let X be non empty set ; :: thesis:
let a, b be Real; :: thesis:
let f be PartFunc of X,REAL ; :: thesis:
assume AS: ( f is nonnegative & a > 0 & b > 0 ) ; :: thesis:
A1: ( dom (f to_power a) = dom f & dom (f to_power b) = dom f ) by MESFUN6C:def 6;
A2: dom ((f to_power a) (#) (f to_power b)) = (dom (f to_power a)) /\ (dom (f to_power b)) by VALUED_1:def 4;
then A4: dom ((f to_power a) (#) (f to_power b)) = dom (f to_power (a + b)) by A1, MESFUN6C:def 6;
for x being set st x in dom ((f to_power a) (#) (f to_power b)) holds
((f to_power a) (#) (f to_power b)) . x = (f to_power (a + b)) . x

let x be set ; :: thesis:
assume A6: x in dom ((f to_power a) (#) (f to_power b)) ; :: thesis:
then ( (f to_power a) . x = (f . x) to_power a & (f to_power b) . x = (f . x) to_power b ) by A1, A2, MESFUN6C:def 6;
then A7: ((f to_power a) (#) (f to_power b)) . x = ((f . x) to_power a) * ((f . x) to_power b) by A6, VALUED_1:def 4;
A8: (f to_power (a + b)) . x = (f . x) to_power (a + b) by A4, A6, MESFUN6C:def 6;
then A9: ( f . x > 0 implies ((f to_power a) (#) (f to_power b)) . x = (f to_power (a + b)) . x ) by A7, POWER:32;

assume C1: f . x = 0 ; :: thesis:
then ((f to_power a) (#) (f to_power b)) . x = 0 * (0 to_power b) by AS, A7, POWER:def 2;
hence ((f to_power a) (#) (f to_power b)) . x = (f to_power (a + b)) . x by A8, AS, C1, POWER:def 2; :: thesis:

end;

hence ((f to_power a) (#) (f to_power b)) . x = (f to_power (a + b)) . x by AS, A9, MESFUNC6:51; :: thesis:

end;

hence (f to_power a) (#) (f to_power b) = f to_power (a + b) by A4, FUNCT_1:9; :: thesis: