Assuming some algorithm has a polynomial time complexity T(n), is it possible for any of the terms to have a negative coefficient? Intuitively, the answer seems like an obvious "No" since there is no part of any algorithm that reduces the existing amount of time taken by previous steps but I want to be certain.
When talking about polynomial complexity, only the coefficient with the highest degree counts.
But I think you can have T(n) = n*n - n = n*(n-1). The n-1 would represent something you don't do on the first or last iteration.
Anyway, the complexity would still be n*n.
It is possible for an algorithm to have a negative coefficient in its time complexity, but overall the algorithm will have some positive time complexity. As an example from Wikipedia, take the function
That is, even if there are negative coefficients in the original equation, there is still some positive overall time complexity based on the term with the highest order of power.
What about for lower bounds? By definition, we can find the lower bound of any function by using the following definition: As
Let's guess that the above function f(x) is also Omega(x^4). This means that:
Solving for k:
The term (2/x) approaches 0, as does (5/x^4) so we can choose
Which holds. So
Why does this work, even though the coefficient was negative? For both Big O and Big Omega notation, we are looking for a bound such that after some point one function dominates another. That is, as these graphs illustrate:
Thinking about our original f(x),
Despite the negative coefficient, clearly
Now, is this always true for any polynomial function with any negative coefficient--that a function
Which can be satisfied by any
Then we can't find the right