{"title":"The generalized IFS Bayesian method and an associated variational principle covering the classical and dynamical cases","authors":"Artur O. Lopes, Jairo. K. Mengue","doi":"10.1080/14689367.2023.2257609","DOIUrl":null,"url":null,"abstract":"AbstractWe introduce a general IFS Bayesian method for getting posterior probabilities from prior probabilities, and also a generalized Bayes' rule, which will contemplate a dynamical, as well as a non-dynamical setting. Given a loss function l, we detail the prior and posterior items, their consequences and exhibit several examples. Taking Θ as the set of parameters and Y as the set of data (which usually provides random samples), a general IFS is a measurable map τ:Θ×Y→Y, which can be interpreted as a family of maps τθ:Y→Y,θ∈Θ. The main inspiration for the results we will get here comes from a paper by Zellner (with no dynamics), where Bayes' rule is related to a principle of minimization of information. We will show that our IFS Bayesian method which produces posterior probabilities (which are associated to holonomic probabilities) is related to the optimal solution of a variational principle, somehow corresponding to the pressure in Thermodynamic Formalism, and also to the principle of minimization of information in Information Theory. Among other results, we present the prior dynamical elements and we derive the corresponding posterior elements via the Ruelle operator of Thermodynamic Formalism; getting in this way a form of dynamical Bayes' rule.Keywords: Generalized Baye's ruleposterior probabilitygeneral IFS Bayesian methodminimization of informationholonomic probabilityThermodynamic Formalism Disclosure statementNo potential conflict of interest was reported by the author(s).Notes1 If there are more than one stationary ρ with respect to (l¯,ν,τ), then we get more than one possible posterior probability π2 observe the importance of considering dπ~=π~p(θ)dθdδy0, to get the below expression from (Equation32(32) supπ~holonomic∫[log(l(θ,y))+log(πa(θ))−log(φ(y))]dπ~+Hdθ(π~).(32) ), and that the supremum is over π~p(θ), which is a probability density function and no more a probability; furthermore, for the last term we take into account (Equation31(31) Hν(π)={−∫log(J)dπifdπ=J(θ,y)dν(θ)dρ(y)−∞ifπis not absolutely continuouswith respect toν×ρ(31) ).","PeriodicalId":50564,"journal":{"name":"Dynamical Systems-An International Journal","volume":"13 1","pages":"0"},"PeriodicalIF":0.5000,"publicationDate":"2023-09-18","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Dynamical Systems-An International Journal","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1080/14689367.2023.2257609","RegionNum":4,"RegionCategory":"数学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q4","JCRName":"MATHEMATICS, APPLIED","Score":null,"Total":0}
引用次数: 0
Abstract
AbstractWe introduce a general IFS Bayesian method for getting posterior probabilities from prior probabilities, and also a generalized Bayes' rule, which will contemplate a dynamical, as well as a non-dynamical setting. Given a loss function l, we detail the prior and posterior items, their consequences and exhibit several examples. Taking Θ as the set of parameters and Y as the set of data (which usually provides random samples), a general IFS is a measurable map τ:Θ×Y→Y, which can be interpreted as a family of maps τθ:Y→Y,θ∈Θ. The main inspiration for the results we will get here comes from a paper by Zellner (with no dynamics), where Bayes' rule is related to a principle of minimization of information. We will show that our IFS Bayesian method which produces posterior probabilities (which are associated to holonomic probabilities) is related to the optimal solution of a variational principle, somehow corresponding to the pressure in Thermodynamic Formalism, and also to the principle of minimization of information in Information Theory. Among other results, we present the prior dynamical elements and we derive the corresponding posterior elements via the Ruelle operator of Thermodynamic Formalism; getting in this way a form of dynamical Bayes' rule.Keywords: Generalized Baye's ruleposterior probabilitygeneral IFS Bayesian methodminimization of informationholonomic probabilityThermodynamic Formalism Disclosure statementNo potential conflict of interest was reported by the author(s).Notes1 If there are more than one stationary ρ with respect to (l¯,ν,τ), then we get more than one possible posterior probability π2 observe the importance of considering dπ~=π~p(θ)dθdδy0, to get the below expression from (Equation32(32) supπ~holonomic∫[log(l(θ,y))+log(πa(θ))−log(φ(y))]dπ~+Hdθ(π~).(32) ), and that the supremum is over π~p(θ), which is a probability density function and no more a probability; furthermore, for the last term we take into account (Equation31(31) Hν(π)={−∫log(J)dπifdπ=J(θ,y)dν(θ)dρ(y)−∞ifπis not absolutely continuouswith respect toν×ρ(31) ).
期刊介绍:
Dynamical Systems: An International Journal is a world-leading journal acting as a forum for communication across all branches of modern dynamical systems, and especially as a platform to facilitate interaction between theory and applications. This journal publishes high quality research articles in the theory and applications of dynamical systems, especially (but not exclusively) nonlinear systems. Advances in the following topics are addressed by the journal:
•Differential equations
•Bifurcation theory
•Hamiltonian and Lagrangian dynamics
•Hyperbolic dynamics
•Ergodic theory
•Topological and smooth dynamics
•Random dynamical systems
•Applications in technology, engineering and natural and life sciences