# Is there a python (scipy) function to determine parameters needed to obtain a target power?

In R there is a very useful function that helps with determining parameters for a two sided t-test in order to obtain a target statistical power.

The function is called `power.prop.test`.

http://stat.ethz.ch/R-manual/R-patched/library/stats/html/power.prop.test.html

You can call it using:

``````power.prop.test(p1 = .50, p2 = .75, power = .90)
``````

And it will tell you n the sample size needed to obtain this power. This is extremely useful in deterring sample sizes for tests.

Is there a similar function in the scipy package?

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I think it would be here if there is. – Raufio Mar 4 '13 at 15:28
That function is also written in pure `R` so by calling it without `()` will show the source code. The port to numpy will be straight forward if it doesn't already exist. – Justin Mar 4 '13 at 15:47
Thanks @Justin this helped in creating the below. – Matt Alcock Mar 5 '13 at 9:11
Thanks @Raufio I used the page you linked to to find the isf function below. – Matt Alcock Mar 5 '13 at 9:12

I've managed to replicate the function using the below formula for n and the inverse survival function `norm.isf` from scipy.stats

``````from scipy.stats import norm, zscore

def sample_power_probtest(p1, p2, power=0.8, sig=0.05):
z = norm.isf([sig/2]) #two-sided t test
zp = -1 * norm.isf([power])
d = (p1-p2)
s =2*((p1+p2) /2)*(1-((p1+p2) /2))
n = s * ((zp + z)**2) / (d**2)
return int(round(n[0]))

def sample_power_difftest(d, s, power=0.8, sig=0.05):
z = norm.isf([sig/2])
zp = -1 * norm.isf([power])
n = s * ((zp + z)**2) / (d**2)
return int(round(n[0]))

if __name__ == '__main__':

n = sample_power_probtest(0.1, 0.11, power=0.8, sig=0.05)
print n  #14752

n = sample_power_difftest(0.1, 0.5, power=0.8, sig=0.05)
print n  #392
``````
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Have you considered donating this to SciPy? It's surely a useful function to have. – larsmans Mar 5 '13 at 10:57
Sounds like a good idea how would I do this @larsmans – Matt Alcock Mar 5 '13 at 12:37
You need to sign up at GitHub, then fork their repo, put your changes in and submit a pull request. (Unfortunately, the SciPy developer documentation is a bit of a mess at present...) – larsmans Mar 5 '13 at 12:42
Thanks @larsmans I'm on github so I'll fork and do just this. Cheers – Matt Alcock Mar 5 '13 at 12:47
This looks really promising. Any chance you can address @erikwestlund's answer below? – samthebrand Oct 13 '15 at 21:08

Some of the basic power calculations are now available in statsmodels

The blog article does not yet take the latest changes to the statsmodels code into account. Also, I haven't decided yet how many wrapper functions to provide, since many power calculations just reduce to the basic distribution.

``````>>> import statsmodels.stats.api as sms
>>> es = sms.proportion_effectsize(0.5, 0.75)
>>> sms.NormalIndPower().solve_power(es, power=0.9, alpha=0.05, ratio=1)
76.652940372066908
``````

In R stats

``````> power.prop.test(p1 = .50, p2 = .75, power = .90)

Two-sample comparison of proportions power calculation

n = 76.7069301141077
p1 = 0.5
p2 = 0.75
sig.level = 0.05
power = 0.9
alternative = two.sided

NOTE: n is number in *each* group
``````

using R's `pwr` package

``````> library(pwr)
> h<-ES.h(0.5,0.75)
> pwr.2p.test(h=h, power=0.9, sig.level=0.05)

Difference of proportion power calculation for binomial distribution (arcsine transformation)

h = 0.5235987755982985
n = 76.6529406106181
sig.level = 0.05
power = 0.9
alternative = two.sided

NOTE: same sample sizes
``````
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Something is wrong with this, the answers produced vary depending on whether you use R or Python, especially when you vary the ratio. Any ideas what's wrong? – robertevansanders Sep 4 '14 at 4:42
It's R `stats` and Stata versus R `pwr` and statsmodels. See github.com/statsmodels/statsmodels/issues/1197 and associated mailing list thread for details. I don't remember where SAS is in this. – user333700 Sep 4 '14 at 11:13

Matt's answer for getting the needed n (per group) is almost right, but there is a small error.

Given d (difference in means), s (standard deviation), sig (significance level, typically .05), and power (typically .80), the formula for calculating the number of observations per group is:

``````n= (2s^2 * ((z_(sig/2) + z_power)^2) / (d^2)
``````

As you can see in his formula, he has

``````n = s * ((zp + z)**2) / (d**2)
``````

the "s" part is wrong. a correct function that reproduces r's functionality is:

``````def sample_power_difftest(d, s, power=0.8, sig=0.05):
z = norm.isf([sig/2])
zp = -1 * norm.isf([power])
n = (2*(s**2)) * ((zp + z)**2) / (d**2)
return int(round(n[0]))
``````

Hope this helps.

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