You can compare some different doubles like this:

```
double a = BitConverter.ToDouble(new byte[] { 156, 153, 153, 153, 153, 153, 33, 64, }, 0);
double b = BitConverter.ToDouble(new byte[] { 155, 153, 153, 153, 153, 153, 33, 64, }, 0);
double c = BitConverter.ToDouble(new byte[] { 154, 153, 153, 153, 153, 153, 33, 64, }, 0);
double d = BitConverter.ToDouble(new byte[] { 153, 153, 153, 153, 153, 153, 33, 64, }, 0);
double e = BitConverter.ToDouble(new byte[] { 152, 153, 153, 153, 153, 153, 33, 64, }, 0);
Console.WriteLine(a.ToString("R"));
Console.WriteLine(b.ToString("R"));
Console.WriteLine(c.ToString("R"));
Console.WriteLine(d.ToString("R"));
Console.WriteLine(e.ToString("R"));
```

Using the format string `"R"`

shows extra digits but only if necessary to distinguish between other representable `System.Double`

.

Addition (explanation of the bytes): `64`

and `33`

give the sign, magnitude and first (most) significant bits of the number `8.8`

. Since `8.8`

is a fraction with a small denominator (the 5 in 44/5), it is not surprising that the rest of the bits repeat over and over with a short period. To get the exact `8.8`

, the 153s would have to continue forever. But there's only room for eight bytes in a `double`

. Therefore we need to round. Rounding to `154`

gives the closest value because the next "term" (`153`

) is closer to `256`

than to `0`

. Therefore `c`

is the most precise representation possible.

When you look through the output of the above code, you see that `c`

is just output as `8.8`

even when we used the `"R"`

format string. But you know that `c`

is halfway between `b`

and `d`

(and also halfway between `a`

and `e`

), and from that you can easily estimate that the "true" decimal value most be very near `8.8000000000000007`

.