JP2017139643A - Optical access network system, station side device, and control program therefor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce the capacity of the buffer of an OLT used for switching the specification of an optical access network system, and to suppress deterioration of latency incident to the changeover time.SOLUTION: An optical access network system has multiple subscriber devices (ONU) requiring different changeover times, and a station side device (OLT) connected with the ONU via optical fibers, for changing over the operation specification. The OLT classifies the changeover times of operation specification of the ONU to changeover time classes of multiple stages, and controls the traffic addressed to the ONU, based on the classified changeover time classes. The ONU has first communicable state before changing over the operation specification, second communicable state after changing over the operation specification, and incommunicable state incident to changeover of the operation specification, and requires a changeover time continuing the incommunicable state for transition from the first communicable state to second communicable state.SELECTED DRAWING: Figure 2

Description

  The present invention relates to an optical access network system, a station side device, and a control program thereof.

  In recent years, with the spread of the Internet, there has been an increasing demand for speeding up communication in networks. In order to meet this demand for speeding up, PON (Passive Optical Network) has been spreading. One PON is connected to the OLT to connect between a station side device (OLT: Optical Line Terminal) installed in a station and a subscriber device (ONU: Optical Network Unit) installed in each user's home. The optical access network (hereinafter referred to as fiber) is branched into a plurality of optical fibers by an optical splitter, and each of the branched fibers is connected to each of a plurality of ONUs.

  When an optical access network system is constructed with such a PON, the fiber laying cost is low and high-speed communication is possible because broadband optical transmission is used. For this reason, PON is now spreading all over the world. Among the methods using PON, optical signals of different wavelengths are used for the optical transmission line for the downstream transmission from the OLT to the ONU and the optical transmission line for the upstream transmission from the ONU to the OLT. Time-division multiplexing (TDM) -PON is widely used. TDM-PON includes B-PON (Broadband PON), E-PON (Ethernet (registered trademark) PON), G-PON (Gigabit Capable PON), 10G-EPON, and XG-PON (10 Gigabit Capable PON). It has been adopted as a standard.

  As a candidate for the next-generation PON, there is a method using WDM (Wavelength Division Multiplexing) / TDM-PON in which conventional TDM-PONs are bundled at a plurality of wavelengths. This WDM / TDM-PON can realize larger capacity communication by using a plurality of wavelengths. In this WDM / TDM-PON, a method is known in which the ONU makes the wavelength used for transmission and reception variable.

  As a method of the next generation of WDM / TDM-PON, there is a method using OFDM (Orthogonal Frequency Division Multiplexing) -PON which bundles a plurality of subcarriers for communication. In this OFDM-PON, high frequency utilization efficiency can be realized by performing communication using a plurality of subcarriers. In this OFDM-PON, it is known that the allocation of subcarriers and the number of subcarriers used for communication are changed according to traffic conditions. Further, in this OFDM-PON, a more flexible optical access network system can be realized by changing various parameters such as wavelength, symbol rate, multi-level number, and number of subcarriers.

  In order to change the functions of optical access network systems and improve the use efficiency of optical frequencies (wavelengths), ONUs switch operation specifications such as switching the wavelength of optical signals to be used and changing circuits such as signal processing and error correction codes. Must be realized during operation of the optical access network system.

  Patent Document 1 discloses an OLT buffer configuration that distributes and processes traffic according to the state of wavelength switching. An ONU distribution unit that sends a packet addressed to a wavelength switching target ONU to a switching queue and a packet addressed to a non-switching target ONU to a through queue, and a scheduler unit that reads packets from the switching queue and the through queue are provided. According to the technique of Patent Document 1, it is possible to prevent frame loss due to switching and to reduce the number of switching queues that hold packets during switching processing from the number of accommodated ONUs.

Japanese Patent Application Laid-Open No. 2015-50623

  In Patent Document 1 corresponding to wavelength switching, the OLT includes switching queues (buffers) for the number of ONUs to be switched simultaneously. When simultaneously switching the wavelengths of many ONUs, the number of switching queues prepared by the OLT increases.

  On the other hand, when the OLT has a switching queue (buffer) shared by all ONUs that are switched at the same time, buffering is performed in the switching queue until the wavelength switching of the ONU having the longest wavelength switching time is completed. Under the influence of an ONU having a long wavelength switching time, latency deterioration due to wavelength switching occurs.

  The ONU circuit change is the same as the ONU wavelength switching in that the predetermined operation of the ONU is interrupted for a time corresponding to the circuit switching time.

  Therefore, it is necessary to reduce the capacity of the OLT buffer for switching the operation specifications such as the wavelength and circuit to be used in the optical access network system and to suppress the deterioration of the latency due to the switching time.

  The disclosed optical access network system is connected to a plurality of subscriber devices that require different switching times for switching operation specifications, and the subscriber devices are connected to the subscriber devices via optical fibers, and the switching times are classified into a plurality of switching time classes. And a station side device for controlling traffic addressed to the subscriber device based on the classified switching time class.

  According to the disclosed optical access network system, it is possible to reduce the capacity of the OLT buffer used for switching the operation specifications of the optical access network system and to suppress the deterioration of latency associated with the switching time.

It is a block diagram of an optical access network system. 1 is a configuration diagram of an OLT according to a first embodiment. FIG. 2 is a hardware configuration diagram of the OLT according to the first embodiment. 1 is a configuration diagram of an ONU according to Embodiment 1. FIG. 3 is a process flowchart of an OLT control unit according to the first embodiment. It is an example of the ONU switching time class management table of Example 1. FIG. 6 is a sequence diagram for collecting wavelength adjustment times according to the first embodiment. FIG. 3 is a wavelength switching sequence diagram of the first embodiment. FIG. 6 is a configuration diagram of an OLT according to a second embodiment. FIG. 6 is a configuration diagram of an ONU according to a second embodiment. FIG. 6 is a circuit rewrite sequence diagram according to the second embodiment. FIG. 6 is a configuration diagram of an OLT according to a third embodiment. 10 is a process flowchart of an OLT control unit according to the third embodiment. FIG. 10 is a wavelength switching sequence diagram of Example 3.

  In the present embodiment, an optical access network system having a plurality of subscriber units (ONUs) that require different switching times for switching operation specifications and a station side unit (OLT) connected to the ONUs via optical fibers will be described. To do. The OLT classifies ONU operation specification switching times into a plurality of switching time classes, and controls traffic addressed to the ONUs based on the classified switching time classes.

  The ONU has a first communicable state before switching of the operation specifications, a second communicable state after switching of the specifications, and a state incapable of communicating with the switching of the specifications. Switching from the communicable state to the second communicable state requires a switching time for continuing the incommunicable state.

  Hereinafter, an optical access network system that is the wavelength of an optical transceiver included in the ONU will be described as a first embodiment, and an optical access network system that is a specification of a logic circuit included in the ONU will be described as an embodiment. This will be described as 2. Further, as a third embodiment, a case of a WDM / TDM-PON system that switches wavelengths of ONUs having different wavelength switching times as an optical access network system will be described.

  In an optical network system that performs wavelength multiplexing using a plurality of OLTs, the optical frequency (wavelength) used in the OLT is changed when the symbol rate or the number of subcarriers is changed. By changing the wavelength of each OLT, a plurality of OLTs can efficiently use the optical frequency. In such a case, it is necessary to change the wavelength of the OLT and the wavelength of the ONU connected to the OLT. The optical access network system of this embodiment meets such a need.

(Optical access network)
FIG. 1 is a configuration diagram of an optical access network system (hereinafter referred to as an optical access network). The optical access network includes four OLTs 10 (10-A to 10-D), optical splitters 30 and 31, a plurality of ONUs 20 (20-A-1 to 20-Dn4), and a plurality of terminals 50 (50- A-1 to 50-Dn4). The OLT 10 is a station side device, and the ONU 20 is a subscriber device.

  The plurality of OLTs 10 are connected to the network 60. The network 60 may be the Internet or a network such as a LAN. The OLT 10 transmits a signal received from the network 60 to the ONU 20. Further, the OLT 10 transmits a signal received from the ONU 20 to the network 60.

  The plurality of OLTs 10 (10-1 to 10-4) are connected to the optical splitter 30. The optical splitter 30 is connected to the optical splitter 31 via the trunk optical fiber 40-0. The optical splitter 31 is connected to the ONU 20 (20-A-1 to 20-Dn4) via branch optical fibers 40 (40-A-1 to 40-Dn4). The terminals 50 (50-A-1 to 50-Dn4) are connected to the ONUs 20 (20-A-1 to 20-Dn4), respectively.

  Communication from the ONU 20 to the OLT 10 is called uplink communication, and the wavelength used for uplink communication is called uplink wavelength. Conversely, communication from the OLT 10 to the ONU 20 is called downlink communication, and the wavelength used for downlink communication is called downlink wavelength.

  A method for multiplexing the signals of the plurality of OLTs 10 will be described. The ONUs 20-A-1 to 20-An-n1 communicate with the OLT 10-1 using the downstream wavelength λAd and the upstream wavelength λAu. The ONUs 20-B-1 to 20-B-n1 communicate with the OLT 10-2 using the downstream wavelength λBd and the upstream wavelength λBu. The ONUs 20-C-1 to 20-Cn1 communicate with the OLT 10-3 using the downstream wavelength λCd and the upstream wavelength λCu. The ONUs 20-D-1 to 20-Dn1 communicate with the OLT 10-4 using the downstream wavelength λDd and the upstream wavelength λDu. The optical splitter 30 combines the signals received from the plurality of OLTs 10 and outputs them to the trunk fiber 40-0. Further, the optical splitter 30 demultiplexes the optical signal input from the trunk fiber 40-0 to the plurality of OLTs 10 and outputs the demultiplexed signals. Similarly, the optical splitter 31 demultiplexes and multiplexes.

  Thus, in the optical access network of this embodiment, the plurality of OLTs 10 communicate with the ONU 20 by wavelength multiplexing at different wavelengths. Further, the OLT 10 according to the present embodiment multiplexes downlink communication and uplink communication by using a wavelength having a different downlink wavelength and uplink wavelength.

  The downlink communication between the OLT 10 and the ONU 20 will be described. The optical signal passing through the trunk optical fiber 40-0 includes multiplexed optical signals of all wavelengths from the OLT 10 to the ONU 20. Therefore, the ONU 20 receives downstream optical signals of all those wavelengths.

  The ONU 20 receives the wavelength used by itself from the wavelength-multiplexed downstream optical signal. Furthermore, the ONU 20 determines whether it is a frame addressed to the own ONU 20 based on an LLID (logical link ID) that is an identifier in the frame received from the OLT 10, thereby automatically A frame addressed to the ONU 20 is specified. For example, the ONU 20-A-1 receives an optical signal including frames addressed to the ONU 20-A-1 to ONU 20-A-n1. Then, the ONU 20-A-1 transfers the frame addressed to the ONU 20-A-1 to the upper layer processing of the communication protocol based on the LLID, and discards the other frames. In this way, the OLT 10 and the plurality of ONUs 20 perform downlink communication.

  The uplink communication between the OLT 10 and the ONU 20 will be described. Each of the ONU 20-A-1 to ONU 20-A-n1 transmits a burst optical signal generated by itself during the period instructed by the OLT 10 using the same upstream wavelength λAu.

  In this way, by transmitting the burst optical signal during the period instructed to each ONU 20 (different period for each ONU 20), the upstream optical signals from the plurality of ONUs 20 are prevented from colliding. The OLT 10 receives burst optical signals from a plurality of ONUs 20 multiplexed in a time division manner. In this way, the OLT 10 and the plurality of ONUs 20 can perform upstream communication. A plurality of OLTs 10 and a plurality of ONUs 20 can communicate by sharing the same optical fiber 40.

(Functional configuration of OLT10)
FIG. 2 is a configuration diagram of the OLT 10 of the present embodiment. The OLT 10 includes an optical transceiver 110, a PON PHY / MAC (PON Physical / Media Access Control) processing unit 120, a multiplexer 130, a demultiplexer 140, an MPCP (Multi-Point Control Protocol) processing unit 150, a downlink traffic processing unit 160, an uplink A traffic processing unit 170 and an OLT control unit 180 are included. Here, a case where the ONU 20 transmits and receives an optical signal having the wavelength λA will be described.

  The optical transceiver 110 mutually converts an electric signal and an optical signal. The optical transceiver 110 receives the upstream optical signal having the upstream wavelength λAu input from the optical splitter 30 and converts the received upstream optical signal into a current signal. Further, the optical transceiver 110 converts and amplifies the converted current signal into a voltage signal, converts an analog electric signal into a digital signal, and outputs the digital signal to the PON PHY / MAC processing unit 120.

  Further, the optical transceiver 110 converts the electrical signal input from the PON PHY / MAC processing unit 120 into an optical signal in OFDM (Orthogonal Frequency-Division Multiplexing) -PON of the downstream wavelength λAd, and this conversion Is output to the optical splitter 30 as a downstream optical signal. As a result, the optical transceiver 110 converts the downstream traffic into a downstream optical signal having a downstream wavelength λAd, and transmits the downstream optical signal to the ONU 20.

  The optical transceiver 110 sets the parameters of the optical signal in the OFDM-PON in the optical transmitter and the optical receiver in the optical transceiver 110 according to the instruction from the OLT controller 180. These parameters can be changed in the OLT control unit 180.

  The optical signal parameters include wavelength, modulation scheme, symbol rate, number of subcarriers, sampling rate, and the like. The optical transceiver 120 can change the transmission capacity of the downstream optical signal and upstream optical signal by changing these parameters. The optical transceiver 110 can change the wavelength transmitted by the optical transmission unit by including, as the optical transmission unit, a device that uses a laser capable of adjusting the wavelength of the transmission optical signal. In addition, the optical transceiver 110 can change the wavelength received by the optical receiving unit by including, as the optical receiving unit, a device that uses an optical filter capable of adjusting the wavelength of the received optical signal.

(PON PHY / MAC processor 120)
The PON PHY / MAC processing unit 120 is a processing unit that executes processing of a PHY (Physical) layer and a MAC (Media Access Control) layer in a PON section. The PON PHY / MAC processing unit 120 assigns an LLID corresponding to the transmission destination to the preamble portion of the MAC frame for the downstream MAC frame input from the multiplexer processing unit 130, and then performs FEC (Forward Error Correction) encoding. Processing and encoding processing such as 64B66B are executed. Further, the PON PHY / MAC processing unit 120 converts the encoded signal from a parallel signal to a serial signal and outputs the converted signal to the optical transceiver 110.

  Further, the PON PHY / MAC processing unit 120 receives an upstream electrical signal digitally converted from the optical transceiver 110, converts the electrical signal as a serial signal into a parallel signal, and performs FEC decoding processing, decoding of 64B66B, and the like. Execute the conversion process. Further, the preamble part of the MAC frame output by decoding is analyzed, the LLID is removed, and the result is output to the demultiplexer 140.

(Multiplexer 130)
The multiplexer 130 multiplexes the MPCP control frame input from the MPCP processing unit 150 and the downlink user data frame input from the downlink traffic processing unit 160 and outputs the multiplexed data to the PON PHY / MAC processing unit 120.

(Demultiplexer 140)
The demultiplexer 140 receives the MAC frame from the PON PHY / MAC processing unit 120, analyzes the header information of the MAC frame, identifies the MPCP control frame and the uplink user data frame, and sends the MPCP control frame to the MPCP processing unit 150. And output the uplink user data frame to the uplink traffic processing unit 170.

(MPCP processing unit 150)
The MPCP processing unit 150 performs transmission and reception processing of the MPCP control frame exchanged between the OLT 10 and the ONU 20. The MPCP processing unit 150 issues a GATE frame that gives upstream transmission permission to the ONU 20, a Discovery GATE frame that gives transmission permission to the newly connected ONU 20, and a REGISTER frame that instructs the ONU 20 to register, and outputs it to the multiplexer. Further, the MPCP processing unit 150 receives from the demultiplexer 140 a REPORT frame in which the ONU 20 notifies the amount of uplink data, and a REGISTER_REQ frame in which the ONU 20 notifies a registration request.

(Downlink traffic processing unit 160)
The downlink traffic processing unit 160 receives a user data frame from the network 60, analyzes header information of the received user data frame, distributes the user data frame to a plurality of queues, and reads the user data frame from the plurality of queues And output to the multiplexer 130.

  The downlink traffic processing unit 160 includes a scheduler 1610, a class-by-class queue 1620, and a frame distribution processing unit 1630. The frame distribution processing unit 1630 analyzes the header information of the downstream user data frame received from the network 60, specifies the switching time class of the ONU 20 that is the destination of the user data frame, and sets a plurality of classes based on the specified class. The queue is assigned to the queue 1620. Here, the destination ONU 20 is specified from the destination address of the user data frame and the VLAN-ID of the assigned VLAN tag, and further, the switching time class (described later) corresponding to the destination ONU 20 is specified, and is set as the switching time class. The data is output to the corresponding queue 1620 for each class. The scheduler 1610 reads the user data frame from the per-class queue 1620 and outputs it to the multiplexer 140. In response to an instruction from the OLT control unit 180, the scheduler 1610 stops reading and resumes reading for each queue. According to this configuration, the OLT control unit 180 can control reading of each class queue in the downlink traffic processing unit 160 based on the timing of completion of wavelength switching of the downlink wavelength λAd.

(Configuration of queue for each class)
The sizes of the plurality of class-by-class queues 1620 provided in the OLT 10 may all be the same, or different sizes may be used depending on the classes. For example, the size of a queue having a long wavelength switching time may be increased, and the size of a queue having a short wavelength switching time may be decreased. By setting the queue size of each class according to the length of the wavelength switching time, the amount of memory provided in the OLT 10 can be reduced.

(Uplink traffic processing unit 170)
The upstream traffic processing unit 170 receives the upstream user data frame from the demultiplexer 140, temporarily stores it in the buffer, performs priority control and bandwidth control if necessary, and outputs the result to the network 60.

(OLT control unit 180)
The OLT control unit 180 monitors the operations of the downlink traffic processing unit 160, the MPCP processing unit 150, and the optical transceiver 110 in the OLT 10, and executes parameter setting change for these processing units. The OLT control unit 180 instructs the optical transceiver 110 to set a transmission wavelength and a reception wavelength. In addition, the OLT control unit 180 instructs the downlink traffic processing unit 160 to stop and resume reading of user data frames from each class queue. The OLT control unit 180 also instructs the MPCP processing unit 150 to transmit a control frame related to wavelength switching, and monitors the reception event of the wavelength switching control frame from the MPCP processing unit. Details of the operation of the OLT control unit 180 will be described later.

According to the configuration of the OLT 10 of the present embodiment, the OLT 10 can control downlink traffic in cooperation with wavelength switching control, and can control traffic for each class of switching time.
(OLT hardware configuration)
FIG. 3 is a hardware configuration diagram of the OLT 10. The OLT 10 includes an optical transceiver 110, a PON logic circuit 190, a CPU 191, and a memory 192. Each unit is connected to each other via a bus and can exchange control data with each other. The PON PHY / MAC processing unit 120, the multiplexer 130, the demultiplexer 140, the MPCP processing unit 150, the downlink traffic processing unit 160, and the uplink traffic processing unit 170 described in the functional configuration of the OLT 10 are ASIC (Application Specific Integrated Circuit) or ASIC. The OLT control unit 180 is realized by a CPU 191 and a memory 192. The OLT control unit 180 is realized by a logic circuit such as an FPGA (Field Programmable Gate Array).

(ONU20)
FIG. 4 is a configuration diagram of the ONU 20 of the present embodiment. The ONU 20 includes an optical transceiver 210, a PON PHY / MAC processing unit 220, a multiplexer 230, a demultiplexer 240, an MPCP processing unit 250, an upstream traffic processing unit 260, a downstream traffic processing unit 270, and an ONU control unit 280. Here, a case where the ONU 20 transmits and receives an optical signal having the wavelength λA will be described.

  The optical transceiver 210 converts electrical signals and optical signals to each other. The optical transceiver 210 receives the downstream optical signal having the downstream wavelength λAd input from the optical splitter 31, and converts the received downstream optical signal into a current signal. Further, the optical transceiver 210 converts and amplifies the converted current signal into a voltage signal, converts an analog electric signal into a digital signal, and outputs the digital signal to the PON PHY / MAC processing unit 220.

  Further, the optical transceiver 210 converts the electrical signal input from the PON PHY / MAC processing unit 220 into an optical signal in OFDM (Orthogonal Frequency Division-Division Multiplexing) -PON of the upstream wavelength λAu, and this conversion Is output to the optical splitter 31 as an upstream optical signal. As a result, the optical transceiver 210 converts the upstream traffic into an upstream optical signal having the upstream wavelength λAu, and transmits the upstream optical signal to the OLT 10.

  The optical transceiver 210 sets the parameters of the optical signal in OFDM-PON in the optical transmitter and the optical receiver in the optical transceiver 210 according to the instruction from the ONU controller 280. These parameters can be changed in the ONU control unit 280 based on an instruction from the OLT control unit 180.

  The optical signal parameters include wavelength, modulation scheme, symbol rate, number of subcarriers, sampling rate, and the like. The optical transceiver 210 can change the wavelength transmitted by the optical transmission unit by including, as the optical transmission unit, a device that uses a laser capable of adjusting the wavelength of the transmission optical signal. Further, the optical transceiver 210 can change the wavelength received by the optical receiving unit by including, as the optical receiving unit, a device that uses an optical filter capable of adjusting the wavelength of the received optical signal.

(PON PHY / MAC processor 220)
The PON PHY / MAC processing unit 220 is a processing unit that executes processing of the PHY layer and the MAC layer in the PON section. The PON PHY / MAC processing unit 220 adds an LLID corresponding to the transmission destination to the preamble portion of the MAC frame for the uplink MAC frame input from the multiplexer processing unit 230, and then performs FEC encoding processing, 64B66B, etc. Perform the encoding process. Further, the PON PHY / MAC processing unit 220 converts the encoded signal from a parallel signal to a serial signal and outputs the converted signal to the optical transceiver 210.

  Further, the PON PHY / MAC processing unit 220 receives a downstream electrical signal that has been digitally converted from the optical transceiver 210, converts the electrical signal as a serial signal into a parallel signal, and performs FEC decoding processing or decoding such as 64B66B. Execute the conversion process. Further, the preamble part of the MAC frame output by decoding is analyzed, the LLID is removed, and the result is output to the demultiplexer 240.

(Multiplexer 230)
The multiplexer 230 multiplexes the MPCP control frame input from the MPCP processing unit 250 and the uplink user data frame input from the uplink traffic processing unit 260 and outputs the multiplexed data to the PON PHY / MAC processing unit 220.

(Demultiplexer 240)
The demultiplexer 240 receives the MAC frame from the PON PHY / MAC processing unit 220, analyzes the header information of the MAC frame, identifies the MPCP control frame and the downlink user data frame, and sends the MPCP control frame to the MPCP processing unit 250. The downlink user data frame is output to the downlink traffic processing unit 270.

(MPCP processor 250)
The MPCP processing unit 250 performs processing for transmitting and receiving MPCP control frames exchanged between the OLT 10 and the ONU 20. In the MPCP processing unit 250, the REPORT frame in which the ONU 20 notifies the uplink data amount and the REGISTER_REQ frame in which the ONU 20 notifies the registration request are issued and output to the multiplexer 230. Further, the MPCP processing unit 250 receives from the demultiplexer 240 a GATE frame that gives upstream transmission permission to the ONU 20, a Discovery GATE frame that gives transmission permission to the newly connected ONU 20, and a REGISTER frame that instructs the ONU 20 to register. .

(Uplink traffic processing unit 260)
The upstream traffic processing unit 260 receives the user data frame from the terminal 50, temporarily stores it in the buffer, performs priority control if necessary, and outputs it to the multiplexer 230.

(Downlink traffic processing unit 270)
The downlink traffic processing unit 270 receives the downlink user data frame from the demultiplexer 240, temporarily stores it in the buffer, performs priority control and bandwidth control, and outputs it to the terminal 50.

(ONU control unit 280)
The ONU control unit 280 monitors the operations of the upstream traffic processing unit 260, the MPCP processing unit 250, and the optical transceiver 210 in the ONU 20, and executes parameter setting change for these processing units. The ONU control unit 280 instructs the optical transceiver 210 to set a transmission wavelength and a reception wavelength. Further, the ONU control unit 280 instructs the MPCP processing unit 250 to transmit a control frame related to wavelength switching, and monitors the reception event of the wavelength switching control frame from the MPCP processing unit 250.

  According to the configuration of the ONU 20 of this embodiment, the ONU 20 receives a control frame instructing wavelength switching from the OLT 10, changes the wavelength of the optical transceiver 210 included in the ONU 20, and controls the control frame at the changed wavelength. Can be transmitted to the OLT 10.

(Processing of OLT control unit 180)
FIG. 5 is a process flowchart of the OLT control unit 180 of the present embodiment.

  The OLT control unit 180 starts executing the process in response to the detection of the wavelength switching trigger (S101). The trigger for wavelength switching is an instruction from an operation terminal (not shown) connected to the OLT 10 directly or via a network (network 60 or other network) and / or detection of a change in traffic volume in the OLT 10. .

  The OLT control unit 180 sends a wavelength switching request to all ONUs 20 registered in the OLT 10 (hereinafter, all ONUs 20 mean all ONUs 20 to be switched registered in the OLT 10). The control frame to be represented is transmitted via the MPCP processing unit 150 (S102). In addition, a GATE frame indicating upstream transmission permission may be transmitted together with transmission of a control frame indicating a wavelength switching request. By transmitting the GATE frame, the ONU 20 can quickly transmit a response to the wavelength switching request.

  The OLT control unit 180 waits for reception of a wavelength switching request response from the ONU 20 that has transmitted the wavelength switching request (S103). If wavelength switching request responses are received from all ONUs 20 within a preset time (timeout time), the process proceeds to S104. If the wavelength switching request response has not been received from all the ONUs 20 within the timeout period, the OLT control unit 180 proceeds to S118. The OLT control unit 180 issues an alarm message indicating that the wavelength switching request response has not been received (S118). This alarm message is transmitted to the operation terminal connected to the OLT 10 and displayed on the operation terminal.

  The OLT control unit 180 analyzes the wavelength switching request response message received from the ONU 20 that transmitted the wavelength switching request, and confirms ACK / NACK in the message (S104). The OLT control unit 180 proceeds to S105 when ACK is confirmed in messages from all ONUs 20, and the OLT 10 interrupts wavelength switching processing when NACK is confirmed in messages from at least one ONU 20. To S117. The OLT control unit 180 issues an event occurrence message indicating that switching has been rejected from the ONU (S117). This message is transmitted to, for example, an operation terminal connected to the OLT 10 and displayed on the operation terminal.

  The OLT control unit 180 transmits a wavelength switching instruction message to all the ONUs 20 subject to wavelength switching (S105). The wavelength switching instruction message includes the changed transmission wavelength and reception wavelength information, and the wavelength switching time. The wavelength switching instruction message may be transmitted by unicast for each ONU 20, or may be transmitted to all ONUs by broadcast.

  The OLT control unit 180 controls the scheduler 1610 of the downlink traffic processing unit 160 to stop reading the downlink user data frame from the per-class queue 1620 (S106). As a result, the downlink traffic processing unit 160 stops outputting the downlink user data frame, and accumulates the downlink user data frame in the class-by-class queue 1620.

  The OLT control unit 180 issues a wavelength switching instruction to the optical transceiver 110 in the OLT 10 (S107). The wavelength switching instruction includes information on the transmission wavelength and reception wavelength after the change, and the wavelength switching time. The optical transceiver 110 that has received the wavelength switching instruction changes the transmission wavelength and the reception wavelength in accordance with the instruction.

  The OLT control unit 180 waits for a predetermined time to receive the notification of switching completion from the wavelength switching target ONU 20, and determines whether or not to receive the notification of switching completion within the predetermined time (S108). The OLT control unit 180 proceeds to S109 when the switch completion notification is received from the wavelength switching target ONU 20, and proceeds to S114 when the switch completion notification is not received within the predetermined time. The OLT control unit 180 measures the elapsed time from the time when the wavelength switching instruction is transmitted to the ONU 20, and determines the magnitude of the elapsed time and a preset threshold (S114). The threshold value is a time-out period for confirming reception of switching completion notifications from all of the wavelength-switching target ONUs 20, and is not a time-out period for individual ONUs 20. The OLT control unit 180 returns to S108 when elapsed time ≦ threshold, and proceeds to S115 when elapsed time> threshold. The OLT control unit 180 forcibly transitions the ONU 20 whose status is being switched in the ONU switching time class management table (described later) to the deregistered state (S115), and proceeds to S116. The OLT control unit 180 issues an alarm indicating that a switching process timeout has occurred (S116), and ends the process. This alarm is transmitted to the operation terminal connected to the OLT 10 and displayed on the operation terminal.

  The OLT control unit 180 identifies the ONU-ID included in the switching completion notification of the ONU 20 that has received the switching completion notification, and changes the status of the corresponding ONU-ID to switching completion in the ONU switching time class management table (S109). ).

  The OLT control unit 180 refers to the ONU switching time class management table and identifies the class (#x) to which the ONU 20 having the identified ONU-ID belongs (S110).

  The OLT control unit 180 acquires the statuses of all ONUs 20 belonging to the identified class #x from the ONU switching time class management table, and determines whether the statuses of all corresponding ONUs 20 have been switched ( S111). The OLT control unit 180 proceeds to S112 when the switching is completed, and returns to S108 when the switching is not completed.

  The OLT control unit 180 instructs the downlink traffic processing unit 160 to resume reading from the queue corresponding to the identified class #x (S112). Upon receiving the instruction, the downlink traffic processing unit 160 controls the scheduler 1610 to resume reading of the user data frame from the queue corresponding to the class #x, and the user data frame stored in the class #x is transmitted to the optical transceiver. 110 is transmitted.

  The OLT control unit 180 refers to the ONU switching time class management table to check the registered status of the ONU 20, and determines whether the status of all the ONUs 20 has been switched (S113). The OLT control unit 180 ends the process when the switching is completed, and returns to S108 when the switching is not completed.

  As described above, the OLT control unit 180 can execute transmission restart processing for traffic accumulated for each switching time class.

(ONU switching time class management table)
FIG. 6 is an example of an ONU switching time class management table provided in the OLT control unit 180. The ONU switching time class management table includes an ONU-ID indicating an ONU 20 identifier, a status indicating the ONU switching state, a wavelength adjustment time required for wavelength adjustment of an ONU optical transceiver, an ONU-OLT round trip time, and an ONU Has a class number to which. An entry is added to the ONU switching time class management table when an ONU 20 is newly registered. The wavelength adjustment time and the round trip value are notified from the ONU 20 to the OLT 10 at the time of initial registration of the ONU 20, and the OLT 10 adds the notified value to the ONU switching time class management table.

  The ONU-ID may be any value as long as the ONU 20 connected to the OLT 10 can be identified. For example, the VLAN ID assigned to the ONU 20 may be used, or the serial number (unique device number) of the ONU 20 may be used.

  The status represents the switching state of the ONU 20, and a value representing “registration (switching completed)”, “switching”, or “registration release state” is input.

  The class number is a number representing a class corresponding to the switching time range including the calculated switching time by setting the switching time range in each class in advance, calculating the switching time from the wavelength adjustment time and the round trip time of the ONU 20. It is.

(ONU wavelength adjustment time collection sequence)
FIG. 7 is a sequence diagram in which the OLT 10 collects the wavelength adjustment time of the ONU 20. The OLT 10 transmits a Discovery GATE frame, which is a kind of control frame, to the ONU 20. This control frame is broadcast to all ONUs 20 connected to the OLT 10.

  When the ONU 20 receives the Discovery GATE frame, the ONU 20 does not respond to this control frame if it has already been registered in the OLT 10, and responds to this control frame if it has not been registered. In the example of FIG. 7, the ONU 20 responds because it is immediately after startup and is not registered in the OLT 10. The ONU 20 transmits a REGISTER_REQ frame that is a response frame to the Discovery GATE frame. When transmitting this response frame, the ONU 20 transmits the wavelength adjustment time of the optical transceiver 210 in the ONU 20 while storing the wavelength adjustment time in a predetermined field in the response frame. The ONU 20 stores the wavelength adjustment time DS_Tuning_Time of the downlink reception unit and the wavelength adjustment time US_Tuning_Time of the uplink transmission unit of the optical transceiver 210 of the ONU 20 in predetermined fields in the response frame and transmits them.

  The OLT 10 transmits a REGISTER frame and a GATE frame, which are a type of control frame, to the ONU 20 to be registered that has received the REGISTER_REQ frame. When receiving the REGISTER frame, the ONU 20 issues REGISTER_ACK as a response, and transmits REGISTER_ACK to the OLT 10 within the transmission permission period specified by the received GATE frame. When the OLT 10 receives REGISTER_ACK, the OLT 10 adds an entry to the ONU switching time class management table and sets the wavelength adjustment time in association with the ONU-ID. The wavelength adjustment time to be set is the upstream and downstream wavelength adjustment times.

  With the above ONU wavelength adjustment time collection sequence, the OLT 10 can collect the wavelength adjustment time of the ONU 20 when registering the ONU 20, and the ONU switching time class management table in which the collected wavelength adjustment time of the ONU 20 is associated with the ONU-ID. Can be built.

(Wavelength switching sequence)
FIG. 8 is a wavelength switching sequence diagram according to this embodiment. Here, in order to make the explanation easy to understand, it is assumed that an event causing an alarm does not occur in the switching request or the switching instruction. Further, it is assumed that the wavelength switching time increases in the order of ONU1, ONU2, ONU3, and ONU4, and ONU1 and ONU2 belong to class 1, and ONU3 and ONU4 belong to class 2.

  The OLT 10 collects the wavelength adjustment time of the optical transceiver 210 of the ONU 20 according to the above-described ONU wavelength adjustment time collection sequence when the ONU 20 is registered. The wavelength switching time is calculated from the wavelength adjustment time and the round trip time.

  When an instruction to change the wavelength used by the OLT 10 and the ONU 20 connected to the OLT 10 is received from an operation terminal (OpS in the figure), the OLT control unit 180 executes the above-described processing (FIG. 5).

  The OLT 10 transmits a control frame including a wavelength switching request message and a GATE frame indicating upstream transmission permission to all ONUs 20 to be switched. Thereafter, the OLT 10 receives the wavelength switching request response from the ONU 20. Here, the wavelength switching request response is an ACK response.

  The OLT 10 transmits a wavelength switching instruction message to all the ONUs 20 to be switched. Here, it transmits by broadcast.

  The OLT 10 controls the scheduler 1610 to stop reading user data frames from the queue 1620 for each class, and stops transmission of user data frames from the OLT 10. Thereafter, the wavelength of the optical transceiver 110 of the OLT 10 is switched. The OLT 10 accumulates traffic (user data frames) received from the network 60 during wavelength switching in the class-by-class queue 1620.

  The ONU 20 receives the wavelength switching instruction message from the OLT 10 and executes wavelength switching at the wavelength switching time specified by the received message. The ONU1 to ONU4 complete the wavelength switching after the respective wavelength adjustment times have elapsed.

  The OLT 10 transmits a GATE frame indicating upstream transmission permission to the ONU 20 that has performed wavelength switching. The transmission of the GATE frame may be periodically transmitted after the wavelength switching of the optical transceiver of the OLT 10 is completed, or the GATE frame may be transmitted after the wavelength switching is completed based on the wavelength adjustment time of the ONU 20.

  When the ONU 20 receives the GATE frame after the wavelength switching is completed, the ONU 20 transmits a switching completion notification message to the OLT 10 during the transmission permission period. Here, since wavelength switching is completed in the order of ONU1, ONU2, ONU3, and ONU4, a switching completion notification message is also transmitted in the order of ONU1, ONU2, ONU3, and ONU4. When the OLT 10 receives the wavelength switching completion notification message from the ONU 1 and ONU 2, the wavelength switching has been completed for all of the ONUs 20 (ONU 1 and ONU 2) belonging to the class 1, and therefore the OLT 10 controls the scheduler 1610 to remove from the class 1 queue. Resume reading of user data frame. When reading is resumed from the class 1 queue, the user data frame addressed to the ONU 1 and the user data frame addressed to the ONU 2 stored in the class 1 queue are transmitted. Thereafter, the OLT 10 also receives the wavelength switching completion notification message from the ONU 3 and ONU 4, and the wavelength switching has been completed for all of the ONUs 20 (ONU 3 and ONU 4) belonging to the class 2. Therefore, the OLT 10 controls the scheduler 1610 for the class 2 Resume reading of user data frames from the queue. When the OLT 10 resumes reading the user data frame from the class 2 queue, the user data frame addressed to the ONU 3 and the ONU 4 stored in the class 2 queue is transmitted.

  According to this wavelength switching sequence, in the wavelength switching of the ONU 20 having a different wavelength adjustment time, it is possible to resume transmission of downlink traffic (downlink user data frame) accumulated for each switching time class when switching is completed.

(Association of OLT-ONU)
In the wavelength switching according to the present embodiment, it has been described as to which OLT 10 each ONU 20 belongs (connected), but is not limited thereto. For example, when there are a plurality of OLTs # 1 and # 2, the connection combination of the OLT 10 and the ONU 20 may be determined so as to reduce the types of ONU switching time classes accommodated in each OLT. For example, in the target optical access network, when each of a plurality of ONUs 20 belongs to either switching time class 1 or switching time class 2, OLT # 1 connects ONUs 20 belonging to switching time class 1. In OLT # 2, if ONU 20 belonging to switching time class 2 is connected, each switching time class queue accommodated in each of OLT # 1 and OLT # 2 only needs one type, and the amount of memory required in OLT 10 is reduced. It is possible.

(Classification method of switching time class)
In the classification of the switching time class according to the present embodiment, the range of the switching time in each class is set in advance, but is not limited to this. For example, when the switching time of the ONU 20 is distributed in a narrow range, the range in each switching time class can be narrowed to realize wavelength switching with finer granularity, and the latency caused by switching the wavelengths of a plurality of ONUs 20 It is possible to suppress deterioration.

(Effects of Example 1)
According to the present embodiment, when the wavelength of the ONU 20 is switched in the optical access network in which the ONUs 20 having different switching times are mixed, it is possible to suppress the deterioration of the latency due to the switching. Further, the number of queues provided in the OLT 10 may be the number corresponding to the switching time class, and the capacity of the buffer provided in the OLT 10 can be reduced. Further, since the number of queues may be equal to the switching time class, it is possible to reduce the distribution of frames and the scale of the logic circuit of the scheduler.

  In addition to wavelength switching, other operation specifications, for example, circuit specifications such as signal processing and error correction codes, are changed in order to change functions and improve performance of the optical access network. Changing the circuit specification can be realized by rewriting the logic circuits of the OLT and ONU. In general, the method of rewriting a logic circuit while maintaining a service is to maintain the current logic circuit on one side of the FPGA, write the new logic circuit on the other side, and then switch to the new logic circuit with a switch. When this method is used, the time required for switching to the new logic circuit is short. On the other hand, in the one-side switching method in which the received frame is temporarily stored in the buffer, rewritten to a new logic circuit, and the buffer is released after switching, the switching time is longer by the circuit rewriting time.

  In the first embodiment, wavelength switching in the optical access network has been described. In this embodiment, a case will be described in which circuit specifications such as an error correction code, a signal processing method, and a MAC protocol are switched instead of a wavelength. The ONU logic circuit is assumed to be implemented by an FPGA, and changes such as error correction codes are realized by rewriting circuit data written to the FPGA. The time required for circuit switching (switching of circuit specifications) varies depending on the type of FPGA device mounted on the ONU and the circuit switching method. Hereinafter, the present embodiment will be described focusing on differences from the first embodiment.

(Configuration of OLT 11)
FIG. 9 is a configuration diagram of the OLT 11 of the present embodiment. The OLT 11 includes an optical transceiver 110, a PON PHY / MAC processing unit 121, a multiplexer 130, a demultiplexer 140, an MPCP processing unit 150, a downstream traffic processing unit 160, an upstream traffic processing unit 170, an OLT control unit 181, and an FPGA circuit data file. A storage unit 193 is included. Compared with the OLT 10 of the first embodiment, the main differences of the OLT 11 of the present embodiment are (1) the logic circuit of the PON PHY / MAC processing unit 121 is configured by FPGA, and (2) the FPGA circuit data file. The storage unit 193 is provided, and (3) the OLT control unit 181 rewrites a part of the circuit of the PON PHY / MAC processing unit 121 instead of changing the wavelength of the optical transceiver 110.

  The PON PHY / MAC processing unit 121, the multiplexer 130, the demultiplexer 140, the MPCP processing unit 150, the downlink traffic processing unit 160, and the uplink traffic processing unit 170 according to the present embodiment are partially and dynamically configured. It consists of a rewritable FPGA. Here, rewriting of the circuit of the PON PHY / MAC processing unit 121 will be described.

  The FPGA circuit data file storage unit 193 stores a plurality of data files for circuit rewriting of the FPGA of the OLT 11. When the OLT circuit is rewritten, the OLT control unit 181 accesses a data file and executes circuit rewriting of the FPGA in the OLT 10 using the data file.

  Similar to the first embodiment, the downlink traffic processing unit 160 distributes user data frames to the class-by-class queue 1620 and processes them based on the switching time corresponding to the destination ONU 20 of the downlink user data frames received from the network 60. As the switching time, the wavelength adjustment time is used in the first embodiment, but the circuit rewriting time is used in this embodiment.

  According to the OLT 11 according to the present embodiment, a part of the logic circuit of the PON PHY / MAC processing unit 121 of the OLT 11 can be rewritten, and the frame is allocated based on the circuit rewrite time, and the circuit rewrite time for each class. It is possible to control traffic.

(Configuration of ONU20)
FIG. 10 is a configuration diagram of the ONU 21 of the present embodiment. The ONU 21 includes an optical transceiver 210, a PON PHY / MAC processing unit 221, a multiplexer 230, a demultiplexer 240, an MPCP processing unit 250, an upstream traffic processing unit 260, a downstream traffic processing unit 270, an ONU control unit 281 and an FPGA circuit data file. A storage unit 290 is included. Compared with the ONU 20 of the first embodiment, the main difference of the ONU 21 of the present embodiment is that (1) the FPGA circuit data file storage unit 290 is provided, and (2) the PON PHY / MAC processing unit 221 is a circuit. Is realized by an rewritable FPGA.

  The FPGA circuit data file storage unit 290 stores the FPGA circuit data file transmitted from the OLT 11. The FPGA circuit data file may rewrite the entire FPGA circuit or may rewrite a part of the FPGA circuit. For example, only the FEC decoder circuit for the PCS (Physical Coding Sublayer) processing of the ONU 21 may be rewritten.

  The MPCP processing unit 250 transmits and receives control frames between the OLT and the ONU. The MPCP processing unit 250 downloads the FPGA circuit data file from the OLT 11. Also, a control frame representing an FPGA circuit data rewrite instruction from the OLT 11 is received.

  The ONU control unit 281 stores the FPGA circuit data file received via the MPCP processing unit 250 in the FPGA circuit data file storage unit 290. Also, when receiving the control frame indicating the circuit data rewrite instruction via the MPCP processing unit 250, the circuit data file is read from the FPGA circuit data file storage unit 290 and written into a specific area of the target FPGA. .

  According to the configuration of the ONU 21 according to the present embodiment, the FPGA circuit data file from the OLT 11 can be downloaded, and the FPGA circuit data is rewritten in accordance with the instruction from the OLT 11, and the switching completion notification is sent to the OLT 11 after the circuit switching is completed. You can send a message.

(Processing of OLT control unit 181)
The OLT control unit 181 of the present embodiment operates in substantially the same manner as the OLT control unit 180 of the first embodiment. The wavelength adjustment processing according to the first embodiment can be realized by replacing it with a circuit rewriting processing in this embodiment. For example, the wavelength switching trigger is replaced with a circuit switching trigger. Also, wavelength switching of the optical transceiver 110 of the OLT 10 of the first embodiment is replaced with circuit rewriting of the PHY / MAC processing unit 221 of the OLT 11 of the present embodiment.

(ONU switching time class management table)
In this embodiment, instead of the wavelength adjustment time of each ONU 20 of Embodiment 1, the circuit rewriting time of each ONU 21 is provided, and the switching time class is specified based on the circuit rewriting time and the round trip time.

(Circuit rewriting sequence)
FIG. 11 is a circuit rewrite sequence diagram according to this embodiment. Here, in order to make the explanation easy to understand, it is assumed that an event causing an alarm does not occur in the switching request or the switching instruction. Further, it is assumed that the circuit rewriting time increases in the order of ONU1, ONU2, ONU3, and ONU4, and ONU1 and ONU2 belong to class 1, and ONU3 and ONU4 belong to class 2.

  The OLT 11 collects the rewrite time of the FPGA circuit included in the ONU 21 when the ONU 21 is registered. The method for collecting the rewrite time of the FPGA circuit is the same as the method for collecting the wavelength adjustment time described in the first embodiment.

  The OLT 11 receives an instruction to change the OLT 11 and the ONU 21 circuit registered in the OLT 11 from an operation terminal (OpS in the figure). For example, the instruction to change the circuit changes the FEC encoder circuit of the PHY transmitting unit included in the PON PHY / MAC processing unit 121 of the OLT 11 and the FEC decoder circuit of the PHY receiving unit included in the PON PHY / MAC processing unit 221 of the ONU 21. It is an instruction to do. Upon receiving this instruction, the OLT control unit 181 executes the above-described processing.

  The OLT 11 transmits a control frame storing a circuit switching request message including a file name for specifying a circuit to be changed and a circuit data file after switching to all ONUs 21 to be switched, and a GATE frame indicating upstream transmission permission. To do. Thereafter, the OLT 11 receives a circuit switching request response from the ONU 21. Here, the circuit switching request response is an ACK response.

  Following the circuit switching request response, the ONU 21 requests the OLT 11 to download the circuit data file specified in the circuit switching request message. However, when the circuit data file specified in the circuit switching request message is stored in the FPGA circuit data file storage unit 290, the ONU 21 does not need to request download. When the OLT 11 receives an ACK for the circuit switching request from all the ONUs 21 to be switched, the OLT 11 transmits a circuit data file to each ONU 21 that has requested download.

  The OLT 11 transmits a circuit switching instruction message to all ONUs 21 to be switched. Here, it transmits by broadcast.

  The OLT 11 controls the scheduler 1610 to stop reading the user data frame from the queue 1620 for each class, and stops the transmission of the downlink user data frame from the OLT 11. Thereafter, the circuit of the PHY / MAC processing unit 121 of the OLT 11 is rewritten. Further, the OLT 11 accumulates the downlink traffic received during circuit switching (during rewriting) in the class-by-class queue 1620.

  The ONU 21 receives the circuit switching instruction message from the OLT 11 and executes circuit switching at the circuit switching time specified by the received message. ONU1 to ONU4 complete the circuit switching after the circuit rewriting time has elapsed.

  The OLT 11 transmits a GATE frame indicating upstream transmission permission to the ONU 21 that has performed circuit switching. The transmission of the GATE frame may be periodically transmitted after the circuit switching of the PHY / MAC processing unit 121 of the OLT 11 is completed, or the GATE frame may be transmitted after the circuit switching is completed based on the circuit rewriting time of the ONU 21. .

  When the ONU 21 receives the GATE frame after the circuit switching is completed, the ONU 21 transmits a switching completion notification message to the OLT 21 during the transmission permission period. Here, since circuit switching is completed in the order of ONU1, ONU2, ONU3, and ONU4, a switching completion notification message is also transmitted in the order of ONU1, ONU2, ONU3, and ONU4. When the OLT 11 receives the circuit switching completion notification message from the ONU 1 and ONU 2, the circuit switching has been completed for all of the ONUs 21 belonging to the class 1, so the scheduler 1610 is controlled to update the user data frame from the class 1 queue. Resume reading. When reading is resumed from the class 1 queue, the user data frame addressed to the ONU 1 and the user data frame addressed to the ONU 2 stored in the class 1 queue are transmitted. After that, the OLT 11 also receives the circuit switching completion notification message from the ONU 3 and ONU 4, and since the circuit switching has been completed for all of the ONUs 21 belonging to the class 2, the OLT 11 controls the scheduler 1610 to control the user from the class 2 queue. Resume data frame reading. When the OLT 11 resumes reading the user data frame from the class 2 queue, the user data frame addressed to the ONU 3 and ONU 4 stored in the class 2 queue is transmitted.

  According to this circuit switching sequence, when the circuit of the ONU 21 having a different circuit rewriting time is switched, transmission of downlink traffic (downlink user data frame) accumulated for each switching time class can be resumed when switching is completed.

  According to the present embodiment, even when the circuit specifications of the ONU 21 are switched in the optical access network in which the ONUs 21 having different circuit specification switching times are mixed, it is possible to suppress the deterioration of the latency due to the switching. Further, the number of queues provided in the OLT 11 may be the same as the switching time class, and the capacity of the buffer provided in the OLT 1 can be reduced.

  In the first embodiment, the wavelength switching of the OLT 12 and all the ONUs 20 connected to the OLT 12 has been described. In the third embodiment, a case will be described in which the wavelength of the ONU 20 is switched in a WDM / TDM-PON system in which the wavelength of the OLT 12 is fixed. Here, the OLT 12 can transmit and receive an optical signal obtained by multiplexing four types of wavelengths λ1 to λ4, and the ONU 20 can select one from four types of wavelengths of the optical signal to be transmitted and received. In the present embodiment, the wavelengths of all the ONUs 20 are not necessarily changed, and the wavelengths of a plurality of ONUs are switched. In the following, differences from the first embodiment will be mainly described.

(OLT12)
FIG. 12 is a configuration diagram of the OLT 12 of the present embodiment. The OLT 12 includes OSUs # 1 to # 4, an OLT control unit 15, a switching processing unit 16, an SNI downlink traffic processing unit 17, and an SNI uplink traffic processing unit 18. OSUs # 1 to # 4 each include an optical transceiver 110, a PON PHY / MAC processing unit 120, a multiplexer 130, a demultiplexer 140, an MPCP processing unit 150, a downlink traffic processing unit 1601, and an uplink traffic processing unit 1701. The SNI downstream traffic processing unit 17 includes a frame distribution processing unit 173, a normal queue and a class-by-class queue 172, and a scheduler 171.

  The optical transceiver 110 mutually converts an electric signal and an optical signal. The optical transceiver 110 receives the upstream optical signal having the upstream wavelength λAu input from the optical splitter 30 and converts the received upstream optical signal into a current signal. Further, the optical transceiver 110 converts and amplifies the converted current signal into a voltage signal, converts an analog electric signal into a digital signal, and outputs the digital signal to the PON PHY / MAC processing unit 120.

  The optical transceiver 110 converts the electrical signal input from the PON PHY / MAC processing unit 120 into an optical signal having a downstream wavelength λAd, and outputs the optical signal generated by this conversion to the optical splitter 30 as a downstream optical signal. As a result, the optical transceiver 110 converts the downstream traffic into a downstream optical signal having a downstream wavelength λAd, and transmits the downstream optical signal to the ONU 20. In this embodiment, since the wavelength of the OLT 12 is fixed, the optical transceiver 110 does not need to change the wavelength according to the instruction from the OLT control unit 15.

  The PON PHY / MAC processing unit 120, the multiplexer 130, the demultiplexer 140, and the MPCP processing unit 150 are the same as those in the first embodiment.

  Unlike the first embodiment, the downlink traffic processing unit 1601 and the uplink traffic processing unit 1701 of each OSU do not accumulate traffic during wavelength switching of the ONU 20.

  The switching processing unit 16 performs switching between the four OSUs # 1 to # 4 and the SNI processing units (the SNI downstream traffic processing unit 17 and the SNI upstream traffic processing unit 18). When a user data frame is input from the SNI downstream traffic processing unit 17 to the switching processing unit 16, the user data frame is transferred to any or all of the OSUs # 1 to # 4 based on the destination. The switching processing unit 16 may perform switching based on the MAC address of the user data frame, or may perform switching based on the VLAN-ID of the VLAN tag attached to the user data frame. The user data frame input from each OSU to the switching processing unit 16 is transferred to the SNI upstream traffic processing unit 18.

  Similar to the downlink traffic processing unit 160 of the first embodiment, the SNI downlink traffic processing unit 17 includes a frame distribution unit 173, a queue 172, and a scheduler 171. The OLT 12 of this embodiment stores the traffic during the wavelength switching of the ONU 20 in the SNI downstream traffic processing unit 17 without storing the traffic in each OSU. This is because the OSU with which the ONU 20 communicates differs before and after the wavelength switching of the ONU 20. For example, when each of the OSUs # 1 to # 4 uses the wavelengths λ1 to λ4 and changes the wavelength of the ONU 20 from λ1 to λ2, the ONU 20 communicates with the OSU # 1 before the wavelength switching, and the wavelength switching After that, it communicates with OSU # 2. In addition, the queue 172 has a normal queue that is used during normal time and a queue for each class that is used when switching wavelengths. This is because, in this embodiment, there are ONUs 20 that perform wavelength switching and ONUs 20 that do not perform wavelength switching. Therefore, traffic (user data frames) addressed to the ONU 20 that does not perform wavelength switching is transferred via the normal queue. The traffic (user data frame) addressed to the wavelength switching target ONU 20 is accumulated in the queue for each class during wavelength switching.

  According to the OLT 12 of the present embodiment, in the WDM / TDM-PON system in which the wavelength used by the ONU 20 is switched, it is possible to instruct the wavelength switching of the ONU 20, and class units based on the wavelength adjustment time and the land trip time of the ONU 20 Thus, it is possible to accumulate downlink traffic (user data frames) received from the network 60 during wavelength switching of the ONU 20.

(ONU20)
Since the ONU 20 of this embodiment is the same as the ONU 20 of the first embodiment, a description thereof is omitted.

(Processing of OLT control unit 15)
FIG. 13 is a process flowchart of the OLT control unit 15. The OLT control unit 15 starts executing processing in response to detection of a wavelength switching trigger. (S301). The trigger for wavelength switching is detection of an instruction from an operation terminal connected to the OLT 10 directly or via a network (network 60 or other network) and / or a change in the traffic amount for each ONU 20 in the OLT 12.

  The OLT control unit 15 transmits a control frame indicating a wavelength switching request to the ONU 20 to be switched via the MPCP processing unit 150 of each OSU (S302). In addition, a GATE frame indicating upstream transmission permission may be transmitted together with transmission of a control frame indicating a wavelength switching request. By transmitting the GATE frame, the ONU 20 can quickly transmit a response to the wavelength switching request.

  The OLT control unit 15 waits until a wavelength switching request response is received from the ONU 20 that has transmitted the wavelength switching request (S303). If the wavelength switching request response is received from all the ONUs 20 that transmitted the wavelength switching request within the preset time, the OLT control unit 15 proceeds to S304. If the wavelength switching request response has not been received from all the ONUs 20 within the time, the OLT control unit 15 proceeds to S318. The OLT control unit 15 issues an alarm message indicating that the wavelength switching request response has not been received (S318). This alarm message is transmitted to the operation terminal connected to the OLT 12 and displayed on the operation terminal.

  The OLT control unit 15 analyzes the wavelength switching request response message received from the ONU 20 that transmitted the wavelength switching request, and confirms ACK / NACK in the message (S304). The OLT control unit 15 proceeds to S305 when ACK is confirmed in messages from all ONUs 20 to be switched, and the OLT 12 performs wavelength switching processing when NACK is confirmed in messages from at least one ONU 20. Is interrupted and the process proceeds to S317. The OLT control unit 15 issues an event occurrence message indicating that switching has been rejected from the ONU 20 (S317). This message is transmitted to, for example, an operation terminal connected to the OLT 12 and displayed on the operation terminal.

  The OLT control unit 15 transmits a wavelength switching instruction message to the wavelength switching target ONU 20 (S305). The wavelength switching instruction message includes the changed transmission wavelength and reception wavelength information, and the wavelength switching time. The wavelength switching instruction message may be transmitted by unicast for each ONU, or may be transmitted to all ONUs by broadcast.

  The OLT control unit 15 controls the scheduler of the SNI downlink traffic processing unit 17 to stop the reading of the downlink user data frame from the normal queue, and accumulates the downlink user data frame in the queue for each class (S306). As a result, the SNI downlink traffic processing unit 17 stops outputting the downlink user frame.

  The OLT control unit 15 waits for a predetermined time to receive the notification of switching completion from the wavelength switching target ONU 20, and determines whether or not to receive the notification of switching completion within the predetermined time (S308). The OLT control unit 15 proceeds to S309 when the switch completion notification is received from the wavelength switching target ONU 20, and proceeds to S314 when the switch completion notification is not received within the predetermined time. The OLT control unit 15 measures the elapsed time from the time when the wavelength switching instruction is transmitted to the ONU 20, and determines the magnitude of the elapsed time and a preset threshold value (S314). The threshold value is a time-out period for confirming reception of switching completion notifications from all of the wavelength-switching target ONUs 20, and is not a time-out period for individual ONUs 20. The OLT control unit 15 returns to S308 when elapsed time ≦ threshold, and proceeds to S315 when elapsed time> threshold. The OLT control unit 15 forcibly shifts the ONU 20 whose status is being switched in the ONU switching time class management table to the registration cancellation state (S315), and proceeds to S316. The OLT control unit 15 issues an alarm indicating that a switching process timeout has occurred (S316), and ends the process. This alarm is transmitted to the operation terminal connected to the OLT 12 and displayed on the operation terminal.

  The OLT control unit 15 identifies the ONU-ID of the ONU 20 that has received the notification of completion of switching, and changes the status of the corresponding ONU-ID to switching completion in the ONU switching time class management table (S309).

  The OLT control unit 15 refers to the ONU switching time class management table and identifies the class (#x) to which the identified ONU-ID belongs (S310).

  The OLT control unit 15 acquires the statuses of all ONUs 20 belonging to the identified class #x from the ONU switching time class management table, and determines whether the statuses of all corresponding ONUs 20 have been switched ( S311). If the switching has been completed, the process proceeds to S312. If the switching has not been completed, the process returns to S308.

  The OLT control unit 15 controls the scheduler 171 to instruct the SNI downlink traffic processing unit 17 to resume reading of the user data frame from the queue corresponding to the identified class #x (S312). Upon receiving the instruction, the SNI downlink traffic processing unit 17 controls the scheduler 171 to resume reading the user data frame from the queue corresponding to the class #x, and the user data frame stored in the class #x is transmitted. Is done.

  The OLT control unit 15 checks the status of the ONU registered from the ONU switching time class management table, and determines whether or not switching has been completed for all ONUs (S313). When reading of user data frames from the queues corresponding to all classes #x is completed, the SNI downlink traffic processing unit 17 controls the scheduler 171 to prepare for reading of downlink user data frames from the normal queues. The OLT control unit 15 ends the process. If the switching has not been completed, the OLT control unit 15 returns to S308.

As described above, even in the WDM / TDM-PON in which the wavelength of the ONU 20 is switched without switching the wavelength of the OLT 12, the OLT control unit 15 performs the transmission restart processing of the traffic accumulated for each switching time class. Can be executed.
(Wavelength switching sequence)
FIG. 14 is a wavelength switching sequence diagram according to this embodiment. Here, in order to make the explanation easy to understand, it is assumed that an event causing an alarm does not occur in the switching request or the switching instruction. Further, it is assumed that the wavelength adjustment time increases in the order of ONU1, ONU2, ONU3, and ONU4, and ONU1 and ONU2 belong to class 1, and ONU3 and ONU4 belong to class 2. Further, it is assumed that the ONU1, ONU2, ONU3, and ONU4 change the wavelength to be used from the wavelength λ1 to the wavelength λ2.

  When the ONU 20 is registered, the OLT 12 collects the wavelength adjustment time of the optical transceiver 210 of the ONU 20 by the ONU wavelength adjustment time collection sequence described in the first embodiment.

  When receiving an instruction to change the wavelength used by the OLT 10 and the ONU 20 registered in the OLT 10 from an operation terminal (OpS in the figure) or a dynamic wavelength control unit (not shown) included in the OLT control unit 15, the OLT control unit 15 The aforementioned processing (FIG. 13) is executed. The dynamic wavelength control unit included in the OLT control unit 15 measures the downstream traffic amount of the ONU 20 to dynamically determine the wavelength to be assigned to each ONU 20, and issues a change instruction when the wavelength of the ONU 20 is changed.

  The OLT 12 transmits a control frame including a wavelength switching request message and a GATE frame indicating permission for uplink transmission via OSU # 1 to the ONUs 1 to 4 which are all ONUs 20 to be switched. Thereafter, the OLT 12 receives the wavelength switching request response of the ONU 20 via the OSU # 1. Here, the wavelength switching request response is an ACK response.

  The OLT 12 transmits a wavelength switching instruction message to all the ONUs 20 to be switched via the OSU # 1. Here, transmission is performed for each ONU 20 by unicast.

  The OLT 12 controls the scheduler 171 of the SNI downlink traffic processing unit 17 to stop reading the downlink user data frame from the normal queue, and stops the transmission of the downlink user data frame from the OLT 12 to the ONU 20. Further, the OLT 12 controls the frame distribution processing unit 173 to accumulate downlink traffic (downlink user data frames) received from the network 60 during wavelength switching in a queue for each class. Here, the OLT 12 stores downlink user data frames addressed to the ONU 1 and ONU 2 in the class 1 queue, and stores downlink user data frames addressed to the ONU 3 and ONU 4 in the class 2 queue. The OLT 12 transfers frames of other destinations (not to be switched) via the normal queue.

  Similar to the first embodiment, the ONU 20 receives the wavelength switching instruction message from the OLT 12, and performs wavelength switching at the wavelength switching time specified by the received message. The ONU1 to ONU4 complete the wavelength switching after the respective wavelength adjustment times have elapsed.

  The OLT 12 transmits a GATE frame indicating upstream transmission permission to the ONU 20 that has performed wavelength switching via the OSU # 2. The transmission of the GATE frame may be periodically performed after the switching of the optical transceiver 110 of the OLT 12 is completed, or the GATE frame may be transmitted after the wavelength switching is completed based on the wavelength adjustment time of the ONU 20.

  When the ONU 20 receives the GATE frame after the wavelength switching is completed, the ONU 20 transmits a switching completion notification message to the OLT 12 during the transmission permission period. Here, since wavelength switching is completed in the order of ONU1, ONU2, ONU3, and ONU4, a switching completion notification message is also transmitted in the order of ONU1, ONU2, ONU3, and ONU4. When the OLT 12 receives the wavelength switching completion notification message from the ONU 1 and the ONU 2 via the OSU # 2, the wavelength switching has been completed for all the ONUs 20 (ONU 1 and ONU 2) belonging to the class 1, so the OLT 12 controls the scheduler 171. Resume reading of the downlink user data frame from the class 1 queue. When reading is resumed from the class 1 queue, frames addressed to the ONU 1 and frames addressed to the ONU 2 stored in the class 1 queue are transmitted via the OSU # 2. After that, the OLT 12 also receives the wavelength switching completion notification message from the ONU 3 and ONU 4, and since the wavelength switching has been completed in all of the ONUs 20 (ONU 3 and ONU 4) belonging to the class 2, it controls the scheduler 171 for class 2. Resume reading of downlink user data frames from the queue. When the OLT 12 resumes reading the downlink user data frame from the class 2 queue, the downlink user data frame addressed to the ONU 3 and the ONU 4 stored in the class 2 queue is transmitted via the OSU # 2.

  Although not shown, the OLT 12 controls the frame distribution processing unit 173 after the completion of reading the downlink user data frame from the queue for each class, and controls the frame distribution processing unit 173 to receive the downlink traffic (downlink user). Data frame) is stored in the normal queue, the scheduler 171 is controlled, the downlink traffic is read from the normal queue, and is transmitted via the switching processing unit 16 and OSU # 2.

  According to this embodiment, even when ONUs 20 having different wavelength switching times are mixed in a WDM / TDM-PON for switching the wavelength of the ONU 20, transmission of downlink traffic accumulated for each switching time class can be resumed when switching is completed, and the latency is increased. It is possible to achieve both suppression of deterioration and reduction of the buffer capacity necessary for the OLT 12.

  In addition, this embodiment is not limited to an above-described Example, Various modifications are included. For example, the present invention can be applied to a case where a number of types of sensors, actuators, and the like for various service uses are accommodated in a gateway. Since the requirements differ depending on the sensor type and service, the switching time is assumed to be different. Even when such sensors and actuators are switched at the same time, this can be realized by providing the gateway with the functions provided in the OLT.

  Further, the above-described embodiments have been described in detail for easy understanding, and are not necessarily limited to those having all the configurations described. Further, a part of the configuration of one embodiment can be replaced with the configuration of another embodiment, and the configuration of another embodiment can be added to the configuration of one embodiment. In addition, it is possible to add, delete, or replace another configuration for a part of the configuration of each embodiment.

  Each of the above-described configurations, functions, processing units, and the like may be realized by hardware by designing a part or all of them with, for example, an integrated circuit. Each of the above-described configurations, functions, and the like may be realized by software by interpreting and executing a program that realizes each function by the processor. Information such as a program, a table, or a file that realizes each function can be placed in a recording device such as a memory, a hard disk, or an SSD (Solid State Drive), or a recording medium such as an IC card or an SD card.

  Further, the control lines and the information lines indicate what is considered necessary for the explanation, and not all the control lines and information lines on the product are necessarily shown. In practice, it may be considered that almost all the components are connected to each other.

  According to the described embodiment, it is possible to reduce the capacity of the OLT buffer for switching the specifications of the optical access network system and to suppress the deterioration of latency associated with the switching time.

  10, 11, 12: OLT, 20, 21: ONU, 110, 210: optical transceiver, 120, 121, 220, 221: PON PHY / MAC processing unit, 130, 230: multiplexer, 140, 240: demultiplexer, 150, 250: MPCP processing unit, 160, 270, 1601: Downlink traffic processing unit, 170, 260, 1701: Uplink traffic processing unit, 1610, 171: Scheduler, 1620, 172: Class queue, 1630, 173: Frame distribution Processing unit, 16: Switching processing unit, 180, 181, 15: OLT control unit, 190: PON logic circuit, 191: CPU, 192: Memory, 193, 290: FPGA circuit data file storage unit, 280, 281: ONU control Part, 30, 31: optical splitter, 4 : Optical fiber, 50: operation terminal, 60: Network.

Claims (13)

A plurality of subscriber devices that require different switching times for switching operation specifications, and the subscriber devices are connected via optical fibers,
An optical access comprising: a station-side device that classifies the switching time into a plurality of switching time classes and controls traffic destined for the subscriber device based on the classified switching time class. Network system.   The subscriber unit is in a first communicable state before switching of the operation specifications, a second communicable state after switching of the operation specifications, and a state incapable of communicating with the switching of the operation specifications. 2. The light according to claim 1, wherein the switching time for continuing the incommunicable state is required for transition from the first communicable state to the second communicable state. Access network system. 3. The optical access network system according to claim 2, wherein the operation specification is a wavelength used by an optical transceiver included in the subscriber unit, which transmits and receives to / from the station side device via the optical fiber.   3. The optical access network system according to claim 2, wherein the operation specification is a specification of a logic circuit included in the subscriber unit.   The station side device specifies a switching time class queue corresponding to the switching time class, the switching time class of the subscriber device as a destination of a user data frame, and the switching time corresponding to the specified switching time class 5. The light according to claim 3, further comprising: a frame distribution processing unit that distributes the user data frame to a queue for each class; and a scheduler that reads the user data frame from the queue for each switching time class. Access network system. The station side device is in the first communicable state of the subscriber unit,
Controlling the scheduler, the subscriber device stops reading the destination user data frame from the queue for each switching time class, and sends a switching instruction message to the second communicable state to the subscriber To the device,
The switching time class of the user data frame destined for the subscriber device by controlling the scheduler in response to receiving the switch completion message to the second communicable communication state from the subscriber device. 6. The optical access network system according to claim 5, wherein reading from each queue is resumed.   6. The optical access network system according to claim 5, wherein each size of the queue for each switching time class is set based on a range of the switching time corresponding to each of the switching time classes.   2. The switching time is calculated based on an adjustment time required for switching the specifications of the subscriber unit and a round trip time between the subscriber unit and the station side unit. Optical access network system.   In response to receiving a control frame including the adjustment time from the subscriber unit, the station side device acquires a correspondence between an identifier for identifying the subscriber unit that has transmitted the control frame and the adjustment time. The optical access network system according to claim 8.   2. The optical access network system according to claim 1, wherein the subscriber unit is connected to either the station side device or another station side device based on the switching time class. Connect to multiple subscriber devices that require different switching times for switching operation specifications via optical fiber,
A queue for each switching time class corresponding to the switching time class that classifies the switching time into a plurality of stages,
A frame distribution processing unit that distributes the user data frame to the queue for each switching time class corresponding to the switching time of the subscriber device that is the destination of the input user data frame; and the user data from the queue for each switching time class A station apparatus having a scheduler for reading out a frame. A control program to be executed by a station side device connected via an optical fiber to a plurality of subscriber devices that require different switching times for switching the operation specifications of the optical access network system,
The station side device
Classifying the switching time into a plurality of switching time classes;
A control program for controlling traffic destined for the subscriber device based on the classified switching time class. The station side device includes a switching time class queue corresponding to the switching time class,
Identify the switching time class of the subscriber device of the destination of the input user data frame;
The user data frame is sorted and stored in the queue for each switching time class corresponding to the specified switching time class,
The control program according to claim 12, wherein the user data frame is read from the queue for each switching time class and transmitted to the subscriber device.

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