CN108169792B - Earthquake disaster data acquisition management method and system - Google Patents

Abstract

The invention discloses an earthquake disaster data acquisition management method and system, wherein a target map is divided into a plurality of grids with preset sizes, grid numbers are added when disaster information is acquired, disaster information acquisition positions are increased when the disaster information is reported, the acquired disaster information can be classified by utilizing the grid numbers, the disaster information is displayed in corresponding grids according to the corresponding relation between acquisition point position information and the grids, multi-angle and multi-dimensional disaster information is stored and managed in a layered mode, and a disaster map is generated according to comprehensive analysis of the disaster information. The invention utilizes the intuition characteristics of disaster information such as pictures, videos and the like to generate the disaster graph in a grid form, and a plurality of disaster information in each grid are accurately displayed according to the disaster information acquisition positions, so that the earthquake disaster site situation can be comprehensively known in real time. And the mobile terminal equipment realizes one-key navigation according to the received disaster situation map and guides the earthquake related disposal personnel to the site.

Description

Earthquake disaster data acquisition management method and system

Technical Field

The invention belongs to the field of data acquisition, and particularly relates to a method and a system for acquiring and managing earthquake disaster data.

Background

After an earthquake occurs, earthquake emergency and disaster situation statistics are problems to be solved urgently, related emergency rescue personnel are required to reach the earthquake epicenter position quickly, and earthquake management personnel need to collect and count earthquake disaster situation information in time. The traditional method is that disaster information is recorded on a paper medium in field investigation, and the disaster information acquired in one day is returned to a field command part and then is arranged and recorded into a computer after the work is finished. With the rapid development of new technologies such as big data, mobile internet, internet of things, new media, artificial intelligence and the like in recent years, earthquake disaster data acquisition mainly depends on a data acquisition module, a camera module and a GPS (global positioning system) positioning module of mobile terminal equipment to acquire field photos, position coordinates and fill in disaster damage forms, and then the scene photos, the position coordinates and the disaster damage forms are transmitted back to a command center through a communication module, and the command center sorts and uses the field earthquake disaster data, so that the field acquisition efficiency and the timeliness of acquiring disaster information are improved to a greater extent. Some of the systems also utilize a geographic information technology to realize position extraction and earthquake disaster pattern management, can display the distribution positions of on-site survey points which have completed acquisition work in real time, but do not generate a complete disaster situation graph (including areas which do not perform disaster situation information acquisition, disaster relief graphs of disaster areas and the like), and most of acquired photos and videos only play a reference role and do not fully play the value and the role of the photos and videos.

In addition, the three seismic elements (seismic time, epicenter, magnitude) are extracted from the seismic monitoring data, which also needs to be managed and utilized effectively. At present, although devices such as a mobile phone and the like can perform navigation positioning, generally, a navigation place needs to be actively input, the accuracy is not high in general and a mobile phone map is completely relied on, the function of automatically navigating to an accurate epicenter position is lacked, and the management and utilization of three earthquake elements cannot be well performed.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide a method and a system for acquiring and managing earthquake disaster data, which can acquire earthquake midsummer position information and the situation of an earthquake disaster area site in real time, quickly, accurately and comprehensively.

In order to achieve the above purposes, the invention adopts the technical scheme that: an earthquake disaster data acquisition and management method comprises the following steps:

dividing the target map into a plurality of grids with preset sizes, and setting corresponding grid numbers;

respectively collecting disaster information in areas represented by each grid, adding grid numbers and collecting point position information in each disaster information, wherein the disaster information comprises at least one of picture, audio, video and character data related to disaster;

reporting the collected disaster information;

and displaying the disaster information in the corresponding grids according to the corresponding relation between the position information of the acquisition points and the grids by utilizing the disaster information acquired by the grid serial number classification, and generating a disaster graph.

Correspondingly, the invention also discloses an earthquake disaster data acquisition and management system, which comprises mobile terminal equipment and an earthquake command center, wherein:

the mobile terminal equipment is used for respectively acquiring disaster information in the area represented by each grid, adding grid numbers and acquisition point position information in each disaster information, wherein the disaster information comprises at least one of picture, audio and video data related to disaster; the disaster information acquisition module is also used for reporting the acquired disaster information;

the earthquake command center is used for dividing the target map into a plurality of grids with preset sizes; the disaster information acquisition system is also used for receiving each disaster information sent by the mobile terminal equipment, classifying the acquired disaster information by using the grid numbers, displaying the disaster information in the corresponding grid according to the corresponding relation between the position information of the acquisition points and the grid, and generating a disaster graph.

Further, the mobile terminal device comprises a task receiving module, a map display module, a camera module, a GNSS chip, a collection reporting module, and a data storage module, wherein:

the task receiving module is connected with the earthquake command center and used for receiving task information from the earthquake command center, wherein the task information comprises corresponding disaster information acquired in a target grid;

the map display module is used for displaying the map and the position of the target grid;

the camera module is connected with the GNSS chip through an interface and is used for shooting disaster information and automatically acquiring the position of the disaster information;

the acquisition reporting module is connected with the GNSS chip through an interface and is used for sending the acquired disaster information, the grid number where each disaster information is located and the position information of the acquisition point to an earthquake command center;

the earthquake command center comprises a task sending module, a data receiving module, a disaster graph display module and a disaster statistic module, wherein:

the task sending module is connected with the message receiving module of the mobile terminal device and used for sending the seismic information acquisition task to the mobile terminal device;

the data receiving module is respectively connected with the acquisition reporting module and the disaster graph display module on the mobile terminal and is used for receiving earthquake disaster information acquired and reported by the mobile terminal equipment;

the disaster situation graph display module is also connected with the disaster situation statistic module and used for dividing the target map into a plurality of grids with preset sizes, setting corresponding grid numbers, displaying corresponding disaster situation information on each grid and summarizing disaster situations output by the statistic module;

and the disaster situation statistics module is used for summarizing and counting disaster situation information and sending a statistical result to the disaster situation graph display module.

The invention has the following effects: the target map is divided into a plurality of grids with preset sizes, grid numbers are added when disaster information is collected, and disaster information collecting positions are added when the disaster information is reported, so that the collected disaster information can be classified by utilizing the grid numbers, and the disaster information is displayed in the corresponding grids according to the corresponding relation between the position information of the collecting points and the grids, and a disaster map is generated. The invention fully utilizes the intuitiveness characteristics of disaster information such as pictures, videos and the like, the disaster situation graph is generated in a grid form, a plurality of disaster situation information in each grid are accurately displayed according to the disaster situation information acquisition positions, and the situations of earthquake disaster situations can be directly, accurately and comprehensively known in real time. In addition, the division of the grids is beneficial to determining corresponding responsible persons in the grid area, and can provide good data support for the subsequent disaster relief work.

Drawings

Fig. 1 is a flowchart of an earthquake disaster data acquisition and management method.

Fig. 2 is a schematic structural diagram of an earthquake disaster data acquisition and management system.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the following embodiments are further described in detail. It should be understood that this embodiment is only one aspect of the application of the present invention and is not intended to limit the present invention.

In some embodiments, fig. 1 illustrates an earthquake disaster data collection and management method, including the following steps:

s101, dividing the target map into a plurality of grids with preset sizes, and setting corresponding grid numbers.

When an earthquake occurs, receiving earthquake three-factor information monitored by an earthquake monitoring center, carrying out fusion management, setting a region map corresponding to the earthquake center position monitored by the earthquake monitoring center as a target map, dividing the target map into a plurality of grids with preset sizes, and setting corresponding grid numbers according to a uniform coding mode.

For example, a regional map corresponding to 1:1 ten thousand epicenter positions is divided into a plurality of grids according to an administrative unit, and corresponding grid numbers are set. Distributing grid managers according to the administrative management areas, wherein each grid manager is responsible for acquiring and reporting earthquake disaster information in a corresponding grid; or dividing the grid into a plurality of cells with the length of 100-300 meters, and then distributing a plurality of grid managers, wherein each grid manager is responsible for acquiring and reporting earthquake disaster information of all grid cell areas in the responsibility area of the grid manager. The division of the grids is beneficial to determining corresponding responsible persons in the grid area, and can provide good data support for the subsequent disaster relief work.

It can be understood that, after an earthquake occurs, in order to guide related personnel to rapidly arrive at the epicenter position, the epicenter position information monitored by the earthquake monitoring center can be automatically displayed in a target map, and the position information is set as a navigation terminal of the navigation device. Compared with the existing method for setting navigation by manual operation, the method for navigating to the terminal point by one key has the characteristics of high speed, high accuracy and the like.

S102, disaster information is collected in the area represented by each grid, grid numbers and collection point position information are added in each disaster information, and the disaster information comprises at least one of picture, audio, video and character data related to the disaster.

The grid manager can collect field disaster information according to a fixed form, wherein the content of the form comprises field photos, audio, video, casualty conditions, house damage conditions, secondary disaster conditions, property loss and the like. The casualty conditions comprise general population, death number, missing number, serious injury number and light injury number of the site; the house damage condition is that house damage information is recorded in detail, and comprises damaged house positions, building age selection, structure type selection, house area input and damage grade selection, wherein the damaged house positions can automatically acquire current point positions or select other positions from an electronic map; the secondary disaster condition is selected from secondary disaster types, such as debris flow, fire, flood, landslide, chemical leakage, explosion, volcanic explosion, storm surge and the like, and corresponding text description can be added; the property loss is the direct economic loss input into the area.

When disaster information is collected, grid numbers are added to the disaster information, and convenience is brought to subsequent disaster management.

When disaster information is collected, the disaster information can be acquired through self-contained positioning information in an electronic map; the camera module can also be connected with the GNSS chip through an interface, and the position information of the current acquisition point can be automatically acquired when the camera module is used for shooting the on-site pictures and videos.

And S103, reporting the acquired disaster information.

It can be understood that a reporting position may be generated during reporting, and if the acquisition point position cannot be directly acquired in S102, the reported position may also be used as acquisition point information.

And the collected disaster information can be subjected to data compression so as to improve the reporting efficiency.

And S104, displaying the disaster information in the corresponding grids according to the disaster information classified and collected by the grid numbers and the corresponding relation between the position information of the collection points and the grids, and generating a disaster graph.

The disaster information with the same grid number is put together and displayed according to the position information of the respective acquisition points. Can be spliced into a plane view or a perspective view according to the collected orientation. Some disaster information may be displayed in the center of the grid and some may be displayed at the four vertices … … of the grid. In actual operation, the same disaster area may be shot in multiple directions, in this case, although there is a difference in the position information of the acquisition points, the difference is generally not large, and whether multiple pieces of disaster information are shot at the same position can be determined by setting a threshold value of a coordinate range. If yes, the disaster information is displayed at one position in a layered mode, and therefore the disaster situation can be displayed in an all-round mode. Of course, if the storage space is limited, the most representative disaster information can be selected according to the angle, quality, direction, range and the like. After the disaster information in each grid is processed, a disaster graph is formed.

The invention fully utilizes the intuitiveness characteristics of disaster information such as pictures, videos and the like, the disaster situation graph is generated in a grid form, a plurality of disaster situation information in each grid are accurately displayed according to the disaster situation information acquisition positions, and the situations of earthquake disaster situations can be directly, accurately and comprehensively known in real time.

It can be understood that, before classifying the received disaster information according to the grids, decompression, geocoding, and other processing of the data are required, correctness and integrity of the disaster information are required to be verified, and disaster information with obvious errors or unclear description is deleted, and even unclear disaster information can be required to be collected again.

After the disaster situation graph is generated, the disaster relief related department can utilize the disaster situation graph to do a lot of things beneficial to disaster relief. Such as: and the earthquake experts visually identify the contents such as pictures, videos and the like, judge and analyze the earthquake neutralizing boundary, and compare and match the earthquake neutralizing boundary information transmitted back by the monitoring station to obtain a more accurate earthquake disaster situation image. The disaster information in the corresponding grid in the boundary (information such as casualty condition, house damage condition, secondary disaster condition, property loss and the like reported in the boundary range) can be gathered and counted according to the disaster boundary visually identified by earthquake experts, or an earthquake disaster grade map is generated by utilizing the comprehensive statistical value of the disaster information in each grid. Or setting different weights, carrying out weighted summation on the respective statistical values of information such as casualty conditions, house damage conditions, secondary disaster conditions, property loss and the like in each grid, and grading the summation result to generate the earthquake damage grade map.

According to the situation displayed in the disaster situation graph, the disaster location (including the epicentre location, the reported picture location, the reported character location and other locations) needing to be focused on is determined according to the disaster situation graph, and the disaster location is pushed to the mobile terminal equipment in the form of characters or pictures, and the mobile terminal equipment can set one key of the received characters or pictures as the navigation end point, so that the process of opening the navigation map to input the destination and then navigating is omitted.

Correspondingly, the present invention further discloses an earthquake disaster data acquisition and management system, in some embodiments, as shown in fig. 2, the earthquake disaster data acquisition and management system includes a mobile terminal device 10 and an earthquake command center 20, wherein:

the mobile terminal device 10 is configured to collect disaster information in areas represented by each grid, and add grid numbers and collection point position information to each disaster information, where the disaster information includes at least one of picture, audio, video, and text data related to a disaster; and the system is also used for reporting the acquired disaster information.

Specifically, the mobile terminal device 10 includes a task receiving module 11, a map display module 12, a camera module 13, a GNSS chip 14, an acquisition reporting module 15, and a data storage module 16, where:

the task receiving module 11 may be connected to the earthquake command center 20 in a wireless communication manner, and is configured to receive task information from the earthquake command center 20, where the task information includes acquiring corresponding disaster information in a target grid.

And the map display module 12 is used for displaying the map and the position of the target grid. The map display module 12 may also be connected to the collection and reporting module 15, and may select a place from a map as a reporting position. When the position of the acquisition point cannot be directly acquired, the reported position can also be used as acquisition point information.

The camera module 13 is connected to the GNSS chip 14 through an interface, and is configured to capture disaster information and automatically obtain a location of the disaster information.

The GNSS chip 14 is configured to obtain the location of the mobile terminal 10 in real time, provide real-time location obtaining and updating, and automatically obtain the location of the disaster information.

The acquisition reporting module 15 is connected to the GNSS chip 14 through an interface, and is configured to send the acquired disaster information to the earthquake command center 20.

The data storage module 16 is used for storing disaster information such as on-site photos, audio, video, casualty conditions, house damage conditions, secondary disaster conditions, property loss and the like.

The earthquake command center 20 is used for dividing the target map into a plurality of grids with preset sizes; and is further configured to receive each disaster information sent from the mobile terminal device 10, classify the acquired disaster information by using the grid number, and display the disaster information in the corresponding grid according to the corresponding relationship between the acquisition point position information and the grid, thereby generating a disaster map.

Specifically, the earthquake command center 20 includes a task sending module 21, a data receiving module 22, a disaster graph display module 23, and a disaster statistics module 24, wherein:

the task sending module 21 is connected to the message receiving module of the mobile terminal device 10, and is configured to send the seismic information acquisition task to the mobile terminal device 10. The module can be used for appointing to send task information to a single user, and can also be used for uniformly sending task information to all users.

The data receiving module 22 is connected to the acquisition reporting module 15 and the disaster graph display module 23 of the mobile terminal device 10, respectively, and is configured to receive the earthquake disaster information acquired and reported by the mobile terminal device 10.

The disaster graph display module 23 is further connected to the disaster statistics module 24, and is configured to divide the target map into a plurality of grids of preset sizes, display corresponding disaster information on each grid, and count the summarized disaster situations output by the statistics module.

And the disaster situation statistics module 24 is used for summarizing and counting disaster situation information and sending a statistical result to the disaster situation graph display module. Specifically, the disaster statistics module 24 processes graphic information, text information, video information, and the like reported by each mobile terminal device 10, and obtains data, categories, and the like related to disaster indicators in various types of information. Then, various disaster situations in the earthquake disaster area are counted, and statistics can be carried out in various modes such as statistics according to any area, statistics according to indexes and the like.

The application method of the earthquake disaster data acquisition and management system comprises the following steps: the earthquake command center 20 sets a map of an area corresponding to the epicenter position monitored by the earthquake monitoring center as a target map, divides the map into a plurality of grids, and sets corresponding grid numbers. And distributing grid managers according to modes such as an administrative management area and the like, wherein each grid manager is responsible for acquiring and reporting earthquake disaster information in a corresponding grid. Each grid manager collects disaster information in an area represented by each grid using the mobile terminal device 10, and adds a grid number and collection point position information to each disaster information. The mobile terminal device 10 reports the acquired disaster information to the earthquake command center 20, the earthquake command center 20 classifies the received data by using the grid number, and then displays the disaster information in the corresponding grid according to the corresponding relation between the position information of the acquisition point and the grid number to generate a disaster map.

The invention fully utilizes the intuitiveness characteristics of disaster information such as pictures, videos and the like, the disaster situation graph is generated in a grid form, a plurality of disaster situation information in each grid are accurately displayed according to the disaster situation information acquisition positions, and the situations of earthquake disaster situations can be directly, accurately and comprehensively known in real time.

In other embodiments, the mobile terminal device 10 further includes a navigation module 17, the navigation module 17 is connected to the task receiving module 11 and the map display module 12, respectively, the task information of the earthquake command center 20 further includes a navigation target position, when the earthquake command center sends the navigation target position to the task receiving module, the task receiving module 11 sets the position as a navigation end point, and displays a navigation path in the map display module 12, where the navigation target address includes an earthquake center address or a disaster location that needs to be focused.

The seismic conductor centre 20 further comprises a first processing module 25, a second processing module 26 connected to each other, wherein:

the first processing module 25 is further connected to the data receiving module 22, and is configured to decompress and geocode the received earthquake disaster data, so as to improve reporting efficiency.

The second processing module 26 is further connected to the disaster graph display module, and is configured to check correctness and integrity of the reported disaster information, and delete the disaster information with obvious errors or unclear description.

The disaster situation graph display module of the earthquake command center 20 is further configured to receive predefined disaster boundary information, notify the disaster situation statistics module 24 to summarize disaster situation information in corresponding grids, and generate an earthquake damage level graph.

For a more detailed implementation of the earthquake disaster data acquisition and management system, reference may be made to the above earthquake disaster data acquisition and management method, which is not described herein again.

It will be appreciated by those skilled in the art that the method and system of the present invention are not limited to the embodiments described in the detailed description, which is for the purpose of explanation and not limitation. Other embodiments will be apparent to those skilled in the art from the following detailed description, which is intended to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.

Claims (2)

1. An earthquake disaster data acquisition and management method is characterized by comprising the following steps:

when an earthquake occurs, receiving earthquake three-element information monitored by an earthquake monitoring center, carrying out fusion management, setting a region map corresponding to an earthquake center position monitored by the earthquake monitoring center as a target map, automatically displaying the earthquake center position information in the target map after the earthquake occurs, and setting the position information as a navigation terminal of a navigation device;

dividing a regional map corresponding to the epicenter position into a plurality of grids according to an administrative management unit, setting corresponding grid numbers, distributing grid managers according to an administrative management area, wherein each grid manager is responsible for acquiring and reporting earthquake disaster information in the corresponding grid; or dividing the grid into a plurality of cells, and then distributing a plurality of grid managers, wherein each grid manager is responsible for acquiring and reporting earthquake disaster information of all grid cell areas in the responsibility area of each grid manager;

respectively collecting disaster information in areas represented by each grid, adding grid numbers and collecting point position information in each disaster information, wherein the disaster information comprises at least one of picture, audio, video and character data related to disaster;

the method comprises the following steps that a grid manager collects field disaster information according to a fixed form, wherein the content of the form comprises a field photo, audio, video, casualty conditions, house damage conditions, secondary disaster conditions and property loss, and the casualty conditions comprise general population, death population, missing population, serious injury population and light injury population of a position; the house damage condition is that house damage information is recorded in detail, and comprises damaged house positions, building age selection, structure type selection, house area input and damage grade selection, wherein the damaged house positions can automatically acquire current point positions or select other positions from an electronic map; selecting a secondary disaster type for the secondary disaster condition, and adding corresponding text description;

when disaster information is collected, grid numbers are added to the disaster information, convenience is brought to subsequent disaster management, and when the disaster information is collected, the disaster information is obtained through self-contained positioning information in an electronic map; the camera module is also connected with the GNSS chip through an interface, and the position information of the current acquisition point is automatically acquired when the camera module is used for shooting on-site pictures and videos;

reporting the collected disaster information; reporting positions can be generated during reporting, and if the positions of the acquisition points cannot be directly acquired, the reported positions are used as acquisition point information;

the disaster information of the classified collection of the grid serial numbers is utilized, and the disaster information is displayed in the corresponding grid according to the corresponding relation between the position information of the collection points and the grid, so that a disaster graph is generated, and the disaster graph comprises the following steps:

the disaster information with the same grid number is arranged together, and is expanded and displayed according to the position information of respective acquisition points, wherein the disaster information is spliced into a plane graph or spliced into a three-dimensional graph according to the acquired directions;

the intuition characteristics of the image and video disaster information are utilized, the disaster graph is generated in a grid form, a plurality of disaster information in each grid are accurately displayed according to the disaster information acquisition positions, and the situation of the earthquake disaster site can be directly, accurately and comprehensively known in real time;

before classifying the received disaster information according to grids, data needs to be decompressed and geocoded, correctness and integrity of the disaster information need to be verified, and disaster information with obvious errors or unclear description is deleted or unclear disaster information is collected again;

after a disaster situation graph is generated, disaster location information needing important attention is determined according to the disaster situation graph, the disaster location information is displayed in a target map, and the location information is set as a navigation terminal of a navigation device;

receiving predefined disaster boundary information, summarizing and counting disaster information in corresponding grids in the boundary according to the disaster boundary, wherein the disaster information comprises casualty conditions, house damage conditions, secondary disaster conditions and property loss information reported in the boundary range, or generating an earthquake disaster grade map by utilizing comprehensive statistical values of the disaster information in each grid, or weighting and summing the respective statistical values of the casualty conditions, the house damage conditions, the secondary disaster conditions and the property loss information in each grid by setting different weights, and grading the summation result to generate the earthquake disaster grade map.

2. The earthquake disaster data acquisition and management system is characterized by comprising mobile terminal equipment and an earthquake command center, wherein:

the mobile terminal equipment is used for respectively acquiring disaster information in the area represented by each grid, adding grid numbers and acquisition point position information in each disaster information, wherein the disaster information comprises at least one of picture, audio and video data related to disaster; the disaster information acquisition module is also used for reporting the acquired disaster information;

the earthquake command center is used for setting a regional map corresponding to the epicenter position monitored by the earthquake monitoring center as a target map and dividing the target map into a plurality of grids with preset sizes; the disaster information collecting device is also used for receiving disaster information sent by mobile terminal equipment, displaying the disaster information in corresponding grids by utilizing grid number classification collection, and according to the corresponding relation between collection point position information and grids, generating a disaster graph, and comprises the steps of sorting the disaster information with the same grid number, developing and displaying according to the respective collection point position information, including splicing into a plane graph or splicing into a three-dimensional graph according to the collected directions, if the same disaster site is shot in multiple directions, judging whether multiple disaster information are shot at the same position in the same grid by setting a coordinate range threshold value, if so, displaying the multiple disaster information in one position in a layering way for displaying the disaster situation in all directions, or selecting the most representative disaster information according to the angle, quality, direction and range, after the disaster information in each grid is processed, a disaster graph is formed;

the mobile terminal equipment comprises a task receiving module, a map display module, a camera module, a GNSS chip, a collecting and reporting module and a data storage module, wherein:

the task receiving module is connected with the earthquake command center and used for receiving task information from the earthquake command center, wherein the task information comprises corresponding disaster information acquired in a target grid;

the map display module is used for displaying the map and the position of the target grid;

the camera module is connected with the GNSS chip through an interface and is used for shooting disaster information and automatically acquiring the position of the disaster information;

the acquisition reporting module is connected with the GNSS chip through an interface and is used for sending the acquired disaster information, the grid number where each disaster information is located and the position information of the acquisition point to an earthquake command center;

the earthquake command center comprises a task sending module, a data receiving module, a disaster graph display module and a disaster statistic module, wherein:

the task sending module is connected with the message receiving module of the mobile terminal device and used for sending the seismic information acquisition task to the mobile terminal device;

the data receiving module is respectively connected with the acquisition reporting module and the disaster graph display module on the mobile terminal and is used for receiving earthquake disaster information acquired and reported by the mobile terminal equipment;

the disaster situation graph display module is also connected with the disaster situation statistic module and used for dividing the target map into a plurality of grids with preset sizes, setting corresponding grid numbers, displaying corresponding disaster situation information on each grid and summarizing disaster situations output by the statistic module;

the disaster situation statistical module is used for summarizing and counting disaster situation information and sending a statistical result to the disaster situation graph display module;

the mobile terminal equipment also comprises a navigation module, and the navigation module is respectively connected with the task receiving module and the map display module;

the earthquake command center is also used for receiving three factors of earthquake monitored by the earthquake monitoring center and setting a regional map corresponding to the epicenter position as a target map;

the task information of the earthquake command center also comprises a navigation target position, when the earthquake command center sends the navigation target position to the task receiving module, the task receiving module sets the position as a navigation terminal and displays a navigation path in the map display module, and the navigation target position comprises an earthquake center address or a disaster location needing important attention;

according to the situation displayed in the disaster situation graph, the disaster location needing important attention is determined and pushed to the mobile terminal equipment in the form of characters or pictures, the mobile terminal equipment sets one key of the received characters or pictures as the navigation end point, and the process that the navigation map is opened firstly to input the destination and then the navigation is carried out is omitted;

the earthquake command center also comprises a first processing module and a second processing module which are connected with each other, wherein:

the first processing module is also connected with the data receiving module and is used for decompressing and geocoding the received earthquake disaster data;

the second processing module is also connected with the disaster graph display module and is used for checking the correctness and the integrity of the reported disaster information and deleting the disaster information with obvious errors or unclear description;

the earthquake expert visually identifies the picture and the video content, judges and analyzes the earthquake neutralization boundary, and performs matching with the earthquake neutralization boundary information transmitted back by the monitoring station to obtain a more accurate earthquake disaster situation picture;

the disaster situation graph display module is further used for receiving predefined disaster boundary information, informing the disaster situation statistics module to summarize disaster situation information in corresponding grids, and generating an earthquake damage level graph.

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