# Borel set

In mathematics, a **Borel set** is any set in a topological space that can be formed from open sets (or, equivalently, from closed sets) through the operations of countable union, countable intersection, and relative complement. Borel sets are named after Émile Borel.

For a topological space *X*, the collection of all Borel sets on *X* forms a σ-algebra, known as the **Borel algebra** or **Borel σ-algebra**. The Borel algebra on *X* is the smallest σ-algebra containing all open sets (or, equivalently, all closed sets).

Borel sets are important in measure theory, since any measure defined on the open sets of a space, or on the closed sets of a space, must also be defined on all Borel sets of that space. Any measure defined on the Borel sets is called a Borel measure. Borel sets and the associated Borel hierarchy also play a fundamental role in descriptive set theory.

In some contexts, Borel sets are defined to be generated by the compact sets of the topological space, rather than the open sets. The two definitions are equivalent for many well-behaved spaces, including all Hausdorff σ-compact spaces, but can be different in more pathological spaces.

## Contents

## Generating the Borel algebra

In the case *X* is a metric space, the Borel algebra in the first sense may be described *generatively* as follows.

For a collection *T* of subsets of *X* (that is, for any subset of the power set P(*X*) of *X*), let

Now define by transfinite induction a sequence *G ^{m}*, where

*m*is an ordinal number, in the following manner:

- For the base case of the definition, let be the collection of open subsets of
*X*. - If
*i*is not a limit ordinal, then*i*has an immediately preceding ordinal*i − 1*. Let - If
*i*is a limit ordinal, set

The claim is that the Borel algebra is *G*^{ω1}, where ω_{1} is the first uncountable ordinal number. That is, the Borel algebra can be *generated* from the class of open sets by iterating the operation

to the first uncountable ordinal.

To prove this claim, note that any open set in a metric space is the union of an increasing sequence of closed sets. In particular, complementation of sets maps *G ^{m}* into itself for any limit ordinal

*m*; moreover if

*m*is an uncountable limit ordinal,

*G*is closed under countable unions.

^{m}Note that for each Borel set *B*, there is some countable ordinal α_{B} such that *B* can be obtained by iterating the operation over α_{B}. However, as *B* varies over all Borel sets, α_{B} will vary over all the countable ordinals, and thus the first ordinal at which all the Borel sets are obtained is ω_{1}, the first uncountable ordinal.

### Example

An important example, especially in the theory of probability, is the Borel algebra on the set of real numbers. It is the algebra on which the Borel measure is defined. Given a real random variable defined on a probability space, its probability distribution is by definition also a measure on the Borel algebra.

The Borel algebra on the reals is the smallest σ-algebra on **R** which contains all the intervals.

In the construction by transfinite induction, it can be shown that, in each step, the number of sets is, at most, the power of the continuum. So, the total number of Borel sets is less than or equal to

## Standard Borel spaces and Kuratowski theorems

Mackey writes that a **Borel space** is "a set together with a distinguished σ-field of subsets called its Borel sets." ^{[1]} However, more modern terminology is to call such spaces *measurable spaces*. The reason for this distinction is that the Borel σ-algebra is the σ-algebra generated by *open* sets of a *topological* space, whereas Mackey's definition refers to a set equipped with an *arbitrary* σ-algebra. There exist measurable spaces which are *not* Borel spaces in this more restricted topological sense.^{[2]}

Measurable spaces form a category in which the morphisms are measurable functions between measurable spaces. A function is measurable if it pulls back measurable sets, i.e., for all measurable sets *B* in *Y*, is a measurable set in *X*.

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

Considered as Borel spaces, the real line **R** and the union of **R** with a countable set are isomorphic.

A **standard Borel space** is the Borel space associated to a Polish space.

Any standard Borel space is defined (up to isomorphism) by its cardinality,^{[3]} and any uncountable standard Borel space has the cardinality of the continuum.

For subsets of Polish spaces, Borel sets can be characterized as those sets which are the ranges of continuous injective maps defined on Polish spaces. Note however, that the range of a continuous noninjective map may fail to be Borel. See analytic set.

Every probability measure on a standard Borel space turns it into a standard probability space.

## Non-Borel sets

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An example of a subset of the reals which is non-Borel, due to Lusin^{[4]} (see Sect. 62, pages 76–78), is described below. In contrast, an example of a non-measurable set cannot be exhibited, though its existence can be proved.

Every irrational number has a unique representation by a continued fraction

where is some integer and all the other numbers are *positive* integers. Let be the set of all irrational numbers that correspond to sequences with the following property: there exists an infinite subsequence such that each element is a divisor of the next element. This set is not Borel. In fact, it is analytic, and complete in the class of analytic sets. For more details see descriptive set theory and the book by Kechris, especially Exercise (27.2) on page 209, Definition (22.9) on page 169, and Exercise (3.4)(ii) on page 14.

Another non-Borel set is an inverse image of an infinite parity function . However, this is a proof of existence (via the axiom of choice), not an explicit example.

## Alternative non-equivalent definitions

According to Halmos Template:Harv, a subset of a locally compact Hausdorff topological space is called a *Borel set* if it belongs to the smallest σ–ring containing all compact sets.

Norberg and Vervaat ^{[5]} redefine the Borel algebra of a topological space as the –algebra generated by its open subsets and its compact saturated subsets. This definition is well-suited for applications in the case where is not Hausdorff. It coincides with the usual definition if is second countable or if every compact saturated subset is closed (which is the case in particular if is Hausdorff).

## See also

## References

An excellent exposition of the machinery of *Polish topology* is given in Chapter 3 of the following reference:

- William Arveson,
*An Invitation to C*-algebras*, Springer-Verlag, 1981

- Richard Dudley,
*Real Analysis and Probability*. Wadsworth, Brooks and Cole, 1989

- {{#invoke:citation/CS1|citation

|CitationClass=book }} See especially Sect. 51 "Borel sets and Baire sets".

- Halsey Royden,
*Real Analysis*, Prentice Hall, 1988

- Alexander S. Kechris,
*Classical Descriptive Set Theory*, Springer-Verlag, 1995 (Graduate texts in Math., vol. 156)

## Notes

- ↑ {{#invoke:citation/CS1|citation |CitationClass=citation }}
- ↑ Jochen Wengenroth (mathoverflow.net/users/21051), Is every sigma-algebra the Borel algebra of a topology?, http://mathoverflow.net/questions/87888 (version: 2012-02-09)
- ↑ {{#invoke:citation/CS1|citation |CitationClass=citation }}
- ↑ {{#invoke:citation/CS1|citation |CitationClass=citation }}.
- ↑ Tommy Norberg and Wim Vervaat, Capacities on non-Hausdorff spaces, in:
*Probability and Lattices*, in: CWI Tract, vol. 110, Math. Centrum Centrum Wisk. Inform., Amsterdam, 1997, pp. 133-150

## External links

- {{#invoke:citation/CS1|citation

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- Formal definition of Borel Sets in the Mizar system, and the list of theorems that have been formally proved about it.
- Weisstein, Eric W., "Borel Set",
*MathWorld*.