JP4615155B2 - Optical communication method and system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an optical communication system that performs monitoring and control in long-distance optical transmission.
[0002]
[Prior art]
Conventionally, in such an optical communication system, it has become the mainstream to use laser light as the transmission distance increases and the transmission capacity increases. In this optical communication system, an optical signal output by modulation of laser light is propagated using, for example, an erbium-doped fiber. In addition, a plurality of relay stations provided with optical amplifiers that directly amplify the optical signal as light is arranged on the fiber, and the optical signal is sequentially amplified and transmitted by each relay station, High-power optical signal transmission was performed, enabling long-distance and large-capacity optical transmission.
[0003]
In such a system, the power of the laser beam is very strong due to the demand of the customer and the light output after being amplified by the optical amplifier is becoming very strong. For this reason, it is dangerous if the laser light enters the eyes of a human body, particularly an operator. For example, the fiber is cut by some obstacle, and the operator is exposed to the laser beam emitted from the end face of the cut fiber. The fear was growing. Thus, in order to operate the optical communication system safely and accurately, it is necessary to consider the safety of the human body.
[0004]
In view of this, an optical communication system in consideration of such safety is disclosed in, for example, Japanese Patent Application Laid-Open No. 2000-209153. In this system, as shown in FIG. 5, two optical transmission lines 10 and 11 are used to transmit an optical signal transmitted from the transmission side of a plurality of communication apparatuses (not shown) to a wavelength division multiplexing apparatus (hereinafter “WDM”). There are some which multiplex 12 and 13 for transmission, and on the receiving side, perform wavelength division by WDM 12 and 13 and then perform bidirectional optical signal transmission received by the communication device.
[0005]
In this optical communication system, an optical signal passes through a plurality of optical amplifiers (hereinafter referred to as “OFA”) 21 to 51 interposed on the optical transmission line 10 and a plurality of OFA 22 to 52 interposed on the optical transmission line 11. Long-distance optical transmission is realized by performing relay amplification.
[0006]
In the OFA 21 to 51 and OFA 22 to 52 interposed between the two optical transmission lines 10 and 11, each OFA on the optical transmission lines 10 and 11 is arranged in a pair and is arranged in each relay station 20 to 50. These relay stations 20 to 50 are also provided with monitoring modules (hereinafter referred to as “SV”) 23 to 53 for monitoring and controlling the optical transmission lines 10 and 11 and each relay station, respectively. ing.
[0007]
As shown in FIG. 6, the OFA is connected to the optical transmission line 10, and includes an optical coupler 60 that branches the return light, a photodiode (hereinafter referred to as “PD”) 61 that receives the branched light, and a PD 61. Are connected to the optical transmission line 10 and are coupled to the optical transmission line 10, and are coupled to the optical couplers 63 and 64, and are connected to the optical couplers 63 and 64 and transmitted to the optical transmission line 10. It is composed of two pump laser diodes (hereinafter referred to as “pump-LD”) 65 and 66 that directly amplify the signal by the emitted light, and control circuits 67 and 68 that control the operation of the pump-LD 65 and 66, The feedback circuit 62 and the control circuits 67 and 68 are connected via a signal line 69.
[0008]
In addition, although the structure of OFA 21-51 by the side of the optical transmission line 10 was shown here, since the structure of OFA 22-52 by the side of the optical transmission line 11 is the same structure as the above, description is abbreviate | omitted.
[0009]
Further, between these adjacent SVs 23 to 53, monitoring signals necessary for monitoring and control are transmitted. Normally, this monitoring signal is an optical signal (mainly to be relayed) by a WDM coupler (not shown). Signal light) and transmitted to the subsequent SV via the optical transmission lines 10 and 11.
[0010]
In such a configuration, for example, when a failure occurs in the optical transmission line, each relay station transmits a line alarm (hereinafter referred to as “LINE-ALM”) and an automatic laser shutdown (hereinafter referred to as “ALS”). ) Two shutdown operations are performed. Hereinafter, the two shutdown operations will be described.
[0011]
Here, for example, if a failure occurs at point A of the optical transmission line 10 between the relay stations 30 and 40 shown in FIG. 5, in the shutdown by LINE-ALM, the relay station 30 side of the relay station 40 in the subsequent stage The strong return light from is detected by PD61. When an optical signal is transmitted from the input side (relay station 20 side in the optical transmission line 10) to the output side (relay station 40 side in the optical transmission line 10), no return light is detected in a steady state, but this strong return When the light is received by the PD 61, it is considered that some trouble such as disconnection of the optical transmission line 10 or disconnection of the connector has occurred after the OFA 31. In this case, there is a risk of being exposed to the danger of being exposed to the laser beam emitted by the worker who is repairing the faulty part.
[0012]
Therefore, in order to protect the worker from this danger, when the PD 61 operates, the feedback circuit 62 generates “LINE-ALM” on the signal line 69 indicating the line failure in the subsequent stage of the OFA 31. When this “LINE-ALM” occurs, in order to stop the output of the OFA 31, the current to the pump-LDs 65 and 66 is cut off under the control of the control circuits 67 and 68.
[0013]
As a result, there is no excitation light to the optical transmission line 10 composed of the erbium-doped fiber, so that the light output from the OFA output side is only the light from the OFA input side. Since the light from the input side is light with very low power attenuated due to transmission loss, even if it is emitted from the cut portion A of the optical transmission line 10 to the outside, it does not cause harm to the operator.
[0014]
Next, shutdown by ALS will be described using, for example, the configuration diagram of the optical amplifier in FIG. 7, in addition to the components shown in FIG. 6, an optical coupler 70 that branches an optical signal from the input side of the OFA, a PD 71 that receives the branched light, and a photocurrent from the PD 71 are detected. The feedback circuit 72 is connected to the control circuits 67 and 68 through the signal line 69 in the same manner as the feedback circuit 62.
[0015]
In the above configuration, when an optical signal is no longer input to the PD 71, it is considered that some trouble has occurred in the previous stage (input side) of the OFA 31. In this case, an in-alarm (hereinafter referred to as “IN-ALM”) indicating that the input light to the OFA 31 is lost is generated from the feedback circuit 62. When this “IN-ALM” occurs, the control circuits 67 and 68 cut off the current supply to the pumps LDs 65 and 66 in order to stop the output of the OFA 31.
[0016]
Considering this shutdown by ALS, it is necessary to monitor the communication state of the optical transmission line 11 facing the ALS. That is, each relay station requires a monitoring system using the SV shown in FIG. 5 and a communication module (not shown) (hereinafter referred to as “COMM”). In this monitoring system, the SV monitors and controls all installed relay stations, and the COMM sends monitoring and control signals (hereinafter referred to as “monitoring signals”) to and from adjacent relay stations. Send and receive.
[0017]
In this monitoring system, the monitoring signal uses an optical wavelength different from that of the main signal light, and is wavelength-divided by a WDM filter (not shown) provided in the optical transmission path immediately before the OFA input and immediately before the output. Monitoring signal transmission is possible.
[0018]
Here, as described above, the case where a failure occurs between the relay stations 30 and 40 will be described. In the relay station 30, as described above, “LINE-ALM” is generated due to the return light from the disconnection point A and shuts down. To do. Further, since the OFA 41 of the relay station 40 does not receive the optical signal from the disconnection point A, “IN-ALM” occurs and shuts down.
[0019]
Next, a suspend alarm (hereinafter referred to as “SUSP-ALM”) is generated from the OFA 41 of the relay station 40 to the opposing OFA 42 via the monitoring system, and the OFA 42 is also shut down. The OFA 51 of the relay station 50 shuts down because the optical signal from the OFA 41 of the relay station 40 does not reach. Eventually, all the OFAs 21 to 51 and OFA 22 to 52 in FIG. 5 are shut down. The “SUSP-ALM” is an alarm indicating that the OFA itself is shut down for safety by an ALM signal from the opposing OFA side even if it is normal.
[0020]
[Problems to be solved by the invention]
However, in the above-described conventional example, when a failure occurs in the optical transmission path between the optical amplifier and the wavelength division multiplexing apparatus, strong reflected light is returned to the preceding optical amplifier even though the optical transmission path is disconnected. In such a state (the angle of the cut end face of the optical transmission line is 8 degrees), a problem occurs.
[0021]
For example, as shown in FIG. 5, when the optical transmission line 11 between the relay station 20 and the WDM 12 is disconnected as described above, the OFA 22 of the relay station 20 cannot detect the return light. “LINE-ALM” does not occur. If this is a disconnection between relay stations (point A), “IN-ALM” occurs in the subsequent OFA and the entire system stops due to ALS, but “IN-ALM” occurs after the B point. Because there is no device to shut down, the entire system will not shut down due to ALS. As a result, in the conventional example, the optical signal may be output after being amplified by the optical amplifier in spite of the disconnection of the optical transmission line, which may cause danger to the human body. It was. For such problems, safety measures are written in international standards such as International Electrotechnical Commission (IEC) 825 and European Standard (EN) 60825.
[0022]
The present invention has been made in view of the above problems, and an object of the present invention is to provide an optical communication system that can reliably detect the occurrence of a failure and that fully considers safety for the human body.
[0023]
[Means for Solving the Problems]
In order to solve the above-described problems and achieve the object, an optical communication method according to the present invention includes: A plurality of relay stations having a plurality of optical transmission lines, communicating optical signals between the first terminal station and the second terminal station via the respective optical transmission lines, and provided on the optical transmission line In the optical communication method for performing bidirectional optical communication by optically amplifying the optical signal by the optical signal and multiplexing and transmitting the monitoring signal to the optical signal, among the relay stations, A branching optical transmission line is branched from the optical transmission line connecting the first or second terminal station, and the monitoring signal is captured by wavelength division from the optical signal flowing to the terminal station via the optical transmission line And a monitoring / control step of monitoring whether or not the monitoring signal is captured and stopping optical amplification of the optical signal when the monitoring signal is not captured.
[0024]
According to the present invention, the monitoring signal is multiplexed and transmitted on the optical signal of the optical transmission line, and the relay station and the terminal station arranged at the last stage on the optical transmission line are connected in the flow of the optical signal. When the monitoring signal is wavelength-divided from the optical signal propagating through the optical transmission line, when this monitoring signal exists, it is determined that the communication state is normal, and when the monitoring signal disappears, it is determined that a failure has occurred. Then, by stopping the optical amplification of the optical signal, it is possible to reliably detect the occurrence of a failure in the optical transmission line that could not be detected until now, and to fully consider the safety for the human body.
[0025]
The optical communication method according to the present invention is the above invention, In the taking-in step, a branching optical transmission line branched from one of the optical transmission lines is connected to the other optical transmission line, and the wavelength-divided monitoring signal is temporarily connected to the other optical transmission line. A characteristic is that the monitoring signal is wavelength-divided and multiplexed after being multiplexed with the optical signal of the transmission line.
[0026]
According to the present invention, the monitoring signal that is wavelength-divided from the optical signal of one optical transmission line is multiplexed with the optical signal of the other optical transmission line via the branching optical transmission line, and then wavelength-divided again. In this way, it is possible to detect the monitoring signal at the relay station that has output the monitoring signal and to stop the amplification of the optical signal associated therewith.
[0027]
In order to solve the above-described problems and achieve the object, an optical communication method according to the present invention includes: A plurality of relay stations having a plurality of optical transmission lines, communicating optical signals between the first terminal station and the second terminal station via the respective optical transmission lines, and provided on the optical transmission line In the optical communication method for performing bidirectional optical communication by optically amplifying the optical signal by the optical signal and multiplexing and transmitting the monitoring signal to the optical signal, among the relay stations, Branching the branching optical transmission line from the optical transmission line connecting the first or second terminal station, capturing the optical signal flowing into the terminal station, monitoring whether the optical signal has been captured, It includes a monitoring / controlling step of stopping optical amplification of the optical signal when the optical signal is not captured.
[0028]
According to the present invention, in the flow of the optical signal, the optical signal propagating through the optical transmission line connecting the relay station and the terminal station arranged at the last stage on the optical transmission line is branched, and the branched optical signal is If it exists, it is determined that the communication status is normal, and when there is no optical signal, it is determined that a fault has occurred and optical amplification of the optical signal is stopped. It is possible to reliably detect the occurrence of a fault on the road and to fully consider the safety to the human body.
[0029]
The optical communication method according to the present invention is the above invention, In the capturing step, the optical signal is converted from light to an electrical signal, and in the monitoring / control step, optical amplification of the optical signal is stopped when the electrical signal is not captured.
[0030]
According to the present invention, after the optical signal is converted from light to an electrical signal, the presence or absence of the optical signal is detected, so that it is possible to detect the occurrence of a failure and stop the amplification of the optical signal associated therewith.
[0031]
In order to solve the above-described problems and achieve the object, an optical communication method according to the present invention includes: A plurality of optical transmission lines, communicating with each other by multiplexing optical signals between the first terminal station and the second terminal station, each comprising a wavelength division multiplexing device, through each of the optical transmission lines; In the optical communication method for performing bidirectional optical communication by optically amplifying the optical signal by a plurality of relay stations provided on a transmission line and multiplexing and transmitting the monitoring signal to the optical signal, the terminal station includes: An output port for outputting the wavelength band of the monitoring signal among the output ports of the demultiplexer, and an input port for inputting the wavelength band of the monitoring signal among the input ports of the multiplexer, the output port and the input port Are connected by an optical transmission line, the optical signal of the one optical transmission line is sent to the demultiplexer, the wavelength of the monitoring signal is divided, and then the optical signal is sent to the multiplexer to the other optical transmission line A capture process for multiplexing and capturing by dividing into optical signals, and monitoring whether the monitoring signal is captured, and monitoring to stop optical amplification of the optical signal if the monitoring signal is not captured -It is characterized by including a control process.
[0032]
According to the present invention, the monitoring signal is multiplexed and transmitted on the optical signal of the optical transmission line, and the relay station and the terminal station arranged at the last stage on the optical transmission line are connected in the flow of the optical signal. From the optical signal propagating in one optical transmission line, the monitoring signal is wavelength-divided by the demultiplexer, and this monitoring signal is multiplexed by the multiplexer to the optical signal of the other optical transmission line, and then wavelength-divided again. When there is a monitoring signal, it is determined that the communication state is normal, and when there is no monitoring signal, it is determined that a failure has occurred and the optical signal amplification is stopped. The failure of the optical transmission line that could not be detected can be reliably detected, and the safety to the human body can be fully considered.
[0033]
In order to solve the above-described problems and achieve the object, an optical communication system according to the present invention includes: A plurality of optical transmission lines, a terminal station connected via each optical transmission line, each communicating with an optical signal, and provided on the optical transmission line, amplifies the optical signal and monitors the optical signal In an optical communication system having a plurality of relay stations that multiplex and transmit signals for transmission and performing bidirectional optical communication, among the relay stations, the relay station at the rearmost stage and the first or second terminal A first dividing unit for wavelength-dividing a monitoring signal from an optical signal transmitted to an optical transmission line to which a station is connected; a monitoring unit for monitoring presence / absence of the monitoring signal; and the light according to the monitoring result An optical amplification control means for stopping optical amplification of the signal is provided.
[0034]
According to the present invention, the monitoring signal output from the relay station is multiplexed with the optical signal of the optical transmission line, and the optical transmission between the relay station and the terminal station at the rearmost stage on the optical transmission line is performed in the flow of the optical signal. If the monitoring signal is wavelength-divided by the dividing means provided in the path, and this monitoring signal no longer exists, the optical amplification control means determines that a failure has occurred and stops the optical amplification of the optical signal so far. It is possible to reliably detect the failure of the optical transmission line that could not be detected, and to give sufficient consideration to safety for the human body.
[0035]
An optical communication system according to the present invention is the above invention, Multiplexing means for multiplexing the wavelength-divided monitoring signal with the optical signal of the other optical transmission line, and second dividing means for wavelength-dividing the monitoring signal from the optical signal transmitted to the other optical transmission line The monitoring means monitors the monitoring signal wavelength-divided by the second dividing means.
[0036]
According to this invention, in the above invention, the monitoring signal obtained by wavelength division from the optical signal of one optical transmission line is multiplexed with the optical signal of the other optical transmission line by the multiplexing means, and then the second division is again performed. By dividing the wavelength by means and taking it into the relay station, it becomes possible to detect the monitoring signal at the relay station that has output this monitoring signal and to stop amplification of the optical signal associated therewith.
[0037]
In order to solve the above-described problems and achieve the object, an optical communication system according to the present invention includes: A plurality of optical transmission lines, first and second terminals that are connected through the respective optical transmission lines and communicate optical signals, respectively, are provided on the optical transmission line, and amplifies the optical signal. A plurality of relay stations that multiplex and transmit the monitoring signal to the optical signal, and perform bidirectional optical communication. A branching unit for branching an optical signal transmitted to an optical transmission line to which the first or second terminal station is connected; a monitoring unit for monitoring presence or absence of the optical signal; and an optical signal of the optical signal according to the monitoring result And an optical amplification control means for stopping the amplification.
[0038]
According to the present invention, in the flow of the optical signal, when the optical signal is branched by the branching means provided in the optical transmission path between the relay station and the terminal station at the rearmost stage on the optical transmission path, and this optical signal no longer exists, By stopping the optical amplification of the optical signal by judging that the optical amplifier has failed, it is possible to reliably detect the failure in the optical transmission line that could not be detected until now, and to ensure sufficient safety for the human body. Can be considered.
[0039]
An optical communication system according to the present invention is the above invention, The apparatus further comprises conversion means for converting the branched optical signal from light to an electrical signal, and the monitoring means monitors the presence or absence of the electrical signal.
[0040]
According to the present invention, after the optical signal is converted from the light to the electric signal by the conversion means, the monitoring means detects the presence or absence, thereby detecting the occurrence of the failure by the relay station and the accompanying optical signal amplification stop. This can be done by the control means.
[0041]
In order to solve the above-described problems and achieve the object, an optical communication system according to the present invention includes: A plurality of optical transmission lines, a first and a second terminal station, each of which is connected via each optical transmission line and multiplexes optical signals and performs communication, and is provided on the optical transmission line; A plurality of relay stations that amplify the optical signal and multiplex and transmit the monitoring signal to the optical signal, and perform bidirectional optical communication, in the relay station, Dividing means for wavelength-dividing the monitoring signal from the optical signal transmitted to the optical transmission line to which the most subsequent relay station and the first or second terminal station are connected, and monitoring for monitoring the presence or absence of the monitoring signal And an optical amplification control means for stopping optical amplification of the optical signal according to the monitoring result, and the first and second terminal stations are one of the optical transmission lines. Wavelength-dividing the monitoring signal from the optical signal flowing from the terminal to the terminal A demultiplexer that is characterized in that the monitoring signal the wavelength division and a multiplexer for transmitting by multiplexing on the other optical signal of the optical transmission path.
[0042]
According to the present invention, the monitoring signal is multiplexed and transmitted on the optical signal of the optical transmission line, and the relay station and the terminal station arranged at the last stage on the optical transmission line are connected in the flow of the optical signal. After the monitoring signal is wavelength-divided by a demultiplexer provided in one optical transmission line, and this monitoring signal is multiplexed with the optical signal of the other optical transmission line by a multiplexer, the monitoring signal is again transmitted by the wavelength division means. When this signal for monitoring no longer exists, the optical amplification control means determines that a failure has occurred and stops the optical amplification of the optical signal. It can be detected reliably and the safety to the human body can be fully considered.
[0043]
DETAILED DESCRIPTION OF THE INVENTION
Exemplary embodiments of a system using an optical communication method according to the present invention will be described below with reference to the accompanying drawings. The overall configuration of the optical communication system according to the present invention is the same as that shown in FIG. 5. In the following drawings, the same components as those shown in FIG.
[0044]
Example 1
FIG. 1 is a configuration diagram showing configurations of a WDM and a relay station according to the first embodiment of the present invention. In the figure, a WDM 12 is provided in an optical transmission line 10 and a multiplexer 14a that multiplexes an optical signal of each wavelength input from each transmission device (not shown), for example, an optical signal in a wavelength band of 1.55 μm and outputs the multiplexed optical signal to the optical transmission line 10. A multiplexed circuit (MUX) 14 having the optical coupler 14b, a demultiplexer 15a that wavelength-divides an optical signal input from the optical transmission line 11 and outputs it to each receiving device (not shown), and a WDM provided in the optical transmission line 11. A wavelength division circuit (DMUX) 15 having a filter 15b and a branching optical transmission line 16 connected between the optical coupler 14b and the WDM filter 15b are configured.
[0045]
The WDM filter 15b is a filter that divides an optical signal having a wavelength band of 1.51 μm, for example. Among the optical signals propagating through the optical transmission line 11, a monitoring signal having a wavelength band of 1.51 μm from the relay station 20 is wavelength-converted. It is divided. The divided monitoring signals are taken into the optical coupler 14b via the branching optical transmission line 16, where they are multiplexed with the optical signal propagating through the optical transmission line 10 and output to the relay station 20.
[0046]
The relay station 20 includes a transmission side optical amplifier (hereinafter referred to as “B-OFA”) 21, a reception side optical amplifier (hereinafter referred to as “P-OFA”) 22, an SV 23, and a COMM 24. Yes.
[0047]
The B-OFA 21 is connected to the optical transmission line 10, and an optical coupler 21a that branches an optical signal or return light, a PD 21b that receives the branched light, a feedback circuit 21c that detects a photocurrent from the PD 21b, An optical coupler 21d that is connected to the optical transmission line 10 and combines light for optical amplification, and a pump that is connected to the optical coupler 21d and directly amplifies the optical signal transmitted to the optical transmission line 10 by the emitted light. An LD 21e, a control circuit 21f for controlling the operation of the pump-LD 21e, a feedback circuit 21c and a control circuit 21f, and an interface circuit 21g for inputting / outputting signals to / from the SV 23, and an optical transmission line 10. WDM filter 21h and an optical coupler 21i connected to the optical transmission line 10.
[0048]
The WDM filter 21h is a filter that divides an optical signal having a wavelength band of 1.51 μm as described above. Of the optical signals propagating through the optical transmission line 10, the WDM filter 21h has a 1.51 μm output from the monitoring circuit 23a of the own station 20. The wavelength band monitoring signal is wavelength-divided. The divided monitoring signals are taken into the COMM 24 via the branching optical transmission line 25. The optical coupler 21 i multiplexes the monitoring signal output from the COMM 24 via the optical transmission path 26 with the optical signal of the optical transmission path 10.
[0049]
The P-OFA 22 has the same configuration as that of the B-OFA 21 and is connected to the optical coupler 22a, the PD 22b, the feedback circuit 22c, the optical coupler 22d, and the optical coupler 22d and is transmitted to the optical transmission line 10. A pump-LD 22e that directly amplifies the output of the pump-LD 22e, a control circuit 22f that controls the operation of the pump-LD 22e, a feedback circuit 22c and a control circuit 22f, and an interface circuit 22g that inputs and outputs signals to and from the SV 23. And an optical coupler 22 h connected to the optical transmission line 10 and a WDM filter 22 i connected to the optical transmission line 11.
[0050]
The optical couplers 22a, 22d, 22h and the WDM filter 22i are respectively connected to the optical transmission line 11. Of these, the optical coupler 22a branches an optical signal and return light, and the optical coupler 22d is used for optical amplification. Light is multiplexed with the optical signal. The optical coupler 22h multiplexes the monitoring signal output from the COMM 24 via the optical transmission path 27 with the optical signal of the optical transmission path 11, and the WDM filter 22i has a wavelength band of 1.51 μm. The filter that divides the signal splits the monitoring signal in the 1.51 μm wavelength band output from the monitoring circuit of the SV 33 of the other station 30 among the optical signals propagating through the optical transmission line 10. The divided monitoring signals are taken into the COMM 24 via the branching optical transmission line 28.
[0051]
The SV 23 includes a monitoring circuit 23a. The monitoring circuit 23a monitors and controls the optical transmission lines 10 and 11 and each relay station, and monitors the optical transmission lines 10 and 11 that are the features of the present invention. The monitoring signal output and the presence or absence of the monitoring signal input from the optical transmission lines 10 and 11 are monitored.
[0052]
The COMM 24 includes electric / optical converters (hereinafter referred to as “E / O”) 24a and 24b, and optical / electrical converters (hereinafter referred to as “O / E”) 24c and 24d. The E / Os 24a and 24b are electrical signals output from the monitoring circuit 23a. for The signal is subjected to electrical / optical conversion and output to the optical couplers 22h and 21i. The O / Es 24c and 24d are optical signals that are wavelength-divided by the WDM filters 21h and 22i. for The signal is optical / electrically converted and output to the monitoring circuit 23a.
[0053]
In such a configuration, the monitoring circuit 23a, E / O 24a, optical transmission line 27, optical coupler 22h, optical transmission line 11, WDM filter 15b, branching optical transmission line 16, optical coupler 14b, optical transmission line 10, WDM filter 21h, the optical transmission path 25 for branching, the O / E 24c, and the monitoring circuit 23a form a loop, and the monitoring signal output from the monitoring circuit 23a is transmitted on this loop. If a failure occurs at point B of the optical transmission line 11, it will not return to the monitoring circuit 23a.
[0054]
That is, in the normal state, the monitoring signal output from the monitoring circuit 23a is converted into an optical signal by the E / O 24a, and the optical signal (mainly) of the optical transmission line 11 is output by the optical coupler 22h at the output unit of the P-OFA 22. Is multiplexed with the main signal light by the WDM filter 15b in the DMUX 15. The demultiplexed monitoring signal flows through the branching optical transmission line 16, is combined with the main signal light of the optical transmission line 10 by the optical coupler 14b in the MUX 14, and is further supplied by the WDM filter 21h in the B-OFA 21. Demultiplexed with signal light. The demultiplexed monitoring signal flows through the branching optical transmission line 25, is converted into an electric signal by the O / E 24c, and is taken into the monitoring circuit 23a.
[0055]
Next, the monitoring operation of the monitoring circuit 23a will be described using the flowchart of FIG. In the figure, the monitoring circuit 23a periodically outputs a monitoring signal (step 101), and is received at regular intervals through the loop in the normal state (step 102), so that the main signal light is also normal. That you are communicating with.
[0056]
Here, for example, if a special failure that does not cause “LINE-ALM” in the optical fiber cord (for example, disconnection at the point B of the optical transmission line 11) occurs between the P-OFA 22 and the DMUX 15, this failure occurs. The monitoring signal output from the E / O 24a cannot reach the O / E 24c. As a result, the monitoring circuit 23a of the SV 23 cannot normally receive the monitoring signal, and therefore determines that the main signal light is not normally transmitted.
[0057]
Therefore, the monitoring circuit 23a outputs a control signal for stopping the operation of the pump-LD 22e to the control circuit 22f via the interface circuit 22g in the P-OFA 22 (step 103), and the control circuit 22f In response to this, the pump-LD 22e is stopped. As a result, there is no excitation light to the optical transmission line 11, so the light output from the output side of the P-OFA 22 is only the light from the input side of the P-OFA 22. Since the light from the input side is light with very low power attenuated due to transmission loss as described above, even if the light is emitted from the cut portion B of the optical transmission line 11 to the outside, it does not harm the operator. Disappear.
[0058]
Further, the monitoring circuit 23a outputs a control signal for stopping the operation of the pump-LD 21e to the control circuit 21f via the interface circuit 21g in the B-OFA 21 in order to shut down the entire system (step 104). The control circuit 21f stops the current supply to the pump-LD 21e in response to this control signal. As a result, since no optical signal is input in OFA 31, “IN-ALM” occurs, shuts down the current to pump-LD, shuts down, and “SUSP-ALM” occurs from SV33. The OFA 32 is also shut down.
[0059]
As described above, in the first embodiment, the optical transmission lines 10 and 11 between the WDM serving as the terminal station and the relay station are connected by the branch optical transmission line to form a loop, and the monitoring signal is supplied to the loop. Thus, even if a special failure that does not cause “LINE-ALM” occurs, by monitoring the monitoring signal, the occurrence of this failure is reliably detected and the optical amplification of the main signal light is stopped. This makes it possible to fully consider safety for the human body.
[0060]
In the first embodiment, the branching optical transmission line 16 for connecting the optical transmission lines 10 and 11 is provided in the WDM. However, the present invention is not limited to this, for example, between the WDM and the relay station, and for the WDM. You may provide so that both near optical transmission lines may be connected. Further, the terminal station of the present invention is not limited to WDM. For example, in the case of a system that does not perform multiplexing, the terminal station may be the communication device itself, or may be a transmitter or receiver of a separate communication device. good.
[0061]
The wavelength of the monitoring signal according to the present invention is not limited to the 1.51 μm wavelength band shown in the first embodiment, and can be set to any wavelength band other than the wavelength band of the main signal light. .
[0062]
1 is provided at the input port of the multiplexer 14a shown in FIG. 1, and the output port 15a1 for outputting the wavelength band of 1.51 μm is provided at the output port of the demultiplexer 15a. If the ports are connected by an optical transmission line 17 indicated by a one-dot chain line, and a monitoring signal having a wavelength of 1.51 μm is output from the monitoring circuit 23a to the optical transmission line 11, the WDM filter 15b and the optical coupler 14b are connected. A loop for flowing a monitoring signal can be formed by using existing equipment without using it, thereby reducing the manufacturing cost.
[0063]
(Example 2)
FIG. 3 is a block diagram showing a part of the configuration of the wavelength division multiplexing apparatus and the relay station according to the second embodiment of the present invention. In addition, about the component similar to FIG. 1, the same code | symbol is attached for convenience of description here.
[0064]
In the figure, a DMUX 15 of the WDM 12 includes a demultiplexer 15a, an optical coupler 15c that is provided in the optical transmission line 11, and branches an optical signal, and a branched light. Light reception And a feedback circuit 15e for detecting the photocurrent from the PD 15d. The feedback circuit 15e is connected to the monitoring circuit 23a of the SV 23 via the interface circuit 22g of the P-OFA 22.
[0065]
The P-OFA 22 of the relay station 20 includes the optical coupler 22a, the PD 22b, the feedback circuit 22c, the optical coupler 22d, the pump-LD 22e, the control circuit 22f, and the interface circuit 22g shown in FIG. The interface circuit 22g is connected to the monitoring circuit 23a of the SV 23 as described above.
[0066]
The monitoring circuit 23a monitors the return light of the optical transmission line 11 detected by the PD 22b when a failure occurs and the presence / absence of an optical signal of the optical transmission line 11 detected by the PD 15d.
[0067]
Next, the monitoring operation of the monitoring circuit 23a will be described using the flowchart of FIG. In the figure, the monitoring circuit 23a determines whether there is return light detected by the PD 22b (step 201). If there is no return light, there is an optical signal detected by the PD 15d. Judgment is made (step 202).
[0068]
Here, when there is no return light and an optical signal is detected, it is determined that optical transmission is performed in a normal state, and the above operation is repeated. -The optical amplification is continued by operating the LD 22e. If there is a return light in step 201, “LINE-ALM” is output from the feedback circuit 22c to the monitoring circuit 23a. Therefore, the monitoring circuit 23a uses the P-LD to stop the operation of the pump-LD 22e. -A control signal is output to the control circuit 22f via the interface circuit 22g in the OFA 22 (step 203). The control circuit 22f stops the current supply to the pump-LD 22e in response to this control signal, and stops the optical amplification. To do.
[0069]
If a special failure that does not cause “LINE-ALM” occurs, the main signal light is emitted from the cut portion B of the optical transmission line 11, and the PD 15d cannot detect the main signal light. As a result, since no photocurrent is input to the feedback circuit 15e, “IN-ALM” is output from the feedback circuit 15e to the monitoring circuit 23a. As a result, the monitoring circuit 23a outputs a control signal for stopping the operation of the pump-LD 22e to the control circuit 22f via the interface circuit 22g in the P-OFA 22 (step 203). The control circuit 22f The current supply to the pump-LD 22e is stopped according to the signal, and the optical amplification is stopped.
[0070]
Further, as in FIG. 1, the monitoring circuit 23a outputs a control signal for stopping the operation of the pump-LD 21e to the control circuit 21f via the interface circuit 21g in the B-OFA 21 in order to shut down the entire system. Then (step 204), the control circuit 21f stops the current supply to the pump-LD 21e in response to this control signal, and stops the optical amplification. As a result, since no optical signal is input in OFA 31, “IN-ALM” is generated, current supply to pump-LD is shut down and shut down, and “SUSP-ALM” is generated from SV 33. Then, the OFA 32 is also shut down.
[0071]
As described above, in the second embodiment, since the main signal light is monitored by providing the PD 15d and the feedback circuit 15e for generating “IN-ALM” at the input unit of the DMUX 15, “LINE-ALM” does not occur. Even if a special failure occurs, the presence or absence of detection of the main signal light can reliably detect the occurrence of this failure and stop the optical amplification of the main signal light. Can be considered.
[0072]
In the second embodiment, the PD 15d and the feedback circuit 15e are provided in the WDM. However, the present invention is not limited to this. For example, the PD 15d is connected to the optical transmission line 11 between the WDM 12 and the relay station 20 and in the vicinity of the WDM 12. You may provide so that the feedback circuit 15e may be connected.
[0073]
In these embodiments, the case where the present invention is used for the WDM 12 has been described. However, it goes without saying that the present invention can also be used in the WDM 13 which is the other terminal station.
[0074]
The present invention is not limited to these embodiments, and various modifications can be made without departing from the spirit of the present invention.
[0075]
【The invention's effect】
As described above, according to the present invention, the monitoring signal is combined with the optical signal on the optical transmission line and transmitted, and the relay station and the terminal arranged at the last stage on the optical transmission line in the flow of the optical signal are connected. When the monitoring signal is wavelength-divided from the optical signal propagating through the optical transmission line connecting the station, when this monitoring signal exists, it is determined that the transmission state is normal and the monitoring signal disappears, Since the optical amplification of the optical signal is stopped as the occurrence, the occurrence of the failure can be detected with certainty, and the safety for the human body can be sufficiently considered.
[Brief description of the drawings]
FIG. 1 is a configuration diagram illustrating configurations of a wavelength division multiplexing apparatus and a relay station according to a first embodiment of the present invention.
FIG. 2 is a flowchart for explaining a monitoring operation of the monitoring circuit shown in FIG. 1;
FIG. 3 is a configuration diagram showing a partial configuration of a wavelength division multiplexing apparatus and a relay station according to Embodiment 2 of the present invention;
4 is a flowchart for explaining a monitoring operation of the monitoring circuit shown in FIG. 2;
FIG. 5 is a configuration diagram showing an overall configuration of an optical communication system.
6 is a block diagram showing an example of the configuration of the optical amplifier shown in FIG.
7 is a block diagram showing another example of the configuration of the optical amplifier shown in FIG. 5. FIG.
[Explanation of symbols]
10, 11, 26, 27 Optical transmission line
12,13 WDM
14 MUX
14a multiplexer
14b, 15c, 21a, 21d, 22a, 22d, 22h, 60, 63, 64, 70 Optical coupler
15 DMUX
15a Demultiplexer
15b, 21h, 22i WDM filter
15d, 21b, 22b, 61, 71 PD
15e, 21c, 22c, 62, 72 Feedback circuit
16, 25, 28 Branch optical transmission line
20-50 relay station
21-51, 22-52 OFA
21e, 22e, 65, 66 Pump-LD
21g, 22g interface circuit
21f, 22f, 67, 68 Control circuit
23-53 SV
23a Monitoring circuit
69 Signal line

Claims (6)

Has two optical transmission lines, to communicate optical signals to and from the first end station and a second end station through the respective optical transmission path, said second end and said first end station In an optical communication method for performing bidirectional optical communication by optically amplifying the optical signal by a plurality of relay stations provided between the stations,
Of the plurality of relay stations, the relay station located at the rearmost stage multiplexes the monitoring signal with the optical signal propagating through one optical transmission line, and the multiplexed optical signal is adjacent to the first relay station. Or a multiple output step of outputting to the second terminal station;
The first or second terminal station that has received the multiplexed optical signal output in the multiple output step wavelength-divides the monitoring signal, and the wavelength-divided monitoring signal is divided into the other optical transmission line. And a multiplexed multiple output step for outputting the multiplexed optical signal to the relay station that has output the multiplexed optical signal in the multiple output step,
The relay station that has received the multiplexed optical signal output in the division multiplexing output step, takes in the monitoring signal output by the local station by wavelength division, and capture step;
A control step of stopping optical amplification of the optical signal propagating through the one optical transmission line when the monitoring signal is not captured in the capturing step;
An optical communication method comprising: Has two optical transmission lines, to communicate optical signals to and from the first end station and a second end station through the respective optical transmission path, said second end and said first end station In an optical communication method for performing bidirectional optical communication by optically amplifying the optical signal by a plurality of relay stations provided between the stations,
An optical signal is branched from an optical transmission line that connects the relay station located at the rearmost stage among the plurality of relay stations and the first or second terminal station adjacent to the relay station, and the branched optical signal is A capture process that converts and captures electrical signals;
When the electrical signal is not captured in the capturing step, a control step of stopping optical amplification of the optical signal propagating through the optical transmission path ;
An optical communication method comprising: Communication of optical signals between each of the first terminal station and the second terminal station, each having two optical transmission lines, each having a wavelength division multiplexing apparatus including a multiplexer and a demultiplexer. In an optical communication method for performing bidirectional optical communication by optically amplifying the optical signal by a plurality of relay stations provided between the first terminal station and the second terminal station ,
Of the plurality of relay stations, the relay station located at the rearmost stage multiplexes the monitoring signal with the optical signal propagating through one optical transmission line, and the multiplexed optical signal is adjacent to the first relay station. Or a multiple output step of outputting to the second terminal station;
The monitoring signal is wavelength-divided by a demultiplexer included in the first or second terminal station that has received the multiplexed optical signal output in the multiple output step, and the wavelength-divided monitoring signal is the same terminal station. A division multiplexing output step of multiplexing the optical signal propagating through the other optical transmission line through the multiplexer and outputting the multiplexed optical signal to the relay station that has output the multiplexed optical signal in the multiplexing output step; ,
The relay station that has received the multiplexed optical signal output in the division multiplexing output step, takes in the monitoring signal output by the local station by wavelength division, and capture step;
A control step of stopping optical amplification of the optical signal propagating through the one optical transmission line when the monitoring signal is not captured in the capturing step ;
An optical communication method comprising: Has two optical transmission lines, to communicate optical signals to and from the first end station and a second end station through the respective optical transmission path, said second end and said first end station In an optical communication system that performs bidirectional optical communication by optically amplifying the optical signal by a plurality of relay stations provided between the stations,
The monitoring signal output by the relay station located at the rearmost stage among the relay stations is propagated through one optical transmission line connecting the relay station and the first or second terminal station adjacent to the relay station. First multiplexing means for multiplexing the optical signal to be transmitted;
First dividing means for wavelength-dividing the monitoring signal multiplexed by the first multiplexing means from an optical signal propagating through the one optical transmission line ;
Second multiplexing means for multiplexing the monitoring signal wavelength-divided by the first dividing means with an optical signal propagating through the other optical transmission line;
Second dividing means for wavelength-dividing the monitoring signal multiplexed by the second multiplexing means from an optical signal propagating through the other optical transmission line ;
Monitoring means for monitoring presence or absence of the monitoring signal wavelength-divided by the second dividing means;
An optical amplification control means for stopping optical amplification of an optical signal propagating through the one optical transmission line according to a monitoring result of the monitoring means;
An optical communication system comprising: The first dividing means includes
A demultiplexer having an output port for outputting the wavelength-divided monitoring signal;
The second multiplexing means includes:
5. The optical communication system according to claim 4, wherein the multiplexer has an input port for inputting the monitoring signal output from the demultiplexer. Has two optical transmission lines, to communicate optical signals to and from the first end station and a second end station through the respective optical transmission path, said second end and said first end station In an optical communication system that performs bidirectional optical communication by optically amplifying the optical signal by a plurality of relay stations provided between the stations,
A branching unit for branching an optical signal propagating to an optical transmission line connecting the relay station located at the rearmost stage among the plurality of relay stations and the first or second terminal station adjacent to the relay station ;
Conversion means for converting the optical signal branched by the branching means into an electrical signal;
Monitoring means for monitoring the presence or absence of the electrical signal converted by the conversion means;
According to the monitoring result of the monitoring means, optical amplification control means for stopping the optical amplification of the optical signal propagating to the optical transmission line ;
An optical communication system comprising:

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