Cylinder set measure explained

In mathematics, cylinder set measure (or promeasure, or premeasure, or quasi-measure, or CSM) is a kind of prototype for a measure on an infinite-dimensional vector space. An example is the Gaussian cylinder set measure on Hilbert space.

Cylinder set measures are in general not measures (and in particular need not be countably additive but only finitely additive), but can be used to define measures, such as the classical Wiener measure on the set of continuous paths starting at the origin in Euclidean space.

Definition

Let

be a separable real topological vector space. Let

l{A}(E)

denote the collection of all surjective continuous linear maps

T:E\toF_T

defined on

whose image is some finite-dimensional real vector space

F_T

\mathcal (E) := \left\.

A cylinder set measure on

is a collection of probability measures

\left\.

where

\mu_T

is a probability measure on

F_T.

These measures are required to satisfy the following consistency condition: if

\pi_ST:F_S\toF_T

is a surjective projection, then the push forward of the measure is as follows:

\mu_ = \left(\pi_\right)_ \left(\mu_\right).

Remarks

The consistency condition $\mu_ = \left(\pi_\right)_ (\mu_)$ is modelled on the way that true measures push forward (see the section cylinder set measures versus true measures). However, it is important to understand that in the case of cylinder set measures, this is a requirement that is part of the definition, not a result.

A cylinder set measure can be intuitively understood as defining a finitely additive function on the cylinder sets of the topological vector space

The cylinder sets are the pre-images in

of measurable sets in

F_T

: if

l{B}_T

denotes the

\sigma

-algebra on

F_T

on which

\mu_T

is defined, then

\mathrm (E) := \left\.

In practice, one often takes

l{B}_T

to be the Borel

\sigma

-algebra on

F_T.

In this case, one can show that when

is a separable Banach space, the σ-algebra generated by the cylinder sets is precisely the Borel

\sigma

-algebra of

\mathrm (E) = \sigma \left(\mathrm (E)\right).

Cylinder set measures versus true measures

A cylinder set measure on

is not actually a true measure on

: it is a collection of measures defined on all finite-dimensional images of

has a probability measure

\mu

already defined on it, then

\mu

gives rise to a cylinder set measure on

using the push forward: set

\mu_T=T_*(\mu)

F_T.

When there is a measure

\mu

such that

\mu_T=T_*(\mu)

in this way, it is customary to abuse notation slightly and say that the cylinder set measure

\left\{\mu_T:T\inl{A}(E)\right\}

"is" the measure

\mu.

Cylinder set measures on Hilbert spaces

When the Banach space

is also a Hilbert space

there is a

\gamma^H

arising from the inner product structure on

Specifically, if

\langle ⋅ , ⋅ \rangle

denotes the inner product on

let

\langle ⋅ , ⋅ \rangle_T

denote the quotient inner product on

F_T.

The measure

	H
\gamma
	T

F_T

is then defined to be the canonical Gaussian measure on

F_T

\gamma_^ := i_ \left(\gamma^\right),

where

	\dim(F_T)
\R

\toF_T

is an isometry of Hilbert spaces taking the Euclidean inner product on

	\dim(F_T)
\R

to the inner product

\langle ⋅ , ⋅ \rangle_T

F_T,

and

\gammaⁿ

is the standard Gaussian measure on

\R^n.

The canonical Gaussian cylinder set measure on an infinite-dimensional separable Hilbert space

does not correspond to a true measure on

The proof is quite simple: the ball of radius

(and center 0) has measure at most equal to that of the ball of radius

in an

-dimensional Hilbert space, and this tends to 0 as

tends to infinity. So the ball of radius

has measure 0; as the Hilbert space is a countable union of such balls it also has measure 0, which is a contradiction. (See infinite dimensional Lebesgue measure.)

An alternative proof that the Gaussian cylinder set measure is not a measure uses the Cameron–Martin theorem and a result on the quasi-invariance of measures. If

\gamma^H=\gamma

really were a measure, then the identity function on

would radonify that measure, thus making

\operatorname{id}:H\toH

into an abstract Wiener space. By the Cameron–Martin theorem,

\gamma

would then be quasi-invariant under translation by any element of

which implies that either

is finite-dimensional or that

\gamma

is the zero measure. In either case, we have a contradiction.

Sazonov's theorem gives conditions under which the push forward of a canonical Gaussian cylinder set measure can be turned into a true measure.

Nuclear spaces and cylinder set measures

A cylinder set measure on the dual of a nuclear Fréchet space automatically extends to a measure if its Fourier transform is continuous.

Example: Let

be the space of Schwartz functions on a finite dimensional vector space; it is nuclear. It is contained in the Hilbert space

L²

functions, which is in turn contained in the space of tempered distributions

S^\prime,

the dual of the nuclear Fréchet space

S \subseteq H \subseteq S^\prime.

The Gaussian cylinder set measure on

gives a cylinder set measure on the space of tempered distributions, which extends to a measure on the space of tempered distributions,

S^\prime.

The Hilbert space

has measure 0 in

S^\prime,

by the first argument used above to show that the canonical Gaussian cylinder set measure on

does not extend to a measure on

References

I.M. Gel'fand, N.Ya. Vilenkin, Generalized functions. Applications of harmonic analysis, Vol 4, Acad. Press (1968)
- - L. Schwartz, Radon measures.