JP2016021644A - Communication control system and communication control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a communication control system that can reduce a burden on a manager and increase availability.SOLUTION: In a radio communication control system, when a server PC 11 does not receive a response packet within a reference time Tth after transmitting a monitoring packet, the server PC 11 automatically outputs a master unit restart instruction signal to a server side restart unit 15 to instruct the server side restart unit 15 to stop a wireless LAN master unit 13 once and then restart it. When the server PC 11 receives a response packet within the reference time Tth, the server PC 11 does not output a master unit restart instruction signal to the server side restart unit 15. If a master unit restart instruction signal is input, the server side restart unit 15 stops the wireless LAN master unit 13 once and then restart it, and if a master unit restart instruction signal is not input, the server side restart unit 15 does not stop the wireless LAN master unit 13.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a communication control system and a communication control method.

2. Description of the Related Art Conventionally, a wireless communication control system has been proposed in which a wireless terminal can check whether there is an abnormality in a communication partner server device (see Patent Document 1).
The wireless terminal described in Patent Literature 1 periodically transmits a life / death monitoring packet for inquiring whether there is an abnormal state of the server device to the server device. On the other hand, when the server apparatus receives the alive monitoring packet, the server apparatus returns a result of confirming whether there is an abnormality in the server apparatus to the wireless terminal as a server state monitoring result. When the server status monitoring result is abnormal or the server status monitoring result is not returned, the wireless terminal notifies the user of the wireless terminal via the display screen or the speaker that the server device is abnormal. .
When the wireless terminal is notified that the server device is abnormal, the user can contact the system administrator and wait for the administrator to restore the server device to resume processing.

JP 2008-236447 A

However, in the invention described in Patent Document 1, if an abnormality occurs, all the managers must deal with it, increasing the burden on the manager.
In addition, every time an abnormality occurs, the user must wait for a recovery operation by the administrator, and there is a possibility that the availability may be reduced due to an increase in MTTR (average repair time).

  The present invention has been made in view of the above reasons, and an object thereof is to provide a communication control system capable of reducing the burden on an administrator who performs abnormality monitoring and abnormality repair and improving availability.

In order to achieve the above object, a communication control system according to the present invention provides:
An information processing unit for outputting a monitoring packet;
A communication unit that transmits the monitoring packet received from the information processing unit;
A restarting unit that restarts after temporarily stopping the communication unit,
Two communication control devices
When the information processing unit or the communication unit included in one of the two communication control devices receives the monitoring packet from the other of the two communication control devices, the information processing unit or the communication unit transmits a response packet destined for the other,
When the information processing unit included in the one side does not receive the response packet within a reference time after transmitting the monitoring packet, the information processing unit included in the one side temporarily stops the communication unit and restarts the communication unit. When outputting the communication unit restart instruction signal instructing to start and receiving the response packet within the reference time, the restart unit included in the one does not output the communication unit restart instruction signal,
The restart unit included in the one side temporarily stops and restarts the communication unit included in the one side based on the communication unit restart instruction signal output from the information processing unit.

The communication control method according to the present invention from another viewpoint is as follows:
A communication unit comprising: an information processing unit that outputs a monitoring packet; a communication unit that transmits the monitoring packet received from the information processing unit; and a restarting unit that temporarily stops the communication unit and then restarts the communication unit. A communication control method using two control devices,
The information processing unit or the communication unit included in one of the two communication control devices, when receiving the monitoring packet from the other of the two communication control devices, transmits a response packet destined for the other; ,
If the information processing unit included in the one does not receive the response packet within a reference time after transmitting the monitoring packet, the restart unit included in the one temporarily stops the communication unit and then restarts the communication. When outputting the communication unit restart instruction signal instructing to start and receiving the response packet within the reference time, the step of not outputting the communication unit restart instruction signal to the restart unit included in the one,
A restart unit included in the one side, based on the communication unit restart instruction signal output from the information processing unit, temporarily stopping and restarting the communication unit included in the one side.

  According to the present invention, it is possible to reduce the burden on an administrator who performs abnormality monitoring and abnormality repair and to improve availability.

1 is a schematic configuration diagram of a radio communication control system according to an embodiment. It is a sequence diagram which shows operation | movement of the server apparatus and terminal device at the time of normal of the radio | wireless communication control system which concerns on embodiment. The operation of the server apparatus when an abnormality occurs in the wireless communication function of the wireless LAN slave unit of the wireless communication control system according to the embodiment, and the operation of the server apparatus when an abnormality occurs in the wired communication function of the wireless LAN base unit FIG. It is a time chart which shows operation | movement of the server apparatus and terminal device when abnormality generate | occur | produces in the radio | wireless communication function of the wireless LAN subunit | mobile_unit of the radio | wireless communication control system which concerns on embodiment. It is a sequence diagram which shows operation | movement of a server apparatus when abnormality generate | occur | produces in the wire communication function of the wireless LAN subunit | mobile_unit of the wireless communication control system which concerns on embodiment. It is a time chart which shows operation | movement of the server apparatus and terminal device when abnormality generate | occur | produces in the wire communication function of the wireless LAN subunit | mobile_unit of the wireless communication control system which concerns on embodiment. It is a sequence diagram which shows operation | movement of the server apparatus when abnormality generate | occur | produces in the wired communication function of server PC of the radio | wireless communication control system which concerns on embodiment. It is a time chart which shows operation | movement of the server apparatus when abnormality generate | occur | produces in the wire communication function of server PC of the radio | wireless communication control system which concerns on embodiment.

  Hereinafter, a communication control system and a communication control method according to an embodiment of the present invention will be described using an example of a wireless communication control system including one server device and one terminal device.

The wireless communication control system according to this embodiment includes a server device 1 and a terminal device 2 that wirelessly communicates with the server device 1. For example, the terminal device 2 reads the number plate of the vehicle, reads a tag possessed by a person, and transmits the read information to the server device 1. On the other hand, the server device 1 collects information received from the terminal device 2 and provides it to the administrator. And the server apparatus 1 and the terminal device 2 perform the operation | movement for monitoring which monitors whether abnormality has mutually generate | occur | produced in parallel with these general operation | movement.
Hereinafter, the structure of each part is demonstrated in order.

  The server device 1 includes a server PC (information processing unit) 11, a wireless LAN (Local Area Network) base unit (communication unit) 13 connected to the server PC 11 via a communication line LEa, a server-side restart unit 15, The server-side power supply unit 17 and the antenna ATa are included. As the communication line LEa, for example, a line that conforms to the Ethernet (registered trademark) standard can be used. The server PC 11 and the wireless LAN base unit 13 are each assigned unique identification information.

The terminal device 2 includes a terminal PC (information processing unit) 21, a wireless LAN slave device (communication unit) 23 connected to the terminal PC 21 via a communication line LEb, a terminal-side restart unit 25, and a terminal-side power supply unit 27 and an antenna ATb. For example, a communication line LEb that conforms to the Ethernet (registered trademark) standard can be used. The terminal PC 21 and the wireless LAN slave device 23 are each assigned unique identification information.
The identification information is composed of, for example, an IP address and a device serial number.

Hereinafter, the configuration of the server device 1 will be described in detail.
The server PC 11 includes a CPU (Central Processing Unit), a memory, and a wired communication port (not shown). The server PC 11 communicates with the wireless LAN base unit 13 via the wired communication port by the CPU executing a communication application stored in the memory in advance.

  The server PC 11 transmits a monitoring packet to the wireless LAN base unit 13 at a preset time interval via the communication line LEa. The monitoring packet includes at least destination identification information for identifying the destination and type identification information for identifying the type of packet (which is a monitoring packet). The server PC 11 holds in advance the identification information of the wireless LAN slave device 23 that can be the destination of the monitoring packet in the memory, and sets the destination identification information of the monitoring packet as the identification information of the wireless LAN slave device 23.

  The server PC 11 automatically restarts when the power supply from the server-side power supply unit 17 is temporarily stopped and then restarted. The server PC 11 temporarily stops the wireless LAN base unit 13 and then outputs a base unit restart instruction signal (communication unit restart instruction signal) for restarting to the server side restart unit 15. The server PC 11 temporarily stops its own machine, and then outputs a PC restart instruction signal (processing section restart instruction signal) for restarting to the server side restart section 15.

  Further, the server PC 11 can measure the elapsed time after the monitoring packet is output by the built-in timer. This built-in timer can be composed of a software timer or a hardware timer.

  The wireless LAN base unit 13 includes a wired communication port and a wireless communication port (not shown). The wireless LAN base unit 13 has a gateway function and a modem function, and wirelessly transmits the monitoring packet received via the wired communication port via the wireless communication port and the antenna ATa. The wireless LAN base unit 13 includes a memory (not shown), and holds the identification information of the own device and the identification information of the server PC 11 in the memory.

  Further, when receiving the monitoring packet from the wireless LAN slave device 23 described later, the wireless LAN master device 13 acquires the destination identification information included in the monitoring packet, and the acquired destination identification information is the identification information of the own device. If they match, a response packet addressed to a terminal PC 21 described later is generated and transmitted. The response packet includes at least destination identification information for identifying the destination and type identification information for identifying the type of packet (that is, a response packet), and the destination identification information is set in the identification information of the information terminal PC21. Has been. On the other hand, if the acquired destination identification information does not match the identification information of the own device, the wireless LAN base unit 13 does not generate a response packet.

  Further, when receiving a response packet from the wireless LAN slave device 23 (to be described later), the wireless LAN master device 13 acquires destination identification information included in the response packet, and the acquired destination identification information matches the identification information of the server PC 11. In this case, the received response packet is transmitted to the server PC 11. On the other hand, if the acquired destination identification information does not match the identification information of the server PC 11, the wireless LAN base unit 13 discards the received response packet.

  The wireless LAN base unit 13 automatically restarts when the power supply from the server-side power supply unit 17 is temporarily stopped and then restarted.

  The server-side power supply unit 17 supplies the generated or stored power to the wireless LAN base unit 13 and the server PC 11. The server side power supply part 17 is comprised from a generator and a battery, for example. The server-side power supply unit 17 supplies power to the wireless LAN base unit 13 via a server-side restart unit 15 described later and a base unit power line (communication unit power line) Laa. The server-side power supply unit 17 supplies power to the server PC 11 via a server-side restart unit 15 described later and a server PC power line (processing unit power line) Lab.

  The server-side restart unit 15 controls power supply from the server-side power supply unit 17 to the wireless LAN base unit 13 and the server PC 11. The power supply control is to stop the power supply and stop the wireless LAN base unit 13 or the server PC 11 and then restart the power supply. With this power supply control, the wireless LAN base unit 13 or the server PC 11 is temporarily stopped and then automatically restarted. That is, the server-side restart unit 15 performs control to restart the wireless LAN base unit 13 or the server PC 11.

  Specifically, the server-side restart unit 15 includes a switch (communication unit switch) SWaa connected to the master unit power line Laa, a server-side switch control unit 151, and a server-side timer 152. When a master unit restart instruction signal is input from the server PC 11, the server-side switch control unit 151 opens the switch SWaa and sends a timing start signal to the server-side timer 152. The server-side timer 152 starts counting the stop time after the switch SWaa is opened when a timing start signal is input from the server-side switch control unit 151.

  The server-side restart unit 15 further includes a switch (processing unit switch) SWab connected to the server PC power line Lab. When a PC restart instruction signal is input from the server PC 11, the server side switch control unit 151 opens the switch SWab and sends a time measurement start signal to the server side timer 152. When the timer start signal is input from the server switch control unit 151, the server timer 152 starts counting the stop time after the switch SWab is opened.

  That is, the server-side switch control unit 151 may function as a control unit for the switch SWaa (communication unit switch control unit) or as a control unit for the switch SWab (processing unit switch control unit) depending on the situation. Sometimes it works. In addition, the server-side timer 152 functions as a timer unit (a timer unit for communication unit) that measures the elapsed time after the switch SWaa is opened, corresponding to each of the functions of the server-side switch control unit 151. Alternatively, it functions as a time measuring unit (processing unit time measuring unit) that measures the elapsed time after the switch SWab is opened.

Hereinafter, the terminal device 2 will be described in detail.
The terminal PC 21 includes a CPU, a memory, and a wired communication port (not shown). The terminal PC 21 communicates with the wireless LAN slave device 23 via the wired communication port by the CPU executing a communication application stored in the memory in advance.

  The terminal PC21 outputs monitoring packets to the wireless LAN slave device 23 at preset time intervals via the communication line LEb. The terminal PC 21 holds in advance the identification information of the wireless LAN base unit 13 that can be the destination of the monitoring packet in the memory, and sets the destination identification information of the monitoring packet in the identification information of the wireless LAN base unit 13.

The terminal PC 21 automatically restarts when the power supply from the terminal-side power supply unit 27 is temporarily stopped and then restarted. The terminal PC 21 generates a slave unit restart instruction signal (communication unit restart instruction signal) and outputs it to the terminal side restart unit 25 when the wireless LAN slave unit 23 is temporarily stopped and then restarted. When the terminal PC 21 is temporarily stopped and then restarted, the terminal PC 21 generates a PC restart instruction signal (processing unit restart instruction signal) and outputs the PC restart instruction signal to the terminal side restart unit 25.
The terminal PC 21 can also measure the elapsed time after the monitoring packet is output by the built-in timer.

  The wireless LAN handset 23 includes a wired communication port and a wireless communication port (not shown). The wireless LAN slave unit 23 has a gateway function and a modem function, and wirelessly transmits the monitoring packet received via the wired communication port via the wireless communication port and the antenna ATb. In addition, the wireless LAN slave device 23 includes a memory (illustrated), and holds the identification information of the own device and the identification information of the terminal PC 21 in the memory.

  In addition, when receiving the monitoring packet from the wireless LAN master device 13, the wireless LAN slave device 23 acquires the destination identification information included in the monitoring packet, and the acquired destination identification information matches the identification information of the own device. In this case, a response packet addressed to the server PC 11 is generated and transmitted. The response packet includes at least destination identification information for identifying the destination and type identification information for identifying the type of packet (that is, a response packet), and the destination identification information is set in the identification information of the server PC 11. Has been. On the other hand, if the acquired destination identification information does not match the identification information of the own device, the wireless LAN slave device 23 does not generate a response packet.

  Further, when receiving the response packet from the wireless LAN master device 13, the wireless LAN slave device 23 acquires the destination identification information included in the response packet, and when the acquired destination identification information matches the identification information of the terminal PC 21. The received response packet is transmitted to the terminal PC 21. On the other hand, when the acquired destination identification information does not match the identification information of the terminal PC 21, the wireless LAN slave device 23 discards the received response packet.

  The wireless LAN slave unit 23 also automatically restarts when the power supply from the terminal-side power supply unit 27 is temporarily stopped and then restarted.

  The terminal-side power supply unit 27 supplies the generated or stored power to the wireless LAN slave unit 23 and the terminal PC 21. Similarly to the server-side power supply unit 17, the terminal-side power supply unit 27 includes, for example, a generator and a battery. The terminal-side power supply unit 27 supplies power to the wireless LAN slave unit 23 via a terminal-side restart unit 25 described later and a slave unit power line (communication unit power line) Lba. The terminal-side power supply unit 27 supplies power to the terminal PC 21 via a terminal-side restart unit 25 described later and a terminal PC power line (processing unit power line) Lbb.

  The terminal-side restart unit 25 controls power supply from the terminal-side power supply unit 27 to the wireless LAN slave device 23 and the terminal PC 21. The power supply control is to stop the power supply and stop the wireless LAN slave unit 23 or the terminal PC 21 and then restart the power supply. By this power supply control, the wireless LAN slave unit 23 or the terminal PC 21 is temporarily stopped and then automatically restarted. That is, the terminal-side restart unit 25 performs control to restart the wireless LAN slave device 23 or the terminal PC 21.

  Specifically, the terminal-side restart unit 25 includes a switch (communication unit switch) SWba, a terminal-side switch control unit 251, and a terminal-side timer 252 connected to the power supply line Lba for the slave unit. When a slave unit restart instruction signal is input from the terminal PC 21, the terminal side switch control unit 251 opens the switch SWba and sends a timing start signal to the terminal side timer 252. When receiving a timing start signal from the terminal-side switch control unit 251, the terminal-side timer 252 starts measuring the stop time after the switch SWba is opened.

  In addition, the terminal-side restart unit 25 further includes a switch (processing unit switch) SWbb connected to the terminal PC power supply line Lbb. When the PC restart instruction signal is input from the terminal PC 21, the terminal side switch control unit 251 opens the switch SWbb and sends a timing start signal to the terminal side timer 252. The terminal timer 252 starts counting the stop time after the switch SWbb is opened when the timing start signal is input from the terminal switch control unit 251.

  That is, the terminal-side switch control unit 251 may function as a communication unit switch control unit or a processing unit switch control unit depending on the situation. The terminal-side timer 252 functions as a communication unit timing unit or functions as a processing unit timing unit corresponding to each of the functions of the terminal-side switch control unit 251.

Next, the operation of the wireless communication control system according to this embodiment will be described.
First, an outline of the operation of the wireless communication control system will be described.
For example, the terminal device 2 reads the number plate of the vehicle, reads a tag possessed by a person, and transmits the read information to the server device 1. On the other hand, the server device 1 collects information received from the terminal device 2 and provides it to the administrator. The server apparatus 1 and the terminal apparatus 2 perform the operation for mutual monitoring described below in parallel with these general operations.
When the server PC 11 of the server device 1 outputs a monitoring packet addressed to the terminal device 2 and receives a response packet within a reference time set as a reference time for determining occurrence of abnormality, the wireless communication control system is normal. Judge that there is.

  On the other hand, if the server PC 11 does not receive a response packet within the reference time, the server PC 11 first stops and then restarts the wireless LAN base unit 13. Thereafter, the server PC 11 outputs a monitoring packet, and if the response packet is not received within the reference time after the monitoring packet is output, the server PC 11 temporarily stops and restarts the server PC 11.

Similarly to the server PC, the terminal PC 21 of the terminal device 2 appropriately stops and restarts the wireless LAN slave device 23 and restarts the own device after temporarily stopping it.
The server PC 11 and the terminal PC 21 perform these operations in parallel. As a result, the abnormality monitoring on the server device 1 side and the recovery to the normal state, and the abnormality monitoring on the terminal device 2 side and the recovery to the normal state are automatically performed in parallel, and wireless communication is performed when an abnormality occurs. The entire communication control system is automatically restored to a normal state.

The specific operation of the wireless communication control system is as follows.
[1] Operation when the wireless communication control system is normal First, the operation when the wireless communication control system is normal will be described. FIG. 2 is a sequence diagram showing the operation of the wireless communication control system when it is normal. As shown in FIG. 2, the server PC 11 generates a monitoring packet destined for the wireless LAN slave device 23 (step S1), and sends the generated monitoring packet to the wireless LAN master device 13 as a communication line LEa. (Step S2). The transmission at the same time, the server PC11, due internal timer, and starts counting the elapsed time after monitoring packet output T ₁ (step S3). The server PC 11 repeats such monitoring packet output (step S2) at a constant cycle Ts. This period Ts is set to 30 seconds, for example.

  When receiving the monitoring packet from the server PC 11, the wireless LAN master device 13 wirelessly transmits the monitoring packet to the wireless LAN slave device 23 (step S4).

  When receiving the monitoring packet from the wireless LAN base unit 13, the wireless LAN handset 23 generates a response packet addressed to the server PC 11 (step S 5), and wirelessly transmits the generated response packet to the wireless LAN base unit 13. (Step S6).

  When receiving the response packet from the wireless LAN slave device 23, the wireless LAN master device 13 transmits the response packet to the server PC 11 through the communication line LEa (step S7).

Server PC11 receives the response packet from the wireless LAN base unit 13 ends the count of the elapsed time _{T 1} by the built-in timer (step S8). In the case shown in FIG. 2, the elapsed time _{T 1} is shorter than the reference time Tth. That is, the server PC 11 receives the response packet within the reference time Tth. In this case, the server PC 11 determines that there is no abnormality in the wireless communication functions of the wireless LAN master device 13 and the wireless LAN slave device 23 and the wired communication functions of the server PC 11, wireless LAN master device 13 and the wireless LAN slave device 23. Therefore, the server PC 11 does not output a parent machine restart instruction signal to the server-side restart unit 15.

On the other hand, the server-side restart unit 15 continues to supply power from the server-side power supply unit 17 to the wireless LAN base unit 13 because no base unit restart instruction signal is input.

  Thereafter, the server PC 11 repeats the output of the monitoring packet and the reception of the response packet in response to the same in the same manner as described above. Thereby, the abnormality monitoring process from the server apparatus 1 side is performed with a fixed period.

In parallel with the abnormality monitoring process performed by the server PC 11, the same abnormality monitoring process is executed on the terminal device 2 side. Specifically, as shown in FIG. 2, the terminal PC 21 generates a monitoring packet destined for the wireless LAN base unit 13 (step S11), and transmits the generated monitoring packet to the wireless LAN slave through the communication line LEb. It outputs to the machine 23 (step S12). The transmission at the same time, the terminal PC21 is a built-in timer, and starts counting the elapsed time after monitoring packet output _{T 2} (step S13). The terminal PC21 repeats such monitoring packet output (step S12) at a constant cycle Ts. Here, it is assumed that the terminal PC21 repeats outputting the monitoring packet substantially in synchronization with the server PC11.

  When receiving the monitoring packet from the terminal PC 21, the wireless LAN slave device 23 wirelessly transmits the monitoring packet to the wireless LAN master device 13 (step S14).

  When receiving the monitoring packet from the wireless LAN slave device 23, the wireless LAN master device 13 generates a response packet destined for the terminal PC 21 (step S15), and wirelessly transmits the generated response packet to the wireless LAN slave device 23. (Step S16).

  When receiving the response packet from the wireless LAN master device 13, the wireless LAN slave device 23 transmits the response packet to the terminal PC 21 through the communication line LEb (step S17).

Terminal PC21 receives the response packet from the wireless LAN terminal 23, and ends the counting of the elapsed time _{T 2} by internal timer (step S18). In the case shown in FIG. 2, the elapsed time _{T 2} are shorter than the reference time Tth. That is, the terminal PC 21 receives the response packet within the reference time Tth. In this case, the terminal PC 21 determines that there is no abnormality in the wireless communication functions of the wireless LAN master device 13 and the wireless LAN slave device 23 and the wired communication functions of the terminal PC 21, wireless LAN master device 13 and the wireless LAN slave device 23. Accordingly, the terminal PC 21 does not output a slave unit restart instruction signal to the terminal-side restart unit 25.

  On the other hand, the terminal-side restart unit 25 continues to supply power from the terminal-side power supply unit 27 to the wireless LAN slave unit 23 because no slave unit restart instruction signal is input.

  Thereafter, the terminal PC 21 repeats the output of the monitoring packet and the reception of the response packet in response to the same in the same manner as described above. Thereby, the abnormality monitoring process from the terminal device 2 side is executed at a constant cycle.

  As described above, the abnormality monitoring process is performed from both the server device 1 and the terminal device 2 and it is confirmed that both are normal. Therefore, it is ensured that the entire wireless communication control system is normal. .

[2] Operation when an abnormality occurs in the wireless communication control system Next, an operation when an abnormality occurs in the wireless communication control system will be described for each case.
[2-1] When an Abnormality Occurs Only in the Wireless Communication Function of the Wireless LAN Slave Unit Next, an operation of the server device 1 when an abnormality occurs only in the wireless communication function of the wireless LAN slave unit 23 will be described. Here, it is assumed that the wired communication function of the server PC 11 and the wired communication function and the wireless communication function of the wireless LAN base unit 13 are normal. Examples of the abnormality of the wireless communication function of the wireless LAN slave unit 23 include an abnormality of the wireless communication control function and an abnormality of the modem function due to the software of the wireless LAN slave unit 23.

The upper half of FIG. 3 is a sequence diagram showing the operation of the server device 1 when an abnormality occurs in the wireless communication function of the wireless LAN slave device 23. As shown in the upper side of FIG. 3, the server PC 11 generates a monitoring packet (step S1), and outputs the generated monitoring packet to the wireless LAN base unit 13 (step S2). Thereafter, the server PC11, due internal timer, and starts counting the elapsed time after monitoring packet output _{T 1} (step S3). As described in [2-1] above, the server PC 11 repeats the output of the monitoring packet at regular intervals (steps S31 and S33).

  Each time the wireless LAN base unit 13 receives a monitoring packet from the server PC 11, the wireless LAN base unit 13 wirelessly transmits the received monitoring packet to the wireless LAN slave unit 23 (steps S4, S32, and S34).

  On the other hand, since the wireless LAN slave unit 23 has an abnormality in the wireless communication function, at least one of the three abnormalities, ie, the inability to receive a monitoring packet, the inability to generate a response packet, and the inability to transmit a response packet occurs. ing. Regardless of which of the three abnormalities occurs, the server PC 11 cannot receive a response packet from the wireless LAN slave unit 23.

FIG. 4 is a time chart showing the operation shown in the upper half of FIG. 3 based on the time axis. Here, the state of the wireless LAN base unit 13 and the wireless LAN handset 23, the output timing of the monitoring packet and the response packet reception timing of the server PC and the terminal PC, the server side restart unit 15 and the terminal side restart unit 25 The relationship with the operation state of is shown.
In Figure 4, the abnormality of the wireless communication function of the wireless LAN terminal 23 is generated at time t _1, the wireless LAN terminal 23 at time t ₅ indicates the case where the restored to a normal state. The circles shown in “Output timing of monitoring packet of server PC” and “Output timing of monitoring packet of terminal PC” indicate the timing at which the server PC 11 and terminal PC 21 output the monitoring packet. Here, a solid line circle indicates a case where a monitoring packet is actually output, and a broken line circle indicates a case where a monitoring packet is not output. The circles shown in “Reception timing of response packet of server PC” and “Reception timing of response packet of terminal PC” indicate that the server PC 11 and the terminal PC 21 receive the response packet in response to the output of the monitoring packet. It shows the timing to be done. Here, a solid line circle indicates a case where a response packet is actually received, and a broken line circle indicates a case where a response packet is not received.

As shown in FIG. 4, when the wireless communication control system is normal, the server PC 11 and the terminal PC 21 output the monitoring packets substantially in synchronization with each other at substantially the same cycle as the monitoring packet output cycle Ts. A response packet is received.
Then, at time _{t 1,} an abnormality occurs in the wireless communication function by wireless LAN terminal 23, the server PC11 does not receive a response packet. This condition (between times t ₅ from time t ₁₎ during the abnormality of the wireless communication function of the wireless LAN terminal 23 is generated continues.

Returning to FIG. 3, if the server PC 11 does not receive a response packet from the wireless LAN base unit 13, it continues to count the elapsed time T ₁ by the built-in timer. Thereafter, when the reference time Tth, which is a time used as a criterion for occurrence of abnormality, elapses, the counting ends (step S35). Then, the server PC 11 outputs a parent machine restart instruction signal to the server side restart unit 15 (step S36). That is, when the server PC 11 does not receive the response packet within the reference time Tth after the monitoring packet is output, the server PC 11 outputs a master unit restart instruction signal to the server side restart unit 15.

  On the other hand, when the base unit restart instruction signal is input, the server side restart unit 15 performs a supply stop process for stopping the power supply to the wireless LAN base unit 13 (step S37). Specifically, the server-side switch control unit 151 opens the switch SWaa. Thereby, the power supply from the server-side power supply unit 17 to the wireless LAN base unit 13 is stopped, and the operation of the wireless LAN base unit 13 is stopped (step S38). Moreover, the server side switch control part 151 will send a time-measurement start signal to the server side timer 152, if a supply stop process is performed.

When the timer start signal is input from the server side switch control unit 151, the server side timer 152 starts counting the stop time of the wireless LAN base unit 13 due to the switch SWaa being opened (step S39).
Server-side timer 152, the count is stopped time reaches the required stopping time T _0, and ends the counting of the stop time (step S40). Here, the “necessary stop time” is set based on the time required for the wireless LAN base unit 13 to completely stop immediately after the power supply to the wireless LAN base unit 13 is stopped, for example. Then, the server-side timer 152 sends a notification signal notifying that the stop time to be counted has reached the required stop time T ₀ to the server-side switch control unit 151.

The server-side restart unit 15 performs a supply restart process for restarting the power supply to the wireless LAN base unit 13 (step S41). That is, the server-side switch control unit 151 receives the notification signal from the server-side timer 152, and closes the switch SWaa again. As a result, the power supply from the server-side power supply unit 17 to the wireless LAN base unit 13 is resumed, and the wireless LAN base unit 13 is automatically restarted by the power supply (step S42). As a result, the abnormality caused by the software hang-up or the like of the wireless LAN base unit 13 is repaired by the initialization process accompanying this restart, and the wireless LAN base unit 13 returns to a normal state. It should be noted that the time T ₁₀ required for the wireless LAN base unit 13 to restart after the server side switch control unit 151 performs the supply stop process is the initialization process of the wireless LAN base unit 13 at the necessary stop time T _0. The processing time required for restarting is added. The processing time required for this restart is, for example, 40 seconds.

That is, the server-side restart unit 15, if the master unit restarts an instruction signal is inputted, stops only requires downtime T ₀ power supply from the server-side power supply unit 17 to the wireless LAN base unit 13. Thereafter, the server-side restart unit 15 starts supplying power to the wireless LAN base unit 13 again. As a result, when an abnormality caused by the software of the wireless LAN base unit 13 occurs, if the abnormality is resolved by restarting the wireless LAN base unit 13, the wireless LAN base unit 13 is automatically recovered. it can.

In FIG. 4, the reference time Tth, which is the time used as the criterion for occurrence of abnormality, is, for example, twice the output period Ts of the monitoring packet, that is, the server PC 11 and the terminal PC 21 count the elapsed times T ₁ and T ₂ . It is assumed that it is set equal to the time required from the start until the response packet is received three times.
The server PC 11 outputs the monitoring packet at time t ₂ after the occurrence of the wired communication abnormality, and starts counting the elapsed time T ₁ after the monitoring packet is output. The terminal PC 21 also outputs the monitoring packet at time t ₂ after the occurrence of the wired communication abnormality, and starts counting the elapsed time T ₁ after the monitoring packet is output.

Next, the server PC 11 outputs a parent machine restart instruction signal to the server side restart unit 15 at time t ₃ when the reference time Tth has elapsed from time t ₂ without receiving a response packet. Then, the server-side restart unit 15 stops power supply to the wireless LAN base unit 13. Also, the terminal PC 21 outputs a slave unit restart instruction signal to the terminal-side restart unit 25 at time t ₃ when the reference time Tth has elapsed from time t ₂ without receiving a response packet. As a result, the terminal-side restart unit 25 stops the power supply to the wireless LAN slave unit 23.

At time t ₄ when the necessary stop time T _{0 has} elapsed from time t ₃ , the server-side restart unit 15 performs supply resumption processing for resuming power supply to the wireless LAN base unit 13. At substantially the same time, the terminal-side restart unit 25 also resumes power supply to the wireless LAN slave unit 23. Then, substantially the same time _{t 5} the wireless LAN base unit 13 and wireless LAN terminal 23 is restarted together. At time _{t 6} after the wireless LAN base unit 13 and wireless LAN terminal 23 is restored, the wireless LAN base unit 13 receives a monitoring packet transmitted from the terminal PC 21, and transmits a response packet to this. Further, the wireless LAN slave unit 23 also receives the monitoring packet transmitted from the server PC 11 and transmits a response packet in response thereto. Server PC 11 and terminal PC 21 each receive a response packet.
Thereafter, the server PC 11 again repeats the output of the monitoring packet and the reception of the response packet in response to this at a constant cycle Ts. Further, the terminal PC 21 again repeats the output of the monitoring packet and the reception of the response packet in response to this at a constant cycle Ts. In this way, the server PC 11 and the terminal PC 21 continue to monitor the abnormality with a constant cycle Ts.

  Note that only an abnormality in the wireless communication function of the wireless LAN base unit 13 may occur. Here, the wired communication function of the terminal PC 21 and the wired communication function and the wireless communication function of the wireless LAN slave unit 23 are normal. In this case, regarding the operation of the terminal device 2, in the description of [2-1], “server-side restart unit”, “server PC”, “wireless LAN master”, “wireless LAN slave” The description replaced with “terminal-side restart unit”, “terminal PC”, “wireless LAN slave”, and “wireless LAN master” is applied. That is, when the terminal PC 21 outputs a monitoring packet via the wireless LAN slave unit 23 and does not receive a response packet thereto, it outputs a slave unit restart instruction signal to the terminal-side restart unit 25. When the slave unit restart instruction signal is input, the terminal-side restart unit 25 temporarily stops the wireless LAN slave unit 23 and then restarts it.

  In the above description of [2-1], it is assumed that the wireless communication control system has a configuration of one server device and one terminal device. In this case, the wireless LAN base unit 13 that is actually normal is also restarted. However, most of the radio control systems that are actually operated have a plurality of terminal devices. In this case, if the wireless LAN base unit receives a response packet from any of the normal wireless LAN handset units among the plurality of terminal devices, the wireless LAN base unit is determined to be normal and restarted. There is nothing.

[2-2] When an Abnormality Occurs Only in the Wired Communication Function of the Wireless LAN Base Unit Next, an operation of the server device 1 when an abnormality occurs only in the wired communication function of the wireless LAN base unit 13 will be described.
Examples of the abnormality in the wired communication function of the wireless LAN base unit 13 include an abnormality in the wired communication control function and an abnormality in the gateway function caused by software.

The lower half of FIG. 3 is a sequence diagram showing the operation of the server device 1 when an abnormality occurs in the wired communication function of the wireless LAN base unit 13. As shown in the lower part of FIG. 3, the server PC 11 generates a monitoring packet (step S1), and outputs the generated monitoring packet to the wireless LAN base unit 13 (step S2). Thereafter, the server PC11, due internal timer, and starts counting the elapsed time after monitoring packet output _{T 1} (step S3). Further, the server PC 11 repeats the output of the monitoring packet at a constant cycle as already described (steps S31 and S33).

  Since the wireless LAN base unit 13 has an abnormality in the wired communication function and cannot receive the monitoring packet from the server PC 11, the monitoring packet is not wirelessly transmitted to the wireless LAN handset 23. Accordingly, since the response packet is not transmitted from the wireless LAN slave device 23, the server PC 11 naturally does not receive the response packet.

If the server PC 11 does not receive a response packet from the wireless LAN base unit 13, the server PC 11 continues to count the elapsed time T ₁ by the built-in timer. Thereafter, when the elapsed time _{T 1} for counting passes a reference time Tth, it stops counting (step S35). Then, the server PC 11 outputs a parent machine restart instruction signal to the server side restart unit 15 (step S36).
Thereafter, the processing from steps S37 to S42 shown in the upper half of FIG. 3 is performed.

Note that the operation of the server device 1 when an abnormality occurs in the wireless communication function of the wireless LAN base unit 13 is the same as the content described in [2-2].
Further, the operation of the terminal device 2 when the abnormality of the wired communication function of the wireless LAN slave unit 23 occurs and when the abnormality of the wireless communication function of the wireless LAN slave unit 23 occurs is also described in [2-2]. It is the same as the contents. In this case, in the description of [2-2], “server-side restart unit”, “server PC”, “wireless LAN master device”, and “wireless LAN slave device” are referred to as “terminal-side restart unit”, The description replaced with “terminal PC”, “wireless LAN slave”, and “wireless LAN master” is applied. That is, when the terminal PC 21 outputs a monitoring packet via the wireless LAN slave unit 23 and does not receive a response packet thereto, it outputs a slave unit restart instruction signal to the terminal-side restart unit 25. When the slave unit restart instruction signal is input, the terminal-side restart unit 25 temporarily stops the wireless LAN slave unit 23 and then restarts it.

[2-3] When an abnormality occurs only in the wired communication function of the wireless LAN slave unit Next, an operation of the server device 1 when an abnormality occurs only in the wired communication function of the wireless LAN slave unit 23 will be described. Examples of the abnormality of the wired communication function of the wireless LAN slave device 23 include an abnormality of the wired communication control function of the wireless LAN slave device 23 caused by software and an abnormality of the gateway function.

FIG. 5 is a sequence diagram showing the operation of the server device 1 when an abnormality occurs in the wired communication function of the wireless LAN slave device 23.
In the terminal device 2, as described in [2-2], the slave unit restart instruction signal is input to the terminal side restart unit 25, and the terminal side restart unit 25 temporarily stops the wireless LAN slave unit 23. Then restart.

  Specifically, the terminal-side restart unit 25 performs a supply stop process (step S137). In this supply stop process, the terminal-side switch control unit 251 stops the power supply from the server-side power supply unit 17 to the wireless LAN slave unit 23 by opening the switch SWba. At this time, the wireless LAN slave unit 23 stops (step S138). In addition, the terminal-side switch control unit 251 sends a timing start signal to the terminal-side timer 252.

On the other hand, in the server apparatus 1, as shown in FIG. 5, the server PC 11 generates a monitoring packet (step S1), and outputs the generated monitoring packet to the wireless LAN base unit 13 (step S2). Thereafter, the server PC11, due internal timer, and starts counting the elapsed time after monitoring packet output _{T 1} (step S3). Further, as described above, the server PC 11 repeats outputting the monitoring packet at a constant cycle Ts (steps S31 and S33).

  While the wireless LAN slave device 23 is stopped, the wireless LAN slave device 23 does not transmit a response packet to the monitoring packet (steps S2 and S31) output from the server PC 11 to the own device. Therefore, the server PC 11 does not receive a response packet.

Thereafter, when the timing start signal is input from the terminal-side switch control unit 251, the terminal-side timer 252 starts counting the stop time in which the switch SWba is in an open state (step S139).
When the stop time to be counted reaches the required stop time T ₀ , the terminal-side timer 252 ends the stop time counting (step S140). Then, the terminal-side timer 252 sends a notification signal notifying that the stop time to be counted has reached the required stop time T ₀ to the terminal-side restart unit 25.

  The terminal-side restart unit 25 performs a supply restart process for restarting power supply to the wireless LAN slave unit (step S141). That is, when the terminal-side switch control unit 251 receives the notification signal from the terminal-side timer 252 and closes the switch SWba again, the power supply from the terminal-side power supply unit 27 to the wireless LAN slave unit 23 is resumed. The wireless LAN slave unit 23 is automatically restarted by the power supply (step S142).

That is, the terminal-side restart unit 25, when the handset restart instruction signal is inputted, it stops only requires downtime T ₀ power supply from the terminal-side power supply unit 27 to the wireless LAN terminal 23. Thereafter, the terminal-side restart unit 25 starts to supply power to the wireless LAN slave device 23 again.

  Upon receiving the monitoring packet from the wireless LAN base unit 13 after restarting (step S34), the wireless LAN handset 23 generates a response packet (step S5), and transmits the generated response packet to the wireless LAN base unit 13. (Step S6).

Server PC11 receives the response packet from the wireless LAN base unit 13 (step S7), and terminates the counting of the elapsed time _{T 1} by the built-in timer (step S8). The case shown in FIG. 5, the elapsed time T ₂₁ after monitoring packet output is shorter than the reference time Tth. That is, the server PC 11 receives the response packet within the reference time Tth. In this case, the server PC 11 determines that there is no abnormality in the wireless communication functions of the wireless LAN master device 13 and the wireless LAN slave device 23 and the wired communication functions of the server PC 11, wireless LAN master device 13 and the wireless LAN slave device 23. Therefore, the server PC 11 does not output a parent machine restart instruction signal to the server-side restart unit 15. On the other hand, the server-side restart unit 15 continues to supply power to the wireless LAN base unit 13 because the base unit restart instruction signal is not input.

  Thereafter, the server PC 11 repeats outputting the monitoring packet and receiving the response packet.

  FIG. 6 is a time chart showing the operation shown in FIG. 5 based on the time axis. Here, the state of the wireless LAN base unit 13 and the wireless LAN handset 23, the output timing of the monitoring packet and the response packet reception timing of the server PC and the terminal PC, the server side restart unit 15 and the terminal side restart unit 25 The relationship with the operation state of is shown.

6, the abnormality of the wire communication function of the wireless LAN terminal 23 is generated at time t _11, the wireless LAN terminal 23 at time t ₁₆ indicates the case where the restored to a normal state. The circles shown in “Output timing of monitoring packet of server PC” and “Output timing of monitoring packet of terminal PC” indicate the timing at which the server PC 11 and terminal PC 21 output the monitoring packet. Here, a solid line circle indicates a case where a monitoring packet is actually output, and a broken line circle indicates a case where a monitoring packet is not output. The circles shown in “Reception timing of response packet of server PC” and “Reception timing of response packet of terminal PC” indicate that the server PC 11 and the terminal PC 21 receive the response packet in response to the output of the monitoring packet. It shows the timing to be done. Here, a solid line circle indicates a case where a response packet is actually received, and a broken line circle indicates a case where a response packet is not received. In Figure 6, a criterion of abnormality reference time Tth is, for example, twice the period Ts of the output of the monitoring packet, i.e., the server PC11 and the terminal PC21 starts to count the elapsed time _T 1, _{T 2} Is set equal to the time required for receiving the response packet three times.

Server PC11 is the time t ₁₂ after the wire communication abnormality occurs, performs output of the monitoring packet, and starts counting the elapsed time after monitoring packet output T _1. The terminal PC 21 also outputs a monitoring packet at time t ₁₂ after the occurrence of a wired communication abnormality, and starts counting elapsed time T ₁ after the monitoring packet is output.

Server PC11, since the wireless communication function of the wireless LAN terminal 23 is normal, even after the time t ₁₂ periodically receives while the response packet. On the other hand, the terminal PC21, since the abnormality of the wire communication function of the wireless LAN terminal 23 does not receive a response packet, and continues counting the elapsed time T ₂ by internal timer. Then, at time t ₁₄ the elapsed time T ₂ which counts has exceeded the reference time Tth is a criterion of abnormality occurrence, the terminal PC21 outputs the handset restart command signal to the terminal restart unit 25. As a result, the terminal-side restart unit 25 stops the power supply to the wireless LAN slave unit 23. Server PC11, when the wireless LAN terminal 23 at time _{t 14} is stopped, no longer receives the response packet.

Required stop time from the time _{t 14 T 0} elapsed time _{t 15,} the terminal-side restart unit 25 resumes the power supply to the wireless LAN terminal 23. After that, the wireless LAN terminal 23 is restarted at time _{t 16.} At time _{t 17} after the wireless LAN terminal 23 is restored, the server PC11 and terminal PC21 receives a response packet corresponding to the monitoring packet output from each of the terminal PC21 and server PC11.

Here, the elapsed time T ₂₁ (time between time t ₁₃ and time t ₁₇ ) counted by the server PC 11 by the built-in timer is shorter than the reference time Tth that is a criterion for occurrence of abnormality. That is, the server PC 11 receives the response packet from the wireless LAN base device 13 within the reference time Tth. In this case, the server PC 11 does not output a master unit restart instruction signal to the server side restart unit 15. Therefore, the server-side restart unit 15 continues to supply power to the wireless LAN base unit 13.

Note that the operation of the terminal device 2 when an abnormality occurs in the wired communication function of the wireless LAN base unit 13 is the same as the content described in [2-3]. In this case, in the description of [2-3], “server side restart unit”, “server PC”, “wireless LAN base unit”, “wireless LAN slave unit”, “terminal side restart unit” The description replaced with “terminal restart unit”, “terminal PC”, “wireless LAN slave”, “wireless LAN master”, and “server restart unit” is applied. That is, the terminal PC21 is via the wireless LAN terminal 23 outputs a monitoring packet, and starts counting the elapsed time T ₂ by internal timer. Thereafter, the terminal PC ₂₁ receives a response packet to the output monitoring packet when the elapsed time T ₂₁ has elapsed since the start of counting by the built-in timer. Here, since the elapsed time T ₂₁ is shorter than the reference time Tth, the terminal PC 21 does not output the slave unit restart instruction signal to the terminal-side restart unit 25. And the terminal side restart part 25 continues the electric power supply to the wireless LAN subunit | mobile_unit 23. FIG.

[2-4] When an Abnormality in the Wired Communication Function of the Server PC Occurs Next, an operation of the server device 1 when an abnormality occurs only in the wired communication function of the server PC 11 will be described. Examples of the abnormality in the wired communication function of the server PC 11 include an abnormality in the wired communication control function caused by software.

  FIG. 7 is a sequence diagram illustrating the operation of the server device 1 when an abnormality occurs in the wired communication function of the server PC 11. As shown in FIG. 7, the server PC 11 generates a monitoring packet (step S1). Here, since an abnormality has occurred in the wired communication function on the server PC 11 side, the generated monitoring packet is not output to the wireless LAN base unit 13. Thereafter, the server PC 11 starts counting the elapsed time after outputting the monitoring packet by the built-in timer (step S3).

Server PC11 does not receive a response packet, and continues counting the elapsed time T ₁ by the internal timer. Thereafter, when the elapsed time T ₁ for counting passes a reference time Tth is a criterion of abnormality, it stops counting (step S35). Then, the server PC 11 outputs a parent machine restart instruction signal to the server side restart unit 15 (step S36).
After that, the server PC 11 starts counting the standby time by the built-in timer after outputting the base unit restart instruction signal (step S43).

  Thereafter, the processing from steps S37 to S42 shown in the upper half of FIG. 3 is performed, and the wireless LAN base unit 13 is restarted.

After that, the server PC 11 outputs the master unit restart instruction signal to the server-side restart unit 15 and then ends the standby time counting by the built-in timer when the standby time to be counted has passed the necessary standby time Tth2. Step S44). Here, the necessary standby time Tth2 is a time required to wait for the output of the monitoring packet until the wireless LAN base unit 13 is temporarily stopped and then restarted. From the server PC 11, at the stage when the response packet is not received for the first time, it is impossible to determine which of the wireless LAN base unit 13 and the own unit is abnormal. Therefore, the server PC 11 identifies the location where the abnormality has occurred based on whether or not the response packet is received after the wireless LAN base unit 13 is temporarily stopped and then restarted.
The required standby time Tth2 is, for example, a time longer than the time required for the wireless LAN base unit 13 to restart after the server PC 11 outputs the base unit restart instruction signal to the server-side restart unit 15. Is set.

  After the necessary waiting time Tth2 has elapsed, the server PC 11 again generates a monitoring packet (step S45). Since an abnormality has occurred in the wired communication function on the server PC 11 side, the generated monitoring packet is not output to the wireless LAN base unit 13. Thereafter, the server PC 11 starts counting the elapsed time after outputting the monitoring packet again (step S46).

Server PC11 does not receive a response packet, and continues counting the elapsed time T ₁ by the internal timer. Thereafter, when the elapsed time T ₁ for counting passes a reference time Tth is a criterion of abnormality, it stops counting (step S47). Then, the server PC 11 outputs a PC restart instruction signal to the server side restart unit 15 (step S48).

  On the other hand, when the PC restart instruction signal is input, the server side restart unit 15 performs a supply stop process (step S49). Specifically, the server-side switch control unit 151 stops the power supply from the server-side power supply unit 17 to the server PC 11 by opening the switch SWab. At this time, the server PC 11 stops (step S50). In addition, the server-side switch control unit 151 sends a time measurement start signal to the server-side timer 152.

When the server-side timer 152 receives a timing start signal from the server-side switch control unit 151, the server-side timer 152 starts counting the stop time during which the switch SWab is open (step S51).
Server-side timer 152, the count is stopped time reaches the required stopping time T _0, and ends the counting of the stop time (step S52). Here, the “necessary stop time” is set, for example, based on the time from immediately after the power supply to the server PC 11 is stopped until the server PC 11 is completely stopped. Then, the server-side timer 152 sends a notification signal notifying that the stop time to be counted has reached the required stop time T ₀ to the server-side switch control unit 151.

  Thereafter, a supply restart process is performed (step S53). Specifically, when a notification signal is input from the server-side timer 152, the server-side switch control unit 151 closes the switch SWab again. Thereby, the power supply from the server-side power supply unit 17 to the server PC 11 is resumed, and the server PC 11 is restarted (step S54).

  FIG. 8 is a time chart showing the operation shown in FIG. 7 based on the time axis. Here, the relationship among the state of the server PC 11, the state of the wireless LAN base unit 13, the output timing of the monitoring packet and the response packet reception timing of the server PC, and the operating state of the server-side restart unit 15 is shown.

FIG. 8 shows a case where an abnormality occurs in the wired communication function of the server PC 11 at time t ₂₁ and the server PC 11 is normally restored at time t ₂₉ . The circles shown at “Server PC monitoring packet output timing” indicate the timing at which the server PC 11 should output the monitoring packet. Here, a solid line circle indicates a case where a monitoring packet is actually output, and a broken line circle indicates a case where a monitoring packet is not output. Further, the circle shown at “Reception timing of server PC response packet” indicates the timing at which server PC 11 should receive the response packet in response to the output of the monitoring packet. Here, a solid line circle indicates a case where a response packet is actually received, and a broken line circle indicates a case where a response packet is not received. In Figure 8, the criterion is a reference time Tth abnormal occurrence, for example, twice the period Ts of the output of the monitoring packet, i.e., 3 times the response packet from the server PC11 starts to count the elapsed time T ₁ It is assumed that it is set equal to the time required for reception.

Server PC11 is the time t ₂₂ after the wire communication abnormality occurs, performs output of the monitoring packet, and starts counting the elapsed time after monitoring packet output T _1. Here, the output of the monitoring packet means that the operation of outputting the monitoring packet is performed. In practice, the monitoring packet is not output due to an abnormality in the wired communication function of the server PC 11.

Next, the server PC11 does not receive a response packet, and continues counting the elapsed time T _1. Then, the server PC 11 outputs a base unit restart instruction signal to the server side restart unit 15 at time t ₂₃ when the elapsed time T ₁ reaches the reference time Tth. The server-side restart unit 15 stops the power supply to the wireless LAN base unit 13 when the base unit restart instruction signal is input. At this time, the server PC 11 starts counting time by the built-in timer.

At time t ₂₄ when the necessary stop time T _{0 has} elapsed from time t ₂₃ , the server-side restart unit 15 resumes power supply to the wireless LAN base unit 13. After that, the wireless LAN master unit 13 is restarted at time _{t 25.} At this time, since the wired communication function of the server PC 11 has not yet been restored normally, the state in which the server PC 11 cannot receive the response packet continues.

At time _{t 26} has elapsed required waiting time Tth2 from the time _{t 23,} the server PC11 performs output of the monitoring packet, and starts counting the elapsed time after monitoring packet output _{T 1.}

Next, the server PC11 does not receive a response packet, and continues counting the elapsed time T _1. Then, the server PC 11 outputs a PC restart instruction signal to the server restart unit 15 at time t ₂₇ when the elapsed time T ₁ reaches the reference time Tth. The server-side restart unit 15 stops power supply to the server PC 11 when the PC restart instruction signal is input.

At time t ₂₈ when the necessary stop time T ₀ has elapsed from time t ₂₇ , the server-side restart unit 15 resumes power supply to the server PC 11. After that, the wireless LAN master unit 13 is restarted at time _{t 29.} At this time, the wired communication function of the server PC 11 is restored to a normal state. At time _{t 30} after the server PC11 is restored, the server PC11 receives the response packet.
Thereafter, the server PC 11 repeats outputting the monitoring packet and receiving a response packet in response thereto.

  Note that the operation of the terminal device 2 when the abnormality of the wired communication function of the terminal PC 21 occurs is the same as the description in [2-4]. In this case, in the description of [2-4], “server-side restart unit”, “server PC”, and “wireless LAN master” are respectively referred to as “terminal-side restart unit”, “terminal PC”, and “wireless”. The description replaced with “LAN slave” is applied. That is, when the terminal PC 21 outputs a monitoring packet to the wireless LAN slave unit 23 and does not receive a response packet thereto, it first outputs a slave unit restart instruction signal to the terminal-side restart unit 25. Thereafter, the terminal PC 21 outputs a monitoring packet to the wireless LAN slave unit 23 again, and outputs a PC restart instruction signal to the terminal-side restart unit 25 when no response packet is received. When the PC restart instruction signal is input, the terminal-side restart unit 25 temporarily stops the terminal PC 21 and then restarts it.

As described above, for example, it is assumed that an abnormality has occurred in the wireless LAN master device 13 or the wireless LAN slave device 23. In this case, the server PC 11 does not receive a response packet within the reference time Tth after outputting the monitoring packet.
On the other hand, according to the wireless communication control system according to the present embodiment, the server PC 11 (terminal PC 21) automatically instructs the server-side restart unit 15 (terminal-side restart unit 25) to restart the master unit. A signal (slave unit restart instruction signal) is output. Then, the server side restart unit 15 (terminal side restart unit 25) temporarily stops the wireless LAN base unit 13 (wireless LAN slave unit 23) and then restarts it. As a result, if an abnormality that can be recovered simply by restarting the wireless LAN master device 13 (wireless LAN slave device 23) has occurred, the wireless LAN master device 13 (wireless LAN slave device 23) is automatically made normal. Can be recovered. Accordingly, if an abnormality that can be recovered by simply restarting the wireless LAN base unit 13 (wireless LAN handset 23) has occurred, no action is required for recovery by the administrator. Can be reduced.
In addition, since the wireless LAN master device 13 (wireless LAN slave device 23) automatically recovers to a normal state without waiting for the recovery work by the administrator, the MTTR (wireless LAN slave device 23) of the wireless LAN master device 13 (wireless LAN slave device 23) is restored. Average repair time) can be reduced. Therefore, there is an advantage that the availability of the wireless communication control system is improved.

  Further, according to the wireless communication control system according to the present embodiment, when only the wired communication function of the wireless LAN slave unit 23 is abnormal, the server PC 11 sends a response packet within the reference time Tth after outputting the monitoring packet. Since it is received, the master unit restart instruction signal is not output to the server side restart unit 15. As a result, it is possible to suppress the server-side restart unit 15 from temporarily stopping the wireless LAN base unit 13 and then restarting it, so that the availability of the server device 1 can be improved.

  Furthermore, according to the wireless communication control system according to the present embodiment, the server-side restart unit 15 has the server-side timer 152. Thereby, the server PC 11 does not need to measure the stop time in which the switch SWaa is in the open state. Therefore, the processing load on the server PC 11 can be reduced. Also, the elapsed time can be measured even when the server PC 11 is stopped after the switch SWab is in the open state.

  Moreover, according to the radio | wireless communication control system which concerns on this Embodiment, the server side restart part 15 is restarted after stopping power supply also about server PC11. Accordingly, there is an advantage that even when an abnormality caused by the server PC 11 occurs, it can be automatically recovered.

  Furthermore, according to the wireless communication control system according to the present embodiment, the server-side restart unit 15 does not receive the reference time Tth response packet after the wireless LAN base unit 13 is temporarily stopped and restarted. In this case, the server PC 11 is temporarily stopped and then restarted for the first time. Thus, for example, when there is no abnormality in the server PC 11, it is possible to suppress the server PC 11 from being restarted after being stopped in vain, so that the availability of the server PC 11 can be improved.

[Modification]
(1) In the embodiment, when the server PC 11 outputs the first monitoring packet addressed to the wireless LAN base unit 13, while the wireless LAN base unit 13 receives the first monitoring packet from the server PC 11, the server PC 11 A first response packet addressed to the PC 11 may be transmitted.
In the embodiment, when the terminal PC 21 outputs a second monitoring packet addressed to the wireless LAN slave device 23 and the wireless LAN slave device 23 receives the second monitoring packet from the terminal PC 21, the address addressed to the terminal CP 21 is addressed. The second response packet may be transmitted.

For example, it is assumed that the server PC 11 does not receive a response packet.
In this case, according to this configuration, the server PC 11 can further determine whether or not a response packet from the wireless LAN base unit 13 has been received. Accordingly, in the server PC 11, the location where the communication abnormality occurs is the wireless communication function of the wireless LAN slave unit 23, or the wireless LAN master unit 13 alone or both of the wireless LAN master unit 13 and the wireless LAN slave unit 23. Can be determined.

For example, it is assumed that the terminal PC 21 does not receive a response packet.
In this case, according to this configuration, the terminal PC 21 can further determine whether or not a response packet from the wireless LAN base unit 13 has been received. Therefore, in the terminal PC 21, the location where the communication abnormality occurs is the wireless communication function of the wireless LAN base unit 13, or only the wireless LAN handset 23 or both of the wireless LAN handset 23 and the wireless LAN base unit 13. Can be determined.

(2) The server PC 11 may output a monitoring packet addressed to the terminal PC 21. On the other hand, when the terminal PC 21 receives the monitoring packet from the server PC 11, a response packet addressed to the server PC 11 may be output.
Alternatively, the terminal PC21 may output a monitoring packet addressed to the server PC11. On the other hand, when the server PC11 receives the monitoring packet from the terminal PC21, a response packet addressed to the terminal PC21 may be output.
Here, the monitoring packet and the response packet are transmitted via the wireless LAN master device 13 and the wireless LAN slave device 23.

  According to this configuration, since the wireless LAN base unit 13 and the wireless LAN slave unit 23 do not have to have a function of generating a response packet, the configuration of the wireless LAN base unit 13 and the wireless LAN slave unit 23 can be simplified. Can be planned.

(3) In the embodiment, instead of the switch control unit 151, the server PC 11 may directly open the switch SWaa and then close the switch SWaa after the necessary stop time has elapsed. In this case, the built-in timer of the server PC 11 may count the stop time during which the power supply to the wireless LAN base unit 13 is stopped.
In place of the switch control unit 251, the terminal PC21 may also be after the direct switch SWba opened, the switch SWba after a required stop time _{T 0} in the closed state. In this case, the built-in timer of the terminal PC 21 may measure the stop time during which the power supply to the wireless LAN slave device 23 is stopped.

  According to this configuration, the server PC 11 or the terminal PC 21 can control the power supply to the wireless LAN master device 13 and the wireless LAN slave device 23. Accordingly, it is not necessary to provide a switch control unit for controlling opening / closing of the switches SWaa and SWba in the server-side restart unit or the terminal-side restart unit. Therefore, it is possible to simplify the configuration of the server-side restart unit or the terminal-side restart unit.

(4) The power supply to the server PC 11 may be stopped at the same time as the power supply to the wireless LAN base unit 13 is stopped in the supply stop process in step S37 of FIG. In the supply restart process in step S41 of FIG. 3, the power supply to the wireless LAN base unit 13 may be restarted and the power supply to the server PC 11 may be restarted.

  According to this configuration, for example, as described with reference to FIG. 7, the server PC 11 temporarily stops the wireless LAN base unit 13 and then restarts it, and then stops and restarts the own device. Thus, the processing in the server PC 11 is simplified. That is, the server PC 11 does not need to measure the elapsed time after performing the supply stop process for the wireless LAN base unit 13. As a result, the processing load on the server PC 11 can be reduced.

(5) In the embodiment, the communication unit switch control unit and the processing unit switch control unit may be separate. In the embodiment, the communication unit timing unit and the processing unit timing unit may be separate.

(6) In the embodiment, the example in which the terminal device 2 is one has been described, but the number of the terminal devices 2 is not limited to one, and may be plural. Further, the number of server devices 1 is not limited to one, and may be plural.
In the configuration including a plurality of terminal devices, the server PC has a table in which the identification information of each of the wireless LAN slave devices of the plurality of terminal devices is registered in the memory, and the wireless LAN slave device in which the identification information is registered in the table A monitoring packet may be output to the destination.
In the configuration including a plurality of server devices, the terminal PC has a table in which the identification information of each of the wireless LAN slave devices of the plurality of server devices is registered in the memory, and the wireless LAN in which the identification information is registered in the table. A monitoring packet may be output to the parent device.

  Alternatively, the server PC may output monitoring packets that are broadcast to a plurality of wireless LAN slave units. In this case, identification information of the server PC may be included in the monitoring packet. Further, the terminal PC may output a monitoring packet that is broadcast to a plurality of wireless LAN slave units. In this case, the identification information of the terminal PC may be included in the monitoring packet.

(7) In the configuration in which the server PC described in (6) holds the table, the server PC may delete the identification information of the wireless LAN slave device that does not return a response packet to the monitoring packet from the table. Good. Further, in the configuration in which the terminal PC described in (6) holds the table, the terminal PC may delete from the table the identification information of the wireless LAN base unit that does not return a response packet to the monitoring packet. .

  According to this configuration, useless transmission of the monitoring packet to the wireless LAN slave device or the wireless LAN master device in which an abnormality has occurred is reduced. Communication congestion can be suppressed.

(8) In the configuration described in (6), the response packet may include identification information of the wireless LAN parent device or the wireless LAN child device.

  According to this configuration, it is possible to distinguish between a plurality of wireless LAN master devices or a plurality of wireless LAN slave devices that are transmission sources of response packets. Therefore, for example, if the response packet includes information indicating the operation state of each of the wireless LAN master device or the wireless LAN slave device, the operation status of the plurality of wireless LAN master devices or the plurality of wireless LAN slave devices is indicated in the server PC or the terminal PC. The information shown can be aggregated separately.

(9) In the embodiment, instead of using the wireless LAN master device 13 and the wireless LAN slave device 23, wired communication may be performed using a wired LAN master device and a wired LAN slave device.

(10) In the embodiment, the server PC 11 and the terminal PC 21 may repeat the output of the monitoring packet at a timing independent from each other without being synchronized.

1: Server device 2: Terminal device 11: Server PC (information processing unit)
13: Wireless LAN base unit (communication unit)
15: Server-side restart unit (restart unit)
17: Server-side power supply (power supply)
21: Terminal PC (information processing unit)
23: Wireless LAN cordless handset (communication unit)
25: Terminal-side restart unit (restart unit)
27: Terminal-side power supply unit (power supply unit)

Claims (7)

An information processing unit for outputting a monitoring packet;
A communication unit that transmits the monitoring packet received from the information processing unit;
A restarting unit that restarts after temporarily stopping the communication unit,
Two communication control devices
When the information processing unit or the communication unit included in one of the two communication control devices receives the monitoring packet from the other of the two communication control devices, the information processing unit or the communication unit transmits a response packet destined for the other,
When the information processing unit included in the one side does not receive the response packet within a reference time after transmitting the monitoring packet, the information processing unit included in the one side temporarily stops the communication unit and restarts the communication unit. When outputting the communication unit restart instruction signal instructing to start and receiving the response packet within the reference time, the restart unit included in the one does not output the communication unit restart instruction signal,
The restart unit included in the one is based on the communication unit restart instruction signal output from the information processing unit, and restarts the communication unit included in the one after temporarily stopping.
Communication control system. The monitoring packet transmitted by the information processing unit included in the one destination is the communication unit included in the other side,
When the communication unit included in the other side receives the monitoring packet from the one side, the communication unit transmits a response packet addressed to the information processing unit included in the one side.
The communication control system according to claim 1. The communication control device further includes a power supply unit that supplies power to the communication unit,
The restarting unit
Based on the communication unit restart instruction signal, after stopping the power supply from the power supply unit to the communication unit for a required stop time that is a preset time, the power supply to the communication unit is started again.
The communication control system according to claim 1. The communication unit is supplied with power from the power supply unit via a communication unit power line,
The restarting unit
A communication unit switch connected to the communication unit power line;
When the communication unit switch is in an open state, the communication unit timing unit counts the stop time during which the power supply to the communication unit is stopped,
When the communication unit restart instruction signal is input from the information processing unit, the communication unit switch is opened, and then the stop time has reached the required stop time by the communication unit timing unit. When notified, it has a communication unit switch control unit for closing the communication unit switch again,
The communication control system according to claim 3. The power supply unit further supplies power to the information processing unit,
The restarting unit further includes:
When the processing unit restart instruction signal for instructing the restarting unit to stop and restart the information processing unit is input to the restarting unit, it is necessary to stop power supply from the power source unit to the information processing unit. After stopping only, the power supply to the information processing unit is started again, and when the processing unit restart instruction signal is not input, the power supply from the power supply unit to the information processing unit is continued.
The communication control system according to claim 3 or 4. The information processing unit is supplied with power from the power supply unit via a processing unit power line,
The restarting unit
A processing unit switch connected to the processing unit power line;
When the processing unit switch is in an open state, a processing unit timing unit that counts a stop time during which power supply to the information processing unit is stopped, and
When the processing unit restart instruction signal is input from the information processing unit, the processing unit switch is opened, and then the stop time has reached the required stop time by the processing unit timing unit. When notified, it has a processing unit switch control unit for closing the processing unit switch again,
The communication control system according to claim 5. A communication unit comprising: an information processing unit that outputs a monitoring packet; a communication unit that transmits the monitoring packet received from the information processing unit; and a restarting unit that temporarily stops the communication unit and then restarts the communication unit. A communication control method using two control devices,
The information processing unit or the communication unit included in one of the two communication control devices, when receiving the monitoring packet from the other of the two communication control devices, transmits a response packet destined for the other; ,
If the information processing unit included in the one does not receive the response packet within a reference time after transmitting the monitoring packet, the restart unit included in the one temporarily stops the communication unit and then restarts the communication. When outputting the communication unit restart instruction signal instructing to start and receiving the response packet within the reference time, the step of not outputting the communication unit restart instruction signal to the restart unit included in the one,
The restarting unit possessed by the one side includes, based on the communication unit restarting instruction signal output from the information processing unit, the communication unit possessed by the one side being temporarily stopped and then restarted.
Communication control method.

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