Article Type:
Research Article

The Effect of Radial Velocity Gridding Artifacts on Variationally Retrieved Vertical Velocities

Scott Collis Centre for Australian Weather and Climate Research, Australian Bureau of Meteorology, Melbourne, Australia

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Alain Protat Centre for Australian Weather and Climate Research, Australian Bureau of Meteorology, Melbourne, Australia

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Kao-Shen Chung Department of Atmospheric and Oceanic Sciences, McGill University, Montreal, Quebec, Canada

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Print Publication:
01 Jul 2010
DOI:
https://doi.org/10.1175/2010JTECHA1402.1
Page(s):
1239–1246
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Abstract

This article investigates the source and impact of artifacts produced by ordered linear interpolation techniques on variationally retrieved updraft intensities. Qualitative reasoning for the generation of periodic perturbations in gridded products is presented, and a simple analytical investigation into the impact of gridding artifacts on updraft retrieval is carried out. By projecting a nonconvergent flow typical of Darwin, Australia, onto the viewing geometry of a scanning radar, a numerical assessment of the impact of gridding artifacts is carried out. A simple enhancement to ordered linear interpolation, mixed-order linear interpolation, is proposed to reduce gridding artifacts. Radial velocity grids produced using both techniques are used to investigate the generation of spurious updrafts, with the simple ordered linear interpolation technique producing erroneous updrafts on the order of 2 m s−1. To investigate the impact on vertical velocities retrieved from a real weather event, radar-derived measurements taken during the active monsoon phase of Tropical Warm Pool International Cloud Experiment are gridded using both techniques, and vertical velocities are retrieved and contrasted.

Corresponding author address: Scott Collis, Centre for Australian Weather and Climate Research, 700 Collins St., Melbourne, VIC 3001, Australia. Email: scollis.acrf@gmail.com

Abstract

This article investigates the source and impact of artifacts produced by ordered linear interpolation techniques on variationally retrieved updraft intensities. Qualitative reasoning for the generation of periodic perturbations in gridded products is presented, and a simple analytical investigation into the impact of gridding artifacts on updraft retrieval is carried out. By projecting a nonconvergent flow typical of Darwin, Australia, onto the viewing geometry of a scanning radar, a numerical assessment of the impact of gridding artifacts is carried out. A simple enhancement to ordered linear interpolation, mixed-order linear interpolation, is proposed to reduce gridding artifacts. Radial velocity grids produced using both techniques are used to investigate the generation of spurious updrafts, with the simple ordered linear interpolation technique producing erroneous updrafts on the order of 2 m s−1. To investigate the impact on vertical velocities retrieved from a real weather event, radar-derived measurements taken during the active monsoon phase of Tropical Warm Pool International Cloud Experiment are gridded using both techniques, and vertical velocities are retrieved and contrasted.

Corresponding author address: Scott Collis, Centre for Australian Weather and Climate Research, 700 Collins St., Melbourne, VIC 3001, Australia. Email: scollis.acrf@gmail.com

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Journal of Atmospheric and Oceanic Technology

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