English

Autoencoder-assisted study of directed percolation with spatial long-range interactions

Statistical Mechanics 2024-10-24 v3 Disordered Systems and Neural Networks Cellular Automata and Lattice Gases

Abstract

Spatial L{\'{e}}vy-like flights are introduced as a way in the absorbing phase transitions to produce non-local interactions. We utilize the autoencoder, an unsupervised learning method, to predict the critical points for (1+1)(1+1)-d directed percolation with such spatial long-range interactions. After making a global coverage of the reaction-diffusion distance and taking a series of different values for the parameter β{\beta} in the distribution P(r)1/rβP(r){\sim}1/r^{\beta}, the critical points PcP_c that can be continuously varied are obtained. And the dynamic decay of the particle density under the critical points was counted as a way to determine the critical exponent δ{\delta} of the survival rate. We also investigate the active behavior of the system's particles under the critical point with increasing time steps, which allows us to determine the characteristic time tft_f of the finite-scale systems. And the dynamic exponents zz are obtained using the scaling relation tfLzt_f{\sim}L^{z}. We find that the autoencoder can identify this characteristic evolutionary behavior of particles. Finally, we discuss the compliance of the scaling form 1/δ(β2)/δz=21/{\delta}-({\beta}-2)/{\delta}z=2 in different β{\beta} intervals as well as a method to introduce a global scaling mechanism by generating a random walking step using the L{\'{e}}vy distribution.

Keywords

Cite

@article{arxiv.2311.12426,
  title  = {Autoencoder-assisted study of directed percolation with spatial long-range interactions},
  author = {Yanyang Wang and Yuxiang Yang and Wei Li},
  journal= {arXiv preprint arXiv:2311.12426},
  year   = {2024}
}
R2 v1 2026-06-28T13:27:07.264Z