减少像差引起的噪音:基于深度学习的 "从像差到像差 "方法。

Mostafa Sharifzadeh, Sobhan Goudarzi, An Tang, Habib Benali, Hassan Rivaz
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引用次数: 0

摘要

相位差是超声成像图像质量不佳的主要原因之一。相位差是由异质介质上声速的空间变化引起的,它干扰了传输波,阻碍了回波信号的连贯求和。在现实世界中获取无像差的地面实况极具挑战性,甚至是不可能的。由于模拟数据和实验数据之间存在域偏移,这一挑战阻碍了基于深度学习技术的性能。在这里,我们首次提出了一种基于深度学习的方法,它不需要地面实况来纠正相差问题,因此可以直接在真实数据上进行训练。我们训练了一个网络,其输入和目标输出都是随机畸变的射频(RF)数据。此外,我们还证明了均方误差等传统损失函数不足以训练这样的网络以达到最佳性能。相反,我们提出了一种自适应混合损失函数,同时采用 B 模式和射频数据,从而提高了收敛效率和性能。最后,我们公开发布了我们的数据集,其中包括 180,000 多幅畸变的单平面波图像(射频数据),其中相位畸变被建模为近场相位屏。虽然在所提出的方法中没有使用,但每幅畸变图像都与相应的畸变轮廓和非畸变版本配对,目的是在开发基于深度学习的相位差校正技术时缓解数据稀缺问题。源代码和训练好的模型以及数据集也可在 http://code.sonography.ai/main-aaa 上获取。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Mitigating Aberration-Induced Noise: A Deep Learning-Based Aberration-to-Aberration Approach.

One of the primary sources of suboptimal image quality in ultrasound imaging is phase aberration. It is caused by spatial changes in sound speed over a heterogeneous medium, which disturbs the transmitted waves and prevents coherent summation of echo signals. Obtaining non-aberrated ground truths in real-world scenarios can be extremely challenging, if not impossible. This challenge hinders the performance of deep learning-based techniques due to the domain shift between simulated and experimental data. Here, for the first time, we propose a deep learning-based method that does not require ground truth to correct the phase aberration problem and, as such, can be directly trained on real data. We train a network wherein both the input and target output are randomly aberrated radio frequency (RF) data. Moreover, we demonstrate that a conventional loss function such as mean square error is inadequate for training such a network to achieve optimal performance. Instead, we propose an adaptive mixed loss function that employs both B-mode and RF data, resulting in more efficient convergence and enhanced performance. Finally, we publicly release our dataset, comprising over 180,000 aberrated single plane-wave images (RF data), wherein phase aberrations are modeled as near-field phase screens. Although not utilized in the proposed method, each aberrated image is paired with its corresponding aberration profile and the non-aberrated version, aiming to mitigate the data scarcity problem in developing deep learning-based techniques for phase aberration correction. Source code and trained model are also available along with the dataset at http://code.sonography.ai/main-aaa.

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