Maxime Plançon scite author profile

Maxime Plançon

3Publications

18Citation Statements Received

26Citation Statements Given

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IBM Research - Zurich, ETH Zurich, École Normale Supérieure Paris-Saclay

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On the Shortness of Vectors to Be Found by the Ideal-SVP Quantum Algorithm

Ducas

Plançon

Wesolowski

2019

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The hardness of finding short vectors in ideals of cyclotomic number fields (hereafter, Ideal-SVP) can serve as a worst-case assumption for numerous efficient cryptosystems, via the average-case problems Ring-SIS and Ring-LWE. For a while, it could be assumed the Ideal-SVP problem was as hard as the analog problem for general lattices (SVP), even when considering quantum algorithms. But in the last few years, a series of works has lead to a quantum algorithm for Ideal-SVP that outperforms what can be done for general SVP in certain regimes. More precisely, it was demonstrated (under certain hypotheses) that one can find in quantum polynomial time a vector longer by a factor at most α = exp( O(n 1/2 )) than the shortest non-zero vector in a cyclotomic ideal lattice, where n is the dimension. In this work, we explore the constants hidden behind this asymptotic claim. While these algorithms have quantum steps, the steps that impact the approximation factor α are entirely classical, which allows us to estimate it experimentally using only classical computing. Moreover, we design heuristic improvements for those steps that significantly decrease the hidden factors in practice. Finally, we derive new provable effective lower bounds based on volumetric arguments. This study allows to predict the crossover point with classical lattice reduction algorithms, and thereby determine the relevance of this quantum algorithm in any cryptanalytic context. For example we predict that this quantum algorithm provides shorter vectors than BKZ-300 (roughly the weakest security level of NIST lattice-based candidates) for cyclotomic rings of rank larger than about 24000.

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Efficient Lattice-Based Blind Signatures via Gaussian One-Time Signatures

Lyubashevsky

Nguyen

Plançon

2022

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Lattice-Based Zero-Knowledge Proofs and Applications: Shorter, Simpler, and More General

Lyubashevsky

Nguyen

Plançon

2022

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Maxime Plançon

On the Shortness of Vectors to Be Found by the Ideal-SVP Quantum Algorithm

Efficient Lattice-Based Blind Signatures via Gaussian One-Time Signatures

Lattice-Based Zero-Knowledge Proofs and Applications: Shorter, Simpler, and More General

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