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The protection number of a vertex $v$ in a tree is the length of the shortest path from $v$ to any leaf contained in the maximal subtree where $v$ is the root. In this paper, we determine the distribution of the maximum protection number of a vertex in simply generated trees, thereby refining a recent result of Devroye, Goh, and Zhao. Two different cases can be observed: if the given family of trees allows vertices of outdegree $1$, then the maximum protection number is on average logarithmic in the tree size, with a discrete double-exponential limiting distribution. If no such vertices are allowed, the maximum protection number is doubly logarithmic in the tree size and concentrated on at most two values. These results are obtained by studying the singular behaviour of the generating functions of trees with bounded protection number. While a general distributional result by Prodinger and Wagner can be used in the first case, we prove a variant of that result in the second case.
We study several parameters of a random Bienaymé–Galton–Watson tree
$T_n$
of size
$n$
defined in terms of an offspring distribution
$\xi$
with mean
$1$
and nonzero finite variance
$\sigma ^2$
. Let
$f(s)=\mathbb{E}\{s^\xi \}$
be the generating function of the random variable
$\xi$
. We show that the independence number is in probability asymptotic to
$qn$
, where
$q$
is the unique solution to
$q = f(1-q)$
. One of the many algorithms for finding the largest independent set of nodes uses a notion of repeated peeling away of all leaves and their parents. The number of rounds of peeling is shown to be in probability asymptotic to
$\log n/\log (1/f'(1-q))$
. Finally, we study a related parameter which we call the leaf-height. Also sometimes called the protection number, this is the maximal shortest path length between any node and a leaf in its subtree. If
$p_1 = \mathbb{P}\{\xi =1\}\gt 0$
, then we show that the maximum leaf-height over all nodes in
$T_n$
is in probability asymptotic to
$\log n/\log (1/p_1)$
. If
$p_1 = 0$
and
$\kappa$
is the first integer
$i\gt 1$
with
$\mathbb{P}\{\xi =i\}\gt 0$
, then the leaf-height is in probability asymptotic to
$\log _\kappa \log n$
.
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