I'm looking for the mathematical proof, not just the answer.
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The recurrence relation of binary search is (in the worst case)
Using Master's theorem
Here a = 1, b = 2 and f(n) = O(1) [Constant] We have f(n) = O(1) = O(n^{logba}) => T(n) = O(n^{logba} log_{2} n)) = O(log_{2} n) 


The proof is quite simple: With each recursion you halve the number of remaining items if you’ve not already found the item you were looking for. And as you can only divide a number n recursively into halves at most log_{2}(n) times, this is also the boundary for the recursion:
Here x is also the number of recursions. And with a local cost of O(1) it’s O(log n) in total. 

