Space-Time Encoded Modulation for High-Fidelity Diffuse Optical Imaging

IEEE transactions on medical imaging Pub Date : 2025-04-08 DOI:10.1109/TMI.2025.3558865

Ben Wiesel;Shlomi Arnon

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Abstract

Diffuse optical imaging (DOI) offers valuable insights into scattering mediums, but the quest for high-resolution imaging often requires dense sampling strategies, leading to higher imaging errors and lengthy acquisition times. This work introduces Space-Time Encoded Modulation (STEM), a novel light modulation scheme enabling low-noise, high-resolution imaging with single-pixel detectors. In STEM, a laser illuminates the sample, and the transmitted light is detected using a single pixel detector. The detected image is partitioned into a two-dimensional array of sub-images, each encoded with a unique quasi-orthogonal code. These coded sub-images represent light transmission at specific locations along the sample boundary. A single-pixel detector then measures their combined transmission. By virtue of their quasi-orthogonality, the relative strength of each sub-image can be measured, enabling image formation. In this paper, we present a comprehensive mathematical description and experimental validation of the STEM method. Compared to traditional raster scanning, STEM significantly enhances imaging quality, reducing imaging errors by up to 60% and yielding a 3.5-fold increase in reconstruction contrast.

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用于高保真漫反射光学成像的时空编码调制技术

漫射光学成像（DOI）提供了对散射介质的宝贵见解，但对高分辨率成像的追求通常需要密集的采样策略，导致更高的成像误差和较长的采集时间。这项工作介绍了时空编码调制（STEM），这是一种新的光调制方案，可以通过单像素探测器实现低噪声，高分辨率成像。在STEM中，激光照射样品，并使用单像素检测器检测透射光。检测到的图像被分割成二维的子图像阵列，每个子图像用唯一的准正交编码编码。这些编码子图像表示沿样品边界特定位置的光透射。然后一个单像素探测器测量它们的联合传输。利用它们的准正交性，可以测量每个子图像的相对强度，从而形成图像。在本文中，我们提出了STEM方法的综合数学描述和实验验证。与传统的光栅扫描相比，STEM显著提高了成像质量，将成像误差降低了60%，重建对比度提高了3.5倍。

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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IEEE transactions on medical imaging

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