KR102059367B1 - Disaster broadcasting system based on virtualization - Google Patents

Abstract

The present invention relates to a disaster broadcasting system, and in particular, each receiving apparatus may first receive and transmit disaster information directly from a transmission server, and in the event of a failure, secondly access a virtualization server to receive and transmit disaster information. By configuring it to be able to do so, it is possible to upgrade while using the existing receiving device as it is, and save time, effort and cost to configure the upgrade of the receiving device. It is possible to receive a broadcast, and by configuring two controller units for controlling the transmission of disaster information in each receiving device, and configured to continuously perform a status check between them, it is possible to ensure the transmission of disaster information at the receiving device, thereby To ensure the protection of human life and property It relates to a screen-based emergency broadcast system.
The constituent means of the virtualization-based disaster broadcasting system of the present invention includes a transmission server for transmitting disaster information, a virtualization server for receiving the disaster information, and providing the disaster information to a receiving device that has a virtual connection, And a receiving apparatus receiving the disaster information transmitted from the transmission server or the disaster information provided by accessing the virtualization server and transmitting the received disaster information through an output device.

Description

Disaster broadcasting system based on virtualization

The present invention relates to a disaster broadcasting system, and in particular, each receiving apparatus may first receive and transmit disaster information directly from a transmission server, and in the event of a failure, secondly access a virtualization server to receive and transmit disaster information. By configuring it to be able to do so, it is possible to upgrade while using the existing receiving device as it is, and save time, effort and cost to configure the upgrade of the receiving device. It is possible to receive a broadcast, and by configuring two controller units for controlling the transmission of disaster information in each receiving device, and configured to continuously perform a status check between them, it is possible to ensure the transmission of disaster information at the receiving device, thereby To ensure the protection of human life and property It relates to a screen-based emergency broadcast system.

Disaster broadcasting system is a broadcasting system for disaster prevention and prevention education such as emergency preparedness, evacuation, and personnel assignment by maintaining a large-scale people's management system such as public notice of village and public office, and prompt and accurate situation propagation in case of disaster. System.

Disaster broadcasting system can be used to inform the entire jurisdiction of disaster occurrence situation and evacuate to the entire jurisdiction collectively, thereby reducing confusion in the status system and allowing people within the jurisdiction to evacuate quickly and safely. have.

However, such a conventional disaster broadcasting system has the following problems.

The conventional disaster broadcasting system has a disadvantage in that it takes more than necessary time, effort, and cost to configure not only hardware but also software in configuring a receiving apparatus for receiving disaster information and transmitting it through an output device such as a speaker.

In addition, the conventional disaster broadcasting system has a problem that can cause irreversible consequences to human life and property because it can not transmit disaster information when a failure of the receiving device.

In addition, the conventional disaster broadcasting system has a disadvantage in that it is not possible to support a situation in which a disaster broadcast can be received through a mobile terminal anytime and anywhere because it can transmit a disaster broadcast through a receiving device having predetermined hardware and software. .

In relation to these problems, Korean Patent Registration No. 10-0977984 (hereinafter referred to as "prior art document") describes a digital disaster broadcast in a predetermined channel in a device that receives a digital disaster broadcast transmitted using a digital broadcasting network. Disclosed is a digital disaster broadcast receiving apparatus for automatically receiving a digital disaster broadcast of another channel when it is not received.

However, the prior art document only discloses a technique for receiving a disaster broadcast through another channel when a disaster broadcast is not received through a preset channel, and can secure reception of a disaster broadcast when a failure occurs in the receiving device itself. There is no technology disclosed, and a technical scheme for simplifying the configuration of a receiver and receiving a disaster broadcast anytime, anywhere has not been disclosed.

Republic of Korea Patent Publication No. 10-0977984 (2010. 08. 25. Registered notification, the name of the invention: Digital disaster broadcasting receiver and method)

The present invention was devised to solve the problems of the prior art as described above, and each receiving apparatus can first receive and transmit disaster information directly from a transmitting server, and in case of a failure, connect to a virtualization server secondly. By configuring the system to receive and send disaster information, it can be upgraded while using the existing receiving device as it is, and can save time, effort, and cost for configuring the upgrade of the receiving device, and anytime, anywhere. The receiving device connected to the object is to provide a virtualization-based disaster broadcasting system that can receive a disaster broadcast.

In addition, the present invention is to configure the two controller units for controlling the disaster information transmission in each receiving device and configured to continuously perform the status check between them, thereby ensuring the disaster information transmission in each receiving device, thereby Its purpose is to provide a virtualization-based disaster broadcasting system that can reliably protect human life and property.

In addition, the present invention is configured to control the transmission by receiving the disaster information by automatically accessing the secondary controller unit immediately upon the failure of the unit itself as a main control for controlling the disaster broadcast transmission in the receiving device, and virtualization By configuring reconnection to be performed automatically and automatically even when the connection is abnormally blocked, the virtualization base can further secure disaster information transmission at the receiving device, thereby protecting human life and property more securely. Its purpose is to provide a disaster broadcasting system.

The constituent means of the virtualization-based disaster broadcasting system of the present invention proposed to solve the above technical problem is, in a disaster broadcasting system, a transmission server for transmitting disaster information, receiving the disaster information, receiving the virtualization connection is made And a virtualization server for providing the disaster information to the device, a reception device for receiving the disaster information transmitted from the transmission server or the disaster information provided by accessing the virtualization server and transmitting the disaster information through an output device.

Here, the receiving device is configured to include a main controller unit and a sub-controller unit, the main controller unit receives the disaster information transmitted from the transmission server through the output device, the failure occurs in the main controller unit Only when the secondary controller unit is connected to the virtualization server receives the disaster information is characterized in that for transmitting through the output device.

In addition, the secondary controller unit periodically transmits a steady state confirmation message to the primary controller unit, and determines that a failure occurs in the primary controller unit when the ACK message is not received from the primary controller unit. It is characterized by automatically connecting to the server.

According to the virtualization-based disaster broadcasting system of the present invention having the above-described problems and solutions, each receiving device can receive and transmit disaster information directly from the transmission server first, and if a failure occurs, Because it is configured to access and receive disaster information by accessing it, it can be upgraded while using the existing receiving device as it is, and can save time, effort and cost to configure the upgrade of the receiving device, anytime, anywhere A receiving device connected to a virtualization server has an advantage of allowing a disaster broadcast to be received.

In addition, according to the present invention, since two controller units for controlling disaster information transmission are configured in each receiving device and configured to continuously perform a status check therebetween, it is possible to secure the discharging information at each receiving device. This has the advantage of ensuring the protection of human life and property.

In addition, according to the present invention, if a failure occurs in the unit itself as the main control for controlling the disaster broadcast transmission in the receiving device, the secondary controller unit is configured to immediately access the virtualization server to receive the disaster information to control the transmission; In addition, the virtual device is configured to automatically reconnect even when the virtual connection is abnormally blocked, so that disaster information can be more securely transmitted from the receiving device, thereby protecting human life and property more securely. It is effective.

1 is a block diagram of a virtualization-based disaster broadcasting system according to an embodiment of the present invention.
2 is an operation configuration diagram of a virtualization-based disaster broadcasting system according to an embodiment of the present invention.
3 is a detailed configuration diagram of FIG. 2.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of a virtualization-based disaster broadcasting system of the present invention having the above problems, solutions and effects.

In this process, the size or shape of the components shown in the drawings may be exaggerated for clarity and convenience of description. In addition, terms that are specifically defined in consideration of the configuration and operation of the present invention may vary depending on the intention or custom of the user or operator.

The present invention relates to a virtualization-based disaster broadcasting system, and when connected to a transmission server anytime, anywhere, or connected to a virtualization server, it is possible to transmit and receive disaster broadcasting between specific equipment, thereby protecting the lives and property of the people in real time. There is a big purpose.

1 is a block diagram of a virtualization-based disaster broadcasting system according to an embodiment of the present invention.

As shown in FIG. 1, the virtualization-based disaster broadcasting system 100 according to an embodiment of the present invention includes a transmission server 10 for transmitting disaster information for disaster broadcasting, and a receiver connected to receive the disaster information. Receiving the disaster information directly from the virtualization server 30 and the transmission server 10 to provide or connected to the virtualization server 30 to receive the disaster information to transmit through the output device 70 such as a speaker It comprises a receiving device 50.

The transmission server 10 may transmit disaster information collected by itself or disaster information provided by a separate disaster information collecting device (not shown) or a disaster information broadcasting device (not shown) only to the virtualization server 30, In addition, the transmission server 10 transmits the disaster information to the receiving device 50 to be broadcasted first, and also necessarily transmits to the virtualization server 30.

In the former case, the reception device 50 is completely constructed or configured. In this case, the reception device 50 receives the disaster information by simply connecting to the virtualization server 30 to receive the output device. The transmission can be made through 70. In the latter case, this may also be the case when the receiving device 50 is newly constructed or configured, but the existing receiving device that receives and broadcasts disaster information from the transmission server 10 without being connected to the virtualization server 30. In this case, the receiver 50 may receive and transmit disaster information transmitted from the transmission server 10 in a general situation. If a failure occurs, the disaster information may be received and transmitted through the output device 70 by accessing the virtualization server 30 through the upgraded and added separate controller unit.

The present invention controls the latter so that the receiver 50 can receive and transmit the disaster information transmitted from the transmission server 10 by default, and a disaster occurs to transmit the disaster broadcast in this manner. In case it is not possible, the separate controller unit adopts a technical configuration that can be virtually connected to the virtualization server 30 to receive the disaster information and send it through the output device 70.

The virtualization server 30 receives the disaster information transmitted by the transmission server 10 and provides the received disaster information to the receiving device 50 where the virtualization connection is made. Specifically, the virtualization server 30 receives the disaster information from the transmission server 10, and provides the disaster information only to the receiving devices 50 connected to it. That is, unless the virtual server 30 receives a special control message, when the disaster information is received from the transmission server 10, the virtualization server 30 immediately provides the reception device 50 connected to itself.

However, the receiving device 50 according to the present invention does not initially connect to the virtualization server 30, but directly receives the disaster information transmitted from the transmission server 10 to be transmitted through the output device 70. Since the control is performed so that a failure occurs and is not connected to the virtualization server 30, the disaster information transmitted to the virtualization server 30 is not provided. Of course, the other receiving device 50 may be connected to the virtualization server 30, in which case the virtualization server 30 receives the disaster information transmitted from the transmission server 10 and the other receiving device connected to the virtualization. Provide to 50.

The virtualization server 30 provides the disaster information transmitted from the transmission server 10 to the reception apparatuses 50 connected to the same, and stores the disaster information in a storage unit (not shown) that the user has. In response to the request of the receiving device 50 or a determination thereof, the receiving device 50 may provide disaster information stored in the storage unit to the receiving device 50.

The virtual server 30 may be configured in plural, and when the virtualization server 30 includes a plurality of virtual servers 30, the plurality of virtual servers 30 may be controlled under the control of a connection broker (CB) manager 90. Any one of the virtualization servers 30 may be assigned and connected to the assigned virtualization server through authentication.

As described above, the reception apparatus 50 receives the disaster information transmitted from the transmission server 10 or the disaster information provided by accessing the virtualization server 30 and receives the disaster information through an output device 70 such as a speaker. Send it out. That is, the receiving device 50 may directly receive the disaster information from the transmission server 10 and transmit the disaster information through the output device 70 such as the speaker, or may virtually access the virtualization server 30 to the The disaster information transmitted by the transmission server 10 may be provided through the virtualization server 30 and transmitted through the output device 70 such as the speaker.

However, in the former case, it is a disaster information sending process that proceeds in a situation where the first receiving device 50 does not have a failure. In the latter case, when a failure occurs, it is necessary to ensure the security of receiving and sending disaster information. To this end, a separate controller unit is connected to the virtualization server to receive and transmit disaster information.

That is, when the virtualization-based disaster broadcasting system 100 according to the present invention fails to receive and transmit disaster information directly from the transmission server 10 due to a failure, it is always necessary to access the virtualization server 30 to transmit the situation. The disaster information transmitted by the server 10 should be provided through the virtualization server 30 to be transmitted through the output device 70 such as the speaker.

The reception device 50 is a device that can be constructed or installed where a disaster broadcast transmission is required, and means a device capable of virtual access, but in a broader sense, it can only access the virtualization server 30 to receive disaster information. If so, it may also include a mobile device that can access the virtualization server anywhere. Therefore, if the reception device 50 can access the virtualization server 30 anytime and anywhere, the reception device 50 can be widely applied without being limited to a fixed device or a mobile device.

The virtualization-based disaster broadcasting system according to the embodiment of the present invention having the above-described configuration may be implemented in two ways, and the disaster broadcasting may be performed through different operations.

Specifically, in the virtualization-based disaster broadcasting system according to an embodiment of the present invention, first, the disaster of the implementation and operation that the receiving device 50 is necessarily connected to the virtualization server 30 to receive and transmit the disaster information Secondly, the reception apparatus 50 receives and transmits the disaster information directly from the transmission server 10 in a general case, and transmits the disaster information to the virtualization server 30 when a failure occurs in itself. It may be configured as a disaster broadcast according to an implementation and operation of accessing and receiving the disaster information.

In the latter case, that is, when the receiving device 50 is normal, the disaster information is directly received and transmitted from the transmission server 10, and in the case of a failure thereof, the present invention accesses the virtualization server 30 to provide the disaster. The present invention relates to a virtualization-based disaster broadcasting system that receives and transmits information. Accordingly, the present invention is to perform only a separate minimum function to ensure the accuracy and reliability of the disaster broadcast transmission to the previously established or installed receiving device 50 for receiving and transmitting disaster information from the transmission server 10. A controller unit capable of accessing the virtualization server, and in the event of a failure, the controller unit may be automatically connected to the virtualization server to receive the disaster information and to be transmitted through the output device 70. Can be.

2 is a diagram illustrating the implementation and operation of a virtualization-based disaster broadcasting system according to an exemplary embodiment of the present invention, and FIG. 3 is a detailed block diagram of FIG. 2.

As shown in Figs. 2 and 3, the receiving device 50 according to the present invention is composed of two controller units. That is, the receiving device 50 applied to the present invention includes a main controller unit 51 and a sub controller unit 56. Although the main controller unit 51 and the sub controller unit 56 may be operated at the same time, in the present invention, only one of the two is operated so that the disaster information received and transmitted can be transmitted through the output device 70. do.

Specifically, the receiving device 50 according to the present invention comprises a main controller unit 51 and the sub-controller unit 56, the main controller unit 51 transmitted from the transmission server 10 Disaster information is immediately received and transmitted through the output device 70, and only when a failure occurs in the main controller unit 51, the secondary controller unit 56 accesses the virtualization server 30 to provide disaster information. It receives and outputs through the output device 70.

As such, the receiving device 50 includes the main controller unit 51 and the sub controller unit 56, but in the normal (normal) case, only the main controller unit 51 from the transmission server 10. Receives the transmitted disaster information immediately and controls it to be transmitted through the output device 70, the sub-controller unit 56 does not perform a separate disaster information receiving and sending operation, the minimum function (main controller unit The state of the normal state check function, which will be described later) only performs the sleep mode.

Therefore, even if the transmission server 10 transmits the disaster information not only to the reception device 50 but also to the virtualization server 30, the reception device, specifically, the sub controller unit 56 is configured to execute the virtualization server ( Since it is not virtually connected to 30, the disaster information cannot be provided from the virtualization server 30, and only the main controller unit 51 receives the disaster information transmitted from the transmission server 10 and It can transmit via the output device 70.

However, when a failure (breakage, power failure, operation stop, etc.) occurs in the main controller unit 51 itself that controls the transmission of the disaster information in such an initial configuration state, the transmission server 10 receives the disaster information. Even if transmitted to the main controller unit 51, the disaster information cannot be transmitted by the main controller unit 51. As a result, an irreversible situation can arise in which the disaster information relating to human life and property is not transmitted.

To this end, the receiving device 50 according to the present invention includes the secondary controller unit 56, so that when the failure occurs in the primary controller unit 51, the secondary controller unit 56 is the virtualization server 30 Access to receive the disaster information to be sent through the output device 70. The disaster information provided by the virtualization server 30 to the secondary controller unit 56 that is virtually connected is the same as the disaster information that the transmission server 10 wants to transmit to the main controller unit 51.

That is, the transmission server 10 not only transmits the disaster information to the receiving device 50, specifically, the main controller unit 51, but also necessarily transmits the same disaster information to the virtualization server 30. However, it is preferable that the transmission server 10 first starts transmitting the disaster information to the main controller unit 51 and then starts transmitting the disaster information to the virtualization server 30. Alternatively, the transmission server 10 may first transmit all of the disaster information to the main controller unit 51 and then transmit the disaster information to the virtualization server 30.

That is, the transmission server 10 preferably transmits the disaster information to the main controller unit 51 first, and then transmits the disaster information to the virtualization server 30 with a time difference. The reason for the transmission with a time difference as described above is that when the secondary controller unit 56 recognizes that the failure of the primary controller unit 51 occurs, it is automatically immediately connected to the virtualization server 30, but there is a certain short time. In order to prevent the loss or interruption of the disaster information provided to the secondary controller unit 51 due to the time for the automatic connection.

In this way, the secondary controller unit 56 is controlled to access the virtualization server 30 to receive disaster information and to send it through the output device 70 only when a failure occurs in the primary controller unit 51. do. As such, when the sub controller unit 56 determines that the main controller unit 51 has failed, the sub controller unit 56 immediately attempts to connect to the virtual server 30, and then the CB manager 90 is involved in the virtual server. 30, and allows the secondary controller unit 56 to be connected to the assigned virtualization server 30 through authentication.

Specifically, since the secondary controller unit 56 is connected to the virtualization server 30, in principle, the secondary controller unit 56 attempts a virtualization connection to the virtualization server 30 through login information or the like. Then, the CB manager 90 allocates one virtual server among a specific virtual server or a plurality of virtual servers, and the sub controller unit 56 connects to the allocated virtual server 30 through an authentication procedure. Allow to do

When the secondary controller unit 56 of the receiving device 50 accesses the virtualization server 30 and maintains a normal connection state through the virtualization connection process, the virtualization server 30 is connected to the transmission server 10. Disaster information transmitted from the controller is provided to the secondary controller unit 56, and the main controller unit 56 controls the disaster information to be transmitted through the output device 70.

In summary, even if a failure occurs in the primary controller unit 51, since the secondary controller unit 56 may perform a virtualization connection to the virtualization server 30, disaster information is subsequently transmitted in the transmission server 10. Is broadcasted, the virtualization server 30 may provide the disaster information to the secondary controller unit 56 that maintains the virtualization connection state, and then the secondary controller unit 56 outputs the disaster information to the output. Control to be transmitted through the device 70.

As a result, even if a failure occurs in the main controller unit 51 which has been performing control so that the disaster information transmitted from the transmission server 10 can be received and transmitted, the secondary controller unit 56 immediately returns the virtualization server ( 30 can be automatically connected, so that disaster information broadcasted later can be received and transmitted. Therefore, it is possible to reliably protect human life and property by increasing the security of disaster broadcast transmission.

As described above, when a failure occurs in the primary controller unit 51, the secondary controller unit 56 is automatically connected to the virtualization server 30 so that the transmission of the disaster information can be secured. Even when the disaster information transmission is controlled by the main controller unit 51, the sub controller unit 56 needs to maintain a function capable of at least checking whether the main controller unit 51 is in a normal state. . That is, in this case, the sub controller unit 56 only performs the function of checking the state of the main controller unit 51, and does not perform any other function. Thus, the secondary controller unit 56 can be configured with only minimal hardware and software, and can minimize unnecessary power consumption.

As described above, in order for the sub controller unit 56 to check the state of the main controller unit 51, the sub controller unit 56 is periodically connected to the main controller unit through the sub state confirmation module 58. The normal status check message is transmitted to the main status check module 53 of 51). Then, the main state checking module 53 of the main controller unit 51 sends an ACK message to the sub state checking module 58 of the sub controller unit 56 in response to the normal state checking message. send. Then, the sub state confirmation module 958 of the sub controller unit 56 determines that the main controller unit 51 maintains the normal state through the ACK message, and checks the normal state again in the next cycle. Repeat the operation of sending the message.

However, when a failure occurs in the main controller unit 51, the main state checking module 53 of the main controller unit 51 may generate and transmit the ACK message in response to the normal state checking message. none. In this case, since the sub-state confirmation module 58 of the sub-controller unit 56 does not receive the ACK message, the sub-server state checking module 58 immediately proceeds to the process of automatically connecting to the virtualization server 30 to the transfer server ( Receives the disaster information transmitted from the 10) through the virtualization server 30 and controls to be transmitted through the output device 70.

As such, the sub controller unit 56 periodically transmits a steady state confirmation message to the main controller unit 51, and when the ACK message is not received from the main controller unit 51. The controller unit 51 determines that a failure has occurred and automatically connects to the virtualization server 30. Therefore, even after the disaster information is broadcasted in the transmission server 10, the sub controller unit 56 receives the disaster information from the virtualization server 30 and transmits the same through the output device 70. can do.

According to the virtualization-based disaster broadcasting system constituting the implementation and operation according to the present invention described above, the receiving device 50 can be upgraded and configured to receive and transmit disaster information by accessing the virtualization server 30. Therefore, the time, effort and cost for configuring the upgrade of the receiving device 50 can be saved, and the receiving device 50 connected to the virtualization server 30 anytime and anywhere can receive the disaster broadcast. have.

In addition, according to the present invention, since the controller unit 51, 56 for controlling the discharging of the disaster information is configured in the receiving device 50, the receiving device 50 is configured to continuously perform a status check therebetween. Disaster information transmission can be secured in the country, which makes it possible to reliably protect human life and property.

The virtualization-based disaster broadcasting system constituting the implementation and operation according to the present invention described above needs to further increase the security of the disaster broadcast transmission, and it is necessary to implement such that the disaster broadcast can be transmitted without interruption as much as possible.

To this end, the main controller unit 51 constituting the receiving device 50 according to the present invention comprises a main state checking module 53, the secondary controller unit 56 is a secondary connection module 57 ), A sub state confirmation module 58 and a sub connection information management module 59 are configured.

As described above, when the disaster information occurs in the normal operation state of the main controller unit 51, the disaster information is sent out through the output device 70 by the main controller unit 51. In this state, that is, in a state in which the main controller unit 51 can normally receive and send disaster information from the transmission server 10, as described above, the secondary controller unit 56 is at least the main controller unit ( Check the status of 51).

Specifically, the sub state confirmation module 58 of the sub controller unit periodically transmits a normal state confirmation message to the main state confirmation module 53 of the main controller unit. Then, the main status check module 53 transmits an ACK message to the sub status check module 58. Through this process, the sub state confirmation module 58 may check whether the main controller unit 51 is in a normal state.

If a failure occurs in the main controller unit 51, since the main state checking module 53 is also inoperable, the main state checking module 53 is connected to the sub state checking module 58. (ACK) Message cannot be generated and transmitted. Then, since the sub-state confirmation module 58 cannot receive the ACK message, it determines that the main controller unit 51 has a failure. Of course, since there is a possibility that a data transmission / reception failure between the main status checking module 53 and the sub status checking module 58 may occur, the sub status checking module 58 transmits a normal status checking message again, If the ACK message is not received within the terminal, it may be determined that a failure has occurred in the main controller unit 51.

When it is determined that a failure has occurred in the main controller unit 51, the sub state confirmation module 58 transmits a failure occurrence message to the sub connection module 57 of the sub controller unit. Then, the secondary access module 57 connects to the allocated virtualization server 30 through an authentication procedure under the control of the CB manager 90.

Specifically, the secondary connection module 57 allows the secondary controller unit 56 to access the virtualization server 30. For example, when the secondary controller unit 56 attempts an automatic connection through a login or the like in order to make a virtual connection to the virtualization server 30, the secondary connection module 56 performs the CB manager 90. Under the control of the virtualization server 30 performs a virtual connection.

When the secondary access module 56 attempts to access the virtualization server 30, the CB manager 90 performs user authentication by the authentication module 91 and virtualizes by the monitoring and assignment module 96. A server 30 is assigned to allow the secondary controller unit 56 to be virtually connected to the assigned virtualization server 30 by the secondary connection module 56.

In this state, when the transmission server 10 transmits the disaster information to the virtualization server 30, the disaster information processing unit 31 of the virtualization server 30 is transferred from the monitoring unit 36 of the virtualization server 30. Unless a separate control message is received, the disaster information is directly provided to the virtual controller connected to the secondary controller unit 56. Then, the secondary controller unit 56 controls the disaster information to be transmitted through the output device 70.

By the way, it is preferable that the secondary controller unit 56 is connected to the virtualization server 30 set in advance. That is, it is preferable that the secondary controller unit 56 does not access the virtualization server allocated by the CB manager 90 every time the connection is made, but rather connects to the virtualization server previously assigned in a policy.

The reason for this is that when the main controller unit 51 fails, the secondary controller unit 56 can be connected to the virtualization server 30 as soon as possible, so that the main controller unit 51 immediately fails. This is to rule out the possibility that the disaster information that can be broadcast cannot be transmitted. In addition, when a failure occurs while the main controller unit 51 transmits the disaster information, the main controller unit 51 is to minimize the interruption or loss of the disaster information.

To this end, the sub controller unit 56 includes a sub connection information management module 59 that stores and manages preset connection information. The connection information includes address information (IP address, virtual machine, etc.) of the virtualization server 30 to which the sub controller unit 56 is to be connected, and login information (ID, password) of the user. The login information of the user is login information given to the receiving device.

In this manner, since the sub-information management module 59 stores and manages address information (IP address, virtual machine, etc.) of the virtualization server 30 previously assigned and user login information (ID, password), When the sub connection module 57 determines that a failure has occurred in the main controller unit 51 by the sub state checking module 58 and receives a failure occurrence message, the sub connection module 57 stores the connection stored in the sub connection information management module 59. Information may be automatically connected to the pre-allocated virtualization server 30 using the information.

On the other hand, the virtualization server 30 and the disaster information processing unit 31 and the virtualized connected receiving apparatus for providing the disaster information received from the transmission server 10 to the receiving apparatus 50 virtually connected to itself And a monitoring unit 35 for monitoring the changed state or the normal state of 50. The monitoring unit 36 may check whether there is a change state or a normal state of the connected receiving device through simple message transmission and reception with the receiving device 50. For example, the same method as the checking method between the main status checking module 53 and the sub status checking module 58 may be applied. That is, when the ACK message is received, it may be determined as a normal state or a virtual server connection state. If the ACK message is not received, the situation may be changed to determine an abnormal state or a connection disconnection state.

Even if a failure occurs in the main controller unit 51 through such a configuration and operation, since the secondary controller unit 56 can be virtually connected to the same virtualization server 30, the transmission security of the disaster broadcast Can improve.

On the other hand, while the secondary controller unit 56 is connected to the virtualization server 30 to perform the transmission control for the disaster broadcast, the main controller unit 51 performs reset, replacement, maintenance, power supply, and the like. Can be restored. As such, when the main controller unit 51 is restored, the main controller unit 51 may be restored to its original state. That is, when the main controller unit 51 is restored, the main controller unit 51 receives the disaster information from the transmission server 30 again to control the disaster broadcast to be transmitted, and the secondary controller unit ( 56 is preferably restored to a state of checking whether the main controller unit 51 is in a normal state.

There may be various ways to do this. For example, even when the sub controller unit 56 is connected to the virtualization server 30, the sub state checking module 58 periodically checks whether the main state checking module 53 is in a normal state. . When the sub state confirmation module 58 transmits the normal state confirmation message, the main state confirmation module 53 acknowledges the acknowledgment in response to the normal state confirmation message because the main controller unit 51 has been restored. ) You can create and send a message.

Then, the secondary controller unit 56 causes the secondary state confirmation module 58 to transmit a sleep mode switch message to the primary state confirmation module 53, and the secondary control unit 56 transmits the virtualization server ( The session connection with the terminal 30 is terminated, and the sub status confirmation module 58 ends all functions other than the function of checking the presence or absence of the normal status with the main status confirmation module 53.

When the main state checking module 53 receives the sleep mode switch message from the sub state checking module 58, the main state checking module 53 transmits a normal operation start message to the main controller unit 51. Then, when the main controller unit 51 receives the disaster information from the transmission server 10, the main controller unit 51 controls it to be transmitted through the output device 70.

On the other hand, the virtualization-based disaster broadcasting system 100 related to the implementation and operation according to the present invention described above, when the reception device 50 itself, specifically, the main controller unit 51 has a failure, transmission security of disaster broadcasting It is about ways to improve. However, in the state in which the sub-controller unit 56 of the receiving device 50 is connected to the virtualization server 30, abnormal connection blocking may occur instead of intentional termination. In this case, it is necessary to allow the secondary controller unit 56 to automatically reconnect to the virtualization server 30.

To this end, the CB manager 90 is responsible for allocating the virtualization server to the receiving device 50, specifically, the secondary controller unit 56 that performs the virtualization connection according to the user's request. More specifically, the CB manager 90 checks the operating state of the authentication module 91 and the virtualization server 30 that allow the connection between the sub controller unit 56 and the virtualization server 30 through user authentication. And a monitoring and assignment module 96 for monitoring and assigning the virtualization server 30 to the secondary controller unit 56.

The authentication module 91 checks the access authority of the user through login authentication of a user who wants to access the virtual server 30 so that only an authorized user accesses the virtualization server 30, and the virtual machine information of the virtual server 30 to be accessed. It is responsible for allowing the allocation of arbitrary virtual machines through. The authentication module 91 also plays a role of setting an environment according to user account information so that the user can access again at a desired time when the use of the virtual machine assigned to the user ends.

The monitoring and assignment module 96 monitors and grasps the real-time operating state of the virtualization server to allocate an optimal virtualization server 30 to the secondary controller unit 56, and the virtualization server 30 Real-time monitoring and grasp of resource allocation status, usage information, and use of the generated virtual machines, and allocates the optimal virtualization server 30 to the secondary controller unit 56 using the monitoring and grasping information. .

The sub-controller unit 56 provided in the receiving device 30 monitors a communication state when connected to the virtualization server 30 and determines whether to disconnect abnormally when the connection is blocked. In this case, an operation of automatically reconnecting to the same virtualization server 30 in which connection is blocked may be performed.

Accordingly, the administrator may automatically reconnect without reconnecting without recognizing that the connection between the receiving device 50 and the virtualization server 30 in use is temporarily interrupted. Therefore, it is possible to further shape the security of the disaster information transmission by minimizing the possibility of interruption or loss of the disaster information.

Here, although automatic reconnection is possible by the operation of the secondary controller unit 56, automatic reconnection may be further ensured by the cooperation of the monitoring unit 35 of the virtualization server 30. The monitoring unit 36 receives the notification to the CB manager 90 when a notification that abnormal blocking is transmitted by the receiving device 50 after the sub-controller unit 56 is connected to the virtualization server 30. It is responsible for notifying that the device 50 has been abnormally blocked. In this case, the monitoring unit 36 is responsible for switching to the standby state so that the secondary controller unit 56 reconnects without ending the session.

In addition to the above-described operation, the sub-state confirmation module 58 of the sub-controller unit 56 further performs a role of monitoring a communication state when the receiving device 50 accesses the virtualization server 30. The sub state confirmation module 58 determines whether a normal block or an abnormal block is detected when the connection block is detected. The determination result is transmitted to the secondary access module 56, and the secondary access module 56 automatically reconnects to the blocked virtualization server 30 when it is determined as abnormal blocking.

The sub state confirmation module 58 stores reference communication state information when the receiving device 50 and the virtualization server 30 normally connect, and the receiving device 50 connects to the virtualization server 30. When it starts, the communication speed of the receiving device 50 is monitored and grasped to monitor in real time whether it matches the stored reference communication state information.

Here, the reference communication state information may be set based on a communication speed when the receiving device 50 first accesses the virtualization server 30. If the communication environment changes, the reference communication state information may be set. It can be updated and managed.

When the sub-state confirmation module 58 does not meet the standard communication status information due to a sudden speed drop as a result of real-time monitoring and grasping, or there is no data transmission / reception regarding the check of the normal state transmitted by the monitoring unit 36 for a predetermined time When the connection confirmation request is transmitted to the virtualization server 30 and there is no response for a predetermined time, it may be determined that the connection is blocked.

The sub-state confirmation module 58 determines whether the connection blocking is a temporary abnormal connection blocking or a normal connection blocking due to a poor communication state or an error of the receiving device 50 when the connection blocking is detected as a result of the monitoring.

When the connection connected between the receiving device 50 and the virtualization server 30 is normally blocked, the receiving device 50 blocks the connection through logout to terminate the connection, or powers the client terminal without logging out. Sometimes it blocks. On the other hand, when the connection is abnormally blocked, the connection is blocked regardless of the user's intention, such as a poor communication state or a temporary operation error of the receiving device.

When the connection state is detected, the sub-state confirmation module 58 checks whether the reception device 50 requests to log out, checks whether the power-off is requested, and determines that the connection is abnormal when there is no request.

The secondary connection module 57 stores and manages connection information of the virtualization server 30 allowed from the CB manager 90 when the reception device 50 accesses the virtualization server 30. When it is determined that the abnormal access is blocked by the sub-state check module 58, the stored access information is retrieved and reconnected to the same virtualization server 30.

Here, the access information may include address information (IP address, virtual machine, etc.) of the virtualization server 30 and login information (ID, PASSWORD) of the user. Therefore, when abnormal blocking is detected, the secondary access module 57 requests reconnection to the same virtualization server 30 before blocking using the stored access information. Here, since it may take time until the connection is disconnected and reconnection is possible, the reconnection request may be periodically transmitted until reconnection is possible.

If the monitoring unit 36 operates in the virtualization server 30, and if it is determined that the connection is disconnected without a normal logout as a result of the monitoring, the session is disconnected, the session is not immediately terminated, and the connection blocking cause confirmation request is not attached. It can be transmitted to the status check module, and terminates the session when a notification that a normal connection is blocked is received from the secondary controller unit, but if there is no response, the session is determined to be abnormal and abnormally blocked with the receiving device 50 to the CB manager 90 In addition, the monitoring and assignment module 96 of the CB manager 90 provides access information so as to automatically reconnect to the virtualization server to which the secondary controller unit has been blocked.

In general, when the connection is abnormally blocked, since the session connected to the virtualization server 30 is terminated, the user must be assigned to the virtualization server 30 through login authentication again in order to access again. In such a case, since the rapid virtual reconnection cannot be performed, if the disaster information is transmitted from the transmission server 10 in the meantime, a problem occurs that the disaster information cannot be received normally from the receiving device.

However, according to the present invention, the secondary access module receives the previous access information from the CB manager 90 without the user having to recognize the disconnection at the time of abnormal access disconnection and without re-connecting the user after the login authentication. Since the automatic reconnection is possible, not only convenience is greatly increased from the user's point of view, but also there is an advantage of enabling accurate and reliable reception of disaster information related to human life and property.

Although embodiments according to the present invention have been described, these are merely exemplary, and those skilled in the art will understand that various modifications and equivalent ranges of embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention will be defined by the following claims.

10: transport server 30: virtualization server
31 disaster information processing unit 36 monitoring unit
50: receiving device 51: main controller unit
53: main status check module 56: secondary controller unit
57: negative connection module 58: negative status check module
59: secondary connection information management module 70: output device
90: CB Manager 91: Authentication Module
96: monitoring and allocation module 100: virtualization-based disaster broadcasting system

Claims (3)

In the disaster broadcasting system,
A transmission server for transmitting disaster information to the main controller unit of the receiving device and the virtualization server; A virtualization server that receives the disaster information and provides the disaster information to a receiving device to which a virtualization connection is made; It includes a receiving device for receiving the disaster information transmitted from the transmission server or the disaster information provided by accessing the virtualization server and transmits through the output device,
The receiving device includes a main controller unit and a sub controller unit, and primarily receives the disaster information transmitted from the transmission server by the main controller unit and transmits it through the output device, and the main controller unit has a failure. Secondly, the secondary controller unit connects to the virtualization server to receive disaster information and sends it through the output device only when it occurs.
The secondary controller unit periodically transmits a steady state confirmation message to the primary controller unit, and determines that a failure has occurred in the primary controller unit when the ACK message is not received from the primary controller unit. Automatic connection,
When the secondary access module of the secondary controller unit attempts to access the virtualization server for the first time, the user authentication is performed by the authentication module, the virtual access server is allocated by the monitoring and assigning module, and the secondary access module of the secondary controller unit is used. Further comprising a CB manager allowing the secondary controller unit to be virtually connected to the assigned virtualization server,
The main controller unit is configured to include a main status confirmation module for transmitting an acknowledge message when the normal status confirmation message is transmitted from the sub status confirmation module of the sub controller unit,
The secondary controller unit automatically connects to the pre-allocated virtualization server using the connection information stored in the secondary access information management module when a failure occurrence message is transmitted from the secondary state checking module. Sending a status check message to check whether the main controller unit is in a normal state, and if it is determined that a failure has occurred in the main controller unit, a sub-status check module and a pre-allocated virtualization to transmit a failure message to the secondary access module And a secondary connection information management module that stores and manages connection information including address information of a server and login information of a user.
The virtualization server includes a disaster information processing unit for providing the disaster information received from the transmission server to a receiving device virtually connected to the monitoring device and a monitoring unit for monitoring a change state or a normal state of the virtually connected receiving device. Is composed,
When the sub-controller unit is connected to the virtualization server, and the sub-status check module checks whether the main status check module and the normal state or not, and receives the Ack message, the sub-controller unit by the sub-status check module A sleep mode switch message is transmitted to the main status checking module, the session connection with the virtualization server is terminated, and the sub status checking module performs all functions other than the function of checking whether the main status checking module and the normal status are present. To exit,
The main state confirming module transmits a normal operation start message to the main controller unit when receiving the sleep mode switch message from the sub state confirming module, and the main controller unit outputs a device when disaster information is received from the transmitting server. Disaster-based disaster broadcasting system characterized in that the control to be transmitted through.
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