Secure data collection and transmission for IoMT architecture integrated with federated learning

IF 0.6 Q4 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS
Priyanka kumari Bhansali, Dilendra Hiran, K. Gulati
{"title":"Secure data collection and transmission for IoMT architecture integrated with federated learning","authors":"Priyanka kumari Bhansali, Dilendra Hiran, K. Gulati","doi":"10.1108/ijpcc-02-2022-0042","DOIUrl":null,"url":null,"abstract":"\nPurpose\nThe purpose of this paper is to secure health data collection and transmission (SHDCT). In this system, a native network consists of portable smart devices that interact with multiple gateways. It entails IoMT devices and wearables connecting to exchange sensitive data with a sensor node which performs the aggeration process and then communicates the data using a Fog server. If the aggregator sensor loses the connection from the Fog server, it will be unable to submit data directly to the Fog server. The node transmits encrypted information with a neighboring sensor and sends it to the Fog server integrated with federated learning, which encrypts data to the existing data. The fog server performs the operations on the measured data, and the values are stored in the local storage area and later it is updated to the cloud server.\n\n\nDesign/methodology/approach\nSHDCT uses an Internet-of-things (IoT)-based monitoring network, making it possible for smart devices to connect and interact with each other. The main purpose of the monitoring network has been in the collection of biological data and additional information from mobile devices to the patients. The monitoring network is composed of three different types of smart devices that is at the heart of the IoT.\n\n\nFindings\nIt has been addressed in this work how to design an architecture for safe data aggregation in heterogeneous IoT-federated learning-enabled wireless sensor networks (WSNs), which makes use of basic encoding and data aggregation methods to achieve this. The authors suggest that the small gateway node (SGN) captures all of the sensed data from the SD and uses a simple, lightweight encoding scheme and cryptographic techniques to convey the data to the gateway node (GWN). The GWN gets all of the medical data from SGN and ensures that the data is accurate and up to date. If the data obtained is trustworthy, then the medical data should be aggregated and sent to the Fog server for further processing. The Java programming language simulates and analyzes the proposed SHDCT model for deployment and message initiation. When comparing the SHDCT scheme to the SPPDA and electrohydrodynamic atomisation (EHDA) schemes, the results show that the SHDCT method performs significantly better. When compared with the SPPDA and EHDA schemes, the suggested SHDCT plan necessitates a lower communication cost. In comparison to EHDA and SPPDA, SHDCT achieves 4.72% and 13.59% less, respectively. When compared to other transmission techniques, SHDCT has a higher transmission ratio. When compared with EHDA and SPPDA, SHDCT achieves 8.47% and 24.41% higher transmission ratios, respectively. When compared with other ways it uses less electricity. When compared with EHDA and SPPDA, SHDCT achieves 5.85% and 18.86% greater residual energy, respectively.\n\n\nOriginality/value\nIn the health care sector, a series of interconnected medical devices collect data using IoT networks in the health care domain. Preventive, predictive, personalized and participatory care is becoming increasingly popular in the health care sector. Safe data collection and transfer to a centralized server is a challenging scenario. This study presents a mechanism for SHDCT. The mechanism consists of Smart healthcare IoT devices working on federated learning that link up with one another to exchange health data. Health data is sensitive and needs to be exchanged securely and efficiently. In the mechanism, the sensing devices send data to a SGN. This SGN uses a lightweight encoding scheme and performs cryptography techniques to communicate the data with the GWN. The GWN gets all the health data from the SGN and makes it possible to confirm that the data is validated. If the received data is reliable, then aggregate the medical data and transmit it to the Fog server for further process. The performance parameters are compared with the other systems in terms of communication costs, transmission ratio and energy use.\n","PeriodicalId":43952,"journal":{"name":"International Journal of Pervasive Computing and Communications","volume":null,"pages":null},"PeriodicalIF":0.6000,"publicationDate":"2022-05-19","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"2","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"International Journal of Pervasive Computing and Communications","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1108/ijpcc-02-2022-0042","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q4","JCRName":"COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS","Score":null,"Total":0}
引用次数: 2

Abstract

Purpose The purpose of this paper is to secure health data collection and transmission (SHDCT). In this system, a native network consists of portable smart devices that interact with multiple gateways. It entails IoMT devices and wearables connecting to exchange sensitive data with a sensor node which performs the aggeration process and then communicates the data using a Fog server. If the aggregator sensor loses the connection from the Fog server, it will be unable to submit data directly to the Fog server. The node transmits encrypted information with a neighboring sensor and sends it to the Fog server integrated with federated learning, which encrypts data to the existing data. The fog server performs the operations on the measured data, and the values are stored in the local storage area and later it is updated to the cloud server. Design/methodology/approach SHDCT uses an Internet-of-things (IoT)-based monitoring network, making it possible for smart devices to connect and interact with each other. The main purpose of the monitoring network has been in the collection of biological data and additional information from mobile devices to the patients. The monitoring network is composed of three different types of smart devices that is at the heart of the IoT. Findings It has been addressed in this work how to design an architecture for safe data aggregation in heterogeneous IoT-federated learning-enabled wireless sensor networks (WSNs), which makes use of basic encoding and data aggregation methods to achieve this. The authors suggest that the small gateway node (SGN) captures all of the sensed data from the SD and uses a simple, lightweight encoding scheme and cryptographic techniques to convey the data to the gateway node (GWN). The GWN gets all of the medical data from SGN and ensures that the data is accurate and up to date. If the data obtained is trustworthy, then the medical data should be aggregated and sent to the Fog server for further processing. The Java programming language simulates and analyzes the proposed SHDCT model for deployment and message initiation. When comparing the SHDCT scheme to the SPPDA and electrohydrodynamic atomisation (EHDA) schemes, the results show that the SHDCT method performs significantly better. When compared with the SPPDA and EHDA schemes, the suggested SHDCT plan necessitates a lower communication cost. In comparison to EHDA and SPPDA, SHDCT achieves 4.72% and 13.59% less, respectively. When compared to other transmission techniques, SHDCT has a higher transmission ratio. When compared with EHDA and SPPDA, SHDCT achieves 8.47% and 24.41% higher transmission ratios, respectively. When compared with other ways it uses less electricity. When compared with EHDA and SPPDA, SHDCT achieves 5.85% and 18.86% greater residual energy, respectively. Originality/value In the health care sector, a series of interconnected medical devices collect data using IoT networks in the health care domain. Preventive, predictive, personalized and participatory care is becoming increasingly popular in the health care sector. Safe data collection and transfer to a centralized server is a challenging scenario. This study presents a mechanism for SHDCT. The mechanism consists of Smart healthcare IoT devices working on federated learning that link up with one another to exchange health data. Health data is sensitive and needs to be exchanged securely and efficiently. In the mechanism, the sensing devices send data to a SGN. This SGN uses a lightweight encoding scheme and performs cryptography techniques to communicate the data with the GWN. The GWN gets all the health data from the SGN and makes it possible to confirm that the data is validated. If the received data is reliable, then aggregate the medical data and transmit it to the Fog server for further process. The performance parameters are compared with the other systems in terms of communication costs, transmission ratio and energy use.
集成联邦学习的IoMT架构的安全数据收集和传输
本文的目的是为了保证健康数据的收集和传输(SHDCT)。在该系统中,本机网络由可与多个网关交互的便携式智能设备组成。它需要连接IoMT设备和可穿戴设备,与执行聚合过程的传感器节点交换敏感数据,然后使用Fog服务器进行数据通信。如果聚合器传感器失去了与Fog服务器的连接,它将无法直接向Fog服务器提交数据。节点与相邻传感器传输加密信息,并将其发送到集成了联邦学习的Fog服务器,该服务器将数据加密到现有数据。雾服务器对测量数据进行操作,测量值存储在本地存储区域,然后更新到云服务器。设计/方法/方法shdct使用基于物联网(IoT)的监控网络,使智能设备能够相互连接和交互。监测网络的主要目的是从移动设备向患者收集生物数据和附加信息。监控网络由三种不同类型的智能设备组成,它们是物联网的核心。本研究讨论了如何在异构物联网联合学习无线传感器网络(wsn)中设计一种安全数据聚合的架构,该架构利用基本编码和数据聚合方法来实现这一目标。作者建议小网关节点(SGN)捕获来自SD的所有感知数据,并使用简单,轻量级的编码方案和加密技术将数据传输到网关节点(GWN)。GWN从SGN获取所有医疗数据,并确保数据的准确性和最新性。如果获得的数据是可信的,则应该聚合医疗数据并将其发送到Fog服务器进行进一步处理。Java编程语言模拟并分析了建议的SHDCT模型,用于部署和消息初始化。将SHDCT方法与SPPDA和EHDA方法进行比较,结果表明SHDCT方法的性能明显优于SPPDA方法。与SPPDA和EHDA方案相比,建议的SHDCT方案需要更低的通信成本。与EHDA和SPPDA相比,SHDCT分别降低了4.72%和13.59%。与其他传输技术相比,SHDCT具有更高的传输率。与EHDA和SPPDA相比,SHDCT的传动比分别提高了8.47%和24.41%。与其他方式相比,它使用更少的电力。与EHDA和SPPDA相比,SHDCT的剩余能量分别提高了5.85%和18.86%。在医疗保健领域,一系列相互连接的医疗设备使用医疗保健领域的物联网网络收集数据。预防性、预测性、个性化和参与性保健在保健部门日益普及。安全的数据收集和传输到集中式服务器是一个具有挑战性的场景。本研究提出了SHDCT的发病机制。该机制由智能医疗物联网设备组成,这些设备致力于联合学习,相互连接以交换健康数据。健康数据非常敏感,需要安全有效地交换。在该机制中,传感设备向SGN发送数据。该SGN使用轻量级编码方案,并执行加密技术与GWN进行数据通信。GWN从SGN获取所有运行状况数据,并确认数据已经过验证。如果接收到的数据是可靠的,则聚合医疗数据并将其传输到Fog服务器以进行进一步处理。从通信成本、传输率和能耗等方面与其他系统进行了性能参数比较。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
求助全文
约1分钟内获得全文 求助全文
来源期刊
International Journal of Pervasive Computing and Communications
International Journal of Pervasive Computing and Communications COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS-
CiteScore
6.60
自引率
0.00%
发文量
54
×
引用
GB/T 7714-2015
复制
MLA
复制
APA
复制
导出至
BibTeX EndNote RefMan NoteFirst NoteExpress
×
提示
您的信息不完整,为了账户安全,请先补充。
现在去补充
×
提示
您因"违规操作"
具体请查看互助需知
我知道了
×
提示
确定
请完成安全验证×
copy
已复制链接
快去分享给好友吧!
我知道了
右上角分享
点击右上角分享
0
联系我们:info@booksci.cn Book学术提供免费学术资源搜索服务,方便国内外学者检索中英文文献。致力于提供最便捷和优质的服务体验。 Copyright © 2023 布克学术 All rights reserved.
京ICP备2023020795号-1
ghs 京公网安备 11010802042870号
Book学术文献互助
Book学术文献互助群
群 号:481959085
Book学术官方微信