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Hauptverfasser: Wang, Binhan, Sun, Peng, Wang, Gao, Liang, Haijian, Guan, Jinge, Dong, Xiaohang, Du, Xiuhao, Liu, Ruichen
Format: Preprint
Veröffentlicht: 2025
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Online-Zugang:https://arxiv.org/abs/2507.23189
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author Wang, Binhan
Sun, Peng
Wang, Gao
Liang, Haijian
Guan, Jinge
Dong, Xiaohang
Du, Xiuhao
Liu, Ruichen
author_facet Wang, Binhan
Sun, Peng
Wang, Gao
Liang, Haijian
Guan, Jinge
Dong, Xiaohang
Du, Xiuhao
Liu, Ruichen
contents Addressing the problem of photon multiple scattering interference caused by turbid media in optical measurements, biomedical imaging, environmental monitoring and other fields, existing Monte Carlo light scattering simulations widely adopt the Henyey-Greenstein (H-G) phase function approximation model. However, traditional computational resource limitations and high numerical complexity have constrained the application of precise scattering models. Moreover, the single-parameter anisotropy factor assumption neglects higher-order scattering effects and backscattering intensity, failing to accurately characterize the multi-order scattering properties of complex media. To address these issues, we propose a GPU-accelerated Monte Carlo-Rigorous Mie scattering transport model for complex scattering environments. The model employs rigorous Mie scattering theory to replace the H-G approximation, achieving efficient parallel processing of phase function sampling and complex scattering processes through pre-computed cumulative distribution function optimization and deep integration with CUDA parallel architecture. To validate the model accuracy, a standard scattering experimental platform based on 5μm polystyrene microspheres was established, with multiple optical depth experimental conditions designed, and spatial registration techniques employed to achieve precise alignment between simulation and experimental images. The research results quantitatively demonstrate the systematic accuracy advantages of rigorous Mie scattering phase functions over H-G approximation in simulating lateral scattering light intensity distributions, providing reliable theoretical foundations and technical support for high-precision optical applications in complex scattering environments.
format Preprint
id arxiv_https___arxiv_org_abs_2507_23189
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle GPU-Accelerated Monte Carlo Simulation and Experimental Study of Radiative Transfer in Multiple Scattering Media
Wang, Binhan
Sun, Peng
Wang, Gao
Liang, Haijian
Guan, Jinge
Dong, Xiaohang
Du, Xiuhao
Liu, Ruichen
Optics
Addressing the problem of photon multiple scattering interference caused by turbid media in optical measurements, biomedical imaging, environmental monitoring and other fields, existing Monte Carlo light scattering simulations widely adopt the Henyey-Greenstein (H-G) phase function approximation model. However, traditional computational resource limitations and high numerical complexity have constrained the application of precise scattering models. Moreover, the single-parameter anisotropy factor assumption neglects higher-order scattering effects and backscattering intensity, failing to accurately characterize the multi-order scattering properties of complex media. To address these issues, we propose a GPU-accelerated Monte Carlo-Rigorous Mie scattering transport model for complex scattering environments. The model employs rigorous Mie scattering theory to replace the H-G approximation, achieving efficient parallel processing of phase function sampling and complex scattering processes through pre-computed cumulative distribution function optimization and deep integration with CUDA parallel architecture. To validate the model accuracy, a standard scattering experimental platform based on 5μm polystyrene microspheres was established, with multiple optical depth experimental conditions designed, and spatial registration techniques employed to achieve precise alignment between simulation and experimental images. The research results quantitatively demonstrate the systematic accuracy advantages of rigorous Mie scattering phase functions over H-G approximation in simulating lateral scattering light intensity distributions, providing reliable theoretical foundations and technical support for high-precision optical applications in complex scattering environments.
title GPU-Accelerated Monte Carlo Simulation and Experimental Study of Radiative Transfer in Multiple Scattering Media
topic Optics
url https://arxiv.org/abs/2507.23189