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Autores principales: Saito, Manabu, Kurose, Ryoichi
Formato: Preprint
Publicado: 2024
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Acceso en línea:https://arxiv.org/abs/2403.13414
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author Saito, Manabu
Kurose, Ryoichi
author_facet Saito, Manabu
Kurose, Ryoichi
contents The computational cost of the boundary-condition-enforced immersed boundary method (IBM) increases in the order of $\mathcal{O}(N^2)$ as the number of Lagrangian points, $N$, increases. This is due to the time-consuming calculation of the correction operator in the diffuse-interface IBM to enforce the no-slip boundary condition. In this study, a computationally efficient IBM algorithm for an extruded wall geometry is developed, and the correction operator calculation is significantly simplified while maintaining the accuracy of the solution. This method takes advantage of the geometrical symmetricity to apply several matrix simplifications, which result in a huge increase in the computational efficiency and an improved scalability of $\mathcal{O}(max(N, N^2/r^2))$ ($r$: the number of grid points towards the extruded direction). The boundary-condition-enforced IBM for an extruded wall geometry is applicable to the numerical simulations of the flow around a wall surface that satisfies both (a) an extruded wall geometry that retains the same cross-section geometry and (b) an Eulerian grid that is either uniform or whose stretch rate towards the extruded direction is constant. As this type of geometry is commonly studied to investigate the fundamental behavior of the fluid, the presented algorithm has wide applications. Several calculations are conducted to demonstrate the higher computational efficiency of the presented algorithm compared with that of the original algorithm. The results show improvements in computational efficiency of up to 2,800 times for the correction operator calculation and 160 times for the overall IBM calculations compared with the original algorithm while retaining the computational accuracy.
format Preprint
id arxiv_https___arxiv_org_abs_2403_13414
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle A fast immersed boundary method for an extruded wall geometry
Saito, Manabu
Kurose, Ryoichi
Fluid Dynamics
The computational cost of the boundary-condition-enforced immersed boundary method (IBM) increases in the order of $\mathcal{O}(N^2)$ as the number of Lagrangian points, $N$, increases. This is due to the time-consuming calculation of the correction operator in the diffuse-interface IBM to enforce the no-slip boundary condition. In this study, a computationally efficient IBM algorithm for an extruded wall geometry is developed, and the correction operator calculation is significantly simplified while maintaining the accuracy of the solution. This method takes advantage of the geometrical symmetricity to apply several matrix simplifications, which result in a huge increase in the computational efficiency and an improved scalability of $\mathcal{O}(max(N, N^2/r^2))$ ($r$: the number of grid points towards the extruded direction). The boundary-condition-enforced IBM for an extruded wall geometry is applicable to the numerical simulations of the flow around a wall surface that satisfies both (a) an extruded wall geometry that retains the same cross-section geometry and (b) an Eulerian grid that is either uniform or whose stretch rate towards the extruded direction is constant. As this type of geometry is commonly studied to investigate the fundamental behavior of the fluid, the presented algorithm has wide applications. Several calculations are conducted to demonstrate the higher computational efficiency of the presented algorithm compared with that of the original algorithm. The results show improvements in computational efficiency of up to 2,800 times for the correction operator calculation and 160 times for the overall IBM calculations compared with the original algorithm while retaining the computational accuracy.
title A fast immersed boundary method for an extruded wall geometry
topic Fluid Dynamics
url https://arxiv.org/abs/2403.13414