Is there any command to find the standard error of the mean in R?
The standard error is just the standard deviation divided by the square root of the sample size. So you can easily make your own function:
> std < function(x) sd(x)/sqrt(length(x))
> std(c(1,2,3,4))
[1] 0.6454972
The standard error (SE) is just the standard deviation of the sampling distribution. The variance of the sampling distribution is the variance of the data divided by N and the SE is the square root of that. Going from that understanding one can see that it is more efficient to use variance in the SE calculation. The sd
function in R already does one square root (code for sd
is in R and revealed by just typing "sd"). Therefore, the following is most efficient.
se < function(x) sqrt(var(x)/length(x))
in order to make the function only a bit more complex and handle all of the options that you could pass to var
, you could make this modification.
se < function(x, ...) sqrt(var(x, ...)/length(x))
Using this syntax one can take advantage of things like how var
deals with missing values. Anything that can be passed to var
as a named argument can be used in this se
call.

4Interestingly, your function and Ian's are nearly identically fast. I tested them both 1000 times against 10^6 million rnorm draws (not enough power to push them harder than that). Conversely, plotrix's function was always slower than even the slowest runs of those two functions  but it also has a lot more going on under the hood. – Matt Parker Apr 20 '10 at 22:52

6

3That's a very good point. I typically use se. I have changed this answer to reflect that. – John Jan 13 '14 at 14:02

5Tom, NO
stderr
does NOT calculate standard error it displaysdisplay aspects. of connection
– forecaster Jan 21 '15 at 0:01 
15@forecaster Tom didn't say
stderr
calculates the standard error, he was warning that this name is used in base, and John originally named his functionstderr
(check the edit history...). – Molx Jul 1 '15 at 19:39
A version of John's answer above that removes the pesky NA's:
stderr < function(x, na.rm=FALSE) {
if (na.rm) x < na.omit(x)
sqrt(var(x)/length(x))
}

1Note that there is an existing function called
stderr
in thebase
package that does something else, so it might be better to chose another name for this one, e.g.se
– sparrow May 26 '20 at 11:11
As I'm going back to this question every now and then and because this question is old, I'm posting a benchmark for the most voted answers.
Note, that for @Ian's and @John's answers I created another version. Instead of using length(x)
, I used sum(!is.na(x))
(to avoid NAs).
I used a vector of 10^6, with 1,000 repetitions.
library(microbenchmark)
set.seed(123)
myVec < rnorm(10^6)
IanStd < function(x) sd(x)/sqrt(length(x))
JohnSe < function(x) sqrt(var(x)/length(x))
IanStdisNA < function(x) sd(x)/sqrt(sum(!is.na(x)))
JohnSeisNA < function(x) sqrt(var(x)/sum(!is.na(x)))
AranStderr < function(x, na.rm=FALSE) {
if (na.rm) x < na.omit(x)
sqrt(var(x)/length(x))
}
mbm < microbenchmark(
"plotrix" = {plotrix::std.error(myVec)},
"IanStd" = {IanStd(myVec)},
"JohnSe" = {JohnSe(myVec)},
"IanStdisNA" = {IanStdisNA(myVec)},
"JohnSeisNA" = {JohnSeisNA(myVec)},
"AranStderr" = {AranStderr(myVec)},
times = 1000)
mbm
Results:
Unit: milliseconds
expr min lq mean median uq max neval cld
plotrix 10.3033 10.89360 13.869947 11.36050 15.89165 125.8733 1000 c
IanStd 4.3132 4.41730 4.618690 4.47425 4.63185 8.4388 1000 a
JohnSe 4.3324 4.41875 4.640725 4.48330 4.64935 9.4435 1000 a
IanStdisNA 8.4976 8.99980 11.278352 9.34315 12.62075 120.8937 1000 b
JohnSeisNA 8.5138 8.96600 11.127796 9.35725 12.63630 118.4796 1000 b
AranStderr 4.3324 4.41995 4.634949 4.47440 4.62620 14.3511 1000 a
library(ggplot2)
autoplot(mbm)
Remembering that the mean can also by obtained using a linear model, regressing the variable against a single intercept, you can use also the lm(x~1)
function for this!
Advantages are:
 You obtain immediately confidence intervals with
confint()
 You can use tests for various hypothesis about the mean, using for example
car::linear.hypothesis()
 You can use more sophisticated estimates of the standard deviation, in case you have some heteroskedasticity, clustereddata, spatialdata etc, see package
sandwich
## generate data
x < rnorm(1000)
## estimate reg
reg < lm(x~1)
coef(summary(reg))[,"Std. Error"]
#> [1] 0.03237811
## conpare with simple formula
all.equal(sd(x)/sqrt(length(x)),
coef(summary(reg))[,"Std. Error"])
#> [1] TRUE
## extract confidence interval
confint(reg)
#> 2.5 % 97.5 %
#> (Intercept) 0.06457031 0.0625035
^{Created on 20201006 by the reprex package (v0.3.0)}
more generally, for standard errors on any other parameter, you can use the boot package for bootstrap simulations (or write them on your own)
You can use the function stat.desc from pastec package.
library(pastec)
stat.desc(x, BASIC =TRUE, NORMAL =TRUE)
you can find more about it from here: https://www.rdocumentation.org/packages/pastecs/versions/1.3.21/topics/stat.desc
y < mean(x, na.rm=TRUE)
sd(y)
for standard deviation var(y)
for variance.
Both derivations use n1
in the denominator so they are based on sample data.