Retinal image preprocessing techniques: Acquisition and cleaning perspective

IF 0.9 Q4 TELECOMMUNICATIONS
Anuj Kumar Pandey, Satya Prakash Singh, Chinmay Chakraborty
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Abstract

Image preprocessing is a method to transform raw image data into clean image data. The objective of preprocessing is to improve the image data by suppressing undesired distortions. Enhancement of some image features which are relevant for further processing of image and analysis task is also done in preprocessing. Screening and diagnosis of various eye diseases like diabetic retinopathy, Choroidal Neovascularization(CNV), DRUSEN, etc. are possible using digital retinal images. This paper aims to provide a better understanding and knowledge of the computer algorithms used for retinal image preprocessing. In this paper, various image preprocessing techniques are incorporated such as color correction, color space selection, noise reduction, and contrast enhancement on retinal images. Retinal blood vessels are better seen in Green color space instead of Red or Blue color space. Noise reduction through Block matching and 3D(BM3D) techniques show a significant result as compared to Total Variation Filter (TVF) and Bilateral Filter (BLF). Contrast enhancement through Contrast Limited Adaptive Histogram Equalization (CLAHE) outperforms Global Equalization (GE) or Adaptive Histogram Equalization (AHE). Evaluation parameters such as Mean square error, Peak Signal Noise ratio, Structured similarity index measures, and Normalized root mean square error values for BM3D noise filtering are 0.0029, 25.3370, 0.6839 and 0.0998 respectively which shows that BM3D outperforms the others.

视网膜图像预处理技术:采集和清洗视角
图像预处理是一种将原始图像数据转换为干净图像数据的方法。预处理的目的是通过抑制不必要的失真来改进图像数据。预处理还能增强一些与图像进一步处理和分析任务相关的图像特征。利用数字视网膜图像可以筛查和诊断各种眼部疾病,如糖尿病视网膜病变、脉络膜新生血管(CNV)、DRUSEN 等。本文旨在让人们更好地了解和掌握用于视网膜图像预处理的计算机算法。本文结合了各种图像预处理技术,如视网膜图像的色彩校正、色彩空间选择、降噪和对比度增强。在绿色空间而不是红色或蓝色空间中,视网膜血管的显示效果更好。与总变异滤波器(TVF)和双侧滤波器(BLF)相比,通过块匹配和三维(BM3D)技术降噪效果显著。通过对比度限制自适应直方图均衡(CLAHE)增强对比度的效果优于全局均衡(GE)或自适应直方图均衡(AHE)。BM3D 噪声过滤的均方误差、峰值信噪比、结构相似性指数测量值和归一化均方根误差值等评估参数分别为 0.0029、25.3370、0.6839 和 0.0998,这表明 BM3D 优于其他方法。
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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CiteScore
3.10
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