Asymptotic expectancy

The asymptotic fidelity to expectations , also called asymptotic undistortion or asymptotic undistorted , is a property of a point estimator in mathematical statistics . Asymptotically unambiguous estimators are clearly those which are not unambiguous for finite samples, i.e. have a systematic bias . However, this disappears in the limit value with ever larger sample sizes.

definition

Given is a statistical model that formalizes the infinite repetition of an experiment. Furthermore, let it be a series of point estimates ${\ displaystyle (X ^ {\ mathbb {N}}, {\ mathcal {A}} ^ {\ mathbb {N}}, (P _ {\ vartheta} ^ {\ mathbb {N}}) _ {\ vartheta \ in \ Theta})}$

{\ displaystyle T_ {n} \ colon X ^ {n} \ to \ mathbb {R}}

given and a function to be estimated

{\ displaystyle g \ colon \ Theta \ to \ mathbb {R}}

.

Then the sequence is called asymptotically unbiased if ${\ displaystyle T_ {n}}$

{\ displaystyle \ lim _ {n \ to \ infty} \ operatorname {E} _ {\ vartheta} (T_ {n}) = g (\ vartheta)}

for everyone .

{\ displaystyle \ vartheta \ in \ Theta}

It denotes the expected value with regard to the probability measure . ${\ displaystyle \ operatorname {E} _ {\ vartheta}}$ ${\ displaystyle P _ {\ vartheta} ^ {\ mathbb {N}}}$

example

A typical asymptotically unbiased estimator arises in the normal distribution model if the variance is estimated using the maximum likelihood method when the expected value is unknown .

The statistical model is given by

{\ displaystyle (\ mathbb {R} ^ {\ mathbb {N}}, {\ mathcal {B}} (\ mathbb {R} ^ {\ mathbb {N}}), {\ mathcal {N}} _ { \ mu, \ sigma ^ {2}} ^ {\ otimes \ mathbb {N}})}

for , the maximum likelihood estimator for a sample of size through ${\ displaystyle (\ mu, \ sigma ^ {2}) \ in \ mathbb {R} \ times (0, \ infty)}$ ${\ displaystyle n}$

{\ displaystyle T_ {n} (X) = {\ frac {1} {n}} \ sum _ {i = 1} ^ {n} \ left (X_ {i} - {\ tfrac {1} {n} } \ sum _ {j = 1} ^ {n} X_ {j} \ right) ^ {2}}

,

the (uncorrected) sample variance. The function to be estimated is

{\ displaystyle g (\ sigma) = \ sigma ^ {2}}

For the sake of simplicity, denote the corresponding probability distribution of the statistical model. Then according to this calculation ${\ displaystyle P (\ mu, \ sigma ^ {2}) = {\ mathcal {N}} _ {\ mu, \ sigma ^ {2}} ^ {\ otimes \ mathbb {N}}}$

{\ displaystyle \ operatorname {E} _ {P (\ mu, \ sigma ^ {2})} (T_ {n}) = {\ frac {n-1} {n}} \ sigma ^ {2}}

.

The estimator is therefore not true to expectations. In particular, applies to the distortion

{\ displaystyle \ operatorname {Bias} _ {T_ {n}} (\ sigma) = {\ frac {\ sigma ^ {2}} {n}}}

The estimator is asymptotically true to expectations, because it is

{\ displaystyle \ lim _ {n \ to \ infty} \ operatorname {E} _ {P (\ mu, \ sigma ^ {2})} (T_ {n}) = \ sigma ^ {2} = g (\ sigma)}

.

More general formulations

There are even more general formulations than those given above. The prerequisites that it is always a repetition of the same experiment (infinite product model) are dropped.

Formally, a probability space is then defined for as well as a sequence of random variables on this probability space. ${\ displaystyle (\ Omega, {\ mathcal {A}}, P _ {\ vartheta})}$ ${\ displaystyle \ vartheta \ in \ Theta}$ ${\ displaystyle (X_ {i}) _ {i \ in \ mathbb {N}}}$

A sequence of point estimators is called asymptotically fair-to-expectation for the function if ${\ displaystyle T_ {n} = T_ {n} (X_ {1}, X_ {2}, \ dots, X_ {n})}$ ${\ displaystyle g}$

{\ displaystyle \ lim _ {n \ to \ infty} \ operatorname {E} _ {\ vartheta} {\ bigl (} T_ {n} (X_ {1}, X_ {2}, \ dots, X_ {n} ) {\ bigr)} = g (\ vartheta)}

for everyone . ${\ displaystyle \ vartheta \ in \ Theta}$

Web links

OV Shalaevskii: Asymptotically-unbiased estimator . In: Michiel Hazewinkel (Ed.): Encyclopaedia of Mathematics . Springer-Verlag , Berlin 2002, ISBN 978-1-55608-010-4 (English, online ).

literature

Ludger Rüschendorf: Mathematical Statistics . Springer Verlag, Berlin Heidelberg 2014, ISBN 978-3-642-41996-6 , doi : 10.1007 / 978-3-642-41997-3 .
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 .
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

^ Georgii: Stochastics. 2009, p. 200.
^ Rüschendorf: Mathematical Statistics. 2014, p. 351.
↑ Czado, Schmidt: Mathematical Statistics. 2011, p. 105.

[1] Georgii: Stochastics. 2009, p. 200.

[2] Rüschendorf: Mathematical Statistics. 2014, p. 351.

[3] Czado, Schmidt: Mathematical Statistics. 2011, p. 105.