I am trying to understand how n^2 is faster than nlogn for n < 100 and opposite when n >= 100. In general this is not the case but this is an exercise that I do not want an answer for but to lead me to the right direction. I can picture two function in a graph that intersection at n = 100 as n < 100 O(n^2) is faster and as n > 100 O(nlogn) is faster.

I came up with an^2+b and c*nlog(n)+d

The key to my understanding here is constant that makes the differences. But what is hard is that I need to come up with constants that will satisfy the above scenario. Is there a way or technique that is done or am I going correctly on the wrong direction?

Original question: James and Brad are arguing about the performance of their sorting algorithms. James claims that hisO(N logN)-time algorithm is always faster than Brad's O(N2)-time algorithm. To settle the issue, they implement and run the two algorithms on many randomly generated data sets. To James' dismay, they find that if N < 100 the O(N2)-time algorithm actually runs faster, and only when N >= 100 the O(N logN)-time one is better. Explain why the above scenario is possible. You may give numerical examples.

`a 100^2 = c 100 log(100)`

– Anycorn Sep 12 '13 at 3:03