WO2019085081A1

WO2019085081A1 - Method and apparatus for correcting target position in map, computer device, and storage medium

Info

Publication number: WO2019085081A1
Application number: PCT/CN2017/112642
Authority: WO
Inventors: 张发友; 陈宗阳
Original assignee: 平安科技（深圳）有限公司
Priority date: 2017-10-31
Filing date: 2017-11-23
Publication date: 2019-05-09
Also published as: CN107885800A; CN107885800B

Abstract

A method and apparatus for correcting a target position in a map, a computer device, and a computer-readable storage medium. The method for correcting a target position in a map comprises: acquiring target position description information (S202); determining a target position in a planimetric map according to the target position description information (S204); jumping to a real-view map, and acquiring, according to the target position determined in the planimetric map, real-view information from a street scene displayed in the real-view map (S206); feeding back the real- view information (S208); receiving position offset description information in response to the real-view information (S210); determining the real-view information in the real-view map according to the position offset description information (S212); using the position, corresponding to the determined real-view information, in the planimetric map as a corrected target position (S214).

Description

Target location correction method, device, computer device and storage medium in map

This application claims the priority of the Chinese patent application filed on October 31, 2017, the Chinese Patent Office, the application number is 2017110430156, and the invention name is "target location correction method, device, computer equipment and storage medium in the map", all contents thereof This is incorporated herein by reference.

Technical field

The present application relates to the field of electronic maps, and in particular to a method, apparatus, computer device and computer readable storage medium for correcting a target position in a map.

Background technique

At present, it is difficult for the staff to determine the precise target position simply by the target position description information, such as verbal description of the voice information or written information in writing. Therefore, staff often use flat maps to retrieve target locations.

However, according to the target position description information, the target position retrieved in the plane map may be due to factors such as confusion or a large range of names, and it is impossible to confirm a more accurate target position, resulting in inaccurate target position of the final confirmation, so that the use is made. The accuracy of the traditional method to obtain the target location is low.

Summary of the invention

In accordance with various embodiments of the present application, a method, apparatus, computer device, and computer readable storage medium for a target location correction in a map are provided.

A method for correcting a target position in a map, the method comprising:

Obtain target location description information;

Determining a target location in the plane map according to the target location description information;

Jumping to the real map, according to the target position determined in the plane map, from the real scene The street scene displayed in the map obtains real-life information;

Feedback the real scene information;

Receiving location offset description information responsive to the real-world information;

Determining the real scene information in the real map according to the position offset description information; and

A position corresponding to the determined real scene information in the plane map is used as the corrected target position.

A target position correction device in a map, the device comprising:

a description information obtaining module, configured to acquire target location description information;

a target location determining module, configured to determine a target location in the plane map according to the target location description information;

a real scene information acquiring module, configured to jump to the real scene map, and obtain real scene information from the street scene image displayed in the real scene map according to the target position determined in the plane map;

a real-time information feedback module, configured to feed back the real-life information;

a description information receiving module, configured to receive location offset description information in response to the real-world information;

a real scene information determining module, configured to determine real scene information in the real scene map according to the location offset description information; and

The target position correction module is configured to use a position corresponding to the determined real scene information in the plane map as the corrected target position.

One or more non-transitory readable storage mediums storing computer readable instructions, when executed by one or more processors, cause the one or more processors to perform the steps of: acquiring Target position description information; determining a target position in the plane map according to the target position description information; jumping to the real scene map, obtaining the street scene image displayed in the real scene map according to the target position determined in the plane map Real-life information; feedback of the real-life information; receiving location offset description information in response to the real-world information; determining real-reality information in the real-time map according to the location-displacement description information; and determining and determining the planar map The position corresponding to the live view information is used as the corrected target position.

A computer device comprising a memory and one or more processors stored in the memory Having computer readable instructions that, when executed by the processor, cause the one or more processors to perform the steps of: acquiring target location description information; in a planar map based on the target location description information Determining a target location; jumping to a real-life map, acquiring real-view information from the street scene displayed in the real-life map according to the determined target location in the plane map; feeding back the real-life information; receiving the response to the real-life information Position offset description information; determining real scene information in the real map according to the position shift description information; and using a position corresponding to the determined real scene information in the plane map as the corrected target position.

Details of one or more embodiments of the present application are set forth in the accompanying drawings and description below. Other features, objects, and advantages of the invention will be apparent from the description and appended claims.

DRAWINGS

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings to be used in the embodiments will be briefly described below. Obviously, the drawings in the following description are only some embodiments of the present application, Those skilled in the art can also obtain other drawings based on these drawings without any creative work.

1 is an application environment diagram of a target position correction method in a map in an embodiment;

2 is a schematic flow chart of a method for correcting a target position in a map in an embodiment;

3 is a schematic flow chart of a method for correcting a target position in a map in another embodiment;

4 is a structural block diagram of a target position correction device in a map in an embodiment;

FIG. 5 is a structural block diagram of a target position correction device in a map in another embodiment; FIG.

6 is a structural block diagram of a target position correction device in a map in an embodiment;

7 is a structural block diagram of a target position correction device in a map in another embodiment;

FIG. 8 is a structural block diagram of a target position correction device in a map in an embodiment; FIG.

Figure 9 is a block diagram showing the structure of a computer device in an embodiment.

Detailed ways

In order to make the objects, technical solutions and advantages of the present application more clear, the following The present application will be further described in detail. It is understood that the specific embodiments described herein are merely illustrative of the application and are not intended to be limiting.

It will be understood that the terms "first", "second" and the like, as used herein, are used to describe various elements, but these elements are not limited by these terms. These terms are only used to distinguish one element from another. For example, the first quotient value can be referred to as a second quotient value without departing from the scope of the invention, and similarly, the second quotient value can be referred to as a first quotient value. Both the first quotient value and the second quotient value are quotient values, but they are not the same quotient value.

FIG. 1 is an application environment diagram of a target position correction method in a map in an embodiment. Referring to Fig. 1, a target position correction method in the map is applied to a corrected target position system. The system includes a terminal 110 and a server 120. The terminal 110 and the server 120 are connected through a network. The terminal 110 may specifically be a desktop terminal or a mobile terminal, and the mobile terminal may specifically be at least one of a mobile phone, a tablet computer, a notebook computer, and the like. The server 120 can be implemented by a stand-alone server or a server cluster composed of a plurality of servers.

As shown in FIG. 2, in one embodiment, a method of correcting a target position in a map is provided. This embodiment is mainly illustrated by the method being applied to the server 120 in FIG. 1 described above. Referring to FIG. 2, the target location correction method in the map specifically includes the following steps:

S202. Acquire target location description information.

The target location description information is information for describing a target location. For example, the target location description information may specifically be voice information transmitted through the terminal, or may be text information transmitted through the terminal, or may be image information transmitted through the terminal. Correspondingly, the manner of obtaining the target location description information may also be the target location description information transmitted by the server receiving terminal.

In an embodiment, the terminal sends the target location description information to the server through the instant messaging software or the real-time communication software installed on the terminal, and the server acquires the target location description information sent by the terminal.

S204. Determine a target location in the plane map according to the target location description information.

Among them, the plane map can be a two-dimensional electronic map. Determining the target position in the plane map, the coordinate point may be directly selected as the target position according to the position information displayed on the plane map, or The target location is retrieved according to the target location description information by the retrieval function of the plane map.

In one embodiment, the server analyzes the received target location description information, obtains corresponding city information, administrative district information, and insurance location information, and searches for city information in a database of the plane map according to the city information, the administrative district information, and the insurance location information. The plurality of location information matching the administrative zone information and the insurance location information displays a plurality of locations corresponding to the plurality of location information on the map, and determines the target location from the plurality of locations according to the target location description information.

S206. Jump to the real scene map, and obtain real scene information from the street scene image displayed in the real map according to the target position determined in the plane map.

Among them, the real map is a map where you can see the street scene. A street scene is a scene of a street displayed in a real map. The real map can display two-dimensional street scenes and three-dimensional street scenes. Real-life information is information that describes a street scene. The real scene information may specifically be text information, voice information, or image information. Jump to the real map, specifically to call the real map to cover the flat map, or to display the flat map and the corresponding real map on the same screen.

In one embodiment, the server triggers a jump instruction that jumps from the flat map to the live view map, and detects whether the target location has corresponding real scene information in the real map before executing the jump instruction. If the detection result is none, the target position is re-selected on the plane map, so that after the server executes the jump instruction, the scene information corresponding to the target position can be obtained by jumping from the plane map to the real map.

S208, feedback real scene information.

The feedback real scene information may be feedback information to the terminal that sends the target location description information.

In one embodiment, the terminal transmits target location description information in the form of textual information to the server. After the server obtains the real scene information according to the target location description information, the server feeds back the real scene information in the form of the voice information to the terminal.

S210. Receive location offset description information in response to real-time information.

The location offset description information is information for describing a target location offset. The location offset description information may specifically be text information, voice information, or image information. Receiving The location offset description information may be specifically transmitted through real-time communication software or instant messaging software on the terminal.

In one embodiment, the terminal transmits location offset description information in the form of voice information via real-time communication software. After receiving the location offset description information, the server analyzes the location offset description information to obtain a message offset to the east by 15 meters.

S212. Determine real-life information in the real-life map according to the location offset description information.

Wherein, the real scene information is determined according to the location offset description information, and the real map may be offset according to the location description information, and the real scene information may be determined in the offset real map.

Specifically, the server shifts the real-life map according to the position offset description information to redisplay the street scene image, and reacquires the real-life map according to the re-displayed street scene image.

In one embodiment, after the real-time map is shifted east by 45 meters according to the positional shift description information, the real-life information is determined as a bank and a street scene on the right side of the bank in a real-life map offset 45 meters eastward.

In one embodiment, after the real-time map is offset according to the position offset description information, the determined real-life information is a street scene image, and the determined street scene image is described by voice to obtain real-life information in the form of voice information.

S214. A position corresponding to the determined real scene information in the plane map is used as the corrected target position.

The position corresponding to the determined real scene information in the plane map may be a position that is calibrated in the plane map after the real map is converted into a plane map, or may be automatically corrected in the plane map when the real scene information is determined in the real map. position.

In one embodiment, the plane map and the real map are simultaneously displayed on the display of the server, and the real scene information corresponding to the target position selected by the plane map is displayed in the real map. When the real map is offset to obtain the re-determined real scene information, the target position is simultaneously determined on the plane map, and the target position determined simultaneously on the plane map corresponds to the re-determined real scene information on the real map.

In one embodiment, the plane map and the real map are simultaneously displayed on the display of the server, and the real scene information corresponding to the target position selected by the plane map is displayed in the real map. When on a flat map When the target position is re-determined, the real-life information corresponding to the re-determined target position is acquired on the real-life map.

The target position correction method in the above map retrieves the target position according to the target position description information in the plane map by acquiring the target position description information. Then jump to the real-life map, display the street scene image in the real-life map according to the target location, and obtain the real-life information corresponding to the target location according to the street scene image, and observe the acquired real-life information, so that the corresponding visual observation can be more intuitively observed. target location. The real scene information is fed back to obtain the position offset description information in response to the real scene information, and the real scene information can be calibrated according to the position offset description information to determine accurate real scene information. By determining the accurate real-life information, the target position can be corrected in the plane map to obtain a precise target position, thereby obtaining a precise target position, thereby improving the accuracy of obtaining the target position.

In one embodiment, jumping to the real-life map, obtaining real-life information from the street scene displayed in the real-life map according to the target position determined in the plane map, including: converting the plane map, and obtaining a real-life map corresponding to the plane map; Extracting the plane coordinates of the target position in the plane map; converting the plane coordinates into real scene coordinates; displaying the street scene image in the real scene map according to the real scene coordinates; obtaining the target scene position in the real scene map corresponding to the street scene image displayed in the real scene map Real information.

Wherein, converting the plane map to the real map may be by triggering a map switching instruction. The plane coordinates may specifically be Martian coordinates. The real scene coordinates may be Baidu coordinates.

In one embodiment, the server converts the plane map, obtains a real map corresponding to the plane map, extracts the plane coordinates of the target position on the plane map, and converts the plane coordinates to the real scene coordinates to obtain the target position in the real map. Corresponding real-life information. When the target position is re-selected on the plane map, the real-life information corresponding to the re-selected target position will be replaced in real time on the real map.

In this embodiment, by converting plane coordinates and real scene coordinates, it is possible to accurately convert between the real map and the plane map, so that the real scene information converted according to the target position can accurately reflect the target position, thereby improving the target position. Accuracy.

In an embodiment, determining the real scene information in the real map according to the location offset description information includes: triggering an instruction to move the real map according to the location offset description information; acquiring the reacquired real Scene information, the re-acquired real-life information is obtained after moving the real-life map; feedbacking the re-acquired real-life information; if receiving the message confirming the re-acquired real-life information, determining the re-acquired real-life information in the real-life map; Upon receiving the message indicating that the re-acquired real-life information is denied, the step of triggering the instruction to move the live view map according to the location offset description information is returned.

The moving real map may specifically trigger the orientation button in the real map to move the real map, or may be converted to move the real map after the plane map re-determines the target position. The message indicating the confirmation of the re-acquired real-life information is the real-life information indicating that the re-acquired real-life information is an accurate target position. The message indicating that the re-acquired real-life information is denied is a real-life information indicating that the re-acquired real-life information is an inaccurate target location.

In an embodiment, after the server receives the location offset description information, the target location is re-selected on the plane map, so that the real scene information corresponding to the reselected target location is displayed on the real map, and the mobile terminal moves according to the location offset description information. Real-life map to regain real-life information. After the re-acquired real-time information is fed back to the terminal, if a message indicating that the re-acquired real-life information is confirmed is received, the re-acquired real-life information is determined in the real-life map; if the re-acquired real-life information is denied The message returns a step of triggering an instruction to move the live view map based on the position offset description information.

In this embodiment, by moving the real map according to the real scene offset description information to obtain accurate real scene information, an accurate target position can be obtained according to the accurate real scene information, thereby improving the accuracy of the target position.

In an embodiment, the target position correction method in the map further includes: when the target position is displayed as a non-passage area in the plane map, the passage area around the target position is retrieved; and the plane coordinate according to the target position is re-opened in the passage area. The target position is selected such that the distance between the target position and the reselected target position is minimized.

Among them, the non-passage area is an area where the road is not displayed on the plane map. A transit area is an area in which a road is displayed on a flat map.

Specifically, when the location of the target location in the plane map does not display the road, the server retrieves the road around the target location in the plane map, and reselects the target location on the retrieved road. The distance between the target position and the selected target position of the reselection is minimized.

In one embodiment, when the location of the target location in the planar map does not show the road, the server retrieves the road in the area around the target location, retrieving the sidewalk and the motorway. The server re-determines the target position on the sidewalk and the motorway, respectively, such that the distance between the target position and the selected target position is minimized, and plans the re-determined target position on the motorway to arrive at the re-determined target position on the sidewalk.

In this embodiment, when the target position is displayed as a non-passing area in the plane map, the target position is re-determined in the passing area, so that the probability that the re-determined target position acquires the real scene information is greater. Therefore, after the real scene information is acquired, the target position is calibrated according to the real scene information, thereby improving the accuracy of acquiring the target position.

In an embodiment, the target position correction method in the map further includes: when the real scene information corresponding to the target position is not detected in the real map, the real image acquisition instruction is fed back; and the real scene image acquired according to the real image acquisition instruction is received; The target position is calibrated according to the real-life image and the target position description information, and an accurate target position is determined in the plane map.

The live image acquisition instruction is an instruction for acquiring a real image. The real-time image acquisition instruction may specifically start a camera program capable of acquiring a real-life image on the terminal, or may be a text message or voice information indicating that the real-life image is captured.

In an embodiment, when the server does not detect the real scene information corresponding to the target location in the real map, the real image acquisition instruction is fed back to the terminal, so that the terminal starts the camera program and collects the live image near the terminal. After receiving the real-life image acquired and transmitted by the terminal, the target position description information is calibrated according to the real-life image, and the target position is calibrated in the plane map according to the calibrated target position description information to determine an accurate target position.

In this embodiment, when the real scene information corresponding to the target position is not detected in the real map, the captured real image is acquired according to the real image acquisition instruction, and then the target position is calibrated according to the real image and the target position description information, thereby Determine the exact target location to improve the accuracy of the target location.

In one embodiment, when the real location information corresponding to the target location is not detected in the real map At this time, the server retrieves the area around the target location to retrieve the area in which the corresponding live view information can be detected. The target position is re-determined in the retrieved area such that the distance between the target position and the re-determined target position is the closest.

FIG. 3 is a schematic flow chart of a method for correcting a target position in a map in an embodiment. Referring to FIG. 3, the target location correction method in the map specifically includes the following steps:

S302. Acquire target location description information.

S304. Determine a target location in the plane map according to the target location description information.

S306. Convert a plane map to obtain a real map corresponding to the plane map.

After step S306 is performed, step S312 is performed. If the target location is displayed as a non-passage area in the plane map, or the plane map where the target location is located does not have a corresponding real-time map, step S312 is canceled, and step S308 is performed.

S308. Retrieve a traffic area around the target location.

S310. Reselect the target position in the transit area according to the plane coordinate of the target position, so that the distance between the target position and the reselected target position is the smallest.

After step S310, the process returns to step S306.

S312. Extract plane coordinates of the target position in the plane map.

S314, converting plane coordinates into real scene coordinates.

S316: Obtain a street scene image in the real scene map according to the real scene coordinates.

S317: Acquire corresponding real-life information of the target location in the real-life map according to the street scene image.

S318, feedback real-life information.

S320. Receive location offset description information in response to real-time information.

S322. Trigger an instruction to move the real map according to the location offset description information.

S324. Acquire real-time information acquired again, and the re-acquired real-life information is obtained after moving the real-life map.

S326, feeding back the re-acquired real-life information.

After the step S326, if a message indicating confirmation of the re-acquired real-time information is received, step S328 is performed. If a message indicating denial of the reacquired real-life information is received, then return Step S322.

S328, determining the re-acquired real-life information in the real-life map.

S330. A position corresponding to the determined real scene information in the plane map is used as the corrected target position.

In this embodiment, by acquiring the target location description information, the target location description information is retrieved in the plane map to determine the target location. Then jump to the real-life map, display the street scene image in the real-life map according to the target location, and obtain the real-life information corresponding to the target location according to the street scene image, and observe the acquired real-life information, so that the corresponding visual observation can be more intuitively observed. target location. The real scene information is fed back to obtain the position offset description information in response to the real scene information, and the real scene information can be calibrated according to the position offset description information to determine accurate real scene information. By determining the accurate real-life information, the target position can be corrected in the plane map to obtain a precise target position, thereby obtaining a precise target position, thereby improving the accuracy of obtaining the target position.

It should be understood that although the various steps in the flowchart of FIG. 3 are sequentially displayed as indicated by the arrows, these steps are not necessarily performed in the order indicated by the arrows. Except as explicitly stated herein, the execution of these steps is not strictly limited, and the steps may be performed in other orders. Moreover, at least some of the steps in FIG. 3 may include a plurality of sub-steps or stages, which are not necessarily performed at the same time, but may be performed at different times, and the execution of these sub-steps or stages The order is also not necessarily sequential, but may be performed alternately or alternately with other steps or at least a portion of the sub-steps or stages of the other steps.

As shown in FIG. 4, in an embodiment, a target position correction device 400 in the map is further provided. The target position correction device 400 includes: a description information acquisition module 402, a target position determination module 404, and real scene information acquisition. The module 406, the real-time information feedback module 408, the description information receiving module 410, the real-time information determining module 412, and the target position correction module 414.

The description information obtaining module 402 is configured to acquire target location description information.

The target location determining module 404 is configured to determine a target location in the plane map according to the target location description information.

The real scene information obtaining module 406 is configured to jump to the real scene map, and obtain real scene information from the street scene image displayed in the real scene map according to the target position determined in the plane map.

The real-time information feedback module 408 is configured to feed back real-time information.

The description information receiving module 410 is configured to receive location offset description information in response to the real-time information.

The real-time information determining module 412 is configured to determine the real-life information in the real-life map according to the location offset description information.

The target position correction module 414 is configured to use a position corresponding to the determined real scene information in the plane map as the corrected target position.

The target position correction device in the above map retrieves the target position based on the target position description information in the plane map by acquiring the target position description information. Then jump to the real-life map, display the street scene image in the real-life map according to the target location, and obtain the real-life information corresponding to the target location according to the street scene image, and observe the acquired real-life information, so that the corresponding visual observation can be more intuitively observed. target location. The real scene information is fed back to obtain the position offset description information in response to the real scene information, and the real scene information can be calibrated according to the position offset description information to determine accurate real scene information. By determining the accurate real-life information, the target position can be corrected in the plane map to obtain a precise target position, thereby obtaining a precise target position, thereby improving the accuracy of obtaining the target position.

As shown in FIG. 5, in an embodiment, the target position correction device 400 in the above-mentioned map further includes: a map conversion module 416, configured to convert a plane map to obtain a real map corresponding to the plane map; and a coordinate extraction module 418, configured to Extracting the plane coordinates of the target position in the plane map; the coordinate conversion module 420 is configured to convert the plane coordinates into the real scene coordinates; the street scene display module 421 is configured to display the street scene image in the real scene map according to the real scene coordinates; The module 406 is further configured to obtain, according to the street scene image displayed in the real-life map, corresponding real-life information of the target location in the real-life map.

As shown in FIG. 6 , in one embodiment, the target position correction apparatus 400 in the above-mentioned map further includes: an instruction triggering module 422, configured to trigger an instruction to move the real-life map according to the position offset description information; and the real-state information acquiring module 406 further For obtaining the re-acquired real-life information, the re-acquired real-life information is obtained after moving the real-life map; the real-time information feedback module 408 is also used for feedback The newly acquired real scene information; the real scene information determining module 412 is further configured to: if receiving the message indicating the confirmation of the reacquired real scene information, determining the reacquired real scene information in the real map; the instruction triggering module 422 is further used to Upon receiving the message indicating that the re-acquired real-life information is denied, the step of triggering the instruction to move the live view map according to the location offset description information is returned.

As shown in FIG. 7, in one embodiment, the target location correction apparatus 400 in the above-mentioned map further includes: a map retrieval module 424, configured to retrieve when the target location is displayed as a non-passage area in the plane map. a passage area around the target position; the target position correction module 412 is further configured to reselect the target position in the pass area according to the plane coordinate of the target position, such that the target position and the reselected target position are between The distance is the smallest.

As shown in FIG. 8 , in one embodiment, the real-time information feedback module 408 is further configured to: when the real-life information corresponding to the target location is not detected in the real-life map, feedback a live-image acquisition instruction;

The target position correction device 400 in the above-mentioned map further includes: a real-image acquisition module 426, configured to receive a real-life image acquired according to the real-image acquisition instruction;

The target position correction module 412 is further configured to calibrate the target location according to the real-life image and the target location description information, and determine an accurate target location in the planar map.

In one embodiment, a computer device is provided, which may be a server or a mobile terminal. When the computer device is a server, its internal structure diagram can be as shown in FIG. The computer device includes a processor, memory, and network interface coupled by a system bus. The processor of the computer device is used to provide computing and control capabilities. The memory of the computer device includes a non-volatile storage medium, an internal memory. The non-volatile storage medium stores operating systems and computer readable instructions. The internal memory provides an environment for operation of an operating system and computer readable instructions in a non-volatile storage medium. The network interface of the computer device is used to communicate with an external terminal via a network connection. The computer readable instructions are executed by the processor to implement a target position correction method in the map. The display of the computer device can be a liquid crystal display or an electronic ink display, and the display can be used to display a flat map or a real map. The input device of the computer device may be a touch layer covered on the display screen, or may be a button or a track set on the computer device casing. The ball or the touchpad can also be an external keyboard, a touchpad or a mouse.

It will be understood by those skilled in the art that the structure shown in FIG. 9 is only a block diagram of a part of the structure related to the solution of the present application, and does not constitute a limitation of the computer device to which the solution of the present application is applied. The specific computer device may It includes more or fewer components than those shown in the figures, or some components are combined, or have different component arrangements.

In one embodiment, the target location correction device in the map provided by the present application can be implemented in the form of a computer readable instruction that can be executed on a computer device as shown in FIG. Each program module constituting the target position correction device in the map may be stored in a memory of the computer device, for example, the description information acquisition module 402, the target position determination module 404, the real scene information acquisition module 406, and the real scene information feedback module 408 shown in FIG. The description information receiving module 410, the live view information determining module 412, and the target position correcting module 414. The computer readable instructions formed by the various program modules cause the processor to perform the steps in the map in the target position correction method of the various embodiments of the present application described in this specification.

For example, the computer device shown in FIG. 9 can perform step S202 by the description information acquisition module 402 in the target position correction device in the map as shown in FIG. The computer device can perform step S204 through the target location determining module 404. The computer device can perform step S206 through the live view information acquisition module 406. The computer device can perform step S208 through the live view information feedback module 408. The computer device can perform step S210 by the description information receiving module 410. The computer device may perform step S212 by the live view information determining module 412. The computer device can perform step S214 through the target location correction module 414.

In one embodiment, a computer apparatus is also provided, comprising a memory and a processor, the memory storing computer readable instructions that, when executed by the processor, cause the processor to perform the steps of: acquiring a target location Descriptive information; determining a target position in the plane map according to the target position description information; jumping to the real scene map, obtaining real scene information from the street scene image displayed in the real map according to the target position determined in the plane map; feeding back the real scene information; receiving Determining information in response to the positional deviation of the real scene information; determining the real scene information in the real map according to the positional shift description information; and using the position corresponding to the determined real scene information in the plane map as the corrected target position Set.

The above computer device retrieves the target location description information according to the target location description information in the plane map by acquiring the target location description information to determine the target location. Then jump to the real-life map, display the street scene image in the real-life map according to the target location, and obtain the real-life information corresponding to the target location according to the street scene image, and observe the acquired real-life information, so that the corresponding visual observation can be more intuitively observed. target location. The real scene information is fed back to obtain the position offset description information in response to the real scene information, and the real scene information can be calibrated according to the position offset description information to determine accurate real scene information. By determining the accurate real-life information, the target position can be corrected in the plane map to obtain a precise target position, thereby obtaining a precise target position, thereby improving the accuracy of obtaining the target position.

In one embodiment, when the computer readable instructions are executed by the processor, causing the processor to perform a jump to the real scene map, the step of obtaining real scene information from the street scene displayed in the real map according to the determined target position in the plane map The processor further performs the following steps: converting the plane map to obtain a real map corresponding to the plane map; extracting the plane coordinates of the target position in the plane map; converting the plane coordinates into real scene coordinates; and mapping the real scene according to the real scene coordinates The street scene is displayed in the middle; the street scene image displayed in the real map is obtained, and the corresponding real scene information in the real map is obtained.

In one embodiment, when the computer readable instructions are executed by the processor, causing the processor to perform the step of determining the live view information in the live view map based on the location offset description information, the processor is further caused to perform the step of: The instruction information triggers the instruction of moving the real map; the re-acquired real-life information is obtained, and the re-acquired real-life information is obtained after moving the real-life map; the re-acquired real-life information is received; and if the re-acquired real-life information is received, the confirmation message is received. And determining, in the real-life map, the re-acquired real-life information; if receiving the message indicating that the re-acquired real-life information is denied, returning the step of triggering the instruction to move the real-time map according to the location offset description information.

In one embodiment, when the computer readable instructions are executed by the processor, the processor is further caused to perform the step of: when the target location is displayed as a non-passage area in the planar map, then retrieving the transit area around the target location; The plane coordinates of the target position are re-selected in the transit area. The target position is such that the distance between the target position and the reselected target position is the smallest.

In one embodiment, when the computer readable instructions are executed by the processor, the processor further causes the processor to perform the step of: feeding back the live image acquisition instruction when the real scene information corresponding to the target location is not detected in the real map; Real-time image acquired according to the real-life image acquisition instruction; the target position is calibrated according to the real-life image and the target position description information, and an accurate target position is determined in the plane map.

In one embodiment, there is also provided a computer readable storage medium storing computer readable instructions, when executed by a processor, causing a processor to perform the steps of: acquiring target location description information; The target position description information determines the target position in the plane map; jumps to the real scene map, obtains the real scene information from the street scene image displayed in the real map according to the target position determined in the plane map; feeds the real scene information; receives the response in the real scene information Position offset description information; determining real scene information in the real map according to the position shift description information; and determining a position corresponding to the determined real scene information in the plane map as the corrected target position.

The above computer readable storage medium retrieves the target location description information according to the target location description information in the plane map to determine the target location. Then jump to the real-life map, display the street scene image in the real-life map according to the target location, and obtain the real-life information corresponding to the target location according to the street scene image, and observe the acquired real-life information, so that the corresponding visual observation can be more intuitively observed. target location. The real scene information is fed back to obtain the position offset description information in response to the real scene information, and the real scene information can be calibrated according to the position offset description information to determine accurate real scene information. By determining the accurate real-life information, the target position can be corrected in the plane map to obtain a precise target position, thereby obtaining a precise target position, thereby improving the accuracy of obtaining the target position.

In one embodiment, when the computer readable instructions are executed by the processor, causing the processor to perform a jump to the real scene map, the step of obtaining real scene information from the street scene displayed in the real map according to the determined target position in the plane map The processor further performs the following steps: converting the plane map to obtain a real map corresponding to the plane map; extracting the plane coordinates of the target position in the plane map; converting the plane coordinates into real scene coordinates; and mapping the real scene according to the real scene coordinates The street scene is displayed in the middle; the street scene image displayed in the real map is obtained, and the corresponding position is obtained in the real map. Scene information.

In one embodiment, when the computer readable instructions are executed by the processor, the processor is further caused to perform the step of: when the target location is displayed as a non-passage area in the planar map, then retrieving the transit area around the target location; The plane coordinate of the target position reselects the target position within the transit area such that the distance between the target position and the reselected target position is minimized.

One of ordinary skill in the art can understand that all or part of the process of implementing the above embodiments can be completed by computer readable instructions, which can be stored in a non-volatile computer. The readable storage medium, which when executed, may include the flow of an embodiment of the methods as described above. Any reference to a memory, database or other medium used in the various embodiments provided herein may include non-volatile memory. Non-volatile memory can include read only memory (ROM), programmable ROM (PROM), electrically programmable ROM (EPROM), electrically erasable programmable ROM (EEPROM), or flash memory.

The technical features of the above embodiments may be combined in any combination, so that the description is concise, All possible combinations of the various technical features in the above embodiments are described. However, as long as there is no contradiction in the combination of these technical features, it should be considered as the scope of the present specification.

The above-mentioned embodiments are merely illustrative of several embodiments of the present application, and the description thereof is more specific and detailed, but is not to be construed as limiting the scope of the invention. It should be noted that a number of variations and modifications may be made by those skilled in the art without departing from the spirit and scope of the present application. Therefore, the scope of the invention should be determined by the appended claims.

Claims

A method for correcting a target position in a map, the method comprising:

Obtain target location description information;

Determining a target location in the plane map according to the target location description information;

Jumping to the real scene map, obtaining real scene information from the street scene image displayed in the real map according to the determined target position in the plane map;

Feedback the real scene information;

Receiving location offset description information responsive to the real-world information;

Determining the real scene information in the real map according to the position offset description information; and

A position corresponding to the determined real scene information in the plane map is used as the corrected target position.
The method according to claim 1, wherein the jump to the real-life map, and the real-life information is obtained from the street scene displayed in the real-life map according to the determined target position in the plane map, including:

Converting the plane map to obtain a real map corresponding to the plane map;

Extracting plane coordinates of the target location in a plane map;

Converting the plane coordinates into real scene coordinates;

Displaying a street scene image in the real scene map according to the real scene coordinates; and

Obtaining corresponding real scene information of the target location in the real map from the street scene displayed in the real map.
The method according to claim 1, wherein the determining the real scene information in the real map according to the location offset description information comprises:

And triggering an instruction to move the real map according to the position offset description information;

Obtaining the re-acquired real-life information, where the re-acquired real-life information is obtained after moving the real-life map;

Feedbacking the re-acquired real-life information;

Receiving a message indicating that the re-acquired real-life information indicates confirmation Determining the re-acquired real-life information in the figure; and

And if a message indicating that the re-acquired real-life information indicates denial is received, returning to the step of triggering an instruction to move the live view map according to the location offset description information.
The method of claim 1 further comprising:

Retrieving a traffic area around the target location when the target location is displayed as a non-passage zone in the plan map; and

And reselecting the target position in the pass area according to the plane coordinate of the target position, so that the distance between the target position and the reselected target position is the smallest.
The method of claim 1 further comprising:

When the real scene information corresponding to the target position is not detected in the real map, the real image acquisition instruction is fed back;

Receiving a real-life image acquired according to the real-image acquisition instruction; and

And calibrating the target location according to the real-life image and the target location description information, and determining an accurate target location in the planar map.
A target position correction device in a map, the device comprising:

a description information obtaining module, configured to acquire target location description information;

a target location determining module, configured to determine a target location in the plane map according to the target location description information;

a real scene information acquiring module, configured to jump to the real scene map, and obtain real scene information from the street scene image displayed in the real scene map according to the target position determined in the plane map;

a real-time information feedback module, configured to feed back the real-life information;

a description information receiving module, configured to receive location offset description information in response to the real-world information;

a real scene information determining module, configured to determine real scene information in the real scene map according to the location offset description information; and

The target position correction module is configured to use a position corresponding to the determined real scene information in the plane map as the corrected target position.
The device according to claim 6, wherein the device further comprises:

a map conversion module, configured to convert the plane map to obtain a real map corresponding to the plane map;

a coordinate extraction module, configured to extract plane coordinates of the target location in a plane map;

a coordinate conversion module, configured to convert the plane coordinates into real scene coordinates;

a street scene display module, configured to display a street scene image in the real scene map according to the real scene coordinates; and

The real-time information acquiring module is further configured to acquire, according to the street scene image displayed in the real-life map, corresponding real-life information of the target location in the real-life map.
The device according to claim 6, wherein the device further comprises:

An instruction triggering module, configured to trigger an instruction to move the real-world map according to the position offset description information;

The real-time information acquiring module is further configured to acquire re-acquired real-life information, where the re-acquired real-life information is obtained after moving the real-life map;

The real-time information feedback module is further configured to feed back the re-acquired real-life information;

The real-time information determining module is further configured to: if the message indicating the re-acquired real-life information is received, determine the re-acquired real-life information in the real-life map; and

The instruction triggering module is further configured to: if receiving a message indicating that the re-acquired real-world information is denied, returning to the step of triggering an instruction to move the real-world map according to the location offset description information.
The device according to claim 6, wherein the device further comprises:

a map retrieval module, configured to retrieve a transit area around the target location when the target location is displayed as a non-passage area in the plan map; and

The target position correction module is further configured to reselect the target position in the pass area according to the plane coordinate of the target position, so that the distance between the target position and the reselected target position is the smallest.
The device according to claim 6, wherein the real-time information feedback module is further configured to: when the real-life information corresponding to the target location is not detected in the real-life map, Feeding the scene image acquisition instruction;

The target position correction device in the map further includes: a real image acquisition module, configured to receive a real scene image acquired according to the real image acquisition instruction; and

The target position correction module is further configured to calibrate the target position according to the real-life image and the target position description information, and determine an accurate target position in the plane map.
One or more non-transitory readable storage mediums storing computer readable instructions, when executed by one or more processors, cause the one or more processors to perform the following steps:

Obtain target location description information;

Determining a target location in the plane map according to the target location description information;

Jumping to the real scene map, obtaining real scene information from the street scene image displayed in the real map according to the determined target position in the plane map;

Feedback the real scene information;

Receiving location offset description information responsive to the real-world information;

Determining the real scene information in the real map according to the position offset description information; and

A position corresponding to the determined real scene information in the plane map is used as the corrected target position.
The storage medium according to claim 11, wherein said one or more processors perform said jump to a live view map, and display from said live view map according to said determined target position in said planar map Steps to get real-life information, including:

Converting the plane map to obtain a real map corresponding to the plane map;

Extracting plane coordinates of the target location in a plane map;

Converting the plane coordinates into real scene coordinates;

Displaying a street scene image in the real scene map according to the real scene coordinates; and

Obtaining corresponding real scene information of the target location in the real map from the street scene displayed in the real map.
The storage medium of claim 11 wherein said one or more locations And the step of determining, by the processor, the real scene information in the real map according to the location offset description information, including:

And triggering an instruction to move the real map according to the position offset description information;

Obtaining the re-acquired real-life information, where the re-acquired real-life information is obtained after moving the real-life map;

Feedbacking the re-acquired real-life information;

And if the message indicating the confirmation of the re-acquired real-life information is received, determining the re-acquired real-life information in the real-life map; and

And if a message indicating that the re-acquired real-life information indicates denial is received, returning to the step of triggering an instruction to move the live view map according to the location offset description information.
The storage medium of claim 11 wherein when said computer readable instructions are executed by one or more processors, said one or more processors further perform the steps of:

Retrieving a traffic area around the target location when the target location is displayed as a non-passage zone in the plan map; and

And reselecting the target position in the pass area according to the plane coordinate of the target position, so that the distance between the target position and the reselected target position is the smallest.
The storage medium of claim 11 wherein when said computer readable instructions are executed by one or more processors, said one or more processors further perform the steps of:

When the real scene information corresponding to the target position is not detected in the real map, the real image acquisition instruction is fed back;

Receiving a real-life image acquired according to the real-image acquisition instruction; and

And calibrating the target location according to the real-life image and the target location description information, and determining an accurate target location in the planar map.
A computer device comprising a memory and one or more processors having stored therein computer readable instructions, the computer readable instructions being executed by the one or more processors such that the one or more The processors perform the following steps:

Obtain target location description information;

Determining a target location in the plane map according to the target location description information;

Jumping to the real scene map, obtaining real scene information from the street scene image displayed in the real map according to the determined target position in the plane map;

Feedback the real scene information;

Receiving location offset description information responsive to the real-world information;

Determining the real scene information in the real map according to the position offset description information; and

A position corresponding to the determined real scene information in the plane map is used as the corrected target position.
The computer apparatus according to claim 16, wherein said one or more processors perform said jump to a live view map, and display from said live view map based on said determined target position in said planar map Steps to get real-life information, including:

Converting the plane map to obtain a real map corresponding to the plane map;

Extracting plane coordinates of the target location in a plane map;

Converting the plane coordinates into real scene coordinates;

Displaying a street scene image in the real scene map according to the real scene coordinates; and

Obtaining corresponding real scene information of the target location in the real map from the street scene displayed in the real map.
The computer device according to claim 16, wherein the one or more processors perform the step of determining real-life information in the real-time map according to the location offset description information, including:

And triggering an instruction to move the real map according to the position offset description information;

Obtaining the re-acquired real-life information, where the re-acquired real-life information is obtained after moving the real-life map;

Feedbacking the re-acquired real-life information;

And if the message indicating the confirmation of the re-acquired real-life information is received, determining the re-acquired real-life information in the real-life map; and

If receiving a message indicating that the re-acquired real-life information indicates denial, returning according to the The step of position offset description information triggers an instruction to move the live view map.
The computer apparatus of claim 16 wherein said computer readable instructions, when executed by one or more processors, further cause said one or more processors to perform the steps of:

Retrieving a traffic area around the target location when the target location is displayed as a non-passage zone in the plan map; and

And reselecting the target position in the pass area according to the plane coordinate of the target position, so that the distance between the target position and the reselected target position is the smallest.
The computer apparatus of claim 16 wherein said computer readable instructions, when executed by one or more processors, further cause said one or more processors to perform the steps of:

When the real scene information corresponding to the target position is not detected in the real map, the real image acquisition instruction is fed back;

Receiving a real-life image acquired according to the real-image acquisition instruction; and

And calibrating the target location according to the real-life image and the target location description information, and determining an accurate target location in the planar map.