Olivier Sanders scite author profile

Abstract. Digital signature is a fundamental primitive with numerous applications. Following the development of pairing-based cryptography, several taking advantage of this setting have been proposed. Among them, the Camenisch-Lysyanskaya (CL) signature scheme is one of the most flexible and has been used as a building block for many other protocols. Unfortunately, this scheme suffers from a linear size in the number of messages to be signed which limits its use in many situations. In this paper, we propose a new signature scheme with the same features as CL-signatures but without the linear-size drawback: our signature consists of only two elements, whatever the message length, and our algorithms are more efficient. This construction takes advantage of using type 3 pairings, that are already widely used for security and efficiency reasons. We prove the security of our scheme without random oracles but in the generic group model. Finally, we show that protocols using CL-signatures can easily be instantiated with ours, leading to much more efficient constructions.

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Pattern Matching on Encrypted Streams

Desmoulins

Fouque

Onete

et al. 2018

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Divisible e‐cash made practical

Canard

Pointcheval

Sanders

et al. 2016

IET Information Security

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International audienceDivisible e-cash systems allow users to withdraw a unique coin of value 2 n units from a bank, but then to spend it in several times to distinct merchants. In such a system, whereas users want anonymity of their transactions, the bank wants to prevent, or at least detect, double-spending, and trace defrauders. While this primitive was introduced two decades ago, quite a few (really) anonymous constructions have been proposed. In addition, all but one were just proven secure in the random oracle model, but still with either weak security models or quite complex settings and thus costly constructions. The unique proposal, secure in the standard model, appeared recently and is unpractical. As evidence, the authors left the construction of an efficient scheme secure in this model as an open problem. In this study, the authors answer it with the first efficient divisible e-cash system secure in the standard model. It is based on a new way of building the coins, with a unique and public global tree structure for all the coins. Actually, they propose two constructions which offer a tradeoff between efficiency and security. They both achieve constant time for withdrawing and spending amounts of 2ℓ units, while allowing the bank to quickly detect double-spendings by a simple comparison of the serial numbers of deposited coins to the ones of previously spent coins

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Efficient Redactable Signature and Application to Anonymous Credentials

Sanders

2020

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Olivier Sanders

Short Randomizable Signatures

Pattern Matching on Encrypted Streams

Divisible e‐cash made practical

Efficient Redactable Signature and Application to Anonymous Credentials

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