HAWKFOG--适用于雾-物联网环境的增强型深度学习框架。

IF 3 Q2 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE Frontiers in Artificial Intelligence Pub Date : 2024-06-28 eCollection Date: 2024-01-01 DOI:10.3389/frai.2024.1354742
R Abirami, Poovammal E
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引用次数: 0

摘要

心脏病被认为是最致命的疾病之一,会不断增加全球的死亡率。由于准确预测心脏病需要大量的专业知识,因此设计心脏疾病智能预测系统仍然复杂而棘手。基于物联网的健康监管系统是一项相对较新的技术。此外,还提出了新颖的边缘和雾设备概念,以推进预测结果。然而,当前系统的主要问题是预测能力差,无法满足有效诊断系统的需求。为了克服这一问题,本研究提出了一种名为 HAWKFOGS 的新型框架,该框架创新性地整合了深度学习,利用边缘和雾计算设备对心脏问题进行实用诊断。当前的数据集是从使用与心电图和血压传感器连接的物联网设备的不同受试者处收集的。然后使用基于逻辑混沌的哈里斯-霍克优化增强门控循环神经网络预测数据的正常和异常。消融实验是使用与医疗传感器连接的物联网节点和基于嵌入式 Jetson Nano 设备的雾网关进行的。对建议算法的性能进行了测量。此外,还计算了模型构建时间,以验证建议模型的响应。与其他算法相比,建议的模型在准确率(99.7%)、精确率(99.65%)、召回率(99.7%)和特异性(99.7%)方面取得了最佳结果。F1-分数(99.69%)和模型构建时间(1.16 秒)方面都是最少的。
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HAWKFOG-an enhanced deep learning framework for the Fog-IoT environment.

Cardiac disease is considered as the one of the deadliest diseases that constantly increases the globe's mortality rate. Since a lot of expertise is required for an accurate prediction of heart disease, designing an intelligent predictive system for cardiac diseases remains to be complex and tricky. Internet of Things based health regulation systems are a relatively recent technology. In addition, novel Edge and Fog device concepts are presented to advance prediction results. However, the main problem with the current systems is that they are unable to meet the demands of effective diagnosis systems due to their poor prediction capabilities. To overcome this problem, this research proposes a novel framework called HAWKFOGS which innovatively integrates the deep learning for a practical diagnosis of cardiac problems using edge and fog computing devices. The current datasets were gathered from different subjects using IoT devices interfaced with the electrocardiography and blood pressure sensors. The data are then predicted as normal and abnormal using the Logistic Chaos based Harris Hawk Optimized Enhanced Gated Recurrent Neural Networks. The ablation experiments are carried out using IoT nodes interfaced with medical sensors and fog gateways based on Embedded Jetson Nano devices. The suggested algorithm's performance is measured. Additionally, Model Building Time is computed to validate the suggested model's response. Compared to the other algorithms, the suggested model yielded the best results in terms of accuracy (99.7%), precision (99.65%), recall (99.7%), specificity (99.7%). F1-score (99.69%) and used the least amount of Model Building Time (1.16 s) to predict cardiac diseases.

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来源期刊
CiteScore
6.10
自引率
2.50%
发文量
272
审稿时长
13 weeks
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