# How to avoid impression bias when calculate the ctr?

When we train a ctr(click through rate) model, sometimes we need calcute the real ctr from the history data, like this


#(click)
ctr   =  ----------------
#(impressions)



We know that, if the number of impressions is too small, the calculted ctr is not real. So we always set a threshold to filter out the large enough impressions.

But we know that the higher impressions, the higher confidence for the ctr. Then my question is that: Is there a impressions-normalized statistic method to calculate the ctr?

Thanks!

You probably need a representation of confidence interval for your estimated ctr. Wilson score interval is a good one to try. You need below stats to calculate the confidence score:

• \hat p is the observed ctr (fraction of #clicked vs #impressions)
• n is the total number of impressions
• zα/2 is the (1-α/2) quantile of the standard normal distribution

A simple implementation in python is shown below, I use z(1-α/2)=1.96 which corresponds to a 95% confidence interval. I attached 3 test results at the end of the code.

# clicks      # impressions       # conf interval
2             10                  (0.07, 0.45)
20            100                 (0.14, 0.27)
200           1000                (0.18, 0.22)


Now you can set up some threshold to use the calculated confidence interval.

from math import sqrt

def confidence(clicks, impressions):
n = impressions
if n == 0: return 0
z = 1.96 #1.96 -> 95% confidence
phat = float(clicks) / n
denorm = 1. + (z*z/n)
enum1 = phat + z*z/(2*n)
enum2 = z * sqrt(phat*(1-phat)/n + z*z/(4*n*n))
return (enum1-enum2)/denorm, (enum1+enum2)/denorm

def wilson(clicks, impressions):
if impressions == 0:
return 0
else:
return confidence(clicks, impressions)

if __name__ == '__main__':
print wilson(2,10)
print wilson(20,100)
print wilson(200,1000)

"""
--------------------
results:
(0.07048879557839793, 0.4518041980521754)
(0.14384999046998084, 0.27112660859398174)
(0.1805388068716823, 0.22099327100894336)
"""

• Thanks for your answer. But I want to know if there is a impressions-normalized statistic method, not the confidence for the estimated ctr. For example, this method may looks like this: #(click)*2/(#(impressions)+avg(#impressions)) – Tim Oct 25 '12 at 6:38
• Actually I am not sure I understand what you want and why you want that way. How about a Bayesian estimator? Or something like the IMDB score? en.wikipedia.org/wiki/Bayes_estimator – greeness Oct 25 '12 at 7:27
• Doesn't z = 1.6 corresponds to 90% confidence? Google helper: google.ru/search?q=z+values+confidence, article for dummies :-): dummies.com/how-to/content/… – skaurus Jun 8 '16 at 13:13
• You are right. Should be 1.96 for 95% confidence.fixed. – greeness Jun 8 '16 at 16:45

If you treat this as a binomial parameter, you can do Bayesian estimation. If your prior on ctr is uniform (a Beta distribution with parameters (1,1)) then your posterior is Beta(1+#click, 1+#impressions-#click). Your posterior mean is #click+1 / #impressions+2 if you want a single summary statistic of this posterior, but you probably don't, and here's why:

I don't know what your method for determining whether ctr is high enough, but let's say you're interested in everything with ctr > 0.9. You can then use the cumulative density function of the beta distribution to look at what proportion of probability mass is over the 0.9 threshold (this will just be 1 - the cdf at 0.9). In this way, your threshold will naturally incorporate uncertainty about the estimate because of limited sample size.

There are many ways to calculate this confidence interval. An alternative to the Wilson Score is the Clopper-Perrson interval, which I found useful in spreadsheets.

Upper Bound Equation

Lower Bound Equation

Where

• B() is the the Inverse Beta Distribution
• alpha is the confidence level error (e.g for 95% confidence-level, alpha is 5%)
• n is the number of samples (e.g. impressions)
• x is the number of successes (e.g. clicks)

In Excel an implementation for B() is provided by the BETA.INV formula.

There is no equivalent formula for B() in Google Sheets, but a Google Apps Script custom function can be adapted from the JavaScript Statistical Library (e.g search github for jstat)