Filter Basis Generates Filter

Theorem
Let $S$ be a set.

Let $\powerset S$ be the power set of $S$.

Let $\BB \subset \powerset S$.

Then:
 * $\FF = \set {V \subseteq S: \exists U \in \BB: U \subseteq V}$ is a filter on $S$


 * $(1): \quad \forall V_1, V_2 \in \BB: \exists U \in \BB: U \subseteq V_1 \cap V_2$
 * $(2): \quad \O \notin \BB, \BB \ne \O$
 * $(2): \quad \O \notin \BB, \BB \ne \O$

That is, $\BB$ is a filter basis of the filter $\FF$, which is generated by $\BB$.

Proof
Assume first that $\FF$ is a filter on $S$.

Then $S \in \FF$ and thus $\BB \ne \O$.

Because $\O \notin \FF$ we have that $\O \notin \BB$, since $\BB \subseteq \FF$.

Let $V_1, V_2 \in \BB$, then $V_1, V_2 \in \FF$.

Because $\FF$ is a filter:
 * $V := V_1 \cap V_2 \in \FF$

The definition of $\FF$ implies therefore that there is $U \in \BB$ such that $U \subseteq V = V_1 \cap V_2$.

Assume now that $\BB$ satisfies conditions $(1)$ and $(2)$.

To show that $\FF$ is a filter, note that because $\BB \ne \O$ there is a $B \in \BB$.

Because $\BB \subset \powerset S$ we know that $B \subseteq S$ and thus $S \in \FF$ by the definition of $\FF$.

Because:
 * the only subset of $\O$ is $\O$

and:
 * since $\O \notin \BB$

it follows that:
 * $\O \notin \FF$

Let $V_1, V_2 \in \FF$.

Then there exist $U_1, U_2 \in \BB$ such that $U_1 \subseteq V_1$ and $U_2 \subseteq V_2$.

Because $\BB$ satisfies condition $(1)$ there exists a set $U \in \BB$ for which $U \subseteq U_1 \cap U_2$ holds.

Because $U_1 \cap U_2 \subseteq V_1 \cap V_2$ this implies that:
 * $U \subseteq V_1 \cap V_2$

and therefore:
 * $V_1 \cap V_2 \in \FF$