What does this research mean for the field?

In simulations of dynamic wave propagation, chimera grids produce less numerical anisotropy than block-structured grids but require longer computational times. Novelty: ClaimNovelty.INCREMENTAL. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

This study aims to explore the impact of different computational grid structures on dynamic wave propagation in elastic materials.

synapse

⌘+K

synapse

⌘+K

April 10, 2026

Research into Approaches to Constructing Computational Grids of Cylindrical Shape Using Chimera and Multiblock Grids

Key Points

This study aims to explore the impact of different computational grid structures on dynamic wave propagation in elastic materials.
Used block-structured and chimera grids for modeling circles and cylinders.
Applied the grid-characteristic method for numerical solutions.
Investigated the effect of grid structure on numerical anisotropy.
Wave propagation results showed less directional dependence on chimera grids compared to block-structured grids.
Computation time was longer for chimera grids than for block-structured grids.

Abstract

The paper considers the construction of a computational grid for a cylinder for the dynamic wave propagation in linearly elastic media. The grid-characteristic method is used for numerical solution. Block-structured and chimera grids are used for a circle and a cylinder. The influence of the computational grid structure on numerical anisotropy was investigated. The calculations showed that the wave propagation result depends less on the direction on the chimera grid than on the block-structured grid, but the calculation time on the chimera grid is longer compared to the block-structured grid.

Bookmark

Research into Approaches to Constructing Computational Grids of Cylindrical Shape Using Chimera and Multiblock Grids

Key Points

Abstract

Cite This Study