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Course Evaluation

Course Evaluation. Now online You should have gotten an email with link. Final Exam. Comprehensive Stress since last midterm Celebration later that afternoon (optional, but fun). Subseasonal and Seasonal Forecasts. Subseasonal : 2-6 weeks Seasonal: 1.5-12 months. How long skill?.

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Course Evaluation

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  1. Course Evaluation • Now online • You should have gotten an email with link

  2. Final Exam • Comprehensive • Stress since last midterm • Celebration later that afternoon (optional, but fun)

  3. Subseasonal and Seasonal Forecasts Subseasonal: 2-6 weeks Seasonal: 1.5-12 months

  4. How long skill? • Weather prediction skill is now extending into the second week • Superstorm Sandy was a famous example, but there are more.

  5. Observed 180 hr (7.5 days)

  6. A number of global models are run out several weeks • GFS goes out to 384 hour (16 days) • ECMWF: Deterministic model: 10 days, 46 days (twice a week), and 7 months (once a month, coupled atmos/ocean) • CFS (NOAA Climate Forecast System): out to 9 months. Coupled atmos/ocean

  7. For week two, the best approach is to use global ensembles for prediction and to determine confidence

  8. http://www.esrl.noaa.gov/psd/map/images/ens/ens.html#us

  9. The Climate Prediction Center has graphics that summarize week two

  10. Longer than 2 weeks • There is the potential to forecast mean or average characteristics of the atmosphere further in time. • The key to this long-range forecasting is the memory of the ocean. • Slowly changing surface characteristics can also be important (e.g., snow cover, sea ice coverage) • These slowly changing surface characteristics have a substantial impact on the atmosphere

  11. The Classic Example: El Nino an La Nina • Persistent and large SST anomalies influence convection, which influences large scale wave patterns.

  12. El Nino and La Nina • An important atmospheric variation that has an average period of three to seven years. • Goes between El Nino, Neutral, and La Nina (ENSO cycle, El Nino Southern Oscillation) • Has large influence both in the tropics and midlatitudes. • Main source of forecast skill beyond a few weeks.

  13. An Important Measure is the Temperature in the Tropical Pacific

  14. Niño Region SST Departures (oC) Recent Evolution The latest weekly SST departures are: Niño 4 -0.6ºC Niño 3.4 -1.1ºC Niño 3 -1.2ºC Niño 1+2 -1.3ºC

  15. Why do we care? • The circulations in the midlatitudes are substantially different in El Nino, Neutral, and La Nina years. • Since the temperature of the tropical Pacific changes relatively slowly, this gives some meteorologist some insights into the weather over the next several months.

  16. Teleconnections from the tropics

  17. El Nino – weak Aleutian High

  18. La Nina – strong Aleutian High

  19. The correlation between El Nino/La Nina (ENSO) and midlatitude weather is the key tool for extended forecasting • The BEST web site for information is at the Climate Prediction Center • http://www.cpc.ncep.noaa.gov/products/analysis_monitoring/enso_advisory/index.shtml

  20. Other features: MJO

  21. Long Range Forecasts • During the past two decades, a new generation of extended forecasting systems that have been developed that run global atmosphere/ocean models out MONTHS • An example is the NOAA Climate Forecasting System (CFS)…now CFSv2 • Runs the GFS and a coupled ocean model out 9 months.

  22. The CFS • GFS run at roughly 60 km grid spacing and 64 levels. • Run every six hours (4 runs each time…an ensemble)

  23. 0 UTC 6 UTC 12 UTC 18 UTC Operational Configuration for CFSv2 real time forecasts (T126L64) • There will be 4 control runs per day from the 0, 6, 12 and 18 UTC cycles of the CFS real-time data assimilation system, out to 9 months. • In addition to the control run of 9 months at the 0 UTC cycle, there will be 3 additional runs, out to one season. These 3 runs per cycle will be initialized as in current operations. • In addition to the control run of 9 months at the 6, 12 and 18 UTC cycles, there will be 3 additional runs, out to 45 days. These 3 runs per cycle will be initialized as in current operations. • There will be a total of 16 CFS runs every day, of which 4 runs will go out to 9 months, 3 runs will go out to 1 season and 9 runs will go out to 45 days. 1 season run (3) 45 day run (9) 9 month run (4)

  24. http://www.cpc.ncep.noaa.gov/products/people/wwang/cfsv2fcst/http://www.cpc.ncep.noaa.gov/products/people/wwang/cfsv2fcst/

  25. CFS loses skill quickly after several weeks

  26. Z500 MAE - week 1 *de-biased

  27. Z500 MAE - week 4 *de-biased

  28. Z500 MAE - week 4 *de-biased Errors saturate after 3 weeks Storm tracks Errors rapidly grow in the first week

  29. SSTs

  30. SST MAE - week 1 *de-biased

  31. SST MAE - week 6 *de-biased

  32. Seasonal Models Like to Push Classic El Nino Pattern, But Show Little Skill for Amplified Wave Patterns.

  33. SST MAE - week 6 *de-biased Errors continue to grow ~linearly

  34. Why do subseasonal and seasonal forecasts go bad after a few weeks? Poor, parameterized convection is a very possible cause.

  35. The nature of tropical convection And how it evolves with lead time

  36. CHI200 Hovmoller: analysis vs week-1 forecasts Winter/Spring ‘87-’88 *single-member forecasts

  37. CHI200 Hovmoller: analysis vs week-1 forecasts Wave propagation in both analyses and forecasts *single-member forecasts

  38. CHI200 Hovmoller: analysis vs week-2 forecasts *single-member forecasts

  39. CHI200 Hovmoller: analysis vs week-3 forecasts *single-member forecasts

  40. CHI200 Hovmoller: analysis vs week-4 forecasts *single-member forecasts

  41. CHI200 Hovmoller: analysis vs week-5 forecasts Coherent propagating structures are lost as lead time increases! More stationary features take over *single-member forecasts

  42. CHI200 Hovmoller: other examples Winter/Spring ‘96-’97 Week-5 forecasts *single-member forecasts

  43. CHI200 Hovmoller: other examples Spring/Summer ‘05 Week-4 forecasts *single-member forecasts

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