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Bibliographic Details
Main Authors: Boneberg, Mario, Kochsiek, Simon, Lesanovsky, Igor
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.24886
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author Boneberg, Mario
Kochsiek, Simon
Lesanovsky, Igor
author_facet Boneberg, Mario
Kochsiek, Simon
Lesanovsky, Igor
contents Quantum neural networks generalize classical artificial neural networks into the quantum domain. They are formulated as parameterized quantum circuits which are optimized by measuring and minimizing a suitably chosen loss function. The core challenge in understanding, implementing and ultimately using quantum neural networks is that they represent many-body systems with an exponentially large Hilbert space, in combination with a large parameter search space. Moreover, noise -- which is inherent to any quantum measurement -- sets practical limits for the estimation of training loss. Here, we study physics-informed large-scale quantum neural networks that are trained through a finite number of noisy loss function measurements. We show that this architecture permits the construction of nontrivial decision boundaries that enable the classification of quantum states through measuring an order parameter. Our approach can directly process quantum data that is output from quantum simulators and computers and is well suited for implementation on current hardware. Moreover, owed to a close link between the neural network dynamics and the evolution of Markovian open many-body quantum systems, one may expect a certain robustness to noise, which is ubiquitous in the current NISQ era.
format Preprint
id arxiv_https___arxiv_org_abs_2604_24886
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Getting large-scale quantum neural networks ready for quantum hardware
Boneberg, Mario
Kochsiek, Simon
Lesanovsky, Igor
Quantum Physics
Quantum neural networks generalize classical artificial neural networks into the quantum domain. They are formulated as parameterized quantum circuits which are optimized by measuring and minimizing a suitably chosen loss function. The core challenge in understanding, implementing and ultimately using quantum neural networks is that they represent many-body systems with an exponentially large Hilbert space, in combination with a large parameter search space. Moreover, noise -- which is inherent to any quantum measurement -- sets practical limits for the estimation of training loss. Here, we study physics-informed large-scale quantum neural networks that are trained through a finite number of noisy loss function measurements. We show that this architecture permits the construction of nontrivial decision boundaries that enable the classification of quantum states through measuring an order parameter. Our approach can directly process quantum data that is output from quantum simulators and computers and is well suited for implementation on current hardware. Moreover, owed to a close link between the neural network dynamics and the evolution of Markovian open many-body quantum systems, one may expect a certain robustness to noise, which is ubiquitous in the current NISQ era.
title Getting large-scale quantum neural networks ready for quantum hardware
topic Quantum Physics
url https://arxiv.org/abs/2604.24886