I'm trying to solve this problem, but I think I haven't understood how to do it correctly. The first thing I do in this type of exercises is taking the bigger value in the row (in this case is n^2) and divide it multiple times, so I can find what kind of relation there is between the values. After found the relation, I try to mathematically found its value and then as the final step, I multiply the result for the root. In this case the result should be n^3. How is possible?

It is not really clear what are you trying to do, but if my guess is right, you probably should (re)read the Master theorem which answers most of the questions of this kind. – SergGr May 31 '18 at 20:30

Unfortunately I need to solve it with the tree method – JimBelushi2 Jun 1 '18 at 8:36

2It doesn't really need to be a tree since there is only one recursive call  the tree method is only useful for multiple different calls. But in case you have to use it, you have the wrong number of branches  it should be 8. – meowgoesthedog Jun 1 '18 at 12:00
Unfortunately @vahidreza's solutions seems false to me because it contradicts the Master theorem. In terms of the Master theorem a = 8
, b = 2
, c = 2
. So log_b(a) = 3
so log_b(a) > c
and thus this is the case of a recursion dominated by the subproblems so the answer should be T(n) = Ө(n^3)
rather than O(m^(2+1/3))
which @vahidreza has.
The main issue is probably in this statement:
Also you know that the tree has log_8 m levels. Because at each level, you divide the number by 8.
Let's try to solve it properly:
On the zeroth level you have
n^2
(I prefer to start counting from0
as it simplifies notation a bit)on the first level you have
8
nodes of(n/2)^2
or a total of8*(n/2)^2
on the second level you have
8 * 8
nodes of(n/(2^2))^2
or a total of8^2*(n/(2^2))^2
on the
i
th level you have8^i
nodes of(n/(2^i))^2
or a total of8^i*(n/(2^i))^2
=n^2 * 8^i/2^(2*i)
=n^2 * 2^i
At each level your value n
is divided by two so at level i
the value is n/2^i
and so you'll have log_2(n)
levels. So what you need to calculate is sum for i
from 0
to log_2(n)
of n^2 * 2^i
. That's a geometric progression with a ratio of 2
so it's sum is
Σ (n^2 * 2^i) = n^2 * Σ(2^i) = n^2 * (2^(log_2(n)+1)  1)/2
Since we are talking about Ө
/O
we can ignore constants and so we need to estimate
n^2 * 2^log_2(n)
Obviously 2^log_2(n)
is just n
so the answer is
T(n) = Ө(n^3)
exactly as predicted by the Master theorem.


Thank you very much, you solved my problem! Just one more question: in this example I divide for two in each level because I have T(n/2), but what about if I have T(n) = T(n/3) + T(2n/3) + n? Here I'm dividing my tree into two branches with two different values – JimBelushi2 Jun 2 '18 at 7:13