let a be Point of (TOP-REAL 2); :: thesis: inf (proj2 .: (north_halfline a)) = a `2
set X = proj2 .: (north_halfline a);
A1: proj2 .: (north_halfline a) is bounded_below by Th4;
A2: now
let r be real number ; :: thesis: ( r in proj2 .: (north_halfline a) implies a `2 <= r )
assume r in proj2 .: (north_halfline a) ; :: thesis: a `2 <= r
then consider x being set such that
A3: x in the carrier of (TOP-REAL 2) and
A4: x in north_halfline a and
A5: r = proj2 . x by FUNCT_2:115;
reconsider x = x as Point of (TOP-REAL 2) by A3;
r = x `2 by A5, PSCOMP_1:def 29;
hence a `2 <= r by A4, TOPREAL1:def 12; :: thesis: verum
end;
now
let s be real number ; :: thesis: ( 0 < s implies ex r being real number st
( r in proj2 .: (north_halfline a) & r < (a `2 ) + s ) )
assume A6: 0 < s ; :: thesis: ex r being real number st
( r in proj2 .: (north_halfline a) & r < (a `2 ) + s )
reconsider r = a `2 as real number ;
take r = r; :: thesis: ( r in proj2 .: (north_halfline a) & r < (a `2 ) + s )
( a in north_halfline a & r = proj2 . a ) by PSCOMP_1:def 29, TOPREAL1:45;
hence r in proj2 .: (north_halfline a) by FUNCT_2:43; :: thesis: r < (a `2 ) + s
r + 0 < (a `2 ) + s by A6, XREAL_1:10;
hence r < (a `2 ) + s ; :: thesis: verum
end;
hence inf (proj2 .: (north_halfline a)) = a `2 by A1, A2, SEQ_4:def 5; :: thesis: verum