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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Interior, boundary, and closure of a set in the discrete metric on $\Bbb{R}$

In the discrete metric on $\Bbb{R}$ , find the interior, boundary, and closure of $(1,2]$. I know that in the discrete metric, all singletons are open and closed sets, and all subsets are both open and closed. I have that: Interior: {2} Boundary:…
kt046172
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Interior, boundary, and closure of sets.

In the usual metric on $ \Bbb{R} $ , find the interior, boundary, and closure of the following sets: $A = (1,2]$ $B = \Bbb{N}$ $C = \Bbb{Q}$ For $A, I$ got the interior to be $(1,2)$, and the closure to be $[1,2]$. I am unsure how to express the…
kt046172
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Distance from an element to a subset

Given a metric space $(X,d)$, an element $x_0 \in X$ an a non-empty subset $A \subset X$, we define the distance from $x_0$ to $A$ as $$d(x_0,A) := \inf\{d(x_0,a) : a \in A\}.$$ Now, in $\mathbb{R}$ with the usual distance we have $A := (1,2]$ and…
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What are the interior points of this set $A=\{(x_n)\in \ell_2 \mid |x_n|<\frac1n, n=1,2,3\ldots\}$?

What are the interior points of this set $A=\{(x_n)\in \ell_2 \mid |x_n|<\frac1n, n=1,2,3\ldots\}$? I know for one that $0=(0,0,\dots) \in A$ is not an interior point. because if $\exists \epsilon>0$ such that $B_{\epsilon}(0) \subseteq A$ then I…
chesslad
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Is $c_{00} $ open or closed in $\ell^\infty$

Is $c_{00} $ open or closed in $\ell^\infty$ My professor gave the following definition for $c_{00}$ $$c_{00} = \{(x_n)_{n\geq 1} | x_i \neq 0 \;\text{for only finitely many values of i}\}$$ from which I made my own inference that $$c_{00}= \{(x_n)…
chesslad
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How does the metric space impact the property of subset?

The question is: let $\mathbb{Z}^+$ be the set of positive integers and let d be the metric on $\mathbb{Z}^+$ defined by $d(m, n) = \begin{cases} 0\text{ if }m = n\\ 1 \text{ if } m \neq n \end{cases}$ for all $m, n \in \mathbb{Z}^+$. Which of the…
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How should I understand this explanation that $\mathbb{Q}$ and $\mathbb{N}$ aren't homeomorphic subspaces of $\mathbb{R}$

The definition of open sets I'm working with (from the Napkin) is: A set $U \subseteq M $ is open if for all $p \in U$, some $r$-neighborhood ($r > 0$) exists in $U$. The question I'm trying to solve is this: Are $\mathbb{Q}$ and $\mathbb{N}$…
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True/false : The Space of all continiuos real valued functions with compact support with supnorm metric is complete .

Is the followimg statement is True/false The Space of all continiuos real valued functions with compact support with supnorm metric is complete . (True/false) i have found the answer here : are they complete metric spaces? Now my confusion…
jasmine
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Incomplete metric on $\mathbb{N}$, set of Natural Number

$\mathbb{N}$ is complete with respect to usual metric. But if I define $d(x, y) =|\frac{1}{x} - \frac{1}{y}|$ then $\mathbb{N}$ is incomplete. How to show this? It is quite interesting. I thought about a cauchy sequence which is not convergent…
Pradip
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$1.)$ Is $d(A) = d( \bar A)$ ? $2.)$ Is $d(A) = d(A^{o})$?

let $(X,d)$ be a metric space . Let $A \subset X$ be bounded $1.)$ Is $d(A) = d( \bar A)$ ? $2.)$ Is $d(A) = d(A^{o})$ ? Note : Here $\bar A$ denotes closure of A and $A^{o}$ denotes the interior of $A$ My attempt : If i take $A= [0,1]$ or…
jasmine
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Can $ \ \ \sup_{x \in X} \inf_{y \in Y} \ d(x,y) \neq 0$?

Let $X, \ Y$ be two non-empty subset of a metric space $ (M,d)$ such that $X \subset Y$. My question is- Can $ \ \ \sup_{x \in X} \inf_{y \in Y} \ d(x,y) \neq 0$ ? My calculation shows that always $ \ \ \sup_{x \in X} \inf_{y \in Y} \ d(x,y) = 0$
MAS
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Do convergence under a metric implies convergence under another metric in the same space?

This question is related to this post Let $(E,d)$ be a metric space and consider the subsets $A,B$ where $A$ is compact and $B$ is closed. Suppose $dist(A,B):=inf_{x\in A, y\in B} d(x,y)=0$. Then I found that there are sequence $\{a_n\}\subseteq A$…
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Show that $d$ is a well-defined norm

The question reads as follows; $$\text{Let } X \text{ be the subset of } \mathbb R^\omega \text{ consisting of all sequences } (x_1, x_2,\dots) \text{ such that } \sum_{i=1}^\infty x_i^2 \text{ converges. Show that }…
hampster
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Proof that a function is a b-metric

I'm trying to prove that this function is a b-metric. I can't prove the triangle inequality. Here's the definition of a b-metric space.bmetric definition. Here's the example. I wanna prove the last inequality.example Any idea would be helpful. My…
ursuv2
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Is this exotic function actually a metric?

I've got this pretty exotic metric of which I cannot seem to prove the triangle inequality. Given that I already have a metric $\delta$ on the unit ball in $\mathbb{R}^n$, I define a new metric $d(x,y)$ to be zero whenever $x=y$ and…
Werner
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