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Hauptverfasser: Yan, Shijie, Dwyer, Douglas, Kaeli, David R., Fang, Qianqian
Format: Preprint
Veröffentlicht: 2025
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2511.22779
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author Yan, Shijie
Dwyer, Douglas
Kaeli, David R.
Fang, Qianqian
author_facet Yan, Shijie
Dwyer, Douglas
Kaeli, David R.
Fang, Qianqian
contents Significance: Monte Carlo (MC) methods are the gold-standard for modeling light-tissue interactions due to their accuracy. Mesh-based MC (MMC) offers enhanced precision for complex tissue structures using tetrahedral mesh models. Despite significant speedups achieved on graphics processing units (GPUs), MMC performance remains hindered by the computational cost of frequent ray-boundary intersection tests. Aim: We propose a highly accelerated MMC algorithm, RT-MMC, that leverages the hardware-accelerated ray traversal and intersection capabilities of ray-tracing cores (RT-cores) on modern GPUs. Approach: Implemented using NVIDIA's OptiX platform, RT-MMC extends graphics ray-tracing pipelines towards volumetric ray-tracing in turbid media, eliminating the need for challenging tetrahedral mesh generation while delivering significant speed improvements through hardware acceleration. It also intrinsically supports wide-field sources without complex mesh retesselation. Results: RT-MMC demonstrates excellent agreement with traditional software-ray-tracing MMC algorithms while achieving 1.5x to 4.5x speedups across multiple GPU architectures. These performance gains significantly enhance the practicality of MMC for routine simulations. Conclusion: Migration from software- to hardware-based ray-tracing not only greatly simplifies MMC simulation workflows, but also results in significant speedups that are expected to increase further as ray-tracing hardware rapidly gains adoption. Adoption of graphics ray-tracing pipelines in quantitative MMC simulations enables leveraging of emerging hardware resources and benefits a wide range of biophotonics applications.
format Preprint
id arxiv_https___arxiv_org_abs_2511_22779
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Accelerating mesh-based Monte Carlo simulations using contemporary graphics ray-tracing hardware
Yan, Shijie
Dwyer, Douglas
Kaeli, David R.
Fang, Qianqian
Distributed, Parallel, and Cluster Computing
Medical Physics
Optics
Significance: Monte Carlo (MC) methods are the gold-standard for modeling light-tissue interactions due to their accuracy. Mesh-based MC (MMC) offers enhanced precision for complex tissue structures using tetrahedral mesh models. Despite significant speedups achieved on graphics processing units (GPUs), MMC performance remains hindered by the computational cost of frequent ray-boundary intersection tests. Aim: We propose a highly accelerated MMC algorithm, RT-MMC, that leverages the hardware-accelerated ray traversal and intersection capabilities of ray-tracing cores (RT-cores) on modern GPUs. Approach: Implemented using NVIDIA's OptiX platform, RT-MMC extends graphics ray-tracing pipelines towards volumetric ray-tracing in turbid media, eliminating the need for challenging tetrahedral mesh generation while delivering significant speed improvements through hardware acceleration. It also intrinsically supports wide-field sources without complex mesh retesselation. Results: RT-MMC demonstrates excellent agreement with traditional software-ray-tracing MMC algorithms while achieving 1.5x to 4.5x speedups across multiple GPU architectures. These performance gains significantly enhance the practicality of MMC for routine simulations. Conclusion: Migration from software- to hardware-based ray-tracing not only greatly simplifies MMC simulation workflows, but also results in significant speedups that are expected to increase further as ray-tracing hardware rapidly gains adoption. Adoption of graphics ray-tracing pipelines in quantitative MMC simulations enables leveraging of emerging hardware resources and benefits a wide range of biophotonics applications.
title Accelerating mesh-based Monte Carlo simulations using contemporary graphics ray-tracing hardware
topic Distributed, Parallel, and Cluster Computing
Medical Physics
Optics
url https://arxiv.org/abs/2511.22779