Optimizing Coded Excitation for Model-Based Ultrasound Imaging With Unfocused Transmissions

IF 4.2 2区计算机科学 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Transactions on Computational Imaging Pub Date : 2025-03-01 DOI:10.1109/TCI.2025.3566224

Didem Dogan;Lixiang Zhu;Yuyang Hu;Johannes G. Bosch;Pieter Kruizinga;Geert Leus

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Abstract

Ultrafast imaging, which uses unfocussed transmissions to form images, provides very high frame rates at the cost of low signal-to-noise ratio (SNR). This loss of SNR becomes especially apparent when imaging deeper structures. Ultrafast imaging is mostly used in combination with Doppler processing. Even if we apply tissue-separation filters, they lead to significant energy loss and decrease the SNR. Previous work showed that this loss in SNR and, hence, penetration depth can be partially regained using coded transmissions. However, these codes are mostly either standard or randomly generated and can be improved with a design rooted in an optimization scheme. To address this limitation, we design an optimized code tailored to ultrasound imaging with unfocused transmissions represented by a generalized encoding matrix in a linear signal model. We employ the minimization of the Cramér-Rao lower bound (CRB) over the unknown coding matrix as a way to optimize the code. Due to the high computational cost of the resulting optimization problems, we also introduce a trace-constraint optimization problem based on the Fisher information matrix (FIM). Simulation results show that the optimized code provides higher SNR in deep image regions than previously tested coding schemes such as the Barker code, albeit with a trade-off for decreased resolution. On the other hand, the application of least-squares QR (LSQR) mitigates this resolution degradation. Lastly, the optimized code was tested in simulations using a numerical model of a clinical transducer setting, demonstrating its potential for higher SNR in ultrafast Doppler imaging.

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基于模型的非聚焦超声成像编码激励优化

超高速成像技术使用非聚焦传输来形成图像，以低信噪比（SNR）为代价提供非常高的帧速率。当成像更深的结构时，这种信噪比的损失变得特别明显。超快成像多与多普勒处理相结合。即使我们使用组织分离滤波器，它们也会导致显著的能量损失并降低信噪比。先前的研究表明，使用编码传输可以部分恢复信噪比的损失，从而恢复穿透深度。然而，这些代码大多要么是标准的，要么是随机生成的，可以通过基于优化方案的设计来改进。为了解决这一限制，我们设计了一种优化的代码，专门针对线性信号模型中由广义编码矩阵表示的无聚焦传输的超声成像。我们采用在未知编码矩阵上最小化cram - rao下界（CRB）作为优化代码的一种方法。由于所产生的优化问题的计算成本很高，我们还引入了基于Fisher信息矩阵（FIM）的跟踪约束优化问题。仿真结果表明，优化后的编码比之前测试过的编码方案（如Barker编码）在深度图像区域提供更高的信噪比，尽管以降低分辨率为代价。另一方面，最小二乘QR （LSQR）的应用减轻了这种分辨率下降。最后，利用临床换能器设置的数值模型对优化后的代码进行了模拟测试，证明了其在超快多普勒成像中具有更高信噪比的潜力。

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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来源期刊

IEEE Transactions on Computational Imaging Mathematics-Computational Mathematics

CiteScore

8.20

自引率

7.40%

发文量

期刊介绍： The IEEE Transactions on Computational Imaging will publish articles where computation plays an integral role in the image formation process. Papers will cover all areas of computational imaging ranging from fundamental theoretical methods to the latest innovative computational imaging system designs. Topics of interest will include advanced algorithms and mathematical techniques, model-based data inversion, methods for image and signal recovery from sparse and incomplete data, techniques for non-traditional sensing of image data, methods for dynamic information acquisition and extraction from imaging sensors, software and hardware for efficient computation in imaging systems, and highly novel imaging system design.