# How do I calculate percentiles with python/numpy?

Is there a convenient way to calculate percentiles for a sequence or single-dimensional numpy array?

I am looking for something similar to Excel's percentile function.

I looked in NumPy's statistics reference, and couldn't find this. All I could find is the median (50th percentile), but not something more specific.

You might be interested in the SciPy Stats package. It has the percentile function you're after and many other statistical goodies.

`percentile()` is available in `numpy` too.

``````import numpy as np
a = np.array([1,2,3,4,5])
p = np.percentile(a, 50) # return 50th percentile, e.g median.
print p
3.0
``````

This ticket leads me to believe they won't be integrating `percentile()` into numpy anytime soon.

• Thank you! So that's where it's been hiding. I was aware of scipy but I guess I assumed simple things like percentiles would be built into numpy.
– Uri
Mar 3, 2010 at 20:51
• By now, a percentile function exists in numpy: docs.scipy.org/doc/numpy/reference/generated/… Oct 29, 2013 at 14:36
• You can use it as an aggregation function as well, e.g. to compute the tenth percentile of each group of a value column by key, use `df.groupby('key')[['value']].agg(lambda g: np.percentile(g, 10))` Nov 26, 2013 at 17:25
• Note that SciPy recommends to use np.percentile for NumPy 1.9 and higher Nov 26, 2015 at 18:21

By the way, there is a pure-Python implementation of percentile function, in case one doesn't want to depend on scipy. The function is copied below:

``````## {{{ http://code.activestate.com/recipes/511478/ (r1)
import math
import functools

def percentile(N, percent, key=lambda x:x):
"""
Find the percentile of a list of values.

@parameter N - is a list of values. Note N MUST BE already sorted.
@parameter percent - a float value from 0.0 to 1.0.
@parameter key - optional key function to compute value from each element of N.

@return - the percentile of the values
"""
if not N:
return None
k = (len(N)-1) * percent
f = math.floor(k)
c = math.ceil(k)
if f == c:
return key(N[int(k)])
d0 = key(N[int(f)]) * (c-k)
d1 = key(N[int(c)]) * (k-f)
return d0+d1

# median is 50th percentile.
median = functools.partial(percentile, percent=0.5)
## end of http://code.activestate.com/recipes/511478/ }}}
``````
• I am the author of the above recipe. A commenter in ASPN has pointed out the original code has a bug. The formula should be d0 = key(N[int(f)]) * (c-k); d1 = key(N[int(c)]) * (k-f). It has been corrected on ASPN. Apr 25, 2011 at 3:43
• How does `percentile` know what to use for `N`? It isn't specified in the function call. Oct 31, 2013 at 9:54
• for those who didn't even read the code, before using it, N must be sorted Mar 4, 2014 at 2:55
• I'm confused by the lambda expression. What does it do and how does it do it? I know what lambda expression are so I am not asking what lambda is. I am asking what does this specific lambda expression do and how is it doing it, step-by-step? Thanks! Oct 27, 2018 at 6:09
• The lambda function lets you transform the data in `N` before calculating a percentile. Say you actually have a list of tuples `N = [(1, 2), (3, 1), ..., (5, 1)]` and you want to get the percentile of the first element of the tuples, then you choose `key=lambda x: x[0]`. You could also apply some (order-changing) transformation to the list elements before calculating a percentile. Nov 25, 2019 at 11:55
``````import numpy as np
a = [154, 400, 1124, 82, 94, 108]
print np.percentile(a,95) # gives the 95th percentile
``````

Here's how to do it without numpy, using only python to calculate the percentile.

``````import math

def percentile(data, perc: int):
size = len(data)
return sorted(data)[int(math.ceil((size * perc) / 100)) - 1]

percentile([10.0, 9.0, 8.0, 7.0, 6.0, 5.0, 4.0, 3.0, 2.0, 1.0], 90)
# 9.0
percentile([142, 232, 290, 120, 274, 123, 146, 113, 272, 119, 124, 277, 207], 50)
# 146
``````
• Yes, you have to sort the list before: mylist=sorted(...) Jul 18, 2013 at 15:54

Starting `Python 3.8`, the standard library comes with the `quantiles` function as part of the `statistics` module:

``````from statistics import quantiles

quantiles([1, 2, 3, 4, 5], n=100)
# [0.06, 0.12, 0.18, 0.24, 0.3, 0.36, 0.42, 0.48, 0.54, 0.6, 0.66, 0.72, 0.78, 0.84, 0.9, 0.96, 1.02, 1.08, 1.14, 1.2, 1.26, 1.32, 1.38, 1.44, 1.5, 1.56, 1.62, 1.68, 1.74, 1.8, 1.86, 1.92, 1.98, 2.04, 2.1, 2.16, 2.22, 2.28, 2.34, 2.4, 2.46, 2.52, 2.58, 2.64, 2.7, 2.76, 2.82, 2.88, 2.94, 3.0, 3.06, 3.12, 3.18, 3.24, 3.3, 3.36, 3.42, 3.48, 3.54, 3.6, 3.66, 3.72, 3.78, 3.84, 3.9, 3.96, 4.02, 4.08, 4.14, 4.2, 4.26, 4.32, 4.38, 4.44, 4.5, 4.56, 4.62, 4.68, 4.74, 4.8, 4.86, 4.92, 4.98, 5.04, 5.1, 5.16, 5.22, 5.28, 5.34, 5.4, 5.46, 5.52, 5.58, 5.64, 5.7, 5.76, 5.82, 5.88, 5.94]
quantiles([1, 2, 3, 4, 5], n=100)[49] # 50th percentile (e.g median)
# 3.0
``````

`quantiles` returns for a given distribution `dist` a list of `n - 1` cut points separating the `n` quantile intervals (division of `dist` into `n` continuous intervals with equal probability):

statistics.quantiles(dist, *, n=4, method='exclusive')

where `n`, in our case (`percentiles`) is `100`.

• Just a note. With method="exclusive" p99 can be larger than maximum value in original list. If it is not what you want, i.e. you want p100 = max, then use method="inclusive". May 20 at 8:53

The definition of percentile I usually see expects as a result the value from the supplied list below which P percent of values are found... which means the result must be from the set, not an interpolation between set elements. To get that, you can use a simpler function.

``````def percentile(N, P):
"""
Find the percentile of a list of values

@parameter N - A list of values.  N must be sorted.
@parameter P - A float value from 0.0 to 1.0

@return - The percentile of the values.
"""
n = int(round(P * len(N) + 0.5))
return N[n-1]

# A = (1, 2, 3, 4, 5, 6, 7, 8, 9, 10)
# B = (15, 20, 35, 40, 50)
#
# print percentile(A, P=0.3)
# 4
# print percentile(A, P=0.8)
# 9
# print percentile(B, P=0.3)
# 20
# print percentile(B, P=0.8)
# 50
``````

If you would rather get the value from the supplied list at or below which P percent of values are found, then use this simple modification:

``````def percentile(N, P):
n = int(round(P * len(N) + 0.5))
if n > 1:
return N[n-2]
else:
return N[0]
``````

Or with the simplification suggested by @ijustlovemath:

``````def percentile(N, P):
n = max(int(round(P * len(N) + 0.5)), 2)
return N[n-2]
``````
• thanks, I also expect percentile/median to result actual values from the sets and not interpolations Nov 16, 2011 at 15:44
• Hi @mpounsett. Thank you for the upper code. Why does your percentile always return integer values? The percentile function should return the N-th percentile of a list of values, and this can be a float number too. For example, the Excel `PERCENTILE` function returns the following percentiles for your upper examples: `3.7 = percentile(A, P=0.3)`,`0.82 = percentile(A, P=0.8)`, `20 = percentile(B, P=0.3)`, `42 = percentile(B, P=0.8)`. Jun 7, 2016 at 10:41
• It's explained in the first sentence. The more common definition of percentile is that it is the number in a series below which P percent of values in the series are found. Since that is the index number of an item in a list, it cannot be a float. Aug 8, 2016 at 18:59
• This doesn't work for the 0'th percentile. It returns the maximum value. A quick fix would be to wrap the `n = int(...)` in a `max(int(...), 1)` function Dec 14, 2016 at 22:07
• To clarify, do you mean in the second example? I get 0 rather than the maximum value. The bug is actually in the else clause.. I printed the index number rather than the value I intended to. Wrapping the assignment of 'n' in a max() call would also fix it, but you'd want the second value to be 2, not 1. You could then eliminate the entire if/else structure and just print the result of N[n-2]. 0th percentile works fine in the first example, returning '1' and '15' respectively. Jan 10, 2017 at 16:19

check for scipy.stats module:

`````` scipy.stats.scoreatpercentile
``````

To calculate the percentile of a series, run:

``````from scipy.stats import rankdata
import numpy as np

def calc_percentile(a, method='min'):
if isinstance(a, list):
a = np.asarray(a)
return rankdata(a, method=method) / float(len(a))
``````

For example:

``````a = range(20)
print {val: round(percentile, 3) for val, percentile in zip(a, calc_percentile(a))}
>>> {0: 0.05, 1: 0.1, 2: 0.15, 3: 0.2, 4: 0.25, 5: 0.3, 6: 0.35, 7: 0.4, 8: 0.45, 9: 0.5, 10: 0.55, 11: 0.6, 12: 0.65, 13: 0.7, 14: 0.75, 15: 0.8, 16: 0.85, 17: 0.9, 18: 0.95, 19: 1.0}
``````

A convenient way to calculate percentiles for a one-dimensional numpy sequence or matrix is by using numpy.percentile <https://docs.scipy.org/doc/numpy/reference/generated/numpy.percentile.html>. Example:

``````import numpy as np

a = np.array([0,1,2,3,4,5,6,7,8,9,10])
p50 = np.percentile(a, 50) # return 50th percentile, e.g median.
p90 = np.percentile(a, 90) # return 90th percentile.
print('median = ',p50,' and p90 = ',p90) # median =  5.0  and p90 =  9.0
``````

However, if there is any NaN value in your data, the above function will not be useful. The recommended function to use in that case is the numpy.nanpercentile <https://docs.scipy.org/doc/numpy/reference/generated/numpy.nanpercentile.html> function:

``````import numpy as np

a_NaN = np.array([0.,1.,2.,3.,4.,5.,6.,7.,8.,9.,10.])
a_NaN[0] = np.nan
print('a_NaN',a_NaN)
p50 = np.nanpercentile(a_NaN, 50) # return 50th percentile, e.g median.
p90 = np.nanpercentile(a_NaN, 90) # return 90th percentile.
print('median = ',p50,' and p90 = ',p90) # median =  5.5  and p90 =  9.1
``````

In the two options presented above, you can still choose the interpolation mode. Follow the examples below for easier understanding.

``````import numpy as np

b = np.array([1,2,3,4,5,6,7,8,9,10])
print('percentiles using default interpolation')
p10 = np.percentile(b, 10) # return 10th percentile.
p50 = np.percentile(b, 50) # return 50th percentile, e.g median.
p90 = np.percentile(b, 90) # return 90th percentile.
print('p10 = ',p10,', median = ',p50,' and p90 = ',p90)
#p10 =  1.9 , median =  5.5  and p90 =  9.1

print('percentiles using interpolation = ', "linear")
p10 = np.percentile(b, 10,interpolation='linear') # return 10th percentile.
p50 = np.percentile(b, 50,interpolation='linear') # return 50th percentile, e.g median.
p90 = np.percentile(b, 90,interpolation='linear') # return 90th percentile.
print('p10 = ',p10,', median = ',p50,' and p90 = ',p90)
#p10 =  1.9 , median =  5.5  and p90 =  9.1

print('percentiles using interpolation = ', "lower")
p10 = np.percentile(b, 10,interpolation='lower') # return 10th percentile.
p50 = np.percentile(b, 50,interpolation='lower') # return 50th percentile, e.g median.
p90 = np.percentile(b, 90,interpolation='lower') # return 90th percentile.
print('p10 = ',p10,', median = ',p50,' and p90 = ',p90)
#p10 =  1 , median =  5  and p90 =  9

print('percentiles using interpolation = ', "higher")
p10 = np.percentile(b, 10,interpolation='higher') # return 10th percentile.
p50 = np.percentile(b, 50,interpolation='higher') # return 50th percentile, e.g median.
p90 = np.percentile(b, 90,interpolation='higher') # return 90th percentile.
print('p10 = ',p10,', median = ',p50,' and p90 = ',p90)
#p10 =  2 , median =  6  and p90 =  10

print('percentiles using interpolation = ', "midpoint")
p10 = np.percentile(b, 10,interpolation='midpoint') # return 10th percentile.
p50 = np.percentile(b, 50,interpolation='midpoint') # return 50th percentile, e.g median.
p90 = np.percentile(b, 90,interpolation='midpoint') # return 90th percentile.
print('p10 = ',p10,', median = ',p50,' and p90 = ',p90)
#p10 =  1.5 , median =  5.5  and p90 =  9.5

print('percentiles using interpolation = ', "nearest")
p10 = np.percentile(b, 10,interpolation='nearest') # return 10th percentile.
p50 = np.percentile(b, 50,interpolation='nearest') # return 50th percentile, e.g median.
p90 = np.percentile(b, 90,interpolation='nearest') # return 90th percentile.
print('p10 = ',p10,', median = ',p50,' and p90 = ',p90)
#p10 =  2 , median =  5  and p90 =  9
``````

If your input array only consists of integer values, you might be interested in the percentil answer as an integer. If so, choose interpolation mode such as ‘lower’, ‘higher’, or ‘nearest’.

• Thanks For mentioning the `interpolation` option since without it the outputs were misleading Jan 24, 2021 at 13:05

In case you need the answer to be a member of the input numpy array:

Just to add that the percentile function in numpy by default calculates the output as a linear weighted average of the two neighboring entries in the input vector. In some cases people may want the returned percentile to be an actual element of the vector, in this case, from v1.9.0 onwards you can use the "interpolation" option, with either "lower", "higher" or "nearest".

``````import numpy as np
x=np.random.uniform(10,size=(1000))-5.0

np.percentile(x,70) # 70th percentile

2.075966046220879

np.percentile(x,70,interpolation="nearest")

2.0729677997904314
``````

The latter is an actual entry in the vector, while the former is a linear interpolation of two vector entries that border the percentile

for a series: used describe functions

suppose you have df with following columns sales and id. you want to calculate percentiles for sales then it works like this,

``````df['sales'].describe(percentiles = [0.0,0.1,0.2,0.3,0.4,0.5,0.6,0.7,0.8,0.9,1])

0.0: .0: minimum
1: maximum
0.1 : 10th percentile and so on
``````

I bootstrap the data and then plotted out the confidence interval for 10 samples. The confidence interval shows the range where the probabilities will fall between 5 percent and 95 percent probability.

`````` import pandas as pd
import matplotlib.pyplot as plt
import seaborn as sns
import numpy as np
import json
import dc_stat_think as dcst

data = [154, 400, 1124, 82, 94, 108]
#print (np.percentile(data,[0.5,95])) # gives the 95th percentile

bs_data = dcst.draw_bs_reps(data, np.mean, size=6*10)

#print(np.reshape(bs_data,(24,6)))

x= np.linspace(1,6,6)
print(x)
for (item1,item2,item3,item4,item5,item6) in bs_data.reshape((10,6)):
line_data=[item1,item2,item3,item4,item5,item6]
ci=np.percentile(line_data,[.025,.975])
mean_avg=np.mean(line_data)
fig, ax = plt.subplots()
ax.plot(x,line_data)
ax.fill_between(x, (line_data-ci[0]), (line_data+ci[1]), color='b', alpha=.1)
ax.axhline(mean_avg,color='red')
plt.show()
``````