TY - GEN
T1 - Remote detection and diagnosis of thunderstorm turbulence
AU - Williams, John K.
AU - Sharman, Robert
AU - Craig, Jason
AU - Blackburn, Gary
PY - 2008
Y1 - 2008
N2 - This paper describes how operational radar, satellite and lightning data may be used in conjunction with numerical weather model data to provide remote detection and diagnosis of atmospheric turbulence in and around thunderstorms. In-cloud turbulence is measured with the NEXRAD Turbulence Detection Algorithm (NTDA) using extensively qualitycontrolled, ground-based Doppler radar data. A real-time demonstration of the NTDA includes generation of a 3-D turbulence mosaic covering the CONUS east of the Rocky Mountains, a web-based display, and experimental uplinks of turbulence maps to en-route commercial aircraft. Near-cloud turbulence is inferred from thunderstorm morphology, intensity, growth rate and environment data provided by (1) satellite radiance measurements, rates of change, winds, and other derived features, (2) lightning strike measurements, (3) radar reflectivity measurements and (4) weather model data. These are combined via a machine learning technique trained using a database of in situ turbulence measurements from commercial aircraft to create a predictive model. This new capability is being developed under FAA and NASA funding to enhance current U.S. and international turbulence decision support systems, allowing rapid-update, high-resolution, comprehensive assessments of atmospheric turbulence hazards for use by pilots, dispatchers, and air traffic controllers. It will also contribute to the comprehensive 4-D weather information database for NextGen.
AB - This paper describes how operational radar, satellite and lightning data may be used in conjunction with numerical weather model data to provide remote detection and diagnosis of atmospheric turbulence in and around thunderstorms. In-cloud turbulence is measured with the NEXRAD Turbulence Detection Algorithm (NTDA) using extensively qualitycontrolled, ground-based Doppler radar data. A real-time demonstration of the NTDA includes generation of a 3-D turbulence mosaic covering the CONUS east of the Rocky Mountains, a web-based display, and experimental uplinks of turbulence maps to en-route commercial aircraft. Near-cloud turbulence is inferred from thunderstorm morphology, intensity, growth rate and environment data provided by (1) satellite radiance measurements, rates of change, winds, and other derived features, (2) lightning strike measurements, (3) radar reflectivity measurements and (4) weather model data. These are combined via a machine learning technique trained using a database of in situ turbulence measurements from commercial aircraft to create a predictive model. This new capability is being developed under FAA and NASA funding to enhance current U.S. and international turbulence decision support systems, allowing rapid-update, high-resolution, comprehensive assessments of atmospheric turbulence hazards for use by pilots, dispatchers, and air traffic controllers. It will also contribute to the comprehensive 4-D weather information database for NextGen.
KW - Atmospheric turbulence
KW - Aviation safety
KW - Convection
KW - Convectively-induced turbulence (CIT)
KW - Doppler weather radar
KW - NEXRAD
KW - NextGen
KW - Thunderstorms
UR - https://www.scopus.com/pages/publications/52349087038
U2 - 10.1117/12.795570
DO - 10.1117/12.795570
M3 - Conference contribution
AN - SCOPUS:52349087038
SN - 9780819473080
T3 - Proceedings of SPIE - The International Society for Optical Engineering
BT - Remote Sensing Applications for Aviation Weather Hazard Detection and Decision Support
T2 - Remote Sensing Applications for Aviation Weather Hazard Detection and Decision Support
Y2 - 13 August 2008 through 14 August 2008
ER -