Complete metric space: Difference between revisions

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In [[mathematics]], '''completeness''' is a property ascribed to a [[metric space]] in which every [[Cauchy sequence]] in that space is ''convergent''. In other words, every Cauchy sequence in the metric space tends in the limit to a point which is again an element of that space. Hence the metric space is, in a sense, "complete."  
In [[mathematics]], a '''complete metric space''' is a [[metric space]] in which every [[Cauchy sequence]] in that space is ''convergent''. In other words, every Cauchy sequence in the metric space tends in the limit to a point which is again an element of that space. Hence the metric space is, in a sense, "complete."  


==Formal definition==
==Formal definition==
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* Any [[compact space|compact]] metric space is [[sequentially compact space|sequentially compact]] and hence complete.  The converse does not hold: for example, '''R''' is complete but not compact.
* Any [[compact space|compact]] metric space is [[sequentially compact space|sequentially compact]] and hence complete.  The converse does not hold: for example, '''R''' is complete but not compact.
* In a space with the discrete metric, the only Cauchy sequences are those which are constant from some point on.  Hence any discrete metric space is complete.
* In a space with the discrete metric, the only Cauchy sequences are those which are constant from some point on.  Hence any discrete metric space is complete.
* The rational numbers '''Q''' are ''not'' complete.  For example, the sequence (''x''<sub>''n''</sub>) defined by ''x''<sub>0</sub> = 1, ''x''<sub>''n''+1</sub> = 1 + 1/''x''<sub>''n''</sub> is Cauchy, but does not converge in '''Q'''.


==Completion==
==Completion==
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==See also==
==See also==
* [[Banach space]]
* [[Banach space]]
* [[Hilbert space]]
* [[Hilbert space]][[Category:Suggestion Bot Tag]]

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In mathematics, a complete metric space is a metric space in which every Cauchy sequence in that space is convergent. In other words, every Cauchy sequence in the metric space tends in the limit to a point which is again an element of that space. Hence the metric space is, in a sense, "complete."

Formal definition

Let X be a metric space with metric d. Then X is complete if for every Cauchy sequence there is an associated element such that .

Examples

  • The real numbers R, and more generally finite-dimensional Euclidean spaces, with the usual metric are complete.
  • Any compact metric space is sequentially compact and hence complete. The converse does not hold: for example, R is complete but not compact.
  • In a space with the discrete metric, the only Cauchy sequences are those which are constant from some point on. Hence any discrete metric space is complete.
  • The rational numbers Q are not complete. For example, the sequence (xn) defined by x0 = 1, xn+1 = 1 + 1/xn is Cauchy, but does not converge in Q.

Completion

Every metric space X has a completion which is a complete metric space in which X is isometrically embedded as a dense subspace. The completion has a universal property.

Examples

  • The real numbers R are the completion of the rational numbers Q with respect to the usual metric of absolute distance.

Topologically complete space

Completeness is not a topological property: it is possible for a complete metric space to be homeomorphic to a metric space which is not complete. For example, the map

is a homeomorphism between the complete metric space R and the incomplete space which is the unit circle in the Euclidean plane with the point (0,-1) deleted. The latter space is not complete as the non-Cauchy sequence corresponding to t=n as n runs through the positive integers is mapped to a non-convergent Cauchy sequence on the circle.

We can define a topological space to be metrically topologically complete if it is homeomorphic to a complete metric space. A topological condition for this property is that the space be metrizable and an absolute Gδ, that is, a Gδ in every topological space in which it can be embedded.

See also