Estimation of the second-order coherence function using quantum reservoir and ensemble methods
- URL: http://arxiv.org/abs/2504.18205v1
- Date: Fri, 25 Apr 2025 09:35:08 GMT
- Title: Estimation of the second-order coherence function using quantum reservoir and ensemble methods
- Authors: Dogyun Ko, Stanisław Świerczewski, Andrzej Opala, Michał Matuszewski, Amir Rahmani,
- Abstract summary: We propose a machine learning-based approach to estimate the zero-time second-order correlation function g2(0).<n>We evaluate this hybrid quantum-classical approach across a variety of quantum optical systems.
- Score: 0.9402213259706237
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: We propose a machine learning-based approach enhanced by quantum reservoir computing (QRC) to estimate the zero-time second-order correlation function g2(0). Typically, measuring g2(0) requires single-photon detectors and time-correlated measurements. Machine learning may offer practical solutions by training a model to estimate g2(0) solely from average intensity measurements. In our method, emission from a given quantum source is first processed in QRC. During the inference phase, only intensity measurements are used, which are then passed to a software-based decision tree-based ensemble model. We evaluate this hybrid quantum-classical approach across a variety of quantum optical systems and demonstrate that it provides accurate estimates of g2(0). We further extend our analysis to assess the ability of a trained model to generalize beyond its training distribution, both to the same system under different physical parameters and to fundamentally different quantum sources. While the model may yield reliable estimates within specific regimes, its performance across distinct systems is generally limited.
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