I'm trying to solve a recurrence `T(n) = T(n/8) + T(n/2) + T(n/4)`

.

I thought it would be a good idea to first try a recurrence tree method, and then use that as my guess for substitution method.

For the tree, since no work is being done at the non-leaves levels, I thought we could just ignore that, so I tried to come up with an upper bound on the # of leaves since that's the only thing that's relevant here.

I considered the height of the tree taking the longest path through `T(n/2)`

, which yields a height of `log2(n)`

. I then assume the tree is complete, with all levels filled (ie. we have `3T(n/2))`

, and so we would have `3^i`

nodes at each level, and so `n^(log2(3))`

leaves. `T(n)`

would then be `O(n^log2(3))`

.

Unfortunately I think this is an unreasonable upper bound, I think I've made it a bit too high... Any advice on how to tackle this?