We compare and contrast the statistical physics and quantum physics inspired approaches for unsupervised generative modeling of classical data. The two approaches represent probabilities of observed data using energy-based models and quantum states, respectively. Classical and quantum information patterns of the target datasets therefore provide principled guidelines for structural design and learning in these two approaches. Taking the Restricted Boltzmann Machines (RBM) as an example, we analyze the information theoretical bounds of the two approaches. We also estimate the classical mutual information of the standard MNIST datasets and the quantum Rényi entropy of corresponding Matrix Product States (MPS) representations. Both info...
Current research in Machine Learning (ML) combines the study of variations on well-established metho...
Within the past decade, machine learning algorithms have been proposed as a po-tential solution to a...
Machine learning algorithms based on parametrized quantum circuits are prime candidates for near-ter...
We compare and contrast the statistical physics and quantum physics inspired approaches for unsuperv...
Generative modeling, which learns joint probability distribution from data and generates samples acc...
The goal of generative machine learning is to model the probability distribution underlying a given ...
Entropy is a central concept in physics and has deep connections with Information theory, which is o...
The core computational tasks in quantum systems are the computation of expectations of operators, in...
The exact description of many-body quantum systems represents one of the major challenges in modern ...
The promise of quantum neural nets, which utilize quantum effects to model complex data sets, has ma...
We propose a series of data-centric heuristics for improving the performance of machine learning sys...
Simulating stochastic processes using less resources is a key pursuit in many sciences. This involve...
Inspired by the success of Boltzmann machines based on classical Boltzmann distribution, we propose ...
Data reported in "Approximating power of machine-learning ansatz for quantum many-body states", http...
In recent years, generative artificial neural networks based on restricted Boltzmann machines (RBMs)...
Current research in Machine Learning (ML) combines the study of variations on well-established metho...
Within the past decade, machine learning algorithms have been proposed as a po-tential solution to a...
Machine learning algorithms based on parametrized quantum circuits are prime candidates for near-ter...
We compare and contrast the statistical physics and quantum physics inspired approaches for unsuperv...
Generative modeling, which learns joint probability distribution from data and generates samples acc...
The goal of generative machine learning is to model the probability distribution underlying a given ...
Entropy is a central concept in physics and has deep connections with Information theory, which is o...
The core computational tasks in quantum systems are the computation of expectations of operators, in...
The exact description of many-body quantum systems represents one of the major challenges in modern ...
The promise of quantum neural nets, which utilize quantum effects to model complex data sets, has ma...
We propose a series of data-centric heuristics for improving the performance of machine learning sys...
Simulating stochastic processes using less resources is a key pursuit in many sciences. This involve...
Inspired by the success of Boltzmann machines based on classical Boltzmann distribution, we propose ...
Data reported in "Approximating power of machine-learning ansatz for quantum many-body states", http...
In recent years, generative artificial neural networks based on restricted Boltzmann machines (RBMs)...
Current research in Machine Learning (ML) combines the study of variations on well-established metho...
Within the past decade, machine learning algorithms have been proposed as a po-tential solution to a...
Machine learning algorithms based on parametrized quantum circuits are prime candidates for near-ter...