Fréchet filter explained

is a certain collection of subsets of

(that is, it is a particular subset of the power set of

).A subset

belongs to the Fréchet filter if and only if the complement of

is finite.Any such set

is said to be, which is why it is alternatively called the cofinite filter on

The Fréchet filter is of interest in topology, where filters originated, and relates to order and lattice theory because a set's power set is a partially ordered set under set inclusion (more specifically, it forms a lattice).The Fréchet filter is named after the French mathematician Maurice Fréchet (1878-1973), who worked in topology.

Definition

A subset

of a set

is said to be cofinite in
X

if its complement in

(that is, the set

X\setminusA

) is finite.If the empty set is allowed to be in a filter, the Fréchet filter on
X

, denoted by

is the set of all cofinite subsets of

.That is:^[1]

F = \.

is a finite set, then every cofinite subset of

is necessarily not empty, so that in this case, it is not necessary to make the empty set assumption made before.

This makes

a on the lattice

(\wp(X),\subseteq),

the power set

\wp(X)

with set inclusion, given that

S^{\operatorname{C}

} denotes the complement of a set

The following two conditions hold:

Intersection condition: If two sets are finitely complemented in

, then so is their intersection, since

(A\capB)^{\operatorname{C}

} = A^ \cup B^, and

Upper-set condition: If a set is finitely complemented in

, then so are its supersets in

Properties

If the base set

is finite, then

F=\wp(X)

since every subset of

, and in particular every complement, is then finite.This case is sometimes excluded by definition or else called the improper filter on

^[2] Allowing

to be finite creates a single exception to the Fréchet filter’s being free and non-principal since a filter on a finite set cannot be free and a non-principal filter cannot contain any singletons as members.

is infinite, then every member of

is infinite since it is simply

minus finitely many of its members.Additionally,

is infinite since one of its subsets is the set of all

\{x\}^{\operatorname{C}

}, where

x\inX.

The Fréchet filter is both free and non-principal, excepting the finite case mentioned above, and is included in every free filter.It is also the dual filter of the ideal of all finite subsets of (infinite)

The Fréchet filter is necessarily an ultrafilter (or maximal proper filter).Consider the power set

\wp(\N),

where

is the natural numbers.The set of even numbers is the complement of the set of odd numbers. Since neither of these sets is finite, neither set is in the Fréchet filter on

\N.

However, an (and any other non-degenerate filter) is free if and only if it includes the Fréchet filter.The ultrafilter lemma states that every non-degenerate filter is contained in some ultrafilter.The existence of free ultrafilters was established by Tarski in 1930, relying on a theorem equivalent to the axiom of choice, and is used in the construction of the hyperreals in nonstandard analysis.^[3]

Examples

is a finite set, assuming that the empty set can be in a filter, then the Fréchet filter on

consists of all the subsets of

On the set

of natural numbers, the set of infinite intervals

B=\{(n,infty):n\in\N\}

is a Fréchet filter base, that is, the Fréchet filter on

consists of all supersets of elements of

External links

- J.B. Nation, Notes on Lattice Theory, course notes, revised 2017.

Notes and References

Web site: Cofinite filter. mathworld.wolfram.com.
Encyclopedia: Hodges, Wilfrid. Model Theory. Encyclopedia of Mathematics and its Applications. Cambridge University Press. 2008. 265. 978-0-521-06636-5.
Book: Pinto, J. Sousa. Hoskins, R.F.. Infinitesimal Methods for Mathematical Analysis. Mathematics and Applications Series. Horwood Publishing. 2004. 53. 978-1-898563-99-0.