KR100912942B1 - The quality inspecting system using overlapping of orthoimage and vector data with coordinate - Google Patents

Abstract

A quality inspecting system using overlapping of actual image and vector data according to coordinates to improve checking accuracy is provided to index/extract actual image/vector data included within a square coordinate of a work window. An actual image management unit(100) extracts coordinates value according to the inputted actual image. The actual image management unit manages/stores each actual image according to the extracted coordinate as described above. A vector data management unit(200) stores/manages vector data according to each actual image. A coordinates calculation unit(300) calculates the square coordinate of the checking object of work window. An overlapping unit(400) overlaps actual image and vector data. A quality inspection unit(500) practices the quality inspection of inspection items based on the overlapped actual image and vector data.

Description

Quality inspection system using orthoimage and vector data superimposition according to coordinate values {THE QUALITY INSPECTING SYSTEM USING OVERLAPPING OF ORTHOIMAGE AND VECTOR DATA WITH COORDINATE}

The present invention relates to a quality inspection system using superimposition of orthoimages and vector data according to coordinate values for improving the quality and work efficiency of high-precision orthoimages.

In general, the scale of aerial photography is defined as the ratio of the focal length of the camera to the altitude from the ground of the plane. At almost every point in the picture, the distance from the camera's focus is different due to the change in the tilt and height, so the points are not all the same scale. Therefore, since aerial photographs do not have a constant scale over the entire image, it is impossible to use them to measure distances or angles to specific features or to extract exact positions unless the relief displacement process is performed. By removing the deviations appearing in the aerial photo, the ortho-photo is a photo that is made to have a constant scale in all points as shown in a general map. And in the process of making ortho-photographs, the ortho-images that are produced after scanning aerial photographs and processed by a computer are called ortho-images, and since they can be used directly on computers, the basic data of GIS / LIS / UIS It is very likely to be used.

On the other hand, the high-definition orthoimage is made on a large scale, in order to inspect the quality of the orthoimage, the inspection is performed by superimposing screen inspection and inspection reference vector data (mosaic lines, digital map data, etc.).

In this case, in the quality inspection of the filing orthoimage, there is a problem in that the same file is repeatedly executed due to a mistake of an operator. In addition, even when a large-scale generated orthoimage is opened and inspected at a time, there is a difficulty in working due to the data capacity problem.

The present invention has been made in view of the above problems, and a first object of the present invention is to store and manage each orthogonal image according to the coordinate value and the vector data according to the orthogonal image included in the rectangular coordinates of the work screen and Only vector data can be easily indexed and extracted, and work efficiency can be improved by preventing duplicate execution of quality inspection.

In addition, a second object of the present invention is to generate and store error information of an orthoimage so that it can be used as a later inspection history.

The present invention relates to a quality inspection system using an orthoimage and a vector data superimposition according to a coordinate value. Ortho image management unit for storing and managing; A vector data manager configured to store and manage vector data according to each orthoimage stored in the orthoimage manager; A coordinate calculation unit calculating square coordinates of a work screen to be inspected; An overlapping unit for indexing and extracting orthoimages and vector data included in rectangular coordinates of the work screen; And a quality inspection unit which executes a quality inspection for each inspection item and stores the result based on the orthoimage and the vector data superimposed through the overlapping unit. Including but, the quality inspection unit, when executing the quality inspection for each inspection item, determines whether an error situation occurs, if an error occurs, generates error information by registering the coordinates of the error point and the error content of each inspection item Characterized in that for storing.

On the other hand, the present invention relates to a quality inspection method using an orthoimage and a vector data superimposition according to a coordinate value, the method comprising the steps of: (a) calculating the rectangular coordinates of the work screen to be examined by the coordinate calculation unit; (b) extracting, by the superimposing unit, the orthoimages included in the rectangular coordinates of the work screen through the orthoimage management unit, and extracting and extracting the vector data according to the extracted orthoimages through the vector data management unit. ; (c) overlapping the orthoimage and the vector data extracted by the overlapping unit (b); (d) storing, by the quality inspecting unit, a quality inspection for each inspection item based on the orthoimage and the vector data superimposed through the overlapping unit; (e) determining whether an error situation occurs when the quality inspecting unit executes quality inspection for each inspection item; And (f) generating an error information by registering the coordinate value of the error point and the error content for each inspection item when an error condition occurs as a result of the determination of step (e); Characterized in that it comprises a.

According to the present invention as described above, by simply indexing and extracting only the orthoimage and the vector data included in the rectangular coordinates of the work screen, there is an effect of reducing the time of the quality inspection, and the inspection accuracy is improved.

In addition, according to the present invention, by generating and storing and managing error information, there is also an effect that can be utilized as the inspection history that proceeds later.

Specific features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings. In the meantime, when it is determined that the detailed description of the known functions and configurations related to the present invention may unnecessarily obscure the subject matter of the present invention, it should be noted that the detailed description is omitted.

Hereinafter, with reference to the accompanying drawings will be described in detail the present invention.

A quality inspection system and method using an orthogonal image and vector data superimposition according to the coordinates according to the present invention will be described with reference to FIGS. 1 to 5.

1 is a block diagram conceptually illustrating a quality inspection system S (hereinafter, referred to as a 'quality inspection system') using an orthoimage and a vector data superimposition according to a coordinate value according to the present invention. 100, the vector data management unit 200, the coordinate calculation unit 300, the superimposition unit 400, and the quality inspection unit 500.

Specifically, the configuration of the orthoimage management unit 100 receives an orthoimage obtained for an arbitrary object, extracts coordinate values for each orthoimage, and stores and manages each orthoimage according to the extracted coordinate value. .

The vector data management unit 200 stores and manages vector data corresponding to each orthogonal image stored in the orthoimage management unit 100. At this time, the vector data management unit 200 separates the layers for each vector data and stores the layers for each layer. Here, the vector data is inspection reference data including mosaic lines of the orthoimage, digital map data, and the like.

The coordinate calculator 300 calculates a rectangular coordinate of the work screen to be inspected.

In this case, the rectangular coordinates refer to the four corner coordinates on the work screen, and the coordinate calculation unit 300 calculates the horizontal, vertical length and the center point of the work screen, and then calculates the coordinates of the four corners by setting the screen scale to 1: 1. Can be.

The overlapping unit 400 indexes and extracts orthoimages and vector data included in the rectangular coordinates of the work screen. That is, the overlapping unit 400 indexes and extracts the orthoimage included in the rectangular coordinates of the work screen through the orthoimage managing unit 100, and extracts the vector data according to the extracted orthogonal image through the vector data managing unit 200. After indexing and extracting, the orthoimage and the vector data are superimposed as shown in FIG.

The quality inspecting unit 500 executes quality inspection for each inspection item and stores the inspection result based on the orthoimage and the vector data superimposed through the overlapping unit 400.

Here, the inspection item of the quality inspection is an item that inspects a DEM error, a Seam error, and other additional errors of the user. The DEM error is an error in which a building is formed in an abnormal shape as shown in FIG. 3 in an orthoimage of an area where an error exists rather than an actual height value. Error.

At this time, in order to achieve the second object of the present invention, 'when the quality inspection of the orthoimage is executed, error information is generated and stored so that it can be used as an inspection history to be performed later', the quality inspection unit 500 checks the quality of each inspection item. When the test is executed, it is determined whether an error condition such as DEM error, Seam error, or other user's additional error occurs.In case of an error condition, the error information is registered by registering the coordinate value of the error point and the error content of each test item. As shown in FIG. 1, the error DB 510 stores and manages error information generated based on the coordinate value of the corresponding error point and the error content of each inspection item.

On the other hand, if the error condition does not occur, the quality inspecting unit 500 stores the quality inspection result in the result DB 520, and determines whether or not the movement signal input to the work area to be inspected by the user. As a result of the determination, when the work area movement signal is input from the user, the quality inspecting unit 500 executes a quality inspection on the work area according to the movement signal, and when the work area movement signal is not input, ends the process.

Referring to the quality inspection method using the orthoimage and the vector data superimposition according to the coordinate value according to the present invention having the above-described configuration is as follows.

5 is a flowchart illustrating a quality inspection method using an orthogonal image and vector data superimposition according to a coordinate value according to the present invention. As illustrated, the coordinate calculation unit 300 calculates a rectangular coordinate of a work screen to be inspected. (S100).

The superimposing unit 400 indexes and extracts the orthoimages included in the rectangular coordinates of the work screen through the orthoimage managing unit 100 (S200), and extracts vector data according to the extracted orthoimages from the vector data managing unit 200. After indexing and extracting through (S300), the orthoimage and the vector data overlap (S400).

The quality inspecting unit 500 executes quality inspection for each inspection item based on the orthoimage and the vector data superimposed through the overlapping unit 400 (S500), and determines whether an error situation occurs (S600).

As a result of the determination in step S600, if an error situation does not occur, the quality inspecting unit 500 stores the quality inspection result in the result DB 520 (S700), and inputs a movement signal of the work area to be inspected by the user. Determine (S800).

As a result of the determination of step S800, when a work area movement signal is input from the user, the quality inspecting unit 500 performs the procedure to step S100, and when the work area movement signal is not input, ends the process.

On the other hand, as a result of the determination in step S600, when an error situation occurs, the quality inspection unit 500 generates the error information by registering the coordinate value of the error point and the error content for each inspection item, and stores it in the error DB (510), In step S800, the procedure is performed (S900).

As described above and described with reference to a preferred embodiment for illustrating the technical idea of the present invention, the present invention is not limited to the configuration and operation as shown and described as described above, it is a deviation from the scope of the technical idea It will be understood by those skilled in the art that many modifications and variations can be made to the invention without departing from the scope of the invention. Accordingly, all such suitable changes and modifications and equivalents should be considered to be within the scope of the present invention.

1 is a block diagram schematically illustrating a quality inspection system using an orthoimage and a vector data superimposition according to a coordinate value according to the present invention.

2 is an exemplary view illustrating a state in which an orthoimage and vector data overlap each other according to the present invention.

3 is an exemplary view showing a DEM error according to the present invention.

4 is an exemplary view showing a Seam error in accordance with the present invention.

5 is a flowchart illustrating a quality inspection method using an orthoimage and a vector data superimposition according to a coordinate value according to the present invention.

** Description of symbols for the main parts of the drawing **

100: ortho image management unit 200: vector data management unit

300: coordinate calculation unit 400: overlapping unit

500: quality inspection unit 510: error DB

520: result DB

Claims (11)

In the quality inspection system using orthoimage and vector data superimposition according to coordinate values, An orthoimage manager configured to receive an orthoimage obtained for an arbitrary object, extract coordinate values for each orthoimage, and store and manage each orthoimage according to the extracted coordinate value; A vector data manager configured to store and manage vector data according to each orthoimage stored in the orthoimage manager; A coordinate calculation unit calculating square coordinates of a work screen to be inspected; The orthoimage included in the rectangular coordinates of the work screen is indexed and extracted through the orthoimage managing unit, and the vector data according to the extracted orthoimage is indexed and extracted through the vector data managing unit, and the orthoimage and the vector data are extracted. Overlapping overlapping portions; And A quality inspection unit which executes a quality inspection for each inspection item and stores a result based on the orthoimage and the vector data superimposed through the overlapping unit; Including but not limited to: The quality inspection unit, When executing the quality inspection for each inspection item, it is determined whether an error situation occurs, and when it is determined that an error situation occurs, the error information is generated and stored in the error DB by registering the coordinate value of the error point and the error content for each inspection item. If the error does not occur, the quality test result is stored in the result DB, and the user determines whether to input the movement signal of the work area to be inspected. As a result of the determination, when the work area movement signal is input, the quality inspection of the work area according to the movement signal is executed, and when the work area movement signal is not input, the process is terminated. Quality Inspection System Using Vector Data Overlay. The method of claim 1, The vector data management unit, Quality inspection system using orthogonal image and vector data superimposition according to the coordinate value, characterized in that the layer for each vector data is separated and stored for each layer. The method of claim 1, The vector data is a quality inspection system using superimposed orthoimages and vector data according to coordinates, characterized in that the data includes mosaic lines and digital map data of the orthoimage. delete delete delete The method of claim 1, The inspection item includes a DEM error inspection item and a SEAM error inspection item. delete delete delete delete

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