A limit theorem for sample maxima and heavy branches in Galton–Watson trees

G. L. O'brien

doi:10.2307/3213043

Abstract

Let Yn be the maximum of n independent positive random variables with common distribution function F and let Sn be their sum. Then converges to zero in probability if and only if is slowly varying. This result implies that in a supercritical Galton-Watson process which does not become extinct, there cannot be a sequence {τ n} of particles, each descended from the preceding one, such that the fraction of all particles which are descendants of τ n does not converge to zero as n →∞. Weakly m-adic trees, which behave to some extent like sample Galton-Watson trees, can have such sequences of particles.

Footnotes

Research supported in part by the Natural Sciences and Engineering Research Council of Canada. I am grateful to Cornell University, whose hospitality I enjoyed while working on part of this paper.

References

Athreya, K. B. and Ney, P. E. (1972) Branching Processes. Springer-Verlag, New York.Google Scholar

Chow, Y. S. and Teicher, H. (1978) Probability Theory: Independence, Interchangeability, Martingales. Springer-Verlag, New York.Google Scholar

Darling, D. A. (1952) The influence of the maximum term in the addition of independent random variables. Trans. Amer. Math. Soc. 73, 95–107.Google Scholar

Feller, W. (1966) An Introduction to Probability Theory and its Applications, Vol. 2, 1st edn. Wiley, New York.Google Scholar

Joffe, A. (1978) Remarks on the structure of trees with applications to supercritical Galton-Watson processes. In Advances in Probability 5, ed. Joffe, A. and Ney, P., Dekker, New York, 263–268.Google Scholar

Joffe, A. and Moncayo, A. R. (1973) Random variables, trees and branching random walks. Adv. Math. 10, 401–416.Google Scholar

Kesten, H. (1971) Sums of random variables with infinite expectation. Solution to Advanced Problem #5716. Amer. Math. Monthly 78, 305–308.Google Scholar

Seneta, E. (1974) Regularly varying functions in the theory of simple branching processes. Adv. Appl. Prob. 6, 408–420.Google Scholar

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Vatutin, V. A. and Zubkov, A. M. 1987. Branching processes. I. Journal of Soviet Mathematics, Vol. 39, Issue. 1, p. 2431.

Sepanski, Steven J. 1994. Probabilistic characterizations of the Generalized Domain of Attraction of the multivariate normal law. Journal of Theoretical Probability, Vol. 7, Issue. 4, p. 857.

Gine, Evarist 1997. Lectures on Probability Theory and Statistics. Vol. 1665, Issue. , p. 37.

Chauvin, B. and Rouault, A. 1997. Classical and Modern Branching Processes. Vol. 84, Issue. , p. 41.

Giné, Evarist Götze, Friedrich and Mason, David M. 1997. When is the Student $t$-statistic asymptotically standard normal?. The Annals of Probability, Vol. 25, Issue. 3,

Liu, Quansheng and Rouault, Alain 1997. Classical and Modern Branching Processes. Vol. 84, Issue. , p. 187.

Mason, David M. and Shao, Qi-Man. 2001. Bootstrapping the Student t-Statistic. The Annals of Probability, Vol. 29, Issue. 4,

Račkauskas, Alfredas and Suquet, Charles 2001. Invariance principles for adaptive self-normalized partial sums processes. Stochastic Processes and their Applications, Vol. 95, Issue. 1, p. 63.

Kruglov, V. M. and Petrovskaya, G. N. 2002. Weak Convergence of a Certain Functional. Theory of Probability & Its Applications, Vol. 46, Issue. 4, p. 721.

CsõRGõ, MiklÓS 2002. A glimpse of the impact of pál erd#ous on probability and statistics. Canadian Journal of Statistics, Vol. 30, Issue. 4, p. 493.

Csörgő, Miklós Szyszkowicz, Barbara and Wu, Qiying 2003. Donsker's theorem for self-normalized partial sums processes. The Annals of Probability, Vol. 31, Issue. 3,

Račkauskas, Alfredas and Suquet, Charles 2004. Hölder norm test statistics for epidemic change. Journal of Statistical Planning and Inference, Vol. 126, Issue. 2, p. 495.

Neves, Cláudia Picek, Jan and Fraga Alves, M.I. 2006. The contribution of the maximum to the sum of excesses for testing max-domains of attraction. Journal of Statistical Planning and Inference, Vol. 136, Issue. 4, p. 1281.

Downey, Peter J. and Wright, Paul E. 2007. The ratio of the extreme to the sum in a random sequence. Extremes, Vol. 10, Issue. 4, p. 249.

Ladoucette, Sophie A. and Teugels, Jef L. 2007. Asymptotics for Ratios with Applications to Reinsurance. Methodology and Computing in Applied Probability, Vol. 9, Issue. 2, p. 225.

Martsynyuk, Yu. V. 2009. Functional asymptotic confidence intervals for the slope in linear error-in-variables models. Acta Mathematica Hungarica, Vol. 123, Issue. 1-2, p. 133.

2011. Extreme Value Methods with Applications to Finance. Vol. 20114852, Issue. , p. 351.

Jones, Owen and Rolls, David 2011. A characterisation of, and hypothesis test for, continuous local martingales. Electronic Communications in Probability, Vol. 16, Issue. none,

Decrouez, Geoffrey and Jones, Owen Dafydd 2012. A class of multifractal processes constructed using an embedded branching process. The Annals of Applied Probability, Vol. 22, Issue. 6,

Choi, Jinho 2012. Rate Allocation for Multipath Routing in Wireless Multihop Networks with Security Constraints Based on Erasure Channel Modeling. IEEE Transactions on Communications, Vol. 60, Issue. 9, p. 2689.

Download full list

Article contents

A limit theorem for sample maxima and heavy branches in Galton–Watson trees

Abstract

Keywords

Access options

Footnotes

References

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

A limit theorem for sample maxima and heavy branches in Galton–Watson trees

Abstract

Keywords

Access options

Footnotes

References

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests