That's exactly what they do. A floating-point number is stored in exponent form. Let's assume that we're working on a decimal-based computer so I don't have to change all these numbers to binary.

You're multiplying `2.159 * 3.507`

, but in actuality `2.159`

is stored as `2159 * 10^-3`

and `3.507`

is stored as `3507 * 10^-3`

. Since we're working on a decimal-based system, the `10`

is assumed, so we only really have to store `-3`

without the `10`

, like this: `2159,-3`

or `3507,-3`

. The `-3`

is the location of the "floating point": as the point moves left the floating point decreases (`.3507`

is stored as `3507,-4`

) and as the point moves right the floating point increases (`35.07`

is stored as `3507,-2`

).

When you multiply the two together, the decimal number (or the binary number on a binary computer) is the only thing that gets multiplied. *The floating point gets added!* So behind the scenes what happens is:

```
2.159 * 3.507
2159,-3 * 3507,-3
2159 * 3507,-3 + -3
7571613,-6
```

`7571613,-6`

is just `7571613 * 10^-6`

(remember we can assume the `10`

because we're working on a decimal computer) which is the same as `7.571613`

.

Of course, the floating point doesn't have to be `-3`

, it could be anything that fits into the storage:

```
21590 * .3507
2159,1 * 3507,-4
2159 * 3507,1 + -4
7571613,-3
7571.613
```

And of course, most computers don't store things in decimal, so the actual numbers would be all in binary, and the floating point would be something like `2^-9 -> -9`

rather than `10^-3 -> -3`

. But you get the idea.