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oai:recercat.cat:10230/422572025-12-24T08:59:30Zcom_2072_6col_2072_452952

00925njm 22002777a 4500 dc Escala, Alex author Herold, Gottfried author Kiltz, Eike author Ràfols, Carla author Villar, Jorge L. author 2019-09-10T13:32:53Z 2019-09-10T13:32:53Z 2013 Comunicació presentada a: CRYPTO 2013 The 33rd Annual Cryptology Conference, celebrada del 18 al 22 d'agost de 2013 a Santa Bàrbara, Califòrnia, Estats Units d'Amèrica. We put forward a new algebraic framework to generalize and analyze Di_e-Hellman like Decisional Assumptions which allows us to argue about security and applications by considering only algebraic properties. Our D`;k-MDDH assumption states that it is hard to decide whether a vector in G` is linearly dependent of the columns of some matrix in G`_k sampled according to distribution D`;k. It covers known assumptions such as DDH, 2-Lin (linear assumption), and k-Lin (the k-linear assumption). Using our algebraic viewpoint, we can relate the generic hardness of our assumptions in m-linear groups to the irreducibility of certain polynomials which describe the output of D`;k. We use the hardness results to _nd new distributions for which the D`;k-MDDH-Assumption holds generically in m-linear groups. In particular, our new assumption 2-SCasc is generically hard in bilinear groups and, compared to 2-Lin, has shorter description size, which is a relevant parameter for e_ciency in many applications. These results support using our new assumption as a natural replacement for the 2-Lin Assumption which was already used in a large number of applications. To illustrate the conceptual advantages of our algebraic framework, we construct several fundamental primitives based on any MDDH-Assumption. In particular, we can give many instantiations of a primitive in a compact way, including public-key encryption, hash-proof systems, pseudo-random functions, and Groth-Sahai NIZK and NIWI proofs. As an independent contribution we give more e_cient NIZK proofs for membership in a subgroup of G`, for validity of ciphertexts and for equality of plaintexts. The results imply very signi_cant e_ciency improvements for a large number of schemes, most notably Naor-Yung type of constructions. Funded by a Sofja Kovalevskaja Award of the Alexander von Humboldt Foundation and the German Federal Ministry for Education and Research. Partially supported by the Spanish Government through projects MTM2009-07694 and Consolider Ingenio 2010 CDS2007-00004 ARES. Diffie-Hellman assumption Generic hardness Groth-Sahai proofs Hash proof systems Public-key encryption An algebraic framework for Diffie-Hellman assumptions