Mueller matrix calculation using Electric field Monte Carlo simulation

Ying-Ju Tsai; Sunil Vyas; Yuan Luo; Kung-Bin Sung

doi:10.1117/12.2615860

27 October 2021 Mueller matrix calculation using Electric field Monte Carlo simulation

Ying-Ju Tsai, Sunil Vyas, Yuan Luo, Kung-Bin Sung

Proceedings Volume 11925, Biomedical Imaging and Sensing Conference 2021; 119251A (2021) https://doi.org/10.1117/12.2615860
Event: SPIE Technologies and Applications of Structured Light, 2021, Online, Japan

Abstract

Understanding the propagating of light in biological tissues have long been an important issue. For this purpose, modeling scattering of light from laser radiation into turbid media has been studied. One of the common modeling tools is Monte Carlo simulation, and Mueller matrix method is a commonly used technique to study birefringence and depolarization properties of biological samples. Based on electric field Monte Carlo simulation in this paper, we present backscattering Muller matrix calculations for different size of particles and performed comparative studies. Our results may find important applications in laser tissue interaction.

Citation Download Citation

Ying-Ju Tsai, Sunil Vyas, Yuan Luo, and Kung-Bin Sung "Mueller matrix calculation using Electric field Monte Carlo simulation", Proc. SPIE 11925, Biomedical Imaging and Sensing Conference 2021, 119251A (27 October 2021); https://doi.org/10.1117/12.2615860

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