The relativistic Hopfield model with correlated patterns
In this work, we introduce and investigate the properties of the “relativistic” Hopfield model endowed with temporally correlated patterns.
First, we review the “relativistic” Hopfield model and we briefly describe the experimental evidence underlying correlation among patterns.
Then, we face the study of the resulting model exploiting statistical-mechanics tools in a low-load regime. More precisely, we prove the
existence of the thermodynamic limit of the related free energy and we derive the self-consistence equations for its order parameters. These
equations are solved numerically to get a phase diagram describing the performance of the system as an associative memory as a function of
its intrinsic parameters (i.e., the degree of noise and of correlation among patterns). We find that beyond the standard retrieval and ergodic
phases, the relativistic system exhibits correlated and symmetric regions, which are genuine effects of temporal correlation, whose width is,
respectively, reduced and increased with respect to the classical case.