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Main Authors: Tucker, Kris, Rege, Amit Kiran, Smith, Conor, Monteleoni, Claire, Albash, Tameem
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2404.05526
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author Tucker, Kris
Rege, Amit Kiran
Smith, Conor
Monteleoni, Claire
Albash, Tameem
author_facet Tucker, Kris
Rege, Amit Kiran
Smith, Conor
Monteleoni, Claire
Albash, Tameem
contents We build upon recent work on using Machine Learning models to estimate Hamiltonian parameters using continuous weak measurement of qubits as input. We consider two settings for the training of our model: (1) supervised learning where the weak measurement training record can be labeled with known Hamiltonian parameters, and (2) unsupervised learning where no labels are available. The first has the advantage of not requiring an explicit representation of the quantum state, thus potentially scaling very favorably to larger number of qubits. The second requires the implementation of a physical model to map the Hamiltonian parameters to a measurement record, which we implement using an integrator of the physical model with a recurrent neural network to provide a model-free correction at every time step to account for small effects not captured by the physical model. We test our construction on a system of two qubits and demonstrate accurate prediction of multiple physical parameters in both the supervised and unsupervised context. We demonstrate that the model benefits from larger training sets establishing that it is in fact "learning," and we show robustness to errors in the assumed physical model by achieving accurate parameter estimation in the presence of unanticipated single particle relaxation.
format Preprint
id arxiv_https___arxiv_org_abs_2404_05526
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Hamiltonian Learning using Machine Learning Models Trained with Continuous Measurements
Tucker, Kris
Rege, Amit Kiran
Smith, Conor
Monteleoni, Claire
Albash, Tameem
Quantum Physics
We build upon recent work on using Machine Learning models to estimate Hamiltonian parameters using continuous weak measurement of qubits as input. We consider two settings for the training of our model: (1) supervised learning where the weak measurement training record can be labeled with known Hamiltonian parameters, and (2) unsupervised learning where no labels are available. The first has the advantage of not requiring an explicit representation of the quantum state, thus potentially scaling very favorably to larger number of qubits. The second requires the implementation of a physical model to map the Hamiltonian parameters to a measurement record, which we implement using an integrator of the physical model with a recurrent neural network to provide a model-free correction at every time step to account for small effects not captured by the physical model. We test our construction on a system of two qubits and demonstrate accurate prediction of multiple physical parameters in both the supervised and unsupervised context. We demonstrate that the model benefits from larger training sets establishing that it is in fact "learning," and we show robustness to errors in the assumed physical model by achieving accurate parameter estimation in the presence of unanticipated single particle relaxation.
title Hamiltonian Learning using Machine Learning Models Trained with Continuous Measurements
topic Quantum Physics
url https://arxiv.org/abs/2404.05526