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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what is the meaning of the "closure of a sequence "

Suppose $X$ is a metric space, $z$ is in $X$ and $(x_n)$ is a sequence in $X$. Then what does it mean to say that, $z$ is in the "closure of every tail of $(x_n)$." What does "closure" of every tail, mean ?
johny
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Is there a generalized metric, with these following properties?

I have come to know from Wikipedia article about what are called generalized metrics, and that they differ from the regular metric definition in terms of the properties/requirements they have to satisfy. Hence I'd like to know if there is any metric…
Rajesh D
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Completeness of uniform metric

Let $C[0,1]$ be the set of continuous real valued functions on $C[0,1]$. Show that $(C[0,1],\rho_\infty)$ is complete. Is $(C[0,1],\rho_1)$ complete? Justify your answer.…
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Special Metric on the set of intervals

Let $X=\{[a,b]\ a,b \in R$ and $a0 : [a,b]\subseteq [c-\epsilon, d+\epsilon] \ \text{and} \ [c,d]\subseteq…
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When is $(f(x),d)$ a complete metric space?

$(X,d)$ is a complete metric space with a metric $d(x,y)=|x-y|$. $f$ is a continuous function. What condition f should satisfy such that $(f(x),d)$ is a complete metric space? I think $f$ is a uniformly continuous, but I don't know whether it is…
user40144
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Total boundedness of a closed ball in a metric space

Let $(X, d)$ be a metric space. Question: Is the closed ball of radius $r > 0$ centered at some $x \in X$, i.e., $\overline{B_r(x)} \subseteq X$ totally bounded? By definition, a set $V \subseteq X$ is totally bounded if for any $\epsilon > 0$,…
3m115
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Different ways to find the distance between a set and a point.

Let $M$ be a metric space with the metric $d$, $X$ a subset of $M$, and $r>0$. Also, $B(x;r)$ is the open ball centered at $x$ with radius $r$. Defining $\begin{equation*}\begin{aligned} B(X;r)=\bigcup_{x \in X}B(x;r), d(a,X)= \underset{x \in…
Marcelo
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What does the following notion mean in terms of metric spaces?

So let (X,d) be a metric space and A $\subset$ X. We have a metric space (A,$D_A$). What does the following notation mean ? $cl_A(B)$ I think it means the closure of B with respect to the set A, i.e its the closure of B in the metric space (X,d)…
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Please help me understand how a modified metric in the complex plane affects whether sets or open or closed.

Let $A = \{a+bi \in \mathbb{C} : a > 4\}$ and $B = \{ a+bi \in \mathbb{C} : a \geq 4\}$ and let $d(z,w)$ be the metric on $\mathbb{C}$ defined as, $$d(z,w) = \begin{cases} 0 &, \mathrm{if}\, z =w\\ |z| +|w| &, \mathrm{if}\, z\neq w \end{cases}$$ My…
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How does a metric space affect whether a subset is closed or not closed?

With respect to the usual metric of C this $${z \in C: 1< |z| <= 2}$$ is not closed, however with another metric such as $$d(z,w)$$ where $$d(z,w) = 0,z=w$$ and $$d(z,w) = |z| +|w|, z\neq w$$ this subset is closed? Can someone please explain why?
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Is this set $A$ open?

I have the set $A =$ {$z \in \mathbb C: z = x + 0i = x, x \in \mathbb R$}. Is this set open in the complex plane? The set $A$ contains all the points on the real axis in the complex plane. This set is open if $A$ contains all of its interior points,…
adisnjo
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$\lvert d(x,a)-d(x,b)\rvert_{\infty}=d(a,b)$

Here $\lvert d(x,a)-d(x,b)\rvert_{\infty}=\sup_{x\in X}\lvert d(x,a)-d(x,b)\rvert$ is the supremum norm, $d$ is a metric and $a, b\in X$. I'm stuck on showing the equality in the title. I can get the direction $$ \lvert…
user1249408
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Do the set of distances between points need to be bounded for its diameter to be defined?

From Baby Rudin: Let $E$ be a non-empty subset of metric space $X$ and let $S = \{ d(x,y) | x,y \in E \} $ Then the diamater of $E$ is the least upper bound of $S$. Question: Don't we need that the set $S$ be bounded above in order for its supremum…
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Modeling through metric spaces: I lose information due to the non-negative requirement of the distance function. Any workaround?

As an exercise, I am considering a real-world example and I am thinking if I can model it through metric spaces, but apparently it is not possible (or I may be very wrong in my reasoning). Say that I have a bunch of cities and I measure the CO2…
Barzi2001
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I want to prove that If every infinite set has a cluster point, then every sequence has a convergent subsequence

I want to prove this from the theorem from Characterization of Compact metric spaces. I don't know how to go about with it. Should I prove that if every infinite set has a cluster point then every sequence is bounded? Then I'll be able to prove it…