310
DOI:10.1016/j.atmosenv.2025.121548