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I found a couple questions on geeksforgeeks.org that i can't seem to understand(#1 and #3). I was hoping someone could clarify the answers for me:

clarify whether true/valid or false

1.Time Complexity of QuickSort is Θ(n^2)

I answered true but it is false, why? If quicksort has a time complexity of O(n^2) and we know that Θ(g(n))={f(n) where c1*g(n) <= f(n) <=c2*g(n) and n >= n0} then doesn't that prove that it is true since c2*g(n) being the upper bound can equal f(n)?

2.Time Complexity of QuickSort is O(n^2) - true

3.Time complexity of all computer algorithms can be written as Ω(1)

This is true but i have no understanding of why this is true. A search algorithm can have a lower bound of Ω(1) assuming we find what we were looking for on the first element but how does this hold true for ALL computer algorithms such as insertion sort algorithm where the worst case is O(n^2)?

link: http://www.geeksforgeeks.org/analysis-of-algorithms-set-3asymptotic-notations/

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These aren't really programming questions as such. You'd be better asking on Computer Science –  Mike W Jan 23 at 8:35
The exercise questions don't make any sense. There is no point on taking about the complexity without telling under what analysis - and thus they are ambigious. Quicksort is Theta(n^2) worst case (and thus also O(n^2) and Omega(n^2)), and Theta(nlogn) average case (and thus also O(nlogn) and Omega(nlogn)). –  amit Jan 23 at 8:46
@user2644819 Yes, since they are all sets of functions. I tried to explain this issue in this thread –  amit Jan 23 at 9:06
@user2644819 O(nlogn) is a subset of O(n^2). Big O gives only 'upper bound', so if something has upper bound of c*nlogn - it will also have an upper bound of c*n^2 (for some constant c). Recall that by definition, big O means: f(n) is in O(nlogn) if there are constants c,N such that for all n>N, f(n) <= cnlogn. Since nlogn < n^2 - we get that f(n) <= cn^2 as well, and by definition it means f(n) is in O(n^2). The bound for big O (and big Omega) does not have to be tight. –  amit Jan 23 at 9:13
let us continue this discussion in chat –  amit Jan 23 at 9:31

2 Answers 2

The worst case scenario for QuickSort is O(n^2). But you expect it to run in O(n log n) time. Hence the running time of the algorithm varies per case and you cannot use the theta symbol to give the general running time of the algorithm.

And of course the lowerbound on the running time of any algorithm is constant time (Ω(1)). It doesn't have to reach this lower bound though but the algorithm should be run, and should have at least one operation.

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Big O, theta and omega has nothing to do with best/worst/average case. See this thread. Big Theta/O/Omega can be applies to any analysis - this is just a set of functions. –  amit Jan 23 at 8:41
I agree that the notation is just mathematically showing bounds on functions. But when talking about runtime analysis Ω is used as a lower bound on the running time, hence best case. And O is used for upperbound, hence worst case. Now when the lowerbound == upperbound we can use Theta. So yes I made mistake and fixed it. –  invalid_id Jan 23 at 8:48

Time Complexity of QuickSort is Θ(n^2)----This means for every value of n, time taken by the algorithm to produce the output is equals to a function which is f(n)=n^2.but we know this is not true for quick sort because we know for some input, running time of quick sort may be equal to a function which is g(n)=nlogn. so we need to specify if it is worst,best or average case.It is correct to say "Worst case time complexity of quicksort is Θ(n^2)".

"Time Complexity of QuickSort is O(n^2)"---this means for each input value of n,running time of the algorithm is at most a function which is f(n)=n^2.This implies there exist some input, for which the algorithm has a running time which may be less than f(n)=n^2.we know best case time complexity of quicksort is g(n)=nlogn and g(n)< f(n).As this statement covers all the cases so the statement is true.

Similarly it is correct to say "Time complexity of quicksort is Ω(nlogn)".because this means running time of the algorithm is at least nlogn, and n^2>nlogn.

"Time complexity of all computer algorithms can be written as Ω(1)"---here 1 represent constant time function.the above statement implies: to execute any computer algorithms we need a minimum constant time.which is correct for all computer algorithms.

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