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4.6: Normal Distribution for Continuous Variables

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    Statistics is the study of variation. You want to see the kind of variation and the quality of the variation. You need to see that the variable actually does vary. The opposite of variation is constant. Constants do not help us because that means everything is the same, which does not help us predict why anything is different.

    The reason you need to see a normal distribution in your variables is because it establishes what is significant and what is not significant. Put differently, the normal distribution establishes what is normal and not normal. Or what is expected and not expected. Recall that a hallmark of statistics is variation, and we get variation through comparison – “this is different than that.” To establish that something is significant, we must compare it to something that is not significant. To determine if something is unexpected, we must compare it to something that is expected. To determine if something is not normal, we must compare it to something normal. Hence, we need a normal distribution.

    The other reason you need a normal distribution is because it satisfies the assumption of statistical tests. You will hear the phrase “satisfy the assumption of statistical tests.” Assumptions are criteria that are met before proceeding with a statistical analysis. Satisfying those assumptions means we can trust the validity of the statistical results. Not satisfying those assumptions means we cannot trust the validity of the statistical results. More on what this means later. One of the assumptions is a normal distribution. Briefly, if we do not have a normal distribution, one problem is that the statistical results might be due to an outlier or an extreme score. The results are due to exceptions rather than the trend of the group. These are just examples. The main point for now is that we examine the distribution of variables to determine if we can proceed with the statistical test. Normal distribution means we can proceed with the statistical test. A non-normal distribution means we cannot proceed with the test.

    When you have a normal distribution, you can use parametric tests. Briefly, these are your common, well-known tests: t-test, ANOVA, correlations, regression. No normal distribution means you might consider a non-parametric test. These non-parametric tests include the chi-square.

    This page titled 4.6: Normal Distribution for Continuous Variables is shared under a CC BY 4.0 license and was authored, remixed, and/or curated by Peter Ji.