Consider a certain quantum mechanical system with action $S[\phi]$, and let $$ G(1,\dots,n)\equiv\langle\phi_1\cdots\phi_n\rangle $$ be the $n$-point function. It is well-known that these functions satisfy a certain set of recurrence relations (cf. the Schwinger-Dyson equations) that allow us to write any $n$-point function as a combination of propagators and $n'$-point functions, for $n'=n,n+1,n+2,\dots$
The path integral of $S$ is the exponential generating functional of the sequence $\{G(1,\dots,n)\}$.
Let $G_t(1,\dots,n)$ be the tree-level contribution to the connected $n$-point function. The generating functional of these functions is the stationary-phase approximation to the path integral of $S$, and as such, I expect that there should exist a set of recurrence relations among them. In other words, we should be able to write any function $G_t(1,\dots,n)$ in terms of propagators and other functions $G_t(1,\dots,n')$. In fact, this is easily confirmed by calculating the first few tree-level $n$-point functions, which can always be written in terms of a finite series that involves propagators and vertices.
Question: What is the exact form of these recurrence relations? What is the analogous to the Schwinger-Dyson equations, but in terms of tree-level $n$ point functions instead of standard $n$-point functions?
