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I'm working through chapter 3 of CLRS, which is about running times and would like to work through some examples. Since I'm not enrolled in an algorithms class I need to resort to the www for help.

1) n^2 = Big-Omega(n^3)

I think this statement is false: if the best case running time is n^3, then the algorithm cannot be n^2, . Even the best case is slower than that.

2) n + log n = Big-Theta (n)

I think this statement is true, we can ignore the lower term of log n. This gives us a worst-case running time of Big-Oh (n). And a best case running time of Big-Omega (n). I'm not quite sure of this though. Some more clarification would be appreciated.

3) n^2 log n =Big-Oh (n^2)

I think this.statement is false: the worst case running time should be n^2 log n.

4) n log n = Big-Oh (n sqrt (n))

Could be true since n log n < n sqrt (n). Not quite sure though.

5) n^2 - 3n - 18 = Big-Theta (n^2) Really no idea...

6) If f (n) = O (g (n)) and g (n) = O (h (n)), then f (n) = O (h (n)).

Holds by the transitive property.

I hope someone Could elaborate a bit on my quite.possibly wrong answers :)

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You have some fundamental misunderstanding about the notations. (1) O(n^2) (for example) is a set, while n^2*log(n) is a function. A function cannot be a set, it can be CONTAINED IN a set. The correct terminology will be is n^2 * log(n) in the set O(n^2)?. (2) "best case/worst case" has nothing to do with the big O notation. Quick sort for example is Theta(nlogn) average case and Theta(n^2) worst case. The big O notation can be applied for each analyzes, since it is "grouping" the function provided by this analyzes. –  amit Nov 25 '12 at 13:07
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@amit the = is often used with the O() notation. –  Jan Dvorak Nov 25 '12 at 13:09
    
Yeah, in the literature they use the '=' sign in stead of the 'is in set' symbol. Lets not disgress too much about this. –  Oxymoron Nov 25 '12 at 13:10
    
@JanDvorak: "often used" != correct. I have never seen a formal definition of the = for these cases. Of course - it doesn't mean one does not exist. –  amit Nov 25 '12 at 13:10
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@amit this is a common practice and perfectly acceptable when calculating complexities. In this context = means belongs to the set, unlike the usual mathematical meaning of =. –  icepack Nov 25 '12 at 13:11

1 Answer 1

up vote 4 down vote accepted
  1. You are correct, but the reason is not. Remember that Omega(n^3) does not directly relate to an algorithm—but to a function.
    The reason why you are correct is because: for each constant c,N, there is some n>N such that n^2 < c * n^3—and thus n^2 is not in Omega(n^3)

  2. You are correct. n < n + logn < 2*n (for large enough n), and thus n + logn is both O(n) and Omega(n)

  3. You are correct, but again, do not use "worst case" in here. The explanation and proof guidelines will be similar to 1.

  4. This is correct since log(n) is asymptotically smaller than sqrt(n) and the rest follows.

  5. Same principle as in 1. It will be true with the same approach.

  6. Correct.


As a side note: Omega(n) does not mean "best case run time of n" it means that the function denoting the complexity (can be worst case complexity, best case complexity or average case complexity,...) holds the conditions for being Omega(n).

For example - Quicksort:

  • Under the worst case analysis , it is Theta(n^2)
  • Whereas under the average case analysis it is Theta(nlogn)
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Congrats on 40k! –  phant0m Nov 25 '12 at 14:22
    
I was tempted to downvote just to make your rep exactly 40K. But I decided to vote based on the quality of the answer instead. –  Daniel Fischer Nov 25 '12 at 16:08
    
Thank you for this, @amit, it is clear I need to pay more attention to being as formal as possible. My understanding is a bit too 'loose' at the moment. –  Oxymoron Nov 25 '12 at 18:07

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