It is known that a trained Restricted Boltzmann Machine (RBM) on the binary Monte Carlo Ising spin configurations, generates a series of iterative reconstructed spin configurations which spontaneously flow and stabilize to the critical point of physical system. Here we construct a variety of Neural Network (NN) flows using the RBM and (variational) autoencoders, to study the q-state Potts and clock models on the square lattice for q = 2, 3, 4. The NN are trained on Monte Carlo spin configurations at various temperatures. We find that the trained NN flow does develop a stable point that coincides with critical point of the q-state spin models. The behavior of the NN flow is nontrivial and generative, since the training is unsupervised and wi...
none4siA specific type of neural network, the Restricted Boltzmann Machine (RBM), is implemented for...
We investigate the Shastry-Sutherland model (SSM), i.e., spin-1/2 quantum Heisen- berg model on a Sh...
Recently, quantum-state representation using artificial neural networks has started to be recognized...
We study the so-called neural network flow of spin configurations in the 2-d Ising ferromagnet. This...
In recent years, generative artificial neural networks based on restricted Boltzmann machines (RBMs)...
We investigate the use of variational wave functions that mimic stochastic recurrent neural networks...
Conventionally, the training of a neural network for learning phases of matter uses real physical qu...
Recent advances in deep learning and neural networks have led to an increased interest in the applic...
Neural network quantum states (NQS) have been widely applied to spin-1/2 systems, where they have pr...
Abstract-The idea of Hopfield network is based on the king spin glass model in which each spin has o...
The renormalization group (RG) is an essential technique in statistical physics and quantum field th...
Despite neural networks’ success, their applications to open-system dynamics are few. In this work, ...
We consider restricted Boltzmann machine (RBMs) trained over an unstructured dataset made of blurred...
Generative neural networks can produce data samples according to the statistical properties of their...
A specific type of neural networks, the Restricted Boltzmann Machines (RBM), are implemented for cla...
none4siA specific type of neural network, the Restricted Boltzmann Machine (RBM), is implemented for...
We investigate the Shastry-Sutherland model (SSM), i.e., spin-1/2 quantum Heisen- berg model on a Sh...
Recently, quantum-state representation using artificial neural networks has started to be recognized...
We study the so-called neural network flow of spin configurations in the 2-d Ising ferromagnet. This...
In recent years, generative artificial neural networks based on restricted Boltzmann machines (RBMs)...
We investigate the use of variational wave functions that mimic stochastic recurrent neural networks...
Conventionally, the training of a neural network for learning phases of matter uses real physical qu...
Recent advances in deep learning and neural networks have led to an increased interest in the applic...
Neural network quantum states (NQS) have been widely applied to spin-1/2 systems, where they have pr...
Abstract-The idea of Hopfield network is based on the king spin glass model in which each spin has o...
The renormalization group (RG) is an essential technique in statistical physics and quantum field th...
Despite neural networks’ success, their applications to open-system dynamics are few. In this work, ...
We consider restricted Boltzmann machine (RBMs) trained over an unstructured dataset made of blurred...
Generative neural networks can produce data samples according to the statistical properties of their...
A specific type of neural networks, the Restricted Boltzmann Machines (RBM), are implemented for cla...
none4siA specific type of neural network, the Restricted Boltzmann Machine (RBM), is implemented for...
We investigate the Shastry-Sutherland model (SSM), i.e., spin-1/2 quantum Heisen- berg model on a Sh...
Recently, quantum-state representation using artificial neural networks has started to be recognized...