CN112085638A - Emergency command interaction method, system and equipment for sudden geological disaster - Google Patents

Abstract

The invention relates to an emergency command interaction method, a system and equipment for sudden geological disasters, which relate to the technical field of geological disaster monitoring and comprise the following steps: acquiring map data of a designated area; acquiring reporting information, wherein the reporting information comprises disaster areas and coordinates thereof, and information of key resources and coordinates thereof; importing map data and report information, searching a corresponding position on a map according to coordinates of a disaster area, displaying a closed graph of the corresponding disaster area at the position, searching a corresponding position on the map according to coordinates of key resources, and displaying a graph element of the corresponding key resource at the position; and displaying the map, the closed graph and the graph element on the map on the man-machine interaction picture. The invention has the effect of reducing the early-stage preparation workload so that personnel in a command center can know the field situation in time and appoint an emergency scheme, thereby improving the rescue efficiency.

Description

Emergency command interaction method, system and equipment for sudden geological disaster

Technical Field

The invention relates to the technical field of geological disaster rescue, in particular to an emergency command interaction method, system and equipment for sudden geological disasters.

Background

At present, sudden geological disasters refer to geological disasters which occur suddenly and complete disaster activities in a short time, and mainly include volcanoes, earthquakes, collapse, landslide, debris flow, ground collapse, rock burst, water and mud outburst in mines, coal and gas outburst and the like. Because sudden geological disasters occur suddenly, precursor phenomena are not obvious generally, and most of the sudden geological disasters have strong activities, prediction, forecast and prevention are difficult, people often fail to prevent the sudden geological disasters, and serious damage and loss are caused.

After a disaster occurs or in the process, after receiving the report, the geological disaster emergency command center needs to comprehensively specify an effective emergency scheme according to the reported information such as the position, the type, the coverage range and the like of the reported disaster, and commands the scheduling center to carry out rescue actions according to the emergency scheme, so that the personnel and economic losses caused by the geological disaster are reduced to the minimum. The existing reported information is mainly obtained by field personnel in a field investigation mode, wherein the reported information is uploaded to a command center in a mobile terminal communication mode, and the contents of an instruction sent to a scheduling center by the command center and the reported information are mainly in a text, voice or report form.

The above prior art solutions have the following drawbacks: because the timeliness of rescue actions is crucial, the existing information reporting modes are scattered, map data needs to be called and the reported information needs to be sorted before an emergency scheme is made, so that the position and the field situation of a disaster are determined, and a large amount of preparation work needs to be spent in the period, so that rescue opportunities are easily delayed, and serious personnel and economic losses are caused.

Disclosure of Invention

Aiming at the defects in the prior art, the first purpose of the invention is to provide an emergency command interaction method for sudden geological disasters, which can reduce the workload of early-stage preparation, and is convenient for personnel in a command center to know the field situation in time and appoint an emergency scheme, thereby improving the rescue efficiency and reducing the personnel and economic losses caused by disasters.

The first invention of the present invention is realized by the following technical solutions: the emergency command interaction method for the sudden geological disaster comprises the following steps: acquiring map data of a designated area;

acquiring reporting information, wherein the reporting information comprises disaster areas and coordinates thereof, and information of key resources and coordinates thereof;

importing map data and report information, searching a corresponding position on a map according to coordinates of a disaster area, displaying a closed graph of the corresponding disaster area at the position, searching a corresponding position on the map according to coordinates of key resources, and displaying a graph element of the corresponding key resource at the position;

and displaying the map, the closed graph and the graph element on the map on the man-machine interaction picture.

By adopting the technical scheme, the map of the disaster occurrence place is firstly acquired, then the reported information of the disaster occurrence area, key resources and the like is acquired, the key resources can be rescuers, ambulances and the like, then the reported information and the map are matched, so that the disaster occurrence area, the key resources and the like can be visually displayed at the corresponding positions on the map, the reported information and the map are displayed on a man-machine interaction picture, the reported information is represented in a closed graph, a graph element and the like mode, the visualization of the reported information is realized, the workload of calling data in the early stage and repeatedly comparing and confirming the positions is reduced, the personnel in a command center can conveniently know the field situation in time and appoint an emergency scheme, the rescue efficiency is improved, and the personnel and economic losses caused by disasters are reduced.

The present invention in a preferred example may be further configured to: determining a disaster area when the reported information is imported, acquiring coordinates of a plurality of sampling points on the boundary of the disaster area, which are acquired by field personnel, searching and marking corresponding positions on a map according to the coordinates of each sampling point, and performing curve fitting on coordinate points of a plurality of marked positions corresponding to the sampling points to form a closed graph.

By adopting the technical scheme, field personnel acquire the sampling points at the boundary of the disaster area and then perform curve fitting on the plurality of sampling points to obtain the closed graph corresponding to the disaster area, so that the command center can conveniently deploy rescue personnel and rescue vehicles.

The present invention in a preferred example may be further configured to: acquiring a road blocking condition when the reported information is imported, acquiring a road containing a coordinate point in a closed graph on a map, and recording a part of the road in the closed graph as a disaster-stricken section;

acquiring road information of a disaster-stricken road section uploaded by field personnel;

the method comprises the steps of calling monitoring images or videos of other road sections on a road except a disaster-stricken road section, and obtaining road information of the other road sections according to the monitoring images or videos;

and integrating and acquiring the road blocking condition according to the road information of all road sections of the road.

By adopting the technical scheme, the ambulance and the disaster relief vehicle need to select a smooth road before reaching the disaster area, so that the rescue is prevented from being influenced by road blockage, the disaster-affected road section needs to be surveyed by on-site personnel or equipment due to being located in the disaster area, the road blockage condition is known, and other road sections on the same road are not influenced by the disaster, so that the road blockage condition can be confirmed by calling and monitoring and the like, the survey workload of on-site personnel is reduced, and the rescue efficiency is improved.

Aiming at the defects in the prior art, the second purpose of the invention is to provide an emergency command interaction system for the sudden geological disaster, which can reduce the workload of early-stage preparation, facilitate personnel in a command center to know the field situation in time and appoint an emergency scheme, thereby improving the rescue efficiency and reducing the personnel and economic losses caused by the disaster.

The second object of the present invention is achieved by the following technical solutions: emergent command interactive system of proruption geological disasters includes: a map data acquisition unit for acquiring map data of a specified area;

the information acquisition unit is used for acquiring reporting information, wherein the reporting information comprises disaster areas and coordinates thereof, and information of key resources and coordinates thereof;

the processing unit is connected with the map data acquisition unit and the information acquisition unit and used for importing map data and reporting information, searching a corresponding position on a map according to the coordinates of the disaster area, displaying a closed graph corresponding to the disaster area at the position, searching a corresponding position on the map according to the coordinates of the key resources and displaying a graph element corresponding to the key resources at the position;

and the display unit is connected with the processing unit and is used for displaying the map, the closed graph and the graph element on the map on the man-machine interaction picture.

By adopting the technical scheme, the map of the disaster occurrence place is acquired through the map data acquisition unit, the reporting information such as the disaster occurrence area and the key resources, which can be rescuers, ambulances and the like, is acquired through the information acquisition unit, the reporting information and the map are matched through the processing unit, so that the disaster occurrence area, the key resources and the like can be visually displayed at the corresponding positions on the map, the reporting information and the map are displayed on a man-machine interaction picture, the reporting information is represented in a closed graph, a graph element and the like mode, so that the visualization of the reporting information is realized, the workload of calling data at the early stage and repeatedly comparing and confirming the positions is reduced, the personnel of a command center can conveniently know the site situation in time and appoint an emergency scheme, the rescue efficiency is improved, and the personnel and economic losses caused by disasters are.

The present invention in a preferred example may be further configured to: the processing unit further comprises a communication subunit, the communication subunit is connected with the mobile terminal held by the field personnel through the server, and the communication subunit is used for realizing data intercommunication between the mobile terminal of the field personnel and the processing unit.

By adopting the technical scheme, the communication subunit realizes the information intercommunication between the working personnel of the command center and the field personnel, and simultaneously realizes the data intercommunication between the processing unit, such as a computer and the like, and the field equipment, thereby improving the timeliness of data uploading and improving the command efficiency and the rescue efficiency.

The present invention in a preferred example may be further configured to: the processing unit further comprises a disaster tracking subunit, and the disaster tracking subunit is used for acquiring map data of a plurality of time nodes between a time node from which a spontaneous disaster starts and a current time node, and a closed graph corresponding to a disaster area.

By adopting the technical scheme, the disaster situation tracing subunit is used for facilitating working personnel of the command center to know the actual disaster occurrence situation of the time nodes, so that the trend of geological disasters can be estimated, precaution or rescue deployment can be made in advance, subsequent personnel and economic losses can be reduced, and meanwhile, the record can be conveniently recorded for later action reference of emergency rescue.

The present invention in a preferred example may be further configured to: the information acquisition unit comprises a meteorological data acquisition subunit, the meteorological data acquisition subunit is connected with the server to acquire meteorological data of a current time node, and the processing unit is connected with the meteorological data acquisition subunit to acquire the meteorological data and display a meteorological view on a man-machine interaction picture.

By adopting the technical scheme, the meteorological data at the current moment, such as wind direction and wind power, weather conditions and the like, are acquired through the meteorological data acquisition subunit, so that emergency rescue facilities aiming at weather are conveniently distributed, a canopy, a raincoat and the like need to be prepared when a rainy day is encountered, and meanwhile, the tendency of disasters can be conveniently estimated by workers according to the influence of weather factors, such as the possibility of predicting the occurrence of debris flow and landslide in the rainy day.

The present invention in a preferred example may be further configured to: the processing unit comprises a commanding and scheduling subunit, and the commanding and scheduling subunit is used for receiving and responding to a trigger signal to adjust the number of the rescue vehicles, the rescue vehicles and the rescue personnel.

By adopting the technical scheme, the number of rescue vehicles and the number of rescue workers can be known through the reported information, the distribution condition and the distribution proportion are known, and the dispatching or recalling can be carried out through the command dispatching subunit when the number is insufficient or redundant, so that the timeliness of instruction issuing is improved.

The present invention in a preferred example may be further configured to: including experts and other staff.

By adopting the technical scheme, the expert can overcome some rescue problems or equipment fault problems appearing on the site, so that the key effect is achieved, the personnel scheduling on the site is facilitated by collecting information such as the geographic position of the expert, and the rescue efficiency is improved.

Aiming at the defects in the prior art, the third purpose of the invention is to provide intelligent equipment which can reduce the workload of preparation in the early period, and is convenient for personnel in a command center to know the field situation in time and appoint an emergency scheme, thereby improving the rescue efficiency and reducing the personnel and economic losses caused by disasters.

The third object of the present invention is achieved by the following technical solutions: the intelligent device comprises a memory and a processor, wherein the memory is stored with a computer program which can be loaded by the processor and can execute the emergency command interaction method for the sudden geological disaster.

In summary, the invention includes at least one of the following beneficial technical effects:

the method comprises the steps of firstly obtaining a map of a disaster occurrence place, then obtaining reported information of a disaster occurrence area, key resources and the like, wherein the key resources can be rescue workers, ambulances and the like, then matching the reported information with the map to enable the disaster occurrence area, the key resources and the like to be visually displayed at corresponding positions on the map, displaying the reported information and the map on a man-machine interaction picture, and representing the reported information in a closed graph mode, a graph element mode and the like to realize the visualization of the reported information, so that the workload of early-stage data calling and repeated comparison and position confirmation is reduced, and personnel in a command center can conveniently know the field situation in time and designate an emergency scheme, thereby improving the rescue efficiency and reducing the personnel and economic losses caused by disasters;

the monitoring camera is used for calling images or videos shot on site, or a geological surveying instrument is used for obtaining the change situation of the landform characteristics on site so as to judge the disaster-developing trend, or a positioner is used for obtaining the coordinates of key resources such as an ambulance and the like, so that the staff of the command center can obtain more site information conveniently, and the accuracy of issuing commands is improved;

the disaster situation tracing subunit is used for facilitating workers of the command center to know the actual disaster occurrence conditions of the time nodes, so that the trend of the geological disaster can be estimated, precaution or rescue deployment can be made in advance, subsequent personnel and economic loss can be reduced, and meanwhile, the record can be conveniently recorded for reference of future emergency rescue actions.

Drawings

FIG. 1 is a schematic view of the overall structure of the present embodiment;

FIG. 2 is a schematic diagram of a human-computer interaction screen in the embodiment;

fig. 3 is a flowchart of the method of the present embodiment.

Reference numerals: 1. a meteorological data acquisition subunit; 2. a command scheduling subunit; 3. a communication subunit; 4. and (4) tracing the sub-unit in the disaster.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The first embodiment is as follows: referring to fig. 1, the emergency command interaction system for sudden geological disasters disclosed by the invention comprises: the map data acquisition unit, the information acquisition unit, processing unit and display unit. The map data acquisition unit is used for acquiring map data of a designated area, the information acquisition unit is used for acquiring reporting information, the processing unit is connected with the map data acquisition unit, the information acquisition unit and the display unit and is used for importing the map data and the reporting information for processing and transmitting an image signal obtained after processing to the display unit for displaying, the display unit can adopt a display device such as a displayer or a projector, the processing unit adopts a device with a data processing function and an image output function, and the processing unit can adopt a computer and the like.

The map data acquisition unit comprises an aircraft, the aircraft can adopt an unmanned aerial vehicle, an aerial camera is arranged on the aircraft, field personnel control the aircraft to fly and shoot through a remote controller, and the aerial camera is connected with the processing unit to upload map data in and around a disaster area. The aerial photography camera on the aircraft and the aerial photography camera on the aircraft acquires an aerial photography map of a disaster occurrence place, and the aerial photography map is matched with a GIS map acquired by the server, so that map data can be updated conveniently and timely, the dynamic state of on-site disaster occurrence can be known, correct judgment and instructions can be made according to actual conditions, and rescue efficiency can be improved.

The information acquisition unit comprises monitoring terminals located on the site, and the monitoring terminals comprise monitoring cameras distributed in and around a disaster area and a geological surveying instrument for detecting geological information. The monitoring camera can adopt a camera which is installed on site or a camera which is installed temporarily, so that images or videos shot on site can be called, and workers can conveniently know the site conditions. The geological surveying instrument can adopt a depth finder, a distance finder and the like, and is used for measuring and calculating the landform characteristics and the like so as to obtain the change condition of the landform characteristics on site and conveniently estimate the disaster occurrence condition and trend.

Referring to fig. 1 and 2, the information acquiring unit further includes a meteorological data acquiring subunit 1, where the meteorological data acquiring subunit 1 is connected to the server to acquire meteorological data of a current time node, where the meteorological data includes, but is not limited to, wind direction and wind power, air temperature and air humidity, and weather conditions, and the weather conditions may be represented as sunny days, light rain, heavy snow, and the like. And the processing unit is connected with the meteorological data acquisition subunit 1 to acquire meteorological data and display a meteorological view on a man-machine interaction picture, the meteorological view is displayed with graphs corresponding to various weather conditions, for example, the cloud-shaped graphs represent cloudy days, and temperature parameters and the like are displayed on one side of the meteorological view, which is positioned at the weather conditions, and when the weather conditions are rainy days or snowy days, rainfall and snowy quantities can be acquired and displayed. The meteorological data are used for facilitating staff of the command center to distribute emergency rescue facilities aiming at weather, a canopy, a raincoat and the like need to be prepared when the staff meet a rainy day, and meanwhile, the staff can predict the trend of disasters according to the influence of weather factors, such as the possibility of predicting the occurrence of debris flow and landslide in the rainy day.

And the processing unit is connected with the map data acquisition unit and the information acquisition unit and used for importing the map data and reporting the information, searching a corresponding position on the map according to the coordinates of the disaster area, displaying a closed graph corresponding to the disaster area at the position, searching a corresponding position on the map according to the coordinates of the key resources and displaying a graph element corresponding to the key resources at the position. The processing unit is matched with the map data acquisition unit and the information acquisition unit, the display unit displays a map, a closed graph and graph elements on the map on a man-machine interaction picture of the display unit, so that a disaster area, key resources and the like can be visually displayed at a corresponding position on the map, the reported information and the map are displayed on the man-machine interaction picture, the reported information is represented in a mode of the closed graph, the graph elements and the like, the visualization of the reported information is realized, the workload of calling data in the early stage and repeatedly comparing and confirming the position is reduced, and the rescue efficiency is improved.

Referring to fig. 2 and 3, the reported information includes, but is not limited to, a disaster area and its coordinates, and information of key resources and its coordinates, the disaster area is an area where geological disasters spread, that is, a region where a change in landform such as surface collapse or a change in facilities such as building collapse occurs, and the following method is adopted for determining the disaster area: firstly, acquiring coordinates of a plurality of sampling points on the boundary of a disaster area, which are acquired by field personnel; and then, searching and marking corresponding positions on the map according to the coordinates of each sampling point, and performing curve fitting on coordinate points of a plurality of marked positions corresponding to the sampling points to form a closed graph, wherein the outline of the closed graph is the boundary of the disaster area, and the area of the closed graph is the disaster area. The disaster area can be conveniently determined, so that rescue workers and rescue vehicles can be conveniently deployed by a command center, and the rescue efficiency is improved. In another embodiment, the disaster area can be defined by comparing and drawing aerial images before and after the disaster transmitted back by the aircraft, and the disaster area is the difference of the aerial images before and after the disaster.

The key resources include but are not limited to ambulance, disaster relief vehicle and rescue personnel, the ambulance comprises emergency vehicles and the like, the disaster relief vehicle comprises cranes, excavators, fire trucks and the like, the rescue personnel comprise experts and other workers, the other workers can be medical personnel, security personnel and the like, the experts can overcome some rescue problems or equipment failure problems occurring on site, so that the key function is achieved, the personnel scheduling on site is facilitated by collecting information such as geographic positions of the experts, and the rescue efficiency is improved. The reported information further includes the number of rescue vehicles, and the number of rescue workers, and the number of key resources may be separately counted or summarized, for example, the total number of the rescue vehicles is 10, where 3 cranes, 7 excavators, and the like.

The method and the system facilitate the workers of the command center to know the current key resource allocation condition and allocation proportion through the presentation of the types and the quantity of the key resources. The information acquisition unit further comprises a positioner, the positioner is bound with the key resources by adopting a GPS (global positioning system) locator and is used for positioning the key resources and uploading the coordinate positions of the key resources so as to acquire the coordinates of the key resources such as the ambulance and the like, thereby conveniently commanding the ambulance, the disaster relief car and the like to rescue in time. The mode through using multiple monitor terminal makes things convenient for command center's staff to obtain more on-the-spot information to promote the accuracy of decision-making and giving the instruction.

And the processing unit comprises a commanding and dispatching subunit 2, wherein the commanding and dispatching subunit 2 is used for receiving and responding to a trigger signal to adjust the number of the rescue vehicles, the disaster relief vehicles and the rescue personnel, and the trigger signal can be output in a form of triggering a mechanical button or a virtual button. When the quantity of the key resources is insufficient or redundancy exists, the command scheduling subunit 2 can be used for dispatching or recalling the key resources, and the adjustment records of the key resources of the command center are synchronous with the distribution records of the key resources of the scheduling center, so that the timeliness of instruction issuing is improved.

And the processing unit must acquire the road blocking condition first when importing the report information, and the concrete steps are as follows: the method comprises the steps of firstly acquiring a road comprising coordinate points in a closed graph on a map, recording a part of the road in the closed graph as a damaged road section, namely a road section affected by geological disasters, wherein the damaged road section is located in a disaster area, so that on-site personnel or equipment is required to perform investigation, and then uploading road information of the damaged road section, thereby knowing the road blocking condition.

And because other road sections on the same road are not affected by geological disasters, the traffic facilities are more perfect, and only the monitoring images or videos of other road sections on the road except the disaster-affected road section need to be taken, and then the road information of the other road sections obtained according to the monitoring images or videos is obtained, so that the investigation workload of field personnel is reduced. And finally, integrating the road information of the disaster-affected road section and the rest road sections, acquiring the road blocking condition according to the road information of all the road sections of the road, and displaying the blocking position on a man-machine interaction picture when any road is in the blocking condition, so that the driving route of the ambulance is conveniently planned, and the rescue efficiency is improved.

The processing unit further comprises a communication subunit 3, the communication subunit 3 is connected with a mobile terminal held by a field person through a server, and is used for realizing data intercommunication between the mobile terminal of the field person and the processing unit, the communication subunit 3 can adopt a network protocol to transmit data, and the data can adopt a form of characters, voice or video. And a communication functional area is displayed on the man-machine interaction picture, and when a trigger signal of a display area of the mobile terminal corresponding to any field person is received, a message window is displayed for the working person to input data or obtain a message, so that the information intercommunication between the working person and the field person in the command center is realized. Meanwhile, data intercommunication between a processing unit, namely a computer and the field equipment is realized, so that the timeliness of data uploading is improved, and the command efficiency and the rescue efficiency are improved.

The processing unit further comprises a disaster tracking subunit 4, and the disaster tracking subunit 4 is configured to obtain map data of a plurality of time nodes between a time node from which a disaster starts and a current time node, and a closed graph corresponding to a disaster area. The time node may be two hours ago, ten hours ago. When a trigger signal corresponding to any time node is received, map data corresponding to the selected time node and a closed graph of a disaster area are displayed on a man-machine interaction picture, and the map data and the closed graph can be represented as a frame image or a video of the man-machine interaction picture, so that workers of a command center can know the disaster actual conditions of the time nodes conveniently, the trends of geological disasters can be estimated, precautionary or rescue deployment can be made in advance, subsequent personnel and economic losses can be reduced, and meanwhile, the records can be recorded conveniently for action reference of later emergency rescue.

The implementation principle of the embodiment is as follows: map data of a designated area is acquired through a map data acquisition unit, and reported information such as a disaster area and key resources, namely the disaster area and coordinates thereof, and information of the key resources and coordinates thereof, is acquired through an information acquisition unit. And then, the processing unit imports map data and report information, searches a corresponding position on a map according to the coordinates of the disaster area and displays a closed graph corresponding to the disaster area, and searches a corresponding position on the map according to the coordinates of key resources and displays graph elements corresponding to key resources such as rescue workers, ambulances and the like, so that the report information and the map are matched, and the disaster area, the key resources and the like are visually displayed at the corresponding position on the map. Meanwhile, the reported information and the map are displayed on a man-machine interaction picture so as to realize the visualization of the reported information, thereby reducing the workload of calling data in the early stage and repeatedly comparing and confirming the position, facilitating personnel of a command center to know the field condition in time and appoint an emergency scheme, further improving the rescue efficiency and reducing the personnel and economic losses caused by disasters.

Example two: the intelligent device comprises a memory and a processor, wherein the memory is stored with a computer program which can be loaded by the processor and can execute the emergency command interaction method for the sudden geological disaster.

The implementation principle of the embodiment is as follows: the method comprises the steps of firstly obtaining map data of a designated area through a processor, then obtaining reported information of a disaster area, key resources and the like, importing the map data and the reported information, searching a corresponding position on a map according to coordinates of the disaster area and displaying a closed graph of the corresponding disaster area, searching a corresponding position on the map according to coordinates of the key resources and displaying graph elements of the key resources of rescue workers, ambulances and the like, and therefore the reported information is matched with the map, and the disaster area, the key resources and the like can be visually displayed at the corresponding position on the map. The reported information and the map are displayed on a man-machine interaction picture to realize the visualization of the reported information, so that the workload of calling data in the early stage and repeatedly comparing and confirming the position is reduced, personnel in a command center can conveniently know the field condition in time and appoint an emergency scheme, the rescue efficiency is improved, and the personnel and economic losses caused by disasters are reduced.

The embodiments of the present invention are preferred embodiments of the present invention, and the scope of the present invention is not limited by these embodiments, so: all equivalent changes made according to the structure, shape and principle of the invention are covered by the protection scope of the invention.

Claims (10)

1. The emergency command interaction method for the sudden geological disaster is characterized by comprising the following steps of: acquiring map data of a designated area;

acquiring reporting information, wherein the reporting information comprises disaster areas and coordinates thereof, and information of key resources and coordinates thereof;

importing map data and report information, searching a corresponding position on a map according to coordinates of a disaster area, displaying a closed graph of the corresponding disaster area at the position, searching a corresponding position on the map according to coordinates of key resources, and displaying a graph element of the corresponding key resource at the position;

and displaying the map, the closed graph and the graph element on the map on the man-machine interaction picture.

2. The emergency command interaction method for the sudden geological disaster according to claim 1, wherein the disaster area is determined when the report information is imported, coordinates of a plurality of sampling points on the boundary of the disaster area, which are acquired by field personnel, are obtained, corresponding positions are searched and labeled on a map according to the coordinates of each sampling point, and curve fitting is performed on coordinate points of a plurality of labeled positions corresponding to the sampling points to form a closed graph.

3. The emergency command interaction method for the sudden geological disaster according to claim 1, wherein the road blocking condition is obtained when the reported information is imported, the road on the map containing the coordinate points in the closed graph is obtained, and the part of the road in the closed graph is recorded as the damaged road section;

acquiring road information of a disaster-stricken road section uploaded by field personnel;

the method comprises the steps of calling monitoring images or videos of other road sections on a road except a disaster-stricken road section, and obtaining road information of the other road sections according to the monitoring images or videos;

and integrating and acquiring the road blocking condition according to the road information of all road sections of the road.

4. Emergent command interactive system of proruption geological disasters, its characterized in that includes: a map data acquisition unit for acquiring map data of a specified area;

the information acquisition unit is used for acquiring reporting information, wherein the reporting information comprises disaster areas and coordinates thereof, and information of key resources and coordinates thereof;

the processing unit is connected with the map data acquisition unit and the information acquisition unit and used for importing map data and reporting information, searching a corresponding position on a map according to the coordinates of the disaster area, displaying a closed graph corresponding to the disaster area at the position, searching a corresponding position on the map according to the coordinates of the key resources and displaying a graph element corresponding to the key resources at the position;

and the display unit is connected with the processing unit and is used for displaying the map, the closed graph and the graph element on the map on the man-machine interaction picture.

5. The emergency command interaction system for sudden geological disaster according to claim 4, wherein the processing unit further comprises a communication subunit (3), and the communication subunit (3) is connected with the mobile terminal of the field personnel through a server, and is used for realizing data intercommunication between the mobile terminal of the field personnel and the processing unit.

6. The emergency command interactive system for sudden geological disaster according to claim 4, wherein the key resources comprise rescue vehicles, rescue vehicles and rescue personnel, the reported information further comprises the number of rescue vehicles, the number of rescue vehicles and the number of rescue personnel, and the processing unit comprises a command scheduling subunit (2), and the command scheduling subunit (2) is configured to receive and respond to a trigger signal to adjust the number of rescue vehicles, rescue vehicles and rescue personnel.

7. The emergency command interaction system for sudden geological disaster according to claim 6, wherein said rescuers comprise experts and other staff.

8. The emergency command interaction system for sudden geological disaster according to claim 4, wherein the processing unit further comprises a disaster tracking subunit (4), and the disaster tracking subunit (4) is configured to obtain map data of a plurality of time nodes from a time node at which the spontaneous disaster starts to a current time node and a closed graph corresponding to a disaster area.

9. The emergency command interactive system for sudden geological disaster according to claim 4, wherein the information acquiring unit comprises a meteorological data acquiring subunit (1), the meteorological data acquiring subunit (1) is connected with the server to acquire meteorological data of a current time node, and the processing unit is connected with the meteorological data acquiring subunit (1) to acquire meteorological data and display a meteorological view on the man-machine interactive screen.

10. An intelligent device, comprising a memory and a processor, the memory having stored thereon a computer program that can be loaded by the processor and execute the emergency command interaction method of any one of claims 1-3 for a sudden geological disaster.

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