JP2012129942A - Optical communication system - Google Patents

Abstract

An optical communication system capable of preventing an increase in OLT processing load and the amount of management information and capable of switching transmission lines at high speed.
The present invention extracts signal light of a specific wavelength from a ring network and outputs it to another node that does not constitute the ring network, and the signal light input from the other node is transmitted to the ring network. Communication including ring nodes 2 ₁ to ₂ 2 that output to each other, remote nodes 3 _{11 to} 3 _nr that operate as other nodes, and ONUs 5 ₁ , 5 ₁₀ , and 5 ₁₀₁ connected to the remote nodes. A part of a ring node operates as an OLT, and a remote node has a function of measuring an RTT with each ONU connected to the ring node, and indicates an upstream band allocation result. When the Gate information is received, the Gate information is corrected based on its own local time and RTT measurement results and then transferred.
[Selection] Figure 1

Description

  The present invention relates to an optical communication system configured by one-to-many connection of a station side device and a subscriber side device (subscriber termination device).

  A PON (Passive Optical Network), which is one form of an optical communication system, includes a station side device (OLT: Optical Line Terminal) disposed at a central office and a subscriber termination device (ONU: Optical) disposed at a plurality of subscriber homes. Network Unit) is connected one-to-many with star couplers and optical fibers, and time division multiplexing communication is performed in the upstream direction (direction from the subscriber to the central office), and continuous communication is performed in the downstream direction. This PON is widely used as an economical communication system in which a plurality of ONUs are accommodated by one OLT by having a function of filtering a downstream signal with an ONU identifier given to a frame on the ONU side (for example, Non-patent document 1). In recent years, standardization of 10 Gbps class PON for the purpose of further increasing the communication capacity of the access network has been completed (see Non-Patent Document 2, for example). This standard is a 10 Gbps version of the 1 Gbps class PON defined in the conventional IEEE 802.3, and is accommodated in the OLT that can accommodate both the conventional 1 Gbps EPON and the 10 Gbps 10 G-EPON ONU, and this OLT. It defines the functions that the ONU should realize. Similarly, ITU-T is also standardizing 10 Gbps class PON.

  When these international standards are applied, the communication speed in the PON section becomes 10 times. In this case, two merits can be considered. The first merit is that the communication carrier operates with the same number of subscribers per OLT as the number of subscribers of a 1 Gbps class PON, so the communication capacity per subscriber increases and the subscribers It is to be able to benefit from the increased capacity of the section. The second advantage is that the communication carrier accommodates more subscribers per OLT than the 1 Gbps class PON, thereby lowering the operation cost and allowing the subscriber to be equal to or more than the 1 Gbps class PON. Service (communication capacity).

  In general, 1-Gbps class PON star couplers use a maximum of 32 to 64 branches, and the number of branches beyond that is almost realized due to the small communication capacity and loss of the optical transmission line due to the branching of the star coupler. Although not done, the number of ONUs accommodated by multi-branching has been studied conventionally. For example, in Patent Document 1, a plurality of PON signals with different wavelengths handled by a plurality of station side devices installed in a central office are coupled to a WDM coupler that multiplexes or demultiplexes each wavelength, and is multiplexed by a WDM coupler. The wavelength-division multiplexed signal is connected to a plurality of transponders capable of transmitting and receiving a PON signal having a wavelength corresponding to a specific station-side device using one optical fiber and a star coupler, and the transponder and the plurality of ONUs are connected to one light. There is disclosed a multi-branching method in which a fiber and a star coupler are connected and a PON signal is transmitted and received by time division multiplexing in the upstream direction.

  Also, when considering the effective use of a 10 Gbps class PON device, it is possible to increase the number of subscribers per OLT and reduce the operating cost of the communication carrier, rather than just considering the improvement of the communication speed per subscriber. It is desirable to have an operational form that improves satisfaction.

  Applying this type of operation and sharing the OLT with a larger number of subscribers results in lowering the OLT power consumption (total power consumption of all OLTs on the station side) and spreading it all over the world. This is in line with the trend toward lower power consumption.

  However, only with the provisions stipulated in the international standard of 10 Gbps class (Non-Patent Document 2 above), the transmission quality deteriorates due to multi-branching, so that the distance between the currently served central office and the subscriber's home is not reduced. It is difficult to realize branching. For example, it is possible to achieve both service distance and multi-branching by increasing the power of OLT and ONU transmitters or inserting an amplifier in the fiber, but the transmission power of OLT and ONU is high. Then, operation and technical problems occur, such as a higher hazard level for access fiber laying workers and difficulty in amplifying an upstream burst signal with an amplifier.

  Further, in the method disclosed in Patent Document 1, the configuration of the station-side device is not changed from the conventional configuration, and a transponder is newly inserted, so that multi-branching is possible, but low power consumption is achieved. The problem that is difficult. Further, as a problem common to the conventional system, when a service is provided to a larger number of subscribers with one OLT, the central office device and the subscriber device are connected by a single fiber. When a fiber (especially a trunk line) breaks down, the problem that a failure area expands arises.

  Therefore, in order to solve the above-mentioned problems, in a PON apparatus of 10 Gbps class or higher, a subscription that allows power saving and a redundant configuration while allowing an increase in the number of subscribers per OLT (multiple branching) is allowed. For the purpose of providing a person accommodation device, a method of consolidating more ONUs into one OLT than before is disclosed by the fusion of OTN technology and PON technology (for example, Non-Patent Document 3).

JP 2008-206008 A

IEEE802.3 IEEE802.3av IEICE Technical Report CS2010-9 (2010-7)

  In Non-Patent Document 3 described above, the PON function is integrated into the OLT, and the PON signal is directly accommodated in the OTN (Optical Transport Network) signal to be transmitted and received, thereby increasing the number of branches, lengthening, and network reliability. A method for realizing low power consumption is shown. However, in the prior art, RTT (Round Trip Time) measurement (ranging) for each ONU necessary to avoid collision of upstream burst signals in the PON interval is measured separately in the OTN interval and the PON interval, and then the combined RTT However, there is a problem that it is difficult to realize high-speed switching of the transmission path as the processing load of the OLT and the amount of information managed by the OLT increase.

  The present invention has been made in view of the above, and even when a configuration in which the PON functions are integrated in the OLT is adopted, it is possible to prevent an increase in the processing load and management information amount of the OLT, and the transmission path. An object is to obtain an optical communication system capable of high-speed switching.

  In order to solve the above-described problems and achieve the object, the present invention constitutes a ring network, extracts signal light of a specific wavelength from the ring network, and does not constitute the ring network. A plurality of ring nodes that output to the ring network the signal light input from the other nodes, a remote node that operates as the other nodes, and the remote node via an optical coupler An optical communication system configured to include a connected ONU, wherein some of the nodes in the ring node operate as an OLT that executes a process of allocating an upstream band to the ONU, and the remote The node has a function of measuring an RTT indicating a transmission delay time between each ONU connected to the node and When receiving the Gate information indicating the allocation result of the uplink band, and wherein the transfer of the Gate information itself local time and the RTT measured on corrected on the basis of the results to the respective ONU in respect.

  According to the present invention, when a communication path higher than that of the remote node is switched, the RTT held by the remote node is not affected, so that the upstream burst control of the PON becomes easy and the communication path can be switched. When it occurs, the time required for communication restoration can be shortened compared to the conventional method.

FIG. 1 is a diagram showing a configuration example of an optical communication system according to the present invention. FIG. 2 is a diagram illustrating a configuration example of the OLT. FIG. 3 is a diagram illustrating a configuration example of the RN. FIG. 4 is a diagram illustrating an example of a control procedure according to the ranging method. FIG. 5 is a diagram illustrating an example of a bandwidth allocation operation. FIG. 6 is a flowchart showing a procedure for updating the GST and a procedure for updating the reference time of the band update cycle.

  Embodiments of an optical communication system according to the present invention will be described below in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

Embodiment.
<System configuration>
First, the overall configuration of the system will be described. FIG. 1 is a diagram showing a configuration example of an optical communication system according to the present invention. As shown in the figure, an optical communication system includes a ring network having a configuration in which a plurality of nodes (OLT1 and ring nodes 2 ₁ to 2 _n ) are connected by a duplexed optical fiber (trunk optical fiber), and a duplex network. Remote nodes (RN) 3 _{11 to} 3 _1p , 3 _{21 to} 3 _2q ,..., 3 _{n1 to} 3 _nr connected to the ring nodes 2 ₁ to 2 _n through the optical fiber, an optical fiber and an optical coupler ONUs (10G-ONU5 ₁₀ , 1G-ONU5 ₁ , 10G · 1G-ONU5 ₁₀₁ ) connected to the RN via a (32 branch coupler) 4. Incidentally, 10G-ONU 5 ₁₀ is capable of uplink and downlink bidirectional 10Gbps communication ONU (e.g., those defined in IEEE802.3av), 1G-ONU5 ₁ is capable of uplink and downlink bidirectional 1Gbps communication ONU 10G · 1G-ONU5 ₁₀₁ is an ONU (for example, specified in IEEE802.3av) that can communicate at an uplink of 1 Gbps and a downlink of 10 Gbps. In the following description, when “ONU” is simply described, 10G-ONU5 ₁₀ , 1G-ONU5 ₁ and 10G · 1G-ONU5 ₁₀₁ are indicated. Further, an RN may be connected to the OLT 1 and various ONUs may be connected to the RN. In this embodiment, the case where the optical coupler 4 is a 32-branch coupler will be described, but other branch numbers may be used.

  In the optical communication system shown in FIG. 1, an OLT 1 is a communication device that connects an upper network and a ring network, and includes a demultiplexing unit, two redundant OLT-IFs, a monitoring control unit, a ROADM ( Reconfigurable Optical Add / Drop Multiplexer) section. Each ring node is a communication device having the same configuration, and has a ROADM unit and a transponder. Each RN is a communication device having the same configuration, and includes a transponder and a monitoring control unit. The OLT 1 is a communication device having a function of operating as a PON OLT in addition to the function of each ring node. Conventionally, the optical communication system of the present embodiment is a communication device under each ring node (FIG. 1). The OLT functions (functions that operate as OLTs) possessed by the communication device at the location where each RN is located in are integrated into one ring node to form OLT 1.

  The demultiplexing unit of OLT 1 outputs the downstream signal light (frame) received from the upper network to one of the two OLT-IFs, and outputs the upstream signal light received from the OLT-IF to the upper network. To do. The OLT-IF executes various processes for the OLT 1 to operate as a station-side device of the PON. Details will be described separately. One of the two OLT-IFs is set as the active system and the other is set as the standby system. The monitoring control unit performs monitoring (failure detection) in the communication system, path switching at the time of failure detection, and the like. The ROLT unit of the OLT 1 and each ring node extracts and adds a specific wavelength (output to the ring network) for a signal (light) flowing on the ring network. The transponder of each ring node performs wavelength conversion of the received signal light. Each RN transponder also converts the wavelength of the received signal light. In the upstream direction, a plurality of optical burst signals having different communication speeds are terminated, and light of at least one wavelength for RN and OLT 1 to communicate with each other. A process of converting to a continuous signal is also performed. On the other hand, in the downlink direction, a signal for each transponder is extracted from a signal having a predetermined communication wavelength predetermined for each RN, and a communication signal is transmitted in a predetermined frame format at a wavelength specific to the PON defined by the standard. To do.

OLT1 and RN3 ₁₁ ~3 _1p (p is the number RN which is connected under the ring node _{2 1), RN3 21 ~3 2q} (q is the number RN which is connected under the ring node _{2 2), RN3 n1 ~3 nr} ( r is the number of RNs connected under the ring node 2 _n ) is connected via one or more ring nodes 2 ₁ to 2 _n (n is the number of ring nodes constituting the ring network), and RN OTU (Optical-channel Transport Unit) frame transmission by continuous optical WDM at a higher transmission speed than the communication speed between the network and the ONUs under its control (10G-ONU, 1G-ONU, 10G / 1G-ONU) Communicate by On the other hand, the transponders accommodated in each RN and the ONUs connected to the transponders are connected in a star topology like the conventional PON and communicate by the conventional TDMA-PON system.

  In the present embodiment, for simplification of description, as shown in FIG. 1, optical communication having a configuration in which the OLT function is integrated in one of the nodes (communication devices) constituting the ring network. The explanation is given assuming the system. However, it is not essential to consolidate into one node. The OLT function may be distributed to some nodes.

<Configuration of OLT>
Next, the configuration of the OLT 1 will be described. FIG. 2 is a diagram illustrating a configuration example of the OLT 1 illustrated in FIG. Here, as an example, it is assumed that the OLT 1 performs PON control conforming to the IEEE standard. As illustrated, the OLT 1 includes a demultiplexing unit 11, OLT-IFs 12A and 12B, a monitoring control unit 13 including an active monitoring control unit 13A and a standby monitoring control unit 13B, and a ROADM unit 14. The OLT-IFs 12A and 12B and the monitoring control unit 13 (the active system monitoring control unit 13A and the standby system monitoring control unit 13B) are connected by a monitoring control bus.

  The demultiplexing unit 11 outputs the received signal light to either one of the two OLT-IFs when receiving the downstream signal light (frame) from the upper network via the NNI (Network Network Interface). Further, the upstream signal light received from the OLT-IFs 12A and 12B is transmitted to the upper network.

  The OLT-IFs 12A and 12B have the same configuration, and either one is set as the active system and the other is set as the standby system. In FIG. 2, the OLT-IF 12A is set as the active system. The OLT-IFs 12A and 12B include a CPU 12-1, a memory 12-2 necessary for the operation of the CPU 12-1, a highly integrated PON control unit 12-3, an optical transceiver (Optical TRx) 12-4, and a packet buffer memory 12- The highly integrated PON control unit 12-3 includes an L2 bridge 121, a PON control unit 122, a multiplexer (MUX) 123, a demultiplexer (DEMUX) 124, an OTN mapper / demapper 125, and a SER / DES 126.

  The L2 bridge 121 performs processing for bridging signals input from a plurality of NNIs via the demultiplexing unit 11 and processing for a VLAN tag. The PON control unit 122 supports a super link (LLID: Logical Link ID) in order to support a plurality of transponders, MPCP (Multi-Point Control Protocol) control, RTT (Round Trip Time) management, uplink bandwidth Performs control such as allocation control. The MUX 123 multiplexes an Ethernet (registered trademark) frame (hereinafter referred to as an Ethernet frame) input from the downstream NNI side and an Ethernet frame generated by the PON control unit 122. The DEMUX 124 sorts the upstream frame into an Ethernet frame necessary for PON control (a frame processed by the PON control unit 122) and an Ethernet frame to be transmitted to the NNI side. The OTN mapper / demapper 125 maps the Ethernet frame input from the NNI or PON control unit 122 via the MUX 123 to the OTU frame and transmits it, and the OTU frame received via the SER / DES 126 as the Ethernet frame. Performs demapping (decapsulation). The SER / DES 126 is a serializer / deserializer necessary for an interface with the optical transceiver 12-4 connected to an OTN (Optical Transport Network) -IF. An OTU frame is a frame used in OTN.

  The optical transceiver 12-4 transmits the signal light having the wavelengths λ111 to λ1nk output from the SER / DES 126 to the ROADM unit 14 and receives the signal light having the wavelengths λ511 to λ5nk from the ROADM unit 14 to the SER / DES 126. Output.

  The active monitoring control unit 13A and the standby monitoring control unit 13B of the monitoring control unit 13 have the same configuration, and perform optical path switching control, failure detection / notification of OLT-IF, switching of OLT-IF, and the like.

  The ROADM unit 14 performs extraction processing and addition processing of signal light having a specific wavelength with respect to signal light flowing through the ring network. Note that the ROADM unit 14 includes a conventional optical switch and a transponder having general functions.

<Configuration of RN>
Next, the configuration of the remote nodes (RN) 3 _{11 to} 3 _1p , 3 _{21 to} 3 _2q ,..., 3 _{n1 to} 3 _nr will be described. Each RN shown in FIG. 1 has the same configuration. Therefore, here it will be described the configuration of each RN as an example RN3 _11. Figure 3 is a diagram showing the RN3 ₁₁ configuration example of that shown in FIG. As shown, RN3 ₁₁ includes a WDM coupler 31, the monitor control unit 32 composed of a working system monitoring control unit 32A and the standby system monitoring control unit 32B, OTN transponders 33A and transponder 33 comprising a transponder 33B ₁ ~33B _n With. The monitoring control unit 32 (active system monitoring control unit 32A, standby system monitoring control unit 32B) and transponder unit 33 (OTN transponder 33A, transponders 33B _{1 to} 33B _n ) are connected by a monitoring control bus.

  The WDM coupler 31 wavelength-multiplexes upstream and downstream communication wavelengths, transmits upstream signal light with wavelengths λ421 to λ42s, and receives downstream signal light with wavelengths λ211 to λ21s.

  The active monitoring control unit 32A and the standby monitoring control unit 32B of the monitoring control unit 32 have the same configuration, and perform failure detection / notification of the transponder unit 33, wavelength mapping setting, and the like. The active system supervisory control unit 32A and the standby system supervisory control unit 32B include an optical transceiver (Optical TRx) 321, an OTN mapper / demapper 322, a management frame transceiver unit 323, a TS adding unit 324, a time synchronization unit 325, and a memory 326. And a CPU 327 that operates using the memory 326.

The optical transmitter / receiver 321 transmits / receives signal light to / from the WDM coupler 31. OTN mapper / demapper 322, the uplink (direction toward the ring nodes 2 _1), generates OTU frame encapsulates Ethernet frame input from the management frame transmission and reception unit 323, and outputs the WDM coupler 31. In the downstream direction, the OTU frame input from the WDM coupler 31 is decapsulated to extract an ether frame. Management frame transmitting and receiving unit 323 transmits and receives a management frame via a ring node 2 _1. When receiving the management frame, the OUT frame to which the management frame is mapped is input from the optical transceiver 321 to the OTN mapper / demapper 322, converted into an Ethernet frame format management frame by the OTN mapper / demapper 322, and then received. . On the other hand, at the time of transmission, the management frame transmission / reception unit 323 generates a management frame in the ether frame format and outputs the management frame to the OTN mapper / demapper 322. After the ether frame (management frame) is mapped to the OTU frame, the optical transceiver 321 is sent to the WDM coupler 31 from being transmitted after being wavelength-multiplexed by the WDM coupler 31 to the ring node 2 _1. When the management frame transmission / reception unit 323 generates and transmits a management frame, the TS adding unit 324 receives information on the current time from the time synchronization unit 325 as necessary, and writes it as a time stamp in the management frame. The time synchronization unit 325 is a 16 ns precision counter (timer) and manages time. Note that the TS adding unit 324 and the time synchronization unit 325 realize a function for measuring a transmission line delay with a ring node accommodating the own RN.

The OTN transponder 33A includes an optical transceiver (Optical TRx) 331 and an OTN mapper / demapper 332. The optical transmitter / receiver 331 transmits / receives signal light to / from the WDM coupler 31. In the upstream direction, the OTN mapper / demapper 332 maps signals received from the connected transponders (transponders 33B _{1 to} 33B _n ) to the OTU frame and outputs the OTU frame to the optical transceiver 331. In the downstream direction, an ether frame is extracted from the OTU frame input from the optical transceiver 331 and is output to any _{one of} the transponders 33B _{1 to} 33B _n . In the configuration example shown in FIG. 3, the OTN transponder 33A is not duplicated (redundant), but may be duplicated to improve reliability.

The transponders 33B _{1 to} 33B _n have the same configuration, and an upstream dual rate burst clock data recovery (DB CDR) 333, a dual rate burst optical receiver (DOB Rx) 334, and a 10 Gbps continuous optical transmitter (Continuous 10G-Tx) 335 1 Gbps continuous optical transmitter (Continuous 1G-Tx) 336, WDM coupler 337, local timer 338, time stamp processing unit 339, and RTT management unit 340.

  The dual-rate burst clock data recovery 333 and dual-rate burst optical receiver 334 are used to transmit upstream signal light having a communication speed of 1 Gbps and 10 Gbps, specifically, burst signals having wavelengths λup41 and λup42 transmitted from the ONU. 337 and received as a continuous signal of 1 Gbps and 10 Gbps. Also, the 10 Gbps continuous optical transmitter 335 and the 1 Gbps continuous optical transmitter 336 convert 1 Gbps and 10 Gbps Ethernet frames, which are downstream signal light transmitted from the OTN transponder 33A, to wavelengths specified by the IEEE standard, and a WDM coupler. Then, the data is transmitted to the optical fiber side to which the star coupler (optical coupler 4) is connected. Note that a time stamp indicating the time managed by the local timer 338 is embedded in the Ether frame input to the 10 Gbps continuous optical transmitter 335 and the 1 Gbps continuous optical transmitter 336. The local timer 338 is configured by a 16-ns granular 32-bit counter that is normally used in PON control, and manages the local time for each transponder. The time stamp processing unit 339 adds a time stamp indicating the time managed by the local timer 338 to the frame input from the OTN mapper / demapper 332. The RTT management unit 340 measures the RTT in the PON section (between the own device (own transponder) and each subordinate ONU) and manages the measurement result. In addition, the managed RTT is notified to the OLT 1 as necessary.

In each RN configured as described above, in the frame processing operation in the downlink direction, each transponder identifies the MPCP frame, and a time stamp indicating the time (local time) managed by the local timer 338 for each transponder is given thereto. Then, the information in the Gate frame is corrected. On the other hand, in the uplink frame processing operation, each transponder calculates and holds the RTT for each logical link using the local timer value and the time stamp value stamped in the received MPCP frame. In FIG. 3, the configuration example in which each of the transponders 33B _{1 to} 33B _n includes the local timer 338 is shown. However, the transponder unit 33 or the RN includes the local timer, and the local time managed by the local timer. Accordingly, the transponders 33B ₁ to 33B _n may operate.

<Management operation of RTT (ranging method)>
Next, the ranging method (transmission path delay measuring method) by the optical communication system of the present embodiment will be described with reference to FIG. Here, as an example, a ranging method executed when registering an ONU will be described. In the PON transfer section (between RN and ONU) shown in FIG. 4, an MPCP frame for PON control is transmitted and received. The MPCP frame is encapsulated in the OTN transfer section (between OLT and RN) and transmitted and received as an OTU frame. However, description of the encapsulation / decapsulation operation in the RN is omitted. In order to simplify the description, the description will be made assuming that the RN includes a single transponder. Accordingly, in the ranging method described below, the process executed by the RN corresponds to the process executed by the transponder in the RN.

  In the control shown in FIG. 4, first, a Discovery Gate frame in which a relative value of a transmission start time (Grant start time, expressed as GST in the figure) is stored is transmitted from the OLT to the RN (step S1).

  The RN impresses a TS (time stamp) indicating the local time managed by the local timer in its own device with respect to the frame received from the OLT, and corrects the GST to an absolute time value (step S2). Transfer to ONU (step S3).

  The ONU that has received the Discovery Gate frame confirms the TS value (absolute time) embedded in the received frame, performs processing (TS synchronization) to synchronize the value of the local timer with this (step S4), and thereafter When the transmission start time (GST) designated by the Discovery Gate frame is reached, a Register Request frame in which TS indicating the value of the local timer of the ONU is stamped is transmitted to the OLT (steps S5 and S6). By executing step S4, the local time of the ONU is in agreement with the local time of the RN at the time when these steps S5 and S6 are executed.

  When the RN receives the Register Request frame, the RN transmits the Discovery Gate frame (TS value assigned to the Discovery Gate frame), the TS value embedded in the received frame, and the frame reception time (local timer at the time of reception). RTT is calculated based on (value) (step S7). Further, a Register Request frame including the calculated RTT is transferred (step S8).

  When the OLT receives the Register Request frame including the RTT, the OLT updates the RTT of the corresponding logical link based on the received RTT (step S9). Also, a predetermined process (such as a process of assigning a logical link to the ONU) for registering the frame transmission source ONU is executed. Next, the OLT transmits a Register frame indicating that the ONU registration process has been completed (step S10), and the RN seals the received frame with a TS and transmits it to the ONU (steps S11 and S12). When the ONU receives the Register frame, the ONU performs TS synchronization as in step S4 (step S13). Also, the setting inside the device is changed according to the information contained in the received frame. For example, the logical link assigned to the own device is grasped, and the identification information (logical link ID) is stored.

  The OLT further allocates a band for the ONU to transmit the response frame to the Register frame transmitted in step S10 (Grant generation), and transmits a Gate frame for notifying the band allocation result (steps S14 and S15). In this Gate frame, the ID of the logical link assigned to the ONU is embedded.

  When receiving the Gate frame, the RN seals the TS indicating the local time of its own device instead of the embedded TS, corrects the GST based on the local time, and forwards it to the ONU (steps S16 and S17). .

  When receiving the Gate frame, the ONU performs TS synchronization in the same manner as steps S4 and S13 (step S18). Also, the TS is stamped and a Register Ack frame is transmitted (steps S19 and S20). The Register Ack frame is transmitted using the band notified by the received Gate frame.

  When receiving the Register Ack frame, the RN calculates the RTT in the same manner as in Step S7 (Step S21), and transfers the Register Ack frame including the calculated RTT (Step S22). When the OLT receives the Register Ack frame including the RTT, the OLT updates the RTT of the corresponding logical link (step S23).

  In addition, when RN calculates RTT, it is not necessary to notify a calculation result to OLT every time. It is only necessary to notify the OLT at least when the previously calculated (previous) RTT is different from the newly calculated RTT (including when the RTT has not been previously notified to the OLT).

  As described above, when the RN receives a frame from the OLT, the RN updates the time stamp value (TS value) in the frame to the local time (local timer value), and transfers it to the ONU. When the received frame includes uplink bandwidth allocation information (in the case of a Discovery Gate frame or a Gate frame), the transmission start time (GST) included in the bandwidth allocation information is also updated and then sent to the ONU. Forward. Further, when a frame is received from the ONU, RTT is calculated. When the RN includes a plurality of transponders, the RN performs ranging according to the above-described procedure for each transponder. Also, each ONU accommodated in the RN is whether the TS value or GST of each frame received via the RN is based on the local time of the RN, and whether time synchronization is performed with the OLT, or It is not necessary to recognize whether time synchronization is performed with the RN. That is, it is sufficient to perform the same operation as that of a conventional ONU, and no special operation is required.

  Here, the band allocation operation including the GST correction operation executed in step S2 and the like will be described. FIG. 5 is a diagram showing an example of the bandwidth allocation operation, and shows an example of the bandwidth allocation operation for a network (denoted as ODN # k in FIG. 5) composed of the k-th RN and each ONU under the RN. ing. The operation in the case of targeting a network including an RN other than the k-th and an ONU under its control is the same as this.

  In the bandwidth allocation operation in the optical communication system of the present embodiment, first, as Step (A), the OLT calculates the bandwidth allocation amount for each logical link (indicated as LL in the figure), and allocates the bandwidth for each logical link. Inform the RN of the result. Note that the band allocation result is notified to the RN in the Gate frame (including the Discovery Gate frame) as described above.

As shown in the figure, the band allocation result is reported as a transmission start time (GST) for each logical link and a length of a period during which transmission is permitted (Grant Length, expressed as GL in the figure). FIG. 5 shows an example of calculating GST and GL (GL _k (LL)) of each logical link by setting GST (GST_LT _k (LL)) of the first logical link (LL = 1) to 0. . In addition, the GL is set to a value obtained by subtracting 10 from the interval (difference) between the GSTs so that transmission signals on the logical links do not collide. Note that the OLT does not need to consider the RTT between terminals connected to each logical link when determining the GST. The GST is corrected in the RN in consideration of the RTT between the RN and each of the ONUs under the RN. Therefore, when the OLT is in normal operation, the timing (time) at which the signal from each ONU arrives at its own device (OLT) Only need to be considered.

Next, as Step (B), the RN that has received the frame (Gate frame, Discovery Gate frame) including the band allocation result (GST and GL) from the OLT is calculated in advance, the local time, the RTT for each logical link, and so on. Based on the previously set reference time (RN_GST_base _k ), the information in the received frame (GST indicating the band allocation result) is corrected. For example, the reference time is uniformly added to the GST of each logical link, and further, the corrected GST is obtained by subtracting the corresponding RTT (RTT for each logical link) from each GST after the addition of the reference time. Note that GL is not changed.

For the bandwidth update period K, LL is the logical link ID, GST for each logical link calculated by the OLT is GST_LT _k (LL), the reference time is RN_GST_base _k , and the RTT for each logical link held by RN is RTT _k (LL ), GST _k (LL), which is an absolute GST (GST after correction), is given by the following equation. By performing such a calculation, it is possible to perform uplink communication control scheduled so that uplink bursts do not collide.
GST _k (LL) = GST_LT _k (LL) + RN_GST_base _k − RTT _k (LL)

  The RN transmits a Gate frame including each corrected GST generated by such a procedure and a GL for each logical link notified from the OLT to each ONU under its control.

  In the operation shown in FIG. 5, the OLT determines GST without considering the RTT between the RN and each ONU, and the RTT (RTT for each logical link) and local time between the RN and each ONU. However, the OLT may determine the GST in consideration of the RTT, and the RN may correct the GST in consideration of only the local time.

  FIG. 6 is a flowchart illustrating a procedure in which the RN updates (corrects) GST and updates the reference time of the band update cycle. FIG. 6A is a flowchart showing a procedure for GST correction value calculation and reference time update, and FIG. 6B is a flowchart showing a reference time update procedure. In the optical communication system according to the present embodiment, as shown in FIG. 6, when the GST correction value is calculated, the reference time is also updated. If necessary, the GST correction value calculation is also performed. An operation for updating the reference time without performing the operation is also performed.

As shown in FIG. 6A, in the GST correction operation, when RN # k (kth RN) receives Gate information (information inserted in a Gate frame and a Discovery Gate frame), It is confirmed whether or not the gate information is received for the first time. If it is received for the first time, the reference time (RN_GST_base _k ) is initialized. In this initialization operation, a predetermined offset value (OFFSET) is added to the value of the local timer (indicated as TS in FIG. 6) to obtain a reference time after initialization.

When the initialization of the reference time is completed, or when the received Gate information is not received for the first time after activation, each GST (GST for each logical link) included in the received Gate information is updated. In this update operation, first, the reference time RN_GST_base _k is added to each transmission start time GST_LT _k (LL) included in the received Gate information to calculate RN_GST _k (LL) for each logical link. Next, from the calculated RN_GST _k (LL), the corresponding RTT for each logical link (RTT _k (LL)) is subtracted, and the updated transmission start time GST _k (LL) and To do.

When all the transmission start times are updated, the reference time is updated. Specifically, the one with the largest value is selected from the transmission start times GST _k (LL) for each logical link calculated by the above-described transmission start time update operation, and set as a new reference time RN_GST_base _k . Each RN performs such GST update operation every time it receives Gate information.

Each RN updates the reference time according to the procedure shown in FIG. 6B in addition to the operation shown in FIG. That is, each RN monitors the local time (Local_Timer) and the reference time (RN_GST_base _k ) in a state where the Gate information has been received, and if it detects a state where the local time is equal to or greater than the reference time, A predetermined offset value (OFFSET) is added to the current time value TS to obtain the updated reference time. The offset value is determined based on the difference between the local time and the reference time. Specifically, the local time is set to a value smaller than the reference time.

  As described above, in the optical communication system according to the present embodiment, each RN calculates and holds an RTT indicating an individual transmission delay amount with each subordinate ONU, and the OLT is accommodated in each RN. When the calculation result of the uplink bandwidth to be assigned to the ONUs being notified is determined, the set value of the transmission start time (GST) is determined without considering the RTT between each RN. The GST setting value included in the received frame is updated based on the local time of the device itself and the retained RTT. That is, the RN controls to synchronize the local time of each subordinate ONU with its own local time, calculates the RTT with each subordinate ONU, and holds each calculated RTT. Each GST set in the received frame is updated based on the local time and the RTT. As a result, when the communication path higher than the RN is switched, the RTT held by the RN is not affected, so that the upstream burst control of the PON is facilitated and the communication is restored when the communication path is switched. The time required until this can be shortened compared to the conventional method.

  As described above, the optical communication system according to the present invention is suitable for an optical communication system having a configuration including a plurality of one-to-many connected networks and using upstream communication as time division multiplex communication.

1 OLT
2 ₁ , 2 ₂ , 2 _n ring nodes 3 ₁₁ , 3 _1p , 3 ₂₁ , 3 _2q , 3 _n1 , 3 _nr remote nodes (RN)
4 Optical coupler 5 ₁ 1G-ONU
5 ₁₀ 10G-ONU
5 ₁₀₁ 10G ・ 1G-ONU
11 Demultiplexer 12A, 12B OLT-IF
12-1,327 CPU
12-2, 326 Memory 12-3 Highly Integrated PON Control Unit 12-4, 321, 331 Optical Transceiver (Optical TRx)
12-5 Packet buffer memory 121 L2 bridge 122 PON control unit 123 Multiplexer (MUX)
124 Demultiplexer (DEMUX)
125,322,332 OTN mapper / demapper 126 SER / DES
13, 32 Monitoring control unit 13A, 32A Active system monitoring control unit 13B, 32B Standby system monitoring control unit 323 Management frame transmission / reception unit 324 TS adding unit 325 Time synchronization unit 14 ROADM unit 31,337 WDM coupler 33 Transponder unit 33A OTN transponder 33B ₁ , 33B _n Transponder 333 Upstream dual rate burst Clock Data Recovery (DB CDR)
334 Dual Rate Burst Optical Receiver (DOB Rx)
335 10Gbps Continuous Optical Transmitter (Continuous 10G-Tx)
336 1Gbps Continuous Optical Transmitter (Continuous 1G-Tx)
338 Local timer 339 Time stamp processing unit 340 RTT management unit

Claims (5)

A ring network is configured, signal light of a specific wavelength is extracted from the ring network and output to other nodes that do not configure the ring network, and signal light input from the other nodes is An optical communication system comprising a plurality of ring nodes that output to a ring network, a remote node that operates as the other node, and an ONU that is connected to the remote node via an optical coupler,
Some of the ring nodes operate as an OLT that executes a process of allocating an upstream band to the ONU;
The remote node has a function of measuring an RTT indicating a transmission delay time between each ONU connected to the remote node, and when receiving Gate information indicating an uplink bandwidth allocation result for each ONU, An optical communication system, wherein the Gate information is corrected based on its own local time and the measurement result of the RTT and then transferred to each ONU. The remote node is
GST is corrected so that uplink signals transmitted from each of the ONUs do not collide with each other including GST indicating transmission start time of each of the ONUs among the information included in the Gate information. The optical communication system according to claim 1. The remote node is
When measuring the RTT indicating the transmission delay time between each ONU accommodated and holding the measurement result, and receiving the gate information indicating the uplink band allocation result for each ONU, the Gate information Is corrected based on its own local time and the measurement result of the RTT and then transferred to each ONU,
The optical communication system according to claim 1, comprising one or more of the following. The transponder is
GST is corrected so that uplink signals transmitted from each of the ONUs do not collide with each other including GST indicating transmission start time of each of the ONUs among the information included in the Gate information. The optical communication system according to claim 3. The ring node operating as the OLT is
The gate information is generated without considering the transmission delay time between each ONU to which the uplink band is allocated after executing the process of allocating the uplink band. An optical communication system according to claim 1.

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