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So I have a bunch of hyperlinks on a web page. From past observation I know the probabilities that a user will click on each of these hyperlinks. I can therefore calculate the mean and standard deviation of these probabilities.

I now add a new hyperlink to this page. After a short amount of testing I find that of the 20 users that see this hyperlink, 5 click on it.

Taking into account the known mean and standard deviation of the click-through probabilities on other hyperlinks (this forms a "prior expectation"), how can I efficiently estimate the probability of a user clicking on the new hyperlink?

A naive solution would be to ignore the other probabilities, in which case my estimate is just 5/20 or 0.25 - however this means we are throwing away relevant information, namely our prior expectation of what the click-through probability is.

So I'm looking for a function that looks something like this:

double estimate(double priorMean, 
                double priorStandardDeviation, 
                int clicks, int views);

I'd ask that, since I'm more familiar with code than mathematical notation, that any answers use code or pseudocode in preference to math.

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Here's the part I don't get: What does W have to do with anything if you only want the probability of randomly selected members of the subgroup clicking the hyperlink? If you are selecting members only of that subgroup then W does not matter. X doesn't matter either, since we're looking at the probability of clicking that link. –  AlbertoPL Jul 15 '09 at 18:52

4 Answers 4

up vote 3 down vote accepted

I made this a new answer since it's fundamentally different.

This is based on Chris Bishop, Machine Learning and Pattern Recognition, Chapter 2 "Probability Distributions" p71++ and http://en.wikipedia.org/wiki/Beta_distribution.

First we fit a beta distribution to the given mean and variance in order to build a distribution over the parametes. Then we return the mode of the distribution which is the expected parameter for a bernoulli variable.

def estimate(prior_mean, prior_variance, clicks, views):
  c = ((prior_mean * (1 - prior_mean)) / prior_variance - 1)
  a = prior_mean * c
  b = (1 - prior_mean) * c
  return ((a + clicks) - 1) / (a + b + views - 2)

However, I am quite positive that the prior mean/variance will not work for you since you throw away information about how many samples you have and how good your prior thus is.

Instead: Given a set of (webpage, link_clicked) pairs, you can calculate the number of pages a specific link was clicked on. Let that be m. Let the amount of times that link was not clicked be l.

Now let a be the number of clicks to your new link be a and the number of visits to the site be b. Then your probability of your new link is

def estimate(m, l, a, b):
  (m + a) / (m + l + a + b)

Which looks pretty trivial but actually has a valid probabilistic foundation. From the implementation perspective, you can keep m and l globally.

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If you want to consider the number of samples in the prior that is fine. Regarding the second estimate() function, this doesn't seem to work. If m and l are very large, as is likely in this scenario since we'll have a lot of data for the other links, then a and b have virtually no effect. –  sanity Jul 25 '09 at 15:28
Correct, since more prior information correspondends to a stronger prior. Maybe what you want is to fix (a + b) / (clicks + views) to a "reasonable"/"arbitrary" mixture in the first function. –  bayer Jul 25 '09 at 19:07
I don't really understand what you mean :-/I don't see (a+b)/(clicks+views) anywhere in either function. –  sanity Jul 25 '09 at 19:57
a and b are "prior" information and m and l are your "current" information. What you want now is to "weight" them in a way that makes sense for you. You can do this by multiplying the prior info a and b with p and the current info m and l with (1 - p). You can also weight them with other arbitrary constants. This might do the job for you, but there is no actual probabilistic reasoning behind this... –  bayer Jul 25 '09 at 21:35
Ok, having some weird output from your first estimate() function, it looks like I get a negative result if clicks=0. For example: estimate(0.10648293141246475, 0.011756461755177718, 0, 43) = -0.0050885467488 - obviously it shouldn't be negative! I cut and pasted your function into python. Any ideas? –  sanity Jul 25 '09 at 22:46

P/N is actually correct from a frequentist perspective.

You could also use a bayesian approach to incorporate prior knowledge, but since you don't seem to have that knowledge, I guess P/N is the way to go.

If you want, you can also use Laplace's rule which iirc comes down to a uniform prior. Just give each link on the page a start of 1 instead of 0. (So if you count the number a link was clicked, give each a +1 bonus and resemble that in your N.)

[UPDATE] Here is a bayesian approach:

Let p(W) be the probability that a person is in a specific group W. Let p(L) be the probability, that a specific link is clicked. then the probability you are looking for is p(L|W). By Bayes' theorem, you can calculate this by

p(L|W) = p(W|L) * p(L) / p(W)

You can estimate p(L) by the amount L was clicked, p(W) by the size of that group with respect to the rest of the users and p(W|L) = p(W and L) / p(L) by the number of persons of the specific group W that clicked L divided by the probability that L is clicked.

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Doesn't X constitute prior knowledge? –  sanity Jul 15 '09 at 20:07
Not so much, since X and W are not independent. I updated the answer with a bayesian approach. –  bayer Jul 15 '09 at 23:11
I've reframed this question significantly since this answer so I'm afraid it won't make much sense any more. –  sanity Jul 24 '09 at 23:47

Bayes' Theorem Proof:

P(A,B) = P( A | B ) * P( B )    (1)


P(A,B) = P(B,A)                 (2)

And substituting (2) with (1),

P(A | B) * P( B ) = P (B | A) * P(A)

thus (Bayes' Theorem),

           P( B | A ) * P(A)
P(A | B) = -----------------

P(A)   -- prior/marginal probability of A, may or may not take into account B
P(A|B) -- conditional/posterior probability of A, given B.
P(B|A) -- conditional probability of B given A.
P(B)   -- prior/marginal probability of B


P( A | B ) = P( A ), then a and b are independent
P( B | A ) = P( B ), and then

and the definition of independence is,

P(A,B) = P(A | B) * P( B ) = P( A )* P( B )

It should be noted, that it is easy to manipulate the probability to your liking by changing the priors and the way the problem is thought of, take a look at this discussion of the Anthropic Principle and Bayes' Theorem.

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What does this general post on Bayes' theorem have to do with the question? –  Martin B Jul 16 '09 at 19:57
You're right, he doesn't need a Bayesian approach at all. I feel you can understand something better by understanding the proof, Bayes' Theorem in itself is a little weird, so I included the proof. –  nlucaroni Jul 16 '09 at 20:10

You need to know how strongly X is correlated with W.

Most likely you also want to have a more complex mathematical model if you want to develop a big website. If you run a website like digg you have a lot of prior knowledge that you have to factor into your calcualtion. That leads to multivariate statistics.

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