Missing frequency recovery through ptychography

Computational Optics 2021 Pub Date : 2021-09-12 DOI:10.1117/12.2597060

A. Dejkameh, I. Mochi, R. Nebling, Hyun-su Kim, Tao Shen, Y. Ekinci

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Abstract

High-resolution imaging at short wavelengths from extreme ultraviolet to hard X-rays has many applications in a plethora of fields from astronomy to biology and semiconductor metrology. Unfortunately, efficient optics for these wavelengths are difficult to manufacture or have limited resolution. For this reason, in the past few years, coherent diffraction imaging (CDI) applications become widely used. In CDI, the object is illuminated by a coherent beam and the diffraction intensity is collected by a 2D pixel detector. In this process, the phase information of the diffracted light is lost. A phase retrieval algorithm is then used to reconstruct the object’s complex amplitude. Ptychography is a scanning version of coherent diffraction imaging and it is based on an iterative reconstruction algorithm that relies on the quality of the recorded diffraction intensity to converge. To obtain diffraction patterns with a high signal-to-noise ratio, a beam stop is used in many ptychography setups to avoid over-saturation and blooming effects on the detector. While using a beam stop in a ptychography setup has become common practice, the limits of affordable data loss due to beam stop have not been systematically investigated. Pixel masking is the conventional method to recover the lost frequencies. In this method, when enforcing the Fourier domain constraint, the invalid pixels are ignored. In the missing data region, the algorithm is allowed to keep the guess from the previous iteration. The illumination conditions of the ptychography experiment play a critical role in the signal recovery procedure. The diffraction pattern on the detector is the convolution of the Fourier transform of the object and the illumination. An illumination with a finite numerical aperture encodes the object information over a larger detector area. This makes the reconstruction algorithm more robust to pixel loss. We provide simulation and experimental results to demonstrate this theory.

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缺失频率恢复通过平面摄影

从极紫外到硬x射线的短波长高分辨率成像在天文学、生物学和半导体计量学等众多领域都有许多应用。不幸的是，这些波长的有效光学元件很难制造或分辨率有限。因此，近年来相干衍射成像(CDI)的应用越来越广泛。在CDI中，物体被相干光束照射，衍射强度由二维像素检测器采集。在这个过程中，衍射光的相位信息丢失了。然后使用相位恢复算法来重建目标的复振幅。平面摄影是扫描版的相干衍射成像，它是基于迭代重建算法，依赖于记录的衍射强度的质量收敛。为了获得具有高信噪比的衍射图案，在许多照相装置中使用了光束停止装置，以避免检测器上的过饱和和盛开效应。虽然在印刷装置中使用波束停止已经成为一种常见的做法，但由于波束停止而造成的可承受的数据丢失的限制还没有系统地研究过。像素掩蔽是恢复丢失频率的常用方法。在该方法中，当施加傅里叶域约束时，无效像素被忽略。在缺失的数据区域，允许算法保留前一次迭代的猜测。感光实验的光照条件在信号恢复过程中起着至关重要的作用。探测器上的衍射图案是物体的傅里叶变换和光照的卷积。具有有限数值孔径的照明在较大的检测器区域上对目标信息进行编码。这使得重建算法对像素丢失具有更强的鲁棒性。我们提供了仿真和实验结果来证明这一理论。

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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Computational Optics 2021

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