JP2012129695A - Optical wavelength multiplexed transmission device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a protection function for a wavelength multiplexed transmission device which divides high-speed signals into low-speed signals before transmitting them, which, even when an operational and a non-operational system have different paths, can suppress occurrence of a problem that client signals cannot each be multiplexed from low-speed to high-speed signals normally.SOLUTION: An optical wavelength multiplexed transmission device of the present invention works in such a way that each signal separated by wavelength from the respective WDM signals of one and the same signal per client which has been transmitted along a plurality of different paths are selectively received per client signal and then time-division multiplexed, in which case, if a fault occurs in one of signals separated by wavelength from the WDM signals, signals separated by wavelength from a WDM signal which has been transmitted along a different path than the wavelength-separated signal in error are received per client signal and then time-division multiplexed.

Description

  The present invention relates to an optical wavelength division multiplexing apparatus having a protection function.

  A wavelength division multiplexing transmission system using an optical fiber is mainly used for the backbone network of the current communication system. A wavelength division multiplexing (WDM) optical transmission system that multiplexes a plurality of optical signals having different wavelengths in a single optical fiber is an extremely effective technique for increasing the capacity of optical fiber communication.

  This type of system may have a redundant configuration with an active system and a standby system in an optical transmission line, and may perform redundant switching in the event of a failure to avoid large-scale communication interruptions. This operation is called a protection operation. The protection method includes a 1 + 1 protection method.

  In the 1 + 1 protection method, a working transmission line (active side) and a backup transmission line (non-operating side) are generally provided as a pair, the same signal is transmitted on the transmitting side to the active side and the standby side, and either one of the two inputs is received on the receiving side. It is a technology to select.

  FIG. 2 shows a configuration as an example of a protection scheme in a wavelength division multiplexing transmission apparatus that is a related technique. In FIG. 2, when a failure is detected by the optical wavelength conversion units B16 and C16, the optical wavelength conversion unit B16 and the optical wavelength conversion unit C16 are switched for each wavelength where the failure has occurred. For example, when there is a failure in the WDM section D11, the failure often occurs in all the optically multiplexed wavelengths. For this reason, the optical wavelength converter B16 detects faults at all wavelengths (λa, λb, λn).

  Accordingly, signals of all wavelengths are switched from the optical wavelength converter B16 side to the optical wavelength converter C16 side between the optical wavelength converter B16 and the optical wavelength converter C16. In such a case, since the failure occurring in the WDM section D11 is also detected by the optical wavelength demultiplexing unit B15, the optical output is performed by the optical signal conversion multiplexing unit B17 corresponding to the optical wavelength demultiplexing unit B15. To stop. On the other hand, the output of the optical signal conversion multiplexing unit C17 that was on the non-operation side is started to be output by protection switching control. In this way, the client signal input by the wavelength division multiplex transmission apparatus 1 E1 is switched to the output on the WDM section C14 side via the path 2 where no failure has occurred. Since all wavelengths are switched, problems such as time delay that may occur when trying to multiplex signals with different paths do not occur.

  On the other hand, when a failure occurs at the output D12 of the optical wavelength demultiplexing unit B15 in the wavelength division multiplex transmission device 2E2, only the optical wavelength conversion unit B16 to which a signal having a wavelength of λa is detected detects the failure. In this case, only the optical wavelength converter B16 corresponding to λa is switched to the non-operation side optical wavelength converter C16. Accordingly, only a part (λa) of the inputs of the optical signal conversion multiplexing unit B17 is switched to the signal via the path 2 by moving to the optical wavelength conversion unit C16 side. However, other signals (λb, etc.) remain selected from the signal via route 1, and the transmission time of route 1 and route 2 when the signal is multiplexed from the low speed signal to the high speed signal in the optical signal conversion multiplexer B17. There is a risk that a normal high-speed signal cannot be generated due to a difference or the like.

  As a related technique, Patent Document 1 discloses a technique that can realize a quick and reliable protection method in a wavelength division multiplexing transmission line. This is a 1 + 1 protection method in a wavelength division multiplexing transmission line, and a failure detection means is provided for each wavelength. In the receiving side node, when the failure detecting means detects a failure in a signal having a wavelength on one working transmission line, the signal on all wavelengths sharing the working transmission line is transferred to the backup transmission path, thereby moving to the backup transmission path. Can complete the switch. Even when a failure occurs in a signal of one wavelength, it is said that a quick protection operation can be realized because signals of all wavelengths are transferred to a backup transmission line.

JP-A-8-125636

  As described above, the protection in the wavelength division multiplexing transmission apparatus, which is the related technology described above, has been realized by detecting a failure in the optical wavelength converters B16 and C16 and switching the signal from the active system to the non-operating system. . In the case of a system in which a high-speed signal is separated into low-speed signals by time division and then wavelength-division-multiplexed, only a part of the low-speed signals (for example, λa in FIG. 2) is switched. Therefore, when the transmission times of the path 1 (B14) and the path 2 (C14) are different, a time difference occurs in the multiplexed signals, and the optical signal conversion multiplexing unit B17 (or C17) cannot normally multiplex from the low speed signal to the high speed signal. There was a problem.

  Further, in the invention of Patent Document 1, it is said that even when a failure occurs in a signal of one wavelength, the signals of all wavelengths are moved to the backup transmission path. May contain client signals. For example, it is assumed that there is a failure in the signal of λa when there are eight wavelengths of λa, λb, λc, λd, λw, λx, λy, and λz. In this case, if λa, λb, λc, λd and λw, λx, λy, λz are different clients (A11 input high-speed serial signal in FIG. 2), λw, λx, Switching to signals of λy and λz will occur. In this case, signals that do not need to be switched are switched, and there is a possibility that unexpected troubles may occur even in the client signals that used λw, λx, λy, and λz that did not cause a failure. Absent.

  The object of the present invention has the following objects in order to solve the above problems. That is, it is an object of the present invention to provide a protection function that can normally multiplex from a low-speed signal to a high-speed signal for each client signal even when the active and non-operating paths are different.

The optical wavelength division multiplexing transmission receiving apparatus of the present invention,
Normally, the same signal for each client is wavelength-separated from each WDM signal transmitted from each of the WDM signals transmitted through a plurality of different paths, and is received and time-division multiplexed for each client signal. When a failure occurs in any one of the signals that are more wavelength-separated, a signal that is wavelength-separated from a WDM signal that is transmitted through a path different from the wavelength-separated signal that causes the failure is a signal of the client. Receive every time and time division multiplex.

The protection method of the optical multiplex transmission receiver of the present invention is as follows:
Normally, the same signal for each client is wavelength-separated from each WDM signal transmitted from each of the WDM signals transmitted through a plurality of different paths, and is received and time-division multiplexed for each client signal. When a failure occurs in any one of the signals that are more wavelength-separated, a signal that is wavelength-separated from the WDM signal that is transmitted through a path different from the wavelength-separated signal that causes the failure is And time division multiplexed.

  As described above, in the present invention, the following effects can be obtained by the above-described configuration. In other words, even when the operating system and non-operating system paths are different, it is possible to provide a protection function that can normally multiplex from a low-speed signal to a high-speed signal for each client signal.

It is a figure explaining 1st Embodiment. It is a figure explaining the protection system of a related technique. It is a figure explaining the other modification. It is a figure explaining 2nd Embodiment.

(First embodiment)
Next, the present embodiment will be described in detail with reference to the drawings. Here, assuming that there are two high-speed serial signals, the “own client” and another client different from the own client will be distinguished as “other clients”. If the transmission rate of the high-speed serial signal of the client is R and the transmission rate of the low-speed signal is R / n, R and the number of divisions n are arbitrary, but in this embodiment, n = 4. If R = 40 Gbps, the low-speed signal transmission rate is 10 Gbps.

  FIG. 1 is an explanatory diagram of the configuration of the first embodiment of the present invention. A1 and A2 are couplers for the own client, and B1 and C1 are optical signal conversion / separation units for the own client. B2 and C2 are optical wavelength converters for own client (n = 4: 4 wavelengths of λa, λb, λc, and λd), B3 and C3 are optical wavelength multiplexing units that are shared by other clients, and B4 and C4 are own clients. This is a WDM section shared by other clients. A101 and A102 are couplers for other clients, B101 and C101 are optical signal conversion / separation units for other clients, B102 and C102 are optical wavelength conversion units for other clients (n = 4: 4 of λw, λx, λy, and λz) Wavelength). Further, B5 and C5 are optical wavelength demultiplexing units shared by the own client and other clients, B6 and C6 are optical wavelength conversion units for the own client, and B7 and C7 are optical signal conversion multiplexing units for the own client. Further, B106 and C106 are optical wavelength conversion units for other clients, and B107 and C107 are optical signal conversion multiplexing units for other clients. E1 is the wavelength division multiplexing transmission apparatus 1, and E2 is the wavelength division multiplexing transmission apparatus 2.

  In FIG. 1, the wavelength division multiplexing transmission apparatus 1 E1 receives a high-speed serial signal (transmission rate R) from its own client side. The high-speed signal is branched into two by the coupler A1 and sent to the optical signal conversion separation units B1 and C1. The optical signal conversion separation units B1 and C1 divide the high-speed serial signal (transmission rate R) into n = 4 low-speed signals (transmission rate R / 4), and send them to the optical wavelength conversion units B2 and C2, respectively. The processing up to this part is the processing of the own client signal.

  In addition, as a coupler of A1, A2, A101, and A102, a space type (bulk type), an optical fiber type coupler, etc. are used. The optical signal conversion / separation unit of B1, C1, B101, and C101 once converts the high-speed serial signal of the client, which is an optical signal, into an electrical signal, and then performs time-division separation with a switch to convert it into a plurality of low-speed signals. The signal is converted again. Also, the optical wavelength converters B2, C2, B102, and C102 once convert a plurality of low-speed optical signals into electrical signals, then convert each of the plurality of low-speed signals into optical signals having different wavelengths and output them. is doing. An arrayed waveguide grating type optical multiplexer or the like is used as the optical wavelength multiplexing unit for B3 and C3. An arrayed waveguide grating type optical demultiplexer or the like can also be used as the B5 and C5 optical wavelength separation unit. The B7, C7, B107, and C107 optical signal conversion multiplexing units once convert a plurality of low-speed signals, which are optical signals, into electrical signals, and then perform time-division multiplexing with a switch to convert them into client high-speed serial signals. The signal is converted again. Further, the optical signal conversion multiplexing units B7, C7, B107, and C107 detect the failure of the input signal independently for each of the plurality of low-speed signals. The optical signal conversion multiplexing unit such as B7 detects a failure not only between the optical wavelength separation unit (B5 etc.) and the optical wavelength conversion unit (B6 etc.) but also the optical wavelength conversion unit (B6 etc.) to light. This is because a failure of the signal conversion multiplexing unit (B7 or the like) is also detected.

  Further, in the case where a failure is detected with only one input (for example, λa) at the input of the optical signal conversion multiplexing unit such as B7, the failure is detected from the optical wavelength demultiplexing unit (B5 etc.) to the optical signal conversion multiplexing unit ( B7 etc.), it can be estimated that a failure has occurred. On the other hand, when a failure is detected at all inputs of the optical signal conversion multiplexing unit such as B7, it may be estimated that a failure has occurred in a section in which all wavelengths are bundled, that is, a WDM section (B4, etc.). I can do it.

  As a failure detection method, for example, encoding is performed in advance so that a certain number of zeros do not continue in the original signal, and if a certain number of consecutive zeros are detected on the receiving side, a failure occurs. Judgment can be made.

  The four divided low-speed signals are converted into signals having different wavelengths (λa, λb, λc, λd) by the optical wavelength converters B2 and C2. The converted signals are wavelength multiplexed in the optical wavelength multiplexing units B3 and C3, and transmitted to the wavelength multiplexing transmission device 2E2 via the WDM sections B4 and C4.

  The signal transmitted through the WDM section is received by the optical wavelength demultiplexing units B5 and C5 in the wavelength division multiplexing transmission device 2E2, and is separated for each wavelength (λa, λb, λc, λd), and the optical wavelength converting unit B6 and Transmitted to C6. The processing up to this part is the WDM signal.

  The signals transmitted to the optical wavelength conversion units B6 and C6 are further converted into a plurality of low-speed signals (transmission rate R / 4) having the same wavelength by the optical wavelength conversion units B6 and C6, respectively, and the optical signal conversion multiplexing unit B7 And a high-speed signal (transmission rate R) at C7. In the WDM sections B4 and C4, which are different paths, the same signal is transmitted from the own client signal. In the optical signal conversion multiplexers B7 and C7, only the operating system of the two paths is optically output, and the non-operating system Output is stopped. The operational signal is output to the client side through the coupler A2.

  The high-speed serial signal of the other client is input to the coupler A101 different from the coupler of A1 in the wavelength division multiplexing transmission apparatus 1 E1. Thereafter, in FIG. 1, the signals are input to the optical wavelength multiplexing unit B3 via the optical signal conversion / separation unit B101 and the optical wavelength conversion unit B102 for other clients, and are bundled together with the signal for the own client as a WDM signal. In the wavelength division multiplex transmission apparatus 2 E2 on the reception side, the received WDM signal is separated into different wavelengths (λw, λx, λy, λz) by the optical wavelength separation unit B5. Thereafter, the signal is converted into a plurality of signals having the same wavelength by the optical wavelength conversion unit B106 on the other client side, and input to the optical signal conversion multiplexing unit B107 different from the own client. From the optical signal conversion multiplexing unit B107, it is input to the coupler A102 for other clients, and is output from the coupler (A102) as a high-speed serial signal for other clients.

  In this embodiment, since it is 1 + 1 protection, the other client signal input to A101 is branched into an active system and a non-operating system and input to the optical signal conversion / separation unit C101. The signals branched and input to the active system and the non-operating system are the same signals up to the optical signal conversion multiplexing unit C107 of the receiving side wavelength division multiplexing transmission apparatus 2 (E2) up to the active optical signal conversion multiplexing unit B107. Is being transmitted.

Although FIG. 1 shows a configuration in one direction (A1 to A2 direction) in the wavelength division multiplexing transmission apparatus, the same applies to signals transmitted in the opposite direction (A2, A102 to A1, A101 direction).
(Description of operation)
Next, the 1 + 1 protection operation of the first embodiment will be described.

  Since it is 1 + 1 protection, the same signal is transmitted from the high-speed serial signal of the client, which is the input of the coupler A1 in FIG. 1, to the optical signal multiplexers B7 and C7 in both the operational system and the non-operational system. The operation when the optical signal conversion multiplexing unit B7 is the active system and the optical signal conversion multiplexing unit C7 is the non-operational system will be described below. The same operation is performed when the active and non-operating systems are reversed.

  As described above, the optical signal conversion multiplexing unit detects a failure in the input signal. Therefore, when a failure occurs at the wavelength λa of the output D2 of the optical wavelength demultiplexing unit B5 in the wavelength division multiplex transmission device 2E2, this failure is caused by the input of the signal λa of the optical signal conversion multiplexing unit B7 as a low-speed signal. Failure will be detected. The optical signal conversion multiplexing unit B7 confirms that no failure is detected in all wavelengths (λa, λb, λc, λd) of the client of the optical signal conversion multiplexing unit C7 that is the planned switching destination. If no failure state is detected in the optical signal conversion multiplexer C7, the output of the optical signal conversion multiplexer B7 on the operation side is stopped at this time, and an optical signal is output from the optical signal conversion multiplexer C7 on the non-operation side To be controlled. As a result, the signal of the own client is switched from the signal transmitted via the route 1 to the signal transmitted via the route 2.

  On the other hand, the operation on the other client side when a failure occurs at the wavelength λa of the output D2 of the optical wavelength demultiplexing unit B5 in the wavelength division multiplex transmission apparatus 2E2 as described above will be described. In this case, this failure is not detected at any wavelength (λw, λx, λy, λz) of the optical signal conversion multiplexer B107 which is the optical signal conversion multiplexer on the other client side. Therefore, the output from the optical signal conversion multiplexing unit C107 that is not currently operated is stopped and the optical signal is continuously output from the optical signal conversion multiplexing unit B107. In other words, the signal of the other client is not switched from the signal transmitted via the path 1 to the signal transmitted via the path 2.

  In the configuration according to the first embodiment, unlike the method of switching the passage path in the WDM section for each part (for example, λa in FIG. 2) of the low-speed signal that is the signal after the optical wavelength separation described in the related art described above, Switching control is performed with a high-speed signal after the low-speed signal is multiplexed. The signals multiplexed by the optical signal conversion multiplexing unit C7 are all signals that have been routed through the path 2 that is the same path. Therefore, even when the transmission times of the path 1 (B4) and the path 2 (C4) are different, the optical signal conversion multiplexing unit B7 (or C7) can normally multiplex from the low speed signal to the high speed signal. Even if the active and non-active paths are different, all the signals after switching are signals that have passed through the same path. Therefore, it is possible to provide a protection function that can normally multiplex a low-speed signal to a high-speed signal even if there is a time difference due to a path difference for each low-speed signal.

  In the configuration according to the first embodiment, only the wavelengths λa, λb, λc, and λd are switched even when a failure occurs in a part of the low-speed signal that is the signal after the optical wavelength separation (λa in the above description). . That is, different switching control is performed for each client signal. This is different from the method described in the related art described above in which signals of all wavelengths (λa, λb, λc, λd and λw, λx, λy, λz) transmitted in the WDM section are transferred to the backup transmission path. Therefore, signals that do not need to be switched are not switched, and the client signals that have used λw, λx, λy, and λz that have not failed are not affected. Accordingly, it is possible to provide a protection function that can normally multiplex from a low-speed signal to a high-speed signal for each client signal even when the active and non-operating paths are different.

As a modification of the present embodiment, the basic configuration is as described above, but the configuration shown in FIG. In the embodiment of FIG. 3, the output from the optical wavelength converters B26, B326, C26 and C326 as in the embodiment of FIG. 1 is configured to have an independent optical signal conversion multiplexer for each path and for each client signal. Not. That is, the outputs from the optical wavelength conversion units B26 and C26 (B326 and C326) are collected for each client signal and combined by one optical signal conversion multiplexing unit A22 and A322, respectively. In the embodiment of FIG. 3, the optical signal conversion multiplexing unit and the coupler in FIG. 1 are integrated to form an optical signal conversion multiplexing unit (A22 and A322). However, in the embodiment of FIG. 3, the operation is the same as in the case of the configuration of FIG. 1 except that the optical signal conversion multiplexing units A22 and A322 perform failure detection and output signal switching. For example, when a failure occurs at λa of D22 of the own client, the failure is detected at A22. In that case, the optical signal conversion multiplexing unit switches the output of the optical wavelength conversion unit B26 to the output of C326 for all wavelengths (λa, λb, λc, λd) of the own client. On the other hand, the signals selected in A322 are not switched for the signals (λw, λx, λy, λz) of other clients.
(Second Embodiment)
Next, a second embodiment for carrying out the present invention will be described.

  FIG. 4 shows an optical wavelength division multiplexing apparatus having a protection function according to the second embodiment of the present invention.

The optical wavelength division multiplexing transmission apparatus 401 having the protection function of the second embodiment
A signal that is wavelength-separated from each WDM signal transmitted through a plurality of different paths for the same signal for each client is selected and received for each client signal and is time-division multiplexed.

  Furthermore, the optical wavelength division multiplexing apparatus 401 having the protection function of the second embodiment performs the following operation when a failure occurs in any of the signals wavelength-separated from the WDM signal. That is, a signal that is wavelength-separated from a WDM signal transmitted through a path different from the wavelength-separated signal in which the failure has occurred is received and time-division multiplexed for each of the client signals.

  In the second embodiment described above, the above-described configuration provides a protection function that can normally multiplex from a low-speed signal to a high-speed signal for each client signal even when the active and non-active paths are different. it can.

  In each embodiment described so far, a dedicated device is assumed, but the following may be used. That is, for example, a personal computer device that performs various types of data processing is loaded with a board or card that performs processing corresponding to this example, and each processing is executed on the computer device side. In this way, a configuration may be adopted in which software for executing the processing is installed in a personal computer device and executed.

  The program installed in the data processing device such as the personal computer device may be distributed via various recording (storage) media such as an optical disk and a memory card, or distributed via communication means such as the Internet. Also good.

A1, A2, A101, A102 Coupler B1, C1, B101, C101 Optical signal converter / separator B2, C2, B102, C102 Optical wavelength converter B3, C3 Optical wavelength multiplexer B4, C4 WDM section B5, C5 Optical wavelength separator B6, C6, B106, C106 Optical wavelength conversion unit B7, C7, B107, C107 Optical signal conversion multiplexing unit E1 Wavelength multiplexing transmission device 1
E2 Wavelength division multiplexing transmission device 2

Claims (9)

Normally, the same signal for each client is wavelength-separated from each WDM signal transmitted from a plurality of different paths and selected for each client signal and received and time division multiplexed.
When a failure occurs in any of the signals wavelength-separated from the WDM signal, the wavelength-separated signal from the WDM signal transmitted through a path different from the wavelength-separated signal in which the failure has occurred Receive for each client signal and time division multiplex,
An optical wavelength division multiplex transmission receiver. A plurality of optical wavelength demultiplexing units for optical wavelength demultiplexing of each WDM signal transmitted through the plurality of different paths for the same signal for each client for each signal of the client;
A plurality of optical signal conversion multiplexers for time-division multiplexing the plurality of identical optical wavelength signals for each of the plurality of different paths;
Usually, a coupler that outputs the time-division multiplexed signal from any one of a plurality of optical signal conversion multiplexing units, and combines the signals output from the plurality of optical signal conversion multiplexing units;
Have
When a failure occurs in any of the plurality of optical wavelength signals output from the optical wavelength separation unit, the path through which the optical wavelength signal in which the failure has occurred passes among the plurality of optical signal conversion multiplexing units A signal is output from an optical signal conversion multiplexing unit that time-division-multiplexes the plurality of optical wavelength signals in different paths
An optical wavelength division multiplex transmission receiver having a protection function. The optical wavelength division multiplexing transmission apparatus having the protection function further includes
A plurality of optical wavelength signals output from the optical wavelength separation unit, respectively, an optical wavelength conversion unit that converts the optical wavelength signals into a plurality of identical optical wavelength signals;
The optical wavelength division multiplex transmission receiver having a protection function according to claim 2. 4. The optical wavelength division multiplexing transmission receiving apparatus having a protection function according to claim 3, wherein the optical wavelength multiplexing unit is an arrayed waveguide grating type optical multiplexer. 5. The optical wavelength division multiplex transmission receiver having a protection function according to claim 4, wherein the optical wavelength separator is an arrayed waveguide grating type optical multiplexer. 6. The optical wavelength division multiplexing transmission receiving apparatus having a protection function according to claim 5, wherein the coupler is a spatial coupler.   The optical wavelength division multiplex transmission receiver according to claim 1, wherein the protection function is a 1 + 1 protection function. An optical wavelength division multiplexing transmission transmitter that transmits the same signal for each client through a plurality of different paths;
The optical wavelength multiplexing transmission receiver according to any one of claims 1 to 7, wherein the same signal is received for each of the clients transmitted through the plurality of different paths,
An optical wavelength division multiplexing transmission system comprising: Normally, the same signal for each client is wavelength-separated from each WDM signal transmitted from a plurality of different paths and selected for each client signal and received and time division multiplexed.
When a failure occurs in any of the signals that are wavelength-separated from the WDM signal, a signal that is wavelength-separated from the WDM signal transmitted through a path different from the wavelength-separated signal in which the failure has occurred is transmitted to the client. Receive and time-division multiplex each signal
A protection method for an optical multiplex transmission apparatus.

Images