English

Intuitionistic Layered Graph Logic: Semantics and Proof Theory

Logic in Computer Science 2023-06-22 v4

Abstract

Models of complex systems are widely used in the physical and social sciences, and the concept of layering, typically building upon graph-theoretic structure, is a common feature. We describe an intuitionistic substructural logic called ILGL that gives an account of layering. The logic is a bunched system, combining the usual intuitionistic connectives, together with a non-commutative, non-associative conjunction (used to capture layering) and its associated implications. We give soundness and completeness theorems for a labelled tableaux system with respect to a Kripke semantics on graphs. We then give an equivalent relational semantics, itself proven equivalent to an algebraic semantics via a representation theorem. We utilise this result in two ways. First, we prove decidability of the logic by showing the finite embeddability property holds for the algebraic semantics. Second, we prove a Stone-type duality theorem for the logic. By introducing the notions of ILGL hyperdoctrine and indexed layered frame we are able to extend this result to a predicate version of the logic and prove soundness and completeness theorems for an extension of the layered graph semantics . We indicate the utility of predicate ILGL with a resource-labelled bigraph model.

Keywords

Cite

@article{arxiv.1702.05795,
  title  = {Intuitionistic Layered Graph Logic: Semantics and Proof Theory},
  author = {Simon Docherty and David Pym},
  journal= {arXiv preprint arXiv:1702.05795},
  year   = {2023}
}
R2 v1 2026-06-22T18:22:29.042Z