proximal neighborhood

Suppose first that $X$ and $\ll$ are defined as above. We will verify the individual nearness relation axioms of $\delta$ by proving their contrapositives in each case, except the last axiom:

1. 1.

   if $A{\delta }^{\prime }B$, then $A\ll B^{\prime }$, or $A\subseteq B^{\prime }$, so $A\cap B=\mathrm{\varnothing }$;

2. 2.

   suppose either $A=\mathrm{\varnothing }$ or $B=\mathrm{\varnothing }$. In either case, $A\ll B^{\prime }$, which means $A{\delta }^{\prime }B$;

3. 3.

   if $A{\delta }^{\prime }B$, then $A\ll B^{\prime }$, so $B^{\prime \prime }\ll A^{\prime }$, or $B\ll A^{\prime }$, or $B{\delta }^{\prime }A$;

4. 4.

   if $A_1{\delta }^{\prime }B$ and $A_2{\delta }^{\prime }B$, then $A_1\ll B$ and $A_2\ll B$, so $(A_1\cup A_2)\ll B$, or $(A_1\cup A_2){\delta }^{\prime }B$;

5. 5.

   if $A{\delta }^{\prime }B$, then $A\ll B^{\prime }$. So there is $D\subseteq X$ with $A\ll D$ and $D\ll B^{\prime }$. Let $C=D^{\prime }$. Then $A\ll C^{\prime }$ and $C^{\prime }\ll B^{\prime }$, or $A{\delta }^{\prime }C$ and $C^{\prime }{\delta }^{\prime }B$.

Next, suppose $(X,\delta )$ is a proximity space. We now verify the six properties of $\ll$ above.

1. 1.

   since $X{\delta }^{\prime }\mathrm{\varnothing }$, $X\ll {\mathrm{\varnothing }}^{\prime }$, or $X\ll X$;

2. 2.

   suppose $A{\delta }^{\prime }{B}^{\prime }$, then if $x\in A$, we have $x{\delta }^{\prime }{B}^{\prime }$, implying $x\cap B^{\prime }=\mathrm{\varnothing }$, or $x\in B$;

3. 3.

   if $A\ll B$ and $C\ll D$, then $A{\delta }^{\prime }{B}^{\prime }$ and $C{\delta }^{\prime }{D}^{\prime }$, which means $A{\delta }^{\prime }(B^{\prime }\cup D^{\prime })$ and $C{\delta }^{\prime }(B^{\prime }\cup D^{\prime })$, which together imply $(A\cap C){\delta }^{\prime }(B^{\prime }\cup D^{\prime })$, or $(A\cap C)\delta {(B\cap D)}^{\prime }$, or $A\cap C\ll B\cap D$;

4. 4.

   if $A\ll B$, then $A{\delta }^{\prime }{B}^{\prime }$, so $B^{\prime }{\delta }^{\prime }A$ (as $\delta$ is symmetric, so is its complement), which is the same as $B^{\prime }{\delta }^{\prime }{A}^{\prime \prime }$, or $B^{\prime }\ll A^{\prime }$;

5. 5.

   if $A\delta D^{\prime }$, then $B\delta C^{\prime }$ (since $A\subseteq B$ and $D^{\prime }\subseteq C^{\prime }$), so $B{\ll }^{\prime }C$, a contradiction;

6. 6.

   if $A\ll B$, then $A{\delta }^{\prime }{B}^{\prime }$, so there is $D\subseteq X$ with $A{\delta }^{\prime }D$ and $D^{\prime }{\delta }^{\prime }{B}^{\prime }$. Define $C=D^{\prime }$, then $A\ll C$ and $C\ll B$, as desired.

This completes the proof. ∎

Since $A{\delta }^{\prime }{B}^{\prime }$, then $x{\delta }^{\prime }{B}^{\prime }$ whenever $x\in A$, which is the contrapositive of the statement: $x\in A^{\prime }$ whenever $x\delta B^{\prime }$, which is equivalent to $B^{\prime c}\subseteq A^{\prime }$, or $A\subseteq B^{\circ }$. Furthermore, if $x\notin B$, then $x\in B^{\prime }$. But $A{\delta }^{\prime }{B}^{\prime }$ b assumption. This implies $x{\delta }^{\prime }A$, which means $x\notin A^c$. Therefore $A^c\subseteq B$. ∎