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Difference between revisions of "Interior of a set"

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(combining with text from Kernel of a set and rewriting)
(combining with text from Interior and rewriting)
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''of a set $A$ in a [[topological space]] $X$''
 
''of a set $A$ in a [[topological space]] $X$''
  
The interior, or (open kernel), of $A$ is the set of all [[Interior point of a set|interior points]] of $A$: the union of all open sets of $X$ which are subsets of $A$; a point $x \in A$ is interior if there is a [[neighbourhood]] $N_x$ contained in $A$ and containing $x$.  The interior may be denoted $A^\circ$, $\mathrm{Int} A$ or $\langle A \rangle$.
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The interior, or (open) kernel, of $A$ is the set of all [[Interior point of a set|interior points]] of $A$: the union of all open sets of $X$ which are subsets of $A$; a point $x \in A$ is interior if there is a [[neighbourhood]] $N_x$ contained in $A$ and containing $x$.  The interior may be denoted $A^\circ$, $\mathrm{Int} A$ or $\langle A \rangle$.
  
 
The interior of $A$ is the complement in $A$ of the boundary of $A$.  If $A$ and $B$ are mutually complementary sets in a topological space $X$, that is, if $B = X \setminus A$, then the interior of $A$ is the complement of the [[Closure of a set|closure]] of $B$: $X \setminus [A] = \langle B \rangle$ and $X \setminus \langle B \rangle = [ A ]$.
 
The interior of $A$ is the complement in $A$ of the boundary of $A$.  If $A$ and $B$ are mutually complementary sets in a topological space $X$, that is, if $B = X \setminus A$, then the interior of $A$ is the complement of the [[Closure of a set|closure]] of $B$: $X \setminus [A] = \langle B \rangle$ and $X \setminus \langle B \rangle = [ A ]$.
  
The terminology  "kernel"  is seldom used in this context in the English mathematical literature.
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The interior of a closed set in a topological space $X$ is a regular open or [[canonical set]]. Spaces in which the open canonical sets form a [[base]] for the topology are called semi-regular. Every regular space is semi-regular.
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The terminology  "kernel"  is seldom used in this context in the modern English mathematical literature.

Revision as of 20:16, 19 December 2015

2020 Mathematics Subject Classification: Primary: 54A [MSN][ZBL]

of a set $A$ in a topological space $X$

The interior, or (open) kernel, of $A$ is the set of all interior points of $A$: the union of all open sets of $X$ which are subsets of $A$; a point $x \in A$ is interior if there is a neighbourhood $N_x$ contained in $A$ and containing $x$. The interior may be denoted $A^\circ$, $\mathrm{Int} A$ or $\langle A \rangle$.

The interior of $A$ is the complement in $A$ of the boundary of $A$. If $A$ and $B$ are mutually complementary sets in a topological space $X$, that is, if $B = X \setminus A$, then the interior of $A$ is the complement of the closure of $B$: $X \setminus [A] = \langle B \rangle$ and $X \setminus \langle B \rangle = [ A ]$.

The interior of a closed set in a topological space $X$ is a regular open or canonical set. Spaces in which the open canonical sets form a base for the topology are called semi-regular. Every regular space is semi-regular.

The terminology "kernel" is seldom used in this context in the modern English mathematical literature.

How to Cite This Entry:
Interior of a set. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Interior_of_a_set&oldid=36994
This article was adapted from an original article by S.M. Sirota (originator), which appeared in Encyclopedia of Mathematics - ISBN 1402006098. See original article