KR100997212B1 - 3D geographical information system and method for generating 3D geographical information data in 3D geographical information system - Google Patents

Abstract

The present invention relates to a method for automatically generating three-dimensional geographic information data using two-dimensional geographic data and digital elevation data that are already built in a three-dimensional geographic information system. Set and store in advance, extract the three-dimensional absolute coordinates using the two-dimensional geographic information and the numerical elevation data, and apply the attribute information to the three-dimensional absolute coordinates to convert the two-dimensional geographic information data to three-dimensional geographic information By converting the data, and visualizing and editing the converted 3D geospatial data to generate the final 3D geospatial data, the 3D geospatial data of the ground and underground facilities can be automatically generated, thus existing 3D Reduce the cost of building geospatial data.

3D Geographic Information System (GIS), 3D Geographic Data, 2D Geographic Data, Numerical Elevation Data, Absolute Coordinates, Relative Coordinates, Terrain Height, Floors, Relative Depth.

Description

3D geographical information system and method for generating 3D geographical information data in 3D geographical information system}

The present invention relates to a 3D geographic information system, and more particularly, to a method for automatically generating 3D geographic data using 2D geographic data and digital elevation data pre-built in a 3D geographic information system.

As the imaging sector has gradually shifted from 2D to 3D (3D), the ripple effect of related fields is also rapidly growing, and the 3D application field is gradually diversified from the public sector, defense sector and general industry. It is becoming. One of these applications, the 3D Geographical Information (GI) software commercial market has been developed by segmentation by function, and the diversity and expertise of using geographic information is based on Geographical Information System (GIS) technology. Contributed to the creation of applications.

In general, a three-dimensional geographic information system (GIS) using the three-dimensional geographic information software is a geographic information system applying a three-dimensional modeling technology, constructing terrain and artificial facilities into three-dimensional information, and linked with geographic information systems and augmented reality technology System to store, process, process, and analyze spatial information.

Such a 3D geographic information system needs to construct 3D data, but the conventional 3D GIS system has a inconvenience in that the 3D data needs to be modeled in spite of the existing 2D data to construct the 3D geographic information.

In addition, the conventional 3D geographic information system is more expensive than the 2D data modeling when the 3D data modeling, 3D data construction using the latest surveying equipment, such as Mobile Mapping System (MMS), but also this It costs a lot. Moreover, the conventional 3D geographic information system has a disadvantage in that it is difficult to update information on underground facilities.

In order to solve the problems described above, the present invention uses a three-dimensional (2D) geographic information data and digital elevation model (DEM: Digital Elevation Model) in the three-dimensional geographic information system and the system Provides a method for generating data.

The three-dimensional geographic data generation method in the three-dimensional geographic information system for achieving the above object of the present invention comprises the steps of setting and storing the two-dimensional geographic information data and numerical elevation data in advance; Extracting three-dimensional absolute coordinates using the two-dimensional geographic information data and the numerical elevation data; Converting the two-dimensional geographic information data into three-dimensional geographic data by applying attribute information to the extracted three-dimensional absolute coordinates; And visualizing and editing the converted 3D geographic data to generate final 3D geographic data.

A three-dimensional geographic information system for achieving the objects of the present invention, the database for setting and storing the two-dimensional geographic information data and numerical elevation data in advance; An absolute coordinate extraction unit for extracting a three-dimensional absolute coordinate using the two-dimensional geographic information data and the numerical elevation data; A data converter converting the 2D geographic information data into 3D geographic data by applying attribute information to the 3D absolute coordinates; And a browser configured to visualize and edit the converted 3D geographic data to generate final 3D geographic data.

Accordingly, the present invention can automatically generate three-dimensional geographic data for ground and underground facilities using a three-dimensional geographic information system without using a separate surveying equipment by using the already constructed two-dimensional geographic data and numerical elevation data. This can reduce the cost of building existing three-dimensional geographic data.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, if it is determined that detailed descriptions of related known functions or configurations may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

1 is a diagram showing the structure of a three-dimensional geographic information system according to an embodiment of the present invention.

Referring to FIG. 1, the 3D geographic information system includes a database unit 110, an absolute coordinate extraction unit 120, a data converter 130, and a browser 140.

The database unit 110 stores two-dimensional (2D) geographic information data and numerical elevation data. The two-dimensional geographic information data may be divided into spatial information including X and Y and attribute information including general information such as the number of floors, depth, and building name. The numerical elevation data is a numerical model that expresses the terrain data of the topographical part in three dimensions except for buildings, trees, and artificial structures.

The absolute coordinate extraction unit 120 reads the two-dimensional geographic data and the numerical elevation data stored in the database 110, and the numerical elevation of the relative coordinates (X, Y) of the read two-dimensional geographic information data. The terrain height (Z) of the terrain data is detected by finding the terrain data of the data. The absolute coordinate extractor 120 extracts the three-dimensional absolute coordinates (X, Y, Z + H) by applying the detected terrain height (Z) to the relative coordinates (X, Y).

The data converter 130 applies two-dimensional geographic information by applying attribute information including general information such as building names to the spatial information which is three-dimensional absolute coordinates (X, Y, Z + H) extracted by the absolute coordinate extractor 120. Convert the information data into three-dimensional geographic information data.

The browser 140 visualizes the converted 3D geographic data, and confirms and edits the 3D geographic data through visualization to generate final 3D geographic data.

Next, a method for generating 3D geographic data in a 3D geographic information system having such a structure will be described in detail.

The method for generating three-dimensional geographic data is a process of extracting three-dimensional absolute coordinates using two-dimensional geographic data and numerical elevation data, and three-dimensional two-dimensional geographic data using extracted three-dimensional absolute coordinates. The process consists of converting into geospatial data and visualizing and editing the converted 3D geospatial data. Through these processes, the 3D geospatial information system is the final 3D geography that can realize the final 3D facilities similar to the real world. Generate information data.

With reference to the accompanying drawings, a method for generating 3D geographic data of the ground snow tongue according to the first embodiment in the 3D geographic information system through these processes will be described.

FIG. 2 is a diagram showing three-dimensional geographic data of ground facilities generated using two-dimensional geographic data and numerical elevation data according to the first embodiment of the present invention, and FIG. 3 is a first embodiment of the present invention. FIG. 3 is a diagram illustrating a process of converting 3D geographic data of ground facilities according to FIG.

2 and 3, the three-dimensional geographic information system is based on the relative coordinates (X, Y) 310 of the two-dimensional geographic data 210, that is, the elevation of the elevation data 220, that is, the terrain data ( 320 is extracted by bilinear interpolation, and the terrain height Z in which the facility is located is obtained from the extracted terrain data 320. Thereafter, the 3D geographic information system applies data on the number of layers (H) of the 2D geographic data 210 to the terrain height Z, and thus the 3D absolute coordinates X, Y, Z + corresponding to the spatial information. H) is extracted. Accordingly, it is possible to know the actual height according to the number of floors of the facility, and can be shaped by the number of floors as in the actual facility.

Then, as shown in FIG. 2, the 3D geographic information system applies the attribute information including the extracted 3D absolute coordinates (X, Y, Z + H) and general information of the facility including the building name. In operation 330, the two-dimensional geographic information data 210 is converted into three-dimensional geographic data 230. Thereafter, the 3D geographic information system visualizes and edits the 3D geographic data converted through the browser 140 to generate final 3D geographic data. That is, the three-dimensional geographic information system implements a three-dimensional facility similar to the real world by constructing a texture library of each general facility and applying it to each floor.

Next, a method for generating three-dimensional geographic information data according to the second embodiment in the three-dimensional geographic information system will be described with reference to the accompanying drawings.

4 is a diagram showing three-dimensional geographic information data of an underground facility generated using two-dimensional geographic data and numerical elevation data according to a second embodiment of the present invention, and FIG. 5 is a second embodiment of the present invention. Figure 3 shows the transformation of three-dimensional geographic data of underground facilities.

3 to 5, the 3D geographic information system uses the 2D geographic information data 410 and the numerical elevation data 420 stored in the database through the absolute coordinate extracting unit 120 for the underground facilities. Extract the world coordinates (X, Y, Z + U). Specifically, the three-dimensional geographic information system checks the relative coordinates (X, Y) 310 of the two-dimensional geographic information data 410, and the numerical elevation of the relative coordinates (X, Y) 310 The terrain data 320 of the data 420 is found to extract the terrain data 320, and the terrain height Z is obtained through the extracted terrain data 320.

Subsequently, as shown in FIG. 5, the 3D geographic information system applies an absolute depth (eg, 5 m underground with respect to the ground surface) U to the obtained terrain height Z, and thus an absolute depth Z +. U), and the three-dimensional absolute coordinates (X, Y, Z + U) are extracted by applying the relative coordinates (X, Y) to the converted absolute depth (Z + U). Thereafter, the 3D geographic information system converts the 2D geographic information data into the 3D geographic data 430 by applying attribute information to the extracted 3D absolute coordinates (X, Y, Z + U). Then, the 3D geographic information system visualizes underground facilities buried in relative depth in 3D, checks and edits the visualized 3D geographic data, and generates the final 3D geographic data. The facility can be implemented.

According to the exemplary embodiments of the present invention as described above, the facility may be implemented in a browser similar to the reality using the final 3D geographic data as shown in FIG. 6.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the scope of the following claims, but also by the equivalents of the claims.

1 is a diagram showing the structure of a three-dimensional geographic information system according to an embodiment of the present invention;

2 is a view showing three-dimensional geographic information data of ground facilities generated using two-dimensional geographic data and numerical elevation data according to the first embodiment of the present invention;

3 is a diagram illustrating a conversion process for 3D geographic data of a ground facility according to a first embodiment of the present invention;

4 is a view showing three-dimensional geographic data of an underground facility generated by using two-dimensional geographic data and numerical elevation data according to a second embodiment of the present invention;

FIG. 5 is a diagram illustrating transformation of three-dimensional geographic data of an underground facility according to a second embodiment of the present invention; FIG.

6 is a diagram illustrating an example of implementing a facility in a browser using 3D geographic data according to embodiments of the present invention.

Claims (8)

Setting and storing two-dimensional geographic information data and numerical elevation data in advance; The relative coordinates of the two-dimensional geographic information data are identified using the two-dimensional geographic information data and the numerical elevation data, the geographical data of the numerical elevation data with respect to the relative coordinates are extracted, and the terrain is determined through the terrain data. Obtaining a height, applying at least one of data on the number of floors of a preset facility and a relative depth at which the preset facility is buried, and applying at least one of the relative coordinates and the data and the relative depth on the number of floors Extracting 3D absolute coordinates using the terrain height; Converting the two-dimensional geographic information data into three-dimensional geographic data by applying attribute information to the extracted three-dimensional absolute coordinates; And And visualizing and editing the converted 3D geographic information data to generate final 3D geographic data. delete delete The method of claim 1, The two-dimensional geographic information data comprises three-dimensional geographic information comprising spatial information including the relative coordinates, attribute information including data on the number of floors or the relative depth and the general information about the facility in which the facility is buried. 3D geospatial data generation method in system. A database for presetting and storing two-dimensional geographic information data and numerical elevation data; Using the two-dimensional geographic information data and the numerical elevation data, the terrain height is obtained through the terrain data of the numerical elevation data with respect to the relative coordinates of the two-dimensional geographic information data, and to the number of floors of the facility preset to the obtained terrain height At least one of data and a relative depth at which a predetermined facility is buried, and an absolute three-dimensional absolute coordinate is extracted by using a terrain height to which at least one of the relative coordinate and the number of floors and the relative depth is applied. A coordinate extraction unit; A data converter converting the 2D geographic information data into 3D geographic data by applying attribute information to the 3D absolute coordinates; And And a browser configured to visualize and edit the converted 3D geographic data to generate final 3D geographic data. The method of claim 5, The database includes geographic data and the two-dimensional geographic information data comprising spatial information including the relative coordinates, attribute information including data on the number of floors or general information about the facility and the relative depth where the facility is buried. 3D geographic information system, characterized in that for storing the digital elevation data. delete delete

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