Noise-tolerant NMF-based parallel algorithm for respiratory rate estimation

The Journal of Supercomputing Pub Date : 2024-08-30 DOI:10.1007/s11227-024-06411-3

Pablo Revuelta-Sanz, Antonio J. Muñoz-Montoro, Juan Torre-Cruz, Francisco J. Canadas-Quesada, José Ranilla

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Abstract

The accurate estimation of respiratory rate (RR) is crucial for assessing the respiratory system’s health in humans, particularly during auscultation processes. Despite the numerous automated RR estimation approaches proposed in the literature, challenges persist in accurately estimating RR in noisy environments, typical of real-life situations. This becomes especially critical when periodic noise patterns interfere with the target signal. In this study, we present a parallel driver designed to address the challenges of RR estimation in real-world environments, combining multi-core architectures with parallel and high-performance techniques. The proposed system employs a nonnegative matrix factorization (NMF) approach to mitigate the impact of noise interference in the input signal. This NMF approach is guided by pre-trained bases of respiratory sounds and incorporates an orthogonal constraint to enhance accuracy. The proposed solution is tailored for real-time processing on low-power hardware. Experimental results across various scenarios demonstrate promising outcomes in terms of accuracy and computational efficiency.

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基于 NMF 的呼吸频率估计并行算法的抗噪算法

准确估计呼吸频率（RR）对于评估人类呼吸系统的健康状况至关重要，尤其是在听诊过程中。尽管文献中提出了许多自动呼吸频率估算方法，但在现实生活中典型的噪声环境中准确估算呼吸频率仍面临挑战。当周期性噪声模式干扰目标信号时，这一点就变得尤为重要。在本研究中，我们提出了一种并行驱动程序，旨在解决真实环境中 RR 估计所面临的挑战，将多核架构与并行和高性能技术相结合。所提出的系统采用非负矩阵因式分解（NMF）方法来减轻输入信号中噪声干扰的影响。这种非负矩阵因式分解方法以预先训练好的呼吸声为基础，并结合了正交约束来提高准确性。所提出的解决方案适合在低功耗硬件上进行实时处理。各种场景下的实验结果表明，该方法在准确性和计算效率方面都取得了可喜的成果。

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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The Journal of Supercomputing

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