set X = Niemytzki-plane ;
let x, y be Point of Niemytzki-plane; :: according to URYSOHN1:def 7 :: thesis: ( x = y or ex b1, b2 being Element of bool the carrier of Niemytzki-plane st
( b1 is open & b2 is open & x in b1 & not y in b1 & y in b2 & not x in b2 ) )
A1: the carrier of Niemytzki-plane = y>=0-plane by Def3;
then A2: y in y>=0-plane ;
x in y>=0-plane by A1;
then reconsider a = x, b = y as Point of (TOP-REAL 2) by A2;
assume x <> y ; :: thesis: ex b1, b2 being Element of bool the carrier of Niemytzki-plane st
( b1 is open & b2 is open & x in b1 & not y in b1 & y in b2 & not x in b2 )
then |.(a - b).| <> 0 by TOPRNS_1:28;
then reconsider r = |.(a - b).| as positive Real ;
consider q being Point of (TOP-REAL 2), U being open Subset of Niemytzki-plane such that
A3: x in U and
q in U and
A4: for c being Point of (TOP-REAL 2) st c in U holds
|.(c - q).| < r / 2 by Th30;
consider p being Point of (TOP-REAL 2), V being open Subset of Niemytzki-plane such that
A5: y in V and
p in V and
A6: for c being Point of (TOP-REAL 2) st c in V holds
|.(c - p).| < r / 2 by Th30;
take U ; :: thesis: ex b1 being Element of bool the carrier of Niemytzki-plane st
( U is open & b1 is open & x in U & not y in U & y in b1 & not x in b1 )
take V ; :: thesis: ( U is open & V is open & x in U & not y in U & y in V & not x in V )
thus ( U is open & V is open & x in U ) by A3; :: thesis: ( not y in U & y in V & not x in V )
hereby :: thesis: ( y in V & not x in V )
assume y in U ; :: thesis: contradiction
then |.(b - q).| < r / 2 by A4;
then A7: |.(a - q).| + |.(b - q).| < (r / 2) + (r / 2) by A3, A4, XREAL_1:8;
|.(a - b).| <= |.(a - q).| + |.(q - b).| by TOPRNS_1:34;
hence contradiction by A7, TOPRNS_1:27; :: thesis: verum
end;
thus y in V by A5; :: thesis: not x in V
assume A8: x in V ; :: thesis: contradiction
A9: |.(a - b).| <= |.(a - p).| + |.(p - b).| by TOPRNS_1:34;
|.(b - p).| < r / 2 by A5, A6;
then |.(a - p).| + |.(b - p).| < (r / 2) + (r / 2) by A8, A6, XREAL_1:8;
hence contradiction by A9, TOPRNS_1:27; :: thesis: verum