KR101796216B1 - IoT­based Emergency Broadcasting System - Google Patents

Abstract

The present invention relates to a disaster broadcasting system based on Internet of things (IoT). Particularly, the present invention relates to the IoT-based disaster broadcasting system capable of making voice data related to disaster broadcasting to be transmitted not only by a UDP-based IP telephony system but also by a TCP-based network streaming system, wherein one of UDP-based voice data and TCP-based voice data is transmitted through a speaker. Accordingly, the IoT-based disaster broadcasting system can achieve speed and accuracy of dispatching a disaster broadcast, and further assures accurate dispatch of a disaster broadcast. The IoT-based disaster broadcasting system of the present invention comprises the following configuration means: an IoT transmitting server for transmitting voice data related to a disaster broadcast to the UDP-based IP telephony system and the TCP-based network streaming system, respectively; and an IoT receiving terminal for transmitting via a speaker either one of UDP-based voice data and TCP-based voice data received through a transmission network from the IoT transmitting server.

Description

[0002] IoTbased Emergency Broadcasting System [

The present invention relates to a disaster broadcasting system based on Internet of Things (IOT), and more particularly to a UDP-based IP telephone system and a TCP-based network streaming system The UDP-based voice data and the TCP-based voice data are transmitted through the speaker. Thus, it is possible to achieve quickness and accuracy of transmission of the disaster broadcast, and furthermore, to ensure accurate transmission of the disaster broadcast Based disaster broadcasting system.

Disaster broadcasting system is a broadcasting system aimed at disaster prevention and prevention education such as preparation for emergency disaster, evacuation and personnel deployment by spreading accurate and precise situation propagation in the event of disaster while maintaining the management system of the army, System.

Such a disaster broadcasting system can guide disaster occurrence situation and evacuation to the entire jurisdiction area collectively, and it is possible not only to reduce confusion of position system, but also to be able to evacuate people in the jurisdiction area quickly and safely have.

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

First, the conventional disaster broadcasting system has a difficulty in transmitting disaster information promptly by guiding the disaster occurrence situation to the corresponding jurisdiction area through analog unidirectional communication.

Secondly, the conventional disaster broadcasting system can not directly monitor the equipment in the jurisdiction, that is, the equipment at the remote place, from the central control station such as the county office directly, There is a problem in that time and manpower are generated due to the necessity of judging the presence or absence thereof, and it is difficult to promptly follow up.

Finally, the conventional disaster broadcasting system broadcasts disaster related to the earth using the existing UHF or VHF radio frequency. In this case, it is not possible to broadcast disaster related to the jurisdiction due to crosstalk and operation error due to the change of the temperature of the area or the frequency interference used by the military units, and the restriction of the propagation power between the main equipment and the local equipment The installation distance between the main equipment and the local equipment becomes short, so that there is a problem that a lot of equipment must be installed.

In order to solve such a problem, Korean Patent Registration No. 10-1210592 (Disaster and Information Broadcasting System) has been proposed. The prior art document guides disaster broadcasting using both UDP packets and TCP / IP packets.

However, in the above prior art document, the UDP packet is for transmitting voice data related to a disaster broadcast, and the TCP / IP packet is for transmitting control data only. That is, the prior art document only transmits a disaster broadcast using a UDP packet.

Similar to the prior art document, UDP-based disaster broadcast data transmission can achieve quickness of transmission of a disaster broadcast, but it has a problem in that it can not assure an accurate disaster broadcast in the case of packet loss due to various reasons such as a communication status failure.

Korean Registered Patent No. 10-1210592 (Dec. 11, 2012 announcement, title of invention: Disaster and announcement system)

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made to solve the above problems occurring in the prior art, and it is an object of the present invention to provide a UDP-based IP telephone system, Based disaster broadcasting system capable of achieving speed and accuracy of transmission of a disaster broadcast and further ensuring accurate dispatch of a disaster broadcast by configuring the disaster-based voice data to be transmitted through a speaker For that purpose.

In addition, the UDP-based voice data received first and the UDP-based voice data received first among the received UDP-based voice data and TCP-based voice data can be transmitted in a primary way to assure the promptness of transmission of the disaster broadcast. Based disaster broadcasting system in which the TCP-based voice data can be transmitted and the accurate disaster broadcast can be transmitted.

According to an aspect of the present invention, there is provided an ioT-based disaster broadcasting system, comprising: a UDP-based IP telephone system and a UDP- And an IoT receiving terminal for transmitting through the speaker any one of UDP-based voice data and TCP-based voice data received through the transmission network from the IoT transmission server, respectively, through the TCP-based network streaming method, .

Here, the IoT transmission server includes a conversion module for converting an analog disaster announcement speech signal into digital voice data, a UDP transmission module for outputting the digital voice data output from the conversion module to be transmitted in a UDP-based IP telephone system, A TCP transmission module for transmitting the digital voice data output from the conversion module in a TCP-based network streaming manner; and a transmission module for transmitting the digital voice data output from the conversion module to a primary And a transmission control module for controlling the TCP transmission module to be transmitted by the UDP transmission module and then to be transmitted secondarily by the TCP transmission module.

Here, the IoT receiving terminal includes a UDP receiving module for receiving UDP-based voice data transmitted through the transmission network, a verification module for determining whether the UDP-based voice data includes a QoS code, a TCP- And a buffer module for buffering the TCP-based voice data. When it is determined by the verification module that the QoS code is included in the UDP board voice data, the UDP-based voice data is output through the output module And a reception control module for controlling the buffered TCP-based voice data to be transmitted to the speaker through the output module when it is determined by the verification module that the QoS code is not included in the UDP board voice data, And a control unit.

Here, the reception control module determines the connection state between the output module and the speaker, and when it is determined that the connection is bad, the reception control module transmits the connection to the IoT transmission server through the transmission network.

The IoT transmission server further comprises a recording module for recording and storing the digital audio data converted by the conversion module.

According to the invention, the disaster broadcasting system of the present invention has the disadvantages that the voice data related to the disaster broadcasting is transmitted not only by the UDP-based IP telephone system but also by the TCP-based network streaming system, Data and TCP-based voice data are transmitted through a speaker. Therefore, it is possible to achieve quickness and accuracy of transmission of a disaster broadcast, and furthermore, it is possible to secure accurate transmission of a disaster broadcast.

In addition, the UDP-based voice data received first and the UDP-based voice data received first among the received UDP-based voice data and TCP-based voice data can be transmitted in a primary way to assure the promptness of transmission of the disaster broadcast. It is possible to transmit the TCP-based voice data temporally and accurately transmit a disaster broadcast.

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

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of an IoT-based disaster broadcasting system having the above-described problems, solutions and effects will be described in detail with reference to the accompanying drawings.

The sizes and shapes of the components shown in the drawings may be exaggerated for clarity and convenience. In addition, terms defined in consideration of the configuration and operation of the present invention may be changed according to the intention or custom of the user, the operator.

Disclosure of Invention Technical Problem [1] The present invention relates to a disaster-based broadcasting system based on the iOuti, and is capable of transmitting and receiving disaster broadcasts between specific equipments when only the Internet is connected anytime and anywhere.

For example, the ioT-based disaster broadcasting system applied to the present invention comprises an IoT transmission server 10 and an IoT reception terminal 30, which are connected to each other via the Internet / network, and the IoT transmission server 10, It is possible to transmit a disaster broadcast to a specific area by transmitting various signals to the IoT receiving terminal 30 through various transmission protocols and to transmit the disaster broadcast to a speaker 50 connected to the IoT receiving terminal 30 Or if an abnormality occurs in the internal configuration of the IoT receiving terminal 30, the status information on the IoT receiving terminal 30 is transmitted to the IoT transmission server 10 through the transmission network, And the like.

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

1, an ioTi based disaster broadcasting system 100 according to an embodiment of the present invention includes an IoT transmission server 10 for transmitting voice data related to a disaster broadcast, And an IoT receiving terminal 30 that receives voice data on a disaster broadcast and sends it through a speaker 50

The IoT transmission server 10 transmits voice data related to a disaster broadcast to a UDP-based IP telephone system and a TCP-based network streaming system, respectively. That is, the IoT transmission server 10 does not transmit disaster-related voice data through one transmission method, but uses the two different transmission methods (UDP transmission method and TCP transmission method) .

The UDP-based IP telephone system is a data transmission system applied in the IP-PBX system, and transmits voice data related to disaster broadcasting based on UDP. The UDP (user datagram protocol) is a method of sending information unilaterally from one side to another when exchanging information on the Internet. In other words, it is a communication protocol that transmits the data unilaterally from the sender without going through the signal process that the information is sent or received when the information is exchanged on the Internet.

On the other hand, the TCP-based network streaming method is a method of transmitting data by streaming and transmitting voice data related to disaster broadcasting based on TCP. The Transmission Control Protocol (TCP) divides the data into several packets for IP processing and reassembles the packets into complete data at the destination. In order to guarantee packet transmission, ACK can be used to guarantee data reception. That is, there is an advantage that reliability of data transmission can be assured.

Thus, unlike TCP, UDP is not responsible for receiving data. This is because the sender has sent the information, but the sender does not need to care about whether the information arrived at the receiver in a timely fashion or whether the information content was reversed. Therefore, although it is less stable than TCP, the speed is much faster. TCP, on the other hand, is less reliable than UDP, but it can guarantee data transmission reliability.

As described above, the disaster-related voice data transmitted from the IoT transmission server 10 is received by the IoT receiving terminal 30. That is, the IoT receiving terminal 30 receives the UDP-based voice data and the TCP-based voice data respectively received from the IoT transmission server 10 via the transmission network (Internet / network) and receives the UDP- And transmits one of the TCP-based voice data through the speaker 50. [

The IoT receiving terminal 30 separately receives different transmission data, that is, UDP-based voice data and TCP-based voice data transmitted from the IoT transmission server 10, selects one of them, 50). Basically, if the rapid disaster broadcast transmission has priority, the UDP-based voice data is transmitted, and if the accurate disaster broadcast transmission has priority, the TCP-based voice data can be controlled to be transmitted.

As described above, the disaster-based disaster broadcasting system 100 according to the present invention transmits disaster-broadcast-related voice data in two different ways and transmits any one of the voice data through the speaker, It is possible to secure transmission of voice data concerning the broadcasting, thereby protecting the property and life of the people.

In addition, when the emergency I / O terminal 30 needs to transmit a disaster broadcast quickly, the UDP-based voice data can be directly transmitted through the speaker, and when accurate disaster broadcast transmission is required, the TCP-based voice data is transmitted through the speaker So that voice data related to disaster broadcasting can be selectively transmitted in response to various situations.

The disaster-based disaster broadcasting system 100 according to the present invention is a system for transmitting a disaster broadcast, and it is a top priority to protect the lives and property of the people. Therefore, the disaster- , And only if there is a problem with the accuracy of the transmission of the disaster broadcast, it is possible to transmit the voice data related to the accurate disaster broadcasting in the second place.

1, the IoT transmission server 10 includes a conversion module 11 for converting an analog disaster broadcast voice signal into digital voice data, a digital voice data outputting unit 11 for converting digital voice data output from the conversion module 11 into UDP Based digital voice data; a code insertion module 13 for inserting and transmitting a QoS code into the digital voice data to be output; The TCP transmission module 14 for transmitting the digital voice data through the TCP based network streaming method and the digital voice data output from the conversion module 11 are primarily transmitted by the UDP transmission module 12, And a transmission control module 16 for controlling the transmission by the TCP transmission module 14.

The conversion module 11 converts the generated analog disaster announcement speech signal into digital voice data and outputs the digital voice data. Specifically, when the transmission control module 16 detects that an analog disaster broadcast voice signal is input or generated, the transmission control module 16 converts the analog disaster broadcast voice signal into digital voice data through the conversion module 11. [ The analog disaster broadcast audio signal may be generated in the IoT transmission server 10 or may be transmitted from a separate voice generator connected by wire or wireless.

When the conversion module 11 converts voice data into voice data, the transmission control module 16 preferentially transmits the digital voice data by the UDP transmission module 12 in a UDP-based IP telephone system. At this time, the transmission control module 16 does not transmit the UDP-based voice data output from the UDP transmission module 12 directly through the transmission network, but can insert the QoS code by the code insertion module 13 .

The code insertion module 13 may insert a QoS code into only the first packet among the UDP voice data, insert a QoS code into only the first packet and the last packet, or insert a QoS code into all packets. In this case, one of various methods can be selectively applied according to the policy related to the data transmission and transmission / reception method. However, the QoS code is inserted into all packets considering the voice data related to the disaster broadcasting, and the IoT reception terminal 30 performs verification It is necessary to confirm whether or not it is correctly received.

After the transmission control module 16 controls the transmission of the UDP-based voice data by the UDP transmission module 12, the TCP transmission module 14 controls the transmission of the TCP-based voice data .

The transmission control module 16 does not control the TCP transmission module 14 to transmit TCP-based voice data after the UDP transmission module 12 transmits the voice data to UDP-based voice data Based voice data to the UDP transmission module 12 to control transmission of the TCP-based voice data to the TCP transmission module 14 when UDP-based voice data packet transmission is started.

As a result, the IOT receiving terminal 30 first receives the UDP-based voice data packet and then receives the TCP-based voice data packet. Further, the TCP-based voice data is received The UDP-based voice data may be received after all the UDP-based voice data has been received through the buffering process.

As described above, when the conversion module 11 converts the voice signal related to the disaster broadcasting into the digital voice data, the transmission control module 16 first reads the UDP-based voice data by the UDP transmission module 12 And controls the TCP transmission module 14 to start transmission of the TCP-based voice data.

When the UDP-based voice data and the TCP-based voice data are separately transmitted by the IoT transmission server 10 having the above-described configuration and operation characteristics, the IoT receiving terminal 30 transmits the UDP-based voice data and the TCP- Respectively. That is, the IOT receiving terminal 30 receives the UDP-based voice data from the UDP receiving module 31, and the TCP receiving module 33 receives the TCP based voice data.

1, the IoT receiving terminal 30 includes a UDP receiving module 31 for receiving UDP-based voice data transmitted through the transmission network, a UDP receiving module 31 for determining whether the UDP- A verification module 32, a TCP receiving module 33 for receiving TCP-based voice data transmitted through the transmission network, a buffering module 34 for buffering the TCP-based voice data, When it is determined that the QoS code is included in the substrate voice data, the UDP-based voice data is controlled to be sent to the speaker through the output module, and the verification module (32) A reception control module 36 for controlling the buffered TCP-based voice data to be output to the speaker 50 through the output module 35, It is configured to include.

The UDP receiving module 31 outputs UDP-based voice data in the UDP transmitting module 12 constituting the IoT transmitting server 10 under the control of the receiving control module 36, ), The UDP-based voice data transmitted through the transmission network after the insertion of the QoS code is sequentially received without an acknowledgment process.

The reception control module 36 does not allow the UDP-based voice data received through the UDP receiving module 31 to be transmitted directly through the speaker 50 via the output module 35, It is judged whether or not the QoS code is included.

Since the UDP-based voice data transmitted from the IoT transmission server 10 is transmitted with the QoS code inserted, if the UDP-based voice data is normally received without loss, the UDP- The UDP-based voice data will have the QoS code inserted, otherwise the QoS code will not be included.

If the UDP-based voice data is received through the UDP receiving module 31, then the TCP-based voice data transmitted from the TCP transmitting module 14 will also be received through the TCP receiving module 33. The TCP-based voice data received through the TCP receiving module 33 is continuously buffered and stored in the buffering module 34.

The UDP-based voice data, which is received first, is sent to the speaker (50) via the output module (35) in order to quickly transmit the voice data related to the disaster broadcast through the speaker (50) 50). Therefore, in this case, even though all the TCP-based voice data are received and are in the buffering state, they are not transmitted.

As a result of the verification by the verification module 32, if the QoS code is not inserted into the UDP-based voice data, the reception control module 36 determines that there is a loss or distortion of the UDP-based voice data, Remove it. That is, it ignores the received UDP-based voice data. For example, the connection between the UDP receiving module and the verification module is blocked, or the receiving operation of the UDP receiving module is blocked.

If the QoS code is not inserted in the UDP-based voice data as described above, the reception control module 36 controls the TCP-based voice data with the accuracy of voice data reception to be transmitted. Accordingly, the reception control module 36 receives the TCP-based voice data buffered in the buffering module 34 after being received through the TCP receiving module 33 and transmits the TCP-based voice data to the speaker 50 via the output module 35. [ So that it can be transmitted through the network.

That is, the reception control module 36 controls to transmit voice data related to the disaster announcement in a primary way. If it is determined that there is a problem in receiving the UDP-based voice data, The TCP-based voice data with reliable reception accuracy is transmitted in consideration of the fact that the accurate voice data related to the disaster broadcasting can be broadcasted.

As described above, the code insertion module 13 configuring the IoT transmission server 10 can insert a QoS code for each packet output from the UDP transmission module 12 and output the transmission. In this case, the verification module 32 constituting the IoT receiving terminal 30 also verifies whether a QoS code is inserted for each packet of the received UDP-based voice data.

In this case, it is necessary to insert a QoS code for each packet of the UDP-based voice data and to verify whether or not the QoS code is included. However, it is a necessary procedure considering that the transmission voice data is voice data related to disaster broadcasting. That is, since it is necessary to transmit the disaster broadcast corresponding to the information related to the life and property of the people with accurate contents, it is preferable to insert a QoS code for each packet of the UDP-based voice data and verify whether or not the QoS code is included .

As a result, when part of the UDP-based voice data is distorted or lost, the TCP-based voice data that can be transmitted with the correct contents is transmitted, so that the voice data related to the accurate content disaster broadcast can be transmitted to the public do.

According to the control of the reception control module 36, disaster-related voice data is transmitted through the speaker 50 via the output module 35. If the speaker 50 does not operate normally or the output If the connection state between the module 35 and the speaker 50 is not normal, the transmission of the disaster broadcasting is not performed, which may seriously affect the safety, life and property of the people.

Accordingly, the reception control module 36 determines the connection state between the output module 35 and the speaker 50. If it is determined that the connection is not good, the reception control module 36 transmits the connection state to the IoT transmission server 10 through the transmission network . Specifically, the reception control module 36 periodically determines whether the speaker is operating normally and whether the connection state between the output module and the speaker is normal. Whether or not the normal operation is determined can be determined by using any of the existing methods. For example, current flow detection through closed loop configuration can be used.

If the result of the determination is affirmative or abnormal, the reception control module 36 transmits the result to the transmission control module 16 constituting the IoT transmission server 10 through the transmission network. Then, the transmission control module 16 generates an alarm, or at the same time notifies the manager of the failure or abnormal state so that quick action can proceed.

Meanwhile, the transmission control module 16 may transmit the reset control data to the reception control module 36 through the transmission network when the voice data related to the disaster announcement can not be normally transmitted through the speaker due to a malfunction of the speaker . Then, the reception control module 36 initializes the speaker and / or the IoT receiving terminal 30.

In the case where the speaker is abnormal, the connection state is poor, or the malfunction of the IoT receiving terminal occurs, the voice data related to the disaster broadcasting can not be transmitted through the speaker. In this case, a disaster broadcast must be sent to the public, so re-transmission is necessary.

Therefore, the IoT transmission server 10 further includes a recording module 15 that can record the digital voice data converted by the conversion module 11 in preparation for a situation of retransmitting voice data related to disaster broadcasting, . That is, the IoT transmission server 10 may further include a recording module 15 for recording and storing the digital voice data converted by the conversion module 11.

Therefore, as described above, the erroneous operation of the IOT receiving terminal 30, the malfunction of the speaker, or the connection state between the output module and the speaker are momentarily defective, so that even if the disaster-related voice data can not be transmitted through the speaker, .

Specifically, when the reception control module 36 transmits the malfunction state information to the transmission control module 16, the transmission control module 16 causes the manager to restore the malfunction state, Is transmitted to the reception control module 36 and is initialized so that the digital voice data related to the disaster broadcast recorded in the recording module 15 can be retransmitted to the IoT receiving terminal 30, So that related voice data can be resent.

The transmission control module 16 controls the digital voice data recorded in the recording module 15 to be primarily transmitted as UDP-based voice data by the UDP transmission module 12, To be transmitted as TCP-based voice data. Since the following procedures and operations are the same as those described above, they are omitted.

Although the embodiments according to the present invention have been described, it is to be understood that various modifications and equivalent embodiments are possible without departing from the scope of the present invention. Accordingly, the true scope of the present invention should be determined by the following claims.

10: IoT transmission server 11: conversion module
12: UDP transmission module 13: code insertion module
14: TCP transmission module 15: recording module
16: Transmission control module 30: IoT receiving terminal
31: UDP receiving module 32: verification module
33: TCP receiving module 34: Buffering module
35: output module 36: reception control module
50: Speaker 100: IoT based disaster broadcasting system

Claims (5)

In an IoT-based disaster broadcasting system,
An IoT transmission server for transmitting voice data related to a disaster broadcast to a UDP-based IP telephone system and a TCP-based network streaming system, respectively; and an IoT transmission server for transmitting UDP-based voice data and TCP- And an IoT receiving terminal for transmitting either one through a speaker,
The IoT transmission server includes a conversion module for converting an analog disaster announcement speech signal into digital voice data, a UDP transmission module for outputting the digital voice data output from the conversion module to be transmitted in a UDP-based IP telephone system, A TCP transmission module for transmitting the digital voice data output from the conversion module in a TCP-based network streaming manner; and a transmission module for receiving the digital voice data output from the conversion module, And a transmission control module for controlling the TCP transmission module to transmit the UDP transmission module by the UDP transmission module,
Wherein the IoT receiving terminal comprises: a UDP receiving module for receiving UDP-based voice data transmitted through the transmission network; a verification module for determining whether a QoS code is included in the UDP-based voice data; And a buffer module for buffering the TCP-based voice data. When it is determined by the verification module that the UDP-based voice data includes the QoS code, the UDP-based voice data is output to the speaker through the output module And a reception control module for controlling the buffered TCP-based voice data to be output to the speaker through the output module when it is determined by the verification module that the QoS code is not included in the UDP-based voice data Respectively,
Wherein the code insertion module inserts a QoS code for each packet of UDP-based voice data output from the UDP transmission module and transmits the inserted QoS code, and the verification module verifies whether a QoS code is inserted for each packet of the received UDP- Wherein the reception control module controls the TCP-based voice data to be transmitted when there is a UDP-based voice data packet in which the QoS code is not inserted.
delete delete The method according to claim 1,
Wherein the reception control module determines a connection state between the output module and the speaker, and transmits the malfunction state information to the IoT transmission server through the transmission network when it is determined that the connection is inadequate. .
The method according to claim 1 or 4,
Wherein the IoT transmission server further comprises a recording module for recording and storing the digital voice data converted by the conversion module.

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