Effect of sample locations on computation of the exact scalar diffraction field (in English)

2012 20th Signal Processing and Communications Applications Conference (SIU) Pub Date : 2012-04-18 DOI:10.1109/SIU.2012.6204493

G. B. Esmer, Haldun M. Özaktas, L. Onural

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Abstract

Computer generated holography is one of common methods to obtain three-dimensional visualization. It can be explained by behavior of propagating waves and interference. To calculate the scalar diffraction pattern on a hologram, there are myriad of algorithms in the literature. Some of them employ several approximations, so the calculated fields may not be the exact scalar diffraction field. However, there are algorithms to compute the exact scalar diffraction field with some limitations on the distribution of the given samples over the space. These algorithms are based on “field model” approach. The performance of an algorithm, based on field model, is investigated according to the distribution of given samples over the space. From the simulations, it was observed that the cumulative information provided by the given samples has to be enough to solve the inverse scalar diffraction field. The cumulative information can be increased by having more samples, but there are some scenarios that differential information obtained from the given samples can be infinitesimal, thus the exact diffraction field may not be computed.

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样品位置对精确标量衍射场计算的影响(双语出版)

计算机生成全息是获得三维可视化的常用方法之一。它可以用传播波和干涉的行为来解释。为了计算全息图上的标量衍射图案，文献中有无数的算法。它们中的一些采用了几个近似，因此计算出的场可能不是精确的标量衍射场。然而，计算精确的标量衍射场的算法对给定样品在空间上的分布有一定的限制。这些算法基于“场模型”方法。根据给定样本在空间上的分布，研究了一种基于场模型的算法的性能。从模拟中观察到，给定样品提供的累积信息必须足以求解反标量衍射场。累积信息可以通过更多的样本来增加，但在某些情况下，从给定样本中获得的微分信息可能是无穷小的，因此可能无法计算出精确的衍射场。

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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2012 20th Signal Processing and Communications Applications Conference (SIU)

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