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| Main Authors: | , |
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| Format: | Preprint |
| Published: |
1999
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| Subjects: | |
| Online Access: | https://arxiv.org/abs/math/9908051 |
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Table of Contents:
- This article addresses some asymptotic and numerical issues related to the solution of Burgers' equation, $-εu_{xx} + u_t + u u_x = 0$ on $(-1,1)$, subject to the boundary conditions $u(-1) = 1 + δ$, $u(1) = -1$, and its generalization to two dimensions, $-εΔu + u_t + u u_x + u u_y = 0$ on $(-1,1) \times (-π, π)$, subject to the boundary conditions $u|_{x=1} = 1 + δ$, $u|_{x=-1} = -1$, with $2π$ periodicity in $y$. The perturbation parameters $δ$ and $ε$ are arbitrarily small positive and independent; when they approach 0, they satisfy the asymptotic order relation $δ= O_s ({\rm e}^{-a/ε})$ for some constant $a \in (0,1)$. The solutions of these convection-dominated viscous conservation laws exhibit a transition layer in the interior of the domain, whose position as $t\to\infty$ is supersensitive to the boundary perturbation. Algorithms are presented for the computation of the position of the transition layer at steady state. The algorithms generalize to viscous conservation laws with a convex nonlinearity and are scalable in a parallel computing environment.