# Why does Big-O Notation use O(1) instead of O(k)?

If I understand Big-O notation correctly, k should be a constant time for the efficiency of an algorithm. Why would a constant time be considered O(1) rather than O(k), considering it takes a variable time? Linear growth ( O(n + k) ) uses this variable to shift the time right by a specific amount of time, so why not the same for constant complexity?

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If I understand Big-O notation correctly, k should be a constant time for the efficiency of an algorithm. What is k? – japreiss Oct 23 '12 at 14:32
When representing linear growth, k is used, such that the complexity is O(n + k). Unless I am incorrect in saying that k is a constant time the algorithm takes? – SImon Oct 23 '12 at 14:34
@Simon When writing O(k) I see k is a variable, not a constant. And thus O(k) is linear time, since it's based on k. k number of operations takes k time units. – Simon Forsberg Oct 23 '12 at 14:35
no, when representing asymptotic linear growth, it is of order O(n), where n is the variable size of input. If k is a constant, O(n + k) = O(n) asymptotically. – im so confused Oct 23 '12 at 14:35
Because you can name your variable whatever you want, whether it be n or k is up to you. It's just customary to use n. – phant0m Oct 23 '12 at 14:53

There is no such linear growth asymptotic O(n + k) where k is a constant. If k were a constant and you went back to the limit representation of algorithmic growth rates, you'd see that O(n + k) = O(n) because constants drop out in limits.

Your answer may be O(n + k) due to a variable k that is fundamentally independent of the other input set n. You see this commonly in compares vs moves in sorting algorithm analysis.

To try to answer your question about why we drop k in Big-O notation (which I think is taught poorly, leading to all this confusion), one definition (as I recall) of O() is as follows:

Read: f(n) is in O( g(n) ) iff there exists d and n_0 where for all n > n_0,
f(n) <= d * g(n)


Let's try to apply it to our problem here where k is a constant and thus f(x) = k and g(x) = 1.

• Is there a d and n_0 that exist to satisfy these requirements?

Trivially, the answer is of course yes. Choose d > k and for n > 0, the definition holds.

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But if k is a constant relevant to the algorithm, why use O(1) instead of O(k)? – SImon Oct 23 '12 at 14:40
@SImon: If k were constant then one would not say O(k), one would say O(1) since they are the same thing. If k is not constant, but depends in some way on the input to the program, then they are not the same thing. – Steve Jessop Oct 23 '12 at 14:42
@SImon Exactly, there may be and usually are many many different physical runtimes experienced by algorithms that have the same O() representation. In your case, I have no choice but to disagree with you: if the final result is O(n + k), k must be a variable that shows a different input set's influence on the algorithm than n. If k is constant, the final result of O(n + k) can be further siplified to O(n) – im so confused Oct 23 '12 at 14:59
Alright, I think I finally get it. Thanks! – SImon Oct 23 '12 at 15:00
No, not at all. It's just that there are different definitions floating around. This is the one I was taught in my datastructures and algorithms course, and since we usually use this to talk about runtimes, the values would be positive anyway. The image defines f to be a positive function, so I thought I'd omit the | | from the textual description as well. I simply recycled the image from an old answer of mine. – phant0m Oct 23 '12 at 15:07