So, someone posted this question earlier, but essentially no effort was put into it, it was poorly tagged and then closed. Nonetheless, I think it could have been a good question. I'm posting because according to the OP, my answer (posted in a comment) did not agree with the solution. So, I'm trying to figure out what I'm doing incorrectly (assuming that the answer that he has in indeed correct):
T(N) = T(N-1) + T(N-2) + T(N-3)
where N > 3. He didn't have a base case listed, but since N > 3, I assumed that there are probably 3 base cases for
T(1) . To calculate
T(K), we do the following:
T(K) = T(K-1) + T(K-2) + T(K-3)
Then we must calculate:
T(K-1) = T((K-1)-1) + T((K-1)-2) + T((K-1)-3) T(K-2) = T((K-2)-1) + T((K-2)-2) + T((K-2)-3) T(K-3) = T((K-3)-1) + T((K-3)-2) + T((K-3)-3)
and so on... Here's a tree-representation:
L0 T(K) / | \ L1 T(K-1) T(K-2) T(K-3) / | \ / | \ / | \ L2 T((K-1)-1) T((K-1)-2) T((K-1)-3) T((K-2)-1) T((K-2)-2) T((K-2)-3) T((K-3)-1) T((K-3)-2) T((K-3)-3) ... ... ...
So we have 3 children, then 9 children, then 27 children,..., until we hit our base cases. Hence, the algorithm is
N-3 is there to account for the three base cases, ie after T(4), we can only have bases cases, no more branching.
The actual solution was never provided, but like I said, I'm told that this is incorrect. Any help would be appreciated.