Abstract
There has been renewed interest in recent years in McKinsey and Tarski's interpretation of modal logic in topological spaces and their proof that S4 is the logic of any separable dense-in-itself metric space. Here we extend this work to the modal mu-calculus and to a logic of tangled closure operators that was developed by Fernández-Duque after these two languages had been shown by Dawar and Otto to have the same expressive power over finite transitive Kripke models. We prove that this equivalence remains true over topological spaces.We extend the McKinsey–Tarski topological ‘dissection lemma’. We also take advantage of the fact (proved by us elsewhere) that various tangled closure logics with and without the universal modality ∀ have the finite model property in Kripke semantics. These results are used to construct a representation map (also called a d-p-morphism) from any dense-in-itself metric space X onto any finite connected locally connected serial transitive Kripke frame.This yields completeness theorems over X for a number of languages: (i) the modal mu-calculus with the closure operator ◇; (ii) ◇ and the tangled closure operators 〈t〉 (in fact 〈t〉 can express ◇); (iii) ◇,∀; (iv) ◇,∀,〈t〉; (v) the derivative operator 〈d〉; (vi) 〈d〉 and the associated tangled closure operators 〈dt〉; (vii) 〈d〉,∀; (viii) 〈d〉,∀,〈dt〉. Soundness also holds, if: (a) for languages with ∀, X is connected; (b) for languages with 〈d〉, X validates the well-known axiom G1. For countable languages without ∀, we prove strong completeness. We also show that in the presence of ∀, strong completeness fails if X is compact and locally connected.
Highlights
Modal logic can be given semantics over topological spaces
McKinsey and Tarski [27] proved that the logic of any given separable1 dense-in-itself metric space in this semantics is S4: it can be axiomatised by the basic modal Hilbert system K augmented by the two axioms 2φ → φ (T) and 2φ → 22φ (4)
Adding the tangled closure operators, we prove that the logic of every dense-in-itself metric space that validates G1 is axiomatised by KD4G1t
Summary
Modal logic can be given semantics over topological spaces. In this setting, the modality 3 can be interpreted in more than one way. McKinsey and Tarski [27] proved that the logic of any given separable dense-in-itself metric space in this semantics is S4: it can be axiomatised by the basic modal Hilbert system K augmented by the two axioms 2φ → φ (T) and 2φ → 22φ (4). Adding the tangled closure operators, we prove that the logic of every dense-in-itself metric space that validates G1 is axiomatised by KD4G1t (including the tangle axioms). Further adding the universal modality, we show that KD4G1t.UC (and KD4G1.UC if the tangle closure operators are dropped) axiomatises the logic of every connected dense-in-itself metric space that validates G1. We do not assume separability, we consider languages that have not previously been much studied in the topological setting, and we obtain some results on strong completeness, a matter that has only recently been investigated in this arena
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