Abstract. Blind signatures (BS), introduced by Chaum, have become a cornerstone in privacy-oriented cryptography. Using hard lattice problems, such as the shortest vector problem, as the basis of security has advantages over using the factoring or discrete logarithm problems. For instance, lattice operations are more efficient than modular exponentiation and lattice problems remain hard for quantum and subexponential-time adversaries. Generally speaking, BS allow a signer to sign a message without seeing it, while retaining a certain amount of control over the process. In particular, the signer can control the number of issued signatures. For the receiver of the signature, this process provides perfect anonymity, e.g., his spendings remain anonymous when using BS for electronic money. We provide a positive answer to the question of whether it is possible to implement BS based on lattice problems. More precisely, we show how to turn Lyubashevsky's identification scheme into a BS scheme, which has almost the same efficiency and security in the random oracle model. In particular, it offers quasi-linear complexity, statistical blindness, and its unforgeability is based on the hardness of worst-case lattice problems with an approximation factor of O(n 5 ) in dimension n. Moreover, it is the first blind signature scheme that supports leakage-resilience, tolerating leakage of a (1 − o(1)) fraction of the secret key in a model that is inspired by Katz and Vaikuntanathan.
Abstract. We propose a variant of the "bonsai tree" signature scheme, a lattice-based existentially unforgeable signature scheme in the standard model. Our construction offers the same efficiency as the "bonsai tree" scheme but supports the stronger notion of strong unforgeability. Strong unforgeability demands that the adversary is unable to produce a new message-signature pair (m, s), even if he or she is allowed to see a different signature s for m. In particular, we provide the first treeless signature scheme that supports strong unforgeability for the post-quantum era in the standard model. Moreover, we show how to directly implement identity-based, and even hierarchical identity-based, signatures (IBS) in the same strong security model without random oracles. An additional advantage of this direct approach over the usual generic conversion of hierarchical identity-based encryption to IBS is that we can exploit the efficiency of ideal lattices without significantly harming security. We equip all constructions with strong security proofs based on mild worst-case assumptions on lattices and we also propose concrete security parameters.
Abstract. Anonymous authentication schemes such as group signatures and anonymous credentials are important privacy-protecting tools in electronic communications. The only currently known scheme based on assumptions that resist quantum attacks is the group signature scheme by Gordon et al. (ASIACRYPT 2010). We present a generalization of group signatures called anonymous attribute tokens where users are issued attribute-containing credentials that they can use to anonymously sign messages and generate tokens revealing only a subset of their attributes. We present two lattice-based constructions of this new primitive, one with and one without opening capabilities for the group manager. The latter construction directly yields as a special case the first lattice-based group signature scheme offering full anonymity (in the random-oracle model), as opposed to the practically less relevant notion of chosen-plaintext anonymity offered by the scheme of Gordon et al. We also extend our scheme to protect users from framing attacks by the group manager, where the latter creates tokens or signatures in the name of honest users. Our constructions involve new lattice-based tools for aggregating signatures and verifiable CCA2-secure encryption.
Abstract. We show that the Winternitz one-time signature scheme is existentially unforgeable under adaptive chosen message attacks when instantiated with a family of pseudo random functions. Compared to previous results, which require a collision resistant hash function, our result provides significantly smaller signatures at the same security level. We also consider security in the strong sense and show that the Winternitz one-time signature scheme is strongly unforgeable assuming additional properties of the pseudo random function. In this context we formally define several key-based security notions for function families and investigate their relation to pseudorandomness. All our reductions are exact and in the standard model and can directly be used to estimate the output length of the hash function required to meet a certain security level.
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