Improved uniform error bounds on time-splitting methods for the long-time dynamics of the Dirac equation with small potentials

W. Bao, Yue Feng, Jia Yin
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引用次数: 11

Abstract

We establish improved uniform error bounds on time-splitting methods for the long-time dynamics of the Dirac equation with small electromagnetic potentials characterized by a dimensionless parameter $\varepsilon\in (0, 1]$ representing the amplitude of the potentials. We begin with a semi-discritization of the Dirac equation in time by a time-splitting method, and then followed by a full-discretization in space by the Fourier pseudospectral method. Employing the unitary flow property of the second-order time-splitting method for the Dirac equation, we prove uniform error bounds at $C(t)\tau^2$ and $C(t)(h^m+\tau^2)$ for the semi-discretization and full-discretization, respectively, for any time $t\in[0,T_\varepsilon]$ with $T_\varepsilon = T/\varepsilon$ for $T>0$, which are uniformly for $\varepsilon \in (0, 1]$, where $\tau$ is the time step, $h$ is the mesh size, $m\geq 2$ depends on the regularity of the solution, and $C(t) = C_0 + C_1\varepsilon t\le C_0+C_1T$ grows at most linearly with respect to $t$ with $C_0\ge0$ and $C_1>0$ two constants independent of $t$, $h$, $\tau$ and $\varepsilon$. Then by adopting the regularity compensation oscillation (RCO) technique which controls the high frequency modes by the regularity of the solution and low frequency modes by phase cancellation and energy method, we establish improved uniform error bounds at $O(\varepsilon\tau^2)$ and $O(h^m +\varepsilon\tau^2)$ for the semi-discretization and full-discretization, respectively, up to the long-time $T_\varepsilon$. Numerical results are reported to confirm our error bounds and to demonstrate that they are sharp. Comparisons on the accuracy of different time discretizations for the Dirac equation are also provided.
小势狄拉克方程长时间动力学时分裂方法的改进一致误差界
对于具有无量纲参数的小电磁势的狄拉克方程的长时间动力学,我们建立了改进的均匀误差界 $\varepsilon\in (0, 1]$ 表示电位的振幅。我们首先用时间分裂法对狄拉克方程进行时间上的半离散,然后用傅立叶伪谱法对狄拉克方程进行空间上的完全离散。利用狄拉克方程二阶时间分裂法的幺正流动性质,证明了在 $C(t)\tau^2$ 和 $C(t)(h^m+\tau^2)$ 分别对任意时刻的半离散化和完全离散化 $t\in[0,T_\varepsilon]$ 有 $T_\varepsilon = T/\varepsilon$ 为了 $T>0$,它们是一致的 $\varepsilon \in (0, 1]$,其中 $\tau$ 是时间步长, $h$ 为网孔大小, $m\geq 2$ 取决于溶液的规律性 $C(t) = C_0 + C_1\varepsilon t\le C_0+C_1T$ 最多线性增长 $t$ 有 $C_0\ge0$ 和 $C_1>0$ 两个常数独立于 $t$, $h$, $\tau$ 和 $\varepsilon$. 然后采用正则性补偿振荡(RCO)技术,通过解的正则性控制高频模态,通过相位抵消和能量法控制低频模态,建立了改进的均匀误差界 $O(\varepsilon\tau^2)$ 和 $O(h^m +\varepsilon\tau^2)$ 分别为半离散化和完全离散化,直至长时间 $T_\varepsilon$. 数值结果证实了我们的误差范围,并证明了它们是尖锐的。比较了不同时间离散化对狄拉克方程的精度。
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