Encapsulation of digital communications traffic for transmission on an optical link

The invention claimed is: 1. A method of encapsulating digital communications traffic for transmission on an optical link, the method comprising: a. receiving an input digital communications signal having an input line code; b. performing clock and data recovery on the input digital communications signal to obtain input line coded digital communications traffic and a recovered clock signal; c. decoding the input line coded digital communications traffic to obtain information bits and non-information bits; d. removing the non-information bits; e. adding service channel bits for monitoring or maintenance; f. assembling the service channel bits and information bits into frames; and g. line coding the assembled frames using an output line code to form an encapsulated digital communications signal for transmission on an optical link, wherein steps c. to g. are performed using a timing of the recovered clock signal. 2. The method as claimed in claim 1 , wherein the input line code has a first spectral efficiency and the output line code has a second spectral efficiency, higher than the first spectral efficiency. 3. The method as claimed in claim 1 , and further comprising obtaining a delay asymmetry of the optical link and step f. comprises buffering the information bits for a time offset substantially equal to the delay asymmetry. 4. The method as claimed in claim 1 , wherein step f. comprises applying forward error correction to the information bits and to the service channel bits using a plurality of interleaved forward error correction codecs each configured to apply a preselected forward error correction code, and wherein the method comprises obtaining a maximum acceptable latency to be added by the forward error correction and selecting said plurality of forward error correction codecs such that a latency added by the forward error correction is not greater than the maximum acceptable latency. 5. The method as claimed in claim 1 , wherein step f. comprises applying forward error correction to the information bits using a plurality of interleaved forward error correction codecs each configured to apply a first forward error correction code and step f. comprises applying forward error correction to the service channel bits using a plurality of interleaved forward error correction codecs each configured to apply a second forward error correction code, different to the first forward error correction code. 6. The method as claimed in claim 1 and comprising at step a. receiving a plurality of input digital communications signals each having the input line code, performing steps b. to g. for each input digital communication signal to form a respective encapsulated digital communications signal and generating and transmitting a respective optical signal carrying each encapsulated digital communications signal, and the method further comprising: i. receiving each said optical signal; ii. performing clock and data recovery on each respective encapsulated digital communications signal to obtain the respective frames and a respective recovered clock signal; iii. obtaining a clock signal from at least one of the recovered clock signals; iv. disassembling the frames of each said signal and removing the forward error correction coding to obtain the respective service channel bits and information bits, and removing the respective service channel bits of each said signal; v. time division multiplexing the information bits from each of the said signals; vi. adding further service channel bits for monitoring or maintenance; vii. applying forward error correction to the further service channel bits and time division multiplexed information bits and assembling the further service channel bits and time division multiplexed information bits into frames; and viii. line coding the assembled frames using the output line code to form an encapsulated aggregate digital communications signal for transmission on an optical link, wherein steps v. to viii. are performed using the timing of the clock signal obtained in step iii. 7. A communications network transmitter comprising: an input arranged to receive an input digital communications signal having an input line code; clock and data recovery apparatus arranged to perform clock and data recovery on the input digital communications signal to obtain input line coded digital communications traffic and a recovered clock signal, and arranged to generate and transmit a clock signal comprising the recovered clock signal; decoder apparatus arranged to decode the input line coded digital communications traffic to obtain information bits and non-information bits and arranged to remove the non-information bits; a framer arranged to receive the information bits and service channel bits for monitoring or maintenance, and arranged to assemble the service channel bits and information bits into frames; line coding apparatus arranged to line code the assembled frames using an output line code to form an encapsulated digital communications signal for transmission on an optical link; and an optical transmitter arranged to generate and transmit an optical signal carrying the encapsulated digital communications signal, wherein each of the decoder apparatus, the framer and the line coding apparatus are arranged to receive the clock signal and are arranged to operate using a timing of the recovered clock signal. 8. The communications network transmitter as claimed in claim 7 , wherein the input line code has a first spectral efficiency and the line coding apparatus is arranged to line code the assembled frames using an output line code having a second spectral efficiency, higher than the first spectral efficiency. 9. The communications network transmitter as claimed in claim 7 , wherein the framer is arranged to obtain a delay asymmetry of the optical link and the framer comprises a buffer arranged to buffer the information bits for a time offset substantially equal to the delay asymmetry. 10. The communications network transmitter as claimed in claim 7 , wherein the framer comprises forward error correction apparatus comprising a plurality of forward error correction codecs each configured to apply a preselected forward error correction code, and wherein the forward error correction codecs are interleaved and said plurality of interleaved forward error correction codecs is such that a latency added by the forward error correction is not greater than a maximum acceptable latency. 11. The communications network transmitter as claimed in claim 7 , wherein the forward error correction apparatus comprises a plurality of interleaved forward error correction codecs each configured to apply a first forward error correction code to the information bits and the forward error correction apparatus comprises a plurality of interleaved forward error correction codecs each configured to apply a second forward error correction code, different to the first forward error correction code, to the service channel bits. 12. The communications network transmitter as claimed in claim 7 , further comprising: at least one further input, clock and data recovery apparatus, decoder apparatus, framer and line coding apparatus; a plurality of optical receivers each arranged to receive a respective optical signal from a respective one of the transmitters carrying a respective encapsulated digital communications signal; a plurality of further clock and data recovery apparatus each arranged to perform clock and data recovery on the respective encapsulated digital communications signal to obtain the respective frames and a respective recovered clock signal; a clock selector arranged to