JP2010239278A - Optical access system, optical line terminal, and optical network unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce communication bands for discovering an optical network unit (ONU) and to reduce power consumption in the ONU in a system that uses an optical switch. <P>SOLUTION: An optical access system includes an optical line terminal (OLT), a plurality of ONUs connected with a user terminal, and an optical communication path switching device. When there is no access from a first ONU for a first time, the OLT transmits a request to the first ONU to set the first ONU to a non-registered state. When the first ONU receives the request from the OLT, the first ONU is set to the non-registered state. The OLT excludes the first ONU from discovery for a second time or decreases a priority of discovery of the first ONU. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an optical access system, and more particularly to a technique for improving a utilization rate of a communication band in an optical access system including an optical switch.

  In recent years, the access network has been increased in speed, and FTTH (Fiber To The Home) using an optical fiber is becoming widespread. Representative examples of FTTH include a PON (Passive Optical Network) system and an optical switch system.

  FIG. 13 is a block diagram showing a configuration of a conventional optical switch system 70.

  An optical switch system 70 shown in FIG. 13 is a plurality (N in FIG. 13) of optical network devices that communicate with terminals 10-1 to 10-N (hereinafter collectively referred to as terminals 10) used by users. An ONU 20-1 to 20-N (Optical Network Unit, hereinafter collectively referred to as ONU 20) and an optical line device OLT 40 (Optical Line Terminal, hereinafter referred to as OLT 40) that communicates with the backbone network 60 via the gateway 50. And an optical communication path switching device 30 (hereinafter referred to as an optical switch 30) for connecting a plurality of ONUs 20 and the OLT 40.

  A method for providing the optical switch system 70 is disclosed in the prior art (see, for example, Patent Document 1 and Patent Document 2).

  The optical switch system 70 connects only the OLT 40 and one arbitrary ONU 20 by using the optical switch 30 with less attenuation of the optical signal transmitted to the ONU 20. Therefore, the optical switch system 70 has advantages over the PON system in terms of improving the confidentiality of communication, increasing the number of ONUs 20 accommodated, and improving the transmission distance of the ONUs 20.

  As described above, the optical switch system 70 has an advantage that the number of accommodated ONUs 20 can be increased. On the other hand, since the optical switch system 70 allocates a communication band to the ONU 20 that does not have effective communication for keeping-alive check, there is a demerit that the effective communication band per ONU 20 decreases. is there.

  When performing the initial registration of the ONU 20, the conventional PON system confirms the existence of each ONU 20 and sequentially registers the ONUs that have responded within a specified time. That is, since the PON system waits for responses from a plurality of ONUs 20 in parallel, all the ONUs 20 that have responded among all the ONUs 20 can be initially registered within a specified time.

  On the other hand, when the ONU 20 is initially registered, the optical switch system 70 confirms the existence of one ONU 20, waits for the time allocated to each ONU 20, and initially registers the ONU 20 that has responded to the confirmation of the existence. Then, after the initial registration of one ONU 20 is completed, the optical switch system 70 confirms the existence of the next ONU 20 and repeats initial registration.

  That is, since the optical switch system 70 waits for a response from each ONU 20 in series, when all the ONUs 20 are initially registered within a specified time, a waiting time (communication band) for confirming the survival of each ONU 20 Need to be assigned.

  Then, when the number of ONUs 20 increases, the optical switch system 70 decreases the effective communication band assigned to each ONU 20.

  As described above, the optical switch system 70 needs to allocate more communication bandwidth for confirmation of survival than the PON system.

  In addition, the ONU 20 that does not have actual effective communication, such as a user not using a terminal, also consumes standby power. Therefore, if the ONU 20 does not communicate for a sufficiently long time, the ONU 20 consumes extra power.

JP 2007-174123 A JP 2007-067948 A

  The ONU 20 without effective communication is prevented from consuming the communication band. Further, power saving of the ONU 20 without effective communication is achieved.

  A typical example of the present invention is as follows. An optical line device connected to another network, a plurality of optical network devices each connected to a user terminal, and the optical line device connected between the optical line device and the optical network device. In the optical access system including an optical communication path switching device that switches an optical communication path between the optical network device and the plurality of optical network devices, the optical line device does not perform a first time communication from the first optical network device. The first optical network device transmits a request to unregister the first optical network device to the first optical network device, and the first optical network device receives the request from the optical line device, The first optical network device is set to an unregistered state, and the optical line device does not target the first optical network device for discovery for a second time. , Or, to lower the priority of discovery of the first optical network device.

  According to one embodiment of the present invention, since the communication band is also allocated to the ONU 20 that communicates effectively, the communication band can be used effectively.

It is explanatory drawing which shows the change of the discovery target of the 1st Embodiment of this invention. It is a flowchart which shows the process of OLT of the 1st Embodiment of this invention. It is a flowchart which shows the process of OLT of the 1st Embodiment of this invention. It is a flowchart which shows the process of OLT of the 1st Embodiment of this invention. It is a flowchart which shows the process of ONU of the 1st Embodiment of this invention. It is a block diagram which shows the structure of ONU of the 2nd Embodiment of this invention. It is a flowchart which shows the process of OLT of the 2nd Embodiment of this invention. It is a flowchart which shows the process of ONU of the 2nd Embodiment of this invention. It is a flowchart which shows the process of ONU of the 3rd Embodiment of this invention. It is a flowchart which shows the process of OLT of the 3rd Embodiment of this invention. It is a flowchart which shows the process of OLT of the 3rd Embodiment of this invention. It is a flowchart which shows the process of ONU of the 4th Embodiment of this invention. It is a block diagram which shows the structure of the optical switch system of a prior art.

(First embodiment)
The configuration of the optical switch system used in the first embodiment of the present invention is the same as the configuration of the optical switch system 70 shown in FIG. Conventionally, the OLT 40 detects an unregistered ONU 20 at the stage of searching for an initial registration target (discovery phase) and performs initial registration, and thereafter, the ONU 20 continues to be registered unless a problem such as network disruption occurs. Note that searching for an initial registration target is referred to as discovery.

  Generally, the ONU 20 has, for example, a time zone when the user is not at home or a time zone when the user is not using the communication device. Maintaining the registration state of the unused ONU 20 in a time zone when the ONU 20 is not used can be a factor that imposes pressure on the communication band of another ONU 20 that is communicating.

  FIG. 1 is an explanatory diagram illustrating a change of a discovery target according to the first embodiment of this invention.

  In the optical switch 30 illustrated in FIG. 1, a group 900 including the terminals 10-3 and 10-4, the ONU 20-3 and the ONU 20-4 that have been initially registered, and the initial registration is not performed. A group 800 including unregistered terminals 10-1 and 10-2 and ONUs 20-1 and 20-2 is connected. An ONU 20-3 illustrated in FIG. 1 indicates the ONU 20 when data to be communicated is not transmitted from the terminal 10-3 to the optical switch 30 for a specified time.

  In the first embodiment, the ONU 20-3 shown in FIG. 1 is deregistered and unregistered when the data to be communicated is not transmitted for the specified time, that is, when the data to be communicated for the specified time is not transmitted to the OLT 40. It becomes a state. Furthermore, the ONU 20-3 shown in FIG. 1 is excluded from the discovery target, or the discovery priority is lowered. Further, the ONU 20-3 is cut off the power supply on the optical line side as necessary. Thereby, the optical switch system 70 of the present invention reduces the power consumption of the optical switch system 70.

  A procedure in which the optical switch system 70 cancels the registration of the ONU 20-3 shown in FIG. 1 and removes the ONU 20-3 from the discovery target or lowers the priority of discovery to the ONU 20-3 will be described later.

  FIG. 2 is a flowchart showing the processing of the OLT 40 according to the first embodiment of this invention.

  The OLT 40 determines whether there is an ONU 20 that does not request communication for a specified time among arbitrary ONUs 20 (S301). When there is an ONU 20 that does not request the specified time communication, the OLT 40 transmits a request to cancel the registration to the ONU 20 that has not requested the communication in order to cancel the registration of the ONU 20 that has not requested the specified time communication (S302). .

  When it is determined in S301 that there is no ONU 20 that does not request communication for a specified time, the OLT 40 ends the process illustrated in FIG. Note that the designated time shown in S301 is a time arbitrarily set by the administrator of the OLT 40, and need not always be the same value. In addition, the designated time shown in S301 may be determined in advance by the administrator based on requirements to be satisfied by the optical switch system 70 or a user contract. The process shown in FIG. 2 is executed automatically or manually by an administrator at an arbitrary time interval even after the process is completed.

  OLT 40 cannot broadcast to all ONUs 20 in optical switch system 70 due to the nature of optical switch 30. For this reason, the OLT 40 selects one port provided in the optical switch 30, selects one specific ONU 20, and communicates with the selected ONU 20. Also in the discovery, the OLT 40 selects a specific ONU 20 and performs discovery.

  The simplest method for selecting an ONU 20 in discovery is a method for selecting unregistered ONUs 20 in a round-robin order. The OLT 40 includes a list of unregistered ONUs 20 in its own memory in advance, and selects the ONUs 20 to be discovered from the list of unregistered ONUs 20 in the round robin order.

  The OLT 40 determines whether or not an arbitrary designated time different from the designated time shown in S301 has elapsed after transmitting a request for canceling registration in S302 shown in FIG. 2 to the ONU 20 (S303). If an arbitrary designated time has not elapsed, the ONU 20 that has transmitted the request to cancel the registration should not be the target of discovery yet. Therefore, the OLT 40 also determines the ONU 20 that has transmitted the request to cancel the registration in the discovery phase. Not subject to discovery (S305). Note that the designated time shown in S303 may be determined in advance by the administrator based on requirements to be satisfied by the optical switch system 70 or a user contract.

  In S305, the OLT 40 does not discover the ONU 20 by removing the ONU 20 from the round robin order in the discovery. After S305, the OLT 40 returns to the process of S303.

  If it is determined in S303 that the specified time has elapsed, the OLT 40 sets the ONU 20 as a discovery target (S304).

  With the processing shown in FIG. 2 described above, the OLT 40 can make the ONU 20 without communication for a specified time unregistered for a specified period, and reduce unnecessary bandwidth consumption by the ONU 20. As a result, the OLT 40 can effectively use the communication band of the optical switch system 70 by the ONU 20 with communication.

  FIG. 3 is a flowchart showing the processing of the OLT 40 according to the first embodiment of this invention.

  S311, S312 and S313 shown in FIG. 3 are the same as S301, S302 and S303 shown in FIG. In the flowchart shown in FIG. 3, the processes in S304 and S305 in the flowchart shown in FIG. 2 are replaced with the processes in S314 and S315.

  After the OLT 40 transmits a request to cancel the registration of S312 shown in FIG. 3 to the ONU 20 and sets the ONU 20 in the unregistered list in the OLT 40, an arbitrary specified time different from the specified time shown in S311 has elapsed. It is determined whether or not (S313). When the arbitrary designated time has not elapsed, it is not necessary to discover the ONUs 20 in the round robin order. Therefore, the OLT 40 lowers the discovery priority of the ONUs 20 that have transmitted the request to cancel the registration (S315), and S313. Return to.

  The OLT 40 may lower the priority by discovering the ONU 20 that has transmitted a request for deregistration in S312 after other ONUs 20 have been discovered in round robin order in S315. Further, the OLT 40 may lower the priority by discovering the ONU 20 that has transmitted the request for canceling the registration in S312 at a low frequency without changing the round robin order. The OLT 40 changes the priority by updating the list of unregistered ONUs 20 included in the memory of the OLT 40 itself.

  If it is determined in S313 that the specified time has elapsed, the OLT 40 restores the discovery priority of the ONU 20 (S314).

  With the process shown in FIG. 3 described above, the OLT 40 can make the ONU 20 that has not been in communication for a specified time unregistered for a specified period or longer, and can reduce unnecessary bandwidth consumption by the ONU 20. As a result, the OLT 40 can effectively use the communication band of the optical switch system 70 by the ONU 20 with communication.

  FIG. 4 is a flowchart showing the processing of the OLT 40 according to the first embodiment of this invention.

  The processes of S301, S302, S303, and S305 shown in FIG. 4 are the same as the processes of S301, S302, S303, and S305 shown in FIG.

  In S324 shown in FIG. 4, the OLT 40 puts the ONU 20 that has been excluded from the discovery target again into the discovery target, and does not immediately add the discovery priority in the round robin order of the normal discovery by the processing after S324. Down and add in order of discovery.

  After S324, the OLT 40 determines whether or not an arbitrary designated time different from the designated time indicated in S301 and the designated time indicated in S303 has elapsed (S313). In S313, when the designated time has not elapsed, it is not necessary to discover the ONUs 20 in the round robin order, so the OLT 40 lowers the discovery priority of the ONUs 20 (S315). The method for lowering the priority is the same as S315 shown in FIG. Note that the designated time shown in S313 may be determined in advance by the administrator based on requirements to be satisfied by the optical switch system 70 or a user contract.

  If it is determined in S313 that the specified time has elapsed, the OLT 40 restores the discovery priority of the ONU 20 (S314).

  By the processing shown in FIG. 4 described above, the OLT 40 can make the ONU 20 without communication for a specified time unregistered for a period longer than that shown in FIG. 3, and can reduce unnecessary bandwidth consumption by the ONU 20. As a result, the OLT 40 can effectively use the communication band of the optical switch system 70 by the ONU 20 with communication.

  FIG. 5 is a flowchart showing processing of the ONU 20 according to the first embodiment of this invention.

  FIG. 5 shows a process in which the ONU 20 is registered and released. Further, the initial state in FIG. 5 is that the ONU 20 is not registered.

  The ONU 20 transmits a request for registering the ONU 20 to the OLT 40 when the ONU 20 itself is discovered from the OLT 40 in the discovery phase (S401). The ONU 20 also puts the ONU 20 itself into an unregistered state. The ONU 20 determines whether or not registration has been completed in S401 (S402). If registration has not been completed, the process returns to S401.

  On the other hand, if it is determined in S402 that the registration has been completed, the ONU 20 enters a normal state.

  The ONU 20 determines whether or not a request for canceling the registration of the ONU 20 is received from the OLT 40 (S403). When receiving the request to cancel the registration, the ONU 20 sets the ONU 20 itself to an unregistered state (S404), and returns to the initial state. In S403, when a request for canceling registration is not received, the determination in S403 is repeated until a request for canceling registration is received.

  The process shown in FIG. 5 can use the conventional ONU 20 as it is.

  According to the first embodiment, the OLT 40 can make the ONU 20 that has not been in communication for a specified time unregistered for a specified period, and wasteful bandwidth consumption by the ONU 20 can be reduced. As a result, the OLT 40 can effectively use the communication band of the optical switch system 70 by the ONU 20 with communication.

(Second Embodiment)
In the second embodiment, in addition to the processing of the first embodiment, a part of the power supply of the ONU 20 is cut off, thereby reducing the power consumption of the optical switch system 70. Also in the second embodiment, the OLT 40 performs the leading process similarly to the first embodiment.

  FIG. 6 is a block diagram illustrating a configuration of the ONU 20 according to the second embodiment of this invention.

  The ONU 20 is connected to the terminal 10, a terminal side circuit 201 for controlling communication with the terminal 10, an optical line side circuit 202 and an optical component 203 for controlling communication with the optical line side, and an optical line side circuit 202. And a power supply control circuit 204 for controlling the power supply of the optical component 203.

  In addition, the ONU 20 is instructed by a user or an administrator to send a power control mode designation 205 to the power control circuit 204 from the outside, thereby instructing a pattern for controlling the power of the optical line side circuit 202 and the optical component 203. The pattern for controlling the power source is, for example, shutting off the power sources of both the optical line side circuit 202 and the optical component 203.

  Further, the ONU 20 controls the power supply of the optical line side circuit 202 and the optical component 203 immediately when there is communication from the terminal 10 by the terminal side circuit 201 transmitting the communication detection notification 210 to the power supply control circuit 204. it can.

  In addition, the ONU 20 transmits the optical signal detection notification 220 to the power supply control circuit 204 by the optical component 203, so that when there is communication from the optical switch 30, the optical line side circuit 202 and the optical component 203 are immediately turned on. Can be controlled.

  The optical line side circuit 202 demodulates and analyzes the electrical signal from the optical component 203 and transmits it to the terminal side circuit 201. The optical line side circuit 202 modulates the signal received from the terminal side circuit 201 and transmits the modulated signal to the optical component 203. The optical component 203 receives the optical signal transmitted from the optical switch 30, amplifies it, and converts it into an electrical signal. The electrical signal from the terminal 10 sent via the terminal side circuit 201 and the optical line side circuit is converted into an optical signal and transmitted to the optical switch 30.

  The optical line side circuit 202 and the optical component 203 are individually controlled to be turned on and off by the power supply control circuit 204.

  FIG. 7 is a flowchart showing the processing of the OLT 40 according to the second embodiment of this invention.

  Of the processes shown in FIG. 7, S301 and S303 to S305 are the same as S301 and S303 to S305 shown in FIG. The process of S322 shown in FIG. 7 is a process in which a request to shut off the power supply on the optical line side of the ONU 20 for an arbitrary designated time is added to the request for canceling registration in the ONU 20 of S302 shown in FIG. 2 (S322).

  Note that the power supply on the optical line side of the ONU 20 indicates at least one of the power supplies for the optical line side circuit 202 and the optical component 203. The means for cutting off the power supply of only the optical line side circuit 202 may be the means shown in the fifth embodiment. In S322, an arbitrary designated time for shutting off the power supply on the optical line side of the ONU 20 may be determined in advance by an administrator based on requirements to be satisfied by the optical switch system 70.

  By the process shown in FIG. 7, the optical switch system 70 according to the second embodiment can reduce the power consumption of the ONU 20 without communication.

  Note that the power consumption of the ONU 20 may be reduced by adding a request to shut off the power supply on the optical line side of the ONU 20 for a specified time to the processing of S302 in the flowchart shown in FIG. As a result, the optical switch system 70 of the second embodiment is unclear whether the ONU 20 is used or not used because the discovery priority of the ONU 20 is lowered even after the ONU 20 is included in the discovery target. Even in a long-time discovery, useless bandwidth consumption by the ONU 20 can be reduced. As a result, the OLT 40 can effectively use the communication band of the optical switch system 70.

  In any case, the OLT 40 causes the ONU 20 without communication to shut off the power supply for an arbitrary designated time.

  FIG. 8 shows the processing of the ONU 20 corresponding to the processing of the OLT 40 shown in FIG.

  FIG. 8 is a flowchart showing processing of the ONU 20 according to the second embodiment of this invention.

  In the initial state in FIG. 8, the ONU 20 is not registered.

  When the ONU 20 itself is discovered from the OLT 40 in the discovery phase, the ONU 20 transmits a request to register the ONU 20 itself to the OLT 40 (S411). The ONU 20 determines whether registration has been completed (S412). If it is determined in S412 that the registration is not completed, the ONU 20 returns to the process of S411.

  If it is determined in S412 that the registration has been completed, the ONU 20 has entered a normal state and has received a request to shut off the power on the optical line side of the ONU 20 transmitted from the OLT 40 and a request to cancel the registration of the ONU 20 It is determined whether or not (S413). If no request is received from the OLT 40 in S413, the ONU 20 repeats the determination in S413 until the request is received.

  In S413, when both the request for shutting off the power on the optical line side and the request for canceling the registration of the ONU 20 are received from the OLT 40 to the ONU 20, the ONU 20 cancels the registration of the ONU 20 itself (S414). Subsequently, the ONU 20 shuts off the power to the optical line side circuit 202 and the optical component 203 shown in FIG. 6 (S415). After that, when there is communication from the terminal 10 or when an arbitrary designated time designated by the OLT 40 in S322 shown in FIG. 7 has passed (S416), the ONU 20 and the optical line side circuit 202 and the optical components that have cut off the power supply The power to 203 is turned on (S417), and the process returns to S411.

  According to the second embodiment, the ONU 20 can reduce power consumption by the ONU 20 when the ONU 20 itself is deregistered in response to a request from the OLT 40. Moreover, since unnecessary bandwidth consumption by the ONU 20 can be reduced, the OLT 40 can effectively use the communication band of the optical switch system 70 by the ONU 20 with communication.

(Third embodiment)
In the third embodiment, the ONU 20 leads the cancellation of the registration of the ONU 20.

  FIG. 9 is a flowchart showing processing of the ONU 20 according to the third embodiment of this invention.

  In the initial state of FIG. 9, the ONU 20 is not registered. When the ONU 20 itself is discovered from the OLT 40 in the discovery phase, the ONU 20 transmits a request to register the ONU 20 itself to the OLT 40 (S421). The ONU 20 determines whether registration has been completed (S422). If it is determined in S422 that the registration is not completed, the ONU 20 returns to the process of S421.

  When it is determined in S412 that the registration is completed, the ONU 20 enters a normal state, and determines whether there is communication from the terminal 10 within an arbitrary designated time by the terminal side circuit 201 illustrated in FIG. S423). If there is communication from the terminal 10 within an arbitrary designated time period, the ONU 20 repeats the determination of S423 because there is no need to lower the discovery priority.

  In S423, when the terminal-side circuit 201 determines that there is no communication from the terminal 10 within an arbitrary specified time, the ONU 20 sets the ONU 20 discovery priority to an arbitrary specified time different from the specified time indicated in S423. A request for lowering is transmitted to the OLT 40, or a request for removing the ONU 20 from the discovery target is transmitted to the OLT 40 (S424). Subsequently, the ONU 20 transmits a request for canceling registration to the OLT 40 (S425), and the ONU 20 itself is also unregistered (S426). Thereafter, the ONU 20 returns to the process of S421.

  Note that the designated times shown in S423 and S424 may be determined in advance by an administrator or a user based on requirements to be satisfied by the optical switch system 70, respectively.

  The processing of the OLT 40 corresponding to the processing of the ONU 20 shown in FIG. 9 is shown in FIGS.

  FIG. 10 is a flowchart illustrating the processing of the OLT 40 according to the third embodiment of this invention.

  The OLT 40 determines whether or not the ONU 20 has received a request to remove the ONU 20 from the discovery target for any specified time and a request to cancel the registration of the ONU 20 (S341). If the OLT 40 has not received the request to remove the ONU 20 from the discovery target for any specified time and the request to cancel the registration of the ONU 20, the OLT 40 repeats the determination of S341.

  When the OLT 40 receives a request to remove the ONU 20 from the target of discovery for an arbitrary designated time and a request to cancel the registration of the ONU 20, the OLT 40 cancels the registration of the ONU 20 to which the request is transmitted. That is, the OLT 40 adds the ONU 20 to which the request is transmitted to the list of unregistered ONUs 20 (S342).

  Thereafter, the OLT 40 determines whether or not an arbitrary designated time designated by the ONU 20 has elapsed (S343). If it is determined in S343 that the arbitrary designated time designated by the ONU 20 has not elapsed, the OLT 40 does not make the ONU 20 a discovery in the discovery phase (S345). Thereafter, the OLT 40 returns to the process of S343.

  If it is determined in S343 that an arbitrary designated time designated by the ONU 20 has elapsed, the ONU 20 is set as a discovery target (S344).

  FIG. 11 is a flowchart showing the processing of the OLT 40 according to the third embodiment of this invention.

  The OLT 40 determines whether or not the ONU 20 has received a request to lower the ONU 20 discovery priority for an arbitrary designated time and a request to cancel the registration of the ONU 20 (S351). If the ONT 20 does not receive a request to lower the priority of discovery for any specified time and a request to cancel the registration of the ONU 20, the OLT 40 repeats the determination of S351.

  When the OLT 40 receives a request to lower the discovery priority of the ONU 20 for an arbitrary designated time and a request to cancel the registration of the ONU 20, the OLT 40 cancels the registration of the ONU 20 to which the request has been transmitted (S352).

  The OLT 40 determines whether or not an arbitrary designated time designated by the ONU 20 has elapsed (S353). In S353, when the arbitrary designated time designated by the ONU 20 has not elapsed, the OLT 40 lowers the discovery priority of the ONU 20 by the process shown in the first embodiment (S355). If it is determined in S353 that an arbitrary designated time designated by the ONU 20 has elapsed, the OLT 40 restores the discovery priority of the ONU 20 (S354).

  9, 10, and 11, the ONU 20 designates an arbitrary designated time for removing the ONU 20 from the discovery target, and an arbitrary designated time for lowering the discovery priority of the ONU 20. However, the arbitrary designated time may be designated in advance in the OLT 40 by the administrator.

  According to the third embodiment, the ONU 20 that does not communicate with the terminal 10 removes the ONU 20 itself from the discovery target, thereby reducing unnecessary bandwidth consumption by the ONU 20. For this reason, the OLT 40 can effectively use the communication band of the optical switch system 70.

(Fourth embodiment)
In the fourth embodiment, the ONU 20 initiatively cancels the registration of the ONU 20 and shuts off the power source of the ONU 20.

  FIG. 12 is a flowchart showing processing of the ONU 20 according to the fourth embodiment of this invention.

  The flowchart shown in FIG. 12 shows a process in which the ONU 20 takes the initiative in releasing the registration of the ONU 20 and a process in which the power of the ONU 20 is shut off. In the initial state of FIG. 12, the ONU 20 is not registered.

  When the ONU 20 itself is discovered from the OLT 40 in the discovery phase, the ONU 20 transmits a request to register the ONU 20 itself to the OLT 40 (S431). The ONU 20 determines whether registration has been completed (S432). If it is determined in S432 that the registration is not completed, the ONU 20 returns to the process of S431.

  When it is determined in S432 that the registration is completed, the ONU 20 enters a normal state, and determines whether or not there is communication from the terminal 10 within an arbitrary designated time by the user terminal side circuit 201 illustrated in FIG. (S433). If there is communication from the terminal 10 within an arbitrary designated time period, the ONU 20 repeats the determination in S433 because it is not necessary to lower the discovery priority.

  In S433, when the terminal-side circuit 201 determines that there is no communication from the terminal 10 within an arbitrary specified time, the ONU 20 sets the ONU 20 discovery priority to an arbitrary specified time different from the specified time indicated in S433. A request to lower or a request to remove the ONU 20 from the discovery target is transmitted to the OLT 40 (S434). Subsequently, the ONU 20 transmits a request for canceling registration to the OLT 40 (S435), and the ONU 20 itself is also unregistered (S436).

Subsequently, the ONU 20 cuts off the power supply between the optical line side circuit 202 and the optical component 203 shown in FIG. 6 (S437). Thereafter, there is communication from the terminal 10, or S433 and S434.
When an arbitrary specified time different from the specified time elapses (S438), the ONU 20 turns on the power of the optical line side circuit 202 and the optical component 203 that have been turned off (S439), and performs the processing of S431. Return.

  Note that the designated times shown in S433, S434, and S438 may be determined in advance by an administrator or a user based on requirements to be satisfied by the optical switch system 70, respectively.

  The flowchart of the OLT 40 in the fourth embodiment is the same as the flowcharts shown in FIGS. In FIG. 12, the ONU 20 designates an arbitrary designated time for removing the ONU 20 from the discovery target and an arbitrary designated time for lowering the discovery priority of the ONU 20. However, the arbitrary designated time may be designated in advance in the OLT 40 by the administrator.

  According to the fourth embodiment, the ONU 20 can reduce the power consumption by the ONU 20 itself when the ONU 20 itself is deregistered.

(Fifth embodiment)
In the fifth embodiment, the ONU 20 determines not only the communication received by the terminal-side circuit 201 but also the communication received by the optical component 203. If it is determined that there is communication, the ONU 20 turns on the power of the optical line circuit 202. throw into.

  Since the optical switch system 70 shown in FIG. 13 uses the optical switch 30, only the OLT 40 and one arbitrary ONU 20 are connected. Therefore, as in 10G-EPON, the ONU 20 does not determine whether the optical signal is addressed to itself by the LLID in the RS (Reconciliation Sublayer) of the ONU 20 without determining whether the optical signal is addressed to itself. , It can be seen that the optical signal is an optical communication addressed to itself.

  Using this characteristic, when the optical component 203 shown in FIG. 6 detects an optical signal from the OLT 40, the optical signal detection notification 220 notifies the power supply control circuit 204 that the optical signal has been detected.

  Since the optical component 203 needs to constantly detect the optical signal from the OLT 40, in the fifth embodiment, the power control circuit 204 controls the power of only the optical line side circuit 202.

  When there is no communication in the ONU 20, the user or administrator may instruct the power supply control circuit 204 using the power supply control mode designation 205 as to whether or not to control the power supply of any part of the ONU 20. In addition, the user or the administrator may set in advance in the power supply control circuit 204 whether or not to control any part of the power supply.

  For example, when the user or the administrator wants to set the ONU 20 to the power saving mode, the power supply control mode designation 205 may be used to cut off the power of the optical line circuit 202 when there is no communication in the ONU 20.

  In the case where the OLT 40 performs the process of leading the registration of the ONU 20 and the process of shutting off the power source of the ONU 20, the flowchart of the OLT 40 in the fifth embodiment is similar to the process of S302 in the flowchart shown in FIG. 6 is a flowchart in which a request for temporarily shutting off the power supply of the optical line side circuit 202 is added. Alternatively, in the flowchart of the OLT 40 in the fifth embodiment, the processing of S322 in the flowchart shown in FIG. 7 is performed, the request to temporarily shut off the power supply of the optical line side circuit 202 of the ONU 20, and the registration of the ONU 20 are canceled. It is the flowchart changed into the process which transmits a request | requirement.

  When the OLT 40 performs the process of leading the registration of the ONU 20 and the process of shutting off the power supply of the ONU 20, the flowchart of the ONU 20 in the fifth embodiment is similar to the process of S 416 shown in FIG. 5 is a flowchart changed when there is communication from the optical switch 30. Whether there is communication from the optical switch 30 is determined by the optical signal detection notification 220 described above. When the ONU 20 receives a request to shut off the power supply, the ONU 20 cuts off the power supply only to the optical line side circuit 202.

  In the case where the ONU 20 performs the process of leading the registration of the ONU 20 and the process of shutting off the power of the ONU 20, the flowchart of the ONU 20 in the fifth embodiment shows that the communication from the terminal 10 is S438 shown in FIG. And when there is communication from the optical switch 30. Whether there is communication from the optical switch 30 is determined by the optical signal detection notification 220 described above.

  In the case where the ONU 20 performs the process of leading the registration of the ONU 20 and the process of shutting off the power source of the ONU 20, the flowchart of the OLT 40 in the fifth embodiment is the same as the flowchart shown in FIG. 10 or FIG. .

  Whichever of the OLT 40 and the ONU 20 is used, when the communication request from the terminal side or the communication request from the OLT 40 side is made after the power supply of the optical line side circuit 202 of the ONU 20 is cut off, the optical line side circuit of the ONU 20 The power source 202 is turned on. That is, the ONU 20 turns on the power of the optical line side circuit 202 by discovery from the OLT 40.

  According to the fifth embodiment, power consumption in the ONU 20 can be reduced when there is no communication by the ONU 20.

  The above-described embodiment is merely an embodiment, and various modifications can be made without departing from the technical idea and the technical scope of the present invention. Further, in the above-described embodiment, the embodiment in which the OLT 40 performs the lead processing and the embodiment in which the ONU 20 performs the lead processing are described. However, both the embodiments seem to coexist in the same optical switch system 70. May be implemented.

  The present invention can be used in an optical access network system using an optical switch. It can also be used in an optical access network system using an optical splitter with some modifications.

10 User terminal 20 ONU
30 Optical switch 40 OLT
50 gateway 60 backbone network 70 access network 201 ONU terminal side circuit 202 ONU optical line side circuit 203 ONU optical component 204 ONU power control circuit 205 ONU power control mode designation means 210 ONU terminal side circuit communication detection means Optical signal detection means for 220 ONU optical components

Claims (14)

An optical line device connected to another network, a plurality of optical network devices each connected to a user terminal, and placed between the optical line device and the optical network device, the optical line device and the optical network device In an optical access system including an optical communication path switching device that switches an optical communication path between a plurality of optical network devices,
When there is no first time communication from the first optical network device, the optical line device transmits a request to make the first optical network device unregistered to the first optical network device. ,
The first optical network device is:
If the request is received from the optical line device, the first optical network device is unregistered,
The optical line device does not set the first optical network device as a target of second time discovery, or lowers the discovery priority of the first optical network device for a second time. Optical access system. The optical line device is:
When the first optical network device is not subject to the second time discovery,
The optical access system according to claim 1, wherein after the second time elapses, the priority of discovery of the first optical network device is lowered. The optical line device transmits a request to shut down the power supply of the first optical network device to the first optical network device;
The first optical network device is:
When the request is received from the optical line device, the power of at least one of the optical line circuit and the optical transceiver of the first optical network device is cut off,
2. The optical access system according to claim 1, wherein when the communication is performed from the user terminal or when a third time has elapsed, the interrupted power supply is turned on. The optical line device transmits a request to temporarily cut off the power supply of the first optical network device to the first optical network device;
The first optical network device is:
When the request is received from the optical line device, the power of the optical line circuit of the first optical network device is shut off,
2. The optical access system according to claim 1, wherein when the communication is performed from the user terminal or the communication is performed from the optical line device, the interrupted power supply is turned on. The second optical network device requests from the user terminal that the second optical network device is not subject to fifth time discovery when there is no fourth time communication, and the second optical network device. A request to set the second optical network device to a non-registered state, or a request to lower the discovery priority of the second optical network device for a fifth time, and a request to set the second optical network device to the unregistered state. To the line device,
The optical line device is:
Putting the second optical network device in an unregistered state;
The second optical network device is not targeted for fifth time discovery, or the discovery priority of the second optical network device is lowered for a fifth time. Optical access system. The second optical network device is:
Cutting off the power of at least one of the optical line circuit and the optical transceiver of the second optical network device;
6. The optical access system according to claim 5, wherein when the communication is made from the user terminal or when the sixth time has elapsed, the interrupted power supply is turned on. The second optical network device is:
Shutting off the power of the optical transceiver of the second optical network device;
6. The optical access system according to claim 5, wherein when the communication is made from the user terminal or when the communication is made from the optical line device, the interrupted power supply is turned on. In an optical line device connected to a plurality of optical network devices via an optical communication path switching device and connected to another network,
When there is no first time communication from the first optical network device, a request to make the first optical network device unregistered is transmitted to the first optical network device,
An optical line device characterized in that the first optical network device is not subject to second time discovery, or the discovery priority of the first optical network device is lowered for a second time. When the first optical network device is not subject to the second time discovery,
9. The optical line device according to claim 8, wherein the discovery priority of the first optical network device is lowered after the second time has elapsed.   9. The optical line device according to claim 8, wherein a request to shut off the power supply of the first optical network device is transmitted to the first optical network device.   9. The optical line device according to claim 8, wherein a request for temporarily shutting off the power supply of the first optical network device is transmitted to the first optical network device. In an optical network device connected to an optical line device connected to another network and an optical communication path switching device, each connected to a user terminal,
When there is no fourth time communication from the user terminal, the second optical network device does not make the second optical network device a target of fifth time discovery, or the second optical network device An optical network device characterized in that a request for lowering the discovery priority of the device for a fifth time and a request for unregistering the second optical network device are transmitted to the optical line device. Cutting off the power of at least one of the optical line circuit and the optical transceiver of the second optical network device;
13. The optical network device according to claim 12, wherein when the communication is performed from the user terminal or when a sixth time has elapsed, the interrupted power supply is turned on. Shutting off the power of the optical line circuit of the second optical network device;
13. The optical network device according to claim 12, wherein the interrupted power is turned on when communication is made from the user terminal or communication is made from the optical line device.

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