JP7288662B2 - Fault monitoring recovery system, its method, and its program - Google Patents

Description

Application of Patent Law Article 30, Paragraph 2 On April 1, 2019, Meikyo Electric Co., Ltd. acquired Meikyo Electric Co. , Ltd. Released to Design Teams, FREEMAN SIGN & ELECTRICAL, TREASURE ISLAND, and CALIFORNIA HIGHLANDS by email. Published at DIGITAL SIGNAGE EXPO 2019 held at Las Vegas Convention Center (3150 Paradise Rd, Las Vegas, NV 89109) from March 27 to 28, 2019.

The present invention relates to a fault monitoring and recovery system, a fault monitoring and recovery method, and a fault monitoring and recovery program, particularly comprising a server device on which an application operates and an interlocking device that operates on the basis of information provided from the server device. The present invention relates to a fault monitoring and recovery system, a fault monitoring and recovery method, and a fault monitoring and recovery program for receiving a heartbeat signal for checking the operation of a server device and checking the operation status of the server device.

Conventionally, services using the Internet often require 24-hour operation. For example, a web server that delivers websites to the Internet, a business server that manages business data within a company, a mail server that sends and receives emails, etc. These servers need to continue to provide services for the business of the company. There is

In addition, surveillance camera systems that transmit video signals captured for the purpose of crime prevention and disaster prevention, and digital displays that display advertisements such as images and text on displays and projectors installed outdoors, in stores, in public places, etc. A signage system is also a service that needs to be continuously provided.

As described above, services that need to be continuously provided need to be continuously monitored from the outside to see if servers, computers, network systems, etc. are operating normally.

Therefore, there are known methods of monitoring servers, computers, network systems, etc., and in the event of a failure, notifying the administrator of the abnormality, or of restoring the system (for example, Patent Document 1 reference).

In the communication failure recovery method disclosed in Patent Document 1, in order to detect an abnormality in two synchronized devices, there is no need to provide an abnormality detection means for monitoring the two devices. This is a communication failure recovery method capable of recovering normal communication even if a failure occurs in

As a specific example, a communication failure recovery method when some failure occurs in a signal transmitted from one device 10 to the other device 40 of two synchronized devices and the device 40 detects the failure. will be described.

First, line synchronization is established between the device 10 and the device 40 . The device 10 then transmits a signal including the life-and-death monitoring signal to the device 40 . In response to the signal, device 40 transmits a signal to device 10 that includes a life-and-death signal. In this manner, communication is performed between the device 10 and the device 40 facing each other.

Then, the device 10 transmits the next signal including the life-and-death monitoring signal to the device 40. At this time, if some kind of failure occurs in either the device 10 or the device 40, the device 40 detects the life-and-death monitoring from the received signal. Suppose no signal was detected.

The device 40 that cannot detect the life-and-death monitoring signal from the signal transmitted by the device 10 transmits a signal including the abnormality detection signal to the device 10, and the device 40 restarts itself. Then, the device 10 that detects the abnormality detection signal from the signal transmitted by the device 40 restarts the device 10 by itself.

After that, line synchronization is established again between the restarted device 10 and the device 40, the device 10 transmits a signal including a life-and-death monitoring signal to the device 40, and in response to the signal, the device 40 , the operation of transmitting a signal including a life-and-death monitoring signal to the device 10 is repeated.

As described above, in the communication failure recovery method disclosed in Patent Document 1, the device 10 that cannot detect the life-and-death monitoring signal from the received signal restarts itself after transmitting the signal including the abnormality detection signal to the device 40. However, since the device 40 restarts itself when an abnormality detection signal is detected from the received signal, the device on the transmitting side does not need to be provided with an abnormality detection means for monitoring both of the two synchronized devices for abnormality detection. , or the device on the receiving side, normal communication can be restored.

JP 2017-183905 A

In the communication failure recovery method disclosed in Patent Document 1, when a life-and-death monitoring signal transmitted from one device cannot be detected, the other device determines that a failure has occurred in the other device. It monitors the operating status of each device.

Specifically, in the case of computers, life-and-death monitoring signals are a mechanism for transmitting data and signals at regular intervals in order to inform each other that devices connected to the network are operating normally. Heartbeat is known.

By enabling this heartbeat setting on your computer, you can send signals to each other at predetermined intervals between devices connected to the network. Therefore, if signal communication is possible at regular intervals, it can be confirmed that the device on the other end is operating normally. can be determined to have occurred.

However, failures are not limited to devices. For example, if only the application software installed on the computer is abnormal, and the operating system installed on the computer is not abnormal, the operating system is working normally, and the computer can send heartbeat signals normally. I am able to send.

For this reason, the devices connected to the network receive the heartbeat signal even though the application software installed on the computer is malfunctioning, so they assume that the computer is operating normally. You will have to judge.

As described above, if the presence or absence of a failure is determined based only on a life-and-death monitoring signal such as a heartbeat signal emitted by the computer, there is a problem that failure occurring in the application software installed in the computer cannot be detected.

As described above, when a failure occurs in application software installed in a computer, it is possible to restart the application software to restore normal operation of the application software. However, in some cases the application software cannot be easily restarted.

For example, in a digital signage system that displays advertisements such as images and text using displays and projectors installed outdoors, in stores, in public places, etc., it is possible to play video and audio files such as images on a computer. A media player is used as application software that can

When a failure occurs in this media player, there is a problem that moving images such as images are displayed in a stopped state on displays or projectors installed outdoors, at stores, in public places, and the like.

Furthermore, if the media player fails and is easily stopped and restarted, the desktop screen on the computer will be displayed on the display, etc., and unnecessary files and personal information will be exposed to the public. There was a fear that it would be published on the site.

The present invention has been made in view of these points, and provides a fault monitoring and recovery system, a fault monitoring and recovery method, and a fault monitoring and recovery method capable of detecting a fault occurring in application software incorporated in an apparatus and safely recovering from the fault. and to provide a fault monitoring recovery program.

In order to solve the above problem, the present invention includes a server device that runs an application and an interlocking device that operates based on information provided by the server device, and sends a heartbeat signal for confirming the operation of the server device. heartbeat stopping means for detecting an abnormality in the application and stopping the heartbeat signal; Application monitoring means comprising server device termination means for terminating a device; server power control means for detecting termination of the server device and controlling cutoff and resupply of power supplied to the server device; and the heartbeat signal. and power control means including server device remote activation means for activating the server device from a network on which communication is performed.

Accordingly, in the application monitoring means, the heartbeat stop means detects an abnormality in the application and stops the heartbeat signal, the server device termination means detects the stoppage of the heartbeat signal and terminates the server device, and the power is turned off. In the control means, the server power control means detects the termination of the server device, cuts off the power supplied to the server device and resupplies it, and the server device remote activation means causes the server device to start the server from the network where the communication of the heartbeat signal is performed. Start the device.

Further, in the present invention, a server device on which an application operates and an interlocking device that operates on the basis of information provided by the server device are provided, and a heartbeat signal for confirming the operation of the server device is received to receive the server device. In a failure recovery method for checking the operation status of a device, application monitoring means detects an abnormality in the application and stops the heartbeat signal, and server device termination means detects the heartbeat signal. a step of detecting a stop of a signal and terminating the server device, wherein the server power control means detects the termination of the server device and cuts off and resupplies power to the server device. and a step in which a server apparatus remote activation means activates the server apparatus from a network on which communication of the heartbeat signal is performed.

Accordingly, in the application monitoring means, the heartbeat stop means detects an abnormality in the application and stops the heartbeat signal, the server device termination means detects the stoppage of the heartbeat signal and terminates the server device, and the power is turned off. In the control means, the server power control means detects the termination of the server device, cuts off the power supplied to the server device and resupplies it, and the server device remote activation means causes the server device to start the server from the network where the communication of the heartbeat signal is performed. Start the device.

Further, in the present invention, a server device on which an application operates and an interlocking device that operates on the basis of information provided by the server device are provided, and a heartbeat signal for confirming the operation of the server device is received to receive the server device. In a failure recovery program for checking the operation status of a device, heartbeat stopping means for detecting an abnormality in the application and stopping the heartbeat signal, and detecting the stoppage of the heartbeat signal and stopping the server device. server device termination means for termination; server power control means for detecting termination of the server device and controlling cutoff and resupply of power supplied to the server device; and communication of the heartbeat signal. Provided is a fault recovery program characterized by functioning as power control means including server device remote activation means for activating the server device from a network where the failure recovery program is performed.

Accordingly, in the application monitoring means, the heartbeat stop means detects an abnormality in the application and stops the heartbeat signal, the server device termination means detects the stoppage of the heartbeat signal and terminates the server device, and the power is turned off. In the control means, the server power control means detects the termination of the server device, cuts off the power supplied to the server device and resupplies it, and the server device remote activation means causes the server device to start the server from the network where the communication of the heartbeat signal is performed. Start the device.

According to the fault monitoring and recovery system, its method, and its program of the present invention, the heartbeat stopping means of the application monitoring means detects an abnormality in the application and stops the heartbeat signal, and the server device terminating means stops the heartbeat signal. The server power control means detects the stop of the beat signal and terminates the server device, and the power control means cuts off and resupplies the power to the server device upon detecting the termination of the server device, and remotely activates the server device. Since the means activates the server device from the network through which the heartbeat signal is communicated, it is possible to detect a failure occurring in the application software installed in the device and safely recover from the failure.

1 is a block diagram showing the overall concept of a fault monitoring and recovery system according to a first embodiment; FIG. It is a block diagram which shows the detail of a monitoring recovery part. 3 is a block diagram showing details of a control unit; FIG. 3 is a block diagram showing details of a power control unit; FIG. A sequence flowchart showing the operation of each device between the server, power control device, and video display device, from the state where each device is operating normally until the video application in the server fails, and the failure occurs until recovery. be. FIG. 10 is a flowchart showing server processing from when a heartbeat signal is transmitted to the power control device to when a failure of the video application is detected and when the heartbeat signal is stopped; FIG. 9 is a flowchart showing processing of the power supply control device from when a video application failure occurs to when the video display device is restarted; It is a block diagram which shows the detail of a monitoring recovery part. A sequence flowchart showing the operation of each device between the server, power control device, and video display device, from the state where each device is operating normally until the video application in the server fails, and the failure occurs until recovery. be. 10 is a flowchart showing processing of the power supply control device from when a failure of the video application occurs until the video display device is restarted; It is a block diagram which shows the detail of a monitoring recovery part. A sequence flowchart showing the operation of each device between the server, power control device, and video display device, from the state where each device is operating normally until the video application in the server fails, and the failure occurs until recovery. be. FIG. 10 is a flowchart showing server processing from when a heartbeat signal is transmitted to the power control device to when a failure of the video application is detected and when the heartbeat signal is stopped; FIG. 10 is a flowchart showing processing of the power supply control device from when a failure of the video application occurs until the video display device is restarted;

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[First Embodiment]
FIG. 1 is a block diagram showing the concept of the entire fault monitoring and recovery system according to the first embodiment.

The failure monitoring and recovery system of the present embodiment is a system incorporated in a digital signage system that displays advertisements such as images and characters on displays installed outdoors, in stores, in public places, etc. An example of monitoring a failure that occurs in the system and recovering from the failure that has occurred will be described.

As shown in FIG. 1, a digital signage system 1000 incorporating a failure monitoring and recovery system includes a server device 100, a video display device 200, and a power control device 300. FIG.

Also, the server device 100 and the power control device 300 are connected to the network 400 via a network cable, and the server device 100 and the power control device 300 can communicate via the network 400 .

The server device 100 is a computer for providing video to the video display device 200 connected via a display cable. An output unit 150 is provided. The server device 100 is also connected to the power control device 300 and operates by being supplied with power by the connected power control device 300 .

The communication unit 110 is connected to the server control unit 120, and is a communication device having a network interface such as a wired LAN (Local Area Network) or a wireless LAN. It can be transmitted to the power control device 300 connected to the network 400 . It can also receive data transmitted from the power control device 300 connected to the network 400 and transmit it to the server control unit 120 .

The server control unit 120 is connected to the communication unit 110 and the monitoring recovery unit 130 and is an operating system for providing basic control of the server device 100 as a whole. The server control unit 120 includes a storage medium (not shown) for storing a program, and an arithmetic device such as a CPU (Central Processing Unit) (not shown) for reading the program into a memory or the like and executing instructions. It can run any kind of application software.

Also, the server control unit 120 can set an operation called a heartbeat to transmit short data to the power control device 300 at predetermined intervals. The server control unit 120 transmits short data at regular intervals to the power control device 300 via the communication unit 110 and the network 400 without interrupting the heartbeat signal. This allows the power control device 300 to detect the failure of the server device 100 when the heartbeat signal of the server device 100 is interrupted due to some failure.

The monitoring recovery unit 130 is connected to the server control unit 120 and the video application 140, monitors the operation status of the video application 140 installed in the server device 100, and recovers from the failure when a failure occurs. application software.

The video application 140 is connected to the monitoring recovery unit 130 and the display information output unit 150, and is application software for reproducing data such as images, video, and audio on the server device 100. FIG.

The video application 140 reads data related to images, videos, audio, etc., stored in a storage medium or the like of the server control unit 120, and outputs the images, videos, and audio to the video display device 200 via the display information output unit 150 connected thereto. etc. is output and displayed.

Display information output unit 150 is connected to video application 140 and video display device 200, and outputs video, audio, and the like, such as HDMI (registered trademark) (High-Definition Multimedia Interface) and DVI (Digital Visual Interface), as digital signals. It is a communication interface that transmits video and audio reproduced by the video application 140 to the video display device 200 .

The video display device 200 is a device for displaying video output by the server device 100 and is connected to the server device 100 via a display cable. The image display device 200 may be, for example, a cathode ray tube, a liquid crystal display, a plasma display, an organic electroluminescence display, or the like.

In addition, a projector or the like that displays an image or video by projecting it onto a large screen or wall may be used. Further, the video display device 200 is connected to the power control device 300, and operates by being supplied with power by the connected power control device 300. FIG.

The power control device 300 is a device capable of supplying power obtained from an external power source P such as a connected commercial power source to connected devices. An information storage unit 340 , a first power output unit 350 and a second power output unit 360 are provided.

The power supply unit 310 is connected to an external power supply P such as a commercial power supply and a power supply control unit 320. The server apparatus 100 is connected to the power supply control unit 300 via a first power output unit 350 and a second power output unit 360. and power can be supplied to the video display device 200 .

The power control unit 320 is connected to the power supply unit 310, the communication unit 330, the information storage unit 340, the first power output unit 350, and the second power output unit 360, and is used to control the operation of each unit provided. It is.

Also, the power control unit 320 can determine whether the server device 100 connected via the network 400 is in operation.
Specifically, as described above, the server device 100 transmits short data at regular intervals without interrupting the heartbeat signal via the network 400 . The power control unit 320 can detect a failure of the server device 100 when this heartbeat is interrupted due to some failure or the like.

Communication unit 330 is connected to power control unit 320 , and is a communication device having a network interface such as a wired LAN or wireless LAN, and transmits data sent from power control unit 320 to network 400 . can be transmitted to the server device 100. Also, it can receive data transmitted from the server device 100 connected to the network 400 and transmit it to the power control unit 320 .

The information storage unit 340 is connected to the power control unit 320, and stores the address information of the server device 100 connected via the network 400 and the first power output unit 350, and the power control unit 320 controls the power control device 300. Information necessary for this is stored.

The first power supply output unit 350 is connected to the power control unit 320, the power input by the power supply unit 310 is controlled by the power control unit 320, and the power controlled by the power control unit 320 is connected from the outside. It is for outputting to the server device 100 .

Specifically, the first power supply output unit 350 is a plug receiver for a wiring plug-in connector, and when the plug of the wiring plug-in connector provided in the server device 100 to be connected is inserted, , power is supplied to the server device 100 via the power control device 300 .

The second power supply output unit 360 is connected to the power control unit 320, the power input by the power supply unit 310 is controlled by the power control unit 320, and the power controlled by the power control unit 320 is connected from the outside. It is for outputting to the video display device 200 .

Specifically, the second power supply output unit 360 is a plug receiver for a wiring plug-in connector, into which the plug of the wiring plug-in connector included in the video display device 200 to be connected is inserted. , power is supplied to the video display device 200 via the power control device 300 .

Here, first, an outline of a recovery method when a failure occurs in the digital signage system 1000 incorporating the failure monitoring recovery system will be described.
The server device 100 outputs images and sounds stored in advance to the image display device 200 by the installed image application 140 . Also, the monitoring recovery unit 130 constantly monitors the operation status of the video application 140 .

Now, consider a case where the server device 100 fails. First of all, if a failure occurs in the server control unit 120, that is, if the server control unit 120 that controls the server device 100 freezes and stops working, the heartbeat that is operated by the server control unit 120 also stops. It will be.

In this case, the power supply control device 300 can detect that a failure has occurred in the server device 100 by interrupting the heartbeat signal transmitted by the server device 100. Then, a magic packet such as WoL (Wake-on-LAN) that can re-supply power to the server device 100 and remotely turn on the power of the server device 100 connected to the network 400 via the network 400 to reboot. As a result, the failure occurring in the server device 100 can be recovered.

Next, consider a case where no failure occurs in the server control unit 120 and only the video application 140 fails. Specifically, since no failure has occurred in the server control unit 120 , the server device 100 is operating without any problems, and the server control unit 120 sends a heartbeat to the power control device 300 via the communication unit 110 and the network 400 . Short data can be transmitted at regular intervals without the beat signal being interrupted. However, the video application 140 has been frozen due to some kind of failure, and is no longer able to provide accurate video information to the video display device 200 .

In such a state, conventionally, the power control device 300 receives short data at regular intervals without interrupting the heartbeat signal, so that the failure occurring in the video application 140 installed in the server device 100 can be prevented. could not be detected.

Therefore, in the failure monitoring and recovery system of the present embodiment, the monitoring recovery unit 130 constantly monitors the operation status of the video application 140, so that the monitoring recovery unit 130 can detect a failure occurring in the video application 140. When the monitoring recovery unit 130 detects a failure occurring in the video application 140, it transmits a heartbeat stop signal to stop the heartbeat signal to the connected server control unit 120. FIG.

Upon receiving the heartbeat stop signal from the monitoring recovery unit 130 , the server control unit 120 stops the heartbeat signal transmitted to the power control device 300 . After that, the monitoring recovery unit 130 transmits a signal for shutting down the server device 100 to the server control unit 120 . As a result, the server device 100 will eventually be shut down.

On the other hand, in the power control unit 300, the power control unit 320, which has stopped receiving the heartbeat signal due to the server control unit 120 stopping the heartbeat signal, detects that the heartbeat signal from the server device 100 has been interrupted. Then, it is determined that the server device 100 or the video application 140 installed inside the server device 100 is faulty.

The power supply control unit 320 determines that the server device 100 or the video application 140 installed inside the server device 100 is faulty, so that the video display device 200 connected to the second power output unit 360 Cut off the power supply.

As a result, an error screen that is displayed on the video display device 200 due to a failure in the server device 100 or the video application 140 that is installed inside the server device 100, or when the server device 100 is shut down. It is possible to prevent the video displayed on the screen from being displayed publicly.

Next, after the power supply to the video display device 200 is cut off, the power control unit 320 executes a PING command, which is used for confirming network communication, to the server device 100 at regular intervals to send packets. Send.

At this time, before the server device 100 shuts down or if the server control unit 120 is in a state of responding, a response packet is normally returned to the power control device 300 that executed the PING command.

The power control unit 320 determines that the server device 100 is not normally shut down when a response packet is returned in this way. The execution of this PING command is repeated until the power control unit 320 stops it.

When the server device 100 is eventually shut down normally, no response packet is returned to the PING command executed by the power control unit 320 . Accordingly, the power control unit 320 determines that the server device 100 has been properly shut down, and cuts off power to the server device 100 connected to the first power output unit 350 .

After cutting off power to the server device 100 connected to the first power output unit 350, the power control unit 320 restarts power to the server device 100 connected to the first power output unit 350, and controls the power. The unit 320 restarts the server device 100 by transmitting a magic packet such as WoL.

At this time, the server device 100 cannot return a response packet to the PING command that the power control unit 320 executes to the server device 100 from the time when the server device 100 is shut down until it is restarted normally. .

When the server device 100 is eventually restarted normally, the server device 100 returns a response packet to the PING command that the power control unit 320 executes to the server device 100 . As a result, the power control unit 320 determines that the server device 100 has been restarted normally, and stops the PING command being executed for the server device 100 .

After that, the server device 100 restarts the heartbeat that is set to be automatically executed after startup, and the video application 140 and the monitoring recovery unit 130 that are also set to be automatically executed after startup. is activated, a reproduced image is provided to the image display device 200, and the operation status thereof is monitored by the monitoring recovery unit 130. FIG.

By restarting the heartbeat after the server control unit 120 restarts, the power supply control unit 320 receives short data at regular intervals without interrupting the heartbeat signal, and the server device 100 or the video application 140 operates normally. can be determined to be

In this way, even if there is no failure in the server control unit 120 and only the video application 140 has failed, the monitoring recovery unit 130 and the power control device 300 operate to restart the server device 100, A failure occurring in the video application 140 can be recovered.

Further, when restarting the server device 100, the power control device 300 cuts off the power supply to the server device 100, so that the server device 100 can be completely powered off. can be cold-started to restart the server device 100 from the state in which is initialized.

As a result, compared to a warm start in which the power of the server device 100 is not turned off, that is, in a state in which the information input to the server device 100 is not initialized, the storage medium, server control unit 120, etc. provided in the server device 100 can be restarted. Since the operating system is completely initialized, the server device 100 can be restarted in a completely initialized state from an unstable state.

In this case, the power control unit 320 cuts off or starts the power supply to the image display device 200 connected to the second power output unit 360, thereby performing power control. and when connected to the network 400, the power control unit 320 transmits a control command to the video display device 200 connected via the network 400, thereby powering the video display device 200. You may make it control.

As described above, as an example of the power control of the video display device 200 via the network 400, a projector/display standardized regardless of manufacturers using TCP (Transmission Control Protocol)/IP (Internet Protocol) A command called PJlink is known as a control command for . The power control unit 320 executes this PJlink command for the preset IP address of the video display device 200 , so that the power control device 300 can control the power of the video display device 200 .

FIG. 2 is a block diagram showing the details of the monitoring restoration unit.
As shown in FIG. 2 , the monitoring recovery unit 130 includes a video application monitoring unit 131 , a heartbeat stop instruction unit 132 and a shutdown execution unit 133 .

The video application monitoring unit 131 is connected to the heartbeat stop command unit 132, the shutdown execution unit 133, and the video application 140, and monitors the operation status of the video application 140 to detect failures occurring in the video application 140. belongs to.

Video application monitoring unit 131 monitors, for example, the operating status of the CPU, and determines whether video application 140 is frozen or occupies the CPU in an abnormal situation. In addition, it may be determined whether or not the image displayed by the image application is displayed in the foreground of the image display device 200 .

When the video application monitoring unit 131 determines that the video application 140 has failed, it transmits a failure occurrence signal to the heartbeat stop command unit 132 and the shutdown execution unit 133 .

The heartbeat stop command unit 132 is connected to the video application monitoring unit 131 and the server control unit 120 and is for issuing a command to stop the heartbeat signal to the connected server control unit 120 .

When the heartbeat stop command unit 132 receives a fault occurrence signal transmitted by the video application monitoring unit 131 due to a fault occurring in the video application 140 , the heartbeat stop command unit 132 sends a heartbeat signal to the server control unit 120 . Send a stop command. As a result, the data transmitted from the server device 100 to the power control device 300 at regular intervals is stopped.

The shutdown execution unit 133 is connected to the video application monitoring unit 131 and the server control unit 120, and transmits a command to shut down the server device 100 to the connected server control unit 120 to execute the shutdown. is.

When the shutdown execution unit 133 receives the failure occurrence signal transmitted by the video application monitoring unit 131 due to a failure occurring in the video application 140, the shutdown execution unit 133 instructs the server control unit 120 to shut down the server device 100. Send. As a result, the server device 100 executes shutdown, and the server device 100 is eventually shut down.

FIG. 3 is a block diagram showing the details of the control unit.
As shown in FIG. 3, the server controller 120 has a heartbeat transmitter 121 and a PING responder 122 . The server control unit 120 also includes a storage medium for storing programs and the like, a memory for reading the programs, and a CPU for executing the programs read into the memory, but these are omitted here. .

The heartbeat transmission unit 121 is connected to the monitoring recovery unit 130 and the communication unit 110, and transmits data at predetermined intervals to a specific device connected to the network, here the server device 100. It is for sending signals.

The heartbeat transmission unit 121 is automatically executed each time the server apparatus 100 is activated, and continues to transmit the heartbeat signal until receiving an instruction to stop the heartbeat signal. However, if the operation of the server control unit 120 becomes unstable and freezes, the heartbeat transmission unit 121 becomes unable to transmit the heartbeat signal accordingly.

When the heartbeat stop command unit 132 transmits a heartbeat stop signal to stop the heartbeat signal to the server control unit 120 due to a failure in the video application 140 , the heartbeat transmission unit 121 causes the power supply control device 300 to stop the heartbeat signal. stop sending heartbeat signals to

The PING response unit 122 is connected to the monitoring recovery unit 130 and the communication unit 110, and responds to a packet transmitted by a PING command executed to the server device 100 from a device connected to the network 400. is for replying.

When the PING response unit 122 receives the packet transmitted by the PING command executed by the power control device 300 via the communication unit 110 and the network 400, the PING response unit 122 returns the response packet to the power control device 300. do.

As a result, network communication between the power control device 300 and the server device 100 can be confirmed, and the power control device 300 can confirm that the server device 100 is operating.

FIG. 4 is a block diagram showing the details of the power control unit.
As shown in FIG. 4 , the power control unit 320 includes a heartbeat reception unit 321 , a PING transmission/reception unit 322 , a power supply unit 323 and a magic packet transmission unit 324 .

Heartbeat receiver 321 is connected to communication unit 330 , PING transmission/reception unit 322 , power supply unit 323 , and information storage unit 340 . It receives the heartbeat signal transmitted by the server device 100 and determines whether or not the server device 100 or the video application 140 installed inside the server device 100 has a failure.

If the heartbeat receiving unit 321 cannot receive a heartbeat signal at predetermined intervals, the heartbeat receiving unit 321 receives the heartbeat from the server device 100 or the video application installed inside the server device 100. 140 is determined to be faulty.

When the heartbeat receiving unit 321 determines that the server device 100 or the video application 140 installed inside the server device 100 has failed, the heartbeat receiving unit 321 notifies the PING transmitting/receiving unit 322 and the power supply unit 323 of Then, a failure notification signal is transmitted to notify that the server device 100 or the video application 140 installed inside the server device 100 has failed.

If the heartbeat receiving unit 321 receives heartbeat signals at predetermined intervals, the heartbeat receiving unit 321 is installed in the server device 100 or the server device 100 that is the source of the heartbeat. It is determined that the video application 140 is operating normally.

The PING transmission/reception unit 322 is connected to the communication unit 330 , the heartbeat reception unit 321 , the magic packet transmission unit 324 , the power supply unit 323 , and the information storage unit 340 . executes a PING command and transmits a packet to the server device 100 , and receives a response packet that the server device 100 responded to the power control device 300 .

The PING transmission/reception unit 322 determines that the heartbeat reception unit 321 has a failure in the server device 100 or the video application 140 installed inside the server device 100, and sends the failure occurrence notification signal transmitted to the PING transmission/reception unit 322. By receiving the command, the PING command is repeatedly executed at regular intervals to the server device 100 in which the failure has occurred.

At this time, if the PING transmission/reception unit 322 receives a response packet returned by the server device 100 in response to the PING command executed by the PING transmission/reception unit 322 at regular intervals, it means that the server device 100 is activated. If the PING transmission/reception unit 322 determines that the response packet returned by the server device 100 is not received by the PING transmission/reception unit 322, the server device 100 is not activated, that is, the server device 100 was shut down normally. The transmitting/receiving unit 322 makes the determination.

When the PING transmission/reception unit 322 determines that the server device 100 has been properly shut down, the PING transmission/reception unit 322 transmits to the power supply unit 323 a shutdown completion signal notifying that the server device 100 has been properly shut down. .

The power supply unit 323 is connected to the heartbeat reception unit 321, the PING transmission unit 322, the magic packet transmission unit 324, the information storage unit 340, the first power output unit 350, and the second power output unit 360, and the first power output. It is for controlling power supply to the server device 100 connected to the section 350 and the image display device 200 connected to the second power output section 360 .

The power supply unit 323 determines that the heartbeat reception unit 321 has a failure in the server device 100 or the video application 140 installed inside the server device 100, and receives the failure notification signal transmitted to the power supply unit 323. , the power supply to the video display device 200 connected to the second power output unit 360 is cut off.

In addition, when the PING transmission/reception unit 322 determines that the power supply unit 323 has successfully shut down the server device 100 and receives the shutdown completion signal transmitted to the power supply unit 323, the server device 100 connected to the first power supply output unit 350 Cut off the power supply to the device, wait for a certain period of time, and then restart the power supply.

When power supply unit 323 cuts off and resupply of power to server device 100 connected to first power supply output unit 350 , power supply unit 323 cuts off/supply of power to magic packet transmission unit 324 . Send a power cutoff/supply complete notification to notify completion.

Further, when the power supply unit 323 receives a magic packet transmission completion signal that notifies the server device 100 that the magic packet transmission unit 324 (to be described later) has completed the transmission of the magic packet, the power supply unit 323 causes the server device 100 to restart. After waiting for a certain period of time until the power is stabilized, the power is supplied again to the image display device 200 connected to the second power supply output section 360 that has been cut off.

The magic packet transmission unit 324 is connected to the PING transmission/reception unit 322, the power supply unit, and the information storage unit 340, and remotely powers on the server device 100 connected via the communication unit 330 and the network 400. This function is for transmitting a magic packet such as WoL that can be used to the server device 100 to restart the server device 100 .

Magic packet transmission unit 324 transmits a magic packet when power supply unit 323 cuts off and restarts power supply to server device 100 connected to first power supply output unit 350 and receives a power cutoff/supply completion notification. A unit 324 transmits a magic packet to the server device 100 . As a result, the power control device 300 can remotely restart the server device 100 that receives the magic packet.

The destination of the PING command executed by the PING transmission/reception unit, the destination of the magic packet transmission unit, the standby time of the power supply unit 323, and the like can be stored in the connected information storage unit 340. FIG.

Figure 5 shows the operation of each device between the server, the power control device, and the video display device, from the state where each device is operating normally until the video application in the server fails and recovers from the failure. It is a sequence flowchart showing. The processing shown in FIG. 5 will be described below in accordance with step numbers.

[Step S11]
Server device 100 transmits a heartbeat signal. Specifically, the heartbeat transmission unit 121 included in the server control unit 120 transmits a heartbeat signal to the power control device 300 at predetermined intervals.

[Step S12]
The power control device 300 recognizes that the server device 100 is operating normally. Specifically, the heartbeat signal transmitted in step S11 is received by the heartbeat receiver 321 included in the power control device 300 at regular intervals, so that the power control device detects that the server device 100 is operating normally. recognize that there are

[Step S13]
A failure occurs in the video application 140 . Specifically, no failure occurs in the server control unit 120 provided in the server device 100, and failures such as freezing and abnormal occupation of the CPU occur only in the video application 140. FIG.

[Step S14]
The server device 100 stops the heartbeat signal. Specifically, the video application monitoring unit 131 included in the monitoring recovery unit 130 monitors the video application 140, and when a failure occurs in the video application 140, the heartbeat stop command unit 132 included in the monitoring recovery unit 130 performs server control. A command to stop the heartbeat signal is sent to the unit 120 .

[Step S15]
The power control device 300 recognizes that the video application 140 has failed. Specifically, since the heartbeat reception unit 321 provided in the power control device 300 cannot receive the heartbeat at regular intervals due to the heartbeat being stopped in step S14, the power control device 300 causes the video application 140 to fail. recognize that

[Step S16]
The power control device 300 cuts off the power of the image display device 200 . Specifically, the power supply unit 323 included in the power supply control device 300 cuts off the power supplied to the video display device 200 connected to the second power supply output unit 360 .

[Step S17]
The video display device 200 stops displaying the video. Specifically, the image publicly displayed on the image display device 200 is stopped because the power supplied in step S16 is cut off.

[Step S18]
The server device 100 starts shutting down. Specifically, the shutdown execution unit 133 included in the monitoring recovery unit 130 transmits a command to shut down the server device 100 to the server control unit 120 to shut down the server device 100 .

[Step S19]
The power control device 300 starts executing the PING command. Specifically, the PING transmission/reception unit 322 included in the power supply control unit 320 starts an operation of executing a PING command to the server device 100 at predetermined intervals.

[Step S20]
Power control device 300 executes the PING command. Specifically, the PING transmission/reception unit 322 included in the power supply control unit 320 executes a PING command and transmits packets to the server device 100 at predetermined intervals, and the server device 100 that has not completed shutdown responds. As a result, the PING transmission/reception unit 322 receives the response packet.

[Step S21]
Shutdown of the server device 100 is completed.
[Step S22]
Power control device 300 executes the PING command. Specifically, the PING transmitting/receiving unit 322 included in the power control unit 320 executes a PING command and transmits packets to the server device 100 at predetermined intervals, and the shutdown of the server device 100 is completed in step S22. Therefore, the server apparatus 100 does not respond, and the PING transmitting/receiving section 322 cannot receive the response packet.

[Step S23]
The power control device 300 recognizes that the server device 100 has been shut down. Specifically, since the PING transmission/reception unit 322 cannot receive the response packet in step S22, the power control device 300 recognizes that the server device 100 has been shut down.

[Step S24]
The power control device 300 stops executing the PING command. Specifically, the PING transmission/reception unit 322 included in the power control unit 320 stops the operation of executing the PING command to the server device 100 at predetermined intervals.

[Step S25]
The power control device 300 cuts off the power of the server device 100 . Specifically, the power supply unit 323 included in the power supply control device 300 cuts off the power supplied to the server device 100 connected to the first power supply output unit 350 .

[Step S26]
The power control device 300 starts powering on the server device 100 . Specifically, the power supply unit 323 included in the power control device 300 starts supplying power to the server device 100 connected to the first power output unit 350 .

[Step S27]
The power control device 300 activates the server device 100 . Specifically, the magic packet transmission unit included in the power control device 300 activates the server device 100 by transmitting a magic packet to the server device 100 .

[Step S28]
Server device 100 starts up. Specifically, when the server device 100 receives the magic packet transmitted by the power control device 300 in step S27, the server device 100 starts booting.

[Step S29]
The server device 100 starts sending heartbeat signals. Specifically, the server device 100 activated in step S28 starts an operation of transmitting a heartbeat signal to the power control device 300 at regular intervals according to the heartbeat settings preset in the server control unit 120 .

[Step S30]
Server device 100 transmits a heartbeat signal. Specifically, the heartbeat transmission unit 121 included in the server control unit 120 transmits a heartbeat signal to the power control device 300 at predetermined intervals.

[Step S31]
The power control device 300 recognizes that the server device 100 is operating normally. Specifically, the heartbeat signal transmitted in step S29 is received by the heartbeat receiver 321 included in the power control device 300 at regular intervals, so that the power control device detects that the server device 100 is operating normally. recognize that there are

[Step S32]
The video application 140 is activated on the server device 100 . Specifically, when the server device 100 is activated in step S28, the preset image application 140 is automatically activated.

[Step S33]
The power control device 300 turns on the power of the image display device 200 . Specifically, the power supply unit 323 included in the power supply control device 300 starts supplying power to the image display device 200 connected to the second power supply output unit 360 .

[Step S34]
The image display device 200 starts displaying images. Specifically, the power supply, which was cut off in step S33, is started, and the video application 140 is activated in step S32, so that the video display device 200 starts to display video.

Although the sequence flowchart of FIG. 5 shows an example in which a failure occurs in the video application 140, a failure occurs in the server device 100 and the server control unit 120 cannot send a heartbeat signal to the power control device 300. Even if there is no such device, it is possible to recover from the failure that occurred in the server device 100 by the processing after step S15.

Specifically, since the failed server device 100 does not respond to the PING command executed by the power control device 300 in step S20, the power control device 300 can cold start the server device 100 .

FIG. 6 is a flowchart showing server processing from the state in which the heartbeat signal is transmitted to the power control device to the detection of a failure in the video application and the stoppage of the heartbeat signal. The processing shown in FIG. 6 will be described below along with the step numbers.

[Step S101]
The server device 100 transmits a heartbeat signal to the power control device 300 . Specifically, the server device 100 transmits a heartbeat signal to the power control device 300 according to the heartbeat settings preset in the server control unit 120 provided in the server device 100 .

[Step S102]
The server device 100 confirms the operation status of the video application 140 . Specifically, the video application monitoring unit 131 included in the server device 100 checks whether the video application 140 is operating normally.

[Step S103]
The server device 100 determines whether the video application 140 is operating normally. Specifically, the video application monitoring unit 131 included in the server device 100 determines whether the video application 140 is operating normally.

When the video application monitoring unit 131 determines that the video application 140 is operating normally, the process proceeds to step S101, and when the video application monitoring unit 131 determines that the video application 140 is not operating normally. , the process proceeds to step S104, and a failure occurrence signal is transmitted to the heartbeat stop instruction unit 132. FIG.

[Step S104]
The server device 100 stops the heartbeat signal. Specifically, when the heartbeat stop command unit 132 provided in the server apparatus 100 receives the failure occurrence signal in step S103, the heartbeat stop command unit 132 causes the server control unit 120 to stop the heartbeat signal. Send a stop signal.

FIG. 7 is a flowchart showing the processing of the power supply control device from when a failure of the video application occurs until the video display device is restarted. The processing shown in FIG. 7 will be described below in accordance with step numbers.

[Step S111]
The power control device 300 confirms the heartbeat signal. Specifically, the heartbeat receiving unit 321 included in the power control device 300 checks the heartbeat signal transmitted from the server device 100 at regular intervals.

[Step S112]
The power control device 300 determines whether or not it has received a heartbeat signal. Specifically, the heartbeat receiving unit 321 included in the power control device 300 determines whether heartbeat signals transmitted from the server device 100 at regular intervals are received at regular intervals.

When it is determined that the heartbeat signal transmitted from the server device 100 is received by the heartbeat receiver 321 at regular intervals, the process proceeds to step S111, and the heartbeat signal transmitted from the server device 100 is received by the heartbeat receiver 321. 321 does not receive the data at regular intervals, the process proceeds to step S113.

[Step S113]
The power control device 300 stops the power of the image display device 200 . Specifically, the power supply unit 323 included in the power supply control device 300 cuts off the power supplied to the video display device 200 connected to the second power supply output unit 360 .

[Step S114]
Power control device 300 executes the PING command. Specifically, the PING transmission/reception unit 322 included in the power control device 300 executes a PING command and transmits a packet to the server device 100 .

[Step S115]
The power control device 300 determines whether or not there is a response to the PING command. Specifically, the PING transmitter/receiver 322 determines whether or not the server device 100 has returned a response packet to the packet transmitted in step S114.

When the PING transmission/reception unit 322 determines that the server device 100 has returned a response packet, the process proceeds to step S114. Proceed to step S116.

[Step S116]
The power control device 300 stops the repeated execution of the PING command. in particular,
The PING transmission/reception unit 322 included in the power control device 300 stops the PING command repeatedly executed to the server device 100 .

[Step S117]
The power control device 300 cuts off the power of the server device 100 and then restarts it. Specifically, the power supply unit 323 included in the power supply control device 300 cuts off the power supplied to the server device 100 connected to the first power supply output unit 350, waits for a predetermined period of time, and then cuts off the power. resume supply.

[Step S118]
Power control device 300 transmits a magic packet. Specifically, the magic packet transmission unit 324 included in the power control device 300 transmits a magic packet for activating the server device 100 to the server device 100 .

[Step S119]
The power control device 300 confirms the heartbeat signal. Specifically, the heartbeat receiving unit 321 included in the power control device 300 checks the heartbeat signal transmitted from the server device 100 at regular intervals.

[Step S120]
The power control device 300 determines whether or not it has received a heartbeat signal. Specifically, the heartbeat receiver 321 provided in the source control device 300 determines whether or not the heartbeat signal transmitted from the server device 100 at regular intervals is received.

When the heartbeat receiving unit 321 determines that the heartbeat signal transmitted from the server device 100 has been received, the process proceeds to step S121, and the heartbeat receiving unit 321 receives the heartbeat signal transmitted from the server device 100. If it is determined that it has not, the process proceeds to step S119.

[Step S121]
The power control device 300 turns on the power of the image display device 200 . Specifically, the power supply unit 323 included in the power supply control device 300 restarts the interrupted power to the image display device 200 connected to the second power supply output unit 360 .

[Second embodiment]
Next, a second embodiment of the invention will be described. The fault monitoring and recovery system of this embodiment has substantially the same configuration as that of the first embodiment, except for the details of the monitoring and recovery unit and the flow of processing. For this reason, substantially the same components as those of the first embodiment are denoted by the same reference numerals, and description thereof will be omitted as appropriate.

FIG. 8 is a block diagram showing the details of the monitoring restoration unit.
As shown in FIG. 8, the monitoring recovery unit 130 includes a video application monitoring unit 131, a heartbeat stop command unit 132, a shutdown execution unit 133, and a server restart execution unit .

Server restart executing unit 134 is connected to video application monitoring unit 131 and server control unit 120 , and transmits a command to restart server device 100 to connected server control unit 120 to restart server device 100 . It is for rebooting.

When the server restart execution unit 134 receives the failure occurrence signal transmitted by the video application monitoring unit 131 due to the failure of the video application 140 , the server restart execution unit 134 instructs the server control unit 120 to restart the server device 100 . Send a command to restart. As a result, the server device 100 is restarted, and eventually the server device 100 is restarted.

When a failure occurs in the video application 140, in order to recover from the failure, instead of cold-starting the server device 100, recovery may be possible simply by restarting the server device 100, and recovery can be performed in a short time. . The server restart executing unit 134 in the second embodiment is effective in such cases.

Figure 9 shows the operation of each device between the server, the power control device, and the video display device, from the state where each device is operating normally until the video application in the server fails, and the recovery from the failure occurs. It is a sequence flowchart showing. The processing shown in FIG. 9 will be described below along with the step numbers. It should be noted that the description of the same processing as in the sequence flowchart of FIG. 5 will be omitted as appropriate.
[Step S11] to [Step S17]
Since the processing is the same as that of the sequence flowchart of FIG. 5, the description is omitted.

[Step S17-1]
The server device 100 starts rebooting. Specifically, the server restart execution unit 134 included in the monitoring recovery unit 130 sends a command to restart the server device 100 to the server control unit 120 to restart the server device 100 .
[Step S19] to [Step S23]
Since the processing is the same as that of the sequence flowchart of FIG. 5, the description is omitted.

[Step S23-1]
The server device 100 starts up. Specifically, the server device 100 automatically starts booting after step S21 in accordance with the reboot instruction sent by the server reboot execution unit 134 included in the monitoring recovery unit 130 in step S17-1. .

[Step S23-2]
Power control device 300 executes the PING command. Specifically, the PING transmission/reception unit 322 included in the power supply control unit 320 executes a PING command and transmits packets to the server device 100 at predetermined intervals, and the server device 100 that has not completed shutdown responds. As a result, the PING transmission/reception unit 322 receives the response packet.

[Step S23-3]
The power control device 300 confirms that the server device 100 has started. Specifically, in step S23-2, the PING transmitting/receiving unit 322 included in the power control unit 320 receives the response packet returned by the server device 100, so that the power control device 300 is activated by the server device 100. Confirm that you have done

[Step S23-4]
The power control device 300 stops executing the PING command. Specifically, the PING transmission/reception unit 322 included in the power control unit 320 stops the operation of executing the PING command to the server device 100 at predetermined intervals.
[Step S28] to [Step S34]
Since the processing is the same as that of the sequence flowchart of FIG. 5, the description is omitted.

FIG. 10 is a flowchart showing the processing of the power supply control device from when a failure of the video application occurs to when the video display device is restarted. The processing shown in FIG. 10 will be described below along with the step numbers.

[Step S131]
The power control device 300 confirms the heartbeat signal. Specifically, the heartbeat receiving unit 321 included in the power control device 300 checks the heartbeat signal transmitted from the server device 100 at regular intervals.

[Step S132]
The power control device 300 determines whether or not it has received a heartbeat signal. Specifically, the heartbeat receiver 321 provided in the source control device 300 determines whether or not the heartbeat signal transmitted from the server device 100 at regular intervals is received.

When it is determined that the heartbeat signal transmitted from the server device 100 is received by the heartbeat receiver 321, the process proceeds to step S131, and the heartbeat receiver 321 receives the heartbeat signal transmitted from the server device 100. If it is determined that the

[Step S133]
The power control device 300 stops the power of the image display device 200 . Specifically, the power supply unit 323 included in the power supply control device 300 cuts off the power supplied to the video display device 200 connected to the second power supply output unit 360 .

[Step S134]
Power control device 300 executes the PING command. Specifically, the PING transmission/reception unit 322 included in the power control device 300 executes a PING command and transmits a packet to the server device 100 .

[Step S135]
The power control device 300 determines whether or not there is a response to the PING command. Specifically, the PING transmitter/receiver 322 determines whether or not the server device 100 has returned a response packet to the packet transmitted in step S114.

When the PING transmitter/receiver 322 determines that the server device 100 has not returned a response packet, the process proceeds to step S136. Proceed to step S142.

[Step S136]
The power supply control device 300 confirms that the server device 100 has completed the server termination process of the server termination process and the activation process of the restart processing. Specifically, since the server apparatus 100 has stopped returning the response packet in step S135, the power control apparatus 300 confirms that the server termination process of the server apparatus 100 has been completed.

[Step S137]
Power control device 300 executes the PING command. Specifically, the PING transmission/reception unit 322 included in the power control device 300 executes a PING command and transmits a packet to the server device 100 .

[Step S138]
The power control device 300 determines whether or not there is a response to the PING command. Specifically, the PING transmitter/receiver 322 determines whether or not the server device 100 has returned a response packet to the packet transmitted in step S114.

When the PING transmission/reception unit 322 determines that the server device 100 has returned a response packet, the process advances to step S139 to confirm that the server device 100 has been restarted. When the PING transmitting/receiving unit 322 determines that the PING transmitting/receiving unit 322 determines that the PING transmitting/receiving unit 322 has performed the processing, the process proceeds to step S137.

[Step S139]
The power control device 300 stops the repeated execution of the PING command. in particular,
The PING transmission/reception unit 322 included in the power control device 300 stops the PING command repeatedly executed to the server device 100 .

[Step S140]
The power control device 300 confirms the heartbeat signal. Specifically, the heartbeat receiving unit 321 included in the power control device 300 checks the heartbeat signal transmitted from the server device 100 at regular intervals.

[Step S141]
The power control device 300 determines whether or not it has received a heartbeat signal. Specifically, the heartbeat receiver 321 provided in the source control device 300 determines whether or not the heartbeat signal transmitted from the server device 100 at regular intervals is received.

When it is determined that the heartbeat signal transmitted from the server device 100 has been received by the heartbeat receiving section 321, the process proceeds to step S142, and the heartbeat receiving section 321 receives the heartbeat signal transmitted from the server device 100. If it is determined that it has not, the process proceeds to step S140.

[Step S142]
The power control device 300 turns on the power of the image display device 200 . Specifically, the power supply unit 323 included in the power supply control device 300 restarts the interrupted power to the image display device 200 connected to the second power supply output unit 360 .

[Step S143]
The power supply control device 300 determines whether or not the processes of steps S134 to S135 have been repeated a predetermined number of times.

When the power control device 300 determines that the processing of steps S134 to S135 has been repeated a predetermined number of times, it determines that the server device 100 cannot be restarted, and advances the processing to step S24 in FIG. If it is determined that the processes of steps S134 to S135 have not been repeated a predetermined number of times, the process proceeds to step S34.

By performing the processing as described above, when a failure occurs in the video application 140, the server device 100 is first restarted. can be turned on to restart the video.

If the restart does not succeed, that is, if the server device 100 does not respond, the process advances to step S24 in FIG. Therefore, it is possible to reliably recover from failures.

[Third Embodiment]
Next, a third embodiment of the invention will be described. The fault monitoring and recovery system of this embodiment has almost the same configuration as those of the first and second embodiments, except for the details of the monitoring and recovery unit and the flow of processing. For this reason, components substantially similar to those of the first and second embodiments are denoted by the same reference numerals, and description thereof will be omitted as appropriate.

FIG. 11 is a block diagram showing the details of the monitoring restoration unit.
As shown in FIG. 11 , the monitoring recovery unit 130 includes a video application monitoring unit 131 , a heartbeat stop command unit 132 , a shutdown execution unit 133 , a server restart execution unit 134 and an application restart execution unit 135 .

Application restart executing unit 135 is connected to video application monitoring unit 131 and server control unit 120, and transmits a command to reactivate video application 140 connected via video application monitoring unit 131 after terminating it. This is for restarting the video application 140 by pressing the button.

When the server restart execution unit 134 receives a failure occurrence signal transmitted by the video application monitoring unit 131 due to a fault occurring in the video application 140, the application restart execution unit 135 restarts the video application 140 after terminating it. This is for sending a command to restart the video application 140 .

When a failure occurs in the image application 140, in order to recover from the failure, instead of cold-starting or restarting the server device 100, recovery may be possible simply by restarting the image application 140, and recovery is performed in a short time. be able to. The application restart executing unit 135 in the third embodiment is effective in such cases.

FIG. 12 shows the operation of each device between the server, power control device, and video display device, from the state in which each device is operating normally, to the time when a video application in the server fails, and then to the recovery from the failure. It is a sequence flowchart showing. The processing shown in FIG. 9 will be described below along with the step numbers. It should be noted that the description of the same processing as in the sequence flowchart of FIG. 5 will be omitted as appropriate.

[Step S11] to [Step S17]
Since the processing is the same as that of the sequence flowchart of FIG. 5, the description is omitted.
[Step S17-2]
Server device 100 terminates video application 140 . Specifically, the application restart executing unit 135 included in the monitoring recovery unit 130 temporarily terminates the video application 140 in order to restart it.

[Step S17-3]
The server device 100 activates the video application 140 . Specifically, the application restart execution unit 135 included in the monitoring recovery unit 130 starts up the video application 140 that was temporarily terminated in order to restart the video application 140 in step S17-2.
[Step S28] to [Step S34]
Since the processing is the same as that of the sequence flowchart of FIG. 5, the description is omitted.

FIG. 13 is a flowchart showing server processing from the state in which the heartbeat signal is transmitted to the power control device to the detection of a failure in the video application and the stoppage of the heartbeat signal. The processing shown in FIG. 6 will be described below along with the step numbers.

[Step S151]
The server device 100 transmits a heartbeat signal to the power control device 300 . Specifically, the server device 100 transmits a heartbeat signal to the power control device 300 according to the heartbeat settings preset in the server control unit 120 provided in the server device 100 .

[Step S152]
The server device 100 confirms the operation status of the video application 140 . Specifically, the video application monitoring unit 131 included in the server device 100 checks whether the video application 140 is operating normally.

[Step S153]
The server device 100 determines whether the video application 140 is operating normally. Specifically, the video application monitoring unit 131 included in the server device 100 determines whether the video application 140 is operating normally.

When the image application monitoring unit 131 determines that the image application 140 is operating normally, the process proceeds to step S151, and when the image application monitoring unit 131 determines that the image application 140 is not operating normally. , the process proceeds to step S154, and a failure occurrence signal is transmitted to the heartbeat stop instruction unit 132. FIG.

[Step S154]
The server device 100 stops the heartbeat signal. Specifically, when the heartbeat stop command unit 132 provided in the server apparatus 100 receives the failure occurrence signal in step S153, the heartbeat stop command unit 132 instructs the server control unit 120 to stop the heartbeat signal. Send a signal.

[Step S155]
Server device 100 terminates video application 140 . Specifically, when the application restart execution unit 135 provided in the server apparatus 100 receives the failure occurrence signal in step S153, the application restart execution unit 135 instructs the server control unit 120 to end the video application 140. Send a signal to terminate the video application 140 .
[Step S156]
Server device 100 activates video application 140 . Specifically, when the application restart execution unit 135 provided in the server apparatus 100 terminates the video application 140 in step S155, the application restart execution unit 135 instructs the server control unit 120 to start the video application 140. A signal is sent to activate the video application 140 again.
[Step S157]
The server device 100 determines whether the video application 140 is operating normally. Specifically, the video application monitoring unit 131 included in the server device 100 determines whether the video application 140 is operating normally.

When the image application monitoring unit 131 determines that the image application 140 is operating normally, the process proceeds to step S158, and when the image application monitoring unit 131 determines that the image application 140 is not operating normally. , the process proceeds to step S155.
[Step S158]
The server device 100 starts sending heartbeat signals. Specifically, the video application monitoring unit 131 included in the server device 100 starts a heartbeat by transmitting to the server control unit 120 a signal for starting an operation of transmitting a heartbeat signal at regular intervals.

[Step S159]
The server device 100 determines whether or not the processes of steps S155 to S157 have been repeated a predetermined number of times.

When the server apparatus 100 determines that the processes of steps S155 to S157 have been repeated a predetermined number of times, it determines that the image application 140 cannot operate normally by restarting, and the process is performed by the server apparatus 100 in step S18 of FIG. Proceeding to the shutdown process or the restarting process of the server device 100 in step S17-1, and when the server device 100 determines that the processing of steps S155 to S157 has not been repeated a predetermined number of times, the processing proceeds to step S17-1. Proceed to S155.

FIG. 14 is a flowchart showing the processing of the power supply control device from when a failure of the video application occurs to when the video display device is restarted. The processing shown in FIG. 14 will be described below according to the step numbers.

[Step S161]
The power control device 300 confirms the heartbeat signal. Specifically, the heartbeat receiving unit 321 included in the power control device 300 checks the heartbeat signal transmitted from the server device 100 at regular intervals.

[Step S162]
The power control device 300 determines whether or not it has received a heartbeat signal. Specifically, the heartbeat receiver 321 provided in the source control device 300 determines whether or not the heartbeat signal transmitted from the server device 100 at regular intervals is received.

When it is determined that the heartbeat signal transmitted from the server device 100 has been received by the heartbeat receiving section 321, the process proceeds to step S161, and the heartbeat receiving section 321 receives the heartbeat signal transmitted from the server device 100. If it is determined that the

[Step S163]
The power control device 300 stops the power of the image display device 200 . Specifically, the power supply unit 323 included in the power supply control device 300 cuts off the power supplied to the video display device 200 connected to the second power supply output unit 360 .

[Step S164]
The power control device 300 confirms the heartbeat signal. Specifically, the heartbeat receiving unit 321 included in the power control device 300 checks the heartbeat signal transmitted from the server device 100 at regular intervals.

[Step S165]
The power control device 300 determines whether or not it has received a heartbeat signal. Specifically, the heartbeat receiver 321 provided in the source control device 300 determines whether or not the heartbeat signal transmitted from the server device 100 at regular intervals is received.

When it is determined that the heartbeat signal transmitted from the server device 100 has been received by the heartbeat receiving section 321, the process proceeds to step S166, and the heartbeat receiving section 321 receives the heartbeat signal transmitted from the server device 100. If it is determined that it has not, the process proceeds to step S164.

[Step S166]
The power control device 300 turns on the power of the image display device 200 . Specifically, the power supply unit 323 included in the power supply control device 300 restarts the interrupted power to the image display device 200 connected to the second power supply output unit 360 .

By performing the processing as described above, a failure occurs in the video application 140. To recover from the failure, restart the video application 140 instead of cold-starting or restarting the server device 100. If it is possible to try and recovery cannot be performed only by restarting the video application 140, the digital signage system 1000 can be recovered from the failure by a cold start from the shutdown processing of the server device 100 or by a restart processing of the server device 100. can.

10, 40 device 100 server device 110 communication unit 120 server control unit 121 heartbeat transmission unit 122 PING response unit 130 monitoring recovery unit 131 video application monitoring unit 132 heartbeat stop instruction unit 133 shutdown execution unit 134 server restart execution unit 135 application Reboot execution unit 140 video application 150 display information output unit 200 video display device 300 power control device 310 power supply unit 320 power control unit 321 heartbeat reception unit 322 PING transmission/reception unit 323 power supply unit 324 magic packet transmission unit 330 communication unit 340 information storage Unit 350 First power output unit 360 Second power output unit 400 Network 1000 Digital signage system P External power supply

Claims (9)

A server device that runs an application, an interlocking device that operates based on information provided by the server device, and a power control device , wherein the power control device receives a heartbeat signal confirming the operation of the server device. In a failure recovery system that checks the operating status of the server device by
heartbeat stopping means for detecting an abnormality in the application and stopping the heartbeat signal;
a server device terminating means for shutting down the server device after stopping the heartbeat signal ;
an application monitoring means comprising
server power control means for detecting shutdown of the server device, interrupting power supply to the server device, and resupplying power;
server device remote activation means for activating the server device from a network on which communication of the heartbeat signal is performed;
a power control means comprising
A failure recovery system comprising: The power supply control means comprises an interlocking device terminating means for terminating the interlocking device by detecting an abnormality in the application by detecting that the heartbeat signal from the server device is interrupted. Item 1. The disaster recovery system according to item 1. 3. The failure recovery system according to claim 2, wherein said interlocking device is a video display device. 3. The failure recovery system according to claim 2, wherein the interlocking device termination means cuts off power supply to the interlocking device. 3. The failure recovery system according to claim 2, wherein said power supply control means terminates said interlocking device according to a communication protocol via said network. 2. The failure recovery system according to claim 1, wherein said server device termination means automatically restarts said server device. 2. The failure recovery system according to claim 1, further comprising application restart means for restarting said application. A server device that runs an application, an interlocking device that operates based on information provided by the server device, and a power control device , wherein the power control device receives a heartbeat signal confirming the operation of the server device. A method executed by a CPU in a failure recovery system for confirming the operating status of the server device by
a heartbeat stop substep of detecting an abnormality in the application and stopping the heartbeat signal;
an application monitoring step comprising a server device termination substep of shutting down the server device after stopping the heartbeat signal ;
a server power control substep that detects shutdown of the server device, cuts off power supply to the server device, and resupplies power to the server device;
a power control step comprising: a server device remote activation substep for activating the server device from a network over which the heartbeat signal is communicated;
A method comprising: A server device that runs an application, an interlocking device that operates based on information provided by the server device, and a power control device , wherein the power control device receives a heartbeat signal confirming the operation of the server device. In the operation program of the failure recovery system described so that it can be read and executed by the failure recovery system, which is a computer for checking the operation status of the server device,
a heartbeat stop substep of detecting an abnormality in the application and stopping the heartbeat signal;
an application monitoring step comprising a server device termination substep of shutting down the server device after stopping the heartbeat signal ;
a server power control substep that detects shutdown of the server device, cuts off power supply to the server device, and resupplies power to the server device;
a power control step comprising: a server device remote activation substep for activating the server device from a network over which the heartbeat signal is communicated;
An operation program of a failure recovery system written so as to be readable and executable by a failure recovery system, which is a computer characterized by comprising:

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