# Python : easy way to do geometric mean in python?

I wonder is there any easy way to do geometric mean using python but without using python package. If there is not, is there any simple package to do geometric mean?

The formula of the gemetric mean is: So you can easily write an algorithm like:

``````import numpy as np

def geo_mean(iterable):
a = np.array(iterable)
return a.prod()**(1.0/len(a))``````

You do not have to use numpy for that, but it tends to perform operations on arrays faster than Python (since there is less "overhead" with casting).

In case the chances of overflow are high, you can map the numbers to a log domain first, calculate the sum of these logs, then multiply by 1/n and finally calculate the exponent, like:

``````import numpy as np

def geo_mean_overflow(iterable):
a = np.log(iterable)
return np.exp(a.sum()/len(a))``````
• Good job with using logs for this. People often forget about overflow. – Pablo Maurin Mar 29 '17 at 17:12
• What actually is overflow ? – WaterRocket8236 Apr 18 '18 at 7:00
• @BhabaniMohapatra: a floating point has a fixed number of bits. Hence it can represent a fixed number of values. Overflow is a sitation in which you calculate a number that can no longer be represented. Python uses a 64-bit float, so that means the maximum value is 1.7976931348623157e+308. Although this is rather large, in case we do not work with logs, and we have for example 310 numbers that each are around 10, then overflow can already occur. – Willem Van Onsem Apr 18 '18 at 7:02
• @BhabaniMohapatra: see for example here stackoverflow.com/questions/40082459/… (this is indeed more specific to JavaScript, but this phenomena happen in all programming languages with floating points). – Willem Van Onsem Apr 18 '18 at 7:05
• Can you comment on the difference between `a.sum()` and `sum(a)` as it relates to efficiency or overlow? and why not write `np.exp(a.mean())` (last line)? Thanks. – PatrickT Oct 23 '18 at 15:17

In case someone is looking here for a library implementation, there is gmean() in scipy, possibly faster and numerically more stable than a custom implementation:

``````>>> from scipy.stats.mstats import gmean
>>> gmean([1.0, 0.00001, 10000000000.])
46.415888336127786
``````

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

``````from statistics import geometric_mean

geometric_mean([1.0, 0.00001, 10000000000.]) // 46.415888336127786
``````

just do this:

``````numbers = [1, 3, 5, 7, 10]

print reduce(lambda x, y: x*y, numbers)**(1.0/len(numbers))
``````
• Now it is correct. Note however that by using `reduce(..)` you will introduce some computational overhead. – Willem Van Onsem Mar 29 '17 at 17:01

Here's an overflow-resistant version in pure Python, basically the same as the accepted answer.

``````import math

def geomean(xs):
return math.exp(math.fsum(math.log(x) for x in xs) / len(xs))
``````

# Geometric mean

``````import pandas as pd
geomean=Variable.product()**(1/len(Variable))
print(geomean)
``````

# Geometric mean with Scipy

``````from scipy import stats
print(stats.gmean(Variable))
``````

You can also calculate the geometrical mean with numpy:

``````import numpy as np
np.exp(np.mean(np.log([1, 2, 3])))
``````

result:

``````1.8171205928321397
``````