4: z-Scores and the Standard Normal Distribution

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Page ID: 42011

Linda R. Cote, Rupa G. Gordon, Chrislyn E. Randell, Judy Schmitt, and Helena Marvin
University of Missouri System

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We now understand how to describe and present our data visually and numerically. These simple tools, and the principles behind them, will help you interpret information presented to you and understand the basics of a variable. Moving forward, we now turn our attention to how scores within a distribution are related to one another, how to precisely describe a score’s location within the distribution, and how to compare scores from different distributions.

4.1: Normal Distributions
This page discusses the normal distribution, or bell curve, which is fundamental in statistics for its symmetrical properties and concentration of values around the mean. It is characterized by equal mean, median, and mode, with an area of 1.0. Key features include the density at the center and the defined roles of mean and standard deviation. Approximately 68% of values are within one standard deviation and 95% within two, essential for analyzing scores across distributions.
4.2: Z-scores
This page explains z-scores as a standardized measure indicating a raw score's position relative to the mean and standard deviation. It highlights their utility in comparing distributions and converting back to raw scores.
4.3: Z-scores and the Area under the Curve
This page explores the relationship between \(z\)-scores and the standard normal distribution, detailing how \(z\)-scores reflect a value's position within the distribution. It covers standardization of scores from any normal distribution to \(z\)-scores and explains the percentage of data within specific \(z\)-score ranges. The total area of the distribution is 1.0, facilitating calculations of proportions outside those ranges.

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