Convergence of Time-Average along Uniformly Behaved in N Sequences on Every Point
Abstract
We define a uniformly behaved in N arithmetic sequence a and an a-mean Lyapunov stable dynamical system f. We consider the time-average of a continuous function φ along the a-orbit of f up to N. The main result we prove in the paper is that this partial time-average converges for every point in the space if a is uniformly behaved in N and f is minimal and uniquely ergodic and a-mean Lyapunov stable. In addition, if a is also completely additive, we then prove that the time-average of a continuous function φ along the square-free a-orbit of f up to N converges for every point in the space as well. All equicontinuous dynamical systems are a-mean Lyapunov stable for any sequence a. When a is a subsequence of N with positive lower density, we give two non-trivial examples of a-mean Lyapunov stable dynamical systems. We give several examples of uniformly behaved in N sequences, including the counting function of the prime factors in natural numbers, the subsequence of natural numbers indexed by the Thue-Morse (or Rudin-Shapiro) sequence, and the sequence of even (or odd) prime factor natural numbers. We also show that the sequence of square-free natural numbers (or even (or odd) prime factor square-free natural numbers) is rotationally distributed in N but not uniformly distributed in Z, thus not uniformly behaved in N. We derive other consequences from the main result relevant to number theory and ergodic theory/dynamical systems.
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