Is there a set of test functions to measure the performance (in terms of speed, maybe trading off with accuracy) of a given algorithm whose task is to find a/the global minimum of a real-valued function over a given interval? Eventually: is this problem an open problem or does there exist a theoretical best algorithm for such a task?
EDIT: there are no restrictions on the function, other that it should be bounded.
With no restrictions on the function except boundedness, it does not seem possible to always find its global minimum, let alone in reasonable time.
Consider the family of real-valued functions defined on [0..1]:
f (x0) = y0
f (x) = 0 for all other x in [0..1]
For any fixed x0 in [0..1] and y0 < 0, the minimum is at x0.
Still, any algorithm with no prior knowledge of x0 will have a hard time finding it.
sin(x)+1/((x-m)²+1000). For a global optimum, local conditions aren't sufficient.
Take a function that is 0 in every point where you evaluate f (x), and c for an unknown c > 0 for every point where you don't evaluate f (x). If you want it continuous, then if x is between a and b, where a and b are the neighbouring points where you evaluated f (a) and f (b), then f goes linear from f (a) = 0 to f ((a + b)/2) = c and back linear to f (b) = 0.
Clearly every time you evaluate f (x), you get a zero. Since you never evaluate anything else, your algorithm cannot conclude that the global maximum is anything but zero - which is wrong.
