Extremal ranks of unlabeled multifurcating rooted trees in a bijective encoding by the positive integers

Abstract

Maranca and Rosenberg (2024) devised a ranking scheme for unlabeled multifurcating rooted trees, in which the trees are bijectively associated with the positive integers. Here, generalizing earlier results for bifurcating trees, we determine, for trees with a fixed number of leaves, which multifurcating trees obtain the maximal and minimal ranks. We identify these maximizing and minimizing trees for each of two sets of unlabeled multifurcating rooted trees: strictly k-furcating trees, in which each internal node possesses exactly k descendants, and at-most-k-furcating trees, in which internal nodes possess at least 2 and at most k descendants. In both scenarios, we find that a tree that can be regarded as maximally balanced attains the minimal rank, and a minimally balanced tree attains the maximal rank. We deduce recurrences for the maximal and minimal rank for trees with fixed numbers of leaves in both the strictly k-furcating and at-most-k-furcating cases. The maximal rank on (n-1)(k-1)+1 leaves grows with (k!)1k-1 βk(kn) in the strictly k-furcating case, and the maximal rank on n leaves grows with (k!)1k-1 γk(kn) in the at-most-k-furcating case, where βk > 1 and γk > 1 are constants that depend on the value of k. We show that βk decreases as the value of k increases, and that γk > βk for k ≥ 3. The results contribute to the use of tree encodings for empirical characterization of phylogenies and measurement of tree balance.