The usual way would be to look at anova(lm1, lm2)
and at summary(lm2)
, although there is an effects
-package that may offer additional capacities. I do not understand what you do need of those are not sufficient. The difference in sum of squares and the degrees of freedom if it is a factor variable that accompanies the addition of "c" is provided by the output of anova
. The "contribution of 'c' toward x" is a bit vague, but could mean the coefficient (labeled "Estimate" for x provided by summary(lm2)
). You are probably being asked to write something like "the contribution of "c" to the variation in "x" when "a" and "b" are controlled for in a regression analysis is ...."
If you want to decompose sums of squares in a single model just look a:
anova(lm2)
######
Analysis of Variance Table
Response: Y
Df Sum Sq Mean Sq F value Pr(>F)
X1 1 2.2167 2.21672 4.9554 0.03982 *
X2 1 1.2316 1.23156 2.7531 0.11540
Residuals 17 7.6047 0.44733
---
Signif. codes: 0 ‘***’ 0.001 ‘**’ 0.01 ‘*’ 0.05 ‘.’ 0.1 ‘ ’ 1
Percentage of total sums of squares in the X1 sums of squares is easily calculated. First look at the object anova(lm2)
with str()
. It's a list:
100*anova(lm2)[['Sum Sq']][1]/sum(anova(lm2)[['Sum Sq']])
#[1] 20.05545
The "Partial-R^2 for X1 controlling for X2" (R^2_Y.X1|X2) is:
anova(lm2)[['Sum Sq']]["X1"]/anova(lm2)[['Sum Sq']][""Residuals"]