Difference between revisions of "Spectral set"
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$$\|p(A)\|\leq\sup\{|p(z)|:z\in S\}$$ | $$\|p(A)\|\leq\sup\{|p(z)|:z\in S\}$$ | ||
− | for any polynomial $p(z)$. Thus, the unit circle is a spectral set for any contraction (an operator whose norm does not exceed one) on a Hilbert space (von Neumann's theorem). This result is closely connected with the existence of a unitary power dilation for any contraction (a power dilation of an operator $A$ on a Hilbert space $H$ is defined as an operator $A_1$ on a Hilbert space $H_1\supset H$ such that $P_HA_1^n|_H=A^n$, $n\in\mathbf Z^+$); a compact subset $S\ | + | for any polynomial $p(z)$. Thus, the unit circle is a spectral set for any contraction (an operator whose norm does not exceed one) on a Hilbert space (von Neumann's theorem). This result is closely connected with the existence of a unitary power dilation for any contraction (a power dilation of an operator $A$ on a Hilbert space $H$ is defined as an operator $A_1$ on a Hilbert space $H_1\supset H$ such that $P_HA_1^n|_H=A^n$, $n\in\mathbf Z^+$); a compact subset $S\subset\mathbf C$ is spectral for $A$ if and only if $S$ has a normal power dilation with spectrum in $\partial S$. The minimal radius of the circle which is a spectral set for every contraction in a Banach space is equal to one. |
A spectral set, or set of spectral synthesis, for a commutative Banach algebra $\mathfrak A$ is a closed subset of the space of maximal ideals $\mathfrak M_{\mathfrak A}$ which is the hull of exactly one closed ideal $I\subset\mathfrak A$. In the case when $\mathfrak A$ is the group algebra of a locally compact Abelian group, spectral sets are also called sets of harmonic synthesis. | A spectral set, or set of spectral synthesis, for a commutative Banach algebra $\mathfrak A$ is a closed subset of the space of maximal ideals $\mathfrak M_{\mathfrak A}$ which is the hull of exactly one closed ideal $I\subset\mathfrak A$. In the case when $\mathfrak A$ is the group algebra of a locally compact Abelian group, spectral sets are also called sets of harmonic synthesis. |
Latest revision as of 15:46, 29 December 2018
A spectral set of an operator $A$ on a normed space is a subset $S\subset\mathbf C$ such that
$$\|p(A)\|\leq\sup\{|p(z)|:z\in S\}$$
for any polynomial $p(z)$. Thus, the unit circle is a spectral set for any contraction (an operator whose norm does not exceed one) on a Hilbert space (von Neumann's theorem). This result is closely connected with the existence of a unitary power dilation for any contraction (a power dilation of an operator $A$ on a Hilbert space $H$ is defined as an operator $A_1$ on a Hilbert space $H_1\supset H$ such that $P_HA_1^n|_H=A^n$, $n\in\mathbf Z^+$); a compact subset $S\subset\mathbf C$ is spectral for $A$ if and only if $S$ has a normal power dilation with spectrum in $\partial S$. The minimal radius of the circle which is a spectral set for every contraction in a Banach space is equal to one.
A spectral set, or set of spectral synthesis, for a commutative Banach algebra $\mathfrak A$ is a closed subset of the space of maximal ideals $\mathfrak M_{\mathfrak A}$ which is the hull of exactly one closed ideal $I\subset\mathfrak A$. In the case when $\mathfrak A$ is the group algebra of a locally compact Abelian group, spectral sets are also called sets of harmonic synthesis.
References
[1] | J. von Neumann, "Eine Spektraltheorie für allgemeine Operatoren eines unitären Raumes" Math. Nachr. , 4 (1951) pp. 258–281 |
[2] | V.E. Katznelson, V.I. Matsaev, Teor. Funkts. Funktsional. Anal. i Prilozhen. , 3 (1966) pp. 3–10 |
Comments
Cf. also Spectral synthesis.
Spectral set. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Spectral_set&oldid=43565