Limit laws are proven by
the contraction method for random vectors of a recursive nature as they
arise as parameters of
combinatorial structures such as random trees or recursive algorithms,
where we use the Zolotarev metric.
In comparison to previous applications of this method, a general transfer
theorem is derived
which allows us to establish a limit law on the basis of the recursive
structure and the
asymptotics of the first and second moments of the sequence.
In particular, a general asymptotic normality result is obtained by this
theorem which
typically cannot be handled by the more common $\ell_2$ metrics.
As applications we derive quite automatically many asymptotic limit
results ranging
from the size of tries or $m$-ary search trees and path lengths in digital
structures to mergesort and parameters of random recursive trees,
which were previously shown by different methods one by one.
We also obtain a related local density approximation result as well as a
global
approximation result. For the proofs of these results we establish that
a smoothed density distance
as well as a smoothed total variation distance can be estimated from above
by the Zolotarev metric, which is the main tool in this article.
Publié le : 2004-02-14
Classification:
Contraction method,
multivariate limit law,
asymptotic normality,
random trees,
recursive algorithms,
divide-and-conquer algorithm,
random recursive structures,
Zolotarev metric,
60F05,
68Q25,
68P10
@article{1075828056,
author = {Neininger, Ralph and R\"uschendorf, Ludger},
title = {A general limit theorem for recursive algorithms and combinatorial structures},
journal = {Ann. Appl. Probab.},
volume = {14},
number = {1},
year = {2004},
pages = { 378-418},
language = {en},
url = {http://dml.mathdoc.fr/item/1075828056}
}
Neininger, Ralph; Rüschendorf, Ludger. A general limit theorem for recursive algorithms and combinatorial structures. Ann. Appl. Probab., Tome 14 (2004) no. 1, pp. 378-418. http://gdmltest.u-ga.fr/item/1075828056/