### Preparations

First, lets state, loosely, the definition of `f`

being in `O(g(n))`

(note: `O(g(n))`

is a *set of functions*, so to be picky, we say that `f`

is in `O(...)`

, rather than `f(n)`

being in `O(...)`

).

If a function f(n) is *in* O(g(n)), then c · g(n) is an upper bound on
f(n), for **some constant c** such that f(n) is always ≤ c · g(n),
**for large enough n** (i.e. , n ≥ n0 for some constant n0).

Hence, to show that `f(n)`

is in `O(g(n))`

, we need to find a set of constants (c, n0) that fulfils

```
f(n) < c · g(n), for all n ≥ n0, (+)
```

but this set **is not unique**. I.e., the problem of finding the constants (c, n0) such that (+) holds is *degenerate*. In fact, if any such pair of constants exists, there will exist an infinite amount of different such pairs.

### Showing that `f ∈ O(n^4)`

Now, lets proceed and look at the example that confused you

Find an upper asymptotic bound for the function

```
f(n) = n^4 + 100n^2 + 50 (*)
```

One straight-forward approach is to express the lower-order terms in `(*)`

in terms of the higher order terms, specifically, w.r.t. bounds (`... < ...`

).

Hence, we see if we can find a lower bound on `n`

such that the following holds

```
100n^2 + 50 ≤ n^4, for all n ≥ ???, (i)
```

We can easily find when equality holds in (i) by solving the equation

```
m = n^2, m > 0
m^2 - 100m - 50 = 0
(m - 50)^2 - 50^2 - 50 = 0
(m - 50)^2 = 2550
m = 50 ± sqrt(2550) = { m > 0, single root } ≈ 100.5
=> n ≈ { n > 0 } ≈ 10.025
```

Hence, `(i)`

holds for `n ≳ 10.025`

, bu we'd much rather present this bound on `n`

with a neat integer value, hence rounding up to `11`

:

```
100n^2 + 50 ≤ n^4, for all n ≥ 11, (ii)
```

From `(ii)`

it's apparent that the following holds

```
f(n) = n^4 + 100n^2 + 50 ≤ n^4 + n^4 = 2 · n^4, for all n ≥ 11, (iii)
```

And this relation is exactly `(+)`

with `c = 2`

, `n0 = 11`

and `g(n) = n^4`

, and hence we've shown that `f ∈ O(n^4)`

. Note again, however, that the choice of constants `c`

and `n0`

is one of *convenience*, that is not unique. Since we've shown that `(+)`

holds for on set of constants `(c,n0`

), we can show that it holds for an infinite amount of different such choices of constants (e.g., it naturally holds for `c=10`

and `n0=20`

, ..., and so on).