Abstract
Rainfall drop size distribution (DSD) measurements made by single disdrometers at isolated ground sites have traditionally been used to estimate the transformation between weather radar reflectivity Z and rainfall rate R. Despite the immense disparity in sampling geometries, the resulting Z-R relation obtained by these single point measurements has historically been important in the study of applied radar meteorology. Simultaneous DSD measurements made at several ground sites within a microscale area may be used to improve the estimate of radar reflectivity in the air volume surrounding the disdrometer array. By applying the equations of motion for non-interacting hydrometers, a volume estimate of Z is obtained from the array of ground based disdrometers by first calculating a 3D drop size distribution. The 3D-DSD model assumes that only gravity and terminal velocity due to atmospheric drag within the sampling volume influence hydrometer dynamics. The sampling volume is characterized by wind velocities, which are input parameters to the 3D-DSD model, composed of vertical and horizontal components. Reflectivity data from four consecutive WSR-88D volume scans, acquired during a thunderstorm near Melbourne, FL on June 1, 1997, are compared to data processed using the 3D-DSD model and data form three ground based disdrometers of a microscale array. © (2000) COPYRIGHT SPIE--The International Society for Optical Engineering.
Original language | American English |
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DOIs | |
State | Published - Apr 2000 |
Externally published | Yes |
Event | Signal Processing, Sensor Fusion, and Target Recognition IX - Orlando, FL Duration: Apr 1 2000 → … |
Conference
Conference | Signal Processing, Sensor Fusion, and Target Recognition IX |
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Period | 4/1/00 → … |
Keywords
- Rainfall rate
- drop size distribution
- radar reflectivity
Disciplines
- Meteorology