JP2014082583A - Transmission system, repeating device, receiver, and transmission path switching method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To alleviate an influence of cumulative noise generated during switching of a transmission path of a transmission system upon fault occurrence, thereby achieving receiver simplification and low power consumption.SOLUTION: The present invention comprises: a repeating device with fault detection means for detecting fault occurrence of a first transmission path and wavelength conversion means for converting a wavelength of a repeating signal when detecting fault occurrence, and a receiver with a transmission path switching means for switching the first transmission path to a second transmission path when detecting conversion of a wavelength of a signal.

Description

  The present invention relates to a transmission system, a relay apparatus, a receiving apparatus, and a transmission path switching method for notifying the occurrence of a transmission path failure.

  In general, an optical transmission system is a backbone system that transmits a large amount of information in a communication infrastructure, and needs to have a protection function in order to improve its reliability.

  Patent Document 1 discloses a repeaterless optical transmission system using an optical transmission apparatus and an optical multiplex transmission apparatus. The repeaterless optical transmission system disclosed in Patent Document 1 discloses a receiving-side device in which signal light is branched into two on the transmitting side, the level of the signal light is detected on the receiving side, and the signal light is switched.

  Patent Document 2 discloses an optical repeater and an optical transmission system using the same. When the level of the signal light falls below a predetermined level, the optical repeater outputs a predetermined alarm signal indicating that a failure has occurred. It is detected from the reception of the alarm signal that a failure has occurred, and the signal light is switched.

  FIG. 9 is a system diagram illustrating a configuration example of an optical transmission system. FIG. 10 is a block diagram illustrating a configuration example of a receiving apparatus.

  A configuration example of the optical transmission system in FIG. 9 will be described. The optical transmission system in FIG. 9 includes a transmission apparatus 1, a reception apparatus 2, a transmission path 101, and a transmission path 102 to a transmission path 10k (k is an integer of 1 or more). The transmission path 101 includes relay devices (1, 1) 10 to relay devices (j, 1) 10 (j is an integer equal to or greater than 1). The transmission path 102 includes the relay apparatus (1, 2) 10 to the relay apparatus (j, 2) 10, and the transmission path 10k includes the relay apparatus (1, k) 10 to the relay apparatus (j, k) 10. Yes.

  The transmission device 1 is a transmission side of the optical transmission system. The receiving device 2 is a receiving side of the optical transmission system. The relay device 10 relays the optical signal from the transmission side to the reception side in each of the transmission paths 101 to 10k.

  With reference to FIG. 9, switching of a transmission line when a failure occurs immediately before the relay device (j−1, 1) 10 on the transmission line 101 will be described.

  The relay device (j-1, 1) 10 monitors the signal light level from the transmission path 101 and detects the occurrence of a failure. The relay device (j-1, 1) 10 determines that a failure has occurred when the signal light level falls below a predetermined level. The relay device (j-1, 1) 10 monitors the failure occurrence information included in the monitoring signal of the relay device (j-2, 1) 10 from the relay device (1, 1) 10 located in the preceding stage. Detects the occurrence of a failure. Then, the relay device (j-1, 1) 10 detects the occurrence of the failure, includes the failure occurrence information in the monitoring signal, and transmits it to the subsequent transmission path 101. The relay device (j, 1) 10 relays the monitoring signal to the subsequent transmission line.

  The receiving device 2 receives the monitoring signal from the transmission path 101 and detects failure occurrence information from the repeater (j−1, 1) 10. Then, the signal from the transmission line 101 in which the failure has occurred is switched to the signal of the predetermined backup transmission line 10k and received. Thus, the receiving device 2 ensures the operation of the optical transmission system.

  FIG. 10 is a block diagram illustrating a configuration example of a receiving apparatus. With reference to FIG. 10, the configuration of the receiving apparatus will be described.

  The receiving device 2 includes a high-speed signal detection receiving unit (1) 21 that processes a signal from the transmission path 101 and a decoding unit (1) 22. The receiving device 2 also includes a high-speed signal detection receiving unit (k) 21 that processes a signal from the transmission path 10 k and a decoding unit (k) 22. The receiving device 2 includes a switch 23 that switches a main signal from each composite unit.

  The high-speed signal detection receiver (1) 21 receives an input signal from the relay device (j, 1) 10 in the transmission path 101. The decoding unit (1) 22 decodes the main signal and the switching signal from the signal received by the high-speed signal detection receiving unit (1) 21.

  The high-speed signal detection receiver (k) 21 receives an input signal from the relay device (j, k) 10 in the transmission path 10k. The decoding unit (k) 22 decodes the main signal and the switching signal from the signal received by the high-speed signal detection receiving unit (k) 21.

  The switch 23 selectively switches the main signal from the decoding unit (1) 22 to the decoding unit (k) 22 by a switching signal from the decoding unit (1) 22 to the decoding unit (k) 22 and outputs the signal.

  Switching when the failure shown in FIG. 9 occurs will be described. The failure information of the transmission path 101 is output from the relay device (j, 1) 10, received by the high-speed signal detection receiving unit (1) 21, and decoded by the decoding unit (1) 22. The decoding unit (1) 22 detects the occurrence of a failure from the failure information and outputs a switching signal. This switching signal indicates the occurrence of a failure in the transmission path 101.

  Upon receiving this switching signal, the switch 23 switches the main signal from the decoding unit (1) corresponding to the transmission line 101 to the main signal from the decoding unit (k) corresponding to the predetermined backup transmission line 10k. Output. At this time, the switch 23 confirms that no failure has occurred in the transmission line 10k by the switching signal of the spare transmission line 10k. As a result, the receiving apparatus 2 switches the main signal from the transmission line 101 in which the failure has occurred to the spare transmission line 10k to ensure the operation of the transmission system.

Japanese Patent Laid-Open No. 2001-223616 (5th page, FIGS. 1 and 2) Japanese Patent Application Laid-Open No. 07-038506 (3rd and 4th pages, FIG. 1)

  The technologies of Patent Document 1, Patent Document 2 and the exemplified optical transmission system monitor the signal light level and detect that a failure has occurred by falling below a predetermined level. Transmission paths relayed in multiple stages by a plurality of relay apparatuses are accumulated as the optical noise goes to the subsequent stage. Therefore, it is difficult for the receiving apparatus to detect a decrease in the level of the signal light due to the influence of the accumulation of optical noise.

  Therefore, in these techniques, there is a problem that the receiving apparatus cannot detect a decrease in the signal light level due to accumulation of optical noise.

  Further, in the relay apparatus according to Patent Document 2 and the exemplified optical transmission system technology, a decrease in the signal light level is detected, and an alarm signal that reports the occurrence of a failure is output. In this technique, it is necessary to provide a receiving device with a function of receiving the alarm signal. For this reason, in a receiving device for multiplexed optical transmission lines, it is necessary to provide a function for receiving a corresponding alarm signal by the number of transmission lines. Therefore, in the receiving device of this technique, the influence due to the accumulation of optical noise described above is reduced, but it is necessary to provide the function of receiving the alarm signal for the number of transmission lines, so the receiving device becomes complicated, There is a problem that power consumption also increases.

  The techniques of Patent Document 1 and Patent Document 2 relate to an optical transmission system. However, regarding the transmission of electrical signals, the accumulation of noise, the complexity of a receiving device using a transmission path for receiving an alarm signal, and power consumption The increase is a common problem.

  An object of the present invention is made in view of the above problems, and reduces the influence of noise accumulation in switching the transmission path of a transmission system when a failure occurs, simplifies a receiving apparatus, and reduces power consumption. It is in.

  The transmission system according to the present invention includes a failure detection unit that detects occurrence of a failure in the first transmission line, a wavelength conversion unit that converts a wavelength of a signal to be relayed when the failure occurrence is detected, a relay device, And a receiving device including transmission path switching means for switching from the first transmission path to the second transmission path when wavelength conversion is detected.

  The relay device according to the present invention includes a failure detection means for detecting the occurrence of a failure in a transmission line, the wavelength of a signal to be relayed when the occurrence of the failure is detected, and the conversion of the wavelength of the signal when the conversion of the wavelength of the signal is detected. Wavelength converting means for outputting to a device for switching from one transmission path to a second transmission path.

  The receiving apparatus of the present invention converts the wavelength when a failure is detected, inputs a signal input from the first transmission path, and detects the wavelength conversion of the signal when the first transmission is detected. A transmission path switching means for switching from the path to the second transmission path is provided.

  The transmission path switching method according to the present invention converts the wavelength of the signal to be relayed when detecting the occurrence of a failure in the first transmission path, and detects the wavelength conversion from the first transmission path to the second transmission path. It is characterized by switching to.

  ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to reduce the influence of the accumulation of the noise in the switching of the transmission line of a transmission system, to simplify a receiver, and to reduce power consumption.

1 is a system diagram showing a configuration example of an optical transmission system according to a first embodiment of the present invention. It is the block diagram which showed the example of a structure of the receiver of the 1st Embodiment of this invention. It is the block diagram which showed the example of a structure of the optical transmission system provided only with an essential structure of the 1st Embodiment of this invention. It is the block diagram which showed the example of a structure of the relay apparatus provided only with an essential structure of the 1st Embodiment of this invention. It is the block diagram which showed the example of a structure of the receiver provided with only the essential structure of the 1st Embodiment of this invention. It is the system figure which showed the structural example of the optical transmission system of the 2nd Embodiment of this invention. It is the block diagram which showed the structural example of the receiver of the 2nd Embodiment of this invention. It is an image figure which shows the example of conversion to the wavelength for fault notification of this invention. 1 is a system diagram illustrating a configuration example of an optical transmission system. It is the block diagram which showed the structural example of the receiver.

Embodiments of the present invention will be described below in detail with reference to the drawings.
(First embodiment)
A first embodiment of the present invention will be described. FIG. 1 is a system diagram showing a configuration example of an optical transmission system according to a first embodiment of the present invention. FIG. 2 is a block diagram showing a configuration example of the receiving apparatus according to the first embodiment of the present invention.

  With reference to FIG. 1, the configuration of the optical transmission system according to the first embodiment of the present invention will be described. The optical transmission system described with reference to FIG. 7 has the same configuration except that the relay device 11 and the receiving device 3 are different. The same configuration is given the same name and the same number, and the description is omitted.

  In the optical transmission system of FIG. 1, the receiving apparatus 3 and the relay apparatus 11 at the final stage of each transmission path 101 to 10k are apparatuses according to the present invention.

  With reference to FIG. 1, switching of a transmission line when a failure occurs immediately before the relay device (j−1, 1) 10 on the transmission line 101 will be described. The relay device (j-1, 1) 10 monitors the signal light level from the transmission path 101 and detects the occurrence of a failure. The relay device (j-1, 1) 10 determines that a failure has occurred when the signal light level falls below a predetermined level. The relay device (j-1, 1) 10 monitors the failure occurrence information included in the monitoring signal of the relay device (j-2, 1) 10 from the relay device (1, 1) 10 located in the preceding stage. Detects the occurrence of a failure. Then, the relay device (j-1, 1) 10 detects the occurrence of the failure, includes the failure occurrence information in the monitoring signal, and transmits it to the subsequent transmission path 101.

  The relay device (j, 1) 11 located at the final stage is a relay device according to the present invention. The relay device (j, 1) 11 detects failure occurrence by monitoring failure occurrence information of the monitoring signal. Then, the signal to be relayed is converted into a failure notification wavelength and transmitted to the subsequent transmission line. The relay device (j, 1) 11 monitors the signal light level from the transmission path 101. The relay device (j, 1) 11 detects that a failure has occurred when the signal light level falls below a predetermined level. Also in this case, the relay device (j, 1) 11 converts the signal to be relayed into a failure notification wavelength and transmits it to the subsequent transmission path.

  The receiving device 3 receives a signal from the transmission path 101 and monitors whether or not it is converted to a failure notification wavelength. The receiving device 3 detects that a signal relayed from the relay device (j, 1) 11 has been converted to a failure notification wavelength and determines that a failure has occurred in the transmission path 101. Then, the receiving apparatus 3 receives the signal from the transmission line 101 by switching to the signal of the predetermined backup transmission line 10k. As a result, the receiving device 3 can switch from the transmission path 101 in which the failure has occurred to the spare transmission path 10k to ensure the operation of the transmission system.

  FIG. 2 is a block diagram showing a configuration example of the receiving apparatus according to the first embodiment of the present invention. With reference to FIG. 2, the structure of the receiver 3 of 1st Embodiment is demonstrated.

  2 receives and processes a signal from the transmission path 101, the optical input drop detection unit (1) 24, the coupler (1) 25, and a filter for fault wavelengths. (1) 26 and detector (1) 27 are provided. In addition, the receiving device 3 receives and processes the signal from the transmission line 10k, so that the optical input drop detection unit (k) 24, the coupler (k) 25, the fault wavelength filter (k) 26, and the detection A device (k) 27 is provided. The reception device 3 includes a switch 23, a high-speed signal detection reception unit 21, and a decoding unit 22.

  The optical input drop detection unit (1) 24 receives an input signal from the relay device (j, 1) 11 on the transmission path 101. Then, the data is relayed to the subsequent coupler (1) 25. Further, the optical input decrease detection unit (1) 24 detects a decrease in the level of the received input signal. The coupler (1) 25 branches the received input signal to the downstream switch 23 and the failure wavelength filter (1) 26. The fault wavelength filter (1) 26 separates the signal converted into the fault notification wavelength from the input signal branched by the coupler (1) 25. The detector (1) 27 detects the signal level of the wavelength for fault notification separated by the filter (1) 26 for fault wavelength in the previous stage. Each unit that receives and processes a signal from the transmission line 10k is the same as each unit that processes a signal on the transmission line 101, and the description is omitted by adding the same name and the same number.

  The switch 23 switches the main signal from the coupler (1) 25 corresponding to the transmission path 101 to the main signal of the coupler (k) 25 corresponding to the transmission path 10k in accordance with a predetermined switching signal and outputs it. The high-speed signal detection receiving unit 21 receives an input signal from the switch 23. The decoding unit 22 decodes the signal from the high-speed signal detection receiving unit 21.

  With reference to FIG. 2, switching of transmission lines when a failure occurs immediately before the relay device (j−1, 1) 10 in the transmission line 101 shown in FIG. 1 will be described. The relay device (j-1, 1) 10 monitors the signal light level from the transmission path 101 and detects the occurrence of a failure. The relay device (j-1, 1) 10 determines that a failure has occurred when the signal light level falls below a predetermined level. Then, the relay device (j-1, 1) 10 detects the occurrence of the failure, includes the failure occurrence information in the monitoring signal, and transmits it to the subsequent transmission path 101.

  The relay device (j, 1) 11 located at the final stage monitors the failure occurrence information of the monitoring signal and detects the failure occurrence. Then, the signal to be relayed is converted into a failure notification wavelength and transmitted to the subsequent transmission line.

  The optical input decrease detection unit (1) 24 of the receiving device 3 receives the input signal from the relay device (j, 1) 11 and relays it to the subsequent coupler (1) 25. The coupler (1) 25 branches the received input signal to the downstream switch 23 and the failure wavelength filter (1) 26. The fault wavelength filter (1) 26 separates the signal converted into the fault notification wavelength from the signal branched by the coupler (1) 25.

  The detector (1) 27 monitors the signal level of the failure notification wavelength separated by the previous failure wavelength filter (1) 26. When the signal level exceeds a predetermined level, the detector (1) 27 determines that a failure has occurred in the transmission path 101 and outputs the switching signal A-1 to the switch 23.

  The switch 23 receives the switching signal A-1 from the detector (1) 27 and corresponds the main signal from the coupler (1) 25 corresponding to the transmission path 101 to the predetermined spare transmission path 10k. The main signal from the coupler (k) 25 is switched to. At this time, the switch 23 confirms that no failure has occurred in the transmission line 10k by the switching signals Ak and Bk of the spare transmission line 10k. Then, the switch 23 outputs the switched signal to the subsequent high-speed signal detection receiver 21. As a result, the receiving device 3 can ensure the operation of the transmission system by switching from the transmission line 101 in which the failure has occurred to the spare transmission line 10k.

  The occurrence of a failure in the transmission line 101 in the section between the last-stage relay device (j, 1) 11 and the receiving device 3 is detected by the optical input drop detection unit (1) 24. That is, the optical input decrease detection unit (1) 24 detects that a failure has occurred when the level of the input signal from the transmission path 101 is below a predetermined level. Then, the switching signal B-1 is output to the switch 23.

  Accordingly, the switch 23 that has received the switching signal B-1 of the light input drop detection unit (1) 24 receives the switching signal A-1 of the detector (1) 27 described above, and similarly to the transmission line 101. The main signal from the coupler (1) 25 corresponding to is switched to the main signal from the coupler (k) 25 corresponding to a predetermined backup transmission line 10k. At this time, the switch 23 confirms that no failure has occurred in the transmission line 10k by the switching signals Ak and Bk of the spare transmission line 10k. Then, the switch 23 outputs the switched signal to the subsequent high-speed signal detection receiver 21. As a result, the receiving apparatus 3 switches the transmission path 101 in which a failure has occurred in the section between the relay apparatus (j, k) 11 and the receiving apparatus 3 to the backup transmission path 10k to ensure the operation of the transmission system. Can do.

  As described above, in the embodiment of the present invention, the occurrence of a failure in the transmission path 101 in the section from the transmission device 1 to the relay device (j, 1) 11 provided in the final stage, the relay device (j, 1) 11 The signal to be relayed is converted to a failure notification wavelength and output. Then, the receiving device 3 detects that the wavelength has been converted to the failure occurrence notification wavelength, determines that a failure has occurred in the transmission path 101, and switches to a predetermined backup transmission path 10k. . In the embodiment of the present invention, the occurrence of a failure in the transmission path 101 in the section between the relay device (j, 1) 11 provided in the final stage and the receiving device 3 is detected by a decrease in the signal level of the input signal of the receiving device 3. Then, the receiving device 3 performs the same transmission path switching.

  As described above, in the present embodiment, it is possible to detect the occurrence of a failure, switch the transmission path, and ensure the operation of the optical transmission system. In the present embodiment, the receiving device 3 can identify the location of the failure from the output source of the switching signal. That is, for example, the switching of the transmission path by the switching signal A-1 indicates the occurrence of a failure in the section from the transmission apparatus 1 to the relay apparatus (j, 1) on the transmission path 101. The switching of the transmission path by the switching signal B-1 indicates the occurrence of a failure in the section from the relay apparatus (j, 1) to the receiving apparatus 3 on the transmission path 101. Further, the units (high-speed signal detection receiving unit 21 and decoding unit 22) required for the number of transmission paths in the receiving apparatus 2 shown in FIG. 10 can be reduced as in the receiving apparatus 3 shown in FIG. This simplifies the configuration of the receiving apparatus and can reduce power consumption. Furthermore, this embodiment notifies that a failure has occurred by converting a signal relayed by the repeater into a failure notification wavelength. This method can reduce the accumulation of optical noise by setting the wavelength for failure notification to a wavelength range that is not affected by the optical noise of the optical amplifier.

  In the embodiment of the present invention, the signal to be wavelength-converted may be a main signal, a monitoring signal, or both signals. In other words, the meaning, use, etc. of the signal are not limited as long as the signal to be subjected to wavelength conversion is a signal that can be detected by performing wavelength conversion on a predetermined failure notification wavelength.

  In the embodiment of the present invention, the relay device 11 has been described as being placed immediately before the receiving device 3, but the positional relationship between the relay device 10 and the relay device 11 is arbitrary. It is preferable that the relay device 11 is placed immediately in front of the receiving device 3 from the standpoint that it is possible to deal with a failure at any point on the transmission path.

  FIG. 3 is a block diagram showing a configuration example of an optical transmission system having only a configuration essential to the present invention. 4 and 5 are block diagrams of a relay device and a receiving device each having only a configuration essential to the present invention.

  The optical transmission system of FIG. 3 includes transmission paths 101 and 102, the relay apparatus 11 and the receiving apparatus 3 of the present invention. The operation of the optical transmission system will be described with reference to FIG.

  The relay apparatus 11 receives an optical signal from the transmission side of the transmission path 101 and transmits it to the subsequent transmission path 101. The relay apparatus 11 includes a failure detection unit 11-1 and a failure wavelength conversion unit 11-2. The failure detection unit 11-1 monitors the received signal and detects the occurrence of a failure in the transmission path 101. When detecting the occurrence of a failure, the failure detection unit 11-1 outputs a failure detection signal. The obstacle wavelength converting unit 11-2 transmits the received signal to the transmission path 101 at the subsequent stage. In response to the input of the failure detection signal from the failure detection unit 11-1, the failure wavelength conversion unit 11-2 converts the received signal into a predetermined failure notification wavelength and transmits the converted signal to the subsequent transmission path 101.

  The receiving device 3 is connected to the transmission lines 101 and 102.

  The receiving device 3 includes transmission path switching means 3-1. The transmission line switching means 3-1 monitors the signals received from the transmission lines 101 and 102, and detects the presence or absence of conversion to the fault wavelength. When the signal received from the transmission line 101 is detected to be converted into a failure wavelength, the transmission line switching unit 3-1 determines that a failure has occurred in the transmission line 101. Then, the transmission line switching means 3-1 switches from the transmission line 101 in which the failure has occurred to a predetermined backup transmission line 102.

In this way, the receiving apparatus 3 can ensure the operation of the transmission system by switching the transmission path from the faulty transmission path 101 to the spare transmission path 102.
(Second Embodiment)
Next, a second embodiment of the present invention will be described. FIG. 6 is a system diagram showing a configuration example of the optical transmission system according to the second embodiment of the present invention. FIG. 7 is a block diagram showing a configuration example of a receiving apparatus according to the second embodiment of the present invention.

  The configuration of the optical transmission system according to the second embodiment of this invention will be described with reference to FIG. The optical transmission system of FIG. 6 is different from the relay device (j, 1) 12 in the final stage of each transmission path except for the difference of the relay device (j, k) 12 and the receiving device 4 from the optical transmission system of FIG. It has the same configuration as the system. The same configuration is given the same name and the same number, and the description is omitted. The receiving device 4 and the relay device 12 are devices according to the present invention.

  With reference to FIG. 6, the switching of the transmission line when a failure occurs immediately before the relay device (j-1, 1) 10 on the transmission line 101 will be described. The relay device (j-1, 1) 10 monitors the signal light level from the transmission path 101 and detects the occurrence of a failure. The relay device (j-1, 1) 10 determines that a failure has occurred when the signal light level falls below a predetermined level. The relay device (j-1, 1) 10 monitors the failure occurrence information included in the monitoring signal of the relay device (j-2, 1) 10 from the relay device (1, 1) 10 located in the preceding stage. Detects the occurrence of a failure. Then, the relay device (j-1, 1) 10 detects the occurrence of the failure, includes the failure occurrence information in the monitoring signal, and transmits it to the subsequent transmission path 101.

The relay device (j, 1) 12 located at the final stage is a relay device according to the present invention. The relay device (j, 1) 12 monitors the failure occurrence information of the monitoring signal and detects the failure occurrence. The relay device (j, 1) 12 monitors the signal light level from the transmission path 101. When the signal light level falls below a predetermined level, it is detected that a failure has occurred.
The relay device (j, 1) 12 detects that a failure has occurred, and stops relay transmission to the subsequent stage of the signal received from the transmission path 101.

  The receiving device 4 is a receiving device according to the present invention. The receiving device 4 monitors the signal level from the transmission path 101 and detects the occurrence of a failure. That is, it detects that the relay signal from the relay device (j, 1) 12 is lower than a predetermined signal level, and switches the signal from the transmission line 101 to a signal of the predetermined transmission line 10k. Receive. As a result, the receiving apparatus 4 can switch from the transmission path 101 where the failure has occurred to the spare transmission path 10k to ensure the operation of the transmission system.

  FIG. 7 is a block diagram showing a configuration example of a receiving apparatus according to the second embodiment of the present invention. With reference to FIG. 7, the structure of the receiver 4 of this embodiment is demonstrated.

  The receiving device 4 according to the present embodiment includes only the optical input decrease detection unit (1) 24 that receives a signal from the transmission line 101, and receives the signal from the transmission line 10k, as compared with the receiving device 3 illustrated in FIG. The difference is that only the received light input drop detection unit (k) 24 is provided. The same configuration is given the same name and the same number, and the description is omitted.

  With reference to FIG. 7, a description will be given of switching of transmission lines when a failure occurs immediately before the relay device (j-1, 1) 10 on the transmission line 101 shown in FIG. The relay device (j-1, 1) 10 monitors the signal light level from the transmission path 101 and detects the occurrence of a failure. The relay device (j-1, 1) 10 determines that a failure has occurred when the signal light level falls below a predetermined level. Then, the relay device (j-1, 1) 10 detects the occurrence of the failure, includes the failure occurrence information in the monitoring signal, and transmits it to the subsequent transmission path 101. The relay device (j, 1) 12 at the final stage monitors the failure occurrence information of the monitoring signal and detects the failure occurrence. The relay device (j, 1) 12 monitors the signal light level from the transmission path 101. When the signal light level falls below a predetermined level, it is detected that a failure has occurred. The relay device (j, 1) 12 detects that a failure has occurred, and stops relay transmission to the subsequent stage of the signal received from the transmission path 101.

  The optical input decrease detection unit (1) 24 of the reception device 4 receives an input signal from the relay device (j, 1) 12 of the transmission path 101. Then, it relays to the coupler (1) 23 at the subsequent stage. Further, the optical input decrease detection unit (1) 24 detects a decrease in the level of the received input signal. That is, the optical input decrease detection unit (1) 24 determines that a failure has occurred when the level of the input signal from the transmission path 101 is below a predetermined level. Then, a switching signal is output to the switch 23.

  The switch 23 receives the switching signal from the optical input drop detector (1) 24, and switches the main signal from the transmission path 101 to the predetermined main signal from the spare transmission path 10k. At this time, the switch 23 confirms that a failure has not occurred in the transmission line 10k by a switching signal of the transmission line 10k. Then, the switch 23 outputs the switched signal to the subsequent high-speed signal detection receiver 21. Thereby, the receiving device 4 can ensure the operation of the transmission system by switching the transmission line from the transmission line 101 where the failure has occurred to the spare transmission line 10k.

  As described above, in this embodiment, the relay device (j, 1) 12 has received the failure of the transmission path 101 in the section from the transmission device 1 to the relay device (j, 1) 12 provided in the final stage. The signal is transmitted to the receiving device 4 by not relaying the signal to the subsequent stage. The receiving device 4 detects a decrease in the input signal level and switches from the transmission path 101 to a predetermined backup transmission path. In the present embodiment, the reception device 4 detects a decrease in the input signal level even when a failure occurs in the transmission path 101 between the relay device (j, 1) 12 and the reception device 4 provided in the final stage. The transmission line 101 is switched to a predetermined spare transmission line 10k.

  Therefore, in the present embodiment, it is possible to detect the occurrence of a failure, switch the transmission path, and ensure the operation of the optical transmission system. In this embodiment, each part (coupler 25, fault wavelength filter 26, and detection unit 27) required for the number of transmission paths in the receiving apparatus 3 shown in FIG. 2 can be reduced as shown in FIG. In addition, the configuration of the receiving apparatus can be further simplified and the power consumption can be reduced. Further, when a failure is detected in the relay device (j, 1) 12, since the signal is not relayed, the receiving device 4 has an effect of reducing the influence due to the accumulation of optical noise.

  Note that the present invention is not limited to the above-described embodiments, and various modifications and changes can be made without departing from the spirit of the present invention.

  For example, the embodiment of the present invention has been described as including a plurality of optical transmission lines, but the number of transmission lines is not limited. That is, as long as it is an optical transmission line, a single optical fiber may be used, or a plurality of optical fibers may be used. That is, any system having a protection function may be used as the optical transmission system.

  In the embodiment of the present invention, the optical transmission system has been described as having a plurality of relay devices on the transmission line, but only the relay device according to the present invention may be provided on the transmission line.

  Furthermore, in the present invention, the type of signal to be transmitted is not limited. The present invention can be applied not only to the optical signal transmission system shown in the embodiment of the present invention but also to an electrical signal transmission system.

  In an electrical signal transmission system, a system in which a carrier wave is modulated by information to be transmitted may be used. When the present invention is applied to such a transmission system, the frequency of a carrier wave that carries information may be converted to a predetermined failure notification frequency by detecting a failure in the transmission path. For example, the frequency of the carrier wave may be converted into a guard band band provided in a transmission channel for transmitting information using the carrier wave.

  In an electric signal transmission system that does not use a carrier wave, a signal having a part of the frequency may be converted into a predetermined failure notification frequency within the transmission band. Alternatively, a frequency signal for failure notification may be generated. FIG. 8 illustrates an example of a conversion image to a failure notification frequency in an electric signal transmission system that does not use a carrier wave. As described above, the present invention can be applied not only to an optical transmission system but also to an electrical signal transmission system.

DESCRIPTION OF SYMBOLS 1 Transmission apparatus 2, 3, 4 Reception apparatus 3-1 Transmission path switching means 10, 11, 12 Relay apparatus 11-1 Failure detection means 11-2 Failure wavelength conversion means 21 High-speed signal detection reception part 22 Composite part 23 Switch 24 Light Input drop detection unit 25 Coupler 26 Filter for obstacle wavelength 27 Detection unit 101, 102, 10k Transmission path

Claims (8)

Failure detection means for detecting occurrence of a failure in the first transmission path;
When the occurrence of the failure is detected, a relay device comprising wavelength conversion means for converting the wavelength of the signal to be relayed;
A receiving device comprising transmission path switching means for switching from the first transmission path to the second transmission path when the conversion of the wavelength of the signal is detected;
A transmission system characterized by including: The wavelength conversion unit performs the conversion so that at least a part of the wavelength of the converted signal is included in a predetermined wavelength range. The transmission path switching unit includes at least a part of the signal in the predetermined wavelength range. The transmission system according to claim 1, wherein the detection is performed by detecting that the transmission is detected. The failure detection means includes
Means for detecting that the signal level from the first transmission line is below a predetermined level;
Or
Means for detecting failure information transmitted by a relay device located in the previous stage in the first transmission path;
The transmission system according to claim 1, further comprising: The transmission line switching means switches to the second transmission line when detecting that the signal level from the first transmission line is below a predetermined level. The transmission system according to any one of claims. A failure detection means for detecting a failure in the transmission line;
Wavelength conversion means for converting the wavelength of a signal to be relayed when the occurrence of the failure is detected, and for outputting to the device for switching from the first transmission path to the second transmission path when the conversion of the wavelength of the signal is detected; A relay device comprising: When the occurrence of a fault is detected, the wavelength is converted, the signal input from the first transmission path is input, and when the conversion of the wavelength of the signal is detected, the first transmission path to the second transmission path Transmission line switching means for switching to
A receiving apparatus comprising: The transmission path switching means switches to the second transmission path when detecting that the signal level from the first transmission path is below a predetermined level;
The receiving device according to claim 6, further comprising: When the failure of the first transmission path is detected, the wavelength of the signal to be relayed is converted,
A transmission line switching method characterized by switching from the first transmission line to the second transmission line when the wavelength conversion is detected.

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