I have randomly selected a number between 1 and 1200 in my mind. If you can only ask questions for which I will only reply with “yes” or “no”, how many questions will you need to ask before you arrive at the answer for the number I’ve selected in my mind ?
closed as off topic by Juhana, dda, Jay Riggs, nnnnnn, talonmies Jan 20 '13 at 9:30Questions on Stack Overflow are expected to relate to programming within the scope defined by the community. Consider editing the question or leaving comments for improvement if you believe the question can be reworded to fit within the scope. Read more about reopening questions here.If this question can be reworded to fit the rules in the help center, please edit the question. 


Look up binary search. Thats what you are looking for. http://en.wikipedia.org/wiki/Binary_search_algorithm In the above link, look up Number Guessing Game 


It has already been pointed out that this is discussed in the wikipedia page at http://en.wikipedia.org/wiki/Binary_search_algorithm. Let's look at it in a little more detail to see if it is in fact true that the answer is ceil(log(1200)/log(2)=11. For this to be true, we have to show two things:
for (1): it's enough to give the algorithm which is, as everyone stated, binary search. for example:
to give an intuition: suppose the number is 3, then we have < 1024 (1 question), < 512 (2), < 256 (3), < 128 (4), < 64 (5), < 32 (6), < 16 (7), < 8 (8), < 4 (9), (not) < 2 (10), < 3 (11). does this work? i won't show this rigorously, but suppose the number you are thinking of is x = a[10]*1+...a[0]*2^10 (binary representation). observe that you start asking is it less than 2^10, then for nth, you ask is it less than sum(a[j]*2^(10j)+2^(10n), j=0...n1). observe that for each ith question, if the answer is yes, then a[i1] = 0 (otherwise a[i1]=1). after 11 questions (i=0,...10), you will have uncovered all a[0]...a[10]. for (2), [again, not rigorous] suppose you asked N questions. from these N questions, you can only deduce 2^N numbers because there are only 2^N possible ways in which the answers can be made. suppose N < 11, then 2^N <= 1024 < 1200. so by Pigeon Hole principle, you can't uniquely identify all 1200 numbers with N<11. In fact, this line of argument (#2) is used to show that comparison sort cannot be faster than O(n log n). now, it would be good if some one can make this rigorous :p can also be generalized to M instead of 1200. Ok, so that is easy enough, what if you are allowed to ask: is a number y constructed by a complicated formula, less than, equal to, or greater than a number z constructed by a complicated formula? (answer can be less than, equal to, or greater than) how many questions do you need? 

