Performance of Emerging Technologies for Measuring Solid and Liquid Precipitation in Cold Climate as Compared to the Traditional Manual Gauges

Author:

Boudala Faisal S.1,Isaac George A.2,Filman Peter3,Crawford Robert1,Hudak David1,Anderson Martha4

Affiliation:

1. Cloud Physics and Severe Weather Research Section, Environment and Climate Change Canada, Toronto, Ontario, Canada

2. Weather Impacts Consulting Inc., Barrie, Ontario, Canada

3. Department of National Defence, Government of Canada, Cold Lake, Alberta, Canada

4. Department of National Defence, Government of Canada, Ottawa, Ontario, Canada

Abstract

AbstractPrecipitation amount, type, and snow depth ) have been analyzed using data collected during the 4Wing Cold Lake Research Project in northeastern Alberta, Canada. The instruments used include the Vaisala present weather detector PWD22 and present weather sensor (FS)11P, the OTT Pluvio2 automatic catchment-type gauge, the manual standard Canadian Nipher (CN) and Type B rain gauges, and a snow ruler. Both the PWD22 and FS11P performed well at detecting snow, rain, and drizzle events as compared to the human observer. The sensors predicted a higher frequency of ice pellet cases than the human observer. Segregation of precipitation phase using temperature alone appeared unrealistic at near-freezing temperatures. All the sensors agreed well at measuring liquid precipitation, but the Pluvio2 gauge with a single Alter shield underestimated the snowfall amount by 40%, mostly due to wind effects. After correcting the CN gauge catch efficiency (CE) due to wind effects, the CE of the Pluvio2 relative to the CN gauge was found dependent on wind speed (ws). Using these data, a new transfer function (TF) for the Pluvio2 as a function of ws has been developed. The new TF was used to correct the Pluvio2 gauge, and the corrected data agreed well with the PWD22 measurements. Using the and corrected CN data, snow density ratios ( were derived, varying from 4.2 to 35 with a mean value of 12.2. The mean value derived in this study is higher than the 10:1 ratio usually assumed for converting to snow water equivalent in Canada. On average increases with increasing temperature and the 10:1 ratio appears to be more appropriate for warmer temperatures.

Publisher

American Meteorological Society

Subject

Atmospheric Science,Ocean Engineering

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