Ideals form Arithmetic Lattice

Theorem
Let $L = \left({S, \vee, \wedge, \preceq}\right)$ be a bounded below lattice.

Let $I = \left({\mathit{Ids}\left({L}\right), \precsim}\right)$ be an inclusion ordered set

where
 * $\mathit{Ids}\left({L}\right)$ denotes the set of all ideals in $L$,
 * $\mathord\precsim = \mathord\subseteq \cap \left({\mathit{Ids}\left({L}\right) \times \mathit{Ids}\left({L}\right)}\right)$

Then $I$ is an arithmetic lattice.

Proof
We will prove that
 * $\forall x, y \in K\left({I}\right): \exists z \in K\left({I}\right): z \precsim x \land z \precsim y \land \forall v \in K\left({I}\right): v \precsim x \land v \precsim y \implies v \precsim z$

Let $x, y \in K\left({I}\right)$.

By definition of compact subset:
 * $x$ and $y$ are compact elements in $I$.

By Compact Element iff Principal Ideal and definition of principal ideal:
 * $\exists a \in S: x = a^\preceq$

and
 * $\exists b \in S: y = b^\preceq$

By Intersection of Ideals is Ideal:
 * $x \cap y \in \mathit{Ids}\left({L}\right)$

Define $z = x \cap y$.

By Meet in Set of Ideals:
 * $z = x \wedge_I y$

We will prove that
 * $\left({a \wedge b}\right)^\preceq \subseteq z$

Let $c \in \left({a \wedge b}\right)^\preceq$

By definition of lower closure of element:
 * $c \preceq a \wedge b$

By Meet Precedes Operands:
 * $a \wedge b \preceq a$ and $a \wedge b \preceq b$

By definition of transitivity:
 * $c \preceq a$ and $c \preceq b$

By definition of lower closure of element:
 * $c \in x$ and $c \in y$

Thus by definition of intersection:
 * $c \in z$

We will prove that
 * $z \subseteq \left({a \wedge b}\right)^\preceq$

Let $c \in z$.

By definition of intersection:
 * $c \in x$ and $c \in y$

By definition of lower closure of element:
 * $c \preceq a$ and $c \preceq b$

By definitions of infimum and lower bound:
 * $c \preceq a \wedge b$

Thus by definition of lower closure of element:
 * $c \in \left({a \wedge b}\right)^\preceq$

By definition of set equality:
 * $z = \left({a \wedge b}\right)^\preceq$

By definition:
 * $z$ is a principal ideal.

By Compact Element iff Principal Ideal:
 * $z$ is a compact element in $I$.

Thus by definition of compact subset:
 * $z \in K\left({I}\right)$

Thus by Meet Precedes Operands:
 * $z \precsim x$ and $z \precsim y$

Let $v \in K\left({I}\right)$ such that
 * $v \precsim x$ and $v \precsim y$

By definition of $\precsim$:
 * $v \subseteq x$ and $v \subseteq y$

By Intersection is Largest Subset:
 * $v \subseteq z$

Thus by definition of $\precsim$:
 * $v \precsim z$

By definition:
 * $K\left({I}\right)$ form a meet semilattice.

By Compact Subset is Join Subsemilattice:
 * $K\left({I}\right)$ form a join semilattice.

By definition:
 * $K\left({I}\right)$ form a lattice.

By Ideals form Algebraic Lattice:
 * $I$ is an algebraic lattice.

Thus by Arithmetic iff Compact Subset form Lattice in Algebraic Lattice:
 * $I$ is an arithmetic lattice.