Extended Dynamic Mode Decomposition for Inhomogeneous Problems

04/13/2020

∙

Dynamic mode decomposition (DMD) is a powerful data-driven technique for construction of reduced-order models of complex dynamical systems. Multiple numerical tests have demonstrated the accuracy and efficiency of DMD, but mostly for systems described by partial differential equations (PDEs) with homogeneous boundary conditions. We propose an extended dynamic mode decomposition (xDMD) approach to cope with the potential unknown sources/sinks in PDEs. Motivated by similar ideas in deep neural networks, we equipped our xDMD with two new features. First, it has a bias term, which accounts for inhomogeneity of PDEs and/or boundary conditions. Second, instead of learning a flow map, xDMD learns the residual increment by subtracting the identity operator. Our theoretical error analysis demonstrates the improved accuracy of xDMD relative to standard DMD. Several numerical examples are presented to illustrate this result.

READ FULL TEXT

Extended Dynamic Mode Decomposition for Inhomogeneous Problems

A Splitting Approach to Dynamic Mode Decomposition of Nonlinear Systems

A Deep Learning-based Collocation Method for Modeling Unknown PDEs from Sparse Observation

Render unto Numerics : Orthogonal Polynomial Neural Operator for PDEs with Non-periodic Boundary Conditions

Diffusion Maps for Embedded Manifolds with Boundary with Applications to PDEs

Dynamic Mode Decomposition for Construction of Reduced-Order Models of Hyperbolic Problems with Shocks

Extension of Dynamic Mode Decomposition for dynamic systems with incomplete information based on t-model of optimal prediction

Temporal Forward-Backward Consistency, Not Residual Error, Measures the Prediction Accuracy of Extended Dynamic Mode Decomposition

Extended Dynamic Mode Decomposition for Inhomogeneous Problems

Related Research

A Splitting Approach to Dynamic Mode Decomposition of Nonlinear Systems

A Deep Learning-based Collocation Method for Modeling Unknown PDEs from Sparse Observation

Render unto Numerics : Orthogonal Polynomial Neural Operator for PDEs with Non-periodic Boundary Conditions

Diffusion Maps for Embedded Manifolds with Boundary with Applications to PDEs

Dynamic Mode Decomposition for Construction of Reduced-Order Models of Hyperbolic Problems with Shocks

Extension of Dynamic Mode Decomposition for dynamic systems with incomplete information based on t-model of optimal prediction

Temporal Forward-Backward Consistency, Not Residual Error, Measures the Prediction Accuracy of Extended Dynamic Mode Decomposition