KR20160059471A - Robot cleaner and controlling method of the same - Google Patents

Abstract

A method for controlling a robot cleaner is disclosed. The present invention divides an entire cleaning area into small areas, easily calculates an entire route using a moving route within the small area and connecting points between the small areas, does not generate an entire cleaning map when the entire cleaning area is increased or a non-cleaning area is searched, and easily updating the entire route using the preliminarily stored moving route within the small area and the connecting point between the small area in order to reduce a calculation amount generating the entire moving route or the entire cleaning map and calculation time, reduce storing load, maintain optimal moving performance, and improve cleaning performance and cleaning efficiency.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a robot cleaner,

The present invention relates to a robot cleaner, and more particularly, to a robot cleaner having improved moving performance and cleaning performance by calculating a total path according to a connection point between a small area or a moving path within a small area and the connection point, And a control method thereof.

In general, robots have been developed for industrial use and have been part of factory automation. In recent years, medical robots, aerospace robots, and the like have been developed, and household robots that can be used in ordinary homes are being developed.

A representative example of the domestic robot is a robot cleaner, which is a type of household appliance that sucks and cleanes dust or foreign matter around the robot while traveling in a certain area by itself. Such a robot cleaner is generally equipped with a rechargeable battery and has an obstacle sensor capable of avoiding obstacles during traveling, so that it can run and clean by itself.

In order to clean all the areas while the robot cleaner runs on its own, a cleaning map should be created and a cleaning area such as a cleaned area and a cleaning area should be determined.

The robot cleaner needs to avoid an obstacle when moving inside the cleaning space, and to create a movement path to move the robot in the shortest distance. At this time, there is a problem that the robot cleaner according to the related art requires a long calculation time to calculate the entire movement path and the shortest distance as the cleaning space increases. Further, the robot cleaner according to the related art needs to know the cleaning map for the entire cleaning area in order to calculate the entire path and the shortest distance, and accordingly, a large amount of memory is required to store the cleaning map for the entire cleaning area There is a problem.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide a cleaning method and a cleaning method for the entire cleaning area by dividing the entire cleaning area into small areas, and using the connection points between the small areas, And to provide a control method of the robot cleaner.

In addition, the present invention does not regenerate the entire cleaning map when the entire cleaning area increases or searches the uncleaned area, and facilitates the entire path by using the movement path in the pre-stored small area and the connection point between the small areas And a control method of the robot cleaner.

According to an aspect of the present invention, there is provided a robot cleaner for cleaning a cleaning area by dividing a cleaning area into a plurality of small areas.

The robot cleaner includes: a drive unit for moving the robot cleaner; And a control unit for controlling the drive unit.

The plurality of small regions may include a first region, a second region that shares a first boundary of the first region with the first region, and a second region that intersects the first boundary of the first region, And a third region sharing a second boundary of the first region with the first region.

Wherein the control unit generates a first connection point on the first boundary side, creates a second connection point on the second boundary side, moves the robot cleaner located in the third area to the second area The control unit controls the drive unit such that the robot cleaner passes the second connection point and the first connection point.

The path from the second connection point to the first connection point includes a straight path.

The control unit controls the drive unit such that the robot cleaner passes the first connection point to move the robot cleaner located in the second area to the first area.

If a new area is present around one or more of the first to third areas, the control unit adds a connecting point to at least one of the first to third areas and the boundary area of the new area .

Within at least one of the first to third regions, the control unit controls the drive unit such that the robot cleaner moves in a zigzag manner.

And a camera for photographing a forward or upward image in a moving process in the cleaning area.

The robot cleaner and the control method thereof according to the present invention can reduce the amount of computation and computation time for computing a movement path by easily calculating an entire path using a connection point of a small area previously stored or a movement path within a small area and the connection point And it is possible to maintain an optimum moving performance.

In addition, the robot cleaner and its control method according to the present invention may not generate the entire cleaning map in the case where the entire cleaning area is increased or the non-cleaning area is searched, The entire path can be easily updated to reduce the calculation amount and calculation time for generating the entire cleaning map, reduce the storage burden, maintain the optimum moving performance, and improve cleaning performance and cleaning efficiency.

1 is a perspective view schematically showing the appearance of a robot cleaner according to the present invention;
FIG. 2 is a block diagram schematically showing a configuration of a robot cleaner according to the present invention; FIG.
3 is a diagram for explaining an operation of calculating a total path using a movement path in a plurality of small areas and a connection point between the small areas in the present invention;
4 is a diagram for explaining an operation of calculating an entire path using a connection point between a plurality of small regions in the present invention;
5 is a flowchart schematically showing a control method of the robot cleaner according to the present invention.

Hereinafter, a robot cleaner and a method of controlling the robot cleaner according to the present invention will be described in detail with reference to the accompanying drawings.

Referring to FIGS. 1 and 2, a robot cleaner according to the present invention includes a drive unit 500 for driving at least one wheel to move a robot cleaner, a cleaning unit 500 for dividing a cleaning area into a plurality of small areas, A control unit (200) for calculating a total path based on a connecting point or a moving path in the small area and the connecting point, and controlling the driving unit (500) And a storage unit 300 for storing the entire path.

In the robot cleaner according to the present invention, the control unit 200 connects the movement paths in the small area through the connection point to calculate the entire path, and causes the robot cleaner to move or clean according to the entire path .

Referring to FIG. 3, the robot cleaner searches a cleaning area to generate a cleaning map, and divides the cleaning area into a plurality of small areas. The control unit (200) generates a movement route in the plurality of small areas and creates a connection point between the small areas. Also, the control unit 200 can easily calculate the entire path by connecting the movement paths within the small area through the connection point. The robot cleaner moves or performs cleaning according to the calculated total path.

In the robot cleaner according to the present invention, the control unit 200 connects the connection points to calculate the entire path, and causes the robot cleaner to move or clean the robot cleaner along the entire path.

Referring to FIG. 4, the robot cleaner searches a cleaning area to generate a cleaning map, and divides the cleaning area into a plurality of small areas. Here, the plurality of small regions are connected to adjacent small regions through a plurality of connection points. The control unit 200 calculates the entire path by connecting the shortest path between the connection points and connecting the shortest paths between the connection points. The control unit 200 transmits a driving signal to the driving unit 500 to move the robot cleaner according to the calculated total path or moves the robot cleaner to the target small area according to the calculated total path, Clean the area. That is, when the robot cleaner tries to move from the current position to another small region, the control unit 200 calculates a path from the current position to the connection point between the small region including the current position and the adjacent small region, The entire path can be generated up to the small area to be processed.

In addition, in the robot cleaner according to the present invention, when the cleaning area is increased, the control unit (200) determines whether the small area adjacent to the increased cleaning area among the small areas stored in the storage unit And generates a movement route from the connection point of The control unit 200 divides the increased cleaning area into small areas or creates a moving path in the increased cleaning area with respect to the entire area, And connects the movement path to the connection point of the adjacent small area. Then, the control unit 200 can calculate the entire modified path easily by adding the movement path for the increased cleaning area to the entire path previously stored.

Referring to FIG. 2, the robot cleaner according to the present invention includes an obstacle detection unit 120 for detecting an obstacle in the cleaning area, a position recognition unit 110 for recognizing the position of the robot cleaner, .

The position recognition unit 110 includes an optical flow sensor for acquiring downward image information using light, an encoder connected to a wheel motor for driving the wheels of the robot cleaner to detect speed, a gyro sensor for detecting the rotational speed of the robot cleaner, One or more of the sensors can be used. Also, it is possible to use a camera for photographing a forward or upward image by the position recognizing unit 110 and determining the absolute position of the robot cleaner.

As the obstacle detection unit 120, signals such as a supersonic sensor, an infrared sensor, an RF sensor, and the like are transmitted, and the position of the obstacle and the distance A collision sensor that detects an obstacle by collision with an obstacle, or the like can be used.

The robot cleaner according to the present invention further comprises an input unit 600 having one or more buttons for directly receiving the control command. For example, the input unit 600 may include an OK button for inputting a command for confirming the cleaning area, a cleaning map, a small area, a connection point, a movement path, and a complete path, a setting button for inputting a command to set, A cleaning button for inputting a command for performing a cleaning operation based on the set areas, a stop button for inputting a command for stopping the cleaning operation, a reset button for inputting a command for stopping the cleaning operation, And < / RTI >

The robot cleaner according to the present invention further comprises an output unit (700) for outputting at least one of a movement path in a small area, a connection point between the small areas, and the whole path. The output unit 700 outputs information detected or recognized through the obstacle detection unit 120 or the position recognition unit 110. [ The output unit 700 displays the cleaning area, a cleaning map generated through the control unit 300, a plurality of small areas that divide the cleaning areas, a connection point of the small areas, a movement path, do. In addition, the output unit 700 may further display status information such as a current status of each unit constituting the robot cleaner, a current cleaning status, and the like. The output unit 700 may be any of a light emitting diode (LED), a liquid crystal display (LCD), a plasma display panel, and an organic light emitting diode (OLED) And may be formed of one element. At this time, the input unit 600 and the output unit 700 may have the form of a touch screen capable of both input and output.

The robot cleaner according to the present invention further includes a power unit 400 having a power supply unit that can be charged and supplies power to the robot cleaner. The power supply unit 400 supplies the operation power for moving the robot cleaner and performing the cleaning, and supplies the charging current from the charging stand when the remaining amount of the battery is insufficient.

Referring to FIG. 5, a method of controlling a robot cleaner according to the present invention includes a step S100 of searching for a cleaning area, a step S210 of dividing the cleaning area into a plurality of small areas, (S230) of creating a movement path, creating a connection point between the small regions, storing the small region information including a movement path in the small region and a connection point between the small regions (S230) And calculating a total path based on the connection point or the movement path within the small area and the connection point (S240). The control method of the robot cleaner according to the present invention further comprises storing the calculated total path (S250). The construction of the apparatus will be described with reference to Figs. 1 and 2. Fig.

In the control method of the robot cleaner according to the present invention, the step of calculating the entire path (S240) may include calculating the entire path by connecting the connection points.

Referring to FIG. 4, the robot cleaner searches a cleaning area to generate a cleaning map, and divides the cleaning area into a plurality of small areas. The plurality of small regions may be connected to adjacent small regions through a plurality of connection points. The control method connects the shortest path between the connection points and connects the shortest paths between the connection points to calculate a total path. The control method moves the robot cleaner according to the calculated total path or moves the robot cleaner to the target small area according to the calculated total path, and then cleans the small area. That is, when the robot cleaner tries to move from a current position to another small region, the control method calculates a path from the current position to the connection point between the small region including the current position and the adjacent small region, It is possible to generate the entire path to the area.

In the control method of the robot cleaner according to the present invention, the step of calculating the entire path (S240) includes calculating the entire path by connecting the movement paths in the small area through the connection point.

Referring to FIG. 3, the robot cleaner searches a cleaning area to generate a cleaning map, and divides the cleaning area into a plurality of small areas. In addition, the control method generates a movement path in the plurality of small areas and creates a connection point between the small areas. The control method can easily calculate the entire path by connecting the movement paths in the small area through the connection point. The robot cleaner moves or performs cleaning according to the calculated total path.

A method of controlling a robot cleaner according to the present invention includes the steps of: creating a movement path in an increased cleaning area when the cleaning area is increased (S310); adding a movement path in the increased cleaning area to the stored overall path S330). The control method may further include a step (not shown) of searching for a small area adjacent to the increased cleaning area, and the step of generating a moving path in the increased cleaning area (S310) And a movement path in the increased cleaning area is generated from the connection point. The control method may further include storing the increased area information including the moving route and the connection point (S320).

In the control method, when the cleaning area increases, a movement path is created from a connection point with the small areas adjacent to the increased cleaning area among the small areas stored in the storage unit. In the case where the cleaning area is increased such as finding a non-cleaning area, the control method divides the increased cleaning area into small areas or creates a moving path in the increased cleaning area with respect to the entire area, To the connection point of the adjacent small area. Then, the control method can calculate the entire modified path easily by adding the movement path for the increased cleaning area to the entire path previously stored.

The robot cleaner and the robot cleaner control method according to the present invention clean the robot cleaner and the robot cleaner in units of cells, store the connection point with the adjacent small area in the small area, and then store the movement path between the connection points. At this time, the movement path is a shortest path between the connection points, a detected movement path, or a movement path according to a method of performing the cleaning. Then, when the cleaning area is expanded, the control method of the robot cleaner and the robot cleaner creates a travel route only up to the connection point with the stored small area, and the subsequent route follows the previously stored route. By doing so, the robot cleaner and the control method thereof according to the present invention can save and update the movement path that has been successfully moved or cleaned, thereby shortening the calculation time and improving the movement performance.

Hereinafter, an example of movement of the robot cleaner in a plurality of small regions will be described.

3 and 4, the plurality of small regions may include a first region 810 and a first region 810 that shares a first boundary 850 of the first region 810 with the first region 810 A third region 830 sharing a second boundary 860 of the first region 810 intersecting the first boundary 850 with the first region 810; . ≪ / RTI >

The first region 810, the second region 820 and the third region 830 included in the plurality of small regions are divided into the second region 820 around the first region 810, And the third region 830 may be disposed close to the first region 810. [

The control unit 200 may create a first connection point 852 on the first boundary side 850 and a second connection point 862 on the second boundary side 860. [

The control unit 200 controls the robot cleaner to move the robot cleaner to the drive unit (not shown) such that the robot cleaner passes through the second connection point 862 and the first connection point 852 to move the robot cleaner located in the third area 830 to the second area 820. [ 500).

The control unit 200 moves the robot cleaner from the third region 830 to the second region 820 through the second connection point 862 to move the robot cleaner located in the third region 830 to the second region 820. [ (810). The control unit 200 controls the robot cleaner to move from the second connection point 862 to the first connection point 852 in the first region 810 and finally to the first connection point 852 2 region 820 in the second embodiment.

The path from the second connection point 862 to the first connection point 852 may include a straight path.

The control unit 200 controls the robot cleaner to move the robot cleaner moved from the third region 830 to the second region 820 to the first region 810 in the above- It is possible to control the driving unit 500 to pass the driving force.

 The control unit 200 can additionally generate a connection point on the boundary of the new area if a new area exists around the first area 810, the second area 820 and the third area 830 . For example, when a fourth area 840, which is a new area, is present in the vicinity of the first area 810, the control unit 200 controls the boundary area between the fourth area 840 and the first area 810 And the third connection point 872 on the boundary side 870.

In at least one of the first to fourth regions 810 to 840, the control unit 200 can control the drive unit 500 so that the robot cleaner moves in a zigzag manner as shown in Fig.

As another example, the plurality of small regions may include a first region 810, a third region 830 that shares the second boundary 860 with the first region 810, And a fourth region 840 that shares the third boundary 870 of the first region 810 facing the side 860 with the first region 810.

The control unit may generate a second connection point 862 on the second border side 860 and a third connection point 872 on the third border side 870. [

The robot cleaner located in the third region 830 may be moved to an additional connection point 830 on the other boundary side (e.g., the first boundary side 850) of the first region 810 The control unit 200 determines that the robot cleaner has moved to the third connection point 872 after passing through the first connection point 852 which is an additional connection point at the second connection point 862. In the case where the first connection point 852 is present, It is possible to control the driving unit 500 to pass the driving force.

That is, when moving the robot cleaner located in the third area 830 to the fourth area 840, the first area 810 is connected to the second connection point 862 and the third connection point 872, When the first connection point 852 is present, the control unit 200 moves from the third area 830 to the first area 810 through the second connection point 862, The driving unit 500 may be controlled to move to the first connection point 852. [ The control unit 200 may control the driving unit 500 such that the robot cleaner moved to the first connection point 852 moves to the fourth region 840 through the third connection point 872. [

The second boundary 860 and the third boundary 870 may be parallel and the first boundary 850 may intersect the second boundary 860 and the third boundary 870.

As described above, in the robot cleaner and the control method thereof according to the present invention, the entire cleaning area is divided into small areas, and the entire path is easily calculated using the movement path in the small area and the connection point between the small areas , The entire cleaning map is not regenerated when the entire cleaning area is increased or the untreated area is searched and the entire path is easily updated using the movement path in the small area and the small area in advance, It is possible to reduce the calculation amount and the calculation time for generating the route or the entire cleaning map, reduce the storage burden, maintain the optimum moving performance, and improve the cleaning performance and the cleaning efficiency.

110: position recognition unit 120: obstacle detection unit
200: control unit 300: storage unit
400: power supply unit 500: drive unit
600: input unit 700: output unit

Claims (6)

A robot cleaner capable of cleaning a cleaning area by dividing a cleaning area into a plurality of small areas,
A driving unit for moving the robot cleaner; And
And a control unit for controlling the drive unit,
The plurality of small regions may include:
A first region,
A second region sharing a first boundary of the first region with the first region,
And a third region sharing a second boundary of the first region that intersects the first boundary of the first region with the first region,
The control unit generates a first connection point on the first boundary side,
Creating a second connection point on the second boundary side,
Wherein the control unit controls the drive unit such that the robot cleaner passes through the second connection point and the first connection point in order to move the robot cleaner located in the third area to the second area. The method according to claim 1,
Wherein the path from the second connection point to the first connection point includes a straight path. The method according to claim 1,
Wherein the control unit controls the drive unit such that the robot cleaner passes the first connection point to move the robot cleaner located in the second area to the first area. The method according to claim 1,
If there is a new area around one or more of the first to third areas,
Wherein the control unit further generates a connection point on at least one of the first to third areas and a boundary area of the new area. The method according to claim 1,
Within one or more of the first to third regions,
Wherein the control unit controls the drive unit such that the robot cleaner moves in a zigzag manner. The method according to claim 1,
Further comprising a camera for photographing a forward or upward image in a moving process in the cleaning area.

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