JP5577520B2 - Communication system, slave station device, and master station device - Google Patents

Description

  The present invention relates to an optical access system, and more particularly to an optical access system in which an optical network device shifts to a sleep state.

  In recent years, an optical network has been introduced in order to cope with high speed and wide bandwidth of a communication network. In the optical network, one station-side optical transmission line termination device (hereinafter referred to as OLT) and one in-home optical transmission line termination device (hereinafter referred to as ONU) are connected via an optical fiber. Communication system.

  An optical passive network system (hereinafter referred to as a PON) is an optical network system in which one OLT forms a star network with a plurality of ONUs via an optical splitter. A typical PON standard is EPON (Ethernet PON (Ethernet is a registered trademark)) standardized by IEEE 802.3.

  Further, the upstream frame transmitted from the ONU to the OLT and the downstream frame transmitted from the OLT to the ONU are multiplexed by wavelength division multiplexing (hereinafter referred to as WDM). The downstream frame is received by all ONUs connected by the optical fiber. Then, the ONU refers to the destination information included in the preamble portion of the downstream frame, and discards the downstream frame that is not addressed to itself. On the other hand, an upstream frame in the PON is multiplexed by time division multiple access (hereinafter referred to as TDMA) and used for communication.

  The communication speed of the PON starts with a system that handles a low-speed signal such as 64 kbit / sec, and the maximum length of a variable length packet of BPON (Broadband PON) or Ethernet that transmits and receives a fixed-length ATM cell at a maximum of about 600 Mbit / sec. The introduction of EPON that transmits and receives at 1 Gbit / sec or GPON (Gigabit capable PON) that handles higher-speed signals of about 2.4 Gbit / sec is underway. In the future, it is desired to realize a high-speed PON capable of using a signal of 10 Gbit / second to 40 Gbit / second.

  As the communication speed increases, the power consumption of the relay device on the transmission path tends to increase. Since ONUs are installed at subscriber's homes, many ONUs are installed on the network. On the other hand, the time required for the ONU to be used is short compared to the OLT and the upper switch group. Therefore, the ONU is left while using wasted power while not communicating.

  In order to reduce power consumption while the ONU is not communicating, when the TE (Terminal Equipment: hereinafter referred to as TE) is not connected to the ONU via a LAN cable, the function block inside the ONU is placed in the low power consumption mode. A method of reducing the power consumption by setting to (for example, see Patent Document 1) is disclosed.

  In addition, a method for setting an ONU to a sleep state by a procedure in which an OLT permits an ONU sleep time request is disclosed (for example, see Patent Document 2).

JP 2008-113193 A JP 2009-260970 A

  With the recent increase in demand for high-speed and large-capacity communication as described above, the power consumption of relay devices such as ONUs on transmission lines is increasing, and low power operation of relay devices is required. However, the technique disclosed in Patent Document 1 described above is a technique that monitors only whether the TE is connected to the LAN port, and shifts to and returns to the low power consumption mode according to the monitoring result. For this reason, when the technique disclosed in Patent Document 1 is used, once the TE is connected to the ONU, the power consumption of the ONU cannot be reduced, and even if communication is not actually performed, The ONU consumes power during steady operation.

  The technique disclosed in Patent Document 2 can suppress the power consumption of the ONU during non-communication in a state where the TE is connected by adding a procedure for shifting to the sleep state when the ONU is not in communication. However, in the technique disclosed in Patent Document 2, since only a predetermined sleep time is a sleep state, for example, when the sleep time is set short, the ONU frequently repeats the transition to and return to the sleep state, The effect of reducing the power consumption of the ONU is limited.

  In view of the above, the present invention selects as long a sleep time as possible based on the UNI link speed between the ONU and the TE and the queue buffer capacity provided in the ONU when the ONU is in a no-communication state. An object of the present invention is to provide a PON system capable of reducing waste of power consumption of end user traffic, particularly in the upstream direction, by shifting to and returning to the sleep state during the selected sleep time.

According to a representative aspect of the present invention, a master station device and a slave station device that relays an uplink frame from a terminal device to the master station device, wherein the slave station device stores the uplink frame And a frame including a sleep time determined based on an amount of uplink frames that can be stored in the predetermined capacity of the buffer and a link speed between the own device and the terminal device. A communication system characterized by transmitting to a station device.

  According to an embodiment of the present invention, the slave station device transmits a frame including a sleep time determined according to the amount of uplink frames to the master station device, thereby reducing the power consumption of the slave station device. it can.

It is a block diagram which shows the PON system of embodiment of this invention. It is a block diagram which shows the structure of OLT of embodiment of this invention. It is a block diagram which shows the structure of ONU of embodiment of this invention. It is a sequence diagram which shows the process for ONU of the embodiment of this invention to transfer to a sleep state and to return. It is a flowchart which shows the processing of ONU for ONU to transfer and return to a sleep state of embodiment of this invention. It is a flowchart which shows the process of OLT for ONU of an embodiment of this invention to transfer to a sleep state and to return. It is explanatory drawing which shows the sleep time management table of ONU of embodiment of this invention. It is explanatory drawing which shows the frame format of the sleep control signal transmitted / received between OLT and ONU of embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described in detail.

  FIG. 1 is a block diagram showing a PON system according to an embodiment of the present invention.

  The PON system shown in FIG. 1 includes an upper network 1, an OLT 2, an optical splitter 3, an ONU 4, and a terminal device 6. The terminal device 6 is connected to the ONU 4. Although only two ONUs 4 and terminal devices 6 are illustrated, a plurality of ONUs 4 are similarly connected to the OLT 2 via the optical splitter 3. The OLT 2 is connected to the upper network 1 and the optical splitter 3.

  The OLT 2 and the ONU 4 shown in FIG. 1 communicate using optical signals multiplexed by wavelength division division. For this reason, communication between the upstream direction and the downstream direction does not collide. On the other hand, since a plurality of ONUs 4 communicate at the same transmission wavelength, the optical transmission time of each ONU 4 is controlled by the OLT 2 so that the optical transmissions do not overlap with the same time.

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

  The OLT 2 includes an electrical transmission / reception unit 201, an electrical / optical conversion unit 202, a medium access control unit 203, a control unit 204, a queue buffer unit 205A, and a queue buffer unit 205B.

  The electric-side transmitting / receiving unit 201 is a device that communicates with a relay device included in the upper network 1 by an electric signal. The electrical / optical converter 202 is a device for communicating with the ONU 4 by optical signals. The electrical / optical converter 202 converts an optical signal into an electrical signal, and converts the electrical signal into an optical signal.

  The medium access control unit 203 is a device for controlling data communication performed while the OLT 2 is in operation. The control unit 204 is a device that controls functional blocks in the OLT 2.

  The queue buffer 205A and the queue buffer 205B are buffers for storing the traffic data of the queue A and the queue B, respectively. A plurality of queue buffers 205A and queue buffers 205B are set as required by the OLT 2. The queue buffer 205A and the queue buffer 205B are collectively referred to as a queue buffer 205.

  The control unit 204 includes a sleep control signal processing unit 207, a sleep state management table 208, a sleep return time management table 209, and a time counter 210.

  The sleep control signal processing unit 207 generates and analyzes a frame that causes the ONU 4 to enter and return to the sleep state. The sleep state management table 208 indicates whether the ONU 4 is in a sleep state.

  The sleep return time management table 209 indicates the time when the ONU 4 returns from the sleep state. The time counter 210 holds the current time and counts a predetermined time.

  The sleep control signal processing unit 207 may be a program executed by a processor provided in the OLT 2 or the like. Further, the sleep state management table 208 and the sleep return time management table 209 may be stored in a memory or the like provided in the OLT 2.

  The upstream frame sent from the ONU 4 is received by the electrical / optical converter 202 and converted into an electrical signal. The medium access control unit 203 holds the MAC address of the upstream frame transmitted from the ONU 4 and the transmission source ONU information given to the preamble unit in association with each other as route information. Then, the upstream frame transmitted from the ONU 4 is transmitted from the electrical side transceiver unit 201 to the upper network 1.

  The downstream frame transmitted from the higher level network 1 is received by the electrical side transmitting / receiving unit 201. Then, the medium access control unit 203 refers to the MAC address added to the downlink frame sent from the upper network 1, and based on the route information held in advance, the identification information of the destination ONU 4 is sent to the preamble part of the downlink frame. Give. Then, the electrical / optical converter 202 converts the downstream frame sent from the upper network 1 into an optical signal and transmits it to the ONU 4.

  The medium access control unit 203 has a switching function as described above. Note that, for example, LLID (Logical Link ID) defined by IEEE802.3ah can be used as the identification information of the ONU 4 of the present embodiment.

  FIG. 3 is a block diagram illustrating the configuration of the ONU 4 according to the embodiment of this invention.

  The ONU 4 includes an electrical transmission / reception unit 401, an electrical / optical conversion unit 402, a medium access control unit 403, a control unit 404, and a queue buffer unit 405.

  The electric side transmitting / receiving unit 401 is a device that communicates with the terminal device 6 by an electric signal. The electrical / optical conversion unit 402 is a device for communicating with the OLT 2 by an optical signal. The electrical / optical converter 402 converts an optical signal into an electrical signal, and converts the electrical signal into an optical signal.

  The medium access control unit 403 is a device that controls data communication when the ONU 4 is in a steady state and a sleep state. The control unit 404 is a device that controls functional blocks in the ONU. The queue buffer unit 405 is a buffer for storing traffic data.

  The control unit 404 includes a sleep control signal processing unit 406, a sleep state control unit 407, a sleep return time management table 408, a time counter 409, a sleep time management table 410, an ONU link speed management unit 411, and an ONU buffer amount management unit 412. Is provided.

  The sleep control signal processing unit 406 generates and analyzes a sleep control signal transmitted to and received from the OLT 2. The sleep state control unit 407 controls transition to and return from the sleep state.

  The sleep return time management table 408 holds the time to return from the sleep state. The time counter 409 holds the current time and counts a predetermined time.

  The sleep time management table 410 is a predetermined table based on the UNI link speed and the queue buffer capacity between the ONU 4 and the terminal device 6. The ONU link speed management unit 411 is connected to the electrical side transmission / reception unit 401 and monitors the UNI link speed between the ONU 4 and the terminal device 6. The ONU buffer amount management unit 412 is connected to the queue buffer unit 405 and monitors the queue buffer capacity of the ONU 4.

  The sleep state of the ONU 4 in the present invention is a state in which communication with the electric / optical conversion unit 202 of the OLT 2 is interrupted by stopping the power supply to the electric / optical conversion unit 402. Further, in the sleep state, the medium access control unit 403 continues the function of accumulating the upstream frame received by the electrical side transmission / reception unit 401 in the queue buffer unit 405 and only a part of the function executed by the control unit 404, Stop other functions.

  In the sleep state, the sleep state control unit 407 determines whether or not the time counter 409 has reached the sleep return time indicated by the sleep control signal processing unit 207 of the OLT 2 based on the sleep return time management table 408. Monitor.

  FIG. 4 is a sequence diagram illustrating processing for the ONU 4 according to the embodiment of the present invention to enter and return to the sleep state.

  The sleep control signals transmitted and received between the ONU 4 and the OLT 2 include a sleep time request signal 11, a sleep permission signal 12, a sleep state request signal 13, a sleep return request signal 14, a grant signal 15, and a sleep non-permission signal 16. It is.

  In the steady state of the ONU 4, the sleep state control unit 407 monitors the passing information of the upstream frame and the downstream frame notified from the control unit 404, and refers to the time counter 409 every time the upstream frame and the downstream frame pass. Then, by referring to the time counter 409, the time of the non-communication state in which the upstream frame and the downstream frame have not passed is measured.

  When a certain time has elapsed in the non-communication state, the sleep state control unit 407 causes the sleep control signal processing unit 406 to generate the sleep time request signal 11 (11-1) via the control unit 404.

  The generated sleep time request signal 11-1 includes ONU 4 identification information, a sleep time acquired by a method to be described later, a value of a time counter 409 indicating a time point when the sleep time request signal 11-1 is generated, The queue buffer 405 includes information indicating that no upstream frame exists.

  The information indicating that no upstream frame exists in the queue buffer 405 includes information transmitted by a Report frame defined by IEEE 802.3ah MPCP (Multi Point-Control Protocol), for example.

  The electrical / optical conversion unit 402 transmits a sleep time request signal 11-1 in accordance with an instruction from the sleep state control unit 407. When the control unit 204 of the OLT 2 receives the sleep time request signal 11-1 from the electrical / optical conversion unit 402, the sleep control signal processing unit 207 analyzes the sleep time request signal 11-1.

  When the sleep control signal processing unit 207 specifies the ONU 4 that is the transmission source of the sleep time request signal 11-1 based on the identification information of the ONU 4 included in the sleep time request signal 11-1, the control unit 204 displays the queue buffer. Referring to 205, it is confirmed whether or not there is a downstream frame addressed to the specified ONU4.

  When there is no downstream frame addressed to the ONU 4 specified in the queue buffer 205, the control unit 204 sends a sleep permission signal 12 (12-1) to the sleep control signal processing unit 207 to permit the ONU 4 to enter the sleep state. ) And the generated sleep permission signal 12-1 is sent to the identified ONU 4. Further, the fact that the identified ONU 4 is in the sleep state is stored in the sleep state management table 208.

  Further, the control unit 204 acquires the value of the time counter 210 indicating the time point when the sleep permission signal 12-1 is generated. Then, by adding the sleep time included in the sleep time request signal 11-1 to the value when the sleep permission signal 12-1 acquired from the time counter 210 is generated, the value of the time counter at the sleep return time Is calculated. The calculated sleep return time is stored in the sleep return time management table 209.

  Further, the control unit 204 calculates a value of the time counter 409 of the ONU 4 that indicates a time point when returning from the sleep state, and stores the value in the sleep return time management table 209. When the time counter 210 of the OLT 2 and the time counter 409 of the ONU 4 are synchronized in advance, the sleep return time is added to the value of the time counter 210 indicating the time when the sleep permission signal 12-1 is generated. The value of the time counter 409 of the ONU 4 at the time of return from sleep may be calculated.

  The generated sleep permission signal 12-1 includes the identification information of the ONU 4 that shifts to the sleep state and the value of the time counter 409 of the ONU 4 that indicates the time point when the ONU 4 returns from the sleep state (sleep return time).

  When the control unit 404 receives the sleep permission signal 12-1 from the electrical / optical conversion unit 202, the control unit 404 causes the sleep control signal processing unit 406 to analyze the sleep permission signal 12-1. When the control unit 204 of the OLT 2 specifies that the ONU 4 is permitted to enter the sleep state, the control unit 404 sets the value of the time counter 409 indicating the sleep return time included in the sleep permission signal 12-1. Is stored in the sleep state control unit 407.

  After storing the sleep return time, the control unit 404 shifts to the sleep state. That is, the control unit 404 performs control so as to stop the power supply to the electrical / optical conversion unit 402. Furthermore, the upstream frame received from the terminal device 6 received by the electrical transmission / reception unit 401 is shifted to a state in which it is transferred from the electrical transmission / reception unit 401 to the queue buffer 405. Stop operation except for necessary functions.

  While the ONU 4 is in the sleep state, the upstream frame transmitted from the terminal device 6 is accumulated in the queue buffer 405. The sleep state control unit 407 monitors the value of the time counter 409 until the time counter 409 reaches the sleep state return time described above.

  When the time counter 409 reaches the sleep state return time, the sleep state control unit 407 shifts the control unit 404 to the steady operation state. The control unit 404 that is in a steady operation state performs control so that power supply to the electrical / optical conversion unit 402 is resumed. As a result, the electrical / optical conversion unit 402 starts operating, and communication between the electrical / optical conversion unit 402 of the ONU 4 and the electrical / optical conversion unit 202 of the OLT 2 is established.

  When communication between the electric / optical conversion unit 202 of the OLT 2 and the electric / optical conversion unit 402 of the ONU 4 is established, the control unit 204 of the OLT 2 inquires of the ONU 4 whether or not the ONU 4 further shifts to the sleep state. The sleep state request signal 13 (13-1) is generated. Then, the control unit 204 causes the electrical / optical conversion unit 202 to transmit the sleep state request signal 13-1 to the electrical / optical conversion unit 402 of the ONU 4 that is in the sleep state.

  When the control unit 404 of the ONU 4 receives the sleep state request signal 13-1 from the electrical / optical conversion unit 202, the control unit 404 refers to the queue buffer 405 and determines whether there is an uplink frame received during the sleep state. When there is no upstream frame even in the sleep state, the control unit 404 inquires of the OLT 2 whether or not to transition to the sleep state again, and the procedure for generating the aforementioned sleep time request signal 11-1 is as follows. The sleep time request signal 11-2 is generated by the same procedure. Then, the generated sleep time request signal 11-2 is transmitted to the electrical / optical conversion unit 202 of the OLT 2.

  When the control unit 204 receives the sleep time request signal 11-2 from the electrical / optical conversion unit 202, the control unit 204 determines whether there is a downlink frame addressed to the ONU 4 that has transmitted the sleep time request signal 11-2. When there is no downstream frame addressed to the ONU 4 that transmitted the sleep time request signal 11-2, the control unit 204 performs the sleep permission signal 12 according to the same procedure as that for generating the sleep permission signal 12-1. -2 is generated. Then, the ONU 4 is shifted to the sleep state by sending the sleep permission signal 12-2 to the ONU 4.

  When at least one of the upstream frame transmitted to the electrical transmission / reception unit 401 of the ONU 4 or the downstream frame transmitted to the electrical transmission / reception unit 201 of the OLT 2 does not exist, the sleep state request signal 13 and the sleep time request 11 described above. The procedure of the sleep permission signal 12 is repeated, and the ONU 4 intermittently shifts to the sleep state.

  When the sleep state request signal 13-2 is received, the control unit 404 refers to the queue buffer 405 and determines whether there is an uplink frame transmitted from the terminal device 6. When there is an upstream frame in the queue buffer 405, the control unit 404 causes the sleep control signal processing unit 406 to generate the sleep return request signal 14 in order to send to the OLT 2 that there is no need to shift to the sleep state. Then, the electrical / optical conversion unit 402 transmits a sleep return request signal 14 to the OLT 2.

  The sleep recovery request signal 14 includes an ONU identification signal for the ONU 4 and information indicating that an upstream frame exists in the queue buffer 405. As information indicating that an upstream frame exists in the queue buffer 405, for example, information transmitted by a Report frame defined by MPCP of IEEE 802.3ah can be used.

  When the control unit 204 receives the sleep return request signal 14 from the electrical / optical conversion unit 402, the control unit 204 causes the sleep control signal processing unit 207 to analyze the received sleep return request signal 14. Then, the control unit 204 acquires that the ONU 4 has an upstream frame that should pass through the ONU 4 based on the analysis result, and then stores information indicating that the ONU 4 is in a steady state in the sleep state management table 208. . Further, the sleep return time information of the ONU 4 that has sent the sleep return request signal 14 is deleted from the sleep return time management table 209.

  After the above-described procedure is completed, the control unit 204 notifies the control unit 404 of the upstream signal transmission timing signal 15 (hereinafter referred to as the grant signal 15) according to a procedure determined when the ONU 4 is in a steady operation. When the grant signal 15 is received, the control unit 404 transmits the upstream frame stored in the queue buffer 405 from the electrical / optical conversion unit 402 to the electrical / optical conversion unit 202 in the same manner as during steady operation.

  When the sleep time request signal 11 is received, the control unit 204 refers to the queue buffer 205 to determine whether there is a downstream frame addressed to the ONU 4. When there is a downstream frame addressed to the ONU 4, the control unit 204 causes the sleep control signal processing unit 207 to generate the sleep non-permission signal 16 in order not to shift the ONU 4 to the sleep state.

  The sleep disapproval signal 16 includes information for identifying the ONU 4 that returns from the sleep state to the steady state.

  The control unit 204 generates the sleep disapproval signal 16 and simultaneously stores information indicating that the ONU 4 is in a steady state in the sleep state management table 208. Further, the sleep return time information of the ONU 4 is deleted from the sleep return time management table 209. After the above procedure is completed, the control unit 204 transmits the sleep non-permission signal 16 from the electrical / optical conversion unit 202.

  When the control unit 404 receives the sleep non-permission signal 16 from the electrical / optical conversion unit 202, the control unit 404 causes the sleep control signal processing unit 406 to analyze the sleep non-permission signal 16. Based on the analysis result, the control unit 404 specifies that the downstream frame that should pass through the ONU 4 is present in the OLT 2, and then transmits the downstream frame transmitted from the electrical / optical conversion unit 202 according to a procedure determined during steady operation. Is received by the electrical / optical conversion unit 402 and transmitted from the electrical transmission / reception unit 401 to the terminal device 6.

  FIG. 5 is a flowchart showing processing of the ONU 4 for the ONU 4 according to the embodiment of the present invention to enter and return to the sleep state.

  In the first process (start) of the flowchart shown in FIG. 5, the ONU 4 is in a steady state. When the PON system of this embodiment is EPON, the steady state means that the link between the electrical / optical conversion unit 202 of the OLT 2 and the electrical / optical conversion unit 402 of the ONU 4 is established, and the registration of the ONU 4 in the OLT 2 is completed. Further, the OLT 2 and the ONU 4 can be connected. In the state where the flowchart shown in FIG. 5 starts, the ONU 4 has not shifted to the sleep state.

  After the processing shown in FIG. 5 is started, the ONU 4 periodically monitors its UNI link speed and queue buffer capacity by the ONU link speed management unit 411 and the ONU buffer amount management unit 412 (S21 and S21). S22). By monitoring each value, a sleep time is determined from a sleep time management table 410 described later.

  In the steady state of the ONU 4, the sleep state control unit 407 of the ONU 4 determines whether or not the non-communication state of the ONU 4 has passed a certain time (S23). When the non-communication state has not passed for a certain time and the OLT 2 and the ONU 4 are communicating, the ONU 4 returns to Step 21. The ONU 4 repeats the processes of S21 to S23 in the steady state.

  If the non-communication state of the ONU 4 has passed a predetermined time in S23, the sleep state control unit 407 refers to the sleep time management table 410 via the control unit 404 and determines the maximum sleep time (S24). In S24, the sleep state control unit 407 determines the maximum sleep time based on the UNI link speed and the queue buffer capacity acquired in S21 and S22. Details of the sleep time management table 410 will be described later with reference to FIG.

  Thereafter, the control unit 404 causes the sleep control signal processing unit 406 to generate the sleep time request signal 11 and transmits the generated sleep time request signal 11 from the electric / optical conversion unit 402 to the electric / optical conversion unit 202 ( S25). When the sleep time request signal 11 is transmitted in S25, the sleep state control unit 407 refers to the value of the time counter 409 and starts counting for receiving a signal from the OLT 2.

  The sleep state control unit 407 determines whether or not a signal is sent from the OLT 2 until the timer of the time counter 409 of the ONU 4 counts a predetermined response time (S26). When the timer of the time counter 409 of the ONU 4 counts a predetermined response time and no signal is sent, the ONU 4 determines that the transition to the sleep state has been rejected and returns to the steady state. That is, the process returns to S21 and S22.

  When the steady state is reached from S26, the sleep state control unit 407 restarts the time count of the non-communication state of the ONU 4 and measures the time during which no upstream frame or downstream frame passes. In S23, when a non-communication state in which no uplink frame or downlink frame passes has passed for a certain period of time, the sleep state control unit 407 refers to the sleep time management table 410 according to the procedure of S24 and S25 described above, and The time is determined and the sleep time request signal 11 is transmitted. These processes are repeated until a signal is received from the OLT 2.

  When the electrical / optical conversion unit 402 receives a signal from the OLT 2 in S <b> 26, the electrical / optical conversion unit 402 transmits the received signal to the medium access control unit 403. The medium access control unit 403 determines whether the received signal is addressed to its own ONU 4 (S27).

  In S27, when the medium access control unit 403 determines that the signal is a destination other than its own ONU 4, the sleep state control unit 407 discards the received signal (S28). Then, the sleep state control unit 407 refers to the time counter 409 of the ONU 4 and determines whether or not the timer of the time counter 409 of the ONU 4 is counting a predetermined response time (S29).

  When the timer of the time counter 409 of the ONU 4 determines in S29 that the predetermined response time has not been counted, the sleep state control unit 407 returns to S26 in order to wait for a signal addressed to its own ONU 4. In S29, if the timer of the time counter 409 of the ONU 4 determines that the predetermined response time has been counted, the ONU 4 returns to S21 and S22, and returns to the steady state.

  When the ONU 4 enters a steady state after S29, the sleep state control unit 407 restarts the time count of the ONU 4 in the non-communication state, and repeats the transition to the sleep state by the same procedure as S21 to S25 described above. Is requested to the OLT 2.

  In S27, when it is determined that the medium access control unit 403 has received the sleep permission signal 12 addressed to its own ONU 4 from the OLT 2, the control unit 404 causes the sleep control signal processing unit 406 to analyze the received signal. Then, the control unit 404 determines whether the received signal is the sleep permission signal 12 based on the result analyzed by the sleep control signal processing unit 406 (S30).

  If it is determined in S30 that the received signal is not the sleep permission signal 12, the ONU 4 returns to the steady state.

  When it is determined in S30 that the received signal is the sleep permission signal 12, the control unit 204 of the OLT 2 permits the ONU 4 to transition to the sleep state. Therefore, the control unit 404 of the ONU 4 performs the sleep return time management table. In 408, the sleep state return time is stored. The sleep state return time is included in the sleep permission signal 12 as described above.

  After storing the sleep state return time, the control unit 404 stops the power supply to the electrical / optical conversion unit 402 and shifts to the sleep state (S31). Then, the sleep state control unit 407 starts the time counter 409 via the control unit 404 (S32).

  Thereafter, the upstream frame is accumulated in the queue buffer 405 while the ONU 4 is in the sleep state. The sleep state control unit 407 monitors the value of the time counter 409 until the time counter 409 reaches the sleep state return time described above (S33).

  When the time counter 409 becomes the same value as the sleep state return time, the sleep state control unit 407 causes the control unit 404 to shift to the steady state (S34). Specifically, the control unit 404 restarts the power supply to the electrical / optical conversion unit 402 when the sleep state is changed to the steady state. As a result, communication with the electrical / optical converter 202 of the OLT 2 is established.

  After the communication between the electrical / optical conversion unit 202 of the OLT 2 and the electrical / optical conversion unit 402 of the ONU 4 is established in S34, the control unit 404 of the ONU 4 counts for receiving the sleep state request signal 13 from the OLT 2. Start. Then, before the timer of the time counter 409 counts the predetermined time, it is determined whether or not the sleep state request signal 13 is received from the OLT 2 (S35).

  In S35, if the timer of the time counter 409 counts a predetermined time before receiving the sleep state request signal 13 from the OLT 2, the transition from the OLT 2 to the sleep state is not permitted, so the ONU 4 returns to S21, and the steady state Return to.

  In S35, when the sleep state request signal 13 is received from the OLT 2 before the timer of the time counter 409 counts the predetermined time, the control unit 404 of the ONU 4 transmits the received sleep state request signal 13 to the sleep control signal processing unit 406. Let the analysis. Based on the analysis result, it is recognized that the sleep state request signal 13 should return to the OLT 2 as to whether or not the sleep state request signal 13 further shifts to the sleep state.

  The control unit 404 of the ONU 4 refers to the queue buffer 405 to determine whether or not to further shift to the sleep state, and determines whether or not there is an uplink frame received during the sleep state (S36).

  When it is determined in S36 that no uplink frame exists, the control unit 404 returns to S24 and generates the sleep time request signal 11 in order to further shift to the sleep state. Then, the sleep time request signal 11 generated in the OLT 2 is transmitted (S24, S25). Furthermore, it shifts to the sleep state (S26 to S33).

  The control unit 404 may acquire the UNI link speed and the buffer capacity when returning from S36 to S24, and may determine the sleep time again in S24.

  When it is determined in S36 that an uplink frame is present, the control unit 404 causes the sleep control signal processing unit 406 to generate the sleep return request signal 14 to return to the steady state from the sleep state. Is transmitted to the OLT 2 (S37). When the OLT 2 receives the sleep return request signal 14, the OLT 2 generates a grant signal 15 and transmits the generated grant signal 15 to the electrical / optical conversion unit 402 of the ONU 4. When the ONU 4 receives the grant signal 15 (S38), the ONU 4 returns to the steady state.

  FIG. 6 is a flowchart showing the processing of the OLT 2 for the ONU 4 according to the embodiment of the present invention to enter and return to the sleep state.

  When the control unit 204 of the OLT 2 receives the sleep time request signal 11 from the ONU 4 in the steady state (S41), it is determined whether or not the downstream frame addressed to the ONU 4 that transmitted the sleep time request signal 11 is in the queue buffer 205. Determine (S42).

  When the downstream frame addressed to the ONU 4 is in the queue buffer 205, the control unit 204 causes the sleep control signal processing unit 207 to generate the sleep disapproval signal 16 in order not to shift the ONU 4 to the sleep state. Then, the sleep / non-permission signal 16 is transmitted to the ONU 4 that has transmitted the sleep time request signal 11 by the electrical / optical conversion unit 202 (S43). Then, the OLT 2 returns to the steady state and waits for the sleep time request signal 11.

  In S42, when there is no downstream frame addressed to the ONU 4 in the queue buffer 205, the control unit 204 causes the sleep control signal processing unit 207 to generate the sleep permission signal 12 in order to shift the ONU 4 to the sleep state. Then, the generated sleep permission signal 12 is sent to the ONU 4 that has transmitted the sleep time request signal 11 (S44).

  Then, the fact that the ONU 4 to which the sleep permission signal 12 has been sent is in the sleep state is stored in the sleep state management table 208 (S45). In S45, the OLT 2 stores the sleep return time in the sleep return time management table 209 as described above with reference to FIG.

  Further, the control unit 204 starts the timer of the time counter 210 (S46) and waits until the sleep time elapses.

  Thereafter, after the timer of the time counter 210 counts the sleep time, the control unit 204 sends a sleep state request signal 13 to the sleep control signal processing unit 207 in order to inquire the ONU 4 whether the ONU 4 further shifts to the sleep state. Generate. Then, the generated sleep state request signal 13 is sent to the ONU 4 in the sleep state (S47).

  Thereafter, the control unit 204 determines whether or not the sleep return request signal 14 is sent from the ONU 4 (S48). When the sleep recovery request signal 14 is not transmitted from the ONU 4, the ONU 4 does not enter the sleep state, and therefore the OLT 2 receives the sleep time request signal 11. Then, the OLT 2 returns to S42.

  When the sleep return request signal 14 is sent from the ONU 4 in S48, the control unit 204 sends the grant signal 15 to the ONU 4 (S50) and returns to the steady state.

  FIG. 7 is an explanatory diagram illustrating the sleep time management table 410 of the ONU 4 according to the embodiment of this invention.

  The sleep time management table 410 illustrated in FIG. 7 holds the maximum sleep time of the ONU 4 based on the UNI link speed of the ONU 4 and the queue buffer capacity. The values in the sleep time management table 410 are stored in advance by an administrator or the like.

  As the buffer capacity is larger, the amount of upstream frames that can be held by the ONU 4 is increased. Therefore, a long time is set as the maximum sleep time in the sleep time management table 410. On the other hand, as the UNI link speed increases, the amount of uplink frames received by the ONU 4 per unit time increases, and the time until the capacity accumulated in the queue buffer 405 reaches the upper limit is faster. A short time is set as the sleep time.

  For example, when the UNI link speed of the electrical transmission / reception unit 401 of the ONU 4 is 1 GBit / s and the capacity of the queue buffer unit 405 is 1 GBit, the ONU 4 of this embodiment has a maximum sleep time of 1 second. And when the UNI link speed | rate of the electric side transmission / reception part 401 of ONU4 is 100 MBit / s, maximum sleep time is 10 second.

  The sleep time management table 410 of this embodiment stores the maximum sleep time in an ideal network where the traffic usage efficiency is 100%. The maximum sleep time value may be determined according to traffic usage efficiency.

  Similarly, when the UNI link speed of the ONU 4 is 1 Gbit / s and the queue buffer 405 is 100 Mbit, the maximum sleep time is 0.1 second, and when the queue buffer 405 is 10 Mbit, the maximum sleep time is 0. 01 seconds.

  FIG. 8 is an explanatory diagram showing a frame format of a sleep control signal transmitted / received between the OLT 2 and the ONU 4 according to the embodiment of this invention.

  The frame format used for the sleep control signal of the present embodiment includes Y.I. Ethernet OAM (Operations Administration Maintenance: hereinafter referred to as Ethernet OAM) is used.

  The PDU (Protocol Data Unit: hereinafter referred to as PDU) of Ethernet OAM includes MEL (Maintenance Entity Group Level), Version, OpCode (Operation Code), Flags, TVL (Type, Length field, and Lu). It is stipulated in.

  The sleep control signal of this embodiment is transmitted and received by an optional VSM Data field of a VSM (Vendor-Specific OAM Message: hereinafter referred to as VSM) frame. The VSM field is a field that can be used independently by each vendor.

  The PDU in the VSM frame can hold vendor-specific information in the field by defining an OUI (Organizationally Unique Identifier) field and a SubOpCode field in addition to the above-described fields.

  In this embodiment, a Sleep Time Identifier (hereinafter referred to as STI) field and a Request Sleep Time (hereinafter referred to as RST) field are provided in the Optional VSM Data field in order to transmit and receive the sleep control signal. The STI field indicates whether the sleep control signal to be transmitted / received is a sleep time request signal 11, a sleep permission signal 12, a sleep state request signal 13, a sleep return request signal 14, a grant signal 15, or a sleep non-permission signal 16. Contains an identifying identifier. The RST field includes the maximum sleep time of the ONU 4 and stores a value defined by the sleep time management table 410.

  According to the present embodiment, the ONU 4 selects the longest possible maximum sleep time and enters the sleep state, thereby reducing the power consumption of the ONU 4 and improving the usage efficiency. The ONU 4 includes a sleep time management table 410 based on its UNI link speed and queue buffer capacity, and selects the maximum sleep time.

  The following are typical examples of aspects of the present invention other than those described in the claims.

  (1) An optical access system comprising an optical line device connected to another network, and an optical network device connected to the optical line device and a plurality of user terminals, wherein the optical network device is the optical network device. When a buffer capacity of a buffer provided in a device and a link speed between the optical network device and the user terminal are acquired, and no communication frame is transmitted from the user terminal or the optical line device for a predetermined time. A sleep time is determined based on the acquired buffer capacity and the acquired link speed, and the optical access system is in a sleep state at the determined sleep time.

  With the configuration of (1), the ONU selects a sleep state that is as long as possible from its own link speed and queue buffer capacity, so that it is possible to reduce the power consumption of the ONU when not communicating.

  (2) The optical network device transmits the determined sleep time to the optical line device, and the optical line device transitions to the sleep state after receiving the determined sleep time. The optical network device transmits permission to the optical network device, and the optical network device receives the permission from the optical line device to shift to the sleep state, and then shifts to the sleep state. An optical access system according to the first aspect.

  (3) After the determined sleep time has elapsed since the transition to the sleep state, the optical network device transmits the communication frame transmitted from the user terminal to the optical network device as a buffer of the optical network device. The determined sleep time is transmitted to the optical line device, and the optical line device has a buffer for accumulating the communication frame to be sent from the optical line device to the user terminal. And, after receiving the determined sleep time, if it is determined that the communication frame is not stored in a buffer provided in the optical line device, the optical network is permitted to enter the sleep state. The optical access system according to the second aspect, wherein the optical access system transmits to an apparatus.

  (4) The optical network device determines that the communication frame transmitted from the user terminal to the optical network device is accumulated in a buffer provided in the optical network device after the determined sleep time has elapsed. In such a case, the optical access system according to the third aspect, wherein a message to the effect of returning from the sleep state is transmitted to the optical line device.

  (5) The optical access system according to the first aspect, wherein the sleep time is longer as the acquired buffer capacity is larger and shorter as the acquired link speed is faster.

  (6) An optical network device connected to an optical line device connected to another network and connected to a plurality of user terminals, wherein the optical network device has a buffer capacity of a buffer provided in the optical network device, and , Acquiring a link speed between the optical network device and the user terminal, and when no communication frame is transmitted for a predetermined time from either the user terminal or the optical line device, the acquired buffer capacity; An optical network device characterized in that a sleep time is determined based on the acquired link speed and is in a sleep state at the determined sleep time.

  (7) The optical network device transmits the determined sleep time to the optical line device, receives from the optical line device that the optical network device is allowed to enter the sleep state, and then enters the sleep state. And when it is determined that the communication frame transmitted from the user terminal to the optical network device is stored in the buffer of the optical network device after the determined sleep time has elapsed, from the sleep state The optical network device according to the sixth aspect, wherein a message to the effect of returning is transmitted to the optical line device.

  (8) The optical network device according to the sixth aspect, wherein the sleep time is longer as the acquired buffer capacity is larger and shorter as the acquired link speed is faster.

  (9) An optical line device connected to an optical network device connected to a plurality of user terminals and connected to another network, wherein the optical line device sends the communication from the optical line device to the user terminal. A buffer for storing frames; when the sleep time determined by the optical network device is received from the optical network device and it is determined that the communication frame is not stored in the buffer provided in the optical line device; An optical line device transmitting to the optical network device that permission to enter a sleep state is transmitted.

  (10) After the elapse of the sleep time after the optical line device transmits to the optical network device that permission to shift to the sleep state is transmitted from the user terminal to the optical network device. When no frame is transmitted and there is no communication frame to be transmitted from the optical line device to the optical network device, transmission to the optical network device is permitted to permit transition to the sleep state. The optical line device according to the ninth aspect, which is characterized.

1 Upper network 2 OLT
3 Optical splitter 4 ONU
6 Terminal device 201 Electric side transmission / reception unit 202 Electric / optical conversion unit 203 Medium access control unit 204 Control unit 205, 205A, 205B Queue buffer unit 207 Sleep control signal processing unit 208 Sleep state management table 209 Sleep return time management table 210 Time counter 401 Electric side transmission / reception unit 402 Electric / optical conversion unit 403 Medium access control unit 404 Control unit 405 Queue buffer unit 406 Sleep control signal processing unit 407 Sleep state control unit 408 Sleep return time management table 409 Time counter 410 Sleep time management table 411 ONU Link speed management unit 412 ONU buffer amount management unit 11 Sleep time request signal 12 Sleep permission signal 13 Sleep state request signal 14 Sleep return request signal 15 Grant signal 16 Three Non-permission signal

Claims (9)

A master station device;
A slave station device that relays an upstream frame from the terminal device to the master station device,
The slave station device is
A buffer having a predetermined capacity for storing the upstream frame;
Transmitting a frame including an amount of uplink frames that can be stored in the predetermined capacity of the buffer and a sleep time determined based on a link speed between the own device and the terminal device to the master station device; A communication system. The sleep time is
The longer the amount of upstream frames that can be stored in the predetermined capacity of the buffer, the longer
The communication system according to claim 1, wherein the higher the link speed, the shorter. The slave station device is
The communication system according to claim 1, wherein the sleep state is a sleep state. The master station device is
When a frame including the sleep time is received, a frame permitting transition to the sleep state is transmitted to the slave station device,
The slave station device is
4. The communication system according to claim 3, wherein the communication system shifts to the sleep state when a frame permitting the shift to the sleep state is received. The communication system is:
An optical access system for optical communication,
The master station device is
OLT (Optical Line Terminal) constituting the optical access system,
The slave station device is
The communication system according to claim 4, wherein the communication system is an ONU (Optical Network Unit) that performs the optical communication with the OLT. A transmission / reception unit that transmits / receives a frame to / from the master station device;
A buffer unit having a predetermined capacity for storing the frame;
A receiving unit that receives the frame from a terminal device that transmits the frame to the master station device;
Sleep time determined based on the amount of the frame to the master station device that can be stored in the predetermined capacity of the buffer unit with respect to the transmitting / receiving unit and the link speed between the receiving unit and the terminal device And a control unit that transmits a frame including the frame to the parent station device. Configure the optical access system with the master station device,
The slave station apparatus according to claim 6, wherein the control unit sets the own apparatus to a sleep state during the sleep time. A transmission / reception unit that transmits / receives a frame to / from a slave station device;
For the transmission / reception unit, the amount of uplink frames to the own device that can be stored in the predetermined capacity of the buffer unit having a predetermined capacity included in the slave station device, and the terminal device connected to the slave station device and the A master station apparatus comprising: a control unit that transmits a first frame including a sleep time determined based on a link speed with a slave station apparatus to the slave station apparatus. Configure the optical access system with the slave station device,
The first frame further includes information allowing the slave station device to enter a sleep state during the sleep time,
A buffer unit for storing frames to be transmitted to the slave station device;
The controller is
When a second frame including information indicating that there is no frame from the local station device to the local device and the sleep time is received via the transmission / reception unit, a frame to be transmitted to the local station device to the buffer unit The base station apparatus according to claim 8, wherein when determining whether or not is stored, and when it is determined that the first frame is not stored, the transmission / reception unit transmits the first frame.

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