Approximation by Quantum Meyer K\"onig and Zeller-Fractal Functions

Abstract

In this paper, a novel class of quantum fractal functions is introduced based on the Meyer-K\"onig-Zeller operator Mq,n. These quantum Meyer-K\"onig-Zeller (MKZ) fractal functions employ Mq,n f as the base function in the iterated function system for α-fractal functions. For f∈ C(I), I closed in R, it is shown that there exists a sequence of quantum MKZ fractal functions \f(qn,α)n\n=0∞ which converges uniformly to f without altering the scaling function α. The shape of f(qn,α)n depends on q as well as the other IFS parameters. For f,g∈ C(I) with g > 0 or f≥ g, we show that there exists a sequence \f(qn,α)n\n=0∞ with f(qn,α)n ≥ g converging to f. Quantum MKZ fractal versions of some classical M\"untz theorems are also presented. For q=1, the box dimension and some approximation-theoretic results of MKZ α-fractal function are investigated in C(I). Finally, MKZ α-fractal functions are studied in Lp spaces with p ≥ 1.