# What is the expected number of biased coin tosses for this algorithm?

Suppose I have a biased coin. When flipped, the probability of yielding heads is 4/5.

To fake a fair toss, I pursue the following algorithm that models this situation. Suppose `True` models heads, and `False` represents tails.

P(doUnfairFlip() = 0) = 0.8
and
P(doUnfairFlip() = 1) = 0.2

``````def fakeFairToss():
flip1 = 0
flip2 = 0
while (flip1 == flip2):
flip1 = doUnfairFlip()
flip2 = doUnfairFlip()
return (True if (flip1 == 0) else False)
``````

It makes use of the fact that one is equally likely to get a heads-tails or a tails-heads after two coin flips.

How many individual flips of this biased coin should I expect every time this function runs?

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Just to be clear, are you saying P(rand() % 2 = 0) = 0.8, P(rand() % 2 = 1) = 0.2? –  Patrick87 Jan 25 '12 at 0:33
Sorry, I clarified it. P(doUnfairFlip() = 0) = 0.8 and P(doUnfairFlip() = 1) = 0.2 –  David Faux Jan 25 '12 at 0:49

The odds of equality are `1/5^2 + 4/5^2 = 17/25 = 68%`, assuming samples from `doUnfairFlip()` are IID.

Instead of thinking of loop iterations per function invocation, we can look at the situation as a unbounded sequence of iterations occasionally "punctuated" by function returns. Notice a function return occurs precisely when equality fails, `100 - 68 = 32%` of the time.

We can now identify the situation as a discrete Poisson process, with `lambda = 0.32`. The mean of corresponding distribution is also `lambda`: we can expect about `0.32` function invocations per loop iteration, or `1.0 / 0.32 = 3.125` iterations per invocation, or `6.25` calls to `doUnfairFlip()` per invocation.

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Just posting to note that another similar route to the same answer is to note that the number of loops is a geometric random variable with p = .32: en.wikipedia.org/wiki/Geometric_distribution ...because this is somehow not the highest voted answer despite being the only correct one. –  Chad Miller Jan 25 '12 at 1:38

I think its about 1.5 runs of the while loop, or 3 calls to rand(). My math may be wrong though.

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If what you're saying is that

``````P(rand() % 2 = 0) = 0.8
P(rand() % 2 = 1) = 0.2
``````

Then the probability of meeting the loop condition is

``````0.8*0.8 + 0.2*0.2 = 0.68
``````

You will execute the loop as many times as the expected number of times to get a failure when p = 0.68, which is 3.125. So you should expect to run the loop 3.125 times, and call rand() a total of 6.25 times.

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Probability of looping is 0.8^2 + 0.2^2 = 0.68 –  ElKamina Jan 25 '12 at 1:41
@ElKamina: Good catch, sorry about the calculational error. I see that somebody has already edited the rest of it, taking the correct value 0.68 into account. –  Patrick87 Jan 25 '12 at 3:21