We construct a stationary random tree, embedded in the upper half plane, with
prescribed offspring distribution and whose vertices are the atoms of a unit
Poisson point process. This process which we call Hammersley's tree process
extends the usual Hammersley's line process. Just as Hammersley's process is
related to the problem of the longest increasing subsequence, this model also
has a combinatorial interpretation: it counts the number of heaps (i.e.
increasing trees) required to store a random permutation. This problem was
initially considered by Byers et. al (2011) and Istrate and Bonchis (2015) in
the case of regular trees. We show, in particular, that the number of heaps
grows logarithmically with the size of the permutation

Basdevant, Anne-Laure

Gerin, Lucas

Gouere, Jean-Baptiste

Singh, Arvind

English

arXiv

International audienceWe construct a stationary random tree, embedded in the upper half plane, with prescribed offspring distribution and whose vertices are the atoms of a unit Poisson point process. This process which we call Hammersley's tree process extends the usual Hammersley's line process. Just as Hammersley's process is related to the problem of the longest increasing subsequence, this model also has a combinatorial interpretation: it counts the number of heaps (i.e. increasing trees) required to store a random permutation. This problem was initially considered by Byers et. al (2011) and Istrate and Bonchis (2015) in the case of regular trees. We show, in particular, that the number of heaps grows logarithmically with the size of the permutation

HAL-Polytechnique

From Hammersley's lines to Hammersley's trees

HAL Université de Tours

https://hal.archives-ouvertes.fr/hal-01313542

From Hammersley's lines to Hammersley's trees

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HAL-Polytechnique

HAL Université de Tours