JP4627479B2 - Communication control device - Google Patents

Description

  The present invention relates to a communication control apparatus, and more particularly to a communication control apparatus having a partial function stop function when power supply is stopped using a battery and a power supply control circuit.

  In Patent Document 1, in order not to stop the network function immediately when the external power supply is stopped, the network relay device is connected to the uninterruptible power supply device, and the relay is interrupted to another adjacent network relay device when the external power supply is stopped. And another network relay device changes the connection relationship.

  In addition, in order to prevent data communication by the communication control device from being interrupted as much as possible, communication routes are multiplexed, and even when a failure occurs in a specific route, data communication is performed by using the remaining route. Just continue. Link aggregation is a technique for realizing this.

JP-A-6-315041

  When a power failure occurs with the uninterruptible power supply connected to the outside of the communication control device as in Patent Document 1, the power supply to the uninterruptible power supply is eventually stopped even if a multiplexed communication path is secured This makes data communication impossible. In addition, since it depends on a power source such as an uninterruptible power supply device arranged outside the device, the uninterruptible power supply device cannot avoid stopping the device when the power switch of the communication control device is turned off for some reason.

  A communication control apparatus that suppresses power consumption by partially stopping power supply by partially degenerating / restoring a communication control apparatus that performs multiplexing of paths, and maintains a communication state as much as possible. provide. Minimize network connection changes. Furthermore, when the power supply should not be turned off as the communication control device due to a dynamic configuration change inside the communication control device, the power supply from the battery is continued until the power supply can be turned off.

  A device management unit that performs overall control, a route control unit that is connected to the device management unit and controls communication paths, a plurality of line control units that are connected to the device management unit and perform line control, an external power supply, and a device management unit And a power supply control circuit connected to the power supply control circuit and a battery that backs up the power supply when power supply from the external power supply stops. The power supply control circuit monitors the remaining battery power and The management unit can be achieved by a communication control device that controls power supply to the path control unit and each line control unit according to the remaining battery level monitored by the power control circuit when receiving power from the battery.

  ADVANTAGE OF THE INVENTION According to this invention, a communication control apparatus with high reliability with respect to a power failure can be provided.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings using some examples. The same parts are denoted by the same reference numerals, and description thereof will not be repeated.

  FIG. 1 is a block diagram showing the configuration of the communication control apparatus. Inside the communication control apparatus 101 connected to the external power supply 203 is a power supply control circuit 202 connected to the external power supply 203 via a power switch 204. The output of the power supply control circuit 202 is connected to the device management unit 11, the m path control units 12-1 to 12-m, and the n line control units 13-1 to 13-n to supply power. The external power supply 203 is connected to the battery 201 via the power supply control circuit 202. When the external power source 203 is healthy, the battery 201 is in a charging mode, and the external power source 203 charges the battery 201 via the power control circuit 202. When the external power source 203 is stopped or the power switch 204 is disconnected, the battery 201 is in a discharge mode, and the battery 201 is connected to the device management unit 11, the path control units 12-1 to 12-m, the line control unit via the power control circuit 202. Power is supplied to 13-1 to 13-n.

  In FIG. 1, the device management unit 11 controls the entire communication control device 101. The route control unit 12 is controlled by the device management unit 11 and controls a route established between other communication control devices. The line control unit 13 is controlled by the device management unit 11 and controls input / output to / from the line control unit of another communication control device.

  The above-described power supply feeder 151 is indicated by a bold line. The power supply control circuit 202 notifies the device management unit 11 of the power supply state and the remaining battery level of the external power supply 203 and the battery 201 as power supply state information. The device management unit 11 is connected to the communication control device operation terminal 22 and controls each part of the communication control device 101 based on the power supply management table 21 set from the communication control device operation terminal 22 and the power state information from the power control circuit 202. To do. The device management unit 11 monitors the power supply state information from the power supply control circuit 202 and determines whether or not the power supply can be turned off for each part using the detected power supply state information and the power supply management table 21. Specifically, the device management unit 11 determines whether the power supply to the path control unit 12, the line control unit 13, and the device management unit 11 can be cut off according to the remaining battery level set in the power supply management table 21. In addition, the device management unit 11 notifies the communication control device of the connection destination that is affected by the portion that is blocked by stopping the power supply for each portion, and the information that is blocked so that the route can be changed. And power supply is stopped.

  By partially stopping the power supply, the power consumption of the communication control apparatus 101 can be suppressed, and the driving time of the battery 201 can be extended. A control line 141 to each part controlled by the apparatus management unit 11 is indicated by a thin line.

  FIG. 2 is a flowchart for explaining the power supply state monitoring process. The device management unit 11 acquires the battery capacity information of the battery 201 from the power supply state information of the power supply control circuit 202, and obtains the current battery remaining level (S001). The device management unit 11 compares the value set in the remaining battery level 211 of the power supply management table 21 (described later in FIG. 4) with the obtained current remaining battery level (S002). As a result of the comparison, if there is a battery level that should be degraded / recovered ("Yes"), the process proceeds to the degradation / recovery process, and if none has reached the current battery level ("No" ") Return to normal processing (S003).

  In the degeneration / recovery process, the degeneration / recovery process of the part described in the degeneration / recovery part 212 of the power supply management table 21 is performed. If the state 213 is on, the degeneration process is performed, and if the state 213 is off, the recovery process is performed (S004). In the update process of the power supply management table 21, the state 213 of the power supply management table 21 is updated. Specifically, when the state 213 is on, the state 213 is changed to off, and when the state 213 is off, the state 213 is changed to on (S005). When the process is completed, the process returns to the normal process and the power supply state monitoring process is continued.

  FIG. 3 is a block diagram illustrating a network configuration. In FIG. 3, a network 1000 is configured by interconnecting communication control devices 101 to 105. The line control unit 13-1 and the communication control device 102 of the communication control device 101, the line control unit 13-4 and the communication control device 103 of the communication control device 101, and the line control units 13-2 and 13-3 of the communication control device 101 The communication control device 105, the communication control device 102 and the communication control device 104, the communication control device 103 and the communication control device 104, and the communication control device 103 and the communication control device 105 are connected to form a ring network 1000. Here, the communication path between the communication control apparatus 102 and the communication control apparatus 105 includes the communication control apparatus 102, the communication control apparatus 101, the communication path 50-1 relayed with the communication control apparatus 105, the communication control apparatus 102, There are two types of communication paths 50-2 that are relayed to the communication control device 104, the communication control device 103, the communication control device 101, and the communication control device 105.

A case where a power failure or the like occurs in the communication control apparatus 101 while the communication control apparatus 102 performs communication using the communication path 50-1 will be described. The communication control apparatus 101 notifies the communication control apparatus 102 of the blockage of the path and prompts the change of the path. The communication control apparatus 101 includes a path control unit 12-1 for a part related to the path for the communication control apparatus 102 that is currently used. The line control unit 13-1 and the line control unit 13-2 are degenerated, the power consumption of the communication control apparatus 101 is suppressed, and the communication with the communication control apparatus 103 and the communication control apparatus 105 is continued. Notified communication control device path obstruction 102 is closes the appropriate path is connected to the communication control device 101, the communication control device 104 and the connected communication path 50 - the communication control device 105 by 2 Communication can be continued. When the communication control apparatus 101 recovers after power recovery, the communication control apparatus 101 notifies the communication control apparatus 102 of path recovery and prompts the path recovery. The communication control apparatus 102 notified of the path recovery recovers the corresponding path connected to the communication control apparatus 101 and resumes communication. As described above, the communication control apparatus 102 ensures data communication with the communication control apparatus 105 before and after the path of the communication control apparatus 101 is degenerated. In the case of the network configuration of the communication control apparatuses 101 to 105, the communication control apparatus 101 is connected to the communication control apparatus 102, the communication control apparatus 103, and the communication control apparatus 105, but a power failure or the like occurs in the communication control apparatus 101. In this case, only the communication control device 102 needs to be changed to change the network connection relationship.

  FIG. 4 is a diagram illustrating the power supply management table. The power supply management table 21 includes a remaining battery level 211 corresponding to the remaining battery level of the battery 201, a degeneration / recovery part 212 that specifies a part to be degenerated / recovered corresponding to the remaining battery level, and current power for each part. And a state 213 representing a supply state. Each part described in the degeneration / recovery part 212 is a part divided into printed circuit board (package) units.

  When the communication control apparatus 101 is supplied with power from the battery 201 due to a power failure or the like, the remaining battery capacity of the battery 201 decreases in accordance with the power supply. The device management unit 11 compares the remaining battery level 211 of the power supply management table 21 with the current remaining battery level of the battery 201 to determine a degenerate site. When the remaining battery level of the battery 201 is 100% to 80% or more, there is nothing corresponding to the remaining battery level 211 in the power supply management table 21, so the degeneration process is not performed. When the power supply from the battery 201 continues and the remaining battery level of the battery 201 decreases to less than 80%, the apparatus management unit 11 sets the remaining battery level 211 in the power supply management table 21 to 80% or more. The degeneration / recovery part 212 is searched, and the line control unit 1, the line control unit 2, and the route control unit 1 are determined to be degenerate parts. The device management unit 11 performs degeneration processing on the line control unit 1, the line control unit 2, and the route control unit 1, turns off the power supply, and turns off the state 213 of the power supply management table 21.

  As described above, the power consumption of the communication control apparatus 101 can be suppressed, and the driving time of the battery 201 can be extended. Communication via the line control unit 3 and the line control unit 4 can be continued.

  When the communication control apparatus 101 recovers, power is supplied to each part of the communication control apparatus 101 from the external power supply 203. However, since there is a possibility of power failure again, a method of performing recovery of each part in stages in accordance with the capacity of the battery 201 and a method of recovering all degenerated parts regardless of the remaining level of the battery 201 There can be.

  Here, the case where recovery of each part is performed in steps will be described. When the capacity of the battery 201 is recovered to 5% or more by supplying power from the external power supply 203, the device management unit 11 causes the degeneration / recovery part 212 in which the remaining battery level 211 of the power supply management table 21 is set to 5% or more. And the line control unit 3, the line control unit 4, the path control unit 2, and the device management unit are determined as the parts to be recovered. The device management unit 11 performs recovery processing on the line control unit 3, the line control unit 4, the path control unit 2, and the device management unit, and changes the state 213 of the power supply management table 21 to ON. When the capacity of the battery 201 is recovered to 80% or more by supplying power from the external power supply 203, the device management unit 11 uses the degeneration / recovery part 212 in which the remaining battery level 211 of the power supply management table 21 is set to 80%. By searching, the line control unit 1, the line control unit 2, and the route control unit 1 are determined as the parts to be recovered. The device management unit 11 performs recovery processing on the line control unit 1, the line control unit 2, and the route control unit 1, and changes the state 213 of the power supply management table 21 to ON.

  When the external power supply does not recover finally, when the power supply from the battery 201 continues and the remaining battery level of the battery 201 decreases to less than 5%, the device management unit 11 sends the power supply management table 21. The degeneration / recovery part 212 in which the remaining battery level 211 is set to 5% or more is searched, and the line control unit 3, the line control unit 4, the path control unit 2, and the device management unit are determined as degenerate parts. . The device management unit 11 performs degeneration processing on the line control unit 3, the line control unit 4, the route control unit 2, and the device management unit, turns off the power supply, and turns off the state 213 of the power supply management table 21. When the degeneration process is performed on the apparatus management unit, since there is no operable part, the own apparatus is blocked. The communication control device 101 that has been blocked is restarted from the communication control device operation terminal 22.

  FIG. 5 is a flowchart for explaining the degeneration and recovery processing of the communication control apparatus. The device management unit 11 acquires the power supply information of the power control circuit 202, grasps the current battery remaining level from the battery capacity information, and corresponds to the value set in the battery remaining level 211 of the power supply management table 21. Search for and compare (S011). The device management unit 11 proceeds to step 013 when there is a target portion corresponding to the battery remaining level, and returns to normal processing when there is no target portion (S012). It is determined whether the state 213 of the power supply management table 21 is on. If the state 213 is off, the process proceeds to step 021 of the target part recovery process, and if the state 213 is on, the process proceeds to step 014 of the degeneration process. Proceed (S013). In step 014, it is determined whether there is a degenerateable portion in the power supply management table 21. If there is a degenerateable portion, the process proceeds to step 015 of the target portion degeneration process, and if there is no degenerateable portion, the communication control apparatus 101. The process proceeds to step 018 of its own blocking process.

  In step 015, it is determined whether or not the communication control apparatus 101 can notify the connection destination. If the connection destination can be notified, degeneration of the target part is notified to the connection destination (S016), and the target part is subjected to degeneration processing and subjected to degeneration processing. The power supply of the part is turned off (S017). On the other hand, when it is impossible to notify the connection destination in step 015, step 016 is omitted and the process proceeds to step 017.

  In the block process of step 018, it is determined whether the communication control apparatus 101 can notify the connection destination. If the connection destination can be notified, the communication control apparatus 101 itself is notified of the blockage (S019), and then the communication is performed. The control device 101 itself is closed (S020). If it is not possible to notify the connection destination in step 018, step 019 is omitted and the process proceeds to step 020.

  If it is determined in step 013 that the process is a recovery process, the target part is powered on (S021). In the recovery process, it is determined whether the connection destination can be notified (S022). If the connection destination can be notified, the recovery of the target part is notified to the connection destination (S023), and the process ends. If it is determined in step 022 that the connection destination cannot be notified, step 023 is omitted and the process returns to the normal process.

  FIG. 6 is a sequence diagram of normal startup processing and stop processing of the communication control apparatus. When the operator turns on the power switch 204 of the communication control apparatus 101 (S061), the power control circuit 202 detects power on (S062) and starts charging the battery 201 (S063). The device management unit 11 is powered and activated via the power supply control circuit 202 (S064). The device management unit 11 starts the power status information monitoring process from the power control circuit 202 (S065). The power supply control circuit 202 starts notification of the battery capacity of the battery 201 (S066). The device management unit 11 detects that the battery 201 can be used from the battery capacity of the battery 201 and the remaining battery level set in the power supply management table 21 (S067), and should not be turned off. In order to hold the information, the device disconnection impossibility is set in the power control information of the power control circuit 202 (S068, S069). Thereafter, the device management unit 11 starts power-on (S070, S071) and initial setting processing of the route control unit 12, the line control unit 13, and the like (S072), and enters a normal operation state. The power supply control circuit 202 stops charging the battery 201 when the charging capacity of the battery 201 reaches an allowable value.

  In the case of normal stop processing, the device management unit 11 starts processing in response to a stop instruction from the communication control device operation terminal 22. First, the device management unit 11 starts blocking processing of the route control unit 12 and the line control unit 13 (S076). When the blocking processing is completed (S077), the power of the route control unit 12 and the line control unit 13 is turned on. Turn off (S078). The device management unit 11 starts its own blocking process (S079), and sets the device disconnection in the power supply control information of the power supply control circuit 202 (S080, S081). Thereafter, the device management unit 11 stops (S082). Thereafter, the operator turns off the power switch 204 (S083). The power control circuit 202 detects power off, but stops the apparatus without switching to the battery 201 according to the power control information (S084).

  FIG. 7 is a sequence diagram when a power failure occurs during normal operation of the communication control device. In the normal operation state, the device management unit 11 is monitoring the remaining battery level (S090). At this time, it is assumed that the power supply from the external power supply 203 is cut off due to a power failure (S091). At this time, the power supply control circuit 202 detects the power failure and switches the battery 201 from the charge mode to the discharge mode (S092). The communication control device continues to operate stably by supplying power from the battery 201, and supplies power without instantaneous interruption. The power supply control circuit 202 periodically notifies the device management unit 11 of the remaining amount of the battery 201 as power supply state information (S093). The device management unit 11 compares the notified power supply state information with the power supply management table 21 and searches for a portion to be degenerated (S094, S095). If there is a corresponding part as a result of the search, the corresponding part is degenerated (S096), and the power supply management table 21 is updated (S097). Here, the degeneracy process is a partial stop of the communication control device. Specifically, in response to an instruction from the device management unit 11, the line control unit 13 requests another device connected to the stop portion to change the path. Is transmitted (S110), the power is turned off, and the response is returned to the apparatus management unit 11 (S111). Upon receiving the response, the device management unit 11 turns off the power of the target part (S112).

When the remaining battery level becomes less than 5%, the device management unit 11 starts a blocking process for the path control unit 12 and the line control unit 13 (S098). Here, the blocking process is a complete stop of the path control unit 12 and the circuit control unit 13, specifically, other than the line control unit 13 connected to the stop part according to an instruction from the device management unit 11. After a route change request is transmitted to the device (S120), the power is turned off and a response is returned to the device management unit 11 (S121). Upon receiving the response, the device management unit 11 turns off the power of the target part (S122). The device management unit 11 sets the device disconnection in the power supply control information of the power supply control circuit 202 when the block processing of the path control unit 12 and the line control unit 13 is completed (S099, S100), and stops (blocks) itself. (S101). Finally, the power supply control circuit 202 stops the power supply from the battery 201 because the apparatus can be disconnected (S102).
Note that the description of FIG. 7 was performed by a power failure, but the same applies to the case where the power switch is turned off by mistake other than the power failure.

  According to the embodiments described above, the power consumption is suppressed by partially stopping the power supply by partially degenerating / restoring the communication control device that performs the multiplexing of the path, and as much as possible. The communication state can be maintained. In addition, changes in the network connection relationship can be minimized. Further, it is possible to prevent the communication control device from being turned off in a state where the switch of the device must not be cut off. Even if the power supply is cut off by mistake, the power supply can be safely turned off after the blocking process is performed. It is also possible to remarkably reduce the risk of destruction and malfunction of the device due to a sudden change in voltage due to power interruption, and the reliability against failure is also improved. Furthermore, it is possible to avoid the risk of malfunction caused by element destruction and data destruction caused by a sudden change in voltage due to power interruption.

  FIG. 8 is a block diagram illustrating a configuration of the communication control apparatus. In the communication control device 101a of FIG. 8, when the external power source 203 is in a power failure or the power switch 204 is disconnected, the battery 201 is in a discharge mode, and the device management unit 11, the path control unit 12, the line from the battery 201 through the power control circuit 202. Power is supplied to the control unit 13 and the line control LSI 31 of the line control unit 13. The line control unit 13 power control LSI 30 individually controls power to the line control LSI 31. Since the lines 41-1 to 41-p are controlled by the line control LSIs 31-1 to 31-p, the power can be turned off / on for each line individually.

  The device management unit 11 performs initial setting so that the route control unit 12 and the line control unit 13 can operate, and performs data communication with the network connected via the lines 41-1 to 41-p. The device management unit 11 monitors the power supply state from the power supply control circuit 202, determines the power-off possibility state for each part using the detected power supply state information and the power supply management table 21, and sets it in the power supply management table 21. The power control LSI 30 of the line control unit 13, the path control unit 12, and the device management unit 11 determine whether or not the power can be turned off according to the remaining battery level.

  FIG. 9 is a block diagram illustrating a configuration of the communication control apparatus. The communication control apparatus 101b of FIG. 9 has a power control circuit 202 connected to an external power source 203, and the power control provided in the apparatus management unit 11, the path control unit 12, and the path control unit 12 with the output of the power control circuit 202 is provided. Power is supplied to the line control unit 13 via the LSI 30. The device management unit 11 performs initial setting so that the route control unit 12 and the line control unit 13 can operate, and performs data communication with the network connected via the lines 41-1 to 41-p. The device management unit 11 monitors the power supply state from the power supply control circuit 202, determines the power-off possibility state for each part using the detected power supply state information and the power supply management table 21, and sets it in the power supply management table 21. The path control unit 12, the line control LSI 31 of the line control unit 13, and whether or not the device management unit 11 can be turned off are determined according to the remaining battery level. Further, when the device management unit 11 is blocked by powering off the entire device or partially, the device management unit 11 notifies the communication control device of the connection destination of the corresponding portion of the route blockage and prompts the change of the route.

  The degeneration / recovery process flow of the communication control apparatus 101 shown in FIGS. 8 and 9 is the same as the flowchart showing the degeneration / recovery process of the communication control apparatus of FIG. 5 regardless of the mounting position of the power supply control LSI.

  FIG. 10 is a block diagram illustrating a network configuration. The network 2000 in FIG. 10 has a configuration in which the communication control apparatus 101 and the communication control apparatus 102 are connected by configuring a link aggregation group with link aggregations 51-1 to 51-q. When the communication control apparatus 101 is degenerated due to a power failure or the like, the communication control apparatus 102 is notified of a path blockage to prompt a change of the path. When some of the lines aggregated in the link aggregations 51-1 to 51-q are turned off, the link aggregation group is left and data communication is continued as a link aggregation group on the remaining lines. . Also, by setting the lines belonging to the link aggregation group across the plurality of line control units 13-1 to 13-n, all the lines in the link aggregation group can be connected even if one or more line control units are turned off. It can be avoided to turn off.

  FIG. 11 is a diagram illustrating a power supply management table for each link aggregation line. The power supply management table 21 includes a remaining battery level 211 corresponding to the remaining battery level of the battery 201, a degeneration / recovery part 212 that specifies a part to be degenerated / recovered corresponding to the remaining battery level, and the current for each part. And a state 213 representing a power supply state.

  When the communication control apparatus 101 is supplying power from the battery 201 due to a power failure or the like, when the remaining battery level of the battery falls below 90%, the apparatus management unit 11 sets the remaining battery level 211 in the power supply management table 21 to 90. The degeneration / recovery site 212 set to% is searched, and the link aggregations LA2 to LAq are determined as sites to degenerate. The device management unit 11 degenerates the link aggregation LA2, turns off the power supply to the target line, and turns off the state 213 of the power supply management table 21. Further, when the remaining battery level of the battery drops below 5%, the device management unit 11 searches for the degeneration / recovery part 212 in which the remaining battery level 211 of the power supply management table 21 is set to 5%, The link aggregation LA1 is determined as a site to be degenerated. The device management unit 11 degenerates the link aggregation LA11 to turn off the power supply to the target line, and turns off the state 213 of the power supply management table 21.

  FIG. 12 is a flowchart showing the degeneration and recovery processing when setting link aggregation. The device management unit 11 acquires battery capacity information from the power supply information of the power supply control circuit 202, acquires the remaining battery level from the power supply management table 21, and searches whether there is a value equal to or lower than the current level value. -Compare (S031). The apparatus management unit 11 refers to the power supply management table 21 and proceeds to the next step 033 if there is a target part that has reached the battery remaining level, and returns to normal processing if there is no target part (S032). . It is determined whether the state 213 of the power supply management table 21 is on. If the state 213 is off, the process proceeds to a recovery process in step 038. If the state 213 is on, the process proceeds to a degeneration process in step 304 (S033). . In step 304, it is determined whether there is a link aggregation setting in the power line management table 21 for the target line of the degenerate portion. Change processing (S036) is performed. At the end of the degeneration process, the power of the line control LSI 31 of the target line is turned off (S037). If there is no link aggregation setting in step 034, steps 035 and 036 are omitted, and the process proceeds to step 037.

  If it is determined in step 033 that the process is recovery processing, the power supply of the line control LSI 31 of the target line is turned on (S038). At this time, it is determined whether or not link aggregation needs to be set for the line to be restored (S039). If link aggregation needs to be set, link aggregation change processing (S040) is performed, and link aggregation is changed to the connection destination. Notification is made (S041). If it is not necessary to set link aggregation in step 039, the process ends.

  According to the second embodiment, since a plurality of lines can be connected to the line control unit, a link aggregation can be formed using these lines. By increasing or decreasing the number of link aggregations according to the remaining battery level, it is possible to ensure minimum communication even during a power failure.

  FIG. 13 is a block diagram of a communication control apparatus having a duplex configuration. The communication control apparatus 101c of FIG. 13 is a configuration in which the configuration of the communication control apparatus 101 of FIG. The communication control device 101c duplicates the device management unit 11, the power supply management table 21, and the communication control device operation terminal 22. The duplex configuration is divided into a part for the active system and a part for the standby system. When a failure occurs in the part for the active system, data communication is continued by switching to the standby system. The power supply management table 21-1 is defined from the communication control apparatus operation terminal 22-1 connected to the communication control apparatus 101c, and the power supply management table 21-2 is defined from the communication control apparatus operation terminal 22-2. The duplexed power management tables 21-1 and 21-2 are set in the power management table 21-1 and the power management table 21-2 by communication between the device management unit 11-1 and the device management unit 11-2. Can be matched, or different settings can be made from the communication control device operation terminal 22-2.

  FIG. 14 is a block diagram of a communication control apparatus having another duplex configuration. The communication control apparatus 101d in FIG. 14 is configured to share the power supply management table of the communication control apparatus 101c in FIG. In the communication control apparatus 101d, the apparatus management unit 11 and the communication control apparatus operation terminal 22 are duplicated. The power supply management table 21 is defined from the communication control device operation terminal 22-1 connected to the communication control device 101d. The power supply management table 21 is commonly used by the device management unit 11-1 and the device management unit 11-2. When a power failure or the like occurs in the communication control apparatus 101 configured in the duplex configuration, there are a case where the communication configuration is degenerated in the duplex configuration and a case where a specific line is preferentially degenerated from a part of the standby system.

  When the settings of the power supply management table 21-1 and the power supply management table 21-2 are matched in the communication control apparatus 101c in FIG. 13 and in the communication control apparatus 101d in FIG. 14, a power failure or the like has occurred in the communication control apparatus 101. Explain the case. At this time, FIG. 15 shows the setting of the power supply management table 21 when the power supply management table 21 is degenerated in the duplex configuration, and FIG. 16 shows the setting of the power supply management table 21 when the specific line is preferentially degenerated from the standby part. Show. Here, FIG. 15 and FIG. 16 are diagrams for explaining the power supply management table.

  In FIG. 15, the remaining battery level 211 in the row of the device management unit 1 and the device management unit 2 of the degeneration / recovery part 212 is 10% or more, both the states 213 are ON, and the device management unit is degenerated while being duplicated. . In this case, even if a failure occurs during the degenerate operation, it is possible to switch from the active system to the standby system and continue communication.

  In FIG. 16, the remaining battery level 211 in the row of the device management unit 1 and the device management unit 2 of the degeneration / recovery part 212 is 10% or more and 80% or more, respectively, and the state 213 is on and off, respectively. 2 degenerates at less than 80%. When the active system is preferentially degenerated from the spare system part, power consumption can be suppressed because there are many parts that degenerate and stop power supply. As a result, the drive time of the battery 201 can be extended and communication can be continued as much as possible.

  Whichever power supply management table 21 of FIG. 15 or FIG. 16 is used, there is a case where the communication control apparatus 101 is degenerated / recovered due to a power failure or the like during the operation of the communication control apparatus 101, and there is a failure in the communication control apparatus 101. Since the contents set in the power supply management table 21 in the active system and the standby system are the same in the case of degeneration / recovery due to a power failure after switching to the system, the priority for degeneration / recovery does not change.

  On the other hand, FIG. 17 shows settings when the settings of the power supply management table 21-1 and the power supply management table 21-2 are not matched in the communication control apparatus 101c of FIG. Here, FIG. 17 is a diagram for explaining the power management tables for the active system and the standby system.

  In FIG. 17, (a) is an active power supply management table 21-1, and (b) is a standby power supply management table 21-2. 17A and 17B, the remaining battery level 211 in the row of the device management unit 1 and the device management unit 2 of the degeneration / recovery part 212 is set to 10% for the own system and 40% for the other system, respectively. Yes. Further, the remaining battery level 211 of each path setting unit and each line control unit is set to the same value in both FIGS. With this setting, when a power failure or the like occurs in the communication control apparatus 101c, the communication is continued with degeneration while keeping the duplex configuration valid. If a failure occurs during the reduced operation and the active system is switched to the standby system, the active device management unit in which the failure has occurred is degenerated and communication on the specific line is continued. In this case, since the remaining battery level 211 of the route setting unit and the line control unit is the same, no fluttering due to switching of the active system occurs.

It is a block diagram which shows the structure of a communication control apparatus. It is a flowchart explaining a power supply state monitoring process. It is a block diagram explaining a network structure. It is a figure explaining an electric power feeding management table. It is a flowchart explaining the degeneration and recovery processing of a communication control apparatus. It is a sequence diagram of a normal start-up process and stop process of a communication control apparatus. It is a sequence diagram when a power failure occurs during normal operation of the communication control device. It is a block diagram which shows the structure of a communication control apparatus. It is a block diagram which shows the structure of a communication control apparatus. It is a block diagram explaining the structure of a network. It is a figure explaining the electric power management table of a link aggregation line unit. It is a flowchart figure which shows the degeneracy and recovery process at the time of link aggregation setting. It is a block diagram of the communication control apparatus of a duplex structure. It is a block diagram of the communication control apparatus of another duplex structure. It is a figure explaining the electric power feeding management table in case priority is given to a duplication structure. It is a figure explaining the electric power feeding management table in the case of giving priority to a specific operation system. It is a figure explaining the electric power management table of an active system and a standby system.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 11 ... Device management part, 12 ... Path control part, 13 ... Line control part, 21 ... Power supply management table, 22 ... Communication control apparatus operation terminal, 30 ... Power supply control LSI, 31 ... Line control LSI, 41 ... Line, 51 ... Link aggregation, 101-105 ... communication control device, 141 ... control line, 151 ... power supply line, 201 ... battery, 202 ... power supply control circuit, 203 ... external power supply, 204 ... power switch, 501-502 ... communication path, 1000 ... Network, 2000 ... Network.

Claims (3)

A communication control device,
A device management unit that performs overall control;
A path control unit connected to the device management unit to control the communication path;
A line control unit connected to the device management unit for line control;
A power control unit connected to an external power source and the device management unit;
A battery that is connected to the power supply controller and performs backup when power supply from an external power supply is stopped,
The communication control device is connected to another communication control device by link aggregation using a plurality of lines,
When the power supply from the external power supply is stopped, the power control unit monitors the remaining amount of the battery,
When the remaining amount of the battery satisfies a preset condition, the device management unit is connected to the line control unit connected to the line constituting the link aggregation via the path control unit and the power supply control unit. A communication control device characterized in that power supply to a part is stopped or restarted. The communication control device according to claim 1,
When the power supply state of a part of the line control unit connected to the line constituting the link aggregation is changed, the device management unit notifies the communication control device adjacent through the line of the change in the line state. A communication control device. The communication control device according to claim 1 or 2,
When power supply to a part of the line control unit connected to the line constituting the link aggregation is stopped, the link aggregation is newly reconfigured with the line connected to the line control unit that is in the remaining power supply. A communication control device.

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