Continuous iff Mapping at Limit Inferior Precedes Limit Inferior of Composition of Mapping and Sequence

Theorem
Let $\struct {S, \preceq_1, \tau_1}$ and $\struct {T, \preceq_2, \tau_2}$ be complete topological lattices with Scott topologies.

Let $f: S \to T$ be a mapping.

Then $f$ is continuous :
 * for all directed set $\struct {D, \precsim}$ and net $N: D \to S$ in $S$: $\map f {\liminf N} \preceq_2 \map \liminf {f \circ N}$

Sufficient Condition
Assume that
 * $f$ is continuous.

Let $\struct {D, \precsim}$ be a directed set.

Let $N: D \to S$ be a net in $S$.


 * $\map f {\liminf N} \npreceq_2 \map \liminf {f \circ N}$

By definition of lower closure of element:
 * $\map f {\liminf N} \notin \paren {\map \liminf {f \circ N} }^{\preceq_2}$

By definition of relative complement:
 * $\map f {\liminf N} \in \relcomp T {\paren {\map \liminf {f \circ N} }^{\preceq_2} }$

By Lower Closure of Element is Topologically Closed in Scott Topological Ordered Set:
 * $\paren {\map \liminf {f \circ N} }^{\preceq_2}$ is closed.

By definition of closed set:
 * $\relcomp T {\paren {\map \liminf {f \circ N} }^{\preceq_2} }$ is open.

By definition of continuous:
 * $f^{-1} \sqbrk {\relcomp T {\paren {\map \liminf {f \circ N} }^{\preceq_2} } }$ is open.

By Open iff Upper and with Property (S) in Scott Topological Lattice:
 * $f^{-1} \sqbrk {\relcomp T {\paren {\map \liminf {f \circ N} }^{\preceq_2} } }$ has property (S).

By Set of Infima for Sequence is Directed:
 * $X := \set {\map \inf {N \sqbrk {\map \precsim j} }: j \in D}$ is directed.

By definition of limit inferior:
 * $\liminf N = \sup X$

By definition of preimage of set:
 * $\liminf N \in f^{-1} \sqbrk {\relcomp T {\paren {\map \liminf {f \circ N} }^{\preceq_2} } }$

By definition of property (S):
 * $\exists y \in X:\forall x \in X: y \preceq_1 x \implies x \in f^{-1} \sqbrk {\relcomp T {\paren {\map \liminf {f \circ N} }^{\preceq_2} } }$

We have:
 * $\exists j \in D: y = \map \inf {N \sqbrk {\map \precsim j} }$

By definition of reflexivity:
 * $y \preceq_1 y$

Then:
 * $y \in f^{-1} \sqbrk {\relcomp T {\paren {\map \liminf {f \circ N} }^{\preceq_2} } }$

Define $y' := \map \inf {\paren {f \circ N} \sqbrk {\map \precsim j} }$

Define $X' := \set {\map \inf {\paren {f \circ N} \sqbrk {\map \precsim j} }: j \in D}$

By Mapping is Increasing implies Mapping at Infimum for Sequence Precedes Infimum for Composition of Mapping and Sequence:
 * $\map f y \preceq_2 y'$

By definition of $X'$:
 * $y' \in X'$

By definitions of supremum and upper bound:
 * $y' \preceq_2 \sup X'$

By definition of limit inferior:
 * $\map \liminf {f \circ N} = \sup X'$

By definition of transitivity:
 * $\map f y \preceq_2 \map \liminf {f \circ N}$

By definition of lower closure of element:
 * $\map f y \in \paren {\map \liminf {f \circ N} }^{\preceq_2}$

By definition of preimage of set:
 * $y \in f^{-1} \sqbrk {\paren {\map \liminf {f \circ N} }^{\preceq_2} }$

By Complement of Preimage equals Preimage of Complement:
 * $f^{-1} \sqbrk {\relcomp T {\paren {\map \liminf {f \circ N} }^{\preceq_2} } } = \relcomp S {f^{-1} \sqbrk {\paren {\map \liminf {f \circ N} }^{\preceq_2} } }$

Thus this contradicts $y \in \relcomp S {f^{-1} \sqbrk {\paren {\map \liminf {f \circ N} }^{\preceq_2} } }$

Necessary Condition
Assume that
 * for all directed set $\struct {D, \precsim}$ and net $N: D \to S$ in $S$: $\map f {\liminf N} \preceq_2 \map \liminf {f \circ N}$

By Mapping at Limit Inferior Precedes Limit Inferior of Composition Mapping and Sequence implies Mapping Preserves Directed Suprema:
 * $f$ preserves directed suprema.

Thus by Mapping Preserves Directed Suprema implies Mapping is Continuous:
 * $f$ is continuous.