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Large-scale quantum reservoir computing using a Gaussian Boson Sampler

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arxiv 2505.13695 v1 pith:UAQUED7U submitted 2025-05-19 quant-ph

Large-scale quantum reservoir computing using a Gaussian Boson Sampler

classification quant-ph
keywords reservoirquantumcomputercorrelationsaccesscomputingwhenaccuracies
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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A Gaussian boson sampler (GBS) is a special-purpose quantum computer that can be practically realized at large scale in optics. Here we report on experiments in which we used a frequency-multiplexed GBS with $>400$ modes as the reservoir in the quantum-machine-learning approach of quantum reservoir computing. We evaluated the accuracy of our GBS-based reservoir computer on a variety of benchmark tasks, including spoken-vowels classification and MNIST handwritten-digit classification. We found that when the reservoir computer was given access to the correlations between measured modes of the GBS, the achieved accuracies were the same or higher than when it was only given access to the mean photon number in each mode -- and in several cases the advantage in accuracy from using the correlations was greater than 20 percentage points. This provides experimental evidence in support of theoretical predictions that access to correlations enhances the power of quantum reservoir computers. We also tested our reservoir computer when operating the reservoir with various sources of classical rather than squeezed (quantum) light and found that using squeezed light consistently resulted in the highest (or tied highest, for simple tasks) accuracies. Our work experimentally establishes that a GBS can be an effective reservoir for quantum reservoir computing and provides a practical platform for experimentally exploring the role of quantumness and correlations in quantum machine learning at very large system sizes.

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Cited by 2 Pith papers

Reviewed papers in the Pith corpus that reference this work. Sorted by Pith novelty score.

  1. Quantum and classical processing with photonic quantum machine learning

    quant-ph 2026-05 unverdicted novelty 7.0

    A programmable silicon photonic chip excited with single photons implements quantum reservoir computing for quantum state tomography, entanglement measurement via negativity, and classical tasks, with an imperfection ...

  2. Efficient classical training of model-free quantum photonic reservoir

    quant-ph 2026-04 unverdicted novelty 7.0

    Classical light training of photonic quantum reservoirs enables accurate model-free estimation of single-qubit observables and two-qubit entanglement witnesses on unseen quantum states.