# Multiplication operator

{{ safesubst:#invoke:Unsubst||$N=Unreferenced |date=__DATE__ |$B= {{#invoke:Message box|ambox}} }} In operator theory, a multiplication operator is an operator T defined on some vector space of functions and whose value at a function φ is given by multiplication by a fixed function f. That is,

${\displaystyle T(\varphi )(x)=f(x)\varphi (x)\quad }$

for all φ in the function space and all x in the domain of φ (which is the same as the domain of f).

This type of operators is often contrasted with composition operators. Multiplication operators generalize the notion of operator given by a diagonal matrix. More precisely, one of the results of operator theory is a spectral theorem, which states that every self-adjoint operator on a Hilbert space is unitarily equivalent to a multiplication operator on an L2 space.

## Example

Consider the Hilbert space X=L2[−1, 3] of complex-valued square integrable functions on the interval [−1, 3]. Define the operator:

${\displaystyle T(\varphi )(x)=x^{2}\varphi (x)\quad }$

for any function φ in X. This will be a self-adjoint bounded linear operator with norm 9. Its spectrum will be the interval [0, 9] (the range of the function xx2 defined on [−1, 3]). Indeed, for any complex number λ, the operator T-λ is given by

${\displaystyle (T-\lambda )(\varphi )(x)=(x^{2}-\lambda )\varphi (x).\quad }$

It is invertible if and only if λ is not in [0, 9], and then its inverse is

${\displaystyle (T-\lambda )^{-1}(\varphi )(x)={\frac {1}{x^{2}-\lambda }}\varphi (x)\quad }$

which is another multiplication operator.

This can be easily generalized to characterizing the norm and spectrum of a multiplication operator on any Lp space.