JP2010028712A - Intra-station termination device, subscriber-side termination device and pon communication system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain a PON communication system which suppresses transmission band consumption due to a standby system while attaining speedy switching of communication paths. <P>SOLUTION: An intra-station termination device 1 comprises: a PON interface unit 10-1, 10-2 for transmitting a control frame, that contains the amount of transmission bands to be allocated, while system information and a destination identifier therein, and for extracting the system information and a transmission source identifier when a control frame containing the amount of stored data is received from a subscriber-side termination device 2, 3; and a system selection unit 12 which one transmission/reception path serves as an active system and the other path serves as a standby system and further switches the systems on the basis of the system information. The system selection unit 12 makes an instruction to mask the amount of stored data received from the standby system of the subscriber-side termination device 2, 3 and the PON interface unit 10-1, 10-2 calculates the amount of transmission bands to be allocated to the subscriber-side termination device 2, 3 on the basis of the amount of stored data not to be masked. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a PON communication system having a redundant PON (Passive Optical Network) configuration.

  As a conventional PON communication system, for example, IEEE 802.3ah (the following non-patent document 1) and ITU-T G. There is an optical passive network defined in 983.1 (the following Non-Patent Document 2). In a PON communication system, a plurality of subscriber-side terminators (ONU: Optical Network Termination) are connected to an optical coupler and an optical terminal with respect to an intra-station terminator (OLT: Optical Line Termination) installed on the station side. One-to-many connection is made using fiber.

  Further, in the following Non-Patent Document 2, as a redundant communication mode in the PON communication system, a method of making only the optical fiber of the communication path redundant, a method of making the optical fiber and OLT redundant, an optical fiber and OLT, and further ONU A method for redundancy is disclosed. Further, Non-Patent Document 2 discloses a method of using an OAM (Operations, Administration and Maintenance) function as a communication path switching method.

"IEEE 802.3ah" IEEE Computer Society 2004 "ITU-T Recommendation G.983.1" ITU 2005

  However, in the above-described conventional technique, in the path switching using the OAM function, the switching time is defined as 50 ms or less. For this reason, there is a problem that the switching is not quick considering the data interruption time. Each ONU transmits data at a time allocated from the OLT, but the OLT uses only operational data. For this reason, there is a problem in that useless bandwidth is consumed by transmission of standby data that is not actually used.

  The present invention has been made in view of the above, and in a redundant PON communication system, an intra-station termination device that realizes quick switching of a communication path and suppresses transmission band consumption by a standby system, and a subscription It is an object of the present invention to obtain a person-side terminal device and a PON communication system.

  In order to solve the above-described problems and achieve the object, the present invention is an intra-station termination apparatus in a PON communication system having a redundant configuration, and includes an active system or a control frame including a transmission band allocation amount. The system information indicating that it is a standby frame and the identifier unique to the destination subscriber-side terminating device are transmitted, and the control frame containing the amount of stored data and user data are multiplexed from the subscriber-side terminating device. Two systems of PON interface units that extract system information indicating that the frame is an active system or a standby system and an identifier unique to a transmission side subscriber-side terminal device from the control frame when the received multiplexed signal is received Provided, one transmission / reception path is the active system, the other transmission / reception path is the standby system, and the system associated with the extracted identifier is based on the extracted system information. A system selection unit that determines whether or not to switch, and the system selection unit further stores the amount of stored data included in the control frame so that a transmission band is not allocated to the standby system of the subscriber-side terminal device of the transmission source Each PON interface unit performs mask processing in accordance with an instruction from the system selection unit, and transmits each other stored data amount not subject to mask processing. A transmission band allocation amount corresponding to the amount of stored data is calculated for the terminal device.

  According to the present invention, it is possible to quickly switch the route and to suppress the transmission band consumption by the standby system.

  Embodiments of an intra-station termination device, a subscriber-side termination device, and a PON communication system according to the present invention will be described below in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

Embodiment 1 FIG.
FIG. 1 is a diagram showing a configuration example of a first embodiment of a PON communication system according to the present invention. The PON communication system of FIG. 1 includes an OLT (Intra-Station Termination Device) 1, an ONU (Subscriber Side Termination Device) 2, an ONU (Subscriber Side Termination Device) 3, optical couplers 4-1, 4-2, It comprises optical fibers 5-1, 5-2, 5-3, 5-4, 5-5 and 5-6, and interface units 6, 7 and 8.

  The OLT 1 includes PON interface units 10-1 and 10-2, a main signal data copy multiplexing unit 11, and a system selection unit 12. The PON interface unit 10-1 is an interface with the ONU 2 and the ONU 3, and is one redundant system (referred to as “0 system”). The PON interface unit 10-2 is an interface with the ONU 2 and the ONU 3, and is another redundant system (referred to as "1 system"). The main signal data copy multiplexing unit 11 copies the data from the network side and transfers it to each of the PON interface units 10-1 and 10-2. The received data is transferred to the network side. The system selection unit 12 selects a communication path to be used as the active system.

  The ONU 2 includes a 0-system unit unit 20-1, a 1-system unit unit 20-2, an abnormality detection unit 21, a system selection unit 22, and a common data buffer unit 23. The 0-system unit 20-1 is an interface with the OLT 1 and is a redundant system (referred to as "0 system"). The 1-system unit 20-2 is an interface with the OLT 1 and is another redundant system (referred to as "1 system"). The abnormality detection unit 21 detects an abnormality in the device or the communication path. The system selection unit 22 selects a communication path to be used as an active system. The common data buffer unit 23 accumulates data from the user network.

  Similarly, the ONU 3 includes a 0-system unit 30-1, a 1-system unit 30-2, an abnormality detection unit 31, a system selection unit 32, and a common data buffer unit 33. The 0-system unit 30-1 is an interface with the OLT 1 and is a redundant system (referred to as "0 system"). The 1-system unit 30-2 is an interface with the OLT 1 and is another redundant system (referred to as "1 system"). The abnormality detection unit 31 detects an abnormality of a device or a communication path. The system selection unit 32 selects a communication path to be used as an active system. The common data buffer unit 33 accumulates data from the user network.

  The optical couplers 4-1 and 4-2 are couplers that branch the communication path (optical fiber) from the OLT 1 to the ONU 2 and the ONU 3. Optical fibers 5-1, 5-2, 5-3, 5-4, 5-5 and 5-6 are communication paths in the present system. The interface unit 6 is an interface with the network side. The interface units 7 and 8 are interfaces with the user side.

  The PON interface unit 10-1 of the OLT 1 is connected to the ONU 2 via the optical fiber 5-1, the optical coupler 4-1, and the optical fiber 5-2, and communicates with the 0-system unit unit 20-1 of the ONU 2. The PON interface unit 10-1 of the OLT 1 is connected to the ONU 3 via the optical fiber 5-1, the optical coupler 4-1, and the optical fiber 5-3, and communicates with the 0 system unit unit 30-1 of the ONU 3. . Similarly, the PON interface unit 10-2 of the OLT 1 is connected to the ONU 2 via the optical fiber 5-4, the optical coupler 4-2, and the optical fiber 5-5, and communicates with the 1-system unit unit 20-2 of the ONU 2. Do. The PON interface unit 10-2 of the OLT 1 is connected to the ONU 3 through the optical fiber 5-4, the optical coupler 4-2, and the optical fiber 5-6, and communicates with the 1-system unit unit 30-2 of the ONU 3. .

  The PON interface units 10-1 and 10-2 of the OLT 1 have the same function. Further, the 0 system unit 20-1 and the 1 system unit 20-2 of the ONU 2 have the same function. Similarly, the 0 system unit 30-1 and the 1 system unit 30-2 of the ONU 3 have the same function. Here, the route in which the PON interface unit 10-1 of the OLT 1, the 0-system unit unit 20-1 of the ONU 2 and the 0-system unit unit 30-1 of the ONU 3 communicate with each other is referred to as an “operation system” used for transmission / reception of main data. To do. The “standby system” is used when the PON interface unit 10-2 of the OLT 1, the 1-system unit unit 20-2 of the ONU 2, and the 1-system unit unit 30-2 of the ONU 3 communicate with each other when a failure occurs in the operational system. "

  In the PON communication system, the OLT 1, the ONU 2, and the ONU 3 perform connection maintenance and transmission band control by transmitting and receiving a control MPCP (Multi-Point Control Protocol) frame defined in IEEE 802.3ah. FIG. 2 is a diagram illustrating a configuration example of an MPCP frame. Modebit is a BIT defined in IEEE 802.3ah. The LLID is a logical link identifier (LLID: Logical Link ID) indicating a destination ONU.

  In the present embodiment, “P_BIT” representing system information is added to the LLID area added to the MPCP frame. When P_BIT is “0”, it indicates a standby system, and when P_BIT is “1”, it indicates an active system. The MPCP frame includes a report frame in which the ONU notifies the OLT of the accumulated data amount, a GATE frame in which the OLT notifies the ONU of the transmission bandwidth allocation amount, and the OLT or ONU used for communication of information such as maintenance. There is an OAM frame.

  FIG. 3 is a diagram illustrating a configuration example of the OLT 1. The PON interface unit 10-1 includes a data buffer unit 13-1, an MPCP processing unit 14-1, a P_BIT processing unit 15-1, a report information adjustment unit 16-1, an allocated bandwidth calculation unit 17-1, Is provided. The data buffer unit 13-1 stores transmission data or reception data. The MPCP processing unit 14-1 extracts and inserts a frame related to access control. The P_BIT processing unit 15-1 detects and assigns P_BIT. The report information adjustment unit 16-1 adjusts the report information based on the system selection result of the system selection unit 12. The allocated bandwidth calculation unit 17-1 calculates the allocated amount of the transmission bandwidth to each ONU based on the adjusted report information.

  Similarly, the PON interface unit 10-2 includes a data buffer unit 13-2, an MPCP processing unit 14-2, a P_BIT processing unit 15-2, a report information adjustment unit 16-2, and an allocated bandwidth calculation unit 17-. 2 is provided. The configuration is the same as that of the PON interface unit 10-1, and the function of each component is the same as the function of each component of the corresponding PON interface unit 10-1.

  FIG. 4 is a diagram illustrating a configuration example of the system selection unit 12 of the OLT 1. The system selection unit 12 includes a P_BIT determination unit 40, a reception P_BIT detection unit 41, a transmission P_BIT selection unit 42, a P_BIT table unit 43, and an ONU link state monitoring unit 44. The P_BIT determination unit 40 determines whether to switch the system. Further, the processing of the report information is determined based on the P_BIT of the received report frame. The reception P_BIT detection unit 41 transfers the P_BIT information of the received frame (Report frame, OAM frame) to the P_BIT determination unit 40 and the P_BIT table unit 43. The transmission P_BIT selection unit 42 selects P_BIT to be added to a frame to be transmitted (GATE frame, OAM frame) and instructs the P_BIT processing units 15-1 and 15-2. The P_BIT table unit 43 is a table for registering P_BIT and the like of received frames. The ONU link status monitoring unit 44 monitors the status of connected ONUs and communication paths.

  FIG. 5 is a diagram illustrating a configuration example of the P_BIT table unit 43. The P_BIT table unit 43 includes an LLID, an active system, a 0-system reception P_BIT, a 1-system reception P_BIT, a 0-system transmission P_BIT, and a 1-system transmission P_BIT. The LLID indicates the connected ONU. Here, LLID “1” is ONU2 and LLID “2” is ONU3. The active system indicates a system that is operating when communicating with each connected ONU. The 0-system reception P_BIT indicates the P_BIT assigned to the frame received in the 0-system for each ONU. The 1-system reception P_BIT indicates the P_BIT assigned to the frame received by the 1-system for each ONU. 0-system transmission P_BIT indicates P_BIT assigned to a frame transmitted in the 0-system for each ONU. 1-system transmission P_BIT indicates P_BIT assigned to a frame transmitted in 1-system for each ONU.

  Here, two ONUs are connected. For example, when transmitting a frame to the ONU 2 whose LLID is “1”, the OLT 1 assigns P_BIT “1” to the 0-system frame based on the P_BIT table unit 43 and P_BIT “0” to the 1-system frame. Is given.

  FIG. 6 is a diagram illustrating a configuration example of the ONU 2. The 0-system unit unit 20-1 includes a P_BIT processing unit 24-1, an MPCP processing unit 25-1, and a report information generation unit 26-1. The P_BIT processing unit 24-1 detects and assigns P_BIT. The MPCP processing unit 25-1 extracts and inserts a frame related to access control. The report information generation unit 26-1 generates report information.

  Similarly, the 1-system unit 20-2 includes a P_BIT processing unit 24-2, an MPCP processing unit 25-2, and a report information generation unit 26-2. The configuration is the same as that of the 0-system unit 20-1, and the function of each component is the same as the function of each component of the corresponding 0-system unit 20-1. The ONU 3 also has the same configuration as the ONU 2. Hereinafter, the operation will be described using the ONU 2.

  Next, transmission / reception of data in the PON communication system of the present embodiment will be described. Here, it is assumed that communication is normally performed with the 0 system as the active system. In the data transmission (downlink transmission) from the OLT 1 to the ONU 2, first, the main signal data copy multiplexing unit 11 is connected to both the 0-system PON interface unit 10-1 and the 1-system PON interface unit 10-2. The user data from the side is copied and transferred. The data buffer units 13-1 and 13-2 transfer the received data to the corresponding MPCP processing units.

  The MPCP processing units 14-1 and 14-2 multiplex control frames such as GATE frames and OAM frames on user data. At this time, the MPCP processing units 14-1 and 14-2 assign and assign the same LLID to the LLID area other than the P_BIT information with the destination set as ONU2. Then, the MPCP processing units 14-1 and 14-2 transfer the multiplexed signals obtained by multiplexing the control frame to the user data to the corresponding P_BIT processing units.

  The P_BIT processing unit 15-1 adds P_BIT “1” to the multiplexed signal transferred from the MPCP processing unit 14-1, and transmits the multiplexed signal to the ONU 2. The P_BIT processing unit 15-2 adds P_BIT “0” to the multiplexed signal transferred from the MPCP processing unit 14-2 and transmits the multiplexed signal to the ONU 2.

  In the ONU 2, the P_BIT processing unit 24-1 confirms the LLID and P_BIT of the received multiplexed signal. Here, the received multiplexed signal is given an LLID destined for the own apparatus and P_BIT “1”. The P_BIT processing unit 24-1 transfers the received multiplexed signal to the MPCP processing unit 25-1. The MPCP processing unit 25-1 extracts a control frame from the received multiplexed signal and transfers user data to the common data buffer unit 23. Normal processing is performed for the control frame. The common data buffer unit 23 transfers the received user data to the user interface unit 7.

  On the other hand, the P_BIT processing unit 24-2 generates a flag indicating discard for the LLID multiplexed signal that is not addressed to the device itself or the multiplexed signal to which the standby P_BIT “0” is assigned. In this case, P_BIT “0” is assigned because the 1-system communication is a standby system. Therefore, the P_BIT processing unit 24-2 adds a flag indicating discarding to the received multiplexed signal and transfers it to the MPCP processing unit 25-2. The MPCP processing unit 25-2 extracts a control frame from the received multiplexed signal, and discards user data that the P_BIT processing unit 24-2 determines to discard. At this time, the MPCP processing unit 25-2 performs normal processing on the control frame addressed to the own device.

  Next, in data transmission (upstream transmission) from the ONU 2 to the OLT 1, the MPCP processing unit 25-1 uses the user data corresponding to the allocation amount from the common data buffer unit 23 according to the allocation amount notified by the GATE frame from the OLT 1. Is read. In addition, the MPCP processing unit 25-1 multiplexes a control frame such as a Report frame or an OAM frame with user data. At this time, the MPCP processing unit 25-1 assigns an LLID with the destination as OLT1. Then, the MPCP processing unit 25-1 transfers the multiplexed signal obtained by multiplexing the control frame to the user data to the P_BIT processing unit 24-1. Since the P_BIT processing unit 24-1 uses the 0 system as the active system, the P_BIT “1” is added to the multiplexed signal transferred from the MPCP processing unit 25-1, and is transmitted to the OLT 1.

  On the other hand, in the first system, which is the standby system, since a bandwidth for transmitting data is not allocated from the OLT 1, only the control frame is transmitted without transmitting data. The MPCP processing unit 25-2 generates a control frame such as a Report frame or an OAM frame. At this time, the MPCP processing unit 25-2 gives the same LLID as the MPCP processing unit 25-1 to the control frame. Then, the MPCP processing unit 25-2 transfers the control frame to the P_BIT processing unit 24-2. Since the P_BIT processing unit 24-2 uses the first system as the standby system, P_BIT “0” is added to the control frame transferred from the MPCP processing unit 25-2, and is transmitted to the OLT 1. The process of assigning the bandwidth by the OLT 1 will be described later.

  In OLT1, the P_BIT processing unit 15-1 confirms the LLID and P_BIT of the received multiplexed signal. Since the LLID of the received user data is addressed to the own apparatus and P_BIT is “1”, the P_BIT processing unit 15-1 transfers the received user data to the MPCP processing unit 14-1. The MPCP processing unit 14-1 extracts a control frame from the received multiplexed signal, and transfers user data to the data buffer unit 13-1. Also, normal processing is performed for the control frame. The data buffer unit 13-1 transfers the user data to the main signal data copy multiplexing unit 11. Finally, the main signal data copy multiplexing unit 11 transfers the user data to the interface unit 6 on the network side.

  The P_BIT processing unit 15-2 of the OLT 1 confirms the LLID and P_BIT of the received control frame. The P_BIT of the received control frame is “0”, but since the LLID is addressed to the own apparatus, the P_BIT processing unit 15-2 transfers the received control frame to the MPCP processing unit 14-2. The MPCP processing unit 14-2 performs normal processing on the control frame.

  Subsequently, processing of the MPCP frame will be described. In the IEEE 802.3ah PON communication system, it is specified that the ONU notifies the OLT of the accumulated data amount (Report information) by using a Report frame. In addition, it is defined that the OLT calculates the allocation amount of the transmission band to each ONU, and notifies the allocation amount to each ONU by a GATE frame.

  In the ONU 2 according to the present embodiment, the report information generation units 26-1 and 26-2 generate report information with reference to the common data buffer unit 23. Then, the P_BIT processing units 24-1 and 24-2 transmit a report frame including report information to the OLT 1. In the OLT 1, the allocated bandwidth calculation units 17-1 and 17-2 calculate the allocated amount of the transmission bandwidth to each ONU from the report information of each ONU. Then, the P_BIT processing units 15-1 and 15-2 transmit a GATE frame including allocation amount information to each ONU.

  FIG. 7 is a flowchart showing processing when the ONU 2 transmits a Report frame. In the ONU 2, when the report frame is transmitted from the active unit unit (step S1: Yes), the report information generation unit 26-1 refers to the common data buffer unit 23 and generates report information indicating the accumulated data amount. Then, the data is transferred to the MPCP processing unit 25-1. The MPCP processing unit 25-1 generates a Report frame including Report information and transfers it to the P_BIT processing unit 24-1. Here, it is confirmed whether there is an operational change instruction (step S2). As a case where the active system is changed, for example, there is a case where the abnormality detection unit 21 detects an abnormality of the own device or a communication path. When there is no instruction to change the active system (step S2: No), the system selection unit 22 instructs the P_BIT processing unit 24-1 to assign the “active system” P_BIT “1” as it is. Based on the instruction from the system selection unit 22, the P_BIT processing unit 24-1 adds P_BIT “1” to the report frame (step S3) and transmits the report frame to the OLT 1 (step S4).

  On the other hand, when there is an instruction to change the active system in the process of step S2 (step S2: Yes), the system selection unit 22 switches the system (step S5). That is, the system selection unit 22 sets the 0 system as the standby system and the 1 system as the active system. The system selection unit 22 instructs the P_BIT processing unit 24-1 to assign “standby system” P_BIT “0”. Based on the instruction from the system selection unit 22, the P_BIT processing unit 24-1 adds P_BIT “0” to the Report frame (step S6) and transmits the report frame to the OLT 1 (step S7).

  Next, when a report frame is transmitted from the standby unit (step S1: No), the report information generation unit 26-2 refers to the common data buffer unit 23 to generate report information, and the MPCP processing unit 25. -2. The MPCP processing unit 25-2 generates a Report frame including Report information and transfers it to the P_BIT processing unit 24-2. Here, it is confirmed whether there is an operational change instruction (step S8). If there is no change instruction for the active system (step S8: No), it is further confirmed whether the report frame to be transmitted is used for maintenance or setting (step S9). In the case of a Report frame that is not used for maintenance or the like (step S9: No), the system selection unit 22 instructs the P_BIT processing unit 24-2 to add the “standby system” P_BIT “0” as it is. Based on the instruction from the system selection unit 22, the P_BIT processing unit 24-2 adds P_BIT “0” to the Report frame (step S10) and transmits the report frame to the OLT 1 (step S11).

  In the case of a Report frame used for maintenance or the like in the process of step S9 (step S9: Yes), the system selection unit 22 gives P_BIT “1” of “operation system” to the P_BIT processing unit 24-2. Instruct to do. Based on the instruction from the system selection unit 22, the P_BIT processing unit 24-2 adds P_BIT “1” to the Report frame (step S12) and transmits the report frame to the OLT 1 (step S13).

  On the other hand, when there is an operation system change instruction in the process of step S8 (step S8: Yes), the system selection unit 22 switches the system (step S14). That is, the system selection unit 22 sets the 0 system as the standby system and the 1 system as the active system. The system selection unit 22 instructs the P_BIT processing unit 24-2 to assign the “active system” P_BIT “1”. Based on the instruction from the system selection unit 22, the P_BIT processing unit 24-2 adds P_BIT “1” to the Report frame (step S15) and transmits the report frame to the OLT 1 (step S16).

  Next, processing when the OLT 1 receives a report frame will be described. FIG. 8 is a flowchart showing processing when the OLT 1 receives a report frame.

  In the OLT 1, when the active PON interface unit 10-1 receives the report frame (step S21: Yes), the P_BIT processing unit 15-1 checks the P_BIT (step S22). The P_BIT processing unit 15-1 transfers the P_BIT information to the received P_BIT detection unit 41 of the system selection unit 12. The reception P_BIT detection unit 41 transfers the information of P_BIT to the P_BIT determination unit 40 and the P_BIT table unit 43. The P_BIT table unit 43 registers the received P_BIT information “1” in the column of the 0-system reception P_BIT with the LLID of 1 (ONU2). Further, the P_BIT processing unit 15-1 transfers the Report frame to the MPCP processing unit 14-1. The MPCP processing unit 14-1 extracts report information from the report frame and transfers the report information to the report information adjustment unit 16-1.

  Here, when the P_BIT of the received Report frame is “1” (step S22: Yes), the P_BIT determination unit 40 reports the report information as it is to the allocated bandwidth calculation unit 17-1, so that the report information adjustment unit 16 −1. The report information adjustment unit 16-1 receives the instruction from the P_BIT determination unit 40, and transfers the report information as it is to the allocated bandwidth calculation unit 17-1 (step S23).

  The allocated bandwidth calculation unit 17-1 calculates the allocated amount of bandwidth to the ONU 2 based on the report information from the ONU 2 and the report information from other ONUs (step S24), and the allocated amount is converted into the MPCP processing unit 14- Output to 1. The MPCP processing unit 14-1 generates a GATE frame for transmitting the allocation amount information to the ONU 2 (step S25), and transfers it to the P_BIT processing unit 15-1. Further, the transmission P_BIT selection unit 42 instructs the P_BIT processing unit 15-1 to add P_BIT “1” to the GATE frame to be transmitted based on the contents of the P_BIT table unit 43. The P_BIT processing unit 15-1 adds P_BIT “1” to the GATE frame and transmits it to the ONU 2 (step S26).

  Next, when the P_BIT of the received Report frame is “0” (step S22: No), the P_BIT determination unit 40 determines that the ONU 2 has detected an abnormality and switches the system (step S27). That is, the P_BIT determination unit 40 sets the 0 system as the standby system and the 1 system as the active system. Further, the P_BIT determination unit 40 rewrites the contents of the P_BIT table unit 43. Specifically, in the column where the LLID indicating the ONU 2 is 1, the active system is “1”, the 0 system transmission P_BIT is “0”, and the 1 system transmission P_BIT is “1”.

  In addition, since the report information of the report frame received in the standby system is not used as information for calculating the bandwidth allocation amount, the P_BIT determination unit 40 sends all report information to the report information adjustment unit 16-1. Is masked and transferred to the allocated bandwidth calculation unit 17-1. The report information adjustment unit 16-1 receives an instruction from the P_BIT determination unit 40, masks all of the report information, and transfers the masked information to the allocated bandwidth calculation unit 17-1 (step S28).

  The masking means processing for setting the value of Report information to “0”. When calculating the bandwidth allocation amount, the allocated bandwidth calculation unit 17-1 does not handle the masked report information as the data storage amount, but calculates the allocation amount based on the report information of other ONUs.

  The allocated bandwidth calculation unit 17-1 calculates a bandwidth allocation amount based on the report information of the ONU other than the masked report information (step S24), and outputs it to the MPCP processing unit 14-1. The allocation amount to ONU 2 at this time is “0”. The MPCP processing unit 14-1 generates a GATE frame for transmitting the allocation amount information to the ONU 2 (step S25). The data is sent to the P_BIT processing unit 15-1. The transmission P_BIT selection unit 42 instructs the P_BIT processing unit 15-1 to give P_BIT “0” to the GATE frame to be transmitted based on the contents of the P_BIT table unit 43. This is because the transmission P_BIT selection unit 42 gives an instruction to assign P_BIT “0” based on the contents of the rewritten P_BIT table unit 43. The P_BIT processing unit 15-1 adds P_BIT “0” to the GATE frame and transmits it to the ONU 2 (step S26). Note that the case where the P_BIT determination unit 40 switches systems in step S27 includes the case where the ONU link state monitoring unit 44 detects an abnormality in the communication path or the like.

  Next, when the standby PON interface unit 10-2 receives the Report frame (step S21: No), the P_BIT processing unit 15-2 checks the P_BIT (step S29). The P_BIT processing unit 15-2 transfers the information of P_BIT to the reception P_BIT detection unit 41 of the system selection unit 12. The reception P_BIT detection unit 41 transfers the information of P_BIT to the P_BIT determination unit 40 and the P_BIT table unit 43. The P_BIT table unit 43 registers the received P_BIT information in the 1-system received P_BIT column with the LLID of 1 (ONU2). Further, the P_BIT processing unit 15-2 transfers the Report frame to the MPCP processing unit 14-2. The MPCP processing unit 14-2 extracts the report information from the report frame, and transfers the report information to the report information adjustment unit 16-2.

  Here, when the P_BIT of the received Report frame is “1” (step S29: Yes), the P_BIT determination unit 40 rewrites the 1-system transmission P_BIT column of the P_BIT table unit 43 to “1”, and further, the operation system In step S30, it is confirmed whether the system has been switched. If the system has been switched in the active system (step S30: Yes), the P_BIT determination unit 40 instructs the report information adjustment unit 16-2 to transfer the report information as it is to the allocated bandwidth calculation unit 17-2. To do. The report information adjustment unit 16-2 receives the instruction from the P_BIT determination unit 40, and transfers the report information as it is to the allocated bandwidth calculation unit 17-2 (step S31).

  Based on the report information from the ONU 2 and the report information from other ONUs, the allocated bandwidth calculation unit 17-2 calculates a bandwidth allocation amount to the ONU 2 (step S24), and the allocation amount is calculated by the MPCP processing unit 14-2. Output to. The MPCP processing unit 14-2 generates a GATE frame for transmitting the allocation amount information to the ONU 2 (step S25), and transfers it to the P_BIT processing unit 15-2. Based on the contents of the P_BIT table unit 43, the transmission P_BIT selection unit 42 instructs the P_BIT processing unit 15-2 to add P_BIT “1” to the GATE frame to be transmitted. The P_BIT processing unit 15-2 adds P_BIT “1” to the GATE frame and transmits it to the ONU 2 (step S26).

  Next, when the system is not switched in the active system (step S30: No), the P_BIT determination unit 40 further confirms whether or not the report frame is received in the active system (step S32). When the report frame is received in the active system (step S32: Yes), the P_BIT determination unit 40 masks a part of the report information and transfers the report information to the allocated bandwidth calculation unit 17-2. Direct to 16-2. As such a case, for example, there is a case where necessary data for maintenance or the like is transmitted in the standby system. The report information adjustment unit 16-2 masks a portion other than information necessary for maintenance or the like and transfers the masked portion to the allocated bandwidth calculation unit 17-2 (step S33).

  Based on the report information from the ONU 2 and the report information from other ONUs, the allocated bandwidth calculation unit 17-2 calculates a bandwidth allocation amount to the ONU 2 for information necessary for maintenance or the like (step S24). The allocated amount is output to the MPCP processing unit 14-2. The MPCP processing unit 14-2 generates a GATE frame for transmitting the allocation amount information to the ONU 2 (step S25). Transfer to the P_BIT processing unit 15-2. Based on the contents of the P_BIT table unit 43, the transmission P_BIT selection unit 42 instructs the P_BIT processing unit 15-2 to add P_BIT “1” to the GATE frame to be transmitted. The P_BIT processing unit 15-2 adds P_BIT “1” to the GATE frame and transmits it to the ONU 2 (step S26).

  Next, when the report frame is not received in the operational system (step S32: No), the P_BIT determination unit 40 determines that there is an abnormality in the ONU 2 and switches the system (step S34). That is, the P_BIT determination unit 40 sets the 0 system as the standby system and the 1 system as the active system. Further, the P_BIT determination unit 40 rewrites the contents of the P_BIT table unit 43. The contents to be rewritten are the same as in step S27. In this case, the P_BIT determination unit 40 instructs the report information adjustment unit 16-2 to transfer the report information as it is to the allocated bandwidth calculation unit 17-2. The report information adjustment unit 16-2 receives the instruction from the P_BIT determination unit 40, and transfers the report information as it is to the allocated bandwidth calculation unit 17-2 (step S35).

  Based on the report information from the ONU 2 and the report information from other ONUs, the allocated bandwidth calculation unit 17-2 calculates a bandwidth allocation amount to the ONU 2 (step S24), and the allocation amount is calculated by the MPCP processing unit 14-2. Output to. The MPCP processing unit 14-2 generates a GATE frame for transmitting the allocation amount information to the ONU 2 (step S25), and transfers it to the P_BIT processing unit 15-2. Based on the contents of the P_BIT table unit 43, the transmission P_BIT selection unit 42 instructs the P_BIT processing unit 15-2 to add P_BIT “1” to the GATE frame to be transmitted. The P_BIT processing unit 15-2 adds P_BIT “1” to the GATE frame and transmits it to the ONU 2 (step S26).

  Next, when the P_BIT of the received report frame is “0” (step S29: No), the P_BIT determination unit 40 masks all of the report information and transfers the report information to the allocated bandwidth calculation unit 17-2. An instruction is given to the information adjustment unit 16-2. The report information adjustment unit 16-2 receives an instruction from the P_BIT determination unit 40, masks all of the report information, and transfers the masked information to the allocated bandwidth calculation unit 17-2 (step S36).

  The allocated bandwidth calculation unit 17-2 calculates a bandwidth allocation amount based on the report information of other ONUs (step S24), and outputs it to the MPCP processing unit 14-2. The allocation amount to ONU 2 at this time is “0”. The MPCP processing unit 14-2 generates a GATE frame for transmitting the allocation amount information to the ONU 2 (step S25). The data is sent to the P_BIT processing unit 15-2. The transmission P_BIT selection unit 42 instructs the P_BIT processing unit 15-2 to add P_BIT “0” to the GATE frame to be transmitted based on the contents of the P_BIT table unit 43. The P_BIT processing unit 15-2 adds P_BIT “0” to the GATE frame and transmits it to the ONU 2 (step S26).

  FIG. 9 is a diagram illustrating the correspondence of the P_BIT determination unit 40 to the P_BIT value of the Report frame received by the active system and the standby system. Here, the P_BIT assigned to the received Report frame indicates how the active system and standby system handle the report information. For example, when a report frame of P_BIT “0” is received in the active system, the P_BIT determination unit 40 instructs the report information adjustment unit 16-1 (or 16-2) to mask all report information. . That is, when calculating the allocation amount of the transmission band, the report information is not handled as the remaining data amount of the ONU 2. When the report frame of P_BIT “1” is received in the active system, the P_BIT determination unit 40 instructs the report information adjustment unit 16-1 (or 16-2) to use the report information as it is. When the P_BIT “0” report frame is received in the standby system, the P_BIT determination unit 40 instructs the report information adjustment unit 16-2 (or 16-1) to mask all report information. If the P_BIT “1” report frame is received in the standby system, the P_BIT determination unit 40 instructs the report information adjustment unit 16-2 (or 16-1) to use the report information as it is. Or, it is instructed to mask a part of the report information.

  FIG. 10 is a sequence diagram showing processing at the time of system switching due to the occurrence of a failure, and shows the exchange between the OLT 1 and the ONU 2 devices. Here, it is assumed that the communication is normally performed with the 0 system as the active system. The ONU 2 confirms the remaining data in the common data buffer unit 23 and transmits a Report frame from the 0 system and the 1 system to the OLT 1. At this time, P_BIT “1” is assigned to the 0 system, and P_BIT “0” is assigned to the 1 system (step S41).

  The OLT 1 receives the Report frame from the ONU 2, and the allocated bandwidth calculation units 17-1 and 17-2 calculate the allocated amount of the transmission bandwidth to the ONU 2. Here, since the 0 system is in operation, a band is allocated only to the 0 system and no band is allocated to the 1 system. Information on the allocated amount is transmitted in a GATE frame (step S42). The ONU 2 transmits data to the OLT 1 using the 0 system according to the allocation amount notified from the OLT 1. At this time, the remaining data in the common data buffer unit 23 is confirmed in both the 0 system and the 1 system, and the report frame is multiplexed and transmitted to the OLT 1 (step S43).

  The OLT 1 receives the data of the ONU 2. Similarly to step S42, the allocated bandwidth calculation units 17-1 and 17-2 calculate the allocated amount of the transmission bandwidth to the ONU 2. Since the 0 system is in operation, the bandwidth is assigned only to the 0 system and no bandwidth is assigned to the 1 system. The allocated amount is transmitted by a GATE frame (step S44). At this time, if a failure occurs in the 0-system communication path, the ONU 2 can receive the 1-system GATE frame, but cannot receive the 0-system GATE frame. , It detects that no optical signal is input in the 0 system, and notifies the system selection unit 22 of the abnormality. Then, the system selection unit 22 changes the P_BIT of the Report frame to be transmitted in accordance with the flowchart of FIG. 7, and the ONU 2 sets the P_BIT of the 1 system that was the standby system to “1” and transmits the Report frame to the OLT 1. (Step S45).

  In the OLT 1, when a report frame of P_BIT “1” is received in the first system, the P_BIT processing unit 15-2 detects the P_BIT information and notifies the system selection unit 12. Here, the report information is adjusted according to the flowchart of FIG. The OLT 1 allocates a band with the 1 system as the active system. The 1-system P_BIT processing unit 15-2 assigns P_BIT "1" indicating the active system to the GATE frame and transmits it to the ONU 2 (step S46). The ONU 2 receives the GATE frame of P_BIT “1” in the 1 system. Thereby, according to the allocation amount notified from OLT1, transmission of data is restarted by using the first system as the active system. At this time, the remaining data in the common data buffer unit 23 is confirmed in both the 0 system and the 1 system, and the Report frame is multiplexed and transmitted (step S47).

  As described above, in this embodiment, when the ONU detects a failure, the system status information (P_BIT) added to the LLID of the Report frame is updated and notified to the OLT. As a result, the OLT can immediately grasp the state of the system, and can quickly switch the path and assign the transmission band.

  The OLT assigns a transmission band for transmitting data only to the system used as the active system to each ONU. This makes it possible to effectively use the transmission band of the system.

Embodiment 2. FIG.
FIG. 11 is a flowchart showing processing when the OLT 1 receives a report frame. This embodiment is different from the first embodiment in the processing when the Report frame is received by the OLT 1. The configuration example of the system in the second embodiment is the same as that in the first embodiment. In the present embodiment, processing different from that of the first embodiment will be described.

  Hereinafter, characteristic processing of the second embodiment will be described. In the second embodiment, when the OLT 1 receives a report frame in the active system (step S21: Yes), it is confirmed whether there is a system switching instruction (step S50). When there is no system switching instruction (step S50: No), the process proceeds to step S22, and thereafter, the same processing as in the first embodiment is performed. On the other hand, when there is an instruction to switch the system (step S50: Yes), the process proceeds to step S27, and thereafter, the same processing as in the first embodiment is performed.

  The processing of the present embodiment is useful when switching routes led by OLT1. For example, this is effective when the connected ONUs are switched to the standby system all at once or individually for maintenance or the like.

  On the other hand, in the ONU, when the standby P_BIT “0” is added to the control frame received by the unit unit serving as the active system, the active P_BIT “1” is added to the control frame received by the unit unit serving as the standby system. If it has been assigned, or in both cases, the system is forcibly switched.

  As described above, in this embodiment, the route is switched by the OLT initiative. Thus, the OLT can easily switch the ONU to the standby system during maintenance or the like.

  As described above, the PON communication system according to the present invention is useful for a communication system having a redundant PON configuration, and is particularly suitable for a PON communication system that operates while switching between an active system and a standby system due to a failure or the like. Yes.

It is a figure which shows the structural example of a PON communication system. It is a figure which shows the structural example of a MPCP frame. It is a figure which shows the structural example of OLT. It is a figure which shows the structural example of a system selection part. It is a figure which shows the structural example of a P_BIT table part. It is a figure which shows the structural example of ONU. It is a flowchart which shows the process at the time of ONU Report frame transmission. 6 is a flowchart showing processing when an OLT Report frame is received in the first embodiment. It is a figure which shows the response | compatibility of Report information with respect to the received P_BIT value. It is a sequence diagram which shows the process of each apparatus at the time of system switching. 10 is a flowchart showing processing when an OLT report frame is received in the second embodiment.

Explanation of symbols

1 OLT (intra-station termination equipment)
2 ONU (Subscriber-side terminal equipment)
3 ONU (Terminal equipment on the subscriber side)
4-1, 4-2 Optical coupler 5-1, 5-2, 5-3, 5-4, 5-5, 5-6 Optical fiber 6, 7, 8 Interface unit 10-1, 10-2 PON interface Unit 11 Main signal data copy multiplexing unit 12 System selection unit 13-1, 13-2 Data buffer unit 14-1, 14-2 MPCP processing unit 15-1, 15-2 P_BIT processing unit 16-1, 16-2 Report Information adjustment unit 17-1, 17-2 Allocation band calculation unit 20-10 0 unit unit 20-2 1 system unit 21 Abnormality detection unit 22 System selection unit 23 Common data buffer unit 24-1, 24-2 P_BIT processing Unit 25-1, 25-2 MPCP processing unit 26-1, 26-2 Report information generation unit 30-1 0 system unit 30-2 1 system unit 31 Abnormality detection unit 32 System selection unit 33 Common Tabaffa portion 40 P_BIT determination unit 41 receiving P_BIT detecting unit 42 transmits P_BIT selecting section 43 P_BIT table unit 44 ONU link status monitoring unit

Claims (12)

An intra-station termination device in a PON communication system having a redundant configuration,
A control frame including the allocated amount of transmission band is transmitted including system information indicating that it is an active system or standby system frame and an identifier unique to the destination subscriber side termination device. When receiving a multiplexed signal in which a control frame including the amount of stored data and user data are multiplexed from the device, system information indicating that the frame is an active system or a standby system, and the transmission source A PON interface unit that extracts an identifier unique to the terminal device on the subscriber side,
2 systems,
One transmission / reception path is the active system, the other transmission / reception path is the standby system,
Furthermore, a system selection unit that determines whether to switch the system associated with the extracted identifier based on the extracted system information;
With
The system selection unit further instructs to mask the information portion of the accumulated data amount included in the control frame so that a transmission band is not allocated to the standby system of the transmission source subscriber terminal device. Done
Each of the PON interface units performs mask processing in accordance with an instruction from the system selection unit, and stores the stored data for each subscriber-side terminal device that has transmitted another stored data amount that is not the target of mask processing. An intra-station terminating device that calculates an allocated amount of a transmission band according to a data amount.   When the active PON interface unit receives a control frame including the amount of accumulated data and the control frame includes system information indicating that it is an active frame, the subscriber-side terminal that transmitted the control frame The intra-station termination device according to claim 1, wherein the allocation amount calculation process for the device is executed.   When the active PON interface unit receives a control frame including the amount of stored data and the control frame includes system information indicating that it is a standby frame, it is associated with the identifier included in the control frame. The registered system is switched, the mask processing is performed in accordance with an instruction from the system selection unit, and a transmission band is not allocated to the standby system of the subscriber-side terminating device that has transmitted the control frame. The intra-station termination device according to claim 1 or 2.   The standby PON interface unit receives a control frame including the amount of stored data, and the control frame includes system information indicating that it is an active system frame, and the subscriber side corresponding to the identifier included in the control frame 4. The intra-station termination device according to claim 1, 2 or 3, wherein when the system is switched in the termination device, the allocation amount calculation process for the subscriber-side termination device is executed.   The standby PON interface unit receives a control frame including the amount of stored data, and the control frame includes system information indicating that it is an active system frame, and the subscriber side corresponding to the identifier included in the control frame When the system is not switched in the terminating device, and the control frame including the accumulated data amount is received by the active PON interface unit, the transmission that can transmit the necessary data amount to the subscriber-side terminating device. 5. The intra-station termination device according to claim 1, wherein a control frame including a bandwidth allocation amount is transmitted.   The standby PON interface unit receives a control frame including the amount of stored data, and the control frame includes system information indicating that it is an active system frame, and the subscriber side corresponding to the identifier included in the control frame If the system is not switched in the termination device and the control frame including the accumulated data amount is not received by the PON interface unit of the active system, the system registered in association with the identifier is switched, and the subscriber-side termination The intra-station termination apparatus according to claim 1, wherein the allocation amount calculation process for the apparatus is executed.   When the standby PON interface unit receives a control frame including the amount of accumulated data, and the control frame includes system information indicating that it is a standby frame, the mask is set according to an instruction from the system selection unit. The intra-station termination device according to any one of claims 1 to 6, wherein a transmission band is not allocated to a standby system of a subscriber-side termination device that performs processing and transmits the control frame.   When the PON interface unit of the active system receives a control frame including the amount of stored data, and when there is a system switching instruction from the system selection unit, the system registered in association with the identifier included in the control frame is switched, 8. The transmission device according to claim 1, wherein the mask processing is performed in accordance with an instruction from the system selection unit, and a transmission band is not allocated to a standby system of a subscriber-side terminal device that has transmitted the control frame. Intra-station termination equipment described in 1. A subscriber-side terminating device in a PON communication system having a redundant configuration,
Multiplex that multiplexes the control frame and user data by including the system information indicating that it is an active or standby frame and an identifier unique to the own device in the control frame including its own accumulated data amount A unit unit that can transmit a control signal that is addressed to the own device including the allocated amount of the transmission band from the intra-station termination device,
2 systems,
One transmission / reception path is the active system, the other transmission / reception path is the standby system,
Furthermore, a system selection unit that performs system switching when an abnormality in the operating system is detected,
With
The active unit unit multiplexes and transmits the data corresponding to the allocated amount of the transmission band included in the control frame received from the in-station terminating device, and the standby unit unit does not transmit the data. Subscriber-side termination device.   When the control frame received by the active unit part contains system information indicating that it is a standby frame, the control frame received by the standby unit part indicates that it is an active frame The subscriber-side terminating device according to claim 9, wherein the system is switched when information is included or when both are included. Intra-station termination device according to any one of claims 1 to 7,
A plurality of terminating devices on the subscriber side according to claim 9;
A PON communication system comprising: Intra-station termination device according to claim 8,
A plurality of terminal devices on the subscriber side according to claim 10;
A PON communication system comprising:

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