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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How do I show that some metric $d$ on the set $\text{I}(\mathbb{R}^n)$ gives the usual metric on $\mathbb{R}^n$?

The problem from "Notes on Geometry" by Rees: On the subset of $\text{I}(\mathbb{R}^n)$ (The set of all isometries of $\mathbb{R}^n$) consisting of all the translations, show that $d$ gives the usual metric on $\mathbb{R}^n$. It didn't mention…
john
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$d$ is a metric on $X$ if $d(a,b) = 0 ⇔ a = b$ and $d(a, b) ≤ d(z, a) + d(z, b)$

The following is a question of Metric Spaces by O'Searcoid (pg 19) Suppose $X$ is a set and $d:X×X→\mathbb{R}$. Show that $d$ is a metric on $X$ if, and only if, for all $a,b,z ∈ X$, the two conditions $d(a,b) = 0 ⇔ a = b$ and $d(a, b) ≤ d(z, a) +…
GovEcon
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How to define a incomplete metric on $\mathbb{S}^1$?

Let $\mathbb{S}^1=\{x\in\mathbb{R}^2:\ \|x\|_2=1\}$. My question is: Is it possible to define a incomplete metric on $\mathbb{S}^1$, i.e. a metric such that $\mathbb{S}^1$ is not complete. Thank you.
Tomás
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Can a metric signature also be [ - - + ++,....]?

So the minkowski metric is -,+,+,+. I was wondering if you can have more combinations of + and -. How would these spaces behave and is there anything interesting to say about them? I cannot really imagine what happens with these kind of metrics. I…
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Can we visualize shortest paths in $L_\infty$ space?

There are a number of demonstrations of rendering in hyperbolic or spherical geometry (See here for example). Is there any way to do something similar such that light travels on the $L_\infty$ shortest path? I'm asking, since I was doing some…
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Show that a subset of $C[0,1]$ is closed

I have a question I my metric spaces course book I cannot solve: Show that the following subset is closed in $C[0,1]$: $\{ f \in C[0,1] \mid f(a)=0 \textrm{ for all }a \in A \}$, where $C[0,1]$ is the space of continuous real-valued functions on…
Pim
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proofs, show that $S$ is complete, if and only if $S$ is closed in $X$, is correct?

Prove the following statement with a counterexample: if $E$ is a compact metric space and $K$ is a closed subset of $E$ then $K$ is compact. demonstration. If we take a sequence $x_n$ of elements of $K$, since $E$ is compact, there must be a…
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Open Spheres on metrics $d$ and $\rho$

Let $(M,d)$ be a metric space and $\rho = d/(1+d)$. $A$ is a subset of $M$. Show that: If $A$ is an open sphere in $(M,d)$ then $A$ is an open sphere on $(M,\rho)$. My approach: I used the fact that if we have metrics with equivalent topologies…
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Show that $B\subseteq \operatorname{cl}(A\cap B)$

Q. $B$ is an open set in $X$ and $A$ is everywhere dense in $X$. Show that $B\subseteq \operatorname{cl}(A\cap B)$. My approach: Should be suffice to say that if $(A\cap B)$ is dense in $B$ then the proof is easily done. Although I am not sure how…
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In other metric spaces, are "line segments" "different"?

I am in the beginning of a topology course. We've seen a bit of metric spaces and we've seen that depending on the metric function, the circles change: I am a bit curious about the following: Do line segments change too? In "common geometry", a…
Red Banana
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Is the $\varepsilon$-neighborhood of an open ball another open ball in general metric spaces?

Let $(X,d)$ be a general metric space. Let $B=B(x,r)$ be the open ball with center $x$ and radius $r$. Let $B^{\varepsilon} := \{y \in X : d(y,B) = \inf_{z \in B} d(y,z) < \varepsilon\}$ be its $\varepsilon$-neighborhood. Is it true that…
Kaitei
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Is there a metric space $(X,d)$, a compact set $K\subset X$ and a point $x \in X$ such that the distance $d(x,K)$ is NOT achieved on the boundary?

Here, I'm defining $d(x,K) = \inf_{z\in K} d(x,z)$. Since $d$ is continuous and $K$ compact, them there is a point $z\in K$ such that $d(x,K) = d(x,z)$. I know that if $(X,d)$ have the structure of a Length Space with $d$ intrinsic to the length…
Kaitei
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Convergence of a Set?

Let $x_n \to x$ in Metric Space $(X,d)$ and A is a subset of X. Show that $d(x_n,A) \to d(x,A)$. I have used the generalized triangle inequality using an element $a$ of A. How do I show that the infimums of over all $a$ belonging to A would satisfy…
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Metric Space Question Structure Problem

Que.) $\{x ∈ :( \;, y)≤ r\}$ defined in metric space is known as ___________ ball. Hey guys, i had given an exam recently and this was the question i have to attempt.... I know this question answer, but I want to know only that "is this question…
Drasto
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Is $id:(C[0, 1], d_1) \to (C[0, 1], d_2)$ homeomorphism? Yes/No

Let $(C[0, 1], d_1)$ and $(C[0, 1], d_2)$ be the metric spaces where $$d_1(f, g) = \sup_{x∈[0,1]} |f(x) − g(x)|\\ d_2(f, g) =\int_{0}^{1}|f(x) − g(x)|dx \,$$ Is $id:(C[0, 1], d_1) \to (C[0, 1], d_2)$ homeomorphism? My attempt : I think No. For…
jasmine
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