Big-O notation is to do with complexity analysis. A function is `O(g(n))`

if (for all except some `n`

values) it is upper-bounded by some constant multiple of `g(n)`

as `n`

tends to infinity. More formally:

`f(n)`

is in `O(g(n))`

iff there exist constants `n0`

and `c`

such that for all `n >= n0`

, `f(n) <= c.g(n)`

In this case, `f(n) = 10n^2 + 10n + 20`

, so `f(n)`

is in `O(n^2)`

, `O(n^3)`

, `O(n^4)`

, etc. The *tightest* upper bound is `O(n^2)`

.

In layman's terms, what this means is that `f(n)`

grows no worse than quadratically as `n`

tends to infinity.

There's a corresponding Big-Omega notation which can be used to lower-bound functions in a similar manner. In this case, `f(n)`

is also `Omega(n^2)`

: that is, it grows no better than quadratically as `n`

tends to infinity.

Finally, there's a `Big-Theta`

notation which combines the two, i.e. iff `f(n)`

is in `O(g(n))`

and `f(n)`

is in `Omega(g(n))`

then `f(n)`

is in `Theta(g(n))`

. In this case, `f(n)`

is in `Theta(n^2)`

: that is, it grows exactly quadratically as `n`

tends to infinity.

--> The point of all this is that as `n`

gets big, the linear (`10n`

) and constant (`20`

) terms become essentially irrelevant, as the value of the function is far more affected by the quadratic term. <--

`10n2`

should be`10n^2`

. – corsiKa Nov 9 '11 at 23:44fartoo broad in scope: you are asking us to teach you something which should be learned over a period of several lectures and assignments. Perhaps go back to the teacher who set you the homework -- did he/she not also spend four hours explaining algorithmic complexity analysis in great detail beforehand? – Lightness Races in Orbit Nov 9 '11 at 23:49asa homework assignment ;) And the word "homework" hassignificantconnotations in the sorts of answers that result, on SO, due to anti-spoonfeeding policy. – Lightness Races in Orbit Nov 10 '11 at 0:23