let FT be non empty RelStr ; :: thesis: for x being Element of FT
for A being Subset of FT holds
( x in A ^delta iff ex y1, y2 being Element of FT st
( P_1 x,y1,A = TRUE & P_2 x,y2,A = TRUE ) )
let x be Element of FT; :: thesis: for A being Subset of FT holds
( x in A ^delta iff ex y1, y2 being Element of FT st
( P_1 x,y1,A = TRUE & P_2 x,y2,A = TRUE ) )
let A be Subset of FT; :: thesis: ( x in A ^delta iff ex y1, y2 being Element of FT st
( P_1 x,y1,A = TRUE & P_2 x,y2,A = TRUE ) )
A1: ( x in A ^delta implies ex y1, y2 being Element of FT st
( P_1 x,y1,A = TRUE & P_2 x,y2,A = TRUE ) )
proof
assume A2: x in A ^delta ; :: thesis: ex y1, y2 being Element of FT st
( P_1 x,y1,A = TRUE & P_2 x,y2,A = TRUE )
reconsider z = x as Element of FT ;
A3: ( U_FT z meets A & U_FT z meets A ` ) by A2, FIN_TOPO:10;
then consider w1 being set such that
A4: ( w1 in U_FT z & w1 in A ) by XBOOLE_0:3;
reconsider w1 = w1 as Element of FT by A4;
take w1 ; :: thesis: ex y2 being Element of FT st
( P_1 x,w1,A = TRUE & P_2 x,y2,A = TRUE )
consider w2 being set such that
A5: ( w2 in U_FT z & w2 in A ` ) by A3, XBOOLE_0:3;
take w2 ; :: thesis: ( w2 is Element of FT & P_1 x,w1,A = TRUE & P_2 x,w2,A = TRUE )
thus ( w2 is Element of FT & P_1 x,w1,A = TRUE & P_2 x,w2,A = TRUE ) by A4, A5, Def1, Def2; :: thesis: verum
end;
( ex y1, y2 being Element of FT st
( P_1 x,y1,A = TRUE & P_2 x,y2,A = TRUE ) implies x in A ^delta )
proof
given y1, y2 being Element of FT such that A6: P_1 x,y1,A = TRUE and
A7: P_2 x,y2,A = TRUE ; :: thesis: x in A ^delta
( y1 in U_FT x & y1 in A ) by A6, Def1;
then (U_FT x) /\ A <> {} by XBOOLE_0:def 4;
then A8: U_FT x meets A by XBOOLE_0:def 7;
( y2 in U_FT x & y2 in A ` ) by A7, Def2;
then U_FT x meets A ` by XBOOLE_0:3;
hence x in A ^delta by A8; :: thesis: verum
end;
hence ( x in A ^delta iff ex y1, y2 being Element of FT st
( P_1 x,y1,A = TRUE & P_2 x,y2,A = TRUE ) ) by A1; :: thesis: verum