Relative cluster entropy for power-law correlated sequences

We propose an information-theoretical measure, the relative cluster entropy \mathcal{D_C}[P\|Q] [ P ∥ Q ] , to discriminate among cluster partitions characterised by probability distribution functions P and Q. The measure is illustrated with the clusters generated by pairs of fractional Brownian mot...

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Bibliographic Details
Published in:SciPost physics Vol. 13; no. 3; p. 076
Main Authors: Carbone, Anna, Ponta, Linda
Format: Journal Article
Language:English
Published: SciPost 01.09.2022
ISSN:2542-4653, 2542-4653
Online Access:Get full text
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Summary:We propose an information-theoretical measure, the relative cluster entropy \mathcal{D_C}[P\|Q] [ P ∥ Q ] , to discriminate among cluster partitions characterised by probability distribution functions P and Q. The measure is illustrated with the clusters generated by pairs of fractional Brownian motions with Hurst exponents H_1 H 1 and H_2 H 2 respectively. For subdiffusive, normal and superdiffusive sequences, the relative entropy sensibly depends on the difference between H_1 H 1 and H_2 H 2 . By using the minimum relative entropy principle, cluster sequences characterized by different correlation degrees are distinguished and the optimal Hurst exponent is selected. As a case study, real-world cluster partitions of market price series are compared to those obtained from fully uncorrelated sequences (simple Browniam motions) assumed as a model. The minimum relative cluster entropy yields optimal Hurst exponents H_1 H 1 =0.55, H_1 H 1 =0.57, and H_1 H 1 =0.63 respectively for the prices of DJIA, S and P500, NASDAQ: a clear indication of non-markovianity. Finally, we derive the analytical expression of the relative cluster entropy and the outcomes are discussed for arbitrary pairs of power-laws probability distribution functions of continuous random variables.
ISSN:2542-4653
2542-4653
DOI:10.21468/SciPostPhys.13.3.076