How does the outlier affect the best-fit line?

Numerically and graphically, we have identified the point (65, 175) as an outlier. We should re-examine the data for this point to see if there are any problems with the data. If there is an error, we should fix the error if possible, or delete the data. If the data is correct, we would leave it in the data set. For this problem, we will suppose that we examined the data and found that this outlier data was an error. Therefore, we will continue on and delete the outlier so that we can explore how it affects the results as a learning experience.

Compute a new best-fit line and correlation coefficient using the ten remaining points:

On the TI-83, TI-83+, and TI-84+ calculators, delete the outlier from L1 and L2. Using the LinRegTTest, the new line of best fit and the correlation coefficient is:

[latex]\hat{y}[/latex] = –355.19 + 7.39x and r = 0.9121

The new line with r = 0.9121 is a stronger correlation than the original (r = 0.6631) because r = 0.9121 is closer to one. This means that the new line is a better fit for the ten remaining data values. The line can better predict the final exam score given the third exam score.

Numerical identification of outliers: Calculating s and finding outliers manually

If you do not have the function LinRegTTest, then you can calculate the outlier in the first example by doing the following.

First, square each |y – ŷ |

The squares are 35²; 17²; 16²; 6²; 19²; 9²; 3²; 1²; 10²; 9²; 1²

Then, add (sum) all the |y – ŷ | squared terms using the formula

[latex]{\sum_{i=1}^{11}}{\left ( |{y_i} - {\hat y_i}| \right )^2}[/latex] = [latex]{\sum_{i=1}^{11}}{\epsilon_i}^2[/latex] (Recall that [latex]{y_i} - {\hat y_i}[/latex] = [latex]{\epsilon_i}[/latex].

= 35² + 17² + 16² + 6² + 19² + 9² + 3² + 1² + 10² + 9² + 1²

= 2440 = SSE. The result, SSE is the Sum of Squared Errors.

Next, calculate s, the standard deviation of all the y – ŷ = ε values where n = the total number of data points.

The calculation is [latex]s = {\sqrt{\dfrac{SSE}{n - 2}}}[/latex].

For the third exam/final exam problem, [latex]s = {\sqrt{\frac{2440}{11 - 2}}} = 16.47[/latex].

Next, multiply s by 2:
(2)(16.47) = 32.94
32.94 is 2 standard deviations away from the mean of the y – [latex]\hat {y}[/latex] values.

If we were to measure the vertical distance from any data point to the corresponding point on the line of best fit and that distance is at least 2s, then we would consider the data point to be “too far” from the line of best fit. We call that point a potential outlier.

For the example, if any of the |y – [latex]\hat {y}[/latex]| values are at least 32.94, the corresponding (x, y) data point is a potential outlier.

For the third exam/final exam problem, all the |y – [latex]\hat {y}[/latex]|’s are less than 31.29 except for the first one which is 35.

35 > 31.29 That is, |y – [latex]\hat {y}[/latex]| ≥ (2)(s)

The point which corresponds to |y – [latex]\hat {y}[/latex]| = 35 is (65, 175). Therefore, the data point (65,175) is a potential outlier. For this example, we will delete it. (Remember, we do not always delete an outlier).

Note