Search of clustered marked states with lackadaisical quantum walks

“…We note that l = 4/N is the degree of the loopless graph divided by the total number of vertices, i.e., d/N , since d = 4. With multiple marked vertices [20][21][22], it is no longer true that d/N is the best value of l.…”

“…More recent results have disproved this speculation, however. Search on the torus with multiple marked vertices [20][21][22], and search on the complete bipartite graph with one or more marked vertices [23], indicate that l should not be the degree centrality at each vertex. In this paper, our observation is specifically restricted to vertex-transitive graphs with a single marked vertex, where the observation does seem to hold.…”

“…Search using the lackadaisical quantum walk has been explored on the complete graph [16], discrete torus with one marked vertex [19] and multiple marked vertices [20][21][22], cycle [22], and complete bipartite graph [23]. Depending on the weight of the self-loop l, the success probability can be improved.…”

Search on Vertex-Transitive Graphs by Lackadaisical Quantum Walk

“…We note that l = 4/N is the degree of the loopless graph divided by the total number of vertices, i.e., d/N , since d = 4. With multiple marked vertices [20][21][22], it is no longer true that d/N is the best value of l.…”

“…More recent results have disproved this speculation, however. Search on the torus with multiple marked vertices [20][21][22], and search on the complete bipartite graph with one or more marked vertices [23], indicate that l should not be the degree centrality at each vertex. In this paper, our observation is specifically restricted to vertex-transitive graphs with a single marked vertex, where the observation does seem to hold.…”

“…Search using the lackadaisical quantum walk has been explored on the complete graph [16], discrete torus with one marked vertex [19] and multiple marked vertices [20][21][22], cycle [22], and complete bipartite graph [23]. Depending on the weight of the self-loop l, the success probability can be improved.…”

Search on Vertex-Transitive Graphs by Lackadaisical Quantum Walk

“…(N − 1) + M + (N − M )From the denominator of the overall coefficient, for large N ,N (N − 1) + M + (N − M ) ≈ N 2 .Then, for large N ,(12) …”

“…Later, the unweighted self-loops at each vertex were replaced by a single self-loop of real-valued weight at each vertex, such that if is an integer, it is equivalent to the original definition of integer self-loops per vertex [10]. This generalization to real-valued weights led to speedups for spatial search on a variety of graphs, including the discrete torus with one marked vertex [11] and multiple marked vertices [12][13][14][15][16], periodic square lattices of arbitrary dimension [17,18], strongly regular graphs [18], Johnson graphs [18], the hypercube [18], regular locally arc-transitive graphs [19], the triangular lattice [20], and the honeycomb lattice [20]. All of these graphs are vertex transitive, meaning they have symmetries such that each vertex has the same structure.…”

Search by Lackadaisical Quantum Walk with Symmetry Breaking

Lackadaisical Quantum Walks with Multiple Marked Vertices