Distributed fibre optic sensing

The invention claimed is: 1. A distributed fibre optic sensor apparatus comprising: an optical generator configured to repeatedly generate a first coded sequence of optical radiation to be launched, in use, into a sensing optical fibre, the first coded sequence being encoded according to a polylevel coding sequence wherein the optical generator comprises a code generator including a code optimisation module for comparing a feedback signal derived from the first coded sequence of optical radiation before transmission with a reference version based on the polylevel coding sequence and deriving a pre-correction to be applied to the digital code signal; a detector configured to detect optical radiation which has been Rayleigh backscattered from within the sensing optical fibre; and a processor configured to process the output of the detector, wherein said processing comprises, for at least one range bin, correlating a detection signal derived from the detector output with the polylevel coding sequence at a time delay corresponding to that range bin. 2. A distributed fibre optic sensor apparatus as claimed in claim 1 wherein the first coded sequence of optical radiation comprises a sequence of chip periods and an optical property of the optical radiation is modulated according to an encoding value of the polylevel coding sequence which is constant over a chip period. 3. A distributed fibre optic sensor apparatus as claimed in claim 2 wherein the polylevel coding sequence has a mathematic autocorrelation function which is non-zero when the correlation is in phase and a value of zero when delayed by an amount equal to a multiple of the chip period. 4. A distributed fibre optic sensor apparatus as claimed in claim 1 wherein the polylevel coding sequence is based on a Frank code. 5. A distributed fibre optic sensor apparatus as claimed in claim 1 wherein the polylevel coding sequence is based on a plurality of complementary codes. 6. A distributed fibre optic sensor apparatus as claimed in claim 1 wherein the polylevel coding sequence comprises a sequence of encoding values, the sequence being of length P<2>, wherein the Mthencoding value of the sequence is equal to: k.i.j modulo P; where M=i+(jxP); i and j can each take any values between and including 0 and (P−1) and k is a constant. 7. A distributed fibre optic sensor apparatus as claimed in claim 6 wherein the value of k is equal to 2ττ/P. 8. A distributed fibre optic sensor apparatus as claimed in claim 1 wherein the optical generator is configured to modulate the phase of the first coded sequence of optical radiation according to the polylevel coding sequence. 9. A distributed fibre optic sensor apparatus as claimed in claim 1 wherein the optical generator comprises; an optical source for generating a continuous wave optical signal; and a first modulator for modulating the continuous wave optical signal based on the polylevel coding sequence to generate the first coded sequence of optical radiation. 10. A distributed fibre optic sensor apparatus as claimed in claim 9 wherein the first modulator comprises a phase modulator. 11. A distributed fibre optic sensor apparatus as claimed in claim 9 wherein the code generator drives the modulator with a drive signal, wherein the value of the drive signal is modulated based on the polylevel coding sequence. 12. A distributed fibre optic sensor apparatus as claimed in claim 11 wherein the code generator is configured to generate the drive signal based on a digital code signal. 13. A distributed fibre optic sensor apparatus as claimed in claim 12 wherein the code generator comprises a digital to analogue converter (DAC) for receiving the digital code signal and generating a code waveform and amplifier downstream in a signal path from the DAC for producing the drive signal. 14. A distributed fibre optic sensor apparatus as claimed in claim 13 comprising an edge enhancer located in the signal path between the DAC and the amplifier, the edge enhancer being configured to reduce a transition time between signal levels in the code waveform. 15. A distributed fibre optic sensor apparatus as claimed in claim 14 wherein the edge enhancer comprises a track-and-hold circuit configured to operate in a hold mode during a period when the DAC transitions from outputting a first signal level for the code waveform to a second signal level, wherein in the hold mode the track-and-hold circuit will hold its output at a first signal level as the code waveform output and subsequently to operate in a track mode to track the second signal level. 16. A distributed fibre optic sensor apparatus as claimed in claim 9 wherein the optical generator comprises a splitter for splitting the continuous wave optical signal generated by the optical source into both a launch signal in a launch path which includes said first modulator and a local oscillator signal in a local oscillator path and wherein the apparatus comprises a mixer for mixing optical radiation which is backscattered from the sensing fibre with the local oscillator signal prior to being detected by said detector. 17. A distributed fibre optic sensor apparatus as claimed in claim 16 further comprising a second modulator for introducing a frequency difference between the launch signal and the local oscillator signal. 18. A distributed fibre optic sensor apparatus as claimed in claim 17 wherein the second modulator comprises an acousto-optic modulator in the launch path. 19. A distributed fibre optic sensor apparatus as claimed in claim 17 wherein the optical generator is configured to generate repeated instances of the first coded sequence at a code repetition rate and the frequency difference between launch signal and the local oscillator signal is equal to an odd integer multiple of a quarter of the code repetition rate. 20. A distributed fibre optic sensor apparatus as claimed in claim 19 wherein the processor is configured to, for at least one range bin, take a first backscatter signal detected in response to a first launch of the first coded sequence of optical radiation and a second backscatter signal detected in response to a second launch of the first coded sequence of optical radiation and process said first and second backscatter signals as in-phase and quadrature components to provide a demodulated backscatter signal as the detection signal. 21. A distributed fibre optic sensor apparatus as claimed in claim 16 wherein the local oscillator path and the launch path between the optical source and the first modulator comprises components that maintain polarisation state. 22. A distributed fibre optic sensor apparatus as claimed in claim 21 comprising a polarising beam splitter for splitting optical radiation which is backscattered from the sensing fibre into first and second orthogonal polarisation states and a polarising beam splitter for splitting the local oscillator signal into the first and second orthogonal polarisation states and the mixer is configured such that, for each of the first and second polarisation states, optical radiation backscattered from the sensing fibre is mixed with the local oscillator signal of the corresponding polarisation state prior to being detected separately by said detector. 23. A distributed fibre optic sensor apparatus as claimed in claim 16 wherein the mixer is configured to mix optical radiation which is backscattered from the sensing fibre separately with first and second local oscil