230 likes | 402 Views
Introduction. Zoltan’s information Matrix (consider a list of people in the branch, maybe take the time to go around the room for brief introductions) Strategic plan Thrust areas Mission . LAPS System. LAPS Motivation. High Resolution (500m – 3km), rapid update (10-60min)
E N D
Introduction Zoltan’s information Matrix (consider a list of people in the branch, maybe take the time to go around the room for brief introductions) Strategic plan Thrust areas Mission
LAPS Motivation • High Resolution (500m – 3km), rapid update (10-60min) • Highly portable system – about 150 users world wide • Federal Gov’t – NWS, RSA, PADS, FAA, DHS • State Gov’t – California Dept of Water Resources • International – Finnish Met. Inst., China Heavy Rain Inst. • Global analysis – used by SOS • Wide variety • of data sources: 3
LAPS Features • Modernization of traditional analysis to fully variational (var-LAPS); • Hot-start with cloud, vertical velocity and other meteorological states reflecting latent heat and forcing; • Multiscale analysis; • Efficient analysis for frequent analysis cycles (currently running on a single processor with 15 minute cycle for CONUS domain). Hotstart with cloud/rain/snow Variational LAPS has higher ETS than persistence fcst.
What is an OSSE? An OSSE is a modeling experiment used to evaluate the impact of new observing systems on operational forecasts when actual observational data is not available. A long free model run is used as the “truth” - the Nature Run The Nature Run fields are used to back out “synthetic observations” from all current and new observing systems. The synthetic observations are assimilated into a different operational model Forecasts are made with the second model and compared with the Nature Run to quantify improvements due to the new observing system Early OSSE works confirmed data impact when observation systems have actually launched (ERS, NSCAT and AIRS, Atlas 1985,1997 and so on).
GSD OSSE UAS impact WISDOM impact Calibrated NOAA joint OSSE; Report to NOAA UAS program on UAS data impact on hurricane tracks; WISDOM OSSE; New nature run; Targeting observation scheme in OSSE.
2ND LAPS USER WORKSHOP Global Systems Division NOAA/OAR/ESRL Acknowledgements: Forecast Applications Branch 23-25 October 2012, Boulder, CO 9
SCOPE of Workshop • Private Sector • Weather Decision Tech., Hydro Meteo, • Precision Wind, Vaisala, Telvent • International agencies (10+ countries) • KMA, CMA, CWB, Finland (FMI), Italy, Spain, • BoM (Australia), Canary Islands, HKO, • Greece, Serbia, Nanjing Inst. of Met. • NOAA • ~120 WFOs (via AWIPS), ARL, NESDIS • Other US Agencies • DHS, DoD, FAA, CA DWR, GA Air Qual. • Academia • Univ of HI, Athens, Arizona, CIRA, UND, McGill 10
1ST LAPS WORKSHOP ATTENDEES Oct. 25-27 2010, ESRL, Boulder, CO
2nd LAPS WORKSHOP ATTENDEES Oct. 23-25 2010, ESRL, Boulder, CO October 23-25 2012
Workshop Statistics Three-day workshop (Oct 23-25, 2012). Attendees Roughly 85 attendees 23 remote attendees all US Several countries represented (prior slide) 30 oral presentations 3-4 remote. 5 posters Three break out topical areas (working groups) Scientific opportunitiesfor further development Fully variational multiscale DA approach Dynamical constraints consistent with WRF Use of LAPS User feedback Change control management Test & evaluation Role of NWS Collaboration / data / software Shared algorithm / software development Software to digest new types of data LAPS repository
Summary and Recommendations Fine scale LAPS analyses and forecasts are widely used for Situational awareness Warn-On-Forecasting Continue development and support of LAPS Serves a unique need within NWS, private sector, and internationally with 150+ total users worldwide Unique combination of features Fine scale, very rapid update, highly portable, easy to use Further enhance unique features of LAPS LAPS analysis system was in Zoltan’s slide set ??
Observing Systems & OSSE’s • Context: Observations provide the initial conditions from which model analyses and predictions are made. • The accuracy of our predictions primarily depend on four things: • Uncertainty (errors) in the initial conditions at the boundaries of our models; • Errors in the model’s background (or first guess) and physics; • Errors in the observations used to modify the initial conditions at each increment, or verify the accuracy of observations, backgrounds, analyses and predictions; • Errors in the analysis of these observations. • Bottom line: Improvements in our predictions require some effort in each of these areas.
Issues • It’s difficult to verify each of these things, especially in remote regions of the planet. • Many of our assumptions are not well tested, especially under extreme conditions associated with severe weather and changes in planetary forcing. • The observations that could reduce uncertainty are expensive and the resources needed to make them are decreasing. • How an we insure continued forecast improvement under these circumstances? • This presentation describes the approach that some of us in FAB are taking.
GPS Observations NOAA Mission: To understand and predict changes in Earth’s environment and conserve and manage coastal and marine resources to meet our nation’s economic, social, and environmental needs GPS-Met supports NOAA’s Mission by providing reliable and accurate refractivity & moisture estimates at low cost under all weather conditions anywhere a permanent GPS tracking station can be established. Climate Goal: Weather & Water Goal: Commerce & Transportation Goal: Satellites Modeling & Observing Systems
TPW Uncertainty MOHAVE 2009 0.24 mm 0.43 mm Leblanc et al. 2011: Measurements of Humidity in the Atmosphere and Validation Experiments (MOHAVE)-2009: overview of campaign operations and results, Atmos. Meas. Tech., 4, 2579-2605, doi:10.5194/amt-4-2579-2011.
Some Applications • Assimilation of GPS PW into operational NWP models. • Subjective forecasting/improved situational awareness for forecasters. • Quality control of in situ and remote sensing (both satellite and surface-based) moisture observations for weather, climate and research. • Development and testing of next-generation satellite algorithms.
Significant Results • It’s possible to use a low cost total-column refractivity measurement to calibrate, validate and monitor the performance of operational observing systems • NOAA Global Model (GFS) has a systematic dry bias over the U.S. in summer. • Global models assimilating GPS observations have smaller systematic errors than models that do not. • Synoptic-mesoscale models assimilating GPS observations have smaller short-range RH prediction errors than models that do not. • Satellite microwave TPW estimates over the ocean are systematically dry-biased in the presence of clouds.
Programmatic Issues • Transition of GPS Met from research into operations is stalled. • Funding for GPS R&D in NOAA is insufficient to support expanded use.