Modal companions share various properties of the original intermediate logic, which enables to study intermediate logics using tools developed for modal logic.
The translation is sometimes presented in slightly different ways: for example, one may insert
For any normal modal logic M that extends S4, we define its si-fragment ρM as The si-fragment of any normal extension of S4 is a superintuitionistic logic.
It can be shown that every superintuitionistic logic also has a largest modal companion, which is denoted by σL.
For example, S4 itself is the smallest modal companion of intuitionistic logic (IPC).
The largest modal companion of IPC is the Grzegorczyk logic Grz, axiomatized by the axiom over K. The smallest modal companion of classical logic (CPC) is Lewis' S5, whereas its largest modal companion is the logic More examples: The set of extensions of a superintuitionistic logic L ordered by inclusion forms a complete lattice, denoted ExtL.
Similarly, the set of normal extensions of a modal logic M is a complete lattice NExtM.
The companion operators ρM, τL, and σL can be considered as mappings between the lattices ExtIPC and NExtS4: It is easy to see that all three are monotone, and
L. Maksimova and V. Rybakov have shown that ρ, τ, and σ are actually complete, join-complete and meet-complete lattice homomorphisms respectively.
The cornerstone of the theory of modal companions is the Blok–Esakia theorem, proved independently by Wim Blok and Leo Esakia.
It states Accordingly, σ and the restriction of ρ to NExtGrz are called the Blok–Esakia isomorphism.
An important corollary to the Blok–Esakia theorem is a simple syntactic description of largest modal companions: for every superintuitionistic logic L, The Gödel translation has a frame-theoretic counterpart.
be a transitive and reflexive modal general frame.
The preorder R induces the equivalence relation on F, which identifies points belonging to the same cluster.
be the induced quotient partial order (i.e., ρF is the set of equivalence classes of
is an intuitionistic general frame, called the skeleton of F. The point of the skeleton construction is that it preserves validity modulo Gödel translation: for any intuitionistic formula A, Therefore, the si-fragment of a modal logic M can be defined semantically: if M is complete with respect to a class C of transitive reflexive general frames, then ρM is complete with respect to the class
The largest modal companions also have a semantic description.
, let σV be the closure of V under Boolean operations (binary intersection and complement).
The skeleton of σF is isomorphic to F. If L is a superintuitionistic logic complete with respect to a class C of general frames, then its largest modal companion σL is complete with respect to
The value of modal companions and the Blok–Esakia theorem as a tool for investigation of intermediate logics comes from the fact that many interesting properties of logics are preserved by some or all of the mappings ρ, σ, and τ.
For example, Every intermediate logic L has an infinite number of modal companions, and moreover, the set
of modal companions of L contains an infinite descending chain.
The set of modal companions of any L is either countable, or it has the cardinality of the continuum.
Rybakov has shown that the lattice ExtL can be embedded in
; in particular, a logic has a continuum of modal companions if it has a continuum of extensions (this holds, for instance, for all intermediate logics below KC).
The Gödel translation can be applied to rules as well as formulas: the translation of a rule is the rule A rule R is admissible in a logic L if the set of theorems of L is closed under R. It is easy to see that R is admissible in a superintuitionistic logic L whenever T(R) is admissible in a modal companion of L. The converse is not true in general, but it holds for the largest modal companion of L.