Difference between revisions of "Cauchy distribution"
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A continuous probability distribution with density | A continuous probability distribution with density | ||
| − | + | $$ | |
| + | p (x; \lambda , \mu ) = \ | ||
| + | { | ||
| + | \frac{1} \pi | ||
| + | } | ||
| + | |||
| + | \frac \lambda {\lambda ^ {2} + (x - \mu ) ^ {2} } | ||
| + | ,\ \ | ||
| + | - \infty < x < \infty , | ||
| + | $$ | ||
and distribution function | and distribution function | ||
| − | + | $$ | |
| + | F (x; \lambda , \mu ) = \ | ||
| + | { | ||
| + | \frac{1}{2} | ||
| + | } + { | ||
| + | \frac{1} \pi | ||
| + | } \ | ||
| + | \mathop{\rm arctan} | ||
| + | \frac{x - \mu } \lambda | ||
| + | , | ||
| + | $$ | ||
| − | where < | + | where $ - \infty < \mu < \infty $ |
| + | and $ \lambda > 0 $ | ||
| + | are parameters. The Cauchy distribution is unimodal and symmetric about the point $ x = \mu $, | ||
| + | which is its mode and median. No moments of positive order — including the expectation — exist. The characteristic function has the form $ \mathop{\rm exp} ( i \mu t - \lambda | t | ) $. | ||
| + | The class of Cauchy distributions is closed under linear transformations: If a random variable $ X $ | ||
| + | has the Cauchy distribution with parameters $ \lambda $ | ||
| + | and $ \mu $, | ||
| + | then the random variable $ Y = aX + b $ | ||
| + | also has a Cauchy distribution, with parameters $ \lambda ^ \prime = | a | \lambda $ | ||
| + | and $ \mu ^ \prime = a \mu + b $. | ||
| + | The class of Cauchy distributions is closed under convolution: | ||
| − | + | $$ \tag{* } | |
| + | p (x; \lambda _ {1} , \mu _ {1} ) | ||
| + | * \dots * p (x; \lambda _ {n} , \mu _ {n} ) = | ||
| + | $$ | ||
| − | + | $$ | |
| + | = \ | ||
| + | p (x; \lambda _ {1} + \dots + \lambda _ {n} , \mu _ {1} + \dots + \mu _ {n} ) ; | ||
| + | $$ | ||
| − | in other words, a sum of independent random variables with Cauchy distributions is again a random variable with a Cauchy distribution. Thus, the Cauchy distribution, like the normal distribution, belongs to the class of stable distributions; to be precise: It is a symmetric stable distribution with index 1 (cf. [[Stable distribution|Stable distribution]]). The following property of Cauchy distributions is a corollary of (*): If | + | in other words, a sum of independent random variables with Cauchy distributions is again a random variable with a Cauchy distribution. Thus, the Cauchy distribution, like the normal distribution, belongs to the class of stable distributions; to be precise: It is a symmetric stable distribution with index 1 (cf. [[Stable distribution|Stable distribution]]). The following property of Cauchy distributions is a corollary of (*): If $ X _ {1} \dots X _ {n} $ |
| + | are independent random variables with the same Cauchy distribution, then their arithmetic mean $ (X _ {1} + \dots + X _ {n} ) /n $ | ||
| + | has the same distribution as each $ X _ {k} $. | ||
| + | One more property of Cauchy distributions: In the family of Cauchy distributions, the distribution of a sum of random variables may be given by (*) even if the variables are dependent. For example, if $ X $ | ||
| + | and $ Y $ | ||
| + | are independent and have the same Cauchy distribution, then the random variables $ X + X $ | ||
| + | and $ X + Y $ | ||
| + | have the same Cauchy distribution. The Cauchy distribution with parameters $ \lambda = 1 $ | ||
| + | and $ \mu = 0 $ | ||
| + | is the Student $ t $- | ||
| + | distribution with one degree of freedom. The Cauchy distribution with parameters $ ( \lambda , \mu ) $ | ||
| + | is identical with the distribution of the random variable $ \mu + ( X/Y ) $, | ||
| + | where $ X $ | ||
| + | and $ Y $ | ||
| + | are independent and normally distributed with parameters $ (0, \lambda ^ {2} ) $ | ||
| + | and $ (0, 1) $, | ||
| + | respectively. A random variable with this distribution is the function $ \mu + \lambda \mathop{\rm tan} z $, | ||
| + | where $ z $ | ||
| + | is a random variable uniformly distributed on the interval $ [- \pi /2, \pi /2] $. | ||
| + | The Cauchy distribution is also defined in spaces of dimension greater than one. The concept was first investigated by A.L. Cauchy. | ||
====References==== | ====References==== | ||
Latest revision as of 15:35, 4 June 2020
2020 Mathematics Subject Classification: Primary: 60E07 [MSN][ZBL]
A continuous probability distribution with density
$$ p (x; \lambda , \mu ) = \ { \frac{1} \pi } \frac \lambda {\lambda ^ {2} + (x - \mu ) ^ {2} } ,\ \ - \infty < x < \infty , $$
and distribution function
$$ F (x; \lambda , \mu ) = \ { \frac{1}{2} } + { \frac{1} \pi } \ \mathop{\rm arctan} \frac{x - \mu } \lambda , $$
where $ - \infty < \mu < \infty $ and $ \lambda > 0 $ are parameters. The Cauchy distribution is unimodal and symmetric about the point $ x = \mu $, which is its mode and median. No moments of positive order — including the expectation — exist. The characteristic function has the form $ \mathop{\rm exp} ( i \mu t - \lambda | t | ) $. The class of Cauchy distributions is closed under linear transformations: If a random variable $ X $ has the Cauchy distribution with parameters $ \lambda $ and $ \mu $, then the random variable $ Y = aX + b $ also has a Cauchy distribution, with parameters $ \lambda ^ \prime = | a | \lambda $ and $ \mu ^ \prime = a \mu + b $. The class of Cauchy distributions is closed under convolution:
$$ \tag{* } p (x; \lambda _ {1} , \mu _ {1} ) * \dots * p (x; \lambda _ {n} , \mu _ {n} ) = $$
$$ = \ p (x; \lambda _ {1} + \dots + \lambda _ {n} , \mu _ {1} + \dots + \mu _ {n} ) ; $$
in other words, a sum of independent random variables with Cauchy distributions is again a random variable with a Cauchy distribution. Thus, the Cauchy distribution, like the normal distribution, belongs to the class of stable distributions; to be precise: It is a symmetric stable distribution with index 1 (cf. Stable distribution). The following property of Cauchy distributions is a corollary of (*): If $ X _ {1} \dots X _ {n} $ are independent random variables with the same Cauchy distribution, then their arithmetic mean $ (X _ {1} + \dots + X _ {n} ) /n $ has the same distribution as each $ X _ {k} $. One more property of Cauchy distributions: In the family of Cauchy distributions, the distribution of a sum of random variables may be given by (*) even if the variables are dependent. For example, if $ X $ and $ Y $ are independent and have the same Cauchy distribution, then the random variables $ X + X $ and $ X + Y $ have the same Cauchy distribution. The Cauchy distribution with parameters $ \lambda = 1 $ and $ \mu = 0 $ is the Student $ t $- distribution with one degree of freedom. The Cauchy distribution with parameters $ ( \lambda , \mu ) $ is identical with the distribution of the random variable $ \mu + ( X/Y ) $, where $ X $ and $ Y $ are independent and normally distributed with parameters $ (0, \lambda ^ {2} ) $ and $ (0, 1) $, respectively. A random variable with this distribution is the function $ \mu + \lambda \mathop{\rm tan} z $, where $ z $ is a random variable uniformly distributed on the interval $ [- \pi /2, \pi /2] $. The Cauchy distribution is also defined in spaces of dimension greater than one. The concept was first investigated by A.L. Cauchy.
References
| [F] | W. Feller, "An introduction to probability theory and its applications", 2 , Wiley (1966) |
Cauchy distribution. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Cauchy_distribution&oldid=26375