JP5566948B2 - Optical network system and optical network termination device - Google Patents

Description

  The present invention relates to a smart grid technology in an optical network system.

  In recent years, smart grid technology that performs efficient energy management by integrating power and communication networks has attracted attention. M2M (Machine to Machine) communication is mainly performed on a communication network used for a smart grid. In M2M communication, a small amount of data is frequently exchanged. In particular, there is a feature that low-speed upstream traffic for collecting sensor data always occurs. The sensor data is transferred to a gateway via a wireless network such as Zigbee, for example, and further transferred to a server via a broadband access network and is made into a database. Non-Patent Document 1, for example, describes M2M communication in smart grid technology.

  It is conceivable to use an IP (Internet Protocol) -based optical access network as a communication network in the smart grid. As one of optical access networks, there is a passive optical network (PON). As shown in FIG. 1, a PON is composed of one optical subscriber line terminal (OLT) 1 and a plurality of optical network terminal (ONU) 2-1, 2-2,. A network that performs point-to-multipoint communication via the 2-n and the optical fiber transmission line 3 and the 1 to n splitter 4 (n is a natural number). As a typical standard of the gigabit class PON, there is EPON (Ethernet (registered trademark) PON) standardized by IEEE802.3. In addition, in the IEEE 802.3av study group, 10G-class 10G-EPON was standardized. The 10 G-EPON of the 10 gigabit class is described in Non-Patent Document 2, for example.

  FIG. 2 shows a functional block diagram of the ONU 2 in EPON. The upstream main signal flows to a PON-IF (PON Interface) port 24 via a UNI (User Network Interface) port 21, a queue management unit 22, and a PON signal processing unit 23. On the other hand, the downstream main signal flows to the UNI port 21 via the PON-IF port 24, the PON signal processing means 23, and the queue management means 22. The ONU 2 includes a plurality of queues in the upstream direction, and has a means for monitoring the data amount in each queue as the queue monitoring means 25. Further, the ONU 2 communicates with the PON signal processing means 23 an MPCP (Multi-Point Control Protocol) unit 231 that reports the amount of data in each queue to the OLT 1 and an OAM that exchanges control frames for maintenance monitoring with the OLT 1 ( (Operations, Administration and Maintenance) section 232.

  FIG. 3 shows a functional block diagram of the OLT 1 in EPON. The downlink main signal flows to the PON-IF port 14 via the SNI (Service Node Interface) port 11, the queue management unit 12, and the PON signal processing unit 13. On the other hand, the upstream main signal flows to the SNI port 11 via the PON-IF port 14, the PON signal processing unit 13, and the queue management unit 12. The OLT 1 causes the PON signal processing means 13 to report the amount of data in the queue included in each ONU 2 to each ONU 2, and the queue in each ONU 2 based on the report message received from each ONU 2. A bandwidth allocation unit 132 that monitors the amount of data and allocates a usage bandwidth to each ONU 2 and an OAM unit 133 that exchanges control frames for maintenance monitoring with each ONU 2.

  On the other hand, in the PON system constituting the broadband access network, a power saving mechanism for reducing the power consumption of the ONU is proposed in ITU-T and IEEE P1904.1. As a power saving mechanism of the PON, there are four methods of Power Shedding, Deep Sleep, Dozing, and Cyclic Sleep. Power Shedding is a method for suspending unnecessary UNI ports. Deep sleep is a method in which a transmission / reception unit is suspended when there is no distribution traffic. Dozing is a method of pausing the transmission unit when there is no upstream traffic. Cyclic Sleep is a method in which the transmission / reception unit is suspended when there is no distribution traffic, and the transmission / reception unit that has been suspended after a certain period of time is activated to confirm the traffic. For example, Non-Patent Documents 3 and 4 describe the power saving mechanism of the ONU.

  4 to 6 show the functional configuration of the PON signal processing means 23 of the ONU 2.

  In the case of the Dozing method, the reception function on the PON-IF port 24 side of the ONU 2 is always in an activated state, but the transmission function is in a power saving state except when there is upstream traffic. In addition, after the power saving state for Ts seconds, the state may be changed to the activation state for Ta seconds, and the continuation of the power saving state may be notified to the OLT 1. In the power saving state, for example, as illustrated in FIG. 4, only the transmission PHY unit (PMD (Physical Medium Dependent)) 234-1 that is a part of the optical transceiver is suspended. Alternatively, as shown in FIG. 5, in addition to the transmission PHY unit (PMD) 234-1, the transmission PHY unit (excluding PMD) 235-1 may be suspended. Alternatively, as shown in FIG. 6, in addition to transmission PHY unit (PMD) 234-1 and transmission PHY unit (excluding PMD) 235-1, transmission MAC unit 236-1 may be suspended.

  In the case of the cyclic sleep method, the transmission / reception function on the PON-IF port 24 side of the ONU 2 is intermittently activated when there is no up / down traffic. That is, the power saving state for Ts seconds and the activation state for Ta seconds are repeated. In the power saving state, for example, as shown in FIG. 4, only the transmission / reception PHY units (PMD) 234-1 and 234-2 that are part of the optical transceiver are suspended. Alternatively, as shown in FIG. 5, in addition to the transmission / reception PHY units (PMD) 234-1 and 234-2, the transmission / reception PHY units (excluding PMD) 235-1 and 235-2 may be suspended. Alternatively, as shown in FIG. 6, in addition to transmission / reception PHY units (PMD) 234-1 and 234-2 and transmission / reception PHY units (excluding PMD) 235-1 and 235-2, transmission / reception MAC units 236-1 and 236- 2 may be paused.

  FIG. 7 shows a first control message exchange example in the conventional Dosing method. When the ONU 2 is in the startup mode, the OLT 1 is notified of the amount of data stored in the upstream queue, and data is transmitted using the upstream bandwidth allocated by the bandwidth allocating unit 132 of the OLT 1. The data amount is notified by transmitting a Report message from the MPCP unit 231 of the ONU 2. Further, an uplink allocated bandwidth is notified by transmitting a Gate message from the MPCP unit 131 of the OLT 1.

  When there is no more data in the upstream queue of the ONU 2, the OLT 1 transmits a Sleep Allow message that permits the ONU 2 to enter the power saving mode. When the ONU 2 determines that the transition to the power saving mode is possible, it transmits a Sleep Request message to the OLT 1 and transitions to the power saving state for Ts 1 second. For example, the power saving period Ts1 is set from 10 milliseconds to 100 milliseconds.

  After Ts1 seconds elapses, the ONU 2 transitions to a startup state for Ta1 seconds and receives a Sleep Allow message from the OLT1. For example, the activation time Ta1 is preferably set to several milliseconds or less in consideration of the time error between the OLT1 and the ONU2. The OLT 1 transmits a Sleep Allow message, for example, at a cycle of Ta1 + Ts1 seconds. When the ONU 2 receives the Sleep Allow message, if there is no data in the upstream queue, the ONU 2 transmits an ACK message to the OLT 1 and transitions again to the power saving state for Ts 1 second.

  If upstream traffic occurs after Ts2 seconds (Ts2 <Ts1), the ONU 2 notifies the OLT 1 of the amount of data in the upstream queue with a Report message. However, the upstream bandwidth for transmitting the ACK message and the Report message is periodically determined by the Gate message transmitted from the OLT 1 at an interval shorter than the Sleep Allow transmission cycle, regardless of the power saving state or the activation state of the ONU 2. Assigned to. The ONU 2 waits for uplink bandwidth allocation by the bandwidth allocation unit 132 of the OLT 1 and transmits uplink data after the uplink bandwidth allocation notification by the Gate message.

  Note that for transmission and reception of the Sleep Allow message, the Sleep Request message, and the ACK message, MPCP messages using the functions of the MPCP units 131 and 231 of the OLT 1 and ONU 2 may be used, or the OAM units 133 and 232 of the OLT 1 and ONU 2 may be used. An OAM message (extended OAM) message using a function may be used, or any other control message may be used.

  FIG. 8 shows a second control message exchange example in the conventional Dosing method. When the ONU 2 is in the startup mode, the OLT 1 is notified of the amount of data stored in the upstream queue, and data is transmitted using the upstream bandwidth allocated by the bandwidth allocating unit 132 of the OLT 1. The data amount is notified by transmitting a Report message from the MPCP unit 231 of the ONU 2. Further, an uplink allocated bandwidth is notified by transmitting a Gate message from the MPCP unit 131 of the OLT 1.

  When there is no more data in the upstream queue of the ONU 2, the OLT 1 transmits a Sleep Allow message that permits the ONU 2 to enter the power saving mode. When the ONU 2 determines that the transition to the power saving mode is possible, the ONU 2 transmits a Sleep Request message to the OLT 1 and transitions to the power saving state.

  When upstream traffic occurs, the ONU 2 notifies the OLT 1 of the amount of data in the upstream queue with a Report message. However, the upstream band for transmitting the Report message is periodically assigned by the Gate message transmitted from the OLT 1 regardless of the power saving state or the activation state of the ONU 2. The ONU 2 waits for uplink bandwidth allocation by the bandwidth allocation unit 132 of the OLT 1 and transmits uplink data after the uplink bandwidth allocation notification by the Gate message.

  Note that for transmission and reception of the Sleep Allow message and the Sleep Request message, an MPCP message using the functions of the MPCP units 131 and 231 of the OLT 1 and the ONU 2 may be used, or the functions of the OAM units 133 and 232 of the OLT 1 and the ONU 2 are used. The OAM message (extended OAM) message may be used, or any other control message may be used.

  FIG. 9 shows a first control message exchange example in the conventional Cyclic Sleep method. When the ONU 2 is in the startup mode, the OLT 1 is notified of the amount of data stored in the upstream queue, and data is transmitted using the upstream bandwidth allocated by the bandwidth allocating unit 132 of the OLT 1. The data amount is notified by transmitting a Report message from the MPCP unit 231 of the ONU 2. Further, an uplink allocated bandwidth is notified by transmitting a Gate message from the MPCP unit 131 of the OLT 1.

  When there is no data in the downstream queue addressed to the ONU 2 of the OLT 1 and there is no data in the upstream queue of the ONU 2, the OLT 1 transmits a Sleep Allow message that permits the ONU 2 to shift to the power saving mode. When the ONU 2 determines that the transition to the power saving mode is possible, it transmits a Sleep Request message to the OLT 1 and transitions to the power saving state for Ts 1 second. For example, the power saving period Ts1 is set from 10 milliseconds to 100 milliseconds.

  After Ts1 seconds elapses, the ONU 2 transitions to a startup state of Ta1 seconds, and a Gate message from the OLT 1 (in the power saving state, the ONU 2 cannot receive the Gate message even if the OLT 1 transmits the Gate message) and the Sleep Allow message. Receive. For example, the activation time Ta1 is preferably set to several milliseconds or less in consideration of the time error between the OLT1 and the ONU2. The OLT 1 transmits a Sleep Allow message, for example, at a cycle of Ta1 + Ts1 seconds. When the ONU 2 receives the Sleep Allow message, if there is no data in the upstream queue, the ONU 2 transmits an ACK message to the OLT 1 and transitions again to the power saving state for Ts 1 second.

  If upstream traffic occurs after Ts2 seconds (Ts2 <Ts1), the ONU 2 notifies the OLT 1 of the amount of data in the upstream queue with a Report message. However, the upstream bandwidth for transmitting the ACK message and the Report message is periodically determined by the Gate message transmitted from the OLT 1 at an interval shorter than the Sleep Allow transmission cycle, regardless of the power saving state or the activation state of the ONU 2. Assigned to. The ONU 2 waits for uplink bandwidth allocation by the bandwidth allocation unit 132 of the OLT 1 and transmits uplink data after the uplink bandwidth allocation notification by the Gate message.

  Note that for transmission and reception of the Sleep Allow message, the Sleep Request message, and the ACK message, MPCP messages using the functions of the MPCP units 131 and 231 of the OLT 1 and ONU 2 may be used, or the OAM units 133 and 232 of the OLT 1 and ONU 2 may be used. An OAM message (extended OAM) message using a function may be used, or any other control message may be used.

  FIG. 10 shows a second control message exchange example in the conventional cyclic sleep system. When the ONU 2 is in the startup mode, the OLT 1 is notified of the amount of data stored in the upstream queue, and data is transmitted using the upstream bandwidth allocated by the bandwidth allocating unit 132 of the OLT 1. The data amount is notified by transmitting a Report message from the MPCP unit 231 of the ONU 2. Further, an uplink allocated bandwidth is notified by transmitting a Gate message from the MPCP unit 131 of the OLT 1.

  When there is no data in the downstream queue addressed to the ONU 2 of the OLT 1 and there is no data in the upstream queue of the ONU 2, the OLT 1 transmits a Sleep Allow message that permits the ONU 2 to shift to the power saving mode. When the ONU 2 determines that the transition to the power saving mode is possible, it transmits a Sleep Request message to the OLT 1 and transitions to the power saving state for Ts 1 second. For example, the power saving period Ts1 is set from 10 milliseconds to 100 milliseconds.

  After Ts1 seconds elapses, the ONU 2 transitions to a startup state of Ta1 seconds, and a Gate message from the OLT 1 (in the power saving state, the ONU 2 cannot receive the Gate message even if the OLT 1 transmits the Gate message) and the Sleep Allow message. Receive. For example, the activation time Ta1 is preferably set to several milliseconds or less in consideration of the time error between the OLT1 and the ONU2. The OLT 1 transmits a Sleep Allow message, for example, at a cycle of Ta1 + Ts1 seconds. When the ONU 2 receives the Sleep Allow message, if there is no data in the upstream queue, the ONU 2 transitions again to the power saving state for Ts 1 second.

  If upstream traffic occurs after Ts2 seconds (Ts2 <Ts1), the ONU 2 notifies the OLT 1 of the amount of data in the upstream queue with a Report message. However, the upstream band for transmitting the Report message is periodically assigned by the Gate message transmitted from the OLT 1 at an interval shorter than the Sleep Allow transmission cycle, regardless of the power saving state or the activation state of the ONU 2. ing. The ONU 2 waits for uplink bandwidth allocation by the bandwidth allocation unit 132 of the OLT 1 and transmits uplink data after the uplink bandwidth allocation notification by the Gate message.

  Note that for transmission and reception of the Sleep Allow message and the Sleep Request message, an MPCP message using the functions of the MPCP units 131 and 231 of the OLT 1 and the ONU 2 may be used, or the functions of the OAM units 133 and 232 of the OLT 1 and the ONU 2 are used. The OAM message (extended OAM) message may be used, or any other control message may be used.

Young-Jin Kim, Marina Thottan, Vladimir Kolesnikov, Wonsuckle Lee, “A secure deducted data-centric infrastrum structure”. 48, no. 11, pp. 58-65, November 2010. Tsutsumu Tatsuta, Noriyuki Oota, Noriki Miki, Kiomi Kumolaki, “Design Philosophy and performance of the GE-PON system”. 6, no. 6, pp. 689-700, June 2007. ITU-T Recommendation G Suppl. 45, “Supplement on GPON power conservation,” May 2009. Ryogo Kubo, Jun-ichi Kani, Hirotaka Ujikawa, Takeshi Sakamoto, Yukihiro Fujimoto, Naoto Yoshimoto, Hisaya Hadama, "Study and demonstration of sleep and adaptive link rate control mechanisms for energy efficient 10G-EPON," IEEE / OSA Journal of Optical Communications and Networking, Vol. 2, no. 9, pp. 716-729, September 2010.

  However, the ONU in the power saving mode has to transition to the activation mode once when low-speed uplink data flows in, and wait for the uplink bandwidth allocation from the OLT. There was a problem of being reduced. Further, since low-speed data is frequently exchanged, there is a problem that the ONU needs to frequently perform state transition between the power saving mode and the startup mode, and the power saving effect is reduced. Furthermore, there is a problem that the queuing delay increases because the uplink data is continuously stored in the queue of the ONU during the period of waiting for the uplink bandwidth allocation.

  Therefore, in order to solve the above problems, the present invention provides an optical network system and an optical network capable of reducing a queuing delay while maintaining a power saving effect while low-speed uplink data is frequently exchanged. An object is to provide a network termination device.

  In order to achieve the above object, when the ONU accumulates the uplink data to the OLT in the power saving state, the ONU is connected to the ONU after the power saving state based on the uplink band assigned to the ONU in the power saving state. In the activated state, the upstream data to the OLT is stored in the payload area of the control message to the OLT, and the control message to the OLT is transmitted.

Specifically, the present invention is an optical network system in which one optical subscriber line termination device and a plurality of optical network termination devices perform point-to-multipoint communication via an optical fiber transmission line. The optical subscriber line termination device allocates an upstream band to each optical network termination device, and each optical network termination device has a power saving state in which transmission to the optical subscriber line termination device is not performed, and the optical subscriber line termination device. The optical subscriber line terminator is connected to each optical network terminator when the state is switched between the active states for transmission to the network and the upstream data is accumulated in the optical subscriber line terminator in the power saving state. based on the uplink band allocation in the power saving state, the active state after the power-saving state, wherein the optical network unit is the cause to the respective optical network termination device Without waiting for allocating the uplink bandwidth in a state, it stores the uplink data to the optical network unit in the payload area of the control message to the optical network unit, the Optical Line Termination An optical network system is characterized in that a control message to a device is transmitted to the optical subscriber line terminating device.

The present invention also provides a state switching unit that switches a state between a power saving state in which transmission to the optical subscriber line termination device is not performed and an activation state in which transmission to the optical subscriber line termination device is performed, and the optical subscription A data storage unit for storing uplink data to the subscriber line terminating device, and when the upstream data to the optical subscriber line terminating device is stored in the power saving state, the optical subscriber line terminating device Based on the upstream bandwidth allocated in the state, in the startup state after the power saving state, without waiting for the optical subscriber line termination device to allocate the upstream bandwidth in the startup state, the optical subscriber line termination Data transmission for storing upstream data to a device in a payload area of a control message to the optical subscriber line terminating device and transmitting a control message to the optical subscriber line terminating device to the optical subscriber line terminating device And parts, an optical network termination apparatus, comprising a.

  According to this configuration, the ONU stores uplink data in the payload area of the control message and transmits the control message to the OLT in the intermittent activation state during the power saving mode. Reduce transitions between Furthermore, since the ONU has already been allocated the upstream band in the power saving state, the ONU does not have to wait for the allocation of the upstream band in the startup state after the power saving state, and does not continue to store the upstream data. Also good.

  Further, the present invention relates to the size of the uplink data to the optical subscriber line termination device accumulated in each power saving state by each optical network termination device, so that the optical subscriber line termination device has When the optical network terminator is smaller than the size of data that can be transmitted in the uplink band allocated in the power state, each optical network terminator, in the startup state after the power saving state, all of the uplink data to the optical subscriber line terminator Is transmitted to the optical subscriber line terminating device.

  Further, the present invention provides that the size of the uplink data stored in the power saving state to the optical subscriber line termination device can be transmitted in the uplink band allocated by the optical subscriber line termination device in the power saving state. When the data size is smaller than the data size, the data transmission unit transmits all of the uplink data to the optical subscriber line terminating device to the optical subscriber line terminating device in an activated state after the power saving state. Is an optical network termination device.

  According to this configuration, when the size of the uplink data is small, the ONU can transmit the uplink data to the OLT in one activation state. Here, the ONU can use one or a plurality of control messages in one activation state.

  Further, the present invention relates to the size of the uplink data to the optical subscriber line termination device accumulated in each power saving state by each optical network termination device, so that the optical subscriber line termination device has When the size of data that can be transmitted in the uplink band allocated in the power state is larger than each of the optical network termination devices, each optical network termination device receives one of the upstream data to the optical subscriber line termination device in the startup state after the power saving state. In the upstream band range, and in the activated state after the activated state, the remaining upstream data to the optical subscriber line terminated device is transferred to the optical subscriber line terminated device. An optical network system characterized by transmitting to an apparatus.

  Further, the present invention provides that the size of the uplink data stored in the power saving state to the optical subscriber line termination device can be transmitted in the uplink band allocated by the optical subscriber line termination device in the power saving state. When the data size is larger than the data size, the data transmission unit, in an activated state after the power saving state, transmits a part of the uplink data to the optical subscriber line terminating device within the range of the uplink band. An optical network termination characterized in that the optical network termination is transmitted to a subscriber line termination device, and in the activated state after the activated state, the remaining uplink data to the optical subscriber line termination device is transmitted to the optical subscriber line termination device. Device.

  According to this configuration, when the size of the uplink data is large, the ONU can transmit the uplink data to the OLT in a plurality of activation states. Here, the ONU can use one or a plurality of control messages in each activation state.

  Also, the present invention provides that each optical network terminator transmits uplink data to the optical subscriber line terminator on the basis of a transmission priority of uplink data to the optical subscriber line terminator. An optical network system characterized by transmitting to an apparatus.

  Further, according to the present invention, the data transmission unit transmits the uplink data to the optical subscriber line termination device based on the transmission priority of the uplink data to the optical subscriber line termination device. An optical network terminator that transmits to the network.

  According to this configuration, uplink data having a high priority is preferentially transmitted.

  The present invention can provide an optical network system and an optical network termination device capable of reducing a queuing delay while maintaining a power saving effect while low-speed uplink data is frequently exchanged.

It is a figure which shows the structure of PON. It is a figure which shows the structure of ONU. It is a figure which shows the structure of OLT. It is a figure which shows the structure of a PON signal processing means. It is a figure which shows the structure of a PON signal processing means. It is a figure which shows the structure of a PON signal processing means. It is a figure which shows the control message exchange method of a prior art. It is a figure which shows the control message exchange method of a prior art. It is a figure which shows the control message exchange method of a prior art. It is a figure which shows the control message exchange method of a prior art. It is a figure which shows the control message exchange method of Embodiment 1. FIG. It is a figure which shows the control message exchange method of Embodiment 2. It is a figure which shows the control message exchange method of Embodiment 3. It is a figure which shows the control message exchange method of Embodiment 4. It is a figure which shows the control message exchange method of Embodiment 5. It is a figure which shows the control message exchange method of Embodiment 6.

  Embodiments of the present invention will be described with reference to the accompanying drawings. The embodiments described below are examples of the present invention, and the present invention is not limited to the following embodiments. In the present specification and drawings, the same reference numerals denote the same components.

(Embodiment 1-4)
An outline of the embodiment 1-4 will be described. The ONU switches the state between a power saving state in which transmission to the OLT is not performed and an activation state in which transmission to the OLT is performed. Then, when the ONU accumulates the uplink data to the OLT in the power saving state, the OLT in the startup state after the power saving state based on the uplink band assigned to the ONU in the power saving state by the OLT The upstream data is stored in the payload area of the control message to the OLT, and the control message to the OLT is transmitted to the OLT.

  Here, when the size of the uplink data to the OLT that the ONU has accumulated in the power saving state is smaller than the size of the data that can be transmitted in the uplink band assigned to the ONU by the ONU in the power saving state, the ONU In the activated state after the power saving state, all the uplink data to the OLT is transmitted to the OLT. The ONU can use one or a plurality of control messages in one activation state.

(Embodiment 1)
Let us consider a case in which the size of uplink data that has flowed in during the power saving mode is equal to or less than the payload size of one control message frame in an ONU that employs the Dozing method. An example of control message exchange in this case is shown in FIG.

  When there is no more data in the upstream queue of the ONU 2, the OLT 1 transmits a Sleep Allow message that permits the ONU 2 to enter the power saving mode. When the ONU 2 determines that the transition to the power saving mode is possible, it transmits a Sleep Request message to the OLT 1 and transitions to the power saving state for Ts 1 second. For example, the power saving period Ts1 is set from 10 milliseconds to 100 milliseconds.

  After Ts1 seconds elapses, the ONU 2 transitions to a startup state for Ta1 seconds and receives a Sleep Allow message from the OLT1. For example, the activation time Ta1 is preferably set to several milliseconds or less in consideration of the time error between the OLT1 and the ONU2. The OLT 1 transmits a Sleep Allow message, for example, at a cycle of Ta1 + Ts1 seconds.

  When the ONU 2 receives the Sleep Allow message and the data stored in the upstream queue is less than or equal to the payload size of one ACK message frame, the ONU 2 stores the upstream data in the payload area of the ACK message and transmits it to the OLT 1. The transition is made again to the power saving state for Ts1 second. Alternatively, when the data stored in the upstream queue is equal to or smaller than the payload size of one Report message frame, the ONU 2 periodically transitions to the activated state without waiting for the reception of the Sleep Allow message, and then periodically receives the Gate message. By using the uplink bandwidth allocated by, the uplink data may be stored in the payload area of the Report message and transmitted to the OLT 1.

  When the data stored in the upstream queue after Ts2 seconds (Ts2 <Ts1) becomes larger than the payload size of one ACK message frame, ONU2 notifies OLT1 of the amount of data in the upstream queue with a Report message. To do. However, the upstream band for transmitting the ACK message and the Report message is periodically determined by the Gate message transmitted from the OLT 1 at an interval shorter than the Sleep Allow transmission cycle, regardless of the power saving state or the activation state of the ONU 2. Assigned.

  Note that for transmission and reception of the Sleep Allow message, the Sleep Request message, and the ACK message, MPCP messages using the functions of the MPCP units 131 and 231 of the OLT 1 and ONU 2 may be used, or the OAM units 133 and 232 of the OLT 1 and ONU 2 may be used. An OAM message (extended OAM) message using a function may be used, or any other control message may be used.

  The ONU 2 may determine data having a specific priority by the ONU 2 itself, preferentially store it in the payload of the control frame and transmit it to the OLT 1 during the power saving mode, and transmit other data after startup. . In addition, the OLT 1 may allocate the upstream band allocated to the power saving mode ONU 2 as a band for one report message and / or a fixed band for one ACK message, and / or a band for a plurality of report messages. Alternatively, the bandwidth may be fixed for a plurality of ACK messages, or may be determined dynamically based on statistical information on the amount of data stored in the queue. For example, when the amount of uplink data for a certain period in the past exceeds a threshold value, the ONU 2 is shifted to the start mode, and when it is equal to or less than the threshold value, one control frame having a payload corresponding to the amount of uplink data Alternatively, a plurality of bands that can be transmitted are allocated to the ONU 2 in the power saving mode.

  In the first embodiment, the present invention is applied to the first control message exchange example in the conventional Dozing method shown in FIG. 7, but the second control message exchange in the conventional Dozing method shown in FIG. It is clear that the present invention can be applied to examples.

(Embodiment 2)
Let us consider a case where, in an ONU adopting the cyclic sleep method, the uplink data size that flows during the power saving mode period is equal to or smaller than the payload size of one control message frame. An example of control message exchange in this case is shown in FIG.

  When there is no data in the downstream queue addressed to the ONU 2 of the OLT 1 and there is no data in the upstream queue of the ONU 2, the OLT 1 transmits a Sleep Allow message that permits the ONU 2 to shift to the power saving mode. When the ONU 2 determines that the transition to the power saving mode is possible, it transmits a Sleep Request message to the OLT 1 and transitions to the power saving state for Ts 1 second. For example, the power saving period Ts1 is set from 10 milliseconds to 100 milliseconds.

  After Ts1 seconds elapses, the ONU 2 transitions to a startup state of Ta1 seconds, and a Gate message from the OLT 1 (in the power saving state, the ONU 2 cannot receive the Gate message even if the OLT 1 transmits the Gate message) and the Sleep Allow message. Receive. For example, the activation time Ta1 is preferably set to several milliseconds or less in consideration of the time error between the OLT1 and the ONU2. The OLT 1 transmits a Sleep Allow message, for example, at a cycle of Ta1 + Ts1 seconds.

  When the ONU 2 receives the Sleep Allow message and the data stored in the upstream queue is less than or equal to the payload size of one ACK message frame, the ONU 2 stores the upstream data in the payload area of the ACK message and transmits it to the OLT 1. The transition is made again to the power saving state for Ts1 second. Alternatively, when the data stored in the upstream queue is equal to or smaller than the payload size of one Report message frame, the ONU 2 periodically transitions to the activated state without waiting for the reception of the Sleep Allow message, and then periodically receives the Gate message. By using the uplink bandwidth allocated by, the uplink data may be stored in the payload area of the Report message and transmitted to the OLT 1.

  When the data stored in the upstream queue after Ts2 seconds (Ts2 <Ts1) becomes larger than the payload size of one ACK message frame, ONU2 notifies OLT1 of the amount of data in the upstream queue with a Report message. To do. However, the upstream band for transmitting the ACK message and the Report message is periodically determined by the Gate message transmitted from the OLT 1 at an interval shorter than the Sleep Allow transmission cycle, regardless of the power saving state or the activation state of the ONU 2. Assigned.

  Note that for transmission and reception of the Sleep Allow message, the Sleep Request message, and the ACK message, MPCP messages using the functions of the MPCP units 131 and 231 of the OLT 1 and ONU 2 may be used, or the OAM units 133 and 232 of the OLT 1 and ONU 2 may be used. An OAM message (extended OAM) message using a function may be used, or any other control message may be used.

  The ONU 2 may determine data having a specific priority by the ONU 2 itself, preferentially store it in the payload of the control frame and transmit it to the OLT 1 during the power saving mode, and transmit other data after startup. . In addition, the OLT 1 may allocate the upstream band allocated to the power saving mode ONU 2 as a band for one report message and / or a fixed band for one ACK message, and / or a band for a plurality of report messages. Alternatively, the bandwidth may be fixed for a plurality of ACK messages, or may be determined dynamically based on statistical information on the amount of data stored in the queue. For example, when the amount of uplink data for a certain period in the past exceeds a threshold value, the ONU 2 is shifted to the start mode, and when it is equal to or less than the threshold value, one control frame having a payload corresponding to the amount of uplink data Alternatively, a plurality of bands that can be transmitted are allocated to the ONU 2 in the power saving mode.

  In the second embodiment, the case where the present invention is applied to the first example of exchanging control messages in the conventional cyclic sleep scheme shown in FIG. 9 has been described, but the second control in the conventional cyclic sleep scheme shown in FIG. It is clear that the present invention can also be applied to message exchange examples.

(Embodiment 3)
Consider a case in which the size of uplink data that has flowed in during the power saving mode is larger than the payload size of one control message frame in an ONU that employs the Dozing method. The ONU transmits uplink data using an uplink band that is divided into a plurality of control frames and allocated in the same allocation cycle. An example of control message exchange in this case is shown in FIG.

  When there is no more data in the upstream queue of the ONU 2, the OLT 1 transmits a Sleep Allow message that permits the ONU 2 to enter the power saving mode. When the ONU 2 determines that the transition to the power saving mode is possible, it transmits a Sleep Request message to the OLT 1 and transitions to the power saving state for Ts 1 second. For example, the power saving period Ts1 is set from 10 milliseconds to 100 milliseconds.

  After Ts1 seconds elapses, the ONU 2 transitions to a startup state for Ta1 seconds and receives a Sleep Allow message from the OLT1. For example, the activation time Ta1 is preferably set to several milliseconds or less in consideration of the time error between the OLT1 and the ONU2. The OLT 1 transmits a Sleep Allow message, for example, at a cycle of Ta1 + Ts1 seconds.

  When the ONU 2 receives the Sleep Allow message, the data stored in the upstream queue is larger than the payload size of one ACK message frame and is less than or equal to the amount of data that can be transmitted in the band allocated by the band allocation unit 132 of the OLT 1. In some cases, uplink data is stored in the payload areas of a plurality of control messages, transmitted to the OLT 1, and again transitions to the power saving state for Ts1 seconds. Alternatively, when the data stored in the upstream queue is larger than the payload size of one Report message frame and is less than or equal to the amount of data that can be transmitted in the band allocated by the band allocation unit 132 of the OLT 1, the ONU 2 Without waiting for reception of the received data, the upstream state is periodically transferred by using the upstream bandwidth allocated by the Gate message, and the upstream data is stored in the payload area of a plurality of control messages and transmitted to the OLT 1 May be. For example, an extended OAM (eOAM) message can be used as the control message.

  If the data stored in the upstream queue after Ts2 seconds (Ts2 <Ts1) becomes larger than the amount of data that can be transmitted in the bandwidth allocated by the bandwidth allocation unit 132 of the OLT 1, the ONU 2 stores the data in the upstream queue. The amount is notified to the OLT 1 by a Report message. However, the upstream band for transmitting the ACK message and the Report message is periodically determined by the Gate message transmitted from the OLT 1 at an interval shorter than the Sleep Allow transmission cycle, regardless of the power saving state or the activation state of the ONU 2. Assigned.

  Note that for transmission and reception of the Sleep Allow message, the Sleep Request message, and the ACK message, MPCP messages using the functions of the MPCP units 131 and 231 of the OLT 1 and ONU 2 may be used, or the OAM units 133 and 232 of the OLT 1 and ONU 2 may be used. An OAM message (extended OAM) message using a function may be used, or any other control message may be used.

  The ONU 2 may determine data having a specific priority by the ONU 2 itself, preferentially store it in the payload of the control frame and transmit it to the OLT 1 during the power saving mode, and transmit other data after startup. . In addition, the OLT 1 may allocate the upstream bandwidth allocated to the ONU 2 in the power saving mode as a bandwidth for a plurality of report messages and / or a fixed bandwidth for a plurality of ACK messages, or statistics on the amount of data stored in the queue. It may be determined dynamically based on the information. For example, when the amount of uplink data for a certain period in the past exceeds a threshold value, the ONU 2 is shifted to the start mode, and when it is equal to or less than the threshold value, one control frame having a payload corresponding to the amount of uplink data Alternatively, a plurality of bands that can be transmitted are allocated to the ONU 2 in the power saving mode.

  In the third embodiment, the case where the present invention is applied to the first example of control message exchange in the conventional Dozing method shown in FIG. 7 has been described. However, the second control message exchange in the conventional Dozing method shown in FIG. It is clear that the present invention can be applied to examples.

(Embodiment 4)
Consider a case in which the size of uplink data that has flowed in during the power saving mode is larger than the payload size of one control message frame in an ONU that employs the cyclic sleep method. The ONU transmits uplink data using an uplink band that is divided into a plurality of control frames and allocated in the same allocation cycle. An example of control message exchange in this case is shown in FIG.

  When there is no data in the downstream queue addressed to the ONU 2 of the OLT 1 and there is no data in the upstream queue of the ONU 2, the OLT 1 transmits a Sleep Allow message that permits the ONU 2 to shift to the power saving mode. When the ONU 2 determines that the transition to the power saving mode is possible, it transmits a Sleep Request message to the OLT 1 and transitions to the power saving state for Ts 1 second. For example, the power saving period Ts1 is set from 10 milliseconds to 100 milliseconds.

  After Ts1 seconds elapses, the ONU 2 transitions to a startup state of Ta1 seconds, and a Gate message from the OLT 1 (in the power saving state, the ONU 2 cannot receive the Gate message even if the OLT 1 transmits the Gate message) and the Sleep Allow message. Receive. For example, the activation time Ta1 is preferably set to several milliseconds or less in consideration of the time error between the OLT1 and the ONU2. The OLT 1 transmits a Sleep Allow message, for example, at a cycle of Ta1 + Ts1 seconds.

  When the ONU 2 receives the Sleep Allow message, the data stored in the upstream queue is larger than the payload size of one ACK message frame and is less than or equal to the amount of data that can be transmitted in the band allocated by the band allocation unit 132 of the OLT 1. In some cases, uplink data is stored in the payload areas of a plurality of control messages, transmitted to the OLT 1, and again transitions to the power saving state for Ts1 seconds. Alternatively, when the data stored in the upstream queue is larger than the payload size of one Report message frame and is less than or equal to the amount of data that can be transmitted in the band allocated by the band allocation unit 132 of the OLT 1, the ONU 2 Without waiting for reception of the received data, the upstream state is periodically transferred by using the upstream bandwidth allocated by the Gate message, and the upstream data is stored in the payload area of a plurality of control messages and transmitted to the OLT 1 May be. For example, an extended OAM (eOAM) message can be used as the control message.

  If the data stored in the upstream queue after Ts2 seconds (Ts2 <Ts1) becomes larger than the amount of data that can be transmitted in the bandwidth allocated by the bandwidth allocation unit 132 of the OLT 1, the ONU 2 stores the data in the upstream queue. The amount is notified to the OLT 1 by a Report message. However, the upstream band for transmitting the ACK message and the Report message is periodically determined by the Gate message transmitted from the OLT 1 at an interval shorter than the Sleep Allow transmission cycle, regardless of the power saving state or the activation state of the ONU 2. Assigned.

  Note that for transmission and reception of the Sleep Allow message, the Sleep Request message, and the ACK message, MPCP messages using the functions of the MPCP units 131 and 231 of the OLT 1 and ONU 2 may be used, or the OAM units 133 and 232 of the OLT 1 and ONU 2 may be used. An OAM message (extended OAM) message using a function may be used, or any other control message may be used.

  The ONU 2 may determine data having a specific priority by the ONU 2 itself, preferentially store it in the payload of the control frame and transmit it to the OLT 1 during the power saving mode, and transmit other data after startup. . In addition, the OLT 1 may allocate the upstream bandwidth allocated to the ONU 2 in the power saving mode as a bandwidth for a plurality of report messages and / or a fixed bandwidth for a plurality of ACK messages, or statistics on the amount of data stored in the queue. It may be determined dynamically based on the information. For example, when the amount of uplink data for a certain period in the past exceeds a threshold value, the ONU 2 is shifted to the start mode, and when it is equal to or less than the threshold value, one control frame having a payload corresponding to the amount of uplink data Alternatively, a plurality of bands that can be transmitted are allocated to the ONU 2 in the power saving mode.

  In the fourth embodiment, the case where the present invention is applied to the first control message exchange example in the conventional cyclic sleep scheme shown in FIG. 9 has been described. However, the second control in the conventional cyclic sleep scheme shown in FIG. It is clear that the present invention can also be applied to message exchange examples.

(Embodiments 5 and 6)
An outline of the fifth and sixth embodiments will be described. The ONU switches the state between a power saving state in which transmission to the OLT is not performed and an activation state in which transmission to the OLT is performed. Then, when the ONU accumulates the uplink data to the OLT in the power saving state, the OLT in the startup state after the power saving state based on the uplink band assigned to the ONU in the power saving state by the OLT The upstream data is stored in the payload area of the control message to the OLT, and the control message to the OLT is transmitted to the OLT.

  Here, when the size of the uplink data to the OLT accumulated by the ONU in the power saving state is larger than the size of the data that can be transmitted in the uplink band allocated to the ONU by the ONU in the power saving state, the ONU In the activated state after the power saving state, a part of the uplink data to the OLT is transmitted to the OLT within the range of the uplink band, and in the activated state after the activated state, the remainder of the uplink data to the OLT is transmitted to the OLT. Send to. The ONU can use one or a plurality of control messages in each activation state.

(Embodiment 5)
Consider a case in which the size of uplink data that has flowed in during the power saving mode is larger than the payload size of one control message frame in an ONU that employs the Dozing method. The ONU transmits uplink data using an uplink band that is divided into a plurality of control frames and allocated over a plurality of allocation periods. An example of control message exchange in this case is shown in FIG.

  When there is no more data in the upstream queue of the ONU 2, the OLT 1 transmits a Sleep Allow message that permits the ONU 2 to enter the power saving mode. When the ONU 2 determines that the transition to the power saving mode is possible, it transmits a Sleep Request message to the OLT 1 and transitions to the power saving state for Ts 1 second. For example, the power saving period Ts1 is set from 10 milliseconds to 100 milliseconds.

  After Ts1 seconds elapses, the ONU 2 transitions to a startup state for Ta1 seconds and receives a Sleep Allow message from the OLT1. For example, the activation time Ta1 is preferably set to several milliseconds or less in consideration of the time error between the OLT1 and the ONU2. The OLT 1 transmits a Sleep Allow message, for example, at a cycle of Ta1 + Ts1 seconds.

  When the ONU 2 receives the Sleep Allow message, the data stored in the upstream queue is larger than the payload size of one ACK message frame and larger than the amount of data that can be transmitted in the band allocated by the band allocation unit 132 of the OLT 1 In this case, the upstream data is stored in the payload area of the control message, a part of the data is transmitted to the OLT 1, and after the transition to the power saving state for Ts1 seconds, when the power saving state ends again, the remaining data is Send.

  Alternatively, if the data stored in the upstream queue is larger than the payload size of one Report message frame and larger than the amount of data that can be transmitted in the band allocated by the band allocation unit 132 of the OLT 1, the ONU 2 Instead of waiting for reception, after transitioning to the activated state, the upstream band allocated by the Gate message is periodically used to store the upstream data in the payload area of a plurality of Report messages and transmit it to the OLT 1 Also good. However, the upstream band for transmitting the ACK message and the Report message is periodically determined by the Gate message transmitted from the OLT 1 at an interval shorter than the Sleep Allow transmission cycle, regardless of the power saving state or the activation state of the ONU 2. Assigned.

  Note that for transmission and reception of the Sleep Allow message, the Sleep Request message, and the ACK message, MPCP messages using the functions of the MPCP units 131 and 231 of the OLT 1 and ONU 2 may be used, or the OAM units 133 and 232 of the OLT 1 and ONU 2 may be used. An OAM message (extended OAM) message using a function may be used, or any other control message may be used.

  The ONU 2 may determine data having a specific priority by the ONU 2 itself, preferentially store it in the payload of the control frame and transmit it to the OLT 1 during the power saving mode, and transmit other data after startup. . In addition, the OLT 1 may allocate the upstream band allocated to the power saving mode ONU 2 as a band for one report message and / or a fixed band for one ACK message, and / or a band for a plurality of report messages. Alternatively, the bandwidth may be fixed for a plurality of ACK messages, or may be determined dynamically based on statistical information on the amount of data stored in the queue. For example, when the amount of uplink data for a certain period in the past exceeds a threshold value, the ONU 2 is shifted to the start mode, and when it is equal to or less than the threshold value, one control frame having a payload corresponding to the amount of uplink data Alternatively, a plurality of bands that can be transmitted are allocated to the ONU 2 in the power saving mode.

  In the fifth embodiment, the case where the present invention is applied to the first control message exchange example in the conventional Dozing method shown in FIG. 7 has been described. However, the second control message exchange in the conventional Dozing method shown in FIG. It is clear that the present invention can be applied to examples.

(Embodiment 6)
Consider a case in which the size of uplink data that has flowed in during the power saving mode is larger than the payload size of one control message frame in an ONU that employs the cyclic sleep method. The ONU transmits uplink data using an uplink band that is divided into a plurality of control frames and allocated over a plurality of allocation periods. An example of control message exchange in this case is shown in FIG.

  When there is no data in the downstream queue addressed to the ONU 2 of the OLT 1 and there is no data in the upstream queue of the ONU 2, the OLT 1 transmits a Sleep Allow message that permits the ONU 2 to shift to the power saving mode. When the ONU 2 determines that the transition to the power saving mode is possible, it transmits a Sleep Request message to the OLT 1 and transitions to the power saving state for Ts 1 second. For example, the power saving period Ts1 is set from 10 milliseconds to 100 milliseconds.

  After Ts1 seconds elapses, the ONU 2 transitions to a startup state of Ta1 seconds, and a Gate message from the OLT 1 (in the power saving state, the ONU 2 cannot receive the Gate message even if the OLT 1 transmits the Gate message) and the Sleep Allow message. Receive. For example, the activation time Ta1 is preferably set to several milliseconds or less in consideration of the time error between the OLT1 and the ONU2. The OLT 1 transmits a Sleep Allow message, for example, at a cycle of Ta1 + Ts1 seconds.

  When the ONU 2 receives the Sleep Allow message, the data stored in the upstream queue is larger than the payload size of one ACK message frame and larger than the amount of data that can be transmitted in the band allocated by the band allocation unit 132 of the OLT 1 In this case, the upstream data is stored in the payload area of the control message, a part of the data is transmitted to the OLT 1, and after the transition to the power saving state for Ts1 seconds, when the power saving state ends again, the remaining data is Send.

  Alternatively, if the data stored in the upstream queue is larger than the payload size of one Report message frame and larger than the amount of data that can be transmitted in the band allocated by the band allocation unit 132 of the OLT 1, the ONU 2 Instead of waiting for reception, after transitioning to the activated state, the upstream band allocated by the Gate message is periodically used to store the upstream data in the payload area of a plurality of Report messages and transmit it to the OLT 1 Also good. However, the upstream band for transmitting the ACK message and the Report message is periodically determined by the Gate message transmitted from the OLT 1 at an interval shorter than the Sleep Allow transmission cycle, regardless of the power saving state or the activation state of the ONU 2. Assigned.

  Note that for transmission and reception of the Sleep Allow message, the Sleep Request message, and the ACK message, MPCP messages using the functions of the MPCP units 131 and 231 of the OLT 1 and ONU 2 may be used, or the OAM units 133 and 232 of the OLT 1 and ONU 2 may be used. An OAM message (extended OAM) message using a function may be used, or any other control message may be used.

  The ONU 2 may determine data having a specific priority by the ONU 2 itself, preferentially store it in the payload of the control frame and transmit it to the OLT 1 during the power saving mode, and transmit other data after startup. . In addition, the OLT 1 may allocate the upstream band allocated to the power saving mode ONU 2 as a band for one report message and / or a fixed band for one ACK message, and / or a band for a plurality of report messages. Alternatively, the bandwidth may be fixed for a plurality of ACK messages, or may be determined dynamically based on statistical information on the amount of data stored in the queue. For example, when the amount of uplink data for a certain period in the past exceeds a threshold value, the ONU 2 is shifted to the start mode, and when it is equal to or less than the threshold value, one control frame having a payload corresponding to the amount of uplink data Alternatively, a plurality of bands that can be transmitted are allocated to the ONU 2 in the power saving mode.

  In the sixth embodiment, the case where the present invention is applied to the first example of exchanging control messages in the conventional cyclic sleep method shown in FIG. 9 has been described. However, the second control in the conventional cyclic sleep method shown in FIG. It is clear that the present invention can also be applied to message exchange examples.

(Modification)
In the embodiment 1-6, the case where the power saving mode of all the ONUs 2 to which the OLT 1 is centrally connected is described. However, the present invention is also applied to the case where the ONU 2 autonomously controls the power saving mode. It is clear that it can be applied. In Embodiment 1-6, the case of EPON and 10G-EPON has been described. However, other PONs such as B-PON, G-PON and XG-PON conforming to the ITU-T recommendation, WDM-PON, It is clear that the present invention can be applied to the power saving mode in the CDM-PON.

  The optical network system and the optical network termination device according to the present invention can be applied to an optical communication network in a smart grid.

1: OLT
2: ONU
3: Optical fiber transmission line 4: Splitter 11: SNI port 12: Queue management means 13: PON signal processing means 14: PON-IF port 21: UNI port 22: Queue management means 23: PON signal processing means 24: PON-IF Port 25: Queue monitoring unit 131: MPCP unit 132: Band allocation unit 133: OAM unit 231: MPCP unit 232: OAM unit 233: Demultiplexing unit 234, 235: PHY unit 236: MAC unit

Claims (8)

An optical network system in which one optical subscriber line termination device and a plurality of optical network termination devices perform point-to-multipoint communication via an optical fiber transmission line,
The optical subscriber line terminating device allocates an upstream band to each optical network terminating device,
Each optical network termination device switches the state between a power saving state in which transmission to the optical subscriber line termination device is not performed and an activation state in which transmission to the optical subscriber line termination device is performed. When the upstream data to the optical subscriber line termination device is stored, the optical subscriber line termination device is connected to each optical network termination device in the power saving state, and then after the power saving state. In the activated state, the optical subscriber line terminating device does not wait for the optical network terminating device to allocate an upstream band in the activated state, and the upstream data to the optical subscriber line terminating device is transmitted to the optical subscriber. An optical system comprising: a control message to be transmitted to the optical subscriber line terminator, and stored in a payload area of a control message to the line terminator. Tsu network system.   The size of the uplink data to the optical subscriber line terminator accumulated by each optical network terminator in the power saving state is the uplink data size assigned by the optical subscriber line terminator to each optical network terminator in the power saving state. When the optical network terminator is smaller than the size of data that can be transmitted in the band, each optical network terminator transmits all the uplink data to the optical subscriber line terminator in the startup state after the power saving state. The optical network system according to claim 1, wherein the optical network system transmits to a terminating device.   The size of the uplink data to the optical subscriber line terminator accumulated by each optical network terminator in the power saving state is the uplink data size assigned by the optical subscriber line terminator to each optical network terminator in the power saving state. When larger than the size of data that can be transmitted in the band, each optical network terminating device, in an activated state after the power saving state, transmits a part of the upstream data to the optical subscriber line terminating device in the upstream band. Transmitting the remaining uplink data to the optical subscriber line terminating device to the optical subscriber line terminating device in the activated state after the activated state. The optical network system according to claim 1, wherein the optical network system is characterized.   Each optical network termination device transmits uplink data to the optical subscriber line termination device to the optical subscriber line termination device based on a transmission priority of the uplink data to the optical subscriber line termination device. The optical network system according to any one of claims 1 to 3, wherein the optical network system is characterized in that: A state switching unit that switches a state between a power saving state in which transmission to the optical subscriber line termination device is not performed and an activation state in which transmission to the optical subscriber line termination device is performed;
A data storage unit for storing upstream data to the optical subscriber line terminating device;
In the power saving state, when uplink data is accumulated in the optical subscriber line terminating device, the optical subscriber line terminating device is connected to the optical subscriber line terminating device after the power saving state based on the uplink bandwidth allocated in the power saving state. In the activated state, the optical subscriber line terminating device controls the upstream data to the optical subscriber line terminating device without waiting for the optical subscriber line terminating device to allocate the upstream bandwidth in the activated state. A data transmission unit that stores in a payload area of the message and transmits a control message to the optical subscriber line terminating device to the optical subscriber line terminating device;
An optical network termination device comprising:   When the size of uplink data stored in the power saving state to the optical subscriber line terminating device is smaller than the size of data that can be transmitted in the upstream band allocated by the optical subscriber line terminating device in the power saving state In addition, the data transmission unit transmits all of the uplink data to the optical subscriber line terminating device to the optical subscriber line terminating device in an activated state after the power saving state. Item 6. The optical network termination device according to Item 5.   When the size of the uplink data stored in the power saving state to the optical subscriber line terminating device is larger than the size of data that can be transmitted in the upstream band allocated by the optical subscriber line terminating device in the power saving state In addition, the data transmission unit transmits a part of the uplink data to the optical subscriber line termination device to the optical subscriber line termination device within the range of the uplink band in an activation state after the power saving state. 6. The optical network according to claim 5, wherein, in an activated state after the activated state, the remainder of uplink data to the optical subscriber line terminating device is transmitted to the optical subscriber line terminating device. Termination device.   The data transmission unit transmits uplink data to the optical subscriber line termination device to the optical subscriber line termination device based on a transmission priority of the uplink data to the optical subscriber line termination device. An optical network termination device according to any one of claims 5 to 7.

Images