I understand that an algorithm's time `T(n)`

can be bounded by `O(g(n))`

by the definition:

```
T(n) is O(g(n)) iff there is a c > 0, n0 > 0, such that for all n >= n0:
```

for every input of size `n,`

A takes at most `c * g(n)`

steps.
`T(n)`

is the time that is the longest out of all the inputs of size n.

However what I don't understand is the definition for `Ω(g(n))`

. The definition is that for **some** input of size n, A takes at least `c * g(n)`

steps.

But if that's the definition for `Ω`

then couldn't I find a lower bound for any algorthm that is the same as the upper bound? For instance if sorting in the worst case takes `O(nlogn)`

then wouldn't I be able to show easily `Ω(nlogn)`

as well seeing as how there has to be at least one bad input for any size n that would take `nlogn`

steps? Lets assume that we're talking about `heapsort`

.
I am really not sure what I'm missing here because whenever I'm being taught a new algorithm the time for a certain method is either `Ɵ(g(n)) or O(g(n))`

, but no explanation is provided as to why it's either `Ɵ or O`

.

I hope what I said was clear enough if not then ask away at what you misunderstood. I really need this confusion cleared up. Thank you.