let X be RealNormSpace-Sequence; for Y being RealNormSpace
for f, h being VECTOR of (R_VectorSpace_of_BoundedMultilinearOperators (X,Y))
for a being Real holds
( h = a * f iff for x being VECTOR of (product X) holds h . x = a * (f . x) )
let Y be RealNormSpace; for f, h being VECTOR of (R_VectorSpace_of_BoundedMultilinearOperators (X,Y))
for a being Real holds
( h = a * f iff for x being VECTOR of (product X) holds h . x = a * (f . x) )
let f, h be VECTOR of (R_VectorSpace_of_BoundedMultilinearOperators (X,Y)); for a being Real holds
( h = a * f iff for x being VECTOR of (product X) holds h . x = a * (f . x) )
let a be Real; ( h = a * f iff for x being VECTOR of (product X) holds h . x = a * (f . x) )
A1:
R_VectorSpace_of_BoundedMultilinearOperators (X,Y) is Subspace of R_VectorSpace_of_MultilinearOperators (X,Y)
by RSSPACE:11;
then reconsider f1 = f, h1 = h as VECTOR of (R_VectorSpace_of_MultilinearOperators (X,Y)) by RLSUB_1:10;
hereby ( ( for x being VECTOR of (product X) holds h . x = a * (f . x) ) implies h = a * f )
end;
assume
for x being Element of (product X) holds h . x = a * (f . x)
; h = a * f
then
h1 = a * f1
by Th17;
hence
h = a * f
by A1, RLSUB_1:14; verum