Irreversible drift-diffusion processes are very common in biochemical reactions. They have a non-equilibrium stationary state (invariant measure) which does not satisfy detailed balance. For the corresponding Fokker-Planck equation on a closed manifold, using Voronoi tessellation, we propose two upwind finite volume schemes with or without the information of the invariant measure. Both schemes possess stochastic $Q$-matrix structures and can be decomposed as a gradient flow part and a Hamiltonian flow part, enabling us to prove unconditional stability, ergodicity and error estimates. Based on the two upwind schemes, several numerical examples - including sampling accelerated by a mixture flow, image transformations and simulations for stochastic model of chaotic system - are conducted. These two structure-preserving schemes also give a natural random walk approximation for a generic irreversible drift-diffusion process on a manifold. This makes them suitable for adapting to manifold-related computations that arise from high-dimensional molecular dynamics simulations.
翻译:不可逆的漂移扩散过程在生化反应中非常普遍。它们具有不满足详细平衡的非平衡稳定状态(不变测度)。对于封闭流形上对应的Fokker-Planck方程,我们使用Voronoi图划分,提出了两种具有或不具有不变测度信息的上风有限体积格式。这两种格式均具有随机Q矩阵结构,并且可分解为梯度流部分和Hamiltonian流部分,使我们能够证明其无条件稳定性,遍历性和误差估计。基于这两种上风格式,进行了几个数值实例研究,包括通过混合流加速的采样,图像变换和混沌系统的随机模型的模拟。这两种结构保持的格式还为一般不可逆的流形上的漂移扩散过程提供了自然的随机漫步逼近。这使它们适用于高维分子动力学模拟中出现的与流形相关的计算。