A New Approach for 4DVar Data Assimilation

TL;DR

This paper introduces an innovative integral correcting 4DVar (i4DVar) method that simultaneously corrects all errors in data assimilation, significantly improving accuracy over existing approaches with practical advantages for scientific and engineering applications.

Contribution

The paper develops a novel i4DVar approach that treats all errors collectively and corrects them at each step using an exponential decay function, enhancing model error correction.

Findings

i4DVar outperforms existing 4DVar methods in Lorenz model simulations.

The approach effectively corrects model errors and reduces uncertainty.

It is easy to implement and suitable for big data applications.

Abstract

Four-dimensional variational data assimilation (4DVar) has become an increasingly important tool in data science with wide applications in many engineering and scientific fields such as geoscience1-12, biology13 and the financial industry14. The 4DVar seeks a solution that minimizes the departure from the background field and the mismatch between the forecast trajectory and the observations within an assimilation window. The current state-of-the-art 4DVar offers only two choices by using different forms of the forecast model: the strong- and weak-constrained 4DVar approaches15-16. The former ignores the model error and only corrects the initial condition error at the expense of reduced accuracy; while the latter accounts for both the initial and model errors and corrects them separately, which increases computational costs and uncertainty. To overcome these limitations, here we develop an integral correcting 4DVar (i4DVar) approach by treating all errors as a whole and correcting them simultaneously and indiscriminately. To achieve that, a novel exponentially decaying function is proposed to characterize the error evolution and correct it at each time step in the i4DVar. As a result, the i4DVar greatly enhances the capability of the strong-constrained 4DVar for correcting the model error while also overcomes the limitation of the weak-constrained 4DVar for being prohibitively expensive with added uncertainty. Numerical experiments with the Lorenz model show that the i4DVar significantly outperforms the existing 4DVar approaches. It has the potential to be applied in many scientific and engineering fields and industrial sectors in the big data era because of its ease of implementation and superior performance.