let X be non empty TopSpace; :: thesis: for F, G, H being VECTOR of (R_Algebra_of_ContinuousFunctions X)
for f, g, h being RealMap of X st f = F & g = G & h = H holds
( H = F + G iff for x being Element of the carrier of X holds h . x = (f . x) + (g . x) )
let F, G, H be VECTOR of (R_Algebra_of_ContinuousFunctions X); :: thesis: for f, g, h being RealMap of X st f = F & g = G & h = H holds
( H = F + G iff for x being Element of the carrier of X holds h . x = (f . x) + (g . x) )
let f, g, h be RealMap of X; :: thesis: ( f = F & g = G & h = H implies ( H = F + G iff for x being Element of the carrier of X holds h . x = (f . x) + (g . x) ) )
assume A1: ( f = F & g = G & h = H ) ; :: thesis: ( H = F + G iff for x being Element of the carrier of X holds h . x = (f . x) + (g . x) )
A2: R_Algebra_of_ContinuousFunctions X is Subalgebra of RAlgebra the carrier of X by C0SP1:6;
reconsider f1 = F, g1 = G, h1 = H as VECTOR of (RAlgebra the carrier of X) by TARSKI:def 3;
hereby :: thesis: ( ( for x being Element of the carrier of X holds h . x = (f . x) + (g . x) ) implies H = F + G )
assume A3: H = F + G ; :: thesis: for x being Element of the carrier of X holds h . x = (f . x) + (g . x)
let x be Element of the carrier of X; :: thesis: h . x = (f . x) + (g . x)
h1 = f1 + g1 by A2, A3, C0SP1:8;
hence h . x = (f . x) + (g . x) by A1, FUNCSDOM:10; :: thesis: verum
end;
assume for x being Element of X holds h . x = (f . x) + (g . x) ; :: thesis: H = F + G
then h1 = f1 + g1 by A1, FUNCSDOM:10;
hence H = F + G by A2, C0SP1:8; :: thesis: verum