Interior (topology): Difference between revisions
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* Interior [[distributivity|distributes]] over finite [[intersection]]: <math>(A \cap B)^{\circ} = A^{\circ} \cap B^{\circ}</math>. | * Interior [[distributivity|distributes]] over finite [[intersection]]: <math>(A \cap B)^{\circ} = A^{\circ} \cap B^{\circ}</math>. | ||
* The complement of the [[closure (topology)|closure]] of a set in ''X'' is the interior of the complement of that set; the complement of the interior of a set in ''X'' is the closure of the complement of that set. | * The complement of the [[closure (topology)|closure]] of a set in ''X'' is the interior of the complement of that set; the complement of the interior of a set in ''X'' is the closure of the complement of that set. | ||
:<math>(X - A)^{\circ} = X - \overline{A};~~ \overline{X-A} = X - A^{\circ}.</math> | :<math>(X - A)^{\circ} = X - \overline{A};~~ \overline{X-A} = X - A^{\circ}.</math>[[Category:Suggestion Bot Tag]] |
Latest revision as of 16:01, 1 September 2024
In mathematics, the interior of a subset A of a topological space X is the union of all open sets in X that are subsets of A. It is usually denoted by . It may equivalently be defined as the set of all points in A for which A is a neighbourhood.
Properties
- A set contains its interior, .
- The interior of a open set G is just G itself, .
- Interior is idempotent: .
- Interior distributes over finite intersection: .
- The complement of the closure of a set in X is the interior of the complement of that set; the complement of the interior of a set in X is the closure of the complement of that set.