I'm trying to use R to calculate the moving average over a series of values in a matrix. There doesn't seem to be a builtin function in R that will allow me to calculate moving averages. Do any packages provide one? Or do I need to write my own?
18 Answers
Or you can simply calculate it using filter, here's the function I use:
ma < function(x, n = 5){filter(x, rep(1 / n, n), sides = 2)}
If you use dplyr
, be careful to specify stats::filter
in the function above.

57I should point out that "sides=2" may be an important option in many people's use cases that they don't want to overlook. If you want only trailing information in your moving average, you should use sides=1. Apr 2, 2012 at 20:58

37Some years later but dplyr now has a filter function, if you have this package loaded use
stats::filter
– blmooreApr 8, 2015 at 14:00 
sides = 2
is equivalent to align="center" for the zoo::rollmean or RcppRoll::roll_mean.sides = 1
is equivalent to "right" alignment. I don't see a way to do "left" alignment or calculate with "partial" data (2 or more values)?– Matt L.Sep 18, 2017 at 20:32 
3
stats::filter
gives a time series object. Pass the result toas.vector
to get a vector.– qwrJul 19, 2020 at 8:34 
This may be useful to read: stackoverflow.com/a/61777773/3348414 Jul 11, 2022 at 14:20

3What is the moving average in R not containing future values of given timestamp? I checked
forecast::ma
and it contains all neighbourhood, not right.– hhhSep 7, 2018 at 20:52 
2Try the
stats::filter
function instead. There you can setsides = 1
for only past values. E.g.stats::filter(x, rep(1,5), sides = 1)/5
for the mean over 5 values.– panuffelMay 7, 2021 at 12:03 
1
Using cumsum
should be sufficient and efficient. Assuming you have a vector x and you want a running sum of n numbers
cx < c(0,cumsum(x))
rsum < (cx[(n+1):length(cx)]  cx[1:(length(cx)  n)]) / n
As pointed out in the comments by @mzuther, this assumes that there are no NAs in the data. to deal with those would require dividing each window by the number of nonNA values. Here's one way of doing that, incorporating the comment from @Ricardo Cruz:
cx < c(0, cumsum(ifelse(is.na(x), 0, x)))
cn < c(0, cumsum(ifelse(is.na(x), 0, 1)))
rx < cx[(n+1):length(cx)]  cx[1:(length(cx)  n)]
rn < cn[(n+1):length(cx)]  cn[1:(length(cx)  n)]
rsum < rx / rn
This still has the issue that if all the values in the window are NAs then there will be a division by zero error.

10One downside to this solution is that it can't handle missings:
cumsum(c(1:3,NA,1:3))
– JthorpeFeb 24, 2016 at 19:15 
@Ricardo Cruz: it might be better to remove the NAs and adjust the vector length accordingly. Think of a vector with a lot of NAs  zeros will pull the average toward zero, while removing the NAs will leave the average as it is. It all depends on your data and the question you want to answer, of course. :)– mzutherOct 2, 2018 at 14:24

1@mzuther, I updated the answer following your comments. Thanks for the input. I think the correct way of dealing with missing data is not extending the window (by removing the NA values), but by averaging each window by the correct denominator.– pipefishOct 5, 2018 at 17:33

1rn < cn[(n+1):length(cx)]  cx[1:(length(cx)  n)] should actually be rn < cn[(n+1):length(cx)]  cn[1:(length(cx)  n)] Feb 21, 2019 at 15:55

In data.table 1.12.0 new frollmean
function has been added to compute fast and exact rolling mean carefully handling NA
, NaN
and +Inf
, Inf
values.
As there is no reproducible example in the question there is not much more to address here.
You can find more info about ?frollmean
in manual, also available online at ?frollmean
.
Examples from manual below:
library(data.table)
d = as.data.table(list(1:6/2, 3:8/4))
# rollmean of single vector and single window
frollmean(d[, V1], 3)
# multiple columns at once
frollmean(d, 3)
# multiple windows at once
frollmean(d[, .(V1)], c(3, 4))
# multiple columns and multiple windows at once
frollmean(d, c(3, 4))
## three above are embarrassingly parallel using openmp
The caTools
package has very fast rolling mean/min/max/sd and few other functions. I've only worked with runmean
and runsd
and they are the fastest of any of the other packages mentioned to date.

1This is awesome! It is the only function that does this in a nice, simple way. And it's 2018 now... Apr 17, 2018 at 22:30
Here is example code showing how to compute a centered moving average and a trailing moving average using the rollmean
function from the zoo package.
library(tidyverse)
library(zoo)
some_data = tibble(day = 1:10)
# cma = centered moving average
# tma = trailing moving average
some_data = some_data %>%
mutate(cma = rollmean(day, k = 3, fill = NA)) %>%
mutate(tma = rollmean(day, k = 3, fill = NA, align = "right"))
some_data
#> # A tibble: 10 x 3
#> day cma tma
#> <int> <dbl> <dbl>
#> 1 1 NA NA
#> 2 2 2 NA
#> 3 3 3 2
#> 4 4 4 3
#> 5 5 5 4
#> 6 6 6 5
#> 7 7 7 6
#> 8 8 8 7
#> 9 9 9 8
#> 10 10 NA 9

4You can use one mutate call for multiple new columns by separating each new column with a comma.– H5470Oct 23, 2020 at 19:32
You could use RcppRoll
for very quick moving averages written in C++. Just call the roll_mean
function. Docs can be found here.
Otherwise, this (slower) for loop should do the trick:
ma < function(arr, n=15){
res = arr
for(i in n:length(arr)){
res[i] = mean(arr[(in):i])
}
res
}

3Can you please explain me in details, how does this algorithm work? Because I cannot understand the idea Mar 13, 2017 at 16:01

First he initializes a vector of the same length with
res = arr
. Then there is a loop that iterates starting atn
or, the 15th element, to the end of the array. that means the very first subset he takes the mean of isarr[1:15]
which fills spotres[15]
. Now, I prefer settingres = rep(NA, length(arr))
instead ofres = arr
so each element ofres[1:14]
equals NA rather than a number, where we couldn't take a full average of 15 elements. Sep 17, 2018 at 0:50 
In fact RcppRoll
is very good.
The code posted by cantdutchthis must be corrected in the fourth line to the window be fixed:
ma < function(arr, n=15){
res = arr
for(i in n:length(arr)){
res[i] = mean(arr[(in+1):i])
}
res
}
Another way, which handles missings, is given here.
A third way, improving cantdutchthis code to calculate partial averages or not, follows:
ma < function(x, n=2,parcial=TRUE){
res = x #set the first values
if (parcial==TRUE){
for(i in 1:length(x)){
t<max(in+1,1)
res[i] = mean(x[t:i])
}
res
}else{
for(i in 1:length(x)){
t<max(in+1,1)
res[i] = mean(x[t:i])
}
res[c(seq(1,n1,1))] #remove the n1 first,i.e., res[c(3,4,...)]
}
}
You may calculate the moving average of a vector x
with a window width of k
by:
apply(embed(x, k), 1, mean)

An extension of this to data.frames is:
apply(df,rc,FUN=function(x) apply(embed(x, k),1,mean))
.rc
can be one or two, for rows or columns, respectively. May 28, 2021 at 17:53 
In order to complement the answer of cantdutchthis and Rodrigo Remedio;
moving_fun < function(x, w, FUN, ...) {
# x: a double vector
# w: the length of the window, i.e., the section of the vector selected to apply FUN
# FUN: a function that takes a vector and return a summarize value, e.g., mean, sum, etc.
# Given a double type vector apply a FUN over a moving window from left to the right,
# when a window boundary is not a legal section, i.e. lower_bound and i (upper bound)
# are not contained in the length of the vector, return a NA_real_
if (w < 1) {
stop("The length of the window 'w' must be greater than 0")
}
output < x
for (i in 1:length(x)) {
# plus 1 because the index is inclusive with the upper_bound 'i'
lower_bound < i  w + 1
if (lower_bound < 1) {
output[i] < NA_real_
} else {
output[i] < FUN(x[lower_bound:i, ...])
}
}
output
}
# example
v < seq(1:10)
# compute a MA(2)
moving_fun(v, 2, mean)
# compute moving sum of two periods
moving_fun(v, 2, sum)
The slider package can be used for this. It has an interface that has been specifically designed to feel similar to purrr. It accepts any arbitrary function, and can return any type of output. Data frames are even iterated over row wise. The pkgdown site is here.
library(slider)
x < 1:3
# Mean of the current value + 1 value before it
# returned as a double vector
slide_dbl(x, ~mean(.x, na.rm = TRUE), .before = 1)
#> [1] 1.0 1.5 2.5
df < data.frame(x = x, y = x)
# Slide row wise over data frames
slide(df, ~.x, .before = 1)
#> [[1]]
#> x y
#> 1 1 1
#>
#> [[2]]
#> x y
#> 1 1 1
#> 2 2 2
#>
#> [[3]]
#> x y
#> 1 2 2
#> 2 3 3
The overhead of both slider and data.table's frollapply()
should be pretty low (much faster than zoo). frollapply()
looks to be a little faster for this simple example here, but note that it only takes numeric input, and the output must be a scalar numeric value. slider functions are completely generic, and you can return any data type.
library(slider)
library(zoo)
library(data.table)
x < 1:50000 + 0L
bench::mark(
slider = slide_int(x, function(x) 1L, .before = 5, .complete = TRUE),
zoo = rollapplyr(x, FUN = function(x) 1L, width = 6, fill = NA),
datatable = frollapply(x, n = 6, FUN = function(x) 1L),
iterations = 200
)
#> # A tibble: 3 x 6
#> expression min median `itr/sec` mem_alloc `gc/sec`
#> <bch:expr> <bch:tm> <bch:tm> <dbl> <bch:byt> <dbl>
#> 1 slider 19.82ms 26.4ms 38.4 829.8KB 19.0
#> 2 zoo 177.92ms 211.1ms 4.71 17.9MB 24.8
#> 3 datatable 7.78ms 10.9ms 87.9 807.1KB 38.7
EDIT: took great joy in adding the side
parameter, for a moving average (or sum, or ...) of e.g. the past 7 days of a Date
vector.
For people just wanting to calculate this themselves, it's nothing more than:
# x = vector with numeric data
# w = window length
y < numeric(length = length(x))
for (i in seq_len(length(x))) {
ind < c((i  floor(w / 2)):(i + floor(w / 2)))
ind < ind[ind %in% seq_len(length(x))]
y[i] < mean(x[ind])
}
y
But it gets fun to make it independent of mean()
, so you can calculate any 'moving' function!
# our working horse:
moving_fn < function(x, w, fun, ...) {
# x = vector with numeric data
# w = window length
# fun = function to apply
# side = side to take, (c)entre, (l)eft or (r)ight
# ... = parameters passed on to 'fun'
y < numeric(length(x))
for (i in seq_len(length(x))) {
if (side %in% c("c", "centre", "center")) {
ind < c((i  floor(w / 2)):(i + floor(w / 2)))
} else if (side %in% c("l", "left")) {
ind < c((i  floor(w) + 1):i)
} else if (side %in% c("r", "right")) {
ind < c(i:(i + floor(w)  1))
} else {
stop("'side' must be one of 'centre', 'left', 'right'", call. = FALSE)
}
ind < ind[ind %in% seq_len(length(x))]
y[i] < fun(x[ind], ...)
}
y
}
# and now any variation you can think of!
moving_average < function(x, w = 5, side = "centre", na.rm = FALSE) {
moving_fn(x = x, w = w, fun = mean, side = side, na.rm = na.rm)
}
moving_sum < function(x, w = 5, side = "centre", na.rm = FALSE) {
moving_fn(x = x, w = w, fun = sum, side = side, na.rm = na.rm)
}
moving_maximum < function(x, w = 5, side = "centre", na.rm = FALSE) {
moving_fn(x = x, w = w, fun = max, side = side, na.rm = na.rm)
}
moving_median < function(x, w = 5, side = "centre", na.rm = FALSE) {
moving_fn(x = x, w = w, fun = median, side = side, na.rm = na.rm)
}
moving_Q1 < function(x, w = 5, side = "centre", na.rm = FALSE) {
moving_fn(x = x, w = w, fun = quantile, side = side, na.rm = na.rm, 0.25)
}
moving_Q3 < function(x, w = 5, side = "centre", na.rm = FALSE) {
moving_fn(x = x, w = w, fun = quantile, side = side, na.rm = na.rm, 0.75)
}
Though a bit slow but you can also use zoo::rollapply to perform calculations on matrices.
reqd_ma < rollapply(x, FUN = mean, width = n)
where x is the data set, FUN = mean is the function; you can also change it to min, max, sd etc and width is the rolling window.

2It is not slow;. Comparing it to base R, it is much faster.
set.seed(123); x < rnorm(1000); system.time(apply(embed(x, 5), 1, mean)); library(zoo); system.time(rollapply(x, 5, mean))
On my machine it is so fast that it returns a time of 0 seconds. Sep 12, 2018 at 15:55
One can use runner
package for moving functions. In this case mean_run
function. Problem with cummean
is that it doesn't handle NA
values, but mean_run
does. runner
package also supports irregular time series and windows can depend on date:
library(runner)
set.seed(11)
x1 < rnorm(15)
x2 < sample(c(rep(NA,5), rnorm(15)), 15, replace = TRUE)
date < Sys.Date() + cumsum(sample(1:3, 15, replace = TRUE))
mean_run(x1)
#> [1] 0.5910311 0.2822184 0.6936633 0.8609108 0.4530308 0.5332176
#> [7] 0.2679571 0.1563477 0.1440561 0.2300625 0.2844599 0.2897842
#> [13] 0.3858234 0.3765192 0.4280809
mean_run(x2, na_rm = TRUE)
#> [1] 0.18760011 0.09022066 0.06543317 0.03906450 0.12188853 0.13873536
#> [7] 0.13873536 0.14571604 0.12596067 0.11116961 0.09881996 0.08871569
#> [13] 0.05194292 0.04699909 0.05704202
mean_run(x2, na_rm = FALSE )
#> [1] 0.18760011 0.09022066 0.06543317 0.03906450 0.12188853 0.13873536
#> [7] NA NA NA NA NA NA
#> [13] NA NA NA
mean_run(x2, na_rm = TRUE, k = 4)
#> [1] 0.18760011 0.09022066 0.06543317 0.03906450 0.10546063 0.16299272
#> [7] 0.21203756 0.39209010 0.13274756 0.05603811 0.03894684 0.01103493
#> [13] 0.09609256 0.09738460 0.04740283
mean_run(x2, na_rm = TRUE, k = 4, idx = date)
#> [1] 0.187600111 0.090220655 0.004349696 0.168349653 0.206571573 0.494335093
#> [7] 0.222969541 0.187600111 0.087636571 0.009742884 0.009742884 0.012326968
#> [13] 0.182442234 0.125737145 0.059094786
One can also specify other options like lag
, and roll only at
specific indexes. More in package and function documentation.
Here is a simple function with filter
demonstrating one way to take care of beginning and ending NAs with padding, and computing a weighted average (supported by filter
) using custom weights:
wma < function(x) {
wts < c(seq(0.5, 4, 0.5), seq(3.5, 0.5, 0.5))
nside < (length(wts)1)/2
# pad x with begin and end values for filter to avoid NAs
xp < c(rep(first(x), nside), x, rep(last(x), nside))
z < stats::filter(xp, wts/sum(wts), sides = 2) %>% as.vector
z[(nside+1):(nside+length(x))]
}
vector_avg < function(x){
sum_x = 0
for(i in 1:length(x)){
if(!is.na(x[i]))
sum_x = sum_x + x[i]
}
return(sum_x/length(x))
}

2

1Please relate your answer to the question and include some output which shows the question has been answered. See How to Answer for guidance on making a good answer.– PeterJul 16, 2020 at 15:35
I use aggregate along with a vector created by rep(). This has the advantage of using cbind() to aggregate more than 1 column in your dataframe at time. Below is an example of a moving average of 60 for a vector (v) of length 1000:
v=1:1000*0.002+rnorm(1000)
mrng=rep(1:round(length(v)/60+0.5), length.out=length(v), each=60)
aggregate(v~mrng, FUN=mean, na.rm=T)
Note the first argument in rep is to simply get enough unique values for the moving range, based on the length of the vector and the amount to be averaged; the second argument keeps the length equal to the vector length, and the last repeats the values of the first argument the same number of times as the averaging period.
In aggregate you could use several functions (median, max, min)  mean shown for example. Again, could could use a formula with cbind to do this on more than one (or all) columns in a dataframe.
Another useful function if you want the two ends of series not to be NA but to be recursively calculated moving averages:
smoothing = function(x, k=1) {
sapply(seq_along(x), function(i) {
i.min = max(ik, 1)
i.max = min(i+k, length(x))
mean(x[i.min:i.max], na.rm=TRUE)
})
}
Example:
x = 1:10/2
[1] 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0
smoothing(x, 2)
[1] 1.00 1.25 1.50 2.00 2.50 3.00 3.50 4.00 4.25 4.50