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Auteurs principaux: Wang, Haoxiang, Weber, Maurice, Izaac, Josh, Lin, Cedric Yen-Yu
Format: Preprint
Publié: 2022
Sujets:
Accès en ligne:https://arxiv.org/abs/2211.16943
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author Wang, Haoxiang
Weber, Maurice
Izaac, Josh
Lin, Cedric Yen-Yu
author_facet Wang, Haoxiang
Weber, Maurice
Izaac, Josh
Lin, Cedric Yen-Yu
contents Machine learning has emerged recently as a powerful tool for predicting properties of quantum many-body systems. For many ground states of gapped Hamiltonians, generative models can learn from measurements of a single quantum state to reconstruct the state accurately enough to predict local observables. Alternatively, classification and regression models can predict local observables by learning from measurements on different but related states. In this work, we combine the benefits of both approaches and propose the use of conditional generative models to simultaneously represent a family of states, learning shared structures of different quantum states from measurements. The trained model enables us to predict arbitrary local properties of ground states, even for states not included in the training data, without necessitating further training for new observables. We first numerically validate our approach on 2D random Heisenberg models using simulations of up to 45 qubits. Furthermore, we conduct quantum simulations on a neutral-atom quantum computer and demonstrate that our method can accurately predict the quantum phases of square lattices of 13$\times$13 Rydberg atoms.
format Preprint
id arxiv_https___arxiv_org_abs_2211_16943
institution arXiv
publishDate 2022
record_format arxiv
spellingShingle Predicting Properties of Quantum Systems with Conditional Generative Models
Wang, Haoxiang
Weber, Maurice
Izaac, Josh
Lin, Cedric Yen-Yu
Quantum Physics
Machine Learning
Machine learning has emerged recently as a powerful tool for predicting properties of quantum many-body systems. For many ground states of gapped Hamiltonians, generative models can learn from measurements of a single quantum state to reconstruct the state accurately enough to predict local observables. Alternatively, classification and regression models can predict local observables by learning from measurements on different but related states. In this work, we combine the benefits of both approaches and propose the use of conditional generative models to simultaneously represent a family of states, learning shared structures of different quantum states from measurements. The trained model enables us to predict arbitrary local properties of ground states, even for states not included in the training data, without necessitating further training for new observables. We first numerically validate our approach on 2D random Heisenberg models using simulations of up to 45 qubits. Furthermore, we conduct quantum simulations on a neutral-atom quantum computer and demonstrate that our method can accurately predict the quantum phases of square lattices of 13$\times$13 Rydberg atoms.
title Predicting Properties of Quantum Systems with Conditional Generative Models
topic Quantum Physics
Machine Learning
url https://arxiv.org/abs/2211.16943