Periodicity and local complexity of Delone sets
Abstract
We study complexity and periodicity of Delone sets by applying an algebraic approach to multidimensional symbolic dynamics. In this algebraic approach, Zd-configurations c: Zd A for a finite set A ⊂eq C and finite Zd-patterns are regarded as formal power series and Laurent polynomials, respectively. In this paper we study also functions c: Rd A where A is as above. These functions are called Rd-configurations. Any Delone set may be regarded as an Rd-configuration by simply presenting it as its indicator function. Conversely, any Rd-configuration whose support (that is, the set of cells for which the configuration gets non-zero values) is a Delone set can be seen as a colored Delone set. We generalize the concept of annihilators and periodizers of Zd-configurations for Rd-configurations. We show that if an Rd-configuration has a non-trivial annihilator, that is, if a linear combination of some finitely many of its translations is the zero function, then it has an annihilator of a particular form. Moreover, we show that Rd-configurations with integer coefficients that have non-trivial annihilators are sums of finitely many periodic functions c1,…,cm: Rd Z. Also, Rd-pattern complexity is studied alongside with the classical patch-complexity of Delone sets. We point out the fact that sufficiently low Rd-pattern complexity of an Rd-configuration implies the existence of non-trivial annihilators. Moreover, it is shown that if a Meyer set has sufficiently slow patch-complexity growth, then it has a non-trivial annihilator. Finally, a condition for forced periodicity of colored Delone sets of finite local complexity is provided.
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