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? enter image description here

  • 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
  • 2
    It 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 from 0 as it simplifies notation a bit)

  • on the first level you have 8 nodes of (n/2)^2 or a total of 8*(n/2)^2

  • on the second level you have 8 * 8 nodes of (n/(2^2))^2 or a total of 8^2*(n/(2^2))^2

  • on the i-th level you have 8^i nodes of (n/(2^i))^2 or a total of 8^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.

  • You are right. I made a dire mistake. I deleted my answer. :) – vahidreza Jun 2 '18 at 1:26
  • 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

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