KR20210149453A - System for broadcasting with function of many channel and multi employing TCP and IP - Google Patents

Abstract

The present invention relates to a broadcasting system with a multichannel multiplex broadcasting function using a TCP and an IP. More specifically, the broadcasting system comprises: a plurality of speaker terminals installed in a number of different zones within the premises in the case of premises broadcasting and individually having an individual IP address to perform individual premises broadcasting in each zone; and a management information processing device controlling a premises broadcasting operation of the plurality of speaker terminals. Each of the plurality of speaker terminals includes a PLC controller having an IoT module interfacing with the management information processing device by IoT data for the premises broadcasting for each individual IP address, so that multichannel multiplex broadcasting is performed for each zone through the TCP and the IP under control of the management information processing device when the premises broadcasting is performed. Accordingly, multichannel multiplex broadcasting is performed by using the TCP and the IP, different broadcasting is performed in various forms at the same time for each zone, for each group or for different broadcasting when the premises broadcasting is performed.

Description

Broadcasting system with multi-channel multi-broadcasting function using TCP and IP {System for broadcasting with function of many channel and multi employing TCP and IP}

The content disclosed in this specification relates to the technical field of a premises broadcasting system, and relates to a technology for performing premises broadcasting through the Internet in various areas or regions.

Unless otherwise indicated herein, the material described in this section is not prior art to the claims of this application, and inclusion in this section is not an admission that it is prior art.

For example, in the event of casualties such as fire or natural disasters such as earthquakes, typhoons, and floods, most people are exposed to the current damage situation through news broadcasts.

In recent years, with the development of the Internet and smartphones, people are accessing news about human casualties or natural disasters in real time using smartphones.

However, as described above, as a problem of general TV broadcasting or the method using a smartphone, conventional TV broadcasting or smartphones are a huge coverage system by reporters and broadcasting stations, so it cannot be relayed in real time for each entire region, and It is done in the form of covering only a certain area.

Accordingly, since the conventional broadcasting system is far from the actual field situation of people living in a small area, such as nationwide, a broadcasting system suitable for each small area situation is required.

As a prior art document 1 for this purpose, in Korean Patent Registration No. 10-1041032, a repeater for transmitting a control image using web casting and an integrated control image providing system using the same,

It is connected to the servers of a plurality of control center control rooms, receives the image data displayed on the control panel screen of each control center control room, and converts the received image data into a common video streaming based on one common codec specified in advance. and a plurality of control video transmission repeaters that provide the converted common video streaming to a user terminal connected to a network system via a network system in a web casting method, and a user connected to the common video streaming transmitted from the plurality of video transmission repeaters By including a network system provided by a terminal, when a user accesses the network system through a user terminal and selects a desired channel of the control center control room, the control panel screen of the control center control room is displayed through a web casting method. It is characterized in that it is provided in real time.

Therefore, according to Prior Document 1, a repeater for transmitting a control image and a corresponding network communication network are installed in each small area, and an image through this is transmitted to a user terminal through the network to transmit the control situation in real time. It provides the advantage of being able to understand in real time.

However, in the prior art document 1 as described above, since it is necessary to install a repeater for transmission of a control image and a communication line corresponding thereto for each small area, it is a problem in terms of cost to install a repeater for a control image and a communication network in a wide range. There is this.

On the other hand, as a prior art document 2, in Republic of Korea Patent Registration No. 10-1380501 (registered on March 26, 2014), as described above, users belonging to each area can use mobile After shooting a relay video using a terminal, by uploading each relay video to a related relay server to be relayed, the advantage of relaying without installing a separate control video repeater as in Prior Document 1 above is providing

Here, the prior art document 2 provides the advantage that a user belonging to each region shoots a relay image using a mobile terminal, thereby allowing the relay to be performed without installing a separate control video repeater. Since it is difficult to transmit an image to a TV installed in the homes of people living in each small area, there is a problem in that, in reality, there is no choice but to watch the relayed image using a terminal such as a PC or a smart phone.

The disclosed content is multi-channel using TCP and IP, which allows multi-channel multi-broadcasting using TCP and IP to be different for each group or other broadcasts at the same time for each zone during intra-premises broadcast. An object of the present invention is to provide a broadcasting system with a multi-broadcasting function.

A broadcasting system having a multi-channel multi-broadcasting function using TCP and IP according to an embodiment,

In the case of premises broadcasting, a plurality of speaker terminals that are installed for a plurality of different zones within the premises and each have their own individual IP addresses to individually broadcast premises for each zone, and a management that controls the premises broadcasting operation of the plurality of speaker terminals information processing device; contains

In addition, each of the plurality of speaker terminals includes a PLC controller having its own IoT module that interfaces with the management information processing device as IoT data for premises broadcasting for each individual IP address, so that when broadcasting in premises It is characterized in that multi-channel multiplex broadcasting is performed for different zones through TCP and IP by the IoT module according to the control of the management information processing device.

According to the embodiments, by performing multi-channel multiplex broadcasting using TCP and IP, different broadcasts are performed in various forms at the same time for each zone or for each group or other broadcasts during premises broadcasting.

1 is a conceptual diagram to which a broadcasting system having a multi-channel multi-broadcasting function using TCP and IP according to an embodiment is applied;
FIG. 2A is a view showing the entire broadcasting system of FIG. 1; FIG.
FIG. 2B is a diagram illustrating the broadcasting system of FIG. 1 as an example; FIG.
3 is a block diagram showing the configuration of a speaker terminal applied to the broadcasting system of FIG.
4 is a flowchart sequentially illustrating the operation of the broadcasting system of FIG. 1;

1 is a conceptual diagram to which a broadcasting system having a multi-channel multiplex broadcasting function using TCP and IP according to an embodiment is applied.

As shown in FIG. 1 , in the broadcasting system according to an exemplary embodiment, when premises broadcasting is performed, a plurality of speakers are installed for a plurality of different zones within the premises and each have their own individual IP address and individually broadcast in each zone. The terminals 100-1, 100-2, 100-3, ... 100'-1, 100'-2, 100'-3, ... ) and a management information processing apparatus 200 thereof.

In this case, the broadcast system according to an embodiment additionally includes the speaker terminals 100-1, 100-2, 100-3, ... 100'-1, 100'-2, 100'-3, ... ). has its own external interface function, and provides the most comfortable classroom environment by interfacing oxygen concentration in each zone (eg, school classroom) to provide an alarm when oxygen is insufficient.

Each of the plurality of speaker terminals 100-1, 100-2, 100-3, ... 100'-1, 100'-2, 100'-3, ... ) is the management information processing device 200 . By having a PLC controller with its own IoT module that interfaces with each other as IoT data for premises broadcasting by its individual IP address, TCP and IP according to the control of the management information processing device 200 when broadcasting in premises Multi-channel multiplex broadcasting for different zones through For example, these multiple speaker terminals (100-1, 100-2, 100-3, ... 100'-1, 100'-2, 100'-3, ...) In the case of two school broadcasts, different broadcasts are made at the same time in each classroom.

The management information processing device 200 of the plurality of speaker terminals (100-1, 100-2, 100-3, ... 100'-1, 100'-2, 100'-3, ...) Control the premises broadcasting operation. In this case, the management information processing device 200 is different from the existing broadcasting system, and the system is simplified, and the broadcasting system is operated by frequently changing various programs.

2A and 2B are diagrams for explaining the broadcasting system of FIG. 1 .

Specifically, FIG. 2A is a diagram illustrating the entire broadcasting system of FIG. 1 , and FIG. 2B is a diagram illustrating the broadcasting system of FIG. 1 as an example.

As shown in FIG. 2A, the broadcasting system of FIG. 1 includes a plurality of speaker terminals 100-1, 100-2, 100-3, ..., 100-n-1, 100-n installed for each zone and , and a management information processing device 200 .

For example, in the broadcasting system of FIG. 1, as shown in FIG. 2B, a plurality of speaker terminals 100-1, 100-2, 100-3, ..., 100-n-1, 100- installed in each classroom in the school. n) and a management information processing device 200 that is a central control panel for a plurality of speaker terminals 100-1, 100-2, 100-3, ..., 100-n-1, 100-n do.

The plurality of speaker terminals 100-1, 100-2, 100-3, ... , 100-n-1, 100-n are installed in a classroom in a school, for example, in a plurality of different zones, Under the control of the management information processing device 200, the premises broadcasts are respectively provided through the own networks of TCP and IP, and are transmitted to their own zones for different zones, thereby performing multi-channel multiplex broadcasting.

The management information processing device 200 controls the premises broadcasting operation of the plurality of speaker terminals 100-1, 100-2, 100-3, ..., 100-n-1, 100-n, For example, it has the following configuration. That is, the management information processing device 200 allows the plurality of speaker terminals 100-1, 100-2, 100-3, ... , 100-n-1, 100-n to transmit an external broadcast signal by itself. an input unit for inputting or receiving and a distribution unit and a communication unit for transmitting the distributed broadcast signal to the plurality of speaker terminals.

FIG. 3 is a block diagram illustrating the configuration of the speaker terminal 100 applied to the broadcasting system of FIG. 1 .

As shown in FIG. 3 , the speaker terminal 100 of FIG. 1 is an IoT-type PLC-based speaker terminal, and mutually as IoT data for premises broadcasting with the management information processing device 200 and its individual IP address. It has a PLC controller with its own IoT module to interface.

More specifically, the speaker terminal 100 of FIG. 1 includes a camera module 110 for monitoring images by photographing each area, a DSP unit 120 thereof, and a sensor unit 130 for detecting information about the surrounding environment of each area. and the PLC controller 140 of the above type for integrally controlling each unit.

In this case, the PLC controller 140 is basically an input module that integrally receives signals from the camera module 110 and various sensor units 130, etc., and an integrated control signal to various control objects such as a CPU module and an air purifier. It includes an output module that outputs

In particular, the PLC controller 140 further includes an IoT module for interfacing with the management information processing device 200 as IoT data for premises broadcasting by itself for each individual IP address.

The camera module 110 acquires image information of the area desired by the administrator by shooting an image of each classroom, for example, in the school. Then, the camera module 110 transmits the image of each area captured in this way to the DSP unit 120 so that it can be processed as a surveillance image to be provided to the management information processing device 200 .

The DSP unit 120 digitally processes the captured image of each area to generate the above-mentioned monitoring image, thereby providing image information for control of each area. To this end, the DSP unit 120 compares the image information of each area collected as described above with the dangerous image information of each area that has been converted into big data. Therefore, as a result of the comparison, if the current image information corresponds to the dangerous image information, the DSP unit 120 processes the high-quality image through a preset prediction viewport and converts the background image and the object except for the prediction viewport to low quality. By processing, the monitoring image is provided to the management information processing device 200 . Accordingly, through this, the DSP unit 120 flexibly determines the image quality so that the image information of each zone can be transmitted with an optimized amount of traffic.

The sensor unit 130 detects the state of the surrounding environment of each zone. The sensor unit 130 includes, for example, an analog oxygen sensor for detecting the oxygen concentration in each zone, an analog fine dust sensor for detecting the dust concentration, a temperature/humidity sensor, and a digital solar sensor. do.

The PLC controller 140 integrally I/O-processes the monitoring image by the DSP unit 120 and various types of detection information by the sensor unit 130 and provides it to the management information processing device 200 . And, in this case, the PLC controller controls the operation of an external device (eg, an air purifier) according to a control signal from the management information processing device. Additionally, the PLC controller 140 has an IoT module on its own and interworks with the input/output module, so that it monitors/controls itself or provides various types of monitoring information to the management information processing device 200 in an integrated manner. make it possible For example, in this case, the PLC controller includes the following configuration.

That is, a power module that supplies power to itself;

a serial communication module communicating with a pre-registered control unit;

an A/I module for receiving analog information about the surrounding environment of each zone from the analog surrounding environment sensor unit including the oxygen concentration installed in each of the plurality of different zones;

A/O module for outputting analog information to a pre-registered analog control unit;

a D/I module for receiving digital information about the surrounding environment of each zone from the digital surrounding environment sensor unit installed in each of the plurality of different zones;

a D/O module for outputting digital information including control signals according to the analog information and digital information of the surrounding environment of each zone to a pre-registered digital control unit;

a D/A module for digitally converting the inputted analog information;

an A/D module for converting the input digital information to analog;

an IoT module for interfacing with the management information processing device as IoT data for premises broadcasting for each individual IP address; and

CPU module for controlling each module; includes

Meanwhile, the configuration of the PLC controller 140 according to the above-described embodiment will be described in more detail.

According to an embodiment, the PLC controller 140 is basically an input module that integrally receives a signal from a sensor unit, etc., and an output module that integrally outputs a control signal to various control objects such as a CPU module and an air purifier. .

And, the PLC controller 140 is provided with an IoT module that performs an IoT function in the PLC itself at this time, so that the CPU module interworks with the input/output module by this IoT module to wirelessly communicate various types of monitoring information in an integrated manner. and the like, to the management information processing device 200 .

In this case, the IoT module includes a wireless communication module, for example, a LoRa module, in order to provide various types of monitoring information to a nearby manager terminal, for example, a manager mobile phone.

Therefore, the PLC controller 140 is provided with an internet connection unit by itself through the IoT module, and directly transmits information about the surrounding environment (eg, oxygen concentration) of each zone sensed in real time to a pre-registered manager terminal app. perform the functions it can.

In this case, the PLC controller has, for example, the following configuration.

a) If the manager terminal in which the CPU module is registered in advance is connected through a wireless communication network, connect to the manager terminal with an individual IP address of the corresponding wireless communication network; Connect with the terminal to secure a real-time connection with the manager terminal.

b) So, when the surrounding environment status information by the sensor unit exceeds a preset reference level, abnormal status information for a plurality of different surrounding environments can be transmitted to the manager terminal by the IoT module.

First of all, additional explanation in this regard requires modules with various functions for existing PLC systems used in various environments, and accordingly, PLC manufacturers provide various modules that satisfy user requirements. For example, a module having various functions, such as a digital input/output module, an analog input/output module, and a communication module, is used in a PLC system, and a system desired by a user is built through these various modules.

For example, the technology of patent document KR101778333 Y1 is an invention registered as such a technology, and specifically relates to a PLC system having a diagnostic module for diagnosing whether an output module of the PLC is defective in operation.

The above-described IoT module according to an embodiment uses these points to provide a PLC that provides an IoT function from the IoT module, and to further facilitate monitoring and control by an administrator through this.

In addition, the input module of the PLC controller 140, that is, the A/D module and the D/I module, provides analog information about the surrounding environment for each zone, such as oxygen concentration and dust concentration, and image, sunlight, etc. of each zone. The digital information of the surrounding environment of each area is received in an integrated manner.

For example, the input module receives the oxygen concentration analog information around each zone from the sensor unit 130, for example, an oxygen sensor. Alternatively, through the D/I module, the sensor unit 130 receives, for example, solar information around each zone as digital information.

In this case, the input module is defined as including an I/O card as an input module of the PLC.

In addition, the output module of the PLC controller 140 receives a signal through the input module and when a control signal is generated by the CPU module, an external device, for example, an air purifier installed in the vicinity of each zone or dust reduction The control signal is transmitted to a device or the like.

Additionally, when a signal is input by the input module, the CPU module processes the input signal according to a preset control logic to generate different control signals related to image monitoring and the like.

Additionally, in addition to the above, the PLC controller 140 issues an alarm or the like with a voice designated for the data collected from the I/O card of the PLC.

To this end, the IoT module is equipped with its own TTS engine, and according to the voice information for each data preset for the data collected from the input module of the PLC, for example, a voice alarm differently according to the voice comment.

Specifically, the IoT module has its own TTS engine, and when the surrounding environment state information of each zone by the sensor unit 150 exceeds the above-described reference level, voice information corresponding to the abnormal state is transmitted to the TTS engine. By means of the speaker terminal itself, the voice alarm is made.

For example, when the oxygen concentration level of a specific area exceeds a preset reference level, the IoT module converts it according to pre-registered voice information and generates a voice alarm.

In this case, the above-mentioned voice message is registered in, for example, a flash voice memory provided in the IoT module itself.

Additionally, in this case, when the state information of the surrounding environment of each zone exceeds the above-described reference level, the IoT module provides an alarm by providing the management information processing device with abnormal status information for a plurality of different surrounding environments.

Also, as another example, the IoT module receives an external voice related to broadcasting, performs noise cancellation, and outputs audio.

Specifically, the IoT module performs an audio IoT function by receiving a voice of a broadcast-related manager, etc., performing noise cancellation, and outputting audio.

For example, in this case, an audio IoT function is performed by receiving an external audio input, performing noise cancellation, and outputting audio through an audio amplifier provided in the IoT module itself.

Meanwhile, in addition to this, the PLC controller 140 includes a separate HMI module to monitor and control the optimized object in the management information processing device 200 in this case.

Specifically, the HMI module performs integrated image measurement by interworking an image signal by a camera module for image monitoring of each area and a detection result by the sensor unit as HMI.

In this case, when the detection result from the sensor unit exceeds the preset reference level, the HMI module pops up the management information processing device by interworking with the HMI module for abnormal state information corresponding to the video signal by the camera module. do.

Additionally, the HMI module pops up in the form of a map based on the HMI when there are multiple camera modules.

On the other hand, additionally, the speaker terminal of the above-described embodiment enables security management on the system when such a broadcast is performed.

To this end, the speaker terminal of one embodiment connects the sensor unit with the PLC controller as IoT data in real time, and configures the lower hash value and mesh networking based on the hash tree as sensing data for the oxygen concentration of each zone in real time. It consists of an IoT sensor device that transmits to a controller.

And, by learning the pattern by turning the oxygen concentration of each zone by the IoT sensor device into big data for each different time period and each season weather under the control of the PLC controller, an index-based standard pattern is derived and the current time zone and By comparing the ambient oxygen concentration according to season and weather to systematically determining whether there is an abnormality, and storing the upper hash value of the hash tree, the hash value is connected to a number of different sensors for security management by configuring a corresponding hash node. It further includes an artificial intelligence algorithm unit (not shown).

So, through this, the oxygen concentration is monitored by season, time, weather, temperature, etc., an air purifier or dust reduction device is operated, and when big data is accumulated, a dust reduction device in an area where there is a lot of dust for each season, etc. It will be a major facility for comprehensive air cleaning measures such as control.

4 is a flowchart sequentially illustrating the operation of the broadcasting system of FIG. 1 (refer to FIG. 1).

As shown in FIG. 4 , when the broadcasting system of FIG. 1 performs premises broadcasting first, a plurality of speaker terminals are installed for a plurality of different zones within the premises and individually broadcast for each zone with their own individual IP addresses. and a management information processing device thereof.

And, in the broadcasting system of FIG. 1, each of the plurality of speaker terminals includes a PLC controller having its own IoT module that interfaces with the management information processing device as IoT data for premises broadcasting for each individual IP address, When broadcasting in the premises, multi-channel multiplex broadcasting can be performed for different zones through TCP and IP under the control of the management information processing device.

In this state, when the management information processing device intends to broadcast through the premises through the manager when a specific situation occurs (S401), the broadcast system communicates individually with a plurality of speaker terminals through TCP and IP based on the aforementioned individual IP addresses. to network (S402).

In this case, the plurality of speaker terminals interface with the management information processing device by the aforementioned IoT module, thereby performing individual networking for multi-channel multi-broadcasting.

Therefore, in the broadcasting system, the management information processing device performs multi-channel multiplex broadcasting by performing intra-premises broadcasting to a plurality of speaker terminals through the IoT module (S403).

For example, when a plurality of these speaker terminals set their IP addresses to broadcast a school broadcast, different broadcasts are performed at the same time in each classroom.

In this case, the broadcast system according to an embodiment additionally has an external interface function on its speaker terminal, interfaces oxygen concentration, etc. for each zone (eg, a classroom of a school) to give an alarm when oxygen is insufficient, etc. By performing the function, it provides the most comfortable classroom environment, etc.

As described above, in one embodiment, when premises broadcasting is performed, a plurality of speaker terminals installed for a plurality of different zones within the premises, each having their own individual IP address, and individual premises broadcasting for each zone, and the plurality of speaker terminals a management information processing device for controlling the premises broadcasting operation of contains

In addition, each of the plurality of speaker terminals includes a PLC controller having its own IoT module that interfaces with the management information processing device as IoT data for premises broadcasting for each individual IP address, so that when broadcasting in premises Multi-channel multiplex broadcasting is performed for different zones through TCP and IP by the IoT module under the control of the management information processing device.

Therefore, by performing multi-channel multiplex broadcasting using TCP and IP through this, when premises broadcasting is performed, the same time, group, or other broadcasting is performed for each zone at the same time.

Additionally, the speaker terminal according to an embodiment has a form different from that of the PLC.

Specifically, the speaker terminal according to an embodiment includes a data collection unit for receiving analog data and digital data, respectively, from an external measuring device, and a commercial CPU according to the data collection unit.

The data collection unit includes an ADC converter that converts a signal of an analog sensor into a digital signal, a GPIO port for receiving an electrical input or output to control an external sensor by interworking with viewer software, and digital data from the external measuring device. An RS485 port, an RS232 port for communication with the data processing unit and communication with the viewer software, and an MCU connected to the ADC converter, GPIO port, RS485 port, and RS232 port to process data and perform control commands of the viewer software may include.

Therefore, through this, the external input/output ports, i.e., digital input, digital output, analog input, RS-485 communication port, RS232 communication port, LAN port, audio port, etc. are handled directly by the speaker terminal, and different specifications are negotiated with many companies. It has an effect that you don't need to do.

In addition, data output (D/O (data out)) for controlling external measurement equipment, contact output, port for controlling alarm, etc., data input (D/I (data in)), analog input (Analog Input: 4-20mA input, etc.) is pre-processed by the MCU and delivered to the CPU.

In addition, RS-485 communication port, LAN port, audio port, etc., the external input data received from various ports are directly data trended at the speaker terminal, so that the manager can easily grasp data such as temperature, and through this, the external system It has the effect of providing an efficient control method.

In addition, in this case, the speaker terminal according to an embodiment directly database data input to the external input/output port in the memory of the speaker terminal, and displays the data trend in a graph format when displaying it as an image on the monitor.

To this end, in the speaker terminal according to an embodiment, analog or digital data such as temperature processed together with the collected images of each zone is stored as a database in the SD, and the database together with the images is managed as a data trend in text or graph format. It may be displayed on the screen of the processing device.

The content displayed on the screen is a database of various conditions such as temperature.

Suga is displayed together with the video, and when text is displayed on the video, it can be set as the text of the text, the unit of the text value, the location of the text on the screen, font, color, etc.

And, at the time of warning, the expression text is displayed in any one of the cases of flickering in a specified color or flickering in which the text is still in a specified color and the entire screen flickers in a specified color or black and white.

In addition, when displaying the database for various situations in the image as a data trend in graph format, the text, unit, and color of the data can be displayed as set by the administrator.

Also, if the trend bar displayed on the image is moved at a desired time, the time value of the trend where the moved bar is located appears, and the data value located on the moving bar disappears systematically after confirming the data.

In addition, at the time of warning, the expression text includes a function to be displayed either in the case of flickering in a specified color or in the case of flickering in which the text is still in a specified color and the entire screen blinks in a specified color or black and white.

100: speaker terminal 200: central control center
110: camera module 120: DSP unit
130: sensor unit 140: PLC controller

Claims (10)

In case of premises broadcasting, a plurality of speaker terminals respectively installed in a plurality of different zones within the premises and having their own individual IP addresses for individual premises broadcasting in each zone;
a management information processing device for controlling the premises broadcasting operation of the plurality of speaker terminals; contains,
Each of the plurality of speaker terminals,
By having a PLC controller having its own IoT module for interfacing with the management information processing device as IoT data for premises broadcasting by its individual IP address, according to the control of the management information processing apparatus when broadcasting in premises Multi-channel multi-broadcasting for different zones through TCP and IP by IoT module; Broadcasting system with multi-channel multi-broadcasting function using TCP and IP, characterized in that The method according to claim 1,
The PLC controller is
a power module that supplies power to itself;
a serial communication module communicating with a pre-registered control unit;
an A/I module for receiving analog information about the surrounding environment of each zone from the analog surrounding environment sensor unit including the oxygen concentration installed in each of the plurality of different zones;
A/O module for outputting analog information to a pre-registered analog control unit;
a D/I module for receiving digital information about the surrounding environment of each zone from the digital surrounding environment sensor unit installed in each of the plurality of different zones;
a D/O module for outputting digital information including control signals according to the analog information and digital information of the surrounding environment of each zone to a pre-registered digital control unit;
a D/A module for digitally converting the inputted analog information;
an A/D module for converting the input digital information to analog;
an IoT module for interfacing with the management information processing device as IoT data for premises broadcasting for each individual IP address; and
CPU module for controlling each module; A broadcasting system having a multi-channel multi-broadcasting function using TCP and IP, characterized in that it comprises a. 3. The method according to claim 2,
The IoT module is
systematically alarming the management information processing device with abnormal state information for a plurality of different surrounding environments as IoT data when the ambient environment detection result by each sensor unit exceeds a pre-registered reference level; Broadcasting system with multi-channel multi-broadcasting function using TCP and IP, characterized in that 3. The method according to claim 2,
The IoT module is
when the detection result of the surrounding environment by each sensor unit exceeds the pre-registered reference level, alarming the abnormal state information for a plurality of different surrounding environments to the pre-registered manager terminal as IoT data; Broadcasting system with multi-channel multi-broadcasting function using TCP and IP, characterized in that 5. The method according to claim 4,
The CPU module is
a) If a pre-registered manager terminal is connected through a wireless communication network, it is connected to the manager terminal with an individual IP address of the corresponding wireless communication network. To secure a real-time connection with the manager terminal,
b) sending the abnormal state information to the manager terminal; Broadcasting system with multi-channel multi-broadcasting function using TCP and IP, characterized in that 5. The method according to claim 4,
The IoT module is
by having its own TTS engine and converting abnormal state information for a plurality of different surrounding environments according to pre-registered voice information, thereby generating a voice alarm by itself; Broadcasting system with multi-channel multi-broadcasting function using TCP and IP, characterized in that 3. The method according to claim 2,
The IoT module is
receiving an external voice related to broadcasting, performing noise cancellation, and outputting an audio; Broadcasting system with multi-channel multi-broadcasting function using TCP and IP, characterized in that 3. The method according to claim 2,
The PLC controller is
an HMI module for integrated image measurement by interworking an image signal by a camera module for image monitoring in each area and a detection result by the sensor unit as HMI; further comprising,
The HMI module is
when the detection result from the sensor unit exceeds a preset reference level, pop-up to the management information processing device by interworking with the human-machine interface (HMI) of abnormal state information corresponding to the video signal by the camera module; Broadcasting system with multi-channel multi-broadcasting function using TCP and IP, characterized in that 9. The method of claim 8,
The HMI module is
If there are a plurality of camera modules, pop-up in the form of a map on the HMI-based; Broadcasting system with multi-channel multi-broadcasting function using TCP and IP, characterized in that 3. The method according to claim 2,
the sensor unit
IoT sensor device that connects the PLC controller and IoT data in real time to configure the surrounding environment state of the area as sensing data with a lower hash value and mesh networking based on the hash tree and transmits it to the PLC controller in real time; is composed of,

By learning the pattern by turning the surrounding environment state of the zone by the IoT sensor device into big data for each different time period and each season weather under the control of the PLC controller, an index-based standard pattern is derived and the current time zone and season, Artificial intelligence that systematically determines whether there is an abnormality by comparing it with the surrounding environment according to the weather, stores the upper hash value of the hash tree, connects the hash value for a number of different sensors, and configures a corresponding hash node for security management. algorithm unit; A broadcasting system having a multi-channel multi-broadcasting function using TCP and IP, characterized in that it further comprises a.

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