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{{distinguish|Q–Q plot}} | |||
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[[File:Probability-Probability plot, quality characteristic data.png|300px|right|thumb]]In statistics, a '''P–P plot''' ('''probability–probability plot''' or '''percent–percent plot''') is a [[probability plot]] for assessing how closely two [[data set]]s agree, which plots the two [[cumulative distribution function]]s against each other. | |||
The [[Q–Q plot]] is more widely used, but they are both referred to as "the" probability plot, and are potentially confused. | |||
== Definition == | |||
A P–P plot plots two [[cumulative distribution function]]s (cdfs) against each other:<ref>[http://books.google.com/books?id=kJbVO2G6VicC Nonparametric statistical inference] by Jean Dickinson Gibbons, Subhabrata Chakraborti, 4th Edition, CRC Press, 2003, ISBN 978-0-8247-4052-8, [http://books.google.com/books?id=kJbVO2G6VicC&pg=PA144#PPA145,M1 p. 145]</ref> | |||
given two probability distributions, with cdfs "''F''" and "''G''", it plots <math>(F(z),G(z))</math> as ''z'' ranges from <math>-\infty</math> to <math>\infty.</math> As a cdf has range [0,1], the domain of this parametric graph is <math>(-\infty,\infty)</math> and the range is the unit square <math>[0,1]\times [0,1].</math> | |||
Thus for input ''z'' the output is the pair of numbers giving what ''percentage'' of ''f'' and what ''percentage'' of ''g'' fall at or below ''z.'' | |||
The comparison line is the 45° line from (0,0) to (1,1) – the distributions are equal if and only if the plot falls on this line – any deviation indicates a difference between the distributions. | |||
== Example == | |||
As an example, if the two distributions do not overlap, say ''F'' is below ''G,'' then the P–P plot will move from left to right along the bottom of the square – as ''z'' moves through the support of ''F,'' the cdf of ''F'' goes from 0 to 1, while the cdf of ''G'' stays at 0 – and then moves up the right side of the square – the cdf of ''F'' is now 1, as all points of ''F'' lie below all points of ''G,'' and now the cdf of ''G'' moves from 0 to 1 as ''z'' moves through the support of ''G.'' | |||
== Use == | |||
As the above example illustrates, if two distributions are separated in space, the P–P plot will give very little data – it is only useful for comparing probability distributions that have nearby or equal location. Notably, it will pass through the point (1/2, 1/2) if and only if the two distributions have the same [[median]]. | |||
P–P plots are sometimes limited to comparisons between two samples, rather than comparison of a sample to a theoretical model distribution.<ref name="thode223">[http://books.google.com/books?id=gbegXB4SdosC Testing for Normality], by Henry C. Thode, CRC Press, 2002, ISBN 978-0-8247-9613-6, | |||
Section 2.2.3, Percent–percent plots, [http://books.google.com/books?id=gbegXB4SdosC&pg=PA31#PPA23,M1 p. 23]</ref> However, they are of general use, particularly where observations are not all modelled with the same distribution. | |||
However, it was found some use in comparing a sample distribution from a ''known'' theoretical distribution: given ''n'' samples, plotting the continuous theoretical cdf against the empirical cdf would yield a stair-step (a step as ''z'' hits a sample), and would hit the top of the square when the last data point was hit. Instead one only plots points, plotting the observed ''k''th observed points (in order: formally the observed ''k''th order statistic) against the ''k''/(''n'' + 1) [[quantile]] of the theoretical distribution.<ref name="thode223" /> This choice of "plotting position" (choice of quantile of the theoretical distribution) has occasioned less controversy than the choice for Q–Q plots. The resulting goodness of fit of the 45° line gives a measure of the difference between a sample set and the theoretical distribution. | |||
A P–P plot can be used as a graphical adjunct to a tests of the fit of probability distributions,<ref name=Michael>Michael J.R. (1983) "The stabilized probability plot". [[Biometrika]], 70(1), 11–17. {{JSTOR|2335939}}</ref><ref name=Shorack>Shorack, G.R., Wellner, J.A (1986) ''Empirical Processes with Applications to Statistics'', Wiley. ISBN 0-471-86725-X p248–250</ref> with additional lines being included on the plot to indicate either specific acceptance regions or the range of expected departure from the 1:1 line. An improved version of the P–P plot, called the SP or S–P plot, is available,<ref name="Michael"/><ref name="Shorack"/> which makes use of a [[variance-stabilizing transformation]] to create a plot on which the variations about the 1:1 line should be the same at all locations. | |||
== See also == | |||
* [[Probability plot]] | |||
== Notes == | |||
{{reflist}} | |||
{{Distribution fitting}} | |||
{{DEFAULTSORT:P-P Plot}} | |||
[[Category:Statistical charts and diagrams]] | |||
Latest revision as of 10:15, 4 December 2013
Template:Distinguish 30 year-old Entertainer or Range Artist Wesley from Drumheller, really loves vehicle, property developers properties for sale in singapore singapore and horse racing. Finds inspiration by traveling to Works of Antoni Gaudí.
In statistics, a P–P plot (probability–probability plot or percent–percent plot) is a probability plot for assessing how closely two data sets agree, which plots the two cumulative distribution functions against each other.
The Q–Q plot is more widely used, but they are both referred to as "the" probability plot, and are potentially confused.
Definition
A P–P plot plots two cumulative distribution functions (cdfs) against each other:[1] given two probability distributions, with cdfs "F" and "G", it plots as z ranges from to As a cdf has range [0,1], the domain of this parametric graph is and the range is the unit square
Thus for input z the output is the pair of numbers giving what percentage of f and what percentage of g fall at or below z.
The comparison line is the 45° line from (0,0) to (1,1) – the distributions are equal if and only if the plot falls on this line – any deviation indicates a difference between the distributions.
Example
As an example, if the two distributions do not overlap, say F is below G, then the P–P plot will move from left to right along the bottom of the square – as z moves through the support of F, the cdf of F goes from 0 to 1, while the cdf of G stays at 0 – and then moves up the right side of the square – the cdf of F is now 1, as all points of F lie below all points of G, and now the cdf of G moves from 0 to 1 as z moves through the support of G.
Use
As the above example illustrates, if two distributions are separated in space, the P–P plot will give very little data – it is only useful for comparing probability distributions that have nearby or equal location. Notably, it will pass through the point (1/2, 1/2) if and only if the two distributions have the same median.
P–P plots are sometimes limited to comparisons between two samples, rather than comparison of a sample to a theoretical model distribution.[2] However, they are of general use, particularly where observations are not all modelled with the same distribution.
However, it was found some use in comparing a sample distribution from a known theoretical distribution: given n samples, plotting the continuous theoretical cdf against the empirical cdf would yield a stair-step (a step as z hits a sample), and would hit the top of the square when the last data point was hit. Instead one only plots points, plotting the observed kth observed points (in order: formally the observed kth order statistic) against the k/(n + 1) quantile of the theoretical distribution.[2] This choice of "plotting position" (choice of quantile of the theoretical distribution) has occasioned less controversy than the choice for Q–Q plots. The resulting goodness of fit of the 45° line gives a measure of the difference between a sample set and the theoretical distribution.
A P–P plot can be used as a graphical adjunct to a tests of the fit of probability distributions,[3][4] with additional lines being included on the plot to indicate either specific acceptance regions or the range of expected departure from the 1:1 line. An improved version of the P–P plot, called the SP or S–P plot, is available,[3][4] which makes use of a variance-stabilizing transformation to create a plot on which the variations about the 1:1 line should be the same at all locations.
See also
Notes
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- ↑ Nonparametric statistical inference by Jean Dickinson Gibbons, Subhabrata Chakraborti, 4th Edition, CRC Press, 2003, ISBN 978-0-8247-4052-8, p. 145
- ↑ 2.0 2.1 Testing for Normality, by Henry C. Thode, CRC Press, 2002, ISBN 978-0-8247-9613-6, Section 2.2.3, Percent–percent plots, p. 23
- ↑ 3.0 3.1 Michael J.R. (1983) "The stabilized probability plot". Biometrika, 70(1), 11–17. Glazier Alfonzo from Chicoutimi, has lots of interests which include lawn darts, property developers house for sale in singapore singapore and cigar smoking. During the last year has made a journey to Cultural Landscape and Archaeological Remains of the Bamiyan Valley.
- ↑ 4.0 4.1 Shorack, G.R., Wellner, J.A (1986) Empirical Processes with Applications to Statistics, Wiley. ISBN 0-471-86725-X p248–250