LEGA: A Lightweight and Efficient Group Authentication Protocol for Massive Machine Type Communication in 5G Networks
查看参考文献24篇
文摘
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Massive machine type communication (mMTC) is anticipated to be an essential part of fifth generation (5G) networks. The main challenge for mMTC devices (mMTCDs) is the design of an access authentication scheme that can fulfill the security and privacy requirements of 5G applications, which have specific conditions, including rigorous latency and simultaneous access. Thus, a novel 5G authentication and key agreement (5G-AKA) protocol was introduced by the 3rd generation partnership project (3GPP) to achieve mMTCD access authentication. However, 5G-AKA protocol comes with some security vulnerabilities and significant delay for real-time mMTC applications, particularly when mMTCDs concurrently roam into new networks. In order to address the real-time secure and efficient access issues of multiple mMTCDs, this paper proposes a lightweight and efficient group authentication protocol for mMTC in 5G wireless networks. The proposed protocol, which integrates bilinear maps and an aggregate certificateless signature mechanism, can achieve several security goals, including avoidance of signaling congestion in the authentication process, mutual authentication, session key agreement,perfect forward/backward secrecy, and masked attack and key escrow resistance. Compared to existing conventional protocols, the proposed protocol demonstrates robust security and improved performance in terms of signaling cost authentication, bandwidth consumption and computational cost. |
来源
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Journal of Communications and Information Networks
,2020,5(4):457-466 【核心库】
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DOI
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10.23919/JCIN.2020.9306019
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关键词
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5G,group authentication
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mMTC
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roaming
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privacy
;
security
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地址
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Department of Information Technology and Security,Jazan University, Saudi Arabia
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语种
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英文 |
文献类型
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研究性论文 |
ISSN
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2096-1081 |
学科
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电子技术、通信技术 |
文献收藏号
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CSCD:6870899
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24
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