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Autor principal: Hoegele, Wolfgang
Formato: Preprint
Publicado: 2026
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Acceso en línea:https://arxiv.org/abs/2603.17466
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author Hoegele, Wolfgang
author_facet Hoegele, Wolfgang
contents The goal of this study is to introduce a unified computational framework for simulating random iteration equations (RIE), understood as iteration equations containing random variables. The novelty of this work is that full probability densities of the state vectors are propagated stepwise through the iterations avoiding the need of repetitive pathwise Monte Carlo simulations of the iteration equation. The presentation of the methodology is conceptually efficient based on recent work on static random equations and intentionally accessible. Based on previous work, the modeling requirements for RIEs allow for potential nonsmooth nonlinearities and stochasticities in the transfer function, as well as nonstandard probability densities and diffusion processes. As results, illustrative applications of nonlinear random and stochastic differential equation simulations, a novel full-density gradient descent method (FDGD) for global optimization under uncertainty and examples of chaotic mappings are presented in order to demonstrate the breadth of the utility of this framework. In total, the character of the presentation is explorative and encourages new applications and theoretical studies.
format Preprint
id arxiv_https___arxiv_org_abs_2603_17466
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle A Full-Density Approach to Simulating Random Iteration Equations with Applications
Hoegele, Wolfgang
Dynamical Systems
Numerical Analysis
Computation
The goal of this study is to introduce a unified computational framework for simulating random iteration equations (RIE), understood as iteration equations containing random variables. The novelty of this work is that full probability densities of the state vectors are propagated stepwise through the iterations avoiding the need of repetitive pathwise Monte Carlo simulations of the iteration equation. The presentation of the methodology is conceptually efficient based on recent work on static random equations and intentionally accessible. Based on previous work, the modeling requirements for RIEs allow for potential nonsmooth nonlinearities and stochasticities in the transfer function, as well as nonstandard probability densities and diffusion processes. As results, illustrative applications of nonlinear random and stochastic differential equation simulations, a novel full-density gradient descent method (FDGD) for global optimization under uncertainty and examples of chaotic mappings are presented in order to demonstrate the breadth of the utility of this framework. In total, the character of the presentation is explorative and encourages new applications and theoretical studies.
title A Full-Density Approach to Simulating Random Iteration Equations with Applications
topic Dynamical Systems
Numerical Analysis
Computation
url https://arxiv.org/abs/2603.17466