Kepler–Bouwkamp constant: Difference between revisions

In mathematics, the Lévy–Prokhorov metric (sometimes known just as the Prokhorov metric) is a metric (i.e., a definition of distance) on the collection of probability measures on a given metric space. It is named after the French mathematician Paul Lévy and the Soviet mathematician Yuri Vasilevich Prokhorov; Prokhorov introduced it in 1956 as a generalization of the earlier Lévy metric.

Definition

Let ${\displaystyle (M,d)}$ be a metric space with its Borel sigma algebra ${\displaystyle \mathcal{ℬ}(M)}$. Let ${\displaystyle \mathcal{𝒫}(M)}$ denote the collection of all probability measures on the measurable space ${\displaystyle (M,\mathcal{ℬ}(M))}$.

For a subset ${\displaystyle A\subseteq M}$, define the ε-neighborhood of ${\displaystyle A}$ by

${\displaystyle A^{\epsilon }:=\{p\in M|\mathrm{\exists }q\in A,d(p,q)<\epsilon \}=\bigcup _{p\in A}{B}_{\epsilon }(p).}$

where ${\displaystyle B_{\epsilon }(p)}$ is the open ball of radius ${\displaystyle \epsilon }$ centered at ${\displaystyle p}$.

The Lévy–Prokhorov metric ${\displaystyle \pi :\mathcal{𝒫}(M{)}^2\to [0,+\mathrm{\infty })}$ is defined by setting the distance between two probability measures ${\displaystyle \mu }$ and ${\displaystyle \nu }$ to be

${\displaystyle \pi (\mu ,\nu ):=\inf \{\epsilon >0|\mu (A)\le \nu (A^{\epsilon })+\epsilon \text{and}\nu (A)\le \mu (A^{\epsilon })+\epsilon \text{for all}A\in \mathcal{ℬ}(M)\}.}$

For probability measures clearly ${\displaystyle \pi (\mu ,\nu )\le 1}$.

Some authors omit one of the two inequalities or choose only open or closed ${\displaystyle A}$; either inequality implies the other, but restricting to open/closed sets changes the metric so defined.

Properties

• If ${\displaystyle (M,d)}$ is separable, convergence of measures in the Lévy–Prokhorov metric is equivalent to weak convergence of measures. Thus, ${\displaystyle \pi }$ is a metrization of the topology of weak convergence.
• The metric space ${\displaystyle (\mathcal{𝒫}(M),\pi )}$ is separable if and only if ${\displaystyle (M,d)}$ is separable.
• If ${\displaystyle (\mathcal{𝒫}(M),\pi )}$ is complete then ${\displaystyle (M,d)}$ is complete. If all the measures in ${\displaystyle \mathcal{𝒫}(M)}$ have separable support, then the converse implication also holds: if ${\displaystyle (M,d)}$ is complete then ${\displaystyle (\mathcal{𝒫}(M),\pi )}$ is complete.
• If ${\displaystyle (M,d)}$ is separable and complete, a subset ${\displaystyle \mathcal{𝒦}\subseteq \mathcal{𝒫}(M)}$ is relatively compact if and only if its ${\displaystyle \pi }$-closure is ${\displaystyle \pi }$-compact.

See also

• Lévy metric
• Wasserstein metric

References

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