Inequalities for some Monotone Matrix Functions
Canadian journal of mathematics, Tome 21 (1969) no. 1, pp. 485-494

Voir la notice de l'article provenant de la source Cambridge University Press

Let V denote a unitary vector space with inner product (x, y). A self-adjoint linear map T: V → V is positive (positive definite) if (Tx, x) ≧ 0 ((Tx, x) ≧ 0) for all x ≠ 0 in V. We write S ≧ T(S > T) if S and T are self-adjoint and S – T ≧ 0 (S – T > 0). If U is a unitary vector space, a function f: Hom(V, V) → Hom(U, U) is monotone idf S ≧ T implies that f(S) ≧ f(T). If both U and V are taken to be the n-dimensional unitary space Cn of n-tuples of complex numbers with standard inner product, then f is a monotone matrix junction, a notion introduced for a more restrictive class of functions by Löwner (3) which has important applications in pure and applied mathematics. For orientation we refer the reader to (1), where several interesting examples of monotone and related functions are displayed in detail.
Marcus, Marvin; Nikolai, Paul J. Inequalities for some Monotone Matrix Functions. Canadian journal of mathematics, Tome 21 (1969) no. 1, pp. 485-494. doi: 10.4153/CJM-1969-054-5
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