Quantum walk search on a two-dimensional grid with extra edges
Abstract
Quantum walk has been successfully used to search for targets on graphs with vertices identified as the elements of a database. This spacial search on a two-dimensional periodic grid takes O(N N) oracle consultations to find a target vertex from N number of vertices with O(1) success probability, while reaching optimal speed of O(N) on d ≥ 3 dimensional square lattice. Our numerical analysis based on lackadaisical quantum walks searches M vertices on a 2-dimensional grid with optimal speed of O(N/M), provided the grid is attached with additional long range edges. Based on the numerical analysis performed with multiple sets of randomly generated targets for a wide range of N and M we suggest that the optimal time complexity of O(N/M) with constant success probability can be achieved for quantum search on a two-dimensional periodic grid with long-range edges.
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