Is there any difference between the computation of small floats  that are close to 0  and big floats  that are far from 0?
It depends what kind of computation you are talking about. Adding two numbers together is likely to take the same length of time regardless of the magnitude of the number. In the case of division, the size of the operand can make a difference  for instance, see Intel reference manual page C.34: If you try compiling the following code, you can see this in action:
Gives the following output for me



As far as I understand how processors work, there should be absolutely no difference at all 


It all depends on the platform that is used to compute the floatingpoint numbers. In general, there should be little or no difference. Internally, a floatingpoint number is represented using a normalized mantissa (a value between 0.5 and 1.0), a sign, and an exponent. The difference between a small and a large number is the value of the exponent. Having said that, there is a notable exception. Really small floatingpoint numbers, so called subnormal numbers or denormalized numbers are represented differently, and some FPU:s do not have support for them. In that case, they escape to software to perform the calculations, which is really slow. Concretely, this is a problem in audio software where a sound can ringoff down to something which can't be heard, but once it is small enough, it will make the calculation slow down significantly. 


No, there's no difference at all (ignoring precision issues). Floating point numbers always represent a number using a sign, fraction and exponent. There can't be any difference depending on its "size" and using some kind of integer replacement in case of small numbers or integer numbers wouldn't make any sense (just cause additional overhead)  to calculate you'd have to convert them again anyway. 


I believe there's no difference when those numbers can sit in a same datatype. 

