extract all standard errors of coefficients from list of logistic regressions

I want to extract the standard errors from a list of logistic regression models.

This is the logistic regression function, designed this way so i can run more than one analysis at once:

``````glmfunk <- function(x) glm(  ldata\$DFREE ~  x , family=binomial)
``````

I run it on a subset of the variables in the dataframe ldata:

``````glmkort <- lapply(ldata[,c(2,3,5,6,7,8)],glmfunk)
``````

I can extract the coefficients like this:

``````sapply(glmkørt, "[[", "coefficients")
``````

But how do i extract the standard error of the coefficients? I can't seem to find it in the str(glmkort)?

Here is the str(glmkort) for AGE where i am looking for the standard error:

``````str(glmkort)
List of 6
\$ AGE    :List of 30
..\$ coefficients     : Named num [1:2] -1.17201 -0.00199
.. ..- attr(*, "names")= chr [1:2] "(Intercept)" "x"
..\$ residuals        : Named num [1:40] -1.29 -1.29 -1.29 -1.29 4.39 ...
.. ..- attr(*, "names")= chr [1:40] "1" "2" "3" "4" ...
..\$ fitted.values    : Named num [1:40] 0.223 0.225 0.225 0.225 0.228 ...
.. ..- attr(*, "names")= chr [1:40] "1" "2" "3" "4" ...
..\$ effects          : Named num [1:40] 3.2662 -0.0282 -0.4595 -0.4464 2.042 ...
.. ..- attr(*, "names")= chr [1:40] "(Intercept)" "x" "" "" ...
..\$ R                : num [1:2, 1:2] -2.64 0 -86.01 14.18
.. ..- attr(*, "dimnames")=List of 2
.. .. ..\$ : chr [1:2] "(Intercept)" "x"
.. .. ..\$ : chr [1:2] "(Intercept)" "x"
..\$ rank             : int 2
..\$ qr               :List of 5
.. ..\$ qr   : num [1:40, 1:2] -2.641 0.158 0.158 0.158 0.159 ...
.. .. ..- attr(*, "dimnames")=List of 2
.. .. .. ..\$ : chr [1:40] "1" "2" "3" "4" ...
.. .. .. ..\$ : chr [1:2] "(Intercept)" "x"
.. ..\$ rank : int 2
.. ..\$ qraux: num [1:2] 1.16 1.01
.. ..\$ pivot: int [1:2] 1 2
.. ..\$ tol  : num 1e-11
.. ..- attr(*, "class")= chr "qr"
..\$ family           :List of 12
.. ..\$ family    : chr "binomial"
.. ..\$ link      : chr "logit"
.. ..\$ variance  :function (mu)
.. ..\$ dev.resids:function (y, mu, wt)
.. ..\$ aic       :function (y, n, mu, wt, dev)
.. ..\$ mu.eta    :function (eta)
.. ..\$ initialize:  expression({     if (NCOL(y) == 1) {         if (is.factor(y))              y <- y != levels(y)[1L]         n <- rep.int(1, nobs)         y[weights == 0] <- 0         if (any(y < 0 | y > 1))              stop("y values must be 0 <= y <= 1")         mustart <- (weights * y + 0.5)/(weights + 1)         m <- weights * y         if (any(abs(m - round(m)) > 0.001))              warning("non-integer #successes in a binomial glm!")     }     else if (NCOL(y) == 2) {         if (any(abs(y - round(y)) > 0.001))              warning("non-integer counts in a binomial glm!")         n <- y[, 1] + y[, 2]         y <- ifelse(n == 0, 0, y[, 1]/n)         weights <- weights * n         mustart <- (n * y + 0.5)/(n + 1)     }     else stop("for the binomial family, y must be a vector of 0 and 1's\n", "or a 2 column matrix where col 1 is no. successes and col 2 is no. failures") })
.. ..\$ validmu   :function (mu)
.. ..\$ valideta  :function (eta)
.. ..\$ simulate  :function (object, nsim)
.. ..- attr(*, "class")= chr "family"
..\$ linear.predictors: Named num [1:40] -1.25 -1.24 -1.24 -1.24 -1.22 ...
.. ..- attr(*, "names")= chr [1:40] "1" "2" "3" "4" ...
..\$ deviance         : num 42.7
..\$ aic              : num 46.7
..\$ null.deviance    : num 42.7
..\$ iter             : int 4
..\$ weights          : Named num [1:40] 0.173 0.174 0.174 0.174 0.176 ...
.. ..- attr(*, "names")= chr [1:40] "1" "2" "3" "4" ...
..\$ prior.weights    : Named num [1:40] 1 1 1 1 1 1 1 1 1 1 ...
.. ..- attr(*, "names")= chr [1:40] "1" "2" "3" "4" ...
..\$ df.residual      : int 38
..\$ df.null          : int 39
..\$ y                : Named num [1:40] 0 0 0 0 1 0 1 0 0 0 ...
.. ..- attr(*, "names")= chr [1:40] "1" "2" "3" "4" ...
..\$ converged        : logi TRUE
..\$ boundary         : logi FALSE
..\$ model            :'data.frame':   40 obs. of  2 variables:
.. ..\$ ldata\$DFREE: int [1:40] 0 0 0 0 1 0 1 0 0 0 ...
.. ..\$ x          : int [1:40] 39 33 33 32 24 30 39 27 40 36 ...
.. ..- attr(*, "terms")=Classes 'terms', 'formula' length 3 ldata\$DFREE ~ x
.. .. .. ..- attr(*, "variables")= language list(ldata\$DFREE, x)
.. .. .. ..- attr(*, "factors")= int [1:2, 1] 0 1
.. .. .. .. ..- attr(*, "dimnames")=List of 2
.. .. .. .. .. ..\$ : chr [1:2] "ldata\$DFREE" "x"
.. .. .. .. .. ..\$ : chr "x"
.. .. .. ..- attr(*, "term.labels")= chr "x"
.. .. .. ..- attr(*, "order")= int 1
.. .. .. ..- attr(*, "intercept")= int 1
.. .. .. ..- attr(*, "response")= int 1
.. .. .. ..- attr(*, ".Environment")=<environment: 0x017a5674>
.. .. .. ..- attr(*, "predvars")= language list(ldata\$DFREE, x)
.. .. .. ..- attr(*, "dataClasses")= Named chr [1:2] "numeric" "numeric"
.. .. .. .. ..- attr(*, "names")= chr [1:2] "ldata\$DFREE" "x"
..\$ call             : language glm(formula = ldata\$DFREE ~ x, family = binomial)
..\$ formula          :Class 'formula' length 3 ldata\$DFREE ~ x
.. .. ..- attr(*, ".Environment")=<environment: 0x017a5674>
..\$ terms            :Classes 'terms', 'formula' length 3 ldata\$DFREE ~ x
.. .. ..- attr(*, "variables")= language list(ldata\$DFREE, x)
.. .. ..- attr(*, "factors")= int [1:2, 1] 0 1
.. .. .. ..- attr(*, "dimnames")=List of 2
.. .. .. .. ..\$ : chr [1:2] "ldata\$DFREE" "x"
.. .. .. .. ..\$ : chr "x"
.. .. ..- attr(*, "term.labels")= chr "x"
.. .. ..- attr(*, "order")= int 1
.. .. ..- attr(*, "intercept")= int 1
.. .. ..- attr(*, "response")= int 1
.. .. ..- attr(*, ".Environment")=<environment: 0x017a5674>
.. .. ..- attr(*, "predvars")= language list(ldata\$DFREE, x)
.. .. ..- attr(*, "dataClasses")= Named chr [1:2] "numeric" "numeric"
.. .. .. ..- attr(*, "names")= chr [1:2] "ldata\$DFREE" "x"
..\$ data             :<environment: 0x017a5674>
..\$ offset           : NULL
..\$ control          :List of 3
.. ..\$ epsilon: num 1e-08
.. ..\$ maxit  : num 25
.. ..\$ trace  : logi FALSE
..\$ method           : chr "glm.fit"
..\$ contrasts        : NULL
..\$ xlevels          : Named list()
..- attr(*, "class")= chr [1:2] "glm" "lm"
\$ BECK   :List of 30
``````

Here is the data i have used for the example. I shortened it for the purporse of this question:

``````> ldata
ID AGE   BECK IVHX NDRUGTX RACE TREAT SITE DFREE
1   1  39  9.000    3       1    0     1    0     0
2   2  33 34.000    2       8    0     1    0     0
3   3  33 10.000    3       3    0     1    0     0
4   4  32 20.000    3       1    0     0    0     0
5   5  24  5.000    1       5    1     1    0     1
6   6  30 32.550    3       1    0     1    0     0
7   7  39 19.000    3      34    0     1    0     1
8   8  27 10.000    3       2    0     1    0     0
9   9  40 29.000    3       3    0     1    0     0
10 10  36 25.000    3       7    0     1    0     0
11 11  38 18.900    3       8    0     1    0     0
12 12  29 16.000    1       1    0     1    0     0
13 13  32 36.000    3       2    1     1    0     1
14 14  41 19.000    3       8    0     1    0     0
15 15  31 18.000    3       1    0     1    0     0
16 16  27 12.000    3       3    0     1    0     0
17 17  28 34.000    3       6    0     1    0     0
18 18  28 23.000    2       1    0     1    0     0
19 19  36 26.000    1      15    1     1    0     1
20 20  32 18.900    3       5    0     1    0     1
21 21  33 15.000    1       1    0     0    0     1
22 22  28 25.200    3       8    0     0    0     0
23 23  29  6.632    2       0    0     0    0     0
24 24  35  2.100    3       9    0     0    0     0
25 25  45 26.000    3       6    0     0    0     0
26 26  35 39.789    3       5    0     0    0     0
27 27  24 20.000    1       3    0     0    0     0
28 28  36 16.000    3       7    0     0    0     0
29 29  39 22.000    3       9    0     0    0     1
30 30  36  9.947    2      10    0     0    0     0
31 31  37  9.450    3       1    0     0    0     0
32 32  30 39.000    3       1    0     0    0     0
33 33  44 41.000    3       5    0     0    0     0
34 34  28 31.000    1       6    1     0    0     1
35 35  25 20.000    1       3    1     0    0     0
36 36  30  8.000    3       7    0     1    0     0
37 37  24  9.000    1       1    0     0    0     0
38 38  27 20.000    1       1    0     0    0     0
39 39  30  8.000    1       2    1     0    0     1
40 40  34  8.000    3       0    0     1    0     0
``````
-
You should be able to extract it from `summary()`. So you need to write an `lapply` that calls `summary()` on each item of your list. –  Andrie Oct 24 '12 at 8:02
Actually `coef(summary(...))` should do it. See ?summary.glm –  BondedDust Oct 24 '12 at 8:12

Using an example from `?glm`

``````## Dobson (1990) Page 93: Randomized Controlled Trial :
counts <- c(18,17,15,20,10,20,25,13,12)
outcome <- gl(3,1,9)
treatment <- gl(3,3)
glm.D93 <- glm(counts ~ outcome + treatment, family=poisson())

## copy twice to a list to illustrate
lmod <- list(mod1 = glm.D93, mod2 = glm.D93)
``````

Then we could compute them as `summary()` would, or extract them after calling `summary()`. The former is far more efficient as you only compute what you want. The latter doesn't rely on knowing how the standard errors are derived.

Compute the standard errors directly

The standard errors can be computed from the variance-covariance matrix of the model. The diagonal of this matrix contains the variances of the coefficients, and the standard errors are simply the square root of these variances. The `vcov()` extractor function gets the variance-covariance matrix for us and we square root the diagonals with `sqrt(diag())`:

``````> lapply(lmod, function(x) sqrt(diag(vcov(x))))
\$mod1
(Intercept)    outcome2    outcome3  treatment2  treatment3
0.1708987   0.2021708   0.1927423   0.2000000   0.2000000

\$mod2
(Intercept)    outcome2    outcome3  treatment2  treatment3
0.1708987   0.2021708   0.1927423   0.2000000   0.2000000
``````

Extract them from a call to `summary()`

Or we can let `summary()` compute the standard errors (and a lot more), then use `lapply()` or `sapply()` to apply an anonymous function that extracts `coef(summary(x))` and takes the second column (in which the standard errors are stored).

``````lapply(lmod, function(x) coef(summary(x))[,2])
``````

Which gives

``````> lapply(lmod, function(x) coef(summary(x))[,2])
\$mod1
(Intercept)    outcome2    outcome3  treatment2  treatment3
0.1708987   0.2021708   0.1927423   0.2000000   0.2000000

\$mod2
(Intercept)    outcome2    outcome3  treatment2  treatment3
0.1708987   0.2021708   0.1927423   0.2000000   0.2000000
``````

whereas `sapply()` would give:

``````> sapply(lmod, function(x) coef(summary(x))[,2])
mod1      mod2
(Intercept) 0.1708987 0.1708987
outcome2    0.2021708 0.2021708
outcome3    0.1927423 0.1927423
treatment2  0.2000000 0.2000000
treatment3  0.2000000 0.2000000
``````

Depending on what you wanted to do , you could extract both the coefficients and the standard errors with a single call:

``````> lapply(lmod, function(x) coef(summary(x))[,1:2])
\$mod1
Estimate Std. Error
(Intercept)  3.044522e+00  0.1708987
outcome2    -4.542553e-01  0.2021708
outcome3    -2.929871e-01  0.1927423
treatment2   1.337909e-15  0.2000000
treatment3   1.421085e-15  0.2000000

\$mod2
Estimate Std. Error
(Intercept)  3.044522e+00  0.1708987
outcome2    -4.542553e-01  0.2021708
outcome3    -2.929871e-01  0.1927423
treatment2   1.337909e-15  0.2000000
treatment3   1.421085e-15  0.2000000
``````

But you might prefer them separately?

-
Thanks! Just what i needed! For now I will stick with your second and easiest answer, but I will definitely return to the first part where you explain how to do more of the calculations "manually". :) Thanks! –  Rene Bern Oct 24 '12 at 10:34