PNL to HOL: From the logic of nominal sets to the logic of higher-order functions

Permissive-Nominal Logic (PNL) extends first-order predicate logic with term-formers that can bind names in their arguments. It takes a semantics in (permissive-)nominal sets. In PNL, the ∀-quantifier or λ-binder are just term-formers satisfying axioms, and their denotation is functions on nominal atoms-abstraction.Then we have higher-order logic (HOL) and its models in ordinary (i.e. Zermelo–Fraenkel) sets; the denotation of ∀ or λ is functions on full or partial function spaces.This raises the following question: how are these two models of binding connected? What translation is possible between PNL and HOL, and between nominal sets and functions?We exhibit a translation of PNL into HOL, and from models of PNL to certain models of HOL. It is natural, but also partial: we translate a restricted subsystem of full PNL to HOL. The extra part which does not translate is the symmetry properties of nominal sets with respect to permutations. To use a little nominal jargon: we can translate names and binding, but not their nominal equivariance properties. This seems reasonable since HOL–and ordinary sets–are not equivariant.Thus viewed through this translation, PNL and HOL and their models do different things, but they enjoy non-trivial and rich subsystems which are isomorphic.