RU99128096A - AUTOMATIC PROTECTION SYSTEM FOR OPTICAL TRANSMISSION SYSTEM - Google Patents

Claims (16)

1. The method of shutting down an optical communication system having extended sections of an optical transmitting fiber dispersed sequentially between optical conversion sections and a plurality of amplification sections containing optical amplifiers included in the forward and reverse directions, the optical conversion sections being selected from the group consisting of a transmitter, an addition multiplexer / tap, an optoelectronic regenerator and a receiver, comprising the steps of: detecting a drop in direct optical signal power below the threshold at the entrance to the optical amplifier, turned on in the forward direction in the first amplifier section, and the decrease in the pump power for the optical amplifier turned on in the forward direction below a predetermined safety level, lower the pump power for the corresponding optical amplifier turned on in the opposite direction in the first amplifier section below a predetermined security level, detect a drop in the power of the reverse optical signal below the threshold at the input of the optical amplifier included in the reverse positioning and located downstream in the second amplifier section directly downstream of the first amplifier section, and lower the pump power for an optical amplifier switched in the opposite direction and located downstream below a predetermined safety level, lower the pump power for the corresponding optical amplifier, turned on in the forward direction in the second next amplification section, below a predetermined safety level, and lower the pump power below a predetermined level safely only for all other optical amplifiers included in the forward and reverse directions positioned between the first amplifier section and the next section of the optical conversion upstream and between the second amplification section and the next section of the optical conversion downstream.  2. The method according to claim 1, in which the detection steps further comprise sub-steps: isolate a portion of the optical signals traveling in the forward and reverse directions, at the input of the corresponding optical amplifiers turned on in the forward and reverse directions, and compare the signal power of the part with a threshold.  3. The method according to claim 2, in which the comparison step is performed using a control circuit for an optical communication system.  4. The method according to claim 1, in which the reduction step is performed in response to a turn-off signal that is generated by a control circuit inside an optical communication system.  5. The method according to claim 1, in which the steps of detecting before lowering the pump power further comprise sub-steps: they wait for a predetermined period of time after the signal power drops below a threshold, and again the signal power drops below a threshold.  6. The method according to claim 1, which further comprises the steps of: waiting for a predetermined period of time after the last step of lowering, and force the amplifier turned on in the forward direction, the amplifier turned on in the reverse direction, and all other optical amplifiers turned on in the reverse and forward directions to ignore the shutdown command, which comes from the control circuit located inside the optical communication system.  7. The method of starting a deactivated optical line located inside the optical communication system, and the optical line has extended sections of the optical transmitting fiber, positioned between two sections of the optical conversion and located in series between many amplification sections containing optical amplifiers included in the forward and reverse directions, the amplifiers of the terminal section are located inside the amplifier sections, which are positioned directly downstream from optical transmission amplifiers, wherein the optical linear amplifiers are located inside the optical sections other than the optical sections located directly downstream of the optical conversion sections, and the optical conversion sections are selected from the group consisting of a transmitter, an add / drop multiplexer, an optoelectronic regenerator and a receiver, comprising steps: force the deactivated amplifier of the terminal section to ignore the shutdown command and work in the low power state, I expect t a predetermined period of time and then confirm the absence of a shutdown command in the amplifier of the terminal section, wait for a second predetermined period of time and then operate the amplifier of the terminal section in full power mode.  8. The method according to claim 7, which further comprises, after the boosting step, the steps of: detecting an increase in signal power above a predetermined threshold at the entrance to the first of the deactivated optical linear amplifiers, which are positioned directly downstream of the amplifier of the terminal section, and the first of the deactivated optical linear amplifiers in low power mode, wait for the first specified period of time and then confirm the absence of the shutdown command in the first optical linearly m amplifier, and wait for a second predetermined period of time and then carry out the operation of the first optical linear amplifier in full power mode.  9. The method of claim 8, which further comprises, after the bringing to operational state step, the following steps: operating in a reduced power mode of each of the subsequent optical linear amplifiers, which are arranged in a cascading manner downstream of the first of the optical linear amplifiers, the first predetermined period of time and then confirm the absence of the shutdown command on each subsequent optical linear amplifier, respectively, and wait for the second predetermined period of time and then The operation of each of the subsequent optical linear amplifiers, respectively, in full power mode.  10. The method according to claim 9, in which the operation step of each subsequent optical linear amplifier occurs after detecting an increase in signal power above a predetermined threshold in each subsequent optical linear amplifier.  11. The method according to claim 9, in which the operation step of each subsequent optical linear amplifier occurs after receiving a signal from a control circuit inside an optical communication system.  12. Dispatch control system for an optical communication line having extended sections of an optical transmitting fiber that are positioned between two sections of an optical transmission and are arranged in series between a plurality of amplification sections containing optical amplifiers included in the forward and reverse directions, and the amplifiers of the terminal section are located inside the amplification sections that are positioned directly downstream of the optical conversion sections, optical linear the amplifiers are located inside the amplification sections located directly downstream of the optical conversion sections, the optical conversion sections being selected from the group consisting of a transmitter, an add / drop multiplexer, an optoelectronic regenerator and a receiver, comprising: a detection circuit associated with optical amplifiers for level detection the input power of optical signals, a control circuit that allows amplifiers surrounding the detected fiber damage, with oschyu detection circuit, and turned off in order to then allow all other optical amplifiers disposed in the optical link off and timing circuit for the delay, and changes the operation state of optical amplifiers for predetermined lengths of time after turning off the optical amplifiers.  13. The control system according to claim 12, in which the control circuit causes the inclusion of one of the amplifiers of the terminal section in the low power mode after receiving an external command.  14. The dispatch control system according to item 13, in which the control circuit causes the inclusion of optical linear amplifiers in low power mode after turning on the amplifier of the terminal section, while the input power is determined first using the detection circuit and the synchronization circuit completes the delay.  15. The control system of claim 12, wherein the detection circuit includes photodiodes associated with an optical communication line at the inputs of optical amplifiers.  16. The control system of claim 12, wherein the control circuit includes a comparison circuit for comparing the detected input power level with a threshold.