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Main Authors: Vetrano, Marco, Monaco, Gabriele Lo, Innocenti, Luca, Lorenzo, Salvatore, Palma, G. Massimo
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2409.06782
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author Vetrano, Marco
Monaco, Gabriele Lo
Innocenti, Luca
Lorenzo, Salvatore
Palma, G. Massimo
author_facet Vetrano, Marco
Monaco, Gabriele Lo
Innocenti, Luca
Lorenzo, Salvatore
Palma, G. Massimo
contents Quantum extreme learning machines (QELMs) leverage untrained quantum dynamics to efficiently process information encoded in input quantum states, avoiding the high computational cost of training more complicated nonlinear models. On the other hand, quantum information scrambling (QIS) quantifies how the spread of quantum information into correlations makes it irretrievable from local measurements. Here, we explore the tight relation between QIS and the predictive power of QELMs. In particular, we show efficient state estimation is possible even beyond the scrambling time, for many different types of dynamics -- in fact, we show that in all the cases we studied, the reconstruction efficiency at long interaction times matches the optimal one offered by random global unitary dynamics. These results offer promising venues for robust experimental QELM-based state estimation protocols, as well as providing novel insights into the nature of QIS from a state estimation perspective.
format Preprint
id arxiv_https___arxiv_org_abs_2409_06782
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle State estimation with quantum extreme learning machines beyond the scrambling time
Vetrano, Marco
Monaco, Gabriele Lo
Innocenti, Luca
Lorenzo, Salvatore
Palma, G. Massimo
Quantum Physics
Quantum extreme learning machines (QELMs) leverage untrained quantum dynamics to efficiently process information encoded in input quantum states, avoiding the high computational cost of training more complicated nonlinear models. On the other hand, quantum information scrambling (QIS) quantifies how the spread of quantum information into correlations makes it irretrievable from local measurements. Here, we explore the tight relation between QIS and the predictive power of QELMs. In particular, we show efficient state estimation is possible even beyond the scrambling time, for many different types of dynamics -- in fact, we show that in all the cases we studied, the reconstruction efficiency at long interaction times matches the optimal one offered by random global unitary dynamics. These results offer promising venues for robust experimental QELM-based state estimation protocols, as well as providing novel insights into the nature of QIS from a state estimation perspective.
title State estimation with quantum extreme learning machines beyond the scrambling time
topic Quantum Physics
url https://arxiv.org/abs/2409.06782