Inversion of band-limited discrete Fourier transforms of binary images: Uniqueness and algorithms

SIAM J. Imaging Sci. Pub Date : 2021-12-10 DOI:10.1137/22M1540442

Howard W. Levinson, Vadim A. Markel

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引用次数: 1

Abstract

Conventional inversion of the discrete Fourier transform (DFT) requires all DFT coefficients to be known. When the DFT coefficients of a rasterized image (represented as a matrix) are known only within a pass band, the original matrix cannot be uniquely recovered. In many cases of practical importance, the matrix is binary and its elements can be reduced to either 0 or 1. This is the case, for example, for the commonly used QR codes. The {\it a priori} information that the matrix is binary can compensate for the missing high-frequency DFT coefficients and restore uniqueness of image recovery. This paper addresses, both theoretically and numerically, the problem of recovery of blurred images without any known structure whose high-frequency DFT coefficients have been irreversibly lost by utilizing the binarity constraint. We investigate theoretically the smallest band limit for which unique recovery of a generic binary matrix is still possible. Uniqueness results are proved for images of sizes $N_1 \times N_2$, $N_1 \times N_1$, and $N_1^\alpha\times N_1^\alpha$, where $N_1 \neq N_2$ are prime numbers and $\alpha>1$ an integer. Inversion algorithms are proposed for recovering the matrix from its band-limited (blurred) version. The algorithms combine integer linear programming methods with lattice basis reduction techniques and significantly outperform naive implementations. The algorithm efficiently and reliably reconstructs severely blurred $29 \times 29$ binary matrices with only $11\times 11 = 121$ DFT coefficients.

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二值图像带限离散傅里叶变换的反演:唯一性和算法

传统的离散傅里叶变换(DFT)反演要求所有的DFT系数都是已知的。当栅格化图像的DFT系数(表示为矩阵)仅在通带内已知时，原始矩阵不能唯一地恢复。在许多实际重要的情况下，矩阵是二进制的，它的元素可以简化为0或1。例如，常用的QR码就是这种情况。矩阵为二值的{\it先验}信息可以补偿缺失的高频DFT系数，恢复图像恢复的唯一性。本文从理论上和数值上讨论了利用二值性约束对高频DFT系数不可逆丢失的模糊图像进行恢复的问题。我们从理论上研究了一般二元矩阵可能唯一恢复的最小带极限。对于大小为$N_1 \times N_2$、$N_1 \times N_1$和$N_1^\alpha\times N_1^\alpha$的图像，证明了唯一性结果，其中$N_1 \neq N_2$是素数，$\alpha>1$是整数。提出了从其带限(模糊)版本中恢复矩阵的反演算法。该算法将整数线性规划方法与格基约简技术相结合，显著优于原始实现。该算法仅使用$11\times 11 = 121$ DFT系数就能高效、可靠地重建严重模糊的$29 \times 29$二值矩阵。

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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SIAM J. Imaging Sci.

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