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Second Category


A subset E of a topological space S is said to be of second category in S if E cannot be written as the countable union of subsets which are nowhere dense in S, i.e., if writing E as a union

 E= union _(n in N)E_n

implies that at least one subset E_n subset S fails to be nowhere dense in S. Said differently, any set which fails to be of first category is necessarily second category and unlike sets of first category, one thinks of a second category subset as a "non-small" subset of its host space. Sets of second category are sometimes referred to as nonmeager.

An important distinction should be made between the above-used notion of "category" and category theory. Indeed, the notions of first and second category sets are independent of category theory.

The irrational numbers are of second category and the rational numbers are of first category in R with the usual topology. In general, the host space and its topology play a fundamental role in determining category. For example, the set Z of integers with the subset topology inherited from R is (vacuously) of second category relative to itself because every subset of Z is open in Z with respect to that topology; on the other hand, Z is of first category in R with its standard topology and in Q with the subset topology inherited by Q from R. Likewise, the Cantor set is a Baire space (i.e., each of its open sets are of second category relative to it) even though it is of first category in the interval [0,1] with the usual topology.


See also

Baire Category Theorem, First Category, Meager Set, Nonmeager Set, Nowhere Dense

Portions of this entry contributed by Christopher Stover

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References

Rudin, W. Functional Analysis. New York: McGraw-Hill, 1991.

Cite this as:

Stover, Christopher and Weisstein, Eric W. "Second Category." From MathWorld--A Wolfram Web Resource. https://mathworld.wolfram.com/SecondCategory.html

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