Bounds on quantum ordered searching
Abstract
We prove that any exact quantum algorithm searching an ordered list of N elements requires more than \frac{1}{\pi}(\ln(N)-1) queries to the list. This improves upon the previously best known lower bound of {1/12}\log_2(N) - O(1). Our proof is based on a weighted all-pairs inner product argument, and it generalizes to bounded-error quantum algorithms. The currently best known upper bound for exact searching is roughly 0.526 \log_2(N). We give an exact quantum algorithm that uses \log_3(N) + O(1) queries, which is roughly 0.631 \log_2(N). The main principles in our algorithm are an quantum parallel use of the classical binary search algorithm and a method that allows basis states in superpositions to communicate.
Cite
@article{arxiv.quant-ph/0009032,
title = {Bounds on quantum ordered searching},
author = {Peter Hoyer and Jan Neerbek},
journal= {arXiv preprint arXiv:quant-ph/0009032},
year = {2007}
}
Comments
This paper has been merged with another paper. See quant-ph/0102078. Except for this comment v2 is unchanged compared to v1. 12 pages, 1 figure