1 / 27

Assimilating Dense Pressure Observations in a High- ResOLUTION WRF Ensemble Using an EnKF

Assimilating Dense Pressure Observations in a High- ResOLUTION WRF Ensemble Using an EnKF. Luke Madaus -- Wed., Sept. 21, 2011. Overview. Motivation Background and previous research Treating the model Treating the observations Future work. Past problems.

lewis
Download Presentation

Assimilating Dense Pressure Observations in a High- ResOLUTION WRF Ensemble Using an EnKF

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Assimilating Dense Pressure Observations in a High-ResOLUTION WRF Ensemble Using an EnKF Luke Madaus -- Wed., Sept. 21, 2011

  2. Overview • Motivation • Background and previous research • Treating the model • Treating the observations • Future work

  3. Past problems • Weather models still poorly predict the timing and intensity of significant weather events • Eckel and Mass (2005) – For short-range forecasts,,important to capture variability at small scales using very high resolution • Data assimilation can try to introduce small-scale features – if variables assimilated are chosen judiciously Images from Phil Regulski

  4. Why pressure? • Less sensitive to representativeness error • Widely available observations • Has far-reaching meso- and synoptic-scale relevance • Also can provide information in the vertical • (Dirren et al 2007)

  5. Previous studies • Surface pressure obs used to do early 20th century reanalysis (Whitaker et al 2004) • Increases in both temporal frequency and spatial density of pressure observations lead to decreased errors (Anderson et al 2005) • Large covariances between pressure and geopotential height through hydrostatic balance (Dirren et al 2007) • Pressure/altimeter observations shown to increase accuracy of modeled MCSs and cold pools (Wheatley and Stensrud 2009)

  6. Fundamental Question We’ve seen that pressure observations contain information relevant to synoptic scales… …but to what extent can pressure observations be used to describe phenomena on the mesoscale?

  7. Fundamental question • To investigate: • Use a large ensemble capable of resolving mesoscale features • Need observations at a density sufficient to represent the same scales of variability we are trying to model To what extent can pressure observations be used to describe phenomena on the mesoscale?

  8. Previous Studies

  9. Previous studies Anderson Et. Al 2005 – “30 latitudes, 60 longitudes”

  10. Previous studies -- high-resolution? Wheatley and Stensrud, 2009 • 30 km grid spacing

  11. High-resolution Current Setup • 4 km grid spacing • Quasi-explicit resolution of: • Some convective processes • Small-scale boundaries • Some localized orographic effects • Need observed data to match! Weisman et al. 2008

  12. Data sources ASOS -- 103 All potential obs -- 1733

  13. Data sources TOTAL – 1000-1600 observations hourly across Pac. NW • ASOS – Canada and US (100) • Weather Underground (650) • AWS Schoolnet (80) • CWOP (250) • RAWS (5) • Oregon RWIS (10) • Pendleton WFO Network (15) • Land/Sea Synop (30) • Other (50)

  14. Experiments in progress • Test case – July 25, 2011

  15. Sample Impacts Control assimilation – only QC obs All obs raw assimilation

  16. Bias Removal • Bias in observations can throw off model estimate of state • Covariances with other variables can amplify the impact of bias

  17. Possible solutions • MADIS RSAS Analysis Grids • Successfully used to quality check MADIS observations (CWOP, AWS, etc.) (Miller and Barth 2002) • Could be applied in a manner similar to Mass and Ferber (1990) • Preliminary success – around 90% of biased obs “corrected” • What about pressure tendency? • Should not be affected by bias • Not investigated as something to assimilate

  18. Short-term future work • Investigate these areas: • Look into how the ensemble responds to pressure assimilation with respect to mesoscale variability • How much of the full state vector can pressure capture? • What is the structure of covariances? • How does model variability on small spatial scales reflect the introduction of more pressure observations? • How does the ensemble’s mesoscale accuracy change with variations in spatial density and temporal frequency of observations? • How can the EnKF assimilation system be appropriately adjusted to reflect the properties of these observations? • Continue bias mitigation efforts

  19. Medium-term future work • Additional case studies • Hopefully a storm this fall… • Begin discussions with forecasters at Seattle WFO • Look into assimilating pressure tendency observations to see their impact • Application to NCAR visiting graduate student program • Developing DART code

  20. Long-term future work • If pressure assimilation can help resolve mesoscale variability, it has great potential to not only help predict, but also to inform • Use this as a tool to investigate convective initiation • High-density pressure assimilation could allow detailed low-level structure to be represented in models • This could help to clarify key features leading to convective initiation

  21. Acknowledgements • Advisors – Cliff Mass and Greg Hakim • Phil Regulski • RahulMahajan • Mark Albright • Jeff Anderson and Nancy Collins at NCAR

  22. References • Anderson, J., B. Wyman, S. Zhang, T. Hoar, 2005: Assimilation of surface pressure observations using an ensemble filter in an idealized global atmospheric prediction system. J. Atmos. Sci., 62, 2925-2938. • Dirren, S., R. Torn, G. Hakim, 2007: A data assimilation case study using a limited-area ensemble filter. Mon. Wea. Rev., 135, 1455-1473. • Eckel, F. A., C. Mass, 2005: Aspects of effective mesoscale, short-range ensemble forecasting. Weather and Forecasting, 20, 328-350. • Mass, C. and G. Ferber, 1990: Surface pressure perturbations produced by an isolated mesoscale topographic barrier, part 1: general characteristics and dynamics. Mon. Wea. Rev., 118, 2579-2596. • McMurdie, L., C. Mass, 2004: Major numerical forecast failures over the northeast Pacific. Weather and Forecasting, 19, 338-356. • Miller, P. and M. Barth, 2002: RSAS Technical Procedures Bulletin. MSAS/RSAS. Web. Accessed: Sept. 12, 2011. • Weisman, M., C. Davis, W. Wang, K. Manning, J. Klemp, 2008: Experiences with 0-36-h explicit convective forecasts with the WRF-ARW model. Weather and Forecasting, 23, 407-437 • Wheatley, D. and D. Stensrud, 2010: The impact of assimilating surface pressure observations on severe weather events in a WRF mesoscale ensemble system. Mon. Wea. Rev., 138, 1673-1694. • Whitaker, J., G. Compo, X. Wei, T. Hamill, 2001: Reanalysis without radiosondes using ensemble data assimilation. Mon. Wea. Rev., 132, 1190-1200.

  23. Pressure tendency • Covariances not as strong—less impact than raw pressure (Wheatley and Stensrud 2009) • Pressure tendency requires continuity of observation • Not currently supported in the DART EnKF assimilation framework

  24. Different Parameterization WSM-3 microphysics WSM-5 microphysics

  25. How bad is bias? Before Bias Correction 535/1100  error >1.5mb After Bias Correction 50/1100  error > 1.5mb

  26. Pressure tendency • What about pressure tendency as a way to avoid bias? Bias not present in this representation of pressure obs

  27. EnKF assimilation New Estimate Observation Ensemble Pressure (hPa) 1009 hPa 1010 hPa

More Related