Standard Borel space

In mathematics, a standard Borel space is the Borel space associated to a Polish space. Discounting Borel spaces of discrete Polish spaces, there is, up to isomorphism of measurable spaces, only one standard Borel space.

Formal definition

A measurable space $(X, Σ)$ is said to be "standard Borel" if there exists a metric on $X$ that makes it a complete separable metric space in such a way that $Σ$ is then the Borel σ-algebra.^[1] Standard Borel spaces have several useful properties that do not hold for general measurable spaces.

Properties

If $(X, Σ)$ and $(Y, Τ)$ are standard Borel then any bijective measurable mapping $f:(X,\Sigma )\rightarrow (Y,\mathrm {T} )$ is an isomorphism (i.e., the inverse mapping is also measurable). This follows from Souslin's theorem, as a set that is both analytic and coanalytic is necessarily Borel.
If $(X, Σ)$ and $(Y, Τ)$ are standard Borel spaces and $f:X\rightarrow Y$ then $f$ is measurable if and only if the graph of $f$ is Borel.
The product and direct union of a countable family of standard Borel spaces are standard.
Every complete probability measure on a standard Borel space turns it into a standard probability space.

Kuratowski's theorem

Theorem. Let X be a Polish space, that is, a topological space such that there is a metric d on X that defines the topology of X and that makes X a complete separable metric space. Then X as a Borel space is Borel isomorphic to one of (1) R, (2) Z or (3) a finite space. (This result is reminiscent of Maharam's theorem.)

It follows that a standard Borel space is characterized up to isomorphism by its cardinality,^[2] and that any uncountable standard Borel space has the cardinality of the continuum.

Borel isomorphisms on standard Borel spaces are analogous to homeomorphisms on topological spaces: both are bijective and closed under composition, and a homeomorphism and its inverse are both continuous, instead of both being only Borel measurable.

References

^ Mackey, G.W. (1957): Borel structure in groups and their duals. Trans. Am. Math. Soc., 85, 134-165.
^ Srivastava, S.M. (1991), A Course on Borel Sets, Springer Verlag, ISBN 0-387-98412-7

[1] Mackey, G.W. (1957): Borel structure in groups and their duals. Trans. Am. Math. Soc., 85, 134-165.

[2] Srivastava, S.M. (1991), A Course on Borel Sets, Springer Verlag, ISBN 0-387-98412-7

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