Analysis of the Measurement Matrix in Directional Predictive Coding for Compressive Sensing of Medical Images

Q4 Computer Science

Electronic Letters on Computer Vision and Image Analysis Pub Date : 2022-01-25 DOI:10.5565/rev/elcvia.1412

Hepzibah Christinal A, Kowsalya G, Abraham Chandy D, J. S, Chandrajit L. Bajaj

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引用次数: 1

Abstract

Compressive sensing of 2D signals involves three fundamental steps: sparse representation, linear measurement matrix, and recovery of the signal. This paper focuses on analyzing the efficiency of various measurement matrices for compressive sensing of medical images based on theoretical predictive coding. During encoding, the prediction is efficiently chosen by four directional predictive modes for block-based compressive sensing measurements. In this work, Gaussian, Bernoulli, Laplace, Logistic, and Cauchy random matrices are used as the measurement matrices. While decoding, the same optimal prediction is de-quantized. Peak-signal-to-noise ratio and sparsity are used for evaluating the performance of measurement matrices. The experimental result shows that the spatially directional predictive coding (SDPC) with Laplace measurement matrices performs better compared to scalar quantization (SQ) and differential pulse code modulation (DPCM) methods. The results indicate that the Laplace measurement matrix is the most suitable in compressive sensing of medical images.

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医学图像压缩感知方向预测编码中的测量矩阵分析

二维信号的压缩感知包括三个基本步骤:稀疏表示、线性测量矩阵和信号恢复。本文重点分析了基于理论预测编码的各种测量矩阵在医学图像压缩感知中的效率。在编码过程中，采用四种方向预测模式对基于块的压缩感知测量进行有效选择。在这项工作中，使用高斯，伯努利，拉普拉斯，Logistic和柯西随机矩阵作为测量矩阵。在解码时，同样的最优预测被去量化。用峰值信噪比和稀疏度来评价测量矩阵的性能。实验结果表明，与标量量化(SQ)和差分脉冲编码调制(DPCM)方法相比，基于拉普拉斯测量矩阵的空间定向预测编码(SDPC)具有更好的性能。结果表明，拉普拉斯测量矩阵最适合用于医学图像的压缩感知。

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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