Classification and reconstruction of optical quantum states with deep neural networks

Carlos Sánchez Muñoz,Shahnawaz Ahmed,Anton Frisk Kockum,Franco Nori

doi:10.1103/physrevresearch.3.033278

Abstract

We apply deep-neural-network-based techniques to quantum state classification and reconstruction. Our methods demonstrate high classification accuracies and reconstruction fidelities, even in the presence of noise and with little data. Using optical quantum states as examples, we first demonstrate how convolutional neural networks (CNNs) can successfully classify several types of states distorted by, e.g., additive Gaussian noise or photon loss. We further show that a CNN trained on noisy inputs can learn to identify the most important regions in the data, which potentially can reduce the cost of tomography by guiding adaptive data collection. Secondly, we demonstrate reconstruction of quantum-state density matrices using neural networks that incorporate quantum-physics knowledge. The knowledge is implemented as custom neural-network layers that convert outputs from standard feed-forward neural networks to valid descriptions of quantum states. Any standard feed-forward neural-network architecture can be adapted for quantum state tomography (QST) with our method. We present further demonstrations of our proposed QST technique with conditional generative adversarial networks (QST-CGAN) [Ahmed et al., Phys. Rev. Lett. 127, 140502 (2021)]. We motivate our choice of a learnable loss function within an adversarial framework by demonstrating that the QST-CGAN outperforms, across a range of scenarios, generative networks trained with standard loss functions. For pure states with additive or convolutional Gaussian noise, the QST-CGAN is able to adapt to the noise and reconstruct the underlying state. The QST-CGAN reconstructs states using up to two orders of magnitude fewer iterative steps than iterative and accelerated projected-gradient-based maximum-likelihood estimation (MLE) methods. We also demonstrate that the QST-CGAN can reconstruct both pure and mixed states from two orders of magnitude fewer randomly chosen data points than these MLE methods. Our paper opens possibilities to use state-of-the-art deep-learning methods for quantum state classification and reconstruction under various types of noise.

Highlights

Neural networks (NNs) are becoming ubiquitous in various areas of physics as a successful machine-learning (ML) technique to solve different tasks [1]
V B, we show the performance of the quantum state tomography (QST)-conditional GANs (CGANs) on noisy data and the role played by various loss functions in the reconstruction
We present a framework that allows any standard neural network to be used for quantum state discrimination and reconstruction by adapting the generative and discriminative modeling framework from machine learning to QSD and QST

Summary

Introduction

Neural networks (NNs) are becoming ubiquitous in various areas of physics as a successful machine-learning (ML) technique to solve different tasks [1]. The NNs are used in classification problems, where the goal is to assign a label to a data sample [10], and for generative tasks, where new data is created after learning the underlying data distribution from samples [11,12]. We set the stage for the paper by providing an overview of the problems of quantum state discrimination (QSD) and quantum state tomography (QST). We discuss generative and discriminative modeling in machine learning, which is related to these problems. We compare different neural-network approaches to such modeling to motivate our choice of methods in this paper for tackling QST and QSD.

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