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In functional analysis, the multiple operator integral is a multilinear map ${\displaystyle T_{\phi }^{H_{0},\ldots ,H_{n}}}$ informally written as

${\displaystyle T_{\phi }^{H_{0},\ldots ,H_{n}}(V_{1},\ldots ,V_{n})=\int \cdots \int \phi (\lambda _{0},\ldots ,\lambda _{n})dE_{H_{0}}(\lambda _{0})V_{1}dE_{H_{1}}(\lambda _{1})\cdots V_{n}dE_{H_{n}}(\lambda _{n}),}$

an expression which can be made precise in several different ways. Multiple operator integrals are of use in various situations where functional calculus appears alongside noncommuting operators (e.g., matrices), for instance in perturbation theory, harmonic analysis, index theory, noncommutative geometry, and operator theory in general. As noncommuting operators, functional calculus, and perturbation theory are central to quantum theory, multiple operator integrals are also frequently applied there. Closely related concepts are Schur multiplication and the Feynman operational calculus. Multiple operator integrals were introduced by Peller as multilinear generalizations of double operator integrals, developed by Daletski, Krein, Birman, and Solomyak.

Definition

A conceptually clean definition of the multiple operator integral is given as follows (it is a special case of both ^[1] and ^[2]). Let ${\displaystyle n\in \mathbb {N} }$ , let ${\displaystyle {\mathcal {H}}}$  be a separable Hilbert space, and denote the space of bounded operators by ${\displaystyle {\mathcal {B}}({\mathcal {H}})}$ . Let ${\displaystyle H_{0},\ldots ,H_{n}}$  be possibly unbounded self-adjoint operators in ${\displaystyle {\mathcal {H}}}$ . For any function ${\displaystyle \phi :\mathbb {R} ^{n+1}\to \mathbb {R} }$  (called the symbol) which admits a decomposition

${\displaystyle \phi (\lambda _{0},\ldots ,\lambda _{n})=\int _{\Omega }a_{0}(\lambda _{0},\omega )\cdots a_{1}(\lambda _{n},\omega )\,{\rm {d}}\omega }$ 

for a certain finite measure space ${\displaystyle (\Omega ,{\rm {d}}\omega )}$  and bounded measurable functions ${\displaystyle a_{0},\ldots ,a_{n}:\mathbb {R} \times \Omega \to \mathbb {C} }$ , the multiple operator integral is the ${\displaystyle n}$ -multilinear operator

${\displaystyle T_{\phi }^{H_{0},\ldots ,H_{n}}:{\mathcal {B}}({\mathcal {H}})\times \cdots \times {\mathcal {B}}({\mathcal {H}})\to {\mathcal {B}}({\mathcal {H}})}$ 

defined by

${\displaystyle T_{\phi }^{H_{0},\ldots ,H_{n}}(V_{1},\ldots ,V_{n})\psi :=\int _{\Omega }a_{0}(H_{0},\omega )V_{1}a_{1}(H_{1},\omega )\cdots V_{n}a_{n}(H_{n},\omega )\psi \,{\rm {d}}\omega }$ 

for all ${\displaystyle \psi \in {\mathcal {H}}}$ . One can show that the integrand is Bochner integrable, and (using Banach-Steinhaus) that ${\displaystyle T_{\phi }^{H_{0},\ldots ,H_{n}}}$  is a bounded multilinear map. Moreover, ${\displaystyle T_{\phi }^{H_{0},\ldots ,H_{n}}}$  only depends on ${\displaystyle (\Omega ,{\rm {d}}\omega )}$  and ${\displaystyle a_{0},\ldots ,a_{n}}$  through ${\displaystyle \phi }$ , as the notation ${\displaystyle T_{\phi }^{H_{0},\ldots ,H_{n}}}$  suggests.

Other definitions

One may similarly define ${\displaystyle T_{\phi }^{H_{0},\ldots ,H_{n}}}$  on the product of Schatten classes ${\displaystyle {\mathcal {S}}^{p_{1}}\times \cdots \times {\mathcal {S}}^{p_{n}}}$  and end up with a mapping

${\displaystyle T_{\phi }^{H_{0},\ldots ,H_{n}}:{\mathcal {S}}^{p_{1}}\times \cdots \times {\mathcal {S}}^{p_{n}}\to {\mathcal {S}}^{p}}$ 

where ${\displaystyle {\frac {1}{p}}={\frac {1}{p_{1}}}+\ldots +{\frac {1}{p_{n}}}}$ . The restriction of the domain allows the multiple operator integral to be defined for a larger class of symbols ${\displaystyle \phi :\mathbb {R} ^{n+1}\to \mathbb {R} }$ . Because one can (and often needs to) trade of assumptions on ${\displaystyle \phi }$ , ${\displaystyle H_{0},\ldots ,H_{n}}$ , and ${\displaystyle V_{1},\ldots ,V_{n}}$ , there are several definitions of the multiple operator integral which are not generalizations of one another, but typically agree in the cases where both are defined.

The multiple operator integral can be defined on the product of noncommutative L^p-spaces as

${\displaystyle T_{\phi }^{H_{0},\ldots ,H_{n}}:{\mathcal {L}}^{p_{1}}({\mathcal {N}},\tau )\times \cdots \times {\mathcal {L}}^{p_{n}}({\mathcal {N}},\tau )\to {\mathcal {L}}^{p}({\mathcal {N}},\tau )}$ 

for a von Neumann algebra ${\displaystyle {\mathcal {N}}}$  admitting a semifinite trace ${\displaystyle \tau }$ . One then additionally assumes that ${\displaystyle H_{0},\ldots ,H_{n}}$  are affiliated to ${\displaystyle {\mathcal {N}}}$ .

Divided differences

The most often used symbol of a multiple operator integral is the divided difference ${\displaystyle \phi =f^{[n]}}$  of an ${\displaystyle n}$  times continuously differentiable function ${\displaystyle f:\mathbb {R} \to \mathbb {R} }$ , defined recursively as

${\displaystyle f^{[0]}(\lambda _{0}):=f(\lambda _{0})}$ 

${\displaystyle f^{[n]}(\lambda _{0},\ldots ,\lambda _{n})=\lim _{x\in \mathbb {R} \setminus \{\lambda _{0}\},x\to \lambda _{n}}{\frac {f^{[n-1]}(\lambda _{0},\ldots ,\lambda _{n-1})-f^{[n-1]}(\lambda _{1},\ldots ,\lambda _{n-1},x)}{\lambda _{0}-x}}.}$ 

In particular, ${\displaystyle f^{[n]}(\lambda ,\ldots ,\lambda )={\frac {1}{n!}}f^{(n)}(\lambda )}$ , and

${\displaystyle f^{[1]}(\lambda ,\mu )={\frac {f(\lambda )-f(\mu )}{\lambda -\mu }}.}$ 

The multiple operator integral ${\displaystyle T_{f^{[n]}}:{\mathcal {B}}({\mathcal {H}})^{\times n}\to {\mathcal {B}}({\mathcal {H}})}$  is known to exist in the case that ${\displaystyle f}$  in a suitable Besov space, for example, when ${\displaystyle {\widehat {f^{(n)}}}\in L^{1}(\mathbb {R} )}$ , and the multiple operator integral ${\displaystyle {\mathcal {S}}^{p_{1}}\times \cdots \times {\mathcal {S}}^{p_{n}}\to {\mathcal {S}}^{p}}$  for H\"older conjugate ${\displaystyle p_{1},\ldots ,p_{n},p\in (1,\infty )}$  (as above), is known to exist when ${\displaystyle f\in C^{n}(\mathbb {R} )}$  with ${\displaystyle f^{(n)}}$  bounded.

Properties

Proofs of the following facts can be found in

Algebraic properties

The double operator integral has the following properties:

1. ${\displaystyle f(A)-f(B)=T_{f^{[1]}}^{A,B}(A-B)}$ 
2. ${\displaystyle [f(A),B]=T_{f^{[1]}}^{A,A}([A,B])}$ 

Using the fact that the multiple operator integral of zero order is simply functional calculus:

${\displaystyle f(A)=T_{f^{[0]}}^{A}(),}$ 

one recognizes that 1. and 2. are identities relating multiple operator integrals of 0 order (single operator integrals) to multiple operator integrals of 1st order (double operator integrals). The properties 1. and 2. can be generalized as follows

1. ${\displaystyle T_{f^{[n]}}^{H_{0},\ldots ,H_{j-1},A,H_{j+1},\ldots ,H_{n}}(V_{1},\ldots ,V_{n})-T_{f^{[n]}}^{H_{0},\ldots ,H_{j-1},B,H_{j+1},\ldots ,H_{n}}(V_{1},\ldots ,V_{n})=T_{f^{[n+1]}}^{H_{0},\ldots ,H_{j-1},A,B,H_{j+1},\ldots ,H_{n}}(V_{1},\ldots ,V_{j},A-B,V_{j+1},\ldots ,V_{n})}$ 
2. ${\displaystyle T_{f^{[n]}}^{H_{0},\ldots ,H_{n}}(V_{1},\ldots ,V_{j},aV_{j+1},\ldots ,V_{n})-T_{f^{[n]}}^{H_{0},\ldots ,H_{n}}(V_{1},\ldots ,V_{j}a,V_{j+1},\ldots ,V_{n})=T_{f^{[n+1]}}^{H_{0},\ldots ,H_{n}}(V_{1},\ldots ,V_{j},[H_{j},a],V_{j+1},\ldots ,V_{n})}$ 

In combination with the operator trace ${\displaystyle {\rm {Tr}}}$  (or any other tracial function) the multiple operator integral satisfies the following cyclicity property:

${\displaystyle {\rm {Tr}}(V_{0}T_{f^{[n]}}^{H_{0},\ldots ,H_{n}}(V_{1},\ldots ,V_{n}))={\rm {Tr}}(V_{1}T_{f^{[n]}}^{H_{1},\ldots ,H_{n},H_{0}}(V_{2},\ldots ,V_{n},V_{0}))}$ 

Under suitable conditions, the above identities follow from elementary properties of the divided difference, combined with the fact that ${\displaystyle T_{\phi }}$  is independent of the integral representation of ${\displaystyle \phi }$ .

In quantum theory

$\Tr(e^{-\beta H})$

1. Peller
2. ACDS