| 게재연도 | 2025 |
|---|---|
| 논문집명 | Journal of the Korean Society for Industrial and Applied Mathematics |
| 논문명 | BOUNDARY-AWARE THOMAS SOLVERS FOR 3D DIFFUSION: IMPLEMENTATION AND ANALYSIS |
| 저자 | Youngjin Hwang, Hyundong Kim, HyunHo Shin |
| 구분 | 국내저널 |
| 요약 | Tridiagonal linear systems arise ubiquitously in finite-difference discretizations of diffusion-type partial differential equations (PDEs). The Thomas algorithm is a workhorse direct solver for such systems and is widely embedded in time-integration frameworks. Bound-ary conditions, however, can alter the algebraic structure significantly. In particular, periodic boundaries induce cyclic couplings that violate strict tridiagonality. Leveraging rank-one cor-rections via the Sherman–Morrison identity, we extend a two-dimensional boundary-treatment strategy to three dimensions within an operator-splitting framework. We detail implementations for periodic, Dirichlet, and Neumann conditions, and assess accuracy and stability through heat- equation benchmarks and Allen–Cahn dynamics. The results furnish a practical blueprint for robust boundary enforcement in Thomas-based solvers for 3D time-dependent PDEs. |
| 핵심어 | Thomas algorithm, Dirichlet boundary, Neumann boundary, periodic boundary. |