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Autori principali: Tosta, Allan, Silva, Thais de Lima, Camilo, Giancarlo, Aolita, Leandro
Natura: Preprint
Pubblicazione: 2023
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Accesso online:https://arxiv.org/abs/2307.11824
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author Tosta, Allan
Silva, Thais de Lima
Camilo, Giancarlo
Aolita, Leandro
author_facet Tosta, Allan
Silva, Thais de Lima
Camilo, Giancarlo
Aolita, Leandro
contents We present a hybrid quantum-classical framework for simulating generic matrix functions more amenable to early fault-tolerant quantum hardware than standard quantum singular-value transformations. The method is based on randomization over the Chebyshev approximation of the target function while keeping the matrix oracle quantum, and is assisted by a variant of the Hadamard test that removes the need for post-selection. The resulting statistical overhead is similar to the fully quantum case and does not incur any circuit depth degradation. On the contrary, the average circuit depth is shown to get smaller, yielding equivalent reductions in noise sensitivity, as explicitly shown for depolarizing noise and coherent errors. We apply our technique to partition-function estimation, linear system solvers, and ground-state energy estimation. For these cases, we prove advantages on average depths, including quadratic speed-ups on costly parameters and even the removal of the approximation-error dependence.
format Preprint
id arxiv_https___arxiv_org_abs_2307_11824
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Randomized semi-quantum matrix processing
Tosta, Allan
Silva, Thais de Lima
Camilo, Giancarlo
Aolita, Leandro
Quantum Physics
We present a hybrid quantum-classical framework for simulating generic matrix functions more amenable to early fault-tolerant quantum hardware than standard quantum singular-value transformations. The method is based on randomization over the Chebyshev approximation of the target function while keeping the matrix oracle quantum, and is assisted by a variant of the Hadamard test that removes the need for post-selection. The resulting statistical overhead is similar to the fully quantum case and does not incur any circuit depth degradation. On the contrary, the average circuit depth is shown to get smaller, yielding equivalent reductions in noise sensitivity, as explicitly shown for depolarizing noise and coherent errors. We apply our technique to partition-function estimation, linear system solvers, and ground-state energy estimation. For these cases, we prove advantages on average depths, including quadratic speed-ups on costly parameters and even the removal of the approximation-error dependence.
title Randomized semi-quantum matrix processing
topic Quantum Physics
url https://arxiv.org/abs/2307.11824