Machine-Learning Quantum States in the NISQ Era

We review the development of generative modeling techniques in machine learning for the purpose of reconstructing real, noisy, many-qubit quantum states. Motivated by its interpretability and utility, we discuss in detail the theory of the restricted Boltzmann machine. We demonstrate its practical use for state reconstruction, starting from a classical thermal distribution of Ising spins, then moving systematically through increasingly complex pure and mixed quantum states. We review recent techniques in reconstruction of a cold atom wavefunction, intended for use on experimental noisy intermediate-scale quantum (NISQ) devices. Finally, we discuss the outlook for future experimental state reconstruction using machine learning in the NISQ era and beyond.

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On the Experimental Feasibility of Quantum State Reconstruction via Machine Learning

IEEE Transactions on Quantum Engineering ◽

10.1109/tqe.2021.3106958 ◽

2021 ◽

Vol 2 ◽

pp. 1-10

Author(s):

Sanjaya Lohani ◽

Thomas A. Searles ◽

Brian T. Kirby ◽

Ryan T. Glasser

Keyword(s):

Machine Learning ◽

Quantum State ◽

State Reconstruction ◽

Quantum State Reconstruction

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Clustering and enhanced classiﬁcation using a hybrid quantum autoencoder

Quantum Science and Technology ◽

10.1088/2058-9565/ac3c53 ◽

2021 ◽

Author(s):

Maiyuren Srikumar ◽

Charles Daniel Hill ◽

Lloyd Hollenberg

Keyword(s):

Machine Learning ◽

Supervised Classification ◽

Quantum Information Theory ◽

Quantum States ◽

Data Sets ◽

New Paradigm ◽

Novel Approach ◽

Representational Space ◽

Quantum Machine Learning ◽

Pure States

Abstract Quantum machine learning (QML) is a rapidly growing area of research at the intersection of classical machine learning and quantum information theory. One area of considerable interest is the use of QML to learn information contained within quantum states themselves. In this work, we propose a novel approach in which the extraction of information from quantum states is undertaken in a classical representational-space, obtained through the training of a hybrid quantum autoencoder (HQA). Hence, given a set of pure states, this variational QML algorithm learns to identify – and classically represent – their essential distinguishing characteristics, subsequently giving rise to a new paradigm for clustering and semi-supervised classiﬁcation. The analysis and employment of the HQA model are presented in the context of amplitude encoded states – which in principle can be extended to arbitrary states for the analysis of structure in non-trivial quantum data sets.

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Machine Learning Based Parameter Estimation of Gaussian Quantum States

IEEE Transactions on Quantum Engineering ◽

10.1109/tqe.2021.3137559 ◽

2021 ◽

pp. 1-1

Author(s):

Neel Kanth Kundu ◽

Matthew R. Mckay ◽

Ranjan K. Mallik

Keyword(s):

Machine Learning ◽

Parameter Estimation ◽

Quantum States

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Vision based supervised restricted Boltzmann machine helps to actuate novel shape memory alloy accurately

Scientific Reports ◽

10.1038/s41598-021-95939-y ◽

2021 ◽

Vol 11 (1) ◽

Author(s):

Ritaban Dutta ◽

Cherry Chen ◽

David Renshaw ◽

Daniel Liang

Keyword(s):

Machine Learning ◽

Computer Vision ◽

Shape Memory ◽

Video Data ◽

The Body ◽

Restricted Boltzmann Machine ◽

Supervised Machine Learning ◽

Machine Learning Techniques ◽

Boltzmann Machine ◽

High Level

AbstractExtraordinary shape recovery capabilities of shape memory alloys (SMAs) have made them a crucial building block for the development of next-generation soft robotic systems and associated cognitive robotic controllers. In this study we desired to determine whether combining video data analysis techniques with machine learning techniques could develop a computer vision based predictive system to accurately predict force generated by the movement of a SMA body that is capable of a multi-point actuation performance. We identified that rapid video capture of the bending movements of a SMA body while undergoing external electrical excitements and adapting that characterisation using computer vision approach into a machine learning model, can accurately predict the amount of actuation force generated by the body. This is a fundamental area for achieving a superior control of the actuation of SMA bodies. We demonstrate that a supervised machine learning framework trained with Restricted Boltzmann Machine (RBM) inspired features extracted from 45,000 digital thermal infrared video frames captured during excitement of various SMA shapes, is capable to estimate and predict force and stress with 93% global accuracy with very low false negatives and high level of predictive generalisation.

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