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Résolvante

In mathematics, the resolvent formalism is a technique for applying concepts from complex analysis to the study of the spectrum of operators on Banach spaces and more general spaces. Formal justification for the manipulations can be found in the framework of holomorphic functional calculus. The resolvent captures the spectral properties of an operator in the analytic structure of the functional. Given an operator A, the resolvent may be defined as Among other uses, the resolvent may be used to solve the inhomogeneous Fredholm integral equations; a commonly used approach is a series solution, the Liouville–Neumann series. The resolvent of A can be used to directly obtain information about the spectral decomposition of A. For example, suppose λ is an isolated eigenvalue in the spectrum of A. That is, suppose there exists a simple closed curve in the complex plane that separates λ from the rest of the spectrum of A. Then the residue defines a projection operator onto the λ eigenspace of A. The Hille–Yosida theorem relates the resolvent through a Laplace transform to an integral over the one-parameter group of transformations generated by A. Thus, for example, if A is a Hermitian, then U(t) = exp(tA) is a one-parameter group of unitary operators. Whenever , the resolvent of A at z can be expressed as the Laplace transform where the integral is taken along the ray . The first major use of the resolvent operator as a series in A (cf. Liouville–Neumann series) was by Ivar Fredholm, in a landmark 1903 paper in Acta Mathematica that helped establish modern operator theory. The name resolvent was given by David Hilbert. For all z, w in ρ(A), the resolvent set of an operator A, we have that the first resolvent identity (also called Hilbert's identity) holds: (Note that Dunford and Schwartz, cited, define the resolvent as (zI −A)−1, instead, so that the formula above differs in sign from theirs.) The second resolvent identity is a generalization of the first resolvent identity, above, useful for comparing the resolvents of two distinct operators.

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Concepts associés (14)
Espace de Hilbert
vignette|Une photographie de David Hilbert (1862 - 1943) qui a donné son nom aux espaces dont il est question dans cet article. En mathématiques, un espace de Hilbert est un espace vectoriel réel (resp. complexe) muni d'un produit scalaire euclidien (resp. hermitien), qui permet de mesurer des longueurs et des angles et de définir une orthogonalité. De plus, un espace de Hilbert est complet, ce qui permet d'y appliquer des techniques d'analyse. Ces espaces doivent leur nom au mathématicien allemand David Hilbert.
Fredholm theory
In mathematics, Fredholm theory is a theory of integral equations. In the narrowest sense, Fredholm theory concerns itself with the solution of the Fredholm integral equation. In a broader sense, the abstract structure of Fredholm's theory is given in terms of the spectral theory of Fredholm operators and Fredholm kernels on Hilbert space. The theory is named in honour of Erik Ivar Fredholm. The following sections provide a casual sketch of the place of Fredholm theory in the broader context of operator theory and functional analysis.
Decomposition of spectrum (functional analysis)
The spectrum of a linear operator that operates on a Banach space is a fundamental concept of functional analysis. The spectrum consists of all scalars such that the operator does not have a bounded inverse on . The spectrum has a standard decomposition into three parts: a point spectrum, consisting of the eigenvalues of ; a continuous spectrum, consisting of the scalars that are not eigenvalues but make the range of a proper dense subset of the space; a residual spectrum, consisting of all other scalars in the spectrum.
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