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Can you suggest a module function from numpy/scipy that can find local maxima/minima in a 1D numpy array? Obviously the simplest approach ever is to have a look at the nearest neighbours, but I would like to have an accepted solution that is part of the numpy distro.

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No that's in 2D (I am talking about 1D) and involves custom functions. I have my own simple implementation, but I was wondering if there is a better one, that comes with Numpy/Scipy modules. –  Navi Jan 7 '11 at 11:31
Maybe you could update the question to include that (1) you have a 1d array and (2) what kind of local minimum you are looking for. Just an entry smaller than the two adjacent entries? –  Sven Marnach Jan 7 '11 at 11:35
You can have a look at scipy.signal.find_peaks_cwt if you are talking of data with noise –  Lakshay Garg Jun 17 at 20:46

7 Answers 7

up vote 26 down vote accepted

If you are looking for all entries in the 1d array a smaller than their neighbors, you can try

numpy.r_[True, a[1:] < a[:-1]] & numpy.r_[a[:-1] < a[1:], True]

You could also smooth your array before this step using numpy.convolve().

I don't think there is a dedicated function for this.

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Hmm, why would I need to smooth? To remove noise? That sounds interesting. It seems to me that I could use another integer instead of 1 in your example code. I was also thinking of calculating gradients. Anyway if there is no function than that's too bad. –  Navi Jan 7 '11 at 12:02
@Navi: The problem is that the notion of "local minimum" varies vastly from use case to use case, so it's hard to provide a "standard" function for this purpose. Smoothing helps to take into account more than just the nearest neighbor. Using a different integer instead of 1, say 3, would be strange as it would only consider the third-next element in both directions, but not the direct neihgbors. –  Sven Marnach Jan 7 '11 at 13:27
I meant considering n number of neighbours in both directions. So that min(x) = min(x[i - n] : x[i + n]). –  Navi Jan 7 '11 at 13:47
Though I like the Scipy solution provided by @danodonovan, this method seems much faster for larger datasets. –  aseagram Jun 9 '14 at 22:10

In SciPy >= 0.11

import numpy as np
from scipy.signal import argrelextrema

x = np.random.random(12)

# for local maxima
argrelextrema(x, np.greater)

# for local minima
argrelextrema(x, np.less)


>>> x
array([ 0.56660112,  0.76309473,  0.69597908,  0.38260156,  0.24346445,
    0.56021785,  0.24109326,  0.41884061,  0.35461957,  0.54398472,
    0.59572658,  0.92377974])
>>> argrelextrema(x, np.greater)
(array([1, 5, 7]),)
>>> argrelextrema(x, np.less)
(array([4, 6, 8]),)

Note, these are the indices of x that are local max/min. To get the values, try:

>>> x[argrelextrema(x, np.greater)[0]]

scipy.signal also provides argrelmax and argrelmin for finding maxima and minima respectively.

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What is the significance of 12? –  marshmallow Nov 27 '14 at 20:43
@marshmallow: np.random.random(12) generates 12 random values, they are used to demonstrate the function argrelextrema. –  sebix Mar 22 at 9:50

For curves with not too much noise, I recommend the following small code snippet:

from numpy import *

# example data with some peaks:
x = linspace(0,4,1e3)
data = .2*sin(10*x)+ exp(-abs(2-x)**2)

# that's the line, you need:
a = diff(sign(diff(data))).nonzero()[0] + 1 # local min+max
b = (diff(sign(diff(data))) > 0).nonzero()[0] + 1 # local min
c = (diff(sign(diff(data))) < 0).nonzero()[0] + 1 # local max

# graphical output...
from pylab import *
plot(x[b], data[b], "o", label="min")
plot(x[c], data[c], "o", label="max")

The "+1" is important, because "diff" reduces the original index number.


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Awesome, that did the trick for me! –  Ivo Flipse Oct 15 '12 at 15:51
nice use of nested numpy functions! but note that this does miss maxima at either end of the array :) –  danodonovan Feb 28 '13 at 17:09
This will also act weird if there are repetitive values. e.g. if you take the array [1, 2, 2, 3, 3, 3, 2, 2, 1], the local maxima is obviously somewhere between the 3's in the middle. But if you run the functions you provided you get maximas at indices 2,6 and minimas at indices 1,3,5,7, which to me doesn't make much sense. –  Korem Mar 24 '13 at 21:06
To avoid this +1 instead of np.diff() use np.gradient(). –  ankostis Jan 30 at 13:41
I know this thread is years old, but it's worth adding that if your curve is too noisy, you can always try low-pass filtering first for smoothing. For me at least, most of my local max/min uses are for global max/min within some local area (e,g, the big peaks and valleys, not every variation in the data) –  marcman Jun 23 at 17:18

Update- I wasn't happy with gradient so I found it more reliable to use numpy.diff. Please let me know if it does what you want.

Regarding the issue of noise, the mathematical problem is to locate maxima/minima if we want to look at noise we can use something like convolve which was mentioned earlier.

import numpy as np
from matplotlib import pyplot


print gradients

for i in gradients[:-1]:

    if ((cmp(i,0)>0) & (cmp(gradients[count],0)<0) & (i != gradients[count])):

    if ((cmp(i,0)<0) & (cmp(gradients[count],0)>0) & (i != gradients[count])):

turning_points = {'maxima_number':maxima_num,'minima_number':minima_num,'maxima_locations':max_locations,'minima_locations':min_locations}  

print turning_points

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Do you know how this gradient is calculated? If you have noisy data probably the gradient changes a lot, but that doesn't have to mean that there is a max/min. –  Navi Jan 27 '11 at 15:09
Yes I know, however noisy data is a different issue. For that I guess use convolve. –  Mike Vella Jan 27 '11 at 15:41

Another approach (more words, less code) that may help:

The locations of local maxima and minima are also the locations of the zero crossings of the first derivative. It is generally much easier to find zero crossings than it is to directly find local maxima and minima.

Unfortunately, the first derivative tends to "amplify" noise, so when significant noise is present in the original data, the first derivative is best used only after the original data has had some degree of smoothing applied.

Since smoothing is, in the simplest sense, a low pass filter, the smoothing is often best (well, most easily) done by using a convolution kernel, and "shaping" that kernel can provide a surprising amount of feature-preserving/enhancing capability. The process of finding an optimal kernel can be automated using a variety of means, but the best may be simple brute force (plenty fast for finding small kernels). A good kernel will (as intended) massively distort the original data, but it will NOT affect the location of the peaks/valleys of interest.

Fortunately, quite often a suitable kernel can be created via a simple SWAG ("educated guess"). The width of the smoothing kernel should be a little wider than the widest expected "interesting" peak in the original data, and its shape will resemble that peak (a single-scaled wavelet). For mean-preserving kernels (what any good smoothing filter should be) the sum of the kernel elements should be precisely equal to 1.00, and the kernel should be symmetric about its center (meaning it will have an odd number of elements.

Given an optimal smoothing kernel (or a small number of kernels optimized for different data content), the degree of smoothing becomes a scaling factor for (the "gain" of) the convolution kernel.

Determining the "correct" (optimal) degree of smoothing (convolution kernel gain) can even be automated: Compare the standard deviation of the first derivative data with the standard deviation of the smoothed data. How the ratio of the two standard deviations changes with changes in the degree of smoothing cam be used to predict effective smoothing values. A few manual data runs (that are truly representative) should be all that's needed.

All the prior solutions posted above compute the first derivative, but they don't treat it as a statistical measure, nor do the above solutions attempt to performing feature preserving/enhancing smoothing (to help subtle peaks "leap above" the noise).

Finally, the bad news: Finding "real" peaks becomes a royal pain when the noise also has features that look like real peaks (overlapping bandwidth). The next more-complex solution is generally to use a longer convolution kernel (a "wider kernel aperture") that takes into account the relationship between adjacent "real" peaks (such as minimum or maximum rates for peak occurrence), or to use multiple convolution passes using kernels having different widths (but only if it is faster: it is a fundamental mathematical truth that linear convolutions performed in sequence can always be convolved together into a single convolution). But it is often far easier to first find a sequence of useful kernels (of varying widths) and convolve them together than it is to directly find the final kernel in a single step.

Hopefully this provides enough info to let Google (and perhaps a good stats text) fill in the gaps. I really wish I had the time to provide a worked example, or a link to one. If anyone comes across one online, please post it here!

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I needed something similar for a project I was working on and used the numpy.diff method mentioned above, I thought it may be helpful to mention that for my data the above code missed a few maxima and minima, by changing the middle term in both if statements to <= and >= respectively, I was able to catch all the points.

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import numpy as np
minm = np.array([])
maxm = np.array([])
i = 0
while i < length-1:
    if i < length - 1:
        while i < length-1 and y[i+1] >= y[i]:

        if i != 0 and i < length-1:
            maxm = np.append(maxm,i)


    if i < length - 1:
        while i < length-1 and y[i+1] <= y[i]:

        if i < length-1:
            minm = np.append(minm,i)

print minm
print maxm

minm and maxm contain indices of minima and maxima. For a huge data set, it will give lots of maximas/minimas so in that case smooth the curve first and then apply this algorithm.

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