Optical communications networks, optical line terminations and related methods

The invention claimed is: 1. An optical communications network comprising: an optical line termination; a first optical multiplexer/demultiplexer comprising a first plurality (N) of input ports and a first plurality (N) of output ports; a plurality of wavelength division multiplexed passive optical network distribution networks, each coupled to a respective one of the plurality of output ports; a plurality of optical network units; a plurality of feeder fibers, each coupled between the optical line termination and a respective one of the plurality of input ports; and a plurality of interconnection fibers each coupled between a respective pair of the plurality of optical network units, wherein each wavelength division multiplexed passive optical network distribution network comprises one of: a wavelength routed wavelength division multiplexed passive optical network distribution network comprising a second optical multiplexer/demultiplexer comprising an input port and a second plurality (N′) of output ports; a broadcast and select passive optical network distribution network comprising an optical splitter comprising an input port and a plurality (N″) of output ports; and a hybrid wavelength division multiplexed/time division multiplexed passive optical network distribution network comprising a second optical multiplexer/demultiplexer comprising an input port and a second plurality (N′) of output ports each coupled to a respective optical splitter comprising an input port and a plurality of output ports, wherein a first network unit and a second network unit of said plurality of optical network units are paired to protect one another dependent on an identity of the second optical multiplexer/demultiplexer, an identity of the output port of the second optical multiplexer/demultiplexer, to which the first and second network units are respectively coupled, an identity of a free spectral range of the first optical multiplexer/demultiplexer used by each output port, the number of working feeder fiber (L) and an identity of the backup feeder fiber of each of the first and second network units. 2. The optical communications network of claim 1 , wherein said feeder fibers comprise L working feeder fibers and K backup feeder fibers, where L plus K is less than or equal to (N) and K is in the range zero to N−1. 3. The optical communications network of claim 1 , wherein, when the wavelength division multiplexed passive optical network distribution network comprises a hybrid wavelength division multiplexed/time division multiplexed passive optical network distribution network, the optical splitter is denoted with the index, i, j, of its respective output port, the optical network units of a first optical splitter, i 1 , j 1 , are coupled to respective said optical network units of a second said optical splitter, i 2 , j 2 , if: (( i 1+ L+q 1)mod N )+ p 1· N=j 2 and (( i 2+ L+q 2)mod N )+ p 2· N=j 1, where i indicates an optical multiplexer/demultiplexer; j indicates an output port of the optical multiplexer/demultiplexer; L is a number of feeder fibers; q=0, 1 . . . K−1; K is a number of backup feeder fibers; p=0, 1 . . . α−1; α is any positive integer and N is a number of input/output ports. 4. The optical communications network of claim 1 , wherein the first optical multiplexer/demultiplexer comprises an arrayed waveguide grating. 5. The optical communications network of claim 1 , wherein each second optical multiplexer/demultiplexer comprises a arrayed waveguide grating. 6. The optical communications network of claim 1 , wherein the optical line termination comprises a plurality of optical transceiver modules, each optical transceiver module comprising a plurality of optical transmitters and a plurality of optical receivers, each optical transmitter and each optical receiver being denoted with an index, i, j, where i indicates a respective module and j indicates an operating wavelength, and each optical transceiver module is coupled to a respective feeder fiber. 7. The optical communications network of claim 6 , wherein a first optical receiver, i 1 ′, j 1 and a first optical transmitter, i 1 ′, j 1 , are arranged to operate as a working optical receiver and a working optical transmitter of the first network unit, i 1 , j 1 , dependent on an identity of a second optical multiplexer/demultiplexer, and an identity of the output port of the second optical multiplexer/demultiplexer, to which the first network unit is coupled, an identity of the optical transceiver module in which the first optical receiver and the first optical transmitter are provided, and the operating wavelength of the first optical receiver and the first optical transmitter. 8. The optical communications network of claim 7 , wherein a first optical receiver, i 1 ′, j 1 and a first optical transmitter, i 1 ′, j 1 , are arranged to operate as a working optical receiver and a working optical transmitter of the first network unit, i 1 , j 1 , where i 1 ′=(j 1 −i 1 )mod N+1, where i indicates an optical multiplexer/demultiplexer; j indicates an output port of the optical multiplexer/demultiplexer; and N is a number of input/output ports. 9. The optical communications network of claim 8 , wherein the first network unit is coupled to the second network unit, a second optical receiver and a second optical transmitter are arranged to operate as a backup optical receiver and a backup optical transmitter for the first optical receiver and the first optical transmitter. 10. An optical line termination comprising a first plurality (N) of optical transceiver modules and a first plurality of optical outputs, each optical transceiver module comprising a plurality of optical transmitters and a plurality of optical receivers, each optical transmitter and each optical receiver being denoted with an index, i, j, where i indicates a respective module and j indicates an operating wavelength, and each optical transceiver module being coupled to a respective optical output, each optical output being arranged to be coupled to a respective optical network unit, wherein a first optical receiver, i 1 ′, j 1 and a first optical transmitter, i 1 ′, j 1 , are arranged to operate as a working optical receiver and a working optical transmitter for a first optical network unit, i 1 , j 1 , where i 1 ′=(j 1 −i 1 )mod N+1, where i indicates an optical multiplexer/demultiplexer; j indicates an output port of the optical multiplexer/demultiplexer; and N is a number of input/output ports, and wherein the first optical network unit is coupled to a second optical network unit and a second optical receiver and a second optical transmitter are arranged to operate as a backup optical receiver and a backup optical transmitter for the first optical receiver and the first optical transmitter. 11. The optical line termination of claim 10 , wherein each optical network unit is coupled to an output port, denoted i, j, of a respective optical multiplexer/demultiplexer and each optical output is arranged to be coupled to a respective optical network unit via a respective optical multiplexer/demultiplexer, a first optical receiver and a first optical transmitter being arranged to operate as a working optical receiver and a working optical transmitter of the respective optical network unit dependent on an identity of the respective optical multiplexer/demultiplexer, an identity of the output port of the respective multiplexer/demultiplexer to which the respective optical network unit is coupled, an identity of the optical transceiver module in which the first optical receiver and the first optical transmitter are provided, and the operating wavelength of the first optical receiver and the firs