Autoencoder-assisted study of directed percolation with spatial long-range interactions
Abstract
Spatial L\'evy-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)-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 in the distribution P(r)1/rβ, the critical points Pc 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 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 tf of the finite-scale systems. And the dynamic exponents z are obtained using the scaling relation tfLz. We find that the autoencoder can identify this characteristic evolutionary behavior of particles. Finally, we discuss the compliance of the scaling form 1/δ-(β-2)/δz=2 in different β intervals as well as a method to introduce a global scaling mechanism by generating a random walking step using the L\'evy distribution.
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