Prewellordering
From Wikipedia, the free encyclopedia
In set theory, a prewellordering is a binary relation that is transitive, wellfounded, and total. In other words, if is a prewellordering on a set X, and if we define by
then is an equivalence relation on X, and induces a wellordering on the quotient . The order-type of this induced wellordering is an ordinal, referred to as the length of the prewellordering.
A norm on a set X is a map from X into the ordinals. Every norm induces a prewellordering; if is a norm, the associated prewellordering is given by
Conversely, every prewellordering is induced by a unique regular norm (a norm is regular if, for any and any α < φ(x), there is such that φ(y) = α).
Contents |
[edit] Prewellordering property
If is a pointclass of subsets of some collection of Polish spaces, closed under Cartesian product, and if is a prewellordering of some subset P of some element X of , then is said to be a -prewellordering of P if the relations and are elements of , where for ,
is said to have the prewellordering property if every set in admits a -prewellordering.
[edit] Examples
and both have the prewellordering property; this is provable in ZFC alone. Assuming sufficient large cardinals, for every , and have the prewellordering property.
[edit] Consequences
[edit] Reduction
If is an adequate pointclass with the prewellordering property, then it also has the reduction property: For any space and any sets , A and B both in , the union may be partitioned into sets , both in , such that and .
[edit] Separation
If is an adequate pointclass whose dual pointclass has the prewellordering property, then has the separation property: For any space and any sets , A and B disjoint sets both in , there is a set such that both C and its complement are in , with and .
For example, has the prewellordering property, so has the separation property. This means that if A and B are disjoint analytic subsets of some Polish space X, then there is a Borel subset C of X such that C includes A and is disjoint from B.
[edit] References
- Moschovakis, Yiannis N. (1980). Descriptive Set Theory. North Holland. ISBN 0-444-70199-0.