Converting a number from a decimal string to binary IEEE is fairly straight-forward if you know how to do IEEE floating-point addition and multiplication. (or if you're using any basic programming language like C/C++)

There's a lot of different approaches to this, but the easiest is to evaluate `9.07 * 10^23`

directly.

First, start with `9.07`

:

```
9.07 = 9 + 0 * 10^-1 + 7 * 10^-2
```

Now evaluate `10^23`

. This can be done by starting with 10 and using any powering algorithm.

Then multiply the results together.

Here's a simple implementation in C/C++:

```
double mantissa = 9;
mantissa += 0 / 10.;
mantissa += 7 / 100.;
double exp = 1;
for (int i = 0; i < 23; i++){
exp *= 10;
}
double result = mantissa * exp;
```

Now, going backwards (IEEE -> to decimal) is a lot harder.

Again, there's also a lot of different approaches. Here's the easiest one I can think of it.

I'll use `1.0011101b * 2^40`

as the example. (the mantissa is in binary)

First, convert the mantissa to decimal: (this should be easy, since there's no exponent)

```
1.0011101b * 2^40 = 1.22656 * 2^40
```

Now, "scale" the number such that the binary exponent vanishes. This is done by multiplying by an appropriate power of 10 to "get rid" of the binary exponent.

```
1.22656 * 2^40 = 1.22656 * (2^40 * 10^-12) * 10^12
= 1.22656 * (1.09951) * 10^12
= 1.34861 * 10^12
```

So the answer is:

```
1.0011101b * 2^40 = 1.34861 * 10^12
```

In this example, `10^12`

was needed to "scale away" the `2^40`

. Determining the power of 10 that is needed is simply equal to:

```
power of 10 = (power of 2) * log(2)/log(10)
```