Denseness: Difference between revisions

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In mathematics, denseness is an abstract notion that captures the idea that elements of a set A can "approximate" any element of a larger set X, which contains A as a subset, up to arbitrary "accuracy" or "closeness".

Formal definition

Let X be a topological space. A subset $\scriptstyle A\subset X$ is said to be dense in X, or to be a dense set in X, if the closure of A coincides with X (that is, if $\scriptstyle {\overline {A}}=X$ ).

Examples

Consider the set of all rational numbers $\scriptstyle \mathbb {Q}$ . Then it can be shown that for an arbitrary real number a and desired accuracy $\scriptstyle \epsilon >0$ , one can always find some rational number q such that $\scriptstyle |q-a|<\epsilon$ . Hence the set of rational numbers are dense in the set of real numbers ( $\scriptstyle {\overline {\mathbb {Q} }}=\mathbb {R}$ )
The set of algebraic polynomials can uniformly approximate any continuous function on a fixed interval [a,b] (with b>a) up to arbitrary accuracy. This is a famous result in analysis known as Weierstrass' theorem. Thus the algebraic polynomials are dense in the space of continuous functions on the interval [a,b] (with respect to the uniform topology).

@@ Line 3: / Line 3: @@
 ==Formal definition==
-Let ''X'' be a [[topological space]] and <math>\scriptstyle A \subset X</math>, then ''A'' is said to be dense in ''X'', or is a dense set in ''X'', if the [[closure (mathematics)|closure]] of ''A'' coincides with ''X''. That is, <math>\scriptstyle \overline{A}=X</math>.
+Let ''X'' be a [[topological space]]. A subset <math>\scriptstyle A \subset X</math> is said to be dense in ''X'', or to be a dense set in ''X'', if the [[closure (mathematics)|closure]] of ''A'' coincides with ''X'' (that is, if <math>\scriptstyle \overline{A}=X</math>).
 ==Examples==
-. Consider the set of all rational numbers <math>\scriptstyle \mathbb{Q}</math>. Then it can be shown that for an arbitrary real number ''a'' and a desired accuracy <math>\scriptstyle \epsilon>0</math>, one can always find some rational number ''q'' such that <math>\scriptstyle |q-a|<\epsilon</math>. Hence the set of rational numbers are dense in the set of real numbers (<math>\scriptstyle \overline{\mathbb{Q}}=\mathbb{R}</math>)
+# Consider the set of all [[rational number]]s <math>\scriptstyle \mathbb{Q}</math>. Then it can be shown that for an arbitrary [[real number]] ''a'' and desired accuracy <math>\scriptstyle \epsilon>0</math>, one can always find some rational number ''q'' such that <math>\scriptstyle |q-a|<\epsilon</math>. Hence the set of rational numbers are dense in the set of real numbers (<math>\scriptstyle \overline{\mathbb{Q}}=\mathbb{R}</math>)
+# The set of algebraic [[polynomials]] can uniformly approximate any [[continuity#continuous_function|continuous function]] on a fixed interval [''a'',''b''] (with ''b''>''a'') up to arbitrary accuracy. This is a famous result in analysis known as [[Weierstrass' theorem]].  Thus the algebraic polynomials are dense in the [[space of continuous functions]] on the interval [''a'',''b''] (with respect to the uniform topology).
-. The set of algebraic [[polynomials]] can uniformly approximate any [[continuity#continuous_function|continuous function]] on a fixed interval [''a'',''b''] (''b''>''a'') up to arbitrary accuracy. This is a famous result in analysis known as [[Weierstrass' Theorem]].  Thus the algebraic polynomials are dense in the set of continuous functions on the interval [''a'',''b''] (with respect to the uniform topology).

Denseness: Difference between revisions

Revision as of 07:13, 22 September 2008

Formal definition

Examples

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