# 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!

## Completely vectorized numpy solution

Here is the code I use. It's not an optimal one (which I'm unable to write with `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. 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. Oct 14 '15 at 20:04
• Nice implementation of the method introduced in the last section of the wiki's webpage about weighted percentile link. Apr 18 '17 at 20:57
• Note: For integer weights, the result of this function will be different from the more naive (or "correct", depending on definition) method of "repeating each value k times, where k is the weight", because it interpolates between a single point (with weight k) instead of k points of identical height. For example, if values=[1, 2] and sample_weight=[1, 3], the weighted median is 1.75, but the un-weighted median of [1, 2, 2, 2] would be 2.
– jick
Sep 16 '19 at 23:54
• @MaxGhenis I think you're right - it's just that with integer weight it's easier to assume that (weight 3) represents (same value repeated 3 times), which tripped me. :)
– jick
Dec 5 '19 at 5:34

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)` Feb 20 '18 at 14:03

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. 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. Sep 26 '14 at 10:02
• From personal experience I can confirm that this approach is definitely not efficient. If your vectors are long and the weights are big numbers your computer can quickly hit the memory limit. Sep 10 '20 at 9:39

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

# 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. Feb 22 '18 at 15:26

Cleaner and simpler using this reference for weighted percentile method.

``````import numpy as np

def weighted_percentile(data, weights, perc):
"""
perc : percentile in [0-1]!
"""
ix = np.argsort(data)
data = data[ix] # sort data
weights = weights[ix] # sort weights
cdf = (np.cumsum(weights) - 0.5 * weights) / np.sum(weights) # 'like' a CDF function
return np.interp(perc, cdf, data)
``````

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 ) Jun 25 '15 at 15:59

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 a, w in zipped:
for j in range(w):
weighted.append(a)
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! Feb 18 '14 at 4:27
• you are supposing weights to be integers 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. Sep 26 '14 at 10:04

This seems to be now implemented in statsmodels

``````from statsmodels.stats.weightstats import DescrStatsW
wq = DescrStatsW(data=np.array([1, 2, 9, 3.2, 4]), weights=np.array([0.0, 0.5, 1.0, 0.3, 0.5]))
wq.quantile(probs=np.array([0.1, 0.9]), return_pandas=False)
# array([2., 9.])
``````

The DescrStatsW object also has other methods implemented, such as weighted mean, etc. https://www.statsmodels.org/stable/generated/statsmodels.stats.weightstats.DescrStatsW.html

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.

The `weightedcalcs` package supports quantiles:

``````import weightedcalcs as wc
import pandas as pd

df = pd.DataFrame({'v': [1, 2, 3], 'w': [3, 2, 1]})
calc = wc.Calculator('w')  # w designates weight

calc.quantile(df, 'v', 0.5)
# 1.5
``````

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.