# Finding local maxima and minima

I'm looking for a computationally efficient way to find local maxima/minima for a large list of numbers in R. Hopefully without `for` loops...

For example, if I have a datafile like `1 2 3 2 1 1 2 1`, I want the function to return 3 and 7, which are the positions of the local maxima.

`diff(diff(x))` (or `diff(x,differences=2)`: thanks to @ZheyuanLi) essentially computes the discrete analogue of the second derivative, so should be negative at local maxima. The `+1` below takes care of the fact that the result of `diff` is shorter than the input vector.

edit: added @Tommy's correction for cases where delta-x is not 1...

``````tt <- c(1,2,3,2,1, 1, 2, 1)
which(diff(sign(diff(tt)))==-2)+1
``````

My suggestion above ( http://statweb.stanford.edu/~tibs/PPC/Rdist/ ) is intended for the case where the data are noisier.

• You beat me by a few seconds - and with a better solution :) But it should be `which(diff(sign(diff(x)))==-2)+1` if the values aren't always changing by one. – Tommy Jul 26 '11 at 21:07
• As Tommy had pointed out, Ben's solution also doesn't works when the input list is in increasing order. e.g. tt <- c(2,3,4,5,6,7) expected answer: index of last element of the list – Kaushik Acharya Feb 13 '18 at 14:01
• The link ...ppc.peaks.html does not work, use statweb.stanford.edu/~tibs/PPC/Rdist instead. – smishra Feb 21 '18 at 22:18

@Ben's solution is pretty sweet. It doesn't handle the follwing cases though:

``````# all these return numeric(0):
x <- c(1,2,9,9,2,1,1,5,5,1) # duplicated points at maxima
which(diff(sign(diff(x)))==-2)+1
x <- c(2,2,9,9,2,1,1,5,5,1) # duplicated points at start
which(diff(sign(diff(x)))==-2)+1
x <- c(3,2,9,9,2,1,1,5,5,1) # start is maxima
which(diff(sign(diff(x)))==-2)+1
``````

Here's a more robust (and slower, uglier) version:

``````localMaxima <- function(x) {
# Use -Inf instead if x is numeric (non-integer)
y <- diff(c(-.Machine\$integer.max, x)) > 0L
rle(y)\$lengths
y <- cumsum(rle(y)\$lengths)
y <- y[seq.int(1L, length(y), 2L)]
if (x[] == x[]) {
y <- y[-1]
}
y
}

x <- c(1,2,9,9,2,1,1,5,5,1)
localMaxima(x) # 3, 8
x <- c(2,2,9,9,2,1,1,5,5,1)
localMaxima(x) # 3, 8
x <- c(3,2,9,9,2,1,1,5,5,1)
localMaxima(x) # 1, 3, 8
``````
• thanks I tried this code, and it works! How do you modify this for local-minima without changing the input? – Vahid Mirjalili Sep 19 '14 at 14:10
• Hi Tommy, I wanted to use your localMinima function in a package, could you please contact me so that I can properly acknowledge you? – Yann Abraham Nov 9 '15 at 13:14
• @VahidMir Basically this functions is a (smart!) way to get the positions where the first derivative of the vector switches from positive to negative. Hence the local-minima would be given where it switches from negative to positive: just replace the first line by `y <- diff(c(.Machine\$integer.max, x)) < 0L` (this conserves the possibility to detect an initial minimum) – ztl Jul 26 '17 at 15:20
• good however `localMaxima()` false triggers on points of inflection `localMaxima(c(1, 2, 2, 3, 2, 1))` returns `2 4` instead of just `4` – jacanterbury Sep 6 '18 at 13:55
• Why is rle(y)\$lengths called twice? I mean I understand `y <- cumsum(rle(y)\$lengths)` but not the preceding standalone `rle(y)\$lengths` – Andy Apr 5 '19 at 17:59

Use the zoo library function rollapply:

``````x <- c(1, 2, 3, 2, 1, 1, 2, 1)
library(zoo)
xz <- as.zoo(x)
rollapply(xz, 3, function(x) which.min(x)==2)
#    2     3     4     5     6     7
#FALSE FALSE FALSE  TRUE FALSE FALSE
rollapply(xz, 3, function(x) which.max(x)==2)
#    2     3     4     5     6     7
#FALSE  TRUE FALSE FALSE FALSE  TRUE
``````

Then pull the index using the 'coredata' for those values where 'which.max' is a "center value" signaling a local maximum. You could obviously do the same for local minima using `which.min` instead of `which.max`.

`````` rxz <- rollapply(xz, 3, function(x) which.max(x)==2)
index(rxz)[coredata(rxz)]
# 3 7
``````

I am assuming you do not want the starting or ending values, but if you do , you could pad the ends of your vectors before processing, rather like telomeres do on chromosomes.

(I'm noting the ppc package ("Peak Probability Contrasts" for doing mass spectrometry analyses, simply because I was unaware of its availability until reading @BenBolker's comment above, and I think adding these few words will increase the chances that someone with a mass-spec interest will see this on a search.)

• This has a very significant advantage over the others. By increasing the interval to something larger than 3, we can ignore cases where one point happens to be very slightly higher than its two nearest neighbors even though there are other nearby points larger. This can be useful for measured data with small, random variations. – jpmc26 May 9 '13 at 0:41
• Thanks for the comment, and thanks to dbaupp, and credit to @GGrothendieck and Achim Zeileis for writing `zoo` so cleanly that I am able to apply it cleanly. – IRTFM Jun 21 '13 at 18:29
• This is a fantastic solution, but a word of warning: it is a good idea to explicitly define the `align` argument. `zoo:::rollapply.zoo` uses `align = "center"` by default, but `xts:::rollapply.xts` uses `align = "right"`. – mikeck May 29 '15 at 4:38
• @dleal, you roll a window of the width 3 over the array `xz`. The content of this window is the argument `x` of the function that returns index of the maximum. If this index points to the center of the window, then you are staying on the local maximum! In this particular case the window width is 3, so the middle element has index of 2. Basically, you are looking for a condition `which.max(x) == m` for a window with the width equal to `2*m–1`. – R Kiselev Jan 30 '17 at 15:29
• Although interestingly, the suggestion by @42- fails in the cases when you have more repeating values than your width (e.g. 3). In other words a saddle point will mistaken for an extreme. A simple case is: `x <- c(3, 2, 2, 2, 2, 1, 3)`, then `rx <- rollapply(as.zoo(x), 3, function(x) {which.min(x)==2)}`, and `index(rx)[coredata(rx)]` falsely gives ` 2 6` (where it should have been ` 6`). – user3375672 May 29 '17 at 18:09

I took a stab at this today. I know you said hopefully without for loops but I stuck with using the apply function. Somewhat compact and fast and allows threshold specification so you can go greater than 1.

### The function:

``````inflect <- function(x, threshold = 1){
up   <- sapply(1:threshold, function(n) c(x[-(seq(n))], rep(NA, n)))
down <-  sapply(-1:-threshold, function(n) c(rep(NA,abs(n)), x[-seq(length(x), length(x) - abs(n) + 1)]))
a    <- cbind(x,up,down)
list(minima = which(apply(a, 1, min) == a[,1]), maxima = which(apply(a, 1, max) == a[,1]))
}
``````

### To a visualize it/play with thresholds you can run the following code:

``````# Pick a desired threshold # to plot up to
n <- 2
# Generate Data
randomwalk <- 100 + cumsum(rnorm(50, 0.2, 1)) # climbs upwards most of the time
bottoms <- lapply(1:n, function(x) inflect(randomwalk, threshold = x)\$minima)
tops <- lapply(1:n, function(x) inflect(randomwalk, threshold = x)\$maxima)
# Color functions
cf.1 <- grDevices::colorRampPalette(c("pink","red"))
cf.2 <- grDevices::colorRampPalette(c("cyan","blue"))
plot(randomwalk, type = 'l', main = "Minima & Maxima\nVariable Thresholds")
for(i in 1:n){
points(bottoms[[i]], randomwalk[bottoms[[i]]], pch = 16, col = cf.1(n)[i], cex = i/1.5)
}
for(i in 1:n){
points(tops[[i]], randomwalk[tops[[i]]], pch = 16, col = cf.2(n)[i], cex = i/1.5)
}
legend("topleft", legend = c("Minima",1:n,"Maxima",1:n),
pch = rep(c(NA, rep(16,n)), 2), col = c(1, cf.1(n),1, cf.2(n)),
pt.cex =  c(rep(c(1, c(1:n) / 1.5), 2)), cex = .75, ncol = 2)
`````` • I love the function <inflect>. Thank Evan (y) – Hoang Le Feb 22 '18 at 21:05
• Pleased to hear that! – Evan Friedland Feb 22 '18 at 21:32
• My data has repeated values for maxima and minima e.g. c(1,2,3,3,2,1,1,2,3) and this generates multiple hits for each max/min. Experimenting with `threshold` only seems to change the dot size on the plot but doesn't fix this. Any suggestions? – jacanterbury Aug 24 '18 at 14:57
• Hi there, what exactly are you expecting to happen when values are tied? The function is treating them as if they are the same point -- to be ignored. On the top of a flat mountain, everywhere you walk is the peak, even if there is a crevice in the middle. What kind of data are you working with that has equal values? And by the way, the dots will vary differently if the adjacent heights are not identical. See vector `c(0,0,0,1,0.7,3,2,3,3,2,1,1,2,3,0.7, 0.5,0,0,0)` at threshold = 3 – Evan Friedland Aug 24 '18 at 15:14

There are some good solutions provided, but it depends on what you need.

Just `diff(tt)` returns the differences.

You want to detect when you go from increasing values to decreasing values. One way to do this is provided by @Ben:

`````` diff(sign(diff(tt)))==-2
``````

The problem here is that this will only detect changes that go immediately from strictly increasing to strictly decreasing.

A slight change will allow for repeated values at the peak (returning `TRUE` for last occurence of the peak value):

`````` diff(diff(x)>=0)<0
``````

Then, you simply need to properly pad the front and back if you want to detect maxima at the beginning or end of

Here's everything wrapped in a function (including finding of valleys):

`````` which.peaks <- function(x,partial=TRUE,decreasing=FALSE){
if (decreasing){
if (partial){
which(diff(c(FALSE,diff(x)>0,TRUE))>0)
}else {
which(diff(diff(x)>0)>0)+1
}
}else {
if (partial){
which(diff(c(TRUE,diff(x)>=0,FALSE))<0)
}else {
which(diff(diff(x)>=0)<0)+1
}
}
}
``````
• FAO future visitors, I tried a few of the suggested solutions here and this worked best for me. – jacanterbury Aug 24 '18 at 15:05

Late to the party, but this might be of interest for others. You can nowadays use the (internal) function `find_peaks` from `ggpmisc` package. You can parametrize it using `threshold`, `span` and `strict` arguments. Since `ggpmisc` package is aimed for using with `ggplot2` you can directly plot minima and maxima using the`stat_peaks` and `stat_valleys` functions:

``````set.seed(1)
x <- 1:10
y <- runif(10)
# Maxima
x[ggpmisc:::find_peaks(y)]
 4 7
y[ggpmisc:::find_peaks(y)]
 0.9082078 0.9446753
# Minima
x[ggpmisc:::find_peaks(-y)]
 5
y[ggpmisc:::find_peaks(-y)]
 0.2016819
# Plot
ggplot(data = data.frame(x, y), aes(x = x, y = y)) + geom_line() + stat_peaks(col = "red") + stat_valleys(col = "green")
`````` Answer by @42- is great, but I had a use case where I didn't want to use `zoo`. It's easy to implement this with `dplyr` using `lag` and `lead`:

``````library(dplyr)
test = data_frame(x = sample(1:10, 20, replace = TRUE))
mutate(test, local.minima = if_else(lag(x) > x & lead(x) > x, TRUE, FALSE)
``````

Like the `rollapply` solution, you can control the window size and edge cases through the `lag`/`lead` arguments `n` and `default`, respectively.

In the case I'm working on, duplicates are frequent. So I have implemented a function that allows finding first or last extrema (min or max):

``````locate_xtrem <- function (x, last = FALSE)
{
# use rle to deal with duplicates
x_rle <- rle(x)

# force the first value to be identified as an extrema
first_value <- x_rle\$values - x_rle\$values

# differentiate the series, keep only the sign, and use 'rle' function to
# locate increase or decrease concerning multiple successive values.
# The result values is a series of (only) -1 and 1.
#
# ! NOTE: with this method, last value will be considered as an extrema
diff_sign_rle <- c(first_value, diff(x_rle\$values)) %>% sign() %>% rle()

# this vector will be used to get the initial positions
diff_idx <- cumsum(diff_sign_rle\$lengths)

# find min and max
diff_min <- diff_idx[diff_sign_rle\$values < 0]
diff_max <- diff_idx[diff_sign_rle\$values > 0]

# get the min and max indexes in the original series
x_idx <- cumsum(x_rle\$lengths)
if (last) {
min <- x_idx[diff_min]
max <- x_idx[diff_max]
} else {
min <- x_idx[diff_min] - x_rle\$lengths[diff_min] + 1
max <- x_idx[diff_max] - x_rle\$lengths[diff_max] + 1
}
# just get number of occurences
min_nb <- x_rle\$lengths[diff_min]
max_nb <- x_rle\$lengths[diff_max]

# format the result as a tibble
bind_rows(
tibble(Idx = min, Values = x[min], NB = min_nb, Status = "min"),
tibble(Idx = max, Values = x[max], NB = max_nb, Status = "max")) %>%
arrange(.data\$Idx) %>%
mutate(Last = last) %>%
mutate_at(vars(.data\$Idx, .data\$NB), as.integer)
}
``````

The answer to the original question is:

``````> x <- c(1, 2, 3, 2, 1, 1, 2, 1)
> locate_xtrem(x)
# A tibble: 5 x 5
Idx Values    NB Status Last
<int>  <dbl> <int> <chr>  <lgl>
1     1      1     1 min    FALSE
2     3      3     1 max    FALSE
3     5      1     2 min    FALSE
4     7      2     1 max    FALSE
5     8      1     1 min    FALSE
``````

The result indicates that the second minimum is equal to 1 and that this value is repeated twice starting at index 5. Therefore, a different result could be obtained by indicating this time to the function to find the last occurrences of local extremas:

``````> locate_xtrem(x, last = TRUE)
# A tibble: 5 x 5
Idx Values    NB Status Last
<int>  <dbl> <int> <chr>  <lgl>
1     1      1     1 min    TRUE
2     3      3     1 max    TRUE
3     6      1     2 min    TRUE
4     7      2     1 max    TRUE
5     8      1     1 min    TRUE
``````

Depending on the objective, it is then possible to switch between the first and the last value of a local extremas. The second result with `last = TRUE` could also be obtained from an operation between columns "Idx" and "NB"...

Finally to deal with noise in the data, a function could be implemented to remove fluctuations below a given threshold. Code is not exposed since it goes beyond the initial question. I have wrapped it in a package (mainly to automate the testing process) and I give below a result example:

``````x_series %>% xtrem::locate_xtrem()
`````` ``````x_series %>% xtrem::locate_xtrem() %>% remove_noise()
`````` • Nice! I had a cumulative value graph, and as such had flat ranges. Yours is the only solution here that worked. Would be nice to have included the plotting code too. – James Hirschorn Jun 28 '20 at 21:14
• This is an awesome function! Being able to control first vs last within a sequence of duplicates is very handy. – VickiB Oct 25 '20 at 23:46

Here's the solution for minima:

@Ben's solution

``````x <- c(1,2,3,2,1,2,1)
which(diff(sign(diff(x)))==+2)+1 # 5
``````

Please regard the cases at Tommy's post!

@Tommy's solution:

``````localMinima <- function(x) {
# Use -Inf instead if x is numeric (non-integer)
y <- diff(c(.Machine\$integer.max, x)) > 0L
rle(y)\$lengths
y <- cumsum(rle(y)\$lengths)
y <- y[seq.int(1L, length(y), 2L)]
if (x[] == x[]) {
y <- y[-1]
}
y
}

x <- c(1,2,9,9,2,1,1,5,5,1)
localMinima(x) # 1, 7, 10
x <- c(2,2,9,9,2,1,1,5,5,1)
localMinima(x) # 7, 10
x <- c(3,2,9,9,2,1,1,5,5,1)
localMinima(x) # 2, 7, 10
``````

Please regard: Neither `localMaxima` nor `localMinima` can handle duplicated maxima/minima at start!

• Not sure what your answer really brings to the table given other answers include same algorithms. – m4rtin Sep 25 '14 at 10:26
• True, but it gives a solution for minima, such as originally asked. Plus the case of duplicated maxima/minima at start was not mentioned yet. – Sebastian Sep 25 '14 at 10:28
• Well... I can't argue with that even if it's basically the same answer. So I won't downvote but not upvote either. You should try answering question not already answered (even if this one is not officially answered, the fact that the top 2 answer have 18 and 20 votes makes it the same). – m4rtin Sep 25 '14 at 10:34
• By the way, I could need help finding a way to adapt the function for maxima/minima with bigger intervalls, so 'delta x > 1'. Anyone an idea? – Sebastian Oct 27 '14 at 7:48
• @Sebastian if not seen already, please see my answer for bigger intervals. – Evan Friedland Mar 31 '18 at 13:47

I had some trouble getting the locations to work in previous solutions and came up with a way to grab the minima and maxima directly. The code below will do this and will plot it, marking the minima in green and the maxima in red. Unlike the `which.max()` function this will pull all indices of the minima/maxima out of a data frame. The zero value is added in the first `diff()` function to account for the missing decreased length of the result that occurs whenever you use the function. Inserting this into the innermost `diff()` function call saves from having to add an offset outside of the logical expression. It doesn't matter much, but i feel it's a cleaner way to do it.

``````# create example data called stockData
stockData = data.frame(x = 1:30, y=rnorm(30,7))

# get the location of the minima/maxima. note the added zero offsets
# the location to get the correct indices
min_indexes = which(diff(  sign(diff( c(0,stockData\$y)))) == 2)
max_indexes = which(diff(  sign(diff( c(0,stockData\$y)))) == -2)

# get the actual values where the minima/maxima are located
min_locs = stockData[min_indexes,]
max_locs = stockData[max_indexes,]

# plot the data and mark minima with red and maxima with green
plot(stockData\$y, type="l")
points( min_locs, col="red", pch=19, cex=1  )
points( max_locs, col="green", pch=19, cex=1  )
``````
• Almost very nice - it doesn't seem to work with a maximum at the end> histData\$counts  18000 0 0 0 0 0 0 0 0 0 0 0  0 0 0 0 0 0 0 0 5992 – idontgetoutmuch Jan 4 '17 at 10:49
• `max_indexes = sign(diff( c(0,histData\$counts,0))))` works though but I don't know if it breaks anything else. – idontgetoutmuch Jan 4 '17 at 10:55
• @idontgetoutmuch... the method essentially uses first derivative calculations of the data and won't find a relative maxima or minima at an endpoint of the series being evaluated. it would work for the second to last value of the series if that was a relative max/min because the derivative can be approximated there. if you are looking for the max in a series the max() function should work fine. combining that with the code above should get you the info you need on max/mins. – Ehren Jan 5 '17 at 16:22
• i should have been more clear on the first sentence of my comment above... the method essentially uses first derivative approximations of the data and won't find a relative maxima or minima at an endpoint of the series being evaluated because there is no way to know if the endpoints are relative max/mins. – Ehren Jan 5 '17 at 21:59

In the `pracma` package, use the

``````tt <- c(1,2,3,2,1, 1, 2, 1)
tt_peaks <- findpeaks(tt, zero = "0", peakpat = NULL,
minpeakheight = -Inf, minpeakdistance = 1, threshold = 0, npeaks = 0, sortstr = FALSE)

[,1] [,2] [,3] [,4]
[1,]  3    3    1    5
[2,]  2    7    6    8
``````

That returns a matrix with 4 columns. The first column is showing the local peaks' absolute values. The 2nd column are the indices The 3rd and 4th column are the start and end of the peaks (with potential overlap).

One caveat: I used it in a series of non-integers, and the peak was one index too late (for all peaks) and I do not know why. So I had to manually remove "1" from my index vector (no big deal).

Finding local maxima and minima for a not so easy sequence e.g. `1 0 1 1 2 0 1 1 0 1 1 1 0 1` I would give their positions at (1), 5, 7.5, 11 and (14) for maxima and 2, 6, 9, 13 for minima.

``````#Position                1 1 1 1 1
#      1 2 3 4 5 6 7 8 9 0 1 2 3 4
x <- c(1,0,1,1,2,0,1,1,0,1,1,1,0,1) #Frequency
#      p v     p v  p  v   p   v p  p..Peak, v..Valey

peakPosition <- function(x, inclBorders=TRUE) {
if(inclBorders) {y <- c(min(x), x, min(x))
} else {y <- c(x, x)}
y <- data.frame(x=sign(diff(y)), i=1:(length(y)-1))
y <- y[y\$x!=0,]
idx <- diff(y\$x)<0
(y\$i[c(idx,F)] + y\$i[c(F,idx)] - 1)/2
}

#Find Peaks
peakPosition(x)
#1.0  5.0  7.5 11.0 14.0

#Find Valeys
peakPosition(-x)
#2  6  9 13

peakPosition(c(1,2,3,2,1,1,2,1)) #3 7
``````

This function by Timothée Poisot is handy for noisy series:

May 3, 2009
An Algorithm To Find Local Extrema In A Vector
Filed under: Algorithm — Tags: Extrema, Time series — Timothée Poisot @ 6:46pm

I spend some time looking for an algorithm to find local extrema in a vector (time series). The solution I used is to “walk” through the vector by step larger than 1, in order to retain only one value even when the values are very noisy (see the picture at the end of the post).

It goes like this :

``````findpeaks <- function(vec,bw=1,x.coo=c(1:length(vec)))
{
pos.x.max <- NULL
pos.y.max <- NULL
pos.x.min <- NULL
pos.y.min <- NULL   for(i in 1:(length(vec)-1))     {       if((i+1+bw)>length(vec)){
sup.stop <- length(vec)}else{sup.stop <- i+1+bw
}
if((i-bw)<1){inf.stop <- 1}else{inf.stop <- i-bw}
subset.sup <- vec[(i+1):sup.stop]
subset.inf <- vec[inf.stop:(i-1)]

is.max   <- sum(subset.inf > vec[i]) == 0
is.nomin <- sum(subset.sup > vec[i]) == 0

no.max   <- sum(subset.inf > vec[i]) == length(subset.inf)
no.nomin <- sum(subset.sup > vec[i]) == length(subset.sup)

if(is.max & is.nomin){
pos.x.max <- c(pos.x.max,x.coo[i])
pos.y.max <- c(pos.y.max,vec[i])
}
if(no.max & no.nomin){
pos.x.min <- c(pos.x.min,x.coo[i])
pos.y.min <- c(pos.y.min,vec[i])
}
}
return(list(pos.x.max,pos.y.max,pos.x.min,pos.y.min))
}
`````` • I like that function. It gives a nice way to determine envelopes. – Seily Jan 6 at 7:55

I posted this elsewhere, but I think this is an interesting way to go about it. I'm not sure what its computational efficiency is, but it's a very concise way of solving the problem.

``````vals=rbinom(1000,20,0.5)

text=paste0(substr(format(diff(vals),scientific=TRUE),1,1),collapse="")

sort(na.omit(c(gregexpr('[ ]-',text)[]+1,ifelse(grepl('^-',text),1,NA),
ifelse(grepl('[^-]\$',text),length(vals),NA))))
``````
• Concise but obfuscated is generally not as useful, unless it's a huge corporation that needs extreme efficiency or a contest where you need to be as unclear as possible :) Care to explain the code or the main gist? Just dumping this weird (and unreadable - why not add some spacing?) code on us like that won't result in people trying to use it – DeanAttali Feb 4 '15 at 8:25
• This is more inefficient than other methods, but it still works. I think this would fall into the contest that needs to be unclear. The general idea is that you convert the differences in code to text and take the first character of it, which is either a space if it's positive or a `-` if it's negative. If you see a `- -` pattern (or a space at either endpoint) you have found a maximum. I tried this on Linux, and I used `substr(...,2,2)` instead of `substr(...,1,1)` since there's a leading space to the text. Regular expressions are not ideal for this problem, but it's a fun solution. – Max Candocia Feb 4 '15 at 21:46

We see many nice functions and ideas with different features here. One issue of almost all examples is the efficiency. Many times we see the use of complex functions like `diff()` or `for()`-loops, which become slow when large data sets are involved. Let me introduce an efficient function I use every day, with minimal features, but very fast:

# Local Maxima Function `amax()`

The purpose is to detect all local maxima in a real valued vector. If the first element `x` is the global maximum, it is ignored, because there is no information about the previous emlement. If there is a plateau, the first edge is detected.

@param x numeric vector

@return returns the indicies of local maxima. If `x = max`, then it is ignored.

``````amax <- function(x)
{
a1 <- c(0,x,0)
a2 <- c(x,0,0)
a3 <- c(0,0,x)
e <- which((a1 >= a2 & a1 > a3)[2:(length(x))])
if(!is.na(e == 1))
if(e==1)
e <- e[-1]
if(length(e) == 0) e <- NaN
return (e)
}

a <- c(1,2,3,2,1,5,5,4)
amax(a) # 3, 6
``````

A little enhancement to the formula proposed by @BEN and regarding to the cases proposed by @TOMMY:

``````which(diff(abs(sign(diff(x)))-sign(diff(x)))==2)+1 %for local maximum
which(diff(abs(sign(diff(x)))-sign(diff(x)))==-2)+1 %for local minimum
``````