Exponential family

In probability theory and statistics , an exponential family (or exponential family ) is a class of probability distributions of a very specific form. One chooses this special form in order to take advantage of certain computational advantages or for reasons of generalization. In a certain sense, exponential families are very natural distributions and a dominated distribution class , which brings many simplifications in handling with it. The concept of exponential families goes back to EJG Pitman , G. Darmois , and BO Koopman (1935–6).

One-parameter exponential family

definition

A family of probability measures on the measurement space with is called a one-parameter exponential family if there is a σ-finite measure such that all are a density function of the shape ${\ displaystyle (P _ {\ vartheta}) _ {\ vartheta \ in \ Theta}}$ ${\ displaystyle (X, {\ mathcal {A}})}$ ${\ displaystyle \ Theta \ subset \ mathbb {R}}$ ${\ displaystyle \ mu}$ ${\ displaystyle P _ {\ vartheta}}$

{\ displaystyle f (x, \ vartheta) = h (x) A (\ vartheta) \ exp (\ eta (\ vartheta) T (x))}

regarding own. Usually it is ${\ displaystyle \ mu}$ ${\ displaystyle \ mu}$

around the Lebesgue measure , the density functions are then conventional probability density functions (continuous case).
around the count , the density functions are then count densities (discrete case).

It is

{\ displaystyle T: (X, {\ mathcal {A}}) \ to (\ mathbb {R}, {\ mathcal {B}} (\ mathbb {R}))}

a measurable function , the natural sufficient statistics or canonical statistics of the exponential family. Likewise is

{\ displaystyle h: (X, {\ mathcal {A}}) \ to (\ mathbb {R}, {\ mathcal {B}} (\ mathbb {R}))}

a measurable function. The function

{\ displaystyle A: \ Theta \ to \ mathbb {R}}

is called the normalization function or normalization constant and guarantees that the normalization required in the definition of a probability measure is given. Furthermore is

{\ displaystyle \ eta: \ Theta \ to \ mathbb {R}}

any real function of the parameter.

Examples

The binomial distributions on with are an elementary example . They have the probability function (or the density function with regard to the count) ${\ displaystyle X = \ {1, \ dots, n \}}$ ${\ displaystyle {\ mathcal {A}} = {\ mathcal {P}} (X)}$

{\ displaystyle f (x, \ vartheta) = {\ binom {n} {x}} \ vartheta ^ {x} (1- \ vartheta) ^ {nx} = {\ binom {n} {x}} (1 - \ vartheta) ^ {n} \ exp \ left (x \ ln \ left ({\ frac {\ vartheta} {1- \ vartheta}} \ right) \ right)}

with . Thus the binomial distribution is part of an exponential family and is characterized by ${\ displaystyle \ vartheta \ in (0,1)}$

{\ displaystyle T (x) = x, \ quad, \ eta (\ vartheta) = \ ln \ left ({\ frac {\ vartheta} {1- \ vartheta}} \ right), \ quad A (\ vartheta) = (1- \ vartheta) ^ {n} {\ text {and}} h (x) = {\ binom {n} {x}}}

.

Another example is the exponential distributions . They are defined with and have the probability density function ${\ displaystyle ([0, \ infty), {\ mathcal {B}} ([0, \ infty))}$ ${\ displaystyle \ vartheta \ in (0, \ infty)}$

{\ displaystyle f (x, \ vartheta) = \ vartheta \ exp \ left (- \ vartheta x \ right)}

So in this case

{\ displaystyle T (x) = x, \ quad \ eta (\ vartheta) = - \ vartheta \, {\ text {and}} A (\ vartheta) = \ vartheta}

.

It should be noted that a one-parameter exponential family can be a multivariate distribution . Single-parameter here only means that the dimensionality of the "shape parameter" is one. Whether the defined probability distribution is univariate or multivariate depends on the dimensionality of the basic space , which is not subject to any requirements. ${\ displaystyle \ vartheta}$ ${\ displaystyle X}$

Alternative definitions

The definitions of an exponential family usually differ in the following points:

Not all authors write the functions and as a product in front of the exponential function, sometimes they are also used as a sum in the exponential function, sometimes with a negative sign. This is how the definitions can be found ${\ displaystyle h}$ ${\ displaystyle A}$

{\ displaystyle f (x, \ vartheta) = \ exp (\ eta (\ vartheta) T (x) + h ^ {*} (x) + A ^ {*} (\ vartheta)) {\ text {or alternatively }} f (x, \ vartheta) = h (x) \ exp (\ eta (\ vartheta) T (x) - {\ tilde {A}} (\ vartheta))}

.

These differently defined functions can usually be converted into one another without any problems. However, when specifying the functions and, it is important to note how precisely they are defined.

{\ displaystyle A}

{\ displaystyle h}

Some authors provide the density function with a characteristic function with respect to a set . The density function is then given as ${\ displaystyle M}$

{\ displaystyle f (x, \ vartheta) = \ chi _ {M} (x) h (x) A (\ vartheta) \ exp (\ eta (\ vartheta) T (x))}

.

The choice of the amount should be independent of the parameter . This definition enables certain criteria that are based on the positivity of the density function to be more general. Such criteria can be found, for example, in regular statistical models .

{\ displaystyle M}

{\ displaystyle \ vartheta}

k -parametric exponential family

definition

A family of probability measures on the measurement space with is called a k-parametric exponential family if there is a σ-finite measure such that all the density function ${\ displaystyle (P _ {\ vartheta}) _ {\ vartheta \ in \ Theta}}$ ${\ displaystyle (X, {\ mathcal {A}})}$ ${\ displaystyle \ Theta \ subset \ mathbb {R} ^ {k}}$ ${\ displaystyle \ mu}$ ${\ displaystyle P _ {\ vartheta}}$

{\ displaystyle f (x, \ vartheta) = h (x) A (\ vartheta) \ exp \ left (\ sum _ {i = 1} ^ {k} \ eta _ {i} (\ vartheta) T_ {i } (x) \ right)}

regarding own. The parameter is often written. Are there ${\ displaystyle \ mu}$ ${\ displaystyle \ vartheta = (\ vartheta _ {1}, \ dots, \ vartheta _ {k})}$

{\ displaystyle h, T_ {1}, \ dots, T_ {k} :( X, {\ mathcal {A}}) \ to (\ mathbb {R}, {\ mathcal {B}} (\ mathbb {R }))}

measurable functions and

{\ displaystyle A, \ eta _ {1}, \ dots, \ eta _ {k}: \ mathbb {R} ^ {k} \ supset \ Theta \ to \ mathbb {R}}

Functions of the k-dimensional parameter . Here, as in the one-parameter case, the function is called the natural sufficient statistics or the canonical statistics. ${\ displaystyle \ vartheta}$ ${\ displaystyle T = (T_ {1}, \ dots, T_ {k})}$

example

A classic example of a 2-parametric exponential family is the normal distribution . It is as well . Each is then of the form . With the parameterizations and one obtains the normal distribution from the usual density function ${\ displaystyle (X, {\ mathcal {A}}) = (\ mathbb {R}, {\ mathcal {B}} (\ mathbb {R}))}$ ${\ displaystyle \ Theta = \ mathbb {R} \ times (0, \ infty)}$ ${\ displaystyle \ vartheta \ in \ Theta}$ ${\ displaystyle \ vartheta = (\ vartheta _ {1}, \ vartheta _ {2})}$ ${\ displaystyle \ mu = \ vartheta _ {1}}$ ${\ displaystyle \ sigma ^ {2} = \ vartheta _ {2} ^ {2}}$

{\ displaystyle f (x, \ vartheta _ {1}, \ vartheta _ {2}) = {\ frac {1} {\ sqrt {2 \ pi \ vartheta _ {2} ^ {2}}}} \ exp \ left (- {\ frac {\ vartheta _ {1} ^ {2}} {2 \ vartheta _ {2} ^ {2}}} \ right) \ exp \ left ({\ frac {\ vartheta _ {1 }} {\ vartheta _ {2} ^ {2}}} x - {\ frac {1} {2 \ vartheta _ {2} ^ {2}}} x ^ {2} \ right)}

.

Thus, the normal distribution is part of a two-parameter exponential family with

{\ displaystyle A (\ vartheta _ {1}, \ vartheta _ {2}) = {\ frac {1} {\ sqrt {2 \ pi \ vartheta _ {2} ^ {2}}}} \ exp \ left (- {\ frac {\ vartheta _ {1} ^ {2}} {2 \ vartheta _ {2} ^ {2}}} \ right), \ quad T_ {1} (x) = x, \ quad T_ {2} (x) = x ^ {2}, \ quad \ eta _ {1} (\ vartheta _ {1}, \ vartheta _ {2}) = {\ frac {\ vartheta _ {1}} {\ vartheta _ {2} ^ {2}}}, \ quad \ eta _ {2} (\ vartheta _ {1}, \ vartheta _ {2}) = - {\ frac {1} {2 \ vartheta _ {2 } ^ {2}}}}

.

Here, too, the following applies again: a k-parametric exponential family can definitely describe a probability distribution in only one dimension. The number k only indicates the number of shape parameters, not the dimensionality of the distribution. In the above example, the normal distribution is one-dimensional, but part of a 2-parametric exponential family.

Another example of a 2-parametric exponential family is the gamma distribution .

Alternative definitions

For the k-parametric exponential family, the same variants exist in the definition as were already discussed in the one-parametric case. In addition, some authors require in the definition that the following two properties apply:

The functions are linearly independent ${\ displaystyle \ eta _ {1}, \ dots, \ eta _ {k}}$
The functions are almost certainly linearly independent for everyone . ${\ displaystyle 1, T_ {1}, \ dots, T_ {k}}$ ${\ displaystyle P _ {\ vartheta}}$

With these additional requirements, statements can be made about the covariance matrix of , for example . ${\ displaystyle T}$

The natural parameterization

In both the one-parametric and the k-parametric case, it is said that the exponential family is present in the natural parameterization if is. ${\ displaystyle \ eta (\ vartheta) = \ vartheta}$

properties

Sufficiency

For the exponential family, canonical statistics are always sufficient statistics . This follows directly from the Neyman criterion for sufficiency. Therefore it is also referred to as natural sufficient statistics. ${\ displaystyle T}$ ${\ displaystyle T}$

Score function

For a one-parameter exponential family the score function is given by

{\ displaystyle S _ {\ vartheta} (x): = {\ frac {\ partial} {\ partial \ vartheta}} \ ln f (x, \ vartheta) = \ eta '(\ vartheta) T (x) + { \ frac {A '(\ vartheta)} {A (\ vartheta)}}}

.

With natural parameterization this is simplified to

{\ displaystyle S _ {\ vartheta} (x) = T (x) + {\ frac {A '(\ vartheta)} {A (\ vartheta)}}}

.

Fisher information

The Fisher information can be derived from the score function . it is

{\ displaystyle I (\ vartheta) = \ operatorname {Var} _ {\ vartheta} (S _ {\ vartheta}) = \ left [\ eta '(\ vartheta) \ right] ^ {2} \ cdot \ operatorname {Var } _ {\ vartheta} (T (x))}

.

With natural parameterization, the Fisher information thus results

{\ displaystyle I (\ vartheta) = \ operatorname {Var} _ {\ vartheta} (T (x))}

.

Role in statistics

Classic appreciation: sufficiency

According to the Pitman-Koopman-Darmois theorem , among probability families whose support does not depend on the parameters there are sufficient statistics only among the exponential families , the dimensions of which remain limited as the sample size increases. A little more detailed: Let be independently and identically distributed random variables whose probability distribution family is known. Only if this family is an exponential family is there a (possibly vectorial) sufficient statistic whose number of scalar components does not increase if the sample size is increased. ${\ displaystyle X_ {n}, \ n = 1,2,3, \ dots}$ ${\ displaystyle T (X_ {1}, \ dots, X_ {n})}$ ${\ displaystyle n}$

Bayesian estimation: conjugate distributions

Exponential families are also important for Bayesian statistics . In Bayesian statistics, an a priori probability distribution is multiplied by a likelihood function and then normalized in order to arrive at the a posteriori probability distribution (see Bayes' theorem ). If the likelihood belongs to an exponential family, there also exists a family of conjugate a priori distributions, which is often also an exponential family. An a priori conjugate distribution for the parameter of an exponential family is defined by ${\ displaystyle \ pi}$ ${\ displaystyle \ eta}$

{\ displaystyle \ pi (\ eta) \ propto \ exp (- \ eta ^ {\ top} \ alpha - \ beta \, A (\ eta)),}

where and are hyperparameters (parameters that are not estimated, but rather determined within the framework of the model). ${\ displaystyle \ alpha \ in \ mathbb {R} ^ {n}}$ ${\ displaystyle \ beta> 0}$

In general, the likelihood function does not belong to any exponential family, which is why there is generally no conjugate a priori distribution. The posterior distribution must then be calculated using numerical methods.

Hypothesis tests: equally best test

The one-parametric exponential family is one of the distribution classes with a monotonic density quotient in canonical statistics if is monotonically increasing. Therefore, for the one-sided test problem with ${\ displaystyle T}$ ${\ displaystyle \ eta}$

{\ displaystyle \ Theta _ {0} = \ {\ vartheta \ in \ Theta \, | \, \ vartheta \ leq \ vartheta _ {0} \} \ quad {\ text {and}} \ quad \ Theta _ { 1} = \ {\ vartheta \ in \ Theta \, | \, \ vartheta> \ vartheta _ {0} \}}

a consistently best test at a given level . An explicit description of the test with sketched derivation from the Neyman-Pearson lemma can be found here . ${\ displaystyle \ alpha}$

literature

EL Lehmann, Casella, G .: Theory of Point Estimation 1998, ISBN 0-387-98502-6 , S. 2nd ed., Sec. 1.5.
Robert W. Keener: Statistical Theory: Notes for a Course in Theoretical Statistics . Springer, 2006, pp. 27-28, 32-33.
Hans-Otto Georgii : Stochastics . Introduction to probability theory and statistics. 4th edition. Walter de Gruyter, Berlin 2009, ISBN 978-3-11-021526-7 , doi : 10.1515 / 9783110215274 .
Ludger Rüschendorf: Mathematical Statistics . Springer Verlag, Berlin Heidelberg 2014, ISBN 978-3-642-41996-6 , doi : 10.1007 / 978-3-642-41997-3 .
Claudia Czado, Thorsten Schmidt: Mathematical Statistics . Springer-Verlag, Berlin Heidelberg 2011, ISBN 978-3-642-17260-1 , doi : 10.1007 / 978-3-642-17261-8 .

Individual evidence

↑ Erling Andersen: Sufficiency and Exponential Families for Discrete Sample Spaces . In: Journal of the American Statistical Association . 65, No. 331, September 1970, pp. 1248-1255. doi : 10.2307 / 2284291 .
^ E. Pitman: Sufficient statistics and intrinsic accuracy . In: Proc. Camb. phil. Soc. . 32, 1936, pp. 567-579.
↑ G. Darmois: Sur les lois de probabilites a estimation exhaustive . In: CR Acad. sci. Paris . 200, 1935, pp. 1265-1266.
^ B Koopman: On distribution admitting a sufficient statistic . In: Trans. Amer. math. Soc. . 39, 1936, pp. 399-409. doi : 10.2307 / 1989758 .

[1] Erling Andersen: Sufficiency and Exponential Families for Discrete Sample Spaces . In: Journal of the American Statistical Association . 65, No. 331, September 1970, pp. 1248-1255. doi : 10.2307 / 2284291 .

[2] E. Pitman: Sufficient statistics and intrinsic accuracy . In: Proc. Camb. phil. Soc. . 32, 1936, pp. 567-579.

[3] G. Darmois: Sur les lois de probabilites a estimation exhaustive . In: CR Acad. sci. Paris . 200, 1935, pp. 1265-1266.

[4] B Koopman: On distribution admitting a sufficient statistic . In: Trans. Amer. math. Soc. . 39, 1936, pp. 399-409. doi : 10.2307 / 1989758 .