Mapping at Limit Inferior Precedes Limit Inferior of Composition Mapping and Sequence implies Supremum of Image is Mapping at Supremum of Directed Subset

Theorem
Let $\left({S, \vee_1, \wedge_1, \preceq_1}\right)$ and $\left({T, \vee_2, \wedge_2, \preceq_2}\right)$ be up-complete lattices.

Let $f: S \to T$ be a mapping such that
 * for all directed set $\left({D, \precsim}\right)$ and Moore-Smith sequence $N:D \to S$ in $S$: $f\left({\liminf N}\right) \preceq_2 \liminf\left({f \circ N}\right)$

Let $D$ be a directed subset of $S$.

Then $\sup \left({f\left[{D}\right]}\right) = f\left({\sup D}\right)$

where $f\left[{D}\right]$ denotes the image of $D$ under $f$.

Proof
By Mapping at Limit Inferior Precedes Limit Inferior of Composition Mapping and Sequence implies Mapping is Increasing:
 * $f$ is an increasing mapping.

By Image of Directed Subset under Increasing Mapping is Directed:
 * $f\left[{D}\right]$ is directed.

By definition of up-complete:
 * $D$ and $f\left[{D}\right]$ admit suprema.

By Subset and Image Admit Suprema and Mapping is Increasing implies Supremum of Image Precedes Mapping at Supremum:
 * $\sup \left({f\left[{D}\right]}\right) \preceq_2 f\left({\sup D}\right)$

By Limit Inferior of Inclusion Moore-Smith Sequence is Supremum of Directed Subset:
 * $\sup D = \liminf i_D$

By assumption:
 * $f\left({\sup D}\right) \preceq_2 \liminf \left({f \circ i_D}\right)$

By Composition of Mapping and Inclusion is Inclusion of Image:
 * $f \circ i_D = i_{f\left[{D}\right]}$

By Limit Inferior of Inclusion Moore-Smith Sequence is Supremum of Directed Subset:
 * $\sup \left({f\left[{D}\right]}\right) = \liminf \left({f \circ i_D}\right)$

Then
 * $f\left({\sup D}\right) \preceq_2 \sup \left({f\left[{D}\right]}\right)$

Thus by definition of antisymmetry:
 * $\sup \left({f\left[{D}\right]}\right) = f\left({\sup D}\right)$