Hilbert–Schmidt integral operator - Alchetron, the free social encyclopedia

In mathematics, a Hilbert–Schmidt integral operator is a type of integral transform. Specifically, given a domain (an open and connected set) Ω in n-dimensional Euclidean space Rⁿ, a Hilbert–Schmidt kernel is a function k : Ω × Ω → C with

∫ Ω ∫ Ω | k ( x , y ) | 2 d x d y < ∞

(that is, the L²(Ω×Ω; C) norm of k is finite), and the associated Hilbert–Schmidt integral operator is the operator K : L²(Ω; C) → L²(Ω; C) given by

( K u ) ( x ) = ∫ Ω k ( x , y ) u ( y ) d y .

Then K is a Hilbert–Schmidt operator with Hilbert–Schmidt norm

∥ K ∥ H S = ∥ k ∥ L 2 .

Hilbert–Schmidt integral operators are both continuous (and hence bounded) and compact (as with all Hilbert–Schmidt operators).

The concept of a Hilbert–Schmidt operator may be extended to any locally compact Hausdorff spaces. Specifically, let X be a locally compact Hausdorff space equipped with a positive Borel measure. Suppose further that L²(X) is a separable Hilbert space. The above condition on the kernel k on Rⁿ can be interpreted as demanding k belong to L²(X × X). Then the operator

( K f ) ( x ) = ∫ X k ( x , y ) f ( y ) d y

is compact. If

k ( x , y ) = k ( y , x ) ¯

then K is also self-adjoint and so the spectral theorem applies. This is one of the fundamental constructions of such operators, which often reduces problems about infinite-dimensional vector spaces to questions about well-understood finite-dimensional eigenspaces. See Chapter 2 of the book by Bump in the references for examples.

References

Hilbert–Schmidt integral operator Wikipedia

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