On box dimension of the graphs of the generalized Riemann-type functions

Abstract

We investigate the box dimension of the graphs of a class of continuous periodic functions Gδ(x)=Σn=1∞g(n2x)n-1-δ with 1-periodic Lipschitz functions g and 0<δ 1, which generalizes the result of the classical Riemann function corresponding to g(x)=(2πx) and δ=1. More precisely, we first prove that the lower box dimension of the graph of Gδ is no less than 74-δ2 when the Fourier coefficients of g satisfy an arithmetic non-vanishing condition related to the distribution of quadratic residues. This result is new and non-trivial even when g has a finite Fourier expansion, highlighting the intrinsic arithmetic complexity of the series. Secondly, if g' is Lipschitz continuous on R, we show that the upper box dimension does not exceed \(74-δ2\), which extends earlier work of Chamizo and Córdoba and reveals deep connection between the regularity of g and the fractal dimension of the associated Riemann-type series. In the end, we give some illustrative examples and propose some further problems.

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