Sensitive Optomechanical Ultrasound Sensor in an LED-Based, Low Fluence Photoacoustic Imaging System

IF 2.2 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Sensors Letters Pub Date : 2024-11-06 DOI:10.1109/LSENS.2024.3492333

Cedric Pieters;Tom Verschooten;Grim Keulemans;Liesbet Lagae;Jon Øyvind Kjellman;Xavier Rottenberg;Hilde Jans

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引用次数: 0

Abstract

Affordable and compact light sources, along with highly sensitive, broadband, low-noise sensors, are essential for enabling point-of-care photoacoustic imaging applications in resource-limited settings. Traditional systems use piezoelectric transducers, which often suffer from limited bandwidth and sensitivity, combined with solid-state lasers that are expensive and bulky. We present a potentially low-cost light-emitting diode (LED)-based photoacoustic imaging system featuring a highly sensitive optomechanical ultrasound sensor operating near thermomechanical noise limits. Utilizing a 620-nm LED, our setup delivers microjoules of pulse energy with 100-ns pulsewidths. We demonstrate its capability to resolve fine details through 2-D scan tomography, with minimal averaging for an effective sample rate of 100 Hz. Future improvements, including the development of larger LED arrays, multiplexed sensors, and on-chip integrated lasers, promise to enhance performance and further expand the technology's applicability.

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基于led的低通量光声成像系统中的灵敏光机械超声传感器

经济实惠的紧凑型光源，以及高灵敏度、宽带、低噪声传感器，对于在资源有限的环境中实现即时光声成像应用至关重要。传统的系统使用的是压电换能器，这种换能器的带宽和灵敏度都很有限，再加上昂贵而笨重的固态激光器。我们提出了一种潜在的低成本的基于发光二极管（LED）的光声成像系统，该系统具有高灵敏度的光机械超声传感器，在热机械噪声极限附近工作。利用一个620纳米的LED，我们的设置提供微焦耳脉冲能量与100纳秒脉冲宽度。我们展示了其通过二维扫描断层扫描解决精细细节的能力，有效采样率为100 Hz的最小平均。未来的改进，包括开发更大的LED阵列、多路复用传感器和片上集成激光器，有望提高性能并进一步扩大技术的适用性。

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来源期刊

IEEE Sensors Letters Engineering-Electrical and Electronic Engineering

CiteScore

3.50

自引率

7.10%

发文量

194