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How to calculate number of sequences over {0,1} such that each sequence contains at least half ones?

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This sounds like homework, right ? –  mjv Oct 8 '09 at 7:40
it's not really a homework question, but it might be related. –  user186189 Oct 8 '09 at 7:44

3 Answers 3

The total number of sequences of length n is 2^n. If n is odd, exactly the half of them (2^(n-1)) have at least half ones. For even n, you have to take into account that there are n!/((n/2)!^2) sequences with exactly half ones. So in this case I think you have in total (1/2)*(2^n + n!/((n/2)!^2)).

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Suppose the total length of the sequence is n , and the number of sequences that contains n/2 one is :



Sorry, I made a mistake. I meant n!/((n/2)!^2) but not n!/(2*(n/2)!). I considered it as combination problems and used following formulas. (substitute k with n/2)

alt text

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Attention, factorial operator in the denominator is wrongly placed... (needed inside parenthesis) –  mjv Oct 8 '09 at 7:52
@mjv:Thanks,changed:) –  pierr Oct 8 '09 at 7:56
Let's look at n = 2 for example. Your formula yields 1 in this case. But I count 2 such sequences: (0, 1) and (1, 0). –  Henrik Oct 8 '09 at 8:03
@Henrik / @pierr I think pierr meant n!/(((n/2)!)^2) Possible explanation is that pierr thought along the general limes of the proof I provide, but added the (n/2)! factors rather than multiplying them. –  mjv Oct 8 '09 at 9:01

Edit: Dang! We (I) should always read the problem carefully!
The following deals with enumerating the number of sequences where the number of 0s and 1s is equal! The actual problem is that the number of zeros should be less or equal to that of 1s !!!

Pierr's formula, n!/(2*(n/2)!) is almost correct, it is actually, n!/((n/2)! * (n/2)!)

but this could use a bit of explanation (pun intended ;-) ).

n being the total length, we know that n has to be even, since the problem requires an equal number of 0s and of 1s.

Let's focus on placing the 0s. For a sequence of length n, we have n/2 zero-bits, to put in one of the n positions of the sequence. We only need to count for the zero-bits, since after that there will be no choices left with regards to the one-bits: all other positions will require a 1 in them.

So... n/2 zero-bits, for n positions... There are n ways to pick the first position, then (n-1) ways to pick the second position (two bits couldn't occupy the same position), etc. This number of choices is therefore

  n! / (n/2)!

for example, for n=6, we have

       6 * 5 * 4 choices,  
       which, by multiplying and dividing by (3*2*1) is equivalent to
    =  6 * 5 * 4 * (3 * 2 * 1) / (3 * 2 * 1)   
    =  6! / 3!
    =  n! / (n/2)!  (a)

Now... some of these choices [of where to put first bit, second bit etc,] result in the same combination, because all zero-bits are the same, and therefore whether one put say the "first" bit in position x and the "2nd" bit in position y, or the first into y and the second into x, we'd have the same combination. There are (n/2)! ways of arranging these n/2 bits. In the example of n = 6, there are 3 ways of picking the position for the "first" bit, 2 ways for the 2nd bit and 1 (i.e. no choice) for the last zero-bit. The complete formula then needs to be (a) divided by (n/2)!, i.e:

  n! / (n/2)! * 1/(n/2)! 
= n! / ((n/2)! * (n/2)!)
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