Abbreviation: MA
A \emph{modal algebra} is a structure $\mathbf{A}=\langle A,\vee,0, \wedge,1,\neg,\diamond\rangle$ such that
$\langle A,\vee,0, \wedge,1,\neg\rangle $ is a Boolean algebras
$\diamond$ is \emph{join-preserving}: $\diamond(x\vee y)=\diamond x\vee \diamond y$
$\diamond$ is \emph{normal}: $\diamond 0=0$
Remark: Modal algebras provide algebraic models for modal logic. The operator $\diamond$ is the \emph{possibility operator}, and the \emph{necessity operator} $\Box$ is defined as $\Box x=\neg\diamond\neg x$.
Let $\mathbf{A}$ and $\mathbf{B}$ be modal algebras. A morphism from $\mathbf{A}$ to $\mathbf{B}$ is a function $h:A\to B$ that is a Boolean homomorphism and preserves $\diamond$:
$h(\diamond x)=\diamond h(x)$
Example 1:
Classtype | variety |
---|---|
Equational theory | decidable |
Quasiequational theory | decidable |
First-order theory | undecidable |
Locally finite | no |
Residual size | unbounded |
Congruence distributive | yes |
Congruence modular | yes |
Congruence n-permutable | yes, $n=2$ |
Congruence regular | yes |
Congruence uniform | yes |
Congruence extension property | yes |
Definable principal congruences | no |
Equationally def. pr. cong. | no |
Discriminator variety | no |
Amalgamation property | yes |
Strong amalgamation property | yes |
Epimorphisms are surjective | yes |
$\begin{array}{lr}
f(1)= &1
f(2)= &
f(3)= &
f(4)= &
f(5)= &
f(6)= &
\end{array}$