Methods and apparatuses for supervision of optical networks

The invention claimed is: 1. A method in a Central Office providing data signals over a feeder fibre to Optical Network Terminals (ONTs), in an optical communication network, the data signals being distributed to the ONTs by a Remote Node communicatively coupled to the Central Office, for enabling supervision of optical fibres in the optical communication network, the method comprising: creating test signals of different monitoring wavelengths associated to predefined groups of said ONTs, each group comprising a plurality of ONTs; and sending the created test signals to the Remote Node, thereby enabling the Remote Node to route said test signals to corresponding associated groups of ONTs according to the wavelengths of the test signals, said monitoring wavelengths including a first component being an integer multiple of a separation parameter (nFSR) configured in the Remote Node for routing the test signals to said groups of ONTs, wherein a received backscattered and back-reflected test signal caused by a faulty optical fibre is used for identifying the faulty optical fibre based on the wavelength, including a combination of the first and a second component, of the back-scattered and back-reflected signal. 2. The method according to claim 1 , wherein said monitoring wavelengths are tied to their associated groups of ONTs by further including the second component being the wavelength of data signals provided to one of the ONTs in each associated groups of ONTs. 3. The method according to claim 1 , wherein the generated test signals are sent to the Remote Node one by one according to a preset testing scheme. 4. The method according to claim 1 , wherein the generated test signals are sent to the Remote Node over said feeder fibre being used for conveying the data signals from the Central Office to the Remote Node, or over a dedicated monitoring fibre separate from the feeder fibre. 5. The method according to claim 1 , wherein measurement data of the received back-scattered and back-reflected test signal is provided to a Fibre Plant Manager for processing. 6. A Central Office providing data signals over a feeder fibre to Optical Network Terminals (ONTs), in an optical communication network, the data signals being distributed to the ONTs by a Remote Node communicatively coupled to the Central Office, the Central Office being configured to enable supervision of optical fibres in the optical communication network, the Central Office comprising: an Optical Line Terminal (OLT) adapted to send said data signals to the ONTs via the Remote Node; and a testing unit adapted to create test signals of different monitoring wavelengths associated to predefined groups of said ONTs, each group comprising a plurality of ONTs, and to send the created test signals to the Remote Node, thereby enabling the Remote Node to route each of said test signals to a corresponding associated group of ONTs based on the wavelengths of the test signals, said monitoring wavelengths including a first component being an integer multiple of a separation parameter (nFSR) configured in the Remote Node for routing the test signals to said groups of ONTs, such that a received back-scattered and back-reflected test signal caused by a faulty optical fibre is used for identifying the faulty optical fibre based on the wavelength, including a combination of the first and a second component, of the back-scattered and back-reflected signal. 7. A method in a Remote Node communicatively coupled to a Central Office that provides data signals over a feeder fibre via the Remote Node to Optical Network Terminals (ONTs), in an optical communication network, the data signals being distributed to the ONTs by the Remote Node, for enabling supervision of optical fibres in the optical communication network, the method comprising: receiving test signals of different monitoring wavelengths associated to predefined groups of said ONTs from the Central Office, each group comprising a plurality of ONTs; and routing each of said received test signals to a corresponding associated group of ONTs according to the wavelengths of the test signals, said monitoring wavelengths including a first component being an integer multiple of a separation parameter (nFSR) configured in the Remote Node for routing the test signals to said groups of ONTS, thereby enabling the Central Office to identify a faulty optical fibre based on the wavelength, including a combination of the first and a second component, of a received back-scattered and back-reflected test signal caused by said faulty optical fibre. 8. The method according to claim 7 , wherein an integer multiple of a separation parameter (nFSR) is configured in the Remote Node for routing the test signals to said groups of ONTs, said integer multiple being included in the monitoring wavelengths as the first component. 9. The method according to claim 7 , wherein the test signals are received from the Central Office over said feeder fibre being used for conveying said data signals, or over a dedicated monitoring fibre separate from the feeder fibre. 10. The method according to claim 9 , wherein the test signals are received from the Central Office over a dedicated monitoring fibre, and the test signals are injected to said feeder fibre in a direction towards the Central Office by filters communicatively coupled to the monitoring fibre and the feeder fibre. 11. A Remote Node communicatively coupled to a Central Office that provides data signals over a feeder fibre via the Remote Node to Optical Network Terminals (ONTs), in an optical communication network, the Remote Node being configured to distribute the data signals to the ONTs and to enable supervision of optical fibres in the optical communication network, the Remote Node comprising: a receiving unit adapted to receive test signals of different monitoring wavelengths associated to predefined groups of said ONTs from the Central Office, each group comprising a plurality of ONTs; and a routing unit adapted to route each of said received test signals to a corresponding associated group of ONTs according to the wavelengths of the test signals, said monitoring wavelengths including a first component being an integer multiple of a separation parameter (nFSR) configured in the Remote Node for routing the test signals to said groups of ONTs, thereby enabling the Central Office to identify a faulty optical fibre based on the wavelength, including a combination of the first and a second component, of a received back-scattered and back-reflected test signal caused by said faulty optical fibre. 12. The Remote Node according to claim 11 , wherein the receiving unit is further adapted to receive the test signals from the Central Office over said feeder fibre being used for conveying said data signals, or over a dedicated monitoring fibre separate from the feeder fibre. 13. The Remote Node according to claim 12 , wherein if the test signals are received from the Central Office over a dedicated monitoring fibre, the test signals are injected to said feeder fibre in a direction towards the Central Office by filters communicatively coupled to the monitoring fibre and the feeder fibre. 14. The central office according to claim 6 , wherein said monitoring wavelengths are tied to their associated groups of ONTs by further including the second component being the wavelength of data signals provided to one of the ONTs in each associated groups of ONTs. 15. The central office according to claim 6 , wherein the testing unit is further adapted to send the created test signals to the Remote Node one by one according to a preset testing