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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 Wong Oct 20 '13 at 7:10

  • This question does not appear to be about programming within the scope defined in the help center.
If this question can be reworded to fit the rules in the help center, please edit the question.

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: 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

1 Answer 1

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.


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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… –  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

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