Difference between revisions of "Metric"
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2) In the space $\mathbb R^n$ various metrics are possible, among them are: | 2) In the space $\mathbb R^n$ various metrics are possible, among them are: | ||
+ | \begin{equation} | ||
+ | \rho(x,y) = \sqrt{\sum(x_i-y_i)^2}; | ||
+ | \end{equation} | ||
+ | \begin{equation} | ||
+ | \rho(x,y)=\sup\limits_i|x_i-y_i|; | ||
+ | \end{equation} | ||
+ | \begin{equation} | ||
+ | \rho(x,y)=\sum|x_i-y_i|; | ||
+ | \end{equation} | ||
− | + | here $\{x_i\}, \{y_i\} \in \mathbb{R}^n$. | |
− | |||
− | |||
− | |||
− | |||
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− | here | ||
3) In a Riemannian space a metric is defined by a [[Metric tensor|metric tensor]], or a quadratic differential form (in some sense, this is an analogue of the first metric of example 2)). For a generalization of metrics of this type see [[Finsler space|Finsler space]]. | 3) In a Riemannian space a metric is defined by a [[Metric tensor|metric tensor]], or a quadratic differential form (in some sense, this is an analogue of the first metric of example 2)). For a generalization of metrics of this type see [[Finsler space|Finsler space]]. | ||
− | 4) In function spaces on a (countably) compact space | + | 4) In function spaces on a (countably) compact space $X$ there are also various metrics; for example, the uniform metric |
− | + | \begin{equation} | |
− | + | \rho(f,g)=\sup\limits_{x\in X}|f(x)-g(x)| | |
+ | \end{equation} | ||
(an analogue of the second metric of example 2)), and the integral metric | (an analogue of the second metric of example 2)), and the integral metric | ||
+ | \begin{equation} | ||
+ | \rho(f,g)=\int\limits_X|f-g|\, dx. | ||
+ | \end{equation} | ||
− | + | 5) In normed spaces over $\mathbb R$ a metric is defined by the norm $\|\cdot\|$: | |
− | + | \begin{equation} | |
− | 5) In normed spaces over | + | \rho(x,y) = \|x-y\|. |
− | + | \end{equation} | |
− | |||
6) In the space of closed subsets of a metric space there is the [[Hausdorff metric|Hausdorff metric]]. | 6) In the space of closed subsets of a metric space there is the [[Hausdorff metric|Hausdorff metric]]. | ||
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If, instead of 1), one requires only: | If, instead of 1), one requires only: | ||
− | 1') | + | 1') $\rho(x,y)=0$ if $x=y$ (so that from $\rho(x,y)=0$ it does not always follows that $x=y$), the function $\rho$ is called a [[Pseudo-metric | pseudo-metric]] [[#References|[2]]], [[#References|[3]]], or finite écart [[#References|[4]]]. |
− | A metric (and even a pseudo-metric) makes the definition of a number of additional structures on the set | + | A metric (and even a pseudo-metric) makes the definition of a number of additional structures on the set $X$ possible. First of all a topology (see [[Topological space|Topological space]]), and in addition a uniformity (see [[Uniform space|Uniform space]]) or a proximity (see [[Proximity space|Proximity space]]) structure. The term metric is also used to denote more general notions which do not have all the properties 1)–3); such are, for example, an [[Indefinite metric|indefinite metric]], a [[Symmetry on a set|symmetry on a set]], etc. |
====References==== | ====References==== | ||
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====Comments==== | ====Comments==== | ||
− | Potentially, any metric space | + | Potentially, any metric space $(X,\rho)$ has a second metric $\sigma \geq \rho$ naturally associated: the intrinsic or [[Internal metric|internal metric]]. Potentially, because the definition may give $\sigma(x,y)=\infty$ for some pairs of points $x, y$. One defines the length (which may be $\infty$) of a continuous path $f:[0,1]\to X$ by $L(f)=\lim\limits_{\epsilon\to 0}\sup L_{\epsilon}(f)$, where $L_{\epsilon}(f)$ is the infimum of all finite sums $\sum \rho(x_i,x_{i+1})$ with $\{x_i\}$ a finite subset of $[0,1]$ which is an $\epsilon$-net (cf. [[Metric space|Metric space]]) and is listed in the natural order. Then $\sigma(x,y)$ is the infimum of the lengths of paths $f$ with $f(0)=x$, $f(1)=y$, but $\sigma(x,y)=\infty$ if there is no such path of finite length. |
− | No reasonable topological restriction on | + | No reasonable topological restriction on $(X,\rho)$ suffices to guarantee that the intrinsic "metric" (or écart) $\sigma$ will be finite-valued. If $\sigma$ is finite-valued, suitable compactness conditions will assure that minimum-length paths, i.e. paths from $x$ to $y$ of length $\sigma(x,y)$, exist. When every pair of points $x, y$ is joined by a path (non-unique, in general) of length $\sigma(x,y)$, the metric is often called convex. (This is much weaker than the surface theorists' [[Convex metric|convex metric]].) The main theorem in this area is that every locally connected metric [[Continuum|continuum]] admits a convex metric [[#References|[a1]]], [[#References|[a2]]]. |
====References==== | ====References==== | ||
<table><TR><TD valign="top">[a1]</TD> <TD valign="top"> R.H. Bing, "Partitioning a set" ''Bull. Amer. Math. Soc.'' , '''55''' (1949) pp. 1101–1110</TD></TR><TR><TD valign="top">[a2]</TD> <TD valign="top"> E.E. Moïse, "Grille decomposition and convexification" ''Bull. Amer. Math. Soc.'' , '''55''' (1949) pp. 1111–1121</TD></TR></table> | <table><TR><TD valign="top">[a1]</TD> <TD valign="top"> R.H. Bing, "Partitioning a set" ''Bull. Amer. Math. Soc.'' , '''55''' (1949) pp. 1101–1110</TD></TR><TR><TD valign="top">[a2]</TD> <TD valign="top"> E.E. Moïse, "Grille decomposition and convexification" ''Bull. Amer. Math. Soc.'' , '''55''' (1949) pp. 1111–1121</TD></TR></table> |
Revision as of 08:20, 9 February 2013
distance on a set $X$
A function $\rho$ with non-negative real values, defined on the Cartesian product $X\times X$ and satisfying for any $x, y\in X$ the conditions:
1) $\rho(x,y)=0$ if and only if $x = y$ (the identity axiom);
2) $\rho(x,y) + \rho(y,z) \geq \rho(x,z)$ (the triangle axiom);
3) $\rho(x,y) = \rho(y,x)$ (the symmetry axiom).
A set $X$ on which it is possible to introduce a metric is called metrizable (cf. Metrizable space). A set $X$ provided with a metric is called a metric space.
Examples.
1) On any set there is the discrete metric \begin{equation} \rho(x,y) = 0 \text{ if } x=y \quad \text{and} \quad \rho(x,y) = 1 \text{ if } x\ne y. \end{equation}
2) In the space $\mathbb R^n$ various metrics are possible, among them are: \begin{equation} \rho(x,y) = \sqrt{\sum(x_i-y_i)^2}; \end{equation} \begin{equation} \rho(x,y)=\sup\limits_i|x_i-y_i|; \end{equation} \begin{equation} \rho(x,y)=\sum|x_i-y_i|; \end{equation}
here $\{x_i\}, \{y_i\} \in \mathbb{R}^n$.
3) In a Riemannian space a metric is defined by a metric tensor, or a quadratic differential form (in some sense, this is an analogue of the first metric of example 2)). For a generalization of metrics of this type see Finsler space.
4) In function spaces on a (countably) compact space $X$ there are also various metrics; for example, the uniform metric \begin{equation} \rho(f,g)=\sup\limits_{x\in X}|f(x)-g(x)| \end{equation}
(an analogue of the second metric of example 2)), and the integral metric \begin{equation} \rho(f,g)=\int\limits_X|f-g|\, dx. \end{equation}
5) In normed spaces over $\mathbb R$ a metric is defined by the norm $\|\cdot\|$: \begin{equation} \rho(x,y) = \|x-y\|. \end{equation}
6) In the space of closed subsets of a metric space there is the Hausdorff metric.
If, instead of 1), one requires only:
1') $\rho(x,y)=0$ if $x=y$ (so that from $\rho(x,y)=0$ it does not always follows that $x=y$), the function $\rho$ is called a pseudo-metric [2], [3], or finite écart [4].
A metric (and even a pseudo-metric) makes the definition of a number of additional structures on the set $X$ possible. First of all a topology (see Topological space), and in addition a uniformity (see Uniform space) or a proximity (see Proximity space) structure. The term metric is also used to denote more general notions which do not have all the properties 1)–3); such are, for example, an indefinite metric, a symmetry on a set, etc.
References
[1] | P.S. Aleksandrov, "Einführung in die Mengenlehre und die allgemeine Topologie" , Deutsch. Verlag Wissenschaft. (1984) (Translated from Russian) |
[2] | J.L. Kelley, "General topology" , Springer (1975) |
[3] | K. Kuratowski, "Topology" , 1 , PWN & Acad. Press (1966) (Translated from French) |
[4] | N. Bourbaki, "Elements of mathematics. General topology" , Addison-Wesley (1966) (Translated from French) |
Comments
Potentially, any metric space $(X,\rho)$ has a second metric $\sigma \geq \rho$ naturally associated: the intrinsic or internal metric. Potentially, because the definition may give $\sigma(x,y)=\infty$ for some pairs of points $x, y$. One defines the length (which may be $\infty$) of a continuous path $f:[0,1]\to X$ by $L(f)=\lim\limits_{\epsilon\to 0}\sup L_{\epsilon}(f)$, where $L_{\epsilon}(f)$ is the infimum of all finite sums $\sum \rho(x_i,x_{i+1})$ with $\{x_i\}$ a finite subset of $[0,1]$ which is an $\epsilon$-net (cf. Metric space) and is listed in the natural order. Then $\sigma(x,y)$ is the infimum of the lengths of paths $f$ with $f(0)=x$, $f(1)=y$, but $\sigma(x,y)=\infty$ if there is no such path of finite length.
No reasonable topological restriction on $(X,\rho)$ suffices to guarantee that the intrinsic "metric" (or écart) $\sigma$ will be finite-valued. If $\sigma$ is finite-valued, suitable compactness conditions will assure that minimum-length paths, i.e. paths from $x$ to $y$ of length $\sigma(x,y)$, exist. When every pair of points $x, y$ is joined by a path (non-unique, in general) of length $\sigma(x,y)$, the metric is often called convex. (This is much weaker than the surface theorists' convex metric.) The main theorem in this area is that every locally connected metric continuum admits a convex metric [a1], [a2].
References
[a1] | R.H. Bing, "Partitioning a set" Bull. Amer. Math. Soc. , 55 (1949) pp. 1101–1110 |
[a2] | E.E. Moïse, "Grille decomposition and convexification" Bull. Amer. Math. Soc. , 55 (1949) pp. 1111–1121 |
Metric. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Metric&oldid=29409