After reading How Not to Sort by Average Rating, I was curious if anyone has a Python implementation of a Lower bound of Wilson score confidence interval for a Bernoulli parameter?

for more precision if n*pcap*(1pcap) is below a certain threshold, say 3035 I'd use a tdistribution with df: (pos+neg)2 instead of a normal distr. anyhow. just my two cents though – luke14free Apr 5 '12 at 14:12
Reddit uses the Wilson score interval for comment ranking, an explanation and python implementation can be found here
#Rewritten code from /r2/r2/lib/db/_sorts.pyx
from math import sqrt
def confidence(ups, downs):
n = ups + downs
if n == 0:
return 0
z = 1.0 #1.44 = 85%, 1.96 = 95%
phat = float(ups) / n
return ((phat + z*z/(2*n)  z * sqrt((phat*(1phat)+z*z/(4*n))/n))/(1+z*z/n))

4If you're just going to post a link, do it in a comment. If you're posting it as an answer, provide more info from the content and / or pull out the code so not everyone needs to follow the link, and the answer has value even if the link goes dead. – agf Apr 5 '12 at 13:41

2

1@Vladtn I just updated it with Gullevek's answer. Let me know if there is anything else wrong with it. – Amelio VazquezReina Jul 10 '13 at 14:36

2I'd just like to add that for a 95% confidence interval the z score should be 1.96, not 1.6. – Wesley Aug 9 '13 at 23:34

1@Wesley yes, and I believe
1.0 = 85%
was also wrong, have updated the answer... there is a table of values here dummies.com/howto/content/… – Anentropic Jan 23 '14 at 7:19
I think this one has a wrong wilson call, because if you have 1 up 0 down you get NaN because you can't do a sqrt
on the negative value.
The correct one can be found when looking at the ruby example from the article How not to sort by average page:
return ((phat + z*z/(2*n)  z * sqrt((phat*(1phat)+z*z/(4*n))/n))/(1+z*z/n))
To get the Wilson CI without continuity correction, you can use proportion_confint
in statsmodels.stats.proportion
. To get the Wilson CI with continuity correction, you can use the code below.
# cf.
# [1] R. G. Newcombe. Twosided confidence intervals for the single proportion, 1998
# [2] R. G. Newcombe. Interval Estimation for the difference between independent proportions: comparison of eleven methods, 1998
import numpy as np
from statsmodels.stats.proportion import proportion_confint
# # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # #
def propci_wilson_cc(count, nobs, alpha=0.05):
# get confidence limits for proportion
# using wilson score method w/ cont correction
# i.e. Method 4 in Newcombe [1];
# verified via Table 1
from scipy import stats
n = nobs
p = count/n
q = 1.p
z = stats.norm.isf(alpha / 2.)
z2 = z**2
denom = 2*(n+z2)
num = 2.*n*p+z21.z*np.sqrt(z221./n+4*p*(n*q+1))
ci_l = num/denom
num = 2.*n*p+z2+1.+z*np.sqrt(z2+21./n+4*p*(n*q1))
ci_u = num/denom
if p == 0:
ci_l = 0.
elif p == 1:
ci_u = 1.
return ci_l, ci_u
def dpropci_wilson_nocc(a,m,b,n,alpha=0.05):
# get confidence limits for difference in proportions
# a/m  b/n
# using wilson score method WITHOUT cont correction
# i.e. Method 10 in Newcombe [2]
# verified via Table II
theta = a/m  b/n
l1, u1 = proportion_confint(count=a, nobs=m, alpha=0.05, method='wilson')
l2, u2 = proportion_confint(count=b, nobs=n, alpha=0.05, method='wilson')
ci_u = theta + np.sqrt((a/mu1)**2+(b/nl2)**2)
ci_l = theta  np.sqrt((a/ml1)**2+(b/nu2)**2)
return ci_l, ci_u
def dpropci_wilson_cc(a,m,b,n,alpha=0.05):
# get confidence limits for difference in proportions
# a/m  b/n
# using wilson score method w/ cont correction
# i.e. Method 11 in Newcombe [2]
# verified via Table II
theta = a/m  b/n
l1, u1 = propci_wilson_cc(count=a, nobs=m, alpha=alpha)
l2, u2 = propci_wilson_cc(count=b, nobs=n, alpha=alpha)
ci_u = theta + np.sqrt((a/mu1)**2+(b/nl2)**2)
ci_l = theta  np.sqrt((a/ml1)**2+(b/nu2)**2)
return ci_l, ci_u
# # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # #
# single proportion testing
# these come from Newcombe [1] (Table 1)
a_vec = np.array([81, 15, 0, 1])
m_vec = np.array([263, 148, 20, 29])
for (a,m) in zip(a_vec,m_vec):
l1, u1 = proportion_confint(count=a, nobs=m, alpha=0.05, method='wilson')
l2, u2 = propci_wilson_cc(count=a, nobs=m, alpha=0.05)
print(a,m,l1,u1,' ',l2,u2)
# # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # # #
# difference in proportions testing
# these come from Newcombe [2] (Table II)
a_vec = np.array([56,9,6,5,0,0,10,10],dtype=float)
m_vec = np.array([70,10,7,56,10,10,10,10],dtype=float)
b_vec = np.array([48,3,2,0,0,0,0,0],dtype=float)
n_vec = np.array([80,10,7,29,20,10,20,10],dtype=float)
print('\nWilson without CC')
for (a,m,b,n) in zip(a_vec,m_vec,b_vec,n_vec):
l, u = dpropci_wilson_nocc(a,m,b,n,alpha=0.05)
print('{:2.0f}/{:2.0f}{:2.0f}/{:2.0f} ; {:6.4f} ; {:8.4f}, {:8.4f}'.format(a,m,b,n,a/mb/n,l,u))
print('\nWilson with CC')
for (a,m,b,n) in zip(a_vec,m_vec,b_vec,n_vec):
l, u = dpropci_wilson_cc(a,m,b,n,alpha=0.05)
print('{:2.0f}/{:2.0f}{:2.0f}/{:2.0f} ; {:6.4f} ; {:8.4f}, {:8.4f}'.format(a,m,b,n,a/mb/n,l,u))
HTH
If you'd like to actually calculate z directly from a confidence bound and want to avoid installing numpy/scipy, you can use the following snippet of code,
import math
def binconf(p, n, c=0.95):
'''
Calculate binomial confidence interval based on the number of positive and
negative events observed. Uses Wilson score and approximations to inverse
of normal cumulative density function.
Parameters

p: int
number of positive events observed
n: int
number of negative events observed
c : optional, [0,1]
confidence percentage. e.g. 0.95 means 95% confident the probability of
success lies between the 2 returned values
Returns

theta_low : float
lower bound on confidence interval
theta_high : float
upper bound on confidence interval
'''
p, n = float(p), float(n)
N = p + n
if N == 0.0: return (0.0, 1.0)
p = p / N
z = normcdfi(1  0.5 * (1c))
a1 = 1.0 / (1.0 + z * z / N)
a2 = p + z * z / (2 * N)
a3 = z * math.sqrt(p * (1p) / N + z * z / (4 * N * N))
return (a1 * (a2  a3), a1 * (a2 + a3))
def erfi(x):
"""Approximation to inverse error function"""
a = 0.147 # MAGIC!!!
a1 = math.log(1  x * x)
a2 = (
2.0 / (math.pi * a)
+ a1 / 2.0
)
return (
sign(x) *
math.sqrt( math.sqrt(a2 * a2  a1 / a)  a2 )
)
def sign(x):
if x < 0: return 1
if x == 0: return 0
if x > 0: return 1
def normcdfi(p, mu=0.0, sigma2=1.0):
"""Inverse CDF of normal distribution"""
if mu == 0.0 and sigma2 == 1.0:
return math.sqrt(2) * erfi(2 * p  1)
else:
return mu + math.sqrt(sigma2) * normcdfi(p)
The accepted solution seems to use a hardcoded zvalue (best for performance).
In the event that you wanted a direct python equivalent of the ruby formula from the blogpost with a dynamic zvalue (based on the confidence interval):
import math
import scipy.stats as st
def ci_lower_bound(pos, n, confidence):
if n == 0:
return 0
z = st.norm.ppf(1  (1  confidence) / 2)
phat = 1.0 * pos / n
return (phat + z * z / (2 * n)  z * math.sqrt((phat * (1  phat) + z * z / (4 * n)) / n)) / (1 + z * z / n)