Counting embeddings of rooted trees into families of rooted trees

Gittenberger, Bernhard; Gołębiewski, Zbigniew; Larcher, Isabella; Sułkowska, Małgorzata

doi:10.48550/arxiv.2008.08312

Cited by 1 publication

(1 citation statement)

References 31 publications

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“…In fact, both noncrossing matchings and plane trees belong to the so-called "Catalan family" (of combinatorial objects counted by Catalan numbers), and it turns out that the classical bijection between noncrossing matchings and plane trees is more precisely an order isomorphism between the associated pattern posets. The relevance of the notion of pattern (or related ones) for trees can also be inferred by several articles exploiting it to address a wide range of problems (see for instance [25] for application to generalization of the secretary problem, [20] where the asymptotic of pattern occurrence is studied, and [2] for an application to database theory).…”

Section: Combinatorics Of Intervals: Preliminary Resultsmentioning

confidence: 99%

Enumeration of Some Classes of Pattern Avoiding Matchings, with a Glimpse into the Matching Pattern Poset

Cervetti

Ferrari

2022

Ann. Comb.

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A matching of the set $$[2n]=\{1,2,\ldots ,2n\}$$ [ 2 n ] = { 1 , 2 , … , 2 n } is a partition of [2n] into blocks with two elements, i.e. a graph on [2n], such that every vertex has degree one. Given two matchings $$\sigma $$ σ and $$\tau $$ τ , we say that $$\sigma $$ σ is a $$pattern $$ pattern of $$\tau $$ τ when $$\sigma $$ σ can be obtained from $$\tau $$ τ by deleting some of its edges and consistently relabelling the remaining vertices. This is a partial order relation turning the set of all matchings into a poset, which will be called the matching pattern poset. In this paper, we continue the study of classes of pattern avoiding matchings (see below for previous work on this subject). In particular, we work out explicit formulas to enumerate the class of matchings avoiding two new patterns, obtained by juxtaposition of smaller patterns, and we describe a recursive formula for the generating function of the class of matchings avoiding the lifting of a pattern and two additional patterns. Moreover, we introduce the notion of unlabeled pattern, as a combinatorial way to collect patterns, and we provide enumerative formulas for two classes of matchings avoiding an unlabeled pattern of order three. In one case, the enumeration follows from an interesting bijection between the matchings of the class and ternary trees. The last part of the paper initiates the study of the matching pattern poset, by providing some preliminary results about its Möbius functions and the structure of some simple intervals.

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Section: Combinatorics Of Intervals: Preliminary Resultsmentioning

confidence: 99%