Quantum learning and universal quantum matching machine
摘要
Suppose that three kinds of quantum systems are given in some unknown states , , and , and we want to decide which \textit{template} state or , each representing the feature of the pattern class or , respectively, is closest to the input \textit{feature} state . This is an extension of the pattern matching problem into the quantum domain. Assuming that these states are known a priori to belong to a certain parametric family of pure qubit systems, we derive two kinds of matching strategies. The first is a semiclassical strategy which is obtained by the natural extension of conventional matching strategies and consists of a two-stage procedure: identification (estimation) of the unknown template states to design the classifier (\textit{learning} process to train the classifier) and classification of the input system into the appropriate pattern class based on the estimated results. The other is a fully quantum strategy without any intermediate measurement which we might call as the {\it universal quantum matching machine}. We present the Bayes optimal solutions for both strategies in the case of K=1, showing that there certainly exists a fully quantum matching procedure which is strictly superior to the straightforward semiclassical extension of the conventional matching strategy based on the learning process.
引用
@article{arxiv.quant-ph/0202173,
title = {Quantum learning and universal quantum matching machine},
author = {Masahide Sasaki and Alberto Carlini},
journal= {arXiv preprint arXiv:quant-ph/0202173},
year = {2009}
}
备注
11 pages, RevTeX, 3 figures