8.3: The Normal Distribution

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Learning Objectives

Identify the characteristics of a normal distribution
Apply the Empirical Rule (68-95-99.7 Rule) for normal distributions
Calculate and interpret z-scores

Introduction

Most high schools have a set amount of time in between classes during which students must get to their next class. If you were to stand at the door of your math class and watch the students coming in, think about how the students would enter. Usually, one or two students enter early, then more students come in, then a large group of students enter, and finally, the number of students entering decreases again, with one or two students barely making it on time, or perhaps even coming in late!

Now consider this. Have you ever popped popcorn in a microwave? Think about what happens in terms of the rate at which the kernels pop. For the first few minutes, nothing happens, and then, after a while, a few kernels start popping. This rate increases to the point at which you hear most of the kernels popping, and then it gradually decreases again until just a kernel or two pop.

Here’s something else to think about. Try measuring the height, shoe size, or the width of the hands of the students in your class. In most situations, you will probably find that there are a couple of students with very low measurements and a couple with very high measurements, with the majority of students centered on a particular value.

$clipboard_e374cf9214a6fa1c54884d3a1f61ee326.png$

All of these examples show a typical pattern that seems to be a part of many real-life phenomena. In statistics, because this pattern is so pervasive, it seems to fit to call it normal, or more formally, the normal distribution. The normal distribution is an extremely important concept, because it occurs so often in the data we collect from the natural world, as well as in many of the more theoretical ideas that are the foundation of statistics. This chapter explores the details of the normal distribution.

The Characteristics of a Normal Distribution

Normal Distribution

The normal distribution is a commonly occurring statistical distribution whose bell shape is determined by the mean and standard deviation of the distribution.

The normal distribution is a continuous probability distribution. The distribution is represented by a smoothed-out histogram. The total area under the normal distribution curve, which represents the probabilities of all outcomes in the sample space, is always 1.

The Empirical Rule for Normal Distributions

Since all normal distributions have the same shape and the total area under the curve is 1 or 100%, it turns out that the amount of data between the mean and the standard deviations for any approximately normal distribution is consistent.

Empirical Rule

For data sets that are approximately bell-shaped:

approximately $68\%$ of the data lie within one standard deviation of the mean, that is, in the interval with endpoints $\mu \pm \sigma$
approximately $95\%$ of the data lie within two standard deviations of the mean, that is, in the interval with endpoints $\mu \pm 2\sigma$
approximately $99.7\%$ of the data lie within three standard deviations of the mean, that is, in the interval with endpoints $\mu \pm 3\sigma$

The Empirical Rule is also referred to as the 68-95-99.7 Rule. The figure below illustrates the Empirical Rule.

68% of data lie with 1 standard deviation above and below the mean; 95% of data lie within 2 standard deviations above and below the mean; 99.7% of data lie within 3 standard deviations above and below the mean

Two key points in regard to the Empirical Rule are that the data distribution must be approximately bell-shaped and that the percentages are only approximately true. The Empirical Rule does not apply to data sets that are not bell-shaped, especially severely asymmetric distributions, and the actual percentage of observations in any of the intervals specified by the rule could be either greater or less than those given in the rule.

Example $\PageIndex{1}$

Scores on IQ tests have a bell-shaped distribution with mean $\mu =100$ and standard deviation $\sigma =10$. Discuss what the Empirical Rule implies concerning individuals with IQ scores of $110$, $120$, and $130$.

Solution:

A sketch of the IQ distribution is shown below. The Empirical Rule states that

approximately $68\%$ of the IQ scores in the population lie between $90$ and $110$
approximately $95\%$ of the IQ scores in the population lie between $80$ and $120$
approximately $99.7\%$ of the IQ scores in the population lie between $70$ and $130$.

Since $68\%$ of the IQ scores lie within the interval from $90$ to $110$, it must be the case that $100\% - 68\% = 32\%$ lie outside that interval. By symmetry approximately half of that $32\%$, or $16\%$ of all IQ scores, will lie above $110$. If $16\%$ lie above $110$, then $100\% - 16\% = 84\%$ lie below. We conclude that the IQ score $110$ is the $84^{th}$ percentile.
The same analysis applies to the score $120$. Since approximately $95\%$ of all IQ scores lie within the interval form $80$ to $120$, only $5\%$ lie outside it, and half of them, or $2.5\%$ of all scores, are above $120$. The IQ score $120$ is thus higher than $97.5\%$ of all IQ scores, and is quite a high score.
By a similar argument, only $\dfrac{15}{100}$ of $1\%$ of all adults, or about one or two in every thousand, would have an IQ score above $130$. This fact makes the score $130$ extremely high.

Try It $\PageIndex{1}$

Heights of $18$-year-old males have a bell-shaped distribution with mean $69.6$ inches and standard deviation $1.4$ inches.

About what proportion of all such men are between $68.2$ and $71$ inches tall?
What interval centered on the mean should contain about $95\%$ of all such men?

Answer

A sketch of the distribution of heights is shown below.

Since the interval from $68.2$ to $71.0$ has endpoints $\mu - \sigma$ and $\mu+ \sigma$, by the Empirical Rule about $68\%$ of all $18$-year-old males should have heights in this range.
By the Empirical Rule, the shortest such interval has endpoints $\mu - 2\sigma$ and $\mu+2\sigma$. Since $\mu-2\sigma =69.6-2(1.4)=66.8$ and $ \mu+2\sigma =69.6+2(1.4)=72.4 $ the interval in question is the interval from $66.8$ inches to $72.4$ inches.

$68% of the data lie between 68.2 and 71.0 inches; 95% of the data lie between 66.9 and 72.4 inches$

Calculating and Interpreting z-Scores

z-score

A z-score is a measure of the number of standard deviations a particular data point is away from the mean.

For example, let’s say the mean score on a test for your math class was an 82, with a standard deviation of 7 points. If your score was an 89, it is exactly one standard deviation to the right of the mean; therefore, your z-score would be 1. If, on the other hand, you scored a 75, your score would be exactly one standard deviation below the mean, and your z-score would be −1. All values that are below the mean have negative z-scores, while all values that are above the mean have positive z-scores. A z-score of −2 would represent a value that is exactly 2 standard deviations below the mean, so in this case, the value would be $82 − 2(7) = 82 - 14 = 68$.

To calculate a z-score for which the numbers are not so obvious, you take the deviation and divide it by the standard deviation.

\[z = \dfrac{\text{deviation}}{\text{standard deviation}} \nonumber \]

You may recall that deviation is the mean value of the variable, $\mu$, subtracted from the observed value, $x$, so in symbolic terms, the z-score would be:

\[z = \dfrac{x-\mu}{\sigma} \nonumber \]

As previously stated, since $\sigma$ is always positive, $z$ will be positive when $x$ is greater than $\mu$ and negative when $x$ is less than $\mu$. A z-score of zero means that the term has the same value as the mean. The value of $z$ represents the number of standard deviations the given value of $x$ is above or below the mean and is usually rounded to 2 decimal places.

Example $\PageIndex{2}$

What is the z-score for an A on the test described above, which has a mean score of 82? (Assume that an A is a 93.)

Solution

For this problem, $x = 93, \mu = 82$ and $\sigma = 7$. The z-score can be calculated as follows:

$z = \dfrac{x-\mu}{\sigma}$

$z = \dfrac{93-82}{7}$

$z ≈ 1.57$

A score of 93 on the test is about 1.57 standard deviations above the average test score.

If we know that the test scores from the last example are distributed normally, then a z-score can tell us something about how our test score relates to the rest of the class. From the Empirical Rule, we know that about 68% of the students would have scored between a z-score of −1 and 1, or between 75 and 89, on the test. 95% of the students scored between a z-score of -2 and 2, or between 68 and 96.

Try It $\PageIndex{2}$

On a nationwide math test, the mean was 65 and the standard deviation was 10. If Robert scored 81, what was his z-score?

Answer

For this problem, $x = 81, \mu = 65$ and $\sigma = 10$. The z-score can be calculated as follows:

$z = \dfrac{x-\mu}{\sigma}$

$z = \dfrac{81-65}{10}$

$z = 1.60$

Robert scored 1.6 standard deviations above the mean.

Notes:

1. Data available on the College Board Website: http://professionals.collegeboard.com/data-reportsresearch/ap/archi ved/2007

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Normal Distribution

Empirical Rule

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z-score

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Solution

Try It \(\PageIndex{2}\)