JP2009141888A - Pon-system station side device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain a passive optical network (PON) system station side device capable of providing fair service to a plurality of users. <P>SOLUTION: The device comprises a plurality of optical transceivers 111 that transmit/receive frames to/from an optical network unit (ONU); a plurality of network node interface (NNI) communication parts 115 that transmit/receive frames to/from an upper network; and a frame distributing part 114 that distributes the frames from the optical transceivers 111 to the plurality of NNI communication parts 115, wherein the frame distributing part 114 performs distribution so that the total of traffics in the minimum-guaranteed band to be distributed to each of the NNI communication parts 115 is uniform. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a PON system station side device used in a PON system in which one station side device and a plurality of subscriber side devices are connected in a one-to-many manner.

  Link aggregation is known as a method of performing frame transmission / reception using a plurality of physical ports (see, for example, Non-Patent Document 1). In conventional link aggregation, the frame distribution method is not clearly defined on condition that the frame order in the same stream (conversation) is guaranteed and the duplicate transmission of the same frame is prohibited. . However, (a) Source MAC address (source MAC (Media Access Control) address), (b) Destination MAC address (destination MAC address), (c) The reception port, (d) The type of destination address (individual or group MAC address) (destination MAC address type), (e) Ethernet (registered trademark) Length / Type value (ie, protocol identification) (Ether Type field), (f) Higher layer protocol information (eg, addressing (g) Combinations of the above (the above combination) are described as examples of identifiers used for frame allocation.

  In addition, a plurality of subscriber-side devices (hereinafter referred to as ONU (Optical Network Unit)) provided on the subscriber terminal side of each home or company, and a single station-side device (hereinafter referred to as OLT (hereinafter referred to as OLT) provided on the upper network side. Optical line terminal) is a PON (Passive Optical Network) system connected by an optical fiber and a splitter, and a plurality of subscriber data are collected and transmitted / received to / from the network by collecting a plurality of subscriber data and a plurality of subscribers. Non-concentrated transmission / reception means for individually transmitting / receiving data to / from the network, and path selection means for selecting one of the above by VLAN (Virtual Local Area Network) unit / LLID (Logical Link Identification) unit / ONU unit / protocol type unit To reduce infrastructure investment costs for optical access network construction It has been disclosed. Further, it is disclosed that reliability is improved by including a failure detection unit that detects a failure occurrence of a route selected by the route selection unit and a detour formation unit that forms a detour when a failure occurs. (For example, see Patent Document 1).

“IEEE Standards 802.3-2005”, 2005, IEEE (Institute of Electrical and Electronics Engineers) Computer Society JP 2007-60438 A

  However, according to the technique described in Non-Patent Document 1, in the case where a specific subscriber transmits a large amount of traffic, for example, when frame distribution is performed using a source MAC address as an identifier, the subscriber Traffic is concentrated on a specific network interface port. In addition, when a large number of subscribers concentrate on a specific service, for example, when frame distribution is performed using the Ether Type field as an identifier, the traffic from the subscriber is also concentrated on a specific network interface port. End up. As a result, in both cases, there is a problem that traffic communication from other subscribers distributed to the same network interface port is hindered, and a fair service cannot be provided to a plurality of users. .

  In the prior art described in Patent Document 1, the station side device mounts a plurality of PON interface boards that accommodate one PON interface, and collects data from the plurality of PON interface boards to one network interface port. And a non-concentrated transmission / reception means for transferring data from a subscriber to the network interface port of the PON interface board. is doing. For this reason, together with the multiplex control panel for performing concentrated transmission / reception, each PON interface panel requires two communication units for performing concentrated transmission / reception and non-concentrated communication, which increases the cost of the apparatus. There was a problem that it was.

  The present invention has been made in view of the above, and an object of the present invention is to obtain a PON system station side apparatus that can provide a fair service to a plurality of users. Another object of the present invention is to obtain a PON system station side device that can improve reliability while suppressing an increase in device cost.

  To achieve the above object, a PON system station side device according to the present invention is connected to one or more subscriber side devices in a PON (Passive Optical Network) system, and is connected between a host network and the subscriber side device. In the PON system station side apparatus that performs communication, a plurality of PON side interface means for transmitting and receiving frames to and from the subscriber side apparatus, and a plurality of network side interface means for transmitting and receiving frames to and from the higher level network, Frame distribution means for distributing frames from the PON side interface means to the plurality of network side interface means, wherein the frame distribution means is a sum of minimum guaranteed bandwidths of traffic distributed to the network side interface means Distribute the frames so that It is characterized by performing.

  According to the present invention, instead of the various fields of the frame, the minimum guaranteed bandwidth is used as the frame distribution identifier, and the frame distribution is performed so that the sum of the minimum guaranteed bandwidth of traffic distributed to each network interface port is equal. In addition, even for best-effort services that communicate using the surplus bandwidth obtained by subtracting the total guaranteed bandwidth from the transmission bandwidth of the network interface port, the surplus bandwidth between each network interface port is equalized. Therefore, there is an effect that a fair service can be provided to a plurality of users.

  Exemplary embodiments of a PON system station side apparatus according to the present invention will be explained below in detail with reference to the accompanying drawings. Note that the present invention is not limited to these embodiments.

Embodiment 1 FIG.
FIG. 1 is a block diagram schematically showing the configuration of a station side apparatus according to the present invention. In FIG. 1, the configuration of the PON system connected to the station side device (hereinafter referred to as OLT) 10 is also shown. First, the configuration of the PON system will be described. The PON system includes a plurality of subscriber side devices (hereinafter referred to as ONUs) to which OLTs 10 connected to the upper network side via layer 2 switches (hereinafter referred to as L2 switches) 50 and subscriber terminals such as homes and businesses are connected. 20) are connected to the optical fiber 30 via the splitter 40. The OLT 10 is connected to an OpS (Operation System) or CLI (Command Line Interface) (hereinafter referred to as an OpS / CLI device) 60 for instructing the OLT 10 from an operator, and performs monitoring and setting for the OLT 10. be able to.

  The OLT 10 includes one to a plurality of PON interface boards (hereinafter referred to as PON I / F boards) 11 serving as an interface between the ONU 20 connected to the optical fiber 30 via the splitter 40 and the upper network (L2 switch 50). A monitoring control board 12 that performs monitoring control of the entire OLT 10 based on information from the OpS / CLI device 60 that performs monitoring control management of the OLT 10.

  One PON I / F board 11 includes one to a plurality of PON interface ports (hereinafter referred to as PON ports) 14 and a plurality of network interface ports (hereinafter referred to as NNI ports; NNI: Network Node Interface) 15. It has. In addition, the OpS / CLI device 60 is connected to the monitoring control panel 12 via a dedicated communication cable or network. Here, as will be described later, the bandwidth control information for each LLID set between the OLT 10 and the ONU 20 is set for each PON I / F board 11 of the OLT 10 by the OpS / CLI device 60. Information input from the operator by the OpS / CLI device 60 is transferred from the monitoring control panel 12 to the PON I / F board 11 to be instructed via the communication bus 13 provided in the OLT 10.

  FIG. 2 is a block diagram showing in detail the configuration of the PON I / F board. The PON I / F board 11 includes an optical transceiver 111, a PON control unit 112, a MAC bridge unit 113, a frame distribution unit 114, an NNI communication unit 115, a monitoring control communication unit 116, and a PON side management table. A storage unit 117 and an NNI side management table storage unit 118 are provided.

  The optical transceiver 111 accommodates the PON port 14, and a case where a plurality of optical transceivers 111 are provided is shown here. A plurality of ONUs 20 are connected to the PON port 14 via the optical fiber 30 and the splitter 40. The optical transceiver 111 or the PON port 14 corresponds to the PON side interface means in the claims. The PON control unit 112 performs frame transmission / reception control and logical link (hereinafter referred to as LLID) control of each PON port 14.

  The MAC bridge unit 113 performs MAC learning of an upstream frame (a frame transmitted from the ONU 20 to the OLT 10) and distribution of a downstream frame (a frame transmitted from the OLT 10 to the ONU 20) based on the MAC learning.

  The frame distribution unit 114 transmits the upstream frame passed from the MAC bridge unit 113 to the PON side management table so that the total guaranteed minimum bandwidth of traffic distributed from the PON port 14 to the NNI port 15 is uniform among the NNI ports 15. Based on the storage unit 117, it is distributed to one NNI communication unit 115 among a plurality of NNI communication units 115. Further, when the bandwidth control information from the monitoring control panel 12 is stored in the PON side management table storage unit 117 via the monitoring control communication unit 116, the sum of the minimum guaranteed bandwidths assigned to the LLIDs distributed to the respective NNI ports 15 Are set to be equal for each LLID.

  The NNI communication unit 115 accommodates the NNI port 15 and transmits / receives a frame to / from the L2 switch 50 in FIG. Here, a case where a plurality of NNI communication units 115 (NNI ports 15) are provided is shown. The NNI communication unit 115 or the NNI port 15 corresponds to the network side interface means in the claims. The monitoring control communication unit 116 communicates with the monitoring control panel 12 and stores information transmitted from the monitoring control panel 12 in the PON side management table storage unit 117.

  The PON side management table storage unit 117 stores a PON side management table including allocated bandwidth information and a transfer destination for each LLID. This PON side management table is a table in which the transfer destinations of frames from each LLID are set so that the total guaranteed minimum bandwidth of traffic distributed from the PON port 14 to the NNI port 15 is equalized at each NNI port 15. It is. FIG. 3 is a diagram illustrating an example of the PON side management table. As shown in this figure, the PON side management table manages the maximum bandwidth, the minimum guaranteed bandwidth, and the transfer destination for each LLID for each PON port 14 of the PON I / F board 11.

  The NNI side management table storage unit 118 stores an NNI side management table, which is bandwidth information for each NNI port 15, based on the result of frame distribution by the frame distribution unit 114. FIG. 4 is a diagram illustrating an example of the NNI side management table. As shown in this figure, the NNI side management table manages the sum of the minimum guaranteed bandwidth set for the LLID assigned to the NNI port 15 for each NNI port 15 of the PON I / F board 11. Yes.

  Next, transfer destination determination processing of the OLT having such a configuration will be described with reference to the flowchart of FIG. First, in the LLID set between the OLT 10 and the ONU 20, individual band control information (maximum band, minimum guaranteed band) is set by the operator via the OpS / CLI device 60 (step S11). This setting includes information about which PON I / F board 11 of which OLT 10 is set. The bandwidth control information set by the OpS / CLI device 60 is sent to the monitoring control board 12 of the OLT 10, and the monitoring control board 12 transmits the bandwidth control information to the set PON I / F board 11. When the monitoring control communication unit 116 of the PON I / F board 11 receives the band control information, the information included in the band control information for the corresponding LLID in the PON side management table in the PON side management table storage unit 117 ( The maximum bandwidth and the minimum guaranteed bandwidth are stored (step S12). Here, as shown in FIG. 6, the transfer destination NNI port 15 of the PON side management table is not set, and as shown in FIG. 7, the minimum guaranteed bandwidth sum in the NNI side management table is initially set to 0. It is assumed that FIG. 6 is a diagram illustrating an example of the PON side management table immediately after the bandwidth control information is stored, and FIG. 7 is an example of the NNI side management table immediately after the bandwidth control information is stored in the PON side management table. FIG.

  Thereafter, the frame distribution unit 114 selects one LLID from all the LLIDs (step S13), and reads the minimum guaranteed bandwidth of the LLID from the PON side management table (step S14). Next, the NNI side management table is searched for the NNI port with the minimum minimum guaranteed bandwidth sum (step S15), and the searched NNI port is set as the transfer destination of the LLID selected in step S13 (step S16). When there are a plurality of NNI ports with the minimum sum of the minimum guaranteed bandwidths searched, one NNI port is selected based on a predetermined criterion, for example, selecting from the smallest identifier assigned to the NNI port. Is done. Thereafter, the PON side management table is updated (step S17). Specifically, the NNI port determined in step S16 is stored in the transfer destination corresponding to this LLID.

  Next, the frame distribution unit 114 also updates the NNI side management table (step S18). Specifically, for the NNI port determined in step S16, a value obtained by adding the minimum guaranteed bandwidth value of the LLID selected in step S13 to the minimum guaranteed bandwidth total value stored in the NNI side management table is newly added. Stored as the total minimum guaranteed bandwidth. Thereafter, it is determined whether transfer destinations have been determined for all LLIDs (step S19). If transfer destinations have not been determined for all LLIDs (No in step S19), the process returns to step S13, and The process is repeated. When the transfer destination is determined for all the LLIDs (Yes in step S19), the frame distribution process ends.

  Based on the transfer destination NNI port determined for each LLID in the PON side management table determined in this way, the frame distribution unit 114 converts the received uplink frame from one LLID to a plurality of NNI ports. Forward to one of them.

  According to the first embodiment, the frame allocating unit 114 uses the minimum guaranteed bandwidth of the LLID instead of the various fields of the conventional frame so that the sum of the minimum guaranteed bandwidths at the transfer destination NNI ports is equalized. Since the transfer destination NNI port is determined at the same time, a service requiring bandwidth guarantee can be provided to each LLID fairly. In addition, for the best effort type service that performs communication using the surplus bandwidth obtained by subtracting the sum of the minimum guaranteed bandwidth from the transmission bandwidth of the NNI port, the surplus bandwidth between the NNI ports 15 is equalized. On the other hand, there is also an effect that the best effort type service can be provided fairly. Further, unlike the prior art, no concentrated / non-concentrated transmission / reception means and multiple control panels are required, and the plurality of NNI ports 15 and the frame distribution unit 114 of each PON I / F panel 11 can be realized with an inexpensive circuit. As a result, an increase in the manufacturing cost of the apparatus can be suppressed.

Embodiment 2. FIG.
In the first embodiment, the transfer destination NNI port is determined for each LLID using the minimum guaranteed bandwidth of the LLID. In the second embodiment, a case where the transfer destination NNI port is determined for each ONU will be described.

  The configuration of the PON I / F board 11 of the OLT 10 of the second embodiment is the same as that of FIG. 2 of the first embodiment. However, in the second embodiment, the PON side management table managed by the PON side management table storage unit 117 is configured in units of ONUs 20, and the frame distribution unit 114 is stored in the PON side management table storage unit 117 in units of ONUs 20. The difference from the first embodiment is that the transfer destination in the PON side management table is determined. Since other configurations are the same as those of the first embodiment, the description thereof is omitted.

  FIG. 8 is a diagram illustrating an example of the second embodiment of the PON side management table. As shown in this figure, the PON side management table includes information on the maximum bandwidth, the minimum guaranteed bandwidth, and the transfer destination for each ONU 20 connected to the PON port 14 for each PON port 14 of the PON I / F board 11. Manage. Note that the maximum bandwidth and the minimum guaranteed bandwidth are actually the sum of the information of one to a plurality of LLIDs set in the ONU 20. That is, the transfer destination is managed using the sum of the minimum guaranteed bandwidths of one to a plurality of LLIDs that are grounded to the ONU 20.

  Next, transfer destination determination processing of the OLT having such a configuration will be described with reference to the flowchart of FIG. First, bandwidth control information (maximum bandwidth, minimum guaranteed bandwidth) set for each ONU 20 is set by the operator via the OpS / CLI device 60 (step S31). This bandwidth control information (maximum bandwidth, minimum guaranteed bandwidth) is the sum of the maximum bandwidth and the minimum guaranteed bandwidth of one to a plurality of LLIDs set in the ONU 20. This setting also includes information about which PON I / F board 11 of which OLT 10 is set. The bandwidth control information set by the OpS / CLI device 60 is received by the monitoring control communication unit 116 of the PON I / F board 11 via the monitoring control board 12 of the OLT 10. Thereafter, the supervisory control communication unit 116 stores the information (maximum bandwidth, minimum guaranteed bandwidth) included in the bandwidth control information in the corresponding ONU 20 of the PON side management table in the PON side management table storage portion 117 (step S32). Here, it is assumed that the transfer destination NNI port in the PON side management table is not set, and the minimum guaranteed bandwidth sum in the NNI side management table is initialized to 0.

  Thereafter, the frame distribution unit 114 selects one ONU 20 from all the ONUs 20 (step S33), and reads the minimum guaranteed bandwidth of the ONU 20 from the PON side management table (step S34). Next, the NNI side management table is searched for the NNI port with the minimum minimum guaranteed bandwidth sum (step S35), and the searched NNI port is set as the transfer destination of the ONU 20 selected in step S33 (step S36). If there are a plurality of NNI ports with the minimum sum of the minimum guaranteed bandwidths searched, one NNI port is selected based on a predetermined criterion.

  Thereafter, the PON side management table is updated (step S37). Specifically, the NNI port determined in step S36 is stored in the transfer destination corresponding to the ONU 20. Next, the frame distribution unit 114 also updates the NNI side management table (step S38). Specifically, for the NNI port determined in step S36, a value obtained by adding the value of the minimum guaranteed bandwidth of the ONU 20 to the value of the minimum guaranteed bandwidth total stored in the NNI side management table is a new minimum guaranteed bandwidth. Store as sum.

  Thereafter, it is determined whether transfer destinations have been determined for all ONUs 20 (step S39). If transfer destinations have not been determined for all ONUs 20 (No in step S39), the process returns to step S33, and the above description is made. The process is repeated. If the transfer destinations have been determined for all ONUs 20 (Yes in step S39), the frame distribution process ends.

  Based on the transfer destination NNI port determined for each ONU 20 in the PON side management table determined in this way, the frame distribution unit 114 converts the received upstream frame from one ONU 20 to a plurality of NNI ports. Forward to one of them.

  According to the second embodiment, the frame distribution unit 114 uses the minimum guaranteed bandwidth of the ONU 20 to determine the transfer destination NNI port so that the sum of the minimum guaranteed bandwidths at the transfer destination NNI port is equal. Therefore, the same effect as in the first embodiment can be obtained. Further, since the control target by the frame distribution unit 114 is not the LLID unit but the ONU 20 unit, the number of control targets can be reduced, and the process of determining the transfer destination NNI port by the frame distribution unit 114 can be simplified. It also has the effect of being able to.

Embodiment 3 FIG.
FIG. 10 is a block diagram showing in detail the configuration of the PON I / F board. The PON I / F board 11 is configured to further include a failure detection unit 119 for detecting the failure state of the NNI port 15 (NNI communication unit 115) in the configuration of FIG. 2 of the first embodiment. When this failure detection unit 119 detects an NNI port failure state change such as a link break or link recovery state of the NNI port 15, the NNI port whose state has changed with respect to the frame distribution unit 114 and the NNI port including the change contents Notify failure status change information. The failure detection unit 119 corresponds to the failure detection unit in the claims, and the NNI port failure state change information corresponds to the failure state change information in the claims.

  In addition, when receiving the NNI port failure state change information, the frame distribution unit 114 performs a process of redeciding the transfer destination of the PON side management table in the PON side management table storage unit 117 according to the change content. Since other components are the same as those in the first embodiment, description thereof is omitted.

  Next, transfer destination redetermination processing of the OLT having such a configuration will be described with reference to the flowchart of FIG. First, when a failure occurs in the NNI communication unit 115 by the failure detection unit 119 and a change in the NNI port failure state is detected, the NNI port failure state including the NNI communication unit 115 in which the failure has occurred and the content of the change. The change information is input to the frame distribution unit 114 (step S51). The frame distribution unit 114 searches the PON side management table for all LLIDs having the NNI port that is the failure occurrence port included in the NNI port failure state change information as a transfer destination (step S52), and searches for all the searched LLIDs. The sum A of the minimum guaranteed bandwidth is calculated (step S53). Although the PON side management table is used here, the sum A may be calculated using the minimum guaranteed bandwidth sum of all the NNI ports corresponding to the failed ports in the NNI side management table.

  Next, the minimum guaranteed bandwidth total B per remaining NNI port B = A / N is calculated using the NNI port number N excluding the failed port and the minimum guaranteed bandwidth total A calculated in step S53 (step S54). Thereafter, one of the LLIDs whose transfer destination is the failed port is selected from the PON side management table, and the minimum guaranteed bandwidth C is acquired (step S55). Further, one NNI port is selected from the remaining NNI ports, and the minimum guaranteed bandwidth total D is obtained from the NNI side management table (step S56). Then, the sum C + D of the minimum guaranteed bandwidth C of the LLID and the minimum guaranteed bandwidth total D of the NNI port is calculated (step S57).

  Then, it is determined whether the sum of the minimum guaranteed bandwidth C of the LLID and the minimum guaranteed bandwidth total D of the NNI port does not exceed the minimum guaranteed bandwidth total B per remaining NNI port calculated in step S54 (step S54). S58). If the sum of the minimum guaranteed bandwidth C of the LLID and the minimum guaranteed bandwidth total D of the NNI port does not exceed the minimum guaranteed bandwidth total B per remaining NNI port (Yes in step S58), the NNI port is Then, a new transfer destination of the LLID is determined (step S59).

  On the other hand, if the sum of the minimum guaranteed bandwidth C of the LLID and the minimum guaranteed bandwidth total D of the NNI port exceeds the minimum guaranteed bandwidth total B per remaining NNI port (No in step S58), the NNI port It is determined whether all the remaining NNI ports have been selected without setting as a new transfer destination of the LLID (step S60). If all the remaining NNI ports have not been selected (No in step S60), the process returns to step S56. If all remaining NNI ports have been selected (Yes in step S60), the NNI port with the minimum minimum guaranteed bandwidth sum among the selected NNI ports is determined as the new transfer destination of the LLID (step S61). ).

  Thereafter or after step S59, the PON side management table is updated (step S62). Specifically, the NNI port determined in step S59 is stored in the transfer destination of the LLID in the PON side management table. Further, the NNI side management table is updated (step S63). Specifically, a value obtained by adding the value of the minimum guaranteed bandwidth of the NNI port to the value of the minimum guaranteed bandwidth of the NNI port determined in step S59 of the NNI side management table is stored as a new minimum guaranteed bandwidth total. Thereafter, it is determined whether transfer destinations have been determined for all LLIDs for which the transfer destination is a failed port (step S64). If transfer destinations have not been determined for all LLIDs for which the transfer destination is a failed port (step S64) In the case of No in S64), the process returns to step S55, and the above-described processing is repeatedly executed. Further, when the transfer destination is determined for all LLIDs whose transfer destination is the failure occurrence port (Yes in step S64), the value of the minimum guaranteed bandwidth sum is set to 0 for all failure occurrence ports in the NNI side management table. (Step S65). Thus, the transfer destination redetermination process ends.

  Based on the transfer destination NNI port determined for each LLID in the PON side management table determined in this way, the frame distribution unit 114 receives the received uplink frame from one LLID even after the NNI port failure occurs. Is transferred to any one of a plurality of NNI ports.

  Although the above description is for the case where the control target is LLID, the transfer destination NNI port can be re-determined by the same processing when the control target is ONU 20.

  According to the third embodiment, when an NNI port failure occurs, the transfer destination is re-determined for all LLIDs or ONUs 20 that have the failed NNI port as the transfer destination. In addition to this, it is possible to quickly distribute frames when a failure occurs, and to improve the reliability.

Embodiment 4 FIG.
In the third embodiment, the case where the transfer destination NNI port is re-determined when an NNI port failure occurs has been described. In the fourth embodiment, when the failure of the NNI port is recovered, the transfer destination NNI port is determined again. Will be described. Since the configuration of the PON I / F board 11 of the OLT 10 is the same as that of FIG. 10 of the third embodiment, description thereof will be omitted, and re-determination processing of the transfer destination NNI port different from that of the third embodiment will be described. .

  FIG. 12 is a flowchart illustrating an example of the procedure of the re-determination process of the transfer destination NNI port when the failure of the NNI port is recovered. First, when the failure of the NNI communication unit 115 in which the failure has occurred is recovered by the failure detection unit 119 and a change in the NNI port failure state is detected, the NNI communication unit 115 in which the failure has been recovered and the contents of the change are displayed. The included NNI port failure state change information is input to the frame distribution unit 114 (step S81). The NNI port failure state change information corresponds to the failure state change information in the claims. The frame distribution unit 114 calculates the sum E of the minimum guaranteed bandwidths of all the LLIDs using the PON side management table (step S82). Thereafter, using the number N of NNI ports in which no failure including the failure recovery port has occurred and the minimum guaranteed bandwidth total E calculated in step S82, the minimum guaranteed bandwidth total F = E / N per NNI port is calculated. Calculate (step S83).

  Next, one of the NNI ports other than the failure recovery port is selected, and the minimum guaranteed bandwidth sum G of the NNI port is acquired (step S84). Then, using the minimum guaranteed bandwidth total F per NNI port calculated in step S83, the minimum guaranteed bandwidth total H = G−F to be distributed to the failure recovery port is calculated (step S85).

  Next, one or a plurality of LLIDs are selected from LLIDs that use this NNI port as the transfer destination NNI port (step S86). Here, with respect to one or a plurality of LLIDs to be selected, the sum of the minimum guaranteed bandwidths of the selected LLIDs is as close as possible within a range that does not exceed the minimum guaranteed bandwidth total H allocated to the failure recovery port calculated in step S85. Like that.

  Thereafter, the PON side management table is updated (step S87). Specifically, the failure recovery port is stored as the transfer destination of the LLID selected in the PON side management table. Next, the NNI side management table is updated (step S88). Specifically, the value of the minimum guaranteed bandwidth of the selected LLID is added to the value of the total guaranteed minimum bandwidth of the failure recovery port in the NNI side management table and stored.

  After that, it is determined whether all NNI ports other than the failure recovery port have been distributed (step S89). If all NNI ports have not been distributed (No in step S89), Returning to step S84, the above-described processing is repeatedly executed for the NNI port for which the distribution processing is not performed. If the distribution process has been performed for all the NNI ports (Yes in step S89), the transfer destination NNI port redetermination process at the time of recovery from the failure of the NNI port ends.

  Based on the transfer destination NNI port determined for each LLID in the PON side management table determined in this way, the frame distribution unit 114 receives the received uplink frame from one LLID even after the NNI port failure recovery. Is transferred to any one of a plurality of NNI ports.

  Although the above description is for the case where the control target is LLID, the transfer destination NNI port can be re-determined by the same processing when the control target is ONU 20.

  According to the fourth embodiment, when the failure of the NNI port is recovered, the transfer destination is assigned to the recovered NNI port so that the LLID or the ONU 20 is distributed to the recovered NNI port so that the total sum of the minimum guaranteed bandwidth is equalized. Since re-determination is performed, in addition to the effect of the first embodiment, it is possible to quickly perform frame allocation at the time of failure recovery and to improve the reliability.

Embodiment 5 FIG.
In the third and fourth embodiments, the transfer destination NNI port is re-determined when an NNI port failure occurs or recovers, but in this fifth embodiment, one of the NNI ports is normally used for frame transmission / reception. A case will be described in which a transfer destination NNI port is re-determined when a failure occurs and when a failure is recovered when the standby port is not used.

  The configuration of the OLT PON I / F board 11 of the fifth embodiment is the same as that of the third embodiment shown in FIG. However, one of the plurality of NNI communication units 115 is set as a standby port so that it is not normally used for frame transmission / reception. Further, it is assumed that the failure detection unit 119 holds this standby port information. The operator can instruct from the OpS / CLI device 60 which NNI port (NNI communication unit 115) is the standby port. This standby port corresponds to the spare network side interface means in the claims.

  Next, an example of the procedure of the re-determination process of the transfer destination NNI port when a failure occurs in the OLT having such a configuration will be described. When a failure occurs in an NNI port other than the standby port, the failure detection unit 119 detects the failure, and the NNI port failure state change information including the NNI communication unit 115 in which the failure has occurred and the content of the change is included in the frame allocation. The minute unit 114 is notified. As a result, the frame distribution unit 114 selects a standby port as a new transfer destination NNI port for all LLIDs (or ONUs 20) that use the NNI port in which the failure is detected as the transfer destination NNI port. That is, the frame distribution unit 114 updates the transfer destination to the standby port for all LLIDs (or ONUs 20) having the failure port as the transfer destination in the PON side management table of the PON side management table storage unit 117. In the NNI side management table, the minimum guaranteed bandwidth sum of the failed ports is stored as the minimum guaranteed bandwidth sum of the standby ports, and the minimum guaranteed bandwidth sum of the failed ports is initialized to zero. As described above, the transfer destination NNI port redetermination process when a failure occurs in the NNI port is completed.

  In the above description, when a failure occurs, the transfer destination re-determination process from the standby port to the failure recovery port can be performed in the same manner when the failure is recovered. In the above description, the case of only one standby port is shown, but a plurality of standby ports may be prepared.

  According to the fifth embodiment, since the standby port that is not used in normal times is provided, when a failure occurs, the frame is quickly compared with the re-determination process of the transfer destination NNI port shown in the third and fourth embodiments. There is an effect that sorting can be performed.

  As described above, the PON system station-side device according to the present invention is useful for a PON system in which a plurality of subscriber-side devices and station-side devices are connected one-to-many.

It is a block diagram which shows typically the structure of the station side apparatus concerning this invention. It is a block diagram which shows the structure of a PON I / F board in detail. It is a figure which shows an example of the PON side management table. It is a figure which shows an example of the NNI side management table. 6 is a flowchart illustrating an example of a procedure according to the first embodiment of an OLT transfer destination determination process; It is a figure which shows an example of the PON side management table immediately after band control information is stored. It is a figure which shows an example of the NNI side management table immediately after band control information was stored in the PON side management table. It is a figure which shows an example of Embodiment 2 of a PON side management table. 10 is a flowchart illustrating an example of a procedure according to a second embodiment of an OLT transfer destination determination process. It is a block diagram which shows the structure of a PON I / F board in detail. 14 is a flowchart illustrating an example of a procedure according to a third embodiment of an OLT transfer destination redetermination process. 15 is a flowchart illustrating an example of a procedure according to a fourth embodiment of an OLT transfer destination redetermination process.

Explanation of symbols

10 Station side equipment (OLT)
11 PON I / F board (PON interface board)
12 Monitoring control panel 13 Communication bus 14 PON port 15 NNI port 20 Subscriber side device (ONU)
30 Optical fiber 40 Splitter 50 Switch 60 OpS / CLI device 111 Optical transceiver 112 Control unit 113 Bridge unit 114 Frame distribution unit 115 NNI communication unit 116 Monitoring control communication unit 117 PON side management table storage unit 118 NNI side management table storage unit 119 Fault detection unit

Claims (7)

In a PON system station-side device that is connected to one or more subscriber-side devices in a PON (Passive Optical Network) system and performs communication between a host network and the subscriber-side device,
A plurality of PON side interface means for transmitting and receiving frames to and from the subscriber side device;
A plurality of network side interface means for transmitting and receiving frames to and from the upper network;
Frame distribution means for distributing the frame from the PON side interface means to the plurality of network side interface means;
With
The PON system station side apparatus characterized in that the frame distribution means distributes the frames so that a total sum of minimum guaranteed bandwidths of traffic distributed to the network side interface means is equalized. It further comprises failure detection means for detecting a failure occurrence of the network side interface means,
When the frame distribution unit receives failure state change information including the network side interface unit in which the failure has occurred from the failure detection unit, the frame distribution unit sends to each operable network side interface unit excluding the network side interface unit in which the failure has occurred. 2. The PON system station side apparatus according to claim 1, further comprising a function of distributing the frames so that a total sum of minimum guaranteed bandwidths of traffic to be distributed is uniform. The failure detection means further comprises a function of detecting recovery from a failure of the network side interface means,
When the frame distribution means receives the failure state change information including the network side interface means recovered from the failure from the failure detection means, each of the operable network side interface means including the network side interface means recovered from the failure. 3. The PON system station side apparatus according to claim 2, further comprising a function of distributing the frames so that a total sum of minimum guaranteed bandwidths of traffic to be distributed is uniform. A predetermined number of network-side interface means among the network-side interface means are set as spare network-side interface means that are not used for frame transmission / reception during normal communication,
It further comprises failure detection means for detecting a failure occurrence of the network side interface means,
When the frame distribution unit receives the failure state change information including the network side interface unit in which the failure has occurred from the failure detection unit, the traffic distributed to the network side interface unit in which the failure has occurred is transferred to the spare network. The PON system station side device according to claim 1, further comprising a function of distributing to the side interface means. The failure detection means further comprises a function of detecting recovery from a failure of the network side interface means,
When the frame distribution unit receives the failure state change information including the network side interface unit recovered from the failure from the failure detection unit, the traffic distributed to the spare network side interface unit is transferred to the network recovered from the failure. 5. The PON system station side apparatus according to claim 4, further comprising a function of distributing to the side interface means.   The frame distribution means uses the minimum guaranteed bandwidth set for each logical link, and distributes the frames so that the sum of the minimum guaranteed bandwidths of traffic distributed to the network side interface means is uniform. The PON system station side device according to any one of claims 1 to 5, wherein:   The frame distribution means uses the sum of minimum guaranteed bands set for each of a plurality of logical links installed in the subscriber side apparatus, and uses the minimum guaranteed band of traffic distributed to the network side interface means. The PON system station side apparatus according to claim 1, wherein the frames are sorted so that the sum of the PONs is equal.

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