Cauchy sequence: Difference between revisions
Jump to navigation
Jump to search
imported>Aleksander Stos (completeness) |
imported>Subpagination Bot m (Add {{subpages}} and remove any categories (details)) |
||
| Line 1: | Line 1: | ||
{{subpages}} | |||
In [[mathematics]], a '''Cauchy sequence''' is a [[sequence]] in a [[metric space]] with the property that elements in that sequence ''cluster'' together more and more as the sequence progresses. Another way of thinking of the clustering is that the distance between any two elements diminishes as their indexes grow larger and larger. | In [[mathematics]], a '''Cauchy sequence''' is a [[sequence]] in a [[metric space]] with the property that elements in that sequence ''cluster'' together more and more as the sequence progresses. Another way of thinking of the clustering is that the distance between any two elements diminishes as their indexes grow larger and larger. | ||
| Line 5: | Line 7: | ||
==Formal definition== | ==Formal definition== | ||
Let <math>(X,d)</math> be a metric space. Then a sequence <math>x_1,x_2,\ldots</math> of elements in ''X'' is a Cauchy sequence if for any real number <math>\epsilon>0</math> there exists a positive integer <math>N(\epsilon)</math>, dependent on <math>\epsilon</math>, such that <math>d(x_n,x_m)<\epsilon</math> for all <math>m,n>N(\epsilon)</math>. In [[limit]] notation this is written as <math>\mathop{\lim}_{n,m \rightarrow \infty}d(x_m,x_n)=0</math>. | Let <math>(X,d)</math> be a metric space. Then a sequence <math>x_1,x_2,\ldots</math> of elements in ''X'' is a Cauchy sequence if for any real number <math>\epsilon>0</math> there exists a positive integer <math>N(\epsilon)</math>, dependent on <math>\epsilon</math>, such that <math>d(x_n,x_m)<\epsilon</math> for all <math>m,n>N(\epsilon)</math>. In [[limit]] notation this is written as <math>\mathop{\lim}_{n,m \rightarrow \infty}d(x_m,x_n)=0</math>. | ||
Revision as of 13:29, 27 January 2008
In mathematics, a Cauchy sequence is a sequence in a metric space with the property that elements in that sequence cluster together more and more as the sequence progresses. Another way of thinking of the clustering is that the distance between any two elements diminishes as their indexes grow larger and larger.
Depending on the underlying space, the Cauchy sequences may be convergent or not. This leads to the notion of completeness of the space.
Formal definition
Let be a metric space. Then a sequence of elements in X is a Cauchy sequence if for any real number there exists a positive integer , dependent on , such that for all . In limit notation this is written as .
