A mathematical framework for maze solving using quantum walks
Abstract
We provide a mathematical framework for identifying the shortest path in a maze using a Grover walk, which becomes non-unitary by introducing absorbing holes. In this study, we define the maze as a network with vertices connected by unweighted edges. Our analysis of the stationary state of the Grover walk on finite graphs, where we strategically place absorbing holes and self-loops on specific vertices, demonstrates that this approach can effectively solve mazes. By setting arbitrary start and goal vertices in the underlying graph, we obtain the following long-time results: (i) in tree structures, the probability amplitude is concentrated exclusively along the shortest path between start and goal; (ii) in ladder-like structures with additional paths, the probability amplitude is maximized near the shortest path.
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Cite
@article{arxiv.2411.12191,
title = {A mathematical framework for maze solving using quantum walks},
author = {Leo Matsuoka and Hiromichi Ohno and Etsuo Segawa},
journal= {arXiv preprint arXiv:2411.12191},
year = {2024}
}
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19 pages