CN113420054B

CN113420054B - Information statistics method, server, client and storage medium

Info

Publication number: CN113420054B
Application number: CN202110507827.1A
Authority: CN
Inventors: 黄志强
Original assignee: Wuhan Time North South Network Technology Consulting Center
Current assignee: Wuhan Time North South Network Technology Consulting Center
Priority date: 2021-05-10
Filing date: 2021-05-10
Publication date: 2023-05-30
Anticipated expiration: 2041-05-10
Also published as: CN113420054A

Abstract

The embodiment of the application discloses an information statistical method, a server, a client and a storage medium, wherein the information statistical method comprises the following steps: the method comprises the steps that a server collects a first user information set, wherein the first user information set comprises first user information of a plurality of first users, and the first user information comprises at least one of identity information, position information, health information, relationship information, equipment information, sensor information and state information of the first users; determining user statistical information of the seismic area according to the first user information set; and outputting user statistical information. The method comprises the steps that a client acquires a twelfth user information set, wherein the twelfth user information set comprises twelfth user information of at least one first user, and the twelfth user information comprises at least one of identity information, position information, health information, relationship information, equipment information, sensor information and state information of the first user; a twelfth set of user information is output.

Description

Information statistics method, server, client and storage medium

Technical Field

The present invention relates to the field of communications technologies, and in particular, to an information statistics method, a server, a client, and a storage medium.

Background

In general, after an earthquake occurs, rescue is mainly performed through two modes of manual searching and positioning and instrument searching and positioning, wherein the manual searching and positioning method is often required to consume a lot of manpower, is long in time consumption and cannot obtain enough trapped personnel information, so that the rescue effect is not ideal; the method for searching and positioning the instrument mainly depends on various detecting instruments, and the complex environment of the earthquake area can greatly reduce the detection performance of the detecting instruments, and also can not obtain accurate information of trapped personnel.

Therefore, the common post-earthquake rescue methods cannot provide reliable data support for rescue operation quickly.

Disclosure of Invention

The embodiment of the application provides an information statistics method, a server, a client and a storage medium, which can rapidly and accurately determine the statistics information of a user, thereby providing reliable data support for search and rescue work and being beneficial to the development of efficient rescue.

The technical scheme of the embodiment of the application is realized as follows:

in a first aspect, an embodiment of the present application provides an information statistics method, where the information statistics method is applied to a server, the method includes:

Collecting a first user information set, wherein the first user information set comprises first user information of a plurality of first users, and the first user information comprises at least one of identity information, position information, health information, relationship information, equipment information, sensor information and state information of the first users;

determining user statistical information of the seismic area according to the first user information set;

and outputting the user statistical information.

Optionally, the collecting the first set of user information includes:

receiving seismic information, and determining a target area according to the seismic information;

sending earthquake information to a client corresponding to the target area;

receiving a third user information set sent by a client, wherein the third user information set comprises third user information of at least one first user;

and updating the first user information set according to the third user information set.

Optionally, the method further comprises:

upon receiving the seismic information, outputting all or part of the first user information for all or part of the users in the first set of user information.

Optionally, the outputting all or part of the first user information of all or part of the users in the first user information set when receiving the seismic information includes:

Receiving the seismic information, and determining a target area according to the seismic information;

acquiring a plurality of first sub-areas of the target area;

for each first sub-region, acquiring a fourth user information set, wherein the fourth user information set comprises all or part of fourth user information of the first user possibly located in the first sub-region;

for each first sub-region, transmitting the corresponding fourth set of user information to at least one client of the first sub-region, and/or transmitting the fourth set of user information to at least one client of the first sub-region adjacent to the first sub-region.

Optionally, the method further comprises:

for each first user meeting first preset conditions, estimating state information according to the corresponding first user information, and updating the first user information of the first user by using the state information.

In a second aspect, an embodiment of the present application provides an information statistics method, where the information statistics method is applied to a client, and the method includes:

acquiring a twelfth user information set, wherein the twelfth user information set comprises twelfth user information of at least one first user, and the twelfth user information comprises at least one of identity information, position information, health information, relationship information, equipment information, sensor information and state information of the first user;

Outputting the twelfth set of user information.

Optionally, the method further comprises:

receiving seismic information;

acquiring a third user information set, wherein the third user information set comprises third user information of at least one first user;

outputting the third user information set, and/or updating the eleventh user information set according to the third user information set.

Optionally, the method further comprises:

receiving the fourth set of user information and/or the sixth set of user information;

and updating the eleventh user information set according to the fourth user information set and/or the sixth user information set.

In a third aspect, an embodiment of the present application provides an information statistics apparatus, including:

a first collection unit configured to collect a first user information set, where the first user information set includes first user information of a plurality of first users, and the first user information includes at least one of identity information, location information, health information, relationship information, device information, sensor information, and status information of the first users;

the first statistics unit is used for determining user statistics information of the seismic area according to the first user information set;

And the first output unit is used for outputting the user statistical information.

Optionally, the first collecting unit collects a first set of user information, including:

sending earthquake information to a client corresponding to the target area;

Optionally, the information statistics device further includes:

and the user information output unit is used for outputting all or part of the first user information of all or part of users in the first user information set when receiving the seismic information.

Optionally, the user information output unit outputs all or part of the first user information of all or part of the users in the first user information set when receiving the seismic information, including:

acquiring a plurality of first sub-areas of the target area;

Optionally, the information statistics device further includes:

and the first state analysis unit is used for estimating state information according to the corresponding first user information for each first user meeting the first preset condition and updating the first user information of the first user by using the state information.

In a fourth aspect, an embodiment of the present application provides an electronic device, including a first processor, a first memory storing instructions executable by the first processor, where the instructions, when executed by the first processor, implement the method according to the first aspect.

In a fifth aspect, embodiments of the present application provide yet another information statistics apparatus, including:

A second acquisition unit configured to acquire a twelfth set of user information including twelfth user information of at least one first user, the twelfth user information including at least one of identity information, location information, health information, relationship information, device information, sensor information, and status information of the first user;

and the second output unit is used for outputting the twelfth user information set.

Optionally, the information statistics device further includes:

and the information updating unit is used for updating an eleventh user information set according to the twelfth user information set, wherein the eleventh user information set comprises eleventh user information of at least one first user, and the eleventh user information comprises at least one of identity information, position information, health information, relationship information, equipment information, sensor information and state information of the first user.

Optionally, the method further comprises:

the second obtaining unit is further configured to obtain, when receiving the seismic information, the third user information set, where the third user information set includes third user information of at least one first user;

The second output unit is further configured to output the third set of information.

Optionally, the method further comprises:

the second obtaining unit is further configured to receive the fourth set of user information and/or the sixth set of user information;

the information updating unit is further configured to update the eleventh user information set according to the fourth user information set and/or the sixth user information set.

And the second state analysis unit is used for estimating state information according to the corresponding eleventh user information for each first user of the eleventh user information set and updating the eleventh user information of the first user by using the state information.

Optionally, the information statistics device further includes:

the prompting unit is used for receiving the earthquake information; acquiring prompt information, wherein the prompt information comprises communication connection information and/or user information receiving and transmitting information; and outputting the prompt information.

Optionally, the information statistics device further includes:

and the third output unit is used for sending all or part of the eleventh user information set to a server and/or a client for establishing communication connection, and/or displaying the eleventh user information set in a display interface.

Optionally, the information statistics device further includes:

a second statistics unit for calculating user statistics according to the eleventh set of user information;

and the fourth output unit is used for outputting the user statistical information.

In a sixth aspect, embodiments of the present application provide yet another electronic device, the electronic device including a second processor, a second memory storing instructions executable by the second processor, the instructions, when executed by the second processor, implementing the method according to the second aspect.

In a seventh aspect, embodiments of the present application provide a computer readable storage medium having stored thereon a program for use in a server and a client, the program when executed by a first processor implementing a method according to the first aspect; the program, when executed by a second processor, implements a method as described in the second aspect.

The embodiment of the application provides an information statistics method, a server, a client and a storage medium, wherein the server collects a first user information set, the first user information set comprises first user information of a plurality of first users, and the first user information comprises at least one of identity information, position information, health information, relationship information, equipment information, sensor information and state information of the first users; determining user statistical information of the seismic area according to the first user information set; and outputting the user statistical information. The method comprises the steps that a client side obtains a twelfth user information set, wherein the twelfth user information set comprises twelfth user information of at least one first user, and the twelfth user information comprises at least one of identity information, position information, health information, relationship information, equipment information, sensor information and state information of the first user; outputting the twelfth set of user information. That is, according to the information statistical method provided by the application, before, during and after an earthquake, the information can be selectively transmitted and reported through various modes through communication connection between the server and the client, so that user information and statistical information of users in an earthquake area can be rapidly and accurately determined, reliable data support can be provided for search and rescue work, and efficient rescue can be facilitated.

Drawings

FIG. 1A is a schematic diagram of a flow chart of an implementation of an information statistics method;

FIG. 1B is a second flowchart of an implementation of the information statistics method;

FIG. 2 is a block diagram of the information statistics system;

FIG. 3 is a third flow chart of an implementation of the information statistics method;

FIG. 4 is a flowchart showing a method for information statistics;

FIG. 5 is a flowchart showing a method for information statistics;

FIG. 6 is a flowchart showing a method for information statistics;

FIG. 7 is a schematic diagram of a flow chart for implementing an information statistics method;

FIG. 8 is a schematic diagram eighth implementation flow chart of an information statistics method;

FIG. 9 is a flowchart of an implementation of an information statistics method;

FIG. 10 is a schematic diagram of an implementation flow of an information statistics method;

FIG. 11 is a flowchart eleven of an implementation of an information statistics method;

FIG. 12 is a schematic diagram showing a flow chart of an implementation of an information statistics method;

FIG. 13 is a flowchart of a method for information statistics;

FIG. 14 is a flowchart showing a method for information statistics;

FIG. 15 is a flowchart fifteen of an implementation of an information statistics method;

FIG. 16 is a sixteen schematic views of an implementation flow of an information statistics method;

FIG. 17 is a seventeenth schematic diagram of an implementation flow of an information statistics method;

FIG. 18 is a schematic diagram of a structure of an information statistics apparatus;

FIG. 19 is a schematic diagram of the composition of a server;

FIG. 20 is a schematic diagram showing a second structure of the information statistics apparatus;

fig. 21 is a schematic diagram of the composition structure of the terminal device.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application. It is to be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to be limiting. It should be noted that, for convenience of description, only a portion related to the related application is shown in the drawings.

The terms first, second, third and the like in the description and in the claims and in the above drawings, are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used may be interchanged where appropriate such that the embodiments described herein may be implemented in other sequences than those illustrated or otherwise described herein. Furthermore, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed or inherent to such process, method, system, article, or apparatus.

The earthquake early warning system captures earthquake longitudinal waves by utilizing monitoring instruments near the earthquake center, rapidly estimates earthquake parameters such as earthquake starting time, earthquake intensity, earthquake position, earthquake center intensity and the like, predicts the influence of the earthquake on surrounding areas, and issues warning information through an electronic communication system such as broadcasting, televisions, networks, telephones, mobile phones, alarms and the like before transverse waves reach the surrounding areas of the earthquake center.

The earthquake early warning has the defect that an early warning blind area exists, and a user in the blind area cannot receive the early warning; and for the area close to the seismic source, the reaction time of the user after receiving the early warning is also very short. However, the most damaging of the earthquake is the area near the source.

Another drawback is that the seismic parameters are difficult to estimate accurately initially, often with a large estimated seismic intensity for small earthquakes, substantially approaching the actual magnitude for medium intensity earthquakes, and with a small estimated magnitude for large earthquakes. The estimated magnitude of the major earthquake is low in the initial stage, which may lead to missing report or even early warning, people don't pay attention because of low intensity. And provide an alarm for areas where vibration is not intense, unnecessary disasters may be caused, such as panic.

Therefore, due to the fact that the earthquake early warning has blind areas and the earthquake parameters are difficult to estimate quickly and accurately, users in the area with the largest earthquake damage do not have enough reaction time, and the users are likely to be trapped in a building and need to wait for rescue.

When searching and positioning trapped personnel, the common search and rescue method mainly comprises manual search and positioning, instrument search and positioning, search and positioning of a search and rescue dog and the like. The manual searching and positioning method comprises the steps of inquiring a person knowledgeable, observing, shouting, fine hearing and the like, and generally consumes much labor, and the earthquake site is generally noisy, so that the sound of the person claiming is difficult to distinguish; the instrument searching and positioning method comprises a video life detector (limited in range), an audio life detector (the audio life detector is an instrument for passively receiving audio signals and vibration signals, and a gap is required to be searched in ruins during rescue to stretch into a probe, so that the instrument is easily affected by site noise, the detection speed is low), an infrared life detector (poor in penetrating power and affected by environmental temperature), a snake eye life detector, a radar life detector (high in price) and the like, so that manpower and material resources are consumed, and meanwhile, the identity and other specific information of trapped personnel are difficult to determine.

Therefore, the current common searching and positioning method needs a large amount of people to perform comprehensive searching, consumes time and labor, consumes gold rescue time, can only acquire a small amount of information such as whether people exist or not and the approximate positions of the people, and is difficult to acquire other specific information such as the number, identity, age, sex, injury condition, food reserve, specific positions and the like of trapped people; that is, the existing personnel searching and positioning method for the seismic area cannot quickly and accurately complete the confirmation and statistics of personnel information

The command part is difficult to quickly acquire some statistical information, and the data can not be obtained until searching and reporting by the searching and positioning personnel.

That is, the common post-earthquake rescue methods cannot provide reliable data support for rescue operation quickly.

In order to solve the above problems, the embodiments of the present application provide an information statistics method, a server, a client, and a storage medium, through communication connection between the server and the client, before, during, and after an earthquake, information is selectively transmitted and reported in a plurality of ways, and user trapped states are evaluated and statistical analysis is performed on the information, so that statistical information of users in an earthquake area, such as trapped conditions, health conditions, and food water source conditions of each region, each district, each building crowd, can be rapidly and accurately determined, thereby providing reliable data support for search and rescue work, and facilitating efficient rescue development. The system can transmit the collected user information of the earthquake area outside the earthquake area, so that rescue commanders outside the earthquake area can quickly know the disaster situation of the masses in the earthquake area, and rescue measures can be formulated pertinently; the earthquake area can be divided into a plurality of small areas, and the user information of each small area is sent back to part of the clients of the small area, so that rescue workers in the small area can quickly and accurately rescue according to the information even after communication is interrupted.

The system comprises at least one client and at least one server. Fig. 2 is a schematic diagram of an information statistics system architecture, according to an exemplary embodiment. As shown in fig. 2, the system comprises earthquake early warning equipment, a server and a client, and after the earthquake early warning equipment detects earthquake information, the earthquake early warning equipment sends the earthquake data to the server; the server determines an information collection area (seismic area) according to the seismic data, sends alarm information to a client of the information collection area, collects information such as user position information, state information and the like from the client, and sends user information of a nearby area to the client; the server analyzes the trapped state of the user according to the collected user information, performs statistical analysis, and distributes the information to rescue commander, trapped personnel relatives and other personnel; the client displays prompt information or specific information according to the acquired user information, so that the user can report the acquired user information to a local rescue commander after an earthquake or execute rescue work according to the user information.

The system can comprise a plurality of servers, such as more servers are deployed in the frequent earthquake regions and the periphery, fewer servers are deployed in other regions, and when an earthquake occurs, the servers in the corresponding earthquake regions are communicated with the clients to mutually transmit the user information of the earthquake regions; the server in the earthquake area sends the collected user information to the server outside the earthquake area in time, so that people outside the earthquake area can quickly learn the disaster situation of people in the earthquake area even if communication is interrupted. The service area may be divided for each server in advance, or the service area may be divided for each server according to the seismic information during the earthquake (for example, the area with the intensity greater than the threshold is divided according to the set of servers in the area or around the area), and each server provides services for the clients of the corresponding service area.

The system comprises a plurality of clients, wherein the clients can comprise ordinary user clients, rescue commander clients and the like. Each client can acquire, propagate and/or output user information of one or more users, such as acquiring information of frequent retention positions of the users before an earthquake, and acquiring information of real-time positions, trapped states and the like during and after the earthquake; transmitting user information, such as the user information transmitted by the earthquake region client to the server, the user information transmitted by the trapped user client to each other, the user information transmitted by the trapped user to the rescue personnel, the collected user information transmitted by the rescue personnel to the local rescue command department and the like; displaying user information, such as information of the number of users displaying user information collected by the client, displaying specific user information of each user, interactively displaying statistical information, and the like.

A plurality of user information collecting devices dedicated to collecting user information may be deployed in advance in each seismic high-rise area, and the user information collecting devices run a client program, for example, at least one user information collecting device may be placed in each of the facilities of the distribution facility, fire department, etc. of the seismic zone area. The information collection device can collect local user information from the server or the common user and the rescue commander client before, during and/or after the earthquake, and the rescue commander can acquire the local user information from the user information collection device after the earthquake occurs so as to improve the rescue efficiency.

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application.

An embodiment of the present application provides an information statistics method, which is applied to a server, where the server may be a distributed server, a server cluster, a cloud server, or the like. The information statistical method can be operated on a single server or can be cooperatively executed by a plurality of servers.

Further, in the application, if the servers are distinguished according to regions, the servers can be divided into servers in the earthquake region and servers outside the earthquake region, and the servers in the earthquake region are close to the trapped users, so that the communication speed is faster, but communication is possibly interrupted or damaged after the earthquake; the server outside the earthquake area is far away from the trapped user, cannot be affected by the earthquake, and continues to work after the earthquake.

Fig. 1A is a schematic flow chart of an implementation of an information statistics method, as shown in fig. 1A, in an embodiment of the present application, a method for performing information statistics by a server may include the following steps:

step 12, collecting a first user information set, wherein the first user information set comprises first user information of a plurality of first users, and the first user information comprises at least one of identity information, position information, health information, relationship information, equipment information, sensor information and state information of the first users.

In an embodiment of the present application, the server may collect a first user set first, where the first user set includes first user information of a plurality of first users, and the first user information includes at least one of identity information, location information, health information, relationship information, device information, sensor information, and status information of the first users.

It should be noted that, in the embodiment of the present application, the first user information may be specific data and information corresponding to the first user, which are acquired from the client and/or the third party platform.

The identity information may include at least one of user identification, name, age, gender, identification card number, telephone number, occupation, etc. User identification the target user identification is used to be able to indicate a unique user identity. For example, the target user identifier is a user mobile phone number, an identification card number, a user account number allocated by the server after the user is registered, and the like, which is not limited herein.

Wherein the location information includes at least one of a location where a user is often detained, a real-time location at the time of an earthquake, or a possible location, etc. The location where the user is often detained, such as a residence address, a working address, a learning address, a telephone number attribution and the like of the user, wherein the user can set page setting address information at a client before an earthquake, the client can automatically upload real-time location information, and a server can acquire receiving address information of the user on a shopping platform, a takeaway platform and other platforms so as to acquire the location where the user is often detained; when an earthquake occurs, the client reports real-time position information after receiving the earthquake information; after the earthquake, the associated user of the seismic area user may set a location for the client that may occur when the earthquake is set. The location information may be latitude and longitude coordinates, address names, and the like.

Further, each location in the location information may further include time duration information of the location, such as each time period in which the user is at the location in a time period (e.g., the last month), an accumulated time duration, a number of times of each time period, and so on.

Further, each position in the position information can also include position description information, and the position description information can be information described in the modes of characters, voice, images, videos, drawings and the like of the corresponding position, and describes information such as a specific building structure, indoor layout, furniture decoration, an access passage and the like corresponding to the position information.

The health information may include at least one of medical history, blood type, allergy, injury during an earthquake, and the like, among others.

The relationship information may include relationship types with a plurality of other users and relationship object identities, where the relationship types include emergency contacts, direct relatives, guardianship and guardianship, teachers and students, colleagues, doctors and patients, and the relationship object identities may be at least one of user identifications, names, identification card numbers, and the like of corresponding objects.

The device information may include at least one of a brand, a model, a remaining power, communication information (such as at least one of a network system, a communication rate, a signal strength, etc.), and the like.

The sensor information may include information obtained by at least one sensor selected from a sound sensor, a camera, an acceleration sensor, a gravity sensor, a magnetic field sensor, a gyroscope, and the like. After receiving the seismic information, the client can acquire the related sensor information and send the information to the server. For example, when a user escapes and hides, the user speaks information such as specific position, health state, food water source condition and the like, and the client can record the site through the sound sensor when an earthquake occurs and estimate the user state information according to the recorded information; the camera can be used for shooting images or recording videos regularly, and the type of the position of a user, such as a toilet, a corridor, a living room and the like, can be known by processing the shot images and videos; the information of the acceleration sensor, the gravity sensor, the magnetic field sensor, the gyroscope and other sensors can be used for knowing the moving track information of the user, so that whether the user is hidden in a certain position or is moving to find an exit or a hiding position in an earthquake can be determined.

The user status information may include at least one of a user trapped state, a possible trapped position, a health state, a food water source state, an activity space state, an emergency level, and the like, among others. The trapped state of the user can be classified into safety, trapped state, rescue state, disconnection state and the like, wherein the safety represents that the user is not in an earthquake area, is in an open area, can move freely and the like; a trapped state indicates that the user is trapped in a certain location; rescue means that the user is successfully rescued by the rescue personnel; a loss of connectivity means that the system does not obtain user information at or after the time of the earthquake. The likely trapped locations may contain one or more location information indicating the likely trapped locations of the user after the occurrence of the earthquake, the likelihood of the trapped locations. Health status such as injury, medical history, eating, etc. Food water source status, such as food water source serving size. The activity space state represents the space size of the trapped region, such as being greater than 10 square meters, 5 square meters, 1 square meter, 0 square meter, etc. The emergency degree indicates the emergency degree of the user for rescue, for example, the emergency degree is high when the user is aged, severely injured, and has little food water source; the user has low emergency degree when the food water source is sufficient for middle-aged and young people and is healthy. The user urgency may be calculated using preset rules according to at least one of user identity information, status information, building damage information, seismic intensity, etc.

The system can acquire identity information, position information, health information and relationship information of all registered users and associated users (such as direct relatives and the like) of the registered users before an earthquake; acquiring position information, health information, equipment information and sensor information of a user possibly in an earthquake area during or after the earthquake, estimating state information of the user possibly in the earthquake area according to all or part of the information by a system, and calculating statistical information according to identity information, health information, state information and the like; and acquiring user behavior data and user attribute data from a third-party platform after the earthquake, and acquiring the position information of the user from the user behavior data and the user attribute data.

The first set of user information may be stored in a database and/or file system, such as sqlite, mySQL, redis, HDFS, etc.

And step 14, determining user statistical information of the seismic area according to the first user information set.

In the application, after acquiring the first user information set, the server determines user statistical information of the seismic area according to the first user information set.

The user statistics may be calculated based on at least one of the user's gender, age, likely trapped location, trapped status, health status, food water source status, activity space status, urgency, and the like. For example, the total number of people in each region (e.g., province, city, district, county, town, street, district, building, etc.), the number of men/women in each region, the number of people in each region safe/trapped/rescued/disunited, the number of people in each region severely injured/lightly injured/healthy, the number of people in each region with sufficient food/insufficient food, the number of people in each region with various degrees of urgency, etc. can be calculated at the time of the earthquake.

The user may include a plurality of possible trapped locations, and in calculating the statistics of a certain area, the user may be designed to be counted as long as one possible trapped location is in the area for each user; alternatively, when the likelihood is above a preset threshold, the user is counted, such as when the total duration of time the user is at a certain location of the area for a period of time exceeds the preset threshold.

The server can acquire the seismic data, determine the seismic areas according to the seismic data, and calculate the user statistical information of each seismic area and each sub-area; the server may also calculate, after receiving the query instruction of the client, user statistics information of a corresponding area in the first user information set according to the area information included in the query instruction.

The statistical information determining process can be performed at any time during or after the earthquake; the statistical information can be updated once according to the latest first user information set at regular intervals; the statistical information may be updated after the first set of user information is updated.

And step 16, outputting the user statistical information.

In the embodiment of the application, after determining the user statistics according to the first user information set, the server may send the statistics to other servers, clients, and other different devices.

For example, the server may send the user statistics to the rescue commander client so that the rescue commander client may display the user statistics, thereby providing data support for rescue command work of the rescue commander; the server can send the user statistical information to a client, and the client displays the user statistical information; the server can send the user statistical information to a news platform server, so that the news platform server can send the user statistical information to a news client, and the news client provides the user statistical information for the masses in a news information mode.

In the embodiment of the disclosure, the information such as the user identity information, the position information and the like is collected in advance before an earthquake, the information such as the position information, the sensor information and the state information of the user possibly positioned in the earthquake area is collected during the earthquake, the user state information is obtained from the associated user and the third party platform after the earthquake, a first user information set is obtained, the user statistical information of the earthquake area is determined according to the first user information set, and the user statistical information is output, so that the user statistical information of the earthquake area can be rapidly and accurately determined, and data support is provided for rescue command work of rescue command personnel.

Referring to fig. 3, the collecting the first user information set may include:

step 1211, receiving a second set of user information sent by the client, where the second set of user information includes second user information of at least one first user, and the second user information includes at least one of identity information, location information, health information, and relationship information of the first user.

The client may display a user information acquisition page to obtain the second user information of at least one first user, and obtain the second user information set. The user information acquisition page may include at least one of an identity information editing unit, a location information editing unit, a health information editing unit, a relationship information editing unit, and a status information editing unit, so as to obtain identity information, location information, health information, relationship information, and status information, respectively. The client may display a user information acquisition page after user registration and/or a user information acquisition portal in the client, which when triggered displays the user information acquisition page. And when the control is triggered, acquiring information such as identity information, position information, health information, relationship information, state information and the like from the controls of the identity information editing unit, the position information editing unit, the health information editing unit, the relationship information editing unit, the state information editing unit and the like, and sending the information to the server as a second user information set. The user can set own user information, such as own identity information, position information, health information and relationship information, through the information acquisition page; user information associated with the user, such as immediate relatives, emergency contacts, guardianship/guardianship, etc. may also be provided. The user can set and upload the user information through the user information acquisition page before the earthquake; the user information can be set and uploaded through the user information acquisition page after the earthquake, for example, the state information is set after the earthquake, so that the client can transmit the state information.

The client can acquire the position information of the client, such as GPS coordinates, wifi information, base station information, IP address and the like which are connected currently, acquire the current time information, and send the position information and the time information to the server as a second user information set. The client can acquire and send the position information and the time information periodically, such as acquiring and sending once per hour; the client may obtain and send location information, time information, etc. when displayed in the foreground, such as when the user opens the client.

Step 1212, updating the first set of user information according to the second set of user information.

After the second user information set sent by the receiving client side, the first user information set can be updated according to the second user information set.

The updating the first user information set may be adding new user information of at least one corresponding first user in the second user information set to user information of the corresponding first user in the first user information set. If the user information is set after the new user is registered, the acquired user information is added into the first user information set; when a user adds new information such as location information, health information, relationship information, etc., the information is added to the user information of the user.

The updating the first user information set may also be changing corresponding user information of a corresponding first user in the first user information set according to user information of at least one corresponding first user in the second user information set. For example, when the user modifies information such as identity information, position information, relationship information and the like, corresponding information of a corresponding user in the first user information set is modified; when the position information and the time information are received, changing the information such as the time duration and the like of the corresponding position of the corresponding user in the first user information set.

Referring to fig. 4, the collecting the first user information set may further include:

step 1221, receiving the seismic information, and determining a target area according to the seismic information.

After receiving the seismic information, the server may first determine the target area based on the seismic information.

When an earthquake occurs, the server can receive earthquake information sent by an earthquake early warning mechanism. The seismic information carries current seismic data. The current seismic data may include seismic source, seismic grade, and the like.

The server can determine the information such as the seismic intensity of each area around the seismic source, the time when the seismic waves reach the corresponding area and the like according to the seismic data. The server can take the area with the earthquake intensity larger than the preset earthquake intensity threshold value as the target area according to the earthquake intensity information.

The server can also determine the influence range corresponding to the current earthquake according to the earthquake grade information and the corresponding relation between the earthquake grade and the influence range preset by the technician, and the influence range of the corresponding earthquake source is used as a target area. For example, the range of influence of a class 8 earthquake is set to a circular area with a radius of 100 km.

The technical staff pre-determines the target areas corresponding to the earthquakes of the plurality of earthquake frequent areas according to the historical earthquake data, the earthquake zone data and other data, and when the server receives the earthquake information, the corresponding target areas are selected according to the earthquake data. For example, a major earthquake occurs in the area a for decades, so that a technician adds a certain area of the area a to a preset reporting/alarming area, and when the earthquake early warning mechanism detects that an earthquake occurs near the area a, the target area of the area a is acquired from a preset target area list according to earthquake data.

Further, for an earthquake with a low earthquake level, such as a level 1 earthquake, a level 2 earthquake, or the like, an area with a fixed size may be used as the target area, such as an area with a radius of 20 km. Because of errors in the measurement of the seismic level, a major earthquake may initially be measured as a lower level. A larger range is determined as a target area for small earthquakes, and even if an early warning blind area exists in an earthquake early warning system, the earthquake information statistics system can timely acquire information such as the real-time position of a user of the early warning blind area.

In this application, the system may include a plurality of servers, where the plurality of servers may be respectively responsible for collecting and processing user information in different areas, for example, a server is set in each county of each city, and then a target area of one server is an area covered by an earthquake in the corresponding area.

In the present application, a process flow at the time of occurrence of an earthquake is taken as an example. In another embodiment, the system including the server and the client may enter the earthquake exercise flow under the instruction of the technician and the related departments, and the processing flow of the earthquake exercise may be completely consistent with the actual earthquake, for example, the server receives the earthquake exercise instruction, where the instruction includes the target area information; the server sends a exercise message to the user clients within the target area, and so on. For example, a city performs a seismic maneuver and a school performs a seismic maneuver. The earthquake exercise can train masses in a target area and can detect system performance and defects.

Step 1222, sending the seismic information to the client corresponding to the target area.

In an embodiment of the present application, after receiving the seismic information and determining the target area according to the seismic information, the server may further determine the client according to the target area, and may then send the seismic information to the client.

The server may determine clients currently likely to be in the target area based on the location information of the user in the first set of user information and send alert information to the clients. The client that may be currently located in the target area may be a client of a user whose at least one location in the user information is located in the target area, for example, at least one address of a residence address, a work address, a learning address, and the like of the user is located in the target area. The clients that may be currently in the target area may be designed to include or exclude clients whose current location is outside the target area, such as clients of users who are going on business from outside.

Step 1223, receiving a third user information set sent by the client, where the third user information set includes third user information of at least one first user.

After receiving the alarm information sent by the server, the client can output the alarm information to the user, acquire part or all of sensor information such as real-time position, equipment information, audio and video, user state information and the like, obtain a third user information set, and send the third user information set to the server. The client can output alarm information to the user by displaying information such as earthquake intensity, earthquake wave arrival time and the like through a display and/or broadcasting information such as earthquake intensity, earthquake wave arrival time and the like through voice.

The third user information may include at least one of location information, sensor information, device information, health information, status information, and the like of the user. The client can acquire real-time position information through a positioning module of the equipment; sensor information is obtained through sensors such as a sound sensor, a camera, an acceleration sensor, a gravity sensor, a magnetic field sensor, a gyroscope and the like; and obtaining equipment information such as equipment brands, models, residual electric quantity, communication information and the like.

The client side can also display a state control after receiving the seismic information, and when the control is triggered, the trapped state information of the user is set to be a corresponding state. For example, the state control is a security control, when the control is triggered, the trapped state information of the user is set to be secure, the state information of the user is sent to the server, and when the user escapes to the open area, the control can be triggered.

For example, in the application, the user can speak specific information such as position information, health condition, food water source condition and the like in real time when receiving earthquake alarm information and escaping. For example, the user may speak his or her own real-time location during the escape, such as "502, …, hallway, …, stairs, …,4 stairs, …,3 stairs, …,2 stairs, …,1 stairs, …, outdoors," or "i am hidden under a table, with half a bottle of water, about 300ml, no food," etc., and the client records and reports the voice message. The client can obtain images through the camera, so that the environment information of the user when escaping or hiding in the earthquake is obtained. The client can obtain sensor data representing the motion condition of the user when the user escapes or hides in an earthquake through sensor information such as an acceleration sensor, a gravity sensor, a magnetic field sensor, a gyroscope and the like, and determine whether the user hides in a certain position or searches an exit or hiding position in a moving manner in the earthquake. In addition, the user can speak the escape or hiding condition of the user, and can also speak the escape or hiding condition of other users such as other family members, colleagues, classmates and the like.

It should be noted that, in the embodiments of the present application, the client may report information to the server in various manners. In particular, if the server has established a communication connection with a client running on the terminal device, the client may send specific information directly to the server. If the server does not establish a communication connection with a client running on the terminal device, the client may first establish a network communication connection and then send the information, or transmit specific information to the server via a short message.

Step 1224, updating the first user information set according to the third user information set.

After receiving the third user information set sent by the client, the server may update the first user information set according to the third user information set.

The server may add third user information of at least one first user included in the third user information set to user information of a first user corresponding to the first user information set.

In the embodiment of the disclosure, the server receives the earthquake information, determines the target area according to the earthquake information, sends the alarm information to the client corresponding to the target area, receives the third user information set sent by the client, and updates the first user information set according to the third user information set, so that the position, the health condition, the food water source condition and other information of the user when the earthquake occurs can be timely obtained before the communication facility is damaged by the earthquake, and the rescue efficiency of rescue command personnel is improved.

Optionally, when receiving the seismic information, outputting all or part of the first user information of all or part of the users in the first user information set.

Referring to fig. 5, the outputting all or part of the first user information of all or part of the users in the first user information set when receiving the seismic information may include:

Step 1232, acquiring a plurality of first sub-regions of the target region.

After determining the target area, the server may divide the target area into a plurality of first sub-areas. Each first sub-region may be a geographical area spanning hundreds of meters to kilometers.

The server may obtain a plurality of first sub-areas of the target area according to at least one of base station information, longitude and latitude GeoHash codes, administrative division, map POI data, and the like.

The server may use the area covered by one or more base stations as one or more first sub-areas according to the base station information. The area covered by one base station can be a circular area taking the base station as a center of a circle, and the radius of the circular area can be determined according to the distance between other base stations adjacent to the base station.

The server may encode the longitude and latitude coordinates by using a GeoHash, where each GeoHash with a certain encoding length represents a geographic rectangular region, and each GeoHash with a certain length (e.g. 5 bits, 6 bits, etc.) may be associated with a first sub-region.

The server may obtain a plurality of first sub-areas based on administrative division, such as dividing each street office jurisdiction, village, into at least one first sub-area.

The server may divide the neighboring POIs into one or more first sub-regions according to the map POI data.

The server can divide the multiple areas before an earthquake to obtain multiple first subareas, and after receiving the earthquake information, the server obtains the multiple first subareas in the target area according to the target area; the server may also divide the target area after obtaining the target area, to obtain a plurality of first sub-areas.

Step 1233, for each of the first sub-areas, obtaining a fourth set of user information, where the fourth set of user information includes all or part of fourth user information of the first user that may be in the first sub-area.

After obtaining the plurality of first sub-regions within the target region, fourth user information of all or part of the users that may be in the first sub-region may be obtained for each first sub-region. The fourth user information may include at least one of identity information, location information, health information, relationship information, device information, sensor information, status information, etc. of the user, such as all or part of second user information uploaded to a server by a user client before an earthquake, third user information uploaded to the server after receiving the earthquake information at the time of the earthquake, etc., or user information obtained by other methods. For example, when the communication speed is slow or the arrival time of the seismic wave is short, the fourth user information may only contain a small amount of key information, such as identity information and real-time location information of the user; and when the communication speed is high or the arrival time of the seismic wave is long, the fourth user information may contain most or all of the information of the user.

For each first sub-area, the server may determine the users that are likely to be in the first sub-area based on the user's location information. For example, it may be that at least one address of a user's client, such as a residence address, a work address, a learning address, etc., of the user, where at least one location in the user information is in the first sub-area, or that the current location of the user is in the first sub-area. The clients that may be currently in the first sub-area may be designed to include or exclude clients whose current location is outside the first sub-area.

For a first sub-area, after obtaining a user set which is possibly in the first sub-area, fourth user information of each user of the user set can be obtained and used as a fourth user information set; the server may also divide the set of users that may be in the first sub-area into a plurality of subsets, and use the fourth user information of the users in each subset as a fourth set of user information, e.g. one sub-area contains 100 users, and divide them into 5 subsets, each subset contains 20 users, so that 5 fourth sets of user information are obtained, and each fourth set of user information contains user information of 20 users. The plurality of fourth user information sets may be designed as mutually exclusive sets or as non-mutually exclusive sets.

Step 1234, for each first sub-region, sending the corresponding fourth set of user information to at least one client of the first sub-region, and/or sending the fourth set of user information to at least one client of an adjacent first sub-region of the first sub-region.

For each of the first sub-areas, after obtaining the fourth set of user information, the server may send the fourth set of user information to at least one client of the first sub-area and/or send the fourth set of user information to at least one client of an adjacent first sub-area of the first sub-area.

For each of the first sub-areas, the server may send a fourth set of user information to clients currently establishing a communication connection with the server and being within or close to the first sub-area. It may be determined whether the client is within or close to the first sub-area based on real-time location information of the client.

Further, when a plurality of clients satisfying the condition (being within or close to the first sub-area) are included, the server may select at least one client from the plurality of clients satisfying the condition as a target client, and transmit the fourth set of user information to the target client. The target client may be selected according to at least one of occupation information of the client login user, client device information, client real-time location information, and status information. For example, a client whose occupation is a police officer, community committee staff, or the like is selected as a target client; selecting a client on terminal equipment with good communication quality and sufficient electric quantity as a target client; selecting a client with a real-time position in an open area as a target client; selecting a client of the user with the trapped state of the user being safe as a target client; corresponding weights are respectively determined according to professional information, client equipment information, client real-time position information, state information and the like (a technician can preset different weight information for different professions, equipment information and the like in advance), the professional information, the client equipment information, the state information and the like are added to obtain comprehensive weights of the clients, at least one client with the highest comprehensive weight is selected as a target client, and the like.

Further, a plurality of user information collecting apparatuses dedicated to collecting user information may be deployed in advance in each area, and the user information collecting apparatuses run a client program, for example, at least one user information collecting apparatus may be placed at each of the posts, fire departments, and the like of the seismic band area. The server records the communication address (such as IP address) and the position of each user information collecting device; the server determines user information collection equipment corresponding to each sub-area in the earthquake and sends the collected user information of each sub-area to the user information collection equipment; after the earthquake occurs, rescue commander can acquire local user information from the user information collecting equipment so as to improve rescue efficiency.

It should be noted that, in this application, when the server sends the fourth set of user information to the client, each sub-area may be sequentially processed, and for each sub-area, the user information of the user in the sub-area is sent to a target client (for example, the comprehensive weight is ranked at the top) first, so that the user information of each user is sent to the target client only once; and after the transmission processing of the user information is completed in all the subareas, sequentially processing each subarea again, and transmitting the statistical information of the users of the subareas to other target clients which do not receive the fourth user information set for each subarea. And, the fourth set of user information transmitted twice may be different because the server may receive new information transmitted by the user client between the first and second transmissions of user information, and thus, the server transmits the fourth set of user information to the target client at the time of the second transmission of user information.

In the embodiment of the disclosure, the earthquake information is received, the target area is determined according to the earthquake information, a plurality of first subareas of the target area are obtained, a fourth user information set is obtained for each first subarea, and the fourth user information set is sent to at least one client side of the first subarea, so that the user information of each subarea of the earthquake area can be timely sent back to the client side of the subarea before the communication facility is damaged by the earthquake, and rescue can be rapidly and accurately implemented by local rescue workers according to the received user information, thereby improving the rescue efficiency of rescue command workers.

Referring to fig. 6, the collecting the first user information set may further include:

Step 1242, a plurality of second sub-areas of the target area are acquired.

The method of step 1232 may be used to obtain a plurality of the second sub-regions, which may be identical to the first sub-region or different from the first sub-region.

Step 1243, for each second sub-area, sending a P2P connection establishment instruction to the client located in the second sub-area, so that the client of each second sub-area establishes a P2P network, and exchanges a fifth user information set through the P2P network, where the fifth user information set includes fifth user information of at least one first user.

In the embodiment of the present application, after dividing the target area to obtain at least one second sub-area of the target area, for each of the second sub-areas, the server may send a P2P network connection establishment instruction to a client in the second sub-area, so that the client in each of the second sub-areas establishes a P2P network, and exchanges the fifth user information set through the P2P network.

The server can enable all clients in the second subarea to establish a P2P network, so that each client can exchange the fifth user information set with any other peer node; the server may also select a part of clients from all clients located in the second sub-area as P2P target clients, so that all clients located in the second sub-area and the corresponding P2P target clients establish a P2P network, each client exchanges the fifth set of user information with at least one P2P target client, and the server may select the P2P target client according to at least one of occupation information, client device information, client real-time location information, and status information of the client login user. For example, a client terminal of a public service person such as police officer, community committee staff and the like is selected as a P2P target client terminal; selecting a client on terminal equipment with good communication quality and sufficient electric quantity as a P2P target client; selecting a client whose real-time position is in an open area as a P2P target client, and the like.

Further, for each second sub-area, the server may use a user information collecting device disposed in the second sub-area and dedicated for collecting user information as a P2P network target client, so that the clients in the second sub-area all send the fifth user information set to the user information collecting device.

The fifth set of user information includes fifth user information of the at least one first user, and may include, for example, at least one of user information of a user currently logged in by the client, user information of an associated user (e.g., direct relative, etc.) of the user currently logged in by the client, user information of other peer nodes received by the client through the P2P network, user information of other users in the vicinity received by the client from the server, and so on. The fifth user information may include at least one of identity information, location information, health information, relationship information, device information, sensor information, status information, etc. of the user, such as all or part of the second user information uploaded to a server by a user client before an earthquake, the third user information acquired after receiving the earthquake information at the time of the earthquake, the fourth user information received after receiving the earthquake information at the time of the earthquake, etc., or user information obtained by other methods. For example, after the P2P network is established, the client may send information such as identity information, location information, sensor information, status information, etc. of the client login user to other peer nodes through the P2P network.

The clients exchange the fifth set of user information through the P2P network, which may be that each client in the P2P network sends the fifth set of user information to all or part of other peer nodes. For example, the clients in the P2P network may send the fifth set of user information to each other, e.g., one client broadcasts the fifth set of user information to other peer nodes; or all clients in the P2P network send the fifth set of user information to only a few clients, for example, to at least one P2P target client; after collecting the fifth user information sets of the plurality of clients, the P2P target client may send them together to some nodes in the P2P network.

Step 1244, receiving the fifth set of user information sent by the client.

The client side can also send the fifth user information set to the server after communicating through the P2P network. For each P2P network, the server may pre-select at least one client as a transit client, and the transit client sends the fifth set of user information to the server.

Step 1245, updating the first set of user information according to the fifth set of user information.

After the server receives the fifth user information set sent by the client, the server may update the first user information set according to the fifth user information set.

The server may add fifth user information of at least one user included in the fifth user information set to user information of a user corresponding to the first user information set.

In the embodiment of the disclosure, receiving seismic information, determining a target area according to the seismic information, acquiring a plurality of second subareas of the target area, sending a P2P connection establishment instruction to a client in the second subareas for each second subarea, enabling the client in each second subarea to establish a P2P network, exchanging a fifth user information set through the P2P network, receiving the fifth user information set sent by the client, updating the first user information set according to the fifth user information set, and enabling a server to obtain user information of a large number of users by communicating with a small number of clients, thereby improving communication efficiency. In addition, the client transmits the user information to other nearby clients through the P2P network, so that rescue commander can quickly collect the user information of one area after an earthquake. User information of a user is transmitted to a plurality of other user clients in the vicinity so that the user information of the user can be obtained by a rescuer as long as one user client establishes communication with the rescuer client.

Referring to fig. 7, the outputting all or part of the first user information of all or part of the users in the first user information set when receiving the seismic information may further include:

Step 1252, obtaining a plurality of third sub-regions of the target region.

The method of step 1232 may be used to obtain a plurality of third sub-regions, where the third sub-region may be identical to the first sub-region and the second sub-region, or may be different from the first sub-region and the second sub-region. Each of the third sub-areas may be a geographic area spanning from a few degrees to tens of kilometers.

Step 1253, for each of the third sub-areas satisfying the second predetermined condition, obtaining a sixth set of user information, and sending the sixth set of user information to at least one client and/or at least one server satisfying the third predetermined condition, where the sixth set of user information includes sixth user information of all or part of the first users that may be in the third sub-area.

The third sub-area satisfying the second predetermined condition may be any of the third sub-areas within the target area, the third sub-area having a seismic intensity greater than a preset threshold (e.g., the preset threshold is set to 6), the third sub-area having a distance from the source within a preset distance threshold (e.g., 20 km), and so on.

After obtaining a plurality of the third sub-areas within the target area, for each of the third sub-areas satisfying the second predetermined condition, sixth user information of all or part of users who may be in the third sub-area may be obtained. The sixth user information may include at least one of identity information, location information, health information, relationship information, device information, sensor information, status information, etc. of the user, such as all or part of second user information uploaded to the server by the user client before the earthquake, third user information uploaded to the server after receiving the earthquake information at the time of the earthquake, etc., or user information obtained by other methods. For example, when the communication speed is slow or the arrival time of the seismic wave is short, the sixth user information may only contain a small amount of key information, such as identity information and real-time location information of the user; and when the communication speed is high or the arrival time of the seismic wave is long, the sixth user information may contain most or all of the information of the user.

The third predetermined condition may be that the client/server is further from the source than the third sub-region and the client/server is closer to the third sub-region (e.g., 5 km, 10 km, 20 km, etc.), e.g., the third sub-region is located on a line connecting the client/server and the source.

For example, user information of the a third sub-area is acquired and sent to at least one user client of the at least one b third sub-area, and/or to a server of the b third sub-area. Wherein a third sub-area is closer to the source than b third sub-area, and/or a third sub-area is more seismic intense than b third sub-area, and/or the seismic wave reaches a third sub-area before reaching b third sub-area; and the geographic distance between the a third sub-area and the b third sub-area is within a preset range, for example, the distance is more than 5 kilometers and less than 10 kilometers; and b third sub-area is approximately on the ray that the source connects with a third sub-area, or the shortest path from b third sub-area to a third sub-area is shortest.

The server may send said sixth set of user information for said third sub-area satisfying a second predetermined condition to a plurality of clients/servers within a plurality of distance ranges from said third sub-area. For example, at least one client/server is selected over 3 distance ranges of 3-5 km, 8-10 km, 15-20 km each, and the sixth set of user information is sent to them.

The client may be selected according to at least one of occupation information of a client login user, client device information, client real-time location information, and status information.

In the embodiment of the disclosure, when the earthquake level is low (the earthquake level may be predicted to be low in the initial stage), the server may acquire the user information of a certain area of the earthquake source and send the user information to the client which is close to the area of the earthquake source and has accessible communication (the communication facility is not destroyed yet, for example, 10 km away from the earthquake source), so that rescue commander in the area near the earthquake source can quickly acquire the user information of the area of the earthquake source, and the acquired user information of the area of the earthquake source can be conveyed back to the area of the earthquake source by means of manual conveying and the like, thereby improving the rescue efficiency of the area of the earthquake source.

Referring to fig. 8, the outputting all or part of the first user information of all or part of the users in the first user information set when receiving the seismic information may further include:

step 1261, receiving the seismic information.

Step 1262, judging whether the data migration condition is met, if so, acquiring a seventh user information set, and sending the seventh user information set to at least one server meeting a fourth preset condition, wherein the seventh user information set comprises all or part of the received seventh user information of the first user.

The seventh user information may include at least one of identity information, location information, health information, relationship information, device information, sensor information, status information, etc. of the user, all or part of user information of each user collected for the server, such as all or part of information of the third user information, etc. uploaded to the server after receiving the seismic information at the time of the earthquake, or user information obtained by other methods.

The data migration condition can be determined according to the seismic intensity of the current position of the server, for example, whether the seismic intensity is greater than a preset threshold value, for example, whether the seismic intensity is greater than 3, i.e., the server meeting the data migration condition can be regarded as the server in the seismic area. The fourth predetermined condition may be determined according to the seismic intensity of the current position of the server, for example, whether the seismic intensity is smaller than a preset threshold, for example, whether the seismic intensity is smaller than 2, that is, the server satisfying the fourth predetermined condition may be regarded as a server outside the seismic area.

In the embodiment of the disclosure, after receiving the earthquake information, the server can receive the information such as the real-time position of the user and send the received user information to the server outside the earthquake area, so that even if the communication is interrupted, the rescue commander outside the earthquake area can obtain the user information inside the earthquake area, and the rescue command work is better implemented.

Referring to fig. 9, the collecting the first user information set may further include:

step 1272, obtaining an eighth set of user information, where the eighth set of user information includes eighth user information of at least one third user, and sending the eighth set of user information to the client of the first user.

The server may obtain the eighth set of user information and send it to the client of the first user during and/or after the earthquake. The eighth set of user information includes eighth user information for at least one third user. The third user and the first user may have an association relationship, such as a direct relative of the first user, a guardian/guardian, an emergency contact, and the like; alternatively, the first user is a user with authority to view the user information, such as a rescue commander (a technician may add authority to view the user information to the rescue commander, such as adding a user identification of the rescue commander to a table of authority to view the user information).

The server can obtain the first user with an association relation with the third user according to the relation information of the third user for each third user possibly in a seismic area (target area), and send the eighth user information set of the third user to the client side of the first user; and/or the number of the groups of groups,

The server may also obtain the eighth user information set of the third user according to a user identifier and/or identity information of at least one third user included in the user query request after receiving the user information query request of the client of the first user. The server can obtain user relation information of the first user according to the user identification of the first user, obtain the third user with an association relation with the first user according to the user relation information, and obtain eighth user information of the third user; the server may also obtain the eighth user information of the third user directly according to the identity information of the third user.

The eighth user information may include at least one of identity information, location information, health information, relationship information, device information, sensor information, status information, etc. of the user, and may be all or part of user information of the corresponding user collected by the server. The eighth user information of each third user may be obtained from the first set of user sets, resulting in the eighth set of user information.

Step 1274, receiving a ninth set of user information sent by the client of the first user, where the ninth set of user information includes at least one ninth piece of user information of the third user, and the ninth piece of user information includes at least the state information of the third user.

After the client of the first user receives the eighth user information set, the eighth user information set can be output, so that the first user can view the eighth user information of the third user, such as viewing the audio and video information of the third user in the earthquake.

After the first user views the eighth user information of at least one third user, the eighth user information of at least one third user can be edited on a corresponding page of a client to obtain the ninth user information set. For example, the user may view information such as track information obtained by audio, video and other sensors, and position description information uploaded before the earthquake, and determine status information such as the trapped position and health condition of the third user. The client outputs the eighth user information set in a mode of an editable control, so that a user can add and modify the eighth user information set when viewing the eighth user information set.

Step 1275, updating the first user information set according to the ninth user information set.

After the server receives the ninth user information set sent by the client, the server may update the first user information set according to the ninth user information set.

The server may add ninth user information of at least one of the third users included in the ninth user information set to user information of the third users in the first user information set. For example, the third user's likely trapped location, provided by the associated user as an informed person, is added to the third user's status information.

The server may change the user information of the third user in the first user information set according to the ninth user information of at least one third user included in the ninth user information set. For example, the third user provided as an informed person to each associated user may be trapped in the location, and the weight information thereof is adjusted, such as adding a preset weight to the potentially trapped location according to the relationship type. The technician may preset the correspondence between different relationship types and weights.

In the embodiment of the disclosure, an eighth user information set is acquired, the eighth user information set is sent to a client of a first user, a ninth user information set sent by the client of the first user is received, and the first user information set is updated according to the ninth user information set, so that user information of a seismic area with higher accuracy and more comprehensive can be obtained. Although the system can automatically process information such as audio and video uploaded by users in the earthquake area during the earthquake to obtain state information of the users, the system may have the conditions of identification errors and the like; and the user may not be able to upload information to the server, and thus cannot determine the status information of the user. The user information of the seismic area with higher accuracy and more comprehensiveness can be obtained by sending the collected user information of the users of the seismic area to the associated users and obtaining the information such as the state information fed back by the associated users.

Referring to fig. 10, the collecting the first user information set may further include:

step 1281, obtaining a first user data set, the first user data set comprising attribute data and/or behavior data of a plurality of first users.

The server can acquire the first user data set from the third party platform before and after the earthquake and the like, and acquire the identity information, the position information and other information of the user according to the first user data set.

Third party platforms such as shopping platform, take-out platform, travel platform, social platform, news platform, video platform, learning platform, intelligent devices (such as intelligent speaker, intelligent television, intelligent furniture, intelligent refrigerator, intelligent range hood, etc.), monitoring system, etc. The system may obtain authorization from the user in advance to obtain user information from these platforms to help analyze the user's likely location when the earthquake occurs. For example, for each authorized user or each authorized user in the earthquake area, a request for obtaining information is sent to a related third party platform server, and the request contains a user identity, such as a mobile phone number, an identity card number, and the like, and can also contain authorization information; and receiving user data sent by the third-party platform. Or sending a query request to a third party platform, wherein the query request comprises target area information, and the target area is all or part of the area where the earthquake occurs currently, and the query request can also comprise an authorized user list so that the third party platform returns data of the authorized user; and receiving the user data of the target area sent by the third party platform, and judging whether the user is in the target area according to the data such as the receiving address, the position information and the like. The location information may be obtained according to at least one of GPS, base station, wifi, etc., for example, the smart speaker may determine its location according to the connected wifi.

Further, data of the user whose user state is not determined may be acquired only from the third party platform. The users determining the user state, such as the users receiving the information reported by the client during/after the earthquake, the users who have been rescued, and other users can be regarded as users not determining the user state.

User attribute data such as identity information, location information (e.g., shipping address, etc.), etc.

User behavior data, such as the time of using the relevant platform, the location of the user, specific behaviors, corresponding contents and the like, and the time of using the relevant platform, such as the time of using the take-out platform and the corresponding receiving address; specific behaviors such as ticket purchasing behavior on a travel platform, learning behavior on a learning platform, and behavior of interaction with intelligent equipment (such as voice and other data for controlling the intelligent equipment through a voice and other methods), and corresponding contents such as contents displayed to a user after the corresponding platform acts on the user by the corresponding platform, such as video contents displayed by an intelligent television, voice contents played by an intelligent sound box, learning resources output by the learning platform and the like. The third party platform may obtain user behavior data from the log system.

Step 1282, obtaining a tenth user information set according to the first user data set, where the tenth user information set includes tenth user information of a plurality of first users.

The tenth user information may include at least one of identity information, location information, and the like.

At least one location information of the user and time duration information of the user at the location may be obtained according to at least one of user attribute data and user behavior data. For each behavior in the user behavior data, obtaining position information and time information therein, and modifying the time duration of the corresponding position according to the time information, such as modifying the number of times the user is in the corresponding time period at the position or adding the time duration of the behavior to the time duration of the position.

Further, before calculating the position and time information of the user, processing the user behavior data to obtain user characteristic data, and matching the user characteristic data with user family data according to the user characteristic data to estimate the user who sends out the behavior as the first user corresponding to the tenth user information. For example, for an intelligent device, voice information generated by a user, such as a voice control instruction sent by the user, may be acquired, and feature analysis may be performed on the voice information to acquire relevant features. For example, gender and age identification is performed on the voice information to obtain gender and age characteristics.

And acquiring the content output to the user by the corresponding platform, and determining the user characteristics according to the output content. For example, for the learning platform, according to the learning content, the age of the user is determined, if the learning content belongs to a junior three physical class, the user is a junior three student, and the age of the user is about 15 years. For the intelligent television/intelligent sound box, determining the gender, age and other characteristics of the user according to the output content, if the output content is input into the gender classification model to obtain the gender of the user, and the output content is input into the age identification model to obtain the age of the user.

After the user characteristics are obtained, the user characteristics are matched with the user family data, so that the user who sends out the behaviors can be identified. For example, for a family including three parents (middle-aged male), mothers (middle-aged female), and children (teenagers), the user characteristics obtained from the behavior data are middle-aged female, and the behavior is determined to be the maternal user, so that the corresponding position time data is added to the position time information of the maternal user.

And 1283, updating the first user information set according to the tenth user information set.

After obtaining the tenth user information set, the server may update the first user information set according to the tenth user information set.

The server may add tenth user information of at least one of the first users included in the tenth user information set to user information of the first users in the first user information set.

It can be understood that in the present application, since some users may not set an address in the system, or not use the system, or the set address is outdated, the server cannot directly determine the target object in the target area, and thus cannot directly determine the client used by the some users. However, the part of users may use other platforms, such as a shopping platform, a takeaway platform, a travel platform and other third party platforms, and address information is set and stored in the third party platforms, or real-time location information is reported through the third party platforms. Thus, the server may obtain user information from the third party platform to more accurately determine users who may be in the seismic area when the earthquake occurs.

As shown in fig. 1B, after the collecting the first set of user information, the method may further include:

and 13, for each first user meeting a first preset condition, estimating state information according to the corresponding first user information, and updating the first user information of the first user by using the state information.

The first user satisfying the first predetermined condition may be any user that may be in the seismic area when the earthquake occurs, may be a user that may be in the seismic area when the earthquake occurs and is trapped or out of contact, or the like.

The server may estimate, for each of the first users satisfying a first predetermined condition, state information of the first user according to the first user information corresponding to the first user information collected in the first user information set. The status information may include at least one of a user trapped state, a likely trapped location, a health state, a food water source state, an activity space state, an emergency level, and the like.

The first user information of the first user comprises user information obtained by a server from a plurality of channels at a plurality of moments, such as user information obtained by a client user information acquisition page before an earthquake, sensor information and/or equipment information obtained during the earthquake, state information such as possible trapped positions of the user obtained from an associated user after the earthquake, user attribute data and/or user behavior data obtained from a third party platform, and the like. And the server performs state analysis on each first user according to the first user information obtained by the channels to obtain the state information of the first user.

For each first user, when the corresponding first user information includes sensor information such as unprocessed audio/video, the sensor information may be processed first to estimate state information from the sensor information. When the client sends sensor information to the server or other clients, raw data obtained from the sensor, such as recorded audio data, image data of a camera and the like, can be directly sent, and the server processes unprocessed sensor data; the method can also be used for processing the sensor information by using a preset sensor information processing method to obtain a processing result, and the processing result is sent to a server or other clients, so that the server does not need to process the processed sensor information.

The processing of the sensor information to estimate the status information from the sensor information may include processing the recorded information to obtain the status information. Such as at least one of a user trapped state, a likely trapped position, a health state, a food water source state, an activity space state, etc. from the recorded information.

The server can use a voice recognition method to recognize the recording information into text information; and processing the text information to obtain state information. Word segmentation can be performed on the text information by using a word segmentation algorithm to obtain a plurality of word segments; each word segment is matched with a preset keyword, when one word segment is matched with one preset keyword, the type of the keyword (the type of the keyword corresponds to the type of the state information) is determined, the type of the keyword is used as the type of the state corresponding to the word segment, the word segment is used as the state value of the type of the state, or the number or degree of the related word segments are determined from adjacent word segments (such as the word segments belonging to the same sentence) and are used as the state value of the corresponding type of the state.

The server may preset various types of keywords, such as location keywords, health keywords, food water source keywords, quantity or degree keywords, item keywords, etc. For example, the location key may include a bathroom, hallway, stairway, living room, kitchen, floor, room number, etc.; health keywords may include body parts, diseases, trauma related keywords, etc.; the number may represent food, water, room number, the extent may represent the extent of injury, etc.

For example, when the user says that the foot of the user is injured, after the user is in a bathroom, voice recognition and word segmentation are performed on the recorded information, so that a plurality of word segments of ' me ', ' foot ', ' injured ', ' is obtained; "in", "toilet". Matching each word with a preset keyword library, wherein 'feet' are in a healthy word library, and 'injured' are in a degree word library, and determining the health state of a user as injured; and (5) determining the position of the user as the bathroom if the bathroom is in the position word stock.

Multiple text modes can be preset, and the text information can be processed by using a mode matching method to obtain state information. For example, setting the "in $loc" mode, the user is said to be "in toilet" and the model is matched, resulting in the location being toilet.

The processing of the sensor information to estimate the state information from the sensor information may include processing the image or video information to obtain the state information. The image information can be classified by using a picture classification model to obtain the category information of the image, and the position type corresponding to the category is obtained according to the category information. The location type can be outdoor or indoor, and the outdoor can be further subdivided into playgrounds, streets, roadways and the like; the interior can be divided into corridor, stairs, living room, bedroom, toilet, office, classroom, conference room, etc. The picture classification model may be a deep learning model, which may be trained using manually calibrated image datasets. For video information, at least one frame of image may be acquired from the video and processed using a picture classification model. The user trapped state can be determined according to the position category, if the user is outside the outdoor position such as a playground, the user trapped state is safe, otherwise, the user trapped state is trapped.

For example, a user can hold a device such as a mobile phone in the escape or hiding process, the device client obtains image information from the camera to obtain environment information when the user escapes or hides, the image classification model is used to obtain a position category corresponding to the environment information, and the GPS position information obtained by combining with GPS, a base station, WIFI and the like is used to accurately determine the position of the user in an earthquake.

The processing the sensor information to estimate the state information from the sensor information may include processing sensor information such as a gyroscope, an acceleration sensor, a magnetic field sensor, etc., to obtain the state information. The sensor information can be processed by using a pedestrian dead reckoning algorithm to obtain information such as the number of steps of movement, the walking speed, the walking direction and the like of a user in an earthquake. For example, if the mobile terminal is not moving, it may be in a room; if the mobile terminal moves a long distance in a certain direction, it may be in a corridor. When the user escapes after receiving the earthquake information, a certain address (such as a residence address, a working address and the like) set by the user before the earthquake is taken as a starting point, and a specific possible trapped position is determined according to the movement information.

For each type of state information, corresponding state values can be obtained through fusion according to a plurality of relevant user information in the first user information. For a certain type of state information, when the user information of multiple information sources has different values for the type of state information, corresponding weights can be given to each value; or the value of the state information of the type is set to the value with the highest possibility. For example, for state information of likely trapped locations, when a user contains multiple likely trapped locations (e.g., multiple associated users set different likely trapped locations for them, or one associated user sets multiple different likely trapped locations for them, etc.), a corresponding weight is calculated for each likely trapped location. The technician can preset different weights for each type of information source, so that the weights corresponding to all information sources of each valued state information are added according to the information sources to serve as the valued weights. For example, high weight is given to user information obtained from user clients during an earthquake, low weight is given to user information obtained from associated users or other knowledgeable clients (high weight may be given to user information obtained after viewing user information during an earthquake while low weight is given to user information obtained without viewing user information during an earthquake).

The user state information may be determined by at least one of position information, state information, etc. at/after the earthquake. Safety may be considered when the user is outside of the seismic area when the user is seismic, and/or when the seismic intensity is below a threshold, and/or when the user is in a safe area. The user can be judged whether to be in a safe area or not according to at least one of the position type, the earthquake intensity, the earthquake resistance level of the position and the like of the corresponding position. For example, if the location is in an open area, it is considered safe; and when the earthquake resistance level and the earthquake intensity of the position reach the conditions, the position is regarded as safe, for example, the earthquake resistance level is larger than the earthquake intensity. The state information of the user can be obtained from sensor information such as audio and video, operation controls, user information acquisition pages and the like, such as the trapped or safe state of the user can be obtained from the audio and video information; the user client may contain a security control, which when triggered, the client sends a security message to the server, causing the system to confirm that the user is in a secure state; the user or associated user may collect page setting status information via user information. If the system does not acquire the information of the user during or after the earthquake, the user state is the disconnection; after the earthquake, the user or the rescue personnel can set the user state to be rescue through the user information acquisition page.

Computing the location where the user may be trapped. The user may be trapped in a location, which may be classified as a coarse location, a fine location. The rough position can be a position obtained by using GPS, wifi, base station and other positioning methods, and the positioning precision is low; accurate location, such as the floor, room number, specific location in the room (toilet, under desk, under bed, etc.) where the user is located. When the user client sends out position information (may contain only a rough position, or both a rough position and a precise position) during/after an earthquake, such as to a server, to other user clients, to a rescuer client, etc., and/or when the rescuer sets the user position, the user position/certain position is determined, and no further determination of the position by other methods is required. For example, when the position information of a certain user includes a plurality of address information set before an earthquake and GPS position information uploaded by a client during the earthquake, the GPS position can be taken as a rough position, the GPS position is matched with a preset address before the earthquake, if a certain preset address is matched with the GPS position, more accurate position information of a room number can be obtained from the preset address, and the possibility of various indoor positions can be further calculated.

When the rough position and/or the accurate position are uncertain, the possibility that the user is at various positions can be calculated through various position information acquired before, during and after the earthquake. For each possible location, the likelihood that the user is at that location obtained by each method may be weighted to obtain a composite weight for that location. For example, for a plurality of addresses set before an earthquake and/or position information acquired by a third party platform, the weight of each address can be obtained according to the possibility (such as the number of times, the number of days, etc.) that the user is at the position in each period and the time when the earthquake occurs; for possible position information set by the associated user, a technician can preset weights, or the associated user can set weights, and the weights can be determined according to the situation when the associated user sets the position information, for example, when the associated user is viewing the audio and video data when the position is reset when the target user is in an earthquake, high weights are given, and when the user is not viewing any information of the target user, low weights are given; and adding the multiple weights of each position to obtain the comprehensive weight.

The accurate position may be determined based on processing results of sensor data such as audio and video, and/or associated user estimated position information, and/or third party platform data. Third party platform data, such as when an earthquake occurs, when the user is watching the smart television, then the user is likely to be in the living room; when the user is using the learning platform, it is likely to be in a bedroom; the user may be in the kitchen while the user is handling the intelligent range hood. The likelihood of each location obtained from the multiple channels may also be added to obtain a composite likelihood for each location.

The health state, food water source state and activity space state of the user can be calculated according to the processing result of the sensor data such as the audio/video and/or the health information, food water source information and activity space information estimated by the associated user.

Further, after obtaining status information such as user safety/trapped/saved, trapped/likely trapped location, health status, food water source status, activity space status, etc., the user urgency may be calculated using preset rules based on at least one of seismic information, user personal information, status information, etc. For example, earthquake intensity is high, users are aged high, severe injuries are caused, food water sources are small, and emergency degree is high; the earthquake intensity is low, and when the user is young and middle-aged, healthy and the food water source is sufficient, the emergency degree is low.

An embodiment of the application provides an information statistics method, which is applied to a client, and the client can run in a terminal device. By way of example, the terminal may be a variety of electronic devices including, but not limited to, mobile electronic devices such as mobile phones, notebook computers, digital broadcast receivers, personal digital assistants (Personal Digital Assistant, PDAs), tablet computers (PADs), portable multimedia players (Portable Media Player, PMPs), in-vehicle electronic devices (e.g., in-vehicle navigation electronic devices), wearable devices, and the like, and stationary electronic devices such as digital Televisions (TVs), desktop computers, and the like.

The client can be installed in at least one electronic device used by the general masses, rescue workers, commanders and the like, and also can be installed in a special user information collecting device, such as at least one user information collecting device deployed in each region of the frequent earthquake region to specially collect user information, so that the local rescue commander can obtain local user information from the user information collecting device, and rescue work can be rapidly and accurately unfolded.

Fig. 11 is a schematic flow chart of an implementation of the information statistics method, as shown in fig. 11, in an embodiment of the present application, the method for performing information statistics by a client may include the following steps:

step 21, a twelfth user information set is acquired, wherein the twelfth user information set comprises twelfth user information of at least one first user, and the twelfth user information comprises at least one of identity information, position information, health information, relationship information, equipment information, sensor information and state information of the first user.

The twelfth user information collection can be user information obtained by the client end through each function module of the equipment, such as a positioning module, a sensor such as an audio and video record, a user information acquisition page and the like, and can be twelfth user information of at least one first user obtained before, during or after an earthquake; the user information collection collected by the client from other clients received by other clients can be used, such as exchanging the user information collected by the clients with each other during or after an earthquake; the user information set received from the server may be, for example, the server may send the user information of the user who may be in the area of the client to the client before, during, or after the earthquake.

The twelfth set of user information may be at least one of the second set of user information, the third set of user information, the fourth set of user information, the fifth set of user information, the sixth set of user information, the ninth set of user information, and the like, and may be a set of user information obtained by integrating at least one of the second set of user information, the third set of user information, the fourth set of user information, the fifth set of user information, the sixth set of user information, the ninth set of user information, and the like.

Step 23, outputting the twelfth user information set.

The outputting the twelfth user information set may be sending the twelfth user information set to a server, so that the server may update the first user information set according to the twelfth user information set, and determine the user statistics information of the seismic area according to the first user information set. For example, the client may obtain the user information through the user information acquisition page, obtain sensor information such as audio and video during an earthquake, and then send the obtained user information to the server.

And outputting the twelfth user information set, namely sending the twelfth user information set to other clients, so that the user information is propagated. For example, the clients of the trapped users can mutually output the user information collected by the clients to the other party, so that the user information is transferred, and the user trapped in the deep building can transfer the user information to the outside through relay of short-range communication; the trapped user client may send the collected user information to the rescuer's client.

Step 24, updating an eleventh user information set according to the twelfth user information set, wherein the eleventh user information set comprises eleventh user information of at least one first user, and the eleventh user information comprises at least one of identity information, position information, health information, relationship information, equipment information, sensor information and state information of the first user.

After the twelfth set of user information is obtained, i.e. after step 21, the eleventh set of user information may be updated according to the twelfth set of user information. The eleventh set of user information may be stored in the storage device of the client, may be stored in the storage device in the form of a database file, a file system file, or the like. That is, after step 21, the client may not only output the obtained twelfth set of user information to other devices (step 23), but also update the eleventh set of user information stored in the client according to the twelfth set of user information (step 24).

The updating the eleventh user information set according to the twelfth user information set may be adding twelfth user information of a plurality of first users included in the twelfth user information set to eleventh user information of a first user corresponding to the eleventh user information set, for example, adding user information not included in the eleventh user information to eleventh user information; and/or the number of the groups of groups,

and modifying eleventh user information of the first users corresponding to the eleventh user information set according to twelfth user information of a plurality of first users contained in the twelfth user information set, for example, updating information such as user state information, weight information of an update position and the like according to latest user information.

The eleventh user information set generally contains user information of a plurality of users in/likely to be in an area where the client is located when an earthquake occurs, so that after the earthquake, even if communication is interrupted, a local rescue commander can rapidly develop rescue according to the eleventh user information set stored by the client, without waiting until communication is established with the server, and then obtaining the user information of the corresponding area from the server.

Step 25, outputting the eleventh user information set.

The outputting the eleventh user information set may be sending the eleventh user information set to a server, so that the server may update the first user information set according to the eleventh user information set, and determine the user statistics of the seismic area according to the first user information set. For example, the client may transmit user information of a plurality of users collected at a plurality of times to the server.

The outputting the eleventh user information set may be sending all or part of information of the eleventh user information set to other clients, so as to realize propagation of user information. For example, the clients of the trapped users can mutually output the user information collected by the clients to the other party, so that the user information is transferred, and the user trapped in the deep building can transfer the user information to the outside through relay of short-range communication; the trapped user client may send the collected user information to the rescuer's client. The eleventh set of user information in the clients of the plurality of trapped users may comprise the same user information, as well as different user information, and the clients may send only different user information to the device establishing the communication connection.

The outputting the eleventh set of user information may be displaying the eleventh set of user information in an interface. For example, the client may display the eleventh user information set according to a certain information type by using a tree control, a list control, and other controls, for example, according to a hierarchical structure of counties, villages and towns, streets, cells, and buildings, and interactively display the eleventh user information set by using the tree control, so that users such as rescue personnel can view the collected eleventh user information set, and rescue work is implemented according to the eleventh user information set.

And step 26, calculating user statistical information according to the eleventh user information set.

User statistics may be calculated based on at least one of gender, age, likely trapped location, trapped state, health state, food water source condition, activity space state, urgency, etc. of each user in the eleventh set of user information. For example, the total number of people in each region (e.g., province, city, district, county, town, street, district, building, etc.), the number of men/women in each region, the number of people in each region safe/trapped/rescued/disunited, the number of people in each region severely injured/lightly injured/healthy, the number of people in each region with sufficient food/insufficient food, the number of people in each region with various degrees of urgency, etc. can be calculated at the time of the earthquake.

Further, before calculating the user statistics according to the eleventh user information set, the client estimates, for each first user of the eleventh user information set, state information of the user according to the eleventh user information of the first user, so that the client can calculate the user statistics according to the user state information. The method for estimating the state information of the user may refer to the description of the corresponding parts in the foregoing method embodiment, which is not repeated here.

And step 27, outputting the user statistical information.

The client can display the user statistical information through a display interface. Superimposing and displaying statistical information at a corresponding position in map data; the statistical information is displayed in a predetermined format using controls such as tree controls, list controls, and the like.

The embodiment is an information statistical method of a client, which is used for correspondingly implementing the foregoing server information statistical method, so that the description is relatively simple, and the relevant parts can refer to the description of the corresponding parts in the foregoing server information statistical method embodiment, which is not repeated herein.

In the embodiment of the disclosure, the twelfth user information set is acquired and output, so that the client can acquire the user information and spread the user information, and the rescue commander can acquire the user data of the earthquake area. The eleventh user information set is updated according to the twelfth user information set, the eleventh user information set is output, the client can store the collected user information, and after communication is established with other trapped users or clients of rescue commanders after an earthquake, the collected user information is transmitted, so that the rescue commanders can quickly obtain disaster situations of local users, rescue is quickly and accurately implemented, and the workload of searching the trapped users by the rescue staff is reduced. And calculating user statistical information according to the eleventh user information set, and outputting the user statistical information, so that rescue command personnel can intuitively know the disaster situation of the local user. Even if the communication facilities are damaged by the earthquake, rescue commander in the earthquake area cannot communicate with the outside, and rescue commander can rescue according to the user information collected by the client, without obtaining the user information of the local user from the server after establishing communication connection with the server.

Fig. 12 is a flowchart of an implementation of the information statistics method, as shown in fig. 12, in an embodiment of the present application, the method for performing information statistics by a client may include the following steps:

step 22, receiving the seismic information.

When an earthquake occurs, the server can earthquake information of the earthquake early warning mechanism and send the earthquake information to the client side of the earthquake area, and the client side receives the earthquake information sent by the server.

When the earthquake is performed, the server can send the earthquake information in the exercise information to the client side of the exercise area according to the exercise information. When a city performs earthquake exercise, information such as a seismic source, a seismic level and the like of the exercise is used as earthquake information and sent to a client side positioned in the city.

Step 28, acquiring prompt information, wherein the prompt information comprises communication connection information and/or user information receiving and transmitting information.

And 29, outputting the prompt information.

After receiving the seismic information, the client can establish communication connection with a server or other clients, transmit user information and realize collection and propagation of the user information. The client can obtain the prompt information according to the communication connection condition with other equipment and/or the user information receiving and transmitting condition, and output the prompt information. The communication connection information may include a connection condition with the server, a connection condition with other clients nearby, such as whether to establish a communication connection with the server, whether to establish a communication connection with other clients nearby, and the number of clients that establish a communication connection. The user information receiving and transmitting information may include transmission information of user information and/or reception information of user information. The information type includes identity information and sensor information, and the sending object includes the server and other nearby clients. And the received information of the user information, such as at least one of a user identity corresponding to the received user information, an information source (such as a server, a client and the like), the number of users contained in the received user information and the like.

The client may display the prompt information on an interface and/or convert the prompt information into voice information using a voice synthesis method and output the voice information.

For example, when the client establishes a communication connection with the server during an earthquake, user information such as sensor information is transmitted to the server, and user information of other users in the vicinity is received from the server, information such as the prompt information to establish a communication connection with the server and the number of users who have received the user information can be output.

The user can know the help seeking condition of the user by outputting the prompt information of the sending condition of the user information to the user, and if the user information is sent to a server or other clients, the user can wait for rescue with tolerance; the prompt information of the received user information is output to the user, so that the user is prompted to send the received user to the rescue commander after an earthquake.

Fig. 13 is a schematic flow chart of an implementation of the information statistics method, as shown in fig. 13, in an embodiment of the present application, the method for performing information statistics by a client may include the following steps:

step 211, obtaining the second user information set, where the second user information set includes second user information of at least one first user, and the second user information includes at least one of identity information, location information, health information, and relationship information of the first user.

I.e. the twelfth set of user information of step 21, may be the second set of user information.

Step 212, outputting the second user information set.

The client may send the second set of user information to the server.

Step 213, updating the eleventh user information set according to the second user information set.

After the second user information set sent by the receiving client, the eleventh user information set may be updated according to the second user information set.

The updating the eleventh user information set may be adding new user information of at least one first user corresponding to the second user information set to user information of the first user corresponding to the eleventh user information set. If the user information is set after the new user is registered, the acquired user information is added into an eleventh user information set; when a user adds new information such as location information, health information, relationship information, etc., the information is added to the user information of the user.

The updating the eleventh user information set may also be changing corresponding user information of the corresponding first user in the eleventh user information set according to user information of at least one corresponding first user in the second user information set. For example, when the user modifies information such as identity information, position information, relationship information and the like, corresponding information of a corresponding user in the eleventh user information set is modified; and when the position information and the time information are received, changing the information such as the time duration and the like of the corresponding position of the corresponding user in the eleventh user information set.

In the embodiment of the disclosure, the client acquires the second user information set, outputs the second user information set, and the user can input the user information before and after the earthquake through the user information acquisition page of the client, so that the system can acquire the user state during/after the earthquake, thereby providing data support for rescue commanders.

Fig. 14 is a flowchart of an implementation of an information statistics method, as shown in fig. 14, in an embodiment of the present application, a method for performing information statistics by a client may include the following steps:

step 221, receiving the seismic information.

Step 222, obtaining the third user information set, where the third user information set includes third user information of at least one first user.

After receiving the seismic information sent by the server, the client can acquire part or all of sensor information such as real-time position, equipment information, audio and video, user state information and the like, and obtain a third user information set. The twelfth set of user information of step 21 may be the third set of user information.

Further, before the third user information set is acquired, the client may determine whether a predetermined condition is reached according to the seismic information, and if the predetermined condition is not reached, the third user information set is not acquired. For example, the predetermined condition may be a seismic intensity condition, and the third set of information is not acquired when the seismic intensity is below a threshold; the predetermined condition may also be set based on information such as distance to the source, magnitude, etc., for example, if the distance to the source is less than 10km, the third set of user information is obtained regardless of the seismic intensity.

After receiving the earthquake information, the client can output the earthquake information to the user in a mode of voice broadcasting, display and the like, so that the user can escape or hide according to the earthquake information. To reduce false positives, the client may determine whether to output alert information to the user based on the seismic intensity, e.g., outputting the seismic information only if the seismic intensity is above a preset threshold. The condition of the client outputting the seismic information to the user may be the same as or different from the condition of determining whether to acquire and output the third user information set, and the condition range of acquiring the third user information set may be greater than or equal to the condition range of outputting the seismic information to the user. For example, the seismic information is output to the user only when the seismic intensity is higher than 3, and the third set of information is acquired when the seismic intensity is higher than 2.

The client may acquire the third set of user information immediately after receiving the seismic information, and may also acquire the third set of user information at one or more specific or non-specific times after receiving the seismic information. For example, the client may acquire the third set of user information during an earthquake and send the third set of user information to the server before the communication facility is destroyed; the client may acquire the third user information set after the earthquake, the user may be separated from the client after the earthquake, and the client may not be operated, so the client may periodically acquire voice information (e.g., acquire voice information every 2 hours during a non-sleep period, the client may output specific voice information before acquiring voice information to prompt the user to acquire information), or acquire voice information after receiving a specific voice instruction.

Further, the client may process the sensor information to obtain a processing result, and the third user information set may include the sensor information and/or the processing result. The processing of the sensor information may be performing voice recognition on the recorded information to obtain text information, and may further obtain user status information from the text information; the image information can be input into a trained picture classification model to obtain a position category; the information of the acceleration sensor, the gravity sensor, the magnetic field sensor, the gyroscope and other sensors can be processed to obtain the information of the step number, the moving direction and the like. After the sensor information is processed, the sensor information is sent to equipment such as a server, and the like, so that the traffic can be greatly reduced. The client may process all or part of the sensor information, e.g. may process only the image information and not the other information.

Optionally, in the present application, the client may also determine whether to process the sensor information according to its own power, signal strength, computing capability of the device, and so on. For example, if the power of the mobile device is higher than a preset power threshold and the computing capability of the device meets the requirement, the sensor information is processed, and if the power of the mobile device is lower than the preset power threshold, the processing is not performed.

Step 223, outputting the third user information set.

The client may output the third set of user information to the device establishing the communication connection. And the third user information set is sent to a server through TCP/UDP connection or a short message signaling channel in the earthquake, and is sent to other clients for establishing connection, such as clients of other trapped users or rescue workers, through Bluetooth, wifi and the like after the earthquake.

Further, before sending the third user information set to the server, the client may determine a reporting policy, and then acquire and report information according to the reporting policy, where the reporting policy includes at least one of a reporting time policy, a reporting information type, and the like.

The reporting time policy includes at least one of reporting time interval, initial reporting time, reporting time point, etc. The client may report information at intervals, for example, 1s, indicating that the client reports information every 1s. The time interval may be a specific value, such as 1s; or a time range, such as 1 to 2 seconds, after each report, the client randomly selects a value from the range as the time interval of the next report; the time interval can be different according to the arrival time of the seismic waves, for example, when the arrival time of the seismic waves is more than 20s, the seismic waves are reported every 5s, when the arrival time of the seismic waves is 10 s-20 s, the seismic waves are reported every 2s, and when the arrival time of the seismic waves is within 10s, the seismic waves are reported every 1s. And the starting reporting time indicates that the client starts reporting from the time, for example, the client near the seismic source begins reporting after the seismic wave reaches the first 10s, so that the client far from the seismic source reports firstly and then reports later. And when the current time of the client is a certain time of the reporting time point, reporting information, wherein the reporting time point is 10s, 8s, 6s, 4s, 3s, 2s and 1s before the arrival of the earthquake waves.

After receiving the earthquake data of the earthquake early warning mechanism, the server can determine a reporting strategy according to the earthquake data and send the reporting strategy to the client, so that the client obtains and reports information according to the reporting strategy. For example, the server calculates the seismic intensity of each area according to the seismic data, and selects different reporting strategies for each area with the seismic intensity, such as reporting the position information and the state information every 1s for the area with the seismic intensity higher than the 9 level; and reporting the position information, the sensor information and the state information every 2s for the area with the seismic intensity of 6 to 8 levels. Or alternatively, the process may be performed,

After receiving the seismic data, the client determines a reporting strategy according to the seismic data. For example, reporting strategies corresponding to different seismic intensities and/or seismic wave arrival times are preset in the client, and after receiving the seismic data, the client acquires the seismic intensity information and/or the seismic wave arrival times and selects the corresponding reporting strategies according to the seismic intensities and/or the seismic wave arrival times.

Further, user information may be automatically exchanged with other devices at regular intervals after the occurrence of an earthquake, such as every two hours, such as collecting information at full points, and exchanging information 10 minutes after each collection.

Step 224, updating the eleventh user information set according to the third user information set.

After the client obtains the third user information set, i.e. after step 222, the eleventh user information set may be updated according to the third user information set.

The updating the eleventh user information set may be adding new user information of at least one first user corresponding to the third user information set to user information of the first user corresponding to the eleventh user information set. And adding sensor information such as audio and video obtained during and after the earthquake into the first user information set.

The updating the eleventh user information set may also be changing corresponding user information of the corresponding first user in the eleventh user information set according to user information of at least one corresponding first user in the third user information set. For example, according to the third user information, user state information is estimated, and state information of a corresponding user in the eleventh user information set is modified to the user state information.

In the embodiment of the disclosure, the client receives the earthquake information, acquires the third user information set, outputs the third user information set, can timely acquire the position, health condition, food water source condition and other information of the user when the earthquake happens before the communication facility is damaged by the earthquake, and sends the information to the server, so that rescue command personnel can quickly acquire the user information of the earthquake area; after the earthquake occurs, the user information can be acquired in a voice mode and sent to other equipment, so that the aim of asking for help is fulfilled, and even if the user is trapped, the user information can be acquired and sent through man-machine separation, and the success rate of asking for help of the user is improved. The client receives the seismic information, acquires the third user information set, and updates the eleventh user information set according to the third user information set, so that the client can store the acquired user information, and the system can acquire richer user information, so that the user state information can be estimated more accurately, and more accurate data can be provided for rescue commanders.

Fig. 15 is a schematic flow chart of an implementation of the information statistics method, as shown in fig. 15, in an embodiment of the present application, the method for performing information statistics by a client may include the following steps:

step 231, receiving the fourth set of user information and/or the sixth set of user information.

The server may determine the first sub-area corresponding to the current location of the client according to the current location of the client, and obtain the fourth user information set corresponding to the first sub-area, where the fourth user information set includes the fourth user information of all or part of the users that may be in the first sub-area. The fourth user information may include at least one of identity information, location information, health information, relationship information, device information, sensor information, status information, etc. of the user, such as all or part of second user information uploaded to a server by a user client before an earthquake, third user information uploaded to the server after receiving the earthquake information at the time of the earthquake, etc., or user information obtained by other methods. Each of the first sub-areas may be a geographical area spanning hundreds of meters to kilometers. That is, the server may send the user information of the user near the location of the client to the client, so that the user may quickly develop rescue according to the user information of the user near the location received by the client.

The server may determine a target area according to the seismic information, acquire a plurality of third sub-areas of the target area, acquire the sixth user information set for each of the third sub-areas satisfying the second predetermined condition, and send the sixth user information set to at least one client satisfying the third predetermined condition. For each of the third sub-areas satisfying the second predetermined condition, the sixth user information of all or part of the users who may be in the third sub-area may be acquired. The sixth user information may include at least one of identity information, location information, health information, relationship information, device information, sensor information, status information, etc. of the user, such as all or part of the second user information uploaded to the server by the user client before the earthquake, the third user information uploaded to the server after receiving the earthquake information at the time of the earthquake, etc., or user information obtained by other methods. The third sub-region that satisfies the second predetermined condition may be any of the third sub-regions within a distance from the source. The client satisfying the third predetermined condition may be a client that is farther from the source than the third sub-region and is closer to the third sub-region. Thus, the sixth set of user information received by the client is a set of information for a range of users closer to the source than the client.

Step 232, updating the eleventh user information set according to the fourth user information set and/or the sixth user information set.

After receiving the fourth user information set and/or the sixth user information set, the client may update the eleventh user information set according to the fourth user information set and/or the sixth user information set, for example, the user information of at least one first user corresponding to the fourth user information set and/or the sixth user information set is added to the user information of the first user corresponding to the eleventh user information set.

In the embodiment of the disclosure, the client receives the fourth user information set and/or the sixth user information set, and updates the eleventh user information set according to the fourth user information set and/or the sixth user information set, so that the client can obtain user information with a certain range of positions of the client when an earthquake occurs, and a local rescue commander can rapidly and accurately develop rescue according to the received user information; the client can obtain user information of a certain area close to the earthquake source during an earthquake, after the earthquake, rescue commander can send the information back to the corresponding area, even if the corresponding area is in an earthquake early warning blind area and is seriously affected by the earthquake, the server can not send the user information of the area back to the corresponding client during the earthquake, and can also send the user information of the area to the client of the adjacent area, so that the related staff can send the corresponding user information back to the corresponding area in a manual conveying mode and the like to assist rescue command work.

Fig. 16 is a schematic flow chart of an implementation of the information statistics method, as shown in fig. 16, in an embodiment of the present application, the method for performing information statistics by a client may include the following steps:

step 241, a P2P network establishment instruction is received, and a P2P network is established.

Step 242, exchanging the fifth set of user information with other peer nodes through the P2P network.

The client may obtain the fifth set of user information from the eleventh set of user information, e.g. obtain information such as identity information, location information, health information, sensor information, etc. of the client login user and/or its associated user from the eleventh set of user information; the client side can also directly obtain user information from sensors such as audio and video and the like, and the user information is used as the fifth user information set; the client may also receive all or part of the user information received from the server or other clients as the fifth set of user information; the client may combine the user information obtained in the above three ways as the fifth set of user information, and so on.

The exchanging the fifth set of user information with other peer nodes through the P2P network may be that each client in the P2P network sends the fifth set of user information to all or part of other peer nodes. For example, the clients in the P2P network may send the fifth set of user information to each other, e.g., one client broadcasts the fifth set of user information to other peer nodes; or all clients in the P2P network send the fifth set of user information to only a few clients, for example, to at least one P2P target client; after collecting the fifth user information sets of the plurality of clients, the P2P target client may send them together to some nodes in the P2P network.

And step 244, if the fifth preset condition is met, the fifth user information set is sent to the server.

The server may select the client in the P2P network as the P2P transit client according to at least one of occupation information, client device information, client real-time location information, and status information of the client login user, and the fifth predetermined condition may be whether the client is the P2P transit client; if the client determines that the client is a P2P transit client, the client may send the fifth set of user information to the server after receiving the fifth set of user information sent by other clients. The P2P transit client may be consistent with the P2P target client.

Step 245, updating the eleventh user information set according to the fifth user information set.

The client may update the eleventh set of user information according to the received fifth set of user information after receiving the fifth set of user information of the other clients. For example, adding new user information of at least one first user included in the fifth set of user information to the eleventh set of user information, adding user information of at least one new first user included in the fifth set of user information to the eleventh set of user information, and so on.

In the embodiment of the disclosure, the client receives the instruction for establishing the P2P network, establishes the P2P network, exchanges the fifth user information set with other peer nodes through the P2P network, and updates the eleventh user information set according to the fifth user information set, so that the client can send the user information to other nearby clients while the communication facility is not destroyed in the earthquake, the way of obtaining the user information of trapped users by local rescue command personnel is improved, and the rescue command personnel can obtain the user information of a plurality of users only by establishing communication with one client, thereby being capable of rapidly expanding rescue. And if the client judges that the fifth preset condition is met, the fifth user information set is sent to the server, so that the server can only communicate with a few clients, the user information of all users in the earthquake area can be obtained, and the information acquisition efficiency is improved.

Fig. 17 is a schematic flow chart of an implementation of the information statistics method, as shown in fig. 17, in an embodiment of the present application, the method for performing information statistics by a client may include the following steps:

step 272, receiving the eighth set of user information, the eighth set of user information comprising the eighth user information of at least one of the third users.

And after receiving the seismic information, the server acquires the eighth user information set and sends the eighth user information set to the client. For example, the server may transmit the collected user information of a certain third user to the client of the user having an association relationship therewith at the time of or after the earthquake.

Further, before receiving the eighth user information set, the client sends a user information query request to the server, where the user query request includes a user identifier and/or identity information of at least one third user, and the server obtains the eighth user information set after receiving the user information query request and sends the eighth user information set to the client.

The client can automatically send a user information inquiry request to the server when entering the user information inquiry page, wherein the user inquiry request comprises the user identification of the current login user so as to obtain the user information of the third user associated with the current login user.

The client may include an identity information obtaining control to obtain identity information, such as a name, an identity card number, a phone number, etc., of at least one third user, and the server sends a user information query request to the server according to the identity information obtained by the identity information obtaining control to obtain user information of the corresponding third user. For example, a user may enter identity information of at least one associated user of immediate relatives, classmates, friends, colleagues, patients, students, etc. in an identity information acquisition control to obtain all or part of their information uploaded before, during, after an earthquake.

Step 273, outputting the eighth user information set.

The client may display the eighth set of user information on a user information display interface.

The client can output the recording information in the eighth user information set through the audio output unit; and/or the client may convert the eighth set of user information into voice information in a predetermined format through a voice synthesis technique and output the voice information using an audio output unit, for example, the client may convert the user status information of the third user into voice information and output recording information and voice information. For example, when the client logs in to the user and is trapped in the earthquake and cannot operate the device, the client may output the eighth set of user information in a voice manner (the client may output the eighth set of user information after receiving a voice instruction of the user).

Step 274, obtaining the ninth set of user information, where the ninth set of user information includes at least one of the ninth pieces of user information of the third user, and the ninth piece of user information includes at least state information of the third user.

The client may obtain the edited user information after detecting the editing operation of the user on the eighth user information set, so as to obtain the ninth user information set.

When the client displays the eighth user information set through the user information display interface, the eighth user information set can be displayed in a mode of an editable control, so that a user can edit the eighth user information set, such as adding new user information, modifying current user information, and the like. For example, the user may correct the state information obtained by the system according to the sensor information processing such as the audio and video of the third user, and correct the error; the user may add new user information to the third user, such as adding possibly stranded locations, health information, identity information, etc.

The client may provide a user information acquisition page, so that the user may directly input the ninth user information set through the user information acquisition page. The user information acquisition page may obtain at least one of identity information, health information, status information, and the like of the third user.

The client can record voice information and process the recorded information to obtain the ninth user information of the third user. For example, when the user is trapped and cannot operate the device, information such as a possible trapped position, state information and the like of the third user having an association relationship with the third user can be described in a voice manner; and the client performs voice recognition and state analysis on the recording information to obtain the state information of the third user.

After the earthquake occurs, the neighbors, classmates, colleagues, etc. of the third user may know the location where the third user may appear when the earthquake occurs, however they may not be the associated users of the third user, e.g. they are not included in the relationship information of the third user, so that they have no authority to obtain the eighth user information of the third user. The client may provide a user information acquisition page so that the user may directly input the ninth user information of the third user as an informed person without obtaining the eighth user information.

Step 275, the ninth user information set is sent to a server, so that the server updates the state information of at least one third user according to the ninth user information set.

The client may send the ninth set of user information to the server when the client establishes a communication connection with the server. For example, after an earthquake, the client may be outside the earthquake area, unaffected by the earthquake, and may establish a communication connection with the server; alternatively, the local area may be in communication with the server after the earthquake, the user may enter the area after rescue, and the client establishes a communication connection with the server.

Step 276, updating the eleventh user information set according to the ninth user information set.

The client may update the eleventh set of user information according to the ninth set of user information. For example, the client receives the eighth user information set of the associated user during an earthquake, the user inputs the ninth user information set of the associated user according to the eighth user information set after the earthquake, the user is trapped, the client cannot establish communication connection with the server, and the ninth user information set cannot be directly sent to the server; the client may update the eleventh set of user information according to the ninth set of user information, so as to send the eleventh set of user information out when establishing communication with other trapped users or rescuer clients.

The updating the eleventh user information set according to the ninth user information set may be adding the ninth user information of at least one third user included in the ninth user information set to the user information of the third user in the eleventh user information set, and/or updating the state information of the third user according to the ninth user information.

In the embodiment of the disclosure, the eighth user information set is received, the eighth user information set is output, the ninth user information set is obtained, and the ninth user information set is sent to the server, so that the user information of the trapped user in the earthquake area can be received, the user information after the user edits the user information is obtained, the error problem caused by the condition analysis of the user information by the system is overcome, the more accurate and comprehensive user information is obtained from the related user, and the accuracy of the data is improved. And updating the eleventh user information set according to the ninth user information set, so that the client can save the ninth user information set even if the client cannot establish communication with a server, and the client can send the ninth user information set after establishing communication with clients of other trapped users or rescue workers.

Referring to fig. 18, a block diagram of an information statistics apparatus of an embodiment of the present disclosure is shown.

The information statistics device of the embodiment of the present application may be provided at a server side, and the information statistics device may include a first collecting unit 101, a first statistics unit 102, a first output unit 103,

the first collecting unit 101 is configured to collect a first user information set, where the first user information set includes first user information of a plurality of first users, and the first user information includes at least one of identity information, location information, health information, relationship information, device information, sensor information, and status information of the first users;

the first statistics unit 102 is configured to determine user statistics of the seismic area according to the first user information set;

the first output unit 103 is configured to output the user statistics information.

Optionally, the collecting, by the first collecting unit, the first set of user information includes: receiving a second user information set sent by a client, wherein the second user information set comprises second user information of at least one first user, and the second user information comprises at least one of identity information, position information, health information and relationship information of the first user; and updating the first user information set according to the second user information set.

Optionally, the collecting, by the first collecting unit, the first set of user information includes: receiving seismic information, and determining a target area according to the seismic information; sending earthquake information to a client corresponding to the target area; receiving a third user information set sent by a client, wherein the third user information set comprises third user information of at least one first user; and updating the first user information set according to the third user information set.

Optionally, the collecting, by the first collecting unit, the first set of user information includes: receiving a ninth user information set sent by a client of a first user, wherein the ninth user information set comprises ninth user information of at least one third user, and the ninth user information at least comprises state information of the third user; and updating the first user information set according to the ninth user information set.

Optionally, the collecting, by the first collecting unit, the first set of user information includes: receiving seismic information, and determining a target area according to the seismic information; acquiring a plurality of second sub-areas of the target area; transmitting a P2P connection establishment instruction to a client side in the second subarea for each second subarea, so that the client side of each second subarea establishes a P2P network, and exchanges a fifth user information set through the P2P network, wherein the fifth user information set comprises fifth user information of at least one first user; receiving the fifth user information set sent by the client; and updating the first user information set according to the fifth user information set.

Optionally, the information statistics apparatus of this embodiment further includes: and a user information output unit configured to output all or part of the first user information of all or part of the users in the first user information set upon receiving the seismic information.

Optionally, the user information output unit outputs all or part of the first user information of all or part of the users in the first user information set when receiving the seismic information, including: receiving the seismic information, and determining a target area according to the seismic information; acquiring a plurality of first sub-areas of the target area; for each first sub-region, acquiring a fourth user information set, wherein the fourth user information set comprises all or part of fourth user information of the first user possibly located in the first sub-region; for each first sub-region, transmitting the corresponding fourth set of user information to at least one client of the first sub-region, and/or transmitting the fourth set of user information to at least one client of the first sub-region adjacent to the first sub-region.

Optionally, the user information output unit outputs all or part of the first user information of all or part of the users in the first user information set when receiving the seismic information, including: receiving the seismic information, and determining a target area according to the seismic information; acquiring a plurality of third sub-areas of the target area; for each third sub-region meeting a second predetermined condition, a sixth set of user information is obtained, and the sixth set of user information is sent to at least one client and/or at least one server meeting a third predetermined condition, wherein the sixth set of user information comprises sixth user information of all or part of the first users possibly in the third sub-region.

Optionally, the user information output unit outputs all or part of the first user information of all or part of the users in the first user information set when receiving the seismic information, including: receiving seismic information; judging whether a data migration condition is met, if so, acquiring a seventh user information set, and sending the seventh user information set to at least one server meeting a fourth preset condition, wherein the seventh user information set comprises all or part of received seventh user information of the first user.

Optionally, the information statistics apparatus of this embodiment further includes: and the first state analysis unit is used for estimating state information according to the corresponding first user information for each first user meeting the first preset condition, and updating the first user information of the first user by using the state information.

The information statistics device of the present embodiment is configured to implement the information statistics method of the server side corresponding to the foregoing multiple method embodiments, and has the beneficial effects of the corresponding method embodiments, which are not described herein. In addition, the information statistics device of the present embodiment is used for correspondingly implementing the foregoing information statistics method, so the description is relatively simple, and the relevant portions may refer to the description of the corresponding portions in the foregoing method embodiments, which is not repeated herein.

Referring to fig. 19, an electronic device according to an embodiment of the present disclosure is shown, where the embodiment is a structural block diagram of a server.

As shown in fig. 19, the server 100 according to the embodiment of the present application may further include a first processor 104, a first memory 105 storing executable instructions of the first processor 104, further, the server 100 may further include a first communication interface 106, and a first bus 107 for connecting the first processor 104, the first memory 105, and the first communication interface 106.

In an embodiment of the present application, the first processor 104 may be at least one of an application specific integrated circuit (Application Specific Integrated Circuit, ASIC), a digital signal processor (Digital Signal Processor, DSP), a digital signal processing device (Digital Signal Processing Device, DSPD), a programmable logic device (ProgRAMmable Logic Device, PLD), a field programmable gate array (Field ProgRAMmable Gate Array, FPGA), a central processing unit (Central Processing Unit, CPU), a controller, a microcontroller, and a microprocessor. It will be appreciated that the electronic device for implementing the above-mentioned processor function may be other for different apparatuses, and embodiments of the present application are not specifically limited. The server 100 may further comprise a first memory 105, which first memory 105 may be connected to the first processor 104, wherein the first memory 105 is adapted to store executable program code comprising computer operation instructions, the first memory 105 may comprise a high speed RAM memory, and may further comprise a non-volatile memory, e.g. at least two disk memories.

In the embodiment of the present application, the first bus 107 is used to connect the first communication interface 106, the first processor 104, and the first memory 105, and the intercommunication among these devices.

In an embodiment of the present application, the first memory 105 is used to store instructions and data.

Further, in the embodiment of the present application, the first processor 104 is configured to collect a first set of user information, where the first set of user information includes first user information of a plurality of first users, and the first user information includes at least one of identity information, location information, health information, relationship information, device information, sensor information, and status information of the first users; determining user statistical information of the seismic area according to the first user information set; and outputting the user statistical information.

Further, in the embodiment of the present application, the first processor 104 is configured to receive a second set of user information sent by a client, where the second set of user information includes second user information of at least one first user, and the second user information includes at least one of identity information, location information, health information, and relationship information of the first user; and updating the first user information set according to the second user information set.

Further, in an embodiment of the present application, the first processor 104 is configured to receive seismic information, and determine a target area according to the seismic information; sending earthquake information to a client corresponding to the target area; receiving a third user information set sent by a client, wherein the third user information set comprises third user information of at least one first user; and updating the first user information set according to the third user information set.

Further, in the embodiment of the present application, the first processor 104 is configured to receive a ninth set of user information sent by a client of a first user, where the ninth set of user information includes ninth user information of at least one third user, and the ninth user information at least includes status information of the third user; and updating the first user information set according to the ninth user information set.

Further, in an embodiment of the present application, the first processor 104 is configured to receive seismic information, and determine a target area according to the seismic information; acquiring a plurality of second sub-areas of the target area; transmitting a P2P connection establishment instruction to a client side in the second subarea for each second subarea, so that the client side of each second subarea establishes a P2P network, and exchanges a fifth user information set through the P2P network, wherein the fifth user information set comprises fifth user information of at least one first user; receiving the fifth user information set sent by the client; and updating the first user information set according to the fifth user information set.

Further, in the embodiment of the present application, the first processor 104 is configured to output the user information after receiving the seismic information.

Further, in the embodiment of the present application, the first processor 104 outputs the user information after receiving the seismic information, including: receiving the seismic information, and determining a target area according to the seismic information; acquiring a plurality of first sub-areas of the target area; for each first sub-region, acquiring a fourth user information set, wherein the fourth user information set comprises all or part of fourth user information of the first user possibly located in the first sub-region; for each first sub-region, transmitting the corresponding fourth set of user information to at least one client of the first sub-region, and/or transmitting the fourth set of user information to at least one client of the first sub-region adjacent to the first sub-region.

Further, in the embodiment of the present application, the first processor 104 outputs the user information after receiving the seismic information, including: receiving the seismic information, and determining a target area according to the seismic information; acquiring a plurality of third sub-areas of the target area; for each third sub-region meeting a second predetermined condition, a sixth set of user information is obtained, and the sixth set of user information is sent to at least one client and/or at least one server meeting a third predetermined condition, wherein the sixth set of user information comprises sixth user information of all or part of the first users possibly in the third sub-region.

Further, in the embodiment of the present application, the first processor 104 outputs the user information after receiving the seismic information, including: receiving seismic information; judging whether a data migration condition is met, if so, acquiring a seventh user information set, and sending the seventh user information set to at least one server meeting a fourth preset condition, wherein the seventh user information set comprises all or part of received seventh user information of the first user.

Further, in the embodiment of the present application, the first processor 104 is configured to, for each first user that satisfies a first predetermined condition, estimate status information according to the corresponding first user information, and update the first user information of the first user using the status information.

The steps executed by the first processor 104 in this embodiment may refer to the corresponding information statistics method at the server side in the foregoing multiple method embodiments, and have the beneficial effects of the corresponding method embodiments, which are not described herein again. In addition, the information statistics device of the present embodiment is used for correspondingly implementing the foregoing information statistics method, so the description is relatively simple, and the relevant portions may refer to the description of the corresponding portions in the foregoing method embodiments, which is not repeated herein.

Referring to fig. 20, a block diagram of another information statistics apparatus of an embodiment of the present disclosure is shown.

The information statistics apparatus of the embodiment of the present application may be provided at the client, and the information statistics apparatus may include a second acquisition unit 201, a second output unit 202,

the second obtaining unit 201 is configured to obtain a twelfth user information set, where the twelfth user information set includes twelfth user information of at least one first user, and the twelfth user information includes at least one of identity information, location information, health information, relationship information, device information, sensor information, and status information of the first user;

the second output unit 202 is configured to output the twelfth set of user information.

Optionally, the information statistics apparatus of this embodiment further includes: and the information updating unit is used for updating an eleventh user information set according to the twelfth user information set, wherein the eleventh user information set comprises eleventh user information of at least one first user, and the eleventh user information comprises at least one of identity information, position information, health information, relationship information, equipment information, sensor information and state information of the first user.

Optionally, the second obtaining unit is further configured to obtain, when receiving the seismic information, the third user information set, where the third user information set includes third user information of at least one first user; the second output unit is further configured to output the third set of information.

Optionally, the second obtaining unit is further configured to receive the fourth set of user information and/or the sixth set of user information; the information updating unit is further configured to update the eleventh user information set according to the fourth user information set and/or the sixth user information set.

Optionally, the information statistics apparatus of this embodiment further includes: and the second state analysis unit is used for estimating state information according to the corresponding eleventh user information for each first user of the eleventh user information set and updating the eleventh user information of the first user by using the state information.

Optionally, the information statistics apparatus of this embodiment further includes: the prompting unit is used for receiving the earthquake information; acquiring prompt information, wherein the prompt information comprises communication connection information and/or user information receiving and transmitting information; and outputting the prompt information.

Optionally, the information statistics apparatus of this embodiment further includes: and the third output unit is used for sending all or part of the eleventh user information set to a server and/or a client for establishing communication connection, and/or displaying the eleventh user information set in a display interface.

Optionally, the information statistics apparatus of this embodiment further includes: a second statistics unit for calculating user statistics according to the eleventh set of user information; and the fourth output unit is used for outputting the user statistical information.

The information statistics device of the present embodiment is configured to implement the information statistics method of the corresponding client side in the foregoing multiple method embodiments, and has the beneficial effects of the corresponding method embodiments, which are not described herein again. In addition, the information statistics device of the present embodiment is used for correspondingly implementing the foregoing information statistics method, so the description is relatively simple, and the relevant portions may refer to the description of the corresponding portions in the foregoing method embodiments, which is not repeated herein.

Referring to fig. 21, another electronic device according to an embodiment of the present disclosure is shown, where the embodiment is a block diagram of a structure of a terminal device.

As shown in fig. 21, the terminal device 200 provided in the embodiment of the present application may further include a second processor 204, a second memory 205 storing executable instructions of the second processor 204, and further, the terminal device 200 may further include a second communication interface 206, and a second bus 207 for connecting the second processor 204, the second memory 205, and the second communication interface 206.

In an embodiment of the present application, the second processor 204 may be at least one of an application specific integrated circuit (Application Specific Integrated Circuit, ASIC), a digital signal processor (Digital Signal Processor, DSP), a digital signal processing device (Digital Signal Processing Device, DSPD), a programmable logic device (ProgRAMmable Logic Device, PLD), a field programmable gate array (Field ProgRAMmable Gate Array, FPGA), a central processing unit (Central Processing Unit, CPU), a controller, a microcontroller, and a microprocessor. It will be appreciated that the electronic device for implementing the above-mentioned processor function may be other for different apparatuses, and embodiments of the present application are not specifically limited. The terminal device 200 may further comprise a second memory 205, which second memory 205 may be connected to the second processor 204, wherein the second memory 205 is adapted to store executable program code comprising computer operation instructions, and wherein the second memory 205 may comprise a high speed RAM memory or may further comprise a non-volatile memory, e.g. at least two disk memories.

In the embodiment of the present application, the second bus 207 is used to connect the second communication interface 206, the second processor 204, and the second memory 205, and the mutual communication between these devices.

In an embodiment of the present application, the second memory 205 is used to store instructions and data.

Further, in the embodiment of the present application, the second processor 204 is configured to obtain a twelfth user information set, where the twelfth user information set includes twelfth user information of at least one first user, and the twelfth user information includes at least one of identity information, location information, health information, relationship information, device information, sensor information, and status information of the first user; outputting the twelfth set of user information.

Further, in an embodiment of the present application, the second processor 204 is configured to update an eleventh user information set according to the twelfth user information set, where the eleventh user information set includes eleventh user information of at least one first user, and the eleventh user information includes at least one of identity information, location information, health information, relationship information, device information, sensor information, and status information of the first user.

Further, in the embodiment of the present application, the second processor 204 is configured to obtain the second set of user information, where the second set of user information includes second user information of at least one first user, and the second user information includes at least one of identity information, location information, health information, and relationship information of the first user; outputting the second user information set, and/or updating an eleventh user information set according to the second user information set.

Further, in an embodiment of the present application, the second processor 204 is configured to receive seismic information; acquiring a third user information set, wherein the third user information set comprises third user information of at least one first user; outputting the third user information set, and/or updating the eleventh user information set according to the third user information set.

Further, in an embodiment of the present application, the second processor 204 is configured to receive the fourth set of user information and/or the sixth set of user information; and updating the eleventh user information set according to the fourth user information set and/or the sixth user information set.

Further, in the embodiment of the present application, the second processor 204 is configured to receive an instruction for establishing a P2P network, and establish the P2P network; exchanging the fifth set of user information with other peer nodes over the P2P network; and if the fifth preset condition is met, the fifth user information set is sent to a server, and/or the eleventh user information set is updated according to the fifth user information set.

Further, in the embodiment of the present application, the second processor 204 is configured to obtain the ninth set of user information, where the ninth set of user information includes at least one piece of the ninth user information of the third user, and the ninth user information includes at least status information of the third user; and sending the ninth user information set to a server, so that the server updates the state information of at least one third user according to the ninth user information set, and/or updates the eleventh user information set according to the ninth user information set.

Further, in an embodiment of the present application, the second processor 204 is configured to receive, before acquiring the ninth set of user information, the eighth set of user information, where the eighth set of user information includes the eighth user information of at least one third user; outputting the eighth set of user information.

Further, in the embodiment of the present application, the second processor 204 is configured to send, to the server, a user information query request before receiving the eighth user information set, where the user query request includes a user identifier and/or identity information of at least one third user.

Further, in the embodiment of the present application, the second processor 204 is configured to estimate, for each first user of the eleventh user information set, status information according to the corresponding eleventh user information, and update the eleventh user information of the first user using the status information.

Further, in an embodiment of the present application, the second processor 204 is configured to receive seismic information; acquiring prompt information, wherein the prompt information comprises communication connection information and/or user information receiving and transmitting information; and outputting the prompt information.

Further, in the embodiment of the present application, the second processor 204 is configured to send all or part of the eleventh set of user information to a server and/or a client that establishes a communication connection, and/or display the eleventh set of user information in a display interface.

Further, in an embodiment of the present application, the second processor 204 is configured to calculate user statistics according to the eleventh user information set; and outputting the user statistical information.

The steps executed by the second processor 204 in this embodiment may refer to the corresponding information statistics method on the client side in the foregoing multiple method embodiments, and have the beneficial effects of the corresponding method embodiments, which are not described herein again. In addition, the information statistics device of the present embodiment is used for correspondingly implementing the foregoing information statistics method, so the description is relatively simple, and the relevant portions may refer to the description of the corresponding portions in the foregoing method embodiments, which is not repeated herein.

It should be noted that, according to implementation requirements, each component/step described in the embodiments of the present invention may be split into more components/steps, or two or more components/steps or part of operations of the components/steps may be combined into new components/steps, so as to achieve the objects of the embodiments of the present invention.

The above-described methods according to embodiments of the present invention may be implemented in hardware, firmware, or as software or computer code storable in a recording medium such as a CD ROM, RAM, floppy disk, hard disk, or magneto-optical disk, or as computer code originally stored in a remote recording medium or a non-transitory machine-readable medium and to be stored in a local recording medium downloaded through a network, so that the methods described herein may be stored on such software processes on a recording medium using a general purpose computer, special purpose processor, or programmable or special purpose hardware such as an ASIC or FPGA. It is understood that a computer, processor, microprocessor controller, or programmable hardware includes a memory component (e.g., RAM, ROM, flash memory, etc.) that can store or receive software or computer code that, when accessed and executed by the computer, processor, or hardware, implements the search methods described herein. Further, when the general-purpose computer accesses code for implementing the search method shown herein, execution of the code converts the general-purpose computer into a special-purpose computer for executing the search method shown herein.

Those of ordinary skill in the art will appreciate that the elements and method steps of the examples described in connection with the embodiments disclosed herein can be implemented as electronic hardware, or as a combination of computer software and electronic hardware. Whether such functionality is implemented as hardware or software depends upon the particular application and design constraints imposed on the solution. Skilled artisans may implement the described functionality in varying ways for each particular application, but such implementation decisions should not be interpreted as causing a departure from the scope of the embodiments of the present invention.

The above embodiments are only for illustrating the embodiments of the present invention, but not for limiting the embodiments of the present invention, and various changes and modifications may be made by one skilled in the relevant art without departing from the spirit and scope of the embodiments of the present invention, so that all equivalent technical solutions also fall within the scope of the embodiments of the present invention.

Claims

1. An information statistical method, wherein the information statistical method is applied to a server, the method comprising:

After the earthquake occurs, determining user statistical information of the earthquake area according to the first user information set;

outputting the user statistical information;

the method further comprises the steps of:

when receiving earthquake early warning information, at least transmitting the identity information of each first user which is possibly in an earthquake area to at least one client side in the earthquake area for each first user in the first user information set, so that the client side of rescue workers in the earthquake area can receive the identity information from the client side by establishing communication connection with the client side; the earthquake early warning message comprises earthquake parameters, and the server determines an earthquake area according to the earthquake parameters; the server determines the first user who may be in the seismic area based on the user's location information.

2. The method of claim 1, wherein the collecting the first set of user information comprises:

receiving a second user information set sent by a client, wherein the second user information set comprises second user information of at least one first user, and the second user information comprises at least one of identity information, position information, health information and relationship information of the first user;

And updating the first user information set according to the second user information set.

3. The method of claim 1, wherein the collecting the first set of user information comprises:

receiving an earthquake early warning message, and determining a target area according to earthquake parameters in the earthquake early warning message, wherein the target area is positioned in the earthquake area;

sending earthquake information to a client corresponding to the target area;

4. The method according to claim 1, wherein said sending, for each first user who may be in a seismic area when receiving a seismic-warning message, at least the identity information of the first user in the first user information set to at least one client that is in the seismic area comprises:

Acquiring a plurality of first sub-areas of the target area;

for each first subarea, acquiring a fourth user information set, wherein the fourth user information set comprises all or part of fourth user information of the first users possibly positioned in the first subarea, and the fourth user information at least comprises identity information;

for each first sub-area, transmitting a corresponding fourth set of user information to at least one client located in the first sub-area, and/or transmitting a corresponding fourth set of user information to at least one client located in an adjacent first sub-area of the first sub-area.

5. The method of claim 1, wherein the collecting the first set of user information comprises:

acquiring a plurality of second sub-areas of the target area;

and sending a P2P connection establishment instruction to the client side in the second subarea for each second subarea, so that the client side in each second subarea establishes a P2P network, and exchanging a fifth user information set through the P2P network, wherein the fifth user information set at least comprises fifth user information of a first user corresponding to the client side, and the fifth user information at least comprises identity information.

6. The method of claim 5, wherein after said sending, for each second sub-region, a P2P connection establishment instruction to a client in said second sub-region, said method further comprises:

receiving a fifth user information set sent by a client;

and updating the first user information set according to the fifth user information set.

7. The method according to claim 1, wherein said sending, for each first user who may be in a seismic area when receiving a seismic-warning message, at least the identity information of the first user in the first user information set to at least one client that is in the seismic area comprises:

acquiring a plurality of third sub-areas of the target area;

for each third sub-region meeting the second preset condition, a sixth user information set is obtained, the sixth user information set is sent to at least one client meeting the third preset condition, the sixth user information set comprises sixth user information of all or part of first users possibly located in the third sub-region, and the sixth user information at least comprises identity information.

8. The method according to claim 1, wherein the method further comprises:

receiving an earthquake early warning message;

judging whether a data migration condition is met, if so, acquiring a seventh user information set, and sending the seventh user information set to at least one server meeting a fourth preset condition, wherein the seventh user information set comprises the received seventh user information of all or part of the first users in the earthquake region, and the seventh user information at least comprises identity information.

9. The method of any of claims 1-8, wherein the collecting the first set of user information comprises:

receiving a ninth user information set sent by a client of a first user, wherein the ninth user information set comprises ninth user information of at least one third user, the ninth user information at least comprises state information of the third user, the third user has an association relationship with the first user, or the first user is a user with authority to view information of the third user, and the third user may be in a seismic area when an earthquake occurs;

And updating the first user information set according to the ninth user information set.

10. The method of claim 9, wherein prior to receiving the ninth set of user information sent by the client, the method further comprises:

an eighth user information set is obtained and is sent to the client of the first user, the eighth user information set comprises eighth user information of at least one third user, and the eighth user information comprises at least one of identity information, position information, health information, relationship information, equipment information, sensor information and state information.

11. The method of claim 10, wherein the obtaining an eighth set of user information, and wherein transmitting the eighth set of user information to the client of the first user comprises:

receiving a user information inquiry request, wherein the user inquiry request comprises a user identifier and/or identity information of at least one third user;

acquiring the eighth user information set according to the user identification and/or the identity information of at least one third user, wherein the eighth user information set comprises eighth user information of at least one third user;

And sending the eighth user information set to a requester.

12. The method of claim 10, wherein the obtaining an eighth set of user information, and wherein transmitting the eighth set of user information to the client of the first user comprises:

for each third user possibly in the earthquake area, obtaining the first user with an association relation with the third user according to the relation information of the third user;

acquiring eighth user information of the third user to obtain an eighth user information set;

and sending the eighth user information set to the client of the first user.

13. The method of claim 1, wherein the collecting the first set of user information comprises:

obtaining a first user data set from a third party platform, wherein the first user data set comprises attribute data and/or behavior data of a plurality of first users;

obtaining a tenth user information set according to the first user data set, wherein the tenth user information set comprises tenth user information of a plurality of first users, and the tenth user information comprises at least one of identity information and position information;

And updating the first user information set according to the tenth user information set.

14. The method of any of claims 1-8, wherein after the collecting the first set of user information, the method further comprises:

for each first user meeting the first preset condition, estimating state information according to the corresponding first user information, and updating the first user information of the first user by using the state information.

15. The method of claim 14, wherein the estimating the status information for each first user satisfying the first predetermined condition based on the corresponding first user information comprises:

when the first user information contains sensor information, processing the sensor information to obtain state information, wherein the processing the sensor information to obtain the state information comprises at least one of the following steps:

performing voice recognition on the recording information to obtain text information, and extracting state information from the text information; inputting the image information into an image classification model to obtain an image category, and obtaining a corresponding position type according to the image category; and processing sensor information of the gyroscope, the acceleration sensor and the magnetic field sensor by using a pedestrian dead reckoning algorithm to obtain position information of a user.

16. An information statistics method, wherein the information statistics method is applied to a client, the method comprising:

updating an eleventh user information set according to the twelfth user information set, wherein the eleventh user information set comprises eleventh user information of at least one first user, and the eleventh user information comprises at least one of identity information, position information, health information, relationship information, equipment information, sensor information and state information of the first user;

outputting the twelfth set of user information;

wherein the acquiring the twelfth set of user information includes: receiving a twelfth user information set sent by a server when an earthquake occurs, wherein the twelfth user information set comprises at least one first user identity information possibly in an earthquake area;

Outputting the eleventh set of user information, comprising: transmitting the eleventh user information set to a client of a rescuer who establishes communication connection with the client;

calculating user statistical information according to the eleventh user information set;

and outputting the user statistical information.

17. The method of claim 16, wherein the obtaining the twelfth set of user information further comprises:

and acquiring a second user information set from the information acquisition page, wherein the second user information set comprises second user information of at least one first user, and the second user information comprises at least one of identity information, position information, health information and relationship information of the first user.

18. The method of claim 16, wherein the method further comprises: receiving seismic information;

the acquiring the twelfth set of user information further includes: responsive to the seismic information, obtaining a third set of user information, the third set of user information comprising third user information for at least one first user;

the outputting the twelfth set of user information further comprises: transmitting the third user information set to a server;

The updating the eleventh set of user information according to the twelfth set of user information comprises: and updating the eleventh user information set according to the third user information set.

19. The method of claim 16, wherein the receiving the twelfth set of user information transmitted by the server at the time of the earthquake, the twelfth set of user information including identity information of at least one first user that may be in the earthquake region, comprises:

and when the earthquake occurs, receiving a fourth user information set sent by the server, wherein the fourth user information set comprises all or part of fourth user information of the first user possibly positioned in the first subarea to which the client belongs, the fourth user information at least comprises identity information, and/or the fourth user information set comprises all or part of fourth user information of the first user possibly positioned in the first subarea adjacent to the first subarea to which the client belongs, and the fourth user information at least comprises the identity information.

20. The method of claim 16, wherein the obtaining the twelfth set of user information further comprises:

And when the earthquake occurs, receiving a sixth user information set sent by the server, wherein the sixth user information set comprises sixth user information of all or part of the first users possibly positioned in a third subarea, the sixth user information at least comprises identity information, the client side meets a third preset condition, and the third subarea meets a second preset condition.

21. The method of claim 16, wherein the method further comprises:

receiving a P2P network establishment instruction, and establishing a P2P network;

the acquiring the twelfth set of user information further includes: exchanging a fifth user information set with other peer nodes through the P2P network, wherein the fifth user information set at least comprises fifth user information of a first user corresponding to a client, and the fifth user information at least comprises identity information;

the method further comprises the steps of: and if the fifth preset condition is met, the fifth user information set is sent to a server, and/or the eleventh user information set is updated according to the fifth user information set.

22. The method of any of claims 16-21, wherein the obtaining a twelfth set of user information further comprises: acquiring a ninth user information set through an interactive interface, wherein the ninth user information set comprises the ninth user information of at least one third user, and the ninth user information at least comprises the state information of the third user;

The method further comprises the steps of: transmitting the ninth user information set to a server, so that the server updates the state information of at least one third user according to the ninth user information set, and/or updates the eleventh user information set according to the ninth user information set;

the third user has an association relationship with the corresponding user of the client, or the corresponding user of the client is a user with authority to view information of the third user, and the third user may be in a seismic area when a seismic occurs.

23. The method of claim 22, wherein prior to the obtaining the ninth set of user information via the interactive interface, the method further comprises:

receiving an eighth set of user information, the eighth set of user information comprising the eighth user information of at least one of the third users, the eighth user information comprising at least one of identity information, location information, health information, relationship information, device information, sensor information, status information;

and displaying the eighth user information set through an interactive interface.

24. The method of claim 23, wherein prior to the receiving the eighth set of user information, the method further comprises:

And sending a user information inquiry request to a server, wherein the user inquiry request comprises a user identifier and/or identity information of at least one third user, so that the server responds to the request, determines the eighth user information set and returns the eighth user information set to the client.

25. The method according to any one of claims 16-21, further comprising:

for each first user of the eleventh set of user information, state information is estimated from the corresponding eleventh user information, and the state information is used to update the eleventh user information of the first user.

26. The method of claim 25, wherein said estimating status information for each first user of said eleventh set of user information based on the corresponding eleventh user information comprises:

27. The method according to any one of claims 16-21, further comprising:

receiving seismic information;

acquiring prompt information, wherein the prompt information comprises communication connection information and/or user information receiving and transmitting information, the communication connection information comprises at least one of connection conditions of a server and connection conditions of other nearby clients, and the user information receiving and transmitting information comprises at least one of information sending conditions of users corresponding to the clients and conditions of other user information received by the clients;

and displaying the prompt information on a display interface, and/or converting the prompt information into voice information by using a voice synthesis method and playing the voice information.

28. The method according to any one of claims 16-21, further comprising:

all or part of the eleventh set of user information is sent to the server and/or the client establishing the communication connection, and/or,

displaying the eleventh set of user information in a display interface.

29. An information statistics apparatus, comprising:

the first output unit is used for outputting the user statistical information;

the apparatus further comprises:

the system comprises a user information output unit, a first user information collection unit and a second user information collection unit, wherein the user information output unit is used for sending the identity information of each first user which is possibly in an earthquake area to at least one client side in the earthquake area when receiving an earthquake early warning message, so that the client side of a rescue worker in the earthquake area can receive the identity information from the client side by establishing communication connection with the client side; the earthquake early warning message comprises earthquake parameters, and the server determines an earthquake area according to the earthquake parameters; the server determines the first user who may be in the seismic area based on the user's location information.

30. The apparatus of claim 29, the first collection unit collects the first set of user information by:

sending earthquake information to a client corresponding to the target area;

31. The apparatus of claim 29, wherein the user information output unit, upon receiving the earthquake early warning message, transmits, for each first user who may be in the earthquake region, at least identity information of the first user in the first user information set to at least one client in the earthquake region, so that a client of a rescuer in the earthquake region can receive the identity information from the client by establishing a communication connection with the client, comprising:

acquiring a plurality of first sub-areas of the target area;

32. The apparatus of claim 29, the first collection unit collects the first set of user information by:

acquiring a plurality of second sub-areas of the target area;

33. The apparatus of claim 29, wherein the user information output unit, upon receiving the earthquake early warning message, transmits, for each first user who may be in the earthquake region, at least identity information of the first user in the first user information set to at least one client that is in the earthquake region, so that a client of a rescuer in the earthquake region can receive the identity information from the client by establishing a communication connection with the client, comprising:

acquiring a plurality of third sub-areas of the target area;

34. The apparatus of claim 29, wherein the user information output unit, upon receiving the earthquake early warning message, transmits, for each first user who may be in the earthquake region, at least identity information of the first user in the first user information set to at least one client that is in the earthquake region, so that a client of a rescuer in the earthquake region can receive the identity information from the client by establishing a communication connection with the client, comprising:

receiving seismic information;

judging whether a data migration condition is met, if so, acquiring a seventh user information set, and sending the seventh user information set to at least one server meeting a fourth preset condition, wherein the seventh user information set comprises the received seventh user information of all or part of the first users, and the seventh user information at least comprises identity information.

35. The apparatus of claim 29, the first collection unit collects the first set of user information by:

36. The apparatus of any one of claims 29-35, further comprising:

37. An electronic device, comprising: a first processor, a first memory storing instructions executable by the first processor, which when executed by the first processor, implement the method of any one of claims 1-15.

38. An information statistics apparatus, comprising:

an information updating unit, configured to update an eleventh user information set according to the twelfth user information set, where the eleventh user information set includes eleventh user information of at least one first user, and the eleventh user information includes at least one of identity information, location information, health information, relationship information, device information, sensor information, and status information of the first user;

a second output unit configured to output the twelfth set of user information;

wherein the second obtaining unit obtaining the twelfth user information set includes: receiving a twelfth user information set sent by a server when an earthquake occurs, wherein the twelfth user information set comprises at least one first user identity information possibly in an earthquake area;

The second output unit is further configured to output the eleventh set of user information, including: means for transmitting the eleventh set of user information to a rescuer who establishes a communication connection with the means;

39. The apparatus of claim 38, wherein,

the second obtaining unit obtaining a twelfth user information set further includes obtaining a third user information set when receiving the seismic information, the third user information set including third user information of at least one first user;

the second output unit outputting a twelfth set of user information further includes transmitting the third set of user information to a server;

the information updating unit updates an eleventh user information set according to the twelfth user information set, including: and updating the eleventh user information set according to the third user information set.

40. The apparatus of claim 38, wherein the second acquisition unit receives a twelfth set of user information transmitted by a server when an earthquake occurs, the twelfth set of user information including identity information of at least one first user that may be in a seismic area, comprising:

And when the earthquake occurs, receiving a fourth user information set sent by the server, wherein the fourth user information set comprises all or part of fourth user information of the first user possibly positioned in the first subarea to which the device belongs, the fourth user information at least comprises identity information, and/or the fourth user information set comprises all or part of fourth user information of the first user possibly positioned in the first subarea adjacent to the first subarea to which the device belongs, and the fourth user information at least comprises the identity information.

41. The apparatus of claim 38, wherein the second obtaining means obtaining a twelfth set of user information further comprises:

and when the earthquake occurs, receiving a sixth user information set sent by the server, wherein the sixth user information set comprises sixth user information of all or part of the first users possibly positioned in a third subarea, the sixth user information at least comprises identity information, the device meets a third preset condition, and the third subarea meets a second preset condition.

42. The apparatus of any one of claims 38-41, further comprising:

43. The apparatus of any one of claims 38-41, further comprising:

the prompting unit is used for receiving the earthquake information; acquiring prompt information, wherein the prompt information comprises communication connection information and/or user information receiving and transmitting information, the communication connection information comprises at least one of connection conditions of a server and connection conditions of other nearby devices, and the user information receiving and transmitting information comprises at least one of information sending conditions of corresponding users of the devices and conditions of other user information received by the devices; and displaying the prompt information on a display interface, and/or converting the prompt information into voice information by using a voice synthesis method and playing the voice information.

44. The apparatus of any one of claims 38-41, further comprising:

and the third output unit is used for sending all or part of the eleventh user information set to a server and/or a device for establishing communication connection, and/or displaying the eleventh user information set in a display interface.

45. An electronic device, comprising: a second processor, a second memory storing instructions executable by the second processor, which when executed by the second processor, implement the method of any of claims 16-28.

46. A computer readable storage medium having stored thereon a program for use in a server and a client, wherein the program when executed by a first processor implements the method of any of claims 1-15; the program, when executed by a second processor, implements the method of any of claims 16-28.