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Auteur principal: Garcia-Escartin, Juan Carlos
Format: Preprint
Publié: 2023
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Accès en ligne:https://arxiv.org/abs/2311.13543
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author Garcia-Escartin, Juan Carlos
author_facet Garcia-Escartin, Juan Carlos
contents This paper presents a hybrid variational quantum algorithm that finds a random eigenvector of a unitary matrix with a known quantum circuit. The algorithm is based on the SWAP test on trial states generated by a parametrized quantum circuit. The eigenvector is described by a compact set of classical parameters that can be used to reproduce the found approximation to the eigenstate on demand. This variational eigenvector finder can be adapted to solve the generalized eigenvalue problem, to find the eigenvectors of normal matrices and to perform quantum principal component analysis (QPCA) on unknown input mixed states. These algorithms can all be run with low depth quantum circuits, suitable for an efficient implementation on noisy intermediate state quantum computers (NISQC) and, with some restrictions, on linear optical systems. Limitations and potential applications are discussed.
format Preprint
id arxiv_https___arxiv_org_abs_2311_13543
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Finding eigenvectors with a quantum variational algorithm
Garcia-Escartin, Juan Carlos
Quantum Physics
This paper presents a hybrid variational quantum algorithm that finds a random eigenvector of a unitary matrix with a known quantum circuit. The algorithm is based on the SWAP test on trial states generated by a parametrized quantum circuit. The eigenvector is described by a compact set of classical parameters that can be used to reproduce the found approximation to the eigenstate on demand. This variational eigenvector finder can be adapted to solve the generalized eigenvalue problem, to find the eigenvectors of normal matrices and to perform quantum principal component analysis (QPCA) on unknown input mixed states. These algorithms can all be run with low depth quantum circuits, suitable for an efficient implementation on noisy intermediate state quantum computers (NISQC) and, with some restrictions, on linear optical systems. Limitations and potential applications are discussed.
title Finding eigenvectors with a quantum variational algorithm
topic Quantum Physics
url https://arxiv.org/abs/2311.13543