# Pareto distribution

The Pareto distribution, named after the Italian civil engineer, economist, and sociologist Vilfredo Pareto, is a power-law probability distribution that is used in description of social, scientific, geophysical, actuarial, and many other types of observable phenomena. Originally applied to describing the distribution of wealth in a society, fitting the trend that a large portion of wealth is held by a small fraction of the population, the Pareto distribution has colloquially become known and referred to as the Pareto principle, or "80-20 rule", and is sometimes called the "Matthew principle". This rule states that, for example, 80% of the wealth of a society is held by 20% of its population. However, one should not conflate the Pareto distribution for the Pareto Principle as the former only produces this result for a particular power value, ${\displaystyle \alpha }$ (α = log45 ≈ 1.16). While ${\displaystyle \alpha }$ is variable, empirical observation has found the 80-20 distribution to fit a wide range of cases, including natural phenomena and human activities.[citation needed]

Parameters Probability density functionPareto Type I probability density functions for various ${\displaystyle \alpha }$ with ${\displaystyle x_{\mathrm {m} }=1.}$ As ${\displaystyle \alpha \rightarrow \infty ,}$ the distribution approaches ${\displaystyle \delta (x-x_{\mathrm {m} }),}$ where ${\displaystyle \delta }$ is the Dirac delta function. Cumulative distribution functionPareto Type I cumulative distribution functions for various ${\displaystyle \alpha }$ with ${\displaystyle x_{\mathrm {m} }=1.}$ ${\displaystyle x_{\mathrm {m} }>0}$ scale (real)${\displaystyle \alpha >0}$ shape (real) ${\displaystyle x\in [x_{\mathrm {m} },\infty )}$ ${\displaystyle {\frac {\alpha x_{\mathrm {m} }^{\alpha }}{x^{\alpha +1}}}}$ ${\displaystyle 1-\left({\frac {x_{\mathrm {m} }}{x}}\right)^{\alpha }}$ ${\displaystyle {\begin{cases}\infty &{\text{for }}\alpha \leq 1\\{\dfrac {\alpha x_{\mathrm {m} }}{\alpha -1}}&{\text{for }}\alpha >1\end{cases}}}$ ${\displaystyle x_{\mathrm {m} }{\sqrt[{\alpha }]{2}}}$ ${\displaystyle x_{\mathrm {m} }}$ ${\displaystyle {\begin{cases}\infty &{\text{for }}\alpha \leq 2\\{\dfrac {x_{\mathrm {m} }^{2}\alpha }{(\alpha -1)^{2}(\alpha -2)}}&{\text{for }}\alpha >2\end{cases}}}$ ${\displaystyle {\frac {2(1+\alpha )}{\alpha -3}}{\sqrt {\frac {\alpha -2}{\alpha }}}{\text{ for }}\alpha >3}$ ${\displaystyle {\frac {6(\alpha ^{3}+\alpha ^{2}-6\alpha -2)}{\alpha (\alpha -3)(\alpha -4)}}{\text{ for }}\alpha >4}$ ${\displaystyle \log \left(\left({\frac {x_{\mathrm {m} }}{\alpha }}\right)\,e^{1+{\tfrac {1}{\alpha }}}\right)}$ ${\displaystyle \alpha (-x_{\mathrm {m} }t)^{\alpha }\Gamma (-\alpha ,-x_{\mathrm {m} }t){\text{ for }}t<0}$ ${\displaystyle \alpha (-ix_{\mathrm {m} }t)^{\alpha }\Gamma (-\alpha ,-ix_{\mathrm {m} }t)}$ ${\displaystyle {\mathcal {I}}(x_{\mathrm {m} },\alpha )={\begin{bmatrix}{\dfrac {\alpha }{x_{\mathrm {m} }^{2}}}&-{\dfrac {1}{x_{\mathrm {m} }}}\\-{\dfrac {1}{x_{\mathrm {m} }}}&{\dfrac {1}{\alpha ^{2}}}\end{bmatrix}}}$

## Definition

If X is a random variable with a Pareto (Type I) distribution,[1] then the probability that X is greater than some number x, i.e. the survival function (also called tail function), is given by

${\displaystyle {\overline {F}}(x)=\Pr(X>x)={\begin{cases}\left({\frac {x_{\mathrm {m} }}{x}}\right)^{\alpha }&x\geq x_{\mathrm {m} },\\1&x

where xm is the (necessarily positive) minimum possible value of X, and α is a positive parameter. The Pareto Type I distribution is characterized by a scale parameter xm and a shape parameter α, which is known as the tail index. When this distribution is used to model the distribution of wealth, then the parameter α is called the Pareto index.

## Properties

### Cumulative distribution function

From the definition, the cumulative distribution function of a Pareto random variable with parameters α and xm is

${\displaystyle F_{X}(x)={\begin{cases}1-\left({\frac {x_{\mathrm {m} }}{x}}\right)^{\alpha }&x\geq x_{\mathrm {m} },\\0&x

### Probability density function

It follows (by differentiation) that the probability density function is

${\displaystyle f_{X}(x)={\begin{cases}{\frac {\alpha x_{\mathrm {m} }^{\alpha }}{x^{\alpha +1}}}&x\geq x_{\mathrm {m} },\\0&x

When plotted on linear axes, the distribution assumes the familiar J-shaped curve which approaches each of the orthogonal axes asymptotically. All segments of the curve are self-similar (subject to appropriate scaling factors). When plotted in a log-log plot, the distribution is represented by a straight line.

### Moments and characteristic function

${\displaystyle \operatorname {E} (X)={\begin{cases}\infty &\alpha \leq 1,\\{\frac {\alpha x_{\mathrm {m} }}{\alpha -1}}&\alpha >1.\end{cases}}}$
${\displaystyle \operatorname {Var} (X)={\begin{cases}\infty &\alpha \in (1,2],\\\left({\frac {x_{\mathrm {m} }}{\alpha -1}}\right)^{2}{\frac {\alpha }{\alpha -2}}&\alpha >2.\end{cases}}}$
(If α ≤ 1, the variance does not exist.)
${\displaystyle \mu _{n}'={\begin{cases}\infty &\alpha \leq n,\\{\frac {\alpha x_{\mathrm {m} }^{n}}{\alpha -n}}&\alpha >n.\end{cases}}}$
${\displaystyle M\left(t;\alpha ,x_{\mathrm {m} }\right)=\operatorname {E} \left[e^{tX}\right]=\alpha (-x_{\mathrm {m} }t)^{\alpha }\Gamma (-\alpha ,-x_{\mathrm {m} }t)}$
${\displaystyle M\left(0,\alpha ,x_{\mathrm {m} }\right)=1.}$
${\displaystyle \varphi (t;\alpha ,x_{\mathrm {m} })=\alpha (-ix_{\mathrm {m} }t)^{\alpha }\Gamma (-\alpha ,-ix_{\mathrm {m} }t),}$
where Γ(ax) is the incomplete gamma function.

### Conditional distributions

The conditional probability distribution of a Pareto-distributed random variable, given the event that it is greater than or equal to a particular number ${\displaystyle x_{1}}$  exceeding ${\displaystyle x_{\text{m}}}$ , is a Pareto distribution with the same Pareto index ${\displaystyle \alpha }$  but with minimum ${\displaystyle x_{1}}$  instead of ${\displaystyle x_{\text{m}}}$ .

### A characterization theorem

Suppose ${\displaystyle X_{1},X_{2},X_{3},\dotsc }$  are independent identically distributed random variables whose probability distribution is supported on the interval ${\displaystyle [x_{\text{m}},\infty )}$  for some ${\displaystyle x_{\text{m}}>0}$ . Suppose that for all ${\displaystyle n}$ , the two random variables ${\displaystyle \min\{X_{1},\dotsc ,X_{n}\}}$  and ${\displaystyle (X_{1}+\dotsb +X_{n})/\min\{X_{1},\dotsc ,X_{n}\}}$  are independent. Then the common distribution is a Pareto distribution.[citation needed]

### Geometric mean

The geometric mean (G) is[2]

${\displaystyle G=x_{\text{m}}\exp \left({\frac {1}{\alpha }}\right).}$

### Harmonic mean

The harmonic mean (H) is[2]

${\displaystyle H=x_{\text{m}}\left(1+{\frac {1}{\alpha }}\right).}$

## Generalized Pareto distributions

There is a hierarchy [1][3] of Pareto distributions known as Pareto Type I, II, III, IV, and Feller–Pareto distributions.[1][3][4] Pareto Type IV contains Pareto Type I–III as special cases. The Feller–Pareto[3][5] distribution generalizes Pareto Type IV.

### Pareto types I–IV

The Pareto distribution hierarchy is summarized in the next table comparing the survival functions (complementary CDF).

When μ = 0, the Pareto distribution Type II is also known as the Lomax distribution.[6]

In this section, the symbol xm, used before to indicate the minimum value of x, is replaced by σ.

Pareto distributions
${\displaystyle {\overline {F}}(x)=1-F(x)}$  Support Parameters
Type I ${\displaystyle \left[{\frac {x}{\sigma }}\right]^{-\alpha }}$  ${\displaystyle x\geq \sigma }$  ${\displaystyle \sigma >0,\alpha }$
Type II ${\displaystyle \left[1+{\frac {x-\mu }{\sigma }}\right]^{-\alpha }}$  ${\displaystyle x\geq \mu }$  ${\displaystyle \mu \in \mathbb {R} ,\sigma >0,\alpha }$
Lomax ${\displaystyle \left[1+{\frac {x}{\sigma }}\right]^{-\alpha }}$  ${\displaystyle x\geq 0}$  ${\displaystyle \sigma >0,\alpha }$
Type III ${\displaystyle \left[1+\left({\frac {x-\mu }{\sigma }}\right)^{1/\gamma }\right]^{-1}}$  ${\displaystyle x\geq \mu }$  ${\displaystyle \mu \in \mathbb {R} ,\sigma ,\gamma >0}$
Type IV ${\displaystyle \left[1+\left({\frac {x-\mu }{\sigma }}\right)^{1/\gamma }\right]^{-\alpha }}$  ${\displaystyle x\geq \mu }$  ${\displaystyle \mu \in \mathbb {R} ,\sigma ,\gamma >0,\alpha }$

The shape parameter α is the tail index, μ is location, σ is scale, γ is an inequality parameter. Some special cases of Pareto Type (IV) are

${\displaystyle P(IV)(\sigma ,\sigma ,1,\alpha )=P(I)(\sigma ,\alpha ),}$
${\displaystyle P(IV)(\mu ,\sigma ,1,\alpha )=P(II)(\mu ,\sigma ,\alpha ),}$
${\displaystyle P(IV)(\mu ,\sigma ,\gamma ,1)=P(III)(\mu ,\sigma ,\gamma ).}$

The finiteness of the mean, and the existence and the finiteness of the variance depend on the tail index α (inequality index γ). In particular, fractional δ-moments are finite for some δ > 0, as shown in the table below, where δ is not necessarily an integer.

Moments of Pareto I–IV distributions (case μ = 0)
${\displaystyle \operatorname {E} [X]}$  Condition ${\displaystyle \operatorname {E} [X^{\delta }]}$  Condition
Type I ${\displaystyle {\frac {\sigma \alpha }{\alpha -1}}}$  ${\displaystyle \alpha >1}$  ${\displaystyle {\frac {\sigma ^{\delta }\alpha }{\alpha -\delta }}}$  ${\displaystyle \delta <\alpha }$
Type II ${\displaystyle {\frac {\sigma }{\alpha -1}}}$  ${\displaystyle \alpha >1}$  ${\displaystyle {\frac {\sigma ^{\delta }\Gamma (\alpha -\delta )\Gamma (1+\delta )}{\Gamma (\alpha )}}}$  ${\displaystyle -1<\delta <\alpha }$
Type III ${\displaystyle \sigma \Gamma (1-\gamma )\Gamma (1+\gamma )}$  ${\displaystyle -1<\gamma <1}$  ${\displaystyle \sigma ^{\delta }\Gamma (1-\gamma \delta )\Gamma (1+\gamma \delta )}$  ${\displaystyle -\gamma ^{-1}<\delta <\gamma ^{-1}}$
Type IV ${\displaystyle {\frac {\sigma \Gamma (\alpha -\gamma )\Gamma (1+\gamma )}{\Gamma (\alpha )}}}$  ${\displaystyle -1<\gamma <\alpha }$  ${\displaystyle {\frac {\sigma ^{\delta }\Gamma (\alpha -\gamma \delta )\Gamma (1+\gamma \delta )}{\Gamma (\alpha )}}}$  ${\displaystyle -\gamma ^{-1}<\delta <\alpha /\gamma }$

### Feller–Pareto distribution

Feller[3][5] defines a Pareto variable by transformation U = Y−1 − 1 of a beta random variable Y, whose probability density function is

${\displaystyle f(y)={\frac {y^{\gamma _{1}-1}(1-y)^{\gamma _{2}-1}}{B(\gamma _{1},\gamma _{2})}},\qquad 00,}$

where B( ) is the beta function. If

${\displaystyle W=\mu +\sigma (Y^{-1}-1)^{\gamma },\qquad \sigma >0,\gamma >0,}$

then W has a Feller–Pareto distribution FP(μ, σ, γ, γ1, γ2).[1]

If ${\displaystyle U_{1}\sim \Gamma (\delta _{1},1)}$  and ${\displaystyle U_{2}\sim \Gamma (\delta _{2},1)}$  are independent Gamma variables, another construction of a Feller–Pareto (FP) variable is[7]

${\displaystyle W=\mu +\sigma \left({\frac {U_{1}}{U_{2}}}\right)^{\gamma }}$

and we write W ~ FP(μ, σ, γ, δ1, δ2). Special cases of the Feller–Pareto distribution are

${\displaystyle FP(\sigma ,\sigma ,1,1,\alpha )=P(I)(\sigma ,\alpha )}$
${\displaystyle FP(\mu ,\sigma ,1,1,\alpha )=P(II)(\mu ,\sigma ,\alpha )}$
${\displaystyle FP(\mu ,\sigma ,\gamma ,1,1)=P(III)(\mu ,\sigma ,\gamma )}$
${\displaystyle FP(\mu ,\sigma ,\gamma ,1,\alpha )=P(IV)(\mu ,\sigma ,\gamma ,\alpha ).}$

## Applications

Pareto originally used this distribution to describe the allocation of wealth among individuals since it seemed to show rather well the way that a larger portion of the wealth of any society is owned by a smaller percentage of the people in that society. He also used it to describe distribution of income.[8] This idea is sometimes expressed more simply as the Pareto principle or the "80-20 rule" which says that 20% of the population controls 80% of the wealth.[9] However, the 80-20 rule corresponds to a particular value of α, and in fact, Pareto's data on British income taxes in his Cours d'économie politique indicates that about 30% of the population had about 70% of the income. The probability density function (PDF) graph at the beginning of this article shows that the "probability" or fraction of the population that owns a small amount of wealth per person is rather high, and then decreases steadily as wealth increases. (Note that the Pareto distribution is not realistic for wealth for the lower end. In fact, net worth may even be negative.) This distribution is not limited to describing wealth or income, but to many situations in which an equilibrium is found in the distribution of the "small" to the "large". The following examples are sometimes seen as approximately Pareto-distributed:

Fitted cumulative Pareto (Lomax) distribution to maximum one-day rainfalls using CumFreq, see also distribution fitting
• The values of oil reserves in oil fields (a few large fields, many small fields)[10]
• The length distribution in jobs assigned supercomputers (a few large ones, many small ones)[13]
• The standardized price returns on individual stocks [10]
• Sizes of sand particles [10]
• The size of meteorites
• Severity of large casualty losses for certain lines of business such as general liability, commercial auto, and workers compensation.[14][15]
• In hydrology the Pareto distribution is applied to extreme events such as annually maximum one-day rainfalls and river discharges.[16] The blue picture illustrates an example of fitting the Pareto distribution to ranked annually maximum one-day rainfalls showing also the 90% confidence belt based on the binomial distribution. The rainfall data are represented by plotting positions as part of the cumulative frequency analysis.

## Relation to other distributions

### Relation to the exponential distribution

The Pareto distribution is related to the exponential distribution as follows. If X is Pareto-distributed with minimum xm and index α, then

${\displaystyle Y=\log \left({\frac {X}{x_{\mathrm {m} }}}\right)}$

is exponentially distributed with rate parameter α. Equivalently, if Y is exponentially distributed with rate α, then

${\displaystyle x_{\mathrm {m} }e^{Y}}$

is Pareto-distributed with minimum xm and index α.

This can be shown using the standard change-of-variable techniques:

{\displaystyle {\begin{aligned}\Pr(Y

The last expression is the cumulative distribution function of an exponential distribution with rate α.

### Relation to the log-normal distribution

The Pareto distribution and log-normal distribution are alternative distributions for describing the same types of quantities. One of the connections between the two is that they are both the distributions of the exponential of random variables distributed according to other common distributions, respectively the exponential distribution and normal distribution.[citation needed]

### Relation to the generalized Pareto distribution

The Pareto distribution is a special case of the generalized Pareto distribution, which is a family of distributions of similar form, but containing an extra parameter in such a way that the support of the distribution is either bounded below (at a variable point), or bounded both above and below (where both are variable), with the Lomax distribution as a special case. This family also contains both the unshifted and shifted exponential distributions.

The Pareto distribution with scale ${\displaystyle x_{m}}$  and shape ${\displaystyle \alpha }$  is equivalent to the generalized Pareto distribution with location ${\displaystyle \mu =x_{m}}$ , scale ${\displaystyle \sigma =x_{m}/\alpha }$  and shape ${\displaystyle \xi =1/\alpha }$ . Vice versa one can get the Pareto distribution from the GPD by ${\displaystyle x_{m}=\sigma /\xi }$  and ${\displaystyle \alpha =1/\xi }$ .

### Relation to Zipf's law

The Pareto distribution is continuous probability distribution. Zipf's law, also sometimes called the zeta distribution, is a discrete distribution, separating the values into a simple ranking. Both are a simple power law with a negative exponent, scaled so that their cumulative distributions equal 1. Zipf's can be derived from the Pareto distribution if the ${\displaystyle x}$  values (incomes) are binned into ${\displaystyle N}$  ranks so that the number of people in each bin follows a 1/rank pattern. The distribution is normalized by defining ${\displaystyle x_{m}}$  so that ${\displaystyle \alpha x_{\mathrm {m} }^{\alpha }={\frac {1}{H(N,\alpha -1)}}}$  where ${\displaystyle H(N,\alpha -1)}$  is the generalized harmonic number. This makes Zipf's probability density function derivable from Pareto's.

${\displaystyle f(x)={\frac {\alpha x_{\mathrm {m} }^{\alpha }}{x^{\alpha +1}}}={\frac {1}{x^{s}H(N,s)}}}$

where ${\displaystyle s=\alpha -1}$  and ${\displaystyle x}$  is an integer representing rank from 1 to N where N is the highest income bracket. So a randomly selected person (or word, website link, or city) from a population (or language, internet, or country) has ${\displaystyle f(x)}$  probability of ranking ${\displaystyle x}$ .

### Relation to the "Pareto principle"

The "80-20 law", according to which 20% of all people receive 80% of all income, and 20% of the most affluent 20% receive 80% of that 80%, and so on, holds precisely when the Pareto index is α = log4(5) = log(5)/log(4), approximately 1.161. This result can be derived from the Lorenz curve formula given below. Moreover, the following have been shown[17] to be mathematically equivalent:

• Income is distributed according to a Pareto distribution with index α > 1.
• There is some number 0 ≤ p ≤ 1/2 such that 100p % of all people receive 100(1 − p)% of all income, and similarly for every real (not necessarily integer) n > 0, 100pn % of all people receive 100(1 − p)n percentage of all income. α and p are related by
${\displaystyle 1-{\frac {1}{\alpha }}={\frac {\ln(1-p^{n})}{\ln(1-(1-p)^{n})}}}$

This does not apply only to income, but also to wealth, or to anything else that can be modeled by this distribution.

This excludes Pareto distributions in which 0 < α ≤ 1, which, as noted above, have infinite expected value, and so cannot reasonably model income distribution.

### Relation to Price's law

Price's square root law is sometimes offered as a property of or as similar to the Pareto distribution. However, the law only holds in the case that ${\displaystyle \alpha =1}$ . Note that in this case, the total and expected amount of wealth are not defined, and the rule only applies asymptotically to random samples. The extended Pareto Principle mentioned above is a far more general rule.

## Lorenz curve and Gini coefficient

Lorenz curves for a number of Pareto distributions. The case α = ∞ corresponds to perfectly equal distribution (G = 0) and the α = 1 line corresponds to complete inequality (G = 1)

The Lorenz curve is often used to characterize income and wealth distributions. For any distribution, the Lorenz curve L(F) is written in terms of the PDF f or the CDF F as

${\displaystyle L(F)={\frac {\int _{x_{\mathrm {m} }}^{x(F)}xf(x)\,dx}{\int _{x_{\mathrm {m} }}^{\infty }xf(x)\,dx}}={\frac {\int _{0}^{F}x(F')\,dF'}{\int _{0}^{1}x(F')\,dF'}}}$

where x(F) is the inverse of the CDF. For the Pareto distribution,

${\displaystyle x(F)={\frac {x_{\mathrm {m} }}{(1-F)^{\frac {1}{\alpha }}}}}$

and the Lorenz curve is calculated to be

${\displaystyle L(F)=1-(1-F)^{1-{\frac {1}{\alpha }}},}$

For ${\displaystyle 0<\alpha \leq 1}$  the denominator is infinite, yielding L=0. Examples of the Lorenz curve for a number of Pareto distributions are shown in the graph on the right.

According to Oxfam (2016) the richest 62 people have as much wealth as the poorest half of the world's population.[18] We can estimate the Pareto index that would apply to this situation. Letting ε equal ${\displaystyle 62/(7\times 10^{9})}$  we have:

${\displaystyle L(1/2)=1-L(1-\varepsilon )}$

or

${\displaystyle 1-(1/2)^{1-{\frac {1}{\alpha }}}=\varepsilon ^{1-{\frac {1}{\alpha }}}}$

The solution is that α equals about 1.15, and about 9% of the wealth is owned by each of the two groups. But actually the poorest 69% of the world adult population owns only about 3% of the wealth.[19]

The Gini coefficient is a measure of the deviation of the Lorenz curve from the equidistribution line which is a line connecting [0, 0] and [1, 1], which is shown in black (α = ∞) in the Lorenz plot on the right. Specifically, the Gini coefficient is twice the area between the Lorenz curve and the equidistribution line. The Gini coefficient for the Pareto distribution is then calculated (for ${\displaystyle \alpha \geq 1}$ ) to be

${\displaystyle G=1-2\left(\int _{0}^{1}L(F)\,dF\right)={\frac {1}{2\alpha -1}}}$

(see Aaberge 2005).

## Parameter estimation

The likelihood function for the Pareto distribution parameters α and xm, given an independent sample x = (x1x2, ..., xn), is

${\displaystyle L(\alpha ,x_{\mathrm {m} })=\prod _{i=1}^{n}\alpha {\frac {x_{\mathrm {m} }^{\alpha }}{x_{i}^{\alpha +1}}}=\alpha ^{n}x_{\mathrm {m} }^{n\alpha }\prod _{i=1}^{n}{\frac {1}{x_{i}^{\alpha +1}}}.}$

Therefore, the logarithmic likelihood function is

${\displaystyle \ell (\alpha ,x_{\mathrm {m} })=n\ln \alpha +n\alpha \ln x_{\mathrm {m} }-(\alpha +1)\sum _{i=1}^{n}\ln x_{i}.}$

It can be seen that ${\displaystyle \ell (\alpha ,x_{\mathrm {m} })}$  is monotonically increasing with xm, that is, the greater the value of xm, the greater the value of the likelihood function. Hence, since xxm, we conclude that

${\displaystyle {\widehat {x}}_{\mathrm {m} }=\min _{i}{x_{i}}.}$

To find the estimator for α, we compute the corresponding partial derivative and determine where it is zero:

${\displaystyle {\frac {\partial \ell }{\partial \alpha }}={\frac {n}{\alpha }}+n\ln x_{\mathrm {m} }-\sum _{i=1}^{n}\ln x_{i}=0.}$

Thus the maximum likelihood estimator for α is:

${\displaystyle {\widehat {\alpha }}={\frac {n}{\sum _{i}\ln(x_{i}/{\widehat {x}}_{\mathrm {m} })}}.}$

The expected statistical error is:[20]

${\displaystyle \sigma ={\frac {\widehat {\alpha }}{\sqrt {n}}}.}$

Malik (1970)[21] gives the exact joint distribution of ${\displaystyle ({\hat {x}}_{\mathrm {m} },{\hat {\alpha }})}$ . In particular, ${\displaystyle {\hat {x}}_{\mathrm {m} }}$  and ${\displaystyle {\hat {\alpha }}}$  are independent and ${\displaystyle {\hat {x}}_{\mathrm {m} }}$  is Pareto with scale parameter xm and shape parameter , whereas ${\displaystyle {\hat {\alpha }}}$  has an inverse-gamma distribution with shape and scale parameters n − 1 and , respectively.

## Graphical representation

The characteristic curved 'long tail' distribution when plotted on a linear scale, masks the underlying simplicity of the function when plotted on a log-log graph, which then takes the form of a straight line with negative gradient: It follows from the formula for the probability density function that for xxm,

${\displaystyle \log f_{X}(x)=\log \left(\alpha {\frac {x_{\mathrm {m} }^{\alpha }}{x^{\alpha +1}}}\right)=\log(\alpha x_{\mathrm {m} }^{\alpha })-(\alpha +1)\log x.}$

Since α is positive, the gradient −(α + 1) is negative.

## Random sample generation

Random samples can be generated using inverse transform sampling. Given a random variate U drawn from the uniform distribution on the unit interval (0, 1], the variate T given by

${\displaystyle T={\frac {x_{\mathrm {m} }}{U^{1/\alpha }}}}$

is Pareto-distributed.[22] If U is uniformly distributed on [0, 1), it can be exchanged with (1 − U).

## Variants

### Bounded Pareto distribution

Parameters ${\displaystyle L>0}$  location (real)${\displaystyle H>L}$  location (real) ${\displaystyle \alpha >0}$  shape (real) ${\displaystyle L\leqslant x\leqslant H}$ ${\displaystyle {\frac {\alpha L^{\alpha }x^{-\alpha -1}}{1-\left({\frac {L}{H}}\right)^{\alpha }}}}$ ${\displaystyle {\frac {1-L^{\alpha }x^{-\alpha }}{1-\left({\frac {L}{H}}\right)^{\alpha }}}}$ ${\displaystyle {\frac {L^{\alpha }}{1-\left({\frac {L}{H}}\right)^{\alpha }}}\cdot \left({\frac {\alpha }{\alpha -1}}\right)\cdot \left({\frac {1}{L^{\alpha -1}}}-{\frac {1}{H^{\alpha -1}}}\right),\alpha \neq 1}$ ${\displaystyle L\left(1-{\frac {1}{2}}\left(1-\left({\frac {L}{H}}\right)^{\alpha }\right)\right)^{-{\frac {1}{\alpha }}}}$ ${\displaystyle {\frac {L^{\alpha }}{1-\left({\frac {L}{H}}\right)^{\alpha }}}\cdot \left({\frac {\alpha }{\alpha -2}}\right)\cdot \left({\frac {1}{L^{\alpha -2}}}-{\frac {1}{H^{\alpha -2}}}\right),\alpha \neq 2}$  (this is the second raw moment, not the variance) ${\displaystyle {\frac {L^{\alpha }}{1-\left({\frac {L}{H}}\right)^{\alpha }}}\cdot {\frac {\alpha *(L^{k-\alpha }-H^{k-\alpha })}{(\alpha -k)}},\alpha \neq j}$  (this is the kth raw moment, not the skewness)

The bounded (or truncated) Pareto distribution has three parameters: α, L and H. As in the standard Pareto distribution α determines the shape. L denotes the minimal value, and H denotes the maximal value.

${\displaystyle {\frac {\alpha L^{\alpha }x^{-\alpha -1}}{1-\left({\frac {L}{H}}\right)^{\alpha }}}}$ ,

where L ≤ x ≤ H, and α > 0.

#### Generating bounded Pareto random variables

If U is uniformly distributed on (0, 1), then applying inverse-transform method [23]

${\displaystyle U={\frac {1-L^{\alpha }x^{-\alpha }}{1-({\frac {L}{H}})^{\alpha }}}}$
${\displaystyle x=\left(-{\frac {UH^{\alpha }-UL^{\alpha }-H^{\alpha }}{H^{\alpha }L^{\alpha }}}\right)^{-{\frac {1}{\alpha }}}}$

is a bounded Pareto-distributed.[citation needed]

### Symmetric Pareto distribution

The symmetric Pareto distribution can be defined by the probability density function:[24]

${\displaystyle f(x;\alpha ,x_{\mathrm {m} })={\begin{cases}{\tfrac {1}{2}}\alpha x_{\mathrm {m} }^{\alpha }|x|^{-\alpha -1}&|x|>x_{\mathrm {m} }\\0&{\text{otherwise}}.\end{cases}}}$

It has a similar shape to a Pareto distribution for x > xm and is mirror symmetric about the vertical axis.

## Multivariate Pareto distribution

The univariate Pareto distribution has been extended to a multivariate Pareto distribution.[25]

## References

1. ^ a b c d Barry C. Arnold (1983). Pareto Distributions. International Co-operative Publishing House. ISBN 978-0-89974-012-6.
2. ^ a b Johnson NL, Kotz S, Balakrishnan N (1994) Continuous univariate distributions Vol 1. Wiley Series in Probability and Statistics.
3. ^ a b c d Johnson, Kotz, and Balakrishnan (1994), (20.4).
4. ^ Christian Kleiber & Samuel Kotz (2003). Statistical Size Distributions in Economics and Actuarial Sciences. Wiley. ISBN 978-0-471-15064-0.
5. ^ a b Feller, W. (1971). An Introduction to Probability Theory and its Applications. II (2nd ed.). New York: Wiley. p. 50. "The densities (4.3) are sometimes called after the economist Pareto. It was thought (rather naïvely from a modern statistical standpoint) that income distributions should have a tail with a density ~ Axα as x → ∞."
6. ^ Lomax, K. S. (1954). "Business failures. Another example of the analysis of failure data". Journal of the American Statistical Association. 49 (268): 847–52. doi:10.1080/01621459.1954.10501239.
7. ^ Chotikapanich, Duangkamon. "Chapter 7: Pareto and Generalized Pareto Distributions". Modeling Income Distributions and Lorenz Curves. pp. 121–22.
8. ^ Pareto, Vilfredo, Cours d'Économie Politique: Nouvelle édition par G.-H. Bousquet et G. Busino, Librairie Droz, Geneva, 1964, pp. 299–345.
9. ^ For a two-quantile population, where approximately 18% of the population owns 82% of the wealth, the Theil index takes the value 1.
10. Reed, William J.; et al. (2004). "The Double Pareto-Lognormal Distribution – A New Parametric Model for Size Distributions". Communications in Statistics – Theory and Methods. 33 (8): 1733–53. CiteSeerX 10.1.1.70.4555. doi:10.1081/sta-120037438.
11. ^ Schroeder, Bianca; Damouras, Sotirios; Gill, Phillipa (2010-02-24). "Understanding latent sector error and how to protect against them" (PDF). 8th Usenix Conference on File and Storage Technologies (FAST 2010). Retrieved 2010-09-10. We experimented with 5 different distributions (Geometric,Weibull, Rayleigh, Pareto, and Lognormal), that are commonly used in the context of system reliability, and evaluated their fit through the total squared differences between the actual and hypothesized frequencies (χ2 statistic). We found consistently across all models that the geometric distribution is a poor fit, while the Pareto distribution provides the best fit.
12. ^ Yuji Ijiri; Simon, Herbert A. (May 1975). "Some Distributions Associated with Bose–Einstein Statistics". Proc. Natl. Acad. Sci. USA. 72 (5): 1654–57. Bibcode:1975PNAS...72.1654I. doi:10.1073/pnas.72.5.1654. PMC 432601. PMID 16578724.
13. ^ Harchol-Balter, Mor; Downey, Allen (August 1997). "Exploiting Process Lifetime Distributions for Dynamic Load Balancing" (PDF). ACM Transactions on Computer Systems. 15 (3): 253–258. doi:10.1145/263326.263344.
14. ^ Kleiber and Kotz (2003): p. 94.
15. ^ Seal, H. (1980). "Survival probabilities based on Pareto claim distributions". ASTIN Bulletin. 11: 61–71. doi:10.1017/S0515036100006620.
16. ^ CumFreq, software for cumulative frequency analysis and probability distribution fitting [1]
17. ^ Hardy, Michael (2010). "Pareto's Law". Mathematical Intelligencer. 32 (3): 38–43. doi:10.1007/s00283-010-9159-2.
18. ^ "62 people own the same as half the world, reveals Oxfam Davos report". Oxfam. Jan 2016.
19. ^ "Global Wealth Report 2013". Credit Suisse. Oct 2013. p. 22.
20. ^ M. E. J. Newman (2005). "Power laws, Pareto distributions and Zipf's law". Contemporary Physics. 46 (5): 323–51. arXiv:cond-mat/0412004. Bibcode:2005ConPh..46..323N. doi:10.1080/00107510500052444.
21. ^ H. J. Malik (1970). "Estimation of the Parameters of the Pareto Distribution". Metrika. 15: 126–132. doi:10.1007/BF02613565.
22. ^ Tanizaki, Hisashi (2004). Computational Methods in Statistics and Econometrics. CRC Press. p. 133. ISBN 9780824750886.
23. ^ http://www.cs.bgu.ac.il/~mps042/invtransnote.htm
24. ^ Grabchak, M. & Samorodnitsky, D. "Do Financial Returns Have Finite or Infinite Variance? A Paradox and an Explanation" (PDF). pp. 7–8.
25. ^ Rootzén, Holger; Tajvidi, Nader (2006). "Multivariate generalized Pareto distributions". Bernoulli. 12 (5): 917–30. CiteSeerX 10.1.1.145.2991. doi:10.3150/bj/1161614952.

## Notes

• Pareto, Vilfredo (1965). Librairie Droz (ed.). "Ecrits sur la courbe de la répartition de la richesse". Œuvres complètes : T. III: 48. ISBN 9782600040211.
• Pareto, Vilfredo (1895). "La legge della domanda". Giornale Degli Economisti. 10: 59–68.