Bijections for Baxter families and related objects

The Baxter number B n can be written as B n = ∑ k = 0 n Θ k , n − k − 1 with Θ k , ℓ = 2 ( k + 1 ) 2 ( k + 2 ) ( k + ℓ k ) ( k + ℓ + 1 k ) ( k + ℓ + 2 k ) . These numbers have first appeared in the enumeration of so-called Baxter permutations; B n is the number of Baxter permutations of size n, and...

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Bibliographic Details
Published in:Journal of combinatorial theory. Series A Vol. 118; no. 3; pp. 993 - 1020
Main Authors: Felsner, Stefan, Fusy, Éric, Noy, Marc, Orden, David
Format: Journal Article Publication
Language:English
Published: Elsevier Inc 01.04.2011
Elsevier
Subjects:
05 Combinatorics
05A Enumerative combinatorics
05C Graph theory
Anàlisi combinatòria
Baxter numbers
Bijections
Catalan numbers
Catalan numbers (Mathematics)
Classificació AMS
Combinatorial analysis
Combinatorics
Combinatòria
Grafs, Teoria de
Graph theory
Matemàtica discreta
Matemàtiques i estadística
Mathematics
Nombres naturals
Orientations of planar maps
Schnyder woods
Teoria de grafs
Àrees temàtiques de la UPC
Bijections
Schnyder woods
Catalan numbers
Orientations of planar maps
Baxter numbers
binary trees
rectangulations
planar maps
Baxter permutations
ISSN:0097-3165, 1096-0899
Online Access:Get full text
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Summary:The Baxter number B n can be written as B n = ∑ k = 0 n Θ k , n − k − 1 with Θ k , ℓ = 2 ( k + 1 ) 2 ( k + 2 ) ( k + ℓ k ) ( k + ℓ + 1 k ) ( k + ℓ + 2 k ) . These numbers have first appeared in the enumeration of so-called Baxter permutations; B n is the number of Baxter permutations of size n, and Θ k , ℓ is the number of Baxter permutations with k descents and ℓ rises. With a series of bijections we identify several families of combinatorial objects counted by the numbers Θ k , ℓ . Apart from Baxter permutations, these include plane bipolar orientations with k + 2 vertices and ℓ + 2 faces, 2-orientations of planar quadrangulations with k + 2 white and ℓ + 2 black vertices, certain pairs of binary trees with k + 1 left and ℓ + 1 right leaves, and a family of triples of non-intersecting lattice paths. This last family allows us to determine the value of Θ k , ℓ as an application of the lemma of Lindström Gessel–Viennot. The approach also allows us to count certain other subfamilies, e.g., alternating Baxter permutations, objects with symmetries and, via a bijection with a class of plane bipolar orientations, also Schnyder woods of triangulations. Most of the enumerative results and some of the bijections are not new. Our contribution is mainly in the simplified and unifying presentation of this beautiful piece of combinatorics.
ISSN:0097-3165
1096-0899
DOI:10.1016/j.jcta.2010.03.017