Modal logic, fundamentally

Abstract

Non-classical generalizations of classical modal logic have been developed in the contexts of constructive mathematics and natural language semantics. In this paper, we discuss a general approach to the semantics of non-classical modal logics via algebraic representation theorems. We begin with complete lattices L equipped with an antitone operation sending 1 to 0, a completely multiplicative operation , and a completely additive operation . Such lattice expansions can be represented by means of a set X together with binary relations , R, and Q, satisfying some first-order conditions, used to represent (L,), , and , respectively. Indeed, any lattice L equipped with such a , a multiplicative , and an additive embeds into the lattice of propositions of a frame (X,,R,Q). Building on our recent study of "fundamental logic", we focus on the case where is dually self-adjoint (a≤ b implies b≤ a) and a≤ a. In this case, the representations can be constrained so that R=Q, i.e., we need only add a single relation to (X,) to represent both and . Using these results, we prove that a system of fundamental modal logic is sound and complete with respect to an elementary class of bi-relational structures (X,, R).