When generating random numbers in R using rnorm (or runif etc.), they seldom have the exact mean and SD as the distribution they are sampled from. Is there any simple one-or-two-liner that does this for me? As a preliminary solution, I've created this function but it seems like something that should be native to R or some package.

# Draw sample from normal distribution with guaranteed fixed mean and sd
rnorm_fixed = function(n, mu=0, sigma=1) {
  x = rnorm(n)  # from standard normal distribution
  x = sigma * x / sd(x)  # scale to desired SD
  x = x - mean(x) + mu  # center around desired mean

To illustrate:

x = rnorm(n=20, mean=5, sd=10)
mean(x)  # is e.g. 6.813...
sd(x)  # is e.g. 10.222...

x = rnorm_fixed(n=20, mean=5, sd=10)
mean(x)  # is 5
sd(x)  # is 10

The reason I want this is that I adjust my analysis on simulated data before applying it to real data. This is nice because with simulated data I know the exact properties (means, SDs etc.) and I avoid p-value inflation because I'm doing inferential statistics. I am asking if there exist anything simple like e.g.

rnorm(n=20, mean=5, sd=10, fixed=TRUE)
  • 2
    You can use the function scale to do this... but isn't this exactly illustrating the difference between sample and population statistics? As your n gets large sd(x) and mean(x) will approach the values you provided, but at only 20 samples you cannot expect perfect distribution...
    – Justin
    Sep 20, 2013 at 14:25
  • 3
    Out of curiosity, why do you need that? I wouldn't expect a sample to have the same mean and sd as the population.
    – Roland
    Sep 20, 2013 at 14:25
  • 2
    I think you've got it right. I think it's simple enough that people just do it like this when they need to. MASS::mvrnorm does have an analogous feature (but it's marginally trickier for the multivariate case, which is presumably why it's built in). Agree with @Justin that you could use mu+sigma*scale(rnorm(n)) as a one-liner ...
    – Ben Bolker
    Sep 20, 2013 at 14:26
  • 2
    Justin and Roland: I've added my motivation in the question :-) It's because I simulate data and want to know its properties! So yes, if I wanted this to represent the real world, these constraints would be strange. But I want a "perfect little world" to play around in, in order to know if I do things right :-) Sep 20, 2013 at 14:31
  • I usually just create a sample and calculate the properties.
    – Roland
    Sep 20, 2013 at 14:35

3 Answers 3


Since you asked for a one-liner:

rnorm2 <- function(n,mean,sd) { mean+sd*scale(rnorm(n)) }
r <- rnorm2(100,4,1)
mean(r)  ## 4
sd(r)    ## 1
  • From math'l point of view, is this erratic? One can desire the equivalence of the means of sample and the population from which it was drawn, but one should not desire the equivalences of the SDs of random numbers sample and its population. Central Limit Theorem: (X1+...+Xn)/n -> N(mean,StdDev.)=N(mu, sigma/sqrt(n)). Hence, to me, for math'l correctness, rnorm3 must be defined with SD=sigma/sqrt(n) (sigma: std dev. of the population) and m=mu. I wonder your considerations on this issue. So, if you also find rnorm3 necessary to be defined in accordance with CLT, how do you define it properly? Aug 1, 2019 at 20:10
  • 2
    I think, I found the answer of my question. Here, in the above code, since we are drawing just one sample from the population (instead of many samples from the population). Hence, it is normal that one may desire the equivalances of both means and SDs for the sample and the population. Aug 1, 2019 at 20:47

The mvrnorm() function in the MASS package can do this.

#empirical=T forces mean and sd to be exact
x <- mvrnorm(n=20, mu=5, Sigma=10^2, empirical=T)
#empirical=F does not impose this constraint
x <- mvrnorm(n=20, mu=5, Sigma=10^2, empirical=F

This is an improvement of the function suggested in a previous answer so that it complies with the OP's need of having a "fixed" argument.

And still in one line ;-)

rnorm. <- function(n=10, mean=0, sd=1, fixed=TRUE) { switch(fixed+1, rnorm(n, mean, sd), as.numeric(mean+sd*scale(rnorm(n)))) }
rnorm.() %>% {c(mean(.), sd(.))}
#### [1] 0 1
rnorm.(,,,F) %>% {c(mean(.), sd(.))}
#### [1] 0.1871827 0.8124567

I chose to enter default values for every argument and add a as.numeric step to get rid of the attributes generated by the scale function.

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