Average Mixing in Quantum Walks of Reversible Markov Chains
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The Szegedy quantum walk is a discrete time quantum walk model which defines a quantum analogue of any Markov chain. The long-term behavior of the quantum walk can be encoded in a matrix called the average mixing matrix, whose columns give the limiting probability distribution of the walk given an initial state. We define a version of the average mixing matrix of the Szegedy quantum walk which allows us to more readily compare the limiting behavior to that of the chain it quantizes. We prove a formula for our mixing matrix in terms of the spectral decomposition of the Markov chain and show a relationship with the mixing matrix of a continuous quantum walk on the chain. In particular, we prove that average uniform mixing in the continuous walk implies average uniform mixing in the Szegedy walk. We conclude by giving examples of Markov chains of arbitrarily large size which admit average uniform mixing in both the continuous and Szegedy quantum walk.
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Cited by 2 Pith papers
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Quantum Fast-Forwarding Beyond Reversibility: The $\alpha$-Perturbed $n$-Cycle
Exact Chebyshev QFF does not extend to the α-perturbed n-cycle for α ≠ 0 due to eigenvalues outside [-1,1], but a truncated-Chebyshev LCU approximation achieves degree O(|α|t + √(t log(t/η))) that recovers the reversi...
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Quantum Fast-Forwarding Beyond Reversibility: The $\alpha$-Perturbed $n$-Cycle
Exact Chebyshev-based quantum fast-forwarding does not extend beyond reversible Markov chains, but a truncated Chebyshev plus LCU approximation works for the α-perturbed n-cycle with degree O(|α|t + sqrt(t log(t/η))).
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