let A, B be ext-real-membered set ; :: thesis: ( A is right_end & A is interval & B is interval & sup A = inf B implies A \/ B is interval )
assume that
A1: ( A is right_end & A is interval ) and
A2: B is interval and
A3: sup A = inf B ; :: thesis: A \/ B is interval
set z = inf B;
A4: inf B in A by A1, A3;
for x, y, r being ExtReal st x in A \/ B & y in A \/ B & x < r & r < y holds
r in A \/ B
proof
let x, y, r be ExtReal; :: thesis: ( x in A \/ B & y in A \/ B & x < r & r < y implies r in A \/ B )
assume that
A5: x in A \/ B and
A6: y in A \/ B and
A7: x < r and
A8: r < y ; :: thesis: r in A \/ B
per cases ( ( x in A & y in A ) or ( x in A & y in B ) or ( x in B & y in A ) or ( x in B & y in B ) ) by ;
suppose ( x in A & y in A ) ; :: thesis: r in A \/ B
then r in A by A1, A7, A8, Th80;
hence r in A \/ B by XBOOLE_0:def 3; :: thesis: verum
end;
suppose that A11: x in B and
A12: y in A ; :: thesis: r in A \/ B
per cases ( inf B <= r or r < inf B ) ;
suppose A13: r < inf B ; :: thesis: r in A \/ B
inf B <= x by ;
hence r in A \/ B by ; :: thesis: verum
end;
end;
end;
suppose ( x in B & y in B ) ; :: thesis: r in A \/ B
then r in B by A2, A7, A8, Th80;
hence r in A \/ B by XBOOLE_0:def 3; :: thesis: verum
end;
end;
end;
hence A \/ B is interval by Th84; :: thesis: verum