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Main Authors: Fuchs, Franz G., Stasik, Alexander J., Miao, Stanley, Kulseng, Ola Tangen, Bassa, Ruben Pariente
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2407.00445
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author Fuchs, Franz G.
Stasik, Alexander J.
Miao, Stanley
Kulseng, Ola Tangen
Bassa, Ruben Pariente
author_facet Fuchs, Franz G.
Stasik, Alexander J.
Miao, Stanley
Kulseng, Ola Tangen
Bassa, Ruben Pariente
contents Utilizing a quantum system for reservoir computing has recently received a lot of attention. Key challenges are related to how on can optimally en- and decode classical information, as well as what constitutes a good reservoir. Our main contribution is a generalization of the standard way to robustly en- and decode time series into subspaces defined by the cosets of a given stabilizer. A key observation is the necessity to perform the decoding step, which in turn ensures a consistent way of encoding. This provides a systematic way to encode classical information in a robust way. We provide a numerical analysis on a discrete time series given by two standard maps, namely the logistic and the Hénon map. Our numerical findings indicate that the system's performance is increasing with the length of the training data.
format Preprint
id arxiv_https___arxiv_org_abs_2407_00445
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Quantum reservoir computing using the stabilizer formalism for encoding classical data
Fuchs, Franz G.
Stasik, Alexander J.
Miao, Stanley
Kulseng, Ola Tangen
Bassa, Ruben Pariente
Quantum Physics
Utilizing a quantum system for reservoir computing has recently received a lot of attention. Key challenges are related to how on can optimally en- and decode classical information, as well as what constitutes a good reservoir. Our main contribution is a generalization of the standard way to robustly en- and decode time series into subspaces defined by the cosets of a given stabilizer. A key observation is the necessity to perform the decoding step, which in turn ensures a consistent way of encoding. This provides a systematic way to encode classical information in a robust way. We provide a numerical analysis on a discrete time series given by two standard maps, namely the logistic and the Hénon map. Our numerical findings indicate that the system's performance is increasing with the length of the training data.
title Quantum reservoir computing using the stabilizer formalism for encoding classical data
topic Quantum Physics
url https://arxiv.org/abs/2407.00445