Exponential separations for one-way quantum communication complexity, with applications to cryptography
Abstract
We give an exponential separation between one-way quantum and classical communication protocols for a partial Boolean function (a variant of the Boolean Hidden Matching Problem of Bar-Yossef et al.) Earlier such an exponential separation was known only for a relational problem. The communication problem corresponds to a \emph{strong extractor} that fails against a small amount of \emph{quantum} information about its random source. Our proof uses the Fourier coefficients inequality of Kahn, Kalai, and Linial. We also give a number of applications of this separation. In particular, we show that there are privacy amplification schemes that are secure against classical adversaries but not against quantum adversaries; and we give the first example of a key-expansion scheme in the model of bounded-storage cryptography that is secure against classical memory-bounded adversaries but not against quantum ones.
Cite
@article{arxiv.quant-ph/0611209,
title = {Exponential separations for one-way quantum communication complexity, with applications to cryptography},
author = {Dmytro Gavinsky and Julia Kempe and Iordanis Kerenidis and Ran Raz and Ronald de Wolf},
journal= {arXiv preprint arXiv:quant-ph/0611209},
year = {2022}
}
Comments
16 pages, improved version, supersedes quant-ph/0607173 and quant-ph/0607174 although some proofs are different