假设我有以下代码来拟合一个双曲抛物线。
# attach(mtcars)
hp_fit <- lm(mpg ~ poly(wt, disp, degree = 2), data = mtcars)
其中 wt 是x变量。disp 是y变量,而 mpg 是z变量。(summary(hp_fit))$coefficients 输出如下。
>(summary(hp_fit))$coefficients
Estimate Std. Error t value Pr(>|t|)
(Intercept) 22.866173 3.389734 6.7457122 3.700396e-07
poly(wt, disp, degree = 2)1.0 -13.620499 8.033068 -1.6955539 1.019151e-01
poly(wt, disp, degree = 2)2.0 15.331818 17.210260 0.8908534 3.811778e-01
poly(wt, disp, degree = 2)0.1 -9.865903 5.870741 -1.6805208 1.048332e-01
poly(wt, disp, degree = 2)1.1 -100.022013 121.159039 -0.8255431 4.165742e-01
poly(wt, disp, degree = 2)0.2 14.719928 9.874970 1.4906301 1.480918e-01
我不明白如何解释Z变量右边的不同数字。poly() 根据 (Intercept) 列。这些数字的意义是什么,我如何从这个摘要中构建双曲抛物线拟合的方程?
当你比较
with(mtcars, poly(wt, disp, degree=2))
with(mtcars, poly(wt, degree=2))
with(mtcars, poly(disp, degree=2))
的 1.0 2.0 喻指第一、二度 wt和 0.1 0.2 喻指第一、二度 disp. 该 1.1 是一个交互术语。你可以通过比较来检查。
summary(lm(mpg ~ poly(wt, disp, degree=2, raw=T), data=mtcars))$coe
# Estimate Std. Error t value Pr(>|t|)
# (Intercept) 4.692786e+01 7.008139762 6.6961935 4.188891e-07
# poly(wt, disp, degree=2, raw=T)1.0 -1.062827e+01 8.311169003 -1.2787937 2.122666e-01
# poly(wt, disp, degree=2, raw=T)2.0 2.079131e+00 2.333864211 0.8908534 3.811778e-01
# poly(wt, disp, degree=2, raw=T)0.1 -3.172401e-02 0.060528241 -0.5241191 6.046355e-01
# poly(wt, disp, degree=2, raw=T)1.1 -2.660633e-02 0.032228884 -0.8255431 4.165742e-01
# poly(wt, disp, degree=2, raw=T)0.2 2.019044e-04 0.000135449 1.4906301 1.480918e-01
summary(lm(mpg ~ wt*disp + I(wt^2) + I(disp^2) , data=mtcars))$coe[c(1:2, 4:3, 6:5), ]
# Estimate Std. Error t value Pr(>|t|)
# (Intercept) 4.692786e+01 7.008139762 6.6961935 4.188891e-07
# wt -1.062827e+01 8.311169003 -1.2787937 2.122666e-01
# I(wt^2) 2.079131e+00 2.333864211 0.8908534 3.811778e-01
# disp -3.172401e-02 0.060528241 -0.5241191 6.046355e-01
# wt:disp -2.660633e-02 0.032228884 -0.8255431 4.165742e-01
# I(disp^2) 2.019044e-04 0.000135449 1.4906301 1.480918e-01
这将产生相同的值。请注意,我使用了 raw=TRUE 以供比较。