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File:The Normal Distribution.svg
comparison of various measures of the normal distribution: standard deviations, cumulative percentages, Z-scores, and T-scores

In statistics, a standard score is a dimensionless quantity derived by subtracting the population mean from an individual raw score and then dividing the difference by the population standard deviation. This conversion process is called standardizing or normalizing; however, "normalizing" can refer to many types of ratios; see normalization (statistics) for more.

Standard scores are also called z-values, z-scores, normal scores, and standardized variables; the use of "Z" is because the normal distribution is also known as the "Z distribution". They are most frequently used to compare a sample to a standard normal deviate (standard normal distribution, with μ=0 and σ=1), though they can be defined without assumptions of normality.

The standard score indicates how many standard deviations an observation is above or below the mean: the standard deviation is the unit of measurement of the z-score. It allows comparison of observations from different normal distributions, which is done frequently in research.

The z-score is only defined if one knows the population parameters, as in standardized testing; if one only has a sample set, then the analogous computation with sample mean and sample standard deviation yields the Student's t-statistic.

The standard score is not the same as the z-factor used in the analysis of high-throughput screening data, but is sometimes confused with it.

Formula Edit

The standard score is

 z = \frac{x - \mu}{\sigma},


x is a raw score to be standardized;
μ is the mean of the population;
σ is the standard deviation of the population.

The quantity z represents the distance between the raw score and the population mean in units of the standard deviation. z is negative when the raw score is below the mean, positive when above.

A key point is that calculating z requires the population mean and the population standard deviation, not the sample mean or sample deviation. It requires knowing the population parameters, not the statistics of a sample drawn from the population of interest. But knowing the true standard deviation of a population is often unrealistic except in cases such as standardized testing, where the entire population is measured. In cases where it is impossible to measure every member of a population, the standard deviation may be estimated using a random sample. For example, a population of people who smoke cigarettes is not fully measured.

When a population is normally distributed, the percentile rank may be determined from the standard score and statistical tables.

Related statistics Edit

If using sample mean and sample standard deviation (rather than the population mean and standard deviation), the resulting ratio is the (single-sample) Student's t-statistic. In regression analysis, one instead uses the studentized residual, as the standard error of estimates of response variables vary for different input explanatory variables.

The T score statistic is a simple transformation of the z score, calculated using the formula

 T = ({z * 10}) + 50

The T score has a mean of 50 and a standard deviation of 10 (Carroll, Carroll & 2002 , p.56).

Applications Edit

The z-score is most often used in the z-test in standardized testing – the analog of the Student's t-test for a population whose parameters are known, rather than estimated. As it is very unusual to know the entire population, the t-test is much more widely used.

Darby and Reissland (1981) make use of z-scores as a way of understanding the contributions from various subsets of data to an overall test of trend. The overall analysis was of trends in the rate of occurrence of cancer and the subsets considered approximately 55 different types of cancer, together with various groupings of these types. In this instance, the use of z-scores is not immediately as a test statistic for a significance test, but rather as a numerical guide to finding subsets of data which might show different trends than others.

Standardizing in mathematical statisticsEdit

Further information: Normalization (statistics)

In mathematical statistics, a random variable X is standardized using the theoretical (population) mean and standard deviation:

Z = {X - \mu \over \sigma}

where μ = E(X) is the mean and σ = the standard deviation of the probability distribution of X.

If the random variable under consideration is the sample mean:

\bar{X}={1 \over n} \sum_{i=1}^n X_i

then the standardized version is


See normalization (statistics) for other forms of normalization.

References and notesEdit

General referencesEdit

  • Richard J. Larsen and Morris L. Marx (2000) An Introduction to Mathematical Statistics and Its Applications, Third Edition, ISBN 0139223037. p. 282.
  • Darby, S.C., Reissland, J.A. (1981) "Low levels of ionizing radiation and cancer — are we underestimating the risk? (with discussion)". Journal of the Royal Statistical Society, Series A, 144(3), 298–331.

External linksEdit

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See alsoEdit

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