# ratio of running times when N doubled in big O notation

I learned that,using Big O notation

``````O(f(n)) + O(g(n)) -> O(max(f(n),g(n))

O( f(n) )* O( g(n)) -> O( f(n) g(n))
``````

but now, I have this equation for running time T for input size N

``````T(N) = O(N^2)  // O of N square
``````

I need to find the ratio `T(2N) / T(N)`

I tried this

``````T(2N) / T(N) --> O((2N)^2) /O( N^2)  --> 4
``````

Is this correct? Or is the above division invalid?

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Keep in mind that T(2N) = T(N) (or O(2*N²) = O(N²), since its a constant) –  CharlyDelta Jun 23 '13 at 14:06
so when inupt is doubled ,the ratio of the running times = 1 ? that seems illogical.. or am I confused? –  damon Jun 23 '13 at 14:16
I'm not a professional in big-o-notation or something, but f(n) in O(n) still means: f(n) grows asympthotic faster than n. even if f(n) = n*1000000000000000000000000000000000000 or something :D –  CharlyDelta Jun 23 '13 at 14:30
Due to T(n) not being given explicitly, all we can say is that T(2n)/T(n) is in O(1). If T(n) were in Θ(a^n), this would not be true; in that case, T(2n)/T(n) would be in Θ(a^n) as well since a^2n = (a^n)^2 and thus (a^2n)/(a^n) = a^n, ignoring whatever constants and terms in o(a^n) might be hidden in T(n). –  G. Bach Jun 23 '13 at 15:00
@G.Bach I thought that too at first, and started writing an answer to that effect, but got part-way through and changed my mind. I now think T(2n)/T(n) could even be O(n^2)! –  TooTone Jun 23 '13 at 18:46

I would also say this is incorrect. My intuition was that if `T(N)` is `O(N^2)`, then `T(2N)/T(N)` is `O(1)`, consistent with your suggestion that `T(2N)/T(N) = 4`. I think however that the intuition is wrong.

Consider a counter-example.

Let `T(N)` be 1 if `N` is odd, and `N^2` if `N` is even, as below.

This is clearly `O(N^2)`, because we can choose a constant `p=1`, such that `T(N) ≤ pN^2` for sufficiently large `N`.

What is `T(2N)`? This is `(2N)^2 = 4N^2`, as below, because `2N` is always even.

Hence `T(2N)/T(N)` is `4N^2/1 = 4N^2` when `N` is odd, and `4N^2/N^2=4` when `N` is even, as below.

Clearly `T(2N)/T(N)` is not 4. It is, however, `O(N^2)`, because we can choose a constant `q=4` such that `T(2N)/T(N) ≤ qN^2` for sufficiently large `N`.

R code for the plots below

``````x=1:50
t1=ifelse(x%%2, 1, x^2)
plot(t1~x,type="l")

x2=2*x
t2=ifelse(x2%%2, 1, x2^2)
plot(t2~x,type="l")

ratio=t2/t1
plot(ratio~x,type="l")
``````

This problem is an interesting one and strikes me as belonging in the realm of pure mathematics, i.e. limits of sequences and the like. I am not trained in pure mathematics and I would be nervous of claiming that `T(2N)/T(N)` is always `O(N^2)`, as it might be possible to invent some rather tortuous counter-examples.

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Suppose `T(2N+1)` is zero, and `T(2N)` is `N^2`. Then there is no finite upper bound on `T(2N)/T(N)`. For odd N greater than 0, it will be infinite. –  Patricia Shanahan Jun 23 '13 at 20:52

Good question!

This is incorrect.

Running time is not the same as time complexity(here Big O).Time complexity says like it can't have a running time worse that a constant times N^2.Running time can be quite different, maybe very low, maybe close to the asymptotic limit.That purely depends on the hidden constants.If someone asked you this question, it's a trick question.

Hidden constants refers to the actual number of primitive instructions carried out.So in this case the total number of operations could be:

``````5*N^2
``````

or

``````1000*N^2.
``````

or maybe

``````100*N^2+90N
``````

or maybe just

``````100*N (Recall this is also O(N^2))
``````

The factor depends on the implementation and the actual instructions carried out.This is found out from the algorithm. So whichever the case we simply say the Big-O is O(N^2).

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What "hidden constants" do you mean? Could you explain that relating to the question? Now I'm curios :) –  CharlyDelta Jun 23 '13 at 14:32
there was a mention in `sedgwick's algorithms` book about `preferring ~ over BigO` when considering performance ..he reasons that using ~ the `doubling ratio test` can be justified where as using bigO cannot.. so I was trying out the equations –  damon Jun 23 '13 at 14:35
@CharlyDelta: See the answer, I've updated it. –  Aravind Jun 23 '13 at 14:45
@damon:I don't get you there, could you elaborate? –  Aravind Jun 23 '13 at 14:51
could you refer last paragraph in page 206 of sedgewick's book..says running time of some algorithm may be both `O(N^2)` and `~a N^b log N` .. Therefore O notaion may not justify a `doubling ratio test` for this algorithm –  damon Jun 23 '13 at 15:11

Even if T(N) = Θ(N²) (big-theta) this doesn't work. (I'm not even going to talk about big-O.)

``````c1 * N² <= T(N) <= c2 * N²
c1 * 4 * N² <= T(2N) <= c2 * 4 * N²

T(N) = c_a * N² + f(N)
T(2N) = c_b * 4 * N² + g(N)
``````

For c_a and c_b somewhere between c1 and c2, and f(N) and g(N) small-o of N². (Thanks G. Bach!) And there is nothing to guarantee that the quotient will be equal to 4 since both c_a, c_b, f(N) and g(N) can be all sorts of things. For example, take c_a = 1, c_b = 2 and f(N) = g(N) = 0. Divide them and you get

``````T(2N)/T(N) = (2 * 4 * N²)/N² = 8
``````
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Even this is incorrect/incomplete since there may be terms in T(n) that are o(N^2) (the less-known small-o describes functions that grow strictly smaller than f(n)). –  G. Bach Jun 23 '13 at 14:59
@G.Bach Thanks for the tip. –  Imre Kerr Jun 23 '13 at 15:05
@TooTone Hurp durp durp I can't into math AT ALL today. :( –  Imre Kerr Jun 23 '13 at 18:03