Add to ORKGWe present a binary classifier based on neural networks to detect gapped quantum phases. By considering the errors on top of a suitable reference state describing the gapped phase, we show that a neural network trained on the errors can capture the correlation between the errors and can be used to detect the phase boundaries of the gapped quantum phase. We demonstrate the application of the method for matrix product state calculations for different quantum phases exhibiting local symmetry-breaking order, symmetry-protected topological order, and intrinsic topological order.Comment: 10 pages, 7 figure
Deep neural networks are a powerful tool for the characterization of quantum states. Existing netw...
Machine learning techniques have been successfully applied to classifying an extensive range of phen...
Neural networks (NNs) representing quantum states are typically trained using Markov chain Monte Car...
Quantum machine learning offers a promising advantage in extracting information about quantum states...
Quantum machine learning offers a promising advantage in extracting information about quantum states...
Quantum machine learning offers a promising advantage in extracting information about quantum states...
Quantum machine learning offers a promising advantage in extracting information about quantum states...
Recently, quantum-state representation using artificial neural networks has started to be recognized...
Code used in the paper "Quantum phase detection generalisation from marginal quantum neural network ...
Quantum convolutional neural networks (QCNNs) have been introduced as classifiers for gapped quantum...
Classical machine learning has succeeded in the prediction of both classical and quantum phases of m...
Identifying phase transitions and classifying phases of matter is central to understanding the prope...
The learning process for multilayered neural networks with many nodes makes heavy demands on computa...
Open quantum systems have been shown to host a plethora of exotic dynamical phases. Measurement-indu...
In the past years Machine Learning has shown to be a useful tool in quantum many-body physics to det...
Deep neural networks are a powerful tool for the characterization of quantum states. Existing netw...
Machine learning techniques have been successfully applied to classifying an extensive range of phen...
Neural networks (NNs) representing quantum states are typically trained using Markov chain Monte Car...
Quantum machine learning offers a promising advantage in extracting information about quantum states...
Quantum machine learning offers a promising advantage in extracting information about quantum states...
Quantum machine learning offers a promising advantage in extracting information about quantum states...
Quantum machine learning offers a promising advantage in extracting information about quantum states...
Recently, quantum-state representation using artificial neural networks has started to be recognized...
Code used in the paper "Quantum phase detection generalisation from marginal quantum neural network ...
Quantum convolutional neural networks (QCNNs) have been introduced as classifiers for gapped quantum...
Classical machine learning has succeeded in the prediction of both classical and quantum phases of m...
Identifying phase transitions and classifying phases of matter is central to understanding the prope...
The learning process for multilayered neural networks with many nodes makes heavy demands on computa...
Open quantum systems have been shown to host a plethora of exotic dynamical phases. Measurement-indu...
In the past years Machine Learning has shown to be a useful tool in quantum many-body physics to det...
Deep neural networks are a powerful tool for the characterization of quantum states. Existing netw...
Machine learning techniques have been successfully applied to classifying an extensive range of phen...
Neural networks (NNs) representing quantum states are typically trained using Markov chain Monte Car...