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利用联合数据差异技术和多实例集成感知器学习增强用于患者健康监测的可穿戴传感器数据分析。

Enhancing wearable sensor data analysis for patient health monitoring using allied data disparity technique and multi instance ensemble perceptron learning.

作者信息

Anjum Mohd, Ahmad Waseem, Shahab Sana, Dutta Ashit Kumar, Elrashidi Ali, Yousef Amr, Shaikh Zaffar Ahmed

机构信息

Department of Computer Engineering, Aligarh Muslim University, Aligarh, 202002, India.

Department of Computer Science and Engineering, Vishveshwarya Group of Institutions (VGI), Gautam Buddha Nagar, Greater Noida, 201314, Uttar Pradesh, India.

出版信息

Sci Rep. 2025 Aug 12;15(1):29555. doi: 10.1038/s41598-025-08051-w.

DOI:10.1038/s41598-025-08051-w
PMID:40796786
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12343896/
Abstract

Wearable Sensor (WS)-based monitoring systems detect minute patient movements/ demands and abnormalities through periodic sensing and imaging. Sensor data observed over different intervals is not constant or available based on operating sequences. Due to variations in data sequences, the analysis process becomes complex, resulting in less precise outputs. To address this problem, an Allied Data Disparity Technique (ADDT) is proposed in this article. This technique identifies the disparity in different monitoring sequences in coherence with the clinical and previous values. Based on the mean disparity, the data requirement for the WS sequence is decided. This decision uses multiple substituted and predicted values obtained from previous instances. Multi-Instance Ensemble Perceptron Learning is used in this decision process, where the substitution instances for clinical and previous outcomes are performed. The ensemble perceptron selects the maximum clinical value correlating sensor data to ensure high sequence prediction. The ensembles are updated based on the highest precision-based WS values for diagnosis. This diagnosis-focused coalition between clinical and predicted WS values is updated periodically for the new precision levels identified.

摘要

基于可穿戴传感器(WS)的监测系统通过定期传感和成像来检测患者的细微动作、需求及异常情况。在不同时间间隔内观测到的传感器数据并非恒定不变,也并非根据操作顺序随时可用。由于数据序列存在变化,分析过程变得复杂,导致输出结果不够精确。为解决这一问题,本文提出了一种联合数据差异技术(ADDT)。该技术结合临床和先前值来识别不同监测序列中的差异。基于平均差异,确定WS序列的数据需求。此决策使用从先前实例中获得的多个替代值和预测值。在这个决策过程中使用多实例集成感知器学习,其中对临床和先前结果进行替代实例操作。集成感知器选择与传感器数据相关的最大临床值,以确保高序列预测。根据用于诊断的基于最高精度的WS值更新集成。针对新确定的精度水平,定期更新临床和预测WS值之间这种以诊断为重点的联合。

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Dev Cogn Neurosci. 2024 Oct;69:101446. doi: 10.1016/j.dcn.2024.101446. Epub 2024 Sep 13.
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