let X, Y be non empty TopSpace; :: thesis: for f being continuous Function of Y,Y st f is idempotent holds
oContMaps f,X is idempotent
let f be continuous Function of Y,Y; :: thesis: ( f is idempotent implies oContMaps f,X is idempotent )
assume A1:
f is idempotent
; :: thesis: oContMaps f,X is idempotent
set fX = oContMaps f,X;
now let g be
Element of
(oContMaps Y,X);
:: thesis: ((oContMaps f,X) * (oContMaps f,X)) . g = (oContMaps f,X) . greconsider h =
g as
continuous Function of
Y,
X by Th2;
thus ((oContMaps f,X) * (oContMaps f,X)) . g =
(oContMaps f,X) . ((oContMaps f,X) . g)
by FUNCT_2:21
.=
(oContMaps f,X) . (h * f)
by Def3
.=
(h * f) * f
by Def3
.=
h * (f * f)
by RELAT_1:55
.=
h * f
by A1, QUANTAL1:def 9
.=
(oContMaps f,X) . g
by Def3
;
:: thesis: verum end;
then
(oContMaps f,X) * (oContMaps f,X) = oContMaps f,X
by FUNCT_2:113;
hence
oContMaps f,X is idempotent
by QUANTAL1:def 9; :: thesis: verum