Quantum Hardcore Functions by Complexity-Theoretical Quantum List Decoding
Abstract
Hardcore functions have been used as a technical tool to construct secure cryptographic systems; however, little is known on their quantum counterpart, called quantum hardcore functions. With a new insight into fundamental properties of quantum hardcores, we present three new quantum hardcore functions for any (strong) quantum one-way function. We also give a "quantum" solution to Damgard's question (CRYPTO'88) on a classical hardcore property of his pseudorandom generator, by proving its quantum hardcore property. Our major technical tool is the new notion of quantum list-decoding of "classical" error-correcting codes (rather than "quantum" error-correcting codes), which is defined on the platform of computational complexity theory and computational cryptography (rather than information theory). In particular, we give a simple but powerful criterion that makes a polynomial-time computable classical block code (seen as a function) a quantum hardcore for all quantum one-way functions. On their own interest, we construct efficient quantum list-decoding algorithms for classical block codes whose associated quantum states (called codeword states) form a nearly phase-orthogonal basis.
Cite
@article{arxiv.quant-ph/0602088,
title = {Quantum Hardcore Functions by Complexity-Theoretical Quantum List Decoding},
author = {Akinori Kawachi and Tomoyuki Yamakami},
journal= {arXiv preprint arXiv:quant-ph/0602088},
year = {2010}
}
Comments
25 pages, 10 point, letter size. This is a revised version of the complete version of a conference paper that appeared in the Proceedings of the 33rd International Colloquium on Automata, Languages and Programming (ICALP 2006), Lecture Notes in Computer Science, Vol.4052 (Part II), pp.216-227. Venice, Italy. July 10-14, 2006