# Weighted percentile using numpy

Is there a way to use the numpy.percentile function to compute weighted percentile? Or is anyone aware of an alternative python function to compute weighted percentile?

thanks!

## 9 Answers

Unfortunately, numpy doesn't have built-in weighted functions for everything, but, you can always put something together.

``````def weight_array(ar, weights):
zipped = zip(ar, weights)
weighted = []
for i in zipped:
for j in range(i):
weighted.append(i)
return weighted

np.percentile(weight_array(ar, weights), 25)
``````
• To add to this solution, you might try just `np.percentile(Counter(dict(zip(ar, weights)).elements()), 25)`. You'd need to `from collections import Counter`, and it doesn't do well with repeated keys in `ar`, but `Counter().elements()` is neat! – colcarroll Feb 18 '14 at 4:27
• thanks Joan! this helps. – user308827 Feb 18 '14 at 5:10
• you are supposing weights to be integers – Ruggero Turra Aug 7 '14 at 7:44
• Also, it will likely use a lot of excess memory and CPU time for storing and sorting, respectively. Not suited for huge amount of data. – PiHalbe Sep 26 '14 at 10:04

## Completely vectorized numpy solution

Here is the code I'm using. It's not an optimal one (which I'm unable write in `numpy`), but still much faster and more reliable than accepted solution

``````def weighted_quantile(values, quantiles, sample_weight=None,
values_sorted=False, old_style=False):
""" Very close to numpy.percentile, but supports weights.
NOTE: quantiles should be in [0, 1]!
:param values: numpy.array with data
:param quantiles: array-like with many quantiles needed
:param sample_weight: array-like of the same length as `array`
:param values_sorted: bool, if True, then will avoid sorting of
initial array
:param old_style: if True, will correct output to be consistent
with numpy.percentile.
:return: numpy.array with computed quantiles.
"""
values = np.array(values)
quantiles = np.array(quantiles)
if sample_weight is None:
sample_weight = np.ones(len(values))
sample_weight = np.array(sample_weight)
assert np.all(quantiles >= 0) and np.all(quantiles <= 1), \
'quantiles should be in [0, 1]'

if not values_sorted:
sorter = np.argsort(values)
values = values[sorter]
sample_weight = sample_weight[sorter]

weighted_quantiles = np.cumsum(sample_weight) - 0.5 * sample_weight
if old_style:
# To be convenient with numpy.percentile
weighted_quantiles -= weighted_quantiles
weighted_quantiles /= weighted_quantiles[-1]
else:
weighted_quantiles /= np.sum(sample_weight)
return np.interp(quantiles, weighted_quantiles, values)
``````

Examples:

weighted_quantile([1, 2, 9, 3.2, 4], [0.0, 0.5, 1.])

array([ 1. , 3.2, 9. ])

weighted_quantile([1, 2, 9, 3.2, 4], [0.0, 0.5, 1.], sample_weight=[2, 1, 2, 4, 1])

array([ 1. , 3.2, 9. ])

• Nice code. What's the difference for old_style? I haven't got the point yet. – Syrtis Major Oct 14 '15 at 5:31
• @SubStruct : there is some minor difference in defining quantile. I.e. you have three elements. I would expect it's 0.5 quantile to be median (which is true in both cases) and 0.33 quantile to be mean of first two elements. For `old_style` (`numpy.percentile` way) this is not true. Difference in practice is minor. – Alleo Oct 14 '15 at 20:04
• Thank you. I noticed that the difference is indeed minor for large sample. However I don't understand why we would expect the 0.33 quantile is 0.25 for array [0, 0.5, 1]. – Syrtis Major Oct 15 '15 at 3:29
• For me it seems 0.33 quantile is 0.33 for array [0, 0.5, 1] is more natural. Or it's a problem of definition, we just choose one according to the question we meet? Of course, it's not problem in most case. – Syrtis Major Oct 15 '15 at 4:22
• @SubStruct my intuition is following: 0.33 should correspond to point where 1/3 of elements are smaller, 2/3 are greater. Taking point 'right in the middle' seems to be good solution, while actually I could use any point between first two elements. – Alleo Oct 15 '15 at 12:25

A quick solution, by first sorting and then interpolating:

``````def weighted_percentile(data, percents, weights=None):
''' percents in units of 1%
weights specifies the frequency (count) of data.
'''
if weights is None:
return np.percentile(data, percents)
ind=np.argsort(data)
d=data[ind]
w=weights[ind]
p=1.*w.cumsum()/w.sum()*100
y=np.interp(percents, p, d)
return y
``````
• This produces different results for `weighted_percentile(np.array([0,3,6,9]),50,weights=np.array([1,3,3,1]))` and `weighted_percentile(np.array([0,3,3,3,6,6,6,9]),50,weights=None)` – Peter9192 Feb 20 '18 at 14:03

Apologies for the additional (unoriginal) answer (not enough rep to comment on @nayyarv's). His solution worked for me (ie. it replicates the default behavior of `np.percentage`), but I think you can eliminate the for loop with clues from how the original `np.percentage` is written.

``````def weighted_percentile(a, q=np.array([75, 25]), w=None):
"""
Calculates percentiles associated with a (possibly weighted) array

Parameters
----------
a : array-like
The input array from which to calculate percents
q : array-like
The percentiles to calculate (0.0 - 100.0)
w : array-like, optional
The weights to assign to values of a.  Equal weighting if None
is specified

Returns
-------
values : np.array
The values associated with the specified percentiles.
"""
# Standardize and sort based on values in a
q = np.array(q) / 100.0
if w is None:
w = np.ones(a.size)
idx = np.argsort(a)
a_sort = a[idx]
w_sort = w[idx]

# Get the cumulative sum of weights
ecdf = np.cumsum(w_sort)

# Find the percentile index positions associated with the percentiles
p = q * (w.sum() - 1)

# Find the bounding indices (both low and high)
idx_low = np.searchsorted(ecdf, p, side='right')
idx_high = np.searchsorted(ecdf, p + 1, side='right')
idx_high[idx_high > ecdf.size - 1] = ecdf.size - 1

# Calculate the weights
weights_high = p - np.floor(p)
weights_low = 1.0 - weights_high

# Extract the low/high indexes and multiply by the corresponding weights
x1 = np.take(a_sort, idx_low) * weights_low
x2 = np.take(a_sort, idx_high) * weights_high

# Return the average
return np.add(x1, x2)

# Sample data
a = np.array([1.0, 2.0, 9.0, 3.2, 4.0], dtype=np.float)
w = np.array([2.0, 1.0, 3.0, 4.0, 1.0], dtype=np.float)

# Make an unweighted "copy" of a for testing
a2 = np.repeat(a, w.astype(np.int))

# Tests with different percentiles chosen
q1 = np.linspace(0.0, 100.0, 11)
q2 = np.linspace(5.0, 95.0, 10)
q3 = np.linspace(4.0, 94.0, 10)
for q in (q1, q2, q3):
assert np.all(weighted_percentile(a, q, w) == np.percentile(a2, q))
``````
• This is useful. However, I had to wrap `idx_high[idx_high > ecdf.size - 1] = ecdf.size - 1` in a conditional statement in order to make it work for single percentiles as well. Guess that's why there's the `zerod` in the numpy source code. – Peter9192 Feb 22 '18 at 15:26

I don' know what's Weighted percentile means, but from @Joan Smith's answer, It seems that you just need to repeat every element in `ar`, you can use `numpy.repeat()`:

``````import numpy as np
np.repeat([1,2,3], [4,5,6])
``````

the result is:

``````array([1, 1, 1, 1, 2, 2, 2, 2, 2, 3, 3, 3, 3, 3, 3])
``````
• I suppose this is the better (as in more efficient) answer. – FooBar Sep 24 '14 at 19:46
• Still, this only supports integer weights. And will most likely be very memory and CPU-time heavy for a larger data set. – PiHalbe Sep 26 '14 at 10:02

I use this function for my needs:

``````def quantile_at_values(values, population, weights=None):
values = numpy.atleast_1d(values).astype(float)
population = numpy.atleast_1d(population).astype(float)
# if no weights are given, use equal weights
if weights is None:
weights = numpy.ones(population.shape).astype(float)
normal = float(len(weights))
# else, check weights
else:
weights = numpy.atleast_1d(weights).astype(float)
assert len(weights) == len(population)
assert (weights >= 0).all()
normal = numpy.sum(weights)
assert normal > 0.
quantiles = numpy.array([numpy.sum(weights[population <= value]) for value in values]) / normal
assert (quantiles >= 0).all() and (quantiles <= 1).all()
return quantiles
``````
• It is vectorized as far as I could go.
• It has a lot of sanity checks.
• It works with floats as weights.
• It can work without weights (→ equal weights).
• It can compute multiple quantiles at once.

Multiply results by 100 if you want percentiles instead of quantiles.

• nb this returns the quantile at value as the function says, interesting and related but not answering the OP which asks about percentiles ( and no percentile != quantile * 100 ) – ILoveCoding Jun 25 '15 at 15:59

As mentioned in comments, simply repeating values is impossible for float weights, and impractical for very large datasets. There is a library that does weighted percentiles here: http://kochanski.org/gpk/code/speechresearch/gmisclib/gmisclib.weighted_percentile-module.html It worked for me.

``````def weighted_percentile(a, percentile = np.array([75, 25]), weights=None):
"""
O(nlgn) implementation for weighted_percentile.
"""
percentile = np.array(percentile)/100.0
if weights is None:
weights = np.ones(len(a))
a_indsort = np.argsort(a)
a_sort = a[a_indsort]
weights_sort = weights[a_indsort]
ecdf = np.cumsum(weights_sort)

percentile_index_positions = percentile * (weights.sum()-1)+1
# need the 1 offset at the end due to ecdf not starting at 0
locations = np.searchsorted(ecdf, percentile_index_positions)

out_percentiles = np.zeros(len(percentile_index_positions))

for i, empiricalLocation in enumerate(locations):
# iterate across the requested percentiles
if ecdf[empiricalLocation-1] == np.floor(percentile_index_positions[i]):
# i.e. is the percentile in between 2 separate values
uppWeight = percentile_index_positions[i] - ecdf[empiricalLocation-1]
lowWeight = 1 - uppWeight

out_percentiles[i] = a_sort[empiricalLocation-1] * lowWeight + \
a_sort[empiricalLocation] * uppWeight
else:
# i.e. the percentile is entirely in one bin
out_percentiles[i] = a_sort[empiricalLocation]

return out_percentiles
``````

This is my function, it give identical behaviour to

``````np.percentile(np.repeat(a, weights), percentile)
``````

With less memory overhead. np.percentile is an O(n) implementation so it's potentially faster for small weights. It has all the edge cases sorted out - it's an exact solution. The interpolation answers above assume linear, when it's a step for most of the case, except when the weight is 1.

Say we have data [1,2,3] with weights [3, 11, 7] and I want the 25% percentile. My ecdf is going to be [3, 10, 21] and I'm looking for the 5th value. The interpolation will see [3,1] and [10, 2] as the matches and interpolate giving 1.28 despite being entirely in the 2nd bin with a value of 2.

here my solution:

``````def my_weighted_perc(data,perc,weights=None):
if weights==None:
return nanpercentile(data,perc)
else:
d=data[(~np.isnan(data))&(~np.isnan(weights))]
ix=np.argsort(d)
d=d[ix]
wei=weights[ix]
wei_cum=100.*cumsum(wei*1./sum(wei))
return interp(perc,wei_cum,d)
``````

it simply calculates the weighted CDF of the data and then it uses to estimate the weighted percentiles.