lower bound of the function f(x) = x^2+x+1? [closed]

the function is f(x) = x^2+x+1

``````   **Upper Bound**
when x>0,
x^2 >= x^2
similarly,  x >= x^2
and,
1 >= x^2
``````
``````    therefore,  f(x)=x^2+x+1  >= x^2+x^2+x^2   (all sufficient large value of x)
>= 3x^2     , where c=3

f(x)= O(x^2)
``````
``````  **Lower Bound**

f(x)=x^2+x+1 >= x^2
f(x) = Ω(x^2)
``````

> but can we write it's lower bound as Ω(x) and Ω(1) because

``````              f(x)=x^2+x+1  >= x    (all sufficient large value of x)
f(x)  = Ω(x)  ??
``````

and

``````             f(x)=x^2+x+1 >= 1   (all sufficient large value of x)
f(x)  = Ω(1)   ?????
``````
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closed as off topic by H2CO3, martin clayton, KooKiz, Xavier T., IronMan84Mar 29 at 13:07

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Yes, definitely we can write it as w(n) and even w(1). However, this doesn't make sense at all, since we are looking for the highest Ω. (Ω would be symboled with small omega rather than this big one to indicate that `c . g(n) < f(n)`. If we use Ω, that means `c . g(n) <= f(n)`).
`c . g(n) < f(n)` means that: there is no constant `c` that enlarges g(n) to be`g(n) = f(n) for all n >= 0`.