for a being set holds
( a in (LSeg |[0 ,0 ]|,|[0 ,1]|) /\ (LSeg |[0 ,1]|,|[1,1]|) iff a = |[0 ,1]| )
proof
set p00 = |[0 ,0 ]|;
set p01 = |[0 ,1]|;
set p11 = |[1,1]|;
let a be set ; :: thesis: ( a in (LSeg |[0 ,0 ]|,|[0 ,1]|) /\ (LSeg |[0 ,1]|,|[1,1]|) iff a = |[0 ,1]| )
thus ( a in (LSeg |[0 ,0 ]|,|[0 ,1]|) /\ (LSeg |[0 ,1]|,|[1,1]|) implies a = |[0 ,1]| ) :: thesis: ( a = |[0 ,1]| implies a in (LSeg |[0 ,0 ]|,|[0 ,1]|) /\ (LSeg |[0 ,1]|,|[1,1]|) )
proof
assume A1: a in (LSeg |[0 ,0 ]|,|[0 ,1]|) /\ (LSeg |[0 ,1]|,|[1,1]|) ; :: thesis: a = |[0 ,1]|
then a in { p2 where p2 is Point of (TOP-REAL 2) : ( p2 `1 <= 1 & p2 `1 >= 0 & p2 `2 = 1 ) } by Th19, XBOOLE_0:def 4;
then A2: ex p2 being Point of (TOP-REAL 2) st
( p2 = a & p2 `1 <= 1 & p2 `1 >= 0 & p2 `2 = 1 ) ;
a in { p where p is Point of (TOP-REAL 2) : ( p `1 = 0 & p `2 <= 1 & p `2 >= 0 ) } by A1, Th19, XBOOLE_0:def 4;
then ex p being Point of (TOP-REAL 2) st
( p = a & p `1 = 0 & p `2 <= 1 & p `2 >= 0 ) ;
hence a = |[0 ,1]| by A2, EUCLID:57; :: thesis: verum
end;
assume A3: a = |[0 ,1]| ; :: thesis: a in (LSeg |[0 ,0 ]|,|[0 ,1]|) /\ (LSeg |[0 ,1]|,|[1,1]|)
then A4: a in LSeg |[0 ,1]|,|[1,1]| by RLTOPSP1:69;
a in LSeg |[0 ,0 ]|,|[0 ,1]| by A3, RLTOPSP1:69;
hence a in (LSeg |[0 ,0 ]|,|[0 ,1]|) /\ (LSeg |[0 ,1]|,|[1,1]|) by A4, XBOOLE_0:def 4; :: thesis: verum
end;
hence (LSeg |[0 ,0 ]|,|[0 ,1]|) /\ (LSeg |[0 ,1]|,|[1,1]|) = {|[0 ,1]|} by TARSKI:def 1; :: thesis: verum