Lattice sieving via quantum random walks
Abstract
Lattice-based cryptography is one of the leading proposals for post-quantum cryptography. The Shortest Vector Problem (SVP) is arguably the most important problem for the cryptanalysis of lattice-based cryptography, and many lattice-based schemes have security claims based on its hardness. The best quantum algorithm for the SVP is due to Laarhoven [Laa16 PhD] and runs in (heuristic) time . In this article, we present an improvement over Laarhoven's result and present an algorithm that has a (heuristic) running time of where is the lattice dimension. We also present time-memory trade-offs where we quantify the amount of quantum memory and quantum random access memory of our algorithm. The core idea is to replace Grover's algorithm used in [Laa16 PhD] in a key part of the sieving algorithm by a quantum random walk in which we add a layer of local sensitive filtering.
Cite
@article{arxiv.2105.05608,
title = {Lattice sieving via quantum random walks},
author = {André Chailloux and Johanna Loyer},
journal= {arXiv preprint arXiv:2105.05608},
year = {2021}
}