I have this as a homework question and don't remember learning it in class. Can someone point me in the right direction or have documentation on how to solve these types of problems?
5 Answers
More formally...
First, we prove that if f(n) = 5n
, then f ∈ O(n)
. In order to show this, we must show that for some sufficiently large k
and i ≥ k
, f(i) ≤ ci
. Fortunately, c = 5
makes this trivial.
Next, I'll prove that for all f ∈ O(n)
that f ∈ O(n * log n)
. Hence, we must show that for some sufficiently large k
, all i ≥ k
, f(i) ≤ ci * log i
. Hence, if we let k
be large enough that f(i) ≤ ci
, and i ≥ 2
, then the result is trivial since ci ≤ ci * log i
.
QED.
Look into the definition of big-O-notation. It means that 5n will run no slower the nlogn, which is true. nlogn is an upper bound of the number of operations to be performed.
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@Ellipsis: Assuming you were being sloppy with the notation, yes. If that's literally what you mean, no... you need to take the limit as n goes to infinity. May 18, 2011 at 2:52
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@Mehrdad yes, that's why I said to look at the definition, but you're right May 18, 2011 at 2:55
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If that works better for you, then yes. But it should be obvious by looking at it that nlogn will grow faster than n as n goes to infinity May 18, 2011 at 2:57
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@Ellipsis: A more rigorous way to show that B(n) grows faster than A(n) is to show that
A(n)/B(n)
goes to zero as n goes to infinity. Try that here. May 18, 2011 at 3:07
You can prove it by applying L'Hopitals rule to lim n-> infinity of 5n/nlogn
g(n) = 5n and f(n)=nlogn
Derivate g(n) and f(n) so you will get something like this
5/(some stuff here that will contain n)
5/infinity = 0 so 5n = O(nlogn) is true
I don't remember the wording of the formal definition, but what you have to show is:
c1 * 5 * n < c2 * n * logn, n>c3
where c1 and c2 are arbitrary constants, for some number c3. Define c3 in terms of c1 and c2, and you're done.
It's been three years since I touched big-O stuff. But I think you can try to show this:
O(5n) = O(n) = O(nlogn)
O(5n) = O(n) is very easy to show, so all you have to do now is to show O(n) = O(nlogn) which shouldn't be too hard too.