KR20150059505A - Apparatus and method for managing disaster using floating population of base station - Google Patents

Abstract

Disclosed is an apparatus for managing disaster using base station floating population information. The disaster management apparatus according to an embodiment of the present invention comprises: a collection unit which collects weather information from an observatory; a disaster information generation unit which generates disaster information based on disaster basis information including at least one from floating population, drainage pipeline water levels, traffic information, and CCTV information when the weather information is collected; and a disaster information display unit which displays the disaster information generated at a location on a disaster safety map corresponding to the location of the observatory. Therefore, disasters can be prepared by prioritizing disaster countermeasures through various kinds of information including precipitation, drainage pipeline water levels, traffic information, floating population, etc.

Description

[0001] APPARATUS AND METHOD FOR MANAGING DISASTER USING FLOATING POPULATION OF BASE STATION [0002]

The present invention relates to a disaster management apparatus and method using base station floating population information. More specifically, the present invention relates to a disaster management apparatus and method using base station call connection information, The present invention relates to a device and a method for visually displaying disaster information based on information and providing disaster information to a user who is going to stay, pass, or get off in the area.

Due to recent developments in the industry, the damage caused by natural disasters has been drastically increased compared with the past due to changes in the global ocean and atmospheric environment. Natural disasters affecting Korea are mostly caused by summer rainy season, strong winds, heavy rainfall and heavy snow accidents such as winter snowfall, and human and material damage caused by typhoon is the most important factor. Typhoon is a meteorological phenomenon that directly affects the climate and diary of the East Asia region. It occurs mainly in summer in the northwest Pacific region, accompanied by a strong storm with a central maximum wind speed of 17m / s, The strong winds and the heavy rain on the Pacific coasts cause extreme social and economic losses.

If a disaster occurs due to a typhoon or rainy season, the state or local government will set up a disaster management center to prepare people for disaster such as evacuating people in the disaster area. In case of a disaster, Restore damage. Korean Patent Laid-Open No. 10-2007-0070677 discloses a technique for notifying a user of a disaster area in a disaster area by tracking the location of a disaster area member in a mobile communication in the event of such a disaster, There is a limit to preventing disasters and restoration.

The present invention provides a disaster management apparatus and method for identifying a floating population information by region using a call connection amount of a base station and enabling appropriate disaster management based on the information.

The present invention also provides a disaster management apparatus and method that can prioritize disaster response through a variety of information such as precipitation, sewage water level, traffic information, and floating population, and to appropriately prepare for disaster according to priorities.

It is another object of the present invention to provide a disaster management apparatus and method for identifying a user who is in a disaster area through base station call connection information and quickly providing disaster information.

It is another object of the present invention to provide a disaster management apparatus and method for providing disaster preparedness information to a user who is scheduled to get off or pass through a disaster area through a user's traffic card use information or navigation path information.

According to one aspect, the disaster management apparatus includes a weather information collecting unit for collecting weather information from an observing site, a disaster information base based on disaster basic information including at least one of a floating population, sewer water level, traffic information, and CCTV information when weather information is collected A disaster information generating unit for generating information and a disaster information displaying unit for displaying disaster information generated at a location on the disaster safety map corresponding to the location of the observing site.

At this time, the observing station may include a mobile communication base station equipped with a weather observation device for measuring at least one of weather information, precipitation amount, temperature and wind speed.

The disaster management apparatus may further include a disaster basic information collection unit for calculating a floating population based on a call connection amount of the mobile communication base station.

The disaster information generating unit may analyze the collected weather information to determine the level of the disaster and analyze the determined disaster level and the disaster basic information to generate the disaster information.

The disaster information generation unit may determine the disaster response priority by analyzing the determined disaster level and the disaster basic information, and determine the display level according to the determined disaster response priority.

The disaster information display unit can visually display a predetermined object indicating the location of the observation station output to the disaster safety map according to the determined display level.

The disaster information display unit can output detailed information about each element of the disaster basic information in response to the selection of a predetermined object on the disaster safety map by the user.

The disaster management apparatus may further include a disaster information notification unit for transmitting disaster information to a terminal of a user staying in an area within a certain range from the observation station or a terminal of a user who is getting off or going to the area when the disaster information is generated.

The disaster information notification unit can determine whether the user is staying in the area based on the mobile communication base station call connection information of the user terminal.

The disaster information notification unit can determine whether the user is going to get off or pass through the area based on the user's traffic card usage information or navigation path information.

According to one aspect, the disaster management method includes the steps of collecting weather information from an observatory, generating disaster information based on disaster basic information including at least one of a floating population, a sewerage level, traffic information, and CCTV information when weather information is collected And displaying the generated disaster information at a location on the disaster safety map corresponding to the location of the station.

The step of generating the disaster information comprises the steps of analyzing the collected weather information to determine the level of the disaster, analyzing the determined disaster level and the disaster basic information, determining the disaster response priority based on the analysis result, And determining the display level according to the corresponding priority.

The step of displaying the disaster information may visually display a predetermined object indicating the position of the observation station output to the disaster safety map according to the display level, when the display level is determined.

The step of displaying the disaster information may include receiving selection information of a predetermined object on a disaster safety map from a user and outputting detailed information on each element of the disaster basic information in response to the user's selection.

The disaster management method includes the steps of confirming a user who is staying in a certain area or a user who is going to get off or going to the area when the disaster information is generated and a user who is staying in the area, And transmitting the disaster information to the terminal of the terminal.

By using base station call connection, it is possible to identify the information of the floating population by region and manage the disaster appropriately based on this information.

In addition, disaster response priority can be determined through various information such as precipitation, sewage water level, traffic information, and floating population, and disaster prepared appropriately according to priorities.

In addition, it can identify users who are in a disaster area through base station call connection information and provide disaster information so that users can quickly cope with a disaster situation.

Also, it is possible to provide disaster information to a user who is going to get off or pass through the disaster area through the user's traffic card use information or navigation path information, so as to prepare for a disaster situation in advance.

1 is a block diagram of a disaster management system that utilizes floating population information according to an embodiment.
2 is a block diagram of a disaster management apparatus according to an embodiment.
3 is a detailed block diagram of the disaster information generating unit of FIG.
Figure 4 is an example of sewage level information collected in accordance with one embodiment.
5 is an example of a disaster safety map displayed on a display according to one embodiment.
6 is an example of detailed information output to the display according to one embodiment.
7 is an overall flowchart of a disaster management method performed by the disaster management system according to an embodiment.
8 is a flowchart of a disaster management method performed by the disaster management apparatus according to an embodiment.
9 is a detailed flowchart of the disaster information generating step of FIG.
10 is a detailed flowchart of the disaster information display step of FIG.

The present invention will now be described in detail with reference to the accompanying drawings. Hereinafter, a detailed description of known functions and configurations that may unnecessarily obscure the gist of the present invention will be omitted. Embodiments of the present invention are provided to more fully describe the present invention to those skilled in the art. Accordingly, the shapes and sizes of the elements in the drawings and the like can be exaggerated for clarity.

Hereinafter, various embodiments of a disaster management apparatus and method using floating population information will be described with reference to the drawings.

1 is a block diagram of a disaster management system that utilizes floating population information according to an embodiment.

Referring to FIG. 1, the disaster management system 1 includes an observation station 110, a connection server 130, a disaster management server 140, and users 150 and 160.

The observation stations 110 and 120 are equipped with weather observation equipment for measuring various weather information such as temperature, precipitation, wind direction, wind speed, and air pressure, and transmit the weather information measured through the weather observation equipment to the disaster management server 140.

At this time, the observing station may include a mobile communication base station 110 equipped with automatic meteorological observation equipment. It is possible to measure local and precise meteorological information within 1 ~ 2km by observing the meteorological observations by installing the automatic meteorological observation equipment in the base stations. In addition, stable weather information transmission is possible by transmitting data using a mobile communication network.

In addition, the observing station may include a meteorological office 120 having its own meteorological observation equipment and measuring weather information. The weather station 120 may analyze the measured weather information to generate various forecasting information and analysis running performance information, and may transmit the information to the disaster management server 140.

The link server 130 may provide disaster basic information to the disaster management server 140. [ At this time, the disaster basic information is information required for the disaster management server 140 to generate disaster information, and may include call connection information, floating population information, sewer water level, traffic information, CCTV information, and precipitation information.

On the other hand, the link server 130 means all systems that manage various disaster basic information except information that can be obtained from the observation stations 11 and 120, such as precipitation, and it should not be interpreted to mean only one hardware device .

The disaster management server 140 collects disaster basic information from the weather information and the link server 130 from the observation stations 110 and 120, and generates disaster information of the entire disaster prepared area using the collected information.

At this time, the disaster management server 140 receives the call connection amount information from the link server 130, for example, a system of the mobile communication company, and can identify the floating population according to the region. Once the information on the floating population of the region is known, it is possible to generate disaster information so that priority is given to disaster preparedness in a region where the floating population is large.

When a user experiences a disaster such as a typhoon, the disaster management center 150 manages the entire disaster situation such as evacuation of persons and restoration of disaster by monitoring the disaster situation, and a general user 160 < / RTI >

 When the disaster information is generated, the disaster management server 140 transmits the disaster information to the terminal of the disaster management center 150 that manages the disaster situation of the corresponding area, and transmits the disaster information to the terminal Disaster information may be transmitted to the terminal of the user 160 so as to be prepared in advance.

In this case, the terminal of the disaster management center 150 includes a disaster management server that manages the entire disaster situation, a mobile terminal such as a computer of a person in charge, a smart phone, or a smart pad, . ≪ / RTI >

2 is a block diagram of a disaster management apparatus according to an embodiment. 3 is a detailed block diagram of the disaster information generating unit of FIG.

The disaster management apparatus 200 according to the embodiment of FIGS. 2 and 3 may be the disaster management server 140 of FIG. 1 and will be described in more detail with reference to FIG. 2 and FIG.

2, the disaster management apparatus 200 includes a weather information collecting unit 210, a disaster basic information collecting unit 220, a disaster information generating unit 230, a disaster information displaying unit 240, 250).

The weather information collecting unit 210 collects various weather information such as precipitation amount, temperature, wind speed, forecast, and running information from a mobile communication base station equipped with automatic weather observation equipment or an observation station such as a weather station.

The disaster basic information collection unit 220 collects disaster basic information necessary for the disaster information generation unit 230 to generate correct disaster information from the link server.

For example, FIG. 4 is a collection of sewerage level information managed by the city of Seoul. The disaster basic information collection unit 220 collects the sewerage level information managed by each local government from the sewerage management system of each municipality Can be collected.

In addition, the disaster basic information collection unit 220 can collect real-time traffic information, CCTV information, and the like from an institutional system that manages traffic information and CCTV information.

In addition, the disaster basic information collection unit 220 may request the call connection amount information to the system of the mobile communication company and analyze the received call connection amount to calculate the floating population according to the area.

The disaster information generating unit 230 generates disaster information using the collected information when the weather information and the disaster basic information are collected.

3, the disaster information generating unit 230 may include a disaster level determining unit 231, a disaster response ranking determining unit 232, A display level determining unit 233, and a detailed information generating unit 234. [

When the weather information is collected, the disaster level determining unit 231 can analyze the weather information such as the amount of precipitation and the wind speed to determine the current disaster level for each station that transmitted the weather information.

At this time, the disaster level can be preset in two or more steps. For example, based on whether the measured value of the weather information exceeds a preset reference value, it can be set to two stages, a normal stage and a disaster stage.

Table 1 below shows an example of the disaster level set in step 2, which shows that the disaster level is set based on the 10-minute cumulative cumulative precipitation.

Disaster level Precipitation (10-minute cumulative precipitation) normal 10mm or less calamity Greater than 10mm

Referring to Table 1, when the weather information is collected, the disaster level determining unit 231 can determine the disaster level based on the precipitation amount in the weather information. For example, if the collected rainfall amount is 20 mm, .

It is also possible to set the disaster level to three or more levels by dividing the reference value into more detailed steps as shown in Table 2 below. At this time, the disaster level "under" is a normal level, and "middle" or "upper" may be a disaster level.

Disaster level Precipitation (10-minute cumulative precipitation) Ha 10mm or less medium Less than 10mm but less than 50mm Prize Greater than 50mm

Referring to Table 2, the disaster level determining unit 231 can determine the current weather condition to be "medium" when the amount of precipitation in the collected weather information is 20 mm.

When the disaster level is determined in the disaster level determining unit 231, the disaster response ranking determining unit 232 can determine the disaster response priority using the determined disaster level and the collected disaster basic information.

For example, if the disaster level determining unit 231 determines the current weather situation to be a disaster stage as illustrated in Table 1, or determines it as "medium" or "higher" as illustrated in Table 2, The decision unit 232 can determine the disaster priority of each region individually or collectively based on the disaster basic information such as the floating population, sewer water level, traffic information, and CCTV information.

Table 3 below illustrates each stage of disaster priority, with visual indication levels linked to each stage.

Priority Display level normal 1 - Bowl Ready 2 - Blue boundary 3 - Orange danger 4 - Red

With reference to Table 3, the disaster response ranking determination unit 232 determines the disaster response priority, for example, in more detail.

The disaster response ranking unit 232 can determine the disaster priority based on the number of the floating population calculated based on the call connection amount of the mobile communication with respect to the jurisdiction area of each observatory where the disaster level is determined as the disaster level.

In this case, even if the disaster level is the same, disaster preparedness priority can be a dangerous stage if the identified floating population is large, and conversely, if the floating population is small, it can be determined as the preparation stage. Likewise, even if the level of disaster is determined to be "medium" as illustrated in Table 2, it can be a dangerous stage depending on the floating population. Also, even if the disaster level is determined as "Upper", if the floating population is small, it can be determined as a boundary step or a preparation step.

In addition, the disaster response ranking determining unit 232 may determine a disaster priority based on the sewerage level or real-time traffic information of the corresponding area. That is, one of the disaster response priorities can be determined by mapping the sewerage level or the traffic flow (for example, the speed) to each stage of the disaster response priority in a predetermined step.

As described above, the disaster response ranking determining unit 232 can determine the disaster response priority by individually considering the collected disaster basic information. In addition, the disaster response ranking determining unit 232 can determine the disaster response priority by combining two or more disaster basic information.

When the disaster response priority is determined for each observation station, the display level determining unit 233 can determine the display level for each observation station. At this time, the display level may be set to be mapped to each step of the disaster response priority, as illustrated in Table 3. In order that users can visually confirm the disaster response priority for each step of the set display level, Can be connected.

For example, when the display level is one level, the display is performed in different colors such as "green", "blue" in step 2, "orange" in step 3, Information can be linked. Or if the display level is four levels, display information may be linked to indicate that it is a "red" and blink simultaneously to emphasize a more dangerous situation.

On the other hand, the visual display information is not limited to the example, and the same color may be displayed differently, or the type and thickness of lines may be different.

The detailed information generating unit 234 may generate detailed information such as a measurement value, a disaster response rank, and real-time traffic information for each element of the collected weather information (for example, precipitation) or disaster basic information.

Referring again to FIG. 2, the disaster information display unit 240 may display disaster information generated for each observation station, that is, a disaster response rank, a display level, detailed information, etc., at a location on a disaster safety map corresponding to each observation station .

At this time, the position of each observation station may be displayed as a predetermined object (e.g., icon) in the disaster safety map. When the display level is determined for each observation station, the disaster information display unit 240 can display the icon using visual information connected to the determined display level, that is, color, blinking, zooming, line type, thickness,

In addition, the disaster information display unit 240 can display the disaster detailed information of the corresponding station when the user clicks an icon of the specific station in the disaster safety map. At this time, users can output the graphs so that the measurement value or the disaster level can be easily identified for each element of weather information or disaster basic information.

According to the disclosed embodiment, the location of each observation station is visually divided and displayed by using the basic information such as the floating population, so that the disaster management person can easily grasp the current priority for disaster, And so on.

Meanwhile, when the disaster information is generated for each observation station, the disaster information reporting unit 250 can identify the user staying in the jurisdiction area of the generated observation station, and transmit the disaster information to the user terminal.

At this time, the disaster information notification unit 250 identifies the user who is currently staying on the basis of the call connection information of each observation station in the disaster area where the disaster information is generated, for example, the mobile communication base station and transmits the disaster information to the terminal .

At this time, the disaster information can be simply transmitted as a text message. Or a push function of a weather information application installed in a terminal of the user, so that the user can visually confirm the disaster safety map through the weather information application.

In addition, the disaster information notification unit 250 can determine whether a user who is traveling on a bus, a subway or an automobile is going to get off the disaster area or is going to pass through the disaster area, Disaster information can be sent to the user's terminal that is expected to get off or pass.

For example, the disaster information notification unit 250 may collect the user's traffic card usage information in real time and analyze the collected traffic card usage information to determine whether the user is going to pass through or leave the disaster area.

That is, when the user recognizes his or her own traffic card to a traffic card recognition terminal such as a subway or a bus, the disaster information notification unit 250 can receive the traffic card usage information from the link server managing the traffic card usage details. If the disaster area exists on the identified route, the user can determine that the user will pass through or leave the disaster area.

At this time, the disaster information notification unit 250 can further collect traffic card usage pattern information of each user from the link server. When the user recognizes his or her own traffic card at the riding position, it determines the expected area to get off according to the traffic card usage pattern of the user. If the predicted area is located before reaching the disaster area, I can not.

In addition, the disaster information notification unit 250 can directly operate the automobile and transmit the disaster information to the navigation device in cooperation with the terminal of the user who is moving, for example, the navigation device. That is, when the user inputs the destination information to the navigation device, the navigation device can request whether the disaster information exists on the route to the destination, and the disaster information notification unit 250 can determine whether the disaster area exists The disaster information of the disaster area can be transmitted to the navigation device. At this time, when the navigation device receives the disaster information, it can search for the route to the destination again and present it to the user.

5 is an example of a disaster safety map displayed on a display according to one embodiment. 6 is an example of detailed information output to the display according to one embodiment.

Referring to FIG. 5, a disaster safety map may be output to a terminal of a disaster management center or a general user. At this time, the disaster safety map may be a jurisdiction of the disaster management center or a map of a zone preset by the general user.

As shown, an icon representing each observation station is displayed on the disaster safety map. Prior to the occurrence of the disaster situation, the visual information of the display level 1 of Table 3 can be displayed so that the icon of each observation station indicates the normal stage. Thereafter, when a disaster situation such as a typhoon or a rainy season occurs and the display level of each observation station is determined as described above, time information corresponding to the determined display level can be displayed.

5, a certain area (DA) in Seoul Gangnam includes an observation station 11, a management stage 12, and a preparation stage 13, in which the disaster response rank is a dangerous stage, It can be seen that the color of the icon is output differently according to each correspondence rank.

Through this, the user can easily understand that the traffic area is very crowded, and the disaster prevention measures can be taken priority in the area (DA).

Also, when the user clicks the observation station icon on the disaster safety map, the detailed information 20 such as the weather information, the floating population, the sewerage level, traffic information, etc. of the observation station area can be outputted as shown in FIG. Referring to FIG. 6, the output detailed information 20 can be output in a graph form 21 and a text form 22 so that users can visually grasp it.

Also, although not shown, when the user clicks the observation station icon on the disaster safety map, a map indicating real-time traffic information may be output to a part of the screen outputting the detailed information 20 of FIG.

7 is an overall flowchart of a disaster management method performed by the disaster management system according to an embodiment.

FIG. 7 is a diagram illustrating an example of a disaster management method performed by the disaster management system of FIG.

Referring to FIG. 7, the disaster management server 140 may request various weather information such as temperature, precipitation, wind direction, wind speed, and air pressure at the observation stations 110 and 120 (step 310).

Then, when the weather information request is received from the disaster management server 140, the observation sites 110 and 120 transmit the measured weather information to the disaster management server 140 (step 320).

Next, the disaster management server 140 requests various kinds of disaster basic information such as call connection amount information, sewer water level, traffic information, and CCTV information necessary for generating disaster information from the connection server 130 (step 330).

Next, the association server 130 transmits the disaster basic information to the disaster management server 140 at the request of the disaster management server 140 (step 340).

Then, the disaster management server 140 generates disaster information using the collected weather information and disaster basic information (step 350).

At this time, when the call connection amount information is received from the mobile communication company's system, the disaster management server 140 can calculate the floating population information which is one of the disaster basic information using the received call connection amount information.

At this time, the disaster level of the current weather situation can be determined based on the collected weather information, and the disaster priority and detail information can be generated for each region in consideration of the disaster level, the floating population, the sewer water level and traffic information.

Thereafter, when a disaster information providing request is received from the user terminal 150 or 160 (step 360), the generated disaster information may be transmitted to the user terminal (step 370).

8 is a flowchart of a disaster management method performed by the disaster management apparatus according to an embodiment. 9 is a detailed flowchart of the disaster information generating step of FIG. 10 is a detailed flowchart of the disaster information display step of FIG.

8 to 10 may be an embodiment of the disaster management method performed by the disaster management apparatus 200 of FIG. Since the embodiments of the disaster management method performed by the disaster management apparatus 200 have been described in detail with reference to FIG. 2 and subsequent drawings, the following description will be briefly described to avoid duplication.

Referring to FIG. 8, various weather information such as precipitation, temperature, wind direction and wind speed are collected from an observation station (step 410).

Then, disaster basic information such as call connection amount information, sewer water level, traffic information, and CCTV information is collected from the link server (step 420).

Then, disaster information is generated based on the collected weather information and disaster basic information (step 430). At this time, the disaster information may include detailed information about each element such as priority of disaster for each station, weather information and disaster basic information.

Referring to FIG. 9, the step of generating disaster information 430 will be described in more detail. First, the collected weather information is analyzed to determine a disaster level (step 510). Disaster levels can be determined for each station.

Then, when the disaster level is determined for each station, the determined disaster level and disaster basic information such as the floating population, the sewer water level, the traffic information, the CCTV information and the like are analyzed (step 520) The corresponding priority can be determined (step 530).

Then, once the disaster response priorities for each station are determined, a display level corresponding to the determined disaster response priorities can be determined (step 540). At this time, the display level can be connected to various visual information such as color, color enhancement, line thickness, and the like as described above.

Next, detailed information on each element of weather information or disaster basic information for each station can be generated (step 550).

Referring again to FIG. 8, if disaster information is generated, it is visually displayed on the disaster safety map (step 440).

Referring to FIG. 10, the step of displaying disaster information 440 will be described in more detail. First, when the display level of each observation station is determined, a predetermined object representing each observation station on the disaster safety map is determined Time information (step 610).

Then, when the user clicks the icon of the specific observatory, the user's selection information is received (step 620) and the detailed information generated for the corresponding observatory can be output (step 630). At this time, the detailed information can be outputted in a graph form so that the user can visually recognize the information easily.

Referring again to FIG. 8, the disaster information may be transmitted to a user who is staying in the disaster area or is scheduled to pass through the disaster area or a user of the user who is scheduled to leave the disaster area (step 450).

At this time, as described above, it is possible to determine whether the user is staying in the current disaster area based on the call connection information received from the system of the mobile communication company. Also, the user can grasp the area to be passed through by using the traffic card use information. In addition, when there is a disaster area on the route to the destination input by the user in cooperation with the navigation terminal of the user, the disaster information can be transmitted to the navigation terminal.

Embodiments of the present invention may be implemented in the form of program instructions that can be executed on various computer means and recorded on a computer readable medium. Such computer readable media may include program instructions, data files, data structures, etc., alone or in combination. Program instructions to be recorded on a computer-readable medium may be those specially designed and constructed for the present invention or may be available to those skilled in the art of computer software. Examples of computer-readable media include magnetic media such as hard disks, floppy disks, and magnetic tape; optical media such as CD-ROMs and DVDs; magnetic media such as floppy disks; Includes all types of hardware devices that are specially configured to store and execute magneto-optical media and program instructions such as ROM, RAM, flash memory, and the like. Examples of program instructions may include machine language code such as those generated by a compiler, as well as high-level language code that may be executed by a computer using an interpreter or the like. Such a hardware device may be configured to operate as one or more software modules to perform the operations of the present invention, and vice versa.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, and that various changes and modifications may be made without departing from the scope of the invention. .

According to the present invention, a floating population is identified through a base station call connection amount, a priority of a disaster response is set based on the floating population, and technology for rapidly transmitting disaster information to a resident or a person who is going to pass through the area is provided, Based high-resolution weather information service in the disaster safety field.

1: Disaster Management System
110, 120: observation station 130: link server
140: Disaster management server 150, 160: User terminal
200: Disaster management apparatus 210: weather information collecting unit
220: Disaster basic information collection unit 230: Disaster information generation unit
231: Disaster level determining unit 232: Disaster response ranking determining unit
233: display level determining unit 234: detailed information generating unit
240: Disaster information display unit 250: Disaster information notification unit

Claims (16)

A weather information collecting unit for collecting weather information from an observing site;
A disaster information generating unit for generating disaster information based on disaster basic information including at least one of a floating population, a sewerage level, traffic information, and CCTV information when the weather information is collected; And
And a disaster information display unit for displaying the generated disaster information at a location on the disaster safety map corresponding to the location of the station. The method according to claim 1,
The station
And a mobile communication base station equipped with weather observation equipment for measuring at least one of weather information, precipitation, temperature and wind speed. The method according to claim 1,
And a disaster basic information collection unit for calculating the floating population based on a call connection amount of the mobile communication base station. The method according to claim 1,
The disaster information generating unit
Analyzing the collected weather information to determine a disaster level, and analyzing the determined disaster level and the disaster basic information to generate the disaster information. 5. The method of claim 4,
The disaster information generating unit
Determining a disaster response priority by analyzing the determined disaster level and the disaster basic information, and determining a display level according to the determined disaster response priority; 6. The method of claim 5,
The disaster information display unit
And displays a predetermined object indicating the position of the observatory output on the disaster safety map visually according to the determined display level. The method according to claim 6,
The disaster information display unit
And when the user selects a predetermined object on the disaster safety map, outputs detailed information on each element of the disaster basic information in response to the selection. The method according to claim 1,
Further comprising a disaster information notifying unit for transmitting the disaster information to a terminal of a user staying in an area within a certain range from the observing station or a terminal of a user getting off or going to the area when the disaster information is generated. 9. The method of claim 8,
The disaster information notification unit
Wherein the mobile terminal determines whether the user is staying in the area based on call connection information of the mobile communication base station of the user terminal. 9. The method of claim 8,
The disaster information notification unit
Wherein the user determines whether the user is going to get off or pass through the area based on the user's traffic card use information or navigation path information. Collecting weather information from an observatory;
Generating disaster information based on disaster basic information including at least one of a floating population, a sewerage level, traffic information, and CCTV information when the weather information is collected; And
And displaying the generated disaster information at a location on the disaster safety map corresponding to the location of the station. 12. The method of claim 11,
The step of generating the disaster information
Analyzing the collected weather information to determine a disaster level;
Analyzing the determined disaster level and the disaster basic information;
Determining a disaster response priority based on the analysis result; And
And determining a display level according to the determined disaster response priority. 13. The method of claim 12,
The step of displaying the disaster information
Wherein when the display level is determined, a predetermined object indicating the position of the observatory output on the disaster safety map is visually displayed according to the display level. 14. The method of claim 13,
The step of displaying the disaster information
Receiving selection information of a predetermined object on the disaster safety map from a user; And
And outputting detailed information about each element of the disaster basic information in response to the user's selection. 12. The method of claim 11,
Confirming a user who is staying in an area within a certain range from the observatory or a user who is getting off or going to the area when the disaster information is generated; And
And transmitting the disaster information to a terminal of a user who is staying in the area or scheduled to get off or going based on the result of the checking. A computer-readable recording medium having recorded thereon a program for executing the method according to any one of claims 11 to 15.

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