Abstract
AbstractWe consider the process of uncovering the vertices of a random labeled tree according to their labels. First, a labeled tree with n vertices is generated uniformly at random. Thereafter, the vertices are uncovered one by one, in order of their labels. With each new vertex, all edges to previously uncovered vertices are uncovered as well. In this way, one obtains a growing sequence of forests. Three particular aspects of this process are studied in this work: first the number of edges, which we prove to converge to a stochastic process akin to a Brownian bridge after appropriate rescaling; second, the connected component of a fixed vertex, for which different phases are identified and limiting distributions determined in each phase; and lastly, the largest connected component, for which we also observe a phase transition.
Funder
Knut och Alice Wallenbergs Stiftelse
Publisher
Springer Science and Business Media LLC
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