Optical techniques for image compression

Data Compression Conference, 1992. Pub Date : 1992-03-24 DOI:10.1109/DCC.1992.227478

J. Reif, A. Yoshida

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引用次数: 9

Abstract

Optical computing has recently become a very active research field. The advantage of optics is its capability of providing highly parallel operations in a three dimensional space. The authors propose optical architectures to execute various image compression techniques. They optically implement the following compression techniques: transform coding; vector quantization; and interframe coding; They show many generally used transform coding methods, for example, the cosine transform, can be implemented by a simple optical system. The transform coding can be carried out in constant time. Most of this paper is concerned with a sophisticated optical system for vector quantization using holographic associative matching. Holographic associative matching provided by multiple exposure holograms can offer advantageous techniques for vector quantization based compression schemes. Photorefractive crystals, which provide high density recording in real time, are used as the holographic media. The reconstruction alphabet can be dynamically constructed through training or stored in the photorefractive crystal in advance. Encoding a new vector can be carried out by holographic associative matching in constant time. An extension to interframe coding is also discussed.<>

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图像压缩的光学技术

近年来，光计算已成为一个非常活跃的研究领域。光学的优点是它能够在三维空间中提供高度并行的操作。作者提出了执行各种图像压缩技术的光学架构。它们光学地实现了以下压缩技术:转换编码;矢量量化;帧间编码;他们展示了许多常用的变换编码方法，例如，余弦变换，可以由一个简单的光学系统实现。变换编码可以在常数时间内完成。本文主要研究了一种利用全息关联匹配实现矢量量化的复杂光学系统。多重曝光全息图提供的全息关联匹配为基于矢量量化的压缩方案提供了有利的技术。光折变晶体可以提供高密度的实时记录，被用作全息介质。重构字母表可以通过训练动态构造，也可以预先存储在光折变晶体中。在常数时间内，通过全息关联匹配实现对新向量的编码。对帧间编码的扩展也进行了讨论。

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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Data Compression Conference, 1992.

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