全息粒子图像测速中噪声抑制和像差补偿的研究进展

K. F. Tamrin, B. Rahmatullah
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摘要

摘要在工程和医学领域的广泛应用中,理解流体的三维流动行为对于提高性能和效率至关重要。全息粒子图像测速(HPIV)是一种真正的三维三分量测量技术,是探测和表征复杂流动动力学的潜在工具。该技术依赖于小种子粒子散射的相干光,这些粒子被假定忠实地跟随流,以便随后重建相同的事件。然而,从这些粒子图像中提取有用的三维位移数据通常会受到光学系统固有的噪声和像差的影响。噪声和像差一直被认为是HPIV获得准确的粒子图像识别及其相应的三维位置的主要障碍。噪声的主要来源包括零级衍射、散焦颗粒、虚像和乳化液颗粒散射。噪声抑制是保证粒子图像与背景噪声清晰区分的关键,而像差补偿则形成高完整性的粒子图像。本文回顾了为解决这些问题而提出的一些HPIV配置,总结了主要发现并概述了后续研究的基础。
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A review on noise suppression and aberration compensation in holographic particle image velocimetry
Abstract Understanding three-dimensional (3D) fluid flow behaviour is undeniably crucial in improving performance and efficiency in a wide range of applications in engineering and medical fields. Holographic particle image velocimetry (HPIV) is a potential tool to probe and characterize complex flow dynamics since it is a truly three-dimensional three-component measurement technique. The technique relies on the coherent light scattered by small seeding particles that are assumed to faithfully follow the flow for subsequent reconstruction of the same the event afterward. However, extraction of useful 3D displacement data from these particle images is usually aggravated by noise and aberration which are inherent within the optical system. Noise and aberration have been considered as major hurdles in HPIV in obtaining accurate particle image identification and its corresponding 3D position. Major contributions to noise include zero-order diffraction, out-of-focus particles, virtual image and emulsion grain scattering. Noise suppression is crucial to ensure that particle image can be distinctly differentiated from background noise while aberration compensation forms particle image with high integrity. This paper reviews a number of HPIV configurations that have been proposed to address these issues, summarizes the key findings and outlines a basis for follow-on research.
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Cogent Physics
Cogent Physics PHYSICS, MULTIDISCIPLINARY-
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