A Robust PPG Heart Rate Estimation Network Based on Frequency-Domain NLMS and Dual-Stream Hierarchical Self-Attention

محتوى المقالة الرئيسي

Shuli Shang
Yong Li

الملخص

The heart rate estimation based on the wearables' photoplethysmography (PPG) sensor always faces serious motion artefacts (MA) under high-intensity exercise. Although adaptive filtering and deep learning methods have demonstrated effectiveness in practice so far; currently, there are problems such as system divergence under the influence of strong power signals, poor generalization due to insufficiently trained high-heart-rate sample sets. The main deficiencies in the existing systems are as follows: Filter instability due to significant noise; The coupling of physiological and motion variables; Imbalanced datasets. To solve the above-mentioned problems, a full-ended design of frequency-domain signal processing and deep neural networks is proposed. Through an energy-normalized NLMS adaptive filter to establish the system's absolute stability constraint condition, in conjunction with a dual-stream multiple-head self-attention (MHSA) mechanism for controllably managing features weights; Moreover, by incorporating a specific data augmentation strategy. On the Public PPG-DaLiA dataset, this built network achieves an average absolute error of 1.81 beats per minute (BPM). Based on the results, a feasible approach can be used in clinical practice to improve the credibility of wearable device applications by providing reasonable uncertainly ranges.

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تفاصيل المقالة

القسم

Articles

كيفية الاقتباس

A Robust PPG Heart Rate Estimation Network Based on Frequency-Domain NLMS and Dual-Stream Hierarchical Self-Attention. (2026). International Conference on Energy, Intelligence Systems, and Cloud Computing (Ingenio 2026), 1(1). https://ingeniot.uclm.es/editorial/index.php/ingenio26/article/view/31

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الأعمال الأكثر قراءة لنفس المؤلف/المؤلفين

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