# Can someone explain why f(n) + o(f(n)) = theta(f(n))? [closed]

The statement: f(n) + o(f(n)) = theta(f(n)) appears to be true.
Where: o = little-O, theta = big theta

This does not make intuitive sense to me. We know that o(f(n)) grows asymptotically faster than f(n). How, then could it be upper bounded by f(n) as is implied by big theta?

Here is a counter-example:

let f(n) = n, o(f(n)) = n^2.
n + n^2 is NOT in theta(n)


It seems to me that the answer in the previously linked stackexchange answer is wrong. Specifically, the statement below seems as if the poster is confusing little-o with little-omega.

Since g(n) is o(f(n)), we know that for each ϵ>0 there is an nϵ such that |g(n)|<ϵ|f(n)| whenever n≥nϵ

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## closed as off-topic by Mike W, Frank, Paul Griffiths, iCodez, CfreakOct 3 '13 at 0:30

• This question does not appear to be about programming within the scope defined in the help center.
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This question should be posted on Mathematics – user1864610 Oct 2 '13 at 2:04
There is some confusion here: o(f(n)) grows slower than f(n) (significantly slower). – maxim1000 Oct 2 '13 at 7:51