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Satellite Wind Products. Presented by Jaime Daniels. Requirement, Science, and Benefit. Requirement/Objective Mission Goal: Weather and Water Research Area: Improve weather forecast and warning accuracy and amount of lead time Mission Goal: Technology and the Mission Support
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Satellite Wind Products Presented by Jaime Daniels
Requirement, Science, and Benefit Requirement/Objective • Mission Goal: Weather and Water • Research Area: Improve weather forecast and warning accuracy and amount of lead time • Mission Goal: Technology and the Mission Support • Research Area: Advancing space-based data collection capabilities and associated platforms and systems Science • How can we use polar imagers to provide wind information in the polar regions where conventional wind observations are scarce? • How can we improve the quality of satellite-derived winds and improve their utility and impact in Numerical Weather Prediction (NWP)? Benefit • Satellite derived wind products: • Provide vital tropospheric wind information over expansive regions of the earth devoid of in-situ wind observations that include oceans, polar regions, and Southern Hemisphere land masses. • Provide vital tropospheric wind information over low latitudes and on scales in higher latitudes where the geostrophic relationship is invalid • Provide key wind observations to operational NWP data assimilation systems where their use has been demonstrated to improved numerical weather prediction forecasts including tropical cyclones • Provide improved guidance for NWS field forecasters
Challenges and Path Forward • Science challenges • Satellite wind height assignment for optically thin clouds • Assignment of a height uncertainty with each satellite wind for the NWP community • Next steps • Development of a NPP VIIRS polar winds products (funded FY10 PSDI effort) • Complete development and validation of GOES-R satellite wind algorithm that includes new tracking algorithm approach (GOES-R AWG funded effort) • Apply GOES-R satellite wind algorithm approach for current operational GOES and polar instruments, but starting with the GOES instruments (funded FY10 PSDI effort) • Work with JCSDA and other NWP centers to assess impact of winds derived with new tracking algorithm on NWP forecast accuracy • Continued development of improved satellite winds validation tools that leverage use of new data sources (CALIPSO/CLOUDSAT, LIDAR winds) that will enable improved characterization of the accuracy and uncertainties associated with satellite derived winds • Transition Path • The GOES-R derived motion winds algorithm is scheduled to be delivered to the GOES-R system integrator by September 2010 • Work to apply the GOES-R derived motion winds algorithm to the current GOES series of satellites/instruments is scheduled to begin June 2010 (a PSDI funded effort). End goal of effort is to replace the current operational derived motion winds algorithm by March 2012 • Transition of VIIRS polar wind products to operations to begin late 2011 (a PSDI funded effort)
Basics of Satellite Winds Derivation Visible (0.64um) Visible (0.64um) SWIR (3.9um) SWIR (3.9um) Mid-IR (6.7um) Mid-IR (6.7um) LWIR (11um) LWIR (11um) • Atmospheric motion is determined through the tracking of features (clouds or moisture gradients) in time • The choice of spectral band determines the intended target and location (low, mid, upper troposphere) in the atmosphere • Use a pattern matching algorithm for estimating motion of features • Sum-of-Squared Differences (SSD) • Use multi-spectral height assignment algorithms to assign heights to features being tracked • Multi-spectral approaches: CO2 slicing, H2O-intercept, Histogram algorithms • Clear-sky radiances per a forward Radiative Transfer Model (RTM) • Atmospheric state per NWP forecasts • Apply quality control • NWP forecast to flag outliers • Internal consistency checks • Compute and assign product quality indicators • QI approach • Error Estimation (EE) approach Visible Cloud-drift Winds - Daytime - Lower troposphere Short-wave IR Cloud-drift Winds - Night-time - Lower troposphere Water Vapor Winds - Cloud-top - Clear-sky - Mid to Upper troposphere Long-wave IR Cloud-drift Winds - Day and night - Lower, mid, and upper troposphere
Satellite Winds Research • Development of polar wind products • Motivation: Provide satellite wind observations over polar regions where conventional in-situ wind observations are lacking • Improving the refresh rate of geostationary wind products • Motivation: Provide more frequent satellite winds for use in emerging operational 4D-VAR data assimilation systems at NWP centers • Development of a new and novel tracking algorithm • Motivation: Address and minimize the long standing problem of the observed slow speed bias associated with mid and upper-level satellite-derived winds; a significant concern of NWP community • Development of new approaches and tools to validate satellite wind height assignments • Motivation: Quantify the height uncertainty of satellite winds, improve their accuracy, and improve their use in NWP
Polar Wind Product Innovations Terra only or Aqua only Aqua, Terra, Aqua Benefits • Provide unprecedented coverage of the polar wind field that improves polar wind analyses • Continuity: Recent use of AVHRR for polar wind estimation prepares us for a future without MODIS • Demonstrated positive forecast impacts • Medium range weather forecasts, not just over the polar regions, but globally • Reduction in the frequency of forecast busts • Reduction in tropical storm track forecast errors MODIS Winds AVHRR Winds Single Satellite (Aqua or Terra) NOAA-AVHRR GAC Winds Mixed Satellite (Aqua and Terra) METOP-AVHRR Winds
Innovation: Improving the Refresh Rateof Geostationary Wind Products Benefits • Improve refresh rate of GOES-E/W wind products from 3-hourly to hourly • Provide a more continuous (in time) source of satellite wind observations for emerging operational 4D-VAR NWP data assimilation systems • Potential for significant and positive impacts on NWP forecast accuracy GOES-12 Hourly Cloud-drift Winds GOES-11 Hourly Cloud-drift Winds
Feature Tracking Algorithm Innovations 10 5 m/s 0 -5 Date Before clustering After clustering New Nested Tracking Algorithm • Developed for future GOES-R ABI • Aims to minimize observed slow speed bias of satellite winds; a significant concern for NWP • Computes local motions (nested) within a larger target scene, together with a clustering algorithm, to arrive at a superior motion solution • Potential for determination of motion at different levels and/or different scales Sat vs. Rawinsonde (100-400 hPa) Mean Vector Difference 1–2 m/s slow bias Speed Bias Nested Tracking 5 Lines Motion of entire box SPD: 22.3 m/s Average of largest cluster SPD: 27.6 m/s 5 Elements 15 Lines 15 Elements
Feature Tracking Algorithm Innovations Comparisons to Rawinsondes Test winds are better fit to radiosonde winds Black - control Light Blue -test AMV Speed (m/s) RAOB Speed (m/s) Benefits • Improved wind estimates • Near elimination of slow speed bias • Reduction of vector RMS error • Potential for significant and positive impacts on NWP forecast accuracy • Impact studies with JCSDA planned Winds generated using Meteosat-8 10.8 μm imagery (15-minute loop interval) for the period Feb 1 - 28, 2008.
Innovations in Satellite Wind Height Assignment Validation CALIPSO Cloud Height Satellite Wind Height Benefits • Leverages unprecedented cloud information offered by CALIPSO and CloudSat measurements • Enables improved error characterization of satellite wind height assignments • Enables feedback for potential improvements to satellite wind height assignments • Improvements to overall accuracy of satellite-derived winds Using CALIPSO/CloudSat Data to Validate Satellite Wind Height Assignments GOES-12 Cloud-drift Wind Heights Overlaid on CALIPSO total attenuated backscatter image at 532nm
Challenges and Path Forward • Science challenges • Satellite wind height assignment for optically thin clouds • Assignment of a height uncertainty with each satellite wind for the NWP community • Next steps • Development of a NPP VIIRS polar winds products (funded FY10 PSDI effort) • Complete development and validation of GOES-R satellite wind algorithm that includes new tracking algorithm approach (GOES-R AWG funded effort) • Apply GOES-R satellite wind algorithm approach for current operational GOES and polar instruments, but starting with the GOES instruments (funded FY10 PSDI effort) • Work with JCSDA and other NWP centers to assess impact of winds derived with new tracking algorithm on NWP forecast accuracy • Continued development of improved satellite winds validation tools that leverage use of new data sources (CALIPSO/CLOUDSAT, LIDAR winds) that will enable improved characterization of the accuracy and uncertainties associated with satellite derived winds • Transition Path • The GOES-R derived motion winds algorithm is scheduled to be delivered to the GOES-R system integrator by September 2010 • Work to apply the GOES-R derived motion winds algorithm to the current GOES series of satellites/instruments is scheduled to begin June 2010 (a PSDI funded effort). End goal of effort is to replace the current operational derived motion winds algorithm by March 2012 • Transition of VIIRS polar wind products to operations to begin late 2011 (a PSDI funded effort)