Name a function that is neither O(n) nor Omega(n)
f ∈ O(g) means the quotient
is bounded from above for all sufficiently large
f ∈ Ω(g) on the other hand means the quotient
is bounded below away from zero for all sufficiently large
So to find a function that is neither
Ω(n) means finding a function
f such that the quotient
becomes arbitrarily large, and arbitrarily close to zero on every interval
I'm thinking this may be a correct answer:
(n^3 (1 + sin n)) is neither O(n) nor Omega(n).
Let's plug it in our quotient:
(n^3*(1 + sin n))/n = n^2*(1 + sin n)
n^2 grows to infinity, and the factor
1 + sin n is larger than 1 for roughly three out of every six
n. So one every interval
[y, ∞) the quotient becomes arbitrarily large. Given an arbitrary
K > 0, let
N_0 = y + K + 1 and
N_1 the smallest of
N_0 + i, i = 0, 1, ..., 4 such that
sin (N_0+i) > 0. Then
f(N_1)/N_1 > (y + K + 1)² > K² + K > K.
Ω(n) part, it's not so easy to prove, although I believe it is satisfied.
But, we can modify the function a bit, retaining the idea of multiplying a growing function with an oscillating one in such a way that the proof becomes simple.
sin n, let us choose
cos (π*n), and, to offset the zeros, add a fast decreasing function to it.
f'(n) = n^3*(1 + cos (π*n) + 1/n^4)
/ n^3*(2 + 1/n^4), if n is even
f'(n) = <
\ 1/n , if n is odd
and it is obvious that
f' is neither bounded from above, nor from below by any positive constant multiple of