Upper semi-Fredholm operators and tauberian operators in Banach spaces admit the following perturbative characterizations [6], [2]: An operator T: X --> Y is upper semi-Fredholm (tauberian) if and only if for every compact operator K: X --> Y the kernel N(T+K) is finite dimensional (reflexive). In [7] Tacon introduces an intermediate class between upper semi-Fredholm operators and tauberian operators, the supertauberian operators, and he studies this class using non-standard analysis....

Pour un opérateur T borné sur un espace de Hilbert dans lui-même, nous montrons que $\gamma \left(\pi \right(T\left)\right)=sup\gamma (T+K):Kopérateurcompact$, où γ est la conorme (the reduced minimum modulus) et π(T) est la classe de T dans l’algèbre de Calkin. Nous montrons aussi que ce supremum est atteint. D’autre part, nous montrons que les opérateurs semi-Fredholm caractérisent les points de continuité de l’application T → γ (π(T)).

This paper is related to the spectral stability of traveling wave solutions of partial differential equations. In the first part of the paper we use the Gohberg-Rouche Theorem to prove equality of the algebraic multiplicity of an isolated eigenvalue of an abstract operator on a Hilbert space, and the algebraic multiplicity of the eigenvalue of the corresponding Birman-Schwinger type operator pencil. In the second part of the paper we apply this result...

We show that the domain of the Ornstein-Uhlenbeck operator on $L^p$$({ℝ}^N,\mu dx...$

Let W(A) and $W_e\left(A\right)$ be the joint numerical range and the joint essential numerical range of an m-tuple of self-adjoint operators A = (A₁, ..., Aₘ) acting on an infinite-dimensional Hilbert space. It is shown that $W_e\left(A\right)$ is always convex and admits many equivalent formulations. In particular, for any fixed i ∈ 1, ..., m, $W_e\left(A\right)$ can be obtained as the intersection of all sets of the form $cl\left(W(A₁,...,A_{i+1},A_i+F,A_{i+1},...,Aₘ)\right)$, where F = F* has finite rank. Moreover, the closure cl(W(A)) of W(A) is always star-shaped with the elements in $W_e\left(A\right)$ as star centers....

Si considera, in uno spazio di Hilbert $H$ l'operatore lineare ${\mathfrak{M}}_0\phi =1/2\text{Tr}\left[D^2\phi \right]+〈x,AD\phi 〉-〈DU\left(x\right),D\phi 〉$, dove $A$ è un operatore negative autoaggiunto e $U$ è un potenziale che soddisfa a opportune condizioni di integrabilità. Si dimostra con un metodo analitico che ${\mathfrak{M}}_0$ è essenzialmente autoaggiunto in uno spazio $L^2\left(H,\nu \right)$ e si caratterizza il dominio della sua chiusura $\mathfrak{M}$ come sottospazio di $W^{2,2}\left(H,\nu \right)$. Si studia inoltre la «spectral gap property» del semigruppo generato da $\mathfrak{M}$.