let FX, GX be Subset-Family of V; ( ( for M being Subset of V holds
( M in FX iff for x being Point of V st x in M holds
ex r being Real st
( r > 0 & Ball (x,r) c= M ) ) ) & ( for M being Subset of V holds
( M in GX iff for x being Point of V st x in M holds
ex r being Real st
( r > 0 & Ball (x,r) c= M ) ) ) implies FX = GX )
assume A1:
for M being Subset of V holds
( M in FX iff for x being Point of V st x in M holds
ex r being Real st
( r > 0 & Ball (x,r) c= M ) )
; ( ex M being Subset of V st
( ( M in GX implies for x being Point of V st x in M holds
ex r being Real st
( r > 0 & Ball (x,r) c= M ) ) implies ( ( for x being Point of V st x in M holds
ex r being Real st
( r > 0 & Ball (x,r) c= M ) ) & not M in GX ) ) or FX = GX )
assume A2:
for N being Subset of V holds
( N in GX iff for y being Point of V st y in N holds
ex p being Real st
( p > 0 & Ball (y,p) c= N ) )
; FX = GX
for Y being Subset of V holds
( Y in FX iff Y in GX )
proof
let Y be
Subset of
V;
( Y in FX iff Y in GX )
A3:
now ( Y in GX implies Y in FX )assume
Y in GX
;
Y in FXthen
for
x being
Point of
V st
x in Y holds
ex
r being
Real st
(
r > 0 &
Ball (
x,
r)
c= Y )
by A2;
hence
Y in FX
by A1;
verum end;
now ( Y in FX implies Y in GX )assume
Y in FX
;
Y in GXthen
for
x being
Point of
V st
x in Y holds
ex
r being
Real st
(
r > 0 &
Ball (
x,
r)
c= Y )
by A1;
hence
Y in GX
by A2;
verum end;
hence
(
Y in FX iff
Y in GX )
by A3;
verum
end;
hence
FX = GX
by SETFAM_1:31; verum