I am trying to produce a random distribution where I control the mean, SD, skewness and kurtosis.
I can solve the mean and SD with some simple maths after the distribution is produced.
Kurtosis I am leaving on the shelf for the moment because it just seems too hard.
Skewness is today's problem.
import scipy.stats
def convert_to_alpha(s):
d=(np.pi/2*((abs(s)**(2/3))/(abs(s)**(2/3)+((4-np.pi)/2)**(2/3))))**0.5
a=((d)/((1-d**2)**.5))
return(a)
for skewness_expected in (.5, .9, 1.3):
alpha = convert_to_alpha(skewness_expected)
r = stats.skewnorm.rvs(alpha,size=10000)
print('Skewness expected:',skewness_expected)
print('Skewness obtained:',stats.skew(r))
print()
Skewness expected: 0.5
Skewness obtained: 0.47851348006629035
Skewness expected: 0.9
Skewness obtained: 0.8917020428586827
Skewness expected: 1.3
Skewness obtained: (1.2794406116842627+0.01780402125888404j)
I understand that the calculated skewness will generally not match the desired skewness - this is a random distribution, after all. But I am confused as to how I can get a distribution with a skewness > 1 without falling into complex number territory. The rvs method appears incapable of handling it, since the parameter alpha is an imaginary number whenever skewness > 1.
How can I fix it so that I can generate distributions with skewness > 1, but not have complex numbers creeping in?
[With credit to Warren Weckesser for pointing me at Wikipedia in order to write the convert_to_alpha function.]