How to calculate complexity when there are more than one recursive calls?
Such as in this problem.
F(n)
{
if (n is 1)
return;
F(n/2) //Call 1
F(n/3) //Call 2
F(n/6) //Call 3
}
How to calculate complexity when there are more than one recursive calls? Such as in this problem.



You just need to solve the equation,
Now as T(n/2)>T(n/3), we can instead solve for
Using master's theorem, T(n)=O(n^(log(base 2)3))=O(n^1.58) Note that there might be better solution but as this is Big O notation, this is valid too 


Interesting question. I believe I can prove that the complexity of this function is O(n^{c}) for any c > 1. Recall the definition of bigO notation. We say a function g(n) is O(f(n)) if there exist constants k and n' such that g(n) < k*f(n) for all n > n'. (Colloquially, g(n) is bounded above by f(n) for sufficiently large n, ignoring constant factors.) Pick any c > 1, and observe that for sufficiently large n, 1 > (1/2)^{c} + (1/3)^{c} + (1/6)^{c} + 1/n^{c} This is easy to see because 1/2 + 1/3 + 1/6 = 1, and (1/2)^{c} < 1/2 etc. because c > 1. And when n is big enough, 1/n^{c} is arbitrarily small. Multiply through by n^{c}, to get that for sufficiently large n: n^{c} > (n/2)^{c} + (n/3)^{c} + (n/6)^{c} + 1 Therefore, if the running time of F(m) is bounded above by m^{c} for m=n/2, m=n/3, and m=n/6, then the running time of F(n) is bounded above by n^{c}. Result follows by induction. So although I was wrong that this function is O(n), it is arbitrarily close... In the sense that for any positive value epsilon, no matter how small, the function is O(n^{1+epsilon}). ... In general, for this type of question, I think you want to guess solutions of the form n^{c} and then try to place a bound on c. This is essentially how the Master Theorem itself works. 

