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6/29/2010 Wan-Shu Wu1 GSI Tutorial 2010 Background and Observation Error Estimation and Tuning.

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Presentation on theme: "6/29/2010 Wan-Shu Wu1 GSI Tutorial 2010 Background and Observation Error Estimation and Tuning."— Presentation transcript:

1 6/29/2010 Wan-Shu Wu1 GSI Tutorial 2010 Background and Observation Error Estimation and Tuning

2 6/29/2010 Wan-Shu Wu2 Background Error 1. Background error covariance 2. Multivariate relation 3. Covariance with fat-tailed power spectrum 4. Estimate background error

3 6/29/2010 Wan-Shu Wu3 Analysis system produces an analysis through the minimization of an objective function given by J = x T B -1 x + ( H x – y ) T R -1 ( H x – y ) J b J o Where x is a vector of analysis increments, B is the background error covariance matrix, y is a vector of the observational residuals, y = y obs – H x guess R is the observational and representativeness error covariance matrix H is the transformation operator from the analysis variable to the form of the observations.

4 6/29/2010 Wan-Shu Wu4 One ob test &SETUP …. oneobtest=.true. &SINGLEOB_TEST maginnov=1.,magoberr=1.,oneob_type=‘t’, oblat=45.,oblon=270.,obpres=850., obdattime=2010062900,obhourset=0.,

5 6/29/2010 Wan-Shu Wu5 Temp Analysis Increment from Single Temp obs

6 6/29/2010 Wan-Shu Wu6 Temp and E-W Wind Analysis Increment from 1 Temp obs

7 6/29/2010 Wan-Shu Wu7 Humidity Analysis Increment from Single Temp obs

8 6/29/2010 Wan-Shu Wu8 Surface Pressure Analysis Increment from Single Temp obs

9 6/29/2010 Wan-Shu Wu9 Multivariate relation  Balanced part of the temperature is defined by T b = G  where G is an empirical matrix that projects increments of stream function at one level to a vertical profile of balanced part of temperature increments. G is latitude dependent.  Balanced part of the velocity potential is defined as  b = c  where coefficient c is function of latitude and height.  Balanced part of the surface pressure increment is defined as P b = W  where matrix W integrates the appropriate contribution of the stream function from each level.

10 6/29/2010 Wan-Shu Wu10 Multivariate Relation Vertical cross section of u and temp global mean fraction of balanced temperature and velocity potential

11 6/29/2010 Wan-Shu Wu11 Control Variable and Error Variances Normalized relative humidity (qoption=2)  RH /  RH b ) = RH b (  P/P b +  q /q b -  T /  b ) where  (RH b ) : standard deviation of background error as function of RH b  b : - 1 / d(RH)/d(T) multivariate relation with Temp and P * Holm et al.(2002) ECMWF Tech Memo

12 6/29/2010 Wan-Shu Wu12 Background error variance of RH *Figure 23 in Holm et al.(2002) ECMWF Tech Memo

13 6/29/2010 Wan-Shu Wu13 Control Variables and Model Vaiables U (left) and v (right) increments at sigma level 0.267, of a 1 m/s westerly wind observational residual at 50N and 330 E at 250 mb.

14 6/29/2010 Wan-Shu Wu14 Background error covariance The error statistics are estimated in grid space with the ‘NMC’ method. Stats of y are shown. Stats are function of latitude and sigma level. The error variance (m 4 s -2 ) is larger in mid-latitudes than in the tropics and larger in the southern hemisphere than in the northern. The horizontal scales are larger in the tropics, and increases with height. The vertical scales are larger in the mid-latitude, and decrease with height.

15 6/29/2010 Wan-Shu Wu15 Background error covariance Horizontal scales in units of 100km vertical scale in units of vertical grid

16 6/29/2010 Wan-Shu Wu16 Fat-tailed Power Spectrum for B

17 6/29/2010 Wan-Shu Wu17 Fat-tailed Power Spectrum Psfc increments with single homogeneous recursive filter. (scale C) Cross validation

18 6/29/2010 Wan-Shu Wu18 Fat-tailed Power Spectrum Psfc increments with inhomogeneous scales with single recursive filter: scale v (left) and multiple recursive filter: fat-tail (right)

19 6/29/2010 Wan-Shu Wu19 Estimate Background Error NMC method time differences of forecasts (48-24hr) Basic assumption: linear error growth with time Ensemble method ensemble differences of forecasts Basic assumption: ensemble represents real spread Conventional method differences of forecasts and obs difficulties: obs coverage, multivariate…

20 6/29/2010 Wan-Shu Wu20 Estimate B from Regional Forecasts Spectral calculation of stream function and velocity potential from forecast differences of wind fields. 1. U & V : e 2 a grid 2. Fill to FFT grid number: taper & zero 3. FFT: both X & Y directions 4. Vor + Div 5. Del -2 6. FFT back to for Psi & Chi 7. Derivatives of Psi & Chi to find U2 & V2

21 6/29/2010 Wan-Shu Wu21 u & v from  & 

22 6/29/2010 Wan-Shu Wu22 Estimate B from Regional Forecasts

23 6/29/2010 Wan-Shu Wu23 Estimate B from Regional Forecasts

24 6/29/2010 Wan-Shu Wu24 Estimate B from Regional Forecasts

25 6/29/2010 Wan-Shu Wu25 Tuning Background Parameters berror=$FIXnam/nam_glb_berror.f77 &BKGERR as=0.28,0.28,0.3,0.7,0.1,0.1,1.0,1.0, hzscl=0.373,0.746,1.50, vs=0.6, (Note that hzscl and vs apply to all variables) Q: How to find out definitions of “as”? A: GSI code ( grep “as(4)” *90 to find in prewgt_reg.f90 )

26 6/29/2010 Wan-Shu Wu26 Impact of Background Error

27 6/29/2010 Wan-Shu Wu27 Impact of Background Error

28 6/29/2010 Wan-Shu Wu28 B adjustment ex2: Analysis increments of ozone

29 6/29/2010 Wan-Shu Wu29 B adjustment ex1: Analysis increments of ozone

30 6/29/2010 Wan-Shu Wu30 Impact of Vertical Scale White: Analysis Green: First Guess

31 6/29/2010 Wan-Shu Wu31 Impact of Vertical Scale

32 6/29/2010 Wan-Shu Wu32 Setup B for a new control variable Uni-variate Sparse observations Poor first guess quality (large error variances) With physical limit of non-negative value Passive scalars Ex: chemicals, aerosols, co2, co,….

33 6/29/2010 Wan-Shu Wu33 NMC method & Normalized Oz

34 6/29/2010 Wan-Shu Wu34 Background error and their estimation 1. Multivariate relation 2. Background error covariance 3. Covariance with fat-tailed power spectrum 4. Estimate background error

35 6/29/2010 Wan-Shu Wu35 Observational Error Conventional adjustments Adaptive Tuning

36 6/29/2010 Wan-Shu Wu36 Analysis system produces an analysis through the minimization of an objective function given by J = x T B -1 x + ( H x – y ) T R -1 ( H x – y ) J b J o Where x is a vector of analysis increments, B is the background error covariance matrix, y is a vector of the observational residuals, y = y obs – H x guess R is the observational and representativeness error covariance matrix H is the transformation operator from the analysis variable to the form of the observations.

37 6/29/2010 Wan-Shu Wu37 No method is optimal; There’ll be issues to solve and subjective tuning, smoothing, and averaging. Ex: 1) background error Ex: 2) ob error tune In a semi-operational system, tune B variances so that the analysis penalties are about half of original penalties; including the scale effects. Tune Oberror’s so that they are about the same as guess fit to data Discussions

38 6/29/2010 Wan-Shu Wu38 Talagrand (1997) on E ( J (X a ) ) Desroziers & Ivanov (2001) E( J o )= ½ Tr ( I p – HK) E( J b )= ½ Tr (KH) where I p is identity matrix with order p K is Kalman gain matrix H is linearlized observation forward operator Chapnik et al.(2004): robust even when B is incorrectly specified Adaptive Tuning of Oberror

39 6/29/2010 Wan-Shu Wu39 Tuning Procedure J (  X) =1/s b 2 J b (  X) + 1/s o 2 J o (  X ) Where s b and s o are the background and oberr weighting parameters S o = sqrt( 2J o / Tr ( I p – HK) ) Adaptive Tuning of Oberror

40 6/29/2010 Wan-Shu Wu40 Analysis system produces an analysis through the minimization of an objective function given by J = x T B -1 x + ( H x – y ) T R -1 ( H x – y ) J b J o Where x is a vector of analysis increments, B is the background error covariance matrix, y is a vector of the observational residuals, y = y obs – H x guess R is the observational and representativeness error covariance matrix H is the transformation operator from the analysis variable to the form of the observations.

41 6/29/2010 Wan-Shu Wu41 Tr ( I p – HK) = N obs - (  R -1/2 H  X a (y+R 1/2  +  R -1/2 H  X a (y  where  is random number with standard Gaussian distribution (mean: 0;variance:1 ) 2 outer iterations each produces an analysis; output new error table Consecutive jobs show the method converged Sum =  (1-s o ) 2 Randomized estimation of Tr (HK )

42 6/29/2010 Wan-Shu Wu42 S o for each ob type S o function of height (pressure) rawinsonde, aircft, aircar, profiler winds, dropsonde, satwind… S o constant with height ship, synoptic, metar, bogus, ssm/I, ers speed, aircft wind, aircar wind… The setup can be changed in penal.f90

43 6/29/2010 Wan-Shu Wu43 Turn on adaptive tuning of Oberr 1)&SETUP oberror_tune=.true. 2) If Global mode: &OBSQC oberrflg=.true. (Regional mode: oberrflg=.true. is default) (find in file stdout: GSIMOD: ***WARNING*** reset oberrflg= T) Note: GSI does not produce a valid analysis under the setup

44 6/29/2010 Wan-Shu Wu44 Sensitivity of adaptive tuning

45 6/29/2010 Wan-Shu Wu45 Adjustment of tuned error table

46 6/29/2010 Wan-Shu Wu46 Adaptive tuning of oberror of rawinsonde wind

47 6/29/2010 Wan-Shu Wu47 1) Can the tuning parameters of background error be changed with different outer loop? A: No, they should not be changed. ( solving for the same original problem) 2) Why more than one outer loop? A: To account for the nonlinear effect of the observational forward operator. Questions on B and outer loop

48 6/29/2010 Wan-Shu Wu48 Working code = answers to most questions with print and plot Plot to check changes Good Luck on Using GSI! Suggestions

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