# Asymptotic notations

From what I have studied: I have been asked to determine the complexity of a function with respect to another function. i.e. Given `f(n)` and `g(n)`, determine `O(f(n()`. In such cases, I substitute values, compare both of them and arrive at a complexity - using `O(), Theta and Omega notations`.

However, in the `substitution method for solving recurrences`, every standard document has the following lines:

`• [Assume that T(1) = Θ(1).]`

`Guess O(n3) . (Prove O and Ω separately.)`

`Assume that T(k) ≤ ck3 for k < n .`

`Prove T(n) ≤ cn3 by induction.`

How am I supposed to find O and Ω when nothing else (apart from f(n)) is given? I might be wrong (I, definitely am), and any information on the above is welcome.

Some of the assumptions above are with reference to this problem: ```T(n) = 4T(n/2) + n ```, while the basic outline of the steps is for all such problems.

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`"Given f(n) and g(n), determine f(n)"` - maybe a typing mistake (since, if you already have f(n), what's there to do?)? –  Dukeling Apr 17 '13 at 14:13

That particular recurrence is solvable via the Master Theorem, but you can get some feedback from the substitution method. Let's try your initial guess of `cn^3`.

``````T(n)  = 4T(n/2) + n
<= 4c(n/2)^3 + n
= cn^3/2 + n
``````

Assuming that we choose `c` so that `n <= cn^3/2` for all relevant `n`,

``````T(n) <= cn^3/2 + n
<= cn^3/2 + cn^3/2
= cn^3,
``````

so `T` is `O(n^3)`. The interesting part of this derivation is where we used a cubic term to wipe out a linear one. Overkill like that is often a sign that we could guess lower. Let's try `cn`.

``````T(n)  = 4T(n/2) + n
<= 4cn/2 + n
= 2cn + n
``````

This won't work. The gap between the right-hand side and the bound we want is is `cn + n`, which is big Theta of the bound we want. That usually means we need to guess higher. Let's try `cn^2`.

``````T(n)  = 4T(n/2) + n
<= 4c(n/2)^2 + n
= cn^2 + n
``````

At first that looks like a failure as well. Unlike our guess of `n`, though, the deficit is little o of the bound itself. We might be able to close it by considering a bound of the form `cn^2 - h(n)`, where `h` is `o(n^2)`. Why subtraction? If we used `h` as the candidate bound, we'd run a deficit; by subtracting `h`, we run a surplus. Common choices for `h` are lower-order polynomials or `log n`. Let's try `cn^2 - n`.

``````T(n)  = 4T(n/2) + n
<= 4(c(n/2)^2 - n/2) + n
= cn^2 - 2n + n
= cn^2 - n
``````

That happens to be the exact solution to the recurrence, which was rather lucky on my part. If we had guessed `cn^2 - 2n` instead, we would have had a little credit left over.

``````T(n)  = 4T(n/2) + n
<= 4(c(n/2)^2 - 2n/2) + n
= cn^2 - 4n + n
= cn^2 - 3n,
``````

which is slightly smaller than `cn^2 - 2n`.

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