In terms of significant digits, the precision is the same, regardless of scale. That is, if you scale your range from [0.0, 1000.0] down to [0.0, 1.0] just by dividing numbers in the natural range by 1000.0, this will have no discernible effect on the precision of your range. In fact, a larger range will have marginally greater precision since it fully contains the smaller range.

As for discovering the absolute precision, you have two problems:

- The absolute precision depends on the magnitude, which varies "infinitely" within the range [0, 1] (lim
_{x→0} log(*x*) = –∞). So there is no one precision for numbers in that range. You can only derive absolute precision at a given point in the range.
- The common technique for discovering the minimum step — known as the ulp — is to interpret the bit-representation of the float as an integer, increment it by one, and reinterpret the result as a float. Ruby doesn't, AFAIK, let you do this.

There is, however, an iterative solution. Simply add 1.0 to the number and subtract (`(x + 1.0) - x`

). If the difference is zero, double the addend (`(x + 2.0) - x`

) and repeat until the difference is non-zero. Otherwise, halve the addend (to 0.5) and repeat until the difference is zero. Whenever you stop, the lowest addend that produces a non-zero difference is the ulp. (I described this from vague memory, so it might be NQR.)