Interior (topology)

The point x is an interior point of S. The point y is on the boundary of S.

In mathematics, specifically in topology, the interior of a subset S of points of a topological space X consists of all points of S that do not belong to the boundary of S. A point that is in the interior of S is an interior point of S.

The interior of S is the complement of the closure of the complement of S. In this sense interior and closure are dual notions.

The exterior of a set is the interior of its complement, equivalently the complement of its closure; it consists of the points that are in neither the set nor its boundary. The interior, boundary, and exterior of a subset together partition the whole space into three blocks (or fewer when one or more of these is empty). The interior and exterior are always open while the boundary is always closed. Sets with empty interior have been called boundary sets.^[1]

Definitions

Interior point

If S is a subset of a Euclidean space, then x is an interior point of S if there exists an open ball centered at x which is completely contained in S. (This is illustrated in the introductory section to this article.)

This definition generalizes to any subset S of a metric space X with metric d: x is an interior point of S if there exists r > 0, such that y is in S whenever the distance d(x, y) < r.

This definition generalises to topological spaces by replacing "open ball" with "open set". Let S be a subset of a topological space X. Then x is an interior point of S if x is contained in an open subset of S. (Equivalently, x is an interior point of S if there exists a neighbourhood of x which is contained in S.)

Interior of a set

The interior of a set S is the set of all interior points of S. The interior of S is denoted int(S), Int(S) or S^o. The interior of a set has the following properties.

int(S) is an open subset of S.
int(S) is the union of all open sets contained in S.
int(S) is the largest open set contained in S.
A set S is open if and only if S = int(S).
int(int(S)) = int(S) (idempotence).
If S is a subset of T, then int(S) is a subset of int(T).
If A is an open set, then A is a subset of S if and only if A is a subset of int(S).

Sometimes the second or third property above is taken as the definition of the topological interior.

Note that these properties are also satisfied if "interior", "subset", "union", "contained in", "largest" and "open" are replaced by "closure", "superset", "intersection", "which contains", "smallest", and "closed", respectively. For more on this matter, see interior operator below.

Examples

a is an interior point of M, because there is an ε-neighbourhood of a which is a subset of M.

In any space, the interior of the empty set is the empty set.
In any space X, if $A\subset X$ , int(A) is contained in A.
If X is the Euclidean space $\mathbb {R}$ of real numbers, then int([0, 1]) = (0, 1).
If X is the Euclidean space $\mathbb {R}$ , then the interior of the set $\mathbb {Q}$ of rational numbers is empty.
If X is the complex plane $\mathbb {C} =\mathbb {R} ^{2}$ , then $\mathrm {int} (\{z\in \mathbb {C} :|z|\leq 1\})=\{z\in \mathbb {C} :|z|<1\}.$
In any Euclidean space, the interior of any finite set is the empty set.

On the set of real numbers one can put other topologies rather than the standard one.

If $X=\mathbb {R}$ , where $\mathbb {R}$ has the lower limit topology, then int([0, 1]) = [0, 1).
If one considers on $\mathbb {R}$ the topology in which every set is open, then int([0, 1]) = [0, 1].
If one considers on $\mathbb {R}$ the topology in which the only open sets are the empty set and $\mathbb {R}$ itself, then int([0, 1]) is the empty set.

These examples show that the interior of a set depends upon the topology of the underlying space. The last two examples are special cases of the following.

In any discrete space, since every set is open, every set is equal to its interior.
In any indiscrete space X, since the only open sets are the empty set and X itself, we have int(X) = X and for every proper subset A of X, int(A) is the empty set.

Interior operator

The interior operator ^o is dual to the closure operator ^—, in the sense that

S^{\circ }=X\backslash {\overline {(X\backslash S)}}

and also

{\bar {S}}=X\backslash (X\backslash S)^{\circ }

where X is the topological space containing S, and the backslash refers to the set-theoretic difference.

Therefore, the abstract theory of closure operators and the Kuratowski closure axioms can be easily translated into the language of interior operators, by replacing sets with their complements.

Exterior of a set

Main article: Exterior (topology)

The exterior of a subset S of a topological space X, denoted ext(S) or Ext(S), is the interior int(X \ S) of its relative complement. Alternatively, it can be defined as X \ S^—, the complement of the closure of S. Many properties follow in a straightforward way from those of the interior operator, such as the following.

ext(S) is an open set that is disjoint with S.
ext(S) is the union of all open sets that are disjoint with S.
ext(S) is the largest open set that is disjoint with S.
If S is a subset of T, then ext(S) is a superset of ext(T).

Unlike the interior operator, ext is not idempotent, but the following holds:

ext(ext(S)) is a superset of int(S).

Interior-disjoint shapes

The red shapes are not interior-disjoint the blue Triangle. The green and the yellow shapes are interior-disjoint with the blue Triangle, but only the yellow shape is entirely disjoint from the blue Triangle.

Two shapes a and b are called interior-disjoint if the intersection of their interiors is empty. Interior-disjoint shapes may or may not intersect in their boundary.

References

↑ Kuratowski, Kazimierz (1922). "Sur l'Operation Ā de l'Analysis Situs" (PDF). Fundamenta Mathematicae. Warsaw: Polish Academy of Sciences. 3: 182–199. ISSN 0016-2736.

External links

Interior at PlanetMath.org.

Functional analysis

Set / subset types	Absolutely convex Absorbing Balanced Bounded Convex Radial Star-shaped Symmetric Linear cone (subset) Convex cone (subset)

TVS types	Banach Barrelled Bornological Brauner F-space Finite-dimensional Fréchet (tame) Hilbert LF-space Locally convex Mackey Montel Nuclear Normed (norm) Quasinormed Reflexive Riesz Smith Stereotype Webbed Topological tensor product (of Hilbert spaces)

Mapping topologies	Dual Dual space Operator Ultraweak Weak (operator) Mackey Strong (polar operator) Ultrastrong Uniform convergence

Linear operators	Adjoint Bilinear (form) Bounded / Unbounded Closed Continuous / Discontinuous Compact Fredholm Hilbert–Schmidt Functionals (positive) Normal Nuclear Self-adjoint Strictly singular Trace class Transpose Unitary

Set operations	Algebraic interior (core) Interior Minkowski addition Polar

Operator theory	Banach algebras C-algebras Spectrum (C-algebra radius) Spectral theory (of ODEs Spectral theorem) Polar decomposition Singular value decomposition

Theorems	Banach–Alaoglu Banach–Saks Banach–Mazur Bessel's inequality Cauchy–Schwarz inequality Closed range Closed graph Eberlein–Šmulian Freudenthal spectral Gelfand–Mazur Goldstine Hahn–Banach (hyperplane separation) Kakutani fixed-point Lomonosov's invariant subspace Mackey–Arens Mazur's lemma M. Riesz extension Open mapping Parseval's identity Schauder fixed-point

Analysis	Bochner space Differentiation in Fréchet spaces Derivatives (Fréchet Gâteaux functional holomorphic) Integrals (Bochner Dunford Gelfand–Pettis regulated weak) Functional calculus (Borel continuous holomorphic) Inverse function theorem (Nash–Moser theorem) Vector measure Weakly measurable function

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