KR100514944B1 - Method For Servicing Order And Search Of The Geographic Information Data Using Internet - Google Patents

Abstract

The present invention order search of geographic information data using the Internet to improve geographic information analysis ability by providing an order search and service to integrate and provide each geographic data that is produced, managed and utilized in various forms using the Internet It relates to a service method.

According to an embodiment of the present invention, an order retrieval service method for geographic information data using the Internet includes accessing a data server to which a geographic information database is connected using the Internet, and searching a target region area in a geographic information search window displayed by the server connection. And selecting the target region to be searched by the user by setting the XY coordinate system on the screen of the searched target region, and displaying the current state of the geospatial data for the geographic region selected by the user on the screen by the geographic information database. Displaying, setting a data type and a demonstration method that a user wants to find according to the current geographic data status, demonstrating simple or superimposed geospatial data by the set data type and demonstration method, and demonstrating Of the geospatial data that the user wants to find Determining the beam data and purchasing the determined geospatial data.

Description

Method for Servicing Order And Search Of The Geographic Information Data Using Internet}

The present invention relates to a geographic information order search service method, in particular, it is possible to improve geographic information analysis ability by order search and service to integrate and provide each geographic data produced, managed and utilized in various forms using the Internet. The present invention relates to an order retrieval service method of geographic information data using the Internet.

In line with the development of the information industry, the importance of geospatial data on the earth's surface is increasing. In particular, GPS (Global Positioning System), LBS (Location Based Service), CNS (Car Navigation System), RS (Remote Sensing), GIS (Geographic Information System; Geography) Information system) Various high-tech information industries require various geospatial data that meets its purpose, and there is a great demand for integrated utilization of such geospatial data.

Geographic information data currently used in the GIS field and its application fields can be classified into the following three types according to their physical form and expression method.

The first is a digital map in the form of a geometric vector as shown in Figure 1a, the second is a digital elevation model (DEM) for expressing topographic relief information as shown in Figure 1b, and finally the scanned paper map in Figure 1c Raster data consisting of pixel values such as aerial photographs and satellite images. Here, the height value representing the ups and downs in the DEM refers to a value due to mean sea level.

Most of spatial information data is displayed in the form of data classified into the above three types, and as the application fields of spatial information such as search, monitoring, and analysis are diversified and specialized, the demand of data for the same area is correlated with various products and data structures. It is occurring comprehensively without.

For the search and purchase of data with comprehensive topographical analysis, select the appropriate data considering the limits of error on the accumulation of digital maps, the spatial resolution of satellite and aerial photographs, and the precision of altitude information. The coordinate system, which is a promise of geographical location, must also coincide.

For example, a high-resolution satellite image (Raster) with 1m spatial resolution can be superimposed with a 1: 1000 to 1: 5000 digital map, but its superposition is meaningless with a small map below 1: 25000. Can be. The altitude data (DEM) also has various precisions, such as the resolution of 1m to 100m, and the same principle applies to the spatial resolution of digital maps, satellite data and aerial photographs to be used in conjunction with the altitude data. In this case, the spatial resolution of satellite image data is determined according to the type of image products. As a result, materials that can be used as actual geographic information data are different from each other in terms of production method, data structure, purchasing procedure, and sales form, which leads to a lot of difficulties in purchasing and using integrated data in the same region.

If a digital map is purchased to produce and analyze topographical relief information and to be used by using satellite image data of the same area, the user must first purchase a digital map. In this case, if a digital map is a map with information produced in a three-dimensional form, it is necessary to produce elevation data such as a digital elevation model (DEM) and a triangular irregular network (TIN) using specialized software. In addition, if the digital map has only two-dimensional information, the user should purchase the desired altitude information data in consideration of the scale of the digital map and use it after processing through professional correction software. If you want to superimpose raster data such as satellite images and aerial photographs, you have to go through cumbersome and complicated preprocessing process that requires you to purchase satellite data and make corrections through professional expensive correction software to have the same coordinates as digital map.

Only through the above process, integrated analysis and utilization using the three types of geospatial data for a target area is possible. This is because each data has a different production method and acquisition method. That is, the acquisition of some data may not be guaranteed due to the problem of purchasing satellite data, altitude data, and digital map separately. There are disadvantages. Due to such a realistic problem, it takes a lot of time and manpower, resulting in cost wastage.

In addition, when looking at the current state of the country and foreign countries, geographic information data is ordered and sold online, that is, on the Internet. However, satellite image data and aerial photograph data of appropriate spatial resolution that can be used by accumulating and overlapping digital maps for the target area that the user wants to purchase, and altitude data that can be superimposed with the satellite data and aerial photograph data are integrated and integrated. There is no service that enables search and purchase.

Accordingly, an object of the present invention is to increase the availability of geospatial data sold in various forms by maintaining the same area, similar precision and accuracy, and to provide an integrated search and service for data that may have interoperability. The present invention provides an order retrieval service method of used geographic information data.

Another object of the present invention is to provide an order retrieval service method of geospatial data using the Internet that enables buyers and users of information to search for a large amount of spatial information about a target region through geospatial data provided in various forms. have.

Still another object of the present invention is to provide a method for searching an order of geographic information data using the Internet, which provides a terrain analysis function of a target area in real time through the Internet.

In order to achieve the above objects, an order retrieval service method for geographic information data using the Internet according to the present invention comprises the steps of accessing a data server to which a geographic information database is connected using the Internet, and a geographic information search window displayed by a server connection. Searching a target region area in the; and selecting a target region region to be searched by the user by setting the XY coordinate system on the screen of the searched target region; and displaying the current state of the geographic information data on the geographic region selected by the user. Displaying on a screen by a base, setting a data type and a demonstration method that a user wants to find according to the current state of geographic data, and simply or superimposed geospatial data by the set data type and demonstration method. Demonstrating the geographic tablet; Determining geographic data that the user wants to find among the beam data and purchasing the determined geographic data.

In the present invention, the search for the target area area includes a first search method for inputting administrative name and terrain / feature name, and function keys such as zooming / reducing / moving a map screen displayed on the screen, keyboard and mouse operation. It is characterized in that performed by the second search method.

Displaying the current state of geospatial data on the screen in the present invention includes displaying geospatial data corresponding to an area selected by a user and retained in the geospatial database in a geometric form; The geometric shapes are displayed in different colors in order to determine whether the polygons and the polygons are shaded in the polygon, and to determine whether the altitude information (DEM), digital maps, satellite image data, and aerial photograph data are retained.

In the present invention, the setting of a data type and a demonstration method to be displayed by the user may include setting a two-dimensional or three-dimensional demonstration method, and setting geospatial data types to be overlapped by the demonstration method. It includes; The data format for representing geographic information data to be superimposed in the two-dimensional method is a digital map, an elevation data (DEM), or a map using satellite data. The three-dimensional geographic data demonstration method has a mesh shape, A grid form that reads altitude differences by substituting the same color value for pixels with the same altitude value, and a TIN (Triangular Irregular Network) form for demonstrating the altitude information by vector information. It is characterized by one.

Each demonstration method of the three-dimensional geographic data of the present invention further includes the step of demonstrating additional information according to the geographic data; The step of demonstrating additional information in the mesh form includes shading the mesh form geographic data with a specific color value to increase reading of the ups and downs, and texture mapping using the retrieved high resolution satellite image and aerial image. (Texture Mapping), and the step of demonstrating the additional information in the grid form, the user displaying the selected altitude value in one pixel on the screen using an input device such as a mouse and the terrain of the path Computing a cross section for determining the undulation and altitude value, and demonstrating the additional information in the TIN form is characterized in that it comprises the step of reading the shape of the longitudinal section as the height value.

Other objects and features of the present invention in addition to the above objects will become apparent from the description of the embodiments with reference to the accompanying drawings.

Hereinafter, exemplary embodiments of the present invention will be described with reference to FIGS. 2 to 15.

2 is a diagram illustrating an order search service method of geographic information data using the Internet according to an embodiment of the present invention.

Referring to FIG. 2, an order retrieval service method of geospatial data using the Internet according to an embodiment of the present invention allows a user to perform geographic order service for each single or integrated geospatial data search having various structural forms. An information data server 6, a database 10 in which geospatial data is stored in various structural forms, and a data controller 8 for changing and controlling geospatial data in the geographic data data server 6. It includes.

The user 2 connects to the geographic information data server 6 via the Internet 4. At this time, the geographic information data server 6 displays menus related to the map information on the user's 2 personal computer or personal digital assistant (PDA).

The database 10 stores various types of geographic information data for each region of Korea. That is, the database 10 is a digital map of a vector form consisting of geometric shapes of a corresponding area, a digital elevation model (DEM) for representing topographical relief information, and pixels such as scanned paper maps, aerial photographs, and satellite images. Raster data and so on made up of values are stored.

The user 2 accesses the geographic information data server 6 via the Internet 4, and then searches and selects a region he / she wants to find by using an input device such as a keyboard and a mouse. The current state of the geospatial data in a variety of two-dimensional or three-dimensional form for the selected area is displayed in a polygonal and shading form on a personal computer or PDA connected to the Internet through the database 10. Here, the polygon and the shading shape may mean the type of geographic data according to the color and shape. In addition, the user 2 selects data and data types to be demonstrated with respect to the geographic information data status. In this case, the user 2 may control various types of geographic information data by the data control unit 8 and then demonstrate the integrated form as shown in FIG. 3. After that, the user 2 decides whether to purchase the geographic information that he / she wants to find on the screen.

4 is a flowchart illustrating a method for searching an order of geographic data using the Internet according to an embodiment of the present invention.

Referring to FIG. 4, the method for order-search service of geospatial data using the Internet according to an embodiment of the present invention first connects to a geospatial data server 6 to which a database is connected using the Internet 4. S1) At this time, the geospatial data server 6 provides menus relating to the terminal of the user 2 to move to the area where the user 2 wants to search and purchase the geospatial data of the area that the user 2 simply wants to search or find. Display it.

The target area is searched in the geographic information search window as shown in FIG. 5 moved through step S1. (S2) At this time, the target area search is performed by inputting the administrative region name and the terrain / feature name as shown in FIG. S21) and searching through direct screen control (S22). The screen moves to the area to be searched by searching the target area.

The search (S21) by entering the administrative region name and the terrain / feature name is performed by directly inputting or designating a region name previously stored as shown in FIG. 7A. In addition, the search through the direct screen control (S22) is performed to specify the area to find the map screen displayed on the screen through a function key of zoom in / zoom out / move, as shown in Figure 7b.

On the map screen searched in step S2, the user selects a target area to be provided by the user (S3). At this time, the selected target area value is substituted into the XY coordinate system. The method for setting the target area by the user is divided into a method of directly inputting the screen using an auxiliary input means such as a mouse as shown in FIG. 8A and a method of inputting coordinate points of polygons constituting the corresponding area as shown in FIG. 8B. Lose. In this case, the area of the target area is mainly selected by rectangular shape. This destination region value is transmitted to a geospatial data server 6 in which elevation data, aerial photographs, satellite image data, and numerical map data are stored, and the geospatial data server 6 stores the database 8. The searcher calculates respective data information corresponding to the target area value input by the user.

In the step S3, the current state of the geographic information data for the geographic area selected by the user is displayed (S4). This displays the current state of the geographic information data corresponding to the area selected by the user in a geometric form on the screen. The geometric shape is displayed by shading the polygon or polygon, such as a rectangle as shown in FIG. At this time, the geometric shapes are displayed in different colors when shading the polygon or polygon. This makes it possible to comprehensively determine whether or not to hold altitude information (DEM), digital maps, satellite imagery data and aerial photographic data. Such various types of geospatial data are determined according to the user's selection.

In step S4, a data type and a presentation method are set according to the data of the demonstration part selected in step S4. In step S4, a two-dimensional method and a three-dimensional method may be selected according to the data type of the demonstration part selected by the user.

According to the selection in step S5, two-dimensional map information data is demonstrated. (S6) In this case, the two-dimensional method refers to a two-dimensional planar form. The two-dimensional representation may include a superimposed representation of a map by digital map and altitude data (DEM) as shown in FIG. 10A, a superimposed representation of a map by satellite data as shown in FIG. 10B, and the like. Through this superimposed expression function, it is possible to visually grasp the accumulation / coordinate / accuracy / information amount of digital map, additional information judgment such as resolution / cloud of satellite image, and precision of altitude data. Through this superimposition expression function, the user can judge the geometric state of the digital map and the satellite image, whether to use the superimposition by determining the adequacy of the digital map scale and the satellite image resolution, and the correspondence of the digital map and the altitude data. By doing so, you can help users make purchasing decisions.

According to the selection in step S5, the map information data demonstration method of the 3D method is selected and demonstrated. (S7) The map information data demonstration method of the 3D method is a mesh form (S71), a grid as shown in FIG. (Grid) type (S72) and TIN (Triangular Irregular Network; irregular triangle network) type (S73) can be classified. In addition, when the map information data demonstration method is selected, additional geographic information data may be demonstrated according to the data demonstration method of each method (S8).

In detail, when the mesh form S71 is selected as the 3D map information data demonstration method, the geographic information data is demonstrated as shown in FIG. 12A. In addition, the mesh type demonstration method can change the direction, axis, etc. through the user's mouse and keyboard manipulation to demonstrate geographic information on the target area from various angles in three dimensions, and increase the reading of ups and downs. In order to express the effect of FIG. 12B, the user may shade (surface) a specific color value as shown in FIG. 12B or texture mapping as shown in FIG. 12C by using the retrieved high resolution satellite image and aerial image. . This additional function may be performed through a check or push function displayed on the screen.

Next, when the grid form S72 is selected as the 3D map information data demonstration method, the geographic information data is demonstrated as shown in FIG. 13. This grid-type map information data demonstration method looks virtually flat but provides 3D data information, and reads the altitude difference on a plane by substituting the same color value for a pixel having the same altitude value. To express it. Further, in the grid-type map information data demonstration method, the user may be provided with a selection altitude value of the pixel A on the screen as shown in FIG. 14A using an input device such as a mouse. This makes it possible to determine the altitude value of the actual area in pixels on the screen. In addition, the grid information map demonstration method includes a function of calculating a cross section as shown in FIG. 14B for a specific path such as "B". Through such a cross-section calculation function it is possible to determine the top and bottom of the route, altitude value.

Finally, if the TIN (irregular triangular network) form S73 is selected as the 3D map information data demonstration method, the geographic information data is demonstrated as shown in FIG. 15. The TIN-type map information data demonstrating method is for demonstrating the altitude information by vector information, which is generated by connecting three points having X, Y, and Z coordinate values by a triangular network. For this reason, the TIN-type map information data demonstration method provides the effect of reading information on the direction of the inclination, the X-axis inclination, and the Y-axis inclination to the user, and at the same time, the numerical value of the pixel to be purchased. You can check the value yourself. In addition, the TIN type map information data demonstration method also provides a function of reading the shape of the longitudinal section as the height value.

In the steps S6 and S7 (including S8), the user determines the geospatial data that the user wants to search / purchase among the geospatial data displayed on the screen. (S9) This is a form that the user wants to find through the steps S6 and S7 (including S8). The geographic data of the is determined.

When the geospatial data type is determined in step S9, the user purchases the determined geospatial data. (S10) At this time, the price of the geospatial data purchase is determined by determining the geospatial data in step S9. The price of the data is calculated in proportion to the calculated area area of the information data, and is added by the quantity and type of each geographic information data due to the superposition of the geographic data. When the purchase price is determined, the user receives the data through a payment process such as card payment, bank account deposit, etc. after the final purchase decision step of purchasing the product for the calculated price.

As described above, the order retrieval service method of geospatial data using the Internet according to the present invention can improve the capability of analyzing geospatial data when a user purchases and integrates each geospatial data having various structural forms. . This avoids the preprocessing step of integrating geospatial data of completely different characteristics and implements it in real time via the Internet, thereby reducing unnecessary manpower and time. In addition, it is possible to promote the utilization of geospatial data by providing interoperability between geospatial data.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the technical spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be defined by the claims.

1A to 1C are diagrams illustrating geospatial data classified according to physical forms and representations.

2 is a diagram illustrating an order search service method of geographic information data using the Internet according to an embodiment of the present invention.

3 is a view showing a demonstration concept to be displayed by the present invention.

4 is a flowchart illustrating a method for searching an order of geographic data using the Internet according to an embodiment of the present invention.

FIG. 5 is a diagram illustrating a geographic information search window connected to a map supply server in FIG. 4.

FIG. 6 is a diagram illustrating a target area search method of FIG. 4 in detail.

FIG. 7A is a diagram illustrating an example of searching by inputting an administrative region name and a terrain / feature name in FIG. 6.

FIG. 7B is a diagram illustrating a function key according to a search through direct screen control in FIG. 6.

FIG. 8A is a diagram illustrating a method of directly inputting on a screen in the method of setting a geographical search region of FIG. 4.

8B is a diagram illustrating a method of inputting coordinate points of a polygon constituting a corresponding area in the method of setting a geographical search area of FIG. 4.

9 is a diagram illustrating an example of a geographic information data status display of FIG. 4.

FIG. 10A illustrates a superimposition of a digital map and a map by altitude data (DEM) in the two-dimensional map demonstration in FIG. 4.

FIG. 10B is a diagram illustrating the superimposition of digital maps and satellite data maps in the two-dimensional map demonstration in FIG. 4.

FIG. 11 is a diagram illustrating types of map information data demonstration methods in a three-dimensional manner. FIG.

FIG. 12A is a diagram illustrating geographic information data according to the demonstration method in the form of a mesh in FIG. 11.

FIG. 12B is a diagram illustrating geographic information obtained by shading the geographic information data of FIG. 12A with a specific color value.

FIG. 12C is a diagram illustrating geographic information that is texture-mapped to geographic data of FIG. 12A.

FIG. 13 is a diagram illustrating geographic information data according to a demonstration method in a grid form in FIG. 11.

14A is a diagram showing a selected altitude value according to the designation of the point “A” in FIG. 13.

FIG. 14B shows a calculated cross section for a particular path, such as line “B”. FIG.

FIG. 15 is a diagram illustrating geographic information data according to a demonstration method having a TIN form in FIG. 11.

Claims (5)

In the method for providing geographic information of a specific area using the Internet, Connecting the user to a predetermined data server to which the geographic information database is connected; Retrieving information about a target area area input in a geographic information search window displayed on the user's terminal according to a connection to the data server; Receiving a selection of a target area to be searched by the user by setting an XY coordinate system on a predetermined screen on which the searched target area area is displayed; Receiving geographic information data of the selected target area from the geographic information database; Selecting and setting the data type and demonstration method to be displayed on the screen from the user with respect to the transmitted geographic information data; Superimposing and demonstrating the geographic information data based on the set data type and demonstration method; And Controlling geographic information data selected by the user from the demonstrated geographic information data to be processed for purchase; Including; The step of selecting and setting the data type and demonstration method, A step of setting a two-dimensional or three-dimensional demonstration method as the demonstration method, wherein the three-dimensional geographic information data demonstration method includes a mesh form, a grid form, and a triangular irregular network (TIN). Receiving one of the forms; And Receiving the data format of the geographic information data to be superimposed by the demonstration method set as the data format, the data format for representing the geographic information data to be superimposed in the two-dimensional manner is numerical map, altitude data (DEM), Receiving set as one of the maps by satellite data Order search service method of geographic information data using the Internet comprising a. According to claim 1, The step of searching for information about the target area area, A command of any one of (1) a first retrieval method for receiving information about an administrative district name and a terrain / feature name from the user, or (2) an enlargement, reduction, or movement of geographic information data demonstrated on the screen Order search service method of geographic information data using the Internet, characterized in that performed by a second search method for receiving an input. The method of claim 1, The step of demonstrating the geographic information data by overlapping, Displaying the geospatial data transmitted corresponding to the area selected by the user in a geometric shape. It includes; The geometric shape is a polygon, or shades within the polygon, and the shading is displayed in a different color to determine the type of data to be retained. The method of claim 1, The grid form reads the altitude difference by substituting the same color value for pixels having the same altitude value, The TIN form is an order retrieval service method of geographic information data using the Internet, characterized in that for demonstrating the vector information of the altitude information. The method of claim 4, wherein Each demonstration method of the three-dimensional geographic information data further includes demonstrating additional information according to the corresponding geographic information data, Demonstrating the additional information in the mesh form, shading the geographic information data in the mesh form to a specific color value in order to increase the reading of the ups and downs, and texture mapping using the retrieved high resolution satellite image and aerial image ( Texture Mapping) Demonstrating the additional information in the grid form, the user displays the selected altitude value at one pixel on the screen using an input device such as a mouse, and calculates a cross section for determining the terrain relief and altitude value of the route. , And demonstrating the additional information in the TIN form, reading the shape of the longitudinal section as a height value.