Random expansions of trees with bounded height

Abstract

We consider a sequence T = (Tn : n ∈ N+) of trees Tn where, for some ∈ N+ every Tn has height at most and as n ∞ the minimal number of children of a nonleaf tends to infinity. We can view every tree as a (first-order) τ-structure where τ is a signature with one binary relation symbol. For a fixed (arbitrary) finite and relational signature σ ⊃eq τ we consider the set Wn of expansions of Tn to σ and a probability distribution Pn on Wn which is determined by a (parametrized/lifted) Probabilistic Graphical Model (PGM) G which can use the information given by Tn. The kind of PGM that we consider uses formulas of a many-valued logic that we call PLA* with truth values in the unit interval [0, 1]. We also use PLA* to express queries, or events, on Wn. With this setup we prove that, under some assumptions on T, G, and a (possibly quite complex) formula (x1, …, xk) of PLA*, as n ∞, if a1, …, ak are vertices of the tree Tn then the value of (a1, …, ak) will, with high probability, be almost the same as the value of (a1, …, ak), where (x1, …, xk) is a ``simple'' formula the value of which can always be computed quickly (without reference to n), and itself can be found by using only the information that defines T, G and . A corollary of this, subject to the same conditions, is a probabilistic convergence law for PLA*-formulas.

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