Linear Fractional p-Adic and Adelic Dynamical Systems

American Mathematical Monthly, 2005

Discrete and Continuous Dynamical Systems, 2011

2021

Berger asked the question To what extent the preperiodic points of a p-adic power series determines a stable p-adic dynamical system ? In this work we have applied the preperiodic points of an invertible p-adic power series in order to determine the corresponding stable p-adic dynamical system.

Chaos, Solitons & Fractals, 2014

This paper is devoted to the problem of ergodicity of p-adic dynamical systems. We solved the problem of characterization of ergodicity and measure preserving for (discrete) p-adic dynamical systems for arbitrary prime p for iterations based on 1-Lipschitz functions. This problem was open since long time and only the case p ¼ 2 was investigated in details. We formulated the criteria of ergodicity and measure preserving in terms of coordinate functions corresponding to digits in the canonical expansion of p-adic numbers. (The coordinate representation can be useful, e.g., for applications to cryptography.) Moreover, by using this representation we can consider non-smooth p-adic transformations. The basic technical tools are van der Put series and usage of algebraic structure (permutations) induced by coordinate functions with partially frozen variables. We illustrate the basic theorems by presenting concrete classes of ergodic functions. As is well known, p-adic spaces have the fractal (although very special) structure. Hence, our study covers a large class of dynamical systems on fractals. Dynamical systems under investigation combine simplicity of the algebraic dynamical structure with very high complexity of behavior.

The American Mathematical Monthly, 2005

The São Paulo Journal of Mathematical Sciences, 2008

It is well-known that stable Cantor sets are topologically conjugate to adding machines. In this work we show are also conjugate to an algebraic object, the ring of P −adic integers with respect to group tramnslation. This ring is closely related to the field of p-adic numbers; connections and distintions are explored. The inverse limit construction provides a purely dynamical proof of an algebraic result: the classification of adding machines, or P −adic integers, up to group isomorphism.

Journal of Differential Equations, 2007

In the paper we describe basin of attraction p-adic dynamical system G(x) = (ax) 2 (x + 1). Moreover, we also describe the Siegel discs of the system, since the structure of the orbits of the system is related to the geometry of the p-adic Siegel discs.

Doklady Mathematics, 2012

Journal of Number Theory, 2013

This paper is devoted to (discrete) p-adic dynamical systems, an important domain of algebraic and arithmetic dynamics. We consider the following open problem from theory of p-adic dynamical systems.

Fundamenta Mathematicae, 2019

We initiate the study of p-adic algebraic groups G from the stability-theoretic and definable topological-dynamical points of view, that is, we consider invariants of the action of G on its space of types over Q p in the language of fields. We consider the additive and multiplicative groups of Q p and Z p , the group of upper triangular invertible 2 × 2 matrices, SL(2, Z p), and, our main focus, SL(2, Q p). In all cases we identify f-generic types (when they exist), minimal subflows, and idempotents. Among the main results is that the "Ellis group" of SL(2, Q p) iŝ Z, yielding a counterexample to Newelski's conjecture with new features: G = G 00 = G 000 but the Ellis group is infinite. A final section deals with the action of SL(2, Q p) on the type-space of the projective line over Q p .