Assuming you are using the IEEE standard, the formula for the representation of numbers is:

```
number = sign*(1+2^(-m)*significand)*2^(exponent-bias)
```

where `m`

is the number of bits used to store the (integer) significand (or mantissa), and `bias`

is equal to `2^(e-1) - 1`

where `e`

is the number of bits used to store the exponent.

Let's see what we can derive from that. Note that

- The value of
`significand`

ranges between `0`

and `2^m - 1`

(in your case: between 0 and 1048575).
- The value of
`exponent`

ranges between `0`

and `2^e - 1`

. However, both extremal values are reserved for exceptions (subnormal numbers, infinites and NANs), called unnormalized numbers.

Consequently,

- The smallest value for the fractional part
`(1+2^(-m)*significand)`

is 1, the biggest value is `2-2^(-m)`

(in your case 2-2^(-20), approximately 1,999999046).
- The smallest non-exceptional value for the total exponent
`exponent-bias`

is `-2^(e-1)+2`

(in your case -14), the biggest is `2^(e-1)-1`

(in your case: 15).

So it turns out that:

- The smallest (positive) normalized number that can be represented is
`2^(-2^(e-1)+2)`

(in your case 2^(-14), approximately 0,000061035)
- The biggest is
`(2-2^(-m))*(2^(2^(e-1)-1))`

(in your case (2-2^(-20))*(2^15), approximately 65535,96875).

As for "machine precision", I'm not sure what you mean, but one calls `m+1`

(21 here) the binary precision, and the precision in terms of decimal digits is `log10(2^(m+1))`

, for you this is approximately 6.3.

I hope I didn't get anything wrong, I'm no expert about this.