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Main Author: Endo, Yoshiyuki
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.20653
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author Endo, Yoshiyuki
author_facet Endo, Yoshiyuki
contents We study polynomial random dynamical systems with complete connections on the Riemann sphere. In this framework, the choice of the next polynomial map is governed by a state-dependent rule with memory, extending both i.i.d. random dynamics and non-i.i.d. Markovian models. For each initial state, we define the probability that the random orbit tends to infinity. We prove that it is locally constant on the Fatou set, and that if all kernel Julia sets are empty, then it is continuous on the whole space. We also introduce stationary-averaged escaping probabilities with respect to stationary distributions of the induced state chain. Under the same kernel-emptiness assumption, these averaged probabilities are continuous. In addition, for each point of the Riemann sphere, the set of all possible stationary-averaged values is shown to be a compact interval determined by ergodic stationary distributions. We further give a sufficient condition for the stationary-averaged escaping probability to be everywhere positive and nontrivial. Finally, we provide examples showing RSCC-specific phenomena, including reinforcement-induced discontinuity, recovery of continuity under truncation, and genuinely mixed escaping behavior produced by stationary averaging.
format Preprint
id arxiv_https___arxiv_org_abs_2603_20653
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Polynomial Random Dynamical Systems with Complete Connections and the Probability of Tending to Infinity
Endo, Yoshiyuki
Dynamical Systems
We study polynomial random dynamical systems with complete connections on the Riemann sphere. In this framework, the choice of the next polynomial map is governed by a state-dependent rule with memory, extending both i.i.d. random dynamics and non-i.i.d. Markovian models. For each initial state, we define the probability that the random orbit tends to infinity. We prove that it is locally constant on the Fatou set, and that if all kernel Julia sets are empty, then it is continuous on the whole space. We also introduce stationary-averaged escaping probabilities with respect to stationary distributions of the induced state chain. Under the same kernel-emptiness assumption, these averaged probabilities are continuous. In addition, for each point of the Riemann sphere, the set of all possible stationary-averaged values is shown to be a compact interval determined by ergodic stationary distributions. We further give a sufficient condition for the stationary-averaged escaping probability to be everywhere positive and nontrivial. Finally, we provide examples showing RSCC-specific phenomena, including reinforcement-induced discontinuity, recovery of continuity under truncation, and genuinely mixed escaping behavior produced by stationary averaging.
title Polynomial Random Dynamical Systems with Complete Connections and the Probability of Tending to Infinity
topic Dynamical Systems
url https://arxiv.org/abs/2603.20653