Magnetic position sensing for self-calibration and image registration of scanning fiber endoscopes

Journal of Optical Microsystems Pub Date : 2024-03-07 DOI:10.1117/1.jom.4.1.014003

Aybuke Calikoglu, Gerardo González-Cerdas, David Ilioae, Marius K. Kienzler, Florian Lux, Yanis Taege, Çağlar Ataman

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Abstract

. We present a magnetic position sensor for scanning fiber endoscopes to address their inherent short-and long-term position instability, which is a major hurdle before their widespread clinical deployment. The position sensor uses a ring-shaped micro-magnet at the tip of the fiber cantilever, producing a dynamic magnetic field as the scanner resonates. A miniaturized three-dimensional Hall sensor accommodated within the endoscopic probe housing measures the magnetic field vector, which is then mapped directly to the beam position using closed-form calibration curves empirically obtained through a one-time calibration step using a position sensitive detector. By integrating the sensor into an OCT-endomicroscope recently developed in our group, we demonstrate an average position resolution of 20 μ m over a field-of-view of 2.1 mm field-of-view and distortion-free OCT images recorded with various scan parameters. We also discuss how sub-pixel (e.g., better than half the diffraction-limited spot size) position resolution can be attained with the new sensing scheme.

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用于扫描光纤内窥镜自我校准和图像注册的磁位置传感技术

.我们提出了一种用于扫描光纤内窥镜的磁性位置传感器，以解决光纤内窥镜固有的短期和长期位置不稳定性问题，这是光纤内窥镜广泛应用于临床的主要障碍。该位置传感器在光纤悬臂顶端使用环形微型磁铁，在扫描仪共振时产生动态磁场。安装在内窥镜探头外壳内的微型三维霍尔传感器可测量磁场矢量，然后通过使用位置敏感探测器进行一次性校准步骤，根据经验得出闭式校准曲线，将磁场矢量直接映射到光束位置。通过将传感器集成到我们小组最近开发的 OCT 内窥镜中，我们展示了在 2.1 mm 视场范围内 20 μ m 的平均位置分辨率，以及用各种扫描参数记录的无畸变 OCT 图像。我们还讨论了如何利用新的传感方案实现亚像素（例如，优于衍射极限光斑尺寸的一半）位置分辨率。

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

Journal of Optical Microsystems

CiteScore

0.60

自引率

0.00%

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