Parameters (statistics)

In statistics , aggregating parameters or measures summarize the essential properties of a frequency distribution , e.g. B. a longer series of measurement data, or a probability distribution .

Some parameters of descriptive statistics correspond to the moments of random variables .

The term parameter is also used in distribution models, in which case one speaks of distribution parameters . It is then usually one of several quantities that, together with the distribution class, determine the exact form of a distribution.

Location parameters

The median (here ) divides the mass of the distribution ${\ displaystyle {\ tfrac {\ ln 2} {\ lambda}}}$
The expected value (here ) is the focus of the distribution ${\ displaystyle {\ tfrac {1} {\ lambda}}}$

The definitions of location parameters aim to describe the location of the sample elements or the elements of the population in relation to the measurement scale . They combine a number of values or a variable that depends on chance (e.g. time until the next decay of an atom) into a single number - the central tendency - which represents the values as well as possible.

definition

Be a sample. A function is called a measure of position if it is translation-equivalent: ${\ displaystyle x_ {1}, \ dots, x_ {n} \ in \ mathbb {R}}$ ${\ displaystyle l: x_ {1}, \ dots, x_ {n} \ mapsto \ mathbb {R}}$

{\ displaystyle l (x_ {1} + a, \ dots, x_ {n} + a) = l (x_ {1}, \ dots, x_ {n}) + a}

With

{\ displaystyle a \ in \ mathbb {R}}

Examples

In descriptive statistics, the location parameters of a distribution are:

Arithmetic mean : ${\ displaystyle l _ {\ text {arithm.}} (x_ {1}, \ dots, x_ {n}) = {\ frac {1} {n}} (x_ {1} + \ cdots + x_ {n} )}$
empirical quantiles : median , quartile , decile , percentile
mode

For the three first mentioned position parameters as well as mode and median see also mean .

In the case of random variables, one speaks of the expected value .

According to the definition above, the following parameters are not position measurements:

Geometric mean : ${\ displaystyle l _ {\ text {geom.}} (x_ {1}, \ dots, x_ {n}) = {\ sqrt [{n}] {x_ {1} \ cdot x_ {2} \ dotsm x_ { n}}}}$
Harmonic mean : ${\ displaystyle l _ {\ text {harm.}} (x_ {1}, \ dots, x_ {n}) = {\ frac {n} {{\ frac {1} {x_ {1}}} + \ cdots + {\ frac {1} {x_ {n}}}}}}$

Dispersion parameters

A measure of dispersion or measure of dispersion (also known as dispersion parameter ) is understood to be statistical key figures , the determination of which enables statements to be made about the distribution of measured values, for example from weighing and counting, around the center point. In descriptive statistics , one describes the scatter (or dispersion; also variation ) with the following measures :

empirical variance , also called (ambiguous) sample variance, the mean squared deviation from the arithmetic mean
Empirical standard deviation , the square root of the empirical variance
Span , (the difference between the largest and smallest observation English range )
Mean absolute deviation from the arithmetic mean
Interquartile range , which contains the middle 50% of the observations (English interquartile range )

Concentration parameters

Shape dimensions or parameters

Individual evidence

^ Norbert Henze: Measure and probability theory (Stochastics II) . Karlsruhe 2010, p. 127 .
^ Andreas Büchter, H.-W. Henn: Elementary Stochastics - An Introduction . 2nd Edition. Springer, 2007, ISBN 978-3-540-45382-6 , pp. 71 .

[1] Norbert Henze: Measure and probability theory (Stochastics II) . Karlsruhe 2010, p. 127 .

[2] Andreas Büchter, H.-W. Henn: Elementary Stochastics - An Introduction . 2nd Edition. Springer, 2007, ISBN 978-3-540-45382-6 , pp. 71 .