# How to Interpret a Q-Q Plot

Statisticians have developed a remarkably powerful set of tools for analyzing normally distributed data. Too bad real data is never normally distributed.

Fortunately for us, most of the time “close enough” is all we really need. But how are we to know? One quick and effective method is a look at a Q-Q plot. The Q’s stand for “quantile” and a Q-Q plot. Technically speaking, a Q-Q plot compares the distribution of two sets of data. In most cases, a probability plot will be most useful. A probability plot compares the distribution of a data set with a theoretical distribution. The R function qqnorm( ) compares a data set with the theoretical normal distibution.

We can start by looking at the mpg column of the familiar mtcars sample dataframe.

```qqnorm(mtcars\$mpg)
qqline(mtcars\$mpg, col = "steelblue", lwd = 2)```

The qqline( ) function plots a line representing perfect quantile matching. If the distributions matched perfectly, all the quantile points would lie along the blue line. Is the deviation we see here cause for concern?

Let’s generate some normally distributed random numbers and see how they look on a probability plot.

dfN1<-rnorm(1000, mean=50, sd = 10)

qqnorm(dfN1)

qqline(dfN1, col=“maroon4”, lwd=2) # there is no maroon five Since a relatively small number of data points in normally distributed data fall in the few highest and few lowest quantiles, we are more likely to see the results of random fluctuations at the extreme ends. We now understand that the mtcars mpg data is not precisely normal, but not too far off.

Now let’s generate some sample random data that we know not to be normal. We can do this using the sn package.

library(sn)

y3 <- dsn(x, xi=0, omega=1.2, alpha=2)

plot(x, y3, type=“l”, ylab=“density”, col=“royalblue”) This dataset is not normally distributed, but doesn’t look that far off. Let’s take a look at the output of qqnorm( ) for this data.

qqnorm(y3)

qqline(y3, col = “dodgerblue4”, lwd = 2) The Q-Q plot clearly shows that the quantile points do not lie on the theoretical normal line. We see that the sample values are generally lower than the normal values for quantiles along the smaller side of the distribution.

### A True Q-Q Plot

It is very common to ask if a particular dataset is close to normally distributed, the task for which qqnorm( ) was designed. However, you may wish to compare the distribution of two datasets to see if the distributions are similar without making any further assumptions. R implements the qqplot( ) for this purpose. Unfortunately, since we are not comparing to any theoretical distribution in this case, there is nothing comparable to qqline( ) available in qqplot. We can, however, use abline( ) to draw the same line if we calculate the appropriate intercept and slope.
abline(intercept,slope)
Just out of curiosity we might compare samples following t-distributions with different values for degrees of freedom.

t20<-rt(1000,df=20)

t3<-rt(1000,df=3)

qqplot(t3,t20)

abline(0,sd(t20)/sd(t3), col=“firebrick2”) Conclusion
As is so often the case in data science, well-chosen graphs communicate information more quickly and more understandably. Q-Q plots and probability plots provide quick comparisons between probability distributions and can tell us how closely a data sample is to normally distributed.

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