A new statistical correction strategy to improve long‐term dynamical prediction

In this study, a new statistical strategy to improve the long‐term prediction skill of a numerical model was developed. This new strategy begins by finding the major principal time series (PTs) in the observations using the self‐organizing map (SOM) method. Next, values at the model grid points that...

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Bibliographic Details
Published in:International journal of climatology 2019-03, Vol.39 (4), p.2173-2185
Main Authors: Lee, Joonlee, Ahn, Joong‐Bae
Format: Article
Language:English
Subjects:
bias correction
Classification
Coefficients
Correlation
Correlation coefficient
Correlation coefficients
coupled general circulation model
Data analysis
Data processing
Educational institutions
Empirical analysis
False alarms
General circulation models
Lead time
Mathematical models
model output statistic
Numerical models
Orthogonal functions
Sea surface
Sea surface temperature
Self‐organizing map method
Statistical correlation
Statistical methods
Statistical prediction
Statistics
Strategy
Surface temperature
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Summary:In this study, a new statistical strategy to improve the long‐term prediction skill of a numerical model was developed. This new strategy begins by finding the major principal time series (PTs) in the observations using the self‐organizing map (SOM) method. Next, values at the model grid points that are highly correlated with the observational PTs for each ensemble member (EM) are combined to yield a modelled PT. Finally, the model prediction is corrected using the model PTs from the previous step. As the predictors for correction are objectively selected from among the signals found in model prediction, automatically considering their statistical correlation with predictands, the correction strategy is relatively free from the problem of selecting the proper predictor compared to conventional statistical correction methods. In addition, SOM shows a better performance in classifying nonlinear complex patterns than conventional data analysis methods, while both SOM and conventional methods such as the empirical orthogonal function show a comparable performance when classifying linear patterns. The new strategy is applied to the 12‐month‐lead sea surface temperatures hindcasted by the Pusan National University coupled general circulation model. After correction using the new strategy, temporal correlation coefficients and the hit rate are increased while normalized root mean square errors and the false alarm rate are decreased for each season and each lead time. The correction becomes more effective as the lead time increases. In particular, this correction effect is large over the region where the prediction skill without correction is apparently low, which implies that the biases leading to poor prediction skills are effectively reduced by the new strategy. Additionally, the prediction skill is steadily improved for all lead times as the number of EMs is increased, whereas it reaches a plateau when the number of neurons in the output layer of the SOM method exceeds a certain threshold. Schematic diagram of the new correction strategy using SOM.
ISSN:0899-8418
1097-0088
DOI:10.1002/joc.5943