Bonferroni correction


In statistics, the Bonferroni correction is one of several methods used to counteract the problem of multiple comparisons.

Background

Italian mathematician Carlo Emilio Bonferroni developed the correction for multiple comparisons for its use on Bonferroni inequalities.
An extension of the method to confidence intervals was proposed by Olive Jean Dunn.
Statistical hypothesis testing is based on rejecting the null hypothesis if the likelihood of the observed data under the null hypotheses is low. If multiple hypotheses are tested, the chance of observing a rare event increases, and therefore, the likelihood of incorrectly rejecting a null hypothesis increases.
The Bonferroni correction compensates for that increase by testing each individual hypothesis at a significance level of, where is the desired overall alpha level and is the number of hypotheses. For example, if a trial is testing hypotheses with a desired, then the Bonferroni correction would test each individual hypothesis at. Likewise, when constructing multiple confidence intervals the same phenomenon appears.

Definition

Let be a family of hypotheses and their corresponding p-values. Let be the total number of null hypotheses and the number of true null hypotheses. The familywise error rate is the probability of rejecting at least one true, that is, of making at least one type I error. The Bonferroni correction rejects the null hypothesis for each, thereby controlling the FWER at. Proof of this control follows from Boole's inequality, as follows:
This control does not require any assumptions about dependence among the p-values or about how many of the null hypotheses are true.

Extensions

Generalization

Rather than testing each hypothesis at the level, the hypotheses may be tested at any other combination of levels that add up to, provided that the level of each test is determined before looking at the data. For example, for two hypothesis tests, an overall of 0.05 could be maintained by conducting one test at 0.04 and the other at 0.01.

Confidence intervals

The procedure proposed by Dunn can be used to adjust confidence intervals. If one establishes confidence intervals, and wishes to have an overall confidence level of, each individual confidence interval can be adjusted to the level of.

Alternatives

There are alternative ways to control the familywise error rate.
For example, the Holm–Bonferroni method and the Šidák correction are universally more powerful procedures than the Bonferroni correction, meaning that they are always at least as powerful. Unlike the Bonferroni procedure, these methods do not control the expected number of Type I errors per family.

Criticism

With respect to FWER control, the Bonferroni correction can be conservative if there are a large number of tests and/or the test statistics are positively correlated.
The correction comes at the cost of increasing the probability of producing false negatives, i.e., reducing statistical power. There is not a definitive consensus on how to define a family in all cases, and adjusted test results may vary depending on the number of tests included in the family of hypotheses. Such criticisms apply to FWER control in general, and are not specific to the Bonferroni correction.