In a recent paper studying some generalizations of Stirling numbers, my coauthors and I needed the following result:

If $f(x)=\sum_{n \geq 1} a_n x^n/n!$ is a power series with $a_1 \neq 0$, and $g(x) = \sum_{n \geq 1} b_n x^n/n!$ is its series reversion (so $f(g(x))=g(f(x))=x$), then
$$
b_n = \sum_{T} w(T)
$$

where the sum is over phylogenetic trees on $\{1, \ldots, n\}$. Here a *phylogenetic tree* on $\{1,\ldots, n\}$ is a rooted tree with $n$ leaves, no vertex with exactly one child, and leaves labelled from the set $\{1, \ldots, n\}$ (but no other vertex receiving a label); see page 3 of the paper linked above for a picture. The weight $w(T)$ is computed as follows: if $T$ has $n$ leaves and $m$ non-leaves then
$$
w(T) = (−1)^m a_1^{-(m+n)} \prod \{a_{d(v)}: v~\mbox{a non-leaf}\}
$$
where $d(v)$ denotes the number of children of $v$ (and when $n=1$ the isolated vertex is considered a leaf).

The proof is short, and this feels like something that should have been written down prior to now, but we could find no reference.

**Question**: Has the above result appeared in the literature?

(There is a paper of Chen from 1990 with a similar result but with a distinctly different and not obviously equivalent formulation. Chen shows that $b_n$ is a weighted sum over *Schroeder trees*: trees on $n$ labelled *vertices* (as opposed to leaves), with no restriction on numbers of children, in which each non-leaf is endowed with an ordered partition of its children. The count of Schroeder trees by number of vertices is A053492. The count of phylogenetic trees by number of leaves is A000311.)