Method and apparatus for automatic signal gain setting

The invention claimed is: 1. An apparatus for automatic amplifier gain setting of an optical amplifier, said apparatus comprising: an optical channel counter, OCC, unit configured to detect a number of channels present in an optical transmission spectrum; a determination unit configured to determine an average power per channel calculated by dividing a measured total power of a signal input and/or signal output of the optical amplifier by the number of channels detected by said optical channel counter, OCC, unit; and a gain adjustment unit configured to adjust the amplifier gain of said optical amplifier automatically depending on a calculated power difference between a predetermined desired power per channel and the determined average power per channel provided by said determination unit, wherein the optical channel counter, OCC, unit is further configured to perform a channel counter process in at least one of the following two operation modes: in a first operation mode, a peak detection algorithm which allows for detection of channels with arbitrary spectral width and spacing between the channels is applied to determine the number of channels present in an optical transmission spectrum, and in a second operation mode, a channel plan concerning channel spacings between channels within the optical transmission spectrum is received to decide whether a channel is present or not at a specific channel frequency slot of the optical transmission spectrum. 2. The apparatus according to claim 1 wherein said optical channel counter, OCC, unit comprises a tunable wide bandwidth optical filter adapted to scan the optical transmission spectrum, a photodetector adapted to detect a filter output of said tunable optical filter and a processor adapted to process the detected filter output provided by said photodetector to count the number of channels present in the optical transmission spectrum. 3. The apparatus according to claim 2 wherein the tunable wide bandwidth optical filter has a bandwidth that is approximately the signal bandwidth and/or channel spacing between channels. 4. The apparatus according to claim 3 wherein a center frequency of the tunable wide bandwidth optical filter of said optical channel counter, OCC, unit is scanned in fixed frequency increments over the optical transmission spectrum and a filter output of the tunable wide bandwidth optical filter is detected and recorded at each frequency increment by the photodetector of said optical channel counter, OCC, unit. 5. The apparatus according to claim 1 wherein the processor of the optical channel counter, OCC, unit is adapted to integrate power within each channel frequency slot indicated in the channel plan and to compare the integrated power with a power threshold value to decide whether a channel is present or not at the respective channel frequency slot. 6. The apparatus according to claim 5 wherein the channel plan is supplied to the processor of said optical channel counter, OCC, unit before scanning of the optical transmission spectrum by the tunable optical filter of said optical channel counter, OCC, unit is initiated. 7. An optical amplifier module comprising an optical amplifier configured to amplify an optical input signal with a gain to generate an optical output signal, and a gain setting apparatus configured to set automatically the gain of said optical amplifier, said gain setting apparatus comprising: an optical channel counter, OCC, unit configured to detect a number of channels present in an optical transmission spectrum using a tunable wide bandwidth optical filter, a determination unit configured to determine an average power per channel calculated by dividing a measured total power of a signal input and/or signal output of the optical amplifier by the number of channels detected by the optical channel counter, OCC, unit and a gain adjustment unit configured to adjust the amplifier gain of said optical amplifier automatically depending on a calculated power difference between a predetermined desired power per channel and the determined average power per channel provided by the determination unit, wherein the optical channel counter, OCC, unit is further configured to perform a channel counter process in at least one of the following two operation modes: in a first operation mode, a peak detection algorithm which allows for detection of channels with arbitrary spectral width and spacing between the channels is applied to determine the number of channels present in an optical transmission spectrum, and in a second operation mode, a channel plan concerning channel spacings between channels within the optical transmission spectrum is received to decide whether a channel is present or not at a specific channel frequency slot of the optical transmission spectrum. 8. A multispan line system comprising cascaded optical amplifiers connected to each other via fiber spans, said system comprising an optical channel counter, OCC, unit configured to detect a number of channels present in an optical transmission spectrum of said multispan line system using a tunable wide bandwidth optical filter, wherein the detected number of channels is communicated via an optical supervisory channel, OSC, to the cascaded optical amplifiers of the multispan line system, and wherein each cascaded amplifier of the multispan line system comprises a determination unit configured to determine an average power per channel calculated by dividing a measured total power of a signal input and/or signal output of the optical amplifier by the number of channels detected by the optical channel counter, OCC, unit communicated via the optical supervisory channel, OSC, and a gain adjustment unit configured to adjust the amplifier gain of said optical amplifier automatically depending on a calculated power difference between a predetermined desired power per channel and the determined average power per channel provided by the determination unit, wherein the optical channel counter, OCC, unit is further configured to perform a channel counter process in at least one of the following two operation modes: in a first operation mode, a peak detection algorithm which allows for detection of channels with arbitrary spectral width and spacing between the channels is applied to determine the number of channels present in an optical transmission spectrum, and in a second operation mode, a channel plan concerning channel spacings between channels within the optical transmission spectrum is received to decide whether a channel is present or not at a specific channel frequency slot of the optical transmission spectrum. 9. The multispan line system according to claim 8 wherein an amplified spontaneous emission, ASE, power generated by each cascaded optical amplifier of the multispan line system is tracked and summed up to determine a cumulative amplified spontaneous emission, ASE, of the cascaded optical amplifiers. 10. The multispan line system according to claim 9 wherein the cumulative amplified spontaneous emission, ASE, of the cascaded optical amplifiers is subtracted from a measured total power to determine a total power of the optical channels. 11. The multispan line system according to claim 10 wherein the determined total power of the optical channels is divided by the number of optical channels present in the optical transmission spectrum of the multispan line system provided by the optical channel counter, OCC, unit to calculate the average power per channel in said multispan line system. 12. The multispan line system according to claim 8 wherein the multispan line system is a wavelength division multiplexed, WDM, multispa