English

Central Limit Theorem for $(t,s)$-sequences, I

Number Theory 2020-12-29 v1

Abstract

Let (Xn)n0 (X_n)_{n \geq 0} be a digital (t,s)(t,s)-sequence in base 22, Pm=(Xn)n=02m1\mathcal{P}_m =(X_n)_{n=0}^{2^m-1} , and let D(Pm,Y)D(\mathcal{P}_m, Y ) be the local discrepancy of Pm\mathcal{P}_m. Let TYT \oplus Y be the digital addition of TT and YY, and let Ms,p(Pm)=([0,1)2sD(PmT,Y)pdTdY)1/p.\mathcal{M}_{s,p} (\mathcal{P}_m) =\Big( \int_{[0,1)^{2s}} |D(\mathcal{P}_m \oplus T , Y ) |^p \mathrm{d}T \mathrm{d}Y \Big)^{1/p} . In this paper, we prove that D(PmT,Y)/Ms,2(Pm)D(\mathcal{P}_m \oplus T , Y ) / \mathcal{M}_{s,2} (\mathcal{P}_m) weakly converge to the standard Gaussisian distribution for mm \rightarrow \infty, where T,YT,Y are uniformly distributed random variables in [0,1)s[0,1)^s. In addition, we prove that \begin{equation} \nonumber \mathcal{M}_{s,p} (\mathcal{P}_m) / \mathcal{M}_{s,2} (\mathcal{P}_m) \to \frac{1}{\sqrt{2\pi}}\int_{-\infty}^{\infty} |u|^p e^{-u^2/2} \mathrm{d}u \quad {\rm for} \; \; m \to \infty , \;\; p>0. \end{equation}

Keywords

Cite

@article{arxiv.2012.14004,
  title  = {Central Limit Theorem for $(t,s)$-sequences, I},
  author = {Mordechay B. Levin},
  journal= {arXiv preprint arXiv:2012.14004},
  year   = {2020}
}
R2 v1 2026-06-23T21:27:52.271Z