JP2016171414A - Station side device, subscriber device, and optical communication system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a station side device, a subscriber device, and an optical communication system that can reliably and quickly restore user communication if a constant light-emission ONU has an impact on user communication.SOLUTION: An OLT 20 is a station side device for performing optical communication with a subordinate ONU 10, and comprises: an optical level measuring unit 28 that measures an optical level received from the ONU 10 if the OLT 20 causes the subordinate ONU 10 to emit light at prescribed forced light-emission timing after detecting the total cutoff of uplink communication; and an optical level management unit 24 that identifies a constant light-emission ONU on the basis of the optical level measured by the optical level measuring unit 28 and the forced light-emission timing.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a station-side device such as an OLT (Optical Line Terminal), a subscriber device such as an ONU (Optical Network Unit), and an optical communication system including these devices, particularly in a PON (Passive Optical Network) network. The present invention relates to a network technology for identifying a constantly light-emitting ONU and restoring user communication when the user communication is affected by the constantly light-emitting ONU.

  In recent years, as an optical communication system, a PON system in which a plurality of ONUs are connected to an OLT via a splitter has become widespread.

  There is a possibility that the ONU always emits light (hereinafter, always emitted) due to a failure of the optical module (for example, Patent Documents 1 to 8). If the always-on ONU is present, the communication influence occurs to other users accommodated under the same PON-IF. When a service interruption of all users under the splitter is detected, the maintenance person rushes to the site and performs ONU replacement.

JP 2011-0666608 A JP 2014-171079 A JP 2014-154992 A JP 2013-135288 A Japanese Patent Application Laid-Open No. 2010-211988 JP 2007-318524 A JP 2007-166696 A JP 2006-197447 A

  Generally, when the user communication is affected by the always-on ONU, the maintenance person cannot identify the cause. Therefore, ONU replacement is performed by rushing to the site, but since there are a maximum of 32 ONUs under the splitter, it is necessary to perform ONU replacement a maximum of 32 times.

  The present invention provides a station-side device, a subscriber device, and an optical communication system that can reliably and quickly restore user communication when the user communication is affected by the always-on ONU in view of the above-described conventional technology. The purpose is to do.

  In order to achieve the above object, the invention according to the first aspect is a station-side device that performs optical communication with a subscribing subscriber device, and the subscribing subscriber device is forced to be subjected to a predetermined compulsory operation after detecting a complete disconnection of uplink communication. A light level measurement unit that measures a light level received from the subscriber device when the light is emitted at a light emission timing, and a subscription of a constant light emission state based on the light level measured by the light level measurement unit and the forced light emission timing The gist of the present invention is to provide a constant light-emitting subscriber unit specifying unit that specifies a subscriber unit.

  The invention according to a second aspect is the invention according to the first aspect, wherein the light level measurement unit measures the light level of each subscriber device when there is a subscriber device in the constantly emitting state, The gist of the always-lighting subscriber device specifying unit is to identify the always-lighting subscriber device based on the relative ratio of the light levels of the subscriber devices measured by the light level measuring unit.

  The invention according to a third aspect is the invention according to the first aspect, wherein the light level measurement unit is configured to provide a light level of each normal subscriber device and a subscriber device in the constantly light emitting state. The light level of each subscriber device is measured, and the always light emitting subscriber device specifying unit specifies the subscriber device in the always light emitting state based on a difference between both light levels measured by the light level measuring unit. This is the gist.

  In order to achieve the above object, the invention according to the fourth aspect is a subscriber device that performs optical communication with a station side device, and the predetermined forced light emission after the upstream side communication is detected by the station side device. The gist of the invention is to include a light emission timing management unit that emits light at a timing, and a power supply unit that turns off the power supply when the station side device is identified as a subscriber device that is always in a light emission state.

  In order to achieve the above object, an invention according to a fifth aspect is an optical communication system, the station-side apparatus according to any one of the first to third aspects, and the subscriber apparatus according to the fourth aspect. It is a summary to provide.

  According to the present invention, it is possible to provide a station-side device, a subscriber device, and an optical communication system that can reliably and quickly restore user communication when the user communication is affected by the always-on ONU. .

It is a block diagram of the optical communication system in embodiment of this invention. It is a functional block diagram of OLT in an embodiment of the invention. It is a functional block diagram of ONU in an embodiment of the invention. It is a flowchart which shows operation | movement of the optical communication system in a comparative example. It is a flowchart which shows operation | movement of the optical communication system in embodiment of this invention. It is a figure which shows the continuous light emission ONU specific sequence in embodiment of this invention. It is a figure which shows the structure of the flame | frame used by embodiment of this invention. It is explanatory drawing of the always light emission ONU identification method in embodiment of this invention. It is a block diagram of the optical level database of OLT in embodiment of this invention. It is a block diagram of the optical level management part of OLT in embodiment of this invention. It is a block diagram of the ONU database of OLT in embodiment of this invention. It is a block diagram of the ONU information database of ONU in embodiment of this invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The following embodiments exemplify an optical communication system for embodying the technical idea of the present invention, and the configuration of the apparatus, the configuration of data, and the like are limited to the following embodiments. is not.
(Optical communication system)
FIG. 1 is a configuration diagram of an optical communication system according to an embodiment of the present invention. This optical communication system is an optical access PON system in which a single optical fiber is shared by a plurality of users.

  As shown in FIG. 1, a plurality of ONU_1, ONU_2, ONU_3,... (Hereinafter collectively referred to as “ONU10”) are connected to the IF of the OLT 20 via a splitter S. The ONU 10 is an optical subscriber line terminator and is installed in the subscriber's home. The OLT 20 is an optical subscriber line terminating station device, and is installed in a subscriber accommodation station. When there is an ONU 10 that is always in a light emitting state (always light emitting ONU), the OLT 20 that detects the ONU 10 notifies the monitoring server 40 via the monitoring network 30 of an alarm.

In the optical communication system according to the embodiment of the present invention, the always-on ONU is specified when the link between the OLT 20 and the ONU 10 is disconnected, and the specified always-on ONU is transmitted to the monitoring server 40. As a result, the maintenance work can be started early, and the maintenance work of the ONU 10 by the maintenance person can be reduced.
(Station equipment)
FIG. 2 is a functional block diagram of the OLT 20 in the embodiment of the present invention. As shown in this figure, the OLT 20 includes an optical level database 21, an alarm management unit 22, an ONU database 23, an optical level management unit 24, a frame generation unit 25, an authentication disconnection detection unit 26, and an ONU_IF unit 27. And a light level measuring unit 28. The light level database 21 stores the light level measured by the light level measurement unit 28. The ONU database 23 stores information (light emission timing, LLID, etc.) of the ONU 10. The light level management unit 24 calculates the light level measured by the light level measurement unit 28. The light level management unit 24 also has a function of managing the calculated light level and specifying a constantly emitting ONU. The frame generation unit 25 generates various frames such as a start frame of a constant light emission ONU specific sequence. The authentication failure detection unit 26 detects the authentication failure of the ONU 10 under the IF. The ONU_IF unit 27 is a communication interface with the ONU 10. The light level measurement unit 28 measures the light level emitted by the ONU 10.
(Subscriber equipment)
FIG. 3 is a functional block diagram of the ONU 10 in the embodiment of the present invention. As shown in this figure, the ONU 10 includes a power supply unit 11, a light emission timing management unit 12, a power-off frame reception unit 13, an OLT_IF unit 14, and an ONU information database 15. The power supply unit 11 manages (disconnects and connects) the power supply. The light emission timing management unit 12 manages the light emission timing. The power-off frame receiving unit 13 receives a power-off frame from the OLT 20. Of course, the ONU 10 can receive various frames other than the power-off frame. The OLT_IF unit 14 is a communication interface with the OLT 20. The ONU information database 15 stores information (light emission timing, LLID, etc.) of the ONU 10.
(Operation)
FIG. 4 is a flowchart showing the operation of the optical communication system in the comparative example. For example, when there is a customer report such as “Internet is not available” (S1), the maintenance department performs service interruption and isolation for all users under the splitter S (S2), and the maintenance person rushes to the site. Then, the ONU exchange is performed (S3). Here, if the Internet cannot be used due to the always-on ONU, the maintenance person cannot identify the cause. Therefore, ONU replacement is carried out by rushing to the site, but since there are a maximum of 32 ONUs under the splitter, it is necessary to execute ONU replacement a maximum of 32 times (S4 → S3 → S4 → ...).

FIG. 5 is a flowchart showing the operation of the optical communication system according to the embodiment of the present invention. First, when it is detected that the communication of the ONU under IF has been completely interrupted (S11), a constant light emission ONU specifying sequence described later is performed (S12). As a result, when the always-on ONU is specified, the power-off of the always-on ONU is performed (S13), and then the communication restart is notified from the OLT 20, and the communication is restored by the ONU normal connection sequence (S14). When the always-on ONU is specified, the always-on ONU is notified from the OLT 20 to the monitoring server 40 (S15). Since the always-on ONU is specified, the maintenance person can replace the always-on ONU with a normal ONU 10 at one time (S16).
(Continuous light emission ONU specific sequence)
FIG. 6 is a diagram showing a constant light emission ONU identification sequence in the embodiment of the present invention. As a precondition, the ONU 10 holds the LLID (identification ID for each ONU 10) immediately before the link is disconnected. In the following description, the immediately preceding LLID is referred to as “always-on ONU specifying LLID”.

  First, when detecting an ONU communication disconnection under IF control, the OLT 20 transmits a frame that always starts a light emitting ONU specific sequence to all ONUs 10 (S21 → S22). All the ONUs 10 stop the upstream communication when receiving the always-ON ONU specific sequence start frame (S23).

  Next, when the upstream communication is stopped, the OLT 20 causes all ONUs 10 to emit light at the forced light emission timing (S24). As a method of causing all ONUs 10 to emit light at the forced light emission timing, there are the following forced light emission method A and forced light emission method B.

  The forced light emission method A is a method in which the ONU 10 emits light upon notification from the OLT 20. First, ONU_1 emits light at a timing when the OLT 20 instructs ONU_1 to emit light, and then ONU_2 emits light at a timing when the OLT 20 instructs ONU_2 to emit light. Such a procedure is repeated as many times as the number of LLIDs for always-on light emission ONU identification. The forced light emission method A has an advantage that less information is managed in the database than the forced light emission method B.

  The forced light emission method B is a method in which the ONU 10 emits light at the time of forced light emission timing. That is, when the OLT 20 instructs the ONU 10 to emit light only once, ONU_1 emits light one second after receiving this instruction, and ONU_2 emits light two seconds after receiving this instruction. Information such as “after 1 second” and “after 2 seconds” is notified to the ONU 10 in advance. As the order of light emission of the ONU 10 as described above, the order of the constant light emission ONU specifying LLID can be adopted. According to the forced light emission method B, since the OLT 20 only needs to instruct the ONU 10 to emit light once, compared to the forced light emission method A, there is an advantage that the separation operation can be speeded up.

  Next, the OLT 20 identifies a constantly emitting ONU (S25). A method for specifying the always-on ONU will be described later. Thereafter, a frame for the end of the constant light emission ONU specific sequence is transmitted to all the ONUs 10 to notify the constant light emission ONU to turn off the power (S26). There are the following methods for notifying the number of times of light emission and a method for notifying a control message as methods for notifying that the power is to be turned off.

  The method of notifying the number of times of light emission is a method of notifying the ONU 10 of the constant light emission ONU by the number of times the OLT 20 emits light. For example, when the OLT 20 emits light once, the ONU_1 turns off the power, and when the OLT 20 emits light twice, the ONU_2 turns off the power. This method of notifying the number of times of light emission is effective when the control message cannot be notified to the ONU 10.

  The control message notification method is a method in which the OLT 20 notifies the ONU 10 of the always-on ONU by a control message. For example, a frame for the end of the constant light emission ONU identification sequence including the information of the always light emission ONU identification LLID of the identified constant light emission ONU is transmitted to all the ONUs 10. That is, it is possible to notify the always-on ONU when the always-on ONU specific sequence ends.

When each ONU 10 receives the frame of the constantly emitting ONU identification sequence end, it compares the constantly emitting ONU identifying LLID in the frame with its own always emitting ONU identifying LLID (S27). Thereby, when both correspond, it recognizes that itself is always light emission ONU, and implements the power-off which is the next flow (refer S13 of FIG. 5).
(Frame structure)
FIG. 7 is a diagram showing the structure of a frame used in the embodiment of the present invention. FIG. 7A is a frame for starting the always-on ONU specific sequence used in S22 of FIG. FIG. 7B is a forced light emission start frame used in S24 of FIG. FIG. 7 (c) is a frame at the end of the constant light emission ONU specific sequence used in S26 of FIG.

Each frame includes “interframe gap”, “always-on ONU identification LLID”, “destination MAC address”, “source MAC address”, “type”, “frame type”, “data field”, “frame check sequence”, “interframe gap”. Is included. When starting the always-on ONU specific sequence, for example, “0000” is set in the data field as shown in FIG. When the forced light emission is started, as shown in FIG. 7B, a constant light emission ONU identifying LLID such as “XXXX” is set in the data field. When the constant light emission ONU specific sequence is ended, as shown in FIG. 7C, for example, “1111XXXX” is set in the data field. “XXXX” shown in FIG. 7C means the always-on ONU identifying LLID of the always-on ONU.
(Continuous light emission ONU identification method)
FIG. 8 is an explanatory diagram of a method for specifying a constantly emitting ONU in the embodiment of the present invention. FIG. 8A is a graph showing the light level when the ONU 10 is in a normal state, and FIG. 8B is a graph showing the light level when there is always a light emitting ONU. In the figure, t1 indicates the light emission timing of ONU_1, t2 in the figure indicates the light emission timing of ONU_2, and t3 in the figure indicates the light emission timing of ONU_3. As will be described below, the OLT 20 determines the light level from the ONU 10 and specifies the always-on ONU based on the light level and the light emission timing.

  First, the constant light emitting ONU specifying method 1 will be described. In the always-on ONU identification method 1, the light level emitted by each ONU_1, 2, 3,... When there is always-on ONU is measured, and based on the relative ratio of the light levels of each ONU_1, 2, 3,. Specify the always-on ONU. Here, as shown in FIG. 8B, the light levels of the ONU_1, 2, 3 when the always-on light ONU is present are L_1 ', L_1' + L_2, L_1 '+ L_3, respectively. In this case, it is possible to determine that the ONU_1 having the lowest light level is a constantly emitting ONU.

Next, the constant light emission ONU specifying method 2 will be described. In the always-on ONU specifying method 2, the light level of each ONU 10 in the normal state and the light level of each ONU 10 when the always-on ONU is present are measured, and the always-on ONU is specified based on the difference between these light levels. . Here, as shown in FIG. 8A, the light levels of the ONU_1, 2, 3 in the normal state are L_1, L_2, L_3, respectively. Further, as shown in FIG. 8B, the light levels of the ONU_1, 2, 3 when the always-on light ONU is present are L_1 ′, L_1 ′ + L_2, L_1 ′ + L_3, respectively. In this case, the optical level difference of ONU_1 is L_1'-L1, the optical level difference of ONU_2 is L_1 '+ L_2-L_2 (= L_1'), and the optical level difference of ONU_3 is L_1 '+ L_3-L_3 ( = L_1 '). Also in this case, it can be determined that the ONU_1 having the lowest light level is the always-on ONU.
(Database configuration)
FIG. 9 is a configuration diagram of the optical level database 21 of the OLT 20 in the embodiment of the present invention. As shown in FIG. 9A, the light level database 21 includes “always-on ONU specifying LLID” and “light level in a state where there is always-on ONU” when the always-on ONU specifying method 1 is adopted. It is managed in association. On the other hand, as shown in FIG. 9B, when the always-on ONU specifying method 2 is adopted, “LLID at normal state”, “light level 1 at authentication”, and “LLID for specifying always-on ONU” And “light level 2 in a state where there is a constant light emission ONU” are managed in association with each other.

  FIG. 10 is a configuration diagram of the optical level management unit 24 of the OLT 20 in the embodiment of the present invention. As illustrated in FIG. 10A, the light level management unit 24 adopts the always-on ONU specifying method 1, “always-on ONU specifying LLID”, “light level sort”, and “light level order”. Are associated with each other and managed. This “order of light levels” means the order after sorting in order of increasing light level 2 values. On the other hand, as shown in FIG. 10 (b), when the constant light emission ONU identification method 2 is adopted, “always light emission ONU identification LLID”, “light level sort by light level 1-2”, “light level "Order" is managed in association with each other. This “order of light levels” means the order after sorting in order of increasing light level 1-2 values.

  FIG. 11 is a configuration diagram of the ONU database 23 of the OLT 20 in the embodiment of the present invention. As shown in FIG. 11A, when the forced light emission method A is adopted, the ONU database 23 is “always-on ONU specifying LLID”, “order of light levels”, and “always-on ONU”. Are associated with each other and managed. On the other hand, as shown in FIG. 11B, when the forced light emission method B is adopted, “always-on ONU specifying LLID” and “emission timing (○ seconds after reception of the always-on ONU specifying sequence start frame)” , “The order of the light levels” and “whether or not the light emission ONU is always on” are managed in association with each other.

  FIG. 12 is a configuration diagram of the ONU information database 15 of the ONU 10 in the embodiment of the present invention. As shown in FIG. 12A, the ONU information database 15 manages the “communication state LLID” and “always-on ONU specifying LLID” in association with each other when the forced light emission method A is adopted. . On the other hand, as shown in FIG. 12B, when the forced light emission method B is adopted, “LLID in communication state”, “LLID for constant light emission ONU identification”, “light emission timing (always light emission ONU specific sequence start frame) "○ seconds after reception)".

  As described above, the OLT 20 according to the embodiment of the present invention is a station-side device that performs optical communication with the subordinate ONU 10, and causes the subordinate ONU 10 to emit light at a predetermined forced light emission timing after detection of all upstream communication interruptions. A light level measuring unit 28 that measures the light level received from the ONU 10 and a light level management unit 24 that identifies the always-on ONU based on the light level measured by the light level measuring unit 28 and the forced light emission timing. Prepare. As a result, the always-on ONU is identified in a state where the upstream communication is stopped, and the maintenance person can immediately perform the replacement operation of the always-on ONU. That is, user communication can be reliably and promptly restored when user communication is affected by the always-on ONU.

  Specifically, the light level measurement unit 28 measures the light level of each ONU 10 when there is always a light emitting ONU, and the light level management unit 24 measures the light level of each ONU 10 measured by the light level measurement unit 28. The always-on ONU may be specified based on the relative ratio. As a result, it is possible to reliably and quickly identify the always-on ONU based on the measured light level.

  Alternatively, the optical level measuring unit 28 measures the optical level of each ONU 10 in a normal state and the optical level of each ONU 10 when there is a constant light emitting ONU, and the optical level managing unit 24 uses the optical level measuring unit 28 to The always-on ONU may be specified based on the difference between the measured two light levels. Also in this case, it is possible to reliably and quickly identify the always-on ONU based on the measured light level.

  Further, the ONU 10 in the embodiment of the present invention is a subscriber device that performs optical communication with the OLT 20, and the light emission timing management unit 12 that emits light at a predetermined forced light emission timing after the upstream communication is completely detected by the OLT 20. And a power supply unit 11 for cutting off the power supply when the OLT 20 identifies itself as a constant light emitting ONU. As a result, the always-on ONU is identified in a state where the upstream communication is stopped, and the maintenance person can immediately perform the replacement operation of the always-on ONU. That is, user communication can be reliably and promptly restored when user communication is affected by the always-on ONU.

  Furthermore, according to the embodiment of the present invention, there are the following effects. First, according to the embodiment of the present invention, since light emission is stopped only when communication is not possible, communication stop does not occur when user communication is not affected. For example, when the light level fluctuates without affecting user communication due to connection point construction or the like, communication stoppage does not occur. Further, since the light level is not always measured and is measured only when there is always a light emitting ONU, no processing load is applied to the OLT 20. Furthermore, since the ONU 10 does not emit light other than the forced light emission timing even when the always-on ONU specifying LLID is given to stop the upstream communication, the always-on ONU can be reliably specified at the light level.

  Note that the present invention can be realized not only as the OLT 20 or the ONU 10 but also as a constant light-emitting ONU identification method using the characteristic processing units included in the OLT 20 or the ONU 10 as steps, It can be realized as a constant light emission ONU specific program to be executed. It goes without saying that such a program can be distributed via a recording medium such as a CD-ROM or a transmission medium such as the Internet.

10 ... ONU (subscriber equipment)
DESCRIPTION OF SYMBOLS 11 ... Power supply part 12 ... Light emission timing management part 13 ... Power-off frame reception part 14 ... OLT_IF part 15 ... ONU information database 20 ... OLT (station side apparatus)
21 ... Light level database 22 ... Alarm management unit 23 ... ONU database 24 ... Light level management unit (constant light emitting subscriber unit identification unit)
25 ... Frame generation unit 26 ... Authentication disconnection detection unit 27 ... ONU_IF unit 28 ... Optical level measurement unit 40 ... Monitoring server

In order to achieve the above object, the invention according to the first aspect is a station-side device that performs optical communication with a subscribing subscriber device, and the subscribing subscriber device is forced to be subjected to a predetermined compulsory operation after detecting a complete disconnection of uplink communication. A light level measurement unit that measures a light level received from the subscriber device when the light is emitted at a light emission timing, and a subscription of a constant light emission state based on the light level measured by the light level measurement unit and the forced light emission timing A constant light emitting subscriber device specifying unit for specifying a subscriber device, and when determining the predetermined forced light emission timing, the constant light emission ONU specifying LLID that is an identification ID for each subscriber device immediately before the link is disconnected The gist of the present invention is to execute a light emitting ONU specific sequence between the station side device and the subscriber device .

In order to achieve the above object, the invention according to the fourth aspect is a subscriber device that performs optical communication with a station side device, and the predetermined forced light emission after the upstream side communication is detected by the station side device. A light emission timing management unit that emits light at a timing, and a power supply unit that turns off power when the station side device is identified as a subscriber device that is always in a light emission state , and determines the predetermined forced light emission timing In doing so, the gist of the present invention is that the station-side device and the subscriber device carry out a constant light-emitting ONU identification sequence based on a constant light-emitting ONU identification LLID, which is an identification ID for each subscriber device immediately before the link is disconnected. To do.

Claims (5)

A station side device that performs optical communication with subordinate subscriber devices,
An optical level measuring unit for measuring the optical level received from the subscriber apparatus when the subordinate subscriber apparatus is caused to emit light at a predetermined forced light emission timing after detecting all interruptions in uplink communication;
A station-side device, comprising: a constant light-emitting subscriber device specifying unit that specifies a subscriber device in a constantly light-emitting state based on the light level measured by the light level measuring unit and the forced light emission timing. The light level measurement unit measures the light level of each subscriber device when there is a subscriber device in the constantly light-emitting state,
The said constant light emission subscriber apparatus specific | specification part specifies the subscriber apparatus of the said constant light emission state based on the relative ratio of the light level of each subscriber apparatus measured by the said light level measurement part. 1. The station side device according to 1. The light level measuring unit measures the light level of each subscriber device in a normal state and the light level of each subscriber device when the subscriber device in the always light emitting state exists,
2. The station according to claim 1, wherein the always-lighting subscriber device specifying unit specifies the always-lighting subscriber device based on a difference between both light levels measured by the light level measuring unit. Side device. A subscriber device that performs optical communication with a station side device,
A light emission timing management unit that emits light at a predetermined forced light emission timing after the upstream communication is detected by the station side device;
A subscriber unit comprising: a power supply unit configured to turn off a power source when the station side unit identifies that the station unit is a subscriber unit that is always in a light emitting state. The station side device according to any one of claims 1 to 3,
An optical communication system comprising: the subscriber unit according to claim 4.

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