具有可依法执行的公平性的安全多方计算

IF 2.4 4区计算机科学 Q3 COMPUTER SCIENCE, INFORMATION SYSTEMS International Journal of Information Security Pub Date : 2024-08-29 DOI:10.1007/s10207-024-00898-w

Takeshi Nakai, Kazumasa Shinagawa

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引用次数: 0

摘要

公平性是安全计算的一个安全概念，在标准设置中，如果对手破坏了大多数计算方，公平性就不一定能实现。Lindell（CT-RSA，2008 年）表明，对对手施加金钱惩罚可以规避这种不可能性。他将这种安全概念正式表述为基于理想可信银行功能的 "法律上可强制执行的公平性"，并展示了一种可满足要求的协议。基于同样的框架，我们介绍了具有可依法强制执行的公平性的安全多方计算，它适用于任意数量的计算方。此外，我们还提出了两个协议来实现我们介绍的功能。第一个协议实现了 O(n) 轮和 \(O(n \alpha )\) 费用，其中 n 是当事人的数量，而 \(\alpha \) 是惩罚金额的参数。费用指的是协议开始时所需的银行存款余额，它从财务意义上评估了参与协议的难度。第二种实现了 O(1) 轮和 \(O(n^2 \alpha )\) 费用。

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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Secure multi-party computation with legally-enforceable fairness

Fairness is a security notion of secure computation and cannot always be achieved if an adversary corrupts a majority of parties in standard settings. Lindell (CT-RSA 2008) showed that imposing a monetary penalty on an adversary can circumvent the impossibility. He formalized such a security notion as “legally enforceable fairness" for the two-party setting based on the ideal trusted bank functionality and showed a protocol achieving the requirements. Based on the same framework, we introduce secure multi-party computation with legally enforceable fairness that is applicable for an arbitrary number of parties. Further, we propose two protocols that realize our introduced functionality. The first one achieves O(n) rounds and \(O(n \alpha )\) fees, where n is the number of parties, and \(\alpha \) is a parameter for the penalty amount. The fee refers to the balance amount in the bank required at the beginning of the protocol, which evaluates the difficulty of participating in the protocol in a financial sense. The second one achieves O(1) rounds and \(O(n^2 \alpha )\) fees.

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来源期刊

International Journal of Information Security 工程技术-计算机：理论方法

CiteScore

6.30

自引率

3.10%

发文量

审稿时长

12 months

期刊介绍： The International Journal of Information Security is an English language periodical on research in information security which offers prompt publication of important technical work, whether theoretical, applicable, or related to implementation. Coverage includes system security: intrusion detection, secure end systems, secure operating systems, database security, security infrastructures, security evaluation; network security: Internet security, firewalls, mobile security, security agents, protocols, anti-virus and anti-hacker measures; content protection: watermarking, software protection, tamper resistant software; applications: electronic commerce, government, health, telecommunications, mobility.