KR102057448B1 - a Three dimensional solid grid based geographic information system data conversion system - Google Patents

Abstract

Disclosed is a system for producing three-dimensional geographic information system data. The system for producing the three-dimensional geographic information system data according to an embodiment of the present invention comprises: a rule definition unit defining a rule for producing the three-dimensional geographic information system space data; a two-dimensional geographic information system data processing unit obtaining and parsing two-dimensional geographic information system data; a rule mapping unit mapping the two-dimensional geographic system data with the rule; a three-dimensional geographic information system space data conversion unit combining the two-dimensional geographic information system data, mapped with the rule, with an altitude value, extracted from a digital elevation model to produce three-dimensional geographic information system space data; a level by level grid producing unit dividing the globe according to a plurality of level by level grids to produce three-dimensional space grid data; a crossover operation unit performing a crossover operation for the three-dimensional geographic system space data and the three-dimensional space grid data; and a matching table producing unit producing a matching table between the three-dimensional geographic information system space data and the three-dimensional space grid data based on the crossover operation result of the crossover operation unit. The present invention easily manages and processes three-dimensional geographic information.

Description

Three dimensional solid grid based geographic information system data conversion system}

The present invention relates to a three-dimensional three-dimensional grid-based geographic information system data conversion system. More specifically, the present invention relates to a method and system for converting geographic information system data by fusing two-dimensional geographic information system data and a three-dimensional grid to facilitate processing and management.

According to the 'National Spatial Information Framework Act', “spatial information” refers to location information on natural or artificial objects in the space such as ground, underground, underwater, or water, and information related to spatial recognition and decision making. That is, the spatial information may be classified into terrestrial spatial information, marine spatial information, and aerial spatial information centering on the ground surface, which is the main living space of a person. The spatial information is produced and utilized by various government departments such as the Ministry of Land, Infrastructure and Transport, Ministry of Maritime Affairs and Fisheries, and Ministry of Defense, and thus provides spatial information from various systems.

Recently, the Ministry of Land, Infrastructure, and Transport's spatial information open platform provides three-dimensional spatial information. The data supports a LOD (level of details) 4,025m resolution, and was created as a three-dimensional precision stereoscopic and three-dimensional model of the facility in PLW software after multidirectional multi-camera shooting.

3D spatial information has the advantage of building the real world precisely, but there is a problem that it takes a lot of time and money, and it is expensive to construct 3D spatial information frequently every time a new building or facility is constructed. In addition, the large data size made it difficult to manage and use data in the past system and network environment.

Two-dimensional spatial information is a reduction of three-dimensional spatial information of the real world, such as general map information, etc. Two-dimensional spatial information is much less expensive to build and financial costs than three-dimensional spatial information, in the past 2 Since it could be used in many services with only dimensional spatial information, most government departments and local governments have built two-dimensional spatial information with a two-dimensional geometric model.

Therefore, 2D spatial information can be generated again through 3D spatial information. To expand 2D spatial information into 3D spatial information, a Z value is added to the 2D spatial information composed of {X, Y}. And expand it into a volumetric three-dimensional entity according to certain rules. This method is generally used when a 2D object is converted into a 3D object in a Geographic Information System (GIS) tool.

In this case, some of the spatial information constructed in two dimensions may have attribute information that can be expanded in three dimensions, or may be expanded in three dimensions by combining with other information.

The present invention collects information that can be expanded into 3D spatial information among open 2D spatial information that has already been constructed, merges it with attribute information, converts it into 3D spatial information, and converts it into stereoscopic boundary system information. An object of the present invention is to propose a method and system for converting three-dimensional grid data, which is simple and light in data size.

The system for producing three-dimensional geographic information system data according to an embodiment of the present invention, a rule definition unit for defining a rule for generating three-dimensional geographic information system data, two for obtaining and parsing two-dimensional geographic information system data A dimensional geographic information system data processing unit, a rule mapping unit that maps the 2 dimensional geographic information system data and the rule, a 3 dimensional geographic information system by combining the two-dimensional geographic information system data to which the rule is mapped and the altitude value extracted from the numerical elevation model A three-dimensional geographic data system for generating stereoscopic data; a three-dimensional data conversion unit for generating three-dimensional data; a grid for each level for generating three-dimensional three-dimensional grid data by dividing the entire globe into a plurality of grids for each level; On the basis of the cross operation unit for cross operation of the three-dimensional solid grid data and the result of the cross operation in the cross operation unit Group comprises three-dimensional geographical information system, three-dimensional data and the three-dimensional space lattice matching table generating unit for generating a matching table between data.

According to the system according to an embodiment of the present invention, it is possible to manage the whole country by three-dimensional gridization.

The system according to an embodiment of the present invention has an advantage that it is easy to manage and process 3D geographic information by having a relatively small data size as compared with the existing complex 3D spatial information size.

1 to 2 are flowcharts illustrating a method of generating three-dimensional stereoscopic grid data according to an embodiment of the present invention.
3 illustrates an example of a rule definition for generating three-dimensional geographic information system stereoscopic data for each item.
4 illustrates an example of defining a three-dimensional geographic information system three-dimensional data generation rule of the two-dimensional geographic information system data opened by the government department.
5 shows an example of the above-described two-dimensional geographic information system data.
6 shows an example of the above-mentioned numerical elevation model data.
FIG. 7 illustrates a process of superimposing analysis of planar coordinates and digital elevation model data of two-dimensional geographic information system data.
8 illustrates an example in which digital elevation model data is applied to two-dimensional geographic information system data.
9 is an example of converting a two-dimensional line into a two-dimensional polygon, and then converted to a three-dimensional polygon by applying a digital elevation model.
10 illustrates an example of converting two-dimensional geographic information system data into three-dimensional geographic data having a volume.
11 to 13 illustrate a three-dimensional lattice level definition process.
14 illustrates a portion of the results of creating a three-dimensional grid of the entire earth according to defined levels.
15 illustrates a cross-computation scenario of three-dimensional geographic information system stereoscopic data and three-dimensional stereoscopic grid data.
16 illustrates an example of visualizing data required or generated during a crossover operation.
17 shows an example of the above-described matching table.
18 is a block diagram illustrating a three-dimensional three-dimensional grid-based geographic information system data conversion system according to an embodiment of the present invention.

Hereinafter, with reference to the drawings will be described in detail a specific embodiment of the present invention. However, the spirit of the present invention is not limited to the following embodiments, and those skilled in the art who understand the spirit of the present invention can easily add, change, delete, or add other components that fall within the scope of the same spirit. It may be proposed, but this is also included within the scope of the present invention.

In the accompanying drawings, in order to easily express the spirit of the present invention, in describing the overall structure, minute parts may not be specifically described, and in describing the minute parts, the overall structure may not be specifically reflected. In addition, even if the specific parts, such as an installation position, differ, when the action is the same, the same name is given, and the convenience of understanding can be improved. When there are a plurality of identical configurations, only one configuration will be described, and the same description will be applied to other configurations, and the description thereof will be omitted.

1 to 2 are flowcharts illustrating a method of generating three-dimensional stereoscopic grid data according to an embodiment of the present invention.

The three-dimensional three-dimensional grid data generation system according to an embodiment of the present invention defines a rule for generating three-dimensional geographic information system (GIS) data (stereoscopic) for each item (S101). This will be described with reference to FIGS. 3 to 4.

3 illustrates an example of a rule definition for generating three-dimensional geographic information system stereoscopic data for each item.

The rule for generating three-dimensional geographic data in three-dimensional geographic information system refers to a rule for generating three-dimensional geographic data in three dimensions with volume by analyzing the characteristics of open two-dimensional geographic data. In general, most government departments, including the Ministry of Land, Infrastructure and Transport, produce and open two-dimensional geographic information system data. In the present invention, the two-dimensional geographic information system data is converted into three-dimensional geographic information system data. Suggest a method.

Here, the open 2D GIS data consists of an array of x, y coordinates, and the 3D GIS data consists of an array of x, y, z coordinates. The three-dimensional geographic information system stereoscopic data refers to three-dimensional geographic information system data having a volume.

As illustrated in (a), first, two-dimensional points represented by x and y may be given. In this case, if the radius is provided, the 3D geographic data generation system converts the 2D point into a circle. In addition, if the height is provided, the three-dimensional geographic data generation system converts the converted circle into a three-dimensional solid (three-dimensional cylinder).

In addition, as illustrated in (b), a two-dimensional line that can be represented by x and y may be given. In this case, if the width is provided, the 3D geographic data system converts the 2D line into a 2D rectangle. In addition, if the height is provided, the 3D geographic data generation system converts the transformed rectangle into a 3D solid (3D cube).

In other words, an item according to the first two-dimensional geographic information system data may be defined, and a rule for converting the two-dimensional geographic information system data into three-dimensional geographic information system stereoscopic data may be defined according to the item.

All objects created according to the above rules have the z value set to zero first. In other words, objects in the mountains and objects on the shore can both be on the same line, and the post-processing can adjust the z value according to the terrain.

4 illustrates an example of defining three-dimensional geographic information system three-dimensional data generation rule of two-dimensional geographic information system data opened by the government department. Specifically, the table illustrated in FIG. 4 is a table extracting a rule definition for a continuous numeric topography that can be converted into 3D geographic information system data among various definable rules.

As illustrated in FIG. 4, open two-dimensional geographic information system data (two-dimensional point or two-dimensional line or two-dimensional polygon) may vary for each spatial information. In addition, height and options may be defined for each spatial information.

As illustrated in FIG. 4, if there is a required value (for example, diameter) such as independent water data, the value is used as it is, but when there is no required value such as waterfall data, an appropriate value is used by default in advance. Can be.

Also, in the case of buildings, even if there is no required value (e.g. height), if the approximate height can be inferred (e.g. floors), the inferred computed value can be assigned and used by default (e.g. height by floor) Can be calculated as 3m).

Returning to FIG. 1 again, the three-dimensional three-dimensional grid-based geographic information system data conversion system receives a two-dimensional geographic information system data file (S102). Here, the 2D GIS data file refers to data modeled as a point / line / face / stereoscopic object of the real world according to a necessary purpose.

5 shows an example of the above-described two-dimensional geographic information system data.

As illustrated in FIG. 5, the two-dimensional geographic information system data may be represented as wells as points, rivers as lines, and lakes as faces.

1 again, the 3D three-dimensional grid-based GIS data conversion system parses the received 2D GIS data file (S103). In other words, the three-dimensional three-dimensional grid-based geographic information system data conversion system decomposes and parses the received two-dimensional data into data that can be understood by the computer.

The three-dimensional three-dimensional grid-based geographic information system data conversion system maps the rules defined in S101 according to the type of the input two-dimensional geographic information system data (S104). In other words, the three-dimensional three-dimensional grid-based geographic information system data conversion system maps a specific rule to each of the two-dimensional geographic information system data, combining data of the two-dimensional geographic data system and three-dimensional geographic information system stereo data conversion options You can create a set.

The 3D three-dimensional grid-based geographic information system data conversion system receives a digital elevation model (DEM) data file (S105). The digital elevation model refers to the surface model produced in the form of a grid using digital ground data.

The digital elevation model is a numerical model that represents the bare earth part of the real-world terrain information excluding buildings, trees, and artificial structures. It may refer to a file about terrain elevations, recorded at regular spatial intervals in the form of a grid equivalent to digital of elevation data on the terrain topography, organized by quadrilaterals.

6 shows an example of the above-mentioned numerical elevation model data.

As described above, the numerical elevation model means the elevation value of the terrain. Specifically, the digital elevation model divides the ground surface into grids and expresses colors differently according to height. As shown in the sample enlargement diagram of the numerical elevation model of FIG. 6, the ground surface is divided into a myriad of grids, and the areas divided by the grids may have different heights according to heights.

1 again, the 3D three-dimensional grid-based geographic information system data conversion system parses the received digital elevation model data file (S106). In detail, the 3D three-dimensional grid-based geographic information system data conversion system decomposes and parses the received digital elevation model data file into data that can be understood by a computer.

The three-dimensional three-dimensional grid-based geographic information system data conversion system analyzes the superposition of the plane coordinates and the digital elevation model data of the two-dimensional geographic information system data (S107). Since 2D GIS data do not have altitude values (z values), the z values must be matched to convert them into 3D GIS data. Therefore, the 3D three-dimensional grid-based geographic information system data conversion system analyzes the numerical elevation model data having the height value and the superposition in order to match the z-value with the two-dimensional geographic information system data.

FIG. 7 illustrates a process of superimposing analysis of planar coordinates and digital elevation model data of two-dimensional geographic information system data.

Digital elevation models can have z values in various forms (eg, slope, altitude, population). Accordingly, the three-dimensional three-dimensional grid-based geographic information system data transformation system analyzes the digital elevation model data that overlaps (matches) the plane coordinates of the two-dimensional geographic data system data before extracting the z value corresponding to the specific coordinate. .

The three-dimensional three-dimensional grid-based geographic information system data conversion system extracts the altitude value (z value) of the digital elevation model data overlapping the plane coordinates of the two-dimensional geographic information system data based on the analysis result (S108). In other words, the three-dimensional three-dimensional grid-based geographic information system data conversion system can extract the altitude value of the terrain located on the plane coordinates of the two-dimensional geographic information system data from the digital elevation model data through the overlapping analysis.

8 illustrates an example in which digital elevation model data is applied to two-dimensional geographic information system data.

FIG. 8A illustrates two-dimensional geographic information system data to which an elevation value is not applied. FIG. 8B illustrates an example of applying altitude to two-dimensional geographic data system through numerical elevation model superimposition analysis.

Referring back to FIG. 2, the three-dimensional three-dimensional grid-based geographic information system data conversion system converts the two-dimensional geographic information system data into three-dimensional geographic information system data by adding an altitude value to the plane coordinates of the two-dimensional geographic information system data. (S109).

9 is an example of converting a two-dimensional line into a two-dimensional polygon, and then converted to a three-dimensional polygon by applying a digital elevation model.

As described above with reference to FIG. 3, an object produced through the 2D geographic information system has a z value of zero. Therefore, in order to fit the real world, the three-dimensional three-dimensional grid-based geographic information system data conversion system assigns an altitude value to two-dimensional geographic information system data represented by x, y and displays three-dimensional geographic information system represented by x, y, z. To produce.

2, the three-dimensional three-dimensional grid-based geographic information system data conversion system converts the two-dimensional geographic information system data to three-dimensional geographic information system stereoscopic data (S110). In detail, the three-dimensional three-dimensional grid-based geographic information system data conversion system applies two-dimensional geographic information system data to the two-dimensional geographic information system data by applying the three-dimensional geographic data system conversion rules and elevation values according to the numerical elevation model superimposition analysis. Transform into volumetric 3D geographic information stereoscopic data.

10 illustrates an example of converting two-dimensional geographic information system data into three-dimensional geographic data having a volume.

As illustrated in FIG. 10, the three-dimensional three-dimensional grid-based geographic information system data transformation system applies a three-dimensional geographic information system data transformation rule (width and height) to a two-dimensional line to produce a three-dimensional three-dimensional object having a volume. And, by applying the altitude extracted from the digital elevation model to the generated three-dimensional three-dimensional object to produce three-dimensional geographic information system stereo data.

2, the 3D three-dimensional grid-based geographic information system data conversion system defines the level of the three-dimensional grid (S111). In other words, the three-dimensional three-dimensional grid-based geographic information system data conversion system may define the level of the three-dimensional grid to define the octree-based three-dimensional grid generation rules.

11 to 13 illustrate a three-dimensional lattice level definition process.

As illustrated in FIG. 11, in order to define a three-dimensional grid level, the three-dimensional three-dimensional grid-based GIS data conversion system first divides the ground surface into a plurality of grids based on an octree. The ground surface may be divided into a myriad of first level gratings, and some of the first level gratings may be divided into eight second level gratings as necessary. In addition, a portion of the second level grating may be divided into eight third level gratings as necessary.

As illustrated in FIG. 11, not all of the specific level gratings have lower level gratings, and even if they have a lower level grating, they do not have lower levels of the same depth.

As illustrated in FIG. 12, the highest level of the grating level may be set to 0 and may be set up to 20 levels. The twenty levels illustrated in FIG. 12 are one example, and the grid may be divided into more levels or less levels as needed.

As illustrated in FIG. 13, the highest zero level grid may be determined by dividing by 36 degrees with respect to the earth center. In conclusion, at level 0, the Earth's surface can be divided into 10 grids. On the other hand, although the shapes illustrated in Figures 11 to 12 are represented by a cube, the cube is actually a cube close to the trapezoidal shape.

2, the 3D grid-based GIS data transformation system defines a spatial range of the 3D grid to be generated (S112). In detail, the three-dimensional three-dimensional grid-based geographic information system data transformation system defines the entire spatial range (ground and underground) of the grid to be produced based on the average sea level.

The 3D three-dimensional grid-based geographic information system data conversion system defines a defined three-dimensional grid-based index generation rule (S113). In detail, the 3D three-dimensional grid-based geographic information system data conversion system can define a conversion rule between coordinates and grid identifiers (ID) using the plane coordinate system and altitude information. The three-dimensional three-dimensional grid-based geographic information system data conversion system may combine the coordinates and the altitude with the grid size to assign an identifier to the three-dimensional grid in a predetermined manner.

 On the contrary, the plane coordinates and the altitude of the three-dimensional grid can be obtained inversely according to a predetermined method by using the identifier of the specific three-dimensional grid.

The 3D three-dimensional grid-based geographic information system data conversion system generates a grid for each level through the steps S111 to S113 (S114). In other words, the three-dimensional three-dimensional grid-based GIS data transformation system defines three-dimensional grid levels, defines the spatial range of the three-dimensional grid, and provides index generation rules for each three-dimensional grid to divide the surface of the surface into many levels. You can create a grid. 14 illustrates a portion of the results of creating a three-dimensional grid of the entire earth according to defined levels.

The 3D stereoscopic grid-based geographic information system data conversion system cross-calculates the 3D geographical information system stereoscopic data generated in step S110 and the 3D stereoscopic grid data generated in step S114 (S115). In other words, the three-dimensional three-dimensional grid-based geographic information system data conversion system performs a cross operation for mapping the three-dimensional geographic information system stereoscopic data to the three-dimensional three-dimensional grid data divided mechanically the whole earth.

15 illustrates a cross-computation scenario of three-dimensional geographic information system stereoscopic data and three-dimensional stereoscopic grid data.

Here, A is three-dimensional geographic information system stereoscopic data, B may represent the three-dimensional three-dimensional grid data. The three-dimensional three-dimensional grid-based GIS data transformation system performs a cross operation except disjoint operation and returns true when two objects overlap each other. In the course of this crossover operation, the 3D geographic information system production system can find 3D stereoscopic grid data that overlaps with the 3D geographic data.

2, the 3D three-dimensional grid-based geographic information system data conversion system generates a matching table between the three-dimensional geographic information system stereoscopic data and the three-dimensional three-dimensional grid data (S116). Specifically, the 3D three-dimensional grid-based geographic information system data conversion system performs matching between the two data through the cross-operation between the three-dimensional geographic information system and the three-dimensional three-dimensional grid data, and tabulates them.

16 illustrates an example of visualizing data required or generated during a crossover operation.

The yellow grid illustrated in FIG. 16 is a 17-level three-dimensional three-dimensional grid for the entire earth, and the blue grid is three-dimensional geographic data generated from two-dimensional geographic data. The red grid is a 17-level three-dimensional grid that is matched by cross analysis between a yellow three-dimensional grid and a blue three-dimensional geographic information system.

17 shows an example of the above-described matching table.

The matching table may be generated by matching the three-dimensional geographic information system stereoscopic data and the three-dimensional three-dimensional grid data. As illustrated in FIG. 19, one or more three-dimensional (3D) geographic data may be matched with one or more three-dimensional (3D) grid data to generate a matching table. For example, there may be three-dimensional geographic information system stereoscopic data for each building, independent tree, and tunnel, and three different three-dimensional geographic information system three-dimensional data may be matched with one three-dimensional three-dimensional grid to generate a matching table. have.

As illustrated in FIG. 17, the 3D GIS stereoscopic data table may include an object identifier, and the 3D grating data table may include a grid identifier. Here, the object identifier is used to identify 3D GIS data and may indicate an item and a value for each item, which are expected in FIG. 4. The grid identifier may be an identifier for identifying any one of numerous grids that divide the entire globe.

As a result, the three-dimensional three-dimensional grid-based geographic information system data conversion system according to an embodiment of the present invention can produce a table in which the three-dimensional geographic information system and the three-dimensional three-dimensional grid matching. In other words, the three-dimensional three-dimensional grid-based geographic information system data conversion system divides the entire globe into three-dimensional three-dimensional grid, and the specific three-dimensional three-dimensional grid through the intersection operation between the specific three-dimensional three-dimensional grid and three-dimensional geographic information system stereo data And 3D geographic information can be matched.

Accordingly, the three-dimensional three-dimensional grid-based geographic information system data conversion system according to an embodiment of the present invention is capable of rendering three-dimensional geographic information at the data receiving side using only the three-dimensional geographic data system data table, matching table, and three-dimensional grid data table Bar, the amount of data to be handled is small, which is advantageous for data transmission and management. In addition, the data related to the geographic information is managed as a table, not rendered data, there is an advantage that it is easy to process in a suitable form according to the needs of the consumer.

18 is a block diagram illustrating a three-dimensional three-dimensional grid-based geographic information system data conversion system according to an embodiment of the present invention.

As shown in FIG. 18, the three-dimensional three-dimensional grid-based geographic information system data conversion system 100 according to an embodiment of the present invention includes a rule definition unit 110, a two-dimensional geographic information system data processing unit 120, and a ruler. Mapping unit 130, numerical elevation model data processing unit 140, three-dimensional geographic information system stereoscopic data conversion unit 150, grid for each level generation unit 160, cross operation unit 170 and matching table generation unit 180 It may include.

The rule definition unit 110 defines a rule for generating three-dimensional geographic data of the three-dimensional geographic information system for each item. Here, the item may be composed of open data and options, and the open data may have items of spatial information name, spatial information type and height in detail. Examples of the spatial information include waterfalls and independent trees. Examples of the spatial information type include two-dimensional points, two-dimensional lines, and two-dimensional polygons. The option may be related to a default value for inferring a value even when there is no value required for each spatial information or even if there is no value required.

The two-dimensional geographic information system data processor 120 acquires the two-dimensional geographic information system data and converts the acquired data into a computer-readable format. The two-dimensional geographic information system data may be two-dimensional geographic information system data opened by the ministry.

The rule mapping unit 130 maps the rules for generating two-dimensional geographic information system data and three-dimensional geographic information system stereoscopic data.

The digital elevation model data processor 140 obtains the digital elevation model data and converts the obtained data into a computer-readable format.

The 3D geographic information system stereoscopic data conversion unit 150 combines the 2D geographic information system data and the digital elevation model data to produce 3D geographic information system stereoscopic data. The three-dimensional geographic information system stereoscopic data conversion unit 150 analyzes the superposition of the two-dimensional geographic information system data and the digital elevation model data, and adds an altitude value to the two-dimensional geographic information system data according to the result of the superimposition analysis. Create information system data. Finally, by applying the rules mapped to the 3D GIS data, the 2D GIS data is finally converted into the 3D GIS data.

The grid generator 160 for each level divides the entire globe into a plurality of grids for each level, and defines an identifier for each grid. The grid generation unit for each level may generate the highest 0 level grid by dividing every 36 degrees from the center of the earth, and generate a lower level grid by dividing the 0 level grid based on the octree.

The intersection operator 170 cross-calculates three-dimensional geographic information system stereoscopic data and three-dimensional triangular grid data to add geographic information to the three-dimensional grid.

The matching table generation unit 180 generates a matching table between three-dimensional geographic information system stereoscopic data and three-dimensional three-dimensional grid data based on the result of the cross operation by the cross operation unit 170. The generated matching table can then be used to utilize the three-dimensional solid grid. For example, when specific geographic information is requested, only an identifier and a matching table of the 3D three-dimensional grid may be delivered, and the geographic information may be rendered based on the identifier and the matching table received from the receiver. In other words, when delivering the geographic information, it is not necessary to transmit the entire information, and the 3D geographic information can be rendered on the receiving side only by passing the identifier and matching table of the 3D solid grid that can be implemented with the minimum capacity.

The present invention described above can be embodied as computer readable codes on a medium in which a program is recorded. The computer-readable medium includes all kinds of recording devices in which data that can be read by a computer system is stored. Examples of computer-readable media include hard disk drives (HDDs), solid state disks (SSDs), silicon disk drives (SDDs), ROMs, RAMs, CD-ROMs, magnetic tapes, floppy disks, optical data storage devices, and the like. This also includes implementations in the form of carrier waves (eg, transmission over the Internet).

The above detailed description should not be construed as limiting in all respects but should be considered as illustrative. The scope of the present invention should be determined by reasonable interpretation of the appended claims, and all changes within the equivalent scope of the present invention are included in the scope of the present invention.

Claims (7)

Defining a rule for generating three-dimensional geographic information system stereoscopic data for each item;
Obtaining two-dimensional geographic information system data;
Mapping the rule defined for each item to the two-dimensional geographic information system data and adding an elevation value to generate three-dimensional geographic data three-dimensional data;
Obtaining three-dimensional solid grid data;
Cross-operating the three-dimensional solid grid data on the three-dimensional geographic information system stereoscopic data; And
Generating a matching table between the three-dimensional geographic information system stereoscopic data and the three-dimensional stereoscopic grid data based on the cross-operation result;
The three-dimensional geographic information system stereoscopic data includes an object identifier,
The three-dimensional solid grid data includes a grid identifier,
The matching table includes a matched object identifier and a grid identifier.
3D geographic information system stereoscopic data production method. The method of claim 1,
The three-dimensional three-dimensional grid data comprises a three-dimensional grid composed of a plurality of levels for dividing the entire earth,
The three-dimensional grid is identified by an identifier for each grid
3D geographic information system stereoscopic data production method. The method of claim 2,
The three-dimensional grid includes a zero-level top grid that divides the entire earth by 36 degrees from the center of the earth,
It includes a plurality of levels of three-dimensional grid generated by octree-based partitioning the zero-level top grid
3D geographic information system stereoscopic data production method. The method of claim 1,
The altitude value is,
The value extracted as a result of the overlapping analysis between the digital elevation model data and the 2D geographic plane coordinates
3D geographic information system stereoscopic data production method. delete The method of claim 1,
The matching table includes one or more object identifiers matched to one grid identifier.
3D geographic information system stereoscopic data production method. A rule definition unit defining rules for generating three-dimensional geographic information system stereoscopic data;
A two-dimensional geographic information system data processing unit for acquiring and parsing two-dimensional geographic information system data;
A rule mapping unit for mapping the 2D geographic information system data and the rule;
A three-dimensional geographic information system stereoscopic data conversion unit for producing three-dimensional geographic information system stereoscopic data by combining the two-dimensional geographic information system data to which the rule is mapped and the altitude value extracted from the digital elevation model;
A lattice generator for each level for generating three-dimensional three-dimensional lattice data by dividing the entire globe into a plurality of lattices for each level;
A cross-operation unit which cross-operates the three-dimensional geographic information system stereoscopic data and the three-dimensional stereoscopic grid data; And
A matching table generator for generating a matching table between the three-dimensional geographic information system stereoscopic data and the three-dimensional three-dimensional lattice data based on the result of the intersection operation in the cross-operating unit;
The three-dimensional geographic information system stereoscopic data includes an object identifier,
The three-dimensional solid grid data includes a grid identifier,
The matching table includes a matched object identifier and a grid identifier.
3D three-dimensional grid based geographic information system data conversion system.

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