In mathematics, an open set is a generalization of an open interval in the real line.
In a metric space (a set with a distance defined between every two points), an open set is a set that, with every point in it, contains all points of the metric space that are sufficiently near to (that is, all points whose distance to is less than some value depending on).
More generally, an open set is a member of a given collection of subsets of a given set, a collection that has the property of containing every union of its members, every finite intersection of its members, the empty set, and the whole set itself. A set in which such a collection is given is called a topological space, and the collection is called a topology. These conditions are very loose, and allow enormous flexibility in the choice of open sets. For example, every subset can be open (the discrete topology), or no subset can be open except the space itself and the empty set (the indiscrete topology).
In practice, however, open sets are usually chosen to provide a notion of nearness that is similar to that of metric spaces, without having a notion of distance defined. In particular, a topology allows defining properties such as continuity, connectedness, and compactness, which were originally defined by means of a distance.
The most common case of a topology without any distance is given by manifolds, which are topological spaces that, near each point, resemble an open set of a Euclidean space, but on which no distance is defined in general. Less intuitive topologies are used in other branches of mathematics; for example, the Zariski topology, which is fundamental in algebraic geometry and scheme theory.
Intuitively, an open set provides a method to distinguish two points. For example, if about one of two points in a topological space, there exists an open set not containing the other (distinct) point, the two points are referred to as topologically distinguishable. In this manner, one may speak of whether two points, or more generally two subsets, of a topological space are "near" without concretely defining a distance. Therefore, topological spaces may be seen as a generalization of spaces equipped with a notion of distance, which are called metric spaces.
In the set of all real numbers, one has the natural Euclidean metric; that is, a function which measures the distance between two real numbers: . Therefore, given a real number x, one can speak of the set of all points close to that real number; that is, within ε of x. In essence, points within ε of x approximate x to an accuracy of degree ε. Note that ε > 0 always but as ε becomes smaller and smaller, one obtains points that approximate x to a higher and higher degree of accuracy. For example, if x = 0 and ε = 1, the points within ε of x are precisely the points of the interval (−1, 1); that is, the set of all real numbers between −1 and 1. However, with ε = 0.5, the points within ε of x are precisely the points of (−0.5, 0.5). Clearly, these points approximate x to a greater degree of accuracy than when ε = 1.
The previous discussion shows, for the case x = 0, that one may approximate x to higher and higher degrees of accuracy by defining ε to be smaller and smaller. In particular, sets of the form (−ε, ε) give us a lot of information about points close to x = 0. Thus, rather than speaking of a concrete Euclidean metric, one may use sets to describe points close to x. This innovative idea has far-reaching consequences; in particular, by defining different collections of sets containing 0 (distinct from the sets (−ε, ε)), one may find different results regarding the distance between 0 and other real numbers. For example, if we were to define R as the only such set for "measuring distance", all points are close to 0 since there is only one possible degree of accuracy one may achieve in approximating 0: being a member of R. Thus, we find that in some sense, every real number is distance 0 away from 0. It may help in this case to think of the measure as being a binary condition: all things in R are equally close to 0, while any item that is not in R is not close to 0.
In general, one refers to the family of sets containing 0, used to approximate 0, as a neighborhood basis; a member of this neighborhood basis is referred to as an open set. In fact, one may generalize these notions to an arbitrary set (X); rather than just the real numbers. In this case, given a point (x) of that set, one may define a collection of sets "around" (that is, containing) x, used to approximate x. Of course, this collection would have to satisfy certain properties (known as axioms) for otherwise we may not have a well-defined method to measure distance. For example, every point in X should approximate x to some degree of accuracy. Thus X should be in this family. Once we begin to define "smaller" sets containing x, we tend to approximate x to a greater degree of accuracy. Bearing this in mind, one may define the remaining axioms that the family of sets about x is required to satisfy.
Several definitions are given here, in an increasing order of technicality. Each one is a special case of the next one.
A subset
U
U
U
U
U
U.
An example of a subset of that is not open is the closed interval, since neither nor belongs to for any, no matter how small.
A subset U of a metric space is called open if, for any point x in U, there exists a real number ε > 0 such that any point
y\inM
This generalizes the Euclidean space example, since Euclidean space with the Euclidean distance is a metric space.
\tau
\tau
X\in\tau
\varnothing\in\tau
\tau
\tau
\left\{Ui:i\inI\right\}\subseteq\tau
\tau
\tau
U1,\ldots,Un\in\tau
together with
\tau
Infinite intersections of open sets need not be open. For example, the intersection of all intervals of the form
\left(-1/n,1/n\right),
n
\{0\}
A metric space is a topological space, whose topology consists of the collection of all subsets that are unions of open balls. There are, however, topological spaces that are not metric spaces.
A set might be open, closed, both, or neither. In particular, open and closed sets are not mutually exclusive, meaning that it is in general possible for a subset of a topological space to simultaneously be both an open subset a closed subset. Such subsets are known as . Explicitly, a subset
S
(X,\tau)
S
X\setminusS
(X,\tau)
S\in\tau
X\setminusS\in\tau.
In topological space
(X,\tau),
\varnothing
X
X
\varnothing
\R
I=(0,1)
\R
\R
I\complement=(-infty,0]\cup[1,infty),
I\complement
I\complement
I
J=[0,1]
K=[0,1)
\R\setminusK=(-infty,0)\cup[1,infty)
K
If a topological space
X
X
X
l{U}
X.
\tau:=l{U}\cup\{\varnothing\}
X
S
X
\varnothing ≠ S\subsetneqX
S ≠ X
S\in\tau
X\setminusS\in\tau.
\varnothing
X.
A subset
S
X
\operatorname{Int}\left(\overline{S}\right)=S
\operatorname{Bd}\left(\overline{S}\right)=\operatorname{Bd}S
\operatorname{Bd}S
\operatorname{Int}S
\overline{S}
S
X
X
X
S
X
\overline{\operatorname{Int}S}=S
\operatorname{Bd}\left(\operatorname{Int}S\right)=\operatorname{Bd}S.
The union of any number of open sets, or infinitely many open sets, is open.[3] The intersection of a finite number of open sets is open.
A complement of an open set (relative to the space that the topology is defined on) is called a closed set. A set may be both open and closed (a clopen set). The empty set and the full space are examples of sets that are both open and closed.[4]
Open sets have a fundamental importance in topology. The concept is required to define and make sense of topological space and other topological structures that deal with the notions of closeness and convergence for spaces such as metric spaces and uniform spaces.
Every subset A of a topological space X contains a (possibly empty) open set; the maximum (ordered under inclusion) such open set is called the interior of A. It can be constructed by taking the union of all the open sets contained in A.
f:X\toY
X
Y
Y
X.
f:X\toY
X
Y.
An open set on the real line has the characteristic property that it is a countable union of disjoint open intervals.
Whether a set is open depends on the topology under consideration. Having opted for greater brevity over greater clarity, we refer to a set X endowed with a topology
\tau
(X,\tau)
\tau.
V\capY
V\capY
As a concrete example of this, if U is defined as the set of rational numbers in the interval
(0,1),
See also: Almost open map and Glossary of topology.
Throughout,
(X,\tau)
A subset
A\subseteqX
X
A~\subseteq~\operatorname{int}X\left(\operatorname{cl}X\left(\operatorname{int}XA\right)\right)
A~\subseteq~\operatorname{int}X\left(\operatorname{cl}XA\right).
D,U\subseteqX
U
X,
D
X,
A=U\capD.
X
U\subseteqX
A
U.
A~\subseteq~\operatorname{int}X\left(\operatorname{cl}XA\right)~\cup~\operatorname{cl}X\left(\operatorname{int}XA\right)
A~\subseteq~\operatorname{cl}X\left(\operatorname{int}X\left(\operatorname{cl}XA\right)\right)
\operatorname{cl}XA
X.
U
X
U\subseteqA\subseteq\operatorname{cl}XU.
X
A,
A.
x\bull=\left(xi
| infty | |
| \right) | |
| i=1 |
X
a\inA
x\bull\tox
(X,\tau),
x\bull
A
i
j\geqi,
xj\inA
A
X,
\begin{alignat}{4} \operatorname{SeqInt}XA :&=\{a\inA~:~wheneverasequenceinXconvergestoain(X,\tau),thenthatsequenceiseventuallyinA\}\\ &=\{a\inA~:~theredoesNOTexistasequenceinX\setminusAthatconvergesin(X,\tau)toapointinA\}\\ \end{alignat}
S\subseteqX
X
S
\operatorname{SeqCl}XS
x\inX
S
x
X
U\subseteqX
AtriangleupU
triangleup
A\subseteqX
E
X
A\capE
E
A~\subseteq~\operatorname{cl}X\left(\operatorname{int}XA\right)
\operatorname{cl}XA=\operatorname{cl}X\left(\operatorname{int}XA\right)
X
X
A\subseteqX,
\operatorname{sCl}XA,
X
A
x\inA
U
X
x\inU\subseteq\operatorname{sCl}XU\subseteqA.
X
X
x\inX
B\subseteqX
U
x
X,
B\cap\operatorname{cl}XU
B\cap\operatorname{int}X\left(\operatorname{cl}XU\right)
Using the fact that
A~\subseteq~\operatorname{cl}XA~\subseteq~\operatorname{cl}XB
\operatorname{int}XA~\subseteq~\operatorname{int}XB~\subseteq~B
whenever two subsets
A,B\subseteqX
A\subseteqB,
Moreover, a subset is a regular open set if and only if it is preopen and semi-closed. The intersection of an α-open set and a semi-preopen (resp. semi-open, preopen, b-open) set is a semi-preopen (resp. semi-open, preopen, b-open) set. Preopen sets need not be semi-open and semi-open sets need not be preopen.
Arbitrary unions of preopen (resp. α-open, b-open, semi-preopen) sets are once again preopen (resp. α-open, b-open, semi-preopen). However, finite intersections of preopen sets need not be preopen. The set of all α-open subsets of a space
(X,\tau)
X
\tau.
A topological space
X
X
X
X
X
X.