I am calculating standard deviations on an expanding window where at each point I recalculate the standard deviation. This seems like a fairly straightforward thing to do that should be relatively fast. However, it takes a lot longer than you might think (~45 seconds). Am I missing something here? In Matlab this is quite fast.
t0 <- proc.time()[[3]]
z <- rep(0, 7000)
x <- rnorm(8000)
for(i in 1000:8000){
## print(i)
z[i] <- sd(x[1:i])
}
print(proc.time()[[3]]- t0)
You might also try an algorithm that updates the standard deviation (well, actually, the sum of squares of differences from the mean) as you go. On my system this reduces the time from ~0.8 seconds to ~0.002 seconds.
n <- length(x)
m <- cumsum(x)/(1:n)
m1 <- c(NA,m[1:(n-1)])
ssd <- (x-m)*(x-m1)
v <- c(0,cumsum(ssd[-1])/(1:(n-1)))
z <- sqrt(v)
See http://en.wikipedia.org/wiki/Algorithms_for_calculating_variance for details.
Also see the answers to this question: Efficient calculation of matrix cumulative standard deviation in r
apply is just a wrapper using a for-loop. Look at the code.
apply might simply use a scripted for-loop but lapply and vapply certainly do not... And R core can improve apply in future releases...
lappy/vapply. So calling a function that does some simple thing is much faster with lapply/vapply. I have a sample that doesn't fit here that is 4x faster with vapply...
Edited to fix some typos, sorry.
This takes ~1.3 seconds on my machine:
t0 <- proc.time()[[3]]
x <- rnorm(8000)
z <- sapply(1000:8000,function(y){sd(x[seq_len(y)])})
print(proc.time()[[3]]- t0)
and I'd be willing to bet there are even faster ways of doing this. Avoid explicit for loops!
rnorm() call out of the timing on both approaches as it is fixed.
Sep 19, 2011 at 17:54
When a somewhat similar question about a cumulative variance and a cumularive kurtosis operation came up in rhelp a few days ago, here is what I offered :
daily <- rnorm(1000000)
mbar <- mean(daily)
cumvar <- cumsum( (daily-cumsum(daily)/1:length(daily) )^2)
cumskew <- cumsum( (daily-cumsum(daily)/1:length(daily))^3)/cumvar^(3/2)
It's certainly faster than the sapply method but may be comparable to Aaron's.
system.time( cumvar <- cumsum( (daily-cumsum(daily)/1:length(daily) )^2) )
user system elapsed
0.037 0.026 0.061
system.time(cumsd <- sqrt(cumvar) )
user system elapsed
0.009 0.005 0.013
cumvar[5] with var(daily[1:5]).
Sep 19, 2011 at 19:25
zbecause you start it with only 7000 but then put something in spots 7001:8000.