1. Chapter 12 Inference for Linear Regression
Target Goals:
I can make predictions using regression for normal distributions.
I can check conditions for performing inference about the slope β of the population (true) regression line.
12.1a
h.w: pg 759: 1 – 11 odd

2. Inference about the Model
We can use LSRL fitted to data to predict y for a given value of x for two quantitative variables.
Now we will do tests and construct confidence intervals in this setting.

3. Pg. 752

4. Ex. Crying and IQ
Infants who cry easily may be more easily stimulated than others and this may be a sign of higher IQ.
The researchers snapped a rubber band on the sole of the foot of infants and caused the infants to cry.
At age 3 years the measured IQ.

5. Step 1: Make a scatterplot of the data.
Explanatory variable: Crying
Response variable: IQ
Enter “crying” data into L1 and “IQ” data into L2.
Plot and Interpret. STAT:CALC:LinReg(a+bx) L1,L2,Y1
Y1:(VARS:Y-VARS:FUNCT:Y1)
Scatterplot shows a roughly linear pattern.
The correlation r describes the direction and strength of the relationship.

6. Step 2: Calculate the LSRL

7. Step 3: Identify outliers and influential points
No extreme outliers or potentially influential observations.

8. Step 4: Calculate the Correlation (r value)
The correlation between crying and IQ is r =

9. Interpret r2 = ,
only about 21% of the variation in IQ scores (response variable) is explained by crying intensity.
r2 is called the coefficient of determination.
Is prediction of IQ accurate with this model? No

10. It is interesting though that behavior shortly after birth can partly predict IQ.

11. Conditions for Regression Inference
How long it will take before Old Faithful erupts again based on the duration of the previous eruption.
Conditions for Regression Inference
3 SRSs of 20 Old Faithful Eruptions
The values of the slope b for the 1000
sample regression lines are plotted.

12. Pg. 742

13. Conditions for Regression Inference
Our goal is to predict the behavior of y for a given value of x.
Linear: The y responses for various samples vary according to a normal distribution.
The mean response μy has a straight-line relationship with x.
The true regression line is written in the form:

14. where μy is the mean response,
and is the true y-intercept and β is the true slope.

15. Independent: The y responses are independent of each other.
Normal: for any fixed value of x, the observed response value y varies according to a normal distribution having mean μy.

16. Equal Variance: The standard deviation s about the true regression line is the same for all values of x. (constant).
It is usually an unknown parameter.
Random: The data come from a well designed random sample or randomized experiment.

17. Linear
Independent
Normal
Equal Variance
Random

18. The LSRL : = a + b x where b is an unbiased estimator of the true slope β and a is the unbiased estimator of the true intercept .

19. The line is the true regression line, which shows how the mean response μy changes as the explanatory variable x changes.

20. Standard Deviation
σ determines whether the points fall close to the true regression line (small σ) or are widely scattered (large σ).
This is also the size of a typical prediction error if we use the least-squares regression line to predict “how long it will take before Old Faithful erupts again” based on the duration of the previous eruption.

21. Ex: Slope and Intercept
The LSRL is = x
The slope measures rate of change: how much higher average IQ is for children with one more peak in their crying measurements.
b est. the unknown β; we est. that on the average IQ is about 1.5 points higher for each additional crying peak.
crying peak IQ

22. Standard Deviation
σ describes the variability of the response y about the true regression line.
Recall that residuals estimate how much y varies about the true line and are the vertical deviations of the data points from the least-square line:
Residual = observed y – predicted y

23. Standard Error about the LSRL
We estimate σ with s, the sample standard deviation, which is also called the standard error (this is the key to inference about the regression).
Since σ is unknown, we use s to estimate the value of σ.
Note: (n – 2) is the degrees of freedom for the regression model.

24. Ex. Calculating Residuals and Standard Error
The quickest way to do this is to: (use ex 14.1 data).
Enter “crying” data into L1 and “IQ” data into L2. (We already did this.)
Recall: LINREG (a+bx) automatically calculates the residuals and stores them in “Resid.”
Store “Resid” in L3
STAT:CALC:1-Var Stats L3
∑ resid2

25. To find s, first find s2: To find s2:
Enter the value of ∑X2 by hand or (VARS:5: : ∑X2 ) and divide by (n-2)
Take sqrt to find s.

26. A level C confidence interval for the slope b of the true regression line is

27. You will rarely have to calculate this by hand.
Regression software gives you the standard error SE b and b itself.

28. Ex. Regression Output: Crying and IQ

29. There are 38 data points so
df = n – 2 = 36.
Find the critical value t* (critical value).
For a 95% C.I. for true slope b, use critical value t* = with df =30 from table C.

30. Conclude
We are 95 % confident that mean IQ increases by, between 0.5 and 2.5 points, for each additional peak in crying.

31. Interpret SEb
Seb estimates how much the slope of the sample regression line typically varies from the slope of the population (true) regression line if we repeat the data production process many times.
If we repeated the experiment many times, the slope the slope of the sample regression line would typically vary by about from the slope of the true regression line for predicting IQ from cry count of infants.