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In the mathematical field of [[descriptive set theory]], a '''pointclass''' is a collection of [[Set (mathematics)|sets]] of [[point (mathematics)|points]], where a ''point'' is ordinarily understood to be an element of some [[perfect set|perfect]] [[Polish space]]. In practice, a pointclass is usually characterized by some sort of ''definability property''; for example, the collection of all [[open set]]s in some fixed collection of Polish spaces is a pointclass. (An open set may be seen as in some sense definable because it cannot be a purely arbitrary collection of points; for any point in the set, all points sufficiently close to that point must also be in the set.)
 
Pointclasses find application in formulating many important principles and theorems from [[set theory]] and [[real analysis]]. Strong set-theoretic principles may be stated in terms of the [[determinacy]] of various pointclasses, which in turn implies that sets in those pointclasses (or sometimes larger ones) have regularity properties such as [[Lebesgue measure|Lebesgue measurability]] (and indeed [[universally measurable set|universal measurability]]), the [[property of Baire]], and the [[perfect set property]].
 
==Basic framework==
In practice, descriptive set theorists often simplify matters by working in a fixed Polish space such as [[Baire space (set theory)|Baire space]] or sometimes [[Cantor space]], each of which has the advantage of being [[zero dimensional]], and indeed [[homeomorphic]] to its finite or countable powers, so that considerations of dimensionality never arise.  [[Yiannis N. Moschovakis|Moschovakis]] provides greater generality by fixing once and for all a collection of underlying Polish spaces, including the set of all naturals, the set of all reals, Baire space, and Cantor space, and otherwise allowing the reader to throw in any desired perfect Polish space. Then he defines a ''product space'' to be any finite [[Cartesian product]] of these underlying spaces. Then, for example, the pointclass <math>\boldsymbol{\Sigma}^0_1</math> of all open sets means the collection of all open subsets of one of these product spaces. This approach prevents <math>\boldsymbol{\Sigma}^0_1</math> from being a [[proper class]], while avoiding excessive specificity as to the particular Polish spaces being considered (given that the focus is on the fact that <math>\boldsymbol{\Sigma}^0_1</math> is the collection of open sets, not on the spaces themselves).
 
==Boldface pointclasses==
The pointclasses in the [[Borel hierarchy]], and in the more complex [[projective hierarchy]], are represented by sub- and super-scripted Greek letters in [[boldface]] fonts; for example, <math>\boldsymbol{\Pi}^0_1</math> is the pointclass of all [[closed set]]s, <math>\boldsymbol{\Sigma}^0_2</math> is the pointclass of all [[F-sigma|''F''<sub>&sigma;</sub>]] sets, <math>\boldsymbol{\Delta}^0_2</math> is the collection of all sets that are simultaneously ''F''<sub>&sigma;</sub> and [[G-delta set|''G''<sub>&delta;</sub>]], and <math>\boldsymbol{\Sigma}^1_1</math> is the pointclass of all [[analytic set]]s.
 
Sets in such pointclasses need be "definable" only up to a point. For example, every [[singleton set]] in a Polish space is closed, and thus <math>\boldsymbol{\Pi}^0_1</math>. Therefore it cannot be that every <math>\boldsymbol{\Pi}^0_1</math> set must be "more definable" than an arbitrary element of a Polish space (say, an arbitrary real number, or an arbitrary countable sequence of natural numbers). Boldface pointclasses, however, may (and in practice ordinarily do) require that sets in the class be definable relative to some real number, taken as an [[oracle machine|oracle]]. In that sense, membership in a boldface pointclass is a definability property, even though it is not absolute definability, but only definability with respect to a possibly undefinable real number.
 
Boldface pointclasses, or at least the ones ordinarily considered, are closed under [[Wadge reducibility]]; that is, given a set in the pointclass, its [[inverse image]] under a [[continuous function]] (from a product space to the space of which the given set is a subset) is also in the given pointclass. Thus a boldface pointclass is a downward-closed union of [[Wadge degree]]s.
 
==Lightface pointclasses==
The Borel and projective hierarchies have analogs in [[effective descriptive set theory]] in which the definability property is no longer relativized to an oracle, but is made absolute. For example, if one fixes some collection of basic open neighborhoods (say, in Baire space, the set of all sets of the form {''x''&isin;&omega;<sup>&omega;</sup>|''x'' ⊇''s''} for any fixed finite sequence ''s'' of natural numbers), then the open, or <math>\boldsymbol{\Sigma}^0_1</math>, sets may be characterized as all (arbitrary) unions of basic open neighborhoods. The analogous <math>\Sigma^0_1</math> sets, with a lightface <math>\Sigma</math>, are no longer ''arbitrary'' unions of such neighborhoods, but [[computable set|computable]] unions of them (that is, a set is <math>\Sigma^0_1</math> if there is a computable set ''S'' of finite sequences of naturals such that the given set is the union of all {''x''&isin;&omega;<sup>&omega;</sup>|''x'' ⊇''s''} for ''s'' in ''S''). A set is lightface <math>\Pi^0_1</math> if it is the complement of a <math>\Sigma^0_1</math> set. Thus each <math>\Sigma^0_1</math> set has at least one '''index''', which describes the computable function enumerating the basic open sets from which it is composed; in fact it will have infinitely many such indices. Similarly, an index for a <math>\Pi^0_1</math> set ''B'' describes the computable function enumerating the basic open sets in the complement of ''B''.
 
A set ''A'' is lightface  <math>\Sigma^0_2</math> if it is a union of a computable sequence of <math>\Pi^0_1</math> sets (that is, there is a computable enumeration of indices of <math>\Pi^0_1</math> sets such that ''A'' is the union of these sets). This relationship between lightface sets and their indices is used to extend the lightface Borel hierarchy into the transfinite, via [[recursive ordinal]]s.  This produces that [[hyperarithmetic hierarchy]], which is the lightface analog of the Borel hierarchy. (The finite levels of the [[Hyperarithmetical_theory|hyperarithmetic hierarchy]] are known as the [[arithmetical hierarchy]].)
 
A similar treatment can be applied to the projective hierarchy. Its lightface analog is known as the [[analytical hierarchy]].
 
==References==
* {{cite book | author=Moschovakis, Yiannis N. | title=Descriptive Set Theory | publisher=North Holland | year=1980 |id=ISBN 0-444-70199-0}}
 
[[Category:Descriptive set theory]]
[[Category:General topology]]

Revision as of 20:12, 8 March 2013

In the mathematical field of descriptive set theory, a pointclass is a collection of sets of points, where a point is ordinarily understood to be an element of some perfect Polish space. In practice, a pointclass is usually characterized by some sort of definability property; for example, the collection of all open sets in some fixed collection of Polish spaces is a pointclass. (An open set may be seen as in some sense definable because it cannot be a purely arbitrary collection of points; for any point in the set, all points sufficiently close to that point must also be in the set.)

Pointclasses find application in formulating many important principles and theorems from set theory and real analysis. Strong set-theoretic principles may be stated in terms of the determinacy of various pointclasses, which in turn implies that sets in those pointclasses (or sometimes larger ones) have regularity properties such as Lebesgue measurability (and indeed universal measurability), the property of Baire, and the perfect set property.

Basic framework

In practice, descriptive set theorists often simplify matters by working in a fixed Polish space such as Baire space or sometimes Cantor space, each of which has the advantage of being zero dimensional, and indeed homeomorphic to its finite or countable powers, so that considerations of dimensionality never arise. Moschovakis provides greater generality by fixing once and for all a collection of underlying Polish spaces, including the set of all naturals, the set of all reals, Baire space, and Cantor space, and otherwise allowing the reader to throw in any desired perfect Polish space. Then he defines a product space to be any finite Cartesian product of these underlying spaces. Then, for example, the pointclass Σ10 of all open sets means the collection of all open subsets of one of these product spaces. This approach prevents Σ10 from being a proper class, while avoiding excessive specificity as to the particular Polish spaces being considered (given that the focus is on the fact that Σ10 is the collection of open sets, not on the spaces themselves).

Boldface pointclasses

The pointclasses in the Borel hierarchy, and in the more complex projective hierarchy, are represented by sub- and super-scripted Greek letters in boldface fonts; for example, Π10 is the pointclass of all closed sets, Σ20 is the pointclass of all Fσ sets, Δ20 is the collection of all sets that are simultaneously Fσ and Gδ, and Σ11 is the pointclass of all analytic sets.

Sets in such pointclasses need be "definable" only up to a point. For example, every singleton set in a Polish space is closed, and thus Π10. Therefore it cannot be that every Π10 set must be "more definable" than an arbitrary element of a Polish space (say, an arbitrary real number, or an arbitrary countable sequence of natural numbers). Boldface pointclasses, however, may (and in practice ordinarily do) require that sets in the class be definable relative to some real number, taken as an oracle. In that sense, membership in a boldface pointclass is a definability property, even though it is not absolute definability, but only definability with respect to a possibly undefinable real number.

Boldface pointclasses, or at least the ones ordinarily considered, are closed under Wadge reducibility; that is, given a set in the pointclass, its inverse image under a continuous function (from a product space to the space of which the given set is a subset) is also in the given pointclass. Thus a boldface pointclass is a downward-closed union of Wadge degrees.

Lightface pointclasses

The Borel and projective hierarchies have analogs in effective descriptive set theory in which the definability property is no longer relativized to an oracle, but is made absolute. For example, if one fixes some collection of basic open neighborhoods (say, in Baire space, the set of all sets of the form {x∈ωω|xs} for any fixed finite sequence s of natural numbers), then the open, or Σ10, sets may be characterized as all (arbitrary) unions of basic open neighborhoods. The analogous Σ10 sets, with a lightface Σ, are no longer arbitrary unions of such neighborhoods, but computable unions of them (that is, a set is Σ10 if there is a computable set S of finite sequences of naturals such that the given set is the union of all {x∈ωω|xs} for s in S). A set is lightface Π10 if it is the complement of a Σ10 set. Thus each Σ10 set has at least one index, which describes the computable function enumerating the basic open sets from which it is composed; in fact it will have infinitely many such indices. Similarly, an index for a Π10 set B describes the computable function enumerating the basic open sets in the complement of B.

A set A is lightface Σ20 if it is a union of a computable sequence of Π10 sets (that is, there is a computable enumeration of indices of Π10 sets such that A is the union of these sets). This relationship between lightface sets and their indices is used to extend the lightface Borel hierarchy into the transfinite, via recursive ordinals. This produces that hyperarithmetic hierarchy, which is the lightface analog of the Borel hierarchy. (The finite levels of the hyperarithmetic hierarchy are known as the arithmetical hierarchy.)

A similar treatment can be applied to the projective hierarchy. Its lightface analog is known as the analytical hierarchy.

References

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