Cumulative distribution function: Difference between revisions

Jump to navigation Jump to search
LBiller (talk | contribs)
No edit summary
 
WikiBot (talk | contribs)
m Bot: Automated text replacement (-{{SIB}} + & -{{EH}} + & -{{EJ}} + & -{{Editor Help}} + & -{{Editor Join}} +)
 
(One intermediate revision by one other user not shown)
Line 1: Line 1:
{{SI}}
{{SI}}
{{EH}}
 


==Overview==
==Overview==
Line 19: Line 19:


== Properties ==leftright|thumb|From top to bottom, the cumulative distribution function of a discrete probability distribution, continuous probability distribution, and a distribution which has both a continuous part and a discrete part.]]
== Properties ==leftright|thumb|From top to bottom, the cumulative distribution function of a discrete probability distribution, continuous probability distribution, and a distribution which has both a continuous part and a discrete part.]]
Every cumulative distribution function ''F'' is (not necessarily strictly) [[monotone increasing]] and [[right-continuous]]. Furthermore, we have
Every cumulative distribution function ''F'' is (not necessarily strictly) monotone increasing and right-continuous. Furthermore, we have
:<math>\lim_{x\to -\infty}F(x)=0, \quad \lim_{x\to +\infty}F(x)=1.</math>
:<math>\lim_{x\to -\infty}F(x)=0, \quad \lim_{x\to +\infty}F(x)=1.</math>


Every function with these four properties is a cdf. The properties imply that all CDFs are [[càdlàg]] functions.
Every function with these four properties is a cdf. The properties imply that all CDFs are càdlàg functions.


If ''X'' is a [[discrete random variable]], then it attains values ''x''<sub>1</sub>, ''x''<sub>2</sub>, ... with probability ''p''<sub>i</sub> = P(''x''<sub>i</sub>), and the cdf of ''X'' will be discontinuous at the points ''x''<sub>''i''</sub> and constant in between:
If ''X'' is a [[discrete random variable]], then it attains values ''x''<sub>1</sub>, ''x''<sub>2</sub>, ... with probability ''p''<sub>i</sub> = P(''x''<sub>i</sub>), and the cdf of ''X'' will be discontinuous at the points ''x''<sub>''i''</sub> and constant in between:
Line 28: Line 28:
:<math>F(x) = \operatorname{P}(X\leq x) = \sum_{x_i \leq x} \operatorname{P}(X = x_i) = \sum_{x_i \leq x} p(x_i)</math>
:<math>F(x) = \operatorname{P}(X\leq x) = \sum_{x_i \leq x} \operatorname{P}(X = x_i) = \sum_{x_i \leq x} p(x_i)</math>


If the CDF ''F'' of ''X'' is [[continuous function|continuous]], then ''X'' is a [[continuous random variable]]; if furthermore ''F'' is [[absolute continuity|absolutely continuous]], then there exists a [[Lebesgue integral|Lebesgue-integrable]] function ''f''(''x'') such that  
If the CDF ''F'' of ''X'' is [[continuous function|continuous]], then ''X'' is a continuous random variable; if furthermore ''F'' is [[absolute continuity|absolutely continuous]], then there exists a Lebesgue-integrable function ''f''(''x'') such that  


:<math>F(b)-F(a) = \operatorname{P}(a\leq X\leq b) = \int_a^b f(x)\,dx</math>
:<math>F(b)-F(a) = \operatorname{P}(a\leq X\leq b) = \int_a^b f(x)\,dx</math>


for all real numbers ''a'' and ''b''.  (The first of the two equalities displayed above would not be correct in general if we had not said that the distribution is continuous.  Continuity of the distribution implies that P(''X'' = ''a'') = P(''X'' = ''b'') = 0, so the difference between "<" and "&le;" ceases to be important in this context.)  The function ''f'' is equal to the [[derivative]] of ''F'' [[almost everywhere]], and it is called the [[probability density function]] of the distribution of ''X''.
for all real numbers ''a'' and ''b''.  (The first of the two equalities displayed above would not be correct in general if we had not said that the distribution is continuous.  Continuity of the distribution implies that P(''X'' = ''a'') = P(''X'' = ''b'') = 0, so the difference between "<" and "&le;" ceases to be important in this context.)  The function ''f'' is equal to the [[derivative]] of ''F'' almost everywhere, and it is called the [[probability density function]] of the distribution of ''X''.


===Point probability===
===Point probability===
Line 95: Line 95:
[[Category:Probability theory]]
[[Category:Probability theory]]


{{SIB}}
 
[[da:Fordelingsfunktion]]
[[da:Fordelingsfunktion]]
[[de:Verteilungsfunktion]]
[[de:Verteilungsfunktion]]

Latest revision as of 00:22, 9 August 2012

WikiDoc Resources for Cumulative distribution function

Articles

Most recent articles on Cumulative distribution function

Most cited articles on Cumulative distribution function

Review articles on Cumulative distribution function

Articles on Cumulative distribution function in N Eng J Med, Lancet, BMJ

Media

Powerpoint slides on Cumulative distribution function

Images of Cumulative distribution function

Photos of Cumulative distribution function

Podcasts & MP3s on Cumulative distribution function

Videos on Cumulative distribution function

Evidence Based Medicine

Cochrane Collaboration on Cumulative distribution function

Bandolier on Cumulative distribution function

TRIP on Cumulative distribution function

Clinical Trials

Ongoing Trials on Cumulative distribution function at Clinical Trials.gov

Trial results on Cumulative distribution function

Clinical Trials on Cumulative distribution function at Google

Guidelines / Policies / Govt

US National Guidelines Clearinghouse on Cumulative distribution function

NICE Guidance on Cumulative distribution function

NHS PRODIGY Guidance

FDA on Cumulative distribution function

CDC on Cumulative distribution function

Books

Books on Cumulative distribution function

News

Cumulative distribution function in the news

Be alerted to news on Cumulative distribution function

News trends on Cumulative distribution function

Commentary

Blogs on Cumulative distribution function

Definitions

Definitions of Cumulative distribution function

Patient Resources / Community

Patient resources on Cumulative distribution function

Discussion groups on Cumulative distribution function

Patient Handouts on Cumulative distribution function

Directions to Hospitals Treating Cumulative distribution function

Risk calculators and risk factors for Cumulative distribution function

Healthcare Provider Resources

Symptoms of Cumulative distribution function

Causes & Risk Factors for Cumulative distribution function

Diagnostic studies for Cumulative distribution function

Treatment of Cumulative distribution function

Continuing Medical Education (CME)

CME Programs on Cumulative distribution function

International

Cumulative distribution function en Espanol

Cumulative distribution function en Francais

Business

Cumulative distribution function in the Marketplace

Patents on Cumulative distribution function

Experimental / Informatics

List of terms related to Cumulative distribution function


Overview

In probability theory, the cumulative distribution function (CDF), also called probability distribution function or just distribution function,[1] completely describes the probability distribution of a real-valued random variable X. For every real number x, the CDF of X is given by

<math>x \to F_X(x) = \operatorname{P}(X\leq x),</math>

where the right-hand side represents the probability that the random variable X takes on a value less than or equal to x. The probability that X lies in the interval (ab] is therefore F(b) − F(a) if a < b. It is conventional to use a capital F for a cumulative distribution function, in contrast to the lower-case f used for probability density functions and probability mass functions.

The CDF of X can be defined in terms of the probability density function f as follows:

<math>F(x) = \int_{-\infty}^x f(t)\,dt</math>

Note that in the definition above, the "less or equal" sign, '≤' is a convention, but it is an important and universally used one. The proper use of tables of the Binomial and Poisson distributions depend upon this convention. Moreover, important formulas like Levy's inversion formula for the characteristic function also rely on the "less or equal" formulation.

== Properties ==leftright|thumb|From top to bottom, the cumulative distribution function of a discrete probability distribution, continuous probability distribution, and a distribution which has both a continuous part and a discrete part.]] Every cumulative distribution function F is (not necessarily strictly) monotone increasing and right-continuous. Furthermore, we have

<math>\lim_{x\to -\infty}F(x)=0, \quad \lim_{x\to +\infty}F(x)=1.</math>

Every function with these four properties is a cdf. The properties imply that all CDFs are càdlàg functions.

If X is a discrete random variable, then it attains values x1, x2, ... with probability pi = P(xi), and the cdf of X will be discontinuous at the points xi and constant in between:

<math>F(x) = \operatorname{P}(X\leq x) = \sum_{x_i \leq x} \operatorname{P}(X = x_i) = \sum_{x_i \leq x} p(x_i)</math>

If the CDF F of X is continuous, then X is a continuous random variable; if furthermore F is absolutely continuous, then there exists a Lebesgue-integrable function f(x) such that

<math>F(b)-F(a) = \operatorname{P}(a\leq X\leq b) = \int_a^b f(x)\,dx</math>

for all real numbers a and b. (The first of the two equalities displayed above would not be correct in general if we had not said that the distribution is continuous. Continuity of the distribution implies that P(X = a) = P(X = b) = 0, so the difference between "<" and "≤" ceases to be important in this context.) The function f is equal to the derivative of F almost everywhere, and it is called the probability density function of the distribution of X.

Point probability

The "point probability" that X is exactly b can be found as

<math>\operatorname{P}(X=b) = F(b) - \lim_{x \to b^{-}} F(x)</math>

Kolmogorov-Smirnov and Kuiper's tests

The Kolmogorov-Smirnov test is based on cumulative distribution functions and can be used to test to see whether two empirical distributions are different or whether an empirical distribution is different from an ideal distribution. The closely related Kuiper's test (pronounced Template:IPA) is useful if the domain of the distribution is cyclic as in day of the week. For instance we might use Kuiper's test to see if the number of tornadoes varies during the year or if sales of a product vary by day of the week or day of the month.

Complementary cumulative distribution function

Sometimes, it is useful to study the opposite question and ask how often the random variable is above a particular level. This is called the complementary cumulative distribution function (ccdf), defined as

<math>F_c(x) = \operatorname{P}(X > x) = 1 - F(x)</math>.

In survival analysis, <math>F_c(x)</math> is called the survival function and denoted <math> S(x) </math>.

Examples

As an example, suppose X is uniformly distributed on the unit interval [0, 1]. Then the CDF of X is given by

<math>F(x) = \begin{cases}

0 &:\ x < 0\\ x &:\ 0 \le x \le 1\\ 1 &:\ 1 < x \end{cases}</math>

Take another example, suppose X takes only the discrete values 0 and 1, with equal probability. Then the CDF of X is given by

<math>F(x) = \begin{cases}

0 &:\ x < 0\\ 1/2 &:\ 0 \le x < 1\\ 1 &:\ 1 \le x \end{cases}</math>

Inverse

If the cdf F is strictly increasing and continuous then <math> F^{-1}( y ), y \in [0,1] </math> is the unique real number <math> x </math> such that <math> F(x) = y </math>.

Unfortunately, the distribution does not, in general, have an inverse. One may define, for <math> y \in [0,1] </math>,

<math>

F^{-1}( y ) = \inf_{r \in \mathbb{R}} \{ F( r ) > y \} </math>.

Example 1: The median is <math>F^{-1}( 0.5 )</math>.

Example 2: Put <math> \tau = F^{-1}( 0.95 ) </math>. Then we call <math> \tau </math> the 95th percentile.

The inverse of the cdf is called the quantile function.

See also

References

  1. Eric W. Weisstein. Distribution Function. From MathWorld—A Wolfram Web Resource.


da:Fordelingsfunktion de:Verteilungsfunktion it:Funzione di ripartizione hu:Eloszlásfüggvény su:Fungsi sebaran kumulatif sv:Kumulativ fördelningsfunktion Template:WH Template:WS