Tensor-Networks-based Learning of Probabilistic Cellular Automata Dynamics
Abstract
Algorithms developed to solve many-body quantum problems, like tensor networks, can turn into powerful quantum-inspired tools to tackle problems in the classical domain. In this work, we focus on matrix product operators, a prominent numerical technique to study many-body quantum systems, especially in one dimension. It has been previously shown that such a tool can be used for classification, learning of deterministic sequence-to-sequence processes and of generic quantum processes. We further develop a matrix product operator algorithm to learn probabilistic sequence-to-sequence processes and apply this algorithm to probabilistic cellular automata. This new approach can accurately learn probabilistic cellular automata processes in different conditions, even when the process is a probabilistic mixture of different chaotic rules. In addition, we find that the ability to learn these dynamics is a function of the bit-wise difference between the rules and whether one is much more likely than the other.
Cite
@article{arxiv.2404.11768,
title = {Tensor-Networks-based Learning of Probabilistic Cellular Automata Dynamics},
author = {Heitor P. Casagrande and Bo Xing and William J. Munro and Chu Guo and Dario Poletti},
journal= {arXiv preprint arXiv:2404.11768},
year = {2024}
}
Comments
9 pages, 7 figures