Fischer机器学习在电子医疗系统中使用区块链机制进行移动云计算

IF 1.9 4区 计算机科学 Q3 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE Microprocessors and Microsystems Pub Date : 2023-11-01 DOI:10.1016/j.micpro.2023.104969
Nithya Rekha Sivakumar , Sara Abdelwahab Ghorashi , Nada Ahmed , Hafiza Elbadie Ahmed Elsrej , Shakila Basheer
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引用次数: 0

摘要

电子医疗(eHealth)系统能够在电子健康记录(EHRs)中确保有效的护理工程和增强的医疗质量,这些都是用户友好的缓存和管理。为了确保基于移动云的电子医疗系统的安全,确保高安全性和数据隐私,星际文件系统在医疗保健领域一直是传统的重点。然而,最近一直在推动实现高质量的电子医疗服务,因为基于区块链的医疗保健应用需要在网络延迟和端到端延迟等要求方面提供QoS保证。在这项工作中,提出了一种基于扩展验证认证的Fischer神经网络优化(EVC-FNNO)方法,用于安全的基于移动云的电子医疗系统。身份作为数字证书,EVC向在网络中进行交易的移动云用户提供身份。通过这种方式,确保移动云用户能够访问交易的分类账。因此,数据隐私和安全都被认为是提供的。接下来,通过Fischer Neural Network Optimization (FNNO),每个通过EVC认证的移动云用户都拥有一份共享账本副本,从而解决云服务器上的数据采集问题,从而解决网络延迟问题。通过实例验证了该方法在QoS寻址中的有效性。实证结果表明,EVC-FNNO方法通过数字证书对移动云用户的敏感健康信息进行验证,提供了一种有效的解决方案。安全性分析证明EVC-FNNO方法是安全的。我们还进行了综合性能评估,与现有的数据共享方法相比,EVC-FNNO方法在端到端延迟、网络延迟和数据隐私方面具有很高的效率。
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Fischer machine learning for mobile cloud computing in eHealth systems using blockchain mechanism

The Electronic Healthcare (eHealth) systems are competent to ensure effective care engineering and intensified healthcare quality which are user-friendly cache and administration, in Electronic Health Records (EHRs). For secure EHRs of Mobile Cloud-based eHealth systems, ensuring high security and data privacy, Interplanetary File System in healthcare has traditionally been concentrated. However, there has been a recent push towards achieving high quality of e-health services because blockchain-based health care applications require QoS guarantees in terms of requirements such as network latency and end-to-end delay. In this work, an Extended Validation Certification-based Fischer Neural Network Optimization (EVC-FNNO) method for secured Mobile Cloud-based E-Health Systems is proposed. With the identity being the digital certificate, the EVC is provided with the identity to the mobile cloud user who will transact in the network. In this way, the mobile cloud user is being ensured to access the ledger for the transaction. Therefore, both data privacy and security is said to be provided. Next, with Fischer Neural Network Optimization (FNNO), every authenticated mobile cloud user via EVC then possess a copy of shared ledger, therefore resolving data acquisition in cloud server and hence solving network latency. The proposed method is verified by some demonstrative examples in addressing QoS. The empirical results show that the EVC-FNNO method provides an efficient solution by validating the mobile cloud user sensitive health information with digital certificate. Security analysis proves that the EVC-FNNO method is secure. We also conduct comprehensive performance evaluations that demonstrate the high efficiency of the EVC-FNNO method in terms of end-to-end delay, network latency and data privacy, compared to the existing data sharing methods.

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来源期刊
Microprocessors and Microsystems
Microprocessors and Microsystems 工程技术-工程:电子与电气
CiteScore
6.90
自引率
3.80%
发文量
204
审稿时长
172 days
期刊介绍: Microprocessors and Microsystems: Embedded Hardware Design (MICPRO) is a journal covering all design and architectural aspects related to embedded systems hardware. This includes different embedded system hardware platforms ranging from custom hardware via reconfigurable systems and application specific processors to general purpose embedded processors. Special emphasis is put on novel complex embedded architectures, such as systems on chip (SoC), systems on a programmable/reconfigurable chip (SoPC) and multi-processor systems on a chip (MPSoC), as well as, their memory and communication methods and structures, such as network-on-chip (NoC). Design automation of such systems including methodologies, techniques, flows and tools for their design, as well as, novel designs of hardware components fall within the scope of this journal. Novel cyber-physical applications that use embedded systems are also central in this journal. While software is not in the main focus of this journal, methods of hardware/software co-design, as well as, application restructuring and mapping to embedded hardware platforms, that consider interplay between software and hardware components with emphasis on hardware, are also in the journal scope.
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