Inferring effective couplings with Restricted Boltzmann Machines

TL;DR

This paper introduces a method to map Restricted Boltzmann Machines to an effective Ising Hamiltonian, capturing complex interactions beyond pairwise, and validates it through numerical experiments on synthetic data.

Contribution

It provides a precise mapping between RBMs and multi-body Ising models, improving inference accuracy for complex datasets compared to previous approaches.

Findings

Effective learning of interaction networks from synthetic data

Inclusion of higher-order interactions improves model accuracy

Validation through numerical experiments confirms method's effectiveness

Abstract

Generative models offer a direct way of modeling complex data. Energy-based models attempt to encode the statistical correlations observed in the data at the level of the Boltzmann weight associated with an energy function in the form of a neural network. We address here the challenge of understanding the physical interpretation of such models. In this study, we propose a simple solution by implementing a direct mapping between the Restricted Boltzmann Machine and an effective Ising spin Hamiltonian. This mapping includes interactions of all possible orders, going beyond the conventional pairwise interactions typically considered in the inverse Ising (or Boltzmann Machine) approach, and allowing the description of complex datasets. Earlier works attempted to achieve this goal, but the proposed mappings were inaccurate for inference applications, did not properly treat the complexity of the problem, or did not provide precise prescriptions for practical application. To validate our method, we performed several controlled inverse numerical experiments in which we trained the RBMs using equilibrium samples of predefined models with local external fields, 2-body and 3-body interactions in different sparse topologies. The results demonstrate the effectiveness of our proposed approach in learning the correct interaction network and pave the way for its application in modeling interesting binary variable datasets. We also evaluate the quality of the inferred model based on different training methods.