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Autori principali: Votto, Matteo, Zeiher, Johannes, Vermersch, Benoît
Natura: Preprint
Pubblicazione: 2023
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Accesso online:https://arxiv.org/abs/2311.10600
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author Votto, Matteo
Zeiher, Johannes
Vermersch, Benoît
author_facet Votto, Matteo
Zeiher, Johannes
Vermersch, Benoît
contents We propose a protocol to realize quantum simulation and computation in spin systems with long-range interactions. Our approach relies on the local addressing of single spins with external fields parametrized by Walsh functions. This enables a mapping from a class of target Hamiltonians, defined by the graph structure of their interactions, to pulse sequences. We then obtain a recipe to implement arbitrary two-body Hamiltonians and universal quantum circuits. Performance guarantees are provided in terms of bounds on Trotter errors and total number of pulses. Additionally, Walsh pulse sequences are shown to be robust against various types of pulse errors, in contrast to previous hybrid digital-analog schemes of quantum computation. We demonstrate and numerically benchmark our protocol with examples from the dynamics of spin models, quantum error correction and quantum optimization algorithms.
format Preprint
id arxiv_https___arxiv_org_abs_2311_10600
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Universal quantum processors in spin systems via robust local pulse sequences
Votto, Matteo
Zeiher, Johannes
Vermersch, Benoît
Quantum Physics
Quantum Gases
We propose a protocol to realize quantum simulation and computation in spin systems with long-range interactions. Our approach relies on the local addressing of single spins with external fields parametrized by Walsh functions. This enables a mapping from a class of target Hamiltonians, defined by the graph structure of their interactions, to pulse sequences. We then obtain a recipe to implement arbitrary two-body Hamiltonians and universal quantum circuits. Performance guarantees are provided in terms of bounds on Trotter errors and total number of pulses. Additionally, Walsh pulse sequences are shown to be robust against various types of pulse errors, in contrast to previous hybrid digital-analog schemes of quantum computation. We demonstrate and numerically benchmark our protocol with examples from the dynamics of spin models, quantum error correction and quantum optimization algorithms.
title Universal quantum processors in spin systems via robust local pulse sequences
topic Quantum Physics
Quantum Gases
url https://arxiv.org/abs/2311.10600