Extract the Degradation Information in Squeezed States with Machine Learning

TL;DR

This paper introduces a machine learning approach using convolutional neural networks for rapid, accurate quantum state tomography of squeezed states, effectively revealing degradation due to noise with high fidelity in real-time.

Contribution

The study presents a novel CNN-based quantum state tomography method that outperforms traditional maximum likelihood estimation in speed and robustness, enabling real-time analysis of quantum state degradation.

Findings

Reconstruction of density matrix in less than one second.

Achieved fidelity of 0.99 even at high anti-squeezing levels.

Effectively unveiled degradation mechanisms under various noise conditions.

Abstract

In order to leverage the full power of quantum noise squeezing with unavoidable decoherence, a complete understanding of the degradation in the purity of squeezed light is demanded. By implementing machine learning architecture with a convolutional neural network, we illustrate a fast, robust, and precise quantum state tomography for continuous variables, through the experimentally measured data generated from the balanced homodyne detectors. Compared with the maximum likelihood estimation method, which suffers from time-consuming and over-fitting problems, a well-trained machine fed with squeezed vacuum and squeezed thermal states can complete the task of reconstruction of the density matrix in less than one second. Moreover, the resulting fidelity remains as high as $0.99$ even when the anti-squeezing level is higher than $20$~dB. Compared with the phase noise and loss mechanisms coupled from the environment and surrounding vacuum, experimentally, the degradation information is unveiled with machine learning for low and high noisy scenarios, i.e., with the anti-squeezing levels at $12$~dB and $18$~dB, respectively. Our neural network enhanced quantum state tomography provides the metrics to give physical descriptions of every feature observed in the quantum state with a single-shot measurement and paves a way of exploring large-scale quantum systems in real-time.