Generalized Fisher information matrix in nonextensive systems with spatial correlation

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 gθn θm for (θ1, θ2, θ3) = (μq, σq2, s), where μq, σq2 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\'er-Rao theorem that (1) an accuracy of an unbiased estimate of μq is improved (degraded) by a negative (positive) correlation s, (2) that of σq2 is worsen with increasing s, and (3) that of s is much improved for s -1/(N-1) or s 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.