To start, take the significand encoding and prefix it with a “1.”, and write the result with the sign determined by the sign bit. So, for your example numbers, we have:

```
+1.010001
-1.010000
```

However, these have different scales, because they have different exponents. The exponent of the second one is four less than the first one (010_{2} compared to 110_{2}). So shift it right by four bits:

```
+1.010001
- .0001010000
```

Now both significands have the same scale (exponent 110_{2}), so we can perform normal arithmetic, in binary:

```
+1.010001
- .0001010000
_____________
+1.0011000000
```

Next, round the significand to the available bits (seven). In this case, the trailing bits are zero, so the rounding does not change anything:

```
+1.001100
```

At this point, we could have a significand that needed more shifting, if it were greater than 2 (10_{2}) or less than 1. However, this significand is just where we want it, between 1 and 2. So we can keep the exponent as is (110_{2}).

Convert the sign back to a bit, take the leading “1.” off the significand, and put the bits together:

```
0 110 001100
```

Exceptions would arise if the number overflowed or underflowed the normal exponent range, but those did not happen here.