# n log n is O(n)?

I am trying to solve this recurrence

T(n) = 3 T(n/2) + n lg n ..

I have come to the solution that it belongs to masters theorem case 2 since n lg n is O(n^2)

but after referring to the solution manual i noticed this solution that they have

The soluttion says that n lg n = O ( n ^(lg 3 - e)) for e between 0 and 0.58

so this means n lg n is O(n) .. is this right? Am i missing something here?

Isn't nlgn O(n^2) ?

This will explain things better

• thanks for the effort .. So I guess n lg n > O(n) .. and the book is wrong? Oct 20 '11 at 3:32
• @WaelAwada The book's answer does not contradict O(n log n) > O(n). Oct 20 '11 at 3:40
• @WaelAwada The excerpt from the book looks a written form (if unfortunate for swapping first and second term) for: We have two terms to consider for stating simple dominating functions: n lg n and n^logb a. Since n lg n is dominated by n to the power of anything larger than one, it is dominated by n^lg 3. Nov 14 '14 at 8:16
• Did you take that chart from here? bigocheatsheet.com You should credit your source! May 12 '16 at 14:26
• It is Log2(100) ~ 7 Apr 14 '17 at 10:49

`n*log(n)` is not `O(n^2)`. It's known as quasi-linear and it grows much slower than `O(n^2)`. In fact `n*log(n)` is less than polynomial.

In other words:

``````O(n*log(n)) < O(n^k)
``````

where `k > 1`

``````3*T(2n) -> O(n^1.585)
``````

Since `O(n^1.585)` is polynomial and dominates `O(n*log(n))`, the latter term drops off so the final complexity is just `O(n^1.585)`.

• I thought the latter term only drops when it is addition .. so O(n + lg n) = O(n) Oct 20 '11 at 3:28
• It also drops off in this case too. But it'll take an all-out example/analysis to show why. Oct 20 '11 at 3:30

nlg3 is not O(n). It outgrows O(n)... In fact, any exponent on n that is larger than 1 results in an asymptotically longer time than O(n). Since lg(3) is about 1.58, as long as you subtract less than .58 from the exponent it is asymptotically greater than O(n).

• So if i understand correctly, you, like me, are thinking the solution manual is wrong by saying n lgn = O(n) Oct 20 '11 at 3:30
• No! n log n is bigger, outgrows, and is NOT bounded by n. It's the other way around.
– user684934
Oct 20 '11 at 3:31
• f(n) = O(g(n)) if f(n) < c.g(n) for for all n > n0 .. so if n lg n = O(n) what would c and n0 be ? Oct 20 '11 at 3:37
• Let c = 1 and n0 be 5, and you'll see that it's NOT TRUE. The other way around is.
– user684934
Oct 20 '11 at 3:45
• so if the other way around is then n = O(n lg n) which I understand but the book is saying n lgn = O (n) Oct 20 '11 at 3:54