Dynamical Tensor Train Approximation for Kinetic Equations
This work provides a more efficient numerical method for researchers solving kinetic equations, which are computationally expensive due to high dimensionality.
The authors developed a dynamical low-rank method using tensor-train format for solving high-dimensional kinetic equations, achieving substantial reductions in memory and computational cost compared to standard approaches.
The numerical solution of kinetic equations is challenging due to the high dimensionality of the underlying phase space. In this paper, we develop a dynamical low-rank method based on the projector-splitting integrator in tensor-train (TT) format. The key idea is to discretize the three-dimensional velocity variable using tensor trains while treating the spatial variable as a parameter, thereby exploiting the low-rank structure of the distribution function in velocity space. In contrast to the standard step-and-truncate approach, this method updates the tensor cores through a sweeping procedure, allowing the use of relatively small TT-ranks and leading to substantial reductions in memory usage and computational cost. We demonstrate the effectiveness of the proposed approach on several representative kinetic equations.