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This is an interview question:

Given: f(n) = O(n)
       g(n) = O(n^2)
find f(n) + g(n) and f(n).g(n)?

What would be the answer for this question?

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What is the 0 in 0(n^2)? Big theta? –  NPE Mar 27 '13 at 8:27
    
they mentioned it as order of n^2. so i believe it is big theta. –  sbala_20 Mar 27 '13 at 8:29
1  
But you've now edited to a big-Oh? They are not synonymous. –  NPE Mar 27 '13 at 8:32
    
What does the dot represent in f(n).g(n)? Function composition? –  Rafał Dowgird Mar 27 '13 at 8:32
    
I rolled back the edit. It is big theta –  jamylak Mar 27 '13 at 8:33

2 Answers 2

up vote 3 down vote accepted

When this answer was prepared, f(n) was shown as o(n) and g(n) as Θ(n²).

From f(n) = o(n) and g(n) = Θ(n²) you get a lower bound of o(n²) for f(n) + g(n), but you don't get an upper bound on f(n) + g(n) because no upper bound was given on f(n). [Note, in above, Θ is a big-θ, or big theta]

For f(n)·g(n), you get a lower bound of o(n³) because Θ(n²) implies lower and upper bounds of o(n²) and O(n²) for g(n). Again, no upper bound on f(n)·g(n) is available, because f(n) can be arbitrarily large; for f(n), we only have an o(n) lower bound.

With the question modified to give only upper bounds on f and g, as f(n) = O(n) and g(n) = O(n²), we have that f(n)+g(n) is O(n²) and f(n)·g(n) is O(n³).

To show this rigorously is a bit tedious, but is quite straightforward. Eg, for the f(n)·g(n) case, suppose that by the definitions of O(n) and O(n²) we are given C, X, K, Y such that n>X ⇒ C·n > f(n) and n>Y ⇒ K·n² > g(n). Let J=C·K and Z=max(X,Y). Then n>Z ⇒ J·n³ > f(n)·g(n) which proves that f(n)·g(n) is O(n³).

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O(f(n) +g (n) )=O( max{ f(n) + g(n) } ) so for first f(n) + g(n)= O(n^2). for f(n).g(n) we will have O( f(n) . g(n) )=O( n * n^2)=O( n^3)

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