Statistics is the discipline that concerns the collection,
organization, analysis, interpretation and presentation of data.In applying
statistics to a scientific, industrial, or social problem, it is conventional
to begin with a statistical population or a statistical model to be studied.
Populations can be diverse groups of people or objects such as "all people
living in a country" or "every atom composing a crystal".
Statistics deals with every aspect of data, including the planning of data
collection in terms of the design of surveys and experiments. See glossary of
probability and statistics.
When census data cannot be collected, statisticians collect
data by developing specific experiment designs and survey samples.
Representative sampling assures that inferences and conclusions can reasonably
extend from the sample to the population as a whole. An experimental study
involves taking measurements of the system under study, manipulating the
system, and then taking additional measurements using the same procedure to
determine if the manipulation has modified the values of the measurements. In
contrast, an observational study does not involve experimental manipulation.
Two main statistical methods are used in data analysis:
descriptive statistics, which summarize data from a sample using indexes such
as the mean or standard deviation, and inferential statistics, which draw
conclusions from data that are subject to random variation (e.g., observational
errors, sampling variation)Descriptive statistics are most often concerned with
two sets of properties of a distribution (sample or population): central
tendency (or location) seeks to characterize the distribution's central or
typical value, while dispersion (or variability) characterizes the extent to
which members of the distribution depart from its center and each other.
Inferences on mathematical statistics are made under the framework of
probability theory, which deals with the analysis of random phenomena.
A standard statistical procedure involves the collection of
data leading to test of the relationship between two statistical data sets, or
a data set and synthetic data drawn from an idealized model. A hypothesis is
proposed for the statistical relationship between the two data sets, and this
is compared as an alternative to an idealized null hypothesis of no
relationship between two data sets. Rejecting or disproving the null hypothesis
is done using statistical tests that quantify the sense in which the null can
be proven false, given the data that are used in the test. Working from a null
hypothesis, two basic forms of error are recognized: Type I errors (null
hypothesis is falsely rejected giving a "false positive") and Type II
errors (null hypothesis fails to be rejected and an actual relationship between
populations is missed giving a "false negative").[6] Multiple
problems have come to be associated with this framework: ranging from obtaining
a sufficient sample size to specifying an adequate null hypothesis.[citation
needed]
Measurement processes that generate statistical data are
also subject to error. Many of these errors are classified as random (noise) or
systematic (bias), but other types of errors (e.g., blunder, such as when an
analyst reports incorrect units) can also occur. The presence of missing data
or censoring may result in biased estimates and specific techniques have been
developed to address these problems.
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