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With the reference of this answer, what is Theta (tight bound)?

Omega is lower bound, quite understood, the minimum time an algorithm may take. And we know Big-O is for upper bound, means the maximum time an algorithm may take. But I have no idea regarding the Theta.

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7 Answers 7

up vote 41 down vote accepted

Big O is the upper bound, while Omega is the lower bound. Theta requires both Big O and Omega, so that's why it's referred to as a tight bound (it must be both the upper and lower bound).

For example, an algorithm taking Omega(n log n) takes at least n log n time, but has no upper limit. An algorithm taking Theta(n log n) is far preferential since it takes at least n log n (Omega n log n) and no more than n log n (Big O n log n).

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Oh.. Now the term "tight bound" appearing quite self-explaining to me. Thanks Chris. Stupid me, perhaps I was expecting some complex idea. :) –  Adeel Ansari Jan 21 '09 at 4:35
Yea, there's a lot of fancy notation thrown around but it's not too complex once you get it under your belt. –  Chris Bunch Jan 21 '09 at 4:37

Θ-notation (theta notation) is called tight-bound because it's more precise than O-notation and Ω-notation (omega notation).

If I were lazy, I could say that binary search on a sorted array is O(n2), O(n3), and O(2n), and I would be technically correct in every case. That's because O-notation only specifies an upper bound, and binary search is bounded on the high side by all of those functions, just not very closely. These lazy estimates would be useless.

Θ-notation solves this problem by combining O-notation and Ω-notation. If I say that binary search is Θ(n log n), that gives you more precise information. It tells you that the algorithm is bounded on both sides by the given function, so it will never be significantly faster or slower than stated.

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If you have something that's O(f(n)) that means there's are k, g(n) such that f(n)k g(n).

If you have something that's Ω(f(n)) that means there's are k, g(n) such that f(n)k g(n).

And if you have a something with O(f(n)) and Ω(f(n)), then it's Θ(f(n).

The Wikipedia article is decent, if a little dense.

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Now reading the family of Bachmann-Landau notations. Thanks Charlie, I went there before, but returned without proceeding to its length. –  Adeel Ansari Jan 21 '09 at 4:38
Hey, it's good to get a refresh on doctoral comps every so often. –  Charlie Martin Jan 21 '09 at 17:30
Notice that Landau's big-O notation is not limited to algorithmic complexity. –  Charlie Martin Feb 20 at 15:00

Asymptotic upper bound means that a given algorithm executes during the maximum amount of time, depending on the number of inputs.

Let's take a sorting algorithm as an example. If all the elements of an array are in descending order, then to sort them, it will take a running time of O(n), showing upper bound complexity. If the array is already sorted, the value will be O(1).

Generally, O-notation is used for the upper bound complexity.

Asymptotically tight bound (c1g(n) ≤ f(n) ≤ c2g(n)) shows the average bound complexity for a function, having a value between bound limits (upper bound and lower bound), where c1 and c2 are constants.

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if the array is sorted, the bound will still be O(n) –  Arun Aravind Dec 28 '13 at 16:46
@ArunAravind Can you explain why? –  Rinzler Feb 20 at 13:43

The phrases minimum time and maximum time are a bit misleading here. When we talk about big O notations, it's not the actual time we are interested in, it is how the time increases when our input size gets bigger. And it's usually the average or worst case time we are talking about, not best case, which usually is not meaningful in solving our problems.

Using the array search in the accepted answer to the other question as an example. The time it takes to find a particular number in list of size n is n/2 * some_constant in average. If you treat it as a function f(n) = n/2*some_constant, it increases no faster than g(n) = n, in the sense as given by Charlie. Also, it increases no slower than g(n) either. Hence, g(n) is actually both an upper bound and a lower bound of f(n) in Big-O notation, so the complexity of linear search is exactly n, meaning that it is Theta(n).

In this regard, the explanation in the accepted answer to the other question is not entirely correct, which claims that O(n) is upper bound because the algorithm can run in constant time for some inputs (this is the best case I mentioned above, which is not really what we want to know about the running time).

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So, can we say that Ω is the best case, and O is the worst?. . .. and should we replace the terms as best case, and worst case, respectively? –  Adeel Ansari Jan 21 '09 at 5:06
Best case is O(1) for any problem? –  Zach Langley Jan 21 '09 at 5:15
@Adeel, no, Theta and O can both refer to either average case or worst case. @Zach, well, not exactly. Thanks for pointing that out. –  PolyThinker Jan 21 '09 at 5:33

The basic difference between


asymptotically upper bound and asymptotically tight Asym.upperbound means a given algorythm that can executes with maximum amount of time depending upon the number of inputs ,for eg in sorting algo if all the array (n)elements are in descending order then for ascending them it will take a running time of O(n) which shows upper bound complexity ,but if they are already sorted then it will take ohm(1).so we generally used "O"notation for upper bound complexity.

Asym. tightbound bound shows the for eg(c1g(n)<=f(n)<=c2g(n)) shows the tight bound limit such that the function have the value in between two bound (upper bound and lower bound),giving the average case.

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You shouldn't answer old questions if your answer doesn't add anythin g to already accepted answers. –  alestanis Oct 21 '12 at 11:47

I once asked my friend this same question and i got a plain english reply.

If i run an algorithm f(n) on arbitrarily different input for a large number of times. and then divide the time taken by all the runs by the number of runs, the time taken would be of the order Ω(f(n)).

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