JP2020113877A - Pon station side device, management server, pon system, and method for managing subscriber line - Google Patents

Abstract

To provide a configuration and a method in a PON system, for allowing an apparatus that aggregates subscriber lines to be miniaturized and allow for communication between the apparatus and a higher-level device.SOLUTION: A PON station side device 3 includes: a relay apparatus 11 configured to be able to perform layer-2 communication; and a subscriber line aggregation apparatus 12 that is detachably attached to the relay apparatus 11, and is configured to aggregate subscriber lines and hold information on a subscriber terminal device connected to the subscriber lines. The relay apparatus 11 is configured to receive IP packets addressed to the subscriber line aggregation apparatus 12 through an IP network, decapsulate the received IP packets to generate frames, and transfer the frames to the subscriber line aggregation apparatus 12.SELECTED DRAWING: Figure 5

Description

The present invention relates to a PON station side device, a management server, a PON system, and a subscriber line management method.

A PON (Passive Optical Network) is composed of an OLT (Optical Line Terminal) and an ONU (Optical Network Unit). The OLT is an optical line terminal device on the side of a communication carrier and has a function of consolidating subscriber lines. The ONU is an optical line terminal device on the subscriber side.

In recent years, a system called a virtualized OLT (virtualized PON) has been studied. In this system, the network function of the conventional OLT is managed by an external server (for example (see Non-Patent Document 1)).

On the other hand, in the VDSL2 system, a configuration replacing the conventional VDSL aggregation device is under study. For example, an SFP (Small Form Factor Pluggable) module capable of VDSL2 communication by connecting to a general-purpose switch has been developed (Non-Patent Document 2).

Open Networking Foundation, [online], 2019, [searched on January 7, 2019], Internet <URL: https://www.opennetworking.org/voltha/> "Small Form-Factor Pluggable Long Reach Ethernet over VDSL2", [online], [January 7, 2019 Search], Internet <URL: https://www.comnet.net/comnet-products/accessories/sfp-vdsl >

Even in the virtualized PON disclosed in Non-Patent Document 1, it is conceivable to make the hardware of the OLT smaller than before. However, by reducing the size of the OLT, the components mounted on the OLT can be limited. Therefore, in the case of a downsized OLT, it is assumed that its function is limited. On the other hand, the function of collecting subscriber lines is necessary for the OLT. Therefore, in the downsized OLT, there is a possibility that the functions relating to the communication with the higher-level device may be limited as compared with the conventional OLT.

An object of the present invention is to provide a configuration and a method for enabling downsizing of a device that aggregates subscriber lines in a PON system and enabling communication between the device and a host device. It is to be.

A PON station side apparatus according to an aspect of the present invention is a relay device configured to enable communication at layer 2, and is attachable/detachable to/from the relay device, aggregates subscriber lines, and subscriber lines. And a subscriber line aggregation device configured to hold information about a subscriber terminal device connected to the. The relay device is configured to receive an IP packet addressed to the subscriber line aggregation device through the IP network, decapsulate the received IP packet to generate a frame, and transfer the frame to the subscriber line aggregation device. It

A management server according to an aspect of the present invention is a management server that manages a subscriber line aggregation device of a PON system. The subscriber line aggregation device is attachable/detachable to/from a relay device configured to be capable of layer 2 communication, aggregates subscriber lines, and is information on a subscriber terminal device connected to the subscriber line. Is configured to hold. The management server includes a subscriber line management unit that manages a subscriber line, and an IP encapsulation/decapsulation unit that is integrated with the subscriber line management unit or is provided separately from the subscriber line management unit. .. The IP encapsulation/decapsulation unit encapsulates a frame including control information regarding control of a subscriber line aggregation device, generates an IP packet, and transfers the IP packet to the IP network. The management server decapsulates the IP packet received via the IP network to generate a frame.

A PON system according to an aspect of the present invention is a relay device configured to be capable of layer 2 communication and detachable from the relay device, aggregates subscriber lines, and connects to the subscriber line. The subscriber line aggregation device configured to hold information regarding the subscriber terminal device, the subscriber terminal device, the IP network, and the management server. The management server generates a frame including control information regarding control of the subscriber line aggregation device, encapsulates the frame to generate an IP packet addressed to the subscriber line aggregation device, and transfers the IP packet to the IP network. The relay device receives the IP packet through the IP network, decapsulates the received IP packet to generate a frame, and transfers the frame to the subscriber line aggregation device.

A subscriber line management method according to an aspect of the present invention is a subscriber line management method performed by a PON station side device. The PON station side device is a relay device configured to enable layer 2 communication, and is attachable/detachable to/from the relay device, aggregates subscriber lines, and is a subscriber terminal connected to the subscriber line. A subscriber line aggregation device configured to retain information about the device. The management method includes a step in which the relay device receives, through the IP network, an IP packet addressed to the subscriber line aggregation device that includes control information regarding control of the subscriber line aggregation device; The method includes the steps of encapsulating and generating a frame including control information, and the relay device transferring the frame to the subscriber line aggregation device.

According to the above, in the PON system, it is possible to reduce the size of the device that aggregates the subscriber lines and to realize communication between the device and the host device.

It is a schematic configuration diagram of a PON system according to the present embodiment. 2 is a block diagram of a subscriber line aggregation device 12 shown in FIG. 1. FIG. FIG. 6 is a diagram showing an example of ONU information held by the subscriber line aggregation device 12. FIG. 2 is a schematic configuration diagram of an external server and a relay device shown in FIG. 1. It is a figure explaining transmission of data from an external server to a subscriber line aggregation device. It is a figure explaining transmission of data from a subscriber line aggregation device to an external server. It is a figure showing an example of an address correspondence table. It is a figure explaining the transmission from the external server of the frame which stored the multicast address based on this Embodiment. It is a figure explaining transmission from the subscriber line aggregation device of the frame which stored the multicast address based on this Embodiment. It is a figure explaining the data transfer by the relay apparatus to which the some subscriber line aggregation apparatus was connected. It is a sequence diagram explaining the 1st example of the process at the time of starting of the PON system which concerns on this Embodiment. It is a sequence diagram explaining the 2nd example of the process at the time of starting of the PON system which concerns on this Embodiment.

[Description of Embodiments of the Present Invention]
First, embodiments of the present invention will be listed and described.

(1) A PON station side device according to an aspect of the present invention is a relay device configured to be capable of layer 2 communication, and is attachable to and detachable from the relay device, consolidating subscriber lines, and And a subscriber line aggregation device configured to hold information about a subscriber terminal device connected to the subscriber line. The relay device is configured to receive an IP packet addressed to the subscriber line aggregation device through the IP network, decapsulate the received IP packet to generate a frame, and transfer the frame to the subscriber line aggregation device. It

According to the above, in the PON system, it is possible to reduce the size of the device that aggregates the subscriber lines and to realize communication between the device and the host device. The subscriber line aggregating device has a function of aggregating subscriber lines. Frames are transferred between the subscriber line aggregation device and the relay device. As a result, the subscriber line aggregation device does not need to have an IP stack. Therefore, the subscriber line aggregation device can be downsized. On the other hand, when the relay device receives the IP packet through the IP network, it is possible to realize communication with a device above the PON station side device, for example.

(2) Preferably, the frame includes control information regarding control of the subscriber line aggregation device.

According to the above configuration, the subscriber line aggregation device can be controlled according to the information included in the frame.

(3) Preferably, the subscriber line aggregation device generates a frame including information about the subscriber terminal device. The relay device encapsulates the frame from the subscriber line aggregation device to generate an IP packet, and transfers the generated IP packet to the IP network.

According to the above configuration, even if the subscriber line aggregation device does not have an IP stack, it is possible to transfer information regarding the subscriber terminal device to the IP network.

(4) Preferably, the relay device stores the IP address of the subscriber line aggregation device, the destination MAC address, and the destination IP address in association with each other, and when receiving the frame from the subscriber line aggregation device, From the destination MAC address stored in the frame, the destination IP address and the IP address of the subscriber line aggregation device are stored in an IP packet.

Based on the above, the relay device can generate an IP packet by encapsulating the frame from the subscriber line aggregation device. Therefore, the relay device can transfer the information from the subscriber line aggregation device to the destination specified by the IP address.

(5) Preferably, the destination IP address is the IP address assigned to the server that manages the subscriber line.

Based on the above, the information from the subscriber line aggregation device can be transferred to the server. The server can manage the subscriber line based on the information.

(6) Preferably, the relay device has a plurality of ports to which a plurality of subscriber line aggregation devices are respectively connected. The relay device refers to the MAC address table that associates the MAC addresses of the plurality of subscriber line aggregation devices with the plurality of ports, and sends the frame from the destination MAC address stored in the frame in which the IP packet is not encapsulated. Transfer to the subscriber line aggregation device corresponding to the MAC address.

According to the above, even when a plurality of subscriber line aggregation devices are connected to the relay device, the relay device selects the subscriber line aggregation device to which the frame is to be transferred from the plurality of subscriber line aggregation devices. Can be determined.

(7) A management server according to an aspect of the present invention is a management server that manages a subscriber line aggregation device of a PON system. The subscriber line aggregation device is attachable/detachable to/from a relay device configured to be capable of layer 2 communication, aggregates subscriber lines, and is information on a subscriber terminal device connected to the subscriber line. Is configured to hold. The management server includes a subscriber line management unit that manages a subscriber line, and an IP encapsulation/decapsulation unit that is integrated with the subscriber line management unit or is provided separately from the subscriber line management unit. .. The IP encapsulation/decapsulation unit encapsulates a frame including control information regarding control of a subscriber line aggregation device, generates an IP packet, and transfers the IP packet to the IP network. The management server decapsulates the IP packet received via the IP network to generate a frame.

According to the above, even if the subscriber line aggregation device does not have an IP stack, the management server can control the subscriber line aggregation device by transmitting control information to the subscriber line aggregation device. The management server can manage the subscriber line.

(8) A PON system according to an aspect of the present invention is a relay device configured to enable communication at layer 2, and is attachable to and detachable from the relay device, and aggregates subscriber lines, and A subscriber line aggregation device configured to hold information about a subscriber terminal device connected to a line, a subscriber terminal device, an IP network, and a management server. The management server generates a frame including control information regarding control of the subscriber line aggregation device, encapsulates the frame to generate an IP packet addressed to the subscriber line aggregation device, and transfers the IP packet to the IP network. The relay device receives the IP packet through the IP network, decapsulates the received IP packet to generate a frame, and transfers the frame to the subscriber line aggregation device.

According to the above, even if the subscriber line aggregation device does not have an IP stack, the management server can control the subscriber line aggregation device by transmitting control information to the subscriber line aggregation device.

(9) Preferably, the subscriber line aggregation device generates a frame including information about the subscriber terminal device. The relay device encapsulates the frame from the subscriber line aggregation device to generate an IP packet, and transfers the generated IP packet to the IP network. The management server decapsulates the IP packet received via the IP network to generate a frame, and extracts information about the subscriber terminal device from the frame.

According to the above, the information from the subscriber line aggregation device can be transferred to the management server. The management server can manage the subscriber line based on the information.

(10) A subscriber line management method according to an aspect of the present invention is a subscriber line management method by a PON station side device. The PON station side device is a relay device configured to enable layer 2 communication, and is attachable/detachable to/from the relay device, aggregates subscriber lines, and is a subscriber terminal connected to the subscriber line. A subscriber line aggregation device configured to retain information about the device. The management method includes a step in which the relay device receives, through the IP network, an IP packet addressed to the subscriber line aggregation device that includes control information regarding control of the subscriber line aggregation device; The method includes the steps of encapsulating and generating a frame including control information, and the relay device transferring the frame to the subscriber line aggregation device.

According to the above, even if the subscriber line aggregation device does not have the IP stack, the subscriber line aggregation device can receive the control information from the relay device. The subscriber line aggregation device can manage the subscriber line based on the information.

[Details of the embodiment of the present invention]
Embodiments of the present invention will be described below with reference to the drawings. The same or corresponding parts in the drawings are designated by the same reference numerals and description thereof will not be repeated. In the PON system, a device having a function of consolidating subscriber lines is referred to as a "PON station side device" in this specification. Further, the term “IP stack” used herein includes a program and a device that executes the program.

FIG. 1 is a schematic configuration diagram of a PON system according to the present embodiment. The PON system 100 according to the present embodiment includes an external server 1, an administrator network 2, a PON station side device 3, one or more ONUs (subscriber terminal devices), and a subscriber line 5. FIG. 1 illustrates three ONUs (ONUs 4A, 4B, 4C). However, the number of ONUs is not particularly limited as long as it is one or more.

The administrator network 2 is an IP network. Routers 8 and 9 are arranged on the administrator network 2. The external server 1 is connected to the router 8, and the PON station side device 3 is connected to the router 9. The administrator network 2 is a higher-level network for the PON station side device 3.

The PON station side device 3 includes a relay device 11 and a subscriber line aggregation device 12. The relay device 11 can be realized by a general-purpose relay device. For example, a general-purpose Ethernet (registered trademark) switch can be applied to the relay device 11.

The subscriber line aggregation device 12 may be a module having an OLT function. The subscriber line aggregation device 12 is connected to the port 13 of the relay device 11 and is attachable to and detachable from the relay device 11. The shape of the subscriber line aggregating apparatus 12 can be any shape that allows the subscriber line aggregating apparatus 12 to be attached to and detached from the port 13. The shape of the subscriber line aggregation device 12 can be determined according to the standard of the port 13. In one example, the subscriber line aggregation device 12 may have a shape conforming to SFP+.

Each of the ONUs 4A, 4B, 4C is an optical line terminal device installed on the subscriber side. The ONUs 4A, 4B and 4C are connected to the subscriber line aggregation equipment 12 via the subscriber lines 5A, 5B and 5C, respectively. In a general PON system, the subscriber line includes an optical transmission line connected to the OLT side, an optical transmission line 6 connected to each ONU, an optical transmission line on the OLT side, and an optical transmission line on each ONU side. It is composed of an optical splitter/combiner for connecting to the optical path. FIG. 1 shows a logical configuration of a subscriber line.

As shown in FIG. 1, the subscriber line aggregation device 12 aggregates a plurality of subscriber lines. On the other hand, the subscriber line aggregation device 12 does not have a function of managing the subscriber line. In this embodiment, the external server 1 manages the subscriber line. Therefore, the external server 1 functions as a management server. For this purpose, the external server 1 has a subscriber line management unit 21.

The subscriber line management unit 21 manages and controls a plurality of subscriber lines aggregated by the subscriber line aggregation device 12. The subscriber line management unit 21 is realized by the arithmetic unit of the external server 1 executing a software module.

FIG. 2 is a block diagram of the subscriber line aggregation device 12 shown in FIG. The subscriber line aggregation device 12 performs communication for managing the subscriber line with the external server 1 (see FIG. 1) via the relay device 11. In addition, the subscriber line aggregation device 12 executes data transmission/reception with the ONU and with the upper network.

The subscriber line aggregation device 12 includes a data transmission unit 121, a logical link management unit 122, a dynamic band allocation (DBA) unit 123, and an in-band management unit 124. The logical link management unit 122, the dynamic band allocation (DBA) unit 123, and the in-band management unit 124 may be integrated in one control circuit, for example. FIG. 2 shows an example in which the logical link management unit 122, the dynamic band allocation (DBA) unit 123, and the in-band management unit 124 are integrated in the control LSI 125.

The data transmission unit 121 converts the transmission data to the ONU into an optical signal and sends the optical signal to the optical transmission line 6. Further, the data transmission unit 121 receives the optical signal from the ONU via the optical transmission line 6 and reproduces the data from the optical signal. The logical link management unit 122 manages an LLID (Logical Link ID) assigned to each ONU. The DBA unit 123 executes upstream band allocation processing. The in-band management unit 124 executes in-band OAM (Operation Administration and Maintenance) management.

FIG. 3 is a diagram showing an example of ONU information held by the subscriber line aggregation device 12. The subscriber line aggregation device 12 can have information such as the maximum number of terminals that can be connected to the ONU, the filter condition in the ONU, the number of services provided by the ONU, and the VLAN used in the service. In the present embodiment, the ONU information held in the subscriber line aggregation device 12 is not limited to the information listed in FIG. The additional information may be held in the subscriber line aggregation device 12, and all or part of the information listed in FIG. 3 may be replaced with other information.

The subscriber line aggregation device 12 does not have an IP stack in order to achieve downsizing and low power consumption. Therefore, in order for the external server 1 to manage and control the subscriber line aggregating equipment 12, it is conceivable that the external server 1 and the subscriber line aggregating equipment 12 communicate at layer 2.

As an example, it is assumed that Layer2 Ethernet (registered trademark) OAM according to IEEE802.3ah is applied to the PON system 100. In this case, adjacent devices and all relay devices existing on the path between the external server 1 and the subscriber line aggregation device 12 must support Layer 2 Ethernet OAM. However, when a plurality of subscriber line aggregation devices 12 are connected to the relay device, the possibility that the external server 1 is adjacent to all the subscriber line aggregation devices 12 is very low. In addition, it is virtually impossible to replace all the relay equipment on the already constructed network with equipment that supports Layer 2 Ethernet OAM from the viewpoint of the cost of the carrier.

As another method, it is possible to construct a dedicated communication path between the external server 1 and the subscriber line aggregation device 12 by a spanning tree protocol according to IEEE802.1D and a VLAN. However, the spanning tree protocol is a per port control protocol. Therefore, this method may lack system flexibility.

In the present embodiment, the relay device 11 has an IP encapsulation/non-encapsulation function. Communication by the layer 3 is possible between the external server 1 and the PON station side device 3. The layer 2 communication is possible between the subscriber line aggregation device 12 and the relay device 11.

FIG. 4 is a schematic configuration diagram of the external server and the relay device shown in FIG. The relay device 11 includes an IP encapsulation/non-encapsulation unit 14. The external server 1 has an IP encapsulation/non-encapsulation unit 22 corresponding to the IP encapsulation/non-encapsulation unit 14. The IP encapsulation/decapsulation unit 22 may be provided inside the external server 1 separately from the subscriber line management unit 21. Alternatively, the IP encapsulation/decapsulation unit 22 may be included in the subscriber line management unit 21.

In the present embodiment, IP encapsulation is to add a IP header to a frame to generate a packet. Decapsulation is the generation of a frame by removing the IP header from the packet. Packets are transmitted between the external server 1 and the relay device 11. That is, the external server 1 and the relay device 11 can communicate at layer 3 (L3). On the other hand, a frame is transmitted between the relay device 11 and the subscriber line aggregation device 12. That is, the relay device 11 and the subscriber line aggregation device 12 communicate at layer 2 (L2).

The IP encapsulation/decapsulation units 14 and 22 allow the external server 1 and the subscriber line aggregation device 12 to communicate with each other even if the subscriber line aggregation device 12 does not have an IP stack.

The subscriber line aggregation device 12 sends the subscriber line information regarding the aggregated subscriber lines to the external server 1. This subscriber line information is information about the ONU and is sent to the subscriber line management unit 21 of the external server 1. On the other hand, the external server 1 sends, to the subscriber line aggregation device 12, control information regarding control of the subscriber line aggregation device 12. The subscriber line aggregation device 12 is controlled according to this control information. Therefore, the external server 1 can control the subscriber line aggregation device 12.

FIG. 5 is a diagram for explaining the transmission of data from the external server to the subscriber line aggregation device. As shown in FIG. 5, the relay device 11 assigns an IP address (denoted as “IP A”) to the subscriber line aggregation device 12.

The external server 1 (see FIG. 1) creates data to be sent to the subscriber line aggregation device 12. This data may include control information regarding control of the subscriber line aggregation device 12. The external server 1 adds the Ethernet header 32 to the data 31 to generate the frame 30. Generally, a frame includes a preamble and an FCS (Frame Check Sequence). However, in FIG. 5, the preamble and FCS are not shown in order to show the frame schematically.

The Ethernet header 32 stores the destination MAC address (DA) and the source MAC address (SA). DA is the MAC address of the subscriber line aggregation device 12, and SA is the MAC address of the external server 1. In FIG. 5 and the drawings described below, the MAC address of the subscriber line aggregation device 12 is represented as “device MAC”, and the MAC address of the external server 1 is represented as “server MAC”.

The IP encapsulation/decapsulation unit 22 of the external server 1 IP-encapsulates the frame 30 to generate the packet 35 (step S1). Specifically, the IP encapsulation/decapsulation unit 22 adds an IP header 33 and an Ethernet header 34 to the frame 30.

The IP header 33 includes a destination IP address (DA) and a source IP address (SA). DA is the IP address of the subscriber line aggregation device 12 (that is, "IP A"). SA is the IP address of the external server 1 (denoted as “server IP” in FIG. 5).

The destination MAC address (DA) of the Ethernet header 34 is the MAC address of the relay device 11. The source MAC address (SA) of the Ethernet header 34 is the MAC address of the adjacent relay device. The "adjacent relay device" is, for example, the router 9 shown in FIG.

The relay device 11 receives the packet 35 addressed to the IP address “IP A” from the external server 1 (step S2). The IP encapsulation/decapsulation unit 14 checks whether the received packet 35 is a packet addressed to the subscriber line aggregation device 12. Whether or not the packet 35 is a packet addressed to the subscriber line aggregation device 12 can be determined based on, for example, the information added to the IP header 33 or the IP data section.

When the packet 35 is a packet addressed to the subscriber line aggregation device 12, the IP encapsulation/decapsulation unit 14 decapsulates the packet 35 (step S3). That is, the IP encapsulation/decapsulation unit 14 removes the Ethernet header 34 and the IP header 33 from the packet 35. As a result, the original frame (frame 30) is transferred to the subscriber line aggregation device 12 (step S4).

FIG. 6 is a diagram for explaining the transmission of data from the subscriber line aggregation device to the external server. FIG. 6 shows a data flow in the opposite direction to the data flow shown in FIG. That is, in the data flow shown in FIG. 6, DA and SA are exchanged with respect to the flow shown in FIG.

As shown in FIG. 6, the subscriber line aggregation device 12 creates data to be sent to the external server 1. This data can include information about the subscriber line aggregated by the subscriber line aggregating device 12, or information about the ONU shown in FIG. The subscriber line aggregation device 12 adds the Ethernet header 42 to the data 41 to generate the frame 40. DA and SA stored in the Ethernet header 42 are the MAC address of the external server 1 (“server MAC”) and the MAC address of the subscriber line aggregation device 12 (“device MAC”), respectively.

The relay device 11 receives the frame 40 from the subscriber line aggregation device 12 (step S11). The IP encapsulation/decapsulation unit 14 IP-encapsulates the frame 40 to generate a packet 45 (step S12). That is, the IP capsule/non-encapsulation unit 14 adds the IP header 43 and the Ethernet header 44 to the frame 40. DA and SA stored in the IP header 43 are the IP address of the external server 1 (“server IP”) and the IP address of the subscriber line aggregation device 12 (“IP A”), respectively.

The IP encapsulation/decapsulation unit 14 may further add information (not shown) indicating that the frame 40 is encapsulated to the packet 45. The relay device 11 transfers the packet 45 to the external server 1 (step S13).

The IP encapsulation/decapsulation unit 14 stores an address correspondence table 15. When the IP encapsulation/non-encapsulation unit 14 encapsulates the frame 40, the IP encapsulation/non-encapsulation unit 14 refers to the address correspondence table and determines DA and SA stored in the IP header 43. ..

FIG. 7 is a diagram showing an example of the address correspondence table. The address correspondence table 15 stores the device IP, the destination IP address, and the destination MAC address, and associates the device IP, the destination IP address, and the destination MAC address with each other.

The IP encapsulation/decapsulation unit 14 refers to the DA stored in the Ethernet header 42 of the frame 40 and stores the destination IP address (“server IP”) in the DA of the IP header 43.

The address correspondence table 15 may be prepared in advance. Alternatively, the address correspondence table 15 may be dynamically created. In order to dynamically create the address correspondence table 15, the IP encapsulation/decapsulation unit 14 may create the address correspondence table 15 by extracting the MAC address and the IP address from the multicast message, for example.

Returning to FIG. 6, the external server 1 receives from the relay device 11 the packet 45 addressed to the IP address “server IP”. The IP encapsulation/decapsulation unit 22 checks whether the received packet 45 is a packet addressed to the external server 1. If the packet 45 is addressed to the external server 1, the IP encapsulation/decapsulation unit 22 decapsulates the packet 45 (step S14). That is, the IP encapsulation/decapsulation unit 22 removes the Ethernet header 44 and the IP header 43 from the packet 45. The original frame (frame 40) is transferred to the subscriber line management unit 21.

The examples shown in FIGS. 5 to 7 are examples of frame transmission by unicast. However, the present embodiment is not limited to this. As shown in FIGS. 8 and 9, this embodiment can be applied to the transmission of a multicast frame.

FIG. 8 is a diagram illustrating transmission of a frame storing a multicast address from an external server according to the present embodiment. Comparing FIG. 5 and FIG. 8, in the embodiment shown in FIG. 8, the reserved multicast address is set in the DA of the Ethernet header 32 of the frame 30. An example of the reserved multicast address can be represented as "01:80:C2:XX:XX:XX".

Also in this case, the IP encapsulation/non-encapsulation unit 22 of the external server 1 encapsulates the frame 30 and adds the IP header 33 to the frame 30. The IP header 33 stores the IP address (“IP A”) of the subscriber line aggregation device 12 as the destination IP address (DA). Therefore, the packet 35 can be transferred to the relay device 11. Similar to the flow shown in FIG. 5, the IP encapsulation/decapsulation unit 14 of the relay device 11 generates a frame 30 from the packet 35 and transfers the frame 30 to the subscriber line aggregation device 12.

FIG. 9 is a diagram for explaining transmission of a frame storing a multicast address from the subscriber line aggregation device according to the present embodiment. As shown in FIG. 9, a reserved multicast address (for example, “01:80:C2:XX:XX:XX”) may be stored in the DA of the Ethernet header 42 of the frame 40 from the subscriber line aggregation device 12. it can. The IP encapsulation/decapsulation unit 14 encapsulates the frame 40 and adds the IP header 43 and the Ethernet header 44 to the frame 40. The IP address of the external server 1 (server IP) is stored in the IP header 43 as the destination IP address (DA). Similar to the flow shown in FIG. 6, the IP encapsulation/decapsulation unit 14 of the relay device 11 generates a packet 45 from the frame 40 and transfers the packet 45 to the external server 1.

When encapsulating the frame 40, the IP encapsulation/decapsulation unit 14 refers to the address correspondence table 15 (see FIG. 7). The IP encapsulation/decapsulation unit 14 refers to the IP address (“IP A”) assigned to the subscriber line aggregation device 12 and the address correspondence table 15 to acquire the IP address of the external server 1. The IP encapsulation/non-encapsulation unit 14 stores the IP address in the IP header 43 as the destination address.

In the above embodiment, one subscriber line aggregation device is connected to the relay device 11. However, the configuration of the PON station side device 3 is not limited to this. As shown in FIG. 10, a plurality of subscriber line aggregation devices may be connected to the relay device 11. In the example shown in FIG. 10, the subscriber line aggregation devices 12A, 12B and 12C are connected to the ports 13A, 13B and 13C of the relay device 11, respectively.

In this configuration, one IP address (for example, "IP A" described above) is assigned to a plurality of subscriber line aggregation devices. The IP encapsulation/decapsulation unit 22 of the external server 1 IP-encapsulates the frame 30 to generate a packet 35. When this frame is a frame to be sent to the subscriber line aggregation device 12A, the Ethernet header 32 stores the MAC address of the subscriber line aggregation device 12A as the destination MAC address (DA). The MAC address of the subscriber line aggregation device 12A will be referred to as "device MAC(A)" in FIG.

The IP encapsulation/decapsulation unit 22 adds an IP header 33 and an Ethernet header 34 to the frame 30. The IP header 33 stores an IP address (“IP A”) commonly assigned to a plurality of subscriber line aggregation devices as a destination IP address (SA).

Similar to the form shown in FIG. 5 and the like, the packet 35 from the external server 1 is transferred to the relay device 11. The IP encapsulation/decapsulation unit 14 decapsulates the packet 35 to generate the frame 30.

The relay device 11 has a switch unit 16. The switch unit 16 stores the MAC address learning table 17. The MAC address learning table 17 associates the numbers of the ports 13A, 13B, and 13C with the MAC address of the subscriber line aggregation device connected to each port.

The switch unit 16 may learn the MAC address of the subscriber line aggregation device connected to the port according to a known method. In learning the MAC address of the subscriber line aggregation device, the switch unit 16 confirms the source MAC address (SA) in the header at the timing when the frame from the subscriber line aggregation device is received. The switch unit 16 associates the port number to which the frame is input with the SA, and registers the port number and SA in the MAC address learning table 17.

The switch unit 16 refers to the MAC address learning table 17 to determine the transfer destination of the frame 30 from the IP encapsulation/non-encapsulation unit 14. As described above, the Ethernet header 32 stores the MAC address of the subscriber line aggregation device 12A as the destination MAC address (DA). Therefore, the switch unit 16 transfers the frame 30 to the port (port 13A) to which the subscriber line aggregation device 12A is connected.

FIG. 11 is a sequence diagram illustrating a first example of processing at startup of the PON system according to this embodiment. “At startup” is a stage until the OLT module and the server can communicate with each other.

As shown in FIG. 11, before the subscriber line aggregation device 12 is inserted into the relay device 11, the IP address of the external server 1 is registered in the relay device 11 (step (1) shown in FIG. 11).

Next, the subscriber line aggregation device 12 is inserted into the port of the relay device 11. At this time, the subscriber line aggregation device 12 transmits a frame indicating that the subscriber line aggregation device 12 is Available. The relay device 11 IP-encapsulates the frame to generate a packet. Then, the relay device 11 transmits the packet by unicast to the external server 1 (steps (2) to (5) shown in FIG. 11).

The external server 1 receives the packet from the relay device 11 and decapsulates the packet. As a result, the external server 1 identifies the subscriber line aggregation device that is available. Then, the external server 1 starts communication with the subscriber line aggregation device (steps (6) to (7) shown in FIG. 11).

FIG. 12 is a sequence diagram illustrating a second example of processing at the time of starting up the PON system according to this embodiment. As shown in FIG. 12, before the subscriber line aggregation device 12 is inserted into the relay device 11, a mapping table that associates the IP address and the MAC address of the subscriber line aggregation device is registered in the external server 1 ( Step (1) shown in FIG.

Next, the external server 1 transmits Request regularly. The subscriber line aggregation device 12 is inserted into the port of the relay device 11 while the external server 1 periodically transmits the Request. Upon receiving the Request, the relay device 11 decapsulates the Request and transmits the Request to the subscriber line aggregation device (steps (2) to (4) shown in FIG. 12).

The subscriber line aggregation device 12 recognizes the server that controls the subscriber line aggregation device 12 by receiving the Request from the relay device 11. Then, the subscriber line aggregation device 12 starts communication with the external server 1 (step (5) shown in FIG. 12).

As described above, according to the present embodiment, an IP address is logically assigned in the relay device to a detachable device having the subscriber line aggregation function without the IP stack. The relay device IP-encapsulates the frame from the subscriber line aggregation device to generate an IP packet addressed to the external server. On the other hand, the relay device decapsulates the IP packet from the external server and generates a frame from the subscriber line aggregation device. As a result, the communication path from the subscriber line aggregation device to the external server can be flexibly configured. A general-purpose relay device can be used as the relay device 11.

The IP encapsulation/decapsulation function of the relay device 11 may be implemented when the PON station side device 3 is configured. Since this function itself is a general function of the relay device, a package is often prepared. Even if the relay device 11 does not originally have the IP encapsulation/non-encapsulation function, the relay device 11 has the IP encapsulation/decapsulation function by installing the package in the relay device 11. The device can be configured.

The embodiments disclosed this time are to be considered as illustrative in all points and not restrictive. The scope of the present invention is shown not by the above-described embodiments but by the scope of the claims, and is intended to include meanings equivalent to the scope of the claims and all modifications within the scope.

1 External Server 2 Administrator Network 3 Station Side Device 5, 5A, 5B, 5C Subscriber Line 6 Optical Transmission Line 8, 9 Router 11 Repeater 12, 12A, 12B, 12C Subscriber Line Aggregator 13, 13A, 13B, 13C port 14,22 IP encapsulation/non-encapsulation unit 15 address correspondence table 16 switch unit 17 MAC address learning table 21 subscriber line management unit 30,40 frame 31,41 data 32,34,42,44 Ethernet header 33, 43 IP header 35, 45 IP packet 100 PON system 121 Data transmission unit 122 Logical link management unit 123 Dynamic band allocation unit 124 In-band management unit 125 Control LSI
S1, S2, S3, S4, S11, S12, S13, S14 steps

Claims (10)

A relay device configured to enable communication at Layer 2,
A subscriber line aggregation device that is removable from the relay device, aggregates the subscriber lines, and is configured to hold information about subscriber terminal devices connected to the subscriber line. ,
The relay device receives an IP packet addressed to the subscriber line aggregation device through an IP network, decapsulates the received IP packet to generate a frame, and transfers the frame to the subscriber line aggregation device. PON station side device configured as follows. The PON station side apparatus according to claim 1, wherein the frame includes control information regarding control of the subscriber line aggregation device. The subscriber line aggregation device generates a frame including information about the subscriber terminal device,
The PON according to claim 1 or 2, wherein the relay device encapsulates the frame from the subscriber line aggregation device to generate an IP packet, and transfers the generated IP packet to the IP network. Station equipment. The relay device stores the IP address of the subscriber line aggregation device, the MAC address of the destination, and the IP address of the destination in association with each other, and when receiving the frame from the subscriber line aggregation device, The PON station side apparatus according to claim 3, wherein the destination IP address and the IP address of the subscriber line aggregation device are stored in the IP packet from the destination MAC address stored in a frame. The PON station side device according to claim 4, wherein the destination IP address is an IP address assigned to a server that manages the subscriber line. The relay device has a plurality of ports to which the plurality of subscriber line aggregation devices are respectively connected,
The relay device refers to a MAC address table that associates the MAC addresses of the plurality of subscriber line aggregation devices with the plurality of ports, and refers to a destination MAC address stored in a frame in which the IP packet is not encapsulated. 6. The PON station side device according to claim 1, wherein the frame is transferred from the device to the subscriber line aggregation device corresponding to the destination MAC address. A management server for managing subscriber line aggregation devices of the PON system,
The subscriber line aggregation device is attachable/detachable to/from a relay device configured to be capable of layer 2 communication, aggregates the subscriber lines, and is connected to the subscriber line terminal device. Configured to hold information about
The management server is
A subscriber line management unit that manages the subscriber line,
An IP encapsulation/decapsulation unit integrated with the subscriber line management unit or provided separately from the subscriber line management unit,
The IP encapsulation/non-encapsulation unit is
A frame including control information related to control of the subscriber line aggregation device is encapsulated to generate an IP packet, and the IP packet is transferred to an IP network;
A management server that decapsulates an IP packet received via the IP network to generate a frame. A relay device configured to enable communication at Layer 2,
A subscriber line aggregation device that is removable from the relay device, aggregates subscriber lines, and is configured to hold information about a subscriber terminal device connected to the subscriber line;
The subscriber terminal device,
IP network,
With a management server,
The management server generates a frame including control information related to control of the subscriber line aggregation device, encapsulates the frame to generate an IP packet addressed to the subscriber line aggregation device, and the IP packet Transfer to IP network,
The PON system, wherein the relay device receives the IP packet through the IP network, decapsulates the received IP packet to generate a frame, and transfers the frame to the subscriber line aggregation device. The subscriber line aggregation device generates a frame including information about the subscriber terminal device,
The relay device encapsulates the frame from the subscriber line aggregation device to generate an IP packet, and transfers the generated IP packet to the IP network,
The PON system according to claim 8, wherein the management server decapsulates an IP packet received via the IP network to generate a frame, and extracts information about the subscriber terminal device from the frame. A method of managing a subscriber line by a PON station side device, comprising:
The PON station side device is a relay device configured to be capable of layer 2 communication, and is attachable to and detachable from the relay device. The PON station side device aggregates the subscriber lines and is connected to the subscriber line. A subscriber line aggregation device configured to hold information about the subscriber terminal device,
The management method is
The relay device receives, via an IP network, an IP packet addressed to the subscriber line aggregation device, the IP packet including control information relating to control of the subscriber line aggregation device;
The relay device decapsulating the received IP packet to generate a frame including the control information;
The relay device transfers the frame to the subscriber line aggregation device.

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