Ida Tucker scite author profile

Ida Tucker

2Publications

52Citation Statements Received

22Citation Statements Given

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IMDEA Software, Claude Bernard University Lyon 1, École Normale Supérieure de Lyon

Publications

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Practical Fully Secure Unrestricted Inner Product Functional Encryption Modulo p

Castagnos

Laguillaumie

Tucker

2018

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Functional encryption is a modern public-key cryptographic primitive allowing an encryptor to finely control the information revealed to recipients from a given ciphertext. Abdalla, Bourse, De Caro, and Pointcheval (PKC 2015) were the first to consider functional encryption restricted to the class of linear functions, i.e. inner products. Though their schemes are only secure in the selective model, Agrawal, Libert, and Stehlé (CRYPTO 16) soon provided adaptively secure schemes for the same functionality. These constructions, which rely on standard assumptions such as the Decision Diffie-Hellman (DDH), the Learning-with-Errors (LWE), and Paillier's Decision Composite Residuosity (DCR) problems, do however suffer of various practical drawbacks. Namely, the DCR based scheme only computes inner products modulo an RSA integer which is oversized for many practical applications, while the computation of inner products modulo a prime p either requires, for their (DDH) based scheme, that the inner product be contained in a sufficiently small interval for decryption to be efficient, or, as in the LWE based scheme, suffers of poor efficiency due to impractical parameters. In this paper, we provide adaptively secure functional encryption schemes for the inner product functionality which are both efficient and allow for the evaluation of unbounded inner products modulo a prime p. Our constructions rely on new natural cryptographic assumptions in a cyclic group containing a subgroup where the discrete logarithm (DL) problem is easy which extend Castagnos and Laguillaumie's assumption (RSA 2015) of a DDH group with an easy DL subgroup. Instantiating our generic construction using class groups of imaginary quadratic fields gives rise to the most efficient functional encryption for inner products modulo an arbitrary large prime p. One of our schemes outperforms the DCR variant of Agrawal et al.'s protocols in terms of size of keys and ciphertexts by factors varying between 2 and 20 for a 112-bit security.

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Bandwidth-Efficient Threshold EC-DSA

Castagnos

Catalano

Laguillaumie

et al. 2020

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Threshold Signatures allow n parties to share the power of issuing digital signatures so that any coalition of size at least t+1 can sign, whereas groups of t or less players cannot. Over the last few years many schemes addressed the question of realizing efficient threshold variants for the specific case of EC-DSA signatures. In this paper we present new solutions to the problem that aim at reducing the overall bandwidth consumption. Our main contribution is a new variant of the Gennaro and Goldfeder protocol from ACM CCS 2018 that avoids all the required range proofs, while retaining provable security against malicious adversaries in the dishonest majority setting. Our experiments show that-for all levels of security-our signing protocol reduces the bandwidth consumption of best previously known secure protocols for factors varying between 4.4 and 9, while key generation is consistently two times less expensive. Furthermore compared to these same protocols, our signature generation is faster for 192-bits of security and beyond.

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Ida Tucker

Practical Fully Secure Unrestricted Inner Product Functional Encryption Modulo p

Bandwidth-Efficient Threshold EC-DSA

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