欧拉相位运动放大在高保真生命体征估计雷达在临床设置

2022 IEEE Sensors Pub Date : 2022-10-30 DOI:10.1109/SENSORS52175.2022.9967051

Md. Farhan Tasnim Oshim, Toral Surti, C. Goldfine, Stephanie Carreiro, Deepak Ganesan, Suren Jayasuriya, Tauhidur Rahman

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引用次数: 0

摘要

在嘈杂环境中高效、准确地检测微小物体产生的细微运动，作为生命体征监测的需要，是具有挑战性的，但可以通过放大大大改善。我们开发了一种基于复杂Gabor滤波器的分解方法，以放大不同空间波长水平的相位来放大运动，并提取一维运动信号用于基频估计。基于相位的复杂Gabor滤波器输出经过处理，然后用于训练机器学习模型，以更高的精度预测呼吸和心率。我们表明，我们提出的技术在临床环境中表现优于传统的基于时间fft的方法，例如睡眠实验室和急诊科，以及各种人体姿势。

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Eulerian Phase-based Motion Magnification for High-Fidelity Vital Sign Estimation with Radar in Clinical Settings

Efficient and accurate detection of subtle motion generated from small objects in noisy environments, as needed for vital sign monitoring, is challenging, but can be substantially improved with magnification. We developed a complex Gabor filter-based decomposition method to amplify phases at different spatial wavelength levels to magnify motion and extract 1D motion signals for fundamental frequency estimation. The phase-based complex Gabor filter outputs are processed and then used to train machine learning models that predict respiration and heart rate with greater accuracy. We show that our proposed technique performs better than the conventional temporal FFT-based method in clinical settings, such as sleep laboratories and emergency departments, as well for a variety of human postures.

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2022 IEEE Sensors

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