# Downsample a 1D numpy array

I have a 1-d numpy array which I would like to downsample. Any of the following methods are acceptable if the downsampling raster doesn't perfectly fit the data:

• overlap downsample intervals
• convert whatever number of values remains at the end to a separate downsampled value
• interpolate to fit raster

basically if I have

``````1 2 6 2 1
``````

and I am downsampling by a factor of 3, all of the following are ok:

``````3 3

3 1.5
``````

or whatever an interpolation would give me here.

I'm just looking for the fastest/easiest way to do this.

I found `scipy.signal.decimate`, but that sounds like it decimates the values (takes them out as needed and only leaves one in X). `scipy.signal.resample` seems to have the right name, but I do not understand where they are going with the whole fourier thing in the description. My signal is not particularly periodic.

Could you give me a hand here? This seems like a really simple task to do, but all these functions are quite intricate...

• how would you recommend I do it? – TheChymera Dec 2 '13 at 6:36
• I would just use `scipy.ndimage.zoom`. I'm sure it won't run as fast as @shx2's neighborhood mean, though, but it is more readable and easier to use if the shapes don't align perfectly. – askewchan Dec 2 '13 at 14:45

In the simple case where your array's size is divisible by the downsampling factor (`R`), you can `reshape` your array, and take the mean along the new axis:

``````import numpy as np
a = np.array([1.,2,6,2,1,7])
R = 3
a.reshape(-1, R)
=> array([[ 1.,  2.,  6.],
[ 2.,  1.,  7.]])

a.reshape(-1, R).mean(axis=1)
=> array([ 3.        ,  3.33333333])
``````

In the general case, you can pad your array with `NaN`s to a size divisible by `R`, and take the mean using `scipy.nanmean`.

``````import math, scipy
b = np.append(a, [ 4 ])
b.shape
=> (7,)
=> (9,)
=> array([ 3.        ,  3.33333333,  4.])
``````
• The syntax `a.reshape(-1, R)` works because of a non-documented (as of today) behaviour of `reshape` that when multiple `int` arguments are passed, they are treated as if they were passed in a tuple. So, `a.reshape(-1, R)` is equivalent to `a.reshape((-1, R))` (the documented syntax). See here. – Luca Citi May 8 '16 at 20:32

If array size is not divisible by downsampling factor (R), reshaping (splitting) of array can be done using np.linspace followed by mean of each subarray.

``````input_arr = np.arange(531)

R = 150 (number of split)

split_arr = np.linspace(0, len(input_arr), num=R+1, dtype=int)

dwnsmpl_subarr = np.split(input_arr, split_arr[1:])

dwnsmpl_arr = np.array( list( np.mean(item) for item in dwnsmpl_subarr[:-1] ) )
``````
• Generally, answers are much more helpful if they include an explanation of what the code is intended to do, and why that solves the problem without introducing others. – Tom Aranda Dec 21 '17 at 18:36

Here are a few approaches using either linear interpolation or the Fourier method. These methods support upsampling as well as downsampling.

``````import numpy as np
import matplotlib.pyplot as plt
from scipy.signal import resample
from scipy.interpolate import interp1d

def ResampleLinear1D(original, targetLen):
original = np.array(original, dtype=np.float)
index_arr = np.linspace(0, len(original)-1, num=targetLen, dtype=np.float)
index_floor = np.array(index_arr, dtype=np.int) #Round down
index_ceil = index_floor + 1
index_rem = index_arr - index_floor #Remain

val1 = original[index_floor]
val2 = original[index_ceil % len(original)]
interp = val1 * (1.0-index_rem) + val2 * index_rem
assert(len(interp) == targetLen)
return interp

if __name__=="__main__":

original = np.sin(np.arange(256)/10.0)
targetLen = 100

# Method 1: Use scipy interp1d (linear interpolation)
# This is the simplest conceptually as it just uses linear interpolation. Scipy
# also offers a range of other interpolation methods.
f = interp1d(np.arange(256), original, 'linear')
plt.plot(np.apply_along_axis(f, 0, np.linspace(0, 255, num=targetLen)))

# Method 2: Use numpy to do linear interpolation
# If you don't have scipy, you can do it in numpy with the above function
plt.plot(ResampleLinear1D(original, targetLen))

# Method 3: Use scipy's resample
# Converts the signal to frequency space (Fourier method), then back. This
# works efficiently on periodic functions but poorly on non-periodic functions.
plt.plot(resample(original, targetLen))

plt.show()
``````