Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I am unsure how to formally prove the Big O Rule of Sums, i.e.:

f1(n) + f2(n) is O(max(g1(n)),g2(n))

So far, I have supposed the following in my effort:

Let there be two constants c1 and c2 such that c2 > c1. By Big O definition:

f1(n) <= c1g1(n) and f2(n) <= c2g2(n)

Can anyone advise how I should proceed? Is it reasonable to introduce numerical substitutions for the variables at this step to prove the relationship? Not knowing g or f, that is the only way I can think to approach.

Any help would be greatly appreciated.

share|improve this question
There must be loads of solutions on the search engines - is this one? forums.codeguru.com/… –  Rup May 25 '13 at 13:00
I had already reviewed Google, and that thread in particular, but it seemed more of an attack on semantics than anything. I did not find anything helpful. The limit approach suggested below makes sense to me, so I will attempt that. –  Rome_Leader May 25 '13 at 13:06
I'm not sure this is really on topic here, but there's already an answer, so clearly there's some interest in it. –  jerry May 25 '13 at 13:21

3 Answers 3

up vote 1 down vote accepted


gmax = max(g1, g2), and gmin = min(g1, g2). 

gmin is O(gmax). Now, using the definition:

gmin(n) <= c*gmax(n) for n > some k

Adding gmax(n) to each side gives:

gmin(n) + gmax(n) <= c*gmax(n) + gmax(n) for n > some k
gmin(n) + gmax(n) <= (c+1)*gmax(n)       for n > some k
g1(n) + g2(n) <= c'*gmax(n)              for n > some k

So we have g1+g2 is O(max(g1, g2)).

Since f1+f2 is O(g1+g2), the transitive property of big-O gives us f1+f2 is O(max(g1, g2)). QED.

share|improve this answer

I suppose I might be more of a constructivist, I'd attack the problem like this:

By the definition of Big-O, there exist positive c1, c2, N1, and N2 such that

f1(n) <= c1g1(n) for all n > N1


f2(n) <= c2g2(n) for all n > N2


N' = max(N1,N2)
c' = c1 + c2
g'(n) = max(g1(n),g2(n))

Then for all n > N' we have:

f1(n) <= c1g1(n) <= c1g'(n)
f2(n) <= c2g2(n) <= c2g'(n)
f1(n) + f2(n) <= c1g'(n) + c2g'(n) = c'g'(n)

Therefore, f1(n) + f2(n) is O(g'(n)) = O(max(g1(n),g2(n)))

share|improve this answer

You don't even need the definition - just divide both sides by the faster-growing function, take the limit in infinity, and the slower-growing function will approach zero (i. e. it's insignificant).

share|improve this answer
Ohh, that makes sense! A limit is not something I thought to include, but it does make perfect sense! Thanks! EDIT: Actually, is that acceptable, since it is not an equation in the strict sense, but rather an element of a set, and thus does not have "two sides"? –  Rome_Leader May 25 '13 at 13:04

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.