Discrete Quantum Walks with Marked Vertices and Their Average Vertex Mixing Matrices
Abstract
We study the discrete quantum walk on a regular graph X that assigns negative identity coins to marked vertices S and Grover coins to the unmarked ones. We find combinatorial bases for the eigenspaces of the transtion matrix, and derive a formula for the average vertex mixing matrix . We then find bounds for entries in , and study when these bounds are tight. In particular, the average probabilities between marked vertices are lower bounded by a matrix determined by the induced subgraph X[S], the vertex-deleted subgraph X S, and the edge deleted subgraph X-E(S). We show this bound is achieved if and only if the marked vertices have walk-equitable neighborhoods in the vertex-deleted subgraph. Finally, for quantum walks attaining this bound, we determine when [S,S] is symmetric, positive semidefinite or uniform.
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