基于人工智能系统的退化超声波图像精确去噪范例。

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
ACS Applied Bio Materials Pub Date : 2024-12-01 Epub Date: 2024-08-15 DOI:10.1002/jemt.24675
F E Al-Tahhan, M E Fares
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引用次数: 0

摘要

超声波图像容易出现各种形式的质量下降,对诊断造成负面影响。常见的劣化形式包括斑点噪声、高斯噪声、椒盐噪声和模糊。这项研究提出了一种精确的超声图像去噪策略,首先检测噪声类型,然后针对每种损坏情况采用合适的去噪方法。该技术依靠卷积神经网络对影响输入超声图像的噪声类型进行分类。开发和训练的预训练卷积神经网络模型包括 GoogleNet、VGG-19、AlexNet 和 AlexNet 支持向量机 (SVM),用于执行该分类。模型的训练和评估使用了由 782 幅不同疾病和噪声类型的数字生成超声图像组成的数据集。结果显示,AlexNet-SVM 在噪声类型分类方面达到了 99.2% 的最高准确率。结果表明,本技术被认为是性能最好的模型之一,然后将其应用于具有不同噪声破坏的真实超声波图像,以证明所提出的 "先检测后噪声 "系统的有效性。研究亮点提出了一种基于先检测噪声类型的精确超声图像去噪策略。使用预先训练的卷积神经网络对输入图像中的噪声类型进行分类。在 782 个合成超声波图像数据集上评估 GoogleNet、VGG-19、AlexNet 和 AlexNet 支持向量机 (SVM) 模型。AlexNet-SVM 对噪声类型的分类准确率最高,达到 99.2%。在真实超声波图像上证明了所提出的 "先检测后噪声 "系统的有效性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
An accurate paradigm for denoising degraded ultrasound images based on artificial intelligence systems.

Ultrasound images are susceptible to various forms of quality degradation that negatively impact diagnosis. Common degradations include speckle noise, Gaussian noise, salt and pepper noise, and blurring. This research proposes an accurate ultrasound image denoising strategy based on firstly detecting the noise type, then, suitable denoising methods can be applied for each corruption. The technique depends on convolutional neural networks to categorize the type of noise affecting an input ultrasound image. Pre-trained convolutional neural network models including GoogleNet, VGG-19, AlexNet and AlexNet-support vector machine (SVM) are developed and trained to perform this classification. A dataset of 782 numerically generated ultrasound images across different diseases and noise types is utilized for model training and evaluation. Results show AlexNet-SVM achieves the highest accuracy of 99.2% in classifying noise types. The results indicate that, the present technique is considered one of the top-performing models is then applied to real ultrasound images with different noise corruptions to demonstrate efficacy of the proposed detect-then-denoise system. RESEARCH HIGHLIGHTS: Proposes an accurate ultrasound image denoising strategy based on detecting noise type first. Uses pre-trained convolutional neural networks to categorize noise type in input images. Evaluates GoogleNet, VGG-19, AlexNet, and AlexNet-support vector machine (SVM) models on a dataset of 782 synthetic ultrasound images. AlexNet-SVM achieves highest accuracy of 99.2% in classifying noise types. Demonstrates efficacy of the proposed detect-then-denoise system on real ultrasound images.

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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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