The prelude is somewhat flawed.
Firstly, barring any restrictions on storage space, conversion from a double to a base 10 significand-exponent form won't alter the precision in any form. To understand that, consider the following: any binary terminating fraction (like the one that forms the mantissa on a typical IEEE-754 float) can be written as a sum of negative powers of two. Each negative power of two is a terminating fraction itself, and hence it follows that their sum must be terminating as well.
However, the converse isn't necessarily true. For instance,
0.3 base 10 is equivalent to the non-terminating
0.01 0011 0011 0011 ... in base 2. Fitting this into a fixed size mantissa would blow some precision out of it (which is why
0.3 is actually stored as something that translates back to
By this, we may assume that any precision that is intended by storing the numbers in decimal significand-exponent form is either lost, or isn't simply gained at all.
Of course, you might think of the apparent loss of accuracy generated by storing a decimal number as a float as loss in precision, in which case the Decimal32 and Decimal64 floating point formats may be of some interest -- check out http://en.wikipedia.org/wiki/Decimal64_floating-point_format.