Tyler Young - July 8

School of Meteorology MS Thesis Defense   GOES-R Stereoscopic Cloud Top Retrieval Algorithm Using Normalized Cross-Correlation for 1-min Overshoot Analysis   Tyler Young   Thursday, July 8, 1:00 pm   Join Google Meet: https://meet.google.com/uva-fqgr-kkp Or dial: ‪(US) +1 505-658-2178 PIN: ‪575 365 334#   Satellite-based cloud top height (CTH) analyses

Start

July 8, 2021 - 1:00 pm

End

July 8, 2021 - 2:00 pm

School of Meteorology MS Thesis Defense

 

GOES-R Stereoscopic Cloud Top Retrieval Algorithm Using Normalized Cross-Correlation for 1-min Overshoot Analysis

 

Tyler Young

 

Thursday, July 8,

1:00 pm

 

Join Google Meet:

https://meet.google.com/uva-fqgr-kkp

Or dial: ‪(US) +1 505-658-2178 PIN: ‪575 365 334#

 

Satellite-based cloud top height (CTH) analyses are instrumental in understanding storm dynamics which can be utilized for severe and tornado warnings. Currently, CTHs are derived using IR imagery which are subject to errors. A few assumptions using IR which ultimately lead to less accurate calculations are that it requires knowledge of cloud emissivity, ambient temperature, lapse rate, and assumes the cloud is in thermodynamic equilibrium which is least true around intense thunderstorms. A method proposed for obtaining more accurate CTHs is stereoscopy since it only depends on geometric relationships. Stereoscopy is a scientific technique used to combine two images to enhance the illusion of depth. This technique can be applied to weather phenomena using visible or infrared satellite images to retrieve CTHs. GOES-16 and GOES-17 are time synchronized and can be used to take images of the same field of view with different viewing points. Conducting stereoscopy on this data can ultimately determine an offset between the two GOES images which is proportional to the corresponding CTH. Previous stereoscopy studies using American satellites have been conducted on thunderstorms and hurricanes in the 1980’s and 1990’s. Since then, satellites have advanced and the spatial and temporal resolution of visible and infrared images from new-era GOES are now available at 0.5 km and 2 km resolution, respectively, every minute. It is hypothesized this increase in resolution will allow cloud height calculations accurate to within 500 m which is higher than the accuracy found in past studies of 1500 m. The nature of analyzing storms through stereoscopy presents several constraints. Visible imagery from GOES constrains analyses to storms during the day. In addition, using GOES-16 and GOES-17 as the two satellites only allows for analyses of storms over the central U.S. since it is where both mesoscale floating domains overlap. These CTH analyses alongside radar data and storm reports can be used to further investigate severe storm dynamics.