Lattice-Based Self-Enhancement Authorized Accessible Privacy Authentication for Cyber-Physical Systems

Secur. Commun. Networks Pub Date : 2022-02-09 DOI:10.1155/2022/8995704

Jinhui Liu, Yong Yu, Houzhen Wang, Huanguo Zhang

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引用次数: 1

Abstract

Healthcare cyber-physical system significantly facilitates healthcare services and patient treatment effectiveness by analyzing patients’ health information data conveniently. Nevertheless, it also develops the threats to the confidentiality of health information, patients’ privacy, and decidability of medical disputes. And, with the advances of quantum computing technology, most existing anonymous authentication schemes are becoming a growing threat to traditional cryptosystems. To address these problems, for healthcare cyber-physical systems, we propose a new lattice-based self-enhancement authorized accessible privacy authentication scheme by using a strong designated verifier double-authentication-preventing signature technique, called SEAPA. The SEAPA achieves three security and privacy requirements including unforgeability, anonymity for patients’ information, and self-enhancement for patients themselves. A detailed security proof shows our proposal achieves those required security goals. Finally, our construction is demonstrated by parameter analysis and performance evaluation to have reasonable efficiency.

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基于格子的网络物理系统自增强授权可访问隐私认证

医疗信息物理系统通过对患者健康信息数据的便捷分析，极大地促进了医疗服务和患者的治疗效果。然而，它也对健康信息的保密性、患者的隐私和医疗纠纷的可判定性构成威胁。而且，随着量子计算技术的进步，大多数现有的匿名认证方案正在对传统的密码系统构成越来越大的威胁。为了解决这些问题，对于医疗保健网络物理系统，我们提出了一种新的基于格的自增强授权可访问隐私身份验证方案，该方案使用强指定验证者双重身份验证防止签名技术，称为SEAPA。SEAPA实现了不可伪造性、患者信息匿名性、患者自我增强等三个安全和隐私要求。详细的安全性证明表明我们的建议达到了所需的安全性目标。最后，通过参数分析和性能评价，证明了我们的结构具有合理的效率。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Secur. Commun. Networks

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