Numerical Complete Solution for Random Genetic Drift by Energetic Variational Approach
Abstract
In this paper, we focus on numerical solutions for random genetic drift problem, which is governed by a degenerated convection-dominated parabolic equation. Due to the fixation phenomenon of genes, Dirac delta singularities will develop at boundary points as time evolves. Based on an energetic variational approach (EnVarA), a balance between the maximal dissipation principle (MDP) and least action principle (LAP), we obtain the trajectory equation. In turn, a numerical scheme is proposed using a convex splitting technique, with the unique solvability (on a convex set) and the energy decay property (in time) justified at a theoretical level. Numerical examples are presented for cases of pure drift and drift with semi-selection. The remarkable advantage of this method is its ability to catch the Dirac delta singularity close to machine precision over any equidistant grid.
Keywords
Cite
@article{arxiv.1803.09436,
title = {Numerical Complete Solution for Random Genetic Drift by Energetic Variational Approach},
author = {Chenghua Duan and Chun Liu and Cheng Wang and Xingye Yue},
journal= {arXiv preprint arXiv:1803.09436},
year = {2018}
}
Comments
22 pages, 11 figures, 2 tables