JP6263211B2 - Subscriber line terminator and recovery method - Google Patents

Description

  The present invention relates to a subscriber line termination device and a restoration method that detect an abnormality occurring in, for example, a subscriber line termination device of an optical communication service system and can recover from the abnormality.

  In the FTTH (Fiber To The Home) service, the number of communication devices arranged in a user's home such as a subscriber line terminal unit (ONU: Optical Network Unit) and a broadband router is very large in the entire communication system. These devices may operate abnormally due to software or hardware malfunctions, temporary environmental changes, latch-up due to cosmic rays, and the like.

  Even if the probability that one device will be in abnormal operation is low, the number of such devices is enormous when viewed from the entire communication system, and abnormal operation frequently occurs. If the user's terminal cannot connect to the Internet normally, or if an abnormal state is found with a lamp of a communication device, etc., the user is notified of the abnormal state to the telecommunications carrier that maintains the device, and is restored. Request.

  The communication carrier tries to recover from the abnormal state by operating it remotely, but the user suffers from the disadvantage that the user cannot use the communication service. In addition, the communication carrier spends a lot of cost for recovery.

  A method for avoiding such an abnormal state is disclosed in Patent Document 1, for example.

Japanese Patent Laid-Open No. 10-269110

  As a method for avoiding an abnormal state, a watchdog timer that performs alive monitoring of a software process and forcibly terminates when there is no response is well known. The method disclosed in Patent Document 1 is a method for detecting an abnormal state by determining that a software process continues to run for a time longer than a threshold value as a runaway state. Further, a mechanism such as Ether-OAM that detects an abnormality of a hardware part by exchanging communication packets between communication nodes and performing mutual monitoring is also well known.

  However, the watch dog timer and the technique disclosed in Patent Document 1 have a problem that only an abnormal state of software can be detected. Also, methods such as a watchdog timer and Ether-OAM have a problem that they cannot be recovered even if an abnormal state can be detected.

  The present invention has been made in view of these problems, and provides a subscriber line termination device and a recovery method that can detect an abnormal state of both software and hardware and can independently recover from that state. Objective.

A subscriber line terminator of the present invention comprises a line terminator that terminates a communication line from a station side, a router part that routes packets received from the communication line by the line terminator, the router part, and the line terminator An integrated control unit connected to a communication line unit, wherein the integrated control unit detects an abnormality of the router unit and an abnormality of the line termination unit, and the abnormality A reset signal output unit that outputs a router reset signal when the detection unit detects an abnormality in the router unit, and outputs an ONU reset signal when the abnormality detection unit detects an abnormality in the line termination unit; And the router unit includes a router reset unit that resets the router unit when the router reset signal is received, and the line termination unit receives the ONU reset signal. If, comprising the ONU reset unit for resetting the該回line terminating unit, the router includes a router main signal section for processing the packet, when the router main signal section is unable to obtain an IP address from the DHCP server, the A router failure detection unit that outputs router failure information indicating a failure of the router main signal unit, and the abnormality detection unit detects an abnormality of the router unit when the router failure information is received.

Further, the restoration method of the present invention includes a line termination unit that terminates a communication line from a station side, a router unit that routes a packet received from the communication line by the line termination unit, the router unit, and the line termination unit. A recovery method performed by a subscriber line terminating device having an integrated control unit connected to the network, wherein the integrated control unit detects an abnormality in the router unit and an abnormality in the line termination unit; A reset signal output that outputs a router reset signal when the abnormality detection unit detects an abnormality in the router unit, and outputs an ONU reset signal when the abnormality detection unit detects an abnormality in the line termination unit. And when the router unit receives the router reset signal, the router unit performs a router reset step for resetting the router unit. When receiving the NU reset signal, have rows ONU reset step of resetting the該回line terminating unit, the router includes a router main process step of processing the packet, the IP address from the DHCP server in the router main process steps A router failure detection step for outputting router failure information indicating a failure in the router main processing step when the router failure information cannot be acquired, and the abnormality detection step detects an abnormality in the router unit when the router failure information is received. Suppose that

  ADVANTAGE OF THE INVENTION According to this invention, the abnormal state of both software and hardware can be detected, and the subscriber line termination | terminus apparatus and recovery method which can be recovered independently from the state can be provided.

It is a figure which shows the function structural example of the subscriber line termination | terminus apparatus 1 of this Embodiment. It is a figure which shows the operation sequence of the alive monitoring which the abnormality detection part 31 of the subscriber line termination apparatus 1 performs. It is a figure which shows the operation | movement flow of the failure detection which the router failure detection part 110 of the subscriber line termination apparatus 1 performs. It is a figure which shows the operation | movement flow of the failure detection which the 2nd router failure detection part 111 of the subscriber line termination apparatus 1 performs. It is a figure which shows the operation | movement flow of the failure detection which the ONU failure detection part 210 of the subscriber line termination apparatus 1 performs. It is a figure which shows the operation | movement sequence of the failure detection which the 2nd ONU failure detection part 211 of the subscriber line termination apparatus 1 performs. 5 is a diagram illustrating a specific example of a router reset unit 13. FIG. It is a figure which shows the function structural example of the subscriber line termination apparatus 2 which deform | transformed the subscriber line termination apparatus 1. FIG.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 shows a functional configuration example of the subscriber line termination device 1 of the present embodiment. The subscriber line termination device 1 includes a router unit 10, a line termination unit 20, and an integrated control unit 30.

  The line termination unit 20 is an (ONU: Optical Network Unit) and is generally called an optical subscriber line termination device, and is connected to the termination unit of the communication line from the station side (OLT: Optical Line Terminal). It is what is done. The router unit 10 routes packets received from the communication line by the line termination unit 20.

  The integrated control unit 30 is connected to the router unit 10 and the line termination unit 20. Thus, the subscriber line termination device 1 is an integrated optical subscriber line termination device and router.

  The integrated control unit 30 includes an abnormality detection unit 31 and a reset signal output unit 32. The abnormality detection unit 31 detects an abnormality in the router unit 10 and an abnormality in the line termination unit 20.

  The reset signal output unit 32 outputs a router reset signal when the abnormality detection unit 31 detects an abnormality of the router unit 10, and when the abnormality detection unit 31 detects an abnormality of the line termination unit 20, the line termination unit An ONU reset signal for resetting 20 is output.

  The router unit 10 includes a router control unit 11, a router main signal unit 12, and a router reset unit 13. The router control unit 11 controls the router main signal unit 12 that processes a packet passing through the router unit 10. The router reset unit 13 resets both the router control unit 11 and the router main signal unit 12.

  The line termination unit 20 includes an ONU control unit 21, an ONU main signal unit 22, and an ONU reset unit 23. The ONU control unit 21 controls the ONU main signal unit 22 that processes a packet passing through the line termination unit 20. The ONU reset unit 23 resets both the ONU control unit 21 and the ONU main signal unit 22.

  The reset is to initialize the router unit 10 or the line termination unit 20, for example, to turn each power ON → OFF → ON (power reset).

  It is well known that resetting the power supply may restore the device to normal operation. Therefore, the integrated control unit 30 of the subscriber line termination device 1 of the present embodiment detects an abnormality in at least one of the router unit 10 and the line termination unit 20, and performs a power reset on the portion where the abnormality is detected. It is possible to return to a normal operation state.

  By the action of the integrated control unit 30, the router reset unit 13, and the ONU reset unit 23, the subscriber line termination device 1 autonomously recovers from the abnormal state of the router unit 10 or the line termination unit 20. As a result, the mean recovery time (MTTR: Mean Time To Recovery) can be shortened. Further, there is an effect that it is possible to recover from an abnormality that cannot be detected by a method such as watchdog or Ether-OAM.

  Next, a specific method for detecting an abnormality (failure) will be described.

  For example, the abnormality detection unit 31 detects an operation stop of at least one of the router unit 10 and the line termination unit 20 as an abnormality. FIG. 2 shows an operation sequence diagram in which the abnormality detection unit 31 detects an operation stop of the router unit 10 and the line termination unit 20.

  The abnormality detection unit 31 in the integrated control unit 30 transmits, for example, a Ping command to the router control unit 11 (step S1). If it is normal, the router control unit 11 returns a response to the Ping command (step S2).

  If the router control unit 11 stops operating, the response in step S2 cannot be obtained. The abnormality detection unit 31 waits for a response for a predetermined time (life detection) (step S3). When the response is not confirmed within the predetermined time (YES in step S4), the abnormality detection unit 31 detects the operation stop of the router unit 10.

  The abnormality detection unit 31 that has detected the operation stop of the router unit 10 outputs a router reset signal (step S5). The router reset unit 13 receives the router reset signal and resets the router unit 10 (step S6).

  If a response is confirmed within a predetermined time (NO in step S4), the abnormality detection unit 31 next detects whether the operation of the line termination unit 20 is stopped or not. The subsequent operation is the same as the life / death detection of the router 10, and a part of the description is omitted.

  When the response from the ONU control unit 21 is not confirmed within a predetermined time (YES in step S10), the abnormality detection unit 31 detects that the operation of the line termination unit 20 is stopped. The abnormality detection unit 31 that has detected the operation stop of the line termination unit 20 outputs an ONU reset signal (step S11). The ONU reset unit 23 receives the ONU reset signal and resets the line termination unit 20 (step S12).

  When a response from the ONU control unit 21 is obtained within a predetermined time (NO in step S10), the abnormality detection unit 31 detects life / death detection (step S3) and a line termination unit that detects the stop of the operation of the router unit 10. 20 life / death detection (step S9) is repeated from step S1. In this way, the life / death detection (step S3) for detecting the operation stop of the router unit 10 and the life / death detection (step S9) of the line termination unit 20 are repeatedly performed, so that each operation stop can be detected immediately.

  The abnormality detection unit 31 outputs a router reset signal when the operation stop of the router control unit 11 is detected. Moreover, the abnormality detection part 31 outputs an ONU reset signal, when the operation stop of the ONU control part 21 is detected.

Therefore, each of the router unit 10 and the line termination unit 20 can immediately recover from the abnormal state in which the operation is stopped.
[Router part failure detection]
Next, an abnormality (failure) detection method performed by the router control unit 11 will be described. In the following description, the terms “abnormal” and “failure” are synonymous.

  The router control unit 11 includes a router failure detection unit 110 and a second router failure detection unit 111. The router failure detection unit 110 outputs router failure information indicating a failure of the router main signal unit 12 when the IP address cannot be acquired from the DHCP server via the router main signal unit 12.

  The DHCP server is a server that assigns an IP address. In FIG. 1, the DHCP server is arranged on the OLT side, but the notation is omitted.

  FIG. 3 shows a failure detection operation flow performed by the router failure detection unit 110. The router control unit 11 makes an IP address acquisition request to the DHCP server (step S20). Next, the router failure detection unit 110 determines whether or not an IP address has been acquired (step S21).

  If the IP address can be acquired, communication via the router main signal unit 12 is normal. When the IP address cannot be acquired, there is an abnormality in communication via the router main signal unit 12.

  The router failure detection unit 110 outputs router failure information indicating a failure of the router main signal unit 12 when an abnormality of the router main signal unit 12 is detected. When the router failure information is input, the abnormality detection unit 31 outputs a router reset signal.

  That is, when the router failure detection unit 110 detects an abnormality in the router main signal unit 12, the abnormality detection unit 31 has detected an abnormality in the router unit 10. As a result, the router reset unit 13 can reset the router unit 10.

  If the IP address cannot be acquired again from the DHCP server after resetting the router unit 10 because the IP address cannot be acquired, the DHCP server may be down. Therefore, it is not necessary to perform the operation of resetting the router unit 10 because the IP address cannot be acquired twice.

  Next, an abnormality (failure) detection method performed by the second router failure detection unit 111 will be described. FIG. 3 shows an operation flow of failure detection performed by the second router failure detection unit 111. Assuming that a personal computer (hereinafter referred to as a PC) is connected to the router unit 10, for example, an upstream packet is transmitted from the PC to the router main signal unit 12. In a situation where an upstream packet is transmitted, the downstream packet is transmitted from the router main signal unit 12 to the PC.

  An abnormality of the router main signal unit 12 can be detected based on the presence / absence of the downstream packet. The second router failure detection unit 111 is in a situation where the number of passages of the upstream packet can be counted (“Yes” in Step S30), and the situation where the number of passages of the downstream packet cannot be counted (“None” in Step S31). Is detected as a failure of the router main signal unit 12 ("None" in step S31). The fact that the number of passing packets can be counted is the situation where packets are observed.

  The second router failure detection unit 111 outputs second router failure information indicating a failure of the router main signal unit 12 when an abnormality of the router main signal unit 12 is detected. When the second router failure information is input, the abnormality detection unit 31 outputs a router reset signal. That is, when the second router failure detection unit 111 outputs the second router failure information, the abnormality detection unit 31 has detected an abnormality in the router unit 10.

[Failure detection at line termination]
Next, failure detection performed by the line termination unit 20 will be described. The ONU failure detection unit 210 determines whether or not the ONU main signal unit 22 has failed based on the network connection state indicating the connection status with the station side and the authentication state, and the ONU main signal unit 22 has failed. If it is, ONU failure information indicating failure of the ONU main signal part is output. The network connection status is also referred to as PON-LINK information, and is information that represents the connection status with the center station. The network connection state is “UP” if the line termination unit 20 is connected to the OLT, and “DOWN” if it is not connected. Note that PON is an abbreviation of “Passive Optical Network” which is one of access network forms.

  The authentication state is information indicating whether or not the line termination unit 20 is authenticated on the station side (OLT). The authentication state is “authenticated” if the line termination unit 20 is authenticated, and “authentication not” if not authenticated.

  FIG. 5 shows an operation flow of failure detection performed by the ONU failure detection unit 210. The ONU control unit 21 acquires the network connection state and the authentication state from the ONU main signal unit 22 (step S40).

  The ONU failure detection unit 210 detects a failure of the ONU main signal unit 22 when the network connection state and the authentication state acquired from the ONU main signal unit 22 are “DOWN” and “authentication disconnection” (YES in step S41). Is output (step S42). When the ONU failure detection unit 210 outputs ONU failure information, it is assumed that the abnormality detection unit 31 has detected an abnormality in the line termination unit 20. This is the same as the router failure information and the second router failure information. That is, when the ONU failure detection unit 210 outputs ONU failure information, the line termination unit 20 is reset by the ONU reset unit 23.

  Next, an abnormality (failure) detection method performed by the second ONU failure detection unit 211 will be described. When the second ONU failure detection unit 211 requests the station side (OLT) to authenticate itself (the line termination unit 20) via the ONU main signal unit 22, the second ONU failure detection unit 211 cannot receive the identifier transmitted from the station side. The second ONU failure information indicating the failure of the ONU main signal unit 22 is transmitted to the integrated control unit 30.

  FIG. 6 shows an operation flow of failure detection performed by the second ONU failure detection unit 211. When the subscriber line termination device 1 (line termination unit 20) of the present embodiment is connected to the OLT via an optical fiber, the OLT automatically discovers the line termination unit 20 and automatically establishes a communication link. .

  The communication link is automatically established by MPCP (Multi Point Control Protocol). First, the MPCP transmits a discovery gate signal from the OLT to the ONU control unit 21 (step S50). The ONU control unit 21 transmits a registration request as a response to the discovery gate signal to the OLT via the ONU main signal unit 22 (step S51).

  When transmitting the registration request to the OLT, assuming that the ONU main signal unit 22 is out of order, the registration request is not transmitted to the OLT (X in FIG. 6). Therefore, the ONU control unit 21 cannot receive a registration notification including an identifier from the OLT.

  When there is no response from the OLT (“None” in step S54), the second ONU failure detection unit 211 outputs second ONU failure information indicating a failure in the ONU main signal unit 22 (step S55). When the second ONU failure information is output, it is the same as the above ONU failure information and the like that the abnormality detection unit 31 detects an abnormality of the line termination unit 20.

  As described above, according to the subscriber line terminating device 1 of the present embodiment, each of the abnormalities of the router control unit 11, the router main signal unit 12, the ONU control unit 21, and the ONU main signal unit 22 is detected. Can do. In the present embodiment, the integrated control unit 30 has been described as an example in which the router unit 10 and the line termination unit 20 are separated. However, the present invention is not limited to this example. The functional configuration unit of the integrated control unit 30 may be included in the router unit 10. In addition, the functional configuration unit of the integrated control unit 30 may be included in the line termination unit 20.

  FIG. 8 shows a functional configuration example of the subscriber line termination device 2 obtained by modifying the subscriber line termination device 1. The subscriber line termination device 2 includes a router unit 210 and a line termination unit 220. The subscriber line termination device 2 is different from the subscriber line termination device 1 (FIG. 1) in that the integrated control unit 30 is not provided.

  The abnormality detection unit 31 and the reset signal output unit 32 of the integrated control unit 30 are distributed as the abnormality detection units 212 and 222 and the reset signal output units 213 and 223 in the router control unit 211 and the ONU control unit 221, respectively. The The abnormality detection unit 212 detects an abnormality in the line termination unit 220. Further, the abnormality detection unit 222 detects an abnormality in the router unit 210. The operation after each detecting an abnormality is the same as the operation of the above embodiment. As described above, the functional unit of the integrated control unit 30 may be provided in any configuration as long as it is inside the subscriber line terminating device 1 and is not limited to the present embodiment.

[Reset section]
FIG. 7 shows a specific example of the router reset unit 13 that resets the router unit 10. The router reset unit 13 in FIG. 7 is an example configured with an inverter having the gate electrodes of the PMOSTr 130 and the NMOSTr131 connected in common as an input terminal and the drain electrodes connected in common and an output terminal. A router reset signal is connected to the input terminal, and the positive power source V ⁺ of the router unit 10 is supplied from the output terminal.

When the router reset signal is “false”, the PMOSTr 130 is turned on and the positive power source V ⁺ is supplied to the router unit 10. When the router reset signal is “true”, the NMOS Tr 131 is turned on ^and only the negative power source V ⁻ is supplied to the router unit 10 and the power source is shut off (power source reset).

  The ONU reset unit 23 may be configured similarly. A transistor other than MOSTr may be used. A relay may be used for the router reset unit 13 and the ONU reset unit 23.

  The ONU reset unit 23 that resets the line termination unit 20 is configured in the same manner as the router reset unit 13. Further, the reset according to the present embodiment is not limited to the power reset. When a failure of the router unit 10 is detected, the router unit 10 may be initialized by software. Specifically, for example, the registration process performed by the above-described MPCP may be executed when an abnormality is detected. The same applies to the line termination unit 20 that may be initialized by software.

  As described above, according to the subscriber line terminating device 1 of the present embodiment, it is possible to detect and restore a communication impossible state caused by an abnormality in both software and hardware only by the device. In addition, since the recovery method of the present embodiment can be automatically performed without human intervention, it contributes to minimizing the average recovery time from the occurrence of a failure to the recovery.

  Although the description of the present embodiment has been made by taking the PON system as an example, the technical idea shown in the present embodiment can be applied to networks other than the PON system. As described above, the present invention is not limited to the above-described embodiment, and various modifications can be made within the scope of the gist thereof.

1: subscriber line termination device 10: router unit 11: router control unit 12: router main signal unit 13: router reset unit 20: line termination unit 21: ONU control unit 22: ONU main signal unit 23: ONU reset unit 110: Router failure detection unit 111: second router failure detection unit 210: ONU failure detection unit 211: second ONU failure detection unit

Claims (8)

A line termination unit for terminating a communication line from the station side, a router unit for routing a packet received from the communication line by the line termination unit, and an integrated control unit connected to the router unit and the line termination unit; A subscriber line terminating device comprising:
The integrated control unit detects an abnormality in the router unit and an abnormality in the line termination unit, and outputs a router reset signal when the abnormality detection unit detects an abnormality in the router unit, A reset signal output unit that outputs an ONU reset signal when the abnormality detection unit detects an abnormality in the line termination unit;
The router unit includes a router reset unit that resets the router unit when the router reset signal is received,
The line termination unit includes an ONU reset unit that resets the line termination unit when the ONU reset signal is received ;
The router unit is a router main signal unit for processing a packet;
A router failure detection unit that outputs router failure information indicating a failure of the router main signal unit when the router main signal unit cannot obtain an IP address from a DHCP server;
The subscriber line termination device according to claim 1, wherein when the router failure information is received, the abnormality detection unit detects an abnormality of the router unit . In the subscriber line terminating device according to claim 1 ,
In a situation where an upstream packet to the router main signal unit is observed, the router unit receives second router failure information indicating a failure of the router main signal unit when a downstream packet is not transmitted from the router main signal unit. A second router failure detection unit for output;
The subscriber line termination device, wherein the abnormality detection unit detects an abnormality of the router unit when receiving the second router failure information. In the subscriber line terminating device according to claim 1,
The line termination unit includes an ONU main signal unit for processing a packet;
It is determined whether or not the ONU main signal unit has failed based on the network connection state and the authentication state representing the connection state with the station side. If the ONU main signal unit has failed, the ONU An ONU failure detection unit that outputs ONU failure information indicating a failure of the main signal unit;
The subscriber line termination device, wherein the abnormality detection unit detects an abnormality of the line termination unit when receiving the ONU failure information. In the subscriber line terminating device according to claim 3 ,
The line termination unit transmits second ONU failure information indicating failure of the ONU main signal unit to the integrated control unit when it cannot receive an identifier transmitted from the station side when requesting its own authentication. Equipped with a fault detector,
The subscriber line terminating device, wherein the abnormality detecting unit detects an abnormality of the line terminating unit when receiving the second ONU failure information. A line termination unit for terminating a communication line from the station side, a router unit for routing a packet received from the communication line by the line termination unit, and an integrated control unit connected to the router unit and the line termination unit; A recovery method performed by a subscriber line terminating device comprising:
The integrated control unit detects an abnormality of the router unit and an abnormality of the line termination unit, and outputs a router reset signal when detecting an abnormality of the router unit in the abnormality detection step, A reset signal output step for outputting an ONU reset signal when an abnormality is detected in the line termination unit in the abnormality detection step;
When the router unit receives the router reset signal, the router unit performs a router reset step for resetting the router unit,
The line termination unit, when receiving the ONU reset signal, have rows ONU reset step of resetting the該回line terminating unit,
The router unit is a router main processing step for processing a packet;
A router failure detection step of outputting router failure information indicating a failure in the router main processing step when an IP address cannot be obtained from a DHCP server in the router main processing step;
The recovery method according to claim 1, wherein the abnormality detection step detects an abnormality of the router unit when the router failure information is received . In the recovery method according to claim 5 ,
The router unit outputs second router failure information indicating a failure in the router main processing step when no downstream packet is transmitted in a situation where an upstream packet is observed in the router main processing step. Do the steps,
The recovery method according to claim 1, wherein the abnormality detection step detects an abnormality of the router unit when the second router failure information is received. In the recovery method according to claim 5 ,
The line termination unit includes an ONU main signal step for processing a packet;
It is determined whether or not the ONU main signal step has failed based on the network connection state and the authentication state indicating the connection state with the station side, and when the ONU main signal step has failed, the ONU An ONU failure detection step for outputting ONU failure information representing a failure in the main signal step,
The abnormality detecting step detects an abnormality of the line termination unit when the ONU failure information is received. In the recovery method according to claim 7 ,
The line termination unit transmits second ONU failure information indicating failure of the ONU main signal step to the integrated control unit when the identifier transmitted from the station side cannot be received when requesting its own authentication. Perform the failure detection step,
The abnormality detection step detects an abnormality of the line termination unit when the second ONU failure information is received.

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