If a program executes in 2seconds with n=10, how much time will it take to execute n=100 with complexity n * log(n)? I thought about it and I think it's probably 4seconds, but how can I prove it?
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Assuming the time taken is exactly proportional to n*log(n), and not just an upper bound (see http://en.wikipedia.org/wiki/Big_O_notation#Family_of_Bachmann.E2.80.93Landau_notations), you'd have:
Plug in n=10 and solve for the constant. Now you have an expression for the execution time at every n. 


Well, consider the following: 10 operations complete in 2 seconds in the linear case, ie: O(n), so
With complexity (ie: BigOh) of O(n*log(n)), you would have this many operations:
Now, with 0.2seconds/operation, for 200 operations, with an algorithm of complexity O(n*log(n)), we get:
This is a pretty good result. In the linear case, (ie: O(n)) the savings aren't that much better, ie:
While if this were O(n^2), it would be horrendous:
Hope this helps! 


for n=10, the program at worst case takes 10*log(10) = 10 operations. then for n=100, it takes 100*log(100) = 200 operations.


