基于bp的泊松噪声医学图像压缩分析

Q3 Computer Science
Victoriia Naumenko, Bogdan Kovalenko, Volodymyr Lukin
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引用次数: 0

摘要

主题是使用BPG编码器对具有不同视觉复杂性水平的医学图像进行有损压缩,这些图像被泊松噪声破坏。本研究的目标是确定图像压缩的最佳参数,并选择最合适的度量来确定最佳操作点。所解决的任务包括:选择灰度大小为512x512、视觉复杂程度不同的测试图像,包括边缘和纹理丰富的视觉复杂图像、边缘和纹理邻近均匀区域的中等复杂图像和主要由均匀区域组成的视觉简单图像;建立图像质量评价指标,并评估其在不同编码器压缩参数下的性能;选择一个或多个指标,明确确定最佳操作点的位置;并根据使用BPG编码器压缩被泊松噪声损坏的医学图像的所得结果提供建议,目的是最大限度地恢复图像与原始图像的质量相似性。所采用的方法包括使用MSE, PSNR, MSSIM和PSNR- hvs - m指标的图像质量评估技术,以及在Python中不使用内置泊松噪声发生器的软件建模。随后的结果表明,当压缩图像质量超过相应的原始图像,并且具有足够高的压缩比时,可以识别所有这些指标的最佳操作点(OOP)。此外,在压缩比和图像质量之间取得适当的平衡可以在不引起压缩图像明显失真的情况下部分降噪。本研究强调了采用适当的指标来评估压缩医学图像质量的重要性,并提供了确定压缩参数Q以达到BPG编码器对特定图像的最佳操作点的见解。结论。这些发现的科学新颖性包括以下内容:1)所有度量标准确定中等视觉复杂性图像或由同质区域主导的图像的OOP的能力;MSE和PSNR指标展示了丰富的纹理和边缘图像的优越结果;2)研究强调了面向对象中Q对图像平均强度的依赖性,可以根据我们的结果合理地建立给定图像指定用于压缩。在面向对象处压缩的图像的压缩比足够高,进一步证实了在接近面向对象处压缩图像的基本原理。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
BPG-based compression analysis of Poisson-noisy medical images
The subject matter is lossy compression using the BPG encoder for medical images with varying levels of visual complexity, which are corrupted by Poisson noise. The goal of this study is to determine the optimal parameters for image compression and select the most suitable metric for identifying the optimal operational point. The tasks addressed include: selecting test images sized 512x512 in grayscale with varying degrees of visual complexity, encompassing visually intricate images rich in edges and textures, moderately complex images with edges and textures adjacent to homogeneous regions, and visually simple images primarily composed of homogeneous regions; establishing image quality evaluation metrics and assessing their performance across different encoder compression parameters; choosing one or multiple metrics that distinctly identify the position of the optimal operational point; and providing recommendations based on the attained results regarding the compression of medical images corrupted by Poisson noise using a BPG encoder, with the aim of maximizing the restored image’s quality resemblance to the original. The employed methods encompass image quality assessment techniques employing MSE, PSNR, MSSIM, and PSNR-HVS-M metrics, as well as software modeling in Python without using the built-in Poisson noise generator. The ensuing results indicate that optimal operational points (OOP) can be discerned for all these metrics when the compressed image quality surpasses that of the corresponding original image, accompanied by a sufficiently high compression ratio. Moreover, striking a suitable balance between the compression ratio and image quality leads to partial noise reduction without introducing notable distortions in the compressed image. This study underscores the significance of employing appropriate metrics for evaluating the quality of compressed medical images and provides insights into determining the compression parameter Q to attain the BPG encoder’s optimal operational point for specific images. Conclusions. The scientific novelty of the findings encompasses the following: 1) the capability of all metrics to determine the OOP for images of moderate visual complexity or those dominated by homogeneous areas; MSE and PSNR metrics demonstrating superior results for images rich in textures and edges; 2) the research highlights the dependency of Q in the OOP on the average image intensity, which can be reasonably established for a given image earmarked for compression based on our outcomes. The compression ratios for images compressed at the OOP are sufficiently high, further substantiating the rationale for compressing images in close proximity to the OOP.
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来源期刊
Radioelectronic and Computer Systems
Radioelectronic and Computer Systems Computer Science-Computer Graphics and Computer-Aided Design
CiteScore
3.60
自引率
0.00%
发文量
50
审稿时长
2 weeks
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