# Big Oh Notation Proof [closed]

The question is to prove that

• f(n) = 4n5 - 17n4 - 33n3 - 13n2

is in Θ(n5)

What I tried to do what split up 4n5 into two separate constants (2n5 + 2n5) and make that whole equation greater than or equal to 2n5 and got C = 2, N >= 6.

I'm unsure if I'm right and I'm still quite unsure how to actually prove that function is in Θ(n5). I hope someone can come along and help me solve this and what steps to take in order to prove other Big Oh notation problems.

Thank you for the help guys!

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## closed as off-topic by millimoose, Thomas, P0W, Chris, Alvin WongOct 20 '13 at 7:10

• This question does not appear to be about programming within the scope defined in the help center.
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Actually, you just need to look into the definition. 1: For any natural number, f(n) <= 4n^5 (since all other terms are negative). 2. For n >= 10, n^5 <= f(n) (for n = 10 all lower-order terms will at most take ~2n^5 from the first term). –  Zeta Oct 19 '13 at 22:08
This is better suited for either Computer Science, or Mathematics. –  millimoose Oct 19 '13 at 22:12
What kind of rules do you know for Landau notation so far? Derivative rules? Limit rules? Or is it definitions only so far? –  G. Bach Oct 19 '13 at 22:13
On wikipedia: en.wikipedia.org/wiki/Big_O_notation. You could prove that according to the definition of big-O notation. –  gongzhitaao Oct 19 '13 at 22:15
Right now, just definitions –  Matt Oct 19 '13 at 22:16

### f(n) ∈ Θ(g(n)) (more general):

We have to show that there exists positive M and N such that

g(n) * M <= f(n) <= g(n) * N

for large enough ns. In this case, that's

M * n5 <= 4n5 - 17n4 - 33n3 - 13n2 <= N * n5

Divide by n5:

M <= 4 - 17(1/n) - 33(1/n2) - 13(1/n3) <= N

For large ns, we'll be left with

M <= 4 - ε <= N

We can pick M = 3 and N = 4.

### f(n) ∈ O(g(n)) (more specific):

This actually follows from the result above, but we can provide a specific proof as well.

We have to show that there exists a positive N such that

|f(n)| <= g(n) * N

for large enough ns. In this case, that's

|4n5 - 17n4 - 33n3 - 13n2| <= N * n5

Divide by n5:

4 - 17(1/n) - 33(1/n2) - 13(1/n3) <= N

For large ns, we'll be left with

4 - ε <= N

We can pick N = 4.

Reference:

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We only have to show |f(n)| <= |g(n)| * N, the other side is for f = Omega(g). You proved that f = Theta(g) which is stronger that f = O(g). –  gongzhitaao Oct 19 '13 at 22:12
@gongzhitaao I thought Θ was bounded both above and below. See en.wikipedia.org/wiki/… –  arshajii Oct 19 '13 at 22:15
I am only looking for Big-Oh, not Theta. –  Matt Oct 19 '13 at 22:15
@Matt Then you only need to prove the right side, i.e., |f(n)| <= |g(n)| * N. –  gongzhitaao Oct 19 '13 at 22:16
@Matt But your question asks for Θ and not for O… –  Donal Fellows Oct 19 '13 at 22:18