I notice that
In : np.mean([1, 2, 3]) Out: 2.0 In : np.average([1, 2, 3]) Out: 2.0
However, there should be some differences, since after all they are two different functions.
What are the differences between them?
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try: mean = a.mean except AttributeError: return _wrapit(a, 'mean', axis, dtype, out) return mean(axis, dtype, out)
... if weights is None : avg = a.mean(axis) scl = avg.dtype.type(a.size/avg.size) else: #code that does weighted mean here if returned: #returned is another optional argument scl = np.multiply(avg, 0) + scl return avg, scl else: return avg ...
In some version of numpy there is another imporant difference that you must be aware:
average do not take in account masks, so compute the average over the whole set of data.
mean takes in account masks, so compute the mean only over unmasked values.
g = [1,2,3,55,66,77] f = np.ma.masked_greater(g,5) np.average(f) Out: 34.0 np.mean(f) Out: 2.0
In addition to the differences already noted, there's another extremely important difference that I just now discovered the hard way: unlike
np.average doesn't allow the
dtype keyword, which is essential for getting correct results in some cases. I have a very large single-precision array that is accessed from an
h5 file. If I take the mean along axes 0 and 1, I get wildly incorrect results unless I specify
>T.shape (4096, 4096, 720) >T.dtype dtype('<f4') m1 = np.average(T, axis=(0,1)) # garbage m2 = np.mean(T, axis=(0,1)) # the same garbage m3 = np.mean(T, axis=(0,1), dtype='float64') # correct results
Unfortunately, unless you know what to look for, you can't necessarily tell your results are wrong. I will never use
np.average again for this reason but will always use
np.mean(.., dtype='float64') on any large array. If I want a weighted average, I'll compute it explicitly using the product of the weight vector and the target array and then either
np.mean, as appropriate (with appropriate precision as well).