Statistical distance: Difference between revisions

Content deleted Content added

Inline

Latest revision as of 17:20, 5 March 2024

In statistics, probability theory, and information theory, a statistical distance quantifies the distance between two statistical objects, which can be two random variables, or two probability distributions or samples, or the distance can be between an individual sample point and a population or a wider sample of points.

A distance between populations can be interpreted as measuring the distance between two probability distributions and hence they are essentially measures of distances between probability measures. Where statistical distance measures relate to the differences between random variables, these may have statistical dependence,^[1] and hence these distances are not directly related to measures of distances between probability measures. Again, a measure of distance between random variables may relate to the extent of dependence between them, rather than to their individual values.

Many statistical distance measures are not metrics, and some are not symmetric. Some types of distance measures, which generalize squared distance, are referred to as (statistical) divergences.

Terminology

Many terms are used to refer to various notions of distance; these are often confusingly similar, and may be used inconsistently between authors and over time, either loosely or with precise technical meaning. In addition to "distance", similar terms include deviance, deviation, discrepancy, discrimination, and divergence, as well as others such as contrast function and metric. Terms from information theory include cross entropy, relative entropy, discrimination information, and information gain.

Distances as metrics

Metrics

A metric on a set X is a function (called the distance function or simply distance) d : X × X → R⁺ (where R⁺ is the set of non-negative real numbers). For all x, y, z in X, this function is required to satisfy the following conditions:

d(x, y) ≥ 0 (non-negativity)
d(x, y) = 0 if and only if x = y (identity of indiscernibles. Note that condition 1 and 2 together produce positive definiteness)
d(x, y) = d(y, x) (symmetry)
d(x, z) ≤ d(x, y) + d(y, z) (subadditivity / triangle inequality).

Generalized metrics

Many statistical distances are not metrics, because they lack one or more properties of proper metrics. For example, pseudometrics violate property (2), identity of indiscernibles; quasimetrics violate property (3), symmetry; and semimetrics violate property (4), the triangle inequality. Statistical distances that satisfy (1) and (2) are referred to as divergences.

Statistically close

The total variation distance of two distributions $X$ and $Y$ over a finite domain $D$ , (often referred to as statistical difference^[2] or statistical distance^[3] in cryptography) is defined as

$\Delta (X,Y)={\frac {1}{2}}\sum _{\alpha \in D}|\Pr[X=\alpha ]-\Pr[Y=\alpha ]|$ .

We say that two probability ensembles $\{X_{k}\}_{k\in \mathbb {N} }$ and $\{Y_{k}\}_{k\in \mathbb {N} }$ are statistically close if $\Delta (X_{k},Y_{k})$ is a negligible function in $k$ .

Examples

Metrics

Total variation distance (sometimes just called "the" statistical distance)
Hellinger distance
Lévy–Prokhorov metric
Wasserstein metric: also known as the Kantorovich metric, or earth mover's distance
Mahalanobis distance
Amari distance
Integral probability metrics generalize several metrics or pseudometrics on distributions

Divergences

Kullback–Leibler divergence
Rényi divergence
Jensen–Shannon divergence
Bhattacharyya distance (despite its name it is not a distance, as it violates the triangle inequality)
f-divergence: generalizes several distances and divergences
Discriminability index, specifically the Bayes discriminability index, is a positive-definite symmetric measure of the overlap of two distributions.

Notes

^ Dodge, Y. (2003)—entry for distance
^ Goldreich, Oded (2001). Foundations of Cryptography: Basic Tools (1st ed.). Berlin: Cambridge University Press. p. 106. ISBN 0-521-79172-3.
^ Reyzin, Leo. (Lecture Notes) Extractors and the Leftover Hash Lemma

External links

Distance and Similarity Measures (Wolfram Alpha)

References

Dodge, Y. (2003) Oxford Dictionary of Statistical Terms, OUP. ISBN 0-19-920613-9

[1] Dodge, Y. (2003)—entry for distance

[2] Goldreich, Oded (2001). Foundations of Cryptography: Basic Tools (1st ed.). Berlin: Cambridge University Press. p. 106. ISBN 0-521-79172-3.

[3] Reyzin, Leo. (Lecture Notes) Extractors and the Leftover Hash Lemma

[1]

[2]

[3]

@@ Line 1: / Line 1: @@
 {{Short description|Distance between two statistical objects}}
+{{Multiple issues|
+{{more footnotes|date=February 2012}}
 {{refimprove|date=December 2020}}
+}}
 In [[statistics]], [[probability theory]], and [[information theory]], a '''statistical distance''' quantifies the [[distance]] between two statistical objects, which can be two [[random variable]]s, or two [[probability distribution]]s or [[Sample (statistics)|samples]], or the distance can be between an individual sample point and a population or a wider sample of points.
@@ Line 6: / Line 9: @@
 A distance between populations can be interpreted as measuring the distance between two [[probability distribution]]s and hence they are essentially measures of distances between [[probability measure]]s. Where statistical distance measures relate to the differences between [[random variable]]s, these may have [[statistical independence|statistical dependence]],<ref>Dodge, Y. (2003)&mdash;entry for distance</ref> and hence these distances are not directly related to measures of distances between probability measures.  Again, a measure of distance between random variables may relate to the extent of dependence between them, rather than to their individual values.
-Statistical distance measures are not typically [[metric (mathematics)|metric]]s, and they need not be symmetric. Some types of distance measures, which generalize ''squared'' distance, are referred to as (statistical) ''[[divergence (statistics)|divergence]]s''.
+Many statistical distance measures are not [[metric (mathematics)|metric]]s, and some are not symmetric. Some types of distance measures, which generalize ''squared'' distance, are referred to as (statistical) ''[[divergence (statistics)|divergence]]s''.
 ==Terminology==
@@ Line 23: / Line 26: @@
 ===Generalized metrics===
-Many statistical distances are not [[metric (mathematics)|metric]]s, because they lack one or more properties of proper metrics. For example, [[pseudometric space|pseudometric]]s violate the "[[Positive-definite function#In dynamical systems|positive definiteness]]" (alternatively, [[metric (mathematics)#Pseudometrics|"identity of indescernibles"]]) property (1 & 2 above); [[quasimetric]]s violate the [[metric (mathematics)#Quasimetrics|symmetry]] property (3); and [[semimetric]]s violate the [[metric (mathematics)#Semimetrics|triangle inequality]] (4). Statistical distances that satisfy (1) and (2) are referred to as [[divergence (statistics)|divergence]]s.
+Many statistical distances are not [[metric (mathematics)|metric]]s, because they lack one or more properties of proper metrics. For example, [[pseudometric space|pseudometric]]s violate property (2), identity of indiscernibles; [[quasimetric]]s violate property (3), symmetry; and [[semimetric]]s violate property (4), the triangle inequality. Statistical distances that satisfy (1) and (2) are referred to as [[divergence (statistics)|divergence]]s.
+==Statistically close==
+The [[Total variation distance of probability measures | total variation distance]] of two distributions <math>X</math> and <math>Y</math> over a finite domain <math>D</math>, (often referred to as ''statistical difference''<ref>
+{{cite book
+ | last = Goldreich
+ | first = Oded
+ | authorlink = Oded Goldreich
+ | title = Foundations of Cryptography: Basic Tools
+ | publisher = [[Cambridge University Press]]
+ | edition = 1st
+ | location = Berlin
+ | date = 2001
+ | page = 106
+ | isbn = 0-521-79172-3
+}}
+</ref>
+or ''statistical distance''<ref>
+Reyzin, Leo. (Lecture Notes) [http://www.cs.bu.edu/~reyzin/teaching/s11cs937/notes-leo-1.pdf Extractors and the Leftover Hash Lemma]
+</ref>  in cryptography) is defined as
+<math> \Delta(X,Y)=\frac{1}{2} \sum _{\alpha \in D} | \Pr[X=\alpha] - \Pr[Y=\alpha] |</math>.
+We say that two [[probability ensembles]] <math>\{X_k\}_{k\in\N}</math> and <math>\{Y_k\}_{k\in\N}</math> are statistically close if <math>\Delta(X_k,Y_k)</math> is a [[negligible function]] in <math>k</math>.
 ==Examples==
@@ Line 32: / Line 58: @@
 * [[Wasserstein metric]]: also known as the Kantorovich metric, or [[earth mover's distance]]
 * [[Mahalanobis distance]]
+* [[Amari distance]]
+* [[Integral probability metric]]s generalize several metrics or pseudometrics on distributions
 ===Divergences===
 * [[Kullback–Leibler divergence]]
-* [[Rényi divergence|Rényi's divergence]]
+* [[Rényi divergence]]
 * [[Jensen–Shannon divergence]]
 * [[Bhattacharyya distance]] (despite its name it is not a distance, as it violates the triangle inequality)
 * [[f-divergence]]: generalizes several distances and divergences
-* [[Discriminability index]], specifically the [[Discriminability index#Bayes discriminability index|Bayes discriminability index]] is a positive-definite symmetric measure of the overlap of two distributions.
+* [[Discriminability index]], specifically the [[Discriminability index#Bayes discriminability index|Bayes discriminability index]], is a positive-definite symmetric measure of the overlap of two distributions.
 == See also ==
 *[[Probabilistic metric space]]
+*[[Randomness extractor]]
+*[[Similarity measure]]
-{{more footnotes|date=February 2012}}
+*[[Zero-knowledge proof]]
 ==Notes==
@@ Line 49: / Line 79: @@
 ==External links==
-*[http://reference.wolfram.com/mathematica/guide/DistanceAndSimilarityMeasures.html Distance and Similarity Measures(Wolfram Alpha)]
+*[http://reference.wolfram.com/mathematica/guide/DistanceAndSimilarityMeasures.html Distance and Similarity Measures (Wolfram Alpha)]
 {{Statistics|inference|collapsed}}