Abstract
We study heavy subtrees of conditional Galton-Watson trees. In a standard Galton-Watson tree conditional on its size being n, we order all children by their subtree sizes, from large (heavy) to small. A node is marked if it is among the k heaviest nodes among its siblings. Unmarked nodes and their subtrees are removed, leaving only a tree of marked nodes, which we call the k-heavy tree. We study various properties of these trees, including their size and the maximal distance from any original node to the k-heavy tree. In particular, under some moment condition, the 2-heavy tree is with high probability larger than cn for some constant c>0, and the maximal distance from the k-heavy tree is O(n 1/(k+1)) in probability. As a consequence, for uniformly random Apollonian networks of size n, the expected size of the longest simple path is Ω(n). We also show that the length of the heavy path (that is, k=1) converges (after rescaling) to the corresponding object in Aldous’ Brownian continuum random tree.
| Original language | English |
|---|---|
| Article number | 2 |
| Number of pages | 44 |
| Journal | Electronic Journal of Probability |
| Volume | 24 |
| DOIs | |
| Publication status | Published - 5 Feb 2019 |
Keywords
- branching processes
- fringe trees
- spine decomposition
- binary trees
- continuum random trees
- Brownian excursion
- exponential functionals
- Apollonian networks