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The application of ensemble Kalman filter in adaptive observation and information content estimation studies Junjie Liu and Eugenia Kalnay July 13th, 2007.

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Presentation on theme: "The application of ensemble Kalman filter in adaptive observation and information content estimation studies Junjie Liu and Eugenia Kalnay July 13th, 2007."— Presentation transcript:

1 The application of ensemble Kalman filter in adaptive observation and information content estimation studies Junjie Liu and Eugenia Kalnay July 13th, 2007

2 Question to address in adaptive observation study Adaptive observation: temporarily adjust observation locations Common question: how to allocate the limited observation resources to maximize effectiveness of observations (improve the analysis and forecast as much as possible)? Question in hand: how to allocate 10% Doppler Wind Lidar (DWL) scanning range? (Future DWL will operate in adaptive targeting mode (NPOESS P 3 I science team) (observation locations change with time)

3 LETKF-based ensemble spread adaptive observation strategy It is the square root difference between ensemble members and ensemble mean state. Ensemble spread estimated from ensemble Kalman filter (EnKF) reflects the dynamical uncertainties related with background dynamic flow.. In EnKF the ensemble spread strategy is very simple: we add the adaptive observations where the ensemble spread is large.

4 Rawinsonde observation locations and simulated satellite winds scanning range 00z and 12z 06z and 18z  The “orbit” allows simulated DWL observations potentially scanning each location twice a day.  Purpose: 10% adaptive observations: 10% of half global grid points.

5 Sampling strategies Ensemble spread strategy (from Local Ensemble Transform Kalman Filter)  Adaptive observations are at locations with large ensemble wind spread at 500hPa.  3D-Var and LETKF have the same adaptive observation points Random picking  Randomly pick locations from potential locations. Uniform distribution  Uniformly distributed. Climatology ensemble spread  Adaptive observations are at locations with large climatological average ensemble wind spread from rawinsonde assimilation.  Constant with time, and same for 3D-Var and LETKF. “Ideal” sampling Adaptive observations are at locations with large background error obtained from the “truth”. Change with time Constant Impossible in reality

6 500hPa zonal wind RMS error 4.042.360.920.740.430.360.30 3D-VarLETKF RMSE Rawinsonde; climatology; uniform; random; ensemble spread; “ideal”; 100%  With 10% adaptive observations, the analysis accuracy is significantly improved for both 3D-Var and LETKF.  3D-Var is more sensitive to adaptive strategies than LETKF. Ensemble spread strategy gets best result among operational possible strategies 1.180.380.360.330.320.290.23

7 500hPa zonal wind RMS error (2% adaptive obs) 3D-VarLETKF  With fewer (2%) adaptive observations, ensemble spread sampling strategy outperforms the other methods in LETKF  For 3D-Var, 2% adaptive observations are not enough to make significant improvement with any method Rawinsonde; climatology; uniform; random; ensemble spread; “ideal”; 100%

8 Analysis sensitivity study within LETKF It can also show the cross sensitivity by exploring the off diagonal term. No cost in LETKF assimilation framework. Reflects the observation impact in the analysis. Show the analysis sensitivity to different type of observations (rawinsonde, different type of satellite observations etc.) Analysis mean state: The analysis sensitivity: Degree of Freedom of Signal (DFS): the trace of the matrix S

9 Control experiment: rawinsonde only All the dynamical variables (winds, temperature, specific humidity and surface pressure) are observed in the observation locations

10 Exp_uv (winds are observed in both rawinsonde and dense network, 30%) Dense wind network

11 Contour: RMS error (zonal wind) difference between rawinsonde and exp_uv; Shaded: DFS of zonal wind in dense network  Winds have large impact over the region that does not have much rawinsonde, especially over Southern Hemisphere and the Tropics.  The DFS reflects the wind impact

12 The impact of winds delete-out experiments  In both add-on (add winds in the ctrlA observation network) and delete-out (delete winds in the ctrlB observation network) experiments, the winds show the significant impact over Tropics  Winds have large impact over mid-latitude in SH in add-on experiment, but does not shown this impact in the delete-out experiment, which is due to the significant covariance between winds and mass field in this area

13 Possible applications to Carbon problem Observation system design: ensemble spread method; Using the posterior uncertainty estimation. Evaluate the significance of the carbon observations: based on the sensitivity study (impact of the carbon concentration data on the flux estimation) Will address the essential problem: uncertainty estimation


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