Additive mappings preserving orthogonality between complex inner product spaces
Abstract
Let H and K be two complex inner product spaces with dim(X)≥ 2. We prove that for each non-zero additive mapping A:H K with dense image the following statements are equivalent: (a) A is (complex) linear or conjugate-linear mapping and there exists γ >0 such that \| A (x) \| = γ \|x\|, for all x∈ X, that is, A is a positive scalar multiple of a linear or a conjugate-linear isometry; (b) There exists γ1 >0 such that one of the next properties holds for all x,y ∈ H: (b.1) A(x) |A(y) = γ1 x|y, (b.2) A(x) |A(y) = γ1 y|x ; (c) A is linear or conjugate-linear and preserves orthogonality in both directions; (d) A is linear or conjugate-linear and preserves orthogonality; (e) A is additive and preserves orthogonality in both directions; (f) A is additive and preserves orthogonality. This extends to the complex setting a recent generalization of the Koldobsky--Blanco--Turnsek theorem obtained by W\'ojcik for real normed spaces.
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