JP5271830B2 - Optical transponder and optical transmission system - Google Patents

Description

  The present invention relates to an optical transponder and an optical transmission system, and more particularly to a multi-rate optical transponder and an optical transmission system using the same.

  As an optical conversion unit of an optical transmission system, a multi-rate transponder corresponding to various interfaces has been put into practical use. The transponder that sets the transmission speed individually according to the transmission interface can be set directly on the transmission device where the transponder is installed, or a monitoring control network is built in advance for the remote transmission device, and this monitoring is performed. It is necessary to set the transmission rate for each transponder through the control network.

  Patent Document 1 proposes a method for setting a relay device and a transponder on a transmission line without using a supervisory control network. However, this method requires manual setting for one transponder or relay device. In other words, when a transmission line failure occurs, the speed must be set again when switching to a spare transmission line by a switch. Patent Document 1 proposes a method capable of setting a speed in advance for a spare transmission line. However, this method requires another interface for monitoring and control. As a result, the influence on the system cost is inevitable.

JP 2008-258701 A

  The present invention provides a highly stable network in an optical repeater optical transmission system using a multirate transponder by setting the transmission rate from the main signal without using another monitoring network. To do.

  According to the present invention, when the speed setting is performed for the transponder or the repeater, the frequency of the client signal is automatically determined, and then the control signal is transmitted to the opposite transponder or the optical repeater. The relay device can easily change the signal speed by setting the transmission speed from the received control signal. At that time, the path switching switch on the transmission path is detected, and when there is a spare transmission path that can be used, the speed is set in advance, so that the immediate path switching can be automatically performed when a failure occurs. Further, since the switching destination is recorded in the switch, automatic speed setting, spare transmission path registration, and automatic path switching when a failure occurs can be realized without the need for an interface for monitoring control.

  The above-described problem is that an optical signal having a plurality of transmission rates is accommodated, connected to the optical repeater, the transmission rate of the optical signal is acquired, and the acquired transmission rate is transmitted to the optical repeater. This can be achieved by an optical transponder that transmits a speed setting request to the optical repeater when a signal capable of corresponding to the transmission speed is received from the optical transmission apparatus connected to the apparatus.

  The optical transponder includes an optical transponder that accommodates optical signals having a plurality of transmission rates, a switch connected to the optical transponder, and a plurality of optical repeaters connected to a plurality of ports of the switch. When the transmission speed of the signal is acquired, the acquired transmission speed is transmitted to the switch, and the signal corresponding to the transmission speed is received from the optical transmission apparatus or the optical transmission apparatus connected to the optical transmission apparatus, the optical transmission apparatus This can be achieved by an optical transmission system that transmits a speed setting request to the network.

  According to the present invention, the signal rate from the client device is automatically determined by the opposing multi-rate transponder, and a special data pattern for setting the transmission rate of the transponder is transmitted to the main signal, so that transmission according to the interface to be used is performed. Speed can be set automatically. In addition, a path switching switch on the transmission path is detected, a usable transmission path is automatically assigned, and when a spare transmission path exists, speed setting is performed in advance so that an immediate path switching can be performed when a failure occurs. As a result of adopting a method of recording the switching destination in the switch, it becomes possible to make the setting simply and economically without using a control network for setting the speed separately.

It is a block diagram explaining the structure of a transponder. It is a flowchart of a process of a transponder. It is a block diagram explaining the structure of an optical repeater. It is a flowchart of a process of an optical repeater. It is a block diagram explaining the structure of a switch. It is a flowchart of the process of a switch (the 1). It is a flowchart of the process of a switch (the 2). It is a flowchart of the process of a switch (the 3). It is a block diagram of an optical transmission system of two relay devices and two transponders. It is a transmission speed change sequence diagram between two transponders via two relay devices. It is a block diagram of the optical transmission system which consists of two transponders, two switches, and four relay apparatuses. It is a transmission rate change sequence diagram between transponders via a switch. FIG. 2 is a block diagram of an optical transmission system sharing a backup transmission path (No. 1). FIG. 2 is a block diagram of an optical transmission system sharing a backup transmission path (No. 2). FIG. 3 is a block diagram of an optical transmission system sharing a backup transmission path (No. 3).

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings using examples. Note that the same reference numerals are assigned to substantially the same parts, and description thereof will not be repeated.

  In this embodiment, client devices installed at two points away from each other are connected to each other. A transponder is connected to each of the two client devices, and data transmission is performed via a plurality of relays of the optical repeater. Can be performed. Depending on system requirements, the optical repeater can be configured when not in use or by an arbitrary number of one or more.

The configuration of the transponder will be described with reference to FIG. In FIG. 1, the transponder 100 includes a signal speed determination unit 102, a speed setting control unit 101, a signal insertion unit 103, and two wavelength conversion units 104. The wavelength conversion unit 104-1 converts the wavelength of the client signal and sends it to the transmission line. The wavelength converter 104-2 converts the wavelength of the optical signal from the transmission path (O / E / O conversion) and sends it to the client. The signal speed determination unit 102 determines the signal speed of the client signal. The speed setting control unit 101 generates a line speed information to be transmitted to the relay device, a speed setting execution request, a port switching request to be transmitted to the switch, and a failure switching destination registration request signal. The signal insertion unit 103 inserts various signals generated by the speed setting control unit into the main signal and sends them to the transmission path. Speed setting control unit 101, regardless of the speed of the main signal, speed setting, for the processing of the route search, to operate at the speed set for a rate determined in advance.

  The process flow of the transponder will be described. In FIG. 1, the speed setting control unit 101 starts the speed setting process when the signal speed determining unit 102 detects a change in the signal speed from the client device. The speed setting control unit 101 sends the signal speed information detected by the signal speed determination unit 102 to the transmission path. When all the relay devices and the opposite transponder accept the speed change, ACK is transmitted from the opposite transponder. When this ACK is received, the speed setting control unit 101 sends a speed setting execution request to the transmission path through the signal inserting unit 103. When the switch is connected, the port number to which the transponder is currently connected and the port number not in use are transmitted from the switch. According to this information, the speed setting control unit 101 sequentially switches to an unused port and sends signal speed information to the transmission path. For the transmission path to which the ACK from the opposite transponder has been returned, the speed setting control unit 101 sends a speed setting execution request and causes the switch to record the unused transmission path as a spare for the transmission path that was initially connected.

However, when an attempt is made to set the speed on a transmission line for which the speed has already been set from another transponder, the port number and the set speed are notified from the switch. In that case, the transponder 100 temporarily records the notification in the speed setting control unit 101 without performing the speed setting. From all the notification contents after attempting to set the speed on all unused transmission lines, the transponder 100 determines that “there is no transponder having no spare transmission line even if the transmission line speed setting is overwritten”. Judge whether to satisfy. Only when the condition is satisfied, the speed setting control unit 101 sends a speed setting execution request. If the condition is not satisfied, the speed setting control unit 101 performs only the process of recording an unused transmission line as a spare for the transmission line that was initially connected.
When a transmission path switching notification is transmitted from the switch, the speed setting control unit 101 transmits a speed setting execution request to the transmission path, performs speed setting, and sends a main signal to the transmission path.

The process flow of the transponder will be described again with reference to FIG. In FIG. 2, when detecting a failure, the transponder 100 determines whether the failure is due to a speed unknown signal from the client device (S11). When YES, the transponder 100 acquires the signal speed (S12). The transponder 100 transfers the acquired signal speed information to the relay device 200 (S13). The transponder 100 determines whether the switch 300 is connected (S14). When YES, the transponder 100 determines whether there is an empty port in the switch 300 that has not been tried for speed setting (S16). When YES, the transponder 100 transmits a transmission path switching command to an empty port to the switch 300, and receives a switching completion notification from the switch 300 (S17). The transponder 100 receives the ACK from the opposite transponder and transmits a speed setting execution request (S18). The transponder 100 determines whether a notification is returned from the switch (S19). If YES, the transponder 100 records the notification content (S21) and returns to step 16. If NO in step 19, the transponder 100 returns to step 16 as it is.

  If NO in step 11, it is a transmission path failure, so the transponder 100 receives a transmission path switching notification from the switch (S22). The transponder 100 transmits a speed setting request to the current transmission path (S23) and ends.

  If NO in step 14, the transponder 100 determines whether the speed setting is completed (S24). When YES, the transponder 100 ends. If NO in step 24, the transponder 100 transfers the speed setting information to the current transmission path (S26), and proceeds to step 17.

  When NO in step 16, the transponder 100 determines whether a notification from the switch is recorded (S27). If YES, the transponder 100 determines whether or not the speed overwrite setting is possible (S28). When YES, the transponder 100 transfers the speed overwrite setting command to the current transmission path, and instructs the switch to set the current transmission path to the backup transmission path (S31). The transponder 100 returns to the initial port setting (S32) and ends. When NO in step 28, the transponder 100 instructs the switch to register the current transmission path as a backup transmission path, returns to the initial port setting (S33), and ends. When NO in step 27, the transponder 100 ends the speed setting, returns the port setting to the original (S34), and ends.

  The configuration of the optical repeater will be described with reference to FIG. In FIG. 3, the optical repeater 200 includes two speed setting control units 201, a signal processing unit 202, and a speed information / speed setting request signal insertion unit 203, respectively. The signal processing unit 202 converts the optical signal into an electrical signal, converts it again into an optical signal, and sends it out to the transmission line. The speed setting control unit 201 receives the speed setting information transmitted from the transponder, and determines whether to return an error upstream or transfer the speed setting information downstream by comparing with the corresponding speed. The speed information / speed setting execution request insertion unit 203 inserts a speed setting signal, a speed setting execution request, and an error into the transmission path.

  In the optical repeater 200 illustrated in FIG. 3, the speed setting control unit 201 receives speed setting information. The speed setting control unit 201 compares the speed included in the received speed setting information with its corresponding speed. In the case of the corresponding speed, the speed setting information is transferred to the downstream as it is through the speed information / speed setting execution request insertion unit 203. If not, the speed setting control unit 201 returns an error upstream through speed information / speed setting execution request insertion unit 203 in the reverse direction.

When the speed setting execution request is received, the speed setting control unit 201 compares it with its corresponding speed. In the case of the corresponding speed, the speed setting control unit 201 transfers the speed setting information as it is through the speed information / speed setting execution request insertion unit 203 as it is. The speed setting control unit 201 performs speed setting. If not, the speed setting control unit 201 returns an error upstream through the reverse speed information / speed setting execution request insertion unit 203.
Although the optical repeater has been described as the regenerative repeater (3R), the optical repeater (1R) may be used.

  The signal processing of the optical repeater will be described with reference to FIG. In FIG. 4, when receiving the signal from the transponder 100, the optical repeater 200 confirms the signal content (S41). When it is speed setting information, the optical repeater 200 determines whether it is a corresponding speed (S42). If YES, the optical repeater 200 transfers the speed setting information (S43) and ends. If NO in step 42, the optical repeater 200 returns an error (S44) and ends.

  In step 41, when the speed setting execution request is received, the optical repeater 200 determines whether the speed is a corresponding speed (S46). If YES, the optical repeater 200 transmits a speed setting request (S47). The optical repeater 200 performs speed setting (S48) and ends. If NO in step 46, the optical repeater 200 returns an error (S49) and ends.

  The configuration of the switch will be described with reference to FIG. In FIG. 5, the switch 300 has three inputs and three outputs on one side, and includes six signal detection units 301, two switch switching units 307, and a control unit 310. Further, the control unit 310 includes a signal insertion unit 311, a switch control unit 312, and a backup transmission path storage unit 313.

  The signal detection unit 301 determines the presence or absence of an optical signal, and detects speed setting information, a speed setting execution request, a port switching request, and backup transmission path information from the transponder. The switch control unit 312 controls switch switching. The backup transmission path recording unit 313 records backup transmission path information transmitted from the transponder when a failure occurs. The signal insertion unit 311 sends the speed information transmitted from the transponder, the speed setting execution request, the port information transmitted to the transponder, the port switching completion notification, the speed information signal, and the port switching request for the opposite switch to the transmission path. The switch switching unit 307 performs port switching.

  In FIG. 5, the switch 300 detects a signal from the transponder by the signal detection unit 301. When a signal from the transponder 100 is detected, the switch control unit 312 and the signal insertion unit 311 are activated. The switch 300 shifts to a mode in which the signal from the transponder 100 is transferred to the transmission path via the switch control unit 312 and the signal insertion unit 311.

  When the signal is speed setting information from the transponder, the switch control unit 312 confirms the presence / absence of an optical signal at each port. The switch control unit 312 returns the connection port and vacant port information to the transponder through the signal insertion unit 311. The switch control unit 312 transfers the speed setting information downstream.

  When the signal is a speed setting execution request from a transponder, the switch control unit 312 confirms whether the speed setting target transmission path has already been set by another transponder and registered as a spare transmission path. If not registered, the switch control unit 312 causes the signal insertion unit 311 to transfer the speed setting execution request downstream. If registered, the switch control unit 312 notifies the transponder 100 of the set operation speed of the transmission path.

  When the signal is a path switching request from the transponder, the switch control unit 312 performs transmission path switching. The switch control unit 312 transfers the path switching request to the opposite switch.

  When the signal is a backup transmission path information recording request from the transponder, the switch control unit 312 records the backup transmission path storage unit 313. The switch control unit 312 transfers the backup transmission path information recording request to the opposite switch.

In the case of other signals, the switch control unit 312 transfers the data as it is downstream.
When the main signal is conducted, the switch control unit 312 and the signal insertion unit 311 are stopped. When the signal detection units 301-6, 301-5, and 301-4 on the transmission line side detect the loss of the optical signal, the switch control unit 312 and the signal insertion unit 311 are activated. The switch control unit 312 switches the transmission path according to the backup transmission path information in the backup transmission path storage unit 313. When the set speed of the switching destination transmission path is not equal to the operation speed of the transponder, the switch control unit 312 transmits a switching notification to the transponder 100. When the signal detection units 301-6, 301-5, and 301-4 on the transmission line side receive a port switching request from the opposite switch, the switch control unit 312 switches the port according to the request.

  With reference to FIG. 6, the processing of the switch will be described. In FIG. 6A, when receiving a signal from the transponder 100, the switch 300 confirms the signal content (S61). When the transmission path switching request is made, the switch 300 switches the transmission path, transmits a switching completion notification to the transponder 100 (S62), and ends. If it is a backup transmission path information recording command in step 61, the switch 300 records backup transmission path information (S63) and ends. When the speed setting information is obtained in step 61, the switch 300 transmits the connection port and free port information to the transponder 100 (S64). The switch 300 transfers the speed setting information (S66) and ends. When a speed setting execution request is made in step 61, the switch 300 determines whether a speed has already been set for the speed setting target transmission line (S67). If YES, the switch 300 transfers the speed setting request as it is (S68) and ends. When YES in step 67, the switch 300 notifies the transponder 100 that the speed is not set for the transmission path (S69), and the process is terminated.

In FIG. 6B, when detecting the loss of signal on the transmission path side, the switch 300 determines whether the speed of the switching destination transmission path is equal to the operating speed of the transponder 100 (S81). If YES, the switch 300 switches the transmission line according to the standby transmission line information (S82) and ends. When NO in step 81, the switch 300 switches the transmission path according to the standby transmission path information, transmits a transmission path switching notification to the transponder 100 (S83), and ends.
In FIG. 6C, when receiving the port switching request from the opposite switch, the switch 300 switches the port according to the request (S86) and ends.

With reference to FIG. 7, a sequence for setting the speed of the transponder facing the relay apparatus based on the speed of the client signal received by the transponder will be described. First, the configuration of the optical transmission system will be described with reference to FIG. 7A. In the optical transmission system 500A illustrated in FIG. 7A , the two transponders 100 are connected via the two relay devices 200.

In FIG. 7B, the transponder 100-1 determines the speed from the input client signal, stops the main signal, and sends the line speed information to the relay apparatus 200-1 at the speed setting rate (S101). The relay apparatus 200-1 that has received the line speed information compares its corresponding speed information with the received line speed information (S102). Here, since it corresponds, the relay apparatus 200-1 transmits line speed information to the relay apparatus 200-2 (S103). The relay device 200-2 that has received the line speed information compares its own corresponding speed information with the received line speed information (S104). Here, since the response, the relay device 200-2 sends a line speed information to the transponder 100-2 (S106).

  The transponder 100-2 receiving the line speed information compares the corresponding speed information with the received line speed information (S107). Here, since it corresponds, the transponder 100-2 returns ACK (line speed correspondence confirmation completion) to the transponder 100-1 (S108). The transponder 100-1 that has received the ACK from the opposite transponder 100-2 determines that all the relay apparatuses and transponders support the line speed, and sends a speed setting execution request to the relay apparatus 200-1 (S109). . The relay device 200-1 performs speed setting (S111). The relay device 200-1 transmits the speed setting execution request to the relay device 200-2 at the speed setting rate (S112). The relay device 200-2 performs speed setting (S113). The relay apparatus 200-2 transmits the speed setting execution request to the transponder 100-2 at the speed setting rate (S114). Receiving the speed setting execution request, the transponder 100-2 performs speed setting (S116). The transponder 100-2 returns ACK (speed setting completion) to the transponder 100-1 at the line speed (S117). The relay apparatuses 200-1 and 200-2 transfer the ACK from the transponder 100-2 as it is. When the transponder 100-1 receives the ACK, the transponder 100-1 determines that the speed setting is completed, and starts to send the client signal (main signal). In FIG. 7B, a thick arrow means a line speed signal, and a thin arrow means a speed setting rate signal.

  With reference to FIG. 8, the sequence of speed setting and spare transmission line registration in the case of having two transmission lines and switching to a spare transmission line when a failure occurs will be described. First, the configuration of the optical transmission system will be described with reference to FIG. 8A. In FIG. 8A, in the optical transmission system 500B, two transponders 100 are connected to two switches 300 via a set of two relay devices 200, respectively. The port number (i) assigned to the switch 300-1 is the active system, and the port number (ii) is the standby system.

  In FIG. 8B, the transponder 100-1 determines the speed from the input client signal, and sends the line speed information to the switch 300-1 at the speed setting rate (S121). The switch 300-1 returns the port number (i) of the transmission path to which the transponder 100-1 is currently connected and the port number (ii) of the transmission path not currently used as a signal 2002 to the transponder 100-1. (S122). After transmitting the port information, the switch 300-1 passes the line speed information for the relay apparatuses 200-1 and 200-2 and the transponder 100-2 as it is, so that the procedure (S101 to S117) in FIG. The speed is set for the transmission line.

  The transponder 100-1 transmits a port switching request to switch to the port number (ii) to the switch 300-1 (S123). The switch 300-1 changes the port (S124). The switch 300-1 requests the opposite switch 300-2 to switch the port number (S126). The switch 300-2 changes the port (S127). The switch 300-2 transmits a port change completion signal to the switch 300-1 (S128). The switch 300-1 transmits a port change completion signal to the transponder 100-1 (S129). The transponder 100-1 also sets the speed for the transmission path (ii) by the procedure shown in FIG. 7B.

  The transponder 100-1 returns the port settings of the switches 300-1 and 300-2 to (i) by the procedure from step 123 to step 129 (S131 to 137). The transponder 100-1 transmits a backup transmission line recording request so as to record the transmission line connected to (ii) as a backup of the transmission line connected to (i) to the switch 300-1 (S138). The switch 300-1 records the transmission line connected to (ii) as a spare for the transmission line connected to (i) (S139). The switch 300-1 transfers the backup transmission path recording request to the switch 300-2 (S141). The switch 300-2 records the transmission line connected to (ii) as a spare for the transmission line connected to (i) (S142).

  The transponder 100-1 starts to send a client signal to the transmission line (S143). When a failure occurs in the transmission path connected to (i), the switches 300-1 and 300-2 switch the port from (i) to (ii) according to the backup transmission path record.

  With reference to FIG. 9, an optical transmission system that uses two transmission lines A1 and C1 operating at the same speed in a normal state and shares one spare transmission line B1 will be described. In FIG. 9, the optical transmission system 500C includes four transponders 100, two switches 300, and an optical repeater 200 installed in three transmission paths. The optical repeaters 200-1 and 200-2 are installed on the transmission line A1. The optical repeaters 200-3 and 200-4 are installed on the transmission line C1. The optical repeaters 200-5 and 200-6 are installed in the transmission line C1. The switch 300-1 is connected to the transponders 100-1 and 100-3. The switch 300-2 is connected to the transponders 100-2 and 100-4. Transponder 100-1 communicates with transponder 100-2. Transponder 100-3 communicates with transponder 100-4.

  Transponder 100-1 sets the speed of transmission lines A1 and B1 to the operating speed of transponder 100-1 in the procedure of FIG. 8B. The transponder 100-1 requests the switch 300-1 to record the transmission line B1 as a spare transmission line of A1 at the operation speed of the transponder 100-1. The switch 300-1 transfers the backup transmission path recording request to the switch 300-2.

  After the switches 300-1 and 300-2 record the preliminary transmission path information, the transponder 100-3 performs speed setting for the transmission paths B1 and C1 in the procedure of FIG. 8B. The switch 300-1 notifies the transponder 100-3 that the transmission line B1 is recorded as a backup at the operating speed of the transponder 100-1. Since the operating speed of the transponder 100-1 matches the operating speed of the transponder 100-3, the transponder 100-3 requests the switch 300-1 to record the transmission path B1 as a spare transmission path for C1. The switch 300-1 transfers the backup transmission path recording request to the switch 300-2. When a failure occurs in the transmission line A1, the switches 300-1 and 300-2 change the port number to (ii) and flow a signal to the immediate transmission line B100-1. Even when a failure occurs in the transmission line C1, the switches 300-1 and 300-2 change the port number to (ii) and send an immediate signal to the transmission line B1.

  Referring to FIG. 10, an optical transmission system that uses two transmission lines A2 and C2 operating at different speeds in a normal state and shares one spare transmission line B2 corresponding to both speeds will be described. To do. 10, the configuration of the optical transmission system 500D is the same as that of the optical transmission system 500C in FIG. However, the communication speed between the transponder 100-1 and the transponder 100-2 is different from the communication speed between the transponder 100-3 and the transponder 100-4.

  The transponder 100-1 sets the speed to the operation speed of the transponder 100-1 for the transmission paths A2 and B2 by the procedure of FIG. 8B. The transponder 100-1 requests the switch 300-1 to record the transmission path B2 as a spare for A2 at the operating speed of the transponder 100-1.

  The transponder 100-3 performs speed setting for the transmission paths B2 and C2 according to the procedure of FIG. 8B. Since the transponder 100-3 returns an ACK from the opposite transponder 100-4, the transponder 100-3 determines that the transmission path B2 corresponds to the operating speed of the transponder 100-3, and tries to set the speed. However, the switch 300-1 notifies the transponder 100-3 that the transmission path B2 is recorded as a backup at the operating speed of the transponder 100-1. Since the operating speed of the transponder 100-1 does not match the operating speed of the transponder 100-3, the transponder 100-3 does not set the speed of the standby system. After attempting to set the speed for all unused transmission lines, it is determined whether the overwrite speed can be set. However, if the speed setting is performed by overwriting the transmission line B, the spare transmission line for the transmission line A2 does not exist, so the overwrite speed No settings are made.

The transponder 100-3 requests the switch 300-1 to record B2 (port ii) at the operating speed of the transponder 100-3 as a spare for the transmission path C2 (port iv ). The switch 300-1 transfers the backup transmission path information recording request to the switch 300-2.

  When a failure occurs in the transmission line A2, the switches 300-1 and 300-2 change the port number to (ii) and switch the transmission line of the transponder 100-1 to the transmission line B2. When a failure occurs in the transmission path C2, the switches 300-1 and 300-2 switch the transmission path of the transponder 100-3 to the transmission path B2, and the switch 300-1 notifies the transponder 100-3 of the switching. The transponder 100-3 transmits a speed setting execution request to the transmission path B2, and sets the speed.

  Referring to FIG. 11, two transmission lines A3 and D3 that operate at different speeds are used in normal times, and spare transmission line B3 that supports both speeds and only one speed. An optical transmission system sharing the transmission line C3 will be described. In FIG. 11, the optical transmission system 500E is composed of four transponders 100, two switches 300, and an optical repeater 200 installed in four transmission lines. The optical repeaters 200-1 and 200-2 are installed on the transmission line A3. The optical repeaters 200-3 and 200-4 are installed on the transmission line C3. The optical repeaters 200-5 and 200-6 are installed in the transmission line B3. The optical repeaters 200-7 and 200-8 are installed on the transmission line D3.

  The switch 300-1 is connected to the transponders 100-1 and 100-3. The switch 300-2 is connected to the transponders 100-2 and 100-4. Transponder 100-1 communicates with transponder 100-2. Transponder 100-3 communicates with transponder 100-4.

  The transponder 100-1 sets the speed to the operation speed of the transponder 100-1 with respect to the transmission paths A3 and B3 by the procedure of FIG. 8B. The transponder 100-1 requests the switch 300-1 to record the transmission line B3 as a spare for A3 at the operating speed of the transponder 100-1. The switch 300-1 transfers the backup transmission path recording request to the switch 300-2.

  The transponder 100-1 sets the speed to the operation speed of the transponder 100-1 for the transmission paths A3 and C3 by the procedure of FIG. 8B. The transponder 100-1 requests the switch 300-1 to record the transmission path C3 as a spare for A3 at the operating speed of the transponder 100-1. The switch 300-1 transfers the backup transmission path recording request to the switch 300-2.

  The transponder 100-3 performs speed setting for the transmission paths B3 and D3 according to the procedure of FIG. 8B. Since an error is returned from the relay apparatus 200-5, the transponder 100-3 determines that the transmission path B3 does not correspond to the operating speed of the transponder 100-3, and ends the speed setting. The transponder 100-3 performs speed setting for the transmission paths C3 and D3 in the procedure of FIG. 8B. Since transponder 100-3 returns an ACK from the opposite transponder, it determines that transmission path C3 corresponds to the operating speed of transponder 100-3, and tries to set the speed. However, the switch 300-1 notifies the transponder 100-3 that the transmission line C3 is recorded as a backup at the operating speed of the transponder 100-1. Transponder 100-3 does not set the speed because the operating speed of transponder 100-1 does not match the operating speed of transponder 100-3. After attempting to set the speed for all unused transmission lines, it is determined whether the overwriting speed can be set. However, even if the transmission line B3 is overwritten and the speed is set, the transmission line A3 has a spare transmission line called the transmission line B3, so the overwrite speed is set. The transponder 100-3 requests the switch 300-1 to record C3 (port iii) at the operation speed of the transponder 100-3 as a spare for the transmission path D3 (port iv). The switch 300-1 transfers the backup transmission path recording request to the switch 300-2. When a failure occurs in the transmission line A3, the switches 300-1 and 300-2 change the port number to (ii) and switch the transmission line of the transponder 100-1 to the transmission line B3. When a failure occurs in the transmission line D3, the switches 300-1 and 300-2 switch the transmission line of the transponder 100-3 to the transmission line C3.

  As an optical transmission apparatus, multi-rate transponders corresponding to various interfaces are increasing. When the multi-rate transponder is used, according to the above-described embodiment, the transmission rate setting is automatically performed for the remote device without separately constructing a monitoring control network for setting the speed according to each interface. Can be done. Further, a path changeover switch on the transmission path is detected, a usable transmission path is automatically assigned, and when there is a usable spare transmission path, speed setting is performed in advance. As a result, immediate path switching can be performed when a failure occurs. Since the switching destination is recorded on the switch, the speed is set, so that the setting can be performed easily and economically.

  DESCRIPTION OF SYMBOLS 100 ... Transponder, 101 ... Speed setting control part, 102 ... Signal speed discrimination | determination part, 103 ... Transponder signal insertion part, 104 ... Wavelength conversion part, 200 ... Optical repeater, 201 ... Speed setting control part, 202 ... Signal processing part, 203 ... Speed information / speed setting execution request insertion unit, 300 ... switch, 301 ... signal detection unit, 307 ... switch switching unit, 310 ... control unit, 311 ... signal insertion unit, 312 ... switch control unit, 313 ... spare transmission path Storage unit, 500... Optical transmission system.

Claims (3)

In an optical transponder that accommodates optical signals of a plurality of transmission rates, is connected to an optical switch by a first transmission path, and is connected to an optical repeater by the optical switch and a second transmission path,
The transmission speed of the optical signal is acquired, the transmission speed acquired by the optical repeater is inserted into the optical signal, and transmitted through the first transmission path, the optical switch, and the second transmission path. When a signal corresponding to the transmission speed is received from the optical repeater or the optical transmission apparatus connected to the optical repeater, a speed setting request is transmitted to the optical repeater or the connected optical transmission apparatus optical transponder, characterized in that, and obtains the port usage information from the previous SL switch. The optical transponder according to claim 1 ,
An optical transponder that transmits a backup transmission path recording request to the switch based on the acquired port usage status information. An optical transponder that accommodates optical signals of a plurality of transmission speeds, a switch connected to the optical transponder via a first transmission path, and a plurality of ports connected to a plurality of ports of the switch via a plurality of second transmission paths In an optical transmission system comprising an optical repeater,
The optical transponder acquires the transmission speed of the optical signal, inserts the transmission speed acquired by the switch into the optical signal, transmits the optical signal via the first transmission path, and transmits the optical relay apparatus or the optical relay. device from the connected optical transmission apparatus, the transmission rate when receiving a possible signal corresponding transmits a speed setting request to the optical relay device or the connected optical transmission device, prior Symbol port usage from the switch An optical transmission system characterized by acquiring information.

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