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Line 49: # <math>\lambda\in\sigma(A)</math> is an isolated point in <math>\sigma(A)</math> and <math>A-\lambda I_{\mathbf{X}}</math> is [[Fredholm operator\|Fredholm]] of index zero; # <math>\lambda\in\sigma(A)</math> is an isolated point in <math>\sigma(A)</math> and the rank of the corresponding [[Riesz projector]] <math>P_\lambda</math> is finite; # <math>\lambda\in\sigma(A)</math> is an isolated point in <math>\sigma(A)</math>, its algebraic multiplicity <math>\nu=\dim\mathfrak{L}_\lambda</math> is finite, and the range of <math>A-\lambda I_{\mathbf{X}}</math> is [[Closed range theorem\|closed]]. (Gohberg–Krein 1957, 1960, 1969). ifIf <math>\lambda</math> is a normal eigenvalue, then <math>\mathfrak{L}_\lambda</math> coincides with the range of the Riesz projector, <math>\mathfrak{R}(P_\lambda)</math> (Gohberg–Krein 1969).▼ ~~The equivalence of (1) and (5) is proved in Theorem 4.1 of (Gohberg–Krein 1957, 1960).~~ The equivalence of (1) and (3) is proved in Theorem 4.2 of (Gohberg–Krein 1957, 1960), and then equivalence of (1) with (2) and (4) follows from the [[Fredholm_operator#Properties\|stability of the index]]. ~~The equivalence of (1) and (6) is stated in (Gohberg–Krein 1969, Chapter 1, §2.1).~~ ~~By Theorem 2.1 of (Gohberg–Krein 1969),~~ ▲if <math>\lambda</math> is a normal eigenvalue, then <math>\mathfrak{L}_\lambda</math> coincides with the range of the Riesz projector, <math>\mathfrak{R}(P_\lambda)</math>. ==Decomposition of the spectrum of nonselfadjoint operators==

Normal eigenvalue: Difference between revisions