|
|
|
|
self-adjoint operator
|
(Definition)
|
|
|
A densely defined linear operator $A\colon\mathscr{D}(A)\subset \mathscr{H}\to\mathscr{H}$ on a Hilbert space $\mathscr{H}$ is a Hermitian or symmetric operator if $(Ax,y) = (x,Ay)$ for all $x,y\in \mathscr{D}(A)$ This means that the adjoint $A^*$ of $A$ is defined at least on $\mathscr{D}(A)$ and that its restriction to that set coincides with $A$ This fact is often denoted by $A\subset A^*$
The operator $A$ is self-adjoint if it coincides with its adjoint, i.e. if $A=A^*$ If $A$ is closable and its closure coincides with its adjoint (i.e. $\overline{A}=A^*$ , then $A$ is said to be essentially self-adjoint.
|
"self-adjoint operator" is owned by Koro.
|
|
(view preamble | get metadata)
See Also: Hermitian matrix
| Also defines: |
Hermitian operator, symmetric operator, essentially self-adjoint, self-adjoint |
|
|
Cross-references: closure, closable, restriction, adjoint, operator, Hilbert space, linear operator, densely defined
There are 20 references to this entry.
This is version 5 of self-adjoint operator, born on 2003-07-28, modified 2006-06-15.
Object id is 4527, canonical name is SelfAdjointOperator.
Accessed 17402 times total.
Classification:
| AMS MSC: | 47B15 (Operator theory :: Special classes of linear operators :: Hermitian and normal operators ) | | | 47B25 (Operator theory :: Special classes of linear operators :: Symmetric and selfadjoint operators ) |
|
|
|
|
|
|
Pending Errata and Addenda
|
|
|
|
|
|
|
|
|
|
|
