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Main Authors: Gili, Marta, Fiorelli, Eliana, Blázquez-García, Ane, Giorgi, Gian Luca, Zambrini, Roberta
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2602.11797
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author Gili, Marta
Fiorelli, Eliana
Blázquez-García, Ane
Giorgi, Gian Luca
Zambrini, Roberta
author_facet Gili, Marta
Fiorelli, Eliana
Blázquez-García, Ane
Giorgi, Gian Luca
Zambrini, Roberta
contents Distributed architectures are gaining prominence in quantum machine learning as a means to overcome hardware limitations and enable scalable quantum information processing. In this context, we analyze the design and performance of distributed Quantum Extreme Learning Machine (QELM) architectures for learning functions of quantum states directly from data, restricting measurements to easily implementable projective measurements in the computational basis. The aim is to determine which schemes can effectively recover specific properties of input quantum states, including both linear and nonlinear features, while also quantifying the resource requirements in terms of measurements and reservoir dimensionality. We compare standard three-layer QELM with a spatially multiplexed architecture composed of multiple independent three-layer units for linear (quantum) tasks, showing a linear reduction in resource requirements per unit. For nonlinear properties, the study examines the multiple-injection architecture and introduces a novel distributed design that incorporates entanglement between subsystems within a spatially multiplexed framework, evaluating its performance through the reconstruction of complex nonlinear quantities such as polynomial targets, Rényi entropy, and entanglement measures. Our results demonstrate that the distributed design enables the reconstruction of higher-order nonlinearities by increasing the number of interacting subsystems with reduced resources, rather than increasing the size of an individual reservoir, providing a scalable and hardware-efficient route to quantum property learning.
format Preprint
id arxiv_https___arxiv_org_abs_2602_11797
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Learning functions of quantum states with distributed architectures
Gili, Marta
Fiorelli, Eliana
Blázquez-García, Ane
Giorgi, Gian Luca
Zambrini, Roberta
Quantum Physics
Distributed architectures are gaining prominence in quantum machine learning as a means to overcome hardware limitations and enable scalable quantum information processing. In this context, we analyze the design and performance of distributed Quantum Extreme Learning Machine (QELM) architectures for learning functions of quantum states directly from data, restricting measurements to easily implementable projective measurements in the computational basis. The aim is to determine which schemes can effectively recover specific properties of input quantum states, including both linear and nonlinear features, while also quantifying the resource requirements in terms of measurements and reservoir dimensionality. We compare standard three-layer QELM with a spatially multiplexed architecture composed of multiple independent three-layer units for linear (quantum) tasks, showing a linear reduction in resource requirements per unit. For nonlinear properties, the study examines the multiple-injection architecture and introduces a novel distributed design that incorporates entanglement between subsystems within a spatially multiplexed framework, evaluating its performance through the reconstruction of complex nonlinear quantities such as polynomial targets, Rényi entropy, and entanglement measures. Our results demonstrate that the distributed design enables the reconstruction of higher-order nonlinearities by increasing the number of interacting subsystems with reduced resources, rather than increasing the size of an individual reservoir, providing a scalable and hardware-efficient route to quantum property learning.
title Learning functions of quantum states with distributed architectures
topic Quantum Physics
url https://arxiv.org/abs/2602.11797