Two-party quantum cryptography

两方量子密码学

• 批准号: 356101-2009
• 负责人: Salvail, Louis
• 金额: $ 1.75万
• 依托单位: Université de Montréal
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2014
• 资助国家: 加拿大
• 起止时间: 2014-01-01 至 2015-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=549926
• 关键词: Two; party; quantum; cryptography

In 1984, Bennett and Brassard proposed a scheme allowing two parties to agree on a secret key provided they have access to a channel capable of transmitting quantum bits. This scheme, called quantum key distribution, is remarkable since it achieves something impossible through classical means alone. Until the mid 90's quantum information appeared to be cryptographers' best friend. Expectations were that all modern cryptographic applications could be resolved unconditionally using quantum communication whereas classical cryptography could only hope for security relying upon unproven computational assumptions out of which the majority do not hold against quantum adversaries. One essential class of cryptographic applications are the ones involving two parties willing to collaborate but otherwise not trusting each other. Many daily electronic transactions are of that kind, making two-party cryptography a critical tool for the information age. An example is our frequent interactions with ATMs asking us to identify ourselves before being granted access to our bank account. In 1995, Mayers and Lo & Chau shattered this dream when they prove that the most important cryptographic primitives for two-party cryptography cannot be implemented securely using quantum communication. On the other hand, quantum protocols have been found for weak two-party primitives otherwise impossible using classical communication alone. Unlike for key distribution, the capabilities of quantum cryptography in the two-party setting are not well understood. The project's main goal is to provide a deeper understanding for the true power of quantum cryptography in two-party applications. Improving our insight on what it can achieve in this setting could have important consequences for the design of systems providing security in electronic transactions. New systems inspired by this research could offer privacy more efficiently and under weaker assumptions. Even entirely classical protocols could benefit from this work by extending the realm of their security to adversaries in possession of quantum computers. Any satisfactory advance toward our main objective would improve our comprehension of the differences between classical and quantum information.

在1984年，班尼特和贝纳德提出了一个方案，允许双方同意一个秘密密钥，只要他们能够访问一个能够传输量子比特的信道。这个被称为量子密钥分发的方案非常引人注目，因为它实现了仅通过经典手段不可能实现的事情。直到90年代中期，量子信息似乎是密码学家最好的朋友。人们的期望是，所有现代密码学应用都可以使用量子通信无条件地解决，而经典密码学只能希望安全性依赖于未经证明的计算假设，其中大多数都不适用于量子对手。加密应用程序的一个基本类别是涉及愿意合作但彼此不信任的两方的应用程序。许多日常的电子交易都是这种类型的，使得双方密码学成为信息时代的关键工具。一个例子是我们经常与自动取款机互动，要求我们在被授予访问我们的银行账户之前识别自己。1995年，Mayer和Lo & Chau打破了这个梦想，他们证明了两方密码学中最重要的密码原语不能使用量子通信安全地实现。另一方面，量子协议已被发现用于弱两方原语，否则单独使用经典通信是不可能的。与密钥分发不同，量子密码学在两方环境中的能力还没有得到很好的理解。该项目的主要目标是更深入地了解量子密码学在双方应用中的真正力量。提高我们的洞察力，它可以实现在这种情况下，可以有重要的影响，系统的设计，提供安全的电子交易。受这项研究启发的新系统可以在更弱的假设下更有效地提供隐私。即使是完全经典的协议也可以从这项工作中受益，将其安全领域扩展到拥有量子计算机的对手。在我们的主要目标方面取得的任何令人满意的进展都将提高我们对经典信息和量子信息之间差异的理解。