Direct integral explained

In mathematics and functional analysis, a direct integral or Hilbert integral is a generalization of the concept of direct sum. The theory is most developed for direct integrals of Hilbert spaces and direct integrals of von Neumann algebras. The concept was introduced in 1949 by John von Neumann in one of the papers in the series On Rings of Operators. One of von Neumann's goals in this paper was to reduce the classification of (what are now called) von Neumann algebras on separable Hilbert spaces to the classification of so-called factors. Factors are analogous to full matrix algebras over a field, and von Neumann wanted to prove a continuous analogue of the Artin–Wedderburn theorem classifying semi-simple rings.

Results on direct integrals can be viewed as generalizations of results about finite-dimensional C*-algebras of matrices; in this case the results are easy to prove directly. The infinite-dimensional case is complicated by measure-theoretic technicalities.

Direct integral theory was also used by George Mackey in his analysis of systems of imprimitivity and his general theory of induced representations of locally compact separable groups.

Direct integrals of Hilbert spaces

The simplest example of a direct integral are the L2 spaces associated to a (σ-finite) countably additive measure μ on a measurable space X. Somewhat more generally one can consider a separable Hilbert space H and the space of square-integrable H-valued functions

2
L
\mu(X,

H).

Terminological note: The terminology adopted by the literature on the subject is followed here, according to which a measurable space X is referred to as a Borel space and the elements of the distinguished σ-algebra of X as Borel sets, regardless of whether or not the underlying σ-algebra comes from a topological space (in most examples it does). A Borel space is standard if and only if it is isomorphic to the underlying Borel space of a Polish space; all Polish spaces of a given cardinality are isomorphic to each other (as Borel spaces). Given a countably additive measure μ on X, a measurable set is one that differs from a Borel set by a null set. The measure μ on X is a standard measure if and only if there is a null set E such that its complement XE is a standard Borel space. All measures considered here are σ-finite.

Definition. Let X be a Borel space equipped with a countably additive measure μ. A measurable family of Hilbert spaces on (X, μ) is a family xX, which is locally equivalent to a trivial family in the following sense: There is a countable partition

\{Xn\}1

by measurable subsets of X such that

Hx=Hnx\inXn

where Hn is the canonical n-dimensional Hilbert space, that is

Hn=\left\{\begin{matrix}Cn&ifn<\omega\\ell2&ifn=\omega\end{matrix}\right.

In the above,

\ell2

is the space of square summable sequences; all separable Hilbert spaces are isomorphic to

\ell2.

A cross-section of xX is a family xX such that sxHx for all xX. A cross-section is measurable if and only if its restriction to each partition element Xn is measurable. We will identify measurable cross-sections s, t that are equal almost everywhere. Given a measurable family of Hilbert spaces, the direct integral

\int
X

Hxd\mu(x)

consists of equivalence classes (with respect to almost everywhere equality) of measurable square integrable cross-sections of xX. This is a Hilbert space under the inner product

\langles|t\rangle=\intX\langles(x)|t(x)\rangled\mu(x)

Given the local nature of our definition, many definitions applicable to single Hilbert spaces apply to measurable families of Hilbert spaces as well.

Remark. This definition is apparently more restrictive than the one given by von Neumann and discussed in Dixmier's classic treatise on von Neumann algebras. In the more general definition, the Hilbert space fibers Hx are allowed to vary from point to point without having a local triviality requirement (local in a measure-theoretic sense). One of the main theorems of the von Neumann theory is to show that in fact the more general definition is equivalent to the simpler one given here.

Note that the direct integral of a measurable family of Hilbert spaces depends only on the measure class of the measure μ; more precisely:

Theorem. Suppose μ, ν are σ-finite countably additive measures on X that have the same sets of measure 0. Then the mapping

s\mapsto\left(

d\mu
d\nu

\right)1/2s

is a unitary operator

\int
X

Hxd\mu(x)

\int
X

Hxd\nu(x).

Example

The simplest example occurs when X is a countable set and μ is a discrete measure. Thus, when X = N and μ is counting measure on N, then any sequence of separable Hilbert spaces can be considered as a measurable family. Moreover,

\int
X

Hxd\mu(x)\congopluskHk

Decomposable operators

For the example of a discrete measure on a countable set, any bounded linear operator T on

H=opluskHk

is given by an infinite matrix

\begin{bmatrix}T1&T1&&T1&\T2&T2&&T2&\\ \vdots&\vdots&\ddots&\vdots&\\ Tn&Tn&&Tn&\\ \vdots&\vdots&&\vdots&\ddots \end{bmatrix}.

For this example, of a discrete measure on a countable set, decomposable operators are defined as the operators that are block diagonal, having zero for all non-diagonal entries. Decomposable operators can be characterized as those which commute with diagonal matrices:

\begin{bmatrix}λ1&0&&0&\ 0&λ2&&0&\\ \vdots&\vdots&\ddots&\vdots&\\ 0&0&&λn&\\ \vdots&\vdots&&\vdots&\ddots \end{bmatrix}.

The above example motivates the general definition: A family of bounded operators xX with Tx ∈ L(Hx) is said to be strongly measurable if and only if its restriction to each Xn is strongly measurable. This makes sense because Hx is constant on Xn.

Measurable families of operators with an essentially bounded norm, that is

\operatorname{ess-sup}x\|Tx\|<infty

define bounded linear operators

\int
X

Txd\mu(x)\in

\operatorname{L}(\int
X

Hxd\mu(x))

acting in a pointwise fashion, that is

[\int
X

Txd\mu(x)]

(\int
X

sxd\mu(x))=

\int
X

Tx(sx)d\mu(x).

Such operators are said to be decomposable.

Examples of decomposable operators are those defined by scalar-valued (i.e. C-valued) measurable functions λ on X. In fact,

Theorem. The mapping

\phi:

infty
L
\mu(X)

\operatorname{L}(\int
X

Hxd\mu(x))

given by

λ\mapsto

\int
X

 λxd\mu(x)

is an involutive algebraic isomorphism onto its image.

This allows Lμ(X) to be identified with the image of φ.

Theorem[1] Decomposable operators are precisely those that are in the operator commutant of the abelian algebra Lμ(X).

Decomposition of Abelian von Neumann algebras

The spectral theorem has many variants. A particularly powerful version is as follows:

Theorem. For any Abelian von Neumann algebra A on a separable Hilbert space H, there is a standard Borel space X and a measure μ on X such that it is unitarily equivalent as an operator algebra to Lμ(X) acting on a direct integral of Hilbert spaces

\int
X

Hxd\mu(x).

To assert A is unitarily equivalent to Lμ(X) as an operator algebra means that there is a unitary

U:H

\int
X

Hxd\mu(x)

such that U A U* is the algebra of diagonal operators Lμ(X). Note that this asserts more than just the algebraic equivalence of A with the algebra of diagonal operators.

This version of the spectral theorem does not explicitly state how the underlying standard Borel space X is obtained. There is a uniqueness result for the above decomposition.

Theorem. If the Abelian von Neumann algebra A is unitarily equivalent to both Lμ(X) and Lν(Y) acting on the direct integral spaces

\int
X

Hxd\mu(x),

\int
Y

Kyd\nu(y)

and μ, ν are standard measures, then there is a Borel isomorphism

\varphi:X-EY-F

where E, F are null sets such that

K\phi(x)=Hxalmosteverywhere

The isomorphism φ is a measure class isomorphism, in that φ and its inverse preserve sets of measure 0.

The previous two theorems provide a complete classification of Abelian von Neumann algebras on separable Hilbert spaces. This classification takes into account the realization of the von Neumann algebra as an algebra of operators. If one considers the underlying von Neumann algebra independently of its realization (as a von Neumann algebra), then its structure is determined by very simple measure-theoretic invariants.

Direct integrals of von Neumann algebras

Let xX be a measurable family of Hilbert spaces. A family of von Neumann algebras xXwith

Ax\subseteq\operatorname{L}(Hx)

is measurable if and only if there is a countable set D of measurable operator families that pointwise generate xX as a von Neumann algebra in the following sense: For almost all xX,

*}(\{S
\operatorname{W
x:

S\inD\})=Ax

where W*(S) denotes the von Neumann algebra generated by the set S. If xX is a measurable family of von Neumann algebras, the direct integral of von Neumann algebras

\int
X

Axd\mu(x)

consists of all operators of the form

\int
X

Txd\mu(x)

for TxAx.

One of the main theorems of von Neumann and Murray in their original series of papers is a proof of the decomposition theorem: Any von Neumann algebra is a direct integral of factors. Precisely stated,

Theorem. If xX is a measurable family of von Neumann algebras and μ is standard, then the family of operator commutants is also measurable and

[\int
X

Axd\mu(x)]'=

\int
X

A'xd\mu(x).

Central decomposition

Suppose A is a von Neumann algebra. Let Z(A) be the center of A. The center is the set of operators in A that commute with all operators A:

Z(A)=A\capA'

Then Z(A) is an Abelian von Neumann algebra.

Example. The center of L(H) is 1-dimensional. In general, if A is a von Neumann algebra, if the center is 1-dimensional we say A is a factor.

When A is a von Neumann algebra whose center contains a sequence of minimal pairwise orthogonal non-zero projections iN such that

1=\sumiEi

then A Ei is a von Neumann algebra on the range Hi of Ei. It is easy to see A Ei is a factor. Thus, in this special case

A=oplusiAEi

represents A as a direct sum of factors. This is a special case of the central decomposition theorem of von Neumann.

In general, the structure theorem of Abelian von Neumann algebras represents Z(A) as an algebra of scalar diagonal operators. In any such representation, all the operators in A are decomposable operators. This can be used to prove the basic result of von Neumann: any von Neumann algebra admits a decomposition into factors.

Theorem. Suppose

H=

\int
X

Hxd\mu(x)

is a direct integral decomposition of H and A is a von Neumann algebra on H so that Z(A) is represented by the algebra of scalar diagonal operators Lμ(X) where X is a standard Borel space. Then

A=

\int
X

Axd\mu(x)

where for almost all xX, Ax is a von Neumann algebra that is a factor.

Measurable families of representations

If A is a separable C*-algebra, the above results can be applied to measurable families of non-degenerate *-representations of A. In the case that A has a unit, non-degeneracy is equivalent to unit-preserving. By the general correspondence that exists between strongly continuous unitary representations of a locally compact group G and non-degenerate *-representations of the groups C*-algebra C*(G), the theory for C*-algebras immediately provides a decomposition theory for representations of separable locally compact groups.

Theorem. Let A be a separable C*-algebra and π a non-degenerate involutive representation of A on a separable Hilbert space H. Let W*(π) be the von Neumann algebra generated by the operators π(a) for aA. Then corresponding to any central decomposition of W*(π) over a standard measure space (X, μ) (which, as stated, is unique in a measure theoretic sense), there is a measurable family of factor representations

\{\pix\}x

of A such that

\pi(a)=

\int
X

\pix(a)d\mu(x),\foralla\inA.

Moreover, there is a subset N of X with μ measure zero, such that πx, πy are disjoint whenever x, yXN, where representations are said to be disjoint if and only if there are no intertwining operators between them.

One can show that the direct integral can be indexed on the so-called quasi-spectrum Q of A, consisting of quasi-equivalence classes of factor representations of A. Thus, there is a standard measure μ on Q and a measurable family of factor representations indexed on Q such that πx belongs to the class of x. This decomposition is essentially unique. This result is fundamental in the theory of group representations.

References

Notes and References

  1. , Chapter IV, Theorem 7.10, p. 259