Deck 18: Multiple Linear Regression

You are given the following data, where X₁ (Pretest score) and X₂ (Hours spent in the program) are used to predict Y (Posttest score):

$\begin{array}{ccc}\hline \boldsymbol{Y} & \boldsymbol{X}_{\mathbf{1}} & \boldsymbol{X}_{\mathbf{2}} \\\hline 65 & 60 & 7.5 \\82 & 62 & 9.0 \\94 & 75 & 8.5 \\80 & 78 & 7.0 \\87 & 65 & 10.0 \\66 & 60 & 8.0 \\\hline\end{array}$
Determine the following values: intercept, b₁, b₂, SS_res, SS_reg, F, s_res², s(b₁), s(b₂), t₁, t₂.

Intercept = -70.662, b₁ = 1.235, b₂ = 8.077.

SS_reg = 619.504, SS_res = 44.496, F(2,3) = 20.884 (p < .017, reject at .05), s²_res = 14.832.

s(b₁) = .227, s(b₂) = 1.660, t₁ = 5.437 (p = .012, reject at .05), t₂ = 4.866 (p = .017, reject at .05).

Procedure:
Create a data set with three variables: Posttest (Y), Pretest (X₁), and Hour (X₂). The data set should have six cases.

1) Go to Analyze $\rightarrow$ Regression $\rightarrow$ Linear.

2) Select Posttest to the Dependent list. Select Pretest and Hour to the Independent(s) list.

"3) Click OK.
Selected SPSS Output:

$\text { Model Summary }$
$\begin{array}{ccccc}\hline \text { Model } & R & R S q u a r e & \text { Adjusted } R \text { Square } & \text { Std. Error of the Estimate } \\\hline 1 & .966^{2} & .933 & .888 & 3.851 \\\hline\end{array}$
$\text { a. Fredictors: (Constant), Hour, Pretest }$ ${ANOVA}^{b}$
$\begin{array}{ccccccc}\hline {\text { Model }} & \text { Sum of Squares } & d f & \text { Mean Square } & F & \text { Sig. } \\\hline {\begin{array}{c}\text { Regression }\end{array}} & \mathbf{6 1 9 . 5 0 4} & 2 & 309.752 & \mathbf{2 0 . 8 8 4} & \mathbf{. 0 1 7}^a \\1\text { Residual } & \mathbf{4 4 . 4 9 6} & 3 & \mathbf{1 4 . 8 3 2} & &\\\text { Total }&664.000&5\\\hline\end{array}$

a. Predictors: (Constant), Hour, Fretest
b. Dependent Variable: Posttest Results:

The results of the multiple linear regression suggest that a significant proportion of the total variation in posttest scores was effectively predicted by pretest scores and hours spent in the program, F(2,3) = 20.884, p = .017. For Pretest, the unstandardized partial slope (1.235) and standardized partial slope (.846) are statistically significantly different from 0 (t = 5.437, df = 3, p = .012); with every one-point increase in pretest, posttest score will increase by 1.235 when controlling for Hour. For Hour, the unstandardized partial slope (8.077) and standardized partial slope (.757) are statistically significantly different from 0 (t = 4.866, df = 3, p = .017); with every additional hour spent in the program, posttest score is expected to increase by 8.077 when controlling for Pretest scores. Thus, Pretest and Hour were shown to be statistically significant predictors of Posttest, both individually and collectively. Multiple R² indicates that 93.3% of the variation in Salary was predicted by Pretest and Hour. This suggests a large effect size.

The intercept was -70.662, which is not statistically significantly different from 0 at the .05 level (t = -3.042, df = 3, p = .056)."

Complete the missing information for this regression model (df = 25).

t₁ = b₁/s(b₁) = 16/4 = 4; t₂ = b₂/s(b₂) = .4/.05 = 8; t₃ = b₃/s(b₃) = 70/10 = 7.
The critical t value is $\pm$ _{$\alpha$ /2}t_df = $\pm$ _0.025t₂₅ = 2.06.
|t₁|, |t₂|, |t₃| > critical t, so X₁, X₂, and X₃ are all significant predictors of Y.

A researcher would like to predict GPA from a set of three predictor variables for a sample of 34 college students. Multiple linear regression analysis was utilized. Complete the following summary table
( $\alpha$ = .05) for the test of significance of the overall regression model:

There are three independent variables, so m = 3. There are 34 students, so n = 34.

df_reg = m = 3, df_res = n - m -1 = 34 - 3 - 1 = 30, df_total = n - 1 = 34 - 1 = 33.

SS_reg = MS_reg*df_reg = 6.5*3 = 19.5, SS_res = SS_total- SS_reg = 66 - 19.5 = 46.5.

MS_res = SS_res/df_res = 46.5/30 = 1.55

F = MS_reg/MS_res = 6.5/1.55 = 4.19; critical value = _.05F_3,30 = 2.92 < F, reject H₀.

You are given the following data, where X₁ (attendance rate) and X₂ (average SAT score) are to be used to predict Y (average score in graduation test). Each case represents one school.

$\begin{array}{|c|c|c|}\hline Y & X_{\mathbf{1}} & X_{\mathbf{2}} \\\hline 78.4 & 93.4 & 1010 \\\hline 81.3 & 94.6 & 1020 \\\hline 81.3 & 95.4 & 1024 \\\hline 82.5 & 91.1 & 1136 \\\hline 77.8 & 91.6 & 952 \\\hline 84.5 & 94.2 & 1042 \\\hline 88.2 & 94.5 & 1106 \\\hline 88.7 & 93.4 & 1004 \\\hline 72.5 & 92.1 & 880 \\\hline 85.4 & 94.9 & 1124 \\\hline 82.9 & 94.3 & 1124 \\\hline 81.4 & 94.7 & 996 \\\hline\end{array}$
Determine the following values: intercept, b₁, b₂, SS_res, SS_reg, F, s_res², s(b₁), s(b₂), t₁, t₂.