KR102596476B1 - Method and device for automatic fine-tuning of boundary points of parcels/polygons - Google Patents

Abstract

The present invention relates to a method and device for automatic fine adjustment of parcel/polygon boundary points. The method changes the coordinate unit of a plurality of parcels or polygon boundary points and selects one of the area before the change, the ledger area registered in the study, and the area designated by the user. A step of specifying as an area condition; Specifying an adjustment order of the plurality of parcels based on parcel information including at least one of parcel lot number, location, area, distribution, inter-point distance, and area error; Performing fine adjustment by moving the positions of the plurality of parcels or polygon boundary points at regular intervals within an adjustment range in the designated adjustment order; and fixing boundary point coordinates that meet the designated area conditions.

Description

Method and device for automatic fine tuning of parcel/polygon boundary points {METHOD AND DEVICE FOR AUTOMATIC FINE-TUNING OF BOUNDARY POINTS OF PARCELS/POLYGONS}

The present invention relates to a technology for fine-tuning boundary points of parcels containing polygons. More specifically, automatic parcel/polygon boundary point automation is used to reduce area errors by automatically fine-tuning the boundary points of multiple parcels or polygons in batches to meet area conditions. It relates to a fine tuning method and device.

In the cadastral resurvey project, cadastral resurvey surveying to improve cadastral nonconformity sites and conversion to the World Geodetic System of boundary point coordinate registration areas commonly result in slight area errors due to changes in coordinate units related to decimal places. When the coordinate unit is changed, the area error does not occur or is minimal for parcels with a small area, but the error becomes worse for parcels with a certain area or more.

In order to eliminate the slight amount of area change caused by changing the coordinate unit, the user directly selected boundary points and attempted to fine-tune the boundary, but it was inefficient and inaccurate because it took too much time and cost.

Due to these problems, in cadastral resurvey practice, boundary fine-adjustment software developed by the 'Korea Land and Land Information Corporation Spatial Information Research Institute' is used to adjust the boundary, but the operation method is such that the user must select the parcel and the adjacent boundary point directly. It takes a lot of time to adjust hundreds to tens of thousands of parcels or polygons one by one, and when adjusting each parcel one by one, the area of the entire parcel may be pushed back, making adjustment impossible for lower-priority parcels. At this time, work efficiency decreases because the lot adjustment order must be changed and adjustments must be made again from the beginning. In addition, the task of converting the boundary point coordinate registration area to the World Geodetic System requires a method to efficiently solve this problem, as the area error is increased due to the change in coordinate units in addition to the minute area error during coordinate conversion.

Korean Patent No. 10-1499181 (2015.02.27)

An embodiment of the present invention seeks to provide a method and device for automatically fine-tuning boundary points of multiple parcels or polygons to reduce area errors by automatically fine-tuning the boundary points of multiple parcels or polygons in batches to meet area conditions.

An embodiment of the present invention is a parcel that can increase the accuracy and efficiency of cadastral resurvey or cadastral map World Geodetic System conversion work by selecting adjustment boundary points by sequentially ordering a number of lots or polygons and fine-tuning the boundaries in that order. /The goal is to provide a method and device for automatic fine adjustment of polygon boundary points.

An embodiment of the present invention seeks to provide a method and device for automatic fine adjustment of parcel/polygon boundary points that can shorten the adjustment time by setting the index differently for each adjustment range.

Among the embodiments, the automatic fine adjustment method for parcel/polygon boundary points changes the coordinate units of multiple parcels or polygon boundary points and specifies as an area condition one of the area before the change, the register area registered in the study, and the area specified by the user. step; Specifying an adjustment order of the plurality of parcels based on parcel information including at least one of parcel lot number, location, area, distribution, inter-point distance, and area error; Performing fine adjustment by moving the positions of the plurality of parcels or polygon boundary points at regular intervals within an adjustment range in the designated adjustment order; and fixing boundary point coordinates that meet the designated area conditions.

The step of specifying the lot order is to specify the order of the lots in order of lot number, to specify the order from the lot in the center to the lot on the outskirts, to specify the order from the lot with the smallest area to the lot with the largest area, or to specify the order of the lot distribution direction. You can specify the order according to .

The boundary point fine adjustment execution step expands the boundary point adjustment range up to 7 cm based on 1 cm, sequentially assigns indices in a specific direction within the adjustment range, and goes through the entire index for a number of boundary points. It can be adjusted sequentially through the adjustment method.

The boundary point fine-adjustment execution step can be adjusted through a section method in which the index is set differently for each section of the adjustment range of the boundary point and a plurality of boundary points are adjusted based on the index for each section.

In the boundary point fine-adjustment execution step, boundary point fine-adjustment may be sequentially performed on a per-lot basis.

In the boundary point fine-adjustment execution step, if the area error is too large, the area error can be reduced by adjusting the adjustment points in a certain direction, and then the boundary point fine-adjustment can be performed.

In the boundary point fine-adjustment execution step, boundary point fine-adjustment may be performed on a unit of 2 lots, and if adjustment fails, boundary point fine-adjustment may be performed on a 1-lot basis for the relevant parcel.

Among the embodiments, the automatic fine-adjustment device for parcel/polygon boundary points changes the coordinate units of a plurality of parcels or polygon boundary points and specifies one of the area before the change, the ledger area registered in the study, and the area specified by the user as an area condition. Coordinate unit change unit; A parcel order designation unit that specifies an adjustment order of the plurality of parcels based on parcel information including at least one of parcel lot number, location, area, distribution, point-to-point distance, and area error; a boundary fine-adjustment execution unit that performs fine-adjustment by moving the positions of the plurality of parcels or polygon boundary points at regular intervals within an adjustment range in the designated adjustment order; and a coordinate fixing unit that fixes boundary point coordinates that meet the designated area conditions.

The disclosed technology can have the following effects. However, since it does not mean that a specific embodiment must include all of the following effects or only the following effects, the scope of rights of the disclosed technology should not be understood as being limited thereby.

The method and device for automatic fine-tuning of parcel/polygon boundary points according to an embodiment of the present invention can reduce area errors by automatically fine-tuning the boundary points of multiple parcels or polygons in batches to meet area conditions.

The automatic fine-adjustment method and device for parcel/polygon boundary points according to an embodiment of the present invention sets the order of a plurality of parcels or polygons in batches, selects the adjustment boundary points, and fine-adjusts the boundaries in that order for cadastral resurvey or cadastral drawing world. The accuracy and efficiency of geodetic conversion work can be improved.

The method and device for automatic fine adjustment of parcel/polygon boundary points according to an embodiment of the present invention can shorten the adjustment time by setting different indices for each adjustment range.

Figure 1 is a block diagram illustrating an automatic fine-adjustment system for parcel/polygon boundary points according to the present invention.
FIG. 2 is a diagram illustrating the physical configuration of the automatic fine-tuning device in FIG. 1.
FIG. 3 is a diagram illustrating the functional configuration of the automatic fine adjustment device in FIG. 1.
Figure 4 is a diagram for explaining the basic principle of boundary fine adjustment.
Figure 5 is a diagram for explaining coordinate adjustment of multiple boundary points.
Figure 6 is an example diagram showing the position number (index) according to the fine adjustment direction when the adjustment range of the boundary point is expanded to 7 cm.
Figure 7 is a flowchart explaining the process of automatic fine adjustment of parcel/polygon boundary points according to the present invention.
Figure 8 is an example diagram showing a case of fine adjustment of boundary points on a per-lot basis.
Figure 9 is an example diagram showing the case of fine adjustment of boundary points in mixed units of 2+1 lots.

Since the description of the present invention is only an example for structural or functional explanation, the scope of the present invention should not be construed as limited by the examples described in the text. In other words, since the embodiments can be modified in various ways and can have various forms, the scope of rights of the present invention should be understood to include equivalents that can realize the technical idea. In addition, the purpose or effect presented in the present invention does not mean that a specific embodiment must include all or only such effects, so the scope of the present invention should not be understood as limited thereby.

Meanwhile, the meaning of the terms described in this application should be understood as follows.

Terms such as “first” and “second” are used to distinguish one component from another component, and the scope of rights should not be limited by these terms. For example, a first component may be named a second component, and similarly, the second component may also be named a first component.

When a component is referred to as being “connected” to another component, it should be understood that it may be directly connected to the other component, but that other components may exist in between. On the other hand, when a component is referred to as being “directly connected” to another component, it should be understood that there are no other components in between. Meanwhile, other expressions that describe the relationship between components, such as "between" and "immediately between" or "neighboring" and "directly neighboring" should be interpreted similarly.

Singular expressions should be understood to include plural expressions unless the context clearly indicates otherwise, and terms such as “comprise” or “have” refer to implemented features, numbers, steps, operations, components, parts, or them. It is intended to specify the existence of a combination, and should be understood as not excluding in advance the possibility of the presence or addition of one or more other features, numbers, steps, operations, components, parts, or combinations thereof.

For each step, identification codes (e.g., a, b, c, etc.) are used for convenience of explanation. The identification codes do not explain the order of each step, and each step clearly follows a specific order in context. Unless specified, events may occur differently from the specified order. That is, each step may occur in the same order as specified, may be performed substantially simultaneously, or may be performed in the opposite order.

The present invention can be implemented as computer-readable code on a computer-readable recording medium, and the computer-readable recording medium includes all types of recording devices that store data that can be read by a computer system. . Examples of computer-readable recording media include ROM, RAM, CD-ROM, magnetic tape, floppy disk, and optical data storage devices. Additionally, the computer-readable recording medium can be distributed across computer systems connected to a network, so that computer-readable code can be stored and executed in a distributed manner.

All terms used herein, unless otherwise defined, have the same meaning as commonly understood by a person of ordinary skill in the field to which the present invention pertains. Terms defined in commonly used dictionaries should be interpreted as consistent with the meaning they have in the context of the related technology, and cannot be interpreted as having an ideal or excessively formal meaning unless clearly defined in the present application.

Figure 1 is a block diagram illustrating an automatic fine-adjustment system for parcel/polygon boundary points according to the present invention.

Referring to FIG. 1, the parcel/polygon boundary point automatic fine-adjustment system 100 may include a user terminal 110, an automatic fine-adjustment device 130, and a database 150.

The user terminal 110 may correspond to a computing device that can use information regarding automatic fine-tuning of parcels or polygon boundary points performed by the automatic fine-tuning device 130. The user terminal 110 may be implemented as a smartphone, a laptop, or a computer, but is not necessarily limited thereto, and may also be implemented as a variety of devices such as a tablet PC. The user terminal 110 may be connected to the automatic fine-tuning device 130 through a network, and a plurality of user terminals 110 may be connected to the automatic fine-tuning device 130 at the same time.

The user terminal 110 may specify the order of adjustment of multiple parcels to be performed by the automatic fine adjustment device 130 through user input. Users can also select boundary points or adjustment directions for parcels or polygons.

The automatic fine-tuning device 130 may be implemented as a server corresponding to a computer or program that automatically fine-tunes boundary points corresponding to the areas of parcels or polygons registered during the cadastral resurvey or cadastral map world geodetic system conversion process. Additionally, the automatic fine-tuning device 130 may be connected to the user terminal 110 through a wired network or a wireless network such as Bluetooth or WiFi, or may be directly connected to the user terminal 110 through a wired or wireless network. The automatic fine-tuning device 130 can store various information during the operation of the parcel/polygon boundary point automatic fine-tuning system 100 in conjunction with the database 150. The automatic fine-tuning device 130 can be implemented as a basic system configuration including a processor, memory, user input/output unit, and network input/output unit, which will be described in more detail in FIG. 2.

The database 150 may correspond to a storage device that stores various information required during the operation of the automatic fine-tuning device 130. The database 150 can store the Korea Land and Infrastructure Information Corporation's cadastral survey result file (JSG) and cadastral study file (CIF), and can store data organizing boundary points of multiple parcels and polygons, but is not necessarily limited thereto. Instead, the automatic fine-adjustment device 130 may store information collected or processed in various forms during the process of fine-tuning the boundary points of parcels or polygons.

FIG. 2 is a diagram illustrating the physical configuration of the automatic fine-tuning device in FIG. 1.

Referring to FIG. 2, the automatic fine tuning device 130 may be implemented including a processor 210, a memory 230, a user input/output unit 250, and a network input/output unit 270.

The processor 210 can execute a procedure that processes each step in the process of operating the automatic fine-tuning device 130, and can manage the memory 230 that is read or written throughout the process, and the memory ( 230), the synchronization time between the volatile memory and the non-volatile memory can be scheduled. The processor 210 can control the overall operation of the automatic fine-tuning device 130 and is electrically connected to the memory 230, the user input/output unit 250, and the network input/output unit 270 to control data flow between them. can do. The processor 210 may be implemented as a central processing unit (CPU) of the automatic fine-tuning device 130.

The memory 230 may be implemented as a non-volatile memory such as a solid state drive (SSD) or a hard disk drive (HDD) and may include an auxiliary memory used to store all data required for the automatic fine tuning device 130. , may include a main memory implemented as volatile memory such as RAM (Random Access Memory).

The user input/output unit 250 may include an environment for receiving user input and an environment for outputting specific information to the user. For example, the user input/output unit 250 may include an input device including an adapter such as a touch pad, touch screen, on-screen keyboard, or pointing device, and an output device including an adapter such as a monitor or touch screen. In one embodiment, the user input/output unit 250 may correspond to a computing device connected through a remote connection, in which case the automatic fine-tuning device 130 may perform as a server.

The network input/output unit 270 includes an environment for connecting with external devices or systems through a network, for example, Local Area Network (LAN), Metropolitan Area Network (MAN), Wide Area Network (WAN), and VAN ( It may include an adapter for communication such as a Value Added Network).

FIG. 3 is a diagram illustrating the functional configuration of the automatic fine adjustment device in FIG. 1.

Referring to FIG. 3, the automatic fine adjustment device 130 includes a coordinate unit change unit 310, a parcel order designation unit 330, a boundary fine adjustment execution unit 350, a coordinate fixing unit 370, and a control unit 390. may include.

The coordinate unit change unit 310 can change the unit of coordinates for a parcel or polygon boundary point and select an area condition. The coordinate unit change unit 310 can change the precision of the boundary point coordinates of a parcel or polygon from 0.001 m to 0.01 m as a preparatory step before fine adjustment of the boundary point is made. The coordinate unit change unit 310 can select whether to set the area condition to the area before the coordinate unit change or to the ledger area registered in the study. In the case of cadastral resurvey surveying, the coordinate unit change unit 310 uses the area before the coordinate unit change as the standard, and in the case of World Geodetic System conversion, the area registered in the cadastral study becomes the standard, so the area condition can be selected accordingly. The coordinate unit change unit 310 may select the area condition as an area designated by the user.

The parcel order designation unit 330 can determine the adjustment order of multiple parcels. The parcel order designation unit 330 can automatically or manually designate the adjustment order between multiple parcels. The parcel order designation unit 330 may specify an adjustment order based on parcel information including at least one of lot number, location, area, distribution, point-to-point distance, and area error for a plurality of parcels. In one embodiment, the lot order designation unit 330 can set the order so that adjustment is carried out in lot order, and when adjustment fails, change the adjustment order and re-assign it. In one embodiment, the parcel order designation unit 330 may adjust the parcels in the central location first and set the parcels on the outskirts last. If adjustment is carried out starting with the outer parcels and the central parcels are set last, the adjustment of the central parcels may fail because there is no space for area errors to be eliminated. The reason why parcels on the outskirts need to be adjusted later is because there are no boundaries that meet other parcels on the outskirts, so subtle area errors can be easily eliminated. In one embodiment, when a parcel with a large area and a parcel with a small area are adjacent, the parcel order designation unit 330 may adjust the parcel with a small area first and set the parcel with a large area last. This means that if a lot with a large area is adjusted first, a large area error is propagated from the beginning, and if it is passed on to smaller lots later, it may become impossible to eliminate the area error. In one embodiment, the lot order designation unit 330 may determine the adjustment order by grouping and separating lots rather than determining the adjustment order of lots on the basis of the entire district. This may fail because errors accumulate during straight direction order adjustment and exceed the limit of the adjustment index range at some point.

In one embodiment, the parcel order designation unit 330 may specify an adjustment order according to parcel distribution by zone. For example, if the lot distribution is long in the north-south direction, the order can be determined from top to bottom or bottom to top. At this time, if adjustment fails in some parcels and disconnection occurs, the order can be determined to move by region for adjustment. You can. If the lots are distributed in the east-west direction, the lot adjustment order path can be set to start from the northeast point, pass west, and proceed toward the southeast. If the lots are distributed from northeast to southwest, the lot adjustment order path can be set so that the adjustment order proceeds from north to east-west and then south-center. If the lots are distributed in the east-west direction, the adjustment order can be determined in the east-west-north-south direction starting from the central lot. The parcel order designation unit 330 can determine the adjustment order according to the parcel distribution direction for each zone, and perform automatic fine-adjustment of boundary points in order, and when adjustment fails, the adjustment order can be changed and readjusted. Here, the lot order designation unit 330 determines the order in the direction of rotation from the center in all directions because area error propagation is more sensitive in the case of areas with a large area scale compared to areas with a small area scale, thereby achieving success in automatic fine-tuning of boundary points. to increase the possibility.

In one embodiment, the parcel order designation unit 330 may adjust parcels with a long distance between boundary points or parcels with a large area error as priority. When adjusting parcels with long distances between boundary points or lots with large area errors, there is a risk of adjustment failure due to the influence of accumulated area errors when adjusting parcels with long distances between boundary points, so they are prioritized to increase the likelihood of success in automatic fine-tuning of boundary points.

In one embodiment, the parcel order designation unit 330 may specify an adjustment order by excluding the area conditions of some parcels. For example, only boundary points can be reflected when adjusting adjacent lots, excluding area conditions for long lots such as roads or rivers. Since there are many parcels adjacent to roads or rivers, an exception condition can be added to the adjustment order by taking this into consideration.

The boundary fine-adjustment executing unit 350 may select a boundary fine-adjustment method and execute boundary fine-adjustment in a determined parcel adjustment order in the corresponding area according to the selected boundary fine-adjustment method.

Boundary fine adjustment refers to adjusting the boundary point by moving it around at regular intervals from its original position to match the actual area of a parcel or polygon with the desired area until the desired area matches. The boundary fine-adjustment direction may include clockwise, counterclockwise, random, or a rule determined by the user.

Figure 4 is a diagram to explain the basic principle of boundary fine adjustment, and is an example of adjusting the boundary point clockwise (rightward).

Referring to Figure 4, when trying to adjust a boundary point whose coordinate unit has been changed to 0.01m, boundary point number 1 to be adjusted is the original position, and numbers 2 to 9 are positions within the adjustable 1cm range. Here, the adjustment range is set to 1 cm, but it is not limited to this and the units and intervals can be varied. Considering that the coordinate unit of boundary point 1 is 0.01m, it can be adjusted in increments of 1cm. In this case, the area is 0.001m before the coordinate unit is changed, or 1~9 until it matches another area with a slight difference desired by the user. The boundary points are adjusted in order of position. When the coordinates of boundary points of a parcel are changed from 0.001 m to 0.01 m, all boundary points are basically checked to see if their areas match at location 1. If the area matches at position 1, there is no need for adjustment. If the area does not match, move one boundary point to position 2, check the area, and if it matches, fix it. If it does not, adjust it to position 3. The remaining positions 4 to 9 are adjusted in the same way until the areas match.

However, there is a limit to satisfying the area condition with only one boundary point, so fine adjustment of multiple boundary points is necessary. Fine-tuning multiple boundary points is when the user selects and applies the basic principles of fine-tuning in an expanded manner when there are multiple boundary points. In other words, it is a method of selecting and adjusting boundary points that can be adjusted among parcel boundary points by selecting several points instead of one point.

Figure 5 is a diagram to explain coordinate adjustment of multiple boundary points, and is an example of adjusting multiple boundary points in one polygon clockwise (rightward).

Referring to Figure 5, when four boundary points are selected within a 1 cm range, 6,561 (9 ⁴ = 6,561) cases are calculated when boundary points 1 to 4 are adjusted. The more adjustment points there are, the higher the probability of area matching can be. In particular, it can be effectively applied in cases where there are a large number of boundary points and the amount of area change is relatively large, such as old houses and roads.

Also, since the area condition may fail when the boundary point is adjusted only within a 1cm range, the probability of area matching can be increased by expanding this range and adjusting the boundary. For example, if the adjustment range of one boundary point is expanded to 2 cm, 25 cases can be adjusted, and if two points are adjusted, 25 ² = 625 cases can be derived. If enlarged to 3cm, 49 cases can be adjusted, and if 2 points are adjusted, 49 ² = 2,401 cases occur.

Returning again to FIG. 3, the boundary fine-adjustment executing unit 350 can perform boundary fine-adjustment by selecting a pass-through method in which a plurality of boundary points are adjusted while going through the entire index and a section method in which adjustments are made based on the index for each section. In one embodiment, the boundary fine-adjustment executing unit 350 can distinguish between the full-scale method and the section method depending on whether or not the adjustment range is separated by section, and considering the area condition, '1 lot' and '2+1' depending on the number of lots. It can be classified by the ‘fill’ adjustment method.

When performing boundary fine-adjustment using the pass-through method, the boundary fine-adjustment unit 350 can select a plurality of boundary points and adjust all selected boundary points, as in the 'multiple boundary point coordinate adjustment' method described in FIG. 5. In one embodiment, the boundary fine-adjustment unit 350 increases the probability of area matching by expanding the adjustment range to 7 cm when performing boundary fine-adjustment using the pass-through method. In the boundary fine-adjustment unit 350, the number of indices at which one boundary point can be adjusted can be up to 225 in a range of 7 cm. Here, the index refers to the order in which the boundary point must be adjusted in a certain order within a certain range when adjusting the boundary point through simulation in boundary fine adjustment. When the maximum adjustment range is expanded to 7 cm and the indices are sequentially assigned clockwise, the boundary fine adjustment index can be expressed as shown in FIG. 6.

Figure 6 is a table showing the boundary fine-tuning index.

Referring to Figure 6, the boundary fine adjustment index indicates a case where the maximum adjustment range is expanded to 7 cm and the adjustment order is determined sequentially in a clockwise direction. Here, the reason for setting the adjustment range to 7 cm is that in Article 7 (Determination of cadastral resurvey survey results) of the Enforcement Rules of the Special Act on Cadastral Resurvey (Enforcement 2017.10.19), the range of connection intersection of inspection for boundary points is ±0.07m. Since it was set within this range, the range was determined based on this. Although the adjustment range can be expanded larger than this, it takes a lot of time to simulate the adjustment, and the amount of adjustment of the boundary point may become large, which may result in a large difference from the original position.

Returning again to FIG. 3, the boundary fine-adjustment executing unit 350 can sequentially adjust boundary points through a transfer method that adjusts a plurality of boundary points by going through the entire index. In the transfer method, the number of boundary points and the number of cases according to the adjustment range are shown in Table 1 below.

[Table 1]

As shown in Table 1 above, the larger the adjustment range and the greater the number of boundary points subject to adjustment, the number of cases in which adjustment can be made can increase exponentially. Therefore, if adjustment within a narrow range fails, the possibility of finding a location that meets the area conditions can be increased by expanding the range.

For example, if the boundary adjustment range of 1 point is 7cm (7 steps), the number of cases is calculated to be 225. The more the number of boundary points to be adjusted, the more the number of cases increases, and the area when adjusting the boundary point coordinates through simulation equal to the number of cases is calculated. When they match, the boundary point position is determined by the corresponding index and the adjustment simulation is stopped.

In one embodiment, the boundary fine-adjustment executing unit 350 may perform boundary fine-adjustment using a section method in which indexes are set differently for each adjustment range section in order to shorten the adjustment time. Here, the index for each section can be set by the user. The section method is a method of adjustment based on the index for each section. By separating the adjustment range from the lower level according to the adjustment range of the index so that it does not cross-adjust, it can alleviate the deviation of the adjustment amount between boundary points and reduce the time cost of simulation. For example, if the adjustment range is 2 cm and the adjustment target point is 2 points, the two points are each simulated in the 1 cm range, and then when the adjustment range of one point is expanded to 2 cm, the other point is adjusted except the index corresponding to 1 cm. It is applied as an index in the 2cm range.

Table 2 below summarizes the indices by adjustment range for the integral method and the section method.

[Table 2]

In one embodiment, the boundary fine-adjustment executing unit 350 may consider area conditions when fine-tuning the boundary and perform simulation by selecting the 1-fill and 2+1-fill methods from the all-number and section methods according to the number of lots. Here, the boundary fine-adjustment executing unit 350 defaults to adjusting in 2 lots, but if it fails, it can adjust in 1-fill units only for the relevant lot.

If the area condition does not match even one lot during boundary fine-tuning, the boundary fine-adjustment executing unit 350 may change the lot order again and then execute boundary fine-tuning. The boundary fine adjustment executing unit 350 can adjust a plurality of boundary points according to the index. If the boundary point of the adjustment target meets the conditions of the adjustment range, the index is adjusted. If the limit of the adjustment range is reached, the first point of the index range of the corresponding section is adjusted. Let the adjustment begin from . By setting the index number change rule in this way, the position of the boundary point can be automatically adjusted. The boundary fine-adjustment executing unit 350 adjusts adjacent boundary points according to the index, temporarily reflects the changed coordinates in the parcel, and adjusts them by rounding them to the area unit of the parcel. The boundary fine-adjustment executing unit 350 checks whether the parcel reflecting the adjusted coordinates meets the area condition and continues to perform boundary fine-adjustment simulation until it meets the area condition. That is, the boundary fine-adjustment executing unit 350 continues the process of adjusting the boundary point of the parcel to be adjusted according to the index according to the section or pass-through method and confirming whether it meets the area condition.

If the parcel on which the boundary fine-adjusted coordinates are reflected meets the area conditions, the coordinate fixing unit 370 can fix the coordinates of the parcel and set it as a parcel for which the adjustment has been completed. The coordinate fixing unit 370 can check the parcel for which adjustment has been completed in the entire zone boundary point list to fix the boundary point location and exclude it from the adjustment target. Here, the entire zone boundary point list may correspond to a separately constructed list to reflect the boundary points of adjacent lots in real time to adjacent lots when adjusting the boundary points.

The control unit 390 controls the overall operation of the boundary fine-adjustment device 130, and includes a coordinate unit change unit 310, a parcel order designation unit 330, a boundary fine-adjustment execution unit 350, and a coordinate fixing unit 370. You can manage control flow or data flow between

Figure 7 is a flowchart explaining the process of automatic fine adjustment of parcel/polygon boundary points according to the present invention.

Referring to FIG. 7, the automatic fine adjustment device 130 can change the unit of coordinates of a parcel or polygon boundary point through the coordinate unit change unit 310 (step S710). In addition, the automatic fine adjustment device 130 can select whether to set the area condition to the area before the coordinate unit change or to the area registered in the study through the coordinate unit change unit 310 (steps S720, S730). The coordinate unit change unit 310 sets the area condition to the area before the coordinate unit change in the case of fine adjustment of the boundary of the cadastral resurvey survey area, and designates the area condition as the area registered in the cadastral study in the case of fine adjustment of the boundary of the World Geodetic System conversion area. You can. The coordinate unit change unit 310 may set the area condition to an area designated by the user.

Additionally, the automatic fine-tuning device 130 can determine the parcel order through the parcel order designator 330 (step S740). Additionally, the automatic fine-adjustment device 130 may select a boundary fine-adjustment method through the boundary fine-adjustment execution unit 350 and execute boundary fine-adjustment according to the selected method (step S750).

In addition, the automatic fine-adjustment device 130, through the boundary fine-adjustment executing unit 350, if the area condition does not match even one lot during the boundary fine-adjustment, changes the lot order again and then executes the boundary fine-adjustment (step S760). In addition, when the automatic fine-adjustment device 130 is adjusted so that the area conditions of all parcels or polygons are completely satisfied, the boundary fine-adjustment can be completed in batches by storing the parcel coordinates through the coordinate fixer 370 (step S770 ).

Figure 8 is an example diagram showing a case of fine-tuning a boundary point on a 1-lot basis, and Figure 9 is an example diagram showing a case of fine-tuning a boundary point in a mixed unit of 2+1 lots.

Referring to FIGS. 8 and 9, the automatic fine-adjustment device 130 may vary the adjustment method depending on the number of parcels considering the area condition when fine-tuning the boundary. As shown in Figure 8, considering the area conditions on a 1-fill basis, the boundary points inherent in the parcel or polygon can be adjusted and simulated in an all-or-interval manner, and as shown in Figure 9, the area conditions can be considered in 2-fill units and adjusted for 2 fills at a time. You can. If the area of 2 lots fails to be adjusted when fine-tuning the boundary at the same time, only the relevant lots can be adjusted on a per-lot basis.

The method and device for automatically fine-tuning parcel/polygon boundary points according to an embodiment automatically fine-adjusts multiple parcel boundary points in batches until they match the desired area for a parcel or polygon on a cadastral map, thereby shortening the adjustment time and reducing the parcel area. Alternatively, it is possible to reduce the coordinate area of a polygon and the area error on the study and increase the work efficiency of cadastral resurvey or conversion of cadastral maps to the World Geodetic System.

Although the present invention has been described above with reference to preferred embodiments, those skilled in the art may make various modifications and changes to the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. You will understand that you can do it.

100: Automatic fine adjustment system for parcel/polygon boundary points
110: User terminal 130: Automatic fine adjustment device
150: database
210: Processor 230: Memory
250: user input/output unit 270: network input/output unit
310: Coordinate unit change unit 330: Lot order designation unit
350: Boundary fine adjustment execution unit 370: Coordinate fixation unit
390: Control unit

Claims (8)

Changing the coordinate units of a plurality of parcel boundary points of a polygon structure and specifying one of the area before the change, the ledger area registered in the study, and the area designated by the user as an area condition;
Based on parcel information including at least one of the parcel lot number, location, area, distribution, point-to-point distance, the area of the specified condition and the error of the area calculated with the coordinates of the boundary point, considering the propagation of the adjacency and area error between the parcels, A parcel order designation step of specifying the adjustment order of multiple parcels;
A boundary point fine-adjustment execution step of performing fine-adjustment by moving the positions of a plurality of parcel boundary points of the polygon structure at regular intervals within an adjustment range in the designated adjustment order; and
Including the step of fixing boundary point coordinates that meet the specified area conditions,
The lot order designation step is
Specify the order of parcels by street number, or
Specify the order from parcels in the central location to parcels on the outskirts, or
Order from the smallest area to the largest area, or
Specify the order according to the direction of parcel distribution, or
In the case of areas with a large area, the order may be specified in the direction of rotation from the center to all directions, or
Prioritize parcels with long distances between boundary points or parcels with large area errors, or
Excluding the area conditions for long parcels of roads or rivers, an exception condition is specified in the adjustment order so that only boundary points are reflected when adjusting adjacent parcels.
An automatic fine-adjustment method for parcel boundary points, characterized in that when the fine-adjustment of the boundary point fails, the adjustment order is changed and readjusted.
delete The method of claim 1, wherein the boundary point fine adjustment execution step is
The adjustment range of boundary points is expanded to a maximum of 7 cm based on 1 cm, and indices are assigned sequentially in specific directions within the adjustment range, and multiple boundary points are sequentially adjusted through the passing method by going through the entire index. A method for automatically fine-tuning parcel boundary points, characterized in that adjustment.
The method of claim 1, wherein the boundary point fine adjustment execution step is
An automatic fine-adjustment method for parcel boundary points, characterized in that the index is set differently for each section of the boundary point adjustment range and adjustment is made through a section method in which multiple boundary points are adjusted based on the index for each section.
The method of claim 3 or 4, wherein the boundary point fine adjustment execution step is
An automatic parcel boundary point fine-adjustment method characterized by sequentially performing boundary point fine-adjustment on a per-lot basis.
delete The method of claim 3 or 4, wherein the boundary point fine adjustment execution step is
An automatic parcel boundary point fine-adjustment method, characterized in that boundary point fine-adjustment is performed on a 2-lot basis, and when adjustment fails, boundary point fine-adjustment is performed on a 1-lot basis for the relevant parcel.
A coordinate unit change unit that changes the coordinate units of a plurality of parcel boundary points of a polygon structure and specifies one of the area before the change, the ledger area registered in the study, and the area designated by the user as an area condition;
Based on parcel information including at least one of the parcel lot number, location, area, distribution, point-to-point distance, the area of the specified condition and the error of the area calculated with the coordinates of the boundary point, considering the propagation of the adjacency and area error between the parcels, A parcel order designation unit that specifies the adjustment order of multiple parcels;
a boundary fine-adjustment execution unit that performs fine-adjustment by moving the positions of a plurality of parcel boundary points of the polygon structure at regular intervals within an adjustment range in the designated adjustment order; and
It includes a coordinate fixing unit that fixes the boundary point coordinates that meet the specified area conditions,
The lot order designation department
Specify the order of parcels by street number, or
Specify the order from parcels in the central location to parcels on the outskirts, or
Specify the order from the parcel with the smallest area to the parcel with the largest area, or
Specify the order according to the direction of parcel distribution, or
In the case of areas with a large area, the order can be specified in the direction of rotation from the center to all directions, or
Prioritize parcels with long distances between boundary points or parcels with large area errors, or
Except for the area conditions of long parcels of roads or rivers, an exception condition is specified in the adjustment order so that only boundary points are reflected when adjusting adjacent parcels.
Automatic fine adjustment device for parcel boundary points, characterized in that when the fine adjustment of the boundary point fails, the adjustment order is changed and readjusted.