scholarly journals Data assimilation for moving mesh methods with an application to ice sheet modelling

2016 ◽  
Author(s):  
Bertrand Bonan ◽  
Nancy K. Nichols ◽  
Michael J. Baines ◽  
Dale Partridge
Keyword(s):  
Data Assimilation ◽  
Nonlinear Dynamical Systems ◽  
Ice Sheet ◽  
Ensemble Methods ◽  
Moving Mesh ◽  
Nonlinear Dynamical ◽  
Evolving Systems ◽  
Surface Ice ◽  
Moving Mesh Methods ◽  
Variational Context

Abstract. We develop data assimilation techniques for nonlinear dynamical systems modelled by moving mesh methods. Such techniques are valuable for explicitly tracking interfaces and boundaries in evolving systems. The unique aspect of these assimilation techniques is that both the states of the system and the positions of the mesh points are updated simultaneously using physical observations. Covariances between states and mesh points are generated either by a correlation structure function in a variational context or by ensemble methods. The application of the techniques is demonstrated on a one-dimensional model of a grounded shallow ice sheet. It is shown, using observations of surface elevation and/or surface ice velocities, that the techniques predict the evolution of the ice sheet margin and the ice thickness accurately and efficiently. This approach also allows the straightforward assimilation of observations of the position of the ice sheet margin.

scholarly journals Data assimilation for moving mesh methods with an application to ice sheet modelling

2017 ◽  
Vol 24 (3) ◽  
pp. 515-534 ◽  
Author(s):  
Bertrand Bonan ◽  
Nancy K. Nichols ◽  
Michael J. Baines ◽  
Dale Partridge
Keyword(s):  
Data Assimilation ◽  
Ice Sheet ◽  
Ensemble Methods ◽  
Moving Mesh ◽  
Linear Dynamical Systems ◽  
One Dimensional ◽  
Evolving Systems ◽  
Surface Ice ◽  
Moving Mesh Methods ◽  
Variational Context

Abstract. We develop data assimilation techniques for non-linear dynamical systems modelled by moving mesh methods. Such techniques are valuable for explicitly tracking interfaces and boundaries in evolving systems. The unique aspect of these assimilation techniques is that both the states of the system and the positions of the mesh points are updated simultaneously using physical observations. Covariances between states and mesh points are generated either by a correlation structure function in a variational context or by ensemble methods. The application of the techniques is demonstrated on a one-dimensional model of a grounded shallow ice sheet. It is shown, using observations of surface elevation and/or surface ice velocities, that the techniques predict the evolution of the ice sheet margin and the ice thickness accurately and efficiently. This approach also allows the straightforward assimilation of observations of the position of the ice sheet margin.

scholarly journals Ensemble Riemannian Data Assimilation: Towards High-dimensional Implementation

2021 ◽  
Author(s):  
Sagar Kumar Tamang ◽  
Ardeshir Ebtehaj ◽  
Peter Jan van Leeuwen ◽  
Gilad Lerman ◽  
Efi Foufoula-Georgiou
Keyword(s):  
Dynamical Systems ◽  
Data Assimilation ◽  
Mean Squared Error ◽  
Likelihood Function ◽  
Nonlinear Dynamical Systems ◽  
High Dimensional ◽  
Nonlinear Dynamical ◽  
Systematic Biases ◽  
Background Probability ◽  
Lorenz 96

Abstract. This paper presents the results of the Ensemble Riemannian Data Assimilation for relatively high-dimensional nonlinear dynamical systems, focusing on the chaotic Lorenz-96 model and a two-layer quasi-geostrophic (QG) model of atmospheric circulation. The analysis state in this approach is inferred from a joint distribution that optimally couples the background probability distribution and the likelihood function, enabling formal treatment of systematic biases without any Gaussian assumptions. Despite the risk of the curse of dimensionality in the computation of the coupling distribution, comparisons with the classic implementation of the particle filter and the stochastic ensemble Kalman filter demonstrate that with the same ensemble size, the presented methodology could improve the predictability of dynamical systems. In particular, under systematic errors, the root mean squared error of the analysis state can be reduced by 20 % (30 %) in Lorenz-96 (QG) model.

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