Questions tagged [metric-spaces]

Metric spaces are sets on which a metric is defined. A metric is a generalization of the concept of "distance" in the Euclidean sense. Metric spaces arise as a special case of the more general notion of a topological space. For questions about Riemannian metrics use the tag (riemannian-geometry) instead.

A function $d: M\times M\to \mathbb R$ is called a metric if for all $x,y,z \in M$ we have

  1. $d(x,y)=0\iff x=y$
  2. $d(x,y)\geq 0$
  3. $d(x,y)=d(y,x)$
  4. $d(x,y)+d(y,z)\geq d(x,z)$.

It is a generalisation of "distance". A metric space is now defined as an ordered pair $(M,d)$, where $M$ is a set and $d:M\times M\to R$ is a metric.

An $\varepsilon$-neighbourhood of $x$ is defined as the set $$B_\epsilon(x):=\{y\in M\mid d(x,y)<\varepsilon\}.$$ $B_\varepsilon(x)$ is commonly also known as the open ball of radius $\varepsilon$ around $x$. All open balls form a base for a topology on $M$. Although all metric spaces are topological spaces, the converse is generally not true.

Some different types of metric space include

  1. Complete metric spaces (every Cauchy sequence converges)

  2. Bounded metric spaces (every metric is bounded by a finite value)

  3. Compact metric spaces (every sequence has a convergent subsequence)

  4. Locally compact metric spaces (every point has a compact neighbourhood)

  5. Separable metric spaces (it possesses a countable dense subset).

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Show that $\mathcal{G}$ generates $\mathcal{B}_X$, the Borel $\sigma$-algebra of $X$.

Let $X$ be a second countable metrizable space and $\mathcal{G}$ a subbase for the topology of $X$. Show that $\mathcal{G}$ generates $\mathcal{B}_X$, the Borel $\sigma$-algebra of $X$. Also show that this need not be true. How to show that…
Idonknow
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Proving that a subset endowed with the discrete metric is both open and closed - choice of radius of the ball around a point

My question is related to proving that any subset $D \subset X$, where $(X,d)$ is a metric space with $d$ being the discrete metric, is both open and closed. I've read some suggestions to a solution, such as the accepted answer from this question:…
harisf
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What does it mean for a number to be "larger" than another number?

In everyday life we have a clear notion of what it means for something to be larger than something else. Usually we would evaluate something's size based on it's volume. However, is there a formal method for extending this everyday notion of size to…
Zach L
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Examples of uniformly discrete proper metric spaces which are not countable.

By uniformly discrete I mean there exists a $C > 0$ such that for all $x \neq y$ we have $d(x, y) \geq C$. By proper I mean the preimage of every closed ball is compact. Are there any examples of such spaces which are uncountable?
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how to prove the sequence based definition of a closure in metric spaces

Let $A$ be a subset of a metric space $\Omega$. By definition, the closure of $A$ is the smallest closed set that contains $A$. How to prove that alternativelly, the closure is given by (1): $\bar A = \{a_* \vert a_* = \lim_{n\rightarrow\infty} a_n;…
zorank
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A question on metric spaces which does not have Lebesgue covering property

Let $X$ be a metric space , $\{U_{\alpha}\}$ be an open cover of $X$ which has no Lebesgue number . So for every $r>0 $ , there is an open ball of radius $r$ which is not contained in any open set of the open cover , in particular , for every $n>1…
user228168
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Proving that the ball is converx

I need to prove that the ball $B(x,r)=\{y\in \mathbb{R^n}:||y-x||
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Some questions about écarts

An écart for a set $X$ is a non-negative real-valued function $e:X\times X\rightarrow \mathbb{R}$ such that $e(x,y)=0$ if and only if $x=y$; for each positive number $s$ there is a positive number $r$ such that $e(x,z)
Jay
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Show that $D(A,B):=\inf\{r:A\subseteq N_r(B) \text{and}B\subseteq N_r(A)\}$ is a metric on bounded closed subsets of $X$.

Let $A,B$ be non empty bounded closed subsets of metric space $(X,d)$, define $D(A,B):=\inf\{r:A\subseteq N_r(B) \text{and}B\subseteq N_r(A)\}$. Show that $D$ is a metric on bounded closed subsets of $X$. I have proved all necessary conditions…
JSCB
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How to prove the triangle inequality for this distance?

I'm studying a proof in 'An Introduction to Metric Spaces and Fixed Point Theory' (M. Khamsi, W. Kirk) that shows the equivalence of injectiveness and hyperconvexity for metric spaces. I stumbled over the following part of the proof. Let $(X, d)$ be…
Jeroen
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Closed set and set, closed in $\mathfrak M$

I've read in my textbook that a set $A$ is called closed if it contains its limit points, i.e. $A'\subseteq A$. But then, coming to next chapter, I came across a term of set $B$, closed in metric space $\mathfrak M$ (or in its set? this was not…
Ruslan
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$T$ is a linear operator

Define $T: l^2 \mapsto l^2$ by $(Tx)_i = \frac{x_i}i \; \forall i=1,\ldots,n\ldots$. Prove that $T$ is a linear operator with $\|T\|=1$.
Muneeb
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To show that $f$ has a fixed point, that is, there exists $x_0 \in X$ such that $f (x_0) = x_o$.

Let $(X, d)$ be a compact metric space. Let $f : X \to X$ be such that $d(f (x), f (y)) < d(x, y)$ for all $x, y \in X$ with $x \neq y$. To show that $f$ has a fixed point, that is, there exists $x_0 \in X$ such that $f (x_0) = x_o$. Finding it…
User8976
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Sets where Heine-Borel theorem works

Possible Duplicate: Are there more general spaces than Euclidean spaces to have the Heine–Borel property? By Heine-Borel theorem, a closed and bounded subset of the Euclidean space is compact. If we analyze the proof, the only characteristic of…
joh
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Show that in a Normed linear Space $X,\overline {B(x,r)}=B[x,r]$

Show that in a Normed linear Space $X,\overline {B(x,r)}=B[x,r]$ where $\overline {B(x,r)}$ is closure of the set $\{y\in X:||y-x||
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