基于模拟二次彩虹的水滴特征

光学与光子学期刊(英文) Pub Date : 2021-06-11 DOI:10.4236/OPJ.2021.116011

Wenting Wang, Jiayi Wang, Yide Zhang

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引用次数: 0

摘要

液滴的尺寸、尺寸分布、折射率和温度可以通过彩虹技术同时测量。本文利用广义Lorenz-Mie理论模拟了二次彩虹区球形液滴的彩虹散射图。为了在密度更大的液滴喷射中实现高空间分辨率，使用了聚焦高斯光束。对于液滴表征，研究了不同的反演算法，包括波谷（θmin1和θmin2）法和拐点拐点（θinf1和θinf2）法。对于波谷算法，折射率的绝对误差在−6.4×10−4和1.7×10−4.液滴半径的误差仅在−0.55%和1.77%之间。对于拐点-拐点算法，反向折射率的最大绝对误差小于−1.1×10−3。液滴半径的误差在-0.75%和5.67%之间。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Droplet Characterization Based on the Simulated Secondary Rainbows

The droplet size, size distribution, refractive index, and temperature can be measured simultaneously by the rainbow technique. In the present work, the rainbow scattering diagram for a spherical droplet in the secondary rainbow region is simulated by the use of the generalized Lorenz-Mie theory. For achieving high spatial resolution in denser droplet sprays, a focused Gaussian beam is used. For droplet characterization, different inversion algorithms are investigated, which includes trough-trough (θmin1 and θmin2) method and inflection-inflection (θinf1 and θinf2) method. For the trough-trough algorithm, the absolute error of the refractive index is between −6.4 × 10−4 and 1.7 × 10−4, and the error of the droplet radius is only between −0.55% and 1.77%. For the inflection-inflection algorithm, the maximum absolute error of the inverted refractive index is less than −1.1 × 10−3. The error of the droplet radius is between −0.75% and 5.67%.

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来源期刊

光学与光子学期刊(英文)

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发文量

431