面向物联网边缘计算的基于弗兰克-沃尔夫学习和迪里夏特-高斯邻域的安全认证

IF 3.3 4区 计算机科学 Q2 COMPUTER SCIENCE, INFORMATION SYSTEMS
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引用次数: 0

摘要

摘要 随着物联网(IoT)的发展,许多用户通过传感器参与到不同的应用中。在物联网边缘计算系统中选择最机密的用户或传感器仍然是首要问题。在这种情况下,终端用户和边缘服务器都有可能是恶意或受损的传感器。在识别和隔离恶意终端用户或边缘服务器方面已有多项研究成果。我们的工作主要集中在物联网边缘服务器的安全方面。我们利用弗兰克-沃尔夫最优服务请求(FWOSR)算法来评估逻辑回归模型的边界或极限,其中线性近似下的凸问题是针对权重稀疏性(即多个用户请求竞争最近的边缘服务器)求解的,以避免在监督机器学习过程中出现过度拟合。我们设计了弗兰克-沃尔夫监督机器学习(FWSL)技术来选择最佳边缘服务器,并进一步最小化用户请求与边缘服务器之间的计算和通信成本。接下来,我们提出了云网络中基于位置服务的 Dirichlet Gaussian Blocked Gibbs Vicinity 认证模型。在这里,基于接收信号强度指示器(RSSI)、MAC 地址和数据包到达时间的邻域认证得以实现。这样,通过在邻近测试中引入高斯函数,提高了认证准确性,并通过考虑多个位置,提供了灵活的邻近范围控制。仿真和实验还验证了计算成本、通信成本、时间复杂性和检测错误率。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Secured Frank Wolfe learning and Dirichlet Gaussian Vicinity based authentication for IoT edge computing

Abstract

With the evolution of the Internet of Things (IoT) several users take part in different applications via sensors. The foremost confront here remains in selecting the most confidential users or sensors in the edge computing system of the IoT. Here, both the end-users and the edge servers are likely to be malicious or compromised sensors. Several works have been contributed to identifying and isolating the malicious end-users or edge servers. Our work concentrates on the security aspects of edge servers of IoT. The Frank-Wolfe Optimal Service Requests (FWOSR) algorithm is utilized to evaluate the boundaries or limits of the logistic regression model, in which the convex problem under a linear approximation is solved for weight sparsity (i.e. several user requests competing for closest edge server) to avoid over-fitting in the supervised machine learning process. We design a Frank Wolfe Supervised Machine Learning (FWSL) technique to choose an optimal edge server and further minimize the computational and communication costs between the user requests and the edge server. Next, Dirichlet Gaussian Blocked Gibbs Vicinity-based Authentication model for location-based services in Cloud networks is proposed. Here, the vicinity-based authentication is implemented based on Received Signal Strength Indicators (RSSI), MAC address and packet arrival time. With this, the authentication accuracy is improved by introducing the Gaussian function in the vicinity test and provides flexible vicinity range control by taking into account multiple locations. Simulation and experiment are also conducted to validate the computational cost, communication cost, time complexity and detection error rate.

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来源期刊
Peer-To-Peer Networking and Applications
Peer-To-Peer Networking and Applications COMPUTER SCIENCE, INFORMATION SYSTEMS-TELECOMMUNICATIONS
CiteScore
8.00
自引率
7.10%
发文量
145
审稿时长
12 months
期刊介绍: The aim of the Peer-to-Peer Networking and Applications journal is to disseminate state-of-the-art research and development results in this rapidly growing research area, to facilitate the deployment of P2P networking and applications, and to bring together the academic and industry communities, with the goal of fostering interaction to promote further research interests and activities, thus enabling new P2P applications and services. The journal not only addresses research topics related to networking and communications theory, but also considers the standardization, economic, and engineering aspects of P2P technologies, and their impacts on software engineering, computer engineering, networked communication, and security. The journal serves as a forum for tackling the technical problems arising from both file sharing and media streaming applications. It also includes state-of-the-art technologies in the P2P security domain. Peer-to-Peer Networking and Applications publishes regular papers, tutorials and review papers, case studies, and correspondence from the research, development, and standardization communities. Papers addressing system, application, and service issues are encouraged.
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