JP2011129970A - Subscriber side optical line terminating apparatus, optical transmission system, switch, and communication control method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide: a subscriber-side optical line-terminating apparatus capable of managing redundancy; an optical transmission system for connecting the subscriber-side optical line-terminating apparatus; a switch capable of achieving redundancy by connecting two or more subscriber-side optical line-terminating apparatuses; and a communication control method for respective units. <P>SOLUTION: Since communication between an OLT 110 and an ONU 105 is managed by a PON identifier and communication between the ONU 105 and a switch 10 is managed by a tag, selection of a communication line between the OLT 110 and the switch 10 cannot be suitably performed if two ONUs 105-1, 105-2 are connected to the switch 10. Thus, a conversion table for mutually correlating the PON identifier and the tag is prepared in advance and the conversion table is installed in the ONU 105 and the switch 10. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a customer premises optical line terminator connected to a center side optical line terminator through a PON type optical transmission line, an optical transmission system, a switch connected to the optical transmission system, and a communication control method.

  In an optical network such as FTTH and CATV, as described in Patent Document 1 below, an optical transmission path connected to a center is branched by a passive splitter, and an optical transmission path is laid to a plurality of subscriber homes. A PON (Passive Optical Network) type optical transmission system is used. Such an optical transmission system is also called PDS (Passive Double Star).

  An example of a conventional PON type optical transmission system is shown in FIG. In the PON type optical transmission system 900 shown in the figure, a center optical line terminator (OLT) 901 is connected to a multiplexing end of a splitter 903 via an optical fiber 902, and a plurality of demultiplexers of the splitter 903 are separated. At the end, optical network termination units (ONUs) 905-1,... 905-n installed at each subscriber's home are connected via optical fibers 904-1,. The

  The configuration of the ONUs 905-1,... 905-n is shown in FIG. This figure shows the configuration of the ONU 905-1 as an example. The ONU 905-1 includes an optical transceiver unit 906, an ONU function unit 907, a physical layer (PHY) 908, and an Ethernet (registered trademark) interface 909. It has become. An optical fiber 904-1 connected to the splitter 903 is connected to the optical transceiver unit 906 via an optical termination unit 910 provided in each subscriber's house.

  As the Ethernet (registered trademark) interface 909, 10/100 / 1000BASE-TX or the like can be used, and for example, a LAN cable 911 is connected thereto. A terminal device 914 such as a computer or a printer can be directly connected to the LAN cable 911, or a switch such as a router 912 or a switching hub 913 can be connected to another terminal device 914. Further, when an MSA interface module corresponding to an MSA (Multi-Source Agreement) interface standard is used as the interface 909, it is possible to directly connect to an MSA interface slot provided in an external node such as a switch. There is a great advantage that the connection of the LAN cable is not required and the space can be saved.

  In order for a switch or the like connected to the optical transmission system using the ONU to communicate with the outside with high reliability, it is important to increase the reliability of the connection with the optical transmission system. In a network system or the like, in order to increase the reliability of connection between devices, a method of providing redundancy by providing two or more transmission lines between devices has been conventionally used. An example of redundancy between conventional apparatuses will be described with reference to FIG. FIG. 2A shows a redundancy method using trunking, and FIG. 3B shows a redundancy method using spanning tree.

  In the trunking method shown in FIG. 9A, two switches 921 and 922 form two transmission lines 923 and 924 using two ports 921a and 921b and 922a and 922b, respectively, and both are active. It has become. In such a trunking method, a plurality of transmission lines 923 and 924 are virtually bundled like a single transmission line, thereby making it possible to increase the speed by distributing the data transfer load. . In addition, when an abnormality occurs in one transmission line, it is possible to continue communication using only the other transmission line.

  In the spanning tree method shown in FIG. 9B, two switches 921 and 922 form two transmission lines 925 and 926 using two ports 921a and 921b and 922a and 922b, respectively. Only the transmission line (transmission line 925 in FIG. 9B) is active. If the two switches 921, 922 are simply connected by the two transmission lines 925, 926, they form a loop and a problem arises.

  Therefore, in the method using the spanning tree, one transmission line is normally blocked (blocked at the port 921b on the transmission line 926 side in FIG. 9B), and when an abnormality occurs in the active transmission line 925, The block of the port 921b is released and used. In such redundancy, a normally blocked transmission line (hereinafter referred to as a “standby transmission line”) is separated from an active transmission line (hereinafter referred to as “active transmission line”). The configuration is provided. Then, when an abnormality occurs in the active transmission line, it is switched to the standby transmission line for use.

JP-A-9-214541

  However, in the PON type optical transmission system, since no standard for redundancy is provided, redundancy cannot be realized at present. When two or more MSA interface slots are provided in the switch, two communication lines can be physically provided by connecting two ONUs, for example. However, since the management method for redundancy is not defined, it is not possible to appropriately control the two communication lines simply by connecting two ONUs. That is, since the management method of the ONU connected to each slot of the switch is not defined, for example, the switch cannot determine to which ONU connected to which slot the upstream data signal should be output. Occurs.

  Accordingly, the present invention has been made to solve such a problem, and a subscriber premises optical line terminator capable of managing redundancy and optical transmission for connecting the subscriber premises optical line terminators. It is an object of the present invention to provide a system, a switch that can be made redundant by connecting two or more subscriber-side optical line terminators, and respective communication control methods.

  According to a first aspect of the subscriber premises optical line termination apparatus of the present invention, an optical transmission line connected to the center side is branched into a plurality of optical transmission lines by a passive optical coupler and connected to the subscriber premises side. A subscriber-side optical line terminator used in a PON (Passive Optical Network) type optical transmission system, a first MAC unit for terminating a data signal transmitted between center-side optical line terminators, and a subscriber A second MAC section for terminating a data signal transmitted between the home side switches, an MSA interface module connected to an MSA (Multi-Source Agreement) interface slot provided in the switch, and the center side optical line termination The PON identifier set for communication with the device and the switch identifier set for identifying the MSA interface slot by the switch are changed in advance. A communication control unit that performs mutual conversion using a table, and when the downlink data signal is input to the first MAC unit, the communication control unit writes the PON written to the downlink data signal from the first MAC unit. An identifier is input, the PON identifier is converted into the switch identifier using the conversion table and output to the second MAC unit, and the second MAC unit writes the switch identifier tag in the downlink data signal, When the uplink data signal is input to the second MAC unit while outputting to the switch, the communication control unit inputs the switch identifier written in the uplink data signal from the second MAC unit, and the conversion table is The switch identifier is converted into the PON identifier and output to the first MAC unit, and the first MAC unit transmits the uplink data. The PON identifier is written in the data signal and output to the center side optical line terminating device.

  In another aspect of the subscriber premises optical line terminator according to the present invention, the conversion table is created by the center side optical line terminator, and an OAM (Operation, Administration, and Maintenance) layer or extension of the downlink data signal It is written in the OAM layer, transmitted to the communication control unit, and stored.

  According to another aspect of the subscriber premises optical line termination apparatus of the present invention, the conversion table is written in the extended OAM layer and further output to the switch.

In another aspect of the subscriber premises optical line terminator according to the present invention, the conversion table is transmitted from the communication control unit via an I ² C (Inter Integrated Circuit) signal line provided in the MSA interface module. It is output to.

  In another aspect of the subscriber premises optical line termination device of the present invention, the switch identifier is associated with the MSA interface slot in advance, and when connected to the MSA interface slot, a predetermined serial interface is connected. The switch identifier is read from the switch, and the conversion table is created by associating the switch identifier with the PON identifier.

In another aspect of the subscriber premises optical line termination device of the present invention, the predetermined serial interface is an interface via the I ² C signal line.

  Another aspect of the subscriber premises optical line terminator of the present invention uses the dedicated OAM interface when the switch identifier is associated with the MSA interface slot in advance and is connected to the MSA interface slot. The switch identifier is read from the switch, and the conversion table is created by associating the switch identifier with the PON identifier.

  In another aspect of the subscriber premises optical line terminator according to the present invention, a setting order of the switch identifiers is determined in advance, and the switch identifiers are connected to the MSA interface slot using a predetermined serial interface. The switch identifier is read from the switch, and the conversion table is created by associating the switch identifier with the PON identifier.

In another aspect of the subscriber premises optical line termination device of the present invention, the predetermined serial interface is an interface via the I ² C signal line.

  According to another aspect of the subscriber premises optical line terminator of the present invention, the switch identifier setting order is determined in advance, and the switch using the dedicated OAM interface in the order of connection to the MSA interface slot. The switch identifier is read out from the switch, and the conversion table is created by associating the switch identifier with the PON identifier.

  According to a first aspect of the optical transmission system of the present invention, there is provided the customer premises optical line termination device according to any one of the first to tenth aspects.

  Another aspect of the optical transmission system of the present invention is characterized in that two or more of the subscriber premises optical line terminators are connected to the same switch.

  In another aspect of the optical transmission system of the present invention, the conversion table in which the PON identifiers and the switch identifiers of the two or more subscriber premises optical line terminators are associated with each other is used as the center side optical line termination. The conversion table is created in a device, the conversion table is written in an OAM layer or an extended OAM layer of the downlink data signal, and transmitted to each of the two or more subscriber premises optical line terminators.

  A first aspect of the switch of the present invention is a switch connected to the customer premises optical line terminator according to any one of the first to tenth aspects, wherein the two or more MSA interface slots And a switch core unit that is connected to the MSA interface slot and controls communication with the subscriber premises optical line terminating device, and the switch core unit uses the conversion table to transmit the uplink data signal. The MSA interface slot to be output is determined.

According to another aspect of the switch of the present invention, the switch core unit creates the conversion table and transmits the conversion table to the communication control unit via the I ² C signal line.

  In another aspect of the switch of the present invention, the switch identifier is associated with the MSA interface slot in advance, and when the subscriber premises optical line terminator is connected to the MSA interface slot, a predetermined serial The conversion table is created by reading out the PON identifier from the subscriber optical fiber terminal using an interface and associating the switch identifier with the PON identifier.

In another aspect of the switch of the present invention, the predetermined serial interface is an interface through the I ² C signal line.

  In another aspect of the switch of the present invention, when the switch identifier is associated with the MSA interface slot in advance, and the subscriber premises optical line terminator is connected to the MSA interface slot, a dedicated OAM interface is provided. The PON identifier is read out from the subscriber-side optical line termination device using, and the conversion table is created by associating the switch identifier with the PON identifier.

  In another aspect of the switch of the present invention, the setting order of the switch identifier is predetermined, and a predetermined serial interface is connected in the order in which the subscriber premises optical line terminator is connected to the MSA interface slot. The PON identifier is read out from the subscriber premises optical line terminating device, and the conversion table is created by associating the switch identifier with the PON identifier.

In another aspect of the switch of the present invention, the predetermined serial interface is an interface through the I ² C signal line.

  According to another aspect of the switch of the present invention, the setting order of the switch identifier is predetermined, and the dedicated OAM interface is used in the order in which the subscriber premises optical line terminator is connected to the MSA interface slot. Then, the PON identifier is read from the subscriber premises optical line terminating device, and the conversion table is created by associating the switch identifier with the PON identifier.

  According to a first aspect of the communication control method of the present invention, a PON (branched from a center side optical line terminator to a plurality of optical transmission lines via a passive optical coupler and connected to a customer side optical line terminator is provided. A communication control method when a switch is connected to a Passive Optical Network) type optical transmission system, wherein a downlink data signal is transmitted from the center side optical line terminator to a first MAC unit of the subscriber premises side optical line terminator. When input, the first MAC unit terminates the downlink data signal, reads the PON identifier written in the downlink data signal, and outputs the PON identifier to the communication control unit of the subscriber premises optical line termination device, The communication control unit converts the PON identifier into a switch identifier set for identifying the MSA interface slot of the switch by using a conversion table created in advance. Output to the second MAC unit of the line termination device, and the second MAC unit writes the switch identifier in the downlink data signal and outputs to the switch, while the uplink data signal is input from the switch to the second MAC unit Then, the second MAC unit terminates the uplink data signal, reads the switch identifier written in the uplink data signal and outputs the switch identifier to the communication control unit, and the communication control unit uses the conversion table. The switch identifier is converted into the PON identifier and output to the first MAC unit, and the first MAC unit writes the PON identifier in the uplink data signal and outputs the PON identifier to the center side optical line terminating device. And

  According to the present invention, a subscriber premises optical line terminator capable of managing redundancy, an optical transmission system connecting the subscriber premises optical line terminators, and two or more subscriber premises optical line terminators are provided. It is possible to provide switches that can be connected and made redundant, and respective communication control methods.

1 is a block diagram illustrating a schematic configuration of an optical transmission system according to a first embodiment. It is explanatory drawing which shows the logical structure of the communication line between OLT and a switch. It is a block diagram which shows schematic structure of the subscriber premises optical line termination | terminus apparatus of this embodiment. It is explanatory drawing which shows an example of a conversion table. It is explanatory drawing which shows the communication control method in the optical transmission system and switch of this embodiment. It is explanatory drawing which shows the setting method of a conversion table. It is a block diagram which shows schematic structure of the conventional PON type | mold optical transmission system. It is a block diagram which shows schematic structure of the conventional subscriber premises optical line termination | terminus apparatus. It is a block diagram which shows the conventional redundancy method.

  A configuration of an optical transmission system according to a preferred embodiment of the present invention will be described in detail with reference to the drawings. In addition, about each structural part which has the same function, the same code | symbol is attached | subjected and shown for simplification of illustration and description.

  A subscriber premises optical line termination device, an optical transmission system, and a switch according to a first embodiment of the present invention will be described with reference to FIG. FIG. 1 is a block diagram illustrating a configuration of an optical transmission system 100 according to the present embodiment. In this embodiment, the center-side OLT system 101 includes an OLT 110 and a center-side management unit 120, and the OLT 110 and subscriber-side optical line terminators 105 (each of which is 105-1,..., 105-n (n: natural number)) Are connected by optical fibers 102 and 104 via a passive optical coupler 103 to constitute a PON type optical transmission system 100. Hereinafter, in the optical transmission system 100, a data signal transmitted from the center side to the subscriber's home side is referred to as a downlink data signal, and a data signal transmitted from the subscriber's home side to the center side is referred to as a downlink data signal.

  In the PON type optical transmission system, OAM (Operation, Administration, and Maintenance) for managing the ONU is defined, and the center side management unit 120 manages the ONU 105 connected to the OLT 110. The center-side management unit 120 performs processing such as establishment and authentication of a PON link when a switch or the like is connected to the ONU 105. The data signal transmitted between the OLT 110 and the ONU 105 is provided with an OAM data layer as data for maintenance management. Then, a communication abnormality detected by the ONU 105 is notified to the center management unit 120 using the OAM data.

  The switch 10 of the present embodiment connected to the optical transmission system 100 using the ONU 105 includes two or more MSA interface slots 11 (two in FIG. 1, 11a and 11b), a switch core unit 12, a personal computer 20, and the like. Is provided with a port 13. The switch core unit 12 controls transmission of a data signal using a CPU (not shown) and controls a communication line with the ONU 105 connected to the MSA interface slot 11.

  FIG. 1 shows an example in which the two ONUs 105-1 and 2 of this embodiment are connected to the two MSA interface slots 11a and 11b of the switch 10, respectively. As a result, the switch 10 has a redundant communication line with the optical transmission system 100 using the two ONUs 105-1 and 2-1. Simultaneously with redundancy, the line bandwidth, that is, the transmission capacity can be increased.

  Since the two ONUs 105-1 and 2 each terminate the data signal, in order for the switch core unit 12 to control the communication line between the ONUs 105-1 and 2, the two connected It is necessary to identify the ONUs 105-1 and 105-2 and communicate with each other. However, the ONUs 105-1 and 105-2 are managed by the center side management unit 120 in accordance with the OAM regulations, and this management information is terminated at the ONU 105 and is not output to the switch 10. According to the OAM regulations, communication between the OLT and the ONU is managed by the PON identifier, and the PON identifier is written in the data signal transmitted between the OLT 110 and the ONU 105.

  In order to be able to manage two or more communication lines formed by connecting two or more ONUs 105 to two or more slots 11 of one switch 10 on each of the ONU 105 side and the switch 10 side, 11 identifiers need to be associated with each other on a one-to-one basis. As the identifier of the ONU 105, the above PON identifier can be used. Similarly, the switch identifier that identifies each slot 11 on the switch 10 side can be used for association with the ONU 105 described above.

  In the switch 10, the switch core unit 12 manages a plurality of slots 11 with VLAN tags (tags) used in a logical network configuration such as VLAN, and each data signal passing through each slot 11 has a tag. Is written. Therefore, this tag can be used as an example of the switch identifier. In the following, an embodiment using a tag as an example of a switch identifier will be described. However, the present invention is not limited to this, and another switch identifier that can identify each slot 11 may be used. This tag information is also terminated at the ONU 105 and is not output to the center side. The logical structure of the communication line between the OLT 110 and the switch 10 is shown in FIG.

  As shown in FIG. 2, since communication between the OLT 110 and the ONU 105 is managed by a PON identifier and between the ONU 105 and the switch 10 is managed by a tag, two ONUs 105-1 and 2 are connected to the switch 10. As a result, the communication line cannot be properly selected between the OLT 110 and the switch 10. Therefore, in this embodiment, a conversion table that associates the PON identifier and the tag with each other is created in advance, and the ONU 105 and the switch 10 have this conversion table.

  The configuration of the ONU 105 of this embodiment will be described with reference to FIG. FIG. 3 is a block diagram showing the configuration of the ONU 105 of this embodiment. The ONU 105 includes an electrical / optical conversion unit (TRx) 130, an optical line terminator function unit (hereinafter referred to as an ONU function unit) 140, a serial / parallel conversion unit (SERDES) 150, and an MSA interface module 160. As the MSA interface module, there are modules such as GBIC and SFP.

  The electrical / optical converter 130 has an optical input / output terminal for transmitting / receiving a data signal as an optical signal to / from the OLT 110 on the center side. The electrical / optical converter 130 converts the optical signal of the downstream data signal transmitted from the OLT 110 into an electrical signal (photoelectric conversion) and outputs the electrical signal to the ONU function unit 140, while the upstream data signal input from the ONU function unit 140 Is converted into an optical signal (electro-optical conversion) and transmitted to the OLT 110.

  The ONU function unit 140 converts the serial signal of the downlink data signal input from the electrical / optical conversion unit 130 into a parallel signal, outputs the signal to the SERDES 150 after performing a predetermined termination process. The ONU function unit 140 converts the parallel signal of the upstream data signal input from the SERDES 150 into a serial signal after performing a predetermined termination process, and outputs the serial signal to the electrical / optical conversion unit 130. The ONU function unit 140 performs the above termination processing in the first MAC unit 141 and the second MAC unit 142, respectively.

  The SERDES 150 includes serial / parallel conversion means and parallel / serial conversion means (not shown), and converts the parallel data downlink data input from the ONU function unit 140 into a serial signal by the parallel / serial conversion means, which is converted into an MSA interface module. 160 is output. Further, the SERDES 150 converts the serial data uplink data signal input from the MSA interface module 160 into a parallel signal by the serial / parallel conversion means and outputs the parallel signal to the ONU function unit 140.

  The MSA interface module 160 is directly connected to the MSA interface slot 11 of the switch 10 to input / output serial electric signals and the like. The MSA interface module 160 includes two interface units, a main interface (I / F) unit 161 and a sub I / F unit 162. Downlink data signals and uplink data signals transmitted to the switch 10 are transmitted via the main I / F unit 161.

  The ONU 105 includes a communication control unit 143 in the ONU function unit 140 in order to appropriately manage a communication line when two or more ONUs 105 are connected to the switch 10 to be redundant. The communication control unit 143 has a conversion table that associates the PON identifier used for identifying the ONU 105 in communication with the OLT 110 and the tag used for identifying the MSA interface slot 11 connected in communication with the switch 10. is doing. An example of the conversion table is shown in FIG. In the conversion table, information on the ONUs 105-1 and 2 connected to the MSA interface slot 11 of the switch 10 is set. Here, the PON identifiers of the ONUs 105-1 and 105-2 are PON-MAC1 and PON-MAC2, respectively, and the tags attached to the MSA interface slots 11a and 11b are TAG1 and TAG2, respectively. The conversion table shown in FIG. 4 indicates that ONUs 105-1 and 105-2 are connected to the MSA interface slots 11a and 11b, respectively.

  The conversion table shown in FIG. 4 is also set in the switch core unit 12 of the switch 10. The switch core unit 12 uses the conversion table to determine from which of the ONUs 105-1 and 2 the downstream data signal is input, or from which of the ONUs 105-1 and 2 the upstream data signal is output. Then, tags can be set. In addition, for communication line management, it is possible to communicate with the ONUs 105-1 and 2 using the PON identifier, and it is possible to perform communication control such as detecting malfunctions in the communication line and using only normal communication lines. It becomes.

  A communication control method performed by the optical transmission system 100 and the switch 10 of this embodiment using the conversion table shown in FIG. 4 will be described below with reference to FIG. In FIG. 5, as an example, when a downlink data signal is transmitted from the OLT 110 via the ONU 105-1 to the switch 10 ((a) in FIG. 5), when uplink data is transmitted from the switch 10 to the OLT 110 via the ONU 105-1. The case where a signal is transmitted ((b) of the figure) is shown.

  5A, when a downlink data signal is transmitted from the OLT 110 to the ONU 105-1, the communication control unit 143 of the ONU 105-1 inputs the PON identifier of the downlink data signal from the first MAC unit 141. When the input PON identifier matches the PON-MAC1 assigned to the ONU 105-1, the communication control unit 143 converts the PON-MAC1 into the tag TAG1 corresponding to the PON-MAC1 using the conversion table, and converts this to the second MAC. Output to the unit 142. The second MAC unit 142 writes TAG1 as a transmission destination in the downlink data signal and outputs it to the switch 10 side.

  In FIG. 5B, when the switch 10 transmits the uplink data signal to the OLT 110 side, when the switch core unit 12 determines that the ONU used for transmission is the ONU 105-1, the switch core unit 12 transmits the upstream data signal to the transmission source. TAG1 is written and output to the ONU 105-1. When the uplink data signal is input from the switch 10 to the ONU 105-1, the communication control unit 143 inputs the tag of the uplink data signal from the second MAC unit 142. The communication control unit 143 converts the input tag (TAG1) into a PON identifier (PON-MAC1) using the conversion table, and outputs this to the first MAC unit 141. The first MAC unit 141 writes PON-MAC1 of the PON identifier converted as the transmission source in the uplink data signal and outputs it to the OLT 110 side.

  As described above, since the communication control unit 143 performs mutual conversion between the PON identifier and the tag, at least information on the column of the PON identifier and the column of the tag in the table shown in FIG. As a conversion table. Similarly, the switch core unit 12 may also have at least information on the PON identifier column and the tag column information (indicated by a broken-line frame in the figure) as a conversion table.

  Next, a method for setting the conversion table in the communication control unit 143 of the ONU 105 and the switch core unit 12 of the switch 10 will be described below with reference to FIG. FIG. 6A is a diagram for explaining a first method for setting a conversion table on the center side, and FIG. 6B is a diagram for explaining a second method for setting on the switch 10 side. In the first method shown in FIG. 6A, when the ONU 105 is registered on the center side, a conversion table is also set. When the administrator registers the conversion table shown in FIG. 4 in the center side management unit 120, the conversion table is written in the OAM layer or the extended OAM layer of the downlink data signal and transmitted from the OLT 110 to the ONU 105.

In the ONU 105, when a downlink data signal is input from the OLT 110, the communication control unit 143 reads and stores the conversion table from the OAM layer or the extended OAM layer. In addition, when the conversion table is written in the extended OAM layer, the conversion table is transmitted to the switch core unit 12 of the switch 10 as it is, and the switch core unit 12 is transferred to the extended OAM layer. It is possible to read out the written conversion table. Alternatively, the conversion table acquired by the communication control unit 143 is transmitted to the switch core unit 12 using a serial signal line (I ² C signal line) passing through the sub I / F unit 162 of the MSA interface module 160. Also good.

In the second method shown in FIG. 6B, each time the ONU 105 is connected to the MSA interface slot 11 of the switch 10, the administrator directly registers the conversion table in the switch core unit 12. The conversion table registered in the switch core unit 12 can be transmitted to the communication control unit 143 of the ONU 105 using an I ² C signal line passing through the sub I / F unit 162. Further, when it is necessary to set the conversion table also in the center side management unit 120, the ONU 105 can write the conversion table in the extended OAM layer of the uplink data signal and transmit it to the center side management unit 120.

Instead of the above setting method by the administrator, it is also possible to automatically create a conversion table on the switch 10 side. As a first method for automatically creating the conversion table, the correspondence between the MSA interface slot 11 and the tag is determined in advance and set in the switch core unit 12. When the ONU 105 is connected to the MSA interface slot 11, The communication control unit 143 reads the corresponding tag from the switch core unit 12 using the I ² C signal line or another serial interface. Alternatively, the tag may be read from the switch core unit 12 using a dedicated OAM interface. When the tag is input from the switch core unit 12, the communication control unit 143 creates a conversion table from the tag and the PON identifier, and uses any one of the I ² C signal line, another serial interface, and the dedicated OAM interface. This is again transmitted to the switch core unit 12.

Alternatively, when the ONU 105 is connected to the MSA interface slot 11, the switch core unit 12 reads the PON identifier from the ONU 105 using any one of the I ² C signal line, another serial interface, and the dedicated OAM interface. Using this, the switch core unit 12 may create a conversion table. By creating the above conversion table every time the ONU 105 is connected to the MSA interface slot 11, the switch core unit 12 can create conversion tables corresponding to all the connected ONUs 105. The created conversion table is transmitted to the ONU 105 or the center side as necessary.

  As a second method for automatically creating a conversion table, it is possible to sequentially set tags that are ordered in advance according to the order in which the ONUs 105 are connected to the MSA interface slot 11. Thus, when the correspondence between the ONU 105 and the tag is determined, a conversion table can be automatically created in the same manner as in the first method. Note that the tags used in the first method and the second method for automatically creating the conversion table are different from those used in the VLAN or the like.

  As described above, according to the present invention, it is possible to provide a highly reliable optical transmission system by connecting two or more subscriber-side optical line terminators to one switch for redundancy. . As a result, even if an abnormality occurs in the communication line formed by one subscriber premises optical line termination device, communication is continued using the communication line formed by another subscriber premises optical line termination device. This makes it possible to perform highly reliable communication. Further, by forming two or more communication lines, the line bandwidth, that is, the transmission capacity can be increased.

  Note that the description in the present embodiment shows an example of the subscriber premises optical line termination device, optical transmission system, switch, and communication control method according to the present invention, and the present invention is not limited to this. The detailed configuration and detailed operation of the subscriber premises optical line termination device and the like in this embodiment can be changed as appropriate without departing from the spirit of the present invention.

10 Switch 11 (11a, 11b) MSA interface slot 12 Switch core unit 13 Port 100 Optical transmission system 101 OLT system 102, 104 Optical fiber 103 Passive optical coupler 105 Subscriber side optical line terminator 110 OLT
120 Center side management unit 130 TRx
140 ONU Function Unit 141 First MAC Unit 142 Second MAC Unit 143 Communication Control Unit 150 SERDES
160 MSA Interface Module 161 Main I / F 162 Sub I / F

Claims (22)

An optical transmission line connected to the center side is branched to a plurality of optical transmission lines by a passive optical coupler and connected to the subscriber's home side. An optical line termination device,
A first MAC unit for terminating a data signal transmitted between the center side optical line terminators;
A second MAC unit for terminating a data signal transmitted between the switches on the subscriber premises side;
An MSA interface module connected to an MSA (Multi-Source Agreement) interface slot provided in the switch;
A PON identifier set for communication with the center side optical line terminator and a switch identifier set for identification of the MSA interface slot by the switch are mutually converted using a conversion table created in advance. A communication control unit for converting to
When a downlink data signal is input to the first MAC unit, the communication control unit inputs the PON identifier written to the downlink data signal from the first MAC unit, and uses the conversion table to input the PON identifier. While converting to a switch identifier and outputting to the second MAC unit, the second MAC unit writes the switch identifier in the downlink data signal and outputs to the switch,
When an uplink data signal is input to the second MAC unit, the communication control unit inputs the switch identifier written in the uplink data signal from the second MAC unit, and uses the conversion table to switch the switch identifier. Is converted into the PON identifier and output to the first MAC unit, and the first MAC unit writes the PON identifier into the uplink data signal and outputs the PON identifier to the center-side optical line terminator. Side optical line terminator. The conversion table is created by the center-side optical line termination device, written to an OAM (Operation, Administration, and Maintenance) layer or an extended OAM layer of the downlink data signal, transmitted to the communication control unit, and stored. The subscriber premises optical line termination device according to claim 1, wherein: 3. The subscriber premises optical line termination device according to claim 2, wherein the conversion table is written in the extended OAM layer and further output to the switch. The conversion table according to claim 2 or 3, characterized in that it is outputted through the ^I 2 C (Inter Integrated Circuit) signal lines provided from the communication control unit to the MSA interface module to the switch Subscriber premises optical line termination equipment. The switch identifier is associated with the MSA interface slot in advance;
When connected to the MSA interface slot, the switch identifier is read from the switch using a predetermined serial interface, and the conversion table is created by associating the switch identifier with the PON identifier. 5. The subscriber premises side optical line termination device according to claim 1, wherein 6. The subscriber premises optical line termination device according to claim 5, wherein the predetermined serial interface is an interface via the I ² C signal line. The switch identifier is associated with the MSA interface slot in advance;
When connected to the MSA interface slot, the switch identifier is read from the switch using a dedicated OAM interface, and the conversion table is created by associating the switch identifier with the PON identifier. 5. The subscriber premises optical line termination device according to any one of claims 1 to 4. The switch identifier setting order is determined in advance, and the switch identifier is read from the switch using a predetermined serial interface in the order of connection to the MSA interface slot. The switch identifier and the PON identifier 5. The subscriber premises optical line terminator according to any one of claims 1 to 4, wherein the conversion table is created in association with each other. 9. The subscriber premises optical line terminator according to claim 8, wherein the predetermined serial interface is an interface through the I ² C signal line. The switch identifier setting order is determined in advance,
The switch identifier is read from the switch using a dedicated OAM interface in the order of connection to the MSA interface slot, and the conversion table is created by associating the switch identifier with the PON identifier. 5. The subscriber premises optical line termination device according to any one of claims 1 to 4. An optical transmission system comprising the subscriber premises optical line termination device according to any one of claims 1 to 10. 12. The optical transmission system according to claim 11, wherein two or more of the subscriber premises optical line terminators are connected to the same switch. The conversion table in which the PON identifier and the switch identifier of each of the two or more subscriber premises optical line terminators are associated with each other is created by the center side optical line terminator, and the conversion table is generated as the downlink data. 13. The optical transmission system according to claim 11, wherein a signal is written in an OAM layer or an extended OAM layer and transmitted to each of the two or more subscriber premises optical line terminators. A switch connected to the subscriber premises optical line terminator according to any one of claims 1 to 10,
Two or more MSA interface slots;
A switch core unit connected to the MSA interface slot for controlling communication with the subscriber premises optical line terminator,
The switch core unit determines the MSA interface slot that outputs the uplink data signal using the conversion table. The switch according to claim 14, wherein the switch core unit creates the conversion table and transmits the conversion table to the communication control unit via the I ² C signal line. The switch identifier is associated with the MSA interface slot in advance;
When the subscriber premises optical line terminator is connected to the MSA interface slot, the PON identifier is read from the subscriber premises optical line terminator using a predetermined serial interface, and the switch identifier and the PON The switch according to claim 14 or 15, wherein the conversion table is created in association with an identifier. 17. The subscriber premises optical line termination device according to claim 16, wherein the predetermined serial interface is an interface via the I ² C signal line. The switch identifier is associated with the MSA interface slot in advance;
When the subscriber premises optical line terminator is connected to the MSA interface slot, the PON identifier is read from the subscriber premises optical line terminator using a dedicated OAM interface, and the switch identifier and the PON identifier 16. The subscriber premises optical line termination device according to claim 14 or 15, wherein the conversion table is created in association with each other. The setting order of the switch identifier is determined in advance, and the subscriber premises optical line termination is performed using a predetermined serial interface in the order in which the subscriber premises optical line termination devices are connected to the MSA interface slot. 16. The switch according to claim 14, wherein the PON identifier is read from a device, and the conversion table is created by associating the switch identifier with the PON identifier. 20. The subscriber premises optical line termination device according to claim 19, wherein the predetermined serial interface is an interface via the I ² C signal line. The setting sequence of the switch identifier is determined in advance, and the subscriber premises optical line terminator using the dedicated OAM interface in the order in which the subscriber premises optical line terminators are connected to the MSA interface slot. 16. The subscriber premises optical line termination device according to claim 14 or 15, wherein the PON identifier is read out from the switch and the conversion table is created by associating the switch identifier with the PON identifier. A switch is connected to a PON (Passive Optical Network) type optical transmission system that is branched from a center side optical line terminator to a plurality of optical transmission lines via a passive optical coupler and connected to a customer side optical line terminator. A communication control method when
When a downlink data signal is input from the center side optical line terminator to the first MAC unit of the subscriber premises side optical line terminator, the first MAC unit terminates the downlink data signal and converts it to the downlink data signal. The written PON identifier is read out and output to the communication control unit of the subscriber premises optical line termination device, and the communication control unit uses the conversion table created in advance to convert the PON identifier into the MSA interface slot of the switch. A switch identifier set for identification is converted and output to the second MAC unit of the subscriber premises optical line terminating device, and the second MAC unit writes the switch identifier in the downlink data signal and writes it to the switch. While output
When the uplink data signal is input from the switch to the second MAC unit, the second MAC unit terminates the uplink data signal, reads the switch identifier written in the uplink data signal, and performs the communication control. And the communication control unit converts the switch identifier into the PON identifier using the conversion table and outputs the PON identifier to the first MAC unit, and the first MAC unit adds the PON identifier to the uplink data signal. A communication control method comprising writing and outputting to the center side optical line terminator.

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