Beamforming-integrated neural networks for ultrasound imaging

IF 3.8 2区物理与天体物理 Q1 ACOUSTICS Ultrasonics Pub Date : 2024-10-03 DOI:10.1016/j.ultras.2024.107474

Di Xiao, Alfred C.H. Yu

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Abstract

Sparse matrix beamforming (SMB) is a computationally efficient reformulation of delay-and-sum (DAS) beamforming as a single sparse matrix multiplication. This reformulation can potentially dovetail with machine learning platforms like TensorFlow and PyTorch that already support sparse matrix operations. In this work, using SMB principles, we present the development of beamforming-integrated neural networks (BINNs) that can rationally infer ultrasound images directly from pre-beamforming channel-domain radiofrequency (RF) datasets. To demonstrate feasibility, a toy BINN was first designed with two 2D-convolution layers that were respectively placed both before and after an SMB layer. This toy BINN correctly updated kernel weights in all convolution layers, demonstrating efficiency in both training (PyTorch – 133 ms, TensorFlow – 22 ms) and inference (PyTorch – 4 ms, TensorFlow – 5 ms). As an application demonstration, another BINN with two RF-domain convolution layers, an SMB layer, and three image-domain convolution layers was designed to infer high-quality B-mode images in vivo from single-shot plane-wave channel RF data. When trained using 31-angle compounded plane wave images (3000 frames from 22 human volunteers), this BINN showed mean-square logarithmic error improvements of 21.3 % and 431 % in the inferred B-mode image quality respectively comparing to an image-to-image convolutional neural network (CNN) and an RF-to-image CNN with the same number of layers and learnable parameters (3,777). Overall, by including an SMB layer to adopt prior knowledge of DAS beamforming, BINN shows potential as a new type of informed machine learning framework for ultrasound imaging.

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用于超声波成像的波束成形集成神经网络。

稀疏矩阵波束成形（SMB）是对延迟与和（DAS）波束成形的一种计算高效的重构，是一种单一的稀疏矩阵乘法。这种重构有可能与 TensorFlow 和 PyTorch 等已经支持稀疏矩阵运算的机器学习平台对接。在这项工作中，我们利用 SMB 原理开发了波束成形集成神经网络（BINN），它可以直接从预波束成形信道域射频（RF）数据集合理推断超声图像。为了证明其可行性，我们首先设计了一个玩具 BINN，它有两个二维卷积层，分别位于 SMB 层之前和之后。这个玩具 BINN 正确更新了所有卷积层的内核权重，在训练（PyTorch - 133 毫秒，TensorFlow - 22 毫秒）和推理（PyTorch - 4 毫秒，TensorFlow - 5 毫秒）方面都表现出高效率。作为应用演示，我们设计了另一个具有两个射频域卷积层、一个 SMB 层和三个图像域卷积层的 BINN，用于从单发平面波通道射频数据推断高质量的活体 B 模式图像。在使用 31 角复合平面波图像（来自 22 名人体志愿者的 3000 帧图像）进行训练时，与具有相同层数和可学习参数（3,777）的图像到图像卷积神经网络（CNN）和射频到图像 CNN 相比，该 BINN 所推断的 B 型图像质量的均方对数误差分别提高了 21.3% 和 431%。总之，通过加入一个采用 DAS 波束成形先验知识的 SMB 层，BINN 显示出作为一种新型超声成像知情机器学习框架的潜力。

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来源期刊

Ultrasonics 医学-核医学

CiteScore

7.60

自引率

19.00%

发文量

186

审稿时长

3.9 months

期刊介绍： Ultrasonics is the only internationally established journal which covers the entire field of ultrasound research and technology and all its many applications. Ultrasonics contains a variety of sections to keep readers fully informed and up-to-date on the whole spectrum of research and development throughout the world. Ultrasonics publishes papers of exceptional quality and of relevance to both academia and industry. Manuscripts in which ultrasonics is a central issue and not simply an incidental tool or minor issue, are welcomed. As well as top quality original research papers and review articles by world renowned experts, Ultrasonics also regularly features short communications, a calendar of forthcoming events and special issues dedicated to topical subjects.