# Quick Probability Concept: N-bit strings

Suppose you generate an N-bit string (composed of only 1's and 0's). The sum of all of these 0's and 1's is X. What is the probability that X is odd, if N is odd? What is the probability that X is odd if N is even?

Since the chance of any bit being a 0 or 1 is 50%, I would just assume that both answers are 50%. However, I don't this is quite right. Can I get some ideas on how to solve this problem? any help would be GREATLY appreciated.

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Off-topic, but I'll bite:

How many possible length-N strings are there? How many of them have an even bit-sum? How many of them have an odd bit-sum?

To put it another way, assume there are `a` even length-(N-1) strings, and `b` odd length-(N-1) strings. To form a length-N string, append either a 0 or 1. This results in `a+b` even strings, and `a+b` odd strings.

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There should be 2^n possible N-length strings, and if we only take odd or even strings this would be 2^(n-1), correct? –  Butts Masterson May 2 '12 at 21:42
Induction, my dear Watson! –  larsmans May 2 '12 at 21:45
sorry, I'm having trouble connecting the dots here. Am I using induction to support my 50% theory, or using it to somehow get a different answer? –  Butts Masterson May 2 '12 at 21:50

There is a 50% chance that X is odd.

If N is 1, the only possible strings are 0 and 1, so there's a 50% chance that X is odd.

The possible strings when N=2 are the strings of N=1 with either 0 or 1 appended: 00, 01, 10, 11. Since the odds are already 50% for N=1, and the odds are 50% for the digit being added, the odds for N=2 are 50%.

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Your intuition is right. Maybe it might be useful to see this formally.

The bits, which are 0 and 1 with probability 1/2, are random variables of the Bernoulli distribution of parameter p=1/2. The sum of N independent Bernoulli random variables of parameter follows (by definition) a Binomial distribution, with parameters (N,p). Thus your sum is a Binomial distribution with parameter (N,1/2).

Now the probability P that the number is (say) even is:

``````P = Sum[Binomial[n,k]*1/2^n,k=all even values between 0 and n]

P = Sum[Binomial[n, 2 k]*1/2^n, k=0..Floor[n/2]]

P = 1/2 * Sum[Binomial[Floor[n/2],k]*1/2^n, k=0..Floor[n/2]]
``````

And that sum is well known to be equal to one (it's Newton's binomial formula), so you're left with

``````P = 1/2
``````

This question would have been more appropriate on Math StackExchange, and by that I mean that I would have been able to use LaTeX in the answer :)

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