KR102014699B1 - Ar and vr structure modeling system based on space data according to site condition - Google Patents

Abstract

The AR and VR building modeling system based on spatial data according to the earth condition of the present invention extracts specific spatial data and position data selected by the user from the spatial data, matches the three-dimensional photographing information of the present and based on the user's request Accordingly, by modeling buildings and landscaping in three dimensions by reflecting the notice conditions on the site and providing them as AR and VR contents according to time changes, the building is implemented to the user in advance, and through this, it is possible to determine whether to purchase the site and construct the building. .

Description

AR and VR STRUCTURE MODELING SYSTEM BASED ON SPACE DATA ACCORDING TO SITE CONDITION}

The present invention relates to a spatial data-based AR and VR building modeling system according to the ground conditions, and more particularly to building a building model for arranging buildings to reflect the known conditions in the ground and to create an AR and VR environment for utilizing the same The present invention relates to an AR and VR building modeling system based on spatial data according to ground conditions.

Recently, due to the increasing interest in self-interior and space renovation, there is an increasing demand for designing their own space. Due to this increase in interest, many people want to virtually model three-dimensional houses or buildings of their desired style.

In general, virtual modeling and construction of a house or building in three dimensions requires various processes such as planning, design, engineering, construction, maintenance, and repair. Many companies are involved in this home buying process, and a lot of information needs to be exchanged.

Until now, contractors and architects have played a pivotal role in the building process, but in practice, the first person to contact a home buyer is a real estate broker.

The real estate agent introduces the buyer from the site selection for the construction of the house to the price and construction process, but there is a problem in that it is impossible to provide an accurate guide because there is a lack of expertise in actual building design or construction.

In addition, home buyers look at the ground conditions before making contact with actual contractors or designers and look at various types of expected architectural plans and make decisions accordingly. The current system lacks a system that can meet these needs. .

Japanese Laid-Open Patent No. 2001-250127 Japanese Laid-Open Patent No. 2009-071264

The present invention is to solve such a conventional problem, an object of the present invention is to provide a system that allows a building buyer to model the virtual building based on known conditions in the site.

Another object of the present invention is to provide a system that can look at the construction status in advance between the real estate agent and the building buyer in the early stage of building purchase and look at the expected design by building modeling accordingly.

According to a feature of the present invention for achieving the above object, the spatial data-based AR and VR building modeling system according to the earth conditions of the present invention extracts specific spatial data and position data from the spatial data and present three-dimensional photographing information A spatial data processing module for matching the spatial data and the position data; An architectural modeling module for modeling a building in three dimensions by reflecting site information according to a user's request based on the spatial data and the position data by the spatial data processing module; And an AR and VR implementation module for implementing and providing 3D modeling information generated by the architectural modeling module as AR and VR data.

The spatial data processing module of the present invention comprises: a spatial data extraction unit for extracting and processing spatial data; An object matching unit for matching an object included in the spatial data extracted by the spatial data extraction unit with position data; A current correcting unit for matching the 3D photographing information of the present state to the object and the spatial data matched by the object matching unit and correcting the corrected object and the spatial data with the present state; and an object in the spatial data corrected by the present state correcting unit. It is preferable to include a target object modification unit for removing and modifying objects.

The present municipal government of the present invention preferably corrects the object and the spatial data based on the three-dimensional photographing information photographed for sale information possessed by the real estate broker.

Building modeling module of the present invention is a building modeling storage unit for storing a plurality of architectural modeling types; An earth condition determination unit guiding a model of a building or a landscape according to a condition in a specific land selected by the user; A building modeling unit modeling a building according to a guide by the land condition determination unit based on the architectural modeling type selected from the building modeling storage unit; A landscape modeling storage unit storing a plurality of landscape modeling types; Landscape modeling unit for modeling the landscape according to the guide by the land condition determination unit based on the landscape modeling type selected from the landscape modeling storage unit; and Merging that merges the modeling results by the building modeling unit and the landscape modeling unit It is preferable to include a part.

The land condition determination unit of the present invention preferably guides the modeling of buildings and landscaping based on known conditions in the site.

It is preferable that the landscaping modeling unit of the present invention recommends a landscaping modeling type in consideration of the building modeling type by the building modeling unit, the environment surrounding the building, and the known conditions in the site.

In the AR and VR implementation model of the present invention, it is preferable that the building and landscape modeling data by the building modeling module is implemented as AR and VR data according to time.

According to the AR and VR building modeling system based on spatial data according to the earth condition according to the present invention, the building modeling based on the spatial data is implemented and implemented by providing the AR and VR, so that the user can preview the building of the desired form in advance. Construction can be confirmed, and through the organic information exchange with the real estate brokers and builders there is an advantage that can be quickly and effectively construct a building.

1 is a block diagram showing the relationship between users using the spatial data-based AR and VR building modeling system according to the earth condition according to the present invention.
Figure 2 is a block diagram showing a preferred embodiment of a spatial data based AR and VR building modeling system according to the earth conditions according to the present invention.
Figure 3 is a block diagram showing the state correction and correction of the target object by the spatial data based AR and VR building modeling system according to the earth condition according to the present invention.
Figure 4 is a block diagram showing a state of modeling the building and the landscape by the spatial data based AR and VR building modeling system according to the earth condition according to the present invention.
5 is a block diagram showing a state of configuring the AR and VR by the spatial data-based AR and VR building modeling system according to the earth condition according to the present invention.
6A to 6J are display screens sequentially showing a state of using an AR and VR building modeling system based on spatial data according to the earth condition according to the present invention.

Description of the present invention is only an embodiment for structural or functional description, the scope of the present invention should not be construed as limited by the embodiments described in the text. That is, since the embodiments may be variously modified and may have various forms, the scope of the present invention should be understood to include equivalents capable of realizing the technical idea. In addition, the objects or effects presented in the present invention does not mean that a specific embodiment should include all or only such effects, the scope of the present invention should not be understood as being limited thereby.

On the other hand, the meaning of the terms described in the present application should be understood as follows.

Terms such as "first" and "second" are intended to distinguish one component from another component, and the scope of rights should not be limited by these terms. For example, the first component may be named a second component, and similarly, the second component may also be named a first component.

When a component is referred to as being "connected" to another component, it should be understood that there may be other components in between, although it may be directly connected to the other component. On the other hand, when a component is referred to as being "directly connected" to another component, it should be understood that there is no other component in between. On the other hand, other expressions describing the relationship between the components, such as "between" and "immediately between" or "neighboring to" and "directly neighboring to", should be interpreted as well.

Singular expressions should be understood to include plural expressions unless the context clearly indicates otherwise, and terms such as "comprise" or "have" refer to a feature, number, step, operation, component, part, or feature thereof. It is to be understood that the combination is intended to be present and does not exclude in advance the possibility of the presence or addition of one or more other features or numbers, steps, operations, components, parts or combinations thereof.

In each step, an identification code (e.g., a, b, c, etc.) is used for convenience of description, and the identification code does not describe the order of the steps, and each step clearly indicates a specific order in context. Unless stated otherwise, they may occur out of the order noted. That is, each step may occur in the same order as specified, may be performed substantially simultaneously, or may be performed in the reverse order.

The present invention can be embodied as computer readable code on a computer readable recording medium, and the computer readable recording medium includes all kinds of recording devices in which data can be read by a computer system. . Examples of computer-readable recording media include ROM, RAM, CD-ROM, magnetic tape, floppy disk, optical data storage device, and the like, and are also implemented in the form of a carrier wave (for example, transmission over the Internet). It also includes. The computer readable recording medium can also be distributed over network coupled computer systems so that the computer readable code is stored and executed in a distributed fashion.

All terms used herein have the same meaning as commonly understood by one of ordinary skill in the art unless otherwise defined. Generally, the terms defined in the dictionary used are to be interpreted to coincide with the meanings in the context of the related art, and should not be interpreted as having ideal or excessively formal meanings unless clearly defined in the present application.

1 and 2 show the use structure and overall configuration diagram of the AR and VR building modeling system based on spatial data according to the land condition according to the present invention, respectively.

The AR and VR building modeling system based on spatial data according to the ground conditions according to the present invention models the building desired by the owner using the spatial data as a 3D image and implements it as AR (Augmented Reality) and VR (Virtual Reality). It provides a system that can provide a variety of construction information related to the construction of the building in real time from the contractor, while supporting the decision making by sharing it with the real estate agent.

As shown in FIG. 1, the building modeling system according to the present invention obtains information on a site site desired by a building owner using spatial data, particularly spatial data provided as public data through a network, such as V World. By modeling the building of the style that the owner wants on the site site, the owner can check the form and construction cost of the building in advance, and the owner and the real estate broker can support the mutual decision-making through the modeled building. have.

First, the landlord can select the site to be constructed and deliver all the requirements for the construction to the system and provide necessary expenses and financial matters for the construction. In addition, the building modeling system according to the present invention may provide AR-VRs of expected building modeling results in the site and may provide information on construction costs and related contractors derived according to the building type desired by the owner.

The real estate agent prioritizes the bidding of the owner of a building that wants to sell the site by providing the building modeling system with current photographing information about the site taken using a three-dimensional imaging device such as a drone or 360 imaging device. Can be given. In addition, the real estate broker can check the information on the real estate sale requirements from the owner and provide land for sale that meets the relevant requirements to support the owner to select the expected land. The period can be provided from the contractor and delivered to the owner.

The contractor provides the building modeling system with information on the projected cost and construction period through the site information and the building style received from the landlord or the real estate agent, preferably the real estate agent, and the construction company chooses the construction work. Will be constructed.

Figure 2 shows the overall configuration of the spatial data based AR and VR building modeling system according to the earth conditions according to the present invention. Building modeling system of the present invention is a spatial data processing module for extracting the site information and location information required by the user from the spatial data by the public data, etc. and building the site information of the present through the three-dimensional shooting information of the present on the site ( 100); An architectural modeling module 200 for modeling the building and the surrounding landscape in three dimensions based on the land condition according to the building style required by the user based on the land information by the spatial data processing module 100; It includes AR and VR implementation module 300 for providing the content by implementing the three-dimensional modeling information generated by the architectural modeling module 200 in AR to VR.

The spatial data processing module 100 includes a spatial data extraction unit 110 for extracting and processing spatial data through public data and the like; An object matching unit 120 matching an object included in the extracted spatial data with position data; A current correcting unit 130 for matching the 3D photographing information to the position data and the spatial data information derived through object matching and correcting the position data and the spatial data in the present state; A target object corrector 140 for removing and modifying a demolition target object from spatial data corrected at present; A land information display unit 150 for displaying the position data and the spatial data information corrected by the prefectural security unit 130 and the target object corrector 140; And a three-dimensional photographing database unit 160 in which three-dimensional photographing information is stored.

The spatial data extracting unit 110 extracts object-related information such as site location information and buildings desired by the user through public data, GIS and GPS information, and digital map information, and modifies them into compatible metadata. The spatial data extraction unit 110 preferably extracts spatial data from publicly available public data such as V World.

The object matching unit 120 matches the object included in the extracted spatial data with the position data. The object matching unit 120 may separate the object from the spatial data by matching the object included in the spatial data with the position data and set it as an individual element so that subsequent correction or deletion may be possible.

The current correction unit 130 may correct the position data and the spatial data information of the present state by matching the 3D photographing information of the present state based on the extracted spatial data and the position data.

The 3D photographing information is configured by registering recent photographing information in the system using a drone or a 360 camera for a property handled by a real estate agent, and is stored in the 3D photographing database unit 160.

The current municipal government 130 extracts the feature points obtained from the 3D photographing information, converts the extracted feature points into polygon morphemes, and corrects the spatial data by matching the converted coordinates and polygon data with the 3D photographing information. It is configured to.

The target object corrector 140 removes an object (demolition target object) in the site desired by the user from the spatial data of the current state corrected by the current security unit 130 to form a site condition in which the modeling of the building is possible.

3 illustrates a process of correcting spatial data by the current security unit 130 and the target object corrector 140.

First, a feature point is extracted from the 3D photographing information stored in the 3D photographing database unit 160, and coordinates are applied to the feature point to be converted into polygon morphemes. The polygon morphemes correspond to the distinguishing elements representing the shapes and features of the object, and the polygon morphemes and the feature point coordinates may be corrected with the spatial data in the present state by matching the objects in the spatial data and the position data.

That is, since the spatial data stored in the existing public data is information that has been photographed or measured in the past, the current municipal government 130 uses the three-dimensional photographing information photographed by the real estate agent to confirm the spatial data changed over time. By correcting with the spatial data of the present state.

As described above, when the correcting operation of the spatial data is completed by the current security unit 130, the target object corrector 140 removes an object located in a desired site of the user, that is, a building, and corrects the site condition in a known state.

Through the corrective work by the current municipal government 130 and the target object correction unit 140, the building modeling of the rear end can be performed more accurately.

When the spatial data and the position data corrected by the spatial data processing module 100 are extracted as described above, the building modeling module 200 performs virtual building modeling based on the corresponding data.

The architectural modeling module 200 includes a building modeling storage unit 210 which stores a plurality of building modeling types; A ground condition determination unit 220 for modeling a building according to a known condition in a specific site selected by the user; A building modeling unit 230 for modeling a building according to a building type stored in the building modeling storage unit 210 based on the spatial data and the position data corrected by the spatial data processing module 100; A landscape modeling storage unit 240 storing a plurality of landscape modeling types; A landscape modeling unit 250 for performing landscape modeling according to building modeling and land conditions; Merger unit 260 for merging the building modeling and landscape modeling.

The architectural modeling storage unit 210 stores a plurality of building modeling types, and selects 3 to 4 optimal building modeling types in consideration of the general requirements, land conditions, geographical characteristics, regional conditions, and surrounding characteristics of the owner. Recommended by.

Site condition determination unit 220 is for applying the known conditions in the site in positioning the building modeling selected by the user in the site. The site condition determination unit 220 applies the public notice conditions within the site in consideration of the ordinances of local governments prescribed by the Enforcement Decree of the Building Act according to the use area, the use area, and the use and size of the building according to the National Land Planning Act. do.

In more detail, when the building modeling type is settled in the site, the guide for the building modeling arrangement is applied according to the result determined by the land condition determination unit 220 by automatically applying the separation distance from the road, the occlusion rate, and the volume ratio. can do.

The building modeling unit 230 may model the building selected by the user in three dimensions based on the corrected spatial data and the position data, but may be modeled in consideration of the earth condition determined by the earth condition determination unit 220.

The building modeling unit 230 may be configured to model a 3D model of a building selected by a user, and to individually change or select each building component of the 3D modeling, that is, a building component such as a roof, a wall, or a column. .

The landscape modeling storage unit 240 may also store a plurality of landscape modeling and recommend landscape modeling according to a user selection condition. The landscape modeling unit 250 may be modeled in three dimensions based on a pre-selected landscape type. The landscaping modeling may be performed according to a known condition on the site determined by the condition determination unit 220.

The landscaping modeling unit 250 may recommend the species and number included in the landscaping according to the building modeling type, and calculate the estimated landscaping ratio according to the landscaping species in real time.

The landscaping modeling unit 250 may recommend a landscaping plan according to the steering and surrounding building positions, and may recommend a landscaping plan in consideration of the arrangement of eyes with adjacent buildings over time.

In addition, it is possible to recommend an optimal landscaping arrangement in consideration of landscaping costs by reflecting well-known conditions on the site (for example, occlusion rate, volume ratio, etc.) that are likely to change in the future.

As shown in FIG. 4, the merger 250 merges the results modeled by the building modeling unit 230 and the landscape modeling unit 250 to complete the final 3D building modeling. When the 3D building modeling is completed, the relevant information can be delivered to the builder to receive related construction information.

When the building and landscape modeling is completed by the architectural modeling module 200, the AR and VR implementation model 300 implements AR and VR contents based on the 3D modeling information. The AR and VR implementation model 300 includes a data compression and objectization unit 310 for providing object information by compressing and subjecting the three-dimensional modeling information finally derived by the architectural modeling module 200 to separate objects; An AR and VR implementation unit 320 for implementing the objectized three-dimensional modeling data into AR and VR contents for each hour according to a change in time; A content provider 330 for providing implemented AR and VR content to a user; And an encryption unit 340 for encrypting and storing 3D modeling information and AR and VR data.

Since the data compression and objectization unit 310 has a large capacity of general 3D modeling data, the data compression and objectization unit 310 divides and compresses the 3D modeling data for each object to reduce the size of the 3D modeling data and to objectize the user.

The AR and VR implementation unit 310 is to enable the user to realistically check the modeled building information and the landscape information by implementing the compressed and objectized 3D data into AR and VR content.

As shown in FIG. 5, the AR and VR implementation unit 310 can look at internal and external rendering changes with time. The change in time may mean a change in conditions according to a change in time or a change in seasons per day, or may mean a change in conditions according to a long time change, that is, a unit of a year or a ten-year unit.

For example, it is possible to know the change in sunshine inside and outside according to the change of time per day, which may represent the sunshine change in consideration of the layout of surrounding buildings or the landscape. In addition, the long-term change in time may be due to changes in the sunshine according to the vegetation growth or changes in the line of sight with surrounding buildings when the vegetation due to the landscape layout is grown for a long time.

In this way, the user can experience various changes in the surrounding environment according to the time change, so that it can be used as a decision data such as a land contract with a real estate broker or a building construction contract.

Hereinafter will be described the state of use of the spatial data based AR and VR building modeling system according to the earth conditions according to the present invention.

A user can access a building modeling system according to the present invention using a PC terminal or a mobile terminal using a network, and a user (architect), a real estate agent, or a builder based on the building modeling system according to the present invention It can send and receive related information about construction.

6A and 6B, when a user or the like selects a specific site to construct a building, the spatial data processing module 100 extracts the spatial data and the position data from the public data, etc. The update is performed with the three-dimensional information of the current state. As illustrated in FIG. 6C, the target object corrector 140 removes an object in the target site to form a site condition in which a building modeling is possible.

When the spatial data and the position data corrected by the spatial data processing module 100 are extracted, the building modeling storage unit 210 displays a plurality of building modeling types, and a specific building modeling type is selected as shown in FIG. 6D. As shown in FIG. 6E, an optimal building modeling type is selected and recommended in consideration of related conditions.

In addition, the land condition determination unit 220 guides the optimal building modeling arrangement in consideration of known conditions in the site as shown in FIG. 6F in positioning the building modeling selected by the user in the site.

The building modeling unit 230 models and presents the building in three dimensions according to the building type selected by the user, and as shown in FIGS. 6H and 6I, the user individually selects each building component of the three-dimensional modeling or You can change the three-dimensional modeling by changing.

Similarly, the user may select according to the landscape modeling type stored in the landscape modeling storage unit 240 as described above, and the landscape modeling may be performed in three dimensions in consideration of known conditions in the site according to the selected landscape type.

When the building and landscape modeling is completed by the architectural modeling module 200, as illustrated in FIG. 6J, the AR and VR implementation model 300 implements the AR and VR contents based on the 3D modeling information.

Building modeling based on spatial data as described above, and implemented by providing them in AR and VR, users can construct and confirm the desired type of building in advance, and quickly through organic information exchange with real estate brokers and builders We can construct effective building.

Although described above with reference to the preferred embodiment of the present application, those skilled in the art various modifications and changes to the present application without departing from the spirit and scope of the invention described in the claims below I can understand that you can.

100: spatial data processing module 200: architectural modeling module
300: AR and VR implementation module

Claims (7)

A spatial data processing module extracting specific spatial data and position data from the spatial data and matching the three-dimensional photographing information of the present to process the spatial data and the position data;
An architectural modeling module for modeling a building in three dimensions by reflecting site information according to a user's request based on the spatial data and the position data by the spatial data processing module; and
It includes an AR and VR implementation module for implementing and providing the three-dimensional modeling information generated by the building modeling module as AR and VR data,
The spatial data processing module
A spatial data extraction unit for extracting and processing the spatial data;
An object matching unit for matching an object included in the spatial data extracted by the spatial data extraction unit with position data;
A current correcting unit for matching three-dimensional photographing information of the present state to the object and the spatial data matched by the object matching unit and correcting the object and the spatial data of the present state; And
A target object correction unit for removing and correcting the target object from the spatial data corrected by the current municipal government,
The prefectural government may correct the object and the spatial data based on the three-dimensional photographing information obtained by photographing the land for sale held by the real estate agent,
The architectural modeling module
A land condition determination unit that guides the modeling of the building or the landscape according to the conditions within the specific land selected by the user.
AR and VR building modeling system based on spatial data according to site conditions.
delete delete The method of claim 1,
The architectural modeling module
A building modeling storage unit storing a plurality of architectural modeling types;
A building modeling unit modeling a building according to a guide by the land condition determination unit based on the architectural modeling type selected from the building modeling storage unit;
A landscape modeling storage unit storing a plurality of landscape modeling types;
A landscaping modeling unit modeling a landscaping model according to the guide by the land condition determining unit based on the landscaping modeling type selected from the landscaping modeling storage unit; and
It includes a merging unit for merging the modeling results by the building modeling unit and the landscape modeling unit mutually
AR and VR building modeling system based on spatial data according to site conditions.
The method of claim 4, wherein
The land condition determination unit
To guide the modeling of buildings and landscapes
AR and VR building modeling system based on spatial data according to site conditions.
The method of claim 4, wherein
The landscape modeling unit
The landscaping modeling type is recommended in consideration of the building modeling type by the building modeling unit, the surrounding environment conditions, and the known conditions in the site.
AR and VR building modeling system based on spatial data according to site conditions.
The method of claim 1,
The AR and VR implementation module
Building and landscape modeling data by the building modeling module to implement the AR and VR data for each hour according to the change of time
AR and VR building modeling system based on spatial data according to site conditions.

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