Open Cover with Closed Locally Finite Refinement is Even Cover/Lemma 2

Theorem
Let $T = \struct {X, \tau}$ be a topological Space.

Let $\UU$ be an open cover of $T$.

Let $\AA$ be a closed locally finite refinement of $\UU$.

For each $A \in \AA$, let $U_A \in \UU$ such that $A \subseteq U_A$.

Let $T \times T = \struct {X \times X, \tau_{X \times X} }$ denote the product space of $T$ with itself.

For each $A \in \AA$, let:
 * $V_A = \paren {U_A \times U_A} \cup \paren {\paren {X \setminus A} \times \paren {X \setminus A} }$

Let:
 * $V = \ds \bigcap_{A \mathop \in \AA} V_A$

Let $\Delta_X$ denote the diagonal on $X$.

Then:
 * $V$ is a neighborhood of the diagonal $\Delta_X$ in $T \times T$.

Proof
Let $x \in X$.

By definition of locally finite:
 * $\exists W \in \tau : x \in W : \set {A \in \AA : W \cap A \ne \O}$ is finite.

Let:
 * $A \in \AA : W \cap A = \O$

From Subset of Set Difference iff Disjoint Set:
 * $W \subseteq X \setminus A$

From Cartesian Product of Subsets:
 * $W \times W \subseteq \paren {X \setminus A} \times \paren {X \setminus A} \subseteq V_A$

Since $A$ was arbitrary, we have established:
 * $\forall A \in \AA : W \cap A = \O \leadsto W \times W \subseteq V_A$

From Set is Subset of Intersection of Supersets:
 * $W \times W \subseteq \bigcap \set {V_A : A \in \AA : W \cap A = \O}$

From Intersection with Subset is Subset:
 * $(1): \quad W \times W = \paren {W \times W} \cap \bigcap \set {V_A : A \in \AA : W \cap A = \O}$

We have:

By definition of product topology:
 * $W \times W$ is open in $T \times T$

Lemma 4
Recall:
 * $\set{A \in \AA : W \cap A \ne \O}$ is finite

By :
 * $\paren{W \times W} \cap V$ is open in $T \times T$

By definition of Cartesian product:
 * $\tuple{x, x} \in W \times W$

By definition of diagonal $\Delta_X$:
 * $\tuple{x, x} \in \Delta_X$

By definition of open neighborhood:
 * $\forall A \in \AA : \tuple{x, x} \in \Delta_X \subseteq V_A$

By definition of set intersection:
 * $\tuple{x, x} \in \paren{W \times W} \cap V$

Hence:
 * $V$ is a neighborhood of $\tuple{x, x}$ in $T \times T$ by definition.

Since $x \in X$ was arbitrary, then:
 * $\forall x \in X : V$ is a neighborhood of $\tuple {x, x}$ in $T \times T$

From Set is Neighborhood of Subset iff Neighborhood of all Points of Subset:
 * $V$ is a neighborhood of the diagonal $\Delta_X$ in $T \times T$.