Towards objective identification and tracking of convective outflow boundaries in next-generation geostationary satellite imagery

<p>Sudden wind direction and speed shifts from outflow boundaries (OFBs) associated with deep convection significantly affect weather in the lower troposphere. Specific OFB impacts include rapid variation in wildfire spread rate and direction, the formation of convection, aviation hazards, and...

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Main Authors: J. M. Apke, K. A. Hilburn, S. D. Miller, D. A. Peterson
Format: Article
Language:English
Published: Copernicus Publications 2020-04-01
Series:Atmospheric Measurement Techniques
Online Access:https://www.atmos-meas-tech.net/13/1593/2020/amt-13-1593-2020.pdf
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spelling doaj-44e3362aacc242e080059b998fcc2b982020-11-25T02:18:20ZengCopernicus PublicationsAtmospheric Measurement Techniques1867-13811867-85482020-04-01131593160810.5194/amt-13-1593-2020Towards objective identification and tracking of convective outflow boundaries in next-generation geostationary satellite imageryJ. M. Apke0K. A. Hilburn1S. D. Miller2D. A. Peterson3Cooperative Institute for Research in the Atmosphere (CIRA), Colorado State University, Fort Collins, CO, USACooperative Institute for Research in the Atmosphere (CIRA), Colorado State University, Fort Collins, CO, USACooperative Institute for Research in the Atmosphere (CIRA), Colorado State University, Fort Collins, CO, USANaval Research Laboratory, Monterey CA, USA<p>Sudden wind direction and speed shifts from outflow boundaries (OFBs) associated with deep convection significantly affect weather in the lower troposphere. Specific OFB impacts include rapid variation in wildfire spread rate and direction, the formation of convection, aviation hazards, and degradation of visibility and air quality due to mineral dust aerosol lofting. Despite their recognized importance to operational weather forecasters, OFB characterization (location, timing, intensity, etc.) in numerical models remains challenging. Thus, there remains a need for objective OFB identification algorithms to assist decision support services. With two operational next-generation geostationary satellites now providing coverage over North America, high-temporal- and high-spatial-resolution satellite imagery provides a unique resource for OFB identification. A system is conceptualized here designed around the new capabilities to objectively derive dense mesoscale motion flow fields in the Geostationary Operational Environmental Satellite 16 (GOES-16) imagery via optical flow. OFBs are identified here by isolating linear features in satellite imagery and backtracking them using optical flow to determine if they originated from a deep convection source. This “objective OFB identification” is tested with a case study of an OFB-triggered dust storm over southern Arizona. The results highlight the importance of motion discontinuity preservation, revealing that standard optical flow algorithms used with previous studies underestimate wind speeds when background pixels are included in the computation with cloud targets. The primary source of false alarms is the incorrect identification of line-like features in the initial satellite imagery. Future improvements to this process are described to ultimately provide a fully automated OFB identification algorithm.</p>https://www.atmos-meas-tech.net/13/1593/2020/amt-13-1593-2020.pdf
collection DOAJ
language English
format Article
sources DOAJ
author J. M. Apke
K. A. Hilburn
S. D. Miller
D. A. Peterson
spellingShingle J. M. Apke
K. A. Hilburn
S. D. Miller
D. A. Peterson
Towards objective identification and tracking of convective outflow boundaries in next-generation geostationary satellite imagery
Atmospheric Measurement Techniques
author_facet J. M. Apke
K. A. Hilburn
S. D. Miller
D. A. Peterson
author_sort J. M. Apke
title Towards objective identification and tracking of convective outflow boundaries in next-generation geostationary satellite imagery
title_short Towards objective identification and tracking of convective outflow boundaries in next-generation geostationary satellite imagery
title_full Towards objective identification and tracking of convective outflow boundaries in next-generation geostationary satellite imagery
title_fullStr Towards objective identification and tracking of convective outflow boundaries in next-generation geostationary satellite imagery
title_full_unstemmed Towards objective identification and tracking of convective outflow boundaries in next-generation geostationary satellite imagery
title_sort towards objective identification and tracking of convective outflow boundaries in next-generation geostationary satellite imagery
publisher Copernicus Publications
series Atmospheric Measurement Techniques
issn 1867-1381
1867-8548
publishDate 2020-04-01
description <p>Sudden wind direction and speed shifts from outflow boundaries (OFBs) associated with deep convection significantly affect weather in the lower troposphere. Specific OFB impacts include rapid variation in wildfire spread rate and direction, the formation of convection, aviation hazards, and degradation of visibility and air quality due to mineral dust aerosol lofting. Despite their recognized importance to operational weather forecasters, OFB characterization (location, timing, intensity, etc.) in numerical models remains challenging. Thus, there remains a need for objective OFB identification algorithms to assist decision support services. With two operational next-generation geostationary satellites now providing coverage over North America, high-temporal- and high-spatial-resolution satellite imagery provides a unique resource for OFB identification. A system is conceptualized here designed around the new capabilities to objectively derive dense mesoscale motion flow fields in the Geostationary Operational Environmental Satellite 16 (GOES-16) imagery via optical flow. OFBs are identified here by isolating linear features in satellite imagery and backtracking them using optical flow to determine if they originated from a deep convection source. This “objective OFB identification” is tested with a case study of an OFB-triggered dust storm over southern Arizona. The results highlight the importance of motion discontinuity preservation, revealing that standard optical flow algorithms used with previous studies underestimate wind speeds when background pixels are included in the computation with cloud targets. The primary source of false alarms is the incorrect identification of line-like features in the initial satellite imagery. Future improvements to this process are described to ultimately provide a fully automated OFB identification algorithm.</p>
url https://www.atmos-meas-tech.net/13/1593/2020/amt-13-1593-2020.pdf
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