Translational tilings of the integers with long periods
The electronic journal of combinatorics, Tome 10 (2003)
Suppose that $A \subseteq {\Bbb{Z}}$ is a finite set of integers of diameter $D=\max A - \min A$. Suppose also that $B \subseteq {\Bbb{Z}}$ is such that $A\oplus B = {\Bbb{Z}}$, that is each $n\in{\Bbb{Z}}$ is uniquely expressible as $a+b$, $a\in A$, $b\in B$. We say then that $A$ tiles the integers if translated at the locations $B$ and it is well known that $B$ must be a periodic set in this case and that the smallest period of $B$ is at most $2^D$. Here we study the relationship between the diameter of $A$ and the least period ${\cal P}(B)$ of $B$. We show that ${\cal P}(B) \le c_2 \exp(c_3 \sqrt D \log D \sqrt{\log\log D})$ and that we can have ${\cal P}(B) \ge c_1 D^2$, where $c_1, c_2, c_3 > 0$ are constants.
@article{10_37236_1715,
author = {Mihail N. Kolountzakis},
title = {Translational tilings of the integers with long periods},
journal = {The electronic journal of combinatorics},
year = {2003},
volume = {10},
doi = {10.37236/1715},
zbl = {1107.11016},
url = {http://geodesic.mathdoc.fr/articles/10.37236/1715/}
}
Mihail N. Kolountzakis. Translational tilings of the integers with long periods. The electronic journal of combinatorics, Tome 10 (2003). doi: 10.37236/1715
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