JP2018014621A - Communication device and communication path switching method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To shorten a time for a switching process of a communication path for a communication signal.SOLUTION: An OLT 1 includes: an active PON interface unit 7 for outputting a communication signal; a standby PON interface unit 9; and a control unit 6 for transmitting a switching control signal. The active PON interface unit 7 includes: a memory 14; a CPU 13 for issuing instructions on data transfer according to the switching control signal; and a communication control unit 18 composed of at least one piece of hardware different from the CPU 13. When a communication path is switched, the communication control unit 18 reads out data stored in the memory 14 according to the instructions from the CPU 13, and transfers it toward the standby PON interface unit 9.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a communication device capable of switching communication paths of communication signals.

  A communication system may have a redundant configuration so that communication can be continued even when a communication failure occurs. For example, a PON (Passive Optical Network) system is one of communication systems. For example, Patent Document 1 discloses an optical termination system capable of switching a communication path of a communication signal from an active optical termination unit (active PON interface) to a standby optical termination unit (protection PON interface).

JP 2007-36926 A

  In the optical termination system disclosed in Patent Document 1, when a communication failure occurs, a CPU (Central Processing Unit) that performs various controls on the components in the active optical termination unit switches the communication path. Management information (takeover data) for reading from the RAM (Random Access Memory) and transmitting it to the backup optical termination unit. The CPU of the backup optical termination unit that has received the management information writes the received management information to the RAM, and uses the received management information to communicate between the ONU (Optical Network Unit) and the upper network. Take over. However, when the CPU that performs various controls in the optical termination unit performs processing such as the transfer of management information when switching the communication path, the load on the CPU is so great that other task processing cannot be performed or data transfer There is a problem that the speed is slow and it takes time to resume communication by the standby optical terminal unit.

  Therefore, an object of the present invention is to shorten the time for switching the communication path of communication signals.

  The communication apparatus according to the present invention controls the switching of the communication path of the communication signal between the active interface unit that outputs a communication signal, the standby interface unit, and the active interface unit and the standby interface unit. A control unit that transmits a switching control signal for the active system, wherein the working interface unit includes a first memory and a first central processing unit that issues a data transfer instruction according to the switching control signal from the control unit; A first communication control unit configured by at least one piece of hardware different from the first central processing unit, and when the communication path is switched, the first communication control unit The data stored in the first memory is read in accordance with the instruction from one central processing unit and transferred to the standby interface unit. To.

  ADVANTAGE OF THE INVENTION According to this invention, the time of the switching process of the communication route of a communication signal can be shortened.

It is a figure which shows the structure of the PON system provided with OLT (Station side optical termination device: Optical Line Terminal) which concerns on Embodiment 1 of this invention. It is a block diagram which shows an example of the communication form in OLT schematically. It is a block diagram which shows the structure of a PON-IF part roughly. It is a flowchart which shows the switching process of the communication path in OLT. It is a block diagram which shows roughly the communication form in OLT which concerns on a modification. It is a block diagram which shows roughly the structure of the PON-IF part of OLT which concerns on a modification. It is a block diagram which shows roughly the structure of the PON-IF part of OLT which concerns on Embodiment 2 of this invention. 10 is a flowchart showing communication path switching processing in the OLT according to the second embodiment. It is a block diagram which shows roughly the structure of the backup PON interface part of OLT which concerns on Embodiment 3 of this invention. It is a flowchart which shows the transfer process of takeover data. 10 is a flowchart showing a communication path switching process in the OLT according to the third embodiment.

Embodiment 1 FIG.
FIG. 1 is a diagram showing a configuration of a PON system as a communication system including an OLT 1 as a communication apparatus according to Embodiment 1 of the present invention.

  The PON system shown in FIG. 1 has an N: 1 PON protection function. The N: 1 PON protection function is used when, for example, a communication failure occurs in any one of the N (N is a natural number) PON interface units (PON-IF units) operating as the active system. This function switches the communication path of communication signals from the active PON interface unit to the standby PON interface unit by a switch. By connecting ONUs connected under the active PON interface unit to the standby PON interface unit, communication can be continued even when a communication failure occurs. However, the present invention can also be applied to a PON system having a 1: 1 protection configuration.

  The PON system according to Embodiment 1 has an OLT 1 and at least one ONU 2. The OLT 1 and the ONU 2 are connected via an optical fiber 4 and can communicate with each other using an optical signal as a communication signal. The optical fiber 4 includes a trunk optical fiber 4a and a branch optical fiber 4b. The trunk optical fiber 4 a is branched into a plurality of branch optical fibers 4 b by the optical splitter 3. Thereby, the OLT 1 and the optical splitter 3 are connected via the trunk optical fiber 4a, and the ONU 2 and the optical splitter 3 are connected via the branch optical fiber 4b.

  The OLT 1 includes a control unit 6 as a main control unit, and a plurality of working PON interface units 7 (PON-IF units # 1, # 2,..., # As a plurality of working system interface units (first interface units)). N; N is a natural number), optical switch unit 8 (optical SW unit), standby system PON interface unit 9 (PON-IF unit # N + 1) as a standby system interface unit (second interface unit), SW− And an IF (switch interface) unit 10.

  The OLT 1 employs N: 1 (N is a natural number) PON protection. That is, the OLT 1 has N working PON interface units 7. When a communication failure occurs in any of the N active PON interface units 7, the active PON interface unit 7 to be switched (the PON-IF unit in which the communication failure has occurred) transfers to the standby PON interface unit 9. Transfer data (transfer data) for switching the communication path is transferred.

  The control unit 6 is connected to each component in the OLT 1 so as to communicate with each other, and controls each component. For example, the control unit 6 can control the optical switch 8 b of the optical switch unit 8 to switch the communication path of the communication signal transmitted in the OLT 1. For example, when a communication failure occurs in any communication line (that is, any PON-IF unit), the control unit 6 communicates between the active PON interface unit 7 and the standby PON interface unit 9. A switching control signal (switch notification) for controlling switching of the signal communication path is transmitted to the PON-IF unit. Furthermore, not only the switching process caused by a communication failure, but also, for example, when the user of the OLT 1 gives an instruction to the control unit 6 when the PON-IF unit is replaced, the communication path switching process is intentionally performed. It can be performed.

  The working PON interface unit 7 is connected to the optical fiber 4 (specifically, the trunk optical fiber 4a) via the optical switch unit 8. The working PON interface unit 7 operates as a working system. The working PON interface unit 7 outputs a communication signal (for example, an Ethernet (registered trademark) frame) for transmitting data.

  The standby PON interface unit 9 is connected to the optical fiber 4 (specifically, the trunk optical fiber 4a) via the optical switch 8b of the optical switch unit 8. The backup PON interface unit 9 is provided in the OLT 1 as a backup system. The standby PON interface unit 9 can output a communication signal (for example, an Ethernet (registered trademark) frame) for transmitting data. The standby PON interface unit 9 is in the extinguished state (stopped optical signal generation) until it receives a light emission start notification, which is an instruction to emit light (generate optical signal), from the control unit 6 after the communication path switching process. is there.

  The optical switch unit 8 includes at least one optical splitter 8a and an optical switch 8b. The optical splitter 8a branches the signal line into two paths. The working PON interface unit 7 is connected to the optical splitter 8a, and the standby PON interface unit 9 is connected to the optical switch 8b.

  The active PON interface unit 7 and the standby PON interface unit 9 are connected to the SW-IF unit 10 and are connected to the higher level network via the SW-IF unit 10. The active PON interface unit 7 and the standby PON interface unit 9 are connected to each other in order to perform data transfer when the communication path is switched, and can communicate with each other via Ethernet (registered trademark).

FIG. 2 is a block diagram schematically showing an example of a communication form in the OLT 1.
In the OLT 1, the control unit 6 and each component are connected by PtoP (point-to-point), and each active PON interface unit 7 and standby PON interface unit 9 are also connected by PtoP. Therefore, the communication mode between the control unit 6 and each PON-IF unit and the communication mode between each active PON interface unit 7 and the standby PON interface unit 9 (data transfer communication in the communication path switching process) Form) may be different from each other.

  FIG. 3 is a block diagram schematically showing the configuration of each PON-IF unit (each of the active PON interface unit 7 and the standby PON interface unit 9). The configurations (components) of the active PON interface unit 7 and the standby PON interface unit 9 are the same, and the operating conditions, that is, the active system and the standby system are different.

  Each PON-IF unit includes a failure detection unit 11, an optical transceiver 12, a CPU 13, a memory 14, a communication control unit 18, a MUX / DEMUX (multiplexer / demultiplexer) unit 19, and a bus 20. .

  The communication control unit 18 is composed of at least one hardware different from the CPU 13. In the present embodiment, the communication control unit 18 includes a DMAC (Direct Memory Access Controller) 15 serving as a control circuit, and a frame transmission unit 16 (Ethernet (registered trademark) frame) each configured by hardware. And a frame receiver 17 (Ethernet (registered trademark) frame receiver).

  The failure detector 11 can detect the occurrence of a communication failure in the PON system shown in FIG. For example, the communication failure is a failure caused by a link down due to a failure of the optical transceiver 12, a failure of the active PON interface unit 7, or a line deterioration due to damage of the optical fiber 4 (particularly, the trunk optical fiber 4a). However, a communication failure may be detected with the occurrence of a failure other than these as a trigger. When the failure detection unit 11 detects the occurrence of a communication failure, the failure detection unit 11 notifies the control unit 6 of the occurrence of the communication failure.

  The optical transceiver 12 (the first optical transceiver in the active PON interface unit 7 and the second optical transceiver in the standby PON interface unit 9) transmits an optical signal as a communication signal to the ONU 2 through the optical fiber 4. Can be received from the ONU 2.

  The CPU 13 is connected to the bus 20. The CPU 13 can control each component in the PON-IF unit and perform setting of the PON-IF unit.

  For example, during communication path switching processing (for example, when a switching notification is received from the control unit 6), in the active PON interface unit 7, the CPU 13 (first CPU) follows the switching notification from the control unit 6. An instruction for data transfer is issued to each component (for example, DMAC 15) configured by hardware in the working PON interface unit 7.

  For example, in the communication path switching process, in the standby PON interface unit 9, the CPU 13 (second CPU) is based on data stored in the memory 14 (takeover data received from the working PON interface unit 7). The standby PON interface unit 9 is set (specifically, control for each component in the standby PON interface unit 9).

  The memory 14 stores various data and programs executed by the CPU 13. The data stored in the memory 14 is, for example, setting information of the working PON interface unit 7 and information indicating the registration state of the ONU 2 connected to the working PON interface unit 7. The memory 14 is, for example, a DRAM (Dynamic Random Access Memory).

  In the present embodiment, data is written to and read from the memory 14 by the communication control unit 18 using a DMA (Direct Memory Access) method by hardware.

  The DMAC 15 is configured by hardware different from the CPU 13. The DMAC 15 can read data stored in the memory 14, write data to the memory 14, and data transfer by the DMA method.

  For example, in switching the communication path, in the active PON interface unit 7, the DMAC 15 (first DMAC) serving as the first control circuit follows the instruction from the CPU 13 (first CPU) in the memory 14 (first CPU). Data (takeover data) stored in the memory) is read out instead of the CPU 13 and transferred to the standby PON interface unit 9. Specifically, the takeover data read by the DMAC 15 is transferred to the frame transmission unit 16.

  For example, when the communication path is switched, in the standby PON interface unit 9, the DMAC 15 (second DMAC) as the second control circuit receives the data received from the active PON interface unit 7 in the memory 14 (second Memory).

  The frame transmission unit 16 is configured by hardware different from the CPU 13. The frame transmission unit 16 is, for example, hardware (for example, an integrated circuit) having a function of transferring data input from the DMAC 15 using an Ethernet (registered trademark) frame (hereinafter also simply referred to as “frame”). . Each PON-IF unit has a different MAC (Media Access Control) address, and a DA (Destination Address) and an SA (Source Address) are stored in a frame transmitted from the frame transmission unit 16. The frame transmission unit 16 can give the priority of the frame output from the active PON interface unit 7 to the frame.

  The frame receiving unit 17 is configured by hardware different from the CPU 13. The frame receiving unit 17 is, for example, hardware (for example, an integrated circuit) having a function of transferring data received from the MUX / DEMUX unit 19 (for example, data received from the active PON interface unit 7) to the DMAC 15 as a frame. It is.

  In the example shown in FIG. 3, the frame transmission unit 16 and the frame reception unit 17 are connected to a MUX / DEMUX unit 19.

  The MUX / DEMUX unit 19 performs data multiplexing and separation (for example, selection of output data).

  The bus 20 (external bus) is connected to the SW-IF unit 10.

FIG. 4 is a flowchart showing communication path switching processing in the OLT 1.
A communication path switching process (communication path switching method) in the PON system shown in FIG. 1 will be described below with reference to FIG.

  The failure detection unit 11 monitors communication failures in the PON system (step S1). The failure detection unit 11 detects whether a communication failure has occurred in the PON system as needed (step S2). If no communication failure is detected (NO in step S2), the communication failure is monitored again (step S1).

  For example, when the failure detection unit 11 of the PON-IF unit # 1 among the plurality of working PON interface units 7 detects a communication failure (YES in step S2), the PON-IF unit # 1 (failure detection unit 11) Notifies the control unit 6 of the occurrence of a communication failure. After receiving the notification from the PON-IF unit # 1, the control unit 6 issues a switching notification to the active PON interface unit 7 (PON-IF unit # 1) and the standby PON interface unit 9 (step S3).

  The control unit 6 determines whether there is an abnormality in the standby PON interface unit 9 (step S4). When there is an abnormality in the standby PON interface unit 9 (YES in step S4), the communication path switching process is stopped (step S5). When there is no abnormality in the standby PON interface unit 9 (NO in step S4), the process proceeds to step S6.

  In step S6, the operation of the standby PON interface unit 9 (operation after completion of switching the communication path) is the same as the operation of the active PON interface unit 7 (PON-IF unit # 1) (operation before switching). In addition, the PON-IF unit # 1 reads the data (takeover data) stored in the memory 14 of the PON-IF unit # 1 by the DMA method and transfers the data to the standby PON interface unit 9. Specifically, the takeover data read from the memory 14 by the DMAC 15 of the communication control unit 18 (first communication control unit) is transmitted to the frame transmission unit 16 and encapsulated into a frame by the frame transmission unit 16. . The encapsulated frame is multiplexed with a plurality of signals by the MUX / DEMUX unit 19 and transmitted to the standby PON interface unit 9 via the bus 20 (step S6).

  The data (frame) received from the PON-IF unit # 1 is distributed by the MUX / DEMUX unit 19 of the standby PON interface unit 9 and input to the frame receiving unit 17. The frame receiver 17 of the standby PON interface unit 9 checks whether the received frame is normal (step S7).

  When the received frame is abnormal (NO in step S7), the standby PON interface unit 9 transmits NACK (Negative ACK knowledge) to the PON-IF unit # 1 (step S8). The frame abnormality is, for example, frame order reversal or omission.

  The active PON interface unit 7 that has received NACK returns to step S6 if the number of NACK reception is less than a predetermined number (for example, less than N; N is a natural number) (NO in step S9), The frame is retransmitted to the standby PON interface unit 9. If the number of NACK receptions is equal to or greater than a predetermined number (for example, N or more) (YES in step S9), the communication path switching process is stopped and the communication state is returned to the state before the start of the switching process ( Step S10).

  In step S7, when the received frame is normal (YES in step S7), the standby PON interface unit 9 transmits an ACK (ACKnowledgement) to the PON-IF unit # 1. Further, in the standby PON interface unit 9, the frame receiving unit 17 of the communication control unit 18 (second communication control unit) receives data (write data) to be written to the memory 14 among the received data (that is, takeover data). Extracted and transmitted to the DMAC 15. In the standby PON interface unit 9, the DMAC 15 writes the data transmitted from the frame receiving unit 17 into the memory 14 by the DMA method (step S11). The standby PON interface unit 9 writes data to the memory 14 and then notifies the control unit 6 that the data transfer process has been completed.

  In step S <b> 12, the CPU 13 of the standby PON interface unit 9 sets the standby PON interface unit 9 based on the data written in the memory 14. Specifically, the CPU 13 of the standby PON interface unit 9 performs the same setting as that of the working PON interface unit 7 (PON-IF unit # 1) for each component in the standby PON interface unit 9. (Step S12). After completion of data transfer and setting to the standby PON interface unit 9, the standby PON interface unit 9 issues a data transfer completion notification to the control unit 6.

  Upon receiving the data transfer completion notification, the control unit 6 issues a light emission stop notification to the active PON interface unit 7 to be switched (in this embodiment, the PON-IF unit # 1), and the light emission in the PON-IF unit # 1 Control (communication) to stop. The control unit 6 transmits a switching notification to the optical switch unit 8 after confirming that the light emission of the PON-IF unit # 1 is stopped. The optical switch unit 8 switches the communication path from the PON-IF unit # 1 to the standby PON interface unit 9. Similarly, the SW-IF unit 10 also switches the communication path (step S13).

  The control unit 6 transmits a light emission start notification to the standby PON interface unit 9, and the standby PON interface unit 9 starts light emission (communication). The standby PON interface unit 9 operates based on the takeover data (transfer data) written in the memory 14 (step S14).

  The communication path switching process is completed through the steps described above.

Modified example.
FIG. 5 is a block diagram schematically showing a communication form in the OLT 1a according to the modification.
As shown in FIG. 5, the connection method of the control unit 6, the active PON interface unit 7, and the standby PON interface unit 9 may be a star type. In this case, the working PON interface unit 7 and the standby PON interface unit 9 are connected via the control unit 6 so as to communicate with each other. As a result, the data transfer bus for switching the communication path can be shared among the plurality of active PON interface units 7, and a new bus is not required.

FIG. 6 is a block diagram schematically showing a configuration of the PON-IF unit 7a (each of the working PON interface unit and the standby PON interface unit) of the OLT 1a according to the modification.
Similar to the PON-IF unit of the OLT 1 according to the first embodiment, the configuration (components) of the working PON interface unit and the standby PON interface unit of the OLT 1a according to the modification are the same. In the PON-IF unit 7a of the OLT 1a according to the modified example, the signal from the CPU 13 and the signal from the communication control unit 18 are multiplexed by the MUX / DEMUX unit 19 in the PON- of the OLT 1 according to the first embodiment. Unlike the IF unit (the active PON interface unit 7 and the standby PON interface unit 9), the other points are the same as those in the first embodiment.

  In the PON-IF unit 7a, a priority may be given to a frame of inherited data transferred from the PON-IF unit 7a of the OLT 1a according to the modification. Further, during the frame transfer, a communication stop instruction for instructing not to perform communication and a release instruction for canceling the communication stop may be issued to components that perform communication via the same bus 20.

  The effects of the OLT 1 according to the first embodiment (including the OLT 1a according to the modification) will be described below.

  As described above, according to the first embodiment, in the communication path switching process, the active PON interface unit 7 is configured with hardware different from the CPU 13 after the CPU 13 issues a data transfer instruction. Since the communication control unit 18 performs data transfer processing (reading and transferring of takeover data), the CPU 13 can perform other task processing. Similarly, in the standby PON interface unit 9, since the communication control unit 18 (specifically, the DMAC 15) writes the takeover data instead of the CPU 13, the CPU 13 can perform other task processing.

  In the PON system as a comparative example, for example, when the CPU performs data transfer processing, the CPU of the active PON interface unit reads the inherited data from the memory, and the CPU of the standby PON interface unit receives information from the received inherited data. And write the read information to the memory. Further, the CPU of the standby PON interface unit performs the same setting as the setting of the working PON interface unit for each component in the standby PON interface unit based on the information written in the memory. In this case, since a series of operations of the communication path switching processing (processing from data transfer to setting completion) is realized by the CPU, that is, software processing, the load on the CPU is heavy, and it takes time until the switching processing is completed. Cost.

  On the other hand, according to the first embodiment, the communication control unit 18 (for example, the DMAC 15) configured by at least one hardware different from the CPU 13 includes the active PON interface unit 7 and the standby PON interface unit 9. Since the data transfer process between the communication paths is performed, the time required for the communication path switching process can be reduced. That is, in the communication path switching process, it is possible to shorten the transfer time of the takeover data and to quickly switch the communication path from the active PON interface unit 7 to the standby PON interface unit 9.

Embodiment 2. FIG.
FIG. 7 is a block diagram schematically showing a configuration of the PON-IF unit 7b (each of the working PON interface unit and the standby PON interface unit) of the OLT according to the second embodiment. The PON-IF unit 7b includes the PON-IF units # 1, # 2,..., And # N + 1 of the OLT 1 according to the first embodiment (that is, each of the working PON interface unit 7 and the standby PON interface unit 9). ). Similar to the PON-IF unit of the OLT 1 according to the first embodiment, the configuration (components) of the active PON interface unit and the standby PON interface unit of the OLT according to the second embodiment are the same. The OLT according to the second embodiment can be applied to the PON system shown in FIG. 1 instead of the OLT 1 according to the first embodiment.

  In the second embodiment, components that are the same as or correspond to the components described in the first embodiment will be described using the same reference numerals as those in the first embodiment.

  The PON-IF unit 7b includes a failure detection unit 11, an optical transceiver 12, a CPU 13, a memory 14, a communication control unit 18, a MUX / DEMUX unit 19, a bus 20, and a management unit 21 (monitoring unit). And a frame generation unit 22. That is, the PON-IF unit 7b is different from the PON-IF unit of the OLT 1 according to the first embodiment in that it includes a management unit 21 and a frame generation unit 22. However, in the PON-IF unit 7b, the signal from the CPU 13 and the frame generation unit 22 and the signal from the communication control unit 18 are multiplexed by the MUX / DEMUX unit 19. The standby PON interface unit and the optical switch unit 8 can communicate with each other via a control line.

  The control unit 6 periodically transmits and receives signals for confirming whether each component in the OLT is operating normally.

  The management unit 21 monitors the state of the control unit 6 by receiving a signal (management signal) periodically transmitted from the control unit 6.

  The frame generation unit 22 generates various frames. For example, when the management unit 21 detects a failure of the control unit 6, the frame generation unit 22 generates a failure notification frame that is an Ethernet (registered trademark) frame notifying that the control unit 6 has failed. The failure notification frame stores a predetermined specific SA and type for notifying the failure of the control unit 6. When a failure notification frame is transmitted from any of the PON-IF units 7b to the SW-IF unit 10, the SW-IF unit 10 that has received the failure notification frame transmits all of the PON-IF units 7b (active PON interface units). And a standby notification PON interface unit).

  The active PON interface unit that has received the failure notification frame from the SW-IF unit 10 determines that the standby PON interface unit performs the communication path switching process. The PON-IF unit 7b that has transmitted the failure notification frame is an Ethernet (registered trademark) frame that notifies that the control unit 6 has recovered when a signal is received from the control unit 6 after the control unit 6 has recovered. The failure recovery notification frame is transmitted to all the PON-IF units 7b via the SW-IF unit 10.

  FIG. 8 is a flowchart showing communication path switching processing in the OLT according to the second embodiment.

  The management unit 21 of the active PON interface unit (PON-IF unit # 1 in the present embodiment) monitors a reception signal from the control unit 6 (step S21).

  The management unit 21 of the PON-IF unit # 1 measures the reception interval of the reception signal from the control unit 6, and receives the signal from the control unit 6 before the elapse of a certain time t1 (predetermined time interval). (NO in step S22) and monitoring of the received signal from the control unit 6 is continued (return to step S21).

  The management unit 21 of the PON-IF unit # 1 measures the reception interval of the reception signal (management signal) from the control unit 6, and when the signal (management signal) from the control unit 6 cannot be received for a certain time t1 or more, It is determined that control unit 6 is out of order (YES in step S22).

  When the management unit 21 of the PON-IF unit # 1 detects the occurrence of a failure of the control unit 6, the PON-IF unit # 1 notifies the occurrence of the failure of the control unit 6 to the standby PON interface unit (step S23).

  For example, in the PON-IF unit # 1, when the management unit 21 detects a failure in the control unit 6, the frame generation unit 22 generates a failure notification frame. When the failure notification frame is transmitted from the PON-IF unit # 1 to the SW-IF unit 10, the SW-IF unit 10 that has received the failure notification frame receives all the PON-IF units 7b (the active PON interface unit and the standby PON interface unit). The failure notification frame is transmitted to the system PON interface unit).

  In steps S <b> 21 to S <b> 23, the management unit 21 of the standby PON interface unit may measure a reception interval of signals transmitted from the control unit 6 and determine a failure of the control unit 6.

  The failure detection unit 11 of each active PON-IF unit 7b monitors a communication failure in the PON system (step S24). If no communication failure is detected (NO in step S25), the communication failure is monitored again (step S24).

  When the failure detection unit 11 detects a communication failure, the PON-IF unit 7b (for example, the failure detection unit 11) that has detected the communication failure notifies the standby PON interface unit of the occurrence of the communication failure (YES in step S25). ).

  The standby PON interface unit selects the PON-IF unit 7b that is the target of the switching process from the PON-IF units 7b in which the occurrence of the failure is detected, and performs switching permission notification (transmission of switching permission notification) (step). S26). As a result, the PON-IF unit 7b that has received the switch permission notification is subject to the switching process of the communication path, so that it is possible to avoid duplicate switching when a plurality of active PON interface units fail simultaneously.

  In step S27, a switching process is executed between the active PON interface unit to be switched and the standby PON interface unit. The switching process in step S27 is the same as the process from steps S6 to S14 shown in FIG.

  The OLT according to the second embodiment has the same effect as the OLT 1 (including the modification) according to the first embodiment.

  In the first embodiment, the control unit 6 performs a switch notification when a communication failure occurs (step S3). In the second embodiment, the standby PON interface unit notifies a switch permission notification when a communication failure occurs. This is performed (step S26). As a result, even if a failure occurs in the control unit 6 and does not function, the standby PON interface unit can take the lead in starting a communication path switching process when a communication failure occurs. Therefore, even if a multiple failure occurs due to a failure in the optical fiber (for example, the trunk optical fiber 4a) and the optical transceiver 12, the standby PON interface unit selects the PON-IF unit 7b to be switched. Thus, it is possible to avoid duplication switching in a plurality of lines.

  Furthermore, according to the OLT according to the second embodiment, the start of the communication path switching process (for example, transmission of a switching permission notification) is led by the standby PON interface unit only during a period when the control unit 6 is out of order. Therefore, the main signal disconnection in the PON system can be avoided with the highest priority.

Embodiment 3 FIG.
FIG. 9 is a block diagram schematically showing the configuration of the standby PON interface unit 9a of the OLT according to the third embodiment. The standby PON interface unit 9a corresponds to the standby PON interface unit 9 (PON-IF unit # N + 1) of the OLT 1 according to the first embodiment. The working PON interface unit of the OLT according to the third embodiment is the same as the working PON interface unit 7 of the OLT 1 according to the first embodiment. The OLT according to the third embodiment can be applied to the PON system shown in FIG. 1 instead of the OLT 1 according to the first embodiment.

  In the third embodiment, components that are the same as or correspond to the components described in the first embodiment will be described using the same reference numerals as those described in the first embodiment.

  The standby PON interface unit 9a includes a failure detection unit 11, an optical transceiver 12, a CPU 13, a memory 14a, a communication control unit 18, a MUX / DEMUX unit 19, a bus 20, a management unit 21, and a frame. And a generation unit 22. That is, the configuration of the memory 14a of the standby PON interface unit 9a is different from the configuration of the memory 14 of the standby PON interface unit 9 of the OLT 1 according to the first embodiment. Further, the standby PON interface unit 9a includes the management unit 21 and the frame generation unit 22 described in the second embodiment. Except for these points, the second embodiment is the same as the first embodiment.

  The memory 14a stores data (takeover data) of each active PON interface unit 7. The memory 14a has at least one memory area 14b. That is, the data of the working PON interface unit 7 is stored in the memory area 14b. In the present embodiment, the memory 14a has the same number of memory areas 14b (# 1, # 2,..., #N) as the number of active PON interface units 7. That is, data of each corresponding active PON interface unit 7 is stored in each memory area 14b.

  In the third embodiment, the takeover data of each active PON interface unit 7 is transferred from each active PON interface unit 7 to the standby PON interface unit 9a at regular intervals, and stored in the memory 14a of the standby PON interface unit 9a. It is written in the memory area 14b (memory area 14b associated with each active PON interface unit 7) (hereinafter referred to as takeover data transfer processing). The takeover data transfer process will be specifically described below.

  FIG. 10 is a flowchart showing transfer processing of takeover data.

  The control unit 6 instructs each active PON interface unit 7 to perform data transfer (takeover data transfer processing) at regular intervals (step S31). The data transfer instruction may be given at different timings for each active PON interface unit 7.

  The working PON interface unit 7 that has received an instruction from the control unit 6 reads the data (takeover data) stored in the memory 14 by the DMA method and transmits the data to the standby PON interface unit 9a (step S32). The specific process in step S32 is the same as the process in step S6 shown in FIG. The working PON interface unit 7 that has received an instruction from the control unit 6 transfers the takeover data at regular time intervals, so that the difference data from the previously transmitted data is used as new takeover data to the standby PON interface unit 9a. You may send it.

  The standby PON interface unit 9a checks whether the received frame is normal (step S33).

  If the received frame is abnormal (NO in step S33), the standby PON interface unit 9a transmits NACK to the active PON interface unit 7 that transmitted the data (step S34).

  The active PON interface unit 7 that has received NACK returns to step S32 if the number of NACK receptions is less than a predetermined number (for example, less than N times; N is a natural number) (NO in step S35), The frame (takeover data) is retransmitted to the standby PON interface unit 9a. If the number of times NACK is received is equal to or greater than a predetermined number (for example, N times or more) (YES in step S35), control unit 6 performs initial setting (initialization) of working PON interface unit 7 that has received NACK. Is performed (step S36).

  In step S33, when the received frame is normal (YES in step S33), the standby PON interface unit 9a transmits ACK to the working PON interface unit 7 that has transmitted the takeover data in step S32. Further, the frame receiving unit 17 of the standby PON interface unit 9 a extracts data (write data) to be written in the memory 14 a from the received data (that is, takeover data) and transmits the data to the DMAC 15. The DMAC 15 writes the data transmitted from the frame receiving unit 17 in any memory area 14b of the memory 14a (step S37). The standby PON interface unit 9a writes data to the memory 14a, and then notifies the control unit 6 that the data transfer process has been completed.

FIG. 11 is a flowchart showing communication path switching processing in the OLT according to the third embodiment.
The processing from step S41 to S45 is the same as the processing from step S1 to S5 shown in FIG.

  In step S46, the CPU 13 of the standby PON interface unit 9a reads the data (takeover data) of the active PON interface unit 7 to be switched from the memory area 14b associated with the active PON interface unit 7 to be switched ( Step S46).

  In step S47, the CPU 13 of the standby PON interface unit 9a sets the standby PON interface unit 9a based on the data read from the memory area 14b. Specifically, the CPU 13 of the standby PON interface unit 9a performs the same setting as the setting of the active PON interface unit 7 to be switched for each component in the standby PON interface unit 9a (step S47). After the setting is completed, the standby PON interface unit 9a notifies the control unit 6 of the setting completion.

  The control unit 6 that has received the setting completion notification issues a light emission stop notification to the active PON interface unit 7 to be switched, and performs control to stop the light emission (communication) in the active PON interface unit 7. The control unit 6 transmits a switching notification to the optical switch unit 8 after confirming the stop of light emission of the active PON interface unit 7 to be switched. The optical switch unit 8 switches the communication path from the active PON interface unit 7 to be switched to the standby PON interface unit 9a. Similarly, the SW-IF unit 10 also switches the communication path (step S48).

  The control unit 6 transmits a light emission start notification to the standby PON interface unit 9a, and the standby PON interface unit 9a starts light emission (communication) and is based on the takeover data (transfer data) written in the memory 14a. Operation is performed (step S49).

  The communication path switching process is completed through the steps described above.

  The OLT according to the third embodiment has the same effect as the OLT 1 (including the modification) according to the first embodiment.

  Furthermore, according to the OLT according to the third embodiment, since the takeover data of each active PON interface unit 7 is written in advance in the memory 14a of the standby PON interface unit 9a before performing the communication path switching process, It is possible to shorten the time from reading of the takeover data in the system PON interface unit 7 to data writing in the standby PON interface unit 9a. As a result, it is possible to shorten the communication path switching processing time, and to quickly switch the communication path from the active PON interface unit 7 to the standby PON interface unit 9a.

  The features in the embodiments described above and the features in the modified examples can be combined as appropriate.

  1, 1a OLT, 2 ONU, 3 optical splitter, 4 optical fiber, 4a trunk optical fiber, 4b branch optical fiber, 6 control unit, 7, 7a, 7b working PON interface unit, 8 optical switch unit, 8a optical splitter, 8b optical switch, 9, 9a standby PON interface unit, 10 SW-IF unit, 11 failure detection unit, 12 optical transceiver, 13 CPU, 14, 14a memory, 14b memory area, 15 DMAC, 16 frame transmission unit, 17 Frame receiving unit, 18 communication control unit, 19 MUX / DEMUX unit, 20 bus, 21 management unit, 22 frame generation unit.

Claims (14)

An active interface unit for outputting communication signals;
A standby interface unit;
A control unit that transmits a switching control signal for controlling switching of a communication path of the communication signal between the working interface unit and the standby interface unit;
The working interface unit is
A first memory;
A first central processing unit that issues a data transfer instruction in accordance with the switching control signal from the control unit;
A first communication control unit configured with at least one hardware different from the first central processing unit;
When the communication path is switched, the first communication control unit reads the data stored in the first memory in accordance with the instruction from the first central processing unit, toward the standby interface unit. A communication device characterized by transferring.   The communication apparatus according to claim 1, wherein the first communication control unit includes a first control circuit that transfers the data by a direct memory access method. The first communication control unit has a frame transmission unit configured by hardware different from the first central processing unit,
The communication apparatus according to claim 2, wherein the frame transmission unit transfers the data input from the first control circuit. The active interface unit and the standby interface unit can communicate with each other by Ethernet,
The communication apparatus according to claim 3, wherein the frame transmission unit transfers the data input from the first control circuit using an Ethernet frame.   The communication apparatus according to claim 4, wherein the frame transmission unit assigns the priority of the Ethernet frame output from the active interface unit to the Ethernet frame. The active interface unit further includes a failure detection unit that detects the occurrence of a communication failure;
The communication apparatus according to any one of claims 1 to 5, wherein the failure detection unit notifies the control unit of the occurrence of the communication failure when the occurrence of the communication failure is detected. The working interface unit further includes a management unit that receives a management signal periodically transmitted from the control unit;
When the management unit cannot receive the management signal from the control unit, the active interface unit notifies the standby interface unit of the occurrence of a failure of the control unit,
The communication apparatus according to claim 1, wherein the standby system interface unit performs switching of the communication path together with the active system interface unit.   The communication apparatus according to any one of claims 1 to 7, wherein the working interface unit includes a first optical transceiver that performs transmission and reception of an optical signal as the communication signal. The standby interface unit is
A second memory;
A second central processing unit configured to set the standby interface unit based on data stored in the second memory;
A second communication control unit configured by at least one piece of hardware different from the second central processing unit;
The communication apparatus according to any one of claims 1 to 8, wherein the second communication control unit writes data received from the active interface unit to the second memory.   The communication apparatus according to claim 9, wherein the second communication control unit includes a second control circuit that writes the data by a direct memory access method. The second communication control unit includes a frame reception unit configured by hardware different from the second central processing unit,
The communication apparatus according to claim 10, wherein the frame reception unit transfers the data received from the active interface unit to the second control circuit. The second memory has at least one memory area in which the data transmitted from the active interface unit at regular intervals is written;
The active interface unit transmits data stored in the first memory to the standby interface unit at regular intervals;
When the communication path is switched, the second central processing unit reads the data stored in the at least one memory area, and the standby interface unit based on the data read from the memory area The communication device according to any one of claims 9 to 11, wherein the communication device is set.   The communication apparatus according to claim 9, wherein the standby interface unit includes a second optical transceiver that transmits and receives an optical signal as the communication signal. A communication path switching method in a communication system comprising a station side optical termination device having an active interface unit and a standby system interface unit, and a subscriber side optical termination device capable of communicating with the station side optical termination device,
The active interface unit includes a first memory, a first central processing unit, and a first control circuit configured by hardware different from the first central processing unit,
The standby interface unit includes a second memory, a second central processing unit, and a second control circuit configured by hardware different from the second central processing unit,
When switching the communication path from the active interface unit to the standby interface unit, the active interface unit reads the data stored in the first memory by the direct memory access method and the backup Transferring to the system interface unit,
In the standby interface unit, writing the data received from the active interface unit to the second memory by a direct memory access method;
A communication path switching method comprising: setting the standby interface unit based on the data written to the second memory.

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