JP5456131B2 - Communication method, optical communication system, user side optical line terminator, station side optical line terminator - Google Patents

Description

  The present invention relates to a communication system and a communication method in which a plurality of terminals are connected by a common line, for example, an OLT (Optical Line Terminal) and a plurality of ONUs (Optical Network Unit). PON (Passive Optical Network) system and the like.

  In the PON system, communication is performed while synchronizing between the OLT and the ONU so that uplink data transmitted from the ONU does not collide. The OLT plans to give transmission permission to each ONU so that uplink data does not collide. At this time, the delay due to the distance to each ONU is considered. For this reason, the OLT measures the round trip time between each ONU. However, in transmission using an optical fiber, there are fluctuations in the transmission path such as jitter and wander, and therefore it is necessary to perform measurement periodically.

  On the other hand, data communication is not always performed. For example, no data communication is performed at night. However, the round trip time is measured periodically regardless of the presence or absence of data communication as described above. Even when data communication is not performed, it is wasteful to make the ONU always communicable for round trip time measurement. For this reason, a technique for making an ONU transition to a power saving state intermittently by requesting a transition from the ONU to a power saving state has been studied.

  Also, a PON system that improves throughput without assigning a useless transmission band to such an ONU when there is no uplink data from the ONU has been studied (Patent Document 1). In this PON system, when the OLT detects that there is no user data for a preset period, the OLT cancels the registration of the ONU and notifies the ONU that the optical link is temporarily stopped. Thereafter, no transmission band is allocated to the ONU, and transmission of a frame for maintaining the link is also suppressed, so the ONU can reduce the number of frame transmissions.

JP 2007-274534 A

  In the PON system described in Patent Document 1, since the link is disconnected for the ONU that does not transmit constant data, the load on the ONU can be reduced. However, when the ONU resumes uplink data transmission, discovery processing for finding an unconnected ONU is performed again, a new link is established, and the ONU is re-registered. Therefore, for example, when communication at a low bit rate is continued, this communication method cannot be used. In addition, since the OLT disconnects the link with the ONU, if a communication abnormality occurs in the ONU or the upstream communication line itself, the abnormality cannot be detected. Furthermore, since the OLT deletes the registration of the ONU, the ONU in the communication abnormality state is not found even by the discovery process, and it becomes difficult to find the communication abnormality.

Communication method of the present invention is a communication method of an optical communication system connecting to the OLT using a plurality of ONU common optical fiber, OLT is a sleep mode to repeat an Tokikyu stop and temporary activation of the optical transmitter for the operation is possible ONU in temporary allocated transmission bandwidth for transmitting the response signal at startup, the transmission bandwidth notification transmitted to the ONU, OLT, the transmission bandwidth assignment period for the ONU has shifted to the sleep mode Is set to be longer than the transmission band allocation period for the ONU before the transition to the sleep mode, and a sleep period during which the optical transmitter is allowed to pause is transmitted to the ONU .

ONU of the present invention is connected to an optical fiber, the transmitter stops the predetermined sleep period temporarily, the operation in the sleep mode that reduces power consumption by repeatedly to temporarily start after the sleep period possible optical transceiver, and when the transmission bandwidth by the OLT assigned during the sleep mode, a control device for transmitting a response signal to the OLT in the optical transceiver, the allocation of the transmission band in the case of transition to the sleep mode period, rather long than assignment cycle of the transmission band before entering the sleep mode, the controller is in a sleep period between the transmission band and the subsequent transmission band allocated in time division by the OLT optical transceiver The transmission unit is temporarily stopped, and activation control is performed to temporarily activate the transmission unit of the optical transceiver in order to transmit a response signal in the transmission band after the sleep period .

OLT of the present invention, an optical transceiver connected to an optical fiber, and the optical transmitter and one Tokikyu stopped predetermined sleep period, the operation in the sleep mode to repeat that temporarily start the optical transmitter after the sleep period for possible ONU, one o'clock allocated transmission bandwidth for transmitting the response signal at startup, the transmission bandwidth notification transmitted to the ONU, the transmission bandwidth assignment period for the ONU has shifted to the sleep mode, the process proceeds to the sleep mode And a control device for transmitting to the ONU a sleep period that is longer than the transmission band allocation period for the previous ONU and permits the optical transmitter to pause .

  The communication method, the optical communication system, the station side optical line terminator, and the user side optical line terminator according to the present invention can detect a failure in a power saving operation by intermittent communication.

FIG. 1 is a configuration diagram showing a configuration of a communication system according to an embodiment of the present invention. FIG. 2 is a sequence diagram showing a communication method according to Embodiment 1 of the present invention. FIG. 3 is a flowchart showing OLT communication control in Embodiment 1 of the present invention. FIG. 4 is a flowchart showing ONU communication control in Embodiment 1 of the present invention. FIG. 5 is a sequence diagram showing a communication method (when a failure occurs) in Embodiment 1 of the present invention. FIG. 6 is a sequence diagram showing a communication method (when the power is turned off) in the first embodiment of the present invention. FIG. 7 is a sequence diagram showing a communication method (modification) according to Embodiment 1 of the present invention. FIG. 8 is a sequence diagram showing a communication method according to Embodiment 2 of the present invention. FIG. 9 is a flowchart showing OLT communication control according to the second embodiment of the present invention. FIG. 10 is a flowchart showing ONU communication control according to Embodiment 2 of the present invention. FIG. 11 is a sequence diagram showing a communication method (when a failure occurs) in Embodiment 2 of the present invention. FIG. 12 is a sequence diagram showing a communication method (when the power is turned off) in the second embodiment of the present invention. FIG. 13 is a sequence diagram illustrating a communication method (modification) according to Embodiment 2 of the present invention. FIG. 14 is a flowchart showing OLT communication control (modification) according to Embodiment 2 of the present invention.

Embodiment 1 FIG.
・ Hardware configuration

  FIG. 1 is a diagram showing a configuration example of a first embodiment of a PON system according to the present invention. As shown in FIG. 1, the PON system of the present embodiment includes an OLT 1 and ONUs 10-1 to 10-3. The OLT 1 and the ONUs 10-1 to 10-3 are connected by a subscriber line 30 via a splitter 40. The splitter 40 branches the subscriber line 30 connected to the OLT 1 into the number of ONUs 10-1 to 10-3. The ONU 10-1 is connected to the terminals 20-1 and 20-2. Although an example in which three ONUs are used is shown here, the number of ONUs is not limited to this, and any number may be used.

  The OLT 1 includes a PON control unit 2 that performs processing on the OLT side based on the PON protocol, a reception buffer 3 that is a buffer for storing uplink data received from the ONUs 10-1 to 10-3, and an ONU 10-1 to A transmission buffer 4 that is a buffer for storing downlink data to be transmitted to 10-3, an optical transceiver 5 that performs transmission / reception processing of optical signals, and a WDM (Wavelength Division Multiplexing) coupler that wavelength-multiplexes uplink data and downlink data (WDM) 6 and a physical layer processing unit (PHY) 7 for realizing an NNI (Network Node Interface) physical interface function between the network and the network. The optical transceiver 5 includes an optical receiver (Rx: Receiver) 51 that performs reception processing, and an optical transmitter (Tx: Transmitter) 52 that performs transmission processing.

  The ONU 10-1 includes a PON control unit 11 that performs processing on the ONU side based on the PON protocol, a transmission buffer (upstream buffer) 12 that is a buffer for storing transmission data (upstream data) to the OLT 1, and an OLT 1 Receive buffer (downlink buffer) 13 which is a buffer for storing received data (downlink data), an optical transceiver 14, a WDM 15 for wavelength-multiplexing uplink data and downlink data, and terminals 20-1, 20- 2, physical layer processing units (PHYs) 16-1 and 16-2 for realizing a physical interface function of UNI (User Network Interface).

  The optical transceiver 14 includes an optical transmitter (Tx: Transmitter) 141 that performs transmission processing and an optical receiver (Rx: Receiver) 142 that performs reception processing. The PHY 16-1 includes a reception unit (Rx: Receiver) 161-1 that performs reception processing and a transmission unit (Tx: Transmitter) 162-1 that performs transmission processing. The PHY 16-2 performs reception processing. It has a receiving unit (Rx: Receiver) 161-2 and a transmitting unit (Tx: Transmitter) 162-2 that performs transmission processing.

  Although two terminals are connected to the ONU 10-1, the number of terminals is not limited to this, and any number of terminals may be provided, and a physical layer processing unit (PHY) corresponding to the number of terminals is provided. Further, in FIG. 1, a configuration example of the ONU 10-1 is shown as a representative, but the ONUs 10-2 and 10-3 have the same configuration as the ONU 10-1.

  Similar to the conventional PON system, the PON control unit 2 of the OLT 1 performs upstream data bandwidth allocation so as to give transmission permission to the ONUs 10-1 to 10-3 so that the transmission time zones do not overlap with each other. -1 to 10-3 transmission data collision is prevented. Any method may be used for this bandwidth allocation. For example, “Su-il Choi and Jae-doo Huh”, “Dynamic Bandwidth Allocation Algorithm for Multimedia Services over Ethernet (registered trademark) PONs”, ETRI Journal, Dynamic Bandwidth Allocation Algorithm described in “Volume 24, Number 6, December 2002, p. 465 to p. 466” can be used.

  Next, the overall operation of the OLT 1 and the ONUs 10-1 to 10-3 of this embodiment will be described. The PON control unit 2 stores downlink data (downlink communication data) received from the network via the PHY 7 in the transmission buffer 4. When transmitting data from the OLT 1, the PON control unit 2 reads the downlink data stored in the transmission buffer 4 and outputs it to the optical transceiver 5, and the Tx 52 of the optical transceiver 5 uses the transmission data as an optical signal. The WDM 6 performs wavelength multiplexing on the optical signal output from the optical transmitter / receiver 5 and outputs it as a downstream signal to the ONUs 10-1 to 10-3 via the subscriber line 30. When the PON control unit 2 transmits a control message such as transmission band allocation for transmitting a transmission permission instruction, the control message generated by the PON control unit 2 is output to the optical transceiver 5, Like the data, it is transmitted to the ONUs 10-1 to 10-3. In the PON system of FIG. 1, the WDMs 6 and 15 are used for wavelength multiplexing, but the WDMs 6 and 15 are not essential when communicating at a single wavelength.

  In the ONUs 10-1 to 10-3, when receiving a downlink signal from the OLT 1, the WDM 15 separates the downlink signal and outputs it to the optical transceiver 14, and the Rx 142 of the optical transceiver 14 converts the downlink signal into downlink data of an electrical signal. And output to the PON control unit 11. The PON control unit 11 stores the downlink data output from the Rx 142 of the optical transceiver 14 in the reception buffer 13. The PON control unit 11 reads the downlink data stored in the reception buffer 13 and outputs it to both or one of the PHYs 16-1 and 16-2 according to the destination of the data. The PHYs 16-1 and 16-2 that have received the downlink data perform predetermined processing on the downlink data and transmit the downlink data to the terminals 20-1 and 20-2 to which they are connected.

  On the other hand, when transmitting upstream data from the ONUs 10-1 to 10-3, the PON control unit 11 transmits upstream data acquired from the terminals 20-1 and 20-2 via the PHYs 16-1 and 16-2. Store in 12. The upstream data stored in the transmission buffer 12 is read out based on the transmission band given from the OLT 1 and output to the optical transceiver 14. The Tx 141 of the optical transceiver 14 converts the upstream data into an optical signal (upstream signal) and transmits it to the OLT 1 via the WDM 15 and the subscriber line 30.

  The PON control unit 2 of the OLT 1 stores the uplink data received from the ONUs 10-1 to 10-3 via the subscriber line 30, the WDM 6, and the Rx 51 of the optical transceiver 5 in the reception buffer 3. The PON control unit 2 reads the uplink data stored in the reception buffer 3 and outputs it to the network via the PHY 7.

  Further, the ONUs 10-1 to 10-3 receive control messages from the OLT 1 by the PON control unit 11 via the WDM 15 and the Rx 142 of the optical transceiver 14 and execute operations based on the instructions of the control messages. Generate a response to.

-Power Save Operation Next, as an example of the power saving operation of the communication system, the power save operation of the PON system will be described with reference to FIG.

(d1)-(d2) & (u1)-(u2) Communication in the normal operation state In FIG. 2, after the discovery process is completed and communication in the normal communication state (Normal mode) is started The sequence is shown. In FIG. 2, only one ONU 10 is shown, but in actuality, OLT 1 communicates with a plurality of ONUs 10 in the same manner. In the PON system, the uplink transmission (uplink) is allocated to a plurality of ONUs 10 by time division multiplex communication. In order to control this time division multiplexing, the OLT 1 transmits a permission signal (Grant) for permitting communication by designating the transmission band Bw to the ONU 10. Since the transmission band can also be referred to as a transmission time, in other words, the OLT 1 allocates a transmission time to the ONU 10 and transmits a permission signal. Grant includes information that can identify each ONU 10, a communication start time, and a communication end time (or communication duration time).

  The ONU 10 transmits uplink data (Data) in a designated band designated by this Grant. The OLT 1 receives the uplink data in the transmission band Bw, relays the data to the host device existing on the core network side, and detects a communication failure with the ONU 10. Here, if the uplink data has not been transmitted in the designated transmission band Bw, the OLT 1 determines that there is an abnormality in the ONU 10 corresponding to this transmission band. This communication failure monitoring will be described later.

(d3)-(d8) & (u3)-(u8) Communication in power saving state When ONU10 is able to communicate in power saving state or when communication in power saving state is required, The ONU 10 notifies the OLT 1 that a transition to the power saving state is made. For this notification, any request signal may be used. For example, a Dying_Gasp signal is transmitted.
Upon receiving this notification, the OLT 1 detects that the ONU 10 has entered the power saving state, and pauses the bandwidth allocation to the ONU 10 for a predetermined period (sleep time). In this communication method, an arbitrary value can be set as the sleep time. However, since it is difficult to maintain the link normally for a long time such as one hour unit, for example, a short period such as milliseconds is designated. .

  When the ONU 10 transitions to the power saving state, the ONU 10 turns off the laser power of the Tx 141 of the optical transceiver 14 and controls it to the off state. At this time, the ONU 10 does not cut the power of the Rx 142 of the optical transceiver 14 and continues to receive the control signal and the downlink data from the OLT 1. On the other hand, the OLT 1 also does not transmit Grant to the ONU 10 that has shifted to the power saving state, but transmits other control signals and downlink data. In FIG. 2, the power supply state of Tx141 of the ONU 10 is indicated by “ON” and “OFF” on the right side of the ONU sequence. In the power saving state, that is, in the sleep mode, the power supply is repeatedly turned on and off repeatedly during that period. A period indicated by “OFF” is a stop period in which the laser power of Tx141 is stopped. Between intermittent stop periods, the ONU 10 starts Tx 141 and creates a temporary wake-up time. “Sleep time” is a predetermined time length. In this example, the absolute time of the stop period is specified based on the start time of the band update cycle. In FIG. 2, the “Sleep time” and the “OFF” period do not coincide with each other, but this is because the ONU 10 that has transmitted the uplink data cuts the supplied power without waiting for the next bandwidth update period. In another embodiment, the present invention is not limited to this example, and the “Sleep time” and the “OFF” period may be matched.

  The OLT 1 measures the sleep time for each ONU 10 and transmits a grant to the ONU 10 when the sleep time elapses (d6). This Grant is transmitted to temporarily wake up the ONU 10 in the power saving state. When the ONU 10 receives a grant from the OLT 1 during this temporary start-up time, the ONU 10 temporarily supplies laser power to the Tx 141 of the optical transceiver 14 even when operating in the power saving state, and turns it on. Since the end time of the sleep time is known, the ONU 10 can turn on the power supply without waiting for the bandwidth allocation notification from the OLT 1. When the ONU 10 continues the power saving state, it resends the sleep request as described in (u3) above, and again turns off the laser power of Tx141 of the optical transceiver 14 and shifts to the power saving state (u6). ).

  The OLT 1 observes the band assigned to the ONU 10 in the power saving state, and detects whether the request signal is normally sent. At this time, if a signal is not normally transmitted from the power saving ONU 10, it is determined that a failure has occurred in the uplink communication path or the ONU 10 itself, and an alarm is issued. The operation when this failure occurs will be described later with reference to FIG.

(d9)-(d10) & (u9)-(u10) Communication at the time of power saving cancellation When it is necessary to cancel the power saving state, such as when a large amount of data transmission is required with ONU10, after the sleep time The ONU 10 requests cancellation of the power saving state during the temporary activation time. The cancellation of the power saving state may be performed by the ONU 10 transmitting a specific signal, but can also be realized by transmitting, for example, valid uplink data in a designated band. By canceling the power saving state by transmitting valid uplink data, transmission bits are saved and the band of transmission data can be used effectively.

  Similar to the operation after (d6) described above, the OLT 1 performs failure detection by observing the band allocated to the power saving ONU 10 after the timing (d9). At the same time, when the ONU 10 transmits a power saving request, the OLT 1 continues to operate in the power saving state for the ONU 10, but when the power saving state release request is received as described above, The operation in the state is canceled, and the operation in the normal operation is started for the ONU 10.

  According to the above-described operation, the OLT 1 can permit the power saving operation by the ONU 10 while maintaining the link to the ONU 10, and at the same time, when a failure occurs in the communication with the ONU 10 that does not normally transmit data. But it can detect the failure early. Furthermore, the ONU 10 can suppress the power consumption by stopping the laser power supply to the Tx 141 of the optical transmitter / receiver 14, and also in the communication necessary for fault monitoring, the bandwidth update cycle can be reduced by the thinned Grant. The power consumption can be reduced compared to the case where some signal transmission is forced every time.

The transmission band allocation cycle is a cycle in which the OLT 1 notifies the transmission band allocation and allocates the transmission band to the ONU 10. The above-mentioned thinned Grant is a grant having a longer transmission bandwidth allocation interval than the power saving ONU 10 operating in the normal state.
The transmission band allocation period allocated to the power saving ONU 10 may be determined in any way. For example, the transmission band allocation period may be a value that matches the detection time T of the MPCP (Multi-Point Control Protocol) timeout alarm. You can have it. If the transmission bandwidth allocation period is set longer than the MPCP timeout time, the ONU 10 in the sleep mode is caught by the MPCP timeout, so the OLT 1 sets the transmission bandwidth allocation period below the MPCP timeout time. In addition, when the ONU 10 is provided with a plurality of (n) transmission periods and is not received once, an unnecessary alarm or the like is suppressed when it is determined that the MPCP time-out occurs. Therefore, for example, when the MPCP timeout T milliseconds is set, the OLT 1 sets the transmission bandwidth allocation period to T / n milliseconds.

  Moreover, since the link between OLT1 and ONU10 is maintained, even if user terminals are continuing communication, power consumption can be reduced.

・ Details of OLT communication control

Next, details of the communication processing of the OLT 1 will be described with reference to FIG.
FIG. 3 shows the processing of the PON control unit 2 (PON controller) of the OLT 1. First, the PON control unit 2 specifies an ONU 10 to which an uplink transmission band is to be allocated based on a list (ActiveONUList) of ONUs 10 discovered and found by discovery, and allocates a transmission band to each ONU 10 (step S1). ). At this time, for example, when the transmission band of one cycle is divided into N, the identifier ID of the corresponding ONU 10 is given by id _bw = ONU [bw], bw = 1, 2,.
Since the ONU 10 during power saving is excluded in the ActiveONUList, the PON control unit 2 can perform dynamic band allocation so that the transmission band is not allocated to the ONU 10 during power saving operation by referring to this list. .

  Next, the PON control unit 2 collects Grant and downlink data into frames, controls the transceiver 5 and transmits this frame to the ONU 10 (step S2). Grant and downlink data may be transmitted in the same frame, or may be transmitted in separate frames.

Subsequently, the PON control unit 2 performs reception processing for each transmission band received by the Rx 51 in the following steps (step S3).
First, the PON control unit 2 specifies the ONU 10 assigned to the next transmission band (step S4). At this time, Rx51 of the transceiver 5 performs uplink reception simultaneously and the PON control unit 2 reads the data received by Rx51 into the internal memory or the like for processing (step S5). The PON control unit 2 checks the type of the received uplink signal (step S6). If there is no valid signal, the process goes to step S17. If the request signal (Dying_gasp) for the power saving state is detected, step S12 is performed. If it is a data signal or the like, the process of step S7 is performed.

  In step S7, the PON control unit 2 checks the transmission source ONU 10 of the received data, and if this ONU 10 is not included in the ActiveONUList, adds it to the ActiveONUList. Here, the OLT 1 detects that the ONU 10 in the power saving state has canceled the power saving state when the ONU 10 has transmitted normal data.

  The received data includes a bandwidth request from the ONU 10, and the PON control unit 2 reads the bandwidth request from the received frame and associates it with the identifier (ID) of the ONU 10 for the next bandwidth allocation in step S1. This bandwidth request is recorded in the memory (step S8). The bandwidth request is expressed by the amount of data accumulated (occupancy) in the transmission buffer 12 of the ONU 10. A method in which the ONU 10 transmits a report on the occupancy of the transmission buffer 12 and the OLT 1 performs dynamic bandwidth allocation based on the report is referred to as SR-DBA (status reporting DBA). The bandwidth request does not need to be explicitly made, and the allocated bandwidth can be adjusted by observing the data amount actually transmitted by the ONU 10 with respect to the bandwidth allocated by the OLT 1 to the ONU 10. This is called TM-DBA (traffic-monitoring DBA). In step S8, this TM-DBA may observe traffic.

Next, the PON control unit 2 transmits the reception data held in the reception buffer 3 to the network via the PHY 7 (step S9).
The PON control unit 2 constantly monitors the uplink communication state with each ONU 10. If the ONU 10 cannot receive the expected frame at the transmission timing of the frame, an alarm signal LOSI (Loss of signal for ONUi) is output. This alarm signal is an alarm necessary for network management. When LOSi occurs, it is notified to the network operator, and the network operator takes trouble countermeasures based on this LOSi. Step S10 is a process of clearing the fault count for this LOSi. LOSi is, for example, a true fault that is output when the signal cannot be received continuously from the i-th ONU 10 four times, and the fault count is a variable that counts the number of consecutive non-receptions. is there. The PON control unit 2 counts up the LOSi count in step S17 described later.

  When the process of step S10 is completed, the PON control unit 2 returns to the beginning of the loop process of step S3 to process the next band. This loop process is a process of repeating the process for the bw th band from the 1st to the Nth.

Next, a process when the OLT 1 receives a sleep request (Dying_Gasp) signal in step S6 will be described.
In this embodiment, there are two types of Dying_Gasp. One is Dying_Gasp (0) that is output when the ONU 10 cuts off the link and turns off the power, and the other is Dying_Gasp (1) that the ONU 10 outputs as a sleep request. The Dying_Gasp signal has a format including a signal identifier indicating that it is a Dying_Gasp signal, an ID of the ONU 10, and a flag (option) indicating that it is a sleep request. The PON control unit 2 checks whether the Dying_Gasp signal received in step S12 is a sleep request, and if it is a sleep request, that is, a Dying_Gasp (1) signal, proceeds to the process of step S13.

  In step S12, the PON control unit 2 detects that the ONU 10 has shifted to the power saving state, and records this. Specifically, the ID of the ONU 10 is excluded from the ActiveONUList that is the transmission band allocation target list. Perform the process. The PON control unit 2 sets a sleep time timer for the i-th ONU 10 in order to measure the power saving period (step S14). The sleep time may be a time stored in advance by the OLT 1 or a time calculated based on the communication status, or a specific time may be acquired from the ONU 10 and this value may be set. The sleep time can be measured by any method as long as the power saving period can be determined, such as a relative time lapse measurement that counts up or down according to a predetermined elapsed time, a clock It is also possible to carry out by absolute time observation specifying the absolute time of. Next, the PON control unit 2 proceeds to the above-described uplink data reception process (step S9) and repeats the same process. If Dying_Gasp (1) and upstream data can be transmitted in the same band (or frame), even if the ONU 10 leaves only a small data fragment in the transmission buffer 12 and completes the data transmission, it will immediately save power. There is an advantage that you can enter. On the other hand, in a situation where a power saving state is possible, the ONU 10 often does not have uplink data. Therefore, when a sleep request is received, the specification may be such that the uplink data of this frame is not processed.

  On the other hand, if it is determined in step S12 that Dying_Gasp (0) has been received, the PON control unit 2 detects that the ONU 10 has been turned off (step S15), and the ONU 10 is While removing from the ActiveONUList, a process of deleting the link information and resources allocated to the ONU 10 is performed. At this time, the OLT 1 transmits a Deactivate signal (Deactivate_ONU-ID) instructing the ONU 10 to discard all information such as link information and link information. The ONU 10 receives this signal and turns off the power of the optical transceiver 14. When this process ends, the PON control unit 2 returns to the process of step S3 in order to process the next band again.

  Step S17 is processing when a valid signal is not received in the transmission band assigned to the ONU 10 in step S6, and the PON control unit 2 detects a communication failure by this processing. Here, in a system having a power saving mode in which the Tx 141 of the optical transceiver 14 is simply turned off to be in the power saving state, the ONU 10 in the power saving state naturally does not transmit uplink data or the like, so the OLT 1 Failure detection is not possible. In this embodiment, the OLT 1 also temporarily allocates a transmission band to the ONU 10 that is in power saving operation, and the ONU 10 also temporarily turns on the power of the Tx 141 after the sleep time and transmits the frame. Therefore, in step S6, an uplink communication failure can be detected based on whether or not the ONU 10 transmits a frame to the assigned transmission band. Here, when the frame cannot be received in the band, the PON control unit 2 counts up the variable LOS [i] for counting the number of non-reception times for the i-th ONU 10.

  When the variable LOS [i] reaches a predetermined number LOS_Max (for example, 4), the PON control unit 2 determines that a communication abnormality has occurred in the uplink of the ONU 10 and sets the above alarm LOSi. (Step S19). Further, the PON control unit 2 proceeds to the process of step S16 and disconnects the link. On the other hand, if the variable LOS [i] has not reached LOS_Max, the PON control unit 2 returns to the process for the next band (step S3) without issuing an alarm.

  After performing the above processing for all the transmission bands within one band update period, the PON control unit 2 checks each ONU 10 in power saving operation for an ONU 10 whose sleep time has expired. If an ONU 10 whose sleep time has expired is found, the ID is added to the ActiveONUList in order to temporarily activate the ONU 10 (step S20). This process enables the monitoring operation of the ONU 10 during the power saving operation described in steps S17 to S19. In addition, when the ONU 10 continues the power saving state, the sleep request is sent back using the transmission band assigned in step S1, so that the ONU 10 can continue the operation with reduced power consumption while maintaining the link. it can.

  Next, the PON control unit 2 determines whether or not to continue the operation of the next band update cycle, and if so, returns to the process of step S1 and restarts the above-described operation.

・ Details of ONU communication control

Next, details of the communication processing of the ONU 10 will be described with reference to FIG.
FIG. 4 is a flowchart showing communication control executed by the PON control unit 11 of the ONU 10. Communication control is roughly divided into downlink reception control (steps S30 to S33) and uplink transmission control (S35 to S51).

Downlink Reception Control First, downlink reception control will be described. The Rx 142 of the optical transceiver 14 receives the downlink frame transmitted from the OLT 1 and records the received data in the reception buffer 13. The PON control unit 11 observes the frame received by the optical transceiver 14 (step S30), and extracts uplink transmission band information from the header information included in the frame (step S31). The transmission band information includes information that can identify the ONU 10 to be allocated, and information that can identify the transmission start time and the transmission end time.

  The PON control unit 11 also extracts the payload portion from the received frame and outputs it to the higher layer processing means (step S32). This process is a process for transmitting data received by a higher-level protocol matched to the terminals 20-1 and 20-2 connected to the ONU 10. Next, the PON control unit 11 determines whether to end the reception control and turn off the power. When the reception is continued without turning off the power, the process returns to step S30 and the above-described reception control is continued.

Uplink Transmission Control Next, uplink transmission control will be described.
The PON control unit 11 waits for transmission band allocation (Grant) from the OLT 1 in step S35. When the transmission band is allocated, the PON control unit 11 supplies power to the Tx 141 of the optical transceiver 14 to turn on the laser power (step S36). Since this process is particularly necessary when returning from the power saving state, when the Tx 141 is already in the ON state during operation in the normal operation state, it is not necessary to perform the process of starting the power supply again.

  Here, the PON control unit 11 instructs the power supply to the Tx 141 before the actual transmission band start time and before the time until the optical output is stabilized after the Tx 141 of the optical transceiver 14 is activated. To do. The bandwidth update cycle of this embodiment is a very short cycle, and the transition from the power saving state to the temporary wake-up state is performed in a very short time and frequently. Therefore, if the activation is performed immediately before the transmission time without considering the behavior of the optical output at the time of activation of Tx141, there are effects such as inability to receive and deterioration of error rate in OLT1. Therefore, as shown in FIG. 4, when the transmission band detects the allocation, the PON control unit 11 starts the power supply of Tx141. After this, other frame creation work is performed, and the PON control unit 11 actually transmits the frame in the subsequent step S46.

  Next, the PON control unit 11 detects the data accumulation state of the transmission buffer 12 and the operation state of the connected devices on the downstream side such as the terminals 20-1 and 20-2 (step S37), and the power saving state (Sleep mode). It is determined whether or not to make a transition to (step S38). For example, when the OLT 1 determines that the data accumulation state of the transmission buffer is a state where there is no data, or that there is only a small amount of data accumulated below a predetermined threshold value for a predetermined period and there is a margin, the power saving state It is determined that the transition is made. It should be noted that since the uplink is maintained when in the power saving state, the ONU 10 can transmit data in a relatively small band with respect to the capacity of the transmission buffer and the transmission speed of the communication line. Other examples of criteria for the ONU 10 to transition to the power saving state include: (1) the number of terminals in the power supply state and the ON state of each terminal, the number of terminals that have a communication response, and (2) connected terminals (here For example, whether or not all of the terminals 20-1 and 20-2) have entered the power saving state is detected by a method such as LPI reception defined in IEEE 802.3az.

  If it is determined that the power saving state is not changed, the PON control unit 11 creates a transmission payload based on the transmission data stored in the transmission buffer 12 (step S39). This payload is data processed and created in an upper layer. Subsequently, a status report is created based on the data occupancy rate of the transmission buffer 12 and the like in order to secure the transmission band of the next cycle (step S40). This is represented by the ratio of the data actually stored in the buffer to the buffer size indicated by the PON control unit 11 by, for example, a protocol such as OMCI (Optical Network Unit Management and Control Interface). A ratio is encoded by a predetermined encoding method to generate a report. The status may be created based on any standard as long as uplink communication traffic is known. In addition, this report is not mandatory when using TM-DBA.

  On the other hand, when transitioning to the power saving state, the PON control unit 11 records information (flag) that transitions to the power saving state in the built-in memory in order to shift to the power saving state in step S50 described later. Further, the PON control unit 11 generates a Dying_Gasp (1) signal that is a sleep request (step S51).

  In step S41, the PON control unit 11 determines whether to turn off the ONU 10 or not. When the power is turned off, the PON control unit 11 creates this signal to insert the Dying_Gasp (0) signal into the transmission frame and transmit it to the OLT 1 (step S42). When the power is turned off, the power supply to the optical transmitter / receiver 14 including the Rx 142 is stopped, and the ONU 10 becomes incapable of both transmission and reception. Therefore, the PON control unit 11 actually turns off the power after step S49 when the necessary transmission processing is completed.

  The PON control unit 11 collects the various signals created in the above steps and creates a frame that accommodates them (step S44). At this time, the PON control unit 11 creates a frame header (step S43) and inserts it into the frame.

  When the frame creation is completed, the PON control unit 11 waits until the transmission start time specified by the transmission band information extracted in step S31 (step S45), and starts frame transmission (step S46). When the transmission of the frame is completed, the PON control unit 11 determines whether or not a transition to the power saving state (Sleep mode) is made (step S47). When the transition to the power saving state is made, the power supply of Tx141 is stopped (step S41). S48). Specifically, the PON control unit 11 can place the Tx 141 in a power saving state by transmitting an electrical signal such as power down or shutdown to the Tx 141 of the optical transceiver 14. By this process, the PON control unit 11 creates an intermittent transmission stop period (a stop period of the transmission unit) in the sleep mode.

Finally, the PON control unit 11 determines whether to turn off the power supply or wait for the next transmission (step S49). When turning off the power supply, the optical transceiver 14 and the like are turned off and the process is performed. finish. Here, if the Dying_Gasp (0) signal is not correctly transmitted to the OLT1 due to a single communication error, an unnecessary alarm will frequently occur in the OLT1, so the Dying_Gasp (0) signal is transmitted several times before the power is turned off. The power can be turned off. In this case, the PON control unit 11 counts the number of transmissions of the Dying_Gasp (0) signal in step S49, and returns to the process of step S35 until the predetermined number is reached.
On the other hand, if it is determined that the power is not turned off, the PON control unit 11 returns to step S35 and repeats the same processing as described above.

・ Operation when failure occurs

Next, the operation of the communication system when a communication failure occurs will be described.
FIG. 5 is a sequence diagram showing a case where a communication failure occurs in the ONU 10 operating in the power saving state. The ONU 10 shifts to the power saving state after the transmission timing (u3), and then receives a large amount of transmission data from the terminal 20-1 and attempts to return from the power saving state after the timing (u4). Here, if a communication failure occurs in the subscriber line 30, data cannot be transmitted. Since OLT1 knows that ONU10 does not transmit data by turning off the power of Tx141 of optical transceiver 14, from the viewpoint of OLT1, there is no abnormality even if there is no uplink communication temporarily, and OLT1 is abnormal It is not possible to detect that has occurred. However, in the communication system of this embodiment, while the upstream communication of the ONU 10 is suppressed during the sleep time, the transmission band is temporarily allocated to the ONU 10 in the power saving state after the sleep time (d6). Therefore, the OLT 1 can detect whether there is a communication abnormality (Loss of Signal for ONUi) on the link with the ONU 10 in the power saving state by observing the bandwidth allocated in (d6).

  In the example of FIG. 5, when there is no response signal from the ONU 10 in the bandwidth Bw assigned at the timing (d6), the bandwidth Bw is assigned to the ONU 10 at the subsequent timing (d7), and the bandwidth is observed twice in total. The LOSi alarm is output based on the observation results of the second band. Note that this bandwidth allocation need not be performed at successive bandwidth update cycles, and may be sent intermittently. In addition, an arbitrary number of observations can be set.

The OLT 1 that has output the alarm LOSi disconnects the link with the ONU 10 and outputs a Deactivate_ONU-ID three times to notify the ONU 10. The ONU 10 that has received the Deactivate_ONU-ID must detect the disconnection of the link, discard the information held regarding the link, and stop data transmission. Thereafter, the ONU 10 shifts to a standby mode for waiting for communication from the OLT 1.
In order for the ONU 10 to reconnect to the OLT 1 after the link is disconnected, the ONU 10 responds to the discovery request transmitted from the OLT 1 and registers itself in the OLT 1. The OLT 1 registers the ONU 10 by discovery and does not allocate a transmission band to the ONU 10 until a link is established.

・ Operation when the power is off

Next, an operation when the ONU 10 is turned off will be described.
FIG. 6 is a sequence diagram for explaining a case where the power is turned off after the ONU 10 is in the power saving state. Until the timing (u8), the ONU 10 operates in the power saving state. However, for example, when the user performs an operation to turn off the power of the ONU 10, it is necessary to start the power-off operation of the ONU 10. At this time, if the ONU 10 immediately turns off the power from the power saving state, the OLT 1 cannot detect this and emits LOSi. Therefore, the ONU 10 waits until bandwidth allocation after the sleep time (d9), transmits a Dying_Gasp (0) signal to the OLT 1 (u9), and then turns off the power.
On the other hand, since the OLT 1 has also received the Dying_Gasp (0) signal, it can recognize that a communication failure has occurred with the ONU 10 or has not returned from the sleep state, so that unnecessary alarm output can be prevented.

・ Sleep time variable setting and Acknowledgment

  FIG. 7 shows a sequence of a communication method for determining the sleep time in the power saving state by signaling. When the ONU 10 outputs a sleep request, it designates the sleep time set according to its own communication state and outputs it to the OLT 1. For example, the ONU 10 sets a long sleep time when there is no uplink data, and sets a short sleep time when a very small bandwidth or intermittent communication continues (but transitions to a power saving state). The sleep request can be changed according to the communication state of the ONU 10 and the sleep request can be output (u3).

  On the other hand, the OLT 1 can also set the sleep time according to the network condition such as the request of the ONU 10 and the maximum delay condition. When the OLT 1 receives a sleep request from the ONU 10, it determines whether the sleep state can be permitted, determines an allowable sleep time while considering the requested sleep time, and responds to the sleep request together with the sleep time. An acknowledgment signal (Acknowledgement) is transmitted (d4). The OLT 1 does not need to notify the transmission band allocation to the ONU 10 together with the acknowledgment signal.

  The ONU 10 does not shift to the power saving state until the acknowledgment signal is received, and shifts to the power saving state after receiving the acknowledgment signal. In this way, by waiting for the acknowledgment signal, it is possible to prevent a situation in which the state is not erroneously recognized with the OLT 1 and the OLT 1 erroneously issues an alarm. Further, since the ONU 10 can operate in a power saving state during the permitted sleep time, it is possible to appropriately adjust the power consumption reduction and the communication balance according to the communication status.

  In the above description, both the ONU 10 and the OLT 1 transmit the sleep time. However, in order to make the sleep time adjustable, only one of the devices may transmit the sleep time. The communication system can also use a sequence without an acknowledgment signal.

Embodiment 2. FIG.
The second embodiment is an embodiment in which a transmission band is allocated to the ONU 10 in the power saving state (sleep mode) to reduce the upstream delay during sleep. The hardware configuration of the communication system is the same as that of the communication system described above with reference to FIG.
FIG. 8 is a sequence showing the communication method of this embodiment. In FIG. 8, as can be seen from the transmission timings (d4), (d5), (d7), and (d8) of the OLT 1, in this embodiment, unlike the sequence of FIG. 2, the OLT 1 is connected to the ONU 10 in the sleep mode. Also, a transmission band is allocated. Therefore, the ONU 10 can cancel the sleep mode without waiting for the end of the sleep time, transition to the normal mode, and resume uplink data transmission.

  On the other hand, in terms of alarm monitoring, the ONU 10 in the sleep mode may or may not transmit a frame at its own discretion, so it must be devised. Therefore, the OLT 1 observes the transmission band assigned to the ONU 10 in the sleep mode, but masks the LOSi count for alarm monitoring, and outputs an alarm even if a valid signal cannot be received in this transmission band. Do not control. On the left side of FIG. 8, “ON” (monitoring enabled) and “MASK” (monitoring disabled) are recorded as the alarm monitoring states of the Loss of Signal. From this figure, we can see that the Loss of Signal alarm monitoring is “MASK” during the sleep time.

・ Details of OLT communication control

Next, details of the communication processing of the OLT 1 will be described with reference to FIG.
FIG. 9 shows the processing of the PON control unit 2 of the OLT 1. 9, the same reference numerals as those in FIG. 3 indicate the same or equivalent processes as those in FIG. In FIG. 3, the PON control unit 2 performs control so that a transmission band is not allocated to the ONU 10 in the power saving state in step S1 and step S13. On the other hand, in the control of FIG. 9, the PON control unit 2 allocates a transmission band including the ONU 10 in the sleep mode in step S60. Since the ONU 10 operating in the sleep mode is considered to require a smaller transmission band, the PON control unit 2 allocates a smaller transmission band than the ONU 10 in the normal mode.

  In step S61, the type of the uplink signal is identified, but the PON control unit 2 detects a sleep request by a PLOAM (Physical Layer OAM Operations, Administrations and Maintenance) message instead of the Dying_Gasp (1) signal. The sleep request includes an identifier that can identify the ONU 10 (may be an identifier of a link with the ONU 10), and a message type identifier that indicates that the PLOAM message is a sleep request. Note that the sleep request may be a Dying_Gasp (1) signal as in the first embodiment. If the received upstream signal includes a sleep request, the PON control unit 2 detects that the ONU 10 has shifted to the sleep mode in step S13. At this time, the ONU 10 is assigned to a transmission band as described above. There is no need to exclude them.

If it is determined in step S61 that there is no valid received signal in the band bw, the PON control unit 2 checks the timer ti in step S62 to determine whether the ONU 10 assigned to the band is in the sleep mode. Detect by. If it is determined that the mode is the sleep mode, the PON control unit 2 masks the alarm process (steps S17 to S19), proceeds to step S11, and performs the next transmission band process.
As described above, the OLT 1 includes means for allocating a transmission band to the ONU 10 in the sleep mode, allowing the ONU 10 in the sleep mode not to transmit a frame, and preventing a false alarm of failure monitoring.

・ Details of ONU communication control

Next, details of the communication processing of the ONU 10 will be described with reference to FIG.
FIG. 10 is a flowchart showing communication control executed by the PON control unit 11 of the ONU 10. 10, the same reference numerals as those in FIG. 4 indicate the same or equivalent processes as those in FIG. In the communication control of FIG. 10, even if the transmission band is assigned in the sleep mode, the ONU 10 does not transmit data using the transmission band in the sleep mode (steps S70 and S71). Therefore, the ONU 10 does not need to start Tx141 and can save power consumption. In step S70, the PON control unit 11 determines whether there is transmission data. If there is transmission data even in the sleep mode, the transmission processing from step S36 is executed. For this reason, the ONU 10 that employs the communication method shown in FIG. 10 can cancel the sleep mode before the sleep time expires and reduce the transmission delay during the sleep mode.

  In step S72, the PON control unit 11 creates a sleep request using a PLOAM Message instead of the Dying_Gasp (1) signal in FIG. On the other hand, in step S73, a normal Dying_Gasp signal is created as the Dying_Gasp signal when the power is turned off.

Operation when a failure occurs Next, the operation of the communication system when a communication failure occurs will be described.
FIG. 11 is a sequence diagram showing a case where a communication failure has occurred in the ONU 10 operating in the power saving state. At timings (d1), (d2), (d5), and (d6) during the sleep mode, the fault monitoring is masked and LOSi is not erroneously detected. On the other hand, when a failure occurs in the uplink after the ONU10 transmission timing (u4), the OLT1 detects a LOSi failure and outputs an alarm LOSi in the transmission bandwidth Bw allocated at the transmission timings (d6) and (d7) of the OLT1. To do.

・ Operation when the power is off

Next, an operation when the ONU 10 is turned off will be described.
FIG. 12 is a sequence diagram illustrating a case where the power is turned off after the ONU 10 is in the power saving state. Until the timing (u8), the ONU 10 operates in the power saving state. However, for example, when the user performs an operation to turn off the power of the ONU 10, it is necessary to start the power-off operation of the ONU 10. At this time, if the ONU 10 immediately turns off the power from the power saving state, the OLT 1 cannot detect this and emits LOSi. Therefore, the ONU 10 waits until bandwidth allocation after the sleep time (d9), transmits a Dying_Gasp signal to the OLT 1 (u9), and then turns off the power.
On the other hand, since the OLT 1 has also received the Dying_Gasp signal, it can recognize that a communication failure has occurred with the ONU 10 or that it has not returned from the sleep state, so that unnecessary alarm output can be prevented.

・ Sleep time variable setting and Acknowledgment

  FIG. 13 shows a sequence of a communication method for determining the sleep time in the power saving state by signaling as in FIG. When the ONU 10 outputs a sleep request, it designates the sleep time set according to its own communication state and outputs it to the OLT 1. For example, the ONU 10 sets a long sleep time when there is no uplink data, and sets a short sleep time when a very small bandwidth or intermittent communication continues (but transitions to a power saving state). The sleep request can be changed according to the ONU communication status and the sleep request can be output (u3).

  On the other hand, the OLT 1 can also set the sleep time according to the network condition such as the request of the ONU 10 and the maximum delay condition. When the OLT 1 receives a sleep request from the ONU 10, it determines whether the sleep state can be permitted, determines an allowable sleep time while considering the requested sleep time, and responds to the sleep request together with the sleep time. An acknowledgment signal (Acknowledgement) is transmitted (d4). The OLT 1 does not need to notify the transmission band allocation to the ONU 10 together with the acknowledgment signal.

  The ONU 10 does not shift to the power saving state until the acknowledgment signal is received, and shifts to the power saving state after receiving the acknowledgment signal. In this way, by waiting for the acknowledgment signal, it is possible to prevent a situation in which the state is not erroneously recognized with the OLT 1 and the OLT 1 erroneously issues an alarm. Further, since the ONU 10 can operate in a power saving state during the permitted sleep time, it is possible to appropriately adjust the power consumption reduction and the communication balance according to the communication status.

  In the above description, both the ONU 10 and the OLT 1 transmit the sleep time. However, in order to make the sleep time adjustable, only one of the devices may transmit the sleep time. It is also possible to use a sequence without an acknowledgment signal.

・ Explicit release of sleep mode by PLOAM Message

  In the first and second embodiments described above, when returning from the power saving state (sleep mode) to the normal state, the ONU 10 performs data transmission without a sleep request in the allocated band. By receiving this data transmission, the OLT 1 detects that the ONU 10 has shifted to the normal state. However, the ONU 10 and the OLT 1 use this power saving state (sleep mode) to request an explicit sleep release using the PLOAM Message. You can also use The flowchart of FIG. 14 shows communication control of the OLT 1 that processes this explicit sleep release request. 14, the same reference numerals as those in FIG. 9 indicate the same or equivalent processes as those in FIG.

  Step S64 in FIG. 14 is processing for determining whether the sleep request received by the OLT 1 is a transition request or a cancellation request. Any format of PLOAM Message may be used. For example, the sleep request includes an identifier that can identify the ONU 10 (may be an identifier of a link with the ONU 10), a message type identifier indicating that the PLOAM message is a sleep request, and a flag indicating one of transition / cancellation including. This flag is a flag indicating whether the sleep request requests a transition to the sleep mode or a cancel request. As another example, a method of assigning message type identifiers in a distinguishable manner between transition / cancellation instead of flags may be considered. By explicitly canceling the sleep mode in this way, both the ONU 10 and the OLT 1 can recognize the transition and release of the sleep mode more reliably, so that the processing becomes more reliable. Further, if a handshake method for returning an Acknowledgment signal for canceling the sleep mode is employed, the reliability of the communication system is further improved.

  The embodiment of the present invention has been described above. The present invention is not limited to these embodiments, and any modifications may be made as long as they are included in the gist of the present invention. For example, the communication system to which this communication method is applied need not be a PON system. The present invention can also be applied to an optical communication system using an active element. Further, the present invention is not limited to optical communication, and can also be applied to a communication system that communicates between terminals using electrical signals.

  The communication system or the communication method of the present invention is an excellent communication system that can suppress power consumption first. Therefore, even if the fault monitoring function is removed from the above-described embodiment, the present invention can be used, and even in that case, the power consumption can be suppressed. Further, as a second additional effect, there is a feature that failure monitoring can be performed while maintaining a link in a communication system with reduced power consumption.

  The present invention is suitable for communication methods and communication systems that require power saving.

  1 OLT, 2 PON control unit, 3, 13 reception buffer, 4,12 transmission buffer, 5,14 optical transceiver, 6 WDM, 7 PHY, 10-1 to 10-3 ONU, 11 PON control unit, 20-1 , 20-2 terminal, 30 subscriber line, 40 splitter, 51, 142, 161-1, 161-2 Rx, 52, 141, 162-1, 162-2 Tx.

Claims (20)

A communication method of an optical communication system for connecting a plurality of user side optical line terminators (hereinafter referred to as ONUs) to a station side optical line terminator (hereinafter referred to as OLT) using a common optical fiber,
The OLT for the operation can the ONU in the sleep mode to repeat an Tokikyu stop and temporary activation of the optical transmitter allocates transmission bandwidth for transmitting a response signal in the temporary start-up, transmission bandwidth notification To the ONU,
The OLT makes a transmission band allocation period for the ONU that has shifted to the sleep mode longer than a transmission band allocation period for the ONU that has shifted to the sleep mode, and permits the optical transmitter to pause. A communication method comprising transmitting a sleep period to the ONU . The communication method according to claim 1, wherein the ONU stops power supply to the laser of the optical transmitter during the temporary suspension period . The OLT, and transmits a signal for permitting the shift to the sleep mode of the ONU in the ONU, the method of communication according to claim 1 or 2. The ONU in the sleep mode transmits a signal requesting a shift to the sleep mode in response to the transmission band notification when the sleep mode is continued after the temporary suspension period. Item 4. The communication method according to any one of Items 1 to 3 . An optical communication system for connecting a plurality of user side optical line terminators (hereinafter referred to as ONUs) to a station side optical line terminator (hereinafter referred to as OLT) using a common optical fiber,
The OLT is
Connected optical transceiver to the optical fiber, and for the operation can the ONU in the sleep mode to repeat an Tokikyu stop and temporary activation of the optical transmitter, for transmitting a response signal during the temporary activation Allocate transmission bandwidth, send transmission bandwidth notification to the ONU,
The transmission bandwidth allocation period for the ONU that has transitioned to the sleep mode is longer than the transmission bandwidth allocation period for the ONU that has transitioned to the sleep mode, and a sleep period that allows the optical transmitter to pause is set to An optical communication system comprising a control device that transmits to an ONU . 6. The optical communication system according to claim 5, wherein the ONU stops power supply to the laser of the optical transmitter during the temporary suspension period . The OLT, and transmits a signal for permitting the shift to the sleep mode of the ONU in the ONU, optical communication system according to claim 5 or 6. The ONU in the sleep mode transmits a signal requesting a shift to the sleep mode in response to the transmission band notification when the sleep mode is continued after the temporary suspension period. Item 8. The optical communication system according to any one of Items 5 to 7 . A user side optical line terminator of an optical communication system for connecting a plurality of user side optical line terminators to a station side optical line terminator using a common optical fiber,
Is connected to the optical fiber, the transmitter stops the predetermined sleep period temporarily, the operation is possible optical transceiver in the sleep mode that reduces power consumption by repeatedly to temporarily start after the sleep period And a control device for transmitting a response signal to the station side optical line terminator to the optical transceiver when a transmission band is allocated by the station side optical line terminator during the sleep mode,
The allocation cycle of the transmission bandwidth in the case of transition to the sleep mode, the rather long than assignment cycle of the transmission band before entering the sleep mode, the control device, in time division by the station side line terminal In order to temporarily stop the transmission unit of the optical transceiver during the sleep period between the allocated transmission band and the subsequent transmission band, and to transmit a response signal in the transmission band after the sleep period A user-side optical line termination device characterized by performing activation control for temporarily activating a transmission unit of a transceiver . The user-side optical line termination device according to claim 9, wherein the optical transceiver stops power supply to the laser of the transmission unit during the sleep period. 11. The optical transceiver according to claim 9, wherein the optical transceiver operates in the sleep mode after receiving a signal permitting transition to the sleep mode from the station-side optical network unit. 11. The user side optical line terminator described. In the sleep mode, when the sleep mode is continued, the control device causes the optical transmitter / receiver to transmit a signal requesting the transition to the sleep mode as a response signal in the assigned transmission band. The user side optical line termination device according to any one of claims 9 to 11. A station side optical line terminator of an optical communication system for connecting a plurality of user side optical line terminators to a station side optical line terminator using a common optical fiber,
Connected optical transceiver to the optical fiber, and the optical transmitter and one Tokikyu stopped predetermined sleep period, the capable of operating in a sleep mode to repeat that temporarily activating said light transmitter after sleep period the for the user-side optical line terminal, the allocated transmission bandwidth for transmitting a response signal to the temporary startup, the transmission bandwidth notification sent to the user side optical network unit,
The transmission band allocation period for the user side optical line termination device that has shifted to the sleep mode is longer than the transmission band allocation period for the user side optical line termination apparatus before the transition to the sleep mode, and the optical A control device for transmitting a sleep period permitting temporary suspension of the transmitter to the user-side optical line termination device;
A station-side optical line termination device comprising: The control device causes the optical transceiver to transmit a signal permitting the user side optical line termination device to enter the sleep mode to the user side optical line termination device. Item 14. The station side optical line termination device according to Item 13. A control device for a user side optical line terminator of an optical communication system for connecting a plurality of user side optical line terminators to a station side optical line terminator using a common optical fiber,
If the transmission bandwidth is allocated by the station-side optical network unit during the sleep mode to repeat to stop temporarily the predetermined sleep period the transmission portion of the connected optical transceiver to the optical fiber by the power control, A response signal to the station side optical line terminator is transmitted to the optical transceiver,
The transmission bandwidth assignment period if the transition to the sleep mode, the rather long than the transmission bandwidth assignment period before entering the sleep mode, stops the transmission unit the sleep period temporarily, after the sleep period A control device that performs start-up control for temporarily starting up the transmission unit in order to transmit a response signal in the transmission band . The control device according to claim 15, wherein power supply to the laser of the transmission unit is stopped during the sleep period. The optical transmitter / receiver is operated in the sleep mode after receiving a signal permitting transition to the sleep mode from the station side optical line termination device. The control device described. When the sleep mode is continued after the sleep period during the sleep mode, the optical transmitter / receiver is caused to transmit a signal requesting a transition to the sleep mode as a response signal in the allocated transmission band. The control device according to any one of claims 15 to 17. A control device for a station side optical line terminator of an optical communication system for connecting a plurality of user side optical line terminators to a station side optical line terminator using a common optical fiber,
For the user-side optical network unit capable of operating in a sleep mode for repeating the activation one Tokikyu stop and temporary optical transmitters by power control, the transmission bandwidth for transmitting a response signal during the temporary activation Send the allocation and transmission bandwidth notification to the user side optical network unit,
The transmission band allocation period for the user side optical line termination device that has shifted to the sleep mode is longer than the transmission band allocation period for the user side optical line termination apparatus before the transition to the sleep mode, and the optical A control apparatus , wherein a sleep period during which a temporary suspension of a transmitter is permitted is transmitted to the user-side optical line terminator . The optical transceiver is configured to cause the user-side optical line termination device to transmit a signal permitting the user-side optical line termination device to enter the sleep mode. Control device.

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