To see that this is a filter, note that since it is thus both closed and unbounded (see club set). If then any subset of containing is also in since and therefore anything containing it, contains a club set.
It is a -complete filter because the intersection of fewer than club sets is a club set. To see this, suppose is a sequence of club sets where Obviously is closed, since any sequence which appears in appears in every and therefore its limit is also in every To show that it is unbounded, take some Let be an increasing sequence with and for every Such a sequence can be constructed, since every is unbounded. Since and is regular, the limit of this sequence is less than We call it and define a new sequence similar to the previous sequence. We can repeat this process, getting a sequence of sequences where each element of a sequence is greater than every member of the previous sequences. Then for each is an increasing sequence contained in and all these sequences have the same limit (the limit of ). This limit is then contained in every and therefore and is greater than
To see that is closed under diagonal intersection, let be a sequence of club sets, and let To show is closed, suppose and Then for each for all Since each is closed, for all so To show is unbounded, let and define a sequence as follows: and is the minimal element of such that Such an element exists since by the above, the intersection of club sets is club. Then and since it is in each with
Clubsuit – in set theory, the combinatorial principle that, for every stationary 𝑆⊂ω₁, there exists a sequence of sets 𝐴_𝛿 (𝛿∈𝑆) such that 𝐴_𝛿 is a cofinal subset of 𝛿 and every unbounded subset of ω₁ is contained in some 𝐴_𝛿Pages displaying wikidata descriptions as a fallback
Filter (mathematics) – In mathematics, a special subset of a partially ordered set