KR101983785B1 - Method of automatic generation of indoor map utilizing the ridar equipment - Google Patents

Abstract

The present invention relates to a method of automatically generating an indoor map using a lidar apparatus, and more particularly, to a method of automatically generating an indoor map using a lidar apparatus, , Height, width, and length, extracting data from the extracted data, creating spaces such as walls, ceilings, and floors in the room, and building indoor maps by combining the created spaces And a method for automatically generating an indoor map.
A method for automatically generating an indoor map using the Lada apparatus of the present invention includes a first step of storing original data obtained by measuring a room area of a lidar apparatus in a data storage unit, A second step of extracting data, a third step of classifying the space data of the room area in the one-dimensional data extracted by the data processing unit, combining the room area using the classified space data, and the third step of using the space data And a fourth step of generating indoor map data and storing the indoor map data in a data storage unit, wherein the space data is at least one of a ceiling, a floor, and a wall, and the space data includes a reflection intensity value, .

Description

[0001] The present invention relates to a method of automatically generating an indoor map using a Lada apparatus,

The present invention relates to a method of automatically generating an indoor map using a lidar apparatus, and more particularly, to a method of automatically generating an indoor map using a lidar apparatus, , Height, width, and length, extracting data from the extracted data, creating spaces such as walls, ceilings, and floors in the room, and building indoor maps by combining the created spaces And a method for automatically generating an indoor map.

Conventional map data is generated so that POIs and traffic information signs around roads can be displayed on the screen around the roads. Navigation using such map data can output related information on the screen when the vehicle travels on the road, but can not be used at all when the user enters a room such as a building or an underground space.

In addition, indoor map data which can be applied to a room, which is recently developed, is composed of a two-dimensional or three-dimensional screen using a CAD drawing of a building and is provided to a user.

In order to construct the indoor map data, additional data such as CAD drawings of the building structure should be used. Therefore, there is a problem that it is difficult to generate an indoor map of a building structure that does not have a CAD drawing.

Furthermore, since the CAD drawing contains detailed data of the building structure, it is not easily disclosed, and there is a problem that it is difficult to easily provide the CAD drawing to generate the indoor map.

In order to solve the problems of the related art as described above, the present invention has been developed to provide indoor map data by using a LiDAR device capable of moving indoors, And generating indoor map data by using the measured data.

In addition, the present invention is also applicable to other purposes for incorporating the location information measured by the GPS / INS provided in the LiDAR device into the indoor map data in order to provide the location information to the user utilizing the indoor map data have.

In addition, the present invention generates information such as doors, windows, lighting devices, floor materials, and the like built in a room of a discharged structure using reflection intensity measured using a LiDAR device, There is another purpose for inclusion in the data.

In addition, the present invention generates a space, a node, and a link for an indoor area using position information measured using a GPS / INS provided in a LiDAR device , There is another purpose of providing location information to users utilizing indoor map data.

According to another aspect of the present invention, there is provided a method of generating indoor map data, the method comprising: a first step of storing original data obtained by measuring a room area in a data storage unit; A third step of classifying the space data for the indoor area in the one-dimensional data from which the data processing unit is extracted and combining the indoor area using the classified space data, And a fourth step of generating the indoor map data using the space data and storing the indoor map data in the data storage unit, wherein the space data is at least one of a ceiling, a floor, and a wall, And a reflection intensity value. This is achieved by an indoor map automatic generation method.

Accordingly, the method for automatically generating an indoor map using the Lada apparatus according to the present invention can measure the numerical values of a room, a ceiling, a floor, and the like in a room using a LiDAR The indoor map data can be generated by using the indoor map data. Therefore, the indoor map data can be easily generated without the need for the CAD drawing for the building structure.

In addition, since the present invention can include position information measured by a GPS / INS provided in a LiDAR device in indoor map data, it is possible to provide location information to a user utilizing indoor map data There are other effects.

In addition, the present invention provides a method and apparatus for generating information such as a door, a window, an illumination device, and a floor material constructed in a room of a dry building using reflection intensity measured using a LiDAR device, There is another effect that can include information such as doors, windows, lighting devices, floor materials, etc. in indoor map data.

In addition, the present invention generates a space, a node, and a link for an indoor area using position information measured using a GPS / INS provided in a LiDAR device , There is another effect that location information can be provided to a user utilizing the indoor map data.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing an indoor map generating apparatus for generating indoor map data according to the present invention;
2 is a flowchart illustrating an indoor map generating method for generating indoor map data according to the present invention.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms and the inventor may appropriately define the concept of the term in order to best describe its invention It should be construed as meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

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

FIG. 1 is a block diagram showing an indoor map generating apparatus for generating indoor map data according to the present invention. FIG. 2 is a flowchart showing an indoor map generating method for generating indoor map data according to the present invention .

As shown in FIGS. 1 and 2, the LiDAR device 100 includes a LiDAR (LiDAR) capable of measuring an indoor area and a GPS (Global Positioning System ) And an INS (Inertial Navigation System). On the other hand, as Lada measures the indoor area, the reflection intensity can be measured to generate a color corresponding to the reflection intensity.

The lidar apparatus 100 measures the indoor area (S105), and stores the original data generated by the survey in the data storage unit 210 of the indoor map generating apparatus 200 (S110). The original data to be stored includes the x, y, z coordinates and the reflection intensity of the measurement position acquired by the lidar and includes the position information corresponding to the measurement position by the GPS and the INS together with the name of the survey object .

The lidar apparatus 100 and the indoor map generating apparatus 200 are connected to each other by wire or wirelessly and store the original data in the data storing unit 210 in the indoor map generating apparatus 200.

Thereafter, the data extracting unit 220 loads the original data stored in the data storage unit 210 and extracts the one-dimensional data from the loaded original data (S215).

The one-dimensional data is obtained by extracting information such as the length, width, height, reflection intensity, and name of the indoor area using the points of x, y, and z coordinates of the indoor area of the original data stored in the data storage unit 210 and the reflection intensity Value. That is, one-dimensional data can be generated by using a line connecting a point and a point in original data composed of a plurality of points and reflection intensity, and the reflection intensity and name corresponding thereto.

The data processing unit 230 classifies the space data for the indoor area using the one-dimensional data extracted by the data extracting unit 220 (S220 to S255).

The space data includes components such as a wall, a ceiling, or a floor in the indoor area measured in the one-dimensional data. Furthermore, the wall includes detailed components such as doors, windows, mirrors, frames, facilities installed on pillars or walls, and such detailed components can be included in the space data.

In addition, the ceiling includes detailed components such as a ceiling material, a ceiling-mounted lighting device, or a ceiling-mounted facility, and these subcomponents can be included in the space data.

In addition, the floor includes the detailed components such as the floor material, the stairs formed on the floor, or the facilities installed on the floor, and these detailed components can be included in the space data.

The components of the wall, the ceiling, the floor, and the like included in the space data and the detailed components included in each component are preferably extracted by the reflection intensity value, but the coordinate values measured by the LIDAR apparatus 100 .

The step of classifying the space data in the data processing unit 230 proceeds as follows. First, one or more one-dimensional data is selected and it is determined whether the selected one-dimensional data corresponds to the ceiling area (S220). When the selected one-dimensional data corresponds to the ceiling area, the data processing unit 230 creates a ceiling space using the one-dimensional data corresponding to one or more ceiling areas associated with the ceiling area (S225).

If the one-dimensional data does not correspond to the ceiling area in step S220, it is determined whether the one-dimensional data corresponds to the bottom area (S230). When the selected one-dimensional data corresponds to the bottom area, the data processing unit 230 creates a bottom space using the one-dimensional data corresponding to the at least one bottom area (S235).

If the one-dimensional data does not correspond to the bottom area in step S230, it is determined whether the one-dimensional data corresponds to the wall area (S240). When the selected one-dimensional data corresponds to the wall area, the data processing unit 230 creates a wall space using the one-dimensional data corresponding to at least one floor area associated with the wall area (S245).

If the one-dimensional data does not correspond to the wall area in step S240, the data processing unit 230 extracts the one-dimensional data from the one-dimensional data extracted by the data extracting unit 220 The operation of sorting the space data from step S220 to step S240 is performed again.

If space data is generated in any one of steps S225, S235, and S245, the data processing unit 230 combines the generated space data (S250).

After step S250, the data processing unit 230 determines whether the extracted one-dimensional data corresponding to the room area is the last data (S255). If it is the final data, the data processing unit 230 uses the space data generated by the space generating unit 240 Indoor map data, and stores the generated indoor map data in the data storage unit 210 (S260).

That is, the space generating unit 240 generates the indoor map data using at least one of the ceiling space, the floor space, and the wall space generated by the data processing unit 230, (210).

If the one-dimensional data determined in operation S255 is not the final data, the data processing unit 230 extracts one-dimensional data from the one-dimensional data extracted from the data extracting unit 220, The process of sorting the space data up to

The indoor map data generated in step S260 includes at least one of attribute information on a node or a link to the indoor area, and the attribute information included in the indoor map data can be used in route guidance performed using the indoor map data.

On the other hand, one or more attribute information of the node or the link to the indoor area is included in at least one of the ceiling space, the wall space, and the bottom space.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, Various changes and modifications will be possible.

100: LiDAR device 200: indoor map generating device
210: Data storage unit 220: Data extraction unit
230: Data processor 240: Space generator

Claims (10)

A method for generating indoor map data,
A first step of storing original data obtained by measuring a room area in a data storage unit;
A second step of extracting one-dimensional data including a length, an area, a height, a reflection intensity, and a name of an indoor area from the original data stored in the data storage unit;
A third step of classifying the one-dimensional data from which the data processing unit is extracted into space data of a wall, a ceiling, and a floor in the room area, and combining indoor data using the classified space data; And
And a fourth step of generating the indoor map data using the space data and storing the indoor map data in the data storage unit,
Wherein the Lidar apparatus includes a GPS and an INS, the indoor area measurement location information generated by the GPS and the INS is included in the source data,
Wherein the space data includes a reflection intensity value.
delete The method according to claim 1,
The wall includes a wall component composed of at least one of a door, a window, a mirror, a frame, a column or a facility,
Wherein the ceiling comprises a ceiling component comprising at least one of a material of the ceiling or an illumination device provided in the ceiling,
Wherein the floor comprises a bottom component composed of at least one of a material of the floor or a stair formed at the floor.
delete delete The method of claim 3,
Wherein at least one of the wall component, the ceiling component, and the floor component is extracted using the reflection intensity value.
delete The method according to claim 1,
Wherein in the third step, when the one-dimensional data not classified in the one-dimensional data exists, the space data is generated by repeating the classification of the space data for the indoor area Automatically generate indoor maps.

delete The method according to claim 1,
Wherein the indoor map data includes at least one of attribute information of a node or a link and route guidance can be performed using the attribute information.

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