JP2008160197A - Subscriber premise optical line terminating apparatus and optical transmission system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a subscriber premise optical line terminating apparatus and an optical transmission system for facilitating the connection of an optical transmission path and a plurality of terminal equipment, and for making an equipment arrangement space narrower than the conventional manner, and for improving reliability of configuring equipment by reducing a power source for ONU and a cable. <P>SOLUTION: The subscriber premise optical line terminating apparatus is provided with an optical transceiver 6 connected through an optical coupler 3 to an optical fiber 2 connected to an OLT1a for performing light-to-electricity conversion and electricity-to-light conversion; an ONU functioning part 7 connected to the electric signal input/output terminal of the optical transceiver 6; a conversion means 8 connected to the media independent interface signal edge of the ONU function part 7 for performing media independence interface/USB interface conversion and inverse conversion; and a USB interface 9. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a subscriber premises optical line terminator and an optical transmission system, and more particularly, to a subscriber premises optical line terminator having a USB interface attached to a subscriber premises end of an optical transmission line and the apparatus. The present invention relates to an optical transmission system including

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

  In such an optical transmission system, as shown in FIG. 7, a splitter 103 is connected to an optical fiber 102 drawn from a center optical line terminator (OLT) 101 to the user side, and branched by the splitter 103. A plurality of optical transmission lines are connected to optical network terminating units (ONUs) 105-1,... 105-n at the subscriber's homes via optical fibers 104-1,.

  The ONUs 105-1,... 105-n are composed of an optical transceiver unit 106 and an ONU function unit 107, as shown in FIG. The optical transceiver unit 106 is connected to the optical fiber 102 that is drawn indoors from the outside through the optical termination unit 108, for example.

For example, a LAN cable 110 is connected to an Ethernet (registered trademark) interface 107a such as 100 / 1000BASE-TX of the ONU function unit 107, and a computer 111, a router 112, a switching hub 113, and the like are connected to the LAN cable 110. Is done. Further, a terminal device 114 such as a computer or a printer is connected to the router 112 or the switching hub 113.
The Ethernet (registered trademark) interface 107a includes a physical layer (PHY: Physical Layer) connected to a media independent interface (MII) of an ONU LSI, a transfer, and a connector sequentially connected thereto. It is configured.
JP-A-9-214541

  In order to connect a plurality of terminal devices 114 to the ONUs 105-1,... 105-n, a router 112 or a switching hub 113 is required. A cable will be interposed.

  For this reason, when a plurality of terminal devices are to be connected to the end of the optical transmission line, the ONU is connected to the end, and the ONU and the router or the switching hub are connected with a cable. Moreover, it is necessary to secure a wide device installation space for the arrangement of these devices and their power supplies for ONUs and for the routing of cables. On the other hand, there is a problem in that the reliability of the entire component equipment is reduced due to the power supply or gable for ONUs. is there.

  An object of the present invention is to facilitate the connection between an optical transmission line and a plurality of terminal devices, narrow the device arrangement space as compared with the conventional device, and improve the reliability of the component devices by reducing the power supply for the ONU and cables. It is an object of the present invention to provide a subscriber premises optical line termination device and an optical transmission system.

  In order to solve the above-described problem, the subscriber premises optical line termination device according to the first aspect of the present invention is connected to the optical transmission line connected to the center side optical line termination device via an optical branching and coupling unit. An electrical / optical conversion means for performing photoelectric conversion and reverse photoelectric conversion, an optical line termination device function unit connected to an electrical signal input / output terminal of the electrical / optical conversion unit, and an optical line termination device function unit The gist of the present invention is to have a USB interface and a conversion means that is connected to a media independent interface signal terminal and performs media independent interface / USB interface conversion and vice versa.

The gist of a subscriber premises optical line terminating device according to another aspect of the present invention is that the media-independent interface is configured by GMII or MII.
In the customer-side optical line terminator according to another aspect of the present invention, the conversion means has a GMII or MII and MDIO interface, and the optical line terminator function section has a GMII, MII, and a management control signal terminal. This is the gist.

  According to another aspect of the present invention, in the customer premises optical line termination device, the conversion means has a GMII or MII and MDIO interface, and the optical line termination device function unit has a GMII, MII and MDIO interface. The gist.

  In a subscriber premises optical line terminating device according to another aspect of the present invention, the optical line terminating device function unit, when a PON link is established between the center side and the optical line terminating device at the subscriber premises, Alternatively, a management for outputting a management control signal for establishing a communication state between the conversion unit and the USB interface, which is output when authentication is established between the center side and the optical line termination device, to the conversion unit. The gist is to have a control signal terminal.

  In a subscriber premises optical line termination device according to another aspect of the present invention, the optical line termination device function unit is configured such that when a PON link is established between the center side and the optical line termination device, or Management control for outputting a management control signal for establishing a communication state between the conversion means and the USB interface, which is output when authentication is established between the center side and the optical line terminating device. And a management control signal control unit for communicating the management control signal input or output from the management control signal terminal between the optical line terminator function unit and the conversion means. The gist.

According to another aspect of the present invention, there is provided a subscriber premises optical line terminator that uses an MDIO interface signal for the management control signal controller of the optical line terminator function unit.
In a subscriber premises optical line termination device according to another aspect of the present invention, the management control signal terminal of the optical line termination device function unit uses an MDIO interface, and the management control signal control unit uses an MDIO interface signal. Is the gist.

  An optical transmission system according to a second aspect of the present invention includes a subscriber premises optical line terminator according to any one of the above aspects, and a first optical transmission line in the subscriber premises optical line terminator. An optical branching and coupling unit having a customer premises port connected via the second optical transmission line; a second optical transmission line connected to the center side port of the optical branching and coupling part; and a second optical transmission line connected to the second optical transmission line And a center-side optical line terminating device.

  The gist of an optical transmission system according to another aspect of the present invention is that the USB interface of the subscriber premises optical line terminator is directly connected to a USB interface slot of a node arranged outside thereof. .

  According to the present invention, a subscriber premises optical line terminator can be directly connected to a node without routing a wiring by inserting the subscriber premises optical line terminator into a USB slot of a node such as a computer. Can do. Further, the subscriber premises optical line termination device can be configured compactly, and a small installation place is sufficient. Further, the power adapter and LAN cable for the subscriber premises optical line terminator are not required, and the reliability of the constituent devices can be improved.

  Also, the subscriber premises optical line terminator communicates between the subscriber premises and the center by a management control signal that is output when the PON link is established or when authentication of the optical line terminator is established. I try to establish a state. For this reason, for example, before the PON link is established or before the authentication of the optical line terminator is confirmed, a signal is transmitted from the inserted computer side to the optical line terminator on the subscriber's home side, and a communication error occurs. It is possible to eliminate the error process.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1 shows a schematic configuration of an optical transmission system according to an embodiment of the present invention. This optical transmission system is a PON type optical transmission system.

  1 is an optical transmission line that is connected to a center side (station side) optical line terminator (hereinafter referred to as “OLT”) 1a. An optical transceiver 6 is connected to the fiber (second optical transmission line) 2 via an optical coupler (optical branching and coupling unit) 3 and serves as an electrical / optical conversion means for performing photoelectric conversion and reverse photoelectric conversion. The subscriber premises optical line terminator includes an ONU function unit 7 which is an optical line terminator function unit connected to an electric signal input / output terminal of the optical transceiver 6 and a media independent interface signal terminal of the ONU function unit 7. 7 includes a GMII / USB conversion unit (conversion unit) 8 that is connected to 7a and 7b (see FIG. 2) and performs media-independent interface / USB interface conversion and reverse conversion, and a USB interface 9.

  In the optical transmission system shown in FIG. 1, the PON interface card 1 provided in the center has an OLT 1a and an authentication function unit 1b, and one end of an optical fiber 2 is connected to the optical input / output end of the OLT 1a. An optical coupler 3 is connected to the other end of the optical fiber 2, that is, the subscriber's home side.

  The optical transmission line branched into a plurality by the optical coupler 3 is a plurality of optical line terminators (hereinafter referred to as “the optical transmission line termination devices”) on the subscriber's home side through optical fibers (first optical transmission lines) 4-1,. ..., 5-n (n: natural number).

  The center OLT 1a determines whether or not a predetermined condition is satisfied by exchanging signals with the ONUs 5-1 to 5-n when connecting to the ONUs 5-1 to 5-n. In this case, it is determined that the establishment of the data link is normal. At this time, the OLT 1a and the ONUs 5-1 to 5-n are in a state where the PON link is established. The establishment of the PON link corresponds to the establishment of the second layer link in terms of an OSI (Open Systems Interconnection) reference model. For example, when the optical transmission system including the OLT and the ONU is GE-PON (which is an abbreviation for Gigabit Ethernet (registered trademark) Passive Optical Network and conforms to the IEEE 802.3ah standard), the establishment of the PON link is as follows. The procedure conforms to the IEEE 802.3ah standard procedure.

  The authentication function unit 1b has an authentication function, and in order to identify the connection partner of the ONUs 5-1 to 5-n after the OLT 1a and the ONUs 5-1,. The ONUs 5-1 to 5-n are accessed to acquire authentication mode data and perform authentication. Authentication modes include a MAC address authentication mode and an automatic authentication mode.

  In the MAC address authentication mode, management is performed based on individual MAC addresses set in each ONU 5-1,..., 5-n, and each MAC address of ONU 5-1,. By doing so, the ONUs 5-1 to 5-n can be identified. The automatic authentication mode is a mode in which all connected logical links are authenticated and communication of the main signal is permitted, and does not require work such as MAC address registration of the ONUs 5-1 to 5-n. It is possible to manage with the values of ONU number switches mounted on -1,.

  OLT1a, ONU5-1,..., 5-n are GPON (which is an abbreviation for Gigabit Passive Optical Network, a system conforming to ITU standard G.984.x), and a device conforming to the above GEPON regulations.

  USB / ONU (ONU with USB interface) 5 is employed as at least one of the ONUs 5-1 to 5-n. As shown in FIGS. 1 and 2, the USB ONU 5 includes an optical transceiver 6 as an electrical / optical conversion means for performing photoelectric conversion and reverse photoelectric conversion, an ONU function unit (optical line termination unit function unit) 7, It has a GMII / USB conversion unit 8, a USB interface 9, and a housing 13 for housing them. The GMII / USB conversion unit 8 corresponds to a conversion unit that performs reverse conversion to media-independent interface / USB interface conversion.

  The USB interface 9 in the USB ONU 5 corresponds to a standard that can be directly connected to a USB interface slot 21 provided in a node disposed outside the USB ONU 5, for example, a personal computer (hereinafter referred to as “personal computer”) 20. is doing. The USB interface 9 is a high-speed interface specification that realizes easy connection of an external peripheral device such as the personal computer 20. The USB ONU 5 is connected to a terminal device such as a personal computer 20 having a USB interface.

More specifically, the USB ONU 5 has a configuration as shown in FIG.
In FIG. 2, an optical transceiver 6 includes an optical coupler 6a connected to an optical fiber 4-1 on the OLT 1a side, and a light receiving element (not shown) optically coupled to the optical fiber 4-1 branched by the optical coupler 6a. And an inverse photoelectric conversion circuit 6c having a light emitting element (not shown) optically coupled to the optical fiber 4-1 branched by the optical coupler 6a. The photoelectric conversion circuit unit 6b and the reverse photoelectric conversion circuit 6c constitute an electrical / optical conversion unit that is connected to the optical transmission line on the center side and performs photoelectric conversion and reverse photoelectric conversion.

  The ONU function unit 7 is an electric circuit, which is a PON processing LSI (integrated circuit) device (ONU LSI) 10 connected to the optical transceiver 6, a synchronous static RAM 11 and flash connected to the LSI device 10. The flash memory 12 has a program written therein. The MAC address is written in the flash memory 12 or a ROM (not shown). The ONU function unit 7 has an ONU number switch (not shown) connected to the LSI device 10.

  As shown in FIG. 3, the LSI device 10 has an IEEE 802.3ah-compliant medium access control (MAC: Media Access Control) connected to the electrical signal end of the optical transceiver 6 via a gigabit serializer / deserializer (Gigabit SERDES) 10a. ) Part (hereinafter referred to as “MAC part”) 10b. The MAC unit 10b is connected to the 100/1000 MAC interface 10f via an EPON (Ethernet (registered trademark) Passive Optical Network) lookup engine 10c, a switch 10d, and a Gigabit Ethernet (registered trademark) lookup engine 10e. A FIFO 10p interposed between the synchronous SRAM 11 and the switch 10d in the LSI device 10 is connected.

  The LSI device 10 has a GMII interface, an MII interface, and a GPIO interface. The GMII / USB converter 8 has a GMII interface or an MII interface and a DMIO interface.

  The LSI device 10 outputs a GPIO signal 30 indicating a PON link establishment state and an authentication establishment state from a GPIO terminal 10 m to an MDIO (Management Data Input Output) control unit 301.

  The MDIO control unit 301 transmits the GPIO signal 30 output from the LSI device 10 to the GMII / USB conversion unit 8 via the MDIO. An MDIO interface signal (MDIO, MDC, MDINT) is used for the MDIO control unit (management control signal control unit) 301 of the ONU function unit 7.

The MAC unit 10b is connected to an 80C51 family CPU 10h and a GPIO (General Purpose I / O) interface 10i via a management interface 10g. Furthermore, the SRAM 10j and the flash memory 12 are connected to the CPU 10h.

  The management interface 10g receives a PON link establishment signal from the OLT 1a via the optical transceiver 6, the serializer / deserializer 10a, and the MAC unit 10b, and becomes a “1” signal before the PON link establishment signal is input. After the link establishment signal is input, a GPIO signal 30 that can be used as a management control signal that becomes a “0” signal is output.

  The GPIO terminal 10m that outputs the GPIO signal 30 in the management interface 10g is connected to the MDIO control unit 301, and the link state of the USB / ONU 5 and the OLT 1a is transmitted to the MDIO control unit 301 via the GPIO terminal 10m. Further, the MDIO control unit 301 notifies the GMII / USB conversion unit 8 as a link state on the GMII interface side of the GMII / USB conversion unit 8 via the MDIO signal.

  More specifically, the GPIO signal 30 output from the GPIO terminal 10m to the MDIO control unit 301 becomes a “1” signal when the PON ring is not established, and conversely, the PON link is established when the PON ring is established. The “0” signal representing That is, the “1” signal of the GPIO signal 30 represents the RX-LOSS state (reception interruption state), and the “0” signal represents the release of the RX-LOSS state (normal state).

  Such a state change is transmitted to the GMII / USB conversion unit 8 by the GMII / USB conversion unit 8 reading out from the MDIO control unit 301 via the MDIO interface.

  A more detailed transmission method from the MDIP control unit 301 to the GMII / USB conversion unit 8 is as follows.

  First, the MDIO control unit 301 outputs the MDIO signal 30 of “0” to the GMII / USB conversion unit 8 to notify the GMII / USB conversion unit 8 that there has been a change in the state of PON link establishment. The GMII / USB conversion unit 8 that has received the MDIO signal 30 of “0” performs polling confirmation to the MDIO control unit 301 using MDIO and MDC, and reads the “0” signal indicating the state of PON link establishment. When the MDIO control unit 301 reads the “0” signal indicating the PON link establishment state, the MDIO control unit 301 can recognize that the link state on the GMII interface side has been established, and the computer 20 side connected to the USB interface 9 side Communication can be started.

  In this way, by transmitting the “0” signal indicating the PON link establishment status to the GMII / USB conversion unit 8 via the MDIO control unit 301, the GMII / USB conversion unit 8 is included after the PON link is established. Communication with the personal computer 20 side can be started.

As the LSI device 10 having the above-described configuration, Technobus Inc. (Teknovus Inc.
There is a chip compliant with EPON.

  The GMII / USB converter 8 connected to the TBI unit 10k of the LSI device 10 has a function of converting / inverting a GMII signal into a USB interface signal, and performs control communication with the PHY-IC connected to the GMII interface. MDIO interface function.

  The USB interface slot 21 (see FIG. 1) has a pin (not shown) for outputting a voltage V applied from a power source (not shown) in the personal computer 20, and the USB / ONU 5 is provided via this pin. Supply power.

  In the above optical transmission system, the optical fiber 4-1 on the subscriber's home side that is optically connected to the optical fiber 2 connected to the OLT 1a is connected to the optical connector 6A (see FIG. 2) of the optical transceiver 6 of the USB ONU 5. . Further, the USB interface 9 of the USB / ONU 5 is inserted into the USB interface slot 21 of the personal computer 20 to connect the USB / ONU 5 to the personal computer 20.

  As a result, power is supplied from the USB interface slot 21 of the personal computer 20 to the USB / ONU 5, and the USB / ONU 5 enters a drive state.

  In this initial state, the GPIO signal 30 output from the management interface 10 g in the LSI device 10 of the USB / ONU 5 is “1”, and the GMII / USB conversion unit 8 sends a GMII interface via the MDIO control unit 301. By recognizing the PHY link state (the reception interruption state) in the conventional application, the signal is not propagated between the LSI device 10 and the personal computer 20.

  Here, when the USB interface 9 of the USB / ONU 5 optically connected to the OLT 1a is inserted into the USB interface slot 21 of the personal computer 20 (step S0 in FIG. 4), the operation is started between the OLT 1a and the USB / ONU 5. Communication for the PON link establishment procedure is started, and it is determined whether or not the PON link is established (step S1 in FIG. 4). On the other hand, the GMII / USB conversion unit 8 is in preparation for communication in the initial state and is in a communication cut-off state. Therefore, even if the signal 9y (see FIG. 2) is received from the personal computer 20 side, the LSI device 10 side It is possible to prevent the early link establishment with. A PON link is established between the OLT 1a and the USB / ONU 5 after an appropriate procedure (step S2 in FIG. 4).

  The LSI device 10 that has established the PON link notifies the GMII / USB conversion unit 8 that the GMII-side interface has been established via the MDIP control unit 301, whereby the GMII / USB conversion unit 8 becomes communicable, and the USB interface 9 and the LSI device 10 are brought into a communication state (step S3 in FIG. 4).

  In step S3 in FIG. 4, the LSI device 10 notifies the GMII / USB conversion unit 8 that the link on the GMII interface side has been established via the MDIO and the MDIO control unit 301. That is, the LSI device 10 first transmits the PON link establishment state to the MDIO control unit 301 via the MDIO bus. Receiving this, the MDIO control unit 301 notifies the GMII / USB conversion unit 8 that the PON link has been established as a state in which the network-side interface has been established. Alternatively, the LSI device 10 may transmit the PON link establishment state (MDIO management control signal 10b of “0”) directly to the GMII / USB conversion unit 8 via the MDIO bus (see FIG. 6).

  When the USB interface 9 and the LSI device 10 are in communication with each other (step S3 in FIG. 4), data such as the physical layer, L1, and L2 are transmitted between the OLT 1a and the personal computer 20 via the USB / ONU 5. It becomes a state.

Thus, in the state where communication between the OLT 1a and the personal computer 20 is possible, the optical signal propagated from the OLT 1 through the optical fiber 2 is branched by the optical coupler 3, and further, the optical fibers 4-1,. To a plurality of ONUs 5-1 to 5-n.
In the USB ONU 5 that constitutes at least one of the ONUs 5-1,..., 5-n, an optical signal is input to the photoelectric conversion unit 6b via the optical coupler 6a in the optical transceiver 6 and converted into an electrical signal here. Then, the data is input to the LSI device 10 in the OUN function unit 7.

  Also, in the LSI device 10, a serial signal, which is an electrical signal, is converted into a parallel signal by a gigabit serializer / deserializer (Gigabit SerDes) 10a, and further output from the GMII unit 10k through various functions in the LSI device 10. Is done. The GMII signal is converted into a USB interface signal by the GMII / USB conversion unit 8 and output to the USB interface 9.

  The USB interface signal output from the USB interface 9 is transmitted to the personal computer 20 via the USB interface slot 21.

  On the other hand, the USB interface signal output from the personal computer 20 is input to the USB interface 9.

  The USB interface signal is input to the USB interface 9 in the USB / ONU 5 via the USB interface slot 21, and further converted into a GMII signal by the GMII / USB conversion unit 8 to be a GMII unit of the LSI device 10 in the ONU function unit 7. It is input to 10k.

  Further, predetermined processing is performed in the ONU function unit 7, and the GMII signal input to the GMII unit 10 k is converted into a serial signal by the serial / parallel conversion unit 10 a of the LSI device 10 and is sent to the inverse photoelectric conversion unit 6 c of the optical transceiver 6. Is output. The reverse photoelectric conversion unit 6c converts the serial electric signal transmitted from the ONU function unit 7 into an optical signal, and the optical signal is output to the optical fiber 4-1 through the optical coupler 6a. The optical signal output from the USB / ONU 5 is transmitted to the OLT 1 a via the optical fiber 4-1, the optical coupler 3, and the optical fiber 2.

  From the above, the PON link establishment signal obtained by establishing the PON link transmitted between the OLT 1a and the USB / ONU 5 is once output to the MDIO control unit 301 and then output to the GMII / USB conversion unit 8 Then, it is transmitted to the GMII / USB conversion unit 8. Thereby, it is possible to notify the GMII / USB conversion unit 8 that the PON link between the OLY / PON has been established. After the PON link between the OLY / PON is established, the GMII / USB conversion unit 8 can be brought into a communicable state, and the personal computer 20 is in a state where the communication state is in a series of systems from the OLT 1 a to the USB interface 9. Communication with can be started.

  By the way, in the USB ONU 5, the output of the GPIO signal 30 output from the LSI device 10 is not based on the PON link establishment signal but by the authentication function unit 1b of the PON interface card 1 to the ONUs 5-1. You may make it control based on the signal by the authentication establishment which shows having identified the other party. That is, even when a PON link establishment signal is output from the OLT 1a, the LSI device 10 to which the signal is input may be configured not to change the GPIO signal 30 to “0”.

  In this configuration, the USB / ONU 5 USB interface 9 optically connected to the OLT 1a is inserted into the USB interface slot 21 of the personal computer 20 to start the operation (step S0 in FIG. 5). Thereafter, it is determined whether or not a PON link is established (step S1 in FIG. 5). When the determination result in step S1 is YES and a PON link establishment signal is output from the OLT 1a, the authentication function unit 1b to which the PON link establishment signal has been input causes the USB ONU 5 to be connected after the OLT 1a has successfully established the PO link. An authentication procedure for identification, that is, determination of whether or not PON authentication has been established is started (step S5 in FIG. 5). Then, if authentication is established between the authentication function unit 1b and the USB ONU 5 via the OLT 1a and the determination result in step S5 in FIG. 5 is YES, the authentication is completed (authentication established state) (step in FIG. 5). S6).

  The LSI device 10 in the ONU function unit 7 in the authentication established state changes the GPIO signal 30 from “1” to “0”. The GPIO signal 30 is transmitted to the GMII / USB conversion unit 8 via the MDIO control unit 301.

  As a result, the LSI device 10 that has established the PON link notifies the GMII / USB conversion unit 8 that the GMII-side interface has been established via the MDIO control unit 301, so that the GMII / USB conversion unit 8 becomes communicable. Then, the USB interface 9 and the LSI device 10 are brought into a communication state (step S7 in FIG. 5).

  In step S7 in FIG. 5, the LSI device 10 notifies the GMII / USB conversion unit 8 that the link on the GMII interface side has been established via the MDIO control unit 301 via MDIO. That is, the LSI device 10 first notifies the MDIO control unit 301 that the PON authentication has been established via the MDIO bus as a state where the network-side interface has been established. Alternatively, the LSI device 10 may transmit the PON link establishment state (MDIO management control signal 10b of “0”) directly to the GMII / USB conversion unit 8 via the MDIO bus (see FIG. 6).

  When the USB interface 9 and the LSI device 10 are in communication with each other (step S7 in FIG. 5), data transmission of the physical layer, L2, L3, etc. is normally performed between the OLT 1a and the personal computer 20 via the USB / ONU 5. It is in a state to be transmitted.

  According to the USB ONU 5 described above, since the GMII output of the LSI device 10 is used to send and receive optical fiber signals, there is no need to use a PHY, transformer, and 1000BASE-T or 1000BASE-T connector. The circuit scale can be reduced, and the installation space can be reduced.

  Moreover, by inserting the USB interface 9 of the USB / ONU 5 into the USB interface slot 21 on the personal computer 20 side, it becomes possible to connect the ONU function unit 7 and the USB interface of the personal computer 20. There is no need to route and connect cables between the cables.

  In addition, since the power necessary for the operation of the USB / ONU 5 is supplied from the USB interface slot 21 of the personal computer 20 via the USB interface 9, a power supply unit and power supply wiring are not required outside the USB / ONU 5, and the power outlet The work of connecting the power cable and the space required for it can be omitted, and the reliability of the entire configuration can be improved.

1 is a block diagram showing a schematic configuration of an optical transmission system according to an embodiment of the present invention. USB used for the optical transmission system. The block diagram which shows the structure of ONU. USB. The block diagram which shows schematic structure of the LSI device in ONU. 6 is a flowchart showing establishment of a communication state in an ONU by transmission of a PON link establishment signal from the center side in the optical transmission system according to the embodiment. 5 is a flowchart showing establishment of a communication state in an ONU by transmitting an authentication establishment signal from the center side in the optical transmission system. USB used in the optical transmission system according to a modification of the optical transmission system according to the embodiment. The block diagram which shows the structure of ONU. The block diagram which shows schematic structure of the conventional optical transmission system. The block diagram which shows schematic structure of the system of the subscriber's house of the optical transmission system.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1a ... Center side optical line termination | terminus device (OLT), 2 ... Optical fiber (2nd optical transmission path), 3 ... Optical coupler (optical branching coupling part), 4-1 to 4-n ... Optical transmission path (1st) 1 optical transmission line), 5-1 to 5-n ... optical line terminator (ONU) on the subscriber premises side, 5 ... USB ONU, 6 ... optical transceiver (electrical / optical conversion means), 7 ... ONU function (Optical line terminator function unit), 7a, 7b ... media-independent interface signal end of the optical line terminator function unit, 8 ... GMII / USB conversion unit as conversion means, 9 ... USB interface, 10m ... management control signal Terminal (GPIO signal terminal), 20 ... Personal computer (node), 21 ... USB interface slot, 30 ... Management control signal (GPIO signal), 301 ... Management control signal control unit (MDIO control unit), 10b ... MDIO tube Physical control terminal (MDIO signal terminal), 30b... MDIO management control signal (MDIO signal).

Claims (10)

An electrical / optical conversion means connected to an optical transmission line connected to the optical line terminator on the center side through an optical branching and coupling unit to perform photoelectric conversion and reverse photoelectric conversion;
An optical line terminator function unit connected to an electric signal input / output terminal of the electric / optical converter;
Conversion means connected to the media independent interface signal end of the optical line termination device function unit to perform media independent interface / USB interface conversion and its inverse conversion;
A subscriber-side optical line terminator having a USB interface.   2. The subscriber premises optical line termination device according to claim 1, wherein the media independent interface is configured by GMII or MII.   2. The subscriber premises optical line termination according to claim 1, wherein said conversion means has a GMII or MII and MDIO interface, and said optical line terminator function unit has GMII, MII and a management control signal terminal. apparatus.   2. The subscriber premises optical line terminator according to claim 1, wherein the conversion means has a GMII or MII and MDIO interface, and the optical line terminator function unit has a GMII, MII and MDIO interface.   The optical line terminator function unit establishes authentication when the PON link is established between the center side and the optical line terminator at the subscriber's home, or between the center side and the optical line terminator. 5. A management control signal terminal for outputting a management control signal, which is output in the event of a failure and which establishes a communication state between the conversion means and the USB interface, to the conversion means. The subscriber premises optical line terminator according to one.   When the PON link is established between the center side and the optical line terminator, or the authentication is established between the center side and the optical line terminator. A management control signal terminal for transmitting a management control signal for establishing a communication state between the conversion means and the USB interface to the conversion means; and the management control input or output from the management control signal terminal. 6. The subscriber according to claim 1, further comprising a management control signal control unit for communicating a signal between the optical line terminator function unit and the conversion unit. Home-side optical line terminator.   7. The subscriber premises optical line terminator according to claim 5 or 6, wherein an MDIO interface signal is used for the management control signal control unit of the optical line terminator function unit.   7. The customer premises light according to claim 5 or 6, wherein the management control signal terminal of the optical line terminator function unit uses an MDIO interface, and the management control signal control unit uses an MDIO interface signal. Line termination equipment. A subscriber premises optical line terminating device according to any one of claims 1 to 8,
An optical branching and coupling unit having a subscriber-side port connected to the subscriber-side optical line terminator via a first optical transmission line;
A second optical transmission line connected to the center side port of the optical branching and coupling unit;
An optical transmission system comprising: the center-side optical line terminator connected to the second optical transmission line.   10. The optical transmission system according to claim 9, wherein the USB interface of the subscriber premises optical line terminator is directly connected to a USB interface slot of a node arranged outside thereof.

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