通过 OptiX 利用光线追踪技术，在 GPU 上计算三维环境中粒子与截止点的相互作用

arXiv - CS - Graphics Pub Date : 2024-08-26 DOI:arxiv-2408.14247

Bérenger Bramas

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引用次数: 0

摘要

在图形处理器（GPU）上进行计算已成为科学计算的标准，在许多计算方法中，GPU 的性能都比传统 CPU 高出许多。由于 GPU 最初是为三维渲染而设计的，因此它仍具有一些科学计算中没有使用的功能。其中，光线追踪是一项用于渲染 3D 场景的强大技术。在本文中，我们提出利用光线追踪技术来计算粒子在三维环境中与截止距离的相互作用。我们描述了为每个粒子寻找相互作用列表的算法技巧和几何模式。这种方法允许我们以粒子数量的准线性复杂度计算相互作用，而无需构建单元网格或显式 kd 树。我们比较了我们的方法和基于单元网格的经典方法的性能，结果表明，目前，我们的方法在大多数情况下速度较慢，但可以为未来的方法铺平道路。

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Exploiting ray tracing technology through OptiX to compute particle interactions with cutoff in a 3D environment on GPU

Computing on graphics processing units (GPUs) has become standard in scientific computing, allowing for incredible performance gains over classical CPUs for many computational methods. As GPUs were originally designed for 3D rendering, they still have several features for that purpose that are not used in scientific computing. Among them, ray tracing is a powerful technology used to render 3D scenes. In this paper, we propose exploiting ray tracing technology to compute particle interactions with a cutoff distance in a 3D environment. We describe algorithmic tricks and geometric patterns to find the interaction lists for each particle. This approach allows us to compute interactions with quasi-linear complexity in the number of particles without building a grid of cells or an explicit kd-tree. We compare the performance of our approach with a classical approach based on a grid of cells and show that, currently, ours is slower in most cases but could pave the way for future methods.

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arXiv - CS - Graphics

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