An optimized mismatched filter for continuous emission ultrasound imaging

Science Talks Pub Date : 2025-06-09 DOI:10.1016/j.sctalk.2025.100469

Axel Adam, Adrian Basarab, Hervé Liebgott, Barbara Nicolas

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Abstract

Current pulse-echo ultrasound imaging techniques provide direct insight into tissue structures but face two key limitations: an upper bounded imaging framerate and an inability to capture phenomena during most of the acquisition time due to a small duty cycle and a short wave-tissue interaction duration. To address these issues, we proposed continuous emission ultrasound imaging (CEUI), demonstrated for motion-mode imaging with a single-input-single-output device.

CEUI relies on the continuous transmission of an encoded signal, requiring decoding upon reception. Initial evaluations of pulse compression approaches revealed a critical limitation: interference from other emission segments during decoding, causing image quality loss.

This paper introduces a mismatched filter designed to reduce integrated sidelobe ratio (ISLR) of a specific point spread function of the imaging system. The latter incorporates the impact of emission segments that interfere on a single decoding step. Simulation results show a significant enhancement of the ISLR by 7 dB compared to the matched filter and 5.5 dB compared to classical mismatched filter, while reducing the mainlobe width by 60 % and respectively 25 %.

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一种用于连续发射超声成像的优化错配滤波器

目前的脉冲回波超声成像技术提供了对组织结构的直接洞察，但面临两个关键限制：成像帧率的上限，以及由于占空比小和短波与组织相互作用持续时间短，在大部分采集时间内无法捕获现象。为了解决这些问题，我们提出了连续发射超声成像（CEUI），演示了单输入单输出设备的运动模式成像。CEUI依赖于编码信号的连续传输，需要在接收后进行解码。对脉冲压缩方法的初步评估揭示了一个关键的限制：解码过程中来自其他发射段的干扰，导致图像质量损失。本文介绍了一种用于降低成像系统中特定点扩展函数的综合旁瓣比（ISLR）的失匹配滤波器。后者包含干扰单个解码步骤的发射段的影响。仿真结果表明，与匹配滤波器相比，ISLR显著提高了7 dB，与经典失匹配滤波器相比提高了5.5 dB，同时主瓣宽度分别降低了60%和25%。

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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