JP4580031B1 - Multi-layer module subscriber-side optical line terminator and optical transmission system using the same - Google Patents

Abstract

Provided is a multi-layer module customer premises optical line termination device capable of centrally managing maintenance information related to optical communication by a center side optical line termination device, and an optical transmission system using the same.
An ONU 100 includes a physical layer module including an ONU side optical input / output terminal 111, an LD driver 112, a limiting amplifier 113, and an ONU side controller 114, and a data link layer module of the ONU side MAC unit 120. The multi-layer module has a two-layer function of a physical layer and a data link layer. The ONU-side controller 114 manages the maintenance information of the ONU 100 and transmits a variation value of maintenance information related to optical communication to the center side.
[Selection] Figure 1

Description

  The present invention relates to a multi-layer module subscriber-side optical line terminator installed in a subscriber's house in a PON type optical transmission system, and an optical transmission system using the same.

  In optical networks such as FTTH and CATV, as described in Patent Documents 1 and 2, the optical transmission line connected to the center is branched by a passive splitter, and the optical transmission line 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).

  In the PON type optical transmission system, as shown in FIG. 9, a center optical line termination device (OLT) 901 is connected to a multiplexing end of a splitter 903 via an optical fiber 902, and a plurality of splitters 903 are connected. At the demultiplexing end, a subscriber premises side optical network unit (ONU) 905 installed at each subscriber premises is connected via an optical fiber 904.

  The ONU 905 uses an Ethernet (registered trademark) interface as an interface with an external node. As the Ethernet (registered trademark) interface, 10/100/1000 BASE-TX or the like can be used, and for example, a LAN cable 906 is connected thereto. Switches such as a router 907 and a switching hub 908 are connected via a LAN cable 906, and a terminal device 909 such as a computer or a printer can be connected thereto. Alternatively, the terminal device 909 can be directly connected to the LAN cable 906.

  When an MSA interface module corresponding to an MSA (Multi-Source Agreement) interface standard is used as an interface with an external node, it can be directly connected to an MSA interface slot provided in the external node. There are significant advantages such as the need for cable connection and space saving.

  One configuration example of a conventional ONU 905 having an MSA interface module will be described with reference to FIG. FIG. 10 is a block diagram showing a schematic configuration of a conventional ONU 905 and shows a state in which it is directly connected to an MSA interface slot 922 provided in an external node (hereinafter referred to as a host device) 920. The ONU 905 includes an optical input / output terminal 911 in order to transmit and receive optical signals to and from the center-side OLT 901.

  The optical input / output terminal 911 performs optical / electrical conversion for converting the optical signal of the signal transmitted from the OLT 901 into an electrical signal, and electrical / optical conversion for converting the electrical signal of the signal input from the host device 920 into an optical signal. Has an optical device to do. As an optical device, a PD (photodiode) is used for optical / electrical conversion, and an LD (laser diode) is used for electrical / optical conversion.

  An electrical signal that is optical / electrically converted at the optical input / output terminal 911 is output to the host device 920 side via a limiting amplifier (LIM) 913. In addition, an electrical signal input from the host device 920 is output to an LD driver (LDD) 912 that drives the LD. The LDD 912 transmits an optical signal of the signal to the OLT 901 side by driving an LD (not shown) provided in the optical input / output terminal 911 according to the input electric signal.

  As shown in FIG. 10, a conventional ONU 905 performs optical / electrical conversion and electrical / optical conversion processing, and includes a physical layer module that performs physical layer (L1) processing in an OSI (Open Systems Interconnection) reference model. It has become. The ONU 905 does not have the functions of the data link layer (L2) of the OSI reference model or higher layers, and these have the configuration that the host device 920 has. Therefore, the ONU 905 of the physical layer module and the host device 920 are integrated to complete a predetermined functional configuration including a communication function. Therefore, it is desirable in terms of system management that the maintenance information in the ONU 905 is centrally managed with the maintenance information in the host device 920 (for example, statistical information of communication packets).

  Therefore, conventionally, the maintenance information in the ONU 905 is output to the host device 920, and the host device 920 is configured to be centrally managed together with the maintenance information in the host device 920. The controller 914 provided in the ONU 905 stores the maintenance information of the ONU 905 in a memory having a memory map having a format as shown in FIG. As shown in FIG. 11, the maintenance information of the ONU 905 includes a fixed value and a fluctuation value.

  The fixed value of the maintenance information of the ONU 905 includes the manufacturer name, model number, and serial number of the ONU 905. The variation value includes control data and state data (LD current, output power, received power, etc.) of a transmission / reception circuit including the optical input / output terminal 911, the limiting amplifier 913, and the LD driver 912. In addition to the interface 910a for transmitting signals, another serial interface 910b is provided between the ONU 905 and the host device 920. The controller 914 outputs maintenance information in the ONU 905 to the logic unit 921 in the host device 920 via the serial interface 910b.

JP-A-9-214541 JP 2008-0667402 A

  On the other hand, in recent years, as described in Patent Document 2, an ONU having even the function of L2 of the OSI reference model has been developed. As described above, when the ONU is configured as a multi-layer module having the functions of L1 and L2, the optical transmission system is a multi-layer in which the OLT on the center side and the ONU on the subscriber premises operate with the same protocol. It becomes a layer module system. In such an optical transmission system, it is desirable in terms of operation to centrally manage status signals related to optical communication on the center side.

  However, even if the ONU is configured as a multi-layer module, all the maintenance information is output to the host device as before, and the host device displays its own maintenance information and ONU maintenance information. The configuration was centrally managed. Therefore, there is a problem that the status signal related to the optical communication of the ONU which is a multi-layer module cannot be centrally managed on the center side, and the status management of the optical communication of the optical transmission system is not easy.

  Therefore, the present invention has been made to solve such a problem, and maintenance information related to optical communication can be centrally managed by the center side optical line terminating device on the subscriber premises side of the multilayer module. An object of the present invention is to provide an optical line terminator and an optical transmission system using the same.

  In order to solve the above-mentioned problem, a first aspect of a subscriber premises optical line terminator of a multilayer module of the present invention is connected to a center side optical line terminator via an optical transmission line, Is a subscriber-side optical line terminator for multi-layer modules connected by an MSA (multi-source agreement) interface, and is connected to the center-side optical line terminator for optical / electrical conversion and electrical / optical conversion of signals. Acquiring and storing a variation value of maintenance information including control data and status data connected to the transmission / reception circuit, and a MAC unit connected to the transmission / reception circuit for terminating the signal. A controller that stores a fixed value of predetermined maintenance information; a first serial interface that connects the controller and the MAC unit; A second serial interface for connecting the controller and the host device, and when the controller inputs the request for the maintenance information, the request is sent from the center side optical line terminator side or the host device side. The maintenance information is selected according to the condition and is output to the center side optical line terminating device or the host device.

  In another aspect of the multi-layer module subscriber premises optical line terminator according to the present invention, the controller selects the variation value when the maintenance information request is from the center optical line terminator side. Output to the MAC unit via the first serial interface, and when the maintenance information request is from the host device side, the fixed value is selected and the host device is selected via the second serial interface. The MAC unit inputs the variation value of the maintenance information from the controller, writes it into the signal, performs electrical / optical conversion by the transmission / reception circuit, and transmits it to the center side optical line termination device. Features.

  In another aspect of the multi-layer module subscriber premises optical line termination device according to the present invention, the controller includes a CPU and a memory that stores a fixed value and a variation value of the maintenance information. When the maintenance information request is input from the center side optical line termination device via the MAC unit and the first serial interface, the variation value is read from the memory and output to the MAC unit, while the second serial interface is When the maintenance information request is input from the host device, the fixed value is read from the memory and output to the host device.

  In another aspect of the multi-layer module subscriber premises optical line termination device of the present invention, the controller includes a CPU, a memory for storing fixed values and fluctuation values of the maintenance information, and the CPU as the first serial. An interface and a BUS switch circuit connected to one of the second serial interfaces, and when the CPU is connected to the first serial interface by the BUS switch circuit, the CPU reads the variation value from the memory. While outputting to the MAC unit, when the BUS switch circuit is connected to the second serial interface, the fixed value is read from the memory and output to the host device.

  In another aspect of the multi-layer module subscriber premises optical line terminator according to the present invention, the BUS switch circuit receives the maintenance information from the center side optical line terminator via the MAC unit and the first serial interface. When the request is input, the CPU is connected to the first serial interface, and when the maintenance information request is input from the host device via the second serial interface, the CPU is connected to the second serial interface. It is characterized by that.

  According to another aspect of the multi-layer module subscriber premises optical line termination device according to the present invention, when the BUS switch circuit determines a signal input from the first serial interface, the CPU is connected to the first serial interface. On the other hand, when the signal input from the second serial interface is determined, the CPU is connected to the second serial interface.

  Another aspect of the multi-layer module customer premises optical line termination device according to the present invention is characterized in that the BUS switch circuit is a latch setting switch.

  In another aspect of the multi-layer module subscriber premises optical line terminator according to the present invention, the BUS switch circuit has a non-latching setting including a capacitor that holds a connection state for a predetermined time when a predetermined signal is input. It is a switch.

  In another aspect of the multi-layer module subscriber premises optical line termination device according to the present invention, the MAC unit uses the OAM (Operation, Administration, and Maintenance) of the signal as a fluctuation value of the maintenance information input from the controller. Write to the layer.

  In another aspect of the multi-layer module subscriber premises optical line terminator according to the present invention, the transmission / reception circuit controls an optical input / output terminal for performing optical / electrical conversion and electrical / optical conversion, and controls the electrical / optical conversion. And a limiting amplifier that allows the optical / electrically converted electrical signal to pass within a predetermined range. The controller includes the optical input / output terminal, the LD driver, and the limiting amplifier. A variation value of information is input.

  According to another aspect of the present invention, the first serial interface and the second serial interface are I2C (Inter-Integrated Circuit) signal lines. .

  According to a first aspect of the optical transmission system of the present invention, there is provided a maintenance function for managing maintenance information related to optical communication and a subscriber premises optical line termination device of one or more multilayer modules according to any one of the above aspects. A center side optical line terminator having a logic unit, an optical transmission line for transmitting a signal of an optical signal by connecting the center side optical line terminator and the customer premises side optical line terminator of the multilayer module; The maintenance function logic unit centrally manages the fluctuation value of the maintenance information transmitted from the subscriber optical fiber terminal unit of the one or more multilayer modules via the optical transmission line. And

  According to the present invention, a multi-layer module customer-side optical line terminator capable of transmitting maintenance information related to optical communication to the center-side optical line terminator and centrally managing it on the center side, and the same are used. An optical transmission system can be provided, and management of maintenance information of the optical transmission system is facilitated.

1 is a block diagram showing a schematic configuration of a subscriber premises optical line terminating device of a multilayer module according to a first embodiment of the present invention. 1 is a block diagram showing a schematic configuration of an optical transmission system according to a first embodiment of the present invention. It is a block diagram which shows schematic structure of the center side optical line termination | terminus apparatus. It is explanatory drawing for demonstrating the management system of the maintenance information by the subscriber premises optical line termination | terminus apparatus of the multilayer module of 1st Embodiment. It is a block diagram which shows schematic structure of the subscriber premises optical line termination | terminus apparatus of the multilayer module which concerns on the 2nd Embodiment of this invention. It is a block diagram which shows schematic structure of the subscriber premises optical line termination | terminus apparatus of the multilayer module which concerns on the 3rd Embodiment of this invention. It is a block diagram showing the schematic configuration of the I 2 ^C line. Is an explanatory view showing an example of data and clock signals are transmitted by the I 2 ^C line. It is a schematic block diagram which shows the conventional optical transmission system. It is a block diagram which shows schematic structure of the conventional subscriber premises optical line termination | terminus apparatus. It is explanatory drawing for demonstrating the memory map of the memory which has preserve | saved maintenance information.

  With reference to the drawings, a detailed description will be given of the configuration of a subscriber-side optical line terminating device of a multi-layer module and an optical transmission system using the same in a preferred embodiment of the present invention. 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 terminal unit (ONU) of a multilayer module according to a first embodiment of the present invention will be described with reference to FIG. FIG. 1 is a block diagram showing the configuration of the ONU 100 of the present embodiment. FIG. 2 shows an optical transmission system 1 according to the first embodiment of the present invention configured using the ONU 100 according to this embodiment shown in FIG. Further, the configuration of the center-side optical line terminator (OLT) 10 provided on the center side of the optical transmission system 1 is shown in the block diagram of FIG.

  In the optical transmission system 1 shown in FIG. 2, the OLT 10 provided on the center side is connected to a multiplexing end of an optical coupler (optical multiplexing / demultiplexing unit) 32 with an optical fiber 31, and a plurality of demultiplexing ends of the optical coupler 32 are connected to each other. One end of each of the plurality of optical fibers 33 is connected. The ONU 100 of this embodiment is used by being connected to the other end of the optical fiber 33 and can transmit an optical signal to and from the OLT 10 via the optical fibers 31 and 33 and the optical coupler 32.

  Each ONU 100 is installed in each subscriber's house and is connected to a host device 50 such as a personal computer, a switch, or a router. Examples of the switch used as the host device 50 include an L2 switch, an L3 switch, and a router. OLT10 and ONU100 are GPON (abbreviation for Gigabit Passive Optical Network, compliant with ITU standard G.984.x), and GEPON (abbreviation for Gigabit Ethernet (registered trademark) PON), compliant with IEEE802.3ah standard. Equipment that conforms to the provisions of

  1 and 2 illustrate an example in which the ONU 100 includes an MSA interface module as an interface with the host device 50. By using the MSA interface module, the ONU 100 can be directly connected to the MSA interface slot provided in the host device 50. As the MSA interface module, there are modules such as GBIC and SFP.

  As shown in FIG. 3, the OLT 10 installed on the center side includes an optical transceiver 11 of a physical layer (L1) module for transmitting and receiving optical signals to and from each ONU 100 on the subscriber's home side, and a data link layer ( And an OLT side MAC (Media Access Control) unit 12 that is a function of L2), an OLT side signal logic unit 13 that processes a signal, and an OLT side maintenance function logic unit 14 that processes a maintenance signal, It has a multi-layer module configuration.

  The optical transceiver 11 includes an OLT side optical input / output terminal 15, an LD driver (LDD) 16, a limiting amplifier (LIM) 17, and an OLT side controller 18. The OLT side optical input / output terminal 15 receives the electrical signal / optical conversion for converting the electrical signal of the downstream signal output from the OLT side signal logic unit 13 side into the optical signal, and the optical signal of the upstream signal received from the subscriber premises side. Each optical device for performing optical / electrical conversion for converting into an electrical signal is provided. As an optical device, a PD (photodiode) is used for optical / electrical conversion, and an LD (laser diode) is used for electrical / optical conversion.

  The electrical signal of the downlink signal input from the OLT side MAC unit 12 is output to the LD driver 16 that drives the LD, and the LD driver 16 drives the LD (not shown) provided in the OLT side optical input / output terminal 15. Thus, it is converted into a downstream optical signal and output. Further, the electrical signal of the upstream signal received and optically / electrically converted by the OLT side optical input / output terminal 15 is output to the OLT side MAC unit 12 via the limiting amplifier 17, and further, the OLT side signal logic unit 13. Is output.

  The OLT-side controller 18 receives control data and status data (LD current, output power, received power, etc.) from the OLT-side optical input / output terminal 15, the LD driver 16, and the limiting amplifier 17, and uses them as fluctuation values of maintenance information. Are output to the OLT side MAC unit 12 and further output from the OLT side MAC unit 12 to the OLT side maintenance function logic unit 14. In addition to the main interface 19 for transmitting signals, a serial interface 20 for connecting the OLT side controller 18 and the OLT side MAC unit 12 is provided between the optical transceiver 11 and the OLT side MAC unit 12. The maintenance information of the OLT 10 is transmitted from the OLT side controller 18 to the OLT side MAC unit 12 via the serial interface 20. The OLT-side MAC unit 12, the OLT-side signal logic unit 13, and the OLT-side maintenance function logic unit 14 are connected by respective BUSs.

  As shown in FIG. 1, the ONU 100 of this embodiment has a configuration similar to the OLT 10 described above, and is a system that operates with the same protocol as the OLT 10. That is, the ONU 100 includes a physical layer module including an ONU side optical input / output terminal 111, an LD driver 112, a limiting amplifier 113, and an ONU side controller 114, and a data link layer module of the ONU side MAC unit 120. As described above, the ONU 100 according to the present embodiment is a multi-layer module having functions of two layers of the physical layer and the data link layer, like the OLT 10.

  On the other hand, the ONU 100 does not include the signal logic unit and the maintenance function logic unit that the OLT 10 has, and the signal processing and the maintenance information processing are performed on the host side signal logic unit 51 and the host device 50 side. This is performed by the host side maintenance function logic unit 52.

  The downstream optical signal transmitted from the OLT 10 is optically / electrically converted at the ONU optical input / output terminal 111 to become an electrical downstream signal, and is transmitted to the ONU MAC unit 120 via the limiting amplifier 113. Then, a downstream signal is output to the host-side signal logic unit 51 of the host device 50 via the signal main interface 131. The upstream signal of the electrical signal output from the host-side signal logic unit 51 of the host device 50 is output to the ONU-side MAC unit 120 via the main interface 131, and further output from the ONU-side MAC unit 120 to the LD driver 112. Then, an LD (not shown) in the ONU side light input / output terminal 111 is driven. Thereby, the electrical signal of the upstream signal is subjected to electrical / optical conversion, and the upstream optical signal is transmitted to the OLT 10 side.

  The ONU-side controller 114 receives control data and status data (LD current, output power, received power, etc.) from the ONU-side optical input / output terminal 111, the LD driver 112, and the limiting amplifier 113. It is stored as a fluctuation value. The ONU 100 manufacturer name, model number, serial number, etc. A fixed value such as is also stored.

  Next, the maintenance information management method of the ONU 100 will be described with reference to FIG. In the conventional multi-layer module ONU, the host device is configured to centrally manage the maintenance information in the ONU together with its own maintenance information, and the maintenance information in the ONU is output only to the host device. It was.

  However, in a system in which the OLT 10 and the ONU 100 are configured by a multilayer module that operates with the same protocol as in the optical transmission system 1 of the present embodiment, at least the status signal related to optical communication among the maintenance information of the ONU 100 is transmitted to the OLT 10. It is desirable from the viewpoint of system management that the central management should be performed together with the maintenance information. In addition, it is desirable that the fixed information necessary for connecting the ONU 100 and the host device 50 among the maintenance information is centrally managed by the host device 50 as in the past.

  Therefore, in the ONU 100 and the optical transmission system 1 according to the present embodiment, the fixed value of the maintenance information is output to the host device 50 and managed on the host device 50 side as in the past, and at least the status signal related to optical communication. The variation value of the maintenance information is transmitted to the OLT 10 on the center side and is centrally managed on the center side.

  In FIG. 4, the ONU side controller 114 includes a CPU 115 and a memory 116. In the memory 116, a fixed value of maintenance information is stored starting from address # A0, and a variation value of maintenance information is stored starting from address # A2.

When there is a request for maintenance information from the host device 50 side, a fixed value of maintenance information is selected by the processing of the CPU 115, and this is output to the host-side maintenance function logic unit 52 of the host device 50 via the serial interface 132. On the other hand, when there is a maintenance information request from the OLT 10 side, a variation value of the maintenance information is selected by the processing of the CPU 115, which is output to the ONU side MAC unit 120 via the serial interface 121, and is transmitted to the ONU side MAC unit 120. It is added to the signal and transmitted to the OLT 10. As the serial interfaces 132 and 121, I ² C (Inter-Integrated Circuit) can be used.

  In the PON type optical transmission system 1, in order to transmit maintenance information between the OLT 10 and the ONU 100, an OAM (Operation, Administration, and Maintenance) layer is provided in the signal. The OAM layer corresponds to the second data link layer in the OSI reference model, and is used to transmit information necessary for maintenance and the like.

  The variation value of the maintenance information transmitted to the OLT 10 is output from the ONU side controller 114 to the ONU side MAC unit 120, and is written in the OAM layer of the upstream signal by the ONU side MAC unit 120. The upstream signal is output to the LD driver 112, and the upstream optical signal subjected to electrical / optical conversion under the control of the LD driver 112 is transmitted from the ONU side optical input / output terminal 111 to the OLT 10. The optical signal transmitted to the OLT 10 is converted into an electrical signal at the OLT side optical input / output terminal 15 and then output to the OLT side MAC unit 12. The OLT side MAC unit 12 then transmits the maintenance information of the ONU 100 from the OAM layer of the upstream signal. Read the fluctuation value. The read variation value of the maintenance information of the ONU 100 is output to the OLT-side maintenance function logic unit 14 where it is centrally managed together with the maintenance information of the OLT 10.

  As described above, according to the ONU 100 of the present embodiment and the optical transmission system 1 using the same, the maintenance information fluctuation value that is at least a status signal related to optical communication among the maintenance information of the ONU 100 that is a multilayer module. Is transmitted to the OLT 10 and can be centrally managed on the center side, and a fixed value of maintenance information necessary for connecting the ONU 100 to the host device 50 is output to the host device 50 and the host Centralized management can be performed on the device 50 side. By using the subscriber premises optical line termination device of this embodiment which is a multi-layer module, management of maintenance information of the optical transmission system is facilitated.

  A subscriber premises optical line terminating device for a multilayer module according to a second embodiment of the present invention will be described with reference to FIG. FIG. 5 is a block diagram showing a configuration of the ONU 200 of the present embodiment. In the ONU 200 according to the present embodiment, the ONU controller 214 further includes a BUS switch circuit 217. The CPU 215 in the ONU-side controller 214 is connected to the ONU-side MAC unit 120 or the host-side maintenance function logic unit 52 in the host device 50 via the BUS switch circuit 217.

  For example, when there is a request for maintenance information from the ONU side MAC unit 120 in response to an instruction from the center side, the BUS switch circuit 217 sets the switch state between the ONU side MAC unit 120 and the CPU 215 (closed state). The host-side maintenance function logic unit 52 is disconnected (opened). Further, the BUS switch circuit 217 outputs a status signal 218 indicating that the request is from the ONU side MAC unit 120 to the CPU 215. Alternatively, a status signal 218 indicating that the switch state is a state in which the ONU side MAC unit 120 and the CPU 215 are connected may be output to the CPU 215.

  Similarly, when there is a request for maintenance information from the host-side maintenance function logic unit 52, the BUS switch circuit 217 sets the switch state between the host-side maintenance function logic unit 52 and the CPU 215 (closed state). The ONU side MAC unit 120 is disconnected (opened). The BUS switch circuit 217 outputs a status signal 218 indicating that the request is from the host-side maintenance function logic unit 52 to the CPU 215. Alternatively, a status signal 218 indicating that the switch state is a state in which the host side maintenance function logic unit 52 and the CPU 215 are connected may be output to the CPU 215.

  Based on the status signal 218 input from the BUS switch circuit 217, the CPU 215 determines whether the maintenance information request is from the ONU side MAC unit 120 or from the host side maintenance function logic unit 52. to decide. As a result, in the case of a request from the ONU side MAC unit 120, the switch state of the BUS switch circuit 217 is in a state connected to the ONU side MAC unit 120 side. The variation value of the maintenance information stored in the address # A2 is output to the ONU side MAC unit 120 via the BUS switch circuit 217. The ONU side MAC unit 120 writes the variation value of the maintenance information input from the CPU 215 to the OAM layer of the upstream signal, and transmits this to the OLT 10.

  On the other hand, when the CPU 215 determines that the maintenance information request is from the host-side maintenance function logic unit 52, the switch state of the BUS switch circuit 217 is connected to the host-side maintenance function logic unit 52 side. Therefore, the CPU 215 outputs the fixed value of the maintenance information stored at the address # A0 in the memory 116 to the host side maintenance function logic unit 52 via the BUS switch circuit 217.

  As the status signal 218 output from the BUS switch circuit 217 to the CPU 215, in the above, a signal indicating whether the maintenance information request is from the ONU side MAC unit 120 or the host side maintenance function logic unit 52, or a BUS switch A signal indicating the connection state of the circuit 217 is used. In addition to this, the status signal 218 may include a signal designating request data. As maintenance information, it is possible to request not only a preset fixed value or a variable value but also one or a plurality of individual data. In this case, for example, when requesting maintenance information from the host-side maintenance function logic unit 52, it is possible not to transmit even if there is a request for variable value data.

  According to the ONU 200 of the present embodiment, as in the ONU 100 of the first embodiment, at least a variation value that is a status signal related to optical communication among the maintenance information of the ONU 200 that is a multilayer module is transmitted to the OLT 10. It is possible to perform centralized management on the center side, and output a fixed value of maintenance information necessary for connecting the ONU 100 to the host device 50 to the host device 50 for centralized management on the host device 50 side. It becomes possible. In addition, the ONU 200 of the present embodiment is provided with a BUS switch circuit 217 that switches the connection state depending on whether the maintenance information request is from the ONU side MAC unit 120 or the host side maintenance function logic unit 52. Thus, the CPU 215 only needs to output the requested maintenance information to the BUS switch circuit 217, and the processing can be simplified.

In the ONU 100 of the first embodiment, the CPU 115 in the ONU-side controller 114 needs to include two I ² C lines of the serial interfaces 121 and 132. However, in the ONU 200 of the present embodiment, the BUS switch circuit 217 is connected to the CPU 215. By providing separately, it is not necessary to provide the CPU 215 with a plurality of I ² C lines, and by configuring the BUS switch circuit 217 with a logic circuit, a simple configuration can be achieved.

  A subscriber premises optical line terminating device for a multilayer module according to a third embodiment of the present invention will be described with reference to FIG. FIG. 6 is a block diagram illustrating a configuration of the ONU 300 according to the present embodiment. In the ONU 300 of this embodiment, the ONU-side controller 314 has a BUS switch circuit 317 as in the ONU 200 of the second embodiment, but the operation of the BUS switch circuit 317 is the same as that of the second embodiment. Different from the BUS switch circuit 217.

Here, an outline of communication using the I ² C line will be described. As shown in FIG. 7, the I ² C line is at least composed of two lines (physical lines), that is, a data line (DATA) 61 and a clock line (CLOCK) 62. An example of a signal transmitted through the I ² C line is shown in FIG. The basic operation of the I ² C line is as follows: (1) Data (indicated by DATA in FIG. 8) is transmitted from the master 63 via the data line 61, (2) the slave 64 receives this DATA, and (3) At the same time, a clock signal (indicated by CLOCK in FIG. 8) is sent from the master 63 to the slave 64 via the clock line 62, and (4) synchronized I ² C communication is performed by this CLOCK.

  In the second embodiment and the third embodiment, the OLT 10 connected to the serial interface 121 side or the host device 50 connected to the serial interface 132 side corresponds to the master 63. In both of the serial interfaces 121 and 132, the BUS switch circuits 217 and 317 correspond to the slave 64.

  The BUS switch circuit 217 of the second embodiment performs a passive operation of switching in accordance with an instruction from the OLT 10 corresponding to the master 63 or the host device 50. On the other hand, the BUS switch circuit 317 of the present embodiment is characterized in that it operates actively as described below.

The BUS switch circuit 317 is normally connected to the serial interface 121 side (OLT 10 side) or the serial interface 132 side (host device 50 side). Here, as an example, it is assumed that the BUS switch circuit 317 is connected to the serial interface 121 side. In this state, when DATA is transmitted from the OLT 10 on the connection side, I ² C communication processing is performed by the serial interface 121 without switching the switch state.

  On the other hand, when DATA is transmitted from the unconnected host device 50 side, the BUS switch circuit 317 switches the connection state and connects to the serial interface 132 side. That is, when BUS switch circuit 317 of this embodiment receives DATA, whether it is from the connection side or the non-connection side when DATA is received (indicated by arrow A in FIG. 8). As a result, an active processing operation is performed such as switching the switch when it is determined that DATA transmission from the non-connection side.

  As described above, in order to prevent malfunction of the BUS switch circuit 317 that operates actively, a latch setting switch is preferably used for the BUS switch circuit 317. When a non-latch setting switch is used for the BUS switch circuit 317, by inputting DATA as shown in FIG. 8, the connection state during the period for inputting DATA and the non-connection state during the period for not inputting DATA are set. The operation is frequently repeated, and the exchange of DATA cannot be performed properly.

  Therefore, when a non-latch setting switch is used for the BUS switch circuit 317, it is preferable that the connection state of the switch is held until a certain time has passed after the DATA is input. In FIG. 8, when the first pulse indicated by the arrow A of DATA is input, the switch is connected and held until a certain time has elapsed, and the connection state of the switch is also held for a certain time after that. . This makes it possible to input DATA while the switch is connected. Furthermore, although the connection state is maintained for a certain time with respect to the last pulse indicated by the arrow B, the switch is disconnected after the certain time has elapsed. Thus, in order to maintain the connection state of the switch for a certain time after the end of the pulse, a predetermined capacitor is preferably inserted into the DATA line. Thereby, the connection state of the switch can be held for a certain period of time with a simple structure.

  Note that the description in the present embodiment shows an example of the multi-layer module subscriber-side optical line terminator according to the present invention and an optical transmission system using the same, and is not limited thereto. . The detailed configuration and detailed operation of the multi-layer module subscriber premises optical line termination device and the like in the present embodiment can be changed as appropriate without departing from the spirit of the present invention.

1 Optical transmission system 10 OLT
DESCRIPTION OF SYMBOLS 11 Optical transceiver 12 OLT side MAC part 13 OLT side signal logic part 14 OLT side maintenance function logic part 15 OLT side optical input / output terminal 16 LD driver 17 Limiting amplifier 18 OLT side controller 19, 131 Main interface 20, 121, 132 Serial Interface 31, 33 Optical fiber 32 Optical coupler 50 Host device 51 Host side signal logic unit 52 Host side maintenance function logic unit 100, 200, 300 ONU
111 ONU side optical input / output terminal 112 LD driver 113 Limiting amplifier 114, 214, 314 ONU side controller 115, 215 CPU
116 memory 120 ONU side MAC unit 217, 317 BUS switch circuit

Claims (12)

It is connected to the center side optical line terminator via the optical transmission line, and the host device is a multi-layer module subscriber's side optical line terminator connected by the MSA (multi source agreement) interface,
A transmission / reception circuit connected to the center-side optical line terminator for performing optical / electrical conversion and electrical / optical conversion of signals;
A MAC unit connected to the transmission / reception circuit to perform termination processing of the signal;
A controller connected to the transmission / reception circuit for acquiring and storing a variation value of maintenance information composed of control data and status data, and storing a fixed value of predetermined maintenance information;
A first serial interface connecting the controller and the MAC unit;
A second serial interface for connecting the controller and the host device,
When the controller inputs the maintenance information request, the controller selects the maintenance information depending on whether the request is from the center side optical line terminator side or from the host side, and the center side optical line terminator or A multi-layer module subscriber premises optical line terminating device, characterized in that the multi-layer module outputs to the host device. When the request for the maintenance information is from the center side optical network unit, the controller selects the variation value and outputs it to the MAC unit via the first serial interface,
When the maintenance information request is from the host device side, the fixed value is selected and output to the host device via the second serial interface;
The MAC unit receives a variation value of the maintenance information from the controller, writes it into the signal, performs electrical / optical conversion by the transmission / reception circuit, and transmits the converted signal to the center side optical line terminator. Item 8. The subscriber-side optical line termination device for a multilayer module according to Item 1. The controller includes a CPU and a memory for storing a fixed value and a fluctuation value of the maintenance information,
When the CPU inputs the maintenance information request from the center-side optical line termination device via the MAC unit and the first serial interface, the CPU reads the variation value from the memory and outputs the variation value to the MAC unit.
3. The multi-layer according to claim 1, wherein when the maintenance information request is input from the host device via the second serial interface, the fixed value is read from the memory and output to the host device. 4. Optical fiber termination equipment on the subscriber's side of the module. The controller includes a CPU, a memory that stores fixed values and fluctuation values of the maintenance information, and a BUS switch circuit that connects the CPU to one of the first serial interface and the second serial interface.
When the CPU is connected to the first serial interface by the BUS switch circuit, the CPU reads the variation value from the memory and outputs it to the MAC unit,
3. The subscriber of the multilayer module according to claim 1, wherein when the BUS switch circuit is connected to the second serial interface, the fixed value is read from the memory and output to the host device. 4. Home-side optical line termination equipment. The BUS switch circuit connects the CPU to the first serial interface when the maintenance information request is input from the center-side optical line termination device via the MAC unit and the first serial interface.
5. The multi-layer module subscriber side according to claim 4, wherein the CPU is connected to the second serial interface when a request for the maintenance information is input from the host device via the second serial interface. Optical line termination equipment. When the BUS switch circuit determines a signal input from the first serial interface, the BUS switch circuit connects the CPU to the first serial interface. On the other hand, when the BUS switch circuit determines a signal input from the second serial interface, the CPU switches the CPU to the first serial interface. The multi-layer module subscriber premises optical line terminator according to claim 4, which is connected to two serial interfaces. The subscriber-side optical line termination device for a multilayer module according to any one of claims 4 to 6, wherein the BUS switch circuit is a latch setting switch. 7. The switch according to claim 4, wherein the BUS switch circuit is a non-latching switch including a capacitor that holds a connection state for a predetermined time when a predetermined signal is input. 8. Multi-layer module subscriber premises optical line terminator. 5. The MAC unit according to claim 1, wherein the MAC unit writes a variation value of the maintenance information input from the controller in an OAM (Operation, Administration, and Maintenance) layer of the signal. 6. Multi-layer module subscriber premises optical line terminator. The transmission / reception circuit passes an optical input / output terminal that performs optical / electrical conversion and electrical / optical conversion, an LD driver that controls the electrical / optical conversion, and the optical / electrically converted electrical signal within a predetermined range. A limiting amplifier is provided, and the controller inputs a variation value of the maintenance information from the optical input / output terminal, the LD driver, and the limiting amplifier. A subscriber-side optical line termination device for a multilayer module as described in the above section. The multi-layer module subscriber side according to any one of claims 1 to 6, wherein the first serial interface and the second serial interface are I2C (Inter-Integrated Circuit) signal lines. Optical line termination equipment. A subscriber premises optical line terminating device of one or more multilayer modules according to any one of claims 1 to 11,
A center-side optical line termination device having a maintenance function logic unit for managing maintenance information related to optical communication;
An optical transmission line that transmits the signal of the optical signal by connecting the center side optical line terminator and the customer premises optical line terminator of the multilayer module;
The maintenance function logic unit centrally manages the fluctuation value of the maintenance information transmitted from the subscriber premises optical line terminating device of the one or more multilayer modules via the optical transmission line. Transmission system.

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