KR102420648B1 - The method for inspecting and correcting of map - Google Patents

Abstract

The present invention relates to a technical field related to a performance inspection and correction method of a digital map by geodetic surveying, wherein errors occurring in a process of displaying survey information obtained through the geodetic surveying and field inspection by a worker on the digital map can be corrected without being omitted step by step. Therefore, the reliability of the digital map can be secured, and manpower and cost can be reduced.

Description

Numerical topographic map performance test and correction method

The present invention relates to a performance test and correction method for a numerical topographic map, and specifically, through reference point surveying, field survey, supplementary surveying, in-place editing, etc., errors in reference points, symbols, road centerlines, distances, etc. It relates to a performance test and correction method for a digital topographic map that can improve the reliability of a finally produced digital topographic map by preventing problems at an early stage by correcting it in case of inappropriateness.

Numerical topographic maps are largely constructed in the following stages: reference point surveying, aerial photography and drawing, field survey and supplementary surveying, in-place editing, and drawing production.

At this time, the entity that discloses and manages the digital topographic map inspects omissions and errors in the production of the digital topographic map in order to disclose the digital topographic map. It is based on a hand-written survey, and when the subject of inspection is extensive or scattered, the on-site inspection method is directly conducted using a road view such as a web map, etc., and the second is to correct omissions and errors reflected by the on-site inspection. There is a method for inspection and correction of digital topographic maps

In the case of the first on-site inspection method, various correction and improvement systems are being developed to improve efficiency by reducing errors in the frequency and range of on-site inspections. However, in the case of showing corrections and corrections made by on-site inspections on the numerical topographic map, it is essential to supplement the drawings to meet the guidelines. It is common. In this process, errors such as errors between reference points and vertices, distance inconsistency, code symbol inconsistency, overlapping objects, and road centerline inconsistency may occur, which may reduce inspection accuracy.

Therefore, there is a need for a new method that can secure the reliability of the numerical topographic map by geodetic surveying and suggest the appropriateness of the complementary direction.

Registered Patent No. 10-2182654

It is an object of the present invention to provide a method for examining and correcting the performance of a numerical topographic map by geodetic surveying, which can secure the reliability of a numerical topographic map by reflecting changes made in the process of measurement and on-site inspection by geodetic surveying.

In order to solve the above-mentioned problems, the performance inspection and correction method of the numerical topographic map by the geodetic survey that corrects the performance inspection from the coordinates of the reference point obtained through the geodetic survey and the field inspection that inspects it is provided. According to an embodiment of the present invention, a method for examining and correcting the performance of a digital topographic map by geodetic surveying includes: (a) a digital topographic map storage step of uploading a digital topographic map prepared by geodetic surveying and field inspection; (b) a coordinate scattering step of inputting the raw coordinates marked on the stored numerical topographic map on a CAD; (c) checking the other points of the coordinates input on the CAD; (d) a layer control step of forming a layer according to the checked points, and checking whether the connection distance of the layers formed according to the points corresponds to a specified distance; (e) after the layer control is completed, a symbol conversion step of converting a symbol for each coordinate; (f) a vertical line correction step of correcting a vertical line between the formed layers; (g) the step of rotating the symbol displayed on the layer after correction of the vertical line; (h) a center setting step of setting a center after the symbol conversion; and (i) searching for and modifying duplicate objects among the dots, layers, and symbols; Including, but in the (d) layer control step, if the connection distance of the layers exceeds the specified distance, adding a dot to (c) ~ (i) is re-examined, the center setting in the (f) center setting step It is characterized by re-inspecting (d)-(i) after.

The performance inspection and correction method of the numerical topographic map according to an example of the present invention includes on-site measurement, occurrence of errors between reference points and vertices of the numerical topographic map recorded by on-site inspection, distance inconsistency, code symbol inconsistency, duplicate object generation, road centerline By inspecting errors such as inconsistencies and correcting them to meet the guidelines, the reliability of previously conducted on-site measurements and on-site inspections can be secured.

1 is a schematic flowchart of a numerical topographic map performance test and correction method according to an embodiment of the present invention.
2 is an example of the guidelines shown on the digital topographic map.
3 is an example in which the RBI is corrected by the method for performing a numerical topographic map performance test and correction according to an embodiment of the present invention.
4 is an example in which a symbol is corrected by a method for performing a numerical topographic map performance test and correction according to an embodiment of the present invention.
5 is an example in which a layer is corrected by the numerical topographic map performance test and correction method according to an embodiment of the present invention.
6 is an example in which a symbol is rotated by a method for examining and correcting a performance of a digital topographic map according to an embodiment of the present invention.
7 is an example in which a center is set by a method for performing a numerical topographic map performance test and correction according to an embodiment of the present invention.
It is revealed that the accompanying drawings are exemplified as a reference for understanding the technical idea of the present invention, and the scope of the present invention is not limited thereby.

In the description of the present invention, if it is determined that the subject matter of the present invention may be unnecessarily obscured as it is obvious to those skilled in the art with respect to related known functions, the detailed description will be omitted.

Hereinafter, a numerical topographic map performance test and correction method according to an embodiment of the present invention will be described.

The numerical topographic map performance test and correction method of the present invention means a method capable of securing accuracy by inspecting and correcting a numerical topographic map produced through reference point coordinates obtained through geodetic surveying and field inspection. Hereinafter, it should be noted that each of the following steps is performed by the digital topographic map correction module.

1 is a schematic flowchart of a method for examining and correcting a performance of a digital topographic map according to an embodiment of the present invention, and FIG. 2 is an example of instructions shown in the digital topographic map. 3 to 5 are examples of correction by the method for securing the accuracy of a digital topographic map according to an embodiment of the present invention.

First, in the case of geodetic surveying, the operator proceeds directly through the surveying inspection equipment at the site and records various topographic features including the coordinates of the reference point. The reflected numerical topographic map is shown. However, as a result of on-site inspection, survey information such as reference points and topographical features is not shown correctly on the digital topographic map, resulting in lower reliability of the digital topographic map. Accordingly, the present invention provides a performance check and correction of the digital topographic map through the digital topographic map storage step, the coordinate scattering step, the other inspection step, the layer control step, the symbol conversion step, the vertical line correction step, the symbol rotation step, the center setting step and the duplicate object correction step. It is possible to secure a numerical topographic map that accurately reflects the contents of the on-site inspection.

In detail, it stores the numerical topographic map including the coordinates of the measurement target such as various facilities and features reflected through the geodetic survey and on-site inspection. Thereafter, the coordinate scattering step of inputting the raw coordinates marked on the stored numerical topographic map on the CAD is performed. At this time, the other points of the coordinates input on the CAD are first found and marked on the numerical map corresponding to the coordinates input by the operator. Therefore, since the coordinates are marked by the operator, the coordinates and the points of the other points may not match exactly, and the layer formed by connecting the coordinates that are not accurately entered is different from the layer that appears on the actual digital topography. Proceed with the other point inspection step of inspecting the other points so as to correspond to the coordinates entered in the .

As above, when the inspection is completed, a layer is formed according to the inspected dots as shown in FIG. 3, and a layer control step of inspecting whether the connection distance of the dots formed according to the dots corresponds to a specified distance is performed. The connection distance of the layer is different according to the guidelines of the institution that requested the numerical measurement. After setting the connection distance of the other points in advance to correspond to each guideline, if the connection distance of the other points exceeds the specified distance, the operator is notified. Accordingly, if it is necessary to correct the connection distance of the RBI, the coordinates input above are added between the connection distances of the RBI, and then the layer control step of resetting the RBI, connecting the RBI and inspecting the connection distance is performed.

After the layer control is completed, a symbol conversion step in which the coordinates marked on the layer and the symbols representing the features corresponding to the coordinates are converted by replacing the coordinates are performed. For example, when the feature located at the corresponding coordinates is a pipe (SA01, ㎈), the coordinates are transformed into the corresponding symbol as shown in FIG. 4 .

On the other hand, when the formed layer includes a horizontal line and a branch line, a vertical line correction step is performed to ensure the consistency and numerical accuracy of the layer by correcting the branch line with a vertical line so as to be vertical from the horizontal line as shown in FIG. 5 . After the layer is corrected with a horizontal line and a corresponding vertical line, a symbol rotation step of rotating the symbol is performed so that the transformed symbol is consistently positioned along the line of the layer on the coordinates of the layer. For example, referring to FIG. 6 , when the corresponding symbol is transformed and inputted to the coordinates on the layer, it can be seen that the coordinates are simply input to the layer in an overlapping state. Reliability of the symbol position can be secured by rotating the symbol so that the center of the symbol is located in line with the line of the layer. Furthermore, in the case of a layer having a predetermined angle as shown in FIG. 5 , the reliability of the symbol position can be secured by rotating the symbol so as to be perpendicular to the layer.

After the symbol conversion is completed, if there are a plurality of converted symbols and a plurality of symbols indicates a single symbol, a center setting step of setting the center of the symbol may be performed. For example, referring to FIG. 7 , when a single manhole is located on the topography and a plurality of manhole covers are arranged around the manhole, the manhole cover is also recognized as a type of manhole and the coordinates are replaced with a symbol corresponding to the manhole. . At this time, by distinguishing the manhole cover from the manhole, connecting the manhole cover as a virtual layer, and designating the center of the layer, it is possible to correct the number of manholes. If correction is not performed with a single manhole, a plurality of points may be displayed due to the coordinates displayed as a plurality of points, and deformation of the layer connecting the points may occur, resulting in a numerical map different from the actual feature. Therefore, after the symbol conversion is completed, it is preferable to proceed with the center setting step according to the type of the converted symbol.

As described above, when the dots, layers, and symbols are all corrected according to the setting of the corresponding step, a duplicate object correction step of searching and correcting duplicate objects is performed. If a plurality of symbols arranged on the coordinates are overlapped, it informs whether there are actually a plurality of features or an error caused by correction of other points, and corrects them by deleting or indicating that they are a plurality of objects in accordance with the facts. If the above duplicate object correction step is not performed, the actual terrain features may be recognized as plural instead of plural, or as a singular number for plural individuals. Therefore, it is desirable to accurately correct whether there are duplicate objects.

The method may include extracting a leader line capable of disclosing layer information from the layer on which the layer control has been completed, and adjusting the length to correspond to the length of a character input on the leader line.

On the other hand, in the (d) layer control step, if the connection distance of the layers exceeds the specified distance, additional points must be added to re-examine (c) to (i). If the RBI is changed, the layer is changed and the angle, position, and arrangement of the layers shown on the numerical map are different. The reliability of the map may be reduced. In addition, it is desirable for the reliability of the numerical map to re-examine (d) to (i) for the same reason as described above after the center setting in the (f) center setting step.

As described above, the method for securing the accuracy of a numerical topographic map according to an embodiment of the present invention corrects the errors occurring in the process of displaying the geodetic information by the primary geodetic survey and the field inspection to check it on the numerical map step by step Therefore, the setting according to the guidelines can be precisely supplemented without omission, and the reliability of the numerical map can be secured because the geodetic information can be accurately shown on the numerical map.

On the other hand, the protection scope of the present invention is not limited to the description and expression of the embodiments explicitly described above. In addition, it is added once again that the protection scope of the present invention cannot be limited due to obvious changes or substitutions in the technical field to which the present invention pertains.

Claims (1)

(a) a digital topographic map storage step of uploading a digital topographic map prepared by geodetic survey and field inspection;
(b) a coordinate scattering step of inputting the raw coordinates marked on the stored numerical topographic map on a CAD;
(c) checking the other points of the coordinates input on the CAD;
(d) a layer control step of forming a layer according to the checked points, and checking whether the connection distance of the layers formed according to the points corresponds to a specified distance;
(e) after the layer control is completed, a symbol conversion step of converting a symbol for each coordinate;
(f) a vertical line correction step of correcting a vertical line between the formed layers;
(g) the step of rotating the symbol displayed on the layer after correction of the vertical line;
(h) a center setting step of setting a center after the symbol conversion; and
(i) searching and modifying duplicate objects among the dots, layers, and symbols; Including, but in the (d) layer control step, if the connection distance of the layer exceeds the specified distance, adding a dot to (c) ~ (i) is re-examined, the center setting in the (h) center setting step Afterwards, if there is a change in at least one of the symbols, leader lines, and center lines marked on the layer because the angle, position, and arrangement of the layer are different, check (d)~(i) again and there is no change. In case the correction is completed, the performance verification and correction method of the numerical topographic map by geodetic surveying.

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