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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To show that $∂C = C$ where $C$ denote the collection of constant functions in $F$.

Consider the set $F$ of functions from $[0 , 1]$ to $[0 , 1]$ with the metric $(f, g) → sup${$|f(x) − g(x)| x ∈ [0 , 1]$}. Let $C$ denote the collection of constant functions in $F$. Show that $∂C = C$. To show that $∂C = C$ we have to show $∂C…
User8976
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closure of the unit ball

Is the closure of the unit ball of $C^1[0,1]$ in $C[0,1]$ compact? For this let us take a sequence $x_n$ in $C^1[0,1]$ to show it has a convergent subseqence How to proceed with this.I am not so sure whether it is the way to ask a question here
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What condition is needed on $S$ and $T$ such that $C(S,T)$ be compact.

If $C(T,S)$ is the set of all continuos function between $T$ and $S$ metric spaces and $S$ compact with the uniform metric. What conditions are needed on $T$ and $S$ such that $C(T,S)$ be compact? This is related with…
EQJ
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Proof that any finite subset of a metric space is closed

I have a metric space $(X, d)$ and I am trying to prove that any finite subset $F = \{x_1,\ldots,x_n\} $ of $X$ is closed. What I have by now is a proof that a subset $F$ of a metric space $X$ is closed if and only if it contains all of its…
Jim
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Which of the following spaces are complete

Is the following space complete? $X_1=\left(0,\dfrac{\pi}{2}\right)$ defined by $d (x,y)=|\tan x-\tan y \ |$ Let $x_n$ be a Cauchy sequence in $X$ then, we will have $n,m\in \mathbb N$ such that $d(x_n,x_m)<\epsilon$ for any arbitrary…
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Need help in metric spaces proving this statement!

Please if someone could help me prove this rather annoying statement. Let $C(0,1)$ be the set of continuous functions on the open interval $(0,1) \subset \mathbb R$. Fro any two functions $x(t), y(t) \in C(0,1)$ define the set $E(x,y)=\{t \in (0,1)…
adoion
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$d,e$ be metrices on $X$ , under what condition(s) the function $g:X \times X \to \mathbb R $ , $g(x,y):=\min \{d(x,y),e(x,y)\}$ , is a metric ?

Let $d,e$ be metrices on a set $X$ , then under what condition(s) the function $g:X \times X \to \mathbb R $ defined by $g(x,y):=\min \{d(x,y),e(x,y)\}$ , is a metric ?
Souvik Dey
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Under what condition(s) is the set of all isolated point in a 2nd countable metric space is empty?

In what condition the set of all isolated point in a 2nd countable metric space is empty? $NOTE :-$ Sir Brian Scott's answer is ok , but I would like an answer of this edited form , Thanks in advance
Souvik Dey
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Open sets in Metric spaces

I need to show that if {x} is open in a metric space X for all x in X,then all subsets of X are open in X I am using the definition that a set A is open if ∀a∈A,∃r>0 s.t. Br(a)⊆A. I tried proving this by induction, by adding points to the set and…
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Ceiling of a metric is a metric

Suppose $d$ is a metric on the set $X$. For $x$, $y \in X$ define the function $c$ by $c(x,y) = \lceil d(x,y) \rceil$. Show that $c$ is a metric on $X$. (The reason I put the question here is because I was wondering if it was possible to…
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Is the set of all $n\times n$ matrices with determinant $1$ an open subset of $M(n,\mathbb R)$?

Is the set of all $n\times n$ matrices with determinant $1$ an open ,dense connected subset of $M(n,\mathbb R) $ i.e set of all matrices over $\mathbb R$? I know it will be a closed subset of $M(n,\mathbb R)$,not bounded and hence not compact.But…
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Finding open balls in $\mathbb{R}^2$

Consider the set $U = \{(x, y) \in \mathbb R^2: y > 0\}$. Working in the metric space $(\mathbb R^2, d_E)$, find open balls $B_1, B_2, B_3,\ldots$ with $U = \bigcup_{i \in \mathbb{N}} B_i$. Then explain why it is not possible to do this for the set…
Sean
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Minimal conditions for $\widetilde{d}$ to be metric

Let $(X,d)$ be an arbitrary metric space and $f:[0,\infty) \rightarrow [0,\infty)$ What are the minimal conditions for function $f$ in order $\widetilde{d} = f \circ d: X \times X \rightarrow [0,\infty) $ be also metric on $X$? Do we need to prove…
John Lennon
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Total boundedness, an equivalent expression

I'm trying to show that a metric space $(X,d)$ is totally bounded iff every sequence in $X$ has a Cauchy sub-sequence. This is a point that rose up the other day in another topic and it seemed like very nice thing to know. The definition of total…
T. Eskin
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is the set of matrices with trace equal equal to zero compact

Is it true that the set of all matrices with trace equal to zero a connected and compact subset of the 2*2 matrices over R?
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