KR100660945B1 - Virtual mapping method of absolute address - Google Patents

Abstract

According to the present invention, a plurality of flooring materials are limited to one unit, and in one unit, flooring materials having different absolute coordinate information are formed to be connected to each other in a bottom area of a predetermined size. Absolute coordinate information and absolute coordinate information formed adjacent to the outer edge of another floor material adjacent to the floor material are related to the absolute virtual mapping method for mapping the absolute coordinates of the flooring material connected to each other to virtual coordinates. (a) Repeatedly installed in the horizontal and vertical axis direction of the bottom surface of the predetermined size, the absolute coordinate information of the outer edges of the floor materials to be installed jointly the absolute coordinate information while the autonomous mobile robot travels in a predetermined manner on the upper surface of the floor materials installed differently; Obtaining by reading with a coordinate reader; (b) The absolute coordinate information obtained by the coordinate reader is stored in the memory, and if the absolute coordinate information violating any one of the ascending and descending rules of the traveling direction of the autonomous mobile robot is obtained, the absolute coordinate information is immediately before and Displaying the absolute coordinates acquired before the war with the same boundary and storing them in a memory; (c) The number of absolute coordinates of the absolute coordinates stored in the memory of the autonomous mobile robot as the boundary line of the absolute coordinates indicated by the boundary line by one of the ascending and descending order rules is M (row) × N Calculating in a (column) manner and designating one region as a different region; (d) Allocating virtual coordinates sequentially based on any one absolute coordinate formed in one region in a plurality of regions designated as different regions, and when the virtual coordinates are allocated to one region, the absolute coordinates designated as adjacent boundaries. And storing the virtual coordinates in the memory in a manner of being allocated to be extended by the rules of ascending and descending order.

Therefore, even if a plurality of flooring materials (floors, floors, reinforced floors, tiles, etc.) in which different absolute coordinates are formed in the same sized area are installed in a predetermined place, the autonomous mobile robot is generally used for each absolute coordinate based on the area boundary of the flooring material. Relative coordinates are given, and the relative coordinates provide an absolute virtual mapping method that causes the autonomous mobile robot to be recognized as a virtual absolute coordinate.

Description

Virtual mapping method of absolute address

1 is a view showing a floor covering and a floor covering having the same coordinate region.

Figure 2 is a view showing a state and the absolute coordinates installed the flooring material of FIG.

Figure 3 is a view showing a virtual coordinate of the virtual mapping is made to the flooring according to the present invention.

Figure 4 is a flow chart illustrating an absolute coordinate virtual mapping method according to the present invention.

5 is a flowchart illustrating a position recognition method using virtual coordinates.

<Description of the symbols for the main parts of the drawings>

101: Flooring 102: Absolute Coordinates (Information)

103: autonomous mobile robot 104: virtual coordinates

According to the present invention, a plurality of flooring materials are limited to one unit, and in one unit, flooring materials having different absolute coordinate information are formed to be connected to each other in a bottom area of a predetermined size. Absolute coordinate information and absolute coordinate information formed adjacent to the outer edge of another floor material adjacent to the floor material are related to the absolute virtual mapping method for mapping the absolute coordinates of the floor material jointly installed differently to virtual coordinates. Even if a plurality of flooring materials (floors, floors, reinforced floors, tiles, etc.) in which different absolute coordinates are formed in an area are installed in a predetermined place, the relative coordinates are determined by autonomous mobile robots based on the floor boundary of the flooring material as a whole. This relative coordinate is given back to the autonomous mobile robot It relates to the absolute coordinate virtual mapping method to be recognized.

The floor plate or flooring material formed with the absolute coordinates forms figures, symbols, numbers, two-dimensional barcodes, etc. on the surface of the flooring material (floorboard, tiles, floors, etc.), so that they may include different absolute coordinate information.

For example, a plurality of two-dimensional barcodes are formed on a surface of a sheet of paper at predetermined intervals, and the two-dimensional barcodes include different absolute coordinates, so that the two-dimensional barcode is used as a barcode reader while the autonomous mobile robot is traveling on the sheet. It is to read the current position of autonomous robot according to the absolute coordinate value.

The technology related to the two-dimensional bar code, autonomous mobile robot and barcode reader is described in Korean Patent Application Nos. 2004-20981, 2004-48356 and Utility Model Registration Nos. 2004-08728, 2004-18102, 2004- 18103, 2004-24013, 2004-24014 and the like are described in detail.

However, as described above, in order for the autonomous mobile robot to identify a location while traveling in a predetermined space, different absolute coordinate information must be formed on a plurality of flooring materials installed in the predetermined space. The process of including the coordinate information has to be carried out additionally.

That is, due to the characteristics of the flooring material, the two-dimensional barcodes and figures formed on the flooring material must be formed differently each time in the process of producing a large amount of flooring materials having the same size and size, so that the work is very cumbersome and different absolute coordinates. The need to include information makes it difficult to mass produce flooring.

The present invention devised to solve the above problems is to form a figure, characters, two-dimensional bar code, etc. so that different absolute coordinate information is included in the flooring is manufactured in the same size and size, each having the same size and size The flooring material is designated as one unit, and in this designated unit, different world coordinate areas may be formed on the flooring material, and each unit is formed so that absolute coordinates are formed as absolute coordinate information of the same range, and thus, various units. After a plurality of flooring materials are installed in a predetermined space, the autonomous mobile robot first reads the absolute coordinate information and assigns virtual coordinates to each absolute coordinate information so that the absolute coordinate information matches the virtual coordinates. The autonomous mobile robot moves by referring to the virtual coordinate matched with the coordinate information. The purpose is to make the absolute position aware.

The above object is, a plurality of flooring material 101 is limited to one unit, and in one unit, the flooring material 101 formed with different absolute coordinate information 102 is installed to be connected to the bottom surface area of a predetermined size mutually However, the absolute coordinate information 102a proximately formed on the outer edge of any one flooring material 101 and the absolute coordinate information 102b proximately formed on the outer edge of another flooring material 101 adjacent to the flooring 101 are differently connected. In the absolute virtual mapping method for mapping the absolute coordinate 102 of the installed flooring material 101 to the virtual coordinate 104, (a) it is repeatedly installed in the horizontal axis direction and the vertical axis direction of the predetermined size, but is connected The outer frame absolute coordinate information 102 of the flooring materials 101 is a coordinate reader (not shown) while the autonomous mobile robot 103 runs in a predetermined manner on the upper surfaces of the flooring materials 101 installed differently. Obtaining by reading to the next), and; (b) Arrange and store the absolute coordinate information 102 obtained by the coordinate reader in a memory (not shown), and the absolute coordinates violating any one of ascending and descending rules of the driving direction of the autonomous mobile robot 103. When the information 102 is obtained, displaying the acquired absolute coordinates 102 and the absolute coordinates 102 obtained immediately before and before, and storing the same in the memory with the same boundary; (c) The absolute value of the absolute coordinates of the absolute coordinates 102 stored in the memory of the autonomous mobile robot 103, which is one of the columns of the absolute coordinates 102 indicated by the boundary line, is linked to one of ascending and descending order. Calculating the number of coordinates 102 in an M (row) x N (column) manner and designating the number of coordinates 102 as one different area; (d) The virtual coordinates 104 are sequentially assigned based on any one absolute coordinate 102 formed in one region in a plurality of regions designated as one different region, but the virtual coordinates 104 in one region. Is assigned, the virtual coordinate 104 is assigned to be extended by the rules of ascending and descending order in order of priority to the absolute coordinates 102 designated as the adjacent boundary, and absolute coordinate virtual, characterized in that it comprises a step of storing in the memory It is also achieved by the mapping method.

The acquiring of the absolute coordinate information 102 as a coordinate reader may include: (a1) the autonomous mobile robot 103 may travel from one side of an upper portion of the area where the flooring material 101 is installed from one side and the flooring material 101; The boundary line between the flooring material 101 is obtained, and the abscissa information 102 of the flooring material 101 formed between the boundary line and the boundary line on the horizontal axis and the vertical axis, the absolute coordinate information 102 of the horizontal axis, and the other absolute information of the lower axis of the vertical axis ( It is preferable to calculate the absolute coordinate information 102 formed inside any one flooring material 101 with reference to the 102 and the vertical axis upper absolute coordinate information 102.

Hereinafter, the present invention will be described with reference to the accompanying drawings, FIGS. 1 to 4.

First, as shown in FIG. 1, the flooring material 101 of which virtual coordinates are virtually mapped according to the present invention is formed by forming a relatively smaller area than the flooring material 101 that is continuously produced, such as wood floor, reinforced floor, and tile. When applied to the flooring material 101 that can be formed at the same time each one is formed at the same time can be said to be efficient, the flooring material 101 is produced continuously in length and width, such as floor coverings, the scope of the present invention It should be regarded as belonging to.

Here, all the drawings referred to in the present invention describe a two-dimensional matrix as shown, but this is expressed or illustrated in order to support a clear interpretation of the drawings and the detailed description of the present invention. As shown, it is not limited to the form of the two-dimensional array.

As shown in FIG. 1, the flooring material 101 of the present invention designates the absolute coordinate information 102 having any one of a predetermined character, graphic, and bar code in a predetermined range, and is limited to a single floor. It is formed in 101 sequentially.

For example, as shown in the figure, the range of the absolute coordinate information 102 is limited to 1 to 1000 times, and the flooring material 101 such as floors, reinforced floors, tiles, etc., which are sold in one unit, 90 pieces (FIG. 1). Is an illustration of the floor), so that the absolute coordinate information 102 within the above range can be formed.

That is, if it is assumed that the virtual serial number is specified from 1 to 90 to each of the 90 floors consisting of one unit, the absolute coordinate information 102 is sequentially formed on the 90 floors from 1 to 1000 times. The absolute coordinate information 102 formed on one floor does not overlap another floor.

In addition, the absolute coordinate information 102 formed on any one floor is sequentially formed at predetermined intervals in the up, down, left, and right directions as shown in FIG. 1 so that the coordinate reader can read it.

In general, when flooring is installed on the floor, the floor area and size of a floor are very narrow and small, and therefore dozens or hundreds of floors are installed in a home or office having an average size of 20 pyeong. .

Therefore, if 90 floors consisting of one unit (hereinafter, referred to as a set) are constructed in the space of about 20 pyeong, usually several sets or dozens of sets must be used to install all of them.

When the flooring 101 is constructed, that is, when the floor is constructed, the flooring 101 (hereinafter, the floor will be described as an example) in which different absolute coordinate information 102 is formed in one unit has a predetermined size floor. Absolute coordinate information 102 formed adjacent to each other in the surface area but adjacent to the floor edge of one floor and absolute coordinate information 102 formed adjacent to the edge of another floor adjacent to the floor are shown in FIG. 2. As described above, the floors are connected to each other differently.

Accordingly, a plurality of floors have a plurality of floors in which the same absolute coordinate information 102 is formed, and when the floors are constructed on the floor by the contractor, the plurality of floors are mixed with each other.

At this time, when constructing each of the floor sets described above, if each floor is designated in one direction, the upper direction and the lower direction, when only one direction, the absolute coordinate information 102 formed on the floor is left to right (or Since the right to left), the bottom to the top (or the top to the bottom) are formed in a sequential ascending or descending order, the absolute coordinate information 102 disposed on the boundary line with adjacent floors may not have the same coordinates.

In addition, as shown in Figure 2, typically, the floor must be constructed in a multi-stage construction to achieve a solid construction in some cases when the situation that must cut the floor in some cases, as shown in the half floor or 1 / Since three floors are constructed, even if several sets of floors are constructed in one space, the same absolute coordinate information 102 cannot be disposed adjacent to each other.

However, since a plurality of sets are constructed in one space, floors (areas) having the same coordinate area may exist. However, in the same area, the autonomous mobile robot 103 is different because the coordinates of the same area and the adjacent area are different from each other. After traveling by a certain distance can be solved by newly recognizing the absolute coordinate (102).

As described above, in order to make the autonomous mobile robot 103 traveling on the flooring material 101 having the absolute coordinates 102 formed thereon recognize the absolute coordinates, FIGS. 2, 3, and 4 are shown. If described with reference to:

First, FIG. 2 is a view illustrating a state in which a plurality of floors are designated as one unit (hereinafter, referred to as a set), and a plurality of sets are constructed in one space, and the illustrated matrix coordinates represent the absolute coordinates 102. It is displayed.

3 is a diagram illustrating a virtual coordinate 104 mapped to the absolute coordinate 102.

First, as shown in FIG. 2, as the autonomous mobile robot 103 travels in a predetermined manner on a floor surface on which floors having different or identical absolute coordinates 102 areas are constructed, embedded absolute coordinate information 102. In operation S1, the method reads the acquired coordinate reader and acquires it.

Here, the predetermined driving method may be one of the mapping algorithms of the autonomous mobile robot 103. Since this algorithm appears in a very variable form in the programming process, this cannot be specified, but the present invention For a detailed description of any one of the driving method as an example as follows.

As shown in FIG. 2, first, the absolute coordinate 102 formed in the driving path is obtained while traveling linearly along the wall from the end of the floor surface on which the flooring material 101 is constructed, and when the obstacle or wall surface is reached, the direction is changed. By repeatedly using the driving method of returning by resetting the adjacent path spaced apart from the previous driving path by a predetermined distance, as shown in FIG. 2, the driving pattern has a zigzag pattern.

In this case, when the space is formed in an irregular shape, the autonomous mobile robot 103 travels in the zigzag pattern and sets a virtual rectangular space based on the irregularly protruding wall surface, and then the autonomous mobile robot. This problem can be solved by adding a variable to the program that allows 103 to travel in a straight line and calculate the distance to zigzag the virtual rectangular space.

Therefore, the driving method of the autonomous mobile robot 103 to obtain the absolute coordinate information 102 as described above may appear in a variety of cases, the present invention is not limited to this, hereinafter such a driving method It will be described by considering a known conventional method.

As described above, when the autonomous mobile robot 103 acquires the absolute coordinate information 102 in a predetermined driving manner, the obtained absolute coordinate information 102 is stored in the memory (S2), and the obtained absolute coordinate information ( When the absolute coordinate information 102 that violates one of the ascending and descending rules 102 is obtained, the acquired absolute coordinate 102 and the absolute coordinate information 102 acquired immediately and before are displayed with the same boundary. A step of storing in the memory is performed (S3).

That is, as shown in Fig. 2, the autonomous mobile robot 103 passes (99,32), (99,33), (99,34) ... When (99,38), (99,39), (99,40) is passed through, in the drawing presented in the present invention, the absolute coordinate information 102 increases by 1 in the ascending order when moving to the right. Because of this method, when the H area is reached via (99,40) of the E area, (49,1), (49,2), (49,3) .... (49,8), (49 , 9) and (49, 10) to travel on the absolute coordinate information (102).

Therefore, the absolute coordinate information 102 obtained through entering the region E through the region E will obtain (99, 40) and (49, 1).

At this time, the control unit has obtained that the absolute coordinate information 102 is in violation of the ascending order (or descending order) as the row is changed from 99 to 49, and the column is in violation of the ascending order (or descending order) by changing from 40 to 1. This can be known by comparison of the information 102.

Therefore, the control unit moves the area E in the path ① to change the arrangement of the absolute coordinate information 102, that is, the first absolute path information 102 of the path E of the area E and the immediately preceding absolute coordinate information 102 and the H area. When the first absolute coordinate information 102 and the next absolute coordinate information 102 are obtained and stored in the memory, the boundary flag is stored together in the absolute coordinate information 102 to obtain the absolute coordinate information 102. After the end, the E region and the H region can be distinguished when the absolute coordinate information 102 map is loaded.

The division of the boundary line is equally applied to the horizontal traveling ① and the vertical traveling ②, and when the autonomous mobile robot 103 acquires all the absolute coordinates 102 of the entire area, the absolute coordinate information stored in the memory. Calculating the number of absolute coordinates 102 in the horizontal direction and the vertical direction to any part of the array of the absolute coordinate information 102 indicated by the boundary line in 102, which is linked by any one of ascending and descending order ( M (row) × N (column)) calculating the absolute coordinate information 102 formed in any one region and designating it as one region (S4), wherein the calculated absolute coordinate information 102 is It is preferable to check whether the absolute coordinate information 102 obtained by traveling of the autonomous mobile robot 103 compares with each other.

As described above, after the entire floor area is designated as a plurality of areas, the virtual coordinates 104 are sequentially assigned based on the absolute coordinates 102 formed in any one area, but the virtual coordinates 104 are allocated to one area. Is allocated, the step of sequentially allocating the virtual coordinates 104 first to another adjacent region (the region with the absolute coordinate information 102 designated as adjacent boundaries) is performed (S5).

Therefore, the virtual coordinate 104 is assigned a continuous coordinate value in the left and right up and down directions from any point of the entire area to obtain the absolute coordinate information 102, the virtual assigned to this absolute coordinate information 102 By referring to the coordinates 104, the autonomous mobile robot 103 can refer to it in the autonomous movement algorithm, even if it is located at any coordinate of any area of the entire area.

Here, in the step of acquiring the absolute coordinate information 102 as a coordinate reader, the autonomous mobile robot 103 travels from one side of the upper part of the area where the flooring material 101 is installed from one side and the flooring material 101 and the flooring material 101. Acquisition of the boundary line between the horizontal axis and the horizontal axis of the flooring material 101 formed between the boundary line and the boundary line in the vertical axis, the absolute coordinate information 102 and the other end absolute coordinate information 102 of the horizontal axis and the vertical axis bottom absolute coordinate information 102 and the vertical axis It is desirable to be able to calculate the absolute coordinate information 102 formed in any one flooring material 101 with reference to the upper absolute coordinate information 102.

On the other hand, it can be implemented to be able to recognize the position of the autonomous robot with reference to the virtual coordinates 104, the position recognition method using the virtual coordinates 104 mapped to the memory according to the present invention, When the coordinate reader of the autonomous mobile robot 103 obtains the absolute coordinate information 102 (S10), the controller performs a step of searching the memory for a region to which the acquired absolute coordinate information 102 belongs (S11).

In this case, if there is only one region to which the absolute coordinate information 102 belongs, the virtual coordinate allocated to the absolute coordinate information 102 of the corresponding region is searched and then referred to by the autonomous movement algorithm (S16). When at least two regions to which the absolute coordinate information 102 belongs are found (S12), the absolute coordinate 102 is acquired while driving to an adjacent boundary line (S13), and the boundary absolute coordinate 102 of another region adjacent to the boundary line is obtained. In operation S14, the method searches for the absolute coordinate 102 region matching the pre-movement region and the post-movement region in the memory.

That is, when the user lifts the autonomous mobile robot 103 from a position moved by autonomous driving of the autonomous mobile robot 103 and moves to a predetermined place, that is, the autonomous mobile robot 103 and the absolute coordinate 102 and When the autonomous mobile robot 103 is moved arbitrarily after the virtual coordinate 104 is not referred to, the autonomous mobile robot 103 refers to the virtual coordinate 104 by the last acquired absolute coordinate information 102. For the path to be moved forward, the absolute acquired coordinate information 102, newly acquired absolute coordinate information 102, and the virtual coordinate 104 are referred to the autonomous movement algorithm.

However, if the absolute coordinate 102 and the virtual coordinate 104 as described above is placed in a predetermined place, the virtual coordinate 104 is referred to on the basis of the incorrect absolute coordinate information 102, thereby autonomously moving. There may be a problem that an error occurs in the algorithm.

Accordingly, in the present invention, even when the absolute coordinate information 102 and the virtual coordinate 104 is driven with reference to the autonomous movement algorithm, the absolute coordinate information 102 designated as the boundary before the movement is obtained when the absolute coordinate information 102 is obtained. After the movement, the absolute coordinate information 102 designated as the boundary line is obtained so that the absolute coordinate information 102 obtained in the region after the movement may be referred to the autonomous movement algorithm (S15).

That is, when the autonomous mobile robot 103 located in the absolute coordinates 102 (49, 15) of the B area is moved to the position of (53, 15) of the K area, as shown in FIGS. The autonomous mobile robot 103 acquires the absolute coordinate 102 of (53, 15) of the K area, and recognizes this coordinate as the coordinate of the B area when the coordinate is located in the B area. Travel is made by referring to the virtual coordinate 104 assigned to.

However, if the autonomous mobile robot 103 enters the N area at a time outside the K area, the absolute coordinates 102 (3, 41) of the F area should be obtained, but the absolute coordinates 102 of the N area ( 3, 91 are obtained, the absolute coordinate information (matching the absolute coordinate 102 and the virtual coordinate 104 to the autonomous movement algorithm immediately and matching the coordinates of the pre-movement region and the coordinates of the post-movement region (boundary coordinates) 102 is searched in the memory to search the matching absolute coordinate information 102 and the region to which the absolute coordinate information 102 belongs, and the virtual coordinate 104 matching the absolute coordinate 102 refers to the autonomous movement algorithm. Will be to perform the step (S15).

Therefore, as described above, even if the autonomous mobile robot 103 does not move while acquiring the absolute coordinates 102 sequentially, the newly arrived flooring material 101 always passes at the point of passing through the boundary line of any one flooring material 101. By storing the region of in the memory so that the virtual coordinate 104 can be referred to based on this region, the information and the region information for the virtual coordinate 104 according to the absolute coordinate 102 are updated or corrected.

As described above, the present invention constructs a plurality of flooring sets in which the same group of absolute coordinate information is formed, and only the absolute coordinates of the boundary line when constructing the flooring differs, and assigns virtual coordinates to these absolute coordinates, so that the autonomous mobile robot When the absolute coordinates are acquired in the area, it is possible to drive by referring to the virtual coordinates assigned to the acquired absolute coordinates, which enables mass production of flooring materials, thereby reducing the cost of the product. In particular, the movement path of the autonomous mobile robot Even if the virtual coordinates to be referred to due to the absolute coordinates are incorrect, the autonomous mobile robot performance is corrected so that the correct virtual coordinates can be referred to by correcting the reference of the invalid virtual coordinates when passing through any floor. This has the effect of being able to be improved.

Claims (2)

A plurality of flooring materials are limited to one unit, and in one unit, flooring materials having different absolute coordinate information are formed to be connected to each other in a bottom area of a predetermined size, but the absolute coordinate information formed adjacent to an outer edge of any flooring material. In the absolute virtual mapping method for mapping the absolute coordinates of the flooring material in which the adjacent coordinate information adjacently formed on the outer edge of another flooring material adjacent to the flooring material is different from each other. (a) Repeatedly installed in the horizontal and vertical axis direction of the bottom surface of the predetermined size, the absolute coordinate information of the outer edges of the floor materials to be installed jointly the absolute coordinate information while the autonomous mobile robot travels in a predetermined manner on the upper surface of the floor materials installed differently; Obtaining by reading with a coordinate reader; (b) The absolute coordinate information obtained by the coordinate reader is stored in the memory, and if the absolute coordinate information violating any one of the ascending and descending rules of the traveling direction of the autonomous mobile robot is obtained, the absolute coordinate information is immediately before and Displaying the absolute coordinates acquired before the war with the same boundary and storing them in a memory; (c) The number of absolute coordinates of the absolute coordinates stored in the memory of the autonomous mobile robot as the boundary line of the absolute coordinates indicated by the boundary line by one of the ascending and descending order rules is M (row) × N Calculating in a (column) manner and designating one region as a different region; (d) Allocating virtual coordinates sequentially based on any one absolute coordinate formed in one region in a plurality of regions designated as different regions, and when the virtual coordinates are allocated to one region, the absolute coordinates designated as adjacent boundaries. And storing the virtual coordinates in the memory by extending the virtual coordinates according to the ascending and descending rules. The method of claim 1, Acquiring the absolute coordinate information with a coordinate reader, (a1) The autonomous mobile robot obtains a boundary line between the flooring material and the flooring material while traveling from one side to the upper part of the area where the flooring material is installed, and the horizontal axis of the flooring material formed between the boundary line and the boundary line on the horizontal axis and the vertical axis. Absolute coordinate virtual mapping method, characterized in that to calculate the absolute coordinate information formed in any one flooring material with reference to the other absolute coordinate information, the lower absolute coordinate information on the vertical axis and the upper absolute coordinate information on the vertical axis.

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