Could this be PDP-11 format? The giveaway for me is that the *second* byte is mostly constant, which suggests that the exponent of the floating-point format is ending up in the second byte rather than the first (as you'd expect for a big-endian machine) or the last (for a little-endian machine). The PDP-11 is notorious for its funny byte order for floats and integers; see the material near the bottom of this Floating-Point Formats page.

The values of `41`

and `42`

would appear to be consistent with positive values of roughly unit-magnitude: the exponent bias for the PDP-11 format appears to be `128`

, so with the unusual byte-order I'd expect the 2nd byte that you list to contain the sign and the topmost 7 bits of the exponent; that would make the unbiased exponent for a second byte of `41`

be either 2 or 3 depending on the 8th exponent bit (which should appear as the MSB of the first byte).

See also this page for a brief description of the PDP-11 format.

[EDIT] Here's some Python code to convert from a 4-byte string in the form you describe to a Python float, assuming that the 4-byte string represents a float in PDP-11 format.

```
import struct
def pdp_to_float(xs):
"""Convert a 4-byte PDP-11 single-precision float to a Python float."""
ordered_bytes = ''.join(xs[i] for i in [1, 0, 3, 2])
n = struct.unpack('>I', ordered_bytes)[0]
fraction = n & 0x007fffff
exponent = (n & 0x7f800000) >> 23
sign = (n & 0x80000000) >> 31
hidden = 1 if exponent != 0 else 0
return (-1)**sign * 2**(exponent-128) * (hidden + fraction / 2.0**23)
```

Example:

```
>>> pdp_to_float('\x00\x00\x00\x00')
0.0
>>> pdp_to_float('\x23\x41\x01\x00')
5.093750476837158
>>> pdp_to_float('\x00\x42\x00\x00')
16.0
```

reallyinteresting to see (and probably wouldn't give valuable data away) is a table or histogram showing how often eachfirstbyte value (0-255) is taken. (A similar table for the 2nd byte might be interesting too; I'd expect the 3rd and 4th to be less interesting.) – Mark Dickinson Jun 7 '12 at 18:21