Abstract
Let $(X, d)$ be an unbounded metric space and let $\tilde r=(r_n)_{n\in\mathbb N}$ be a sequence of positive real numbers tending to infinity. A pretangent space $\Omega_{\infty, \tilde r}^{X}$ to $(X, d)$ at infinity is a limit of the rescaling sequence $\left(X, \frac{1}{r_n}d\right).$ The set of all pretangent spaces $\Omega_{\infty, \tilde r}^{X}$ is called an asymptotic cluster of pretangent spaces. Such a cluster can be considered as a weighted graph $(G_{X, \tilde r}, \rho_{X})$ whose maximal cliques coincide with $\Omega_{\infty, \tilde r}^{X}$ and the weight $\rho_{X}$ is defined by metrics on $\Omega_{\infty, \tilde r}^{X}$. We describe the structure of metric spaces having finite asymptotic clusters of pretangent spaces and characterize the finite weighted graphs which are isomorphic to these clusters.
Highlights
Under an asymptotic cluster of metric spaces we mean the set of metric spaces which are the limits of rescaling metric spaces for rn tending to infinity
We describe the structure of metric spaces having finite asymptotic clusters of pretangent spaces and characterize the finite weighted graphs which are isomorphic to these clusters
Using some elements of the graph theory, we introduce the concept of cluster of pretangent spaces which will allow us to describe some relationships between these spaces
Summary
Under an asymptotic cluster of metric spaces we mean the set of metric spaces which are the limits of rescaling metric spaces for rn tending to infinity. The cluster of pretangent spaces to (X, d) at infinity is a graph GX,rwith the vertex set V (GX,r) consisting of the equivalence classes generated by the relation ≡ on Seq(X, r) and the edge set E(GX,r) defined by the rule: u, v ∈ V (GX,r) are adjacent if and only if u = v and every two sequences x ∈ u and y ∈ v are mutually stable. The first nontrivial result is Theorem 3.1 and Theorem 3.4 giving an explicit geometric description of unbounded metric spaces which have finite clusters of pretangent spaces These theorems are based on Lemma 3.3 which describes the interrelations between independent subsets of V (GX,r) and a property of the weight ρX. We mention only the Gromov product which can be used to define a metric structure on the boundaries of hyperbolic spaces [4], [20], the balleans theory [18] and the Wijsman convergence [13], [23], [24]
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