IEEE-11073 is a commonly used format in medical devices. The table you quoted has everything in it for you to decode the numbers, though might be hard to decipher at first.

Let's take the first example you have: `0xFF00016C`

. This is a 32-bit number and the first byte is the exponent, and the last three bytes are the mantissa. Both are encoded in 2s complement representation:

- Exponent,
`0xFF`

, in 2's complement this is the number `-1`

- Mantissa,
`0x00016C`

, in 2's complement this is the number `364`

(If you're not quite sure how numbers are encoded in 2's complement, please ask that as a separate question.)

The next thing we do is to make sure it's not a "special" value, as dictated in your table. Since the exponent you have is not `0`

(it is `-1`

), we know that you're OK. So, no special processing is needed.

Since the value is not special, its numeric value is simply: `mantissa * 10^exponent`

. So, we have: `364*10^-1 = 36.4`

, as your example shows.

Your second example is similar. The exponent is `0xFE`

, and that's the number `-2`

in 2's complement. The mantissa is `0x000D97`

, which is `3479`

in decimal. Again, the exponent isn't 0, so no special processing is needed. So you have: `3479*10^-2 = 34.79`

.

You say for the `98.5`

value, you get the byte-array `[113, 14, 0, 254]`

. Let's see if we can make sense of that. Your byte array, written in hex is: `[0x71, 0x0E, 0x00, 0xFE]`

. I'm guessing you receive these bytes in the "reverse" order, so as a 32-bit hexadecimal this is actually `0xFE000E71`

.

We proceed similarly: Exponent is again `-2`

, since `0xFE`

is how you write `-2`

in 2's complement using 8-bits. (See above.) Mantissa is `0xE71`

which equals `3697`

. So, the number is `3697*10^-2 = 36.97`

.

You are claiming that this is actually `98.5`

. My best guess is that you are reading it in Fahrenheit, and your device is reporting in Celcius. If you do the math, you'll find that `36.97C = 98.55F`

, which is close enough. I'm not sure how you got the `98.5`

number, but with devices like this, this outcome seems to be within the precision you can about expect.

Hope this helps!