CN115761189A - Multi-element space design method, device, equipment and readable storage medium - Google Patents

Abstract

The application discloses a multivariate space design method, a device, equipment and a readable storage medium, wherein the method comprises the following steps: acquiring environmental information of an environment where a user is located in the real world; displaying a first arbitrary gate merged with the environment after rendering; the first arbitrary gate is used for connecting the real world and the first virtual space; displaying a partially rendered screen in the first virtual space in the first arbitrary gate; when the user is detected to pass through the first arbitrary door, calling all rendering pictures of the first virtual space; the first arbitrary gate currently displays a portion of the rendered screen in the real world. The application aims to improve the fusion degree of reality and virtual space.

Description

Multi-element space design method, device, equipment and readable storage medium

Technical Field

The present application relates to the field of AR, and in particular, to a method, an apparatus, a device, and a readable storage medium for designing a multivariate space.

Background

The AR technology is a technology for skillfully fusing virtual information and the real world, and is widely applied to the fields of multimedia, three-dimensional modeling, real-time tracking and registration, intelligent interaction, sensing and the like. Virtual information such as characters, images, three-dimensional models, music, videos and the like generated by a computer is applied to the real world after analog simulation, and the two kinds of information are mutually supplemented, so that the real world is enhanced.

At present, the AR technology is only simple reality enhancement, the fusion degree with a virtual scene is not high, and scene switching and scene entering are hard.

Disclosure of Invention

In view of this, the present application provides a method, an apparatus, a device and a readable storage medium for designing a multivariate space, which aims to improve the degree of fusion between a real space and a virtual space.

In order to achieve the above object, the present application provides a multivariate space design method, including:

acquiring environmental information of an environment where a user is located in the real world;

displaying a first arbitrary gate merged with the environment after rendering; the first arbitrary gate is used for connecting the real world and the first virtual space; displaying a partially rendered screen in the first virtual space in the first arbitrary gate;

when the user is detected to pass through the first arbitrary door, calling all rendering pictures of the first virtual space; the first arbitrary gate currently displays a partially rendered screen in the real world.

Illustratively, the invoking of all rendered screens of the first virtual space when the user is detected to pass through the first arbitrary gate comprises:

returning to the real world when it is detected that the user passes the first arbitrary gate again;

when the user is detected to pass through a second arbitrary door, calling all rendering pictures of a second virtual space connected with the second arbitrary door; the second arbitrary gate is any arbitrary gate from which the first arbitrary gate is removed from the first virtual space.

Illustratively, the displaying before a first arbitrary gate merged with the environment after rendering comprises:

if an LBS starting instruction input by the user is received, acquiring longitude and latitude information of the user in the real world;

and determining the environment of the user based on the longitude and latitude information and the environment information.

Illustratively, the first arbitrary gate includes a fixed arbitrary gate, and before acquiring the environmental information of the environment where the user is located in the real world, the method further includes:

and planning any door with preset longitude and latitude and preset orientation in a preset area based on a first planning strategy of a host, and fixing to obtain the fixed any door.

Illustratively, the first arbitrary gate comprises a custom arbitrary gate, and the displaying before the first arbitrary gate merged with the environment after rendering comprises:

and when an LBS closing instruction input by the user is received, planning any door with a preset coordinate and a preset orientation in the constructed map based on a second planning strategy of the user to obtain the user-defined any door.

Illustratively, the retrieving all rendering screens of the first virtual space when the user is detected to pass through the first arbitrary gate includes:

acquiring real-time position information and angle information of the user;

generating a movement track of the user in the real world based on the real-time position information;

and calling a corresponding rendering picture based on the moving track and the angle information.

Illustratively, the retrieving all rendering screens of the first virtual space when the user is detected to pass through the first arbitrary gate includes:

and counting the number of users in at least one virtual space connected with the first virtual space in real time, and displaying the number on an interactive interface.

Illustratively, to achieve the above object, the present application further provides a multivariate space design apparatus, comprising:

the first acquisition module is used for acquiring environmental information of the environment where the user is located in the real world;

a display module for displaying a first arbitrary gate merged with the environment after rendering; the first arbitrary gate is used for connecting the real world and the first virtual space; displaying a partially rendered screen in the first virtual space in the first arbitrary gate;

the first retrieving module is used for retrieving all rendering pictures of the first virtual space when the user is detected to pass through the first arbitrary door; the first arbitrary gate currently displays a portion of the rendered screen in the real world.

Illustratively, to achieve the above object, the present application further provides a multivariate space design device, which comprises a memory, a processor and a multivariate space design program stored on the memory and operable on the processor, wherein the multivariate space design program, when executed by the processor, implements the steps of the multivariate space design method as described above.

Illustratively, to achieve the above object, the present application further provides a computer readable storage medium, on which a multivariate space design program is stored, which when executed by a processor implements the steps of the multivariate space design method as described above.

Compared with the prior art, the AR technology is simple reality augmentation, scene switching and scene hardening, and the fusion degree between the real world and the virtual scene is not high. The method includes the steps that environmental information of the environment where a user is located in the real world is obtained; displaying a first arbitrary gate merged with the environment after rendering; the first arbitrary gate is used for connecting the real world and the first virtual space; displaying a partially rendered screen in the first virtual space in the first arbitrary gate; when the user is detected to pass through the first arbitrary door, calling all rendering pictures of the first virtual space; the first arbitrary gate currently displays a portion of the rendered screen in the real world. According to the method, the real space and the virtual space are connected through any door, and as the two spaces are connected through the door in real life, a scene that a user enters another space through the door in reality can be simulated, switching between two virtual world scenes is achieved through any door, partial scenes in the virtual space can be observed through any door when the user is in the real world, and partial scenes in the real scene can be observed through any door after the user enters the virtual space through any door. Therefore, the method and the device improve the degree of fusion of the real space and the virtual space.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the present application and together with the description, serve to explain the principles of the application.

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious for those skilled in the art to obtain other drawings without inventive labor.

FIG. 1 is a schematic flow chart diagram illustrating a first embodiment of a multivariate space design method according to the present application;

FIG. 2 is a schematic diagram of a custom arbitrary gate plan according to a first embodiment of the multivariate space design method of the present application;

FIG. 3 is a schematic diagram of a logic architecture of a first embodiment of the multivariate space design method of the present application;

fig. 4 is a schematic structural diagram of a hardware operating environment according to an embodiment of the present application.

The implementation, functional features and advantages of the objectives of the present application will be further explained with reference to the accompanying drawings.

Detailed Description

It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

Referring to fig. 1, fig. 1 is a schematic flow chart of a first embodiment of the multivariate space design method of the present application.

While the embodiments of the present application provide examples of multivariate spatial design methods, it should be noted that although a logical order is shown in the flow charts, in some cases, the steps shown or described may be performed in an order different from that shown or described herein. For convenience of description, the following omits the execution of the steps of the subject description multivariate spatial design method, which includes:

and step S10, acquiring environment information of the environment where the user is located in the real world.

Step S20, displaying a first arbitrary door which is fused with the environment after being rendered; the first arbitrary gate is used for connecting the real world and the first virtual space; the first arbitrary gate displays a partially rendered screen in the first virtual space.

Step S30, when the user is detected to pass through the first arbitrary door, all rendering pictures of the first virtual space are taken; the first arbitrary gate currently displays a portion of the rendered screen in the real world.

The method comprises the following specific steps:

and step S10, acquiring environment information of the environment where the user is located in the real world.

In the present embodiment, the environment information is image information of an environment in which the user is located, posture information of the user, and the like.

In this embodiment, the user is a person wearing a device, which may be a handheld device, glasses, helmet, or the like. The camera can be used for collecting the ambient photos around the user, and the sensor is used for collecting the posture information of the user.

Illustratively, the user turns on a visual XR (extended reality) device, and collects sensor information such as positioning information and gyroscope information. The visual XR equipment combines the camera tracking and real-time image rendering technology, so that a display medium (an LED/projection bowl screen) and a virtual scene outside the display medium track the visual angle of the camera in real time, and the visual angle is synthesized with a real shooting picture in front of a camera lens, thereby constructing the technology of infinite space sense. Wherein, camera tracking system includes with real camera's real-time motion position, gesture and camera lens parameter: x, Y, Z, pan (rotation around the Y axis, horizontal yaw angle in the Y axis), tilt (rotation around the X axis, vertical pitch angle to the right of the X axis), roll (rotation around the Z axis, forward rotation angle in the Z axis), FOV (Field of View angle), and the like, are transmitted to the virtual production server, and the environment information of the environment where the user is located is determined.

Illustratively, the first arbitrary gate includes a fixed arbitrary gate, and before acquiring the environmental information of the environment where the user is located in the real world, the method further includes:

step a, planning any door with preset longitude and latitude and preset orientation in a preset area based on a first planning strategy of a host, and fixing to obtain the fixed any door.

In this embodiment, the first planning strategy is a strategy that the host plans and wakes of the first arbitrary door according to the latitude and longitude and fixes the position and wake of the first arbitrary door to the latitude and longitude.

Step S20, displaying a first arbitrary door which is fused with the environment after being rendered; the first arbitrary gate is used for connecting the real world and the first virtual space; the first arbitrary gate displays a partially rendered screen in the first virtual space.

In this embodiment, the first arbitrary gate is used to connect the real world and a first virtual space, where the first virtual space is a preset virtual space. Since the user is currently in the real world, the partially rendered picture in the first virtual space is observable through the first arbitrary door, and the picture changes as the user's perspective changes.

Wherein, arbitrary door includes self-defined arbitrary door and fixed arbitrary door, and wherein, the planner of arbitrary door includes designer and user, and self-defined arbitrary door is the arbitrary door that the user set up, and fixed arbitrary door is arbitrary door that the designer placed in advance, and arbitrary door is used for connecting two virtual spaces of connection, and wherein, the quantity of arbitrary door sets up according to user or designer's needs in same virtual space, and this embodiment does not do specifically and restricts. For example, the number of any door is 1, 5, 10. Illustratively, 2 designers plan 1 fixed arbitrary door and 2 fixed arbitrary doors at different positions in the virtual forest space respectively, and 3 users plan 1 user arbitrary door, 1 user arbitrary door and 2 user-defined arbitrary doors respectively.

Illustratively, the displaying before a first arbitrary gate merged with the environment after rendering comprises:

b, if an LBS starting instruction input by the user is received, acquiring longitude and latitude information of the user in the real world;

and c, determining the environment of the user based on the longitude and latitude information and the environment information.

In this embodiment, when the user opens an LBS (Location Based Services) function of the visual XR device, the latitude and longitude information of the user is acquired. And determining the environment of the user according to the longitude and latitude information of the user and the acquired environment information, and matching and calling the environment with the template environment.

Illustratively, the displaying before the first arbitrary gate merged with the environment after rendering further comprises:

and d, when an LBS closing instruction input by the user is received, planning any door with a preset coordinate and a preset orientation in the constructed map based on a second planning strategy of the user to obtain the user-defined any door.

In this embodiment, when the user inputs "no", the LBS location function is not enabled, an instant map is constructed from the captured images or videos, and a custom arbitrary door is set in the instant map. The second planning strategy is to plan custom arbitrary gates based on coordinates in the instant map. When the LBS positioning function is closed, an instant map is constructed according to the collected images or videos, and the coordinates of the user in the map are determined. The second planning strategy is a strategy of self-defining any door according to the coordinates in the instant map. For example, the user coordinate is (1,0,0), and the user sets the coordinate of the custom arbitrary door to (3,1,0).

For example, images or videos can be acquired by a visual camera, a depth camera, or other cameras, and point cloud data can be acquired by a radar; and extracting the characteristic points of the collected images and videos according to a direct sparse algorithm and a semi-direct sparse algorithm, and constructing an instant map according to the characteristic points and point cloud data.

Further, when the LBS is enabled by the user, a user can plan a custom arbitrary gate according to a third planning strategy, which comprises the following specific steps:

step e, if an LBS starting instruction input by the user is received, planning the first arbitrary door based on a third planning strategy; the first planning strategy is to plan the first arbitrary gate through latitude and longitude.

In this embodiment, the third planning strategy is a planning strategy LBS when the user turns on LBS (Location Based Services) function of the visual XR device, which is a service developed around geographical Location data by the mobile terminal using a wireless communication network (or a satellite positioning system), based on the spatial database, to acquire and integrate geographical Location coordinate information of the user with other information to provide the user with a desired Location-related value-added service. When the LBS function is turned on, the visualization XR device may obtain the latitude and longitude of the user.

And displaying whether to start LBS or not on an interactive interface of the visualization XR equipment, and if the user clicks yes, starting the LBS function. After the LBS function is turned on, the visual XR device may obtain the environmental information of the user, and the real-time location information is latitude and longitude information or coordinate information of the user, for example, the latitude and longitude of the user a is (101 ° E,40 ° N), and the latitude and longitude of the user B is (90 ° E,30 ° N). The first planning strategy is that the user inputs the longitude and latitude of a user-defined arbitrary door in the longitude and latitude coordinate range of the real world or the current virtual space and sets the orientation of the user-defined arbitrary door.

Illustratively, the longitude and latitude of the user A are (101 DEG E,40 DEG N), the user A is in a virtual forest space, the longitude range of the called virtual forest space is 100 DEG E-101 DEG 5'E, and the latitude range is 39 DEG 40' N-40 '11' N, and then the longitude and latitude of any door is defined in the range.

Further, a virtual forest space edge schematic diagram is constructed, the edge schematic diagram is an equal proportion reduction diagram of the virtual forest space edge, and the longitude and latitude coordinates of each edge point in the edge schematic diagram are the longitude and latitude coordinates of the edge point corresponding to the virtual forest space edge point.

Illustratively, the first arbitrary gate includes a fixed arbitrary gate, and if the LBS open instruction input by the user is received, the first arbitrary gate is planned based on a third planning strategy, including:

and e1, judging whether any fixed door exists in the preset area of the real world or not when receiving the LBS starting instruction input by the user.

In this embodiment, any gate is fixed as an arbitrary gate planned in advance by the designer. The fixed arbitrary door has the same purpose as any door planned by a user and is used for connecting a real world and a virtual world. And after receiving an LBS opening instruction input by a user, the processing equipment judges whether any fixed door exists in a preset area in the real world or not according to the real-time position information of the user. The preset area is a partial area in the real world, and the preset area is an area within a preset distance by taking a user as a center. The preset distance is set as required, and the present embodiment is not particularly limited, and for example, the preset distance is 20m,30m,40m, and the like.

And e2, if the fixed arbitrary door exists, acquiring the longitude and latitude of the fixed arbitrary door.

In the present embodiment, if there is a fixed arbitrary door, the longitude and latitude coordinates of the fixed arbitrary door are acquired by the LBS function of the visualization XR apparatus. And if no fixed arbitrary door exists, planning and self-defining an arbitrary door in a preset area according to a first planning strategy of a user.

Step e3, planning a first arbitrary door with preset longitude and latitude and preset orientation in the preset area based on a third planning strategy of the user; the preset longitude and latitude is the longitude and latitude without the fixed arbitrary door longitude and latitude in the preset area.

In this embodiment, the third planning strategy is a strategy for planning the first arbitrary gate according to the longitude and latitude. After a first planning strategy input by a user is received, a first arbitrary door with a preset longitude and latitude position and a preset orientation is planned in a preset area, wherein the preset longitude and latitude is the longitude and latitude which is obtained by removing the longitude and latitude of the fixed arbitrary door in the preset area. Any door orientation may be east, south, west, north, southeast, northwest, etc.

Specifically, as shown in fig. 2, 201 is a real world, 202 is a preset area in the real world, 203 is a position of a user, 204 is a fixed arbitrary door position, and 205 is a position of a custom arbitrary door planned for the user. For example, the longitude and latitude of the user a are (101 ° E,40 ° N), the longitude and latitude of the fixed arbitrary door are (101 ° 01 ″ -111e, 40 ° 01 ″ -1n), the radius of the preset area is 1000m, and the longitude and latitude of the user-defined arbitrary door planned by the user is (101 ° 01 ″ -10e, 40 ° 01 ″ -10n).

When the LBS function is started by a user, the user can self-define any door through latitude and longitude positioning, and can also construct an instant map without self-defining any door through latitude positioning, and the user can self-define any door through coordinate positioning. As shown in fig. 3, when the LBS function is turned on, the combination situation of any door includes 4 kinds, and when there is no fixed any door in the preset area and the user does not limit the position of the customized any door by the LBS function, the combination situation of any door is the customized any door without the fixed any door + the LBS limited position; when no fixed arbitrary door exists in the preset area and the user limits the position of the user-defined arbitrary door through the LBS function, the combination condition of the arbitrary door is the user-defined arbitrary door without the fixed arbitrary door plus the LBS limit position; when any fixed door exists in the preset area and the position of the user-defined door is not limited by the LBS function, the combination condition of the any door is the fixed door plus the user-defined door without the LBS limit position; when any fixed door exists in the preset area and the position of the user-defined door is limited by the LBS function, the combination condition of the any door is the user-defined door with the fixed any door plus the LBS limit position.

According to the method and the system, any gate is constructed through the LBS and combined with the instant positioning and map construction technology, the accuracy of combination and positioning of reality and virtual space is greatly improved, and the switching between scenes is more natural.

When the user does not limit the position of any self-defined door through the LBS function, an instant map is constructed through images or videos collected by the camera, and the user sets the coordinate of the any self-defined door in the instant map.

Step S30, when the user is detected to pass through the first arbitrary door, all rendering pictures of the first virtual space are taken; the first arbitrary gate currently displays a portion of the rendered screen in the real world.

In this embodiment, the user enters the first virtual space through a first arbitrary door in the real world, as does the entry into another space through a door in reality. And if the user bypasses the first arbitrary door and cannot enter the first virtual space, continuing to move in the real world. And if the user passes through the first arbitrary door, the user enters the first virtual space, visits in the virtual space and acts. The first arbitrary door is any one of a fixed arbitrary door or a custom arbitrary door.

Illustratively, the virtual space includes: personal museums, personal virtual houses, public museums, grasslands, woods or depths of universe and the like, and the indoor virtual space or the world can be realized according to specific business planning.

Illustratively, the retrieving all rendering screens of the first virtual space when the user is detected to pass through the first arbitrary gate includes:

and c, returning to the real world when the user is detected to pass through the first arbitrary door again.

In this embodiment, when the user passes through the first arbitrary gate again, that is, when it is determined that the user is currently in the intention to return, it is determined to return to the first virtual space or the real world according to the user selection. For example, user a enters the virtual desert space from the virtual forest space through a first arbitrary gate, and returns to the virtual forest space or to the real world when user a again passes through the first arbitrary gate in the virtual desert space.

D, when the user is detected to pass through a second arbitrary door, calling all rendering pictures of a second virtual space connected with the second arbitrary door; the second arbitrary gate is any arbitrary gate from which the first arbitrary gate is removed from the first virtual space.

In this embodiment, the second arbitrary door is any arbitrary door in the first virtual space except the first arbitrary door. When it is detected that the user passes through the second arbitrary door, the second virtual space is entered, and the previous space is not returned. For example, user a enters virtual starry space when passing through a second arbitrary gate in virtual desert space.

In this embodiment, any gate supports a nested manner, i.e. the user a enters the virtual space B through any gate a in the virtual space a and enters the virtual space C through any gate B in the virtual space B.

When the user passes through the second arbitrary door, namely, the user is in the second virtual space, the partial rendering picture in the first virtual space can be seen through the second arbitrary door. And the planning method is basically the same as that of the first arbitrary gate, and is not described herein again.

Illustratively, the retrieving all rendering screens of the first virtual space when the user is detected to pass through the first arbitrary gate includes:

step e, acquiring real-time position information and angle information of the user;

step f, generating a movement track of the user in the real world based on the real-time position information;

and g, calling a corresponding rendering picture based on the moving track and the angle information.

In this embodiment, the real-time location information and angle information of the user in the instant map are determined through the sensor information, image information and location information acquired by the device. The movement track of the user in the real world is generated through the real-time position information. And adjusting a corresponding rendering picture in the first virtual space according to the track information and the angle information of the user.

Illustratively, the retrieving all rendering screens of the first virtual space when the user is detected to pass through the first arbitrary gate includes:

and h, counting the number of the users in at least one virtual space connected with the first virtual space in real time, and displaying the number on an interactive interface.

In this embodiment, one or more arbitrary gates exist in the second virtual space, and each arbitrary gate is correspondingly connected to one virtual space. When the user uses the LBS to position, the number of the users in the virtual space connected with the second virtual space can be counted and displayed on the interactive interface, so that the users can select the next virtual space according to the number of the users, and the experience of the users is further improved.

In this embodiment, for avoiding the user to find the arbitrary door that gets into because of the direction sense is poor, light first arbitrary door when the user passes through first arbitrary door, extinguish first arbitrary door after the user passes through first arbitrary door once more, promoted user's experience sense.

Compared with the prior art, the AR technology is simple reality augmentation, scene switching and scene entering are harsh, and the fusion degree between the real world and the virtual scene is not high. The method includes the steps that environmental information of the environment where a user is located in the real world is obtained; displaying a first arbitrary gate merged with the environment after rendering; the first arbitrary gate is used for connecting the real world and the first virtual space; displaying a partially rendered screen in the first virtual space in the first arbitrary gate; when the user is detected to pass through the first arbitrary door, calling all rendering pictures of the first virtual space; the first arbitrary gate currently displays a portion of the rendered screen in the real world. According to the method and the device, the real space and the virtual space are connected through any door, like the two spaces are connected through the door in real life, a scene that a user enters another space through the door in reality can be simulated, switching between the two virtual world scenes is achieved through any door, part of scenes in the virtual space can be observed through any door when the user is in the real world, and part of scenes in the real scene can be observed through any door after the user enters the virtual space through any door. Therefore, the method and the device improve the degree of fusion of the real space and the virtual space.

Illustratively, the present application further provides a multivariate spatial design apparatus, comprising:

the first acquisition module is used for acquiring environmental information of the environment where the user is located in the real world;

a display module for displaying a first arbitrary gate merged with the environment after rendering; the first arbitrary gate is used for connecting the real world and the first virtual space; displaying a partially rendered screen in the first virtual space in the first arbitrary gate;

the first retrieving module is used for retrieving all rendering pictures of the first virtual space when the user is detected to pass through the first arbitrary door; the first arbitrary gate currently displays a partially rendered screen in the real world.

Illustratively, the multivariate spatial design apparatus further includes:

a return module for returning to the real world when it is detected that the user passes the first arbitrary gate again;

the second retrieving module is used for retrieving all rendering pictures of a second virtual space connected with a second arbitrary door when the user is detected to pass through the second arbitrary door; the second arbitrary gate is any arbitrary gate from which the first arbitrary gate is removed from the first virtual space.

Illustratively, the multivariate spatial design apparatus further includes:

the second acquisition module is used for acquiring longitude and latitude information of the user in the real world if an LBS starting instruction input by the user is received;

and the determining module is used for determining the environment of the user based on the longitude and latitude information and the environment information.

Illustratively, the multivariate spatial design apparatus further includes:

and the first planning module is used for planning any door with preset longitude and latitude and preset orientation in a preset area based on a first planning strategy of a host and fixing the any door to obtain the fixed any door.

Illustratively, the multivariate spatial design apparatus further includes:

and the second planning module is used for planning any door with a preset coordinate and a preset orientation in the constructed map based on a second planning strategy of the user when the LBS closing instruction input by the user is received, so as to obtain the user-defined any door.

Illustratively, the multivariate spatial design apparatus further includes:

the second acquisition module is used for acquiring the real-time position information and the angle information of the user;

a generating module, configured to generate a movement trajectory of the user in the real world based on the real-time location information;

and the third calling module is used for calling a corresponding rendering picture based on the moving track and the angle information.

Exemplarily, the multivariate space design apparatus further includes:

and the counting module is used for counting the number of the users in at least one virtual space connected with the first virtual space in real time and displaying the number on an interactive interface.

The specific implementation of the multi-element space design apparatus of the present application is substantially the same as the embodiments of the multi-element space design method, and is not described herein again.

In addition, this application still provides a many first space design equipment. As shown in fig. 4, fig. 4 is a schematic structural diagram of a hardware operating environment according to an embodiment of the present application.

For example, fig. 4 is a schematic structural diagram of a hardware operating environment of a multiple space design device.

As shown in fig. 4, the multiple space designing apparatus may include a processor 401, a communication interface 402, a memory 403 and a communication bus 404, wherein the processor 401, the communication interface 402 and the memory 403 complete communication with each other through the communication bus 404, and the memory 403 is used for storing a computer program; the processor 401 is configured to implement the steps of the multiple space design method when executing the program stored in the memory 403.

The communication bus 404 mentioned in the above-mentioned multiple space design apparatus may be a Peripheral Component Interconnect (PCI) bus, an Extended Industry Standard Architecture (EISA) bus, or the like. The communication bus 404 may be divided into an address bus, a data bus, a control bus, and the like. For ease of illustration, only one thick line is shown, but this does not mean that there is only one bus or one type of bus.

The communication interface 402 is used for communication between the aforementioned multiple space design apparatus and other apparatuses.

The Memory 403 may include a Random Access Memory (RMD) and a Non-Volatile Memory (NM), such as at least one disk Memory. Optionally, the memory 403 may also be at least one storage device located remotely from the processor 401.

The Processor 401 may be a general-purpose Processor, including a Central Processing Unit (CPU), a Network Processor (NP), and the like; but also Digital Signal Processors (DSPs), application Specific Integrated Circuits (ASICs), field Programmable Gate Arrays (FPGAs) or other Programmable logic devices, discrete Gate or transistor logic devices, discrete hardware components.

The specific implementation of the multiple space design apparatus of the present application is substantially the same as the embodiments of the multiple space design method described above, and is not described herein again.

In addition, an embodiment of the present application further provides a computer-readable storage medium, where a multivariate space design program is stored on the computer-readable storage medium, and when executed by a processor, the multivariate space design program implements the steps of the multivariate space design method as described above.

The specific implementation of the computer-readable storage medium of the present application is substantially the same as the embodiments of the above-mentioned multiple space design method, and is not described herein again.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising a … …" does not exclude the presence of another identical element in a process, method, article, or apparatus that comprises the element.

The above-mentioned serial numbers of the embodiments of the present application are merely for description and do not represent the merits of the embodiments.

Through the above description of the embodiments, those skilled in the art will clearly understand that the method of the above embodiments can be implemented by software plus a necessary general hardware platform, and certainly can also be implemented by hardware, but in many cases, the former is a better implementation manner. Based on such understanding, the technical solutions of the present application may be embodied in the form of a software product, which is stored in a storage medium (e.g., ROM/RAM, magnetic disk, optical disk) and includes instructions for enabling a terminal device (e.g., a mobile phone, a computer, a server, a device, or a network device) to execute the method according to the embodiments of the present application.

The above description is only a preferred embodiment of the present application, and not intended to limit the scope of the present application, and all modifications of equivalent structures and equivalent processes, which are made by the contents of the specification and the drawings of the present application, or which are directly or indirectly applied to other related technical fields, are included in the scope of the present application.

Claims (10)

1. A multivariate spatial design method, comprising:

acquiring environmental information of an environment where a user is located in the real world;

displaying a first arbitrary gate merged with the environment after rendering; the first arbitrary gate is used for connecting the real world and the first virtual space; displaying a partially rendered screen in the first virtual space in the first arbitrary gate;

when the user is detected to pass through the first arbitrary door, calling all rendering pictures of the first virtual space; the first arbitrary gate currently displays a portion of the rendered screen in the real world.

2. The method of claim 1, wherein said invoking all rendered screens of the first virtual space when the user is detected passing the first arbitrary gate comprises:

returning to the real world when it is detected that the user passes the first arbitrary gate again;

when the user is detected to pass through a second arbitrary door, calling all rendering pictures of a second virtual space connected with the second arbitrary door; the second arbitrary gate is any arbitrary gate from which the first arbitrary gate is removed from the first virtual space.

3. The method of claim 1, wherein displaying the rendered first arbitrary door merged with the environment comprises:

if an LBS starting instruction input by the user is received, acquiring longitude and latitude information of the user in the real world;

and determining the environment of the user based on the longitude and latitude information and the environment information.

4. The method of claim 1, wherein the first arbitrary gate comprises a fixed arbitrary gate, and before the obtaining environmental information of an environment in which the user is located in the real world, the method further comprises:

and planning any door with preset longitude and latitude and preset orientation in a preset area based on a first planning strategy of a host, and fixing to obtain the fixed any door.

5. The method of claim 1, wherein the first arbitrary gate comprises a custom arbitrary gate, and wherein the displaying before the first arbitrary gate merged with the environment after rendering comprises:

and when an LBS closing instruction input by the user is received, planning any door with a preset coordinate and a preset orientation in the constructed map based on a second planning strategy of the user to obtain the user-defined any door.

6. The method of claim 1, wherein said invoking all rendered screens of the first virtual space upon detecting that the user passes the first arbitrary gate comprises:

acquiring real-time position information and angle information of the user;

generating a movement track of the user in the real world based on the real-time position information;

and calling a corresponding rendering picture based on the moving track and the angle information.

7. The method of claim 1, wherein said invoking all rendered screens of the first virtual space upon detecting that the user passes the first arbitrary gate comprises:

and counting the number of users in at least one virtual space connected with the first virtual space in real time, and displaying the number on an interactive interface.

8. An apparatus for multivariate spatial design, the apparatus comprising:

the first acquisition module is used for acquiring environmental information of the environment where the user is located in the real world;

a display module for displaying a first arbitrary gate merged with the environment after rendering; the first arbitrary gate is used for connecting the real world and the first virtual space; displaying a partially rendered screen in the first virtual space in the first arbitrary gate;

a first retrieving module, configured to retrieve all rendered frames of the first virtual space when it is detected that the user passes through the first arbitrary gate; the first arbitrary gate currently displays a portion of the rendered screen in the real world.

9. A multivariate space design apparatus, comprising a memory, a processor, and a multivariate space design program stored on the memory and executable on the processor, the multivariate space design program when executed by the processor implementing the steps of the multivariate space design method as recited in any one of claims 1 to 7.

10. A computer-readable storage medium, having stored thereon a multivariate space design program, which when executed by a processor, implements the steps of the multivariate space design method as defined in any one of claims 1 to 7.

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