CN113297341A

CN113297341A - Data processing method and system, client device and server device

Info

Publication number: CN113297341A
Application number: CN202010888031.0A
Authority: CN
Inventors: 耿桦
Original assignee: Alibaba Group Holding Ltd
Current assignee: Alibaba Group Holding Ltd
Priority date: 2020-08-28
Filing date: 2020-08-28
Publication date: 2021-08-24

Abstract

The application discloses a data processing method and system, client equipment and server equipment. The data processing method comprises the following steps: acquiring block data of a plurality of divided blocks of a field map; positioning a map position corresponding to the geographic position of the client device on the site map; the geographic position is the position of the client equipment in the actual site corresponding to the site map; determining the block identifier of the partition block where the graph position is located according to the block data of the plurality of partition blocks; and determining the report information sent to the server side equipment according to the block identifier. In the report information determined by the block identifier, the block identifier is used for describing the position to be reported, so that the problems caused by roughly describing the position by using characters in the prior art are solved.

Description

Data processing method and system, client device and server device

Technical Field

The present application belongs to the field of computer technologies, and in particular, to a data processing method and system, a client device, and a server device.

Background

In daily site management, construction processes or construction results are often subjected to inspection and inspection, and found problems are reported. In the prior art, because the specific position of building site is difficult to describe, and there is no high-recognition space (such as meeting room, station, parking stall, etc.) under most circumstances, therefore can only roughly describe the position of problem emergence with the characters, for example: building No. 1, in the southeast corner of floor 2. The location description is very fuzzy, and it is difficult to locate and find the problem occurrence point during the problem review.

Disclosure of Invention

In order to solve or improve the problems in the prior art, embodiments of the present application provide a data processing method and system, a client device, and a server device.

In one embodiment of the present application, a data processing method is provided. The method comprises the following steps:

acquiring block data of a plurality of divided blocks of a field map;

positioning a map position corresponding to the geographic position of the client device on the site map; the geographic position is the position of the client equipment in the actual site corresponding to the site map;

determining the block identifier of the partition block where the graph position is located according to the block data of the plurality of partition blocks;

and determining the report information sent to the server side equipment according to the block identifier.

In another embodiment of the present application, a data processing method is provided. The method comprises the following steps:

carrying out block division on the field map to obtain block data of a plurality of divided blocks;

and sending the block data of the plurality of partitioned blocks of the field map to the server side equipment, so that the client side equipment determines the report information sent to the server side equipment by using the block data of the plurality of partitioned blocks.

In yet another embodiment of the present application, a data processing method is provided. The method comprises the following steps:

sending block data of a plurality of divided blocks of a field map to a first client device;

receiving report information sent by the first client device;

wherein the reporting information includes: determining a block identifier of a partition block to which the geographical position of the first client equipment corresponds to the map position by using block data of the plurality of partition blocks; the geographic position is a position of the first client device in an actual field corresponding to the field map.

In yet another embodiment of the present application, a data processing system is provided. The data processing system includes:

a first client device for acquiring block data of a plurality of divided blocks of a field map; positioning a map position corresponding to the geographic position of the site map; the geographic position is the position of the first client device in the actual site corresponding to the site map; determining the block identifier of the partition block where the graph position is located according to the block data of the plurality of partition blocks; according to the block identifier, determining report information sent to the server equipment;

and the server side equipment is used for receiving the report information sent by the first client side equipment.

In yet another embodiment of the present application, a client device is provided. The client device comprises a memory and a processor; wherein the content of the first and second substances,

the memory is used for storing programs;

the processor, coupled with the memory, to execute the program stored in the memory to:

acquiring block data of a plurality of divided blocks of a field map;

the memory is used for storing programs;

In yet another embodiment of the present application, a server device is provided. The server device comprises a memory, a processor and a communication component, wherein,

the memory is used for storing programs and block data of a plurality of divided blocks of a field map;

instructing the communication component to send block data of a plurality of partitioned blocks of a field map to a first client device;

receiving report information sent by the first client device;

In the technical scheme provided by each embodiment of the application, a site map is divided into a plurality of divided blocks, and when a client device positions the map position on the site map, block data of the divided blocks are used for determining the block identifier of the divided block where the map position is located; in the reporting information determined by using the block identifiers, the block identifiers are used for describing positions to be reported, the precision of the block identifiers is related to the partition granularity of the partition blocks, and the finer the partition of the partition blocks is, the higher the precision of the positions described by using the partition blocks is; the method solves a plurality of problems caused by using characters to roughly describe the position in the prior art, and in addition, the method for describing the position by using the block identifier is more friendly to users and more convenient to view and position compared with the description of coordinates and the like.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present application, and other drawings can be obtained by those skilled in the art without creative efforts. In the drawings:

FIG. 1a is a block diagram of a data processing system according to an embodiment of the present application;

FIG. 1b is a block diagram of another data processing system according to an embodiment of the present application;

fig. 2 is a schematic flowchart of a data processing method according to an embodiment of the present application;

FIG. 3 is a schematic diagram illustrating an interface operation process according to an embodiment of the present disclosure;

FIG. 4a is a schematic diagram of an application interface according to an embodiment of the present application;

FIG. 4b is a schematic view of a shaft network according to an embodiment of the present application;

fig. 5 is a schematic flowchart of a data processing method according to another embodiment of the present application;

FIG. 6 is a schematic diagram of a display interface according to an embodiment of the present application;

fig. 7 is a schematic flowchart of a data processing method according to another embodiment of the present application;

fig. 8 is a schematic structural diagram of a data processing apparatus according to an embodiment of the present application;

fig. 9 is a schematic structural diagram of a data processing apparatus according to another embodiment of the present application;

FIG. 10 is a schematic structural diagram of a data processing apparatus according to yet another embodiment of the present application;

fig. 11 is a schematic structural diagram of a client device according to an embodiment of the present application.

Detailed Description

In the existing space positioning method, the positioning result is generally longitude and latitude coordinates or default card support coordinates. These coordinates are computer friendly and not human friendly. For some sites, such as construction sites, there is a lack of effective and easily understood location positioning. For example, when a worker is patrolling at a construction site, the patrolling personnel can see that a problem exists, and the problem position and the problem description need to be reported. At this time, the inspection personnel can only describe the problem position by characters, such as an electric box on the floor-1-east side of the No. 1 building. The problem location description here is rather ambiguous and less accurate. For the maintainer, the-1 floor-east side of the building No. 1 needs to be accurately distinguished; then the problem electrical box is searched in a larger range on the east side. Or, the patrol personnel need to manually find the corresponding graph position on the construction site plane drawing according to the situation of the site position, and the efficiency is low.

To this end, the present application provides the following embodiments. In order to make the objects, technical solutions and advantages of the embodiments of the present application clearer, 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, and it is obvious that the described embodiments are some embodiments of the present application, but not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

In some of the flows described in the specification, claims, and above-described figures of the present application, a number of operations are included that occur in a particular order, which operations may be performed out of order or in parallel as they occur herein. The sequence numbers of the operations, e.g., 101, 102, etc., are used merely to distinguish between the various operations, and do not represent any order of execution per se. Additionally, the flows may include more or fewer operations, and the operations may be performed sequentially or in parallel. It should be noted that, the descriptions of "first", "second", etc. in this document are used for distinguishing different messages, devices, modules, etc., and do not represent a sequential order, nor limit the types of "first" and "second" to be different. In the present application, the term "or/and" is only one kind of association relationship describing the associated object, and means that three relationships may exist, for example: a or/and B, which means that A can exist independently, A and B can exist simultaneously, and B can exist independently; the "/" character in this application generally indicates that the objects associated with each other are in an "or" relationship.

First, a hardware system on which the technical solution provided by the present application depends will be described. As shown in fig. 1a and 1b, the data processing system provided in the present embodiment includes: a first client device 101 and a server device 102. Wherein the content of the first and second substances,

a first client device 101 for acquiring block data of a plurality of divided blocks of a field map; positioning a map position corresponding to the geographic position of the site map; the geographic position is the position of the first client device in the actual site corresponding to the site map; determining the block identifier of the partition block where the graph position is located according to the block data of the plurality of partition blocks; according to the block identifier, determining report information sent to the server equipment;

the server device 102 is configured to receive the report information sent by the first client device 101.

In a specific implementation, the first client device may be a mobile phone, a tablet computer, a notebook computer, a PDA (Personal Digital Assistant), an intelligent wearable device (e.g., an intelligent watch, an intelligent glasses), and the like, which is not limited in this embodiment. The server device may include, but is not limited to: a server, a server cluster, a virtual server, or a cloud device. The cloud device may be a cloud server in a cloud computing system, or may be a virtual machine on the cloud server. Among them, Cloud Computing (Cloud Computing) is a kind of distributed Computing, which means that a huge data Computing processing program is decomposed into numerous small programs through a network "Cloud", and then the small programs are processed and analyzed by a system composed of a group of loosely coupled computer sets to obtain results and returned to users.

Further, the system provided by the present embodiment may further include a second client device 103, as shown in fig. 1a and 1 b. The second client device 103 is configured to obtain, from the server device 102, reporting information related to the venue diagram; and displaying a visual icon 2 corresponding to the report information at a partition block corresponding to the block identifier of the displayed field map 1 according to the block identifier contained in the report information.

Further, the second client device 102 is further configured to perform block division on the site map to obtain block data of a plurality of divided blocks; sending block data of a plurality of partitioned blocks of the field map to the server device 102; the server device 102 is further configured to store block data of a plurality of partitioned blocks of the field map.

It should be added here that the work of dividing the site map and then transmitting the block data of the divided blocks to the server apparatus can also be performed by the first client apparatus 101. That is, the first client apparatus 101 and the second client apparatus 103 in this embodiment may be the same apparatus or may be two different apparatuses. Certainly, in an actual application scenario, workers of different types of work need to be equipped with corresponding client devices, and therefore, in most cases, the first client device and the second client device are different devices. For example, the work of the inspection personnel is mainly the site inspection, and the problems are reported when the problems are found out, so that the first client equipment used by the inspection personnel does not need to have other functions, such as a site map dividing function. After the site map designer uses the second client device to complete the design of the site map, the site map can be divided, and block data of a plurality of divided blocks is triggered to be sent to the server.

In addition, the second client device in this embodiment may be the same type of device as the first client device, or may be a different type of device. For example, the first client device is a mobile phone or a tablet computer, which is convenient to carry. The second client device may be a desktop computer, which is more powerful for computing. For another example, the first client device and the second client device may be a tablet computer or a notebook computer, and the like, which is not limited in this embodiment.

In addition, as can be seen from fig. 1a and fig. 1b, in the technical solution provided in this embodiment, two ways may be adopted to locate the map position corresponding to the geographic position of the first client device 101. As shown in fig. 1a, positioning beacons, such as bluetooth beacon, RFID (radio frequency identification) tag, UWB (Ultra Wide Band) base station, etc., arranged in the actual field may be used to locate the map position. As shown in fig. 1b, positioning information of the first client device is obtained first by using satellite positioning (such as GPS or beidou), and then the positioning information is converted into a map position. More specific details can be found in the corresponding description of the method embodiments below. This is illustrated by: positioning by adopting a positioning beacon is suitable for indoor positioning; satellite positioning (e.g., GPS or beidou) is suitable for outdoor positioning.

The system provided in this embodiment is described below with reference to a specific application scenario. Assume that a worksite inspection person takes a first client device 101 (e.g., a cell phone) to a worksite (i.e., the site mentioned above) for inspection. When the electric box in a certain position is found to have a problem after walking to a construction site, the inspection problem and the problem position are reported. For example, in the example shown in fig. 3, the patrol inspector triggers an Application (APP) on the first client device 101 to enter the application interface 3, and the first client device 101 acquires block data of a plurality of divided blocks of the drawing (i.e., the above-mentioned field map) corresponding to the worksite in response to a triggering operation of the user; then, according to the GPS positioning information of the first client device 101, determining a graph position corresponding to the current geographic position of the first client device 101 on a drawing; from the graph position and the block data of the plurality of partitioned blocks, the partitioned block in which the first client device 101 is located may be determined. The inspector can see the division block identifier, for example, "building-1 floor-C area of location information No. 1" shown in fig. 3, in the opened application interface 3. Of course, the first client device 101 may also display a field map in the application interface 3, where the map identifier (e.g. the circular dot in fig. 3) corresponding to the first client device 101 is displayed at the corresponding partition identification position of the field map. The polling personnel can trigger the reporting operation by clicking the circular point or other modes (such as clicking a corresponding control, a voice mode and the like). As shown in fig. 3, the first client device 101 jumps to the reporting interface 4, the problem location information, the site name, and the like are displayed in the reporting interface 4, and the inspection personnel can input the problem description in the problem input box of the reporting interface 4 and then click the "submit" control, so as to complete the reporting of the problem content and the problem location. That is, after monitoring the operation of the "submit" control, the first client device 101 sends corresponding report information to the server device 102 according to the problem description input by the inspector and the determined block identifier of the partition block in which the first client device 101 is located.

After receiving the report information, the server device 102 stores the report information in association with the site map. Thus, the administrator can check or query the report information associated with the site map through the second client 103. Or after receiving the report information, the server device 102 sends the report information to the second client device 103 used by the maintainer or the site worker, so that the maintainer or the site worker can obtain the report information in time and process the problem description in time.

In summary, the technical scheme provided by the embodiment of the application can locate the corresponding map position of the client device on the map of the site in the actual site, and then describe the position by adopting the way of dividing the block identifier, thereby solving a plurality of problems caused by roughly describing the position by characters in the prior art, being more friendly to users, and being more convenient to check and locate compared with the description of coordinates and the like.

The technical scheme provided by the embodiment of the application is not only suitable for positioning the sites such as construction sites, but also suitable for any other scenes which are not easy to accurately describe problems. Certainly, for scenes where positions are easy to describe, such as shopping mall and hotel position description scenes, a user can describe the positions by using a house number, a functional area and the like, and the scenes can also use the technical scheme provided by the embodiment of the application, and the application is not limited to fixed scenes. The embodiment of the application provides a new position positioning scheme, and the position is described by adopting block identification of a partition block.

The method embodiments provided by the present application will be explained below from the perspective of the devices of the system.

Fig. 2 is a schematic flowchart illustrating a data processing method according to an embodiment of the present application. The execution subject of the method provided by this embodiment may be the first client device in the data processing system. As shown in fig. 2, the method includes:

101. acquiring block data of a plurality of divided blocks of a field map;

102. positioning a map position corresponding to the geographic position of the client device on the site map; the geographic position is the position of the client equipment in the actual site corresponding to the site map;

103. and determining the report information sent to the server side equipment according to the block data of the plurality of partitioned blocks.

In the above 101, the site map may be a two-dimensional map or a three-dimensional map drawn by a designer using drawing software, and the like, which is not specifically limited in this embodiment. The division of the field map can be realized by the execution main body of the method, and also can be realized by other equipment and stored in the server-side equipment, so that the execution main body of the method can request to acquire the block data of a plurality of divided blocks of the field map from the server-side equipment. In specific implementation, the plurality of division blocks may be the same or different in size and shape. The block data may include, but is not limited to: block shape, block location information, block size, block boundary feature point coordinates (e.g., vertex coordinates), etc.

That is, in this step 101 ", acquiring block data of a plurality of divided blocks of the field map includes:

carrying out block division on the field map to obtain block data of a plurality of divided blocks; or

And acquiring block data of a plurality of divided blocks of the field map from a server device.

As can be seen from fig. 1a and fig. 1b, in the technical solution provided in this embodiment, two ways may be adopted to locate the map location corresponding to the geographic location of the client device. As shown in fig. 1a, positioning beacons (such as bluetooth beacons, RFID tags, UWB base stations, etc.) arranged in the actual field can be used to locate the map position; as shown in fig. 1b, positioning information of the client device is first obtained by satellite positioning (such as GPS or beidou), and then the positioning information is converted into a map position.

In 103, "determining reporting information to be sent to the server device according to the block data of the plurality of partitioned blocks" may include:

1031. determining the block identifier of the partition block where the graph position is located according to the block data of the plurality of partition blocks;

1032. and determining the report information sent to the server side equipment according to the block identifier.

In a specific embodiment, the "dividing the site map to obtain block data of a plurality of divided blocks" in 1031 includes:

dividing the field map into a plurality of divided blocks to obtain boundary information of the divided blocks;

and obtaining block data of the division blocks according to the boundary information of the division blocks and the floor marks corresponding to the field map.

In a specific implementation, the plan blocks may be triangles, quadrangles, pentagons, hexagons, and the like, which is not specifically limited in this embodiment. If the partition block is a quadrangle, a pentagon or a hexagon, the boundary information of the partition block may be coordinates of each vertex of the partition block.

In the technical scheme provided by this embodiment, a site map is divided into a plurality of divided blocks, and when a client device locates a map position on the site map, block data of the plurality of divided blocks is used to determine a block identifier of the divided block where the map position is located; in the reporting information determined by using the block identifiers, the block identifiers are used for describing positions to be reported, the precision of the block identifiers is related to the partition granularity of the partition blocks, and the finer the partition of the partition blocks is, the higher the precision of the positions described by using the partition blocks is; the method solves a plurality of problems caused by using characters to roughly describe the position in the prior art, and in addition, the method for describing the position by using the block identifier is more friendly to users and more convenient to view and position compared with the description of coordinates and the like.

Further, in this embodiment, the positioning of the graph position corresponding to the geographic position of the client device in step 102 may be implemented by using the following two schemes.

First, positioning information determination using client device

Specifically, the step 102 "of locating, on the presence map, a map location corresponding to the geographic location of the client device includes:

1021. acquiring positioning information corresponding to the geographical position of the client equipment;

1022. and determining a map position corresponding to the positioning information according to the reference point information on the field map.

The positioning information in 1021 includes a first default card holder coordinate; the reference point information includes: the image coordinates of the reference point and the default card holder coordinates of the reference point are called as second default card holder coordinates. Correspondingly, the step 1021 "determining the map position corresponding to the positioning information according to the reference point information on the field map", specifically includes:

10211. acquiring the map scale of the field map;

10212. and determining the map position according to the map scale, the first default card holder coordinate, the second default card holder coordinate and the map coordinate of the reference point.

The default card support coordinate can be determined by GPS or Beidou positioning information. That is, the method provided by this embodiment further includes: and converting the longitude and latitude coordinates into the first default card holder coordinates.

The Mercator coordinates are coordinates obtained by Mercator Projection (Mercator Projection). The default carto projection, also called positive axis equiangular cylinder projection, is an equiangular cylindrical map projection method. On the map drawn by the projection method, the longitude and the latitude are vertically intersected at any position, so that the world map can be drawn on a rectangle. In the projection, the linear scale is kept constant around any point in the figure, so that the angle and the shape of the continental contour after projection can be kept constant.

More specifically, a reference point is set in the site map; the graph coordinates of the reference point are (X1, Y1), and the second Mokato coordinates of the reference point are (MX1, MY 1). The graph coordinates of the reference points are (X1, Y1) and the second victor coordinates of the reference points (MX1, MY1) are both known quantities. The longitude and latitude coordinates of the client-side equipment returned by the GPS or Beidou satellite are (Lat2, Lgt 2); the longitude and latitude coordinates (Lat2, Lgt2) are converted into first default Carto coordinates (MX2, MY 2). The method for converting the longitude and latitude coordinates into the default carter coordinates can refer to corresponding contents in the prior art, and is not described herein in detail. Then, map coordinates (X2, Y2) on the presence map of the client device are obtained using the following formula:

X2＝X1+c*(MX2-MX1)，

Y2＝Y1+c*(MY2-MY1)，

where c is the scale of the map of the field, such as the scale of a CAD drawing, which is typically 1/100.

Scheme two, positioning beacon determination set in field

1021', receiving communication information sent by the positioning beacon in the field;

1022', determining the signal strength of the communication signal and the beacon identifier of the positioning beacon according to the communication information;

1023' according to the beacon mark, obtaining the map coordinate of the positioning beacon on the field map;

1024', calculate the map location based on the signal strength and map coordinates of the positioning beacon.

The positioning beacon includes but is not limited to: such as bluetooth beacon, RFID tag, UWB base station, etc. A plurality of actual sites can be distributed; the map coordinates of the distributed positions in the field and the positioning beacons are designed and correspond to each other one by one. The map coordinates of the positioning beacon may be stored in the own device to be carried within it when the communication information is transmitted. Or the map coordinates of the positioning beacon are stored in the server-side equipment, and the execution subject of the method can acquire the map coordinates from the server-side equipment according to the identification of the positioning beacon. The identity of the positioning beacon may be, but is not limited to: UUID (universal Unique Identifier).

In specific implementation, the method execution main body can receive communication information sent by a plurality of positioning beacons at different positions. At this time, the map coordinates corresponding to the geographic position of the first client device on the presence map may be calculated by using a multipoint positioning algorithm in combination with the map coordinates of the plurality of positioning beacons and the signal strength of the communication signal transmitted by each positioning beacon. The contents of the multi-point positioning algorithm can be referred to the related descriptions in the prior art, and are not described herein again.

The first scheme is suitable for a building site which is a one-storey or outdoor site (such as a site for making a foundation) and has no floor division. The second scheme is suitable for a building site with multiple floors, and the floor where the first client device is located cannot be obtained according to the GPS positioning information or the Beidou positioning information. In the second scheme, the floors of the positioning beacons are fixed, so that the floor where the first client device is located can be obtained according to the floor where the positioning beacon is located. During specific implementation, the positioning beacon also carries the floor where the positioning beacon is located in the communication information to send out.

Further, the method provided by this embodiment may further include the following steps:

104. responding to a report request triggered by a user, and displaying a report interface;

105. and acquiring the reported content input by the user through the reporting interface.

Correspondingly, the step 103 of determining the reporting information sent to the server device according to the block data of the plurality of partitioned blocks may specifically be:

and sending reporting information to the server equipment based on the reporting content and the block identifier.

For example, the method provided by this embodiment is suitable for inspecting a scene by using a building site, and the reporting content may include: and finding problem description when the inspection personnel inspects the problems. In the example shown in fig. 3, the patrol personnel triggers an Application (APP) on the client device to enter the application interface 3, and the client device responds to the triggering operation of the user to acquire block data of a plurality of partitioned blocks of the drawing (i.e. the above-mentioned field map) corresponding to the construction site; then determining a graph position corresponding to the current geographic position of the client equipment on a drawing according to the GPS positioning information of the client equipment; and determining the partition block where the client equipment is located according to the graph position and the block data of the plurality of partition blocks. The inspector can see the division block identifier, for example, "building-1 floor-C area of location information No. 1" shown in fig. 3, in the opened application interface 3. Of course, the client device 101 may also display a field map in the application interface 3, where the map identifier (e.g. the circular dot in fig. 3) corresponding to the first client device 101 is displayed at the corresponding partition identification position of the field map. The polling personnel can trigger the reporting operation by clicking the circular point or other modes (such as clicking a corresponding control, a voice mode and the like). As shown in fig. 3, the client device jumps to the reporting interface 4, the problem location information, the site name, and the like are displayed in the reporting interface 4, and the inspection personnel can input the problem description in the problem input box of the reporting interface 4 and then click the "submit" control, so that the reporting of the problem content and the problem location can be completed.

Further, in order to facilitate the user to see and know which position of the venue he is currently located at in real time, the map position obtained in step 102 may be displayed at the corresponding position of the venue map, that is, the method provided in this embodiment may further include the following steps:

106. and displaying the field map and the block identifier, wherein the map position of the field map shows the map identifier corresponding to the client equipment.

Referring to the application interface 3 in fig. 3 and 4a, a site map 5 is displayed in the application interface, and a map identifier 6 corresponding to the client device, such as a circular dot, is shown at the map position of the site map 5.

Assuming that the user wants to report information at a certain position, in order to facilitate user operation, in the scheme provided in this embodiment, the user may trigger the report request in a manner of directly operating the graph identifier corresponding to the client device. Namely, the method provided by the embodiment may further include:

107. and triggering the report request in response to the operation of the user on the graph identifier corresponding to the client equipment.

As shown in fig. 3, after clicking the graph identifier 6 on the application interface 3, the user triggers a report request. The application interface of the client device jumps to the reporting interface 4, and the user can input the content to be reported (such as the problem content) through the reporting interface, and then click the "submit" control, and the report information can be sent to the server device.

Certainly, in specific implementation, the user may also use other manners to trigger the report request, such as voice triggering, action triggering (for example, shaking one), and touching a corresponding control, which is not specifically limited in this embodiment.

After acquiring block data of a plurality of divided blocks of the presence map, an executing body of the method provided by the embodiment can plan one or more routes based on the block data. If this embodiment is applied to the construction site scene, then the building site personnel of patrolling and examining alright carry out the building site according to one or more routes of planning out and patrol and examine. That is, the method provided by this embodiment may further include the following steps:

108. planning at least one route according to the block data of the plurality of divided blocks;

109. on the field map, the at least one route is shown.

In specific implementation, a route sequentially connecting all the partitioned blocks can be planned based on the block data of each partitioned block, and a plurality of routes can also be planned. For example, the dividing blocks containing the electronic boxes are connected to plan a route; connecting the dividing blocks containing the gas valves to plan a route; … …, etc.; the staff of different work types of being convenient for like this only need patrol and examine according to the route that its facility that is responsible for overhauing corresponds. The route planning can refer to the content in the prior art, and the embodiment does not limit this.

In another implementation, a route may also be planned for the user based on the user identification; that is, the present embodiment may also plan a route based on the user identifier (such as work category or assigned responsibility) of the current user (the user who logs in the client application through the execution subject in the present solution). Specifically, the method provided in this embodiment further includes:

110. determining at least one target partition block in the plurality of partition blocks according to the user identification;

111. based on the at least one target partition, planning a route for the user identification corresponding to the user;

112. on the field map, the route is shown.

For example, an inspector is responsible for inspecting electrical equipment laid within a worksite. The patrol inspection personnel can input corresponding patrol inspection duties through the client application, or the patrol inspection duties are filled in when the patrol inspection personnel register. Therefore, when the patrol personnel use the client application, the client application acquires the block data of a plurality of divided blocks of the field map, wherein the block data of each divided block not only contains the boundary information of the divided block, but also can contain the facility identifier needing to be patrolled in the area corresponding to the divided block. The client application can acquire at least one target division block from the plurality of division blocks according to the routing inspection duty; the blocks are then partitioned based on the at least one target, and a corresponding route is planned and displayed on the site map. Therefore, the patrol personnel can consult the route displayed on the map of the reference place to carry out patrol so as to avoid missing.

In an actual scene, for example, in a construction site, some places need to be mainly patrolled, and some places can be patrolled or not. Therefore, in order to highlight the routing inspection, the embodiment further includes the following steps:

113. acquiring the grade of each route;

114. and on the field map, lines of different grades are displayed in a distinguishing manner.

In the above 113, the level of each route may be set manually, for example, a manager sets at a management end (e.g., a management device connected to a server), and sends the set level of the route to the server, so that the executing entity of this embodiment can obtain the level from the server. Or the grade of each route is determined by the server-side equipment according to the current construction stage. For example, the current construction stage is a wire laying stage, and if the current construction stage is missed, the subsequent error correction cannot be carried out or the error correction cost is high; at this time, the grade of the line in which the divided blocks into which the electric wire is laid are chained may be determined as a high grade. Displaying the site map in a highlight mode; and the other lines can be displayed in a normal or gray scale display mode. Or, on the site map, the high-grade route is displayed in a manner of breathing lamp effect, the middle-grade route is displayed in normal brightness, and the low-grade route is displayed in a manner of gray scale display; and the display mode of each grade is not particularly limited in this embodiment, as long as it is ensured that there is a difference in the line display of each grade.

Fig. 5 is a schematic flow chart illustrating a data processing method according to another embodiment of the present application. The execution subject of the method provided by this embodiment may be the first client device in the data processing system, or may be the second client device. Specifically, the method comprises the following steps:

201. carrying out block division on the field map to obtain block data of a plurality of divided blocks;

202. and sending the block data of the plurality of partitioned blocks of the field map to the server side equipment, so that the client side equipment determines the report information sent to the server side equipment by using the block data of the plurality of partitioned blocks.

In the above 201, the site map may be a two-dimensional map or a three-dimensional map drawn by the user using drawing software, and the like, which is not specifically limited in this embodiment. The division of the field map can be realized by the execution main body of the method, and also can be realized by other equipment and stored in the server-side equipment, so that the execution main body of the method can request to acquire the block data of a plurality of divided blocks of the field map from the server-side equipment. In specific implementation, the plurality of division blocks may be the same or different in size and shape. The block data may include, but is not limited to: block shape, block location information, block size, block boundary feature point coordinates (e.g., vertex coordinates), etc.

In the technical scheme provided by this embodiment, the site map is divided into a plurality of divided blocks, which is convenient for self or other client devices to obtain and use block data positioning positions of the plurality of divided blocks. Specifically, a map position of a geographic position of the client device on a presence map is located; then, determining the block identifier of the partition block where the map position is located by using the block data of the plurality of partition blocks; thus, the reporting information determined by the block identifier can be utilized. The block identifier in the report information is used for describing the position to be reported, the precision of the block identifier is related to the partition granularity of the partition blocks, and the finer the partition of the partition blocks is, the higher the precision of the position described by the partition blocks is; the method solves a plurality of problems caused by using characters to roughly describe the position in the prior art, and in addition, the method for describing the position by using the block identifier is more friendly to users and more convenient to view and position compared with the description of coordinates and the like.

The step 201 of "dividing the site map to obtain block data of a plurality of divided blocks" includes:

2011. dividing the field map into a plurality of divided blocks to obtain boundary information of the divided blocks;

2012. and obtaining block data of the division blocks according to the boundary information of the division blocks and the floor marks corresponding to the field map.

In a specific embodiment, the field map is a two-dimensional map, and the divided blocks are rectangular blocks. Correspondingly, the step of dividing the field map into a plurality of divided blocks to obtain boundary information of the plurality of divided blocks includes:

20111. dividing the field map into a plurality of rectangular blocks by adopting a plurality of transverse axes and a plurality of longitudinal axes;

20112. calculating the image coordinates of four vertexes of each rectangular block according to the shaft distances of the transverse shafts and the shaft distances of the longitudinal shafts;

20113. and obtaining the block data of the rectangular block according to the map coordinates of the four vertexes of the rectangular block and the floor marks corresponding to the field map.

Wherein the plurality of transverse axes may be parallel and the plurality of longitudinal axes may be parallel. The plurality of horizontal axes may be equally spaced or unequally spaced, and are determined according to the actual situation of the field map. Likewise, the longitudinal axes may be equally or unequally spaced. In addition, for a field map with a relatively simple building structure, as shown in fig. 4a, the horizontal axis and the vertical axis may be perpendicular to each other, forming a rectangular grid axis network. However, for more complex building structures, as shown in fig. 4b, the hub network of the field map may be composed of axes in multiple directions, such as z1, z2, z3, z4, z5, z6, and z 7. The purpose of the axle network is to divide the field map into a plurality of division blocks, and the division blocks may be triangular blocks, rectangular blocks, polygonal blocks, and the like, which is not specifically limited in this embodiment. Specifically, a mesh consisting of a plurality of transverse axes and a plurality of longitudinal axes may be referred to as an axial mesh. In the field of construction drawings, axle networks: the network of building axes is a nominal one according to the usual customary standard, in order to indicate the detailed dimensions of the components in the building drawings (AutoCAD files), and is customarily marked on the center line of the symmetrical interface or section components. The shaft net consists of an axis (the center line of a wall or a column in a building structure), a mark size (marking the distance between the axes of the building) and a shaft number. Therefore, in specific implementation, the execution main body in this embodiment can automatically analyze the axis network information on the construction drawing, and after the axis network information is analyzed, the block data divided by the axis network can be automatically acquired.

In addition, AutoCAD: AutoCAD (AutoCAD Computer aid design) is the automatic Computer Aided design software developed by Autodesk (Ottek) corporation for the first time in 1982 for two-dimensional drawing, detailed drawing, design documentation, and basic three-dimensional design. The AutoCAD file is generated by AutoCAD software based on user design data.

203. acquiring reported information which is stored by server equipment and related to the site map;

204. and displaying a visual icon corresponding to the report information at a partition block corresponding to the block identifier of the displayed field map according to the block identifier contained in the report information.

Referring to the example shown in fig. 6, a visual icon "r" is shown on the displayed field map 1;

205. and responding to the operation of the user on the visual icon, and displaying the reported information.

The user can view the reported information by clicking the visual icon 'r'. Assuming that the user clicks the visual icon "r", on the interface shown in fig. 6, the information reported includes: a field map name, location information, submitter, submission date, question description, etc. Of course, the interface shown in fig. 6 may also show the status of the problem related to the reported information, such as unprocessed or processed. If the problem state of the reported information is processed, the information of the processor can be displayed.

After a plurality of dividing blocks of the site map are divided, a route can be planned. The route can be automatically planned by the scheme in the above and can be specified by the user. For example, the administrator sets a route of the site map on a management side (e.g., a management computer), and then sends the set route and the site map to the server side device in association, so as to be conveniently acquired and displayed by other client side devices (e.g., devices used by inspection personnel or maintenance personnel). That is, the method provided by this embodiment may further include the following steps:

206. acquiring at least one route set by a user in response to a route setting operation of the user for the plurality of divided blocks;

207. and sending the at least one route to a server device in association with the site map so as to be convenient for the client device to acquire and display the at least one route.

Assuming a scenario, after the field inspection of the inspector, the inspector reports the problem to be repaired (i.e., the reported information mentioned in this embodiment) to the server device. For the maintainer, an actual site (such as a construction site) corresponding to the site map is unfamiliar with, after at least one piece of report information sent by server-side equipment is downloaded or received from the server-side equipment through client-side equipment used by the maintainer, a planned route which starts from the current position and can reach an area corresponding to a block identifier contained in the report information can be planned for the maintainer based on the current geographical position of the maintainer, so that the maintainer can be helped to quickly arrive at and find a facility to be overhauled; the planned route can be the shortest route of the route, so that the maintainers can bypass the route less, and the overhauling efficiency is improved. For this reason, the method provided by this embodiment may further include the following steps:

208. acquiring at least one piece of reported information related to the site map; wherein, the reported information contains block identification;

209. generating a first planning route according to the block identifier contained in the at least one piece of reporting information;

210. displaying the first planned route on the field map.

Of course, in the step 209 described above in practical application, when planning the first planned route, the current location of the user may also be referred to. For example, the map position of the current position of the user of the execution subject on the map of the field is located, and then the first planned route is generated based on the map position where the user is located and the block identifier included in the at least one piece of reported information.

Similarly, the related contents in the prior art can be referred to as a planning method of route planning here, and this embodiment is not particularly limited thereto.

Further, in specific implementation, the embodiment may also prioritize the reporting information, so that the reporting information that needs to be processed preferentially can be highlighted. That is, the method provided by this embodiment may further include the following steps:

211. acquiring reported information related to the site map; wherein, the reported information contains block identification;

212. carrying out priority division on the reported information to obtain the priority corresponding to the reported information;

213. and displaying the visual icon corresponding to the reported information at the division block corresponding to the block identifier of the field map by adopting a display mode corresponding to the priority.

An achievable technical solution is that, when reporting information, the user sets the urgency of the reported information. Therefore, the priority of the reported information can be determined by the above 212 based on the urgency level set by the user and carried in the reported information. For example, the higher the urgency, the higher the priority.

Another achievable technical solution is that, based on the content reported in the report information, the report information is prioritized. For example, the client application of the execution subject in this embodiment is preset with a prioritization mechanism based on content type, such as but not limited to: a list of content type to priority relationships. In this embodiment, after the execution main body identifies the content type to which the content in the report information belongs, the priority corresponding to the report information may be determined by querying the relationship list between the content type and the priority.

Certainly, the priority of the reported information may also be determined by other methods, which are not listed here, and the determination means of the priority is not particularly limited.

The solutions 211 to 213 are provided to highlight the visual icon corresponding to the report information with high priority. Continuing on the assumption in the above, the maintainer is unfamiliar with the actual place that the place map corresponds, for the maintenance efficiency who accelerates the maintainer, reduces the detour. The method provided by the embodiment may further include the following steps:

214. acquiring at least one piece of reported information related to the site map; wherein, the reported information contains block identification;

215. performing priority classification on the at least one piece of reported information to obtain the priority corresponding to the reported information;

216. determining the reported information belonging to the set priority;

217. generating a second planning route according to the block identifiers contained in the report information belonging to the set priority;

218. displaying the second planned route on the field map.

The priority of the reported information is assumed to be divided into three types: high, medium, low. The priority setting in 216 may be a high priority.

Here, it should be noted that: the content of each step in the method provided by the embodiment of the present application, which is not described in detail in the foregoing embodiments, may be referred to corresponding content in the foregoing embodiments, and is not described in detail herein. In addition, the method provided in the embodiment of the present application may further include, in addition to the above steps, other parts or all of the steps in the above embodiments, and specific reference may be made to corresponding contents in the above embodiments, which is not described herein again.

Fig. 7 is a flowchart illustrating a data processing method according to another embodiment of the present application. The execution main body of the method provided by this embodiment may be the server device of the data processing system. Specifically, as shown in fig. 7, the method includes:

301. sending block data of a plurality of divided blocks of a field map to a first client device;

302. receiving report information sent by the first client device;

In 301 and 302, the obtaining of the block data of the plurality of divided blocks and the determining of the report information may refer to corresponding contents in the above embodiments, which is not described in detail in this embodiment.

303. and sending reporting information corresponding to the site map to a second client device, so that the second client device displays a visual icon corresponding to the reporting information at a partition block corresponding to the block identifier of the site map.

In specific implementation, the report information may be sent to the second client device after the second client device sends the acquisition request. Or after receiving the report information, the report information can be sent to the second client, so that corresponding staff can see and process the report information in time.

As can be seen from the above, the route for the user to refer to can be set manually (e.g. by an administrator). Therefore, the administrator sets a route through the client device (which may be the first client device, the second client device, or other client devices except the first and second client devices in this embodiment), and then sends the route to the server device, so as to store the route and the site map in association on the server device side, so that the user can download the corresponding route from the server device through the client device used by the user, and display the route on the site map. For this reason, the method provided by this embodiment may further include the following steps:

304. and receiving and storing at least one route which is sent by the first client device and is related to the site map so as to be acquired and displayed by the second client device.

In the above embodiments, the route planning is implemented by the client device. In essence, the route planning can also be implemented by the execution subject of the embodiment, i.e. the server device, and the client device can download. That is, the method provided by this embodiment may further include the following steps:

305. acquiring at least one piece of reported information related to the site map; wherein, the reported information contains block identification;

306. generating a first planning route according to the block identifier contained in the at least one piece of reporting information;

307. sending the first planned route to a second client device for the second client device to display the first planned route on the field map.

Similarly, the prioritization of the reported information in the scheme provided by the embodiment is implemented by the client device. In fact, the implementation subject, i.e. the server device, of the present embodiment may also be implemented. Specifically, the method provided in this embodiment may further include the following steps:

308. acquiring reported information related to the site map;

309. carrying out priority division on the reported information to obtain the priority corresponding to the reported information;

310. and sending the priority corresponding to the reported information to a second client device.

The technical scheme provided by each embodiment of the application is suitable for various scenes and is suitable for scenes in which problems cannot be accurately described in a field. For example, in a mall, office space, a property or inspection person may describe a problem based on landmark information in the mall, office space, such as house number, shop number, office number, conference number, and the like. For the positioning of the building site, when the patrol personnel find problems, no referenceable symbolic information exists in the building site, and the technical scheme provided by the embodiment of the application needs to be used under the condition. Taking a building site as an example, a site map of the building site is hereinafter referred to as a building map.

Firstly, carrying out grid division on a building map of a building site

Step 1.1, according to an axis (comprising a horizontal axis and a vertical axis) on the architectural drawing; dividing the architectural drawing into a plurality of divided blocks; in addition, the positions of floors are added, and a block identifier is combined: x (horizontal axis number)/y (vertical axis number)/z (floor number).

And 1.2, calculating the graph coordinates of 4 vertexes of each divided block. And taking the graph coordinates and the block identifications of the 4 vertexes of the divided block as block data of the divided block.

Second, positioning the graph position of the client device by using a multipoint positioning algorithm

And 2.1, downloading block data of a plurality of partitioned blocks of the architectural drawing from server-side equipment (such as a cloud).

Step 2.2, a multipoint positioning algorithm:

locally deployed positioning beacons, such as bluetooth beacons, RFID tags, UWM base stations, and the like, wirelessly communicate with client devices. The method comprises the steps that data such as a positioning beacon UUID and signal strength are obtained by client equipment, and graph coordinates (X, Y) (namely graph positions) of the client equipment on a building graph are calculated by the client equipment according to a multipoint positioning algorithm and by combining the graph coordinates and the signal strength of the positioning beacon; then, the division block in which the map coordinate (X, Y) is located is determined based on the relative positions of the map coordinate (X, Y) and the 4 vertex coordinates of the division blocks. The floor number z can be obtained from the floor on which the positioning beacon is located.

The method is suitable for indoor scenes, a GPS or Beidou positioning technology is adopted for outdoor departments, but the GPS or the Beidou returns longitude and latitude coordinates (Lat/Lgt), so the following processing is required, and the coordinates are finally converted into graph coordinates. Namely, another implementation scheme is as follows:

step 2.2', satellite positioning algorithm

A reference point, map coordinates (X1, Y1) of the reference point, and second vicat coordinates (MX1, MY1) of the reference point are set to be known in the architectural map.

For the longitude and latitude coordinates (Lat2/Lgt2) of the client device returned by the GPS or the Beidou, the longitude and latitude coordinates are converted into first default Cartesian coordinates (MX2 and MY2), and then the longitude and latitude coordinates are converted into graph coordinates by adopting the following formula:

X2＝X1+c*(MX2-MX1)

Y2＝Y1+c*(MY2-MY1)

where c is the scale of the architectural drawing (generally 1/100).

And 2.3, reporting the block identification of the divided blocks to the server side equipment.

In the process of field inspection, the automatic positioning technology is introduced, namely, engineering personnel find engineering problems in the field inspection, and when the problems are submitted through client equipment, the current partition block can be automatically obtained and reported. Thus, the efficiency is remarkably improved when problems are rechecked, checked and analyzed.

What needs to be added here is: the technical scheme provided by each embodiment of the application can also comprise a dividing block importance level dividing function, namely, corresponding importance levels are configured for each dividing block on the field map. In specific implementation, the importance levels corresponding to the divided blocks may be configured manually, or may be configured automatically by a method execution subject (e.g., client device or server device). For example, one implementation of the following:

at least some of the embodiments of the present application may further include:

s11, responding to the important level configuration operation triggered by the user aiming at the partition blocks, and acquiring the important level configured by the user;

and S12, associating the user configuration importance level with the block identification of the divided block.

Alternatively, at least some of the embodiments of the present application may further include the following steps:

s11', determining the importance level according to the block data of the divided blocks; wherein, the block data contains facility identification in the corresponding area of the divided block;

s12', associating the importance level with the block identity of the partitioned block.

It is assumed that in a building site scenario, facilities within the region corresponding to a partition block may include, but are not limited to: cameras, electrical boxes, communications facilities, and the like. The facility identifier may be a serial number of the facility, a device name, and the like, and for different types of sites, the facilities in the site may be different, which is not listed in this embodiment.

One function of the importance levels of the partition blocks is that the alarm with different degrees or modes can be timely given out after the report information corresponding to the partition blocks with high importance levels exists. For example, the reported information corresponding to the high-importance grade division block adopts a multi-time alarm mode, such as once alarm at an interval of 30 seconds; and reporting information corresponding to the low-importance grade division block by adopting a single alarm mode. Or, the reporting information corresponding to the high-importance grade division block alarms in a high-volume alarm sound mode; reporting information corresponding to the low-importance grade division block to alarm in a low-volume alarm sound mode; etc., the embodiment is not limited to the specific form of the alarm. That is, at least some of the embodiments of the present application may further include the following steps:

s13, after receiving the report information, determining an alarm mode based on the importance level corresponding to the block identifier contained in the report information;

and S14, executing alarm action according to the alarm mode.

In particular implementations, the alert action may include, but is not limited to: vibration, playing an alarm tone, flashing lights on the device (i.e., the execution subject of this step S14, such as a smartphone, PDA, personal digital assistant, etc.), and so forth.

Still further, the scheme provided by each embodiment of the application is suitable for a building construction scene. The construction site has construction drawings of construction stages, for example, foundation construction stages, and corresponding foundation construction drawings. In the building construction stage, a building construction drawing is correspondingly arranged. Therefore, in the same building construction site, corresponding construction drawings (namely, the site maps mentioned herein) are different at different construction stages; in different construction stages, the construction drawings need to be switched, and the division blocks of different construction drawings can be changed; therefore, for the same construction site, the map positions of the same geographical position corresponding to the corresponding construction map at different construction stages are different, and the block identifiers of the corresponding division blocks may also be different.

Further, even if the construction drawing is not changed, the division manner of the divided blocks may be changed as the construction stage advances. For example, in a building subject construction (subject wall casting) stage, division of the division blocks may be divided based on subject walls, columns, and the like. In the partition construction stage inside the building, the partition blocks can be divided according to rooms inside the building, and the like. Therefore, in different construction stages, the block identifiers contained in the report information reported by the user at the same geographical position are different, and the block identifiers are dynamically updated along with the construction stages.

Fig. 8 shows a schematic flowchart of a data processing apparatus according to an embodiment of the present application. As shown in fig. 8, the apparatus includes: an acquisition module 11, a positioning module 12 and a determination module 13. The obtaining module 11 is configured to obtain block data of a plurality of divided blocks of a field map. The positioning module 12 is configured to position a map location corresponding to a geographic location of the client device on the presence map; and the geographic position is the position of the client equipment in the actual site corresponding to the site map. The determining module 13 is configured to determine, according to block data of the plurality of partitioned blocks, a block identifier of the partitioned block where the map position is located; and determining the report information sent to the server side equipment according to the block identifier.

In an implementation scenario, when the location module 12 locates a map location corresponding to a geographic location of a client device on a presence map, it is specifically configured to: acquiring positioning information corresponding to the geographical position of the client equipment; and determining a map position corresponding to the positioning information according to the reference point information on the field map.

In a specific embodiment, the positioning information comprises first default card holder coordinates; the reference point information includes: the image coordinates of the reference point and the default card holder coordinates of the reference point are called as second default card holder coordinates. Correspondingly, when the determining module 13 determines the map position corresponding to the positioning information according to the reference point information on the field map, the determining module is specifically configured to: acquiring the map scale of the field map; and determining the map position according to the map scale, the first default card holder coordinate, the second default card holder coordinate and the map coordinate of the reference point.

Further, the positioning information is longitude and latitude coordinates. Correspondingly, the positioning module 12 is further configured to convert the longitude and latitude coordinates into the first default card holder coordinates.

In another implementation, when the positioning module 12 locates a map location corresponding to the geographic location of the client device on the presence map, the positioning module is specifically configured to: receiving communication information sent by the positioning beacon in the field; determining the signal strength of a communication signal and the beacon identification of the positioning beacon according to the communication information; acquiring the map coordinates of the positioning beacon on the field map according to the beacon identifier; and calculating the map position according to the signal strength and the map coordinates of the positioning beacon.

Further, the device provided by the embodiment may further include a display module. The display module is used for responding to a report request triggered by a user and displaying a report interface. Correspondingly, the obtaining module 11 is further configured to obtain the report content input by the user through the report interface. The determining module 13 is configured to determine, according to the block identifier, reporting information to be sent to the server device, and specifically configured to send the reporting information to the server device based on the reporting content and the block identifier.

Further, the display module is further configured to display the field map and the block identifier, and a map identifier corresponding to the client device is displayed at the map position of the field map.

Further, the apparatus provided in this embodiment further includes a triggering module. The triggering module is used for responding to the operation of the user on the graph identifier corresponding to the client device and triggering the reporting request.

Further, when the obtaining module 11 obtains block data of a plurality of divided blocks of the field map, it is specifically configured to: carrying out block division on the field map to obtain block data of a plurality of divided blocks; or acquiring block data of a plurality of divided blocks of the field map from the server-side equipment.

Further, when the obtaining module 11 divides the field map to obtain block data of a plurality of divided blocks, it is specifically configured to: dividing the field map into a plurality of divided blocks to obtain boundary information of the divided blocks; and obtaining block data of the division blocks according to the boundary information of the division blocks and the floor marks corresponding to the field map.

Further, the apparatus provided in this embodiment may further include a planning module and a display module. Wherein the planning module is used for planning at least one route according to the block data of the plurality of divided blocks; the presentation module is configured to present the at least one route on the field map.

Still further, when the display module provided in this embodiment displays the at least one route on the map, the display module is specifically configured to: acquiring the grade of each route; and on the field map, lines of different grades are displayed in a distinguishing manner.

Here, it should be noted that: the data processing apparatus provided in the foregoing embodiment may implement the technical solutions described in the foregoing corresponding method embodiments, and the principles and beneficial effects of the specific implementation of each module or unit may refer to the corresponding contents in the foregoing corresponding method embodiments, which are not described herein again.

Fig. 9 shows a schematic structural diagram of a data processing apparatus according to another embodiment of the present application. As shown in fig. 9, the data processing apparatus includes: a dividing module 21 and a sending module 22. The dividing module 21 is configured to divide the field map into blocks to obtain block data of a plurality of divided blocks. The sending module 22 is configured to send the block data of the multiple partitioned blocks of the field map to the server device, so that the client device determines the report information sent to the server device by using the block data of the multiple partitioned blocks.

Further, the dividing module 21 is specifically configured to, when dividing the site map to obtain block data of a plurality of divided blocks: dividing the field map into a plurality of divided blocks to obtain boundary information of the divided blocks; and obtaining block data of the division blocks according to the boundary information of the division blocks and the floor marks corresponding to the field map.

Further, the division blocks are rectangular blocks. Correspondingly, when the dividing module 21 divides the field map into a plurality of divided blocks to obtain boundary information of the plurality of divided blocks, it is specifically configured to: dividing the field map into a plurality of rectangular blocks by adopting a plurality of transverse axes and a plurality of longitudinal axes; calculating the image coordinates of four vertexes of each rectangular block according to the shaft distances of the transverse shafts and the shaft distances of the longitudinal shafts; and obtaining the block data of the rectangular block according to the map coordinates of the four vertexes of the rectangular block and the floor marks corresponding to the field map.

Further, the apparatus provided in this embodiment may further include: the device comprises an acquisition module and a display module. The acquisition module is used for acquiring the report information which is stored by the server-side equipment and related to the site map. The display module is used for displaying a visual icon corresponding to the report information at a division block corresponding to the block identifier of the displayed field map according to the block identifier contained in the report information.

Still further, the display module is further configured to display the report information in response to an operation of the user on the visual icon.

Further, the apparatus provided in this embodiment may further include an obtaining module. The obtaining module is used for responding to the route setting operation of the user for the plurality of divided blocks, and obtaining at least one route set by the user; the sending module is further configured to send the at least one route to a server device in association with the venue diagram, so that the client device can obtain and display the at least one route.

Further, the apparatus provided in this embodiment further includes a generation module and a display module. Specifically, the obtaining module is configured to obtain at least one report information related to the site map; wherein, the reported information contains block identification; the generating module is used for generating a first planning route according to the block identifier contained in the at least one piece of reporting information; the display module is configured to display the first planned route on the field map.

Still further, the apparatus provided in this embodiment includes a dividing module and a display module. The dividing module is used for acquiring reporting information related to the site map; wherein, the reported information contains block identification; and carrying out priority division on the reported information to obtain the priority corresponding to the reported information. And the display module is used for displaying the visual icon corresponding to the reported information in the division block corresponding to the block identifier of the field map by adopting the display mode corresponding to the priority.

Further, the apparatus provided in this embodiment includes a dividing module, a generating module, and a display module. The dividing module is used for acquiring at least one piece of reporting information related to the site map; wherein, the reported information contains block identification; and performing priority division on the at least one piece of reported information to obtain the priority corresponding to the reported information. The generating module is used for determining the report information belonging to the set priority; and generating a second planning route according to the block identifiers contained in the report information belonging to the set priority. The display module is configured to display the second planned route on the site map.

Fig. 10 is a schematic structural diagram of a data processing apparatus according to yet another embodiment of the present application. As shown, the apparatus comprises: a transmitting module 31 and a receiving module 32. The sending module is used for sending block data of a plurality of divided blocks of the field map to the first client device. The receiving module is used for receiving the report information sent by the first client device; wherein the reporting information includes: determining a block identifier of a partition block to which the geographical position of the first client equipment corresponds to the map position by using block data of the plurality of partition blocks; the geographic position is a position of the first client device in an actual field corresponding to the field map.

Further, the sending module 31 is further configured to: and sending reporting information corresponding to the site map to a second client device, so that the second client device displays a visual icon corresponding to the reporting information at a partition block corresponding to the block identifier of the site map.

Further, the apparatus provided in this embodiment further includes a storage module. The storage module is used for receiving and storing at least one route which is sent by the first client device and is related to the site map so as to be obtained and displayed by the second client device.

Further, the apparatus provided in this embodiment further includes a generating module. The generation module is used for acquiring at least one piece of reporting information related to the site map; wherein, the reported information contains block identification; and generating a first planning route according to the block identifier contained in the at least one piece of reporting information. The sending module is further configured to send the first planned route to a second client device for the second client device to display the first planned route on the field map.

Further, the apparatus provided in this embodiment further includes a dividing module. The dividing module is used for acquiring reporting information related to the site map; and carrying out priority division on the reported information to obtain the priority corresponding to the reported information. The sending module is further configured to send the priority corresponding to the report information to a second client device.

Fig. 11 shows a schematic structural diagram of a client device according to an embodiment of the present application. As shown in fig. 11, the client device includes a memory 41 and a processor 42. The memory 41 may be configured to store other various data to support operations on the electronic device. Examples of such data include instructions for any application or method operating on the client device. The memory 41 may be implemented by any type or combination of volatile or non-volatile memory devices, such as Static Random Access Memory (SRAM), electrically erasable programmable read-only memory (EEPROM), erasable programmable read-only memory (EPROM), programmable read-only memory (PROM), read-only memory (ROM), magnetic memory, flash memory, magnetic or optical disks.

The memory 41 is used for storing programs;

the processor 42, coupled to the memory 41, is configured to execute the program stored in the memory 41 to:

acquiring block data of a plurality of divided blocks of a field map;

When the processor 42 executes the program in the memory 41, in addition to the above functions, other functions may be implemented, and reference may be specifically made to the description of the foregoing embodiments.

Further, as shown in fig. 11, the electronic apparatus further includes: communication components 43, power components 44, and a display 45. Only some of the components are schematically shown in fig. 11, and it is not meant that the electronic device includes only the components shown in fig. 11.

Another embodiment of the present application further provides a client device. The structure of the client device is the same as that of fig. 11 above. Specifically, the client device includes: a memory and a processor; wherein the content of the first and second substances,

the memory is used for storing programs;

When the processor executes the program in the memory, the processor may implement other functions in addition to the above functions, which may be specifically referred to the description of the foregoing embodiments.

Another embodiment of the present application provides a server device. The structure of the server device is the same as that of fig. 11. Specifically, the server device includes a memory, a processor and a communication component, wherein,

receiving report information sent by the first client device;

Further, when the processor executes the program in the memory, other functions may be implemented in addition to the above functions, which may be specifically referred to in the description of the foregoing embodiments.

Accordingly, embodiments of the present application also provide a computer-readable storage medium storing a computer program, where the computer program can implement the steps or functions of the data processing method provided in the foregoing embodiments when executed by a computer.

The above-described embodiments of the apparatus are merely illustrative, and the units described as separate parts may or may not be physically separate, and parts displayed as units may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the modules may be selected according to actual needs to achieve the purpose of the solution of the present embodiment. One of ordinary skill in the art can understand and implement it without inventive effort.

Through the above description of the embodiments, those skilled in the art will clearly understand that each embodiment can be implemented by software plus a necessary general hardware platform, and certainly can also be implemented by hardware. With this understanding in mind, the above-described technical solutions may be embodied in the form of a software product, which can be stored in a computer-readable storage medium such as ROM/RAM, magnetic disk, optical disk, etc., and includes instructions for causing a computer device (which may be a personal computer, a server, or a network device, etc.) to execute the method according to the embodiments or some parts of the embodiments.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solutions of the present application, and not to limit the same; although the present application has been described in detail with reference to the foregoing embodiments, it should be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions in the embodiments of the present application.

Claims

1. A data processing method, comprising:

acquiring block data of a plurality of divided blocks of a field map;

2. The method of claim 1, wherein locating a map location on the presence map corresponding to the geographic location of the client device comprises:

acquiring positioning information of the geographic position of the client equipment;

and determining a map position corresponding to the positioning information according to the reference point information on the field map.

3. The method of claim 2, wherein the positioning information comprises first default Cartesian coordinates; the reference point information includes: the image coordinates of the reference point and the default card holder coordinates of the reference point are called as second default card holder coordinates; and

determining a map position corresponding to the positioning information according to the reference point information on the field map, including:

acquiring the map scale of the field map;

and determining the map position according to the map scale, the first default card holder coordinate, the second default card holder coordinate and the map coordinate of the reference point.

4. The method of claim 3, wherein the positioning information is latitude and longitude coordinates; and

the method further comprises the following steps:

and converting the longitude and latitude coordinates into the first default card holder coordinates.

5. The method of claim 1, wherein locating a map location on the presence map corresponding to the geographic location of the client device comprises:

receiving communication information sent by the positioning beacon in the field;

determining the signal strength of a communication signal and the beacon identification of the positioning beacon according to the communication information;

acquiring the map coordinates of the positioning beacon on the field map according to the beacon identifier;

and calculating the map position according to the signal strength and the map coordinates of the positioning beacon.

6. The method of any one of claims 1 to 5, further comprising:

responding to a report request triggered by a user, and displaying a report interface;

acquiring the reported content input by the user through the reported interface;

and determining the report information sent to the server side equipment according to the block identifier, wherein the report information comprises:

7. The method of claim 6, further comprising:

and displaying the field map and the block identifier, wherein the map position of the field map shows the map identifier corresponding to the client equipment.

8. The method of claim 7, further comprising:

and triggering the report request in response to the operation of the user on the graph identifier corresponding to the client equipment.

9. The method of any one of claims 1 to 5, wherein obtaining block data of a plurality of partitioned blocks of a field map comprises:

10. The method of claim 9, wherein dividing the field map into a plurality of divided blocks of data comprises:

11. The method of any one of claims 1 to 5, further comprising:

planning at least one route according to the block data of the plurality of divided blocks;

on the field map, the at least one route is shown.

12. The method of claim 11, wherein presenting the at least one route on the field map comprises:

acquiring the grade of each route;

and on the field map, lines of different grades are displayed in a distinguishing manner.

13. A data processing method, comprising:

14. The method of claim 13, wherein dividing the field map into a plurality of divided blocks of data comprises:

15. The method of claim 14, wherein the partitioned blocks are rectangular blocks; and

dividing the field map into a plurality of division blocks to obtain boundary information of the division blocks, wherein the boundary information comprises:

dividing the field map into a plurality of rectangular blocks by adopting a plurality of transverse axes and a plurality of longitudinal axes;

calculating the image coordinates of four vertexes of each rectangular block according to the shaft distances of the transverse shafts and the shaft distances of the longitudinal shafts;

and obtaining the block data of the rectangular block according to the map coordinates of the four vertexes of the rectangular block and the floor marks corresponding to the field map.

16. The method of any of claims 13 to 15, further comprising:

acquiring reported information which is stored by server equipment and related to the site map;

and displaying a visual icon corresponding to the report information at a partition block corresponding to the block identifier of the displayed field map according to the block identifier contained in the report information.

17. The method of claim 16, further comprising:

and responding to the operation of the user on the visual icon, and displaying the reported information.

18. The method of any of claims 13 to 15, further comprising:

acquiring at least one route set by a user in response to a route setting operation of the user for the plurality of divided blocks;

and sending the at least one route to a server device in association with the site map so as to be convenient for the client device to acquire and display the at least one route.

19. The method of any of claims 13 to 15, further comprising:

acquiring at least one piece of reported information related to the site map; wherein, the reported information contains block identification;

generating a first planning route according to the block identifier contained in the at least one piece of reporting information;

displaying the first planned route on the field map.

20. The method of any of claims 13 to 15, further comprising:

acquiring reported information related to the site map; wherein, the reported information contains block identification;

carrying out priority division on the reported information to obtain the priority corresponding to the reported information;

and displaying the visual icon corresponding to the reported information at the division block corresponding to the block identifier of the field map by adopting a display mode corresponding to the priority.

21. The method of any of claims 13 to 15, further comprising:

performing priority division on the at least one piece of reported information to obtain the priority corresponding to the reported information;

determining the reported information belonging to the set priority;

generating a second planning route according to the block identifiers contained in the report information belonging to the set priority;

displaying the second planned route on the field map.

22. A data processing method, comprising:

receiving report information sent by the first client device;

23. The method of claim 22, further comprising:

and sending reporting information corresponding to the site map to a second client device, so that the second client device displays a visual icon corresponding to the reporting information at a partition block corresponding to the block identifier of the site map.

24. The method of claim 22 or 23, further comprising:

and receiving and storing at least one route which is sent by the first client device and is related to the site map so as to be acquired and displayed by the second client device.

25. The method of claim 22 or 23, further comprising:

sending the first planned route to a second client device for the second client device to display the first planned route on the field map.

26. The method of claim 22 or 23,

acquiring reported information related to the site map;

and sending the priority corresponding to the reported information to a second client device.

27. A data processing system, comprising:

28. The system of claim 27, further comprising:

the second client device is used for acquiring reporting information related to the site map from the server device; and displaying a visual icon corresponding to the report information at a partition block corresponding to the block identifier of the displayed field map according to the block identifier contained in the report information.

29. The system of claim 27,

the second client device is further configured to perform block division on the site map to obtain block data of a plurality of divided blocks; sending the block data of the plurality of divided blocks of the field map to server-side equipment;

the server-side equipment is also used for storing block data of a plurality of divided blocks of the field map.

30. A client device, comprising: a memory and a processor; wherein the content of the first and second substances,

the memory is used for storing programs;

acquiring block data of a plurality of divided blocks of a field map;

31. A client device, comprising: a memory and a processor; wherein the content of the first and second substances,

the memory is used for storing programs;

32. A server device, comprising a memory, a processor, and a communication component, wherein,

receiving report information sent by the first client device;