JP2010199969A - Optical access system, optical communication path switching device, and optical line apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a starting procedure of a system using a technology by which an optical line device (hereafter, OLT) notifies a switching time of an input and output port of an optical switch to an optical communication path switching apparatus (hereafter OSW) for the intended optical network apparatus (hereafter ONU) with the use of a control frame. <P>SOLUTION: The optical access system includes: an OLT connected to the network; a plurality of ONUs connected to user terminals by each; and an OSW installed between the OLT and the ONU and switching an optical communication path between the OLT and the plurality of ONUs. The OLT transmits a first control signal for discovering the OSW to the OSW, after that, the OSW transmits a second control signal for requesting the registration of the OSW to the OLT, after that, the OLT transmits a third control signal including information for registering the OSW to the OSW, and the OSW transmits a fourth control signal for expressing the receipt of the third control signal at the time specified by the OLT to the OLT. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an optical access system, and more particularly to a technique for controlling switching of an optical communication path in an optical access system that switches an optical communication path using an optical switch.

  As a technology that enables high-speed Internet access, optical access by PON (Passive Optical Network) is widely used. PON includes EPON (Ethernet Passive Optical Network) (Ethernet is a registered trademark) (for example, see Non-Patent Document 1).

  A system using a PON includes an optical line device (OLT) that terminates an optical fiber on the station side of a telecommunications carrier, an optical network device (ONU: Optical Network Unit) that terminates an optical fiber on the terminal side, It is comprised with the splitter which branches the optical fiber pulled from OLT into several ONU.

  Since the splitter in the conventional PON is a passive element, a network can be constructed at low cost. However, since the signal transmitted from the OLT is branched to all ONUs in the splitter, the signal reaches the ONU that is not the original communication partner. For this reason, when a system using PON is used, sufficient communication confidentiality is not always obtained. In addition, when the signal branches in the splitter, the signal strength decreases, so that the system using the PON has a shorter communication distance as the number of splitters increases.

  As a method for solving these problems of PON, networks using optical switches as active elements instead of splitters in PON have been proposed (see, for example, Patent Documents 1 and 2, Non-Patent Documents 2 and 3). .

JP 2006-246262 A JP 2007-067948 A

IEEE Std 802.3TM-2005 IEICE TRANS. COMMUN. , VOL. E89-B, NO. 3 pp. 724-730 IEICE TRANS. COMMUN. , VOL. E89-B, NO. 11 pp. 3021-3031 2008 IEICE Communication Society Conference, B-8-14

  In the techniques described in Patent Documents 1 and 2 and Non-Patent Documents 2 and 3, the optical signal transmitted by the OLT in the device that switches the input / output port to the desired ONU that is the transmission destination of the optical signal is Branches into an optical switch and a circuit for reading the frame of the optical signal. When the optical signal transmitted from the OLT is an EPON frame, a circuit that reads the optical signal frame may be changed depending on the logical identifier (Logical Link Identifier, LLID) set in the preamble portion of the EPON frame used for the optical signal. The output port of the optical switch is switched according to the LLID.

  This prior art delays the arrival of the optical signal to the optical switch by the time required for determining the desired ONU in the circuit that reads the frame of the optical signal based on the LLID. Is provided with a delay circuit (see, for example, Non-Patent Document 3). When the delay circuit is constituted by an optical fiber, the length of the optical fiber is 42.4 m.

  Further, when the ONU transmits a REPORT message using MPCP (Multipoint Control Protocol) to the OLT, the REPORT message is extracted in a device that switches an input / output port to the ONU (see, for example, Patent Document 2). For this reason, a device that switches an input / output port to an ONU needs a function (O / E converter) that converts an optical signal into an electrical signal in uplink communication, that is, communication in the direction from the ONU to the OLT. .

  As described above, in the prior art, an apparatus for switching an input / output port to an ONU needs to be provided with a delay circuit using an optical fiber and an O / E converter for upstream communication, and an apparatus for switching an input / output port to an ONU. Hinders downsizing.

  The first object of the present invention is to reduce the size of an apparatus for switching an input / output port to an ONU.

  Further, in the conventional technology, the OLT notifies a device that switches the input / output port to the ONU using a control frame to notify the time when the optical switch switches the input / output port (for example, see Non-Patent Document 4). . In Non-Patent Document 4, the switching time of the optical switch is calculated by using the time for the device that switches the input / output port to the ONU to process the control frame and the time for the processing to switch the input / output port by the optical switch. In order to realize the technique of Non-Patent Document 4, the OLT needs to acquire these processing times when the system is started.

  A second object of the present invention is to provide an optical access system that uses a technique in which an OLT uses a control frame to notify a device that switches an input / output port to an ONU, using a control frame. It is to provide a system startup procedure.

  A typical example of the present invention is as follows. That is, an optical line device connected to another network, a plurality of optical network devices each connected to a user terminal, and the optical line device installed between the optical line device and the optical network device, In an optical access system including an optical communication path switching device that switches an optical communication path between the plurality of optical network devices, the optical line device transmits a first control signal for discovering the optical communication path switching device. , To the optical communication path switching device, the communication path switching device, after receiving the first control signal, a second control signal for requesting registration of the optical communication path switching device, After transmitting to the optical line device, the optical line device receives the second control signal, and then transmits a third control signal including information for registering the optical communication path switching device to the optical communication path switching Equipment And Shin, the optical communication path switching device, at the time specified by the optical line terminal, a fourth control signal indicating reception of said third control signal is transmitted to the optical line terminal.

  According to the present invention, an O / E converter for uplink communication is not required in the optical communication path switching device. Therefore, the optical communication path switching device can be reduced in size.

It is a block diagram which shows the structural example of the network of the 1st Embodiment of this invention. It is a block diagram which shows the structural example of OSW of the 1st Embodiment of this invention. It is a block diagram which shows the structure of the downstream optical switch element of the 1st Embodiment of this invention. It is a block diagram which shows the structure of the upstream optical switch element of the 1st Embodiment of this invention. It is a block diagram which shows the structure of the optical switch for downward branching of the 1st Embodiment of this invention. It is a block diagram which shows the structure of the optical switch for uplink branching of the 1st Embodiment of this invention. It is a block diagram which shows the structure of OLT of the 1st Embodiment of this invention. It is explanatory drawing which shows the format of the frame of EPON of the 1st Embodiment of this invention. It is explanatory drawing which shows the format of MPCPDU of the 1st Embodiment of this invention. It is explanatory drawing which shows the format of the optical switch switching control frame of the 1st Embodiment of this invention. It is explanatory drawing which shows the format of the Register Request message of the 1st Embodiment of this invention. It is explanatory drawing which shows the table in which the correspondence of the switch port number and LLID of the optical switch element of the 1st Embodiment of this invention was set. It is a sequence diagram which shows the procedure of the initial registration of OSW of the 1st Embodiment of this invention. It is a flowchart which shows the procedure of the initial registration of OSW in OLT of the 1st Embodiment of this invention. It is a flowchart which shows the procedure of the initial registration of OSW in OSW of the 1st Embodiment of this invention. It is a sequence diagram which shows the procedure of the initial registration of ONU of the 1st Embodiment of this invention. It is a flowchart which shows the procedure of the initial registration of ONU of the 1st Embodiment of this invention. It is a sequence diagram which shows the process between OLT and OSW of the initial registration of OSW of the 2nd Embodiment of this invention. It is a flowchart which shows the procedure of the initial registration of OSW in OSW of the 2nd Embodiment of this invention. It is a flowchart which shows the procedure of the initial registration of OSW in OLT of the 2nd Embodiment of this invention.

  A first embodiment of the present invention will be described below with reference to the drawings.

  FIG. 1 is a block diagram illustrating a configuration example of a network according to the first embodiment of this invention.

  The optical access system 50 includes an optical line device (OLT) 1, an optical communication path switching device (OSW) 2, and an optical network device (ONU) 3. A plurality of ONUs 3 are provided according to the number of terminals used by the user. The ONU is expressed as ONU3 when the whole is shown without being distinguished, and is expressed as ONU3-1 through ONU3-n when distinguished from each other.

  A plurality of user terminals 4 (4-1 to 4-n) are connected to the ONU 3. The user terminal 4 communicates with the core network 55 via the optical access system 50 and the gateway (GW) 53.

  FIG. 2 is a block diagram illustrating a configuration example of the OSW 2 according to the first embodiment of this invention.

  OSW2 includes multiplexing / demultiplexing units (WDM) 210-1 to 210-n, downstream optical switch element 211, upstream optical switch element 212, downstream switch driver 213, upstream switch driver 214, switch control circuit 215, optical-electrical Signal conversion unit (O / E converter) 216, electro-optical signal conversion unit (E / O converter) 217, downstream branching optical switch 218, upstream branching optical switch 219, and multiplexing / demultiplexing unit (WDM) 220).

  The multiplexing / demultiplexing units (WDM) 210-1 to 210-n separate and multiplex the upstream optical signal and the downstream optical signal that are wavelength-multiplexed between the OSW 2 and the ONUs 3-1 to 3-n, respectively. To do.

  The downstream optical switch element 211 is a switch for switching an optical communication path of a signal transmitted from the OLT 1 to the ONUs 3-1 to 3-n.

  FIG. 3A is a block diagram illustrating a configuration of the downstream optical switch element 211 according to the first embodiment of this invention. The downstream optical switch element 211 is an optical switch element for signals transmitted from the OLT 1 to the ONU 3, and includes an input port 2111 connected to the downstream branching optical switch 218, and multiplexing / demultiplexing units (WDM) 210-1 to 210. Output ports 2112-1 to 2112-n connected to −n. Note that the output port 2112-1 to 2112-n as a whole is represented as an output port 2112.

  The downstream optical switch element 211 switches the downstream signal communication path by the drive signal from the downstream switch driver 213 so that the input port 2111 is electrically connected to the arbitrary output ports 2112-1 to 2112-n.

  The upstream optical switch element 212 is a switch for switching an optical communication path of a signal transmitted from the ONUs 3-1 to 3-n to the OLT 1.

  FIG. 3B is a block diagram illustrating a configuration of the upstream optical switch element 212 according to the first embodiment of this invention.

  The upstream optical switch element 212 is an optical switch element for a signal transmitted from the ONU 3 to the OLT 1, an output port 2121 connected to the upstream branching optical switch 219, and multiplexing / demultiplexing units (WDM) 210-1 to 210. Input ports 2122-1 to 2122-n connected to -n. When the entire input ports 2122-1 to 2122-n are shown, they are expressed as an input port 2122.

  The upstream optical switch element 212 switches the upstream signal communication path according to the drive signal from the upstream switch driver 214 so that the arbitrary input ports 2122-1 to 2122-n and the output port 2121 are electrically connected.

  In addition, about the downstream optical switch element 211 and the upstream optical switch element 212, when showing both, it describes with an optical switch element.

  When the transmission destination of the optical signal transmitted from the OLT 1 is the ONU 3-1 to 3 -n, the downstream branching optical switch 218 is switched from the optical signal path toward the downstream optical switch element 211 and transmitted from the OLT 1. When the optical signal transmission destination is OSW2, the optical signal path is switched toward the switch control circuit 215.

  When the transmission source of the optical signal transmitted to the OLT 1 is the ONUs 3-1 to 3-n, the upstream branching optical switch 219 switches the path of the optical signal toward the upstream optical switch element 212, and is transmitted to the OLT 1. When the transmission source of the optical signal to be transmitted is the switch control circuit 215, the optical signal path is switched toward the switch control circuit 215.

  The downstream switch driver 213 is a circuit that drives the downstream optical switch element 211 and the downstream branching optical switch 218. The upstream switch driver 214 is a circuit that drives the upstream optical switch element 212 and the upstream branching optical switch 219.

  The optical-electrical signal converter (O / E converter) 216 converts an optical signal into an electric signal. The electrical-optical signal converter (E / O converter) 217 converts the electrical signal into an optical signal.

  The multiplexing / demultiplexing unit (WDM) 223 separates and multiplexes the upstream optical signal and the downstream optical signal that are wavelength-multiplexed between the OSW 2 and the OLT 1.

  The switch control circuit 215 controls switching of the downstream optical switch element 211, the upstream optical switch element 212, the downstream branching optical switch 218, and the upstream branching optical switch 219, based on a switch switching control frame (described later) received from the OLT 1. .

  The time at which the downstream optical switch element 211, upstream optical switch element 212, downstream branching optical switch 218, and upstream branching optical switch 219 are switched is calculated by the OLT 1 and uses the optical switch switching control frame in the format shown in FIG. , Notify OSW2.

  FIG. 4A is a block diagram illustrating a configuration of the downlink branching optical switch 218 according to the first embodiment of this invention.

  The downlink branching optical switch 218 includes an input port 2181 and output ports 2182-1 and 2182-2. The downstream branching optical switch 218 is a 1-input 2-output switch. The input port 2181 is connected to the multiplexing / demultiplexing unit (WDM) 220. The output port 2182-1 is connected to the downstream optical switch element 211. The output port 2182-2 is connected to the electro-optical signal converter 216.

  FIG. 4B is a block diagram illustrating the configuration of the upstream branching optical switch 219 according to the first embodiment of this invention.

  The upstream branching optical switch 219 includes an output port 2191, input ports 2192-1 and 2192-2. The upstream branching optical switch 219 is a two-input one-output switch. The output port 2191 is connected to the multiplexing / demultiplexing unit (WDM) 220. The input port 2192-1 is connected to the optical-electrical signal conversion unit 217. The input port 2182-2 is connected to the upstream optical switch element 212.

  FIG. 5 is a block diagram illustrating a configuration of the OLT 1 according to the first embodiment of this invention.

  The OLT 1 includes a multiplexing / demultiplexing unit (WDM) 101, an electrical-optical signal conversion unit (E / O converter) 102, an optical-electrical signal conversion unit (O / E converter) 103, a downstream frame processing unit 104, An upstream frame processing unit 105, a protocol control unit 106, and a gateway interface (GW IF) 110 are provided.

  A multiplexing / demultiplexing unit (WDM) 101 separates and multiplexes the upstream optical signal and the downstream optical signal that are wavelength-multiplexed between the OLT 1 and the OSW 2.

  The electrical-optical signal converter (E / O converter) 102 converts an electrical signal into an optical signal. The optical-electrical signal converter (O / E converter) 103 converts an optical signal into an electric signal.

  The downlink frame processing unit 104 generates a frame transmitted to the OSW 2. The upstream frame processing unit 105 processes the frame received from the OSW 2. The protocol control unit 106 processes control protocols exchanged between the OLT 1 and the OSW 2 and between the OLT 1 and the ONUs 3-1 to 3-n.

  The gateway interface 110 is an interface that transmits and receives signals to and from the gateway (GW) 53.

  FIG. 6 is an explanatory diagram showing the format of the EPON frame 60 according to the first embodiment of this invention.

  An EPON frame 60 includes a preamble 610, a destination MAC address (DA) 620, a source MAC address (SA) 630, a Type / Length field 640 indicating a frame type or a frame length, a payload 650, and a frame check sequence (FCS) 660. Each field.

  The preamble 610 includes reserved fields 611 and 613, an SLD (Start of LLID Delimiter) 612, a logical identifier (LLID) 614, and a CRC (Cyclic Redundancy Check) 615 for performing a code error check.

  The SLD 612 is a field indicating that a logical identifier (Logical Link Identifier, LLID) is described in the preamble area. The LLID 614 is a logical identifier that the OLT 1 assigns to the ONU 3 or the OSW 2.

  In the optical access system according to the present embodiment, MPCPDU (Multipoint Control Protocol Data Unit) defined in Non-Patent Document 1 is used as a format of a control frame transmitted / received between OLT 1 and OSW 2 or between OLT 1 and ONU 3. An equivalent format can be used.

  FIG. 7 is an explanatory diagram illustrating the format of the MPCPDU 65 according to the first embodiment of this invention.

  The MPCPDU 65 includes DA620, SA630, Type / Length field 640, payload 650, and FCS 660 of the EPON frame 60 shown in FIG. In particular, the payload 650 includes an instruction code 651, a time stamp 652, and data 653.

  FIG. 8 is an explanatory diagram illustrating the format of the optical switch switching control frame according to the first embodiment of this invention.

  FIG. 8 shows only the payload 650 portion of the EPON frame 60 shown in FIG. The format of the optical switch switching control frame shown in FIG. 8 is the downstream optical switch element 211, the upstream optical switch element 212, the downstream branching optical switch 218, or the upstream branching optical switch 219 provided by the OLT 1 in the OSW2. Is a format of a message to be transmitted to the OSW 2 in order to perform switching control. When OLT 1 initially registers OSW 2 or ONU 3, OLT 1 is provided in OSW 2 using an optical switch switching control frame so that a message transmitted from OLT 1 to OSW 2 or ONU 3 reaches an appropriate destination. The downstream optical switch element 111 or the downstream branching optical switch 218 is switched. . Further, when the OLT 1 initially registers the OSW 2 or the ONU 3, the OLT 1 uses the optical switch switching control frame so that the message transmitted to the OSW 2 or the ONU 3 reaches the OLT 1. The switch element 212 or the upstream branching optical switch 219 is switched.

  In the optical switch switching control frame, a value indicating switching of the optical switch element is set in the instruction code 651. Further, following the time stamp 652, the data 653 is set to a control target 6531 indicating which of the upstream optical switch element 212 and the downstream optical switch element 211 is to be controlled, and an optical switch switching control frame. The switch setting number 6532 of the optical switch switching schedule and the association 6533 (6533-1 to 6533-n) of the switch time t of the optical switch element and the port number Port # of the optical switch element are set.

  FIG. 9 is an explanatory diagram illustrating a format of the Register Request message 75 according to the first embodiment of this invention.

  The format of the Register Request message 75 shown in FIG. 9 is one of messages that the OSW 2 transmits to the OLT 1 when the OLT 1 initially registers the OSW 2.

  In the Register Request message 75, a value indicating that this message is the Register Request message 75 is set in the instruction code 751. Further, in the Register Request message 75, a time stamp 752, a flag 753, discovery information 754, a pending grant 755, a laser on time 756, and a laser off time 757 are set.

  In the Register Request message 75, following the laser off time 757, the time required for the OSW 2 to process the optical switch switching control frame received from the OLT 1 (Tc) 758, the connection destination of the output port of the optical switch element in the OSW 2 A time (Ts) 759 for switching between and the number of switch ports 760 of the optical switch element of OSW2 are set. Following the number of switch ports 760, a padding field 761 is provided, and finally a frame check sequence (FCS) 762 is set.

  FIG. 10 is an explanatory diagram illustrating a table 1061 in which a correspondence relationship between the switch port number 10611 and the LLID 10612 of the optical switch element according to the first embodiment of this invention is set.

  FIG. 10 illustrates the output ports 2112-1 to 2112-n of the downstream optical switch element 211 or the input ports 2122-1 to 2122-n of the upstream optical switch element 212 included in the OLT 1 according to the first embodiment of this invention. And the LLID assigned by the OLT 1 to the ONUs 3-1 to 3-n, and the round trip time (RTT) that is the time required for the signal to reciprocate between the OLT 1 and the ONU 3, or between the OLT 1 and the OSW 2 This is a table 1061 showing the correspondence with the round trip time RTT.

  The table 1061 includes a switch port number 10611, an LLID 10612, and a round trip time RTT 10613. The switch port number 10611 is a number for identifying the output port 2112 of the downstream optical switch element 211 or the input port 2122 of the upstream optical switch element 212. The LLID 10612 is an LLID number assigned by the OLT 1 to the ONU 3 connected to the switch port indicated by the switch port number 10611. The round trip time RTT 10613 is a time required for a signal to reciprocate between the OLT 1 and the ONU 3. The RTT 10613 may be a time required for a signal to reciprocate between the OLT 1 and the OSW 2.

  The table 1061 includes the switch port number 10611, the LLID 10612, and the round trip time RTT 10613 in the entry 10614 (10614-1 to 10614-n, where n is the number of output ports of the downstream optical switch element 211 of the OSW2, or upstream optical The number is the same as the number of input ports of the switch element 212 or the total number of all switch ports of the optical switch element).

  Further, the table 1061 may be provided with a port entry 10614-0 indicating the switch control circuit 215 of the OSW2. Here, the port indicating the switch control circuit 215 of the OSW 2 is the output port 2182-2 of the downward branching optical switch 218 shown in FIG. 4A or the input port 2192- of the upstream branching optical switch 219 shown in FIG. 4B. 1.

  The switch port 10611, the LLID 10612, and the RTT 10613 are associated with each other by the entry 10614 of the table 1061.

  The OLT 1 includes a table 1061 in the protocol control unit 106.

  The procedure for initial registration of the OSW 2 according to the first embodiment of the present invention will be described with reference to FIG.

  FIG. 11 is a sequence diagram illustrating a procedure of initial registration of the OSW 2 according to the first embodiment of this invention.

  The OLT 1 initially registers the OSW 2 in the OLT 1 after the optical access system 50 is activated or the OSW 2 is activated. First, the OLT 1 transmits the optical switch switching control frames FR-C1d and FR-C1u to the OSW2. Here, FR-C1d is a frame for switching control of the downstream optical switch element 211 and the downstream optical switch 218. FR-C1u is a frame for switching control of the upstream optical switch element 212 and the upstream branching optical switch 219.

  The optical switch switching control frames FR-C1d and FR-C1u are the EPON frame 60 shown in FIG. 6 and include the payload 650 shown in FIG.

  When the OSW 2 receives the optical switch switching control frames FR-C1d and FR-C1u, the OSW 2 sets the output port 2182-1 of the downward branching optical switch 218 and the input port 2192-2 of the upstream branching optical switch 219, respectively. By switching to the output port 2182-2 and the input port 2192-1, the communication path is switched to the switch control circuit 215 of the OSW2. As a result, the OSW 2 can process the optical switch switching control frame transmitted from the OLT 1 in the switch control circuit 215, and can transmit the optical switch switching control frame to the OLT 1.

  Next, the OLT 1 transmits a Discovery Gate message FR-DG1, which is an optical switch switching control frame for discovering the OSW2, to the OSW2. The Discovery Gate message FR-DG1 is the EPON frame 60 shown in FIG. 6, and is equivalent to the EPON Discovery Gate message shown in Non-Patent Document 1.

  When the OSW2 receives the Discovery Gate message FR-DG1, it sends a Register Request message FR-RR1 to the OLT1 as a response to the Discovery Gate message FR-DG1. The OSW 2 notifies the OLT 1 of a request for registering the OSW 2 by transmitting a Register Request message FR-RR 1. The Register Request message FR-RR1 is the EPON frame 60 shown in FIG. 6, and includes a Register Request message 75 shown in FIG.

  The OSW2 sends a Register Request message FR-RR1 to the OLT1 so that at least the time (Tc) 758 required for the OSW2 to process the optical switch switching control frame received from the OLT1 and the optical switch element in the OSW2 have A time (Ts) 759 for switching the connection destination of the output port 2112, the number of switch ports of the optical switch element of the OSW 2, and a time t 1 for transmitting a Register Request message FR-RR 1 described later are notified.

  The time (Tc) 758 required for the OSW 2 to process the optical switch switching control frame received from the OLT 1 and the time (Ts) 759 for switching the connection destination of the output port of the optical switch element in the OSW 2 are: OSW2 is a value stored in advance.

  The initial registration procedure of the ONU 3 using EPON described in Non-Patent Document 1 is that the ONU 3 that has received the Discovery Gate message waits for a random time from the transmission time of the frame specified by the Discovery Gate message, and then receives a Register Request. This is a procedure for sending a message. On the other hand, the initial registration procedure of OSW2 in the first embodiment of the present invention does not wait for a random time, and the OSW2 transmits a Register Request message FR-RR1 to the OLT1 when the frame transmission time specified by the Discovery Gate message comes. It is a procedure to do.

  When the OLT 1 receives the Register Request message FR-RR 1 from the OSW 2, the OLT 1 transmits the Register message FR-R 1 to the OSW 2 in order to register the OSW 2.

  The Register message FR-R1 includes an LLID indicating the OSW2 assigned by the OLT1.

  Further, the OLT 1 transmits a Gate message FR-G1 to the OSW 2 in order to designate a time at which the OSW 2 is permitted to transmit the Register Ack message FR-RA1 to the OLT 1.

  The OSW 2 transmits a Register Ack message FR-RA 1 to the OLT 1 at a time designated by the Gate message FR-G 1.

  OLT 1 performs initial registration of OSW 2 by the above-described procedure.

  Further, according to the above-described procedure, the OLT 1 measures the round trip time RTTs between the OLT 1 and the OSW 2.

  The OLT 1 sets a time t 0 at which the OLT 1 transmits the Discovery Gate message FR-DG 1 to the OSW 2 in the Discovery Gate message FR-DG 1 transmitted to the OSW 2. The OLT 1 sets the transmission time t0 in the Timestamp 652 shown in FIG. 8 in the Discovery Gate message FR-DG1. When OSW2 receives Discovery Gate message FR-DG1 from OLT1, OSW2 sets the time at which Discovery Gate message FR-DG1 is received as the local time t0 of OSW2 itself. The OSW2 synchronizes the time between the OLT1 and the OSW2 by setting the transmission time t0 of the Discovery Gate message FR-DG1 by the OLT1 to the time when the Discovery Gate message FR-DG1 is received.

  Here, the time from when the OLT 1 transmits the Discovery Gate message FR-DG1 to when the OSW 2 receives the Discovery Gate message FR-DG 1, that is, the propagation delay time of the signal transmitted from the OLT 1 to the OSW 2 is defined as time Td. .

  The OSW2 sets a time t1 at which the Register Request message FR-RR1 is transmitted to the OLT1 in the Register Request message FR-RR1 to be transmitted to the OLT1. OSW2 sets time t1 to Timestamp752 shown in FIG. 9 among Register Request message FR-RR1. Here, the time from when the OSW 2 receives the Discovery Gate message FR-DG1 from the OLT 1 to when the OSW 2 transmits the Register Request message FR-RR1 to the OLT 1 is defined as a time Tw.

  The OLT 1 receives the Register Request message FR-RR1 from the OSW 2 at time t2. Here, the time from when the OSW2 transmits the Register Request message FR-RR1 to when the OLT1 receives the Register Request message FR-RR1, that is, the propagation delay time of the signal transmitted from the OSW2 to the OLT1 is defined as the time Tu. .

  As described above, the round trip time RTTs can be expressed by RTTs = Td + Tu = (t2−t0) −Tw = (t2−t0) − (t1−t0) = t2−t1.

  The round trip time RTTs is a time required for a signal to reciprocate between the OLT 1 and the OSW 2.

  The OLT 1 calculates the round trip time RTTs from the time t1 included in the Register Request message FR-RR1, and sets the round trip time RTTs in the RTT 10613 (see FIG. 10) of the table 1061. The round trip time RTTs is set in the entry 10614-0 of the table 1061. Further, the value of the LLID assigned to OSW2 is set in the LLID 10612 of the entry 10614-0.

  FIG. 12 is a flowchart illustrating a procedure of initial registration of the OSW 2 in the OLT 1 according to the first embodiment of this invention.

  First, the OLT 1 sets the value of the OSW2 registration flag to 0 to indicate that the OSW2 is not registered (step 1000). The OSW2 registration flag is stored in the protocol control unit 106 of the OLT1.

  Next, the switch control circuit of OSW2 is used for the period during which the initial registration processing of OSW2 is performed on the output port 2182-1 of the optical switch for downstream branching of OSW2 and the input port 2192-2 of the optical switch for upstream branching 219. In order to switch to 215, the optical switch switching control frames FR-C1d and FR-C1u are transmitted to OSW2 (step 1010). Subsequently, the OLT 1 transmits a Discovery Gate message FR-DG1 to the OSW 2 (Step 1020).

  The OLT 1 determines whether or not the Register Request message FR-RR1, which is a response to the Discovery Gate message FR-DG1 transmitted in Step 1020, has been received within a predetermined time (Step 1030).

  When the Register Request message FR-RR1 is not received within a predetermined time, the OLT 1 has not started the OSW 2 normally, or the optical switch switching control frame FR-C1d or the FR-C 1u has normally switched the switch control circuit of the OSW 2 Since the process has not reached 215, the process returns to step 1020, and the optical switch switching control frames FR-C1d and FR-C1u are transmitted to the OSW 2 again.

  When the Register Request message FR-RR1 is received within a predetermined time, the initial registration of the OSW2 in the OLT 1 proceeds to Step 1040.

  When the OLT 1 receives the Register Request message FR-RR1 from the OSW 2, the table 1061 indicating the correspondence relationship between the switch port 10611 of the OSW 2 and the LLID 10612 assigned to the ONU 3 based on the information included in the Register Request message FR-RR1 (FIG. 10) is created (step 1040). Here, the number n of entries in the table to be generated is the same as the number of switch ports of the optical switch element of OSW2 included in the Register Request message FR-RR1 received in Step 1030.

  Next, OLT1 transmits Register message FR-R1 to OSW2 (step 1050). Subsequently, the OLT 1 transmits the Gate message FR-G1 to the OSW 2 in order to notify the OST 2 of the time when the transmission of the Register Ack message FR-RA1 is permitted to the OLT 1 (Step 1060).

  The OLT 1 receives the Register Ack message FR-RA1 that is a response to the Register message FR-R1 transmitted in Step 1050 (Step 1070). The OLT 1 changes the value of the OSW 2 registration flag to 1 to indicate that the initial registration of the OSW 2 has been completed and the OSW 2 has been registered (step 1080).

  FIG. 13 is a flowchart illustrating a procedure of initial registration of the OSW 2 in the OSW 2 according to the first embodiment of this invention.

  When the OSW2 receives the optical switch switching control frames FR-C1d and FR-C2u from the OLT 1 (step 1200), the output port 2182-1 of the downstream branching optical switch 218 of the OSW2 and the upstream branching optical switch 219 By switching the input port 2192-2 to the output port 2182-2 and the input port 2192-1 respectively, the communication path is switched to the switch control circuit 215 of the OSW2. (Step 1210).

  Subsequently, the OSW 2 receives the Discovery Gate message FR-DG1 from the OLT 1 (Step 1220). The OSW2 transmits a Register Request message FR-RR1 shown in FIG. 9 to the OLT1 as a response to the Discovery Gate message FR-DG1 sent from the OLT1 (Step 1230).

  The OSW2 receives the Register message FR-R1 from the OLT1 (Step 1240), and then receives the Gate message FR-G1 (Step 1250). The OSW 2 transmits a Register Ack message FR-RA 1 to the OLT 1 at the frame transmission time indicated in the Gate message FR-G 1 received in Step 1250 (Step 1260).

  FIG. 14 is a sequence diagram illustrating a procedure for initial registration of the ONU 3 according to the first embodiment of this invention.

  When the initial registration of the OSW 2 is completed by the procedure shown in FIG. 11, the OLT 1 performs the initial registration of the ONU 3.

  The initial registration shown in FIG. 14 shows a procedure for initial registration of ONU # j (3-j) (j is an arbitrary value among 1 to n). According to the initial registration procedure shown in FIG. 14, ONU # j (3-j) is assigned to the output port 2112-j of the downstream optical switch element 211 and the input port 2122-j of the upstream optical switch element 212 in OSW2.

  The OLT 1 selects the switch port 10611 of the OSW 2 assigned to the ONU #j (3-j) to be initially registered with reference to the table 1061 (see FIG. 10) indicating the correspondence between the number of the switch port 10611 and the LLID 10612. To do. The selected switch port 10611 is an entry 1064 whose LLID 10612 and RTT 10613 are NULL. In FIG. 14, the selected switch port 10611 is an output port 2112-j and an input port 2122-j.

  The OLT 1 uses the values of the selected input port 2122-j and output port 2112-j as the port numbers Port of the optical switch elements in the association 6533 of the optical switch switching control frames FR-C2d and FR-C2u shown in FIG. Set to #.

  The switching time t of the optical switch element to be set is calculated by the OLT 1 based on the time Tc and the time Ts transmitted from the OSW 2 to the OLT 1 during the initial registration of the OSW 2.

  The OLT 1 switches the output port 2112-j of the downstream optical switch element 211 of the OSW 2 and the input port 2122-j of the upstream optical switch element 212 to ONU # j (3-j), so that the optical switch switching control frame FR- C2d and FR-C2u are transmitted to OSW2.

  In OSW2, the optical switch switching control frames FR-C2d and FR-C2u are sent to the switch control circuit 215. When receiving the optical switch switching control frames FR-C2d and FR-C2u, the switch control circuit 215 receives the switching time t of the optical switch elements included in the optical switch switching control frames FR-C2d and FR-C2u and the light. According to the schedule shown in the association 6533 with the port number Port # of the switch element, the output port of the downstream optical switch element 211 is input to the output port 2112-j, and the input port of the upstream optical switch element 212 is input. Switch to port 2122-j.

  Next, the OLT 1 transmits a Discovery Gate message FR-DG2, which is a control frame for finding the ONU #j (3-j), to the ONU #j (3-j). Here, the output port 2112-j of the OSW 2 is already connected to the ONU #j (3-j) according to the schedule instructed by the switch control circuit 215. Therefore, the Discovery Gate message FR-DG2 passes through the downstream optical switch element 211 of the OSW2 switched by the optical switch switching control frame FR-C2d.

  The ONU # j (3-j) is connected to the output port 2112-j of the downstream optical switch element 211 of the OSW 2, and receives the Discovery Gate message FR-DG2 from the OLT 1. Subsequently, the ONU #j (3-j) notifies the OLT 1 of a request for registering the ONU #j (3-j) by transmitting a Register Request message FR-RR2. Here, the input port 2122-j of OSW2 is already connected to ONU # j (3-j) according to the schedule instructed by the switch control circuit 215. Therefore, the Register Request message FR-RR2 passes through the upstream optical switch element 212 of OSW2.

  When the OLT 1 receives the Register Request message FR-RR2, the OLT 1 transmits the Register message FR-R2 to the ONU #j (3-j) in order to register the ONU #j (3-j).

  The Register message FR-R2 includes an LLID indicating ONU # j (3-j) assigned by the OLT 1.

  When the OLT 1 transmits the Register message FR-R2, the ONU is set to the LLID 10612 corresponding to the switch port 01611 selected when transmitting the optical switch switching control frame FR-C2d and FR-C2u in the table 1061 (see FIG. 10). LLID indicating #j (3-j) is set.

  Further, the OLT 1 transmits a Gate message FR-G2 to the ONU #j (3-j) in order to designate a time at which the ONU #j (3-j) is permitted to transmit the Register Ack message FR-RA2 to the OLT 1. To do.

  When ONU # j (3-j) receives Gate message FR-G2, ONU # j (3-j) transmits Register Ack message FR-RA2 to OLT 1 at the time designated by Gate message FR-G2.

  As described above, the initial registration of ONU # j (3-j) ends. However, if there is ONU # k (3-k) to be initially registered, the procedure for initial registration of ONU # j (3-j) Is repeated for ONU # k (3-k).

  Moreover, OLT1 measures round trip time RTTj between OLT1 and ONU # j (3-j) by this initial registration of ONU # j (3-j).

  The OLT 1 sets a time t0 at which the OLT 1 transmits the Discovery Gate message FR-DG2 to the ONU #j (3-j) in the Discovery Gate message FR-DG2 to be transmitted to the ONU #j (3-j). When ONU # j (3-j) receives Discovery Gate message FR-DG2 from OLT1, ONU # j (3-j) sets the time at which Discovery Gate message FR-DG2 is received as the local time t0 of ONU # j (3-j) itself. To do. The ONU #j (3-j) sets the transmission time t0 of the Discovery Gate message FR-DG2 by the OLT 1 as the reception time of the Discovery Gate message FR-DG2, and thereby the OLT 1 and the ONU #j (3-j) Synchronize the time.

  Here, the time from when the OLT 1 transmits the Discovery Gate message FR-DG2 to when the ONU #j (3-j) receives the Discovery Gate message FR-DG2, that is, the OLT 1 is ONU #j (3-j). ) Let Td be the propagation delay time of the signal transmitted to.

  The ONU # j (3-j) sets the time t1 at which this Register Request message FR-RR2 is transmitted to the OLT1 in the Register Request message FR-RR2 to be transmitted to the OLT1. Here, the time from when ONU #j (3-j) receives the Discovery Gate message FR-DG2 from OLT1 to when ONU #j (3-j) transmits the Register Request message FR-RR2 to OLT1 is set. Let Tw.

  The OLT 1 receives the Register Request message FR-RR2 from the ONU # j (3-j) at time t2. Here, the time from when the ONU #j (3-j) transmits the Register Request message FR-RR2 to when the OLT 1 receives the Register Request message FR-RR2, that is, the ONU #j (3-j) is Let Tu be the propagation delay time of a signal to be transmitted to the OLT 1.

  As described above, the round trip time RTTj can be expressed by RTTj = Td + Tu = (t2−t0) −Tw = (t2−t0) − (t1−t0) = t2−t1.

  The OLT 1 calculates the round trip time RTTj from the time t1 included in the Register Request message FR-RR1, and sets it in the RTT 10613 (see FIG. 10) of the table 1061.

  In addition, by using the round trip time RTTs between OLT1 and OSW2 and the round trip time RTTj between OLT1 and ONU # j (3-j), OLT1 uses OSW2 and ONU # j (3-j). ) Is calculated as RTTsj = RTTj−RTTs.

  The round trip time RTTj is a time required for a signal to reciprocate between the OLT 1 and the ONU # j (3-j). The round trip time RTTsj is a time required for a signal to reciprocate between OSW2 and ONU # j (3-j). By calculating the round trip time RTTsj, it is possible to schedule the timing of connecting the input port 2122 of the upstream switch element 212 to the ONU 3 when transmitting a data frame from the ONU 3 to the OLT 1.

  FIG. 15 is a flowchart illustrating a procedure for initial registration of the ONU 3 according to the first embodiment of this invention.

  The OLT 1 determines whether or not the initial registration of the OSW 2 has been completed based on the OSW registration flag (step 1410).

  When the OSW registration flag is 0 and the initial registration of the OSW 2 is not completed, the OLT 1 performs the initial registration of the OSW 2 shown in the flowchart of FIG. 12 (step 1500).

  When the OSW registration flag is 1 and the initial registration of the OSW2 is completed, the OLT 1 sets the OSW2 connected to the ONU # j (3-j) to perform the initial registration of the ONU # j (3-j). With reference to the switch port, a table 1061 (see FIG. 10) showing the correspondence between the switch port 10611 and the LLID 10612 (see FIG. 10), the switch port 10611 of the OSW 2 to which the control frame is transmitted is selected (step 1420). In step 1420, the OLT 1 selects the switch port 10611 of the entry 10614 in which the LLID 10612 of the table 1061 is NULL. As a result, the initial registration processing of the ONU 3 newly connected to the switch port 10611 whose LLID 10612 is NULL is started.

  In FIG. 15, the output port 2112-j of the downstream optical switch element 211 and the input port 2122-2 of the upstream optical switch element 212 in the OSW 2 connected to the ONU #j (3-j) to be initially registered by the OLT 1. j is selected.

  The OLT 1 transmits the optical switch switching control frames FR-C2d and FR-C2u to the OSW 2 so as to switch the switch port of the optical switch element in the OSW 2 (Step 1430). Subsequently, the OLT 1 transmits a Discovery Gate message FR-DG2 to the ONU # j (3-j) (Step 1440).

  The OLT 1 determines whether or not the Register Request message FR-RR2, which is a response to the Discovery Gate message FR-DG2 transmitted in Step 1440, is received within a predetermined time (Step 1450).

  In step 1450, if the Register Request message FR-RR2 is not received, the Discovery Gate message FR-DG2 has not arrived normally at the ONU #j (3-j), so the initial registration of the ONU #j (3-j) Exit.

  When the OLT 1 receives the Register Request message FR-RR2 from the ONU # j (3-j), the OLT 1 determines the LLID to be assigned to the ONU #j (3-j) that has transmitted the Register Request message FR-RR2, and determines the OSL2 The determined LLID value is set in a table 1061 (see FIG. 10) showing the correspondence between the switch port 10611 number and the LLID 10612 (step 1460).

  Next, the OLT 1 sets the value of the LLID determined in Step 1460 in the Register message FR-R2, and transmits the Register message FR-R2 to the ONU #j (3-j). Subsequently, the Gate message FR-G2 is transmitted.

  When the OLT 1 receives the Register Ack message FR-RA2 corresponding to the Register message FR-R2 (step 1490), the OLT 1 ends the initial registration of the ONU 3.

  FIG. 16 is a sequence diagram illustrating processing between the OLT 1 and the OSW 2 for initial registration of the OSW 2 according to the second embodiment of this invention.

  In the first embodiment shown in the sequence diagram of FIG. 11, the OLT 1 transmits the optical switch switching control frames FR-C2d, FR-C2u, and the Discovery Gate message FR-DG2 by the OLT 1 itself. Start registration.

  On the other hand, in the second embodiment shown in the sequence diagram of FIG. 16, the initial registration of OSW2 is started by transmitting the Register Request message FR-RR0 to OLT1 when OSW2 first starts up. Is done.

  The OSW 2 outputs the output port 2182-1 of the downlink branching optical switch 218 and the input port 2192-2 of the upstream branching optical switch 219 in advance before transmitting the Register Request message FR-RR0. By switching to the port 2182-2 and the input port 2192-1, the communication path is switched to the switch control circuit 215 of the OSW2.

  When the OLT 1 receives the Register Request message FR-RR0 transmitted from the OSW 2, the OLT 1 transmits a Discovery Gate message FR-DG3 to the OSW 2 in order to discover the OSW 2. Subsequently, OSW2 transmits a Register Request message FR-RR3 to OLT1.

  Similarly to the first embodiment, the OSW 2 sends a Register Request message FR-RR3 to the OLT 1 so that the time required for the OSW 2 to process the optical switch switching control frame received from the OLT 1 (Tc) 758, A time (Ts) 759 for switching the connection destination of the output port of the optical switch element in the OSW 2 and the number of switch ports of the optical switch element of the OSW 2 are notified.

  Hereinafter, the Register message FR-R3, the Gate message FR-G3, and the Register Ack message FR-RA3 are the Register message FR-R1, the Gate message FR-G1, and the Register Ack message FR-RA1 in the first embodiment. The same.

  The OLT 1 starts the initial registration of the OSW 2 when the OLT 1 receives the Register Request message FR-RR 3 sent from the OSW 2.

  FIG. 17 is a flowchart illustrating a procedure of initial registration of the OSW 2 in the OSW 2 according to the second embodiment of this invention.

  FIG. 17 is a flowchart showing the processing in OSW 2 in the procedure shown in FIG.

  First, the switch control circuit 215 of OSW2 switches the switch port of OSW2 toward the switch control circuit 215 (step 1610).

  Next, OSW2 transmits a Register Request message FR-RR0 to OLT1 (step 1620). The OSW 2 determines whether or not the Discovery Gate message FR-DG3 is received from the OLT 1 within a predetermined time (step 1630).

  In Step 1630, when the Discovery Gate message FR-DG3 is not received from the OLT 1 within a predetermined time, the OSW 2 returns to Step 1620 and transmits the Register Request message FR-RR0 again. In Step 1630, when the Discovery Gate message FR-DG3 is received, the OSW2 transmits a Register Request message FR-RR3 (Step 1640).

  The OSW2 receives the Register message FR-R3 from the OLT 1 (step 1650), and then receives the Gate message FR-G3 from the OLT 1 (step 1660), and transmits the Register Ack message FR-RA3 (step 1650). As a result, the initial registration procedure of the OSW 2 in the OSW 2 of the second embodiment is completed.

  FIG. 18 is a flowchart illustrating a procedure of initial registration of the OSW 2 in the OLT 1 according to the second embodiment of this invention.

  After starting the optical access system 50, the OLT 1 sets the value of the OSW registration flag to 0 (step 1810).

  The OLT 1 waits until it receives a Register Request message FR-RR0 from the OSW 2 (step 1820).

  When the OLT 1 receives the Register Request message FR-RR0 from the OSW 2, the OLT 1 transmits a Discovery Gate message FR-DG3 to the OSW 2 (Step 1830). When the OLT 1 receives the Register Request message FR-RR3 from the OSW 2 (Step 1840), the OLT 1 transmits the Register message FR-R3 (Step 1850), and then transmits the Gate message FR-G3 (Step 1860).

  When the OLT 1 receives the Register Ack message FR-RA3 from the OSW 2 (step 1870), the OLT 1 sets the value of the OSW registration flag to 0 (step 1880). Thereby, the procedure of initial registration of OSW2 in OLT1 is completed.

  As described above, according to the first and second embodiments of the present invention, when the optical access system 50 is activated, the OSW 2 and the ONU 3 can be initially registered. Further, the switch control circuit 215 of the OSW 2 designates the switching schedule of the optical switch element based on the information transmitted from the OLT 1, so that a delay circuit using an optical fiber and an O / E converter for upstream communication are provided in the OSW 2. It is possible to provide a device for switching the input / output port to the ONU 3 without any problem.

1 Optical line equipment (OLT)
2 Optical communication path switching device (OSW)
3 Optical network equipment (ONU)
4 terminal 50 optical access system 53 gateway 55 core network 210 multiplexing / demultiplexing unit 211 downstream optical switch element 212 upstream optical switch element 213 downstream switch driver 214 upstream switch driver 215 switch control circuit 216 optical-electrical signal conversion unit (O / E converter)
217 Electric-optical signal converter (E / O converter)
218 Down-branch optical switch 219 Up-branch optical switch 220 multiplexer / demultiplexer

Claims (18)

An optical line device connected to another network; a plurality of optical network devices each connected to a user terminal; and the optical line device and the plurality of optical network devices installed between the optical line device and the optical network device In an optical access system comprising an optical communication path switching device for switching an optical communication path with an optical network device of
The optical line device transmits a first control signal for discovering the optical communication path switching device to the optical communication path switching device,
The communication path switching device, after receiving the first control signal, transmits a second control signal for requesting registration of the optical communication path switching device to the optical line device,
The optical line device, after receiving the second control signal, transmits a third control signal including information for registering the optical communication path switching device to the optical communication path switching device,
The optical communication path switching device transmits a fourth control signal indicating that the third control signal has been received to the optical line device at a time designated by the optical line device. Optical access system.   The second control signal is provided in the optical communication path switching device and a time required for the optical communication path switching device to switch an optical communication path between the optical line device and the plurality of optical network devices. The optical access system according to claim 1, further comprising information on the number of ports of the switch. After the optical communication path switching device is registered in the optical line device, the optical communication path switching device switches to connect an optical communication path between the optical line device and the optical network device,
Thereafter, the optical line device transmits a fifth control signal for discovering the optical network device to the optical network device,
The optical network device, after receiving the fifth control signal, transmits a sixth control signal for requesting registration of the optical network device to the optical line device;
The optical line device, after receiving the sixth control signal, transmits a seventh control signal including information of the registered optical network device to the optical network device,
The optical network device transmits an eighth control signal indicating that the seventh control signal has been received to the optical line device at a time designated by the optical line device. The optical access system according to 1. An optical line device connected to another network; a plurality of optical network devices each connected to a user terminal; and the optical line device and the plurality of optical network devices installed between the optical line device and the optical network device In an optical access system comprising an optical communication path switching device for switching an optical communication path with an optical network device of
The optical communication path switching device transmits a first control signal for starting registration processing of the optical communication path switching device to the optical line device,
The optical line device, after receiving the first control signal, transmits a second control signal for discovering the optical communication path switching device to the optical communication path switching device,
The optical communication path switching device, after receiving the second control signal, transmits a third control signal for requesting registration of the optical communication path switching device to the optical line device,
The optical line device, after receiving the third control signal, transmits a fourth control signal including information for registering the optical communication path switching device to the optical communication path switching device,
The optical communication path switching device transmits a fifth control signal indicating that the fourth control signal has been received to the optical line device at a time designated by the optical line device. Access system.   The third control signal is provided in the optical communication path switching device and a time required for the optical communication path switching device to switch an optical communication path between the optical line device and the plurality of optical network devices. 5. The optical access system according to claim 4, further comprising information on the number of ports of the switch. After the optical communication path switching device is registered in the optical line device, the optical communication path switching device switches to connect an optical communication path between the optical line device and the optical network device,
Thereafter, the optical line device transmits a sixth control signal for discovering the optical network device to the optical network device,
The optical network device, after receiving the sixth control signal, transmits a seventh control signal requesting registration of the optical network device to the optical line device;
The optical line device, after receiving the seventh control signal, transmits an eighth control signal including information for registering information about the optical network device to the optical line device;
The optical network device transmits a ninth control signal indicating that the eighth control signal has been received to the optical line device at a time designated by the optical line device. 5. The optical access system according to 4. An optical communication path installed between an optical line device connected to another network and a plurality of optical network devices each connected to a user terminal, and between the optical line device and the plurality of optical network devices In the optical communication path switching device for switching between
Receiving a first control signal for discovering the optical communication path switching device from the optical line device;
After receiving the first control signal, a second control signal for requesting registration of the optical communication path switching device is transmitted to the optical line device,
After transmitting the second control signal, a third control signal including information for registering the optical communication path switching device is received from the optical line device,
An optical communication path switching device, wherein a fourth control signal indicating that the third control signal has been received is transmitted to the optical line device at a time designated by the optical line device.   The second control signal is provided in the optical communication path switching device and a time required for the optical communication path switching device to switch an optical communication path between the optical line device and the plurality of optical network devices. 8. The optical communication path switching device according to claim 7, further comprising information on the number of ports of the switch. An optical communication path installed between an optical line device connected to another network and a plurality of optical network devices each connected to a user terminal, and between the optical line device and the plurality of optical network devices In the optical communication path switching device for switching between
A first control signal for starting the registration process of the optical communication path switching device is transmitted to the optical line device;
After transmitting the first control signal, a second control signal for discovering the optical communication path switching device is received from the optical line device,
After receiving the second control signal, a third control signal for requesting registration of the optical communication path switching device is transmitted to the optical line device,
After transmitting the third control signal, information for registering the optical communication path switching device is received from the optical line device as a fourth control signal,
An optical communication path switching device, wherein a fifth control signal indicating that the fourth control signal has been received is transmitted to the optical line device at a time designated by the optical line device.   The third control signal is provided in the optical communication path switching device and a time required for the optical communication path switching device to switch an optical communication path between the optical line device and the plurality of optical network devices. 10. The optical communication path switching device according to claim 9, further comprising information on the number of ports of the switch. In an optical line device connected to a plurality of optical network devices via an optical communication path switching device and connected to another network,
Each of the plurality of optical network devices is connected to a user terminal,
The optical communication path switching device switches an optical communication path between the optical line device and the plurality of optical network devices,
The optical line device is:
A first control signal for discovering the optical communication path switching device is transmitted to the optical communication path switching device;
After transmitting the first control signal, a second control signal for requesting registration of the optical communication path switching device is received from the optical communication path switching device,
After receiving the second control signal, a third control signal including information for registering the optical communication path switching device is transmitted to the optical communication path switching device,
An optical line characterized by confirming reception of a fourth control signal transmitted from the optical communication path switching apparatus and indicating that the third control signal has been received at a time designated by the optical line apparatus. apparatus.   The second control signal is provided in the optical communication path switching device and a time required for the optical communication path switching device to switch an optical communication path between the optical line device and the plurality of optical network devices. 12. The optical line device according to claim 11, further comprising information on the number of ports of the switch.   A transmission time of the first control signal by the optical line device, a reception time of the first control signal by the optical communication channel switching device, a transmission time of the second control signal by the optical communication channel switching device, and A first delay time of signal propagation between the optical line device and the optical communication path switching device is measured based on a reception time of the second control signal by the optical line device. The optical line device according to claim 11.   Holding a port of a switch of the optical communication path switching device connected to the optical communication path switching device, an identifier of the optical communication path switching device, and the measured first delay time in association with each other. The optical line device according to claim 13, After the optical communication path switching device is registered in the optical line device, the optical communication path switching device is switched to connect the optical communication path between the optical line device and the optical network device, and then Transmitting a fifth control signal for discovering the optical network device to the optical network device;
After receiving the fifth control signal, a sixth control signal for requesting registration of the optical network device is received from the optical network device;
15. The optical line according to claim 14, wherein after receiving the sixth control signal, a seventh control signal including information for registering the optical network device is transmitted to the optical network device. apparatus.   The transmission time of the fifth control signal by the optical network device, the reception time of the fifth control signal by the optical network device, the transmission time of the sixth control signal by the optical network device, and the sixth 16. The second delay time of signal propagation between the optical line device and the optical network device is measured based on a reception time of the control signal by the optical line device. Optical line equipment.   The port of the switch of the optical communication path switching device connected to the optical network device, the identifier of the optical network device, and the measured second delay time are held in correspondence with each other. Item 17. The optical line device according to Item 16.   18. The signal propagation delay time between the optical communication path switching device and the optical network device is calculated based on the first delay time and the second delay time. The optical line device as described.

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