Standard score

"Standardize" redirects here. For industrial and technical standards, see Standardization.

For Z-values in ecology, see Z-value. For Z-factor in high-throughput screening, see Z-factor. For Z-score financial analysis tool, see Altman Z-score.

Compares the various grading methods in a normal distribution. Includes: Standard deviations, cumulative percentages, percentile equivalents, Z-scores, T-scores, standard nine, percent in stanine

In statistics, a standard score indicates how many standard deviations an observation or datum is above or below the mean. It 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 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 though the two are often conflated.

Calculation from raw score

The standard score is

where:

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.

Applications

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.

Percentile ranks and prediction intervals

With a population that is normally distributed with known mean and known variance, the percentile rank and prediction interval may be determined from the standard score.

With known mean and known variance, prediction intervals can be calculated by subtracting from or adding to the mean (µ) with the standard deviation (σ) multiplied by a standard score (z) that is specific for what prediction intervals are desired:

Prediction interval	Standard score (z)
50%	0.67[1]
68%	1.00[1]
90%	1.64[1]
95%	1.96[1]
99%	2.58[1]

Diagram showing the cumulative distribution function for the normal distribution with mean (µ) of 0 and variance (σ²) of 1. The prediction interval for any standard score corresponds numerically to (1 − (1 − Φ_µ,σ²(standard score))*2). For example, a standard score of x = 1.96 gives Φ_µ,σ²(1.96) = 0.9750 corresponding to a prediction interval of (1 − (1 − 0.9750)·2) = 0.9500 = 95%.

• Lower limit of prediction interval = µ − σz
• Upper limit of prediction interval = µ + σz

About 68.27% of the values lie within 1 standard deviation of the mean. Similarly, about 95.45% of the values lie within 2 standard deviations of the mean. Nearly all (99.73%) of the values lie within 3 standard deviations of the mean. This is known as the 68-95-99.7 rule.

For example, to calculate the 95% prediction interval for a normal distribution with a mean (µ) of 5 and a standard deviation (σ) of 1, then the lower limit of the prediction interval is approximately 5 ‒ (1*2) = 3, and the upper limit is approximately 7, thus giving a prediction interval of approximately 3 to 7.

Standardizing in mathematical statistics

Further information: Normalization (statistics)

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

where is the mean and the standard deviation of the probability distribution of X.

If the random variable under consideration is the sample mean:

then the standardized version is

See normalization (statistics) for other forms of normalization.

A common name for standard score is the z-score. It is often used in statistics.

See also

• Central moment
• Moment (mathematics)
• Normalization (statistics)
• Sampling distribution
• Standard normal deviate
• Standard normal table
• Stanine
• Student's t-test
• Student's t-statistic
• Studentized residual
• Z-factor
• Z-test
• Sten scores

References

1. ^ Page 111 in: Kirkup, Les (2002). Data analysis with Excel: an introduction for physical scientists. Cambridge, UK: Cambridge University Press. ISBN 0-521-79737-3. 

Further reading

• Carroll, Susan Rovezzi; Carroll, David J. (2002). Statistics Made Simple for School Leaders (illustrated ed.). Rowman & Littlefield. ISBN 9780810843226. http://books.google.com/?id=gccHkMDikb0C. Retrieved 7 June 2009 
• Richard J. Larsen and Morris L. Marx (2000) An Introduction to Mathematical Statistics and Its Applications, Third Edition, ISBN 0139223037. p. 282.