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'''Percentiles''' are statistical parameters which describe the distribution
of a (real) value in a population (or a sample).
Roughly speaking, the ''k''-th percentile separates the smallest ''p'' percent
of values from the largest (100-''p'') percent.
Special percentiles are the [[median]] (50th percentile),
the quartiles (25th and 75th percentile),
and the deciles (the ''k''-th decile is the (10''k'')-th percentile).
Percentiles are special cases of [[quantile]]s:
The ''k''-th percentile is the same as the (''k''/100)-quantile.
== Definition ==
The value ''x'' is  ''k''-th percentile if
:    <math> P(\omega\le x) \ge {k\over100}    \textrm{\ \ and \ \ }
            P(\omega\ge x) \le 1-{k\over100}  </math>
== Special cases ==
For a continuous distribution (like the [[normal distribution]]) the
''k''-th percentile ''x'' is uniquely determined by
:    <math> P(\omega\le x) = {k\over100}    \textrm{\ \ and \ \ }
            P(\omega\ge x) = 1-{k\over100}  </math>
In the general case (e.g., for discrete distributions, or for finite samples)
it may happen that the separating value has positive probability:
:    <math> P(\omega = x) > 0 \Rightarrow
            P(\omega\le x) > {k\over100}    \textrm{\ \ and \ \ }
            P(\omega\ge x) > 1-{k\over100}  </math>
or that there are two distinct values for which equality holds
<math> x_1 < x_2 </math> such that
:    <math> P(\omega\le x_1) = {k\over100}    \textrm{\ \ and \ \ }
            P(\omega\ge x_2) = 1-{k\over100}  </math>
Then every value in the (closed) intervall between the smallest and the largest such value
<math> \left [ \min \{ x \mid P(\omega\le x) = {k\over100} \},
              \max \[ x \mid P(\omega\ge x) = 1-{k\over100} \} \right]</math>
is a ''k''-th percentiles.
== Example ==
The following examples illustrates this:
Take a sample of 101 values, ordered according to their size:
:  <math> x_1 \le x_2 \le \dots \le x_{100} \le x_{101} </math>
Then the unique ''k''-th percentile is <math>x_{k+1}</math>.
If there are only 100 values
:  <math> x_1 \le x_2 \le \dots \le x_{99} \le x_{100} </math>
then any value between <math>x_k</math> and <math>x_{k+1}</math> is a ''k''-th percentile.

Revision as of 09:30, 23 November 2009

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Percentiles are statistical parameters which describe the distribution of a (real) value in a population (or a sample). Roughly speaking, the k-th percentile separates the smallest p percent of values from the largest (100-p) percent.

Special percentiles are the median (50th percentile), the quartiles (25th and 75th percentile), and the deciles (the k-th decile is the (10k)-th percentile). Percentiles are special cases of quantiles: The k-th percentile is the same as the (k/100)-quantile.

Definition

The value x is k-th percentile if

Special cases

For a continuous distribution (like the normal distribution) the k-th percentile x is uniquely determined by

In the general case (e.g., for discrete distributions, or for finite samples) it may happen that the separating value has positive probability:

or that there are two distinct values for which equality holds such that

Then every value in the (closed) intervall between the smallest and the largest such value Failed to parse (syntax error): {\displaystyle \left [ \min \{ x \mid P(\omega\le x) = {k\over100} \}, \max \[ x \mid P(\omega\ge x) = 1-{k\over100} \} \right]} is a k-th percentiles.

Example

The following examples illustrates this:

Take a sample of 101 values, ordered according to their size:

Then the unique k-th percentile is .

If there are only 100 values

then any value between and is a k-th percentile.