Effects of sequential or simultaneous assimilation of observations and localization methods on the performance of the ensemble Kalman filter

Holland, Brian; Wang, Xuguang

doi:10.1002/qj.2006

Cited by 16 publications

(28 citation statements)

References 33 publications

(67 reference statements)

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“…2) EnKF assimilated observations sequentially whereas 3DEnsVar1way assimilated all observations simultaneously. A recent study by Holland and Wang (2013) suggested that the simultaneous/sequential assimilation in combination with different covariance localization methods could lead to performance differences in the ensemble-based data assimilation. 3) The ensemble smoother version of EnKF was adopted where effectively the fourdimensional ensemble covariance was utilized during the 6-h assimilation window.…”

Section: Gsi3dvarmentioning

confidence: 99%

“…The background ensemble covariance could also become more balanced due to the 6-h spinup during the forecast steps of the data assimilation cycling. On the other hand, the covariance localization applied to the ensemble covariance could degrade the balance (e.g., Lorenc 2003;Kepert 2009;Holland and Wang 2013). The impact of the TLNMC on the ensemble increment was therefore investigated.…”

Section: Impact Of Tlnmc Balance Constraintmentioning

confidence: 99%

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GSI 3DVar-Based Ensemble–Variational Hybrid Data Assimilation for NCEP Global Forecast System: Single-Resolution Experiments

Wang

Parrish

Kleist

et al. 2013

Monthly Weather Review

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262

234

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An ensemble Kalman filter-variational hybrid data assimilation system based on the gridpoint statistical interpolation (GSI) three-dimensional variational data assimilation (3DVar) system was developed. The performance of the system was investigated using the National Centers for Environmental Prediction (NCEP) Global Forecast System model. Experiments covered a 6-week Northern Hemisphere winter period. Both the control and ensemble forecasts were run at the same, reduced resolution. Operational conventional and satellite observations along with an 80-member ensemble were used. Various configurations of the system including oneor two-way couplings, with zero or nonzero weights on the static covariance, were intercompared and compared with the GSI 3DVar system. It was found that the hybrid system produced more skillful forecasts than the GSI 3DVar system. The inclusion of a static component in the background-error covariance and recentering the analysis ensemble around the variational analysis did not improve the forecast skill beyond the one-way coupled system with zero weights on the static covariance. The one-way coupled system with zero static covariances produced more skillful wind forecasts averaged over the globe than the EnKF at the 1-5-day lead times and more skillful temperature forecasts than the EnKF at the 5-day lead time. Sensitivity tests indicated that the difference may be due to the use of the tangent linear normal mode constraint in the variational system. For the first outer loop, the hybrid system showed a slightly slower (faster) convergence rate at early (later) iterations than the GSI 3DVar system. For the second outer loop, the hybrid system showed a faster convergence.

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Section: Gsi3dvarmentioning

confidence: 99%

Section: Impact Of Tlnmc Balance Constraintmentioning

confidence: 99%

GSI 3DVar-Based Ensemble–Variational Hybrid Data Assimilation for NCEP Global Forecast System: Single-Resolution Experiments

Wang

Parrish

Kleist

et al. 2013

Monthly Weather Review

Self Cite

262

234

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“…Whitaker et al (2008) also compared the assimilation performance of the EnSRF with the LETKF when applied with a global atmospheric model and found only small differences. Similarly, Holland and Wang (2013) compared the LETKF with the EnSRF without particular observation ordering for the assimilation with a simplified atmospheric model. They found only small differences in the state estimates with slightly smaller errors in the LETKF estimates.…”

Section: Introductionmentioning

confidence: 99%

On Serial Observation Processing in Localized Ensemble Kalman Filters

Nerger

2015

Monthly Weather Review

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Ensemble square root filters can either assimilate all observations that are available at a given time at once, or assimilate the observations in batches or one at a time. For large-scale models, the filters are typically applied with a localized analysis step. This study demonstrates that the interaction of serial observation processing and localization can destabilize the analysis process, and it examines under which conditions the instability becomes significant. The instability results from a repeated inconsistent update of the state error covariance matrix that is caused by the localization. The inconsistency is present in all ensemble Kalman filters, except for the classical ensemble Kalman filter with perturbed observations. With serial observation processing, its effect is small in cases when the assimilation changes the ensemble of model states only slightly. However, when the assimilation has a strong effect on the state estimates, the interaction of localization and serial observation processing can significantly deteriorate the filter performance. In realistic large-scale applications, when the assimilation changes the states only slightly and when the distribution of the observations is irregular and changing over time, the instability is likely not significant.

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“…Additional efforts include the successive covariance localization (Zhang et al 2009) and the multi-scale localization approach Kondo et al 2013). More information about comparing simultaneous and sequential assimilation can be found in (Holland et al 2013). …”

Section: Discussionmentioning

confidence: 99%

Optimal Localization for Ensemble Kalman Filter Systems

Periáñez

Reich

Potthast

2014

Journal of the Meteorological Society of Japan

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In ensemble Kalman filter methods, localization is applied for both avoiding the spurious correlations of distant observations and increasing the effective size of the ensemble space. The procedure is essential in order to provide quality assimilation in large systems; however a severe localization can cause imbalances that impact negatively on the accuracy of the analysis.We want to understand the fundamental properties of localized ensemble methods and to investigate an optimal localization expression which minimizes the analysis error. The novel analytical expression derived in this work depends on the observation error, the density of measurements, and the approximation error, i.e., the error that comes from working in the ensemble space. The mathematical results are tested with two numerical simulations using a toy model. We demonstrate that observations with different observation error or density need different localization length scales.

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Effects of sequential or simultaneous assimilation of observations and localization methods on the performance of the ensemble Kalman filter

Cited by 16 publications

References 33 publications

GSI 3DVar-Based Ensemble–Variational Hybrid Data Assimilation for NCEP Global Forecast System: Single-Resolution Experiments

GSI 3DVar-Based Ensemble–Variational Hybrid Data Assimilation for NCEP Global Forecast System: Single-Resolution Experiments

On Serial Observation Processing in Localized Ensemble Kalman Filters

Optimal Localization for Ensemble Kalman Filter Systems

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