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引用次数: 0
摘要
如今,物联网(IoT)和物联网平台已广泛应用于多个医疗保健领域。物联网设备在医疗保健领域产生了大量数据,这些数据可以在物联网平台上进行检测。本文开发了一种新型算法,名为基于人工植物群优化的变色龙蜂群算法(AFO-based CSA),用于优化路径查找。本文提出的基于 AFO 的 CSA 是将人工植物群优化(AFO)集成到变色龙群算法(CSA)中得出的。这种集成是指基于 AFO 的 CSA 模型增强了 AFO 和 CSA 的优势和特点,从而实现物联网中医疗数据的优化路由。此外,所提出的基于 AFO 的 CSA 算法考虑了能量、延迟和距离等因素,以实现有效的数据路由。在 BS 阶段,通过基于 AFO 的 CSA 训练的递归神经网络进行预测、预处理、特征降维、采用皮尔逊相关性和疾病检测等阶段。实验结果表明,基于 AFO 的 CSA 在能耗(0.538 J)、准确性(0.950)、灵敏度(0.965)和特异性(0.937)方面均优于其他竞争方法。
Optimization-enabled deep learning model for disease detection in IoT platform.
Nowadays, Internet of things (IoT) and IoT platforms are extensively utilized in several healthcare applications. The IoT devices produce a huge amount of data in healthcare field that can be inspected on an IoT platform. In this paper, a novel algorithm, named artificial flora optimization-based chameleon swarm algorithm (AFO-based CSA), is developed for optimal path finding. Here, data are collected by the sensors and transmitted to the base station (BS) using the proposed AFO-based CSA, which is derived by integrating artificial flora optimization (AFO) in chameleon swarm algorithm (CSA). This integration refers to the AFO-based CSA model enhancing the strengths and features of both AFO and CSA for optimal routing of medical data in IoT. Moreover, the proposed AFO-based CSA algorithm considers factors such as energy, delay, and distance for the effectual routing of data. At BS, prediction is conducted, followed by stages, like pre-processing, feature dimension reduction, adopting Pearson's correlation, and disease detection, done by recurrent neural network, which is trained by the proposed AFO-based CSA. Experimental result exhibited that the performance of the proposed AFO-based CSA is superior to competitive approaches based on the energy consumption (0.538 J), accuracy (0.950), sensitivity (0.965), and specificity (0.937).
期刊介绍:
Network: Computation in Neural Systems welcomes submissions of research papers that integrate theoretical neuroscience with experimental data, emphasizing the utilization of cutting-edge technologies. We invite authors and researchers to contribute their work in the following areas:
Theoretical Neuroscience: This section encompasses neural network modeling approaches that elucidate brain function.
Neural Networks in Data Analysis and Pattern Recognition: We encourage submissions exploring the use of neural networks for data analysis and pattern recognition, including but not limited to image analysis and speech processing applications.
Neural Networks in Control Systems: This category encompasses the utilization of neural networks in control systems, including robotics, state estimation, fault detection, and diagnosis.
Analysis of Neurophysiological Data: We invite submissions focusing on the analysis of neurophysiology data obtained from experimental studies involving animals.
Analysis of Experimental Data on the Human Brain: This section includes papers analyzing experimental data from studies on the human brain, utilizing imaging techniques such as MRI, fMRI, EEG, and PET.
Neurobiological Foundations of Consciousness: We encourage submissions exploring the neural bases of consciousness in the brain and its simulation in machines.
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