1. Use of ensemble background-error covariances within variational data assimilation for NWP
Collaborators:
Peter Houtekamer
Herschel Mitchell
Cecilien Charette
Bin He
Gerald Desroziers
Loik Berre
Ron McTaggart-Cowan
Mark Buehner
Meteorological Research Division
August 1-11, 2011
LMS - EPSRC Durham Symposium on the Mathematics of Data Assimilation

2. Contents Brief description of Canadian operational NWP systems
Description of experimental configurations
Spatial covariance localization
Full analysis-forecast NWP experiments with different approaches for B matrix:
3D ensemble covariances with spatial localization
4D ensemble covariances with spatial localization
weighted average of stationary covariances and 3D ensemble covariances with spatial localization
Approach and results from using 3D ensemble covariances with spatial and spectral localization
Conclusions and next steps

3. Introduction
Goal: examine various approaches for using flow-dependent ensemble-based background error covariances within global deterministic analysis system for operational NWP
Initial project initiated in anticipation of WMO workshop on intercomparison of 4D-Var and EnKF, Buenos Aires, November 2008
4D-Var and EnKF:
both operational at CMC since 2005
both use GEM forecast model
both assimilate similar set of observations using mostly the same observation operators and observation error covariances
current effort towards unifying code of the two systems
4D-Var is used to initialize medium range global deterministic forecasts
EnKF is used to initialize global Ensemble Prediction System

4. Operational Systems (up to June 2009)
4D-Var (Gauthier et al. 2007)
incremental approach: ~35km/150km grid spacing, 58 levels, 10hPa top (now 80 levels, 0.1hPa top)
EnKF (Houtekamer and Mitchell 2005, Houtekamer et al. 2005)
96 ensemble members (soon 192): ~100km grid spacing, 28 levels, 10hPa top (now 58 levels)
uses 4D background-error covariances to produce 4D analysis (somewhat like 4D-Var, but without TL/AD of forecast model)
assimilates batches of observations sequentially by expliciting solving analysis equation and updating ensemble covariances
additive model error, no covariance inflation

5. Experimental Configurations Modifications relative to 2009 operational systems
Exactly same observations, including conventional data and satellite radiances, assimilated in all experiments
Increased number of levels in EnKF to match 4D-Var
Increased horizontal resolution of 4D-Var inner loop to match EnKF
Other minor modifications in both systems to obtain nearly identical innovations (each tested to ensure no degradation)

6. Experimental Configurations
Variational data assimilation system (Buehner et al. 2010):
3D-Var and 4D-Var with stationary B matrix as in operational system: NMC method (Bnmc)
3D-Var and 4D-Var with flow-dependent B matrix from EnKF with same localization parameters as in EnKF (Benkf)
Ensemble-Var (En-Var): use 4D ensemble covariances to produce 4D analysis without TL/AD models (most similar to EnKF approach)
3D-Var with B matrix computed as weighted average between Bnmc and Benkf (Bavg) (idea from Hamill and Snyder 2000)
3D-Var with B matrix from EnKF, but with spatial and spectral localization (Buehner 2011, submitted)
EnKF: Deterministic forecasts initialized with EnKF ensemble mean analysis (requires interpolation from ~100km to ~35km grid)

7. Experimental Configurations
Variational data assimilation system (Buehner et al. 2010):
3D-Var and 4D-Var with stationary B matrix as in operational system: NMC method (Bnmc)
3D-Var and 4D-Var with flow-dependent B matrix from EnKF with same localization parameters as in EnKF (Benkf)
Ensemble-Var (En-Var): use 4D ensemble covariances to produce 4D analysis without TL/AD models (most similar to EnKF approach)
3D-Var with B matrix computed as weighted average between Bnmc and Benkf (Bavg) (idea from Hamill and Snyder 2000)
3D-Var with B matrix from EnKF, but with spatial and spectral localization (Buehner 2011, submitted)
EnKF: Deterministic forecasts initialized with EnKF ensemble mean analysis (requires interpolation from ~100km to ~35km grid)
Interesting alternative to 4D-Var: doesn’t require development work related to TL/AD of forecast model, lower computational cost if ensemble members already available

8. Spatial covariance localization (Hamill et al. 2001)
At large separation distances covariances should be small, but estimation error dominates sample covariance estimate
Necessary to reduce distant covariances to reasonably fit large number of observations with only ~100 ensemble members
Severe localization can cause imbalance – more localization required for small ensemble size
Smoothly taper 3D spatial correlations to zero at large separation distance using a Schur product with a positive semi-definite “localization” matrix: B = L◦Bsample
Elements of L typically computed with a function resembling a Gaussian, but reaches zero at finite distance (e.g. 2800km)
For En-Var each 3D block of 4D B matrix is localized in the same way

9. Spatial localization in variational system (Buehner 2005, Lorenc 2003)
In variational assimilation pre-conditioned with respect to background term, control vector is related to analysis increment by:
∆x = B1/2 ξ
Approach for using ensemble-based B:
no localization: elements of control vector determine global contribution of each normalized ensemble member deviation to the analysis increment:
∆x = ∑k ek ξk (ξk is a scalar)
spatial localization: elements of control vector determine local contribution of each ensemble member to the analysis increment:
∆x = ∑k ek o (L1/2 ξk) (ξk is a 3D vector, ek is 3D or 4D)
can also combine with standard BNMC matrix (βBens+(1-β)BNMC):
∆x = β1/2 ∑k ek o (L1/2 ξk) + (1-β)1/2 BNMC1/2 ξHI
in each case, background cost function Jb is Euclidean inner product:
Jb = 1/2 ξT ξ (augmented control vector in case of averaged covariances)

10. Analysis and Forecast Verification Results En-Var vs
Analysis and Forecast Verification Results En-Var vs. standard approaches and En-Var vs. use of 3D ensemble B matrix
En-Var vs. EnKF
and
En-Var vs. 4D-Var-Bnmc
En-Var vs. 3D-Var-Benkf
En-Var vs. 4D-Var-Benkf

11. 4D error covariances Temporal covariance evolution (explicit vs
4D error covariances Temporal covariance evolution (explicit vs. implicit evolution)
EnKF and En-Var:
96 NLM integrations
3D-Var-Benkf only uses these members
4D-Var:
55 TL/AD integrations,
2 outer loop iterations,
then 3h NLM forecast
-3h 0h
+3h
“analysis time”

12. Single observation experiments Difference in temporal covariance evolution
En-Var
radiosonde temperature observation at 500hPa
observation at beginning of assimilation window (-3h)
with same B, increments very similar from 4D-Var, EnKF
contours are 500hPa GZ background state at 0h (ci=10m) + +
contour plots at 500 hPa + +

13. Single observation experiments Difference in temporal covariance evolution
En-Var
radiosonde temperature observation at 500hPa
observation at middle of assimilation window (+0h)
with same B, increments very similar from 4D-Var, EnKF
contours are 500hPa GZ background state at 0h (ci=10m) + +
contour plots at 500 hPa + +

14. Single observation experiments Difference in temporal covariance evolution
En-Var
radiosonde temperature observation at 500hPa
observation at end of assimilation window (+3h)
with same B, increments very similar from 4D-Var, EnKF
contours are 500hPa GZ background state at 0h (ci=10m) + +
contour plots at 500 hPa + +

15. Forecast Results: En-Var vs. EnKF
north tropics south
Difference in
stddev relative
to radiosondes:
Positive 
En-Var better
Negative 
EnKF better
En-Var uses incremental approach, deterministic analysis
EnKF uses ens mean at lower resolution
zonal
wind
temp.
height

16. Forecast Results: En-Var vs. 4D-Var-Bnmc
north tropics south
Difference in
stddev relative
to radiosondes:
Positive 
En-Var better
Negative 
4D-Var-Bnmc better
zonal
wind
temp.
height

17. Forecast Results: En-Var vs. 3D-FGAT-Benkf
north tropics south
Difference in
stddev relative
to radiosondes:
Positive 
En-Var better
Negative 
3D-FGAT-Benkf better
zonal
wind
temp.
height

18. Forecast Results: En-Var vs. 4D-Var-Benkf
north tropics south
Difference in
stddev relative
to radiosondes:
Positive 
En-Var better
Negative 
4D-Var-Benkf better
zonal
wind
temp.
height

19. Results – 500hPa GZ anomaly correlation
Verifying analyses from 4D-Var with Bnmc
Northern hemisphere
Southern hemisphere
3D-FGAT Benkf
En-Var
4D-Var Benkf
3D-FGAT Benkf
En-Var
4D-Var Benkf

20. Results – 850hPa Temperature bias
Verifying analyses from mean of 3 reanalyses
(ECMWF, NCEP/NCAR, JMA)
4D-Var-Bnmc
0UTC, 12UTC
6UTC, 18UTC

21. Results – 850hPa Temperature bias
Verifying analyses from mean of 3 reanalyses
(ECMWF, NCEP/NCAR, JMA)
4D-Var-Benkf
0UTC, 12UTC
6UTC, 18UTC

22. Results – 850hPa Temperature bias
Verifying analyses from mean of 3 reanalyses
(ECMWF, NCEP/NCAR, JMA)
En-Var
0UTC, 12UTC
6UTC, 18UTC

23. Results – Temperature error over N. Africa
Verifying analyses from mean of 3 reanalyses
(ECMWF, NCEP/NCAR, JMA)
Bias
StdDev
large sensitivity to B at 850hPa over certain areas in the tropics, why?
possible problem over land affecting all experiments

24. Results – Temperature error over N. midlat
Verifying analyses from mean of 3 reanalyses
(ECMWF, NCEP/NCAR, JMA)
Improvement in background state less clear over the northern extra-tropics
Bias
StdDev

25. 3D-Var-Bavg vs. 3D-Var-Bnmc and 3D-Var-Bavg vs. 3D-Var-Benkf
Analysis and Forecast Verification Results Averaged covariances vs. Bnmc and Benkf (similar approach already operational at Met Office)
Bavg = ½ Bnmc + ½ Benkf
3D-Var-Bavg vs. 3D-Var-Bnmc
and
3D-Var-Bavg vs. 3D-Var-Benkf

26. Forecast Results: 3D-Var-Bavg vs. 3D-Var-Bnmc
north tropics south
Difference in
stddev relative
to radiosondes:
Positive 
3D-Var-Bavg better
Negative 
3D-Var-Bnmc better
zonal
wind
temp.
height

27. Forecast Results: 3D-Var-Bavg vs. 3D-Var-Benkf
north tropics south
Difference in
stddev relative
to radiosondes:
Positive 
3D-Var-Bavg better
Negative 
3D-Var-Benkf better
zonal
wind
temp.
height

28. Results – 500hPa GZ anomaly correlation
Verifying analyses from 4D-Var with Bnmc
Northern hemisphere
Southern hemisphere
Benkf 0.50 and 0.75 are best
Benkf 0.75 and 1.00 are best
Bnmc and
Benkf 1.00 worst
Bnmc worst
Bnmc
Benkf 0.25
Benkf 0.50
Benkf 0.75
Benkf 1.00

29. Comparison of several approaches for using ensemble correlations (Buehner 2011, submitted)
During visit to Meteo-France, compared several approaches for using ensemble-based covariances in a variational assimilation system:
spatial localization (standard Schur product approach):
B = L◦Bsample
wavelet diagonal (as developed and used at ECMWF):
B = W-1diag(WBsampleWT) W-T
spectral diagonal (homogeneous/isotropic correlations):
B = S-1diag(SBsampleST) S-T  also variances averaged for each n
new spatial/spectral localization approach that combines aspects of spatial localization and wavelet diagonal approaches:
B = Σj Lj◦(WjBsampleWjT)  spatial localization and diagonal wrt scale j
***new approach allows scale-dependent spatial localization***

30. Spatial/Spectral correlation localization
In variational assimilation pre-conditioned with respect to background term, control vector is related to analysis increment by:
∆x = B1/2 ξ
Approach for using ensemble-based B:
spatial localization: elements of control vector determine local contribution of each ensemble member to the analysis increment:
∆x = ∑k ek o (L1/2 ξk) (ξk is a 3D vector)
spatial/spectral localization: elements of control vector determine local contribution of each ensemble member for a particular horizontal scale:
∆x = ∑j ∑k ek,j o (Lj1/2 ξk,j) where ek,j = Wj ek = S-1 Ψj S ek
could also be used in EnKF

31. Spatial/Spectral correlation localization
In variational assimilation pre-conditioned with respect to background term, control vector is related to analysis increment by:
∆x = B1/2 ξ
Approach for using ensemble-based B:
spatial localization: elements of control vector determine local contribution of each ensemble member to the analysis increment:
∆x = ∑k ek o (L1/2 ξk) (ξk is a 3D vector)
spatial/spectral localization: elements of control vector determine local contribution of each ensemble member for a particular horizontal scale:
∆x = ∑j ∑k ek,j o (Lj1/2 ξk,j) where ek,j = Wj ek = S-1 Ψj S ek
could also be used in EnKF
3D field for each scale and each member
wavelet functions: overlapping band-pass spectral filter

32. Spatial/Spectral correlation localization Effective wavenumber localization matrix
wavelet functions used for
wavelet diagonal approach
making correlations diagonal with respect to wavelet bands causes spectral localization
spectral localization is equivalent to local spatial averaging of correlation functions  more severe localization causes spatial averaging over a larger area
extent of spectral localization governed by choice of wavelet functions
wavelet functions used for new
spatial/spectral localization approach

33. Spatial/Spectral correlation localization Measuring correlation estimation error for each spectral band
n=032
n=165
mean correlation and estimation error as function of separation distance for different spectral bands
compute covariance between 2 independent samples: “agreement”
for higher wavenumber bands:
average correlation sharper (no surprise)
large estimation error begins at shorter separation distance
therefore could benefit from more severe spatial localization: scale-dependent spatial localization
n=3498
n=6799
note: estimation error is large when
agreement < magnitude
n=099

34. Spatial/Spectral correlation localization
idealized experiments with “true” correlations produced from 96-member EnKF ensemble of 500hPa temperature with weak spatial localization
48-member random ensemble generated using “true” correlations and each approach applied
with new approach, less spatial localization applied to large scales than small scales: scale-dependent localization

35. Spatial/Spectral correlation localization
zonal correlation length scale computed using Daley’s definition: (-d2c/dx2)-1/2
finite difference approximation for second derivative centered on origin of each correlation function

36. Spatial/Spectral correlation localization
rms error of each correlation estimate averaged over all separation distances (up to 3000km) and over many locations over North America

37. Spatial/Spectral correlation localization
raw sample
raw sample and truth
mean correlation and error stddev of correlations as a function of separation distance
spatial/spectral localization and wavelet diagonal approaches do not reproduce variance of 1 everywhere (possibly due to uneven spectral localization)

38. Spatial/Spectral correlation localization Impact of using scale-dependent localization
mean correlation and error stddev of correlations as a function of separation distance
solid = scale-dependent localization (3500km, 3000km, 2500km, 2000km)
dashed = scale-independent localization (3000km)
smaller negative bias with scale-dependence
similar error stddev with scale-dependence
truth

39. Spatial/Spectral correlation localization
single observation of 500hPa temperature near region of strong north-westerly winds
temperature increment = shading
wind increment = vectors
background 500hPa geopotential height = contours

40. Spatial/Spectral correlation localization
single observation of 500hPa temperature near region of strong north-westerly winds
temperature increment = shading
wind increment = vectors
background 500hPa geopotential height = contours

41. Spatial/Spectral correlation localization 1-month 3D-Var data assimilation experiments
initial value of radiosonde cost function shows that spatial/spectral localization produces better analyses than with spatial localization only
scale-dependent spatial localization better than using same spatial localization for all scales
Initial value of Jraob

42. Spatial/Spectral correlation localization 1-month 3D-Var data assimilation experiments
48h forecasts from using a B matrix estimated from:
grey: 96 ensemble members with spatial localization only
black: 48 ensemble members with spatial localization only

43. Spatial/Spectral correlation localization 1-month 3D-Var data assimilation experiments
48h forecasts from using a B matrix estimated from:
grey: 96 ensemble members with spatial localization only
black: 48 ensemble members with spatial localization and spectral localization over 6 evenly spaced total wavenumber bands

44. Spatial/Spectral correlation localization 1-month 3D-Var data assimilation experiments
48h forecasts from using a B matrix estimated from:
grey: 96 ensemble members with spatial localization only
black: 48 ensemble members with spatial localization and spectral localization over 6 evenly spaced total wavenumber bands, scale-dependent spatial localization

45. Conclusions
En-Var approach is attractive possible alternative to 4D-Var and current EnKF sequential* analysis approach (*wrt batches of observations)
advantages of En-Var vs. full 4D-Var:
no need to maintain TL/AD version of model dynamics and physical parameterizations (EnKF members already available)
more computationally efficient and likely easier to parallelize for high spatial resolution and large data volumes
potential advantages from using En-Var within EnKF instead of current approach:
global analysis (all obs treated together – don’t have to perform all analyses in parallel)
localization of B instead of BHT (latter is a potential problem for non-local observations: satellite radiances)
allows use of alternative approaches for modelling covariances: e.g. averaged covariances
allows use of variational quality control

46. Next Steps
Test En-Var approach in operational configuration of deterministic prediction system to compare with 4D-Var (requires raising top level of EnKF to 0.1hPa and synchronization in development of the two systems)
Examine possibility of using a variational approach for EnKF analysis step (i.e. can En-Var be made efficient enough to perform 192 analyses in < 1 hour? Or can we use less members with En-Var than EnKF? Can the minimizations work together?--Gerald’s talk)
Continue to modularize/unify the code for Variational and EnKF data assimilation systems to facilitate further development of both systems and hybrid approaches as described above

47. References
Buehner, M., 2005, "Ensemble-derived stationary and flow-dependent background error covariances: Evaluation in a quasi-operational setting for NWP ." Quart. J. Roy. Meteor. Soc. Vol. 131, p
Buehner, M., P.L. Houtekamer, C. Charette, H.L. Mitchell, B. He, 2010, "Intercomparison of variational data assimilation and the Ensemble Kalman Filter for global deterministic NWP. Part I: Description and Single-Observation experiments." Monthly Weather Review. Vol. 138, p
Buehner, M., P.L. Houtekamer, C. Charette, H.L. Mitchell, B. He, 2010, "Intercomparison of variational data assimilation and the Ensemble Kalman Filter for global deterministic NWP. Part II: One-Month Experiments with Real Observations." Monthly Weather Review. Vol. 138, p
Gauthier, P., M. Tanguay, S. Laroche, S. Pellerin, J. Morneau, 2007, “Extension of 3DVAR to 4DVAR: Implementation of 4DVAR at the Meteorological Service of Canada.” Mon. Wea. Rev., Vol 135, p2339–2354.
Hamill, T. M. and Snyder, C A hybrid ensemble Kalman filter—3D variational analysis scheme. Mon. Weather Rev., Vol. 128, p2905–2919.
Hamill, T. M., Whitaker, J. S. and Snyder, C Distance-dependent filtering of background error covariance estimates in an ensemble Kalman filter. Mon. Weather Rev., Vol. 129, p2776–2790
Houtekamer, P. L., H. L. Mitchell, G. Pellerin, M. Buehner, M. Charron, L. Spacek and B. Hansen, 2005, "Atmospheric data assimilation with the ensemble Kalman filter: Results with real observations ." Monthly Weather Review, Vol. 133, p
Houtekamer, P. L., and H. L. Mitchell, 2005, “Ensemble Kalman filtering.” Quarterly Journal of the Royal Meteorological Society, Vol 131, p3269–3289
Houtekamer, P. L., H. L. Mitchell, X. Deng, 2009, “Model Error Representation in an Operational Ensemble Kalman Filter.” Monthly Weather Review. Vol 137, p
Lorenc, A. C The potential of the ensemble Kalman filter for NWP: A comparison with 4D-Var. Q. J. R. Meteorol. Soc., Vol. 129, p3183–3203.

48. Extra Slides Follow

49. Forecast Results: En-Var vs. EnKF
north tropics south
Significance level of difference in stddev relative to radiosondes:
Positive 
En-Var better
Negative 
EnKF better
zonal
wind
temp.
Computed using bootstrap resampling of the individual scores for 48-hour non-overlapping periods.
Shading for 90% and 95% confidence levels
height

50. Forecast Results: En-Var vs. 4D-Var-Bnmc
north tropics south
Significance level of difference in stddev relative to radiosondes:
Positive 
En-Var better
Negative 
4D-Var-Bnmc better
zonal
wind
temp.
Computed using bootstrap resampling of the individual scores for 48-hour non-overlapping periods.
Shading for 90% and 95% confidence levels
height

51. Forecast Results: En-Var vs. 3D-FGAT-Benkf
north tropics south
Significance level of difference in stddev relative to radiosondes:
Positive 
En-Var better
Negative 
3D-FGAT-Benkf better
zonal
wind
temp.
Computed using bootstrap resampling of the individual scores for the 56 cases (28 days, twice per day).
Shading for 90% and 95% confidence levels
height

52. Forecast Results: En-4D-Var vs. 4D-Var-Benkf
north tropics south
Significance level of difference in stddev relative to radiosondes:
Positive 
En-Var better
Negative 
4D-Var-Benkf better
zonal
wind
temp.
Computed using bootstrap resampling of the individual scores for the 56 cases (28 days, twice per day).
Shading for 90% and 95% confidence levels
height

53. Results – Temperature error over Tropics
Verifying analyses from mean of 3 reanalyses
(ECMWF, NCEP/NCAR, JMA)
Improvement in background state over the tropics from using ensemble-based covariances
Bias
StdDev