Generalized Fisher information matrix in nonextensive systems with spatial correlation

TL;DR

This paper derives the generalized Fisher information matrix for nonextensive systems with spatial correlation, revealing how correlation affects estimation accuracy of system parameters, and discusses implications for neuronal decoding.

Contribution

It introduces a method to compute the Fisher information matrix for nonextensive, spatially-correlated systems using the $q$-Gaussian distribution, providing new insights into parameter estimation.

Findings

Negative correlation improves mean estimate accuracy.

Correlation increases variance estimation error.

Certain correlation values significantly enhance estimation of correlation degree.

Abstract

By using the $q$-Gaussian distribution derived by the maximum entropy method for spatially-correlated $N$-unit nonextensive systems, we have calculated the generalized Fisher information matrix of $g_{\theta_n \theta_m}$ for $(\theta_1, \theta_2, \theta_3) = (\mu_q, \sigma_q^2$, $s$), where $\mu_q$, $\sigma_q^2$ and $s$ denote the mean, variance and degree of spatial correlation, respectively, for a given entropic index $q$. It has been shown from the Cram\'{e}r-Rao theorem that (1) an accuracy of an unbiased estimate of $\mu_q$ is improved (degraded) by a negative (positive) correlation $s$, (2) that of $\sigma_q^2$ is worsen with increasing $s$, and (3) that of $s$ is much improved for $s \simeq -1/(N-1)$ or $s \simeq 1.0$ though it is worst at $s = (N-2)/2(N-1)$. Our calculation provides a clear insight to the long-standing controversy whether the spatial correlation is beneficial or detrimental to decoding in neuronal ensembles. We discuss also a calculation of the $q$-Gaussian distribution, applying the superstatistics to the Langevin model subjected to spatially-correlated inputs.