let X, Y, Z be RealNormSpace; :: thesis: for f, g, h being VECTOR of holds
( h = f + g iff for x being VECTOR of X
for y being VECTOR of Y holds h . (x,y) = (f . (x,y)) + (g . (x,y)) )

let f, g, h be VECTOR of ; :: thesis: ( h = f + g iff for x being VECTOR of X
for y being VECTOR of Y holds h . (x,y) = (f . (x,y)) + (g . (x,y)) )

A1: R_VectorSpace_of_BoundedBilinearOperators (X,Y,Z) is Subspace of R_VectorSpace_of_BilinearOperators (X,Y,Z) by RSSPACE:11;
then reconsider f1 = f as VECTOR of () by RLSUB_1:10;
reconsider h1 = h as VECTOR of () by ;
reconsider g1 = g as VECTOR of () by ;
hereby :: thesis: ( ( for x being VECTOR of X
for y being VECTOR of Y holds h . (x,y) = (f . (x,y)) + (g . (x,y)) ) implies h = f + g )
assume A2: h = f + g ; :: thesis: for x being Element of X
for y being Element of Y holds h . (x,y) = (f . (x,y)) + (g . (x,y))

let x be Element of X; :: thesis: for y being Element of Y holds h . (x,y) = (f . (x,y)) + (g . (x,y))
let y be Element of Y; :: thesis: h . (x,y) = (f . (x,y)) + (g . (x,y))
h1 = f1 + g1 by ;
hence h . (x,y) = (f . (x,y)) + (g . (x,y)) by Th16; :: thesis: verum
end;
assume for x being Element of X
for y being Element of Y holds h . (x,y) = (f . (x,y)) + (g . (x,y)) ; :: thesis: h = f + g
then h1 = f1 + g1 by Th16;
hence h = f + g by ; :: thesis: verum