The Deutsch-Jozsa Problem: De-quantisation and Entanglement
Abstract
The Deustch-Jozsa problem is one of the most basic ways to demonstrate the power of quantum computation. Consider a Boolean function f : {0,1}^n to {0,1} and suppose we have a black-box to compute f. The Deutsch-Jozsa problem is to determine if f is constant (i.e. f(x) = const forall x in {0,1}^n) or if f is balanced (i.e. f(x) = 0 for exactly half the possible input strings x in {0,1}^n) using as few calls to the black-box computing f as is possible, assuming f is guaranteed to be constant or balanced. Classically it appears that this requires at least 2^{n-1}+1 black-box calls in the worst case, but the well known quantum solution solves the problem with probability one in exactly one black-box call. It has been found that in some cases the algorithm can be de-quantised into an equivalent classical, deterministic solution. We explore the ability to extend this de-quantisation to further cases, and examine with more detail when de-quantisation is possible, both with respect to the Deutsch-Jozsa problem, as well as in more general cases.
Cite
@article{arxiv.0910.1990,
title = {The Deutsch-Jozsa Problem: De-quantisation and Entanglement},
author = {Alastair A. Abbott},
journal= {arXiv preprint arXiv:0910.1990},
year = {2022}
}
Comments
17 pages. Presented at the Workshop on Physics and Computation at the conference 'Unconventional Computation 2009'. To Be published in workshop proceedings