光学相干层析成像的统一k空间理论

IF 25.2 1区物理与天体物理 Q1 OPTICS

Advances in Optics and Photonics Pub Date : 2020-12-09 DOI:10.1364/AOP.417102

Kevin C Zhou, Ruobing Qian, Al-Hafeez Z. Dhalla, Sina Farsiu, J. Izatt

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引用次数: 9

摘要

我们提出了光学相干断层扫描（OCT）的一般理论，该理论在通用的三维k空间框架下综合了OCT的基本概念和实现。该分析的核心是傅里叶衍射定理，该定理将样品和平面波之间的相干相互作用与样品的三维k空间表示中的埃瓦尔德球联系起来。虽然在k空间中通常只分析OCT的轴向尺寸，但我们表明，采用完全3D的k空间形式可以解释OCT的几乎所有基本物理现象或特性，包括对比度机制、分辨率、色散、像差、有限焦深和散斑。该理论还结合了衍射层析成像、共焦显微镜、点扫描OCT、线场OCT、全场OCT、贝塞尔光束OCT、透照OCT、干涉合成孔径显微镜（ISAM）和光学相干折射层析成像（OCRT）等。我们的统一理论不仅使我们能够清楚地理解现有的技术，而且为继续推进OCT领域提出了新的研究方向。

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Unified k-space theory of optical coherence tomography

We present a general theory of optical coherence tomography (OCT), which synthesizes the fundamental concepts and implementations of OCT under a common 3D k-space framework. At the heart of this analysis is the Fourier diffraction theorem, which relates the coherent interaction between a sample and plane wave to the Ewald sphere in the 3D k-space representation of the sample. While only the axial dimension of OCT is typically analyzed in k-space, we show that embracing a fully 3D k-space formalism allows explanation of nearly every fundamental physical phenomenon or property of OCT, including contrast mechanism, resolution, dispersion, aberration, limited depth of focus, and speckle. The theory also unifies diffraction tomography, confocal microscopy, point-scanning OCT, line-field OCT, full-field OCT, Bessel-beam OCT, transillumination OCT, interferometric synthetic aperture microscopy (ISAM), and optical coherence refraction tomography (OCRT), among others. Our unified theory not only enables clear understanding of existing techniques, but also suggests new research directions to continue advancing the field of OCT.

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来源期刊

Advances in Optics and Photonics OPTICS-

CiteScore

56.60

自引率

0.00%

发文量

期刊介绍： Advances in Optics and Photonics (AOP) is an all-electronic journal that publishes comprehensive review articles and multimedia tutorials. It is suitable for students, researchers, faculty, business professionals, and engineers interested in optics and photonics. The content of the journal covers advancements in these fields, ranging from fundamental science to engineering applications. The journal aims to capture the most significant developments in optics and photonics. It achieves this through long review articles and comprehensive tutorials written by prominent and respected authors who are at the forefront of their fields. The journal goes beyond traditional text-based articles by enhancing the content with multimedia elements, such as animation and video. This multimedia approach helps to enhance the understanding and visualization of complex concepts. AOP offers dedicated article preparation and peer-review support to assist authors throughout the publication process. This support ensures that the articles meet the journal's standards and are well-received by readers. Additionally, AOP welcomes comments on published review articles, encouraging further discussions and insights from the scientific community. In summary, Advances in Optics and Photonics is a comprehensive journal that provides authoritative and accessible content on advancements in optics and photonics. With its diverse range of articles, multimedia enhancements, and dedicated support, AOP serves as a valuable resource for professionals and researchers in these fields.