JP2014138232A - Communication system and high-order side communication device and low-order side communication device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To solve the problem that disconnection of a logical link in a power-saving mode cannot be avoided so far.SOLUTION: A high-order side communication device transmits, in a specific cycle, a control message for monitoring a low-order side communication device, and, when a response message is not received within a set period, disconnects a link, and, when the low-order side communication device is in a specific operation mode, transmits a control message to the low-order side communication device upon receiving a response message from the low-order side communication device within a preset first period, thereby maintaining the link with the low-order side communication device. The low-order side communication device has a specific operation mode in which a first period shorter than the specific cycle in which to communicate with the high-order side communication device and a second period in which not to communicate with the high-order side communication device are repeated in a preset cycle, so that, when in the specific operation mode, the low-order side communication device transmits a response message to the high-order side communication device and receives a control message from the high-order side communication device within the first period.

Description

  The present invention relates to a communication system, a higher-level communication device, and a lower-level communication device.

  In recent years, an EPON (Ethernet (registered trademark) Passive Optical Network) system has become widespread as an access communication system for connecting to a network from a subscriber side using an optical fiber. In the EPON system, an OLT (Optic Line Terminater) is arranged as a higher-level communication device. An ONU (Optical Network Unit) is connected to the OLT as a plurality of lower-level communication devices. In the EPON system, an optical signal transmitted / received from the OLT through a single optical fiber is branched by an optical splitter and connected to the ONU. A technique for realizing power saving of an apparatus used in such an EPON system has been studied (for example, see Patent Document 1).

JP 2011-181990 A

  In the EPON system, since a plurality of ONUs share a single optical fiber and perform communication by a TDM (Time Division Multiplexing) method, the OLT controls the transmission timing of upstream data of the ONU. Further, the EPON system uses an OAM (Operation Administration and Maintenance) protocol to perform monitoring control. In the OAM protocol, the OLT transmits a message for confirming whether the ONU is operating normally (also referred to as an alive confirmation message, but hereinafter referred to as an operation confirmation message) to the ONU. Then, for example, when the OLT cannot receive a response message from the ONU within 5 seconds, the OLT disconnects the logical link with the ONU. However, the ONU having the power saving mode repeats the active state and the sleep state at a preset time interval. For this reason, for example, when the ONU is in a sleep state, even if the OLT transmits an operation confirmation message to the ONU, the ONU cannot be received. As described above, the ONU has a problem that the logical link is disconnected by the OLT even though it is operating normally.

  An object of the present invention is to provide a communication system, a higher-level communication device, and a lower-level communication device that can avoid disconnection of a logical link in a power saving mode.

  A communication system according to one aspect is a communication system including a lower-level communication device and a higher-level communication device arranged on the upper side of the lower-level communication device, and the higher-level communication device monitors the lower-level communication device. When a control message is transmitted at a specific cycle and a response message is not received from the lower-level communication device within a preset period, the link with the lower-level communication device is disconnected, and the lower-level communication device When in the operation mode, when a response message is received from the lower-level communication device within a preset first period, a control message is transmitted to the lower-level communication device to maintain a link with the lower-level communication device, The lower-level communication device repeats the first period shorter than the specific cycle for communicating with the higher-level communication device and the second period for not communicating with the higher-level communication device at a predetermined cycle. If there is an operation mode and is not in a specific operation mode, a response message is transmitted to the upper communication device when a control message periodically transmitted from the upper communication device is received. Within one period, a response message is transmitted to the upper communication apparatus and a control message is received from the upper communication apparatus.

  A higher-level communication device according to one aspect transmits a control message for monitoring a lower-level communication device at a specific period, and if a response message is not received from the lower-level communication device within a preset period, When the link with the communication device is disconnected and the lower-level communication device is in a specific operation mode, a control message is sent to the lower-level communication device when a response message is received from the lower-level communication device within a preset first period. To maintain the link with the lower-level communication device.

  The lower-level communication device according to one aspect has a specific operation mode in which a first period for communicating with the higher-level communication device and a second period for not communicating with the higher-level communication device are repeated in a preset cycle. When not in a specific operation mode, when a control message periodically transmitted from the higher-level communication device is received, a response message is transmitted to the higher-level communication device. When in a specific operation mode, within the first period In addition, a response message is transmitted to the higher-level communication device, and a control message is received from the higher-level communication device.

  The communication system, the upper communication apparatus, and the lower communication apparatus according to the present invention can avoid the disconnection of the logical link in the power saving mode.

It is a figure which shows an example of a communication system. It is a figure which shows an example of ONU. It is a figure which shows an example of OLT. It is a figure which shows an example of the prior sequence of a power saving mode. It is a figure which shows an example of the power saving sequence led by OLT. It is a figure which shows an example of the power saving sequence led by ONU. It is a figure which shows an example of a Wakeup sequence led by OLT. It is a figure which shows an example of the control sequence of MPCPDU in power saving mode. It is a figure which shows an example of the control sequence of OAMPDU in power saving mode. It is a figure which shows the problem of the control sequence of OAMPDU in power saving mode. It is a figure which shows an example of the control sequence of OAMPDU in the power saving mode in this embodiment.

  Hereinafter, embodiments of a communication system, a higher-level communication device, and a lower-level communication device according to the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a diagram illustrating an example of a communication system 100. In the communication system 100 of FIG. 1, the OLT 101 of the higher-level communication device arranged on the station side accommodates a plurality of ONUs 102 arranged on the subscriber side by the PON line 103. The PON line 103 is branched by a splitter 104 and connected to each ONU 102.

  In the example of FIG. 1, n (n is a positive integer) ONUs 102 (ONU102_1, ONU102_2, and ONU102_n) are connected to the OLT 101 via the PON line 103. And each user terminal 105 (user terminal 105_1, user terminal 105_2, and user terminal 105_n) is connected to each ONU102. The user terminal 105_1, the user terminal 105_2, and the user terminal 105_n can access the upper network via the ONU 102 and the OLT 101.

  Here, in the following description, when a matter common to the ONU 102_1, the ONU 102_2, and the ONU 102_n is described, the “_ code” at the end of the code is omitted and represented as the ONU 102. In addition, in order to indicate a specific subscriber-side device, a “_ code” is added and expressed as, for example, ONU102_1. The same applies to the user terminal 105.

  In FIG. 1, the OLT 101 time-division-multiplexes and transmits a downstream signal to each ONU 102, receives a frame addressed to itself by each ONU 102, and discards a frame addressed to another device. Further, the upstream signal from the ONU 102 to the OLT 101 is transmitted to the PON line 103 according to the timing instructed from the OLT 101. The OLT 101 manages the transmission timing and transmission data amount (corresponding to the transmission time) of each ONU 102, and manages so that the frames transmitted by each ONU 102 do not collide with each other on the PON line 103.

  For example, when the ONU 102_n is unregistered and the ONU 102_n is connected to the PON line 103, the OLT 101 automatically detects the unregistered ONU 102_n and notifies the provisional transmission timing. In response to this, when receiving a registration request from the unregistered ONU 102_n, the OLT 101 issues and notifies an LLID (Logical Link ID) and establishes a link. Then, the OLT 101 notifies the unregistered ONU 102_n of the transmission timing and transmission band (transmission data amount, transmission time, etc.). In this way, the unregistered ONU 102 — n can perform data communication by establishing a link with the OLT 101. When the logical link is disconnected, the OLT 101 and the ONU 102 re-execute the above connection sequence.

  Further, the ONU 102 of the communication system 100 according to the present embodiment has a power saving mode and can reduce power consumption. For example, the ONU 102 periodically switches between the normal operation state (active state) and the sleep state in which the transmission / reception function is temporarily stopped, thereby stopping the power supply of the circuit that is not operating in the sleep state, thereby reducing the power consumption. To reduce.

  On the other hand, the communication system 100 according to the present embodiment corresponds to the EPON standard, and may be referred to as a monitoring control message (control message) for monitoring and controlling operations between the OLT 101 and the ONU 102 in accordance with Ethernet OAM regulations. ).

  Here, in order to manage the logical link between the OLT and the ONU, the data units used in the EPON standard are the following two. One is MPCPDU (Multi-Point Control Protocol Data Unit). The other is OAMPDU (Operations, Administration, and Maintenance Protocol Data Unit).

  The OLT 101 periodically transmits an MPCPDU frame and an OAMPDU frame to the ONU 102 in order to maintain the logical link in an established state. Then, the OLT 101 monitors whether or not responses from the ONU 102 to the MPCPDU and OAMPDU can be received within a predetermined period. The OLT 101 disconnects the logical link due to a timer (called mpcp_timer) when there is no response from the ONU 102 to the MPCPDU within one second, for example. Also, the OLT 101 disconnects the logical link due to a timer (referred to as local_lost_link_timer) when there is no response from the ONU 102 to the OAM PDU within 5 seconds, for example. In this way, the OLT 101 monitors and manages the logical link with each ONU 102.

Next, frame examples of MPCPDU and OAMPDU that are periodically transmitted and received between the OLT 101 and the ONU 102 will be described.
(Example of MPCPDU)
GATE frame: For example, it is transmitted from the OLT 101 to the ONU 102 at a short interval of several hundred microseconds (μsec) to several milliseconds (msec).
REPORT frame: a response frame returned by the ONU 102 in response to a GATE frame transmitted by the OLT 101.
(Example of OAMPDU)
Information frame: transmitted from the OLT 101 to the ONU 102 at a longer interval (for example, 1 second (sec)) than the MPC PDU. A response frame returned by the ONU in response to the Information frame transmitted by the OLT 101 is also an Information frame.

  Thus, the MPCPDU frame and the OAMPDU frame are transmitted and received between the OLT 101 and the ONU 102 at different periods.

Here, the period during which the OLT 101 and the ONU 102 can transmit and receive each frame during the power saving mode is an active state (T1: ActiveDuration) period (hereinafter referred to as an active period). The conditions for maintaining the logical link in the MPCPDU frame are as follows.
・ Condition 1: T1> To1
To1 of condition 1 indicates the time (response time of ONU 102) from the reception timing of the GATE frame to the transmission timing of the REPORT frame.
・ Condition 2: T2 <To2
T2 of Condition 2 indicates a period of sleep state (T2: SleepDuration) (hereinafter referred to as a sleep period). Further, To2 indicates the time until the OLT 101 determines that the logical link is disconnected when the OLT 101 transmits a GATE frame and the REPORT frame cannot be received from the ONU 102. In the EPON standard, To2 corresponds to 1 second set in a timer (mpcp_timer), for example.

  In order to enhance the power saving effect while maintaining the logical link with the MPCPDU, it is preferable to shorten the active period (T1) of condition 1 as much as possible and the sleep period (T2) of condition 2 as long as possible. For example, T1 is set to 10 milliseconds (msec) and T2 is set to 100 milliseconds (msec). In this case, for example, as described above, since the GATE frame is transmitted with a period of several hundred microseconds (μsec) to several milliseconds (msec), the ONU 102 has at least 1 in the active period (T1: 10 msec). Times of GATE frames can be reliably received. Thereby, the OLT 101 can maintain the logical link with the MPC PDU.

  In this way, the OLT 101 can maintain the logical link with the ONU 102 established by the MPCPDU.

On the other hand, in the power saving mode, the conditions for maintaining the logical link with the OAMPDU are as follows.
Condition 3: The OLT 101 transmits an Information frame from the OLT 101 in accordance with the active period (T1) of the ONU 102.

  As described above, in order to maintain the logical link by the OAMPDU frame, the OLT 101 is required to satisfy the condition 3. However, when the power saving mode continues for a long period of time, the timer time of the OLT 101 and the ONU 102 Deviations occur little by little. For this reason, the timings of the active period (T1) and sleep period (T2) managed by the OLT 101 and the respective periods (T1 and T2) managed by the ONU are shifted, so that the condition 3 is satisfied. Becomes difficult. For example, even when the OLT 101 transmits the information frame on the assumption that the ONU 102 is in the active period (T1), the ONU 102 may be in the sleep period (T2). In the example described with the MPC PDU, T1 is set to 10 msec and T2 is set to 100 msec. Therefore, the OLT 101 transmits an information frame aiming at a period of 10 msec in an active state. However, if there is a time lag of 10 msec or more between the OLT 101 and the ONU 102, the ONU 102 enters the sleep period (T2) and cannot receive the information frame. Then, the OLT 101 disconnects the logical link of the ONU 102 when a timer (local_lost_link_timer) for determining disconnection of the logical link by the OAMPDU elapses for a predetermined time (for example, 5 seconds).

  As described above, when the ONU 102 is in the sleep state of the power saving mode, the ONU 102 does not receive the monitoring control message (Information OAMPDU) transmitted from the OLT 101, and therefore no response message is returned. For this reason, in the OAM layer, there arises a problem that the logical link of the ONU 102 set to the power saving mode is disconnected.

  Therefore, as shown below, the PON system 100 according to the present embodiment avoids disconnection of the logical link of the ONU 102 set in the power saving mode in the OAM layer.

  Next, an example of the ONU 102 will be described with reference to FIG.

  FIG. 2 is a diagram illustrating an example of an ONU. In FIG. 2, the ONU 102 includes a user IF (Interface) 201, an ONU control unit 202, a PONIF (Interface) 203, a transmission buffer 204, a power saving control unit 205, and an OAM control unit 206.

  The user IF 201 is an interface for connecting the user terminal 105 shown in FIG. 1, and for example, a LAN (Local Area Network) interface is used. Data input from the user terminal 105 via the user IF 201 is temporarily stored in the transmission buffer 204.

  The ONU control unit 202 includes a CPU (Central Processing Unit) and the like, and controls the entire ONU 102. The ONU control unit 202 performs DBA (Dynamic Bandwidth Allocation) control with the OLT 101 illustrated in FIG. DBA is a technique in which the OLT 101 allocates a communication band according to the amount of data transmitted by the ONU 102. For example, the ONU control unit 202 notifies the OLT 101 of the amount of transmission data stored in the transmission buffer 204 and transmits the transmission data to the OLT 101 in the communication band allocated from the OLT 101. The ONU control unit 202 extracts data addressed to the ONU 102 from data received by the PONIF 203 from the OLT side, and outputs the data to the user terminal 105 side via the user IF 201.

  The PONIF 203 is an interface for communicating with the OLT 101. For example, the PONIF 203 converts the data read from the transmission buffer 204 by the ONU control unit 202 into an optical signal and transmits it to the OLT 101, and conversely converts the optical signal received from the OLT 101 into an electrical signal and sends it to the ONU control unit 202. Output.

  For example, a semiconductor memory is used as the transmission buffer 204 and temporarily stores transmission data of the user terminal 105.

  Based on a command from the OLT 101, the power saving control unit 205 controls the stop of power supply and the supply of power to circuits not used in the ONU 102. For example, the power saving control unit 205 stops the power source of a circuit that transmits / receives an optical signal inside the PONIF 203 to change the ONU 102 from the active state to the sleep state. Further, the power saving control unit 205 returns from the sleep state to the active state after a predetermined time has elapsed. As described above, the power saving control unit 205 includes a timer therein and performs control to periodically repeat the sleep state and the active state.

  The OAM control unit 206 transmits and receives a monitoring control message between the OLT 101 and the ONU 102 in accordance with Ethernet OAM regulations. For example, the OAM control unit 206 receives the information OAMPDU of the monitoring control message transmitted from the OLT 101 at a cycle of 1 second and transmits the response message. As a result, the OLT 101 confirms the connection of the ONU 102. The ONU 102 disconnects the logical link with the OLT 101 when the monitoring control message transmitted by the OLT 101 in a cycle of 1 second cannot be received within a predetermined time (for example, 5 seconds).

  As described above, the ONU 102 temporarily stores the data received from the user terminal 105 in the transmission buffer 204. Then, data is transmitted to the OLT 101 in the communication band assigned by the OLT 101, and data addressed to the ONU 102 received from the OLT 101 is output to the user terminal 105. The monitoring control message is periodically transmitted / received between the OLT 101 and the ONU 102 in accordance with Ethernet OAM regulations.

  Next, an example of the OLT 101 will be described with reference to FIG.

  FIG. 3 is a diagram illustrating an example of the OLT. In FIG. 3, the OLT 101 basically includes a PONIF (Interface) 301, an OLT control unit 302, and an upper network IF (Interface) 303. Further, the OLT 101 includes a packet filter unit 304, an ONUDB (Data Base) 305, a power saving control unit 306, and an OAM control unit 307.

  The PONIF 301 is an interface for transmitting and receiving data to and from the ONU 102 shown in FIG. For example, the PONIF 301 converts data transmitted / received to / from an upper network via the packet filter unit 304 or control data transmitted / received by the OLT control unit 302 into an optical signal and communicates with the ONU 102.

  The OLT control unit 302 includes, for example, a CPU (Central Processing Unit) and the like, and controls the entire OLT 101. In addition, the OLT control unit 302 performs DBA control with the ONU 102 and performs processing for assigning a communication band to the ONU 102 according to, for example, the amount of transmission data notified from the ONU 102.

  The host network IF 303 is an interface for accessing the host network.

  The packet filter unit 304 determines the type of packet transmitted / received between the ONU 102 and the OLT 101. The packet filter unit 304 inputs / outputs PON control data (such as MPCPDU and OAMPDU) transmitted / received to / from the ONU 102 to / from the OLT control unit 302, and inputs user data to / from the higher level network IF 303. Output.

  The ONUDB 305 is a database for managing the MAC (Media Access Control) addresses and link states of a plurality of ONUs 102 accommodated by the OLT 101. The OLT control unit 302 authenticates the ONU 102, registers the authenticated ONU 102 in the ONU DB 305, and manages the state of the operating ONU 102. Then, the OLT control unit 302 transfers user data transmitted from the authenticated ONU 102 managed by the ONUDB 305 to the upper network.

  The power saving control unit 306 instructs the ONU 102 to set the ONU 102 from a normal operation mode to a specific operation mode (power saving mode). Note that the normal operation mode is a mode in which the ONU 102 always operates without going into the sleep state. Then, the power saving control unit 306 receives a message requesting the transition to the sleep state from the ONU 102 and transmits a message permitting the transition to the sleep state to the ONU 102. Further, when the power saving control unit 306 receives a wake-up message from the ONU 102, the power-saving control unit 306 grasps that the ONU 102 is in a wake-up state (normal operation mode). Whether each ONU 102 is set to the power saving mode is managed by the ONUDB 305 via the OLT control unit 302.

  The OAM control unit 307 transmits and receives an OAM message between the OLT 101 and the ONU 102 in accordance with Ethernet OAM regulations. For example, the OAM control unit 307 transmits Information OAMPDU to the ONU 102 at a cycle of 1 second, receives a response message from each ONU 102, and checks whether the ONU 102 is active or not. When the OLT 101 fails to receive a response message from the ONU 102 within a predetermined time (for example, 5 seconds) after transmitting the monitoring control message, the OLT 101 disconnects the logical link of the ONU 102. The OAM control unit 307 stores the logical link state of each ONU 102 in the ONU DB 305 and manages the ONU 102 so that the state of each ONU 102 can be understood.

  As described above, the OLT 101 manages the ONU 102 and controls communication of the ONU 102 to the upper network so that the ONU 102 can transmit and receive data to and from the upper network.

  Next, a processing sequence for setting the ONU 102 to the power saving mode will be described with reference to FIG.

  FIG. 4 is a diagram illustrating an example of a pre-sequence in the power saving mode. In FIG. 4, the OLT 101 shows an example in which the ONU 102 is set to the power saving mode by transmitting / receiving an OAM message to / from the ONU 102.

  (Step S401) The OLT 101 transmits an eOAM-GetReq (Capability) message to the ONU 102 to request notification of the type and function of the power saving mode supported by the ONU 102 or the current set value. Examples of the power saving mode include a power saving mode in which both the transmission circuit and the receiving circuit of the ONU 102 are in a sleep state, and a power saving mode in which only the transmission circuit is in a sleep state.

  (Step S402) The OLT 101 receives an eOAM-GetRes (Capability) message from the ONU 102, and grasps the type, function, setting value, and the like of the power saving mode of the ONU 102.

  (Step S403) The OLT 101 transmits an eOAM-SetReq (Configuration) message to the ONU 102, and sets the ONU 102 to a predetermined power saving mode. For example, the OLT 101 can select the type and function of the power saving mode.

  (Step S404) The OLT 101 receives an eOAM-SetRes (Configuration) message from the ONU 102, and confirms that the power saving mode of the ONU 102 is set as requested.

  In this way, the ONU 102 is set to the power saving mode. Thereafter, when the ONU 102 receives a command to shift to the sleep state from the OLT 101, the ONU 102 executes the operation in the power saving mode that periodically repeats the sleep state and the active state.

  Next, the flow of control between the OLT 101 and the ONU 10 when the OLT 101 takes the initiative and shifts to the power saving mode and confirms the logical link by the MPC PDU will be described with reference to FIG.

  FIG. 5 is a diagram illustrating an example of a power saving sequence led by the OLT. In FIG. 5, similarly to FIG. 4, the state of the control frame transmitted and received between the OLT 101 and the ONU 102 is depicted with the horizontal axis as the time axis. Note that the OLT 101 periodically transmits a GATE frame to the ONU 102. Then, the ONU 102 returns a REPORT frame to the OLT 101 and requests a communication band for transmitting data to the OLT 101. In FIG. 5, the return of the REPORT frame in the normal mode is omitted.

  Hereinafter, the flow of control for shifting from the normal mode to the power saving mode will be described in order.

  (Step S411) The OLT 101 transmits a control frame (SLEEP_ALLOW (TRx)) to the ONU 102 to shift the ONU 102 from the normal mode to the power saving mode. Note that TRx indicates a function of a power saving mode in which both the transmission circuit and the reception circuit for the ONU 102 to communicate with the OLT 101 are set to the sleep state. In this case, the ONU 102 is in a state where not only transmission to the OLT 101 but reception is possible. Note that data transmitted by the user terminal 105 can be received. In addition, there is a Tx power saving mode in which only the transmission circuit is in a sleep state. In this embodiment, a case where the TRx power saving mode is used will be described. In the example of FIG. 5, the period from time p1 is normal mode (Normal mode), the period from time p1 to p2 is power saving mode (Power saving sleep mode), and the normal mode is again after time p2. It is. Here, the power saving mode is an operation mode in which an active period (Active Duration): T1 and a sleep period (Sleep Duration): T2 are periodically repeated. For the sake of easy understanding in FIG. 5, the active period T1 and the sleep period T2 are drawn to the same length. However, the active period T1 is actually compared with the sleep period T2 in order to increase the power saving effect. And set short.

  (Step S412) In response to the request from the OLT 101, the ONU 102 responds to the OLT 101 to shift to the power saving mode (SLEEP_ACK (TRx)). Then, a predetermined active period T1 and sleep period T2 are repeated.

  (Step S413) The OLT 101 periodically transmits a GATE frame.

  (Step S414) The ONU 102 receives the GATE frame and returns a REPORT frame to the OLT 101.

  (Step S415) When any traffic (Data) is input from the user terminal 105 during the power saving mode, the ONU 102 transmits a control frame (SLEEP_ACK (Wakeup)) notifying the end of the power saving mode to the OLT 101. . The ONU 102 can accept the traffic from the user terminal 105 at any time even in the sleep state. Thereafter, the ONU 102 shifts to the normal mode and transmits data transmitted from the user terminal 105 to the OLT 101.

  In this way, the ONU 102 can switch between the power saving mode and the normal mode.

  Next, the flow of control between the OLT 101 and the ONU 102 when the logical link is confirmed by the MPC PDU by switching to the power saving mode led by the ONU 102 will be described with reference to FIG.

  FIG. 6 is a diagram illustrating an example of an ONU-led power saving sequence. 6 is a diagram depicting a state of a control frame transmitted and received between the OLT 101 and the ONU 102 with the horizontal axis as a time axis, as in FIG. The difference from FIG. 5 is that the control frame (SLEEP_INDICATION) is transmitted from the ONU 102 in step S451 before the control frame (SLEEP_ALLOW (TRx)) is transmitted from the OLT 101 in step S411. Here, SLEEP_INDICATION is a control frame for requesting the OLT 101 to enter the sleep mode from the ONU 102, for example, because the traffic of the user terminal 105 connected to the ONU 102 is not flowing. In FIG. 6, the processes other than step S410 are the same as or similar to those in FIG.

  Next, a control flow when the OLT 101 shifts the ONU 102 to the normal mode when the OLT 101 receives traffic (Data) for the ONU 102 in the power saving mode from the upper network will be described with reference to FIG.

  FIG. 7 is a diagram illustrating an example of a Wakeup sequence led by the OLT. In FIG. 7, similarly to FIG. 5 and FIG. 6, the state of the control frame transmitted and received between the OLT 101 and the ONU 102 is depicted with the horizontal axis as the time axis. In FIG. 7, the processes denoted by the same reference numerals as those in FIGS. 5 and 6 indicate the same processes as in FIGS. 5 and 6. In FIG. 7, the timing when shifting from the power saving mode to the normal mode is different from that in FIGS. 5 and 6. 5 and 6, when receiving data from the user terminal 105, the ONU 102 transmits a control frame (SLEEP_ACK (Wakeup)), which is led by the ONU 102 to notify the end of the power saving mode, to the OLT 101 in step S 415. On the other hand, in the case of FIG. 7, the OLT 101 that has received the data addressed to the ONU 102 from the upper network in step S452 transmits a control frame (SLEEP_ALLOW (Wakeup)) requesting the end of the power saving mode to the ONU 102. Upon receiving the control frame, the ONU 102 transmits a control frame (SLEEP_ACK (Wakeup)) notifying the end of the power saving mode to the OLT 101.

  In this manner, the ONU 102 in the power saving mode under the leadership of the OLT 101 can be shifted to the normal mode.

  FIG. 8 is a diagram illustrating an example of an MPCPDU control sequence in the power saving mode. 8 shows an example in which the ONU 102 shifts to the power saving mode under the initiative of the ONU 102 side, and the processing with the same reference numerals as in FIG. 6 shows the same processing as in FIG. In FIG. 8, the ONU 102 that has shifted to the power saving mode at time p1 periodically repeats the active period (T1) and the sleep period (T2). When the ONU 102 receives a GATE frame from the OLT 101 during the active period (T1), it returns a REPORT frame to the OLT 101. However, when a GATE frame is received from the OLT 101 during the sleep period (T2), the ONU 102 does not return a REPORT frame to the OLT 101. However, since the period T1 and the period T2 are set so as to satisfy the conditions 1 and 2 described above, the OLT 101 can receive at least one GATE frame before the timer times out. As a result, the logical link between the OLT 101 and the ONU 102 is maintained.

  Thus, in the case of MPCPDU, a logical link between the OLT 101 and the ONU 102 can be maintained. This is because the frame of the MPCPDU is periodically transmitted at a time interval shorter than the active period (T1), so that the ONU 102 receives at least one GATE frame and transmits a REPORT frame in the active period (T1). Because it can be done. That is, the ONU 102 cannot transmit / receive during the sleep period, but can transmit / receive the MPCPDU frame to / from the OLT 101 during the active period until the timer times out.

  Next, an example of maintaining a logical link between the OLT 101 and the ONU 102 in the case of OAMPDU will be described with reference to FIG.

  FIG. 9 is a diagram illustrating an example of a control sequence of the OAM PDU during the power saving mode. 9, the ONU 102 corresponds to FIG. 8 when the ONU 102 shifts to the power saving mode under the initiative of the ONU 102, and the processes with the same reference numerals as those in FIG. 8 indicate the same processes as in FIG. In FIG. 9, the ONU 102 that has shifted to the power saving mode at time p1 periodically repeats the active period (T1) and the sleep period (T2). When the ONU 102 receives the information frame of the OAMPDU from the OLT 101 during the active period (T1) (step S461), the ONU 102 returns the information frame (step S462). In this case, in step S412, the OLT 101 performs monitoring control corresponding to the power saving mode from the timing (time p1a) at which the control frame (SLEEP_ACK (TRx)) indicating the transition to the power saving mode is received from the ONU 102. In this case, the OLT 101 manages the operation state of the ONU 102 by counting the period of the active period (T1) and the sleep period (T2) that are determined in advance from the time p1a. Then, the OLT 101 transmits an information frame to the ONU 102 in anticipation of the active period (T1) of the ONU 102 (step S461, step S463). Further, the ONU 102 returns an information frame to the OLT 101 (steps S462 and S464). Here, as described above, the information frame of the OAMPDU is periodically transmitted from the OLT 101 to the ONU 102 at intervals of 1 second, for example.

  However, since there is a difference between the timer of the OLT 101 and the timer of the ONU 102, the information frame transmitted in anticipation of the active period (T1) of the ONU 102 may hit the sleep period (T2) of the ONU 102. An example of this case will be described with reference to FIG.

  FIG. 10 is a diagram illustrating problems in the control sequence of the OAMPDU during the power saving mode. FIG. 10 is a diagram corresponding to FIG. 9, and the processes denoted by the same reference numerals as those in FIG. 9 indicate the same processes as in FIG. 9. In FIG. 10, the ONU 102 that has shifted to the power saving mode at the time p1 periodically repeats the active period (T1) and the sleep period (T2). When the ONU 102 receives the information frame of the OAMPDU from the OLT 101 during the active period (T1) (step S461), the ONU 102 returns the information frame (step S462). However, since the Information frame transmitted from the OLT 101 next reaches the ONU 102 during the sleep period (T2) of the ONU 102, the ONU 102 does not receive the Information frame. For this reason, since the ONU 102 cannot return the information frame, the OLT 101 estimates that the operation of the ONU 102 is stopped. The OLT 101 determines that the logical link with the ONU 102 has been disconnected when it cannot receive a response of the Information frame from the ONU 102 for a predetermined time (for example, 5 seconds).

  As described above, a time lag between the OLT 101 and the ONU 102 causes a problem that it is difficult to maintain the logical link by the OAM PDU.

  Therefore, in the communication system 100 according to the present embodiment, when the power saving mode is set, the ONU 102 transmits an Information frame, and the OLT 101 that has received the information returns a Information frame to the ONU 102. FIG. 11 shows a control flow between the OLT 101 and the ONU 102 in this case.

  FIG. 11 is an example of a control sequence of OAMPDU in the power saving mode in the present embodiment. FIG. 11 is a diagram corresponding to FIG. 10, and the processes denoted by the same reference numerals as those in FIG. 10 indicate the same processes as in FIG. 10. In FIG. 11, the ONU 102 that has shifted to the power saving mode at the time p1 periodically repeats the active period (T1) and the sleep period (T2). The ONU 102 transmits an information frame of OAMPDU to the OLT 101 when the active period (T1) is reached (step S465). Then, the OLT 101 returns an information frame to the ONU 102 (step S466). In the active period (T1) after the elapse of a predetermined period (for example, 1 second), the ONU 102 transmits the information frame of the OAMPDU again to the OLT 101 (step S467). Then, the OLT 101 returns an information frame to the ONU 102 (step S468). In this way, in the power saving mode, the ONU 102 transmits the information frame of the OAMPDU from the ONU 102 to the OLT 101 when the active period (T1) is reached. As a result, as in the example shown in FIG. 10, the problem that the ONU 102 cannot transmit the Information frame in the sleep state can be solved, and the logical link by the OAM PDU between the OLT 101 and the ONU 102 can be maintained even in the power saving mode.

  From the above detailed description, features and advantages of the embodiments will become apparent. This is intended to cover the features and advantages of the embodiments described above without departing from the spirit and scope of the claims. Also, any improvement and modification should be readily conceivable by those having ordinary knowledge in the art. Therefore, there is no intention to limit the scope of the inventive embodiments to those described above, and appropriate modifications and equivalents included in the scope disclosed in the embodiments can be used.

DESCRIPTION OF SYMBOLS 100 ... Communication system; 101 ... Station side apparatus (OLT); 102 ... Subscriber side apparatus (ONU); 103 ... PON line; 104 ... Splitter; 105 ... User terminal; 201 ... User IF; 202 ... ONU control unit; 203 ... PONIF; 204 ... Transmission buffer; 205 ... Power saving control unit; 206 ... OAM control unit; PONIF; 302 ... OLT control unit; 303 ... upper network IF; 304 ... packet filter unit; 305 ... ONUDB; 306 ... power saving control unit;

Claims (6)

A communication system including a lower-level communication device and a higher-level communication device arranged on the higher-level side of the lower-level communication device,
The upper communication device is
When a control message for monitoring the lower-level communication device is transmitted at a specific cycle and a response message is not received from the lower-level communication device within a preset period, the link with the lower-level communication device is disconnected. When the lower-level communication device is in a specific operation mode, the control message is transmitted to the lower-level communication device when the response message is received from the lower-level communication device within a preset first period. And maintaining a link with the lower communication device,
The lower-level communication device is
The specific operation mode in which the first period shorter than the specific period communicating with the higher-level communication apparatus and the second period not communicating with the higher-level communication apparatus are repeated at a preset period. When not in the specific operation mode, when the control message periodically transmitted from the higher-level communication device is received, the response message is transmitted to the higher-level communication device, and in the specific operation mode. The communication system transmits the response message to the higher-level communication device and receives the control message from the higher-level communication device within the first period. The communication system according to claim 1, wherein the communication system is a PON system, the upper communication device is an OLT, and the lower communication device is an ONU.
The specific operation mode is a power saving mode,
The control message and the response message transmitted / received between the OLT and the ONU are OAM PDUs in the OAM layer, and the control message is a keep-alive for confirming a connection between the OLT and the ONU. A communication system characterized by being a message. When a control message for monitoring the lower-level communication device is transmitted at a specific cycle and a response message is not received from the lower-level communication device within a preset period, the link with the lower-level communication device is disconnected. When the lower-level communication device is in a specific operation mode, the control message is transmitted to the lower-level communication device when the response message is received from the lower-level communication device within a preset first period. And maintaining a link with the lower-level communication device. The upper communication apparatus according to claim 3, wherein the upper communication apparatus is an OLT of a PON system, and the lower communication apparatus is an ONU.
The specific operation mode is a power saving mode,
The control message and the response message transmitted / received between the OLT and the ONU are OAM PDUs in the OAM layer, and the control message is a keep-alive for confirming a connection between the OLT and the ONU. A higher-level communication device characterized by being a message. When there is a specific operation mode in which a first period in which communication is performed with a higher-level communication device and a second period in which communication with the higher-level communication device is not performed is repeated in a preset cycle, and the specific operation mode is not present When the control message periodically transmitted from the higher-level communication device is received, the response message is transmitted to the higher-level communication device, and when in the specific operation mode, the first period, The lower communication apparatus, wherein the response message is transmitted to the upper communication apparatus and the control message is received from the upper communication apparatus. The lower communication apparatus according to claim 5, wherein the lower communication apparatus is an ONU of a PON system, and the upper communication apparatus is an OLT.
The specific operation mode is a power saving mode,
The control message and the response message transmitted / received between the OLT and the ONU are OAM PDUs in the OAM layer, and the control message is a keep-alive for confirming a connection between the OLT and the ONU. A lower-level communication device characterized by being a message.

Images