I want to calculate O(n log(n))
without using the master theorem.
Does anyone know a mathematical way of calculating O(n log(n))
from the recursive formula T(n) = 2T(n/2) + O(n)
?
I want to calculate O(n log(n))
without using the master theorem.
Does anyone know a mathematical way of calculating O(n log(n))
from the recursive formula T(n) = 2T(n/2) + O(n)
?
Notice the pattern (simplified a bit, better would be to keep O(n)
rather than n
):
T(n) = 2T(n/2) + n
= 2(2T(n/4) + n/2) + n = 4T(n/4) + n + n = 4T(n/4) + 2n
= 4(2T(n/8) + n/4) + 2n = 8T(n/8) + n + 2n = 8T(n/8) + 3n
= 8(2T(n/16) + n/8)+ 3n = 8T(n/16)+ n + 3n = 16T(n/16) + 4n
... = 32T(n/32) + 5n
...
= n*T(1) + log2(n)*n
= O(n*log2(n))
Draw a recursion tree:
height of the tree will be log n
cost at each level will come out to be constant times n
Hence the total cost will be O(nlogn). http://homepages.ius.edu/rwisman/C455/html/notes/Chapter4/RecursionTree.htm
And you can always prove it by induction if you want.
For anyone still figuring out how to draw the recursion tree:
Image : recursion tree for an T(n) = 2T(n/2) + O(n) algorithm
Drawing a tree as below we can see that each time we divide by two and going till our leaves are equal to 1
n/2^k = 1
2^k = n
k= log(n)
The above statements prove that our tree has a depth of log(n).
At each level, we do an operation costing us O(n).
Even though we divide by two each time, we still do the operation on both parts so we have n iterations at each level.
Since we execute it a number of times equal to our depth, the resulting complexity is O(nlog(n)).
Also, check out this video tutorial https://youtu.be/1K9ebQJosvo