Normal operator
A closed linear operator $ A $
defined on a linear subspace $ D _ {A} $
that is dense in a Hilbert space $ H $
such that $ A ^ {*} A = AA ^ {*} $,
where $ A ^ {*} $
is the operator adjoint to $ A $.
If $ A $
is normal, then $ D _ {A ^ {*} } = D _ {A} $
and $ \| A ^ {*} x \| = \| A x \| $
for every $ x $.
Conversely, these conditions guarantee that $ A $
is normal. If $ A $
is normal, then so are $ A ^ {*} $;
$ \alpha A + \beta I $
for any $ \alpha , \beta \in \mathbf C $;
$ A ^ {-} 1 $
when it exists; and if $ AB = BA $,
where $ B $
is a bounded linear operator, then also $ A ^ {*} B = BA ^ {*} $.
A normal operator has:
1) the multiplicative decomposition
$$ A = U \sqrt {A ^ {*} A } = \sqrt {A ^ {*} A } U , $$
$$ A ^ {*} = U ^ {-} 1 \sqrt {A ^ {*} A } = \sqrt {A ^ {*} A } U ^ {-} 1 , $$
where $ U $ is a unitary operator which is uniquely determined on the orthogonal complement of the null space of $ A $ and $ A ^ {*} $;
2) the additive decomposition
$$ A = A _ {1} + iA _ {2} ,\ \ A ^ {*} = A _ {1} - iA _ {2} , $$
where $ A _ {1} $ and $ A _ {2} $ are uniquely determined self-adjoint commuting operators.
The additive decomposition implies that for an ordered pair $ ( A, A ^ {*} ) $ there exists a unique two-dimensional spectral function $ E ( \Delta _ \zeta ) $, where $ \Delta _ \zeta $ is a two-dimensional interval, $ \Delta _ \zeta = \Delta _ \xi \times \Delta _ \eta $, $ \zeta = \xi + i \eta $, such that
$$ A = \int\limits _ {\Delta _ \infty } \zeta dE ( \Delta _ \zeta ),\ \ A ^ {*} = \int\limits _ {\Delta _ \infty } \overline \zeta \; dE ( \Delta _ \zeta ). $$
The same decomposition also implies that a normal operator $ A $ is a function of a certain self-adjoint operator $ C $, $ A = F ( C) $. Conversely, every function of some self-adjoint operator is normal.
An important property of a normal operator $ A $ is the fact that $ \| A ^ {n} \| = \| A \| ^ {n} $, which implies that the spectral radius of a normal operator $ A $ is its norm $ \| A \| $. Eigen elements of a normal operator corresponding to distinct eigen values are orthogonal.
References
[1] | A.I. Plesner, "Spectral theory of linear operators" , F. Ungar (1965) (Translated from Russian) |
[2] | W. Rudin, "Functional analysis" , McGraw-Hill (1973) |
Comments
References
[a1] | J.B. Conway, "Subnormal operators" , Pitman (1981) |
Normal operator. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Normal_operator&oldid=17283