From The Floating-Point Guide:
Why floating-point numbers are needed
Since computer memory is limited, you
cannot store numbers with infinite
precision, no matter whether you use
binary fractions or decimal ones: at
some point you have to cut off. But
how much accuracy is needed? And where
is it needed? How many integer digits
and how many fraction digits?
- To an engineer building a
highway, it does not matter whether
it’s 10 meters or 10.0001 meters wide - his measurements are probably not that accurate in the first place.
- To someone designing a microchip,
0.0001 meters (a tenth of a millimeter) is a huge difference - But
he’ll never have to deal with a
distance larger than 0.1 meters.
- A physicist needs to use the speed of
light (about 300000000) and Newton’s
gravitational constant (about
0.0000000000667) together in the same calculation.
To satisfy the engineer and the chip
designer, a number format has to
provide accuracy for numbers at very
different magnitudes. However, only
relative accuracy is needed. To
satisfy the physicist, it must be
possible to do calculations that
involve numbers with different
Basically, having a fixed number of
integer and fractional digits is not
useful - and the solution is a format
with a floating point.
As for your other questions:
- All inaccuracies arise because of exactly one reason: you're trying to fit an infinite amount of data (such as all rational numbers) into a limited space (such as 64 bits). The only thing that differs between formats is how the numbers that can be represented accurately are distributed.
- Floating-point formats are better, period. They lack many of the limitations of fixed-point formants, though they still have many limitations (Pretty much all of which fixed-point formats also have).
That being said, the issue of floating-point vs. fixed point is often confused with binary vs. decimal - specifically, people often compare binary floating-point formats with (implicitly) decimal fixed point formats. Not being able to represent decimal fractions accurately is something that surprises most people and which they consequently consider a great disadvantage of "floating-point formats", when in reality it's a disadvantage of binary formats and they are not at all suprised at not being able to represent numbers like 1/3 accurately.