English

Uniform Interpolation in Distributed Knowledge Modal Logics

Logic in Computer Science 2026-03-31 v1

Abstract

Uniform interpolation is the property that, for any formula and set of atoms, there exists the strongest consequence omitting those atoms. It plays a central role in knowledge representation and reasoning tasks such as knowledge update and information hiding. This paper studies the uniform interpolation property in epistemic modal logics with distributed knowledge, which captures agents' collective reasoning abilities. Building on the bisimulation-quantifier perspective, we extend the canonical-formula and literal-elimination framework of Fang, Liu, and van Ditmarsch to distributed knowledge settings and introduce the concept of collective pp-bisimulation. We show that, for distributed knowledge modal logics KnD\mathsf{K}_n\mathbf{D}, DnD\mathsf{D}_n\mathbf{D}, and TnD\mathsf{T}_n\mathbf{D}, every satisfiable canonical formula's uniform interpolant omitting an atom pp is exactly its remainder of eliminating pp. Then, we provide a finer analysis for the transitive and Euclidean systems K45nD\mathsf{K45}_n\mathbf{D}, KD45nD\mathsf{KD45}_n\mathbf{D}, and S5nD\mathsf{S5}_n\mathbf{D}, and prove that every formula of modal depth k+1k + 1 has a uniform interpolant of modal depth 2k+12 k + 1. Thus, we prove the uniform interpolation property in all the six distributed knowledge modal logics. Finally, we generalize the results to some variants with propositional common knowledge and discuss the method's limitations.

Keywords

Cite

@article{arxiv.2603.28036,
  title  = {Uniform Interpolation in Distributed Knowledge Modal Logics},
  author = {Kexu Wang and Liangda Fang},
  journal= {arXiv preprint arXiv:2603.28036},
  year   = {2026}
}
R2 v1 2026-07-01T11:43:28.784Z