Efficient parallelization of quantum basis state shift
Abstract
Basis state shift is central to many quantum algorithms, most notably the quantum walk. Efficient implementations are of major importance for achieving a quantum speedup for computational applications. We optimize the state shift algorithm by incorporating the shift in different directions in parallel. This provides a significant reduction in the depth of the quantum circuit in comparison to the currently known methods, giving a linear scaling in the number of gates versus working qubits in contrast to the quadratic scaling of the state-of-the-art method based on the quantum Fourier transform. For a one-dimensional array of size for , we derive the total number of two-qubit gates in the parallel circuit, using a total of qubits including an ancilla register for the decomposition of multi-controlled gates. We focus on the one-dimensional and periodic shift, but note that the method can be extended to more complex cases.
Cite
@article{arxiv.2304.01704,
title = {Efficient parallelization of quantum basis state shift},
author = {Ljubomir Budinski and Ossi Niemimäki and Roberto Zamora-Zamora and Valtteri Lahtinen},
journal= {arXiv preprint arXiv:2304.01704},
year = {2023}
}