JP2007066086A - Robot system and robot management apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To easily confirm the current state (operation executing/moving/standby/abnormal state, etc.) of a mobile robot. <P>SOLUTION: A plurality of display panels each of which has at least one light emitting component whose light emission is controlled are arranged on the floor surface of a passage of the mobile robot and a plurality of pressure sensors each of which is arranged so as to measure pressure based on the weight of the mobile robot are arranged on respective points (base points) on which the display panels are arranged on the passage. A position management part in a robot management apparatus detects the base point on which the mobile robot exists out of the plurality of base points on which the plurality of display panels are respectively arranged on the basis of a pressure value measured by each of the plurality of pressure sensors. A display control part controls the light emission of the plurality of display panels on the basis of the state of the mobile robot, which is transmitted from the mobile robot and the base point detected by the position management part. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a mobile robot, and more particularly to a mobile robot system for displaying the status of a mobile robot.

  In a mobile robot used in a factory or the like, in Patent Document 1, a position confirmation lamp is provided in the mobile robot so that it can be easily confirmed where the mobile robot is in the factory. Moreover, in patent document 1, the display lamp for displaying the operation state in the mobile robot itself is provided.

In order to give a command to a mobile robot, for example, in Patent Document 2, a plurality of colors are arranged two-dimensionally, and a color marker that associates specific information with the two-dimensional arrangement of colors is used. . The mobile robot searches for and tracks this color marker, decodes specific information, and recognizes the location, thereby enabling autonomous traveling.
Japanese Patent Laid-Open No. 7-24750 Japanese Patent Laid-Open No. 11-272328

  In recent years, mobile robots have been developed that coexist with humans and support the lives of, for example, the elderly and the physically disabled. In the case of mobile robots used in such homes and facilities, When help is needed, it is inconvenient if the mobile robot can not immediately see what state it is in, where it is, and what it is doing.

  However, in the past, mobile robots used in homes and facilities that support daily life are moved when a person sees the mobile robot, when the mobile robot disappears from view, or when the mobile robot is not found. There is a problem that it is not possible to display the state of the robot (what it is doing), where it is going, where it is, etc. in a way that can be easily understood by humans. .

  Therefore, in view of the above problems, the present invention can easily check the current state of the mobile robot (work in progress / moving / standby / abnormal state, etc.) even when the mobile robot is not found. It is another object of the present invention to provide a mobile robot management device.

  In the robot system of the present invention, a plurality of display panels having at least one light-emitting component to be controlled for light emission are arranged in the path of the mobile robot, and the robot management device receives the state of the mobile robot transmitted from the mobile robot. The light emission of the plurality of display panels is controlled based on the received state of the mobile robot.

  It is possible to easily check the current state of the mobile robot (work in progress / moving / standby / abnormal state, etc.).

  Embodiments of the present invention will be described below with reference to the drawings.

  FIG. 1 shows a configuration example of a robot system according to this embodiment. The mobile robot according to the present embodiment can move freely within a predetermined range of movement such as in a house (to avoid an obstacle in the traveling direction). A control route for managing the state and position of the mobile robot is set in advance on a part of the floor of the passage where the robot travels and walks. The mobile robot 1 travels on the control route, and also moves to a remote location that is off the control route, and performs the instructed work.

  The robot system of FIG. 1 mainly includes a plurality of (for example, four in FIG. 1) base point devices 9a to 9a arranged to be embedded in the floor surface along the mobile robot 1, the robot management device 3, and the control route 5. Including 9d.

  A place where the base point devices 9a to 9d are embedded side by side is a control route.

  The mobile robot 1 includes a control unit 1, a communication unit 12, a state management unit 13, a calibration processing unit 14, a position detection unit 15, and a self-running unit 16.

  The self-propelled portion 16 is for driving a wheel provided in the mobile robot 1 for moving the mobile robot 1 to move within the movement range.

  The position detector 15 determines the position within the movement range from the position before the movement of the mobile robot 1 within the movement range, the direction and rotation direction of the wheel when the movement of the mobile robot 1 starts, the number of rotations of the moving wheel, and the like. The position of the mobile robot 1 is detected. For example, the amount of movement (movement distance) between them is obtained by multiplying the circumference of the wheel by the number of rotations of the wheel until the mobile robot 1 starts moving in a certain direction and stops. Further, the moving direction of the mobile robot 1 is obtained from the direction and rotation direction of the wheels, or the difference between the rotation amounts of the left and right wheels. A point within the movement range that is separated from the position of the mobile robot 1 before movement in the obtained movement direction by the obtained movement amount is a position after the movement of the mobile robot 1. The position information of the mobile robot 1 detected by the position detection unit 15 is notified to the robot management device 3 via the communication unit 12 as needed.

  The calibration processing unit 14 is for correcting / adjusting the position of the mobile robot 1 detected by the position detection unit 15 when the mobile robot 1 is regularly checked. When calibration is performed by the calibration processing unit 14, the mobile robot 1 is not in a normal operation mode but in a calibration mode for performing calibration. In the calibration mode, the calibration processing unit 14 performs calibration by causing the mobile robot 1 to travel on the control route. The calibration processing unit 14 will be described later.

  The state management unit 13 manages the state of the mobile robot 1. The mobile robot 1 has a plurality of states such as a work executing state, a moving state, a standby (idling) state, and an abnormal state.

  The work execution state is a state in which work instructed by the mobile robot is being performed within the movement range. The standby state is a state where there is no work to be performed. Within the movement range, a place (standby place) where the mobile robot 1 should wait when the mobile robot 1 is in a standby state may be provided. The abnormal state is a state where an abnormality has occurred in the mobile robot 1, such as a state where the mobile robot 1 is caught by something and cannot move, or a state where the amount of battery is extremely small.

  The state of the mobile robot 1 may be further subdivided. For example, the moving state is divided into a moving state in which the user is moving to a target location to perform work and a moving state in which the user is moving to return to a predetermined waiting place after the work is completed. It may be divided. Moreover, you may distinguish the state which is performing the operation | work accompanied by movements, such as cleaning and a patrol, among the work execution states especially as a traveling work state.

  The state management unit 13 recognizes various states of the mobile robot 1 based on information detected from each functional unit in the mobile robot 1 and holds information indicating the recognized state. Detect state changes. When the state change is detected by the state management unit 13, the detected new state is notified to the robot management apparatus 3 via the communication unit 12.

  The communication unit 12 is for communicating with the robot management apparatus 3. Communication is performed between the communication unit 12 of the mobile robot 1 and the communication unit 32 of the robot management apparatus 3 using a wireless communication method such as infrared data communication IrDA (Infrared Data Association) or wireless LAN communication.

  The control unit 11 controls the above-described units of the mobile robot 1.

  Each of the plurality of base point devices 9a to 9d embedded in the floor surface along the control route 5 includes the display unit 6 and the pressure sensor 7, and includes at least one base point device (here, the base point devices 9a to 9d). The base point device 9 d) further includes a charging unit 8.

  The display unit 6 of each base device and the display control unit 34 of the robot management device 3 are connected so that they can communicate with each other, or the display unit 6 of each base device can be controlled from the display control unit 34. .

  The pressure sensor 7 of each base point device and the position management unit 35 of the robot management device 3 can communicate with each other, or can transmit the pressure value measured by the pressure sensor 7 of each base point device to the position management unit 35. So connected.

  The charging unit 8 of each base point device (here, the base point device 9d) and the charging control unit 36 of the robot management device 3 can communicate with each other or the charging unit 8 of each base point device controls from the charging control unit 36. Connected as possible.

  The display unit 6 displays the state and position of the mobile robot 1 under the control of the display control unit 34 of the robot management apparatus 3. The display unit 6 is a display panel having at least one light emitting component (for example, LED) whose light emission is controlled.

  The pressure sensor 7 is arranged so as to measure a pressure value by each weight when a person or the mobile robot 1 stands on the pressure sensor 7. The pressure sensor 7 outputs the measured pressure value to the position management unit 35.

  The charging unit 8 is for charging the mobile robot 1 by non-contact electromagnetic induction, or charging the mobile robot 1 by bringing the charging terminal into contact with an electric supply terminal provided on the surface of the base point device 9d. It is.

  The base point device 9d may be a standby place for the mobile robot 1.

  The robot management device 3 is a server device that performs control and management while communicating with the mobile robot 1 and a plurality of base point devices 9a to 9d on the control route.

  The robot management device 3 includes a control unit 31, a communication unit 32, a state management unit 33, a display control unit 34, a position management unit 35, and a charge control unit 36.

  The control unit 31 controls the communication unit 32, the state management unit 33, the display control unit 34, the position management unit 35, and the charge control unit 36.

  The communication unit 32 is for communicating with the mobile robot 1. When the mobile robot 1 is in the normal operation mode (during normal operation), the mobile robot 1 receives the state of the mobile robot 1 detected by the state management unit 13 and the movement detected by the position detection unit 15. The position information of the robot 1 is received. The position information and state information of the mobile robot 1 received by the communication unit 32 are output to the control unit 31 and further output from the control unit 31 to the position management unit 35 and the state management unit 33, respectively.

  The state management unit 33 stores the state of the mobile robot 1 received via the communication unit 32, and manages the current state of the mobile robot 1 such as state changes.

  The position management unit 35 always tracks the location of the mobile robot 1 using the pressure value measured by the pressure sensor 7 of each base point device and the position information of the mobile robot 1 received via the communication unit 32. It is like that. The position information of the mobile robot 1 obtained by the position management unit 35 is output to the control unit 31 and further output from the control unit 31 to the display control unit 34.

  During normal operation of the mobile robot 1, the position of the mobile robot 1 within the movement range can be confirmed using the position information notified from the mobile robot 1.

  When the mobile robot 1 is on the control route 5, the base point where the mobile robot 1 on the control route is present (passed) is determined from the pressure value obtained from each pressure sensor. Detect as the position of. When the control robot 1 traveling on the control route moves to a target location off the control route, a base point near the target location (the mobile robot 1 moves from the base point to the target location). After passing through a predetermined route), leave the control route and head for the destination. Thereafter, while the weight of the mobile robot 1 is measured by the pressure sensor 7 of the base point, that is, until the mobile robot 1 returns to the control route again, the position management unit 35 controls the mobile robot 1. The base point of the point deviating from the route is determined as the location where the mobile robot 1 is present.

  As described above, the position management unit 35 detects the base point where the mobile robot 1 exists among the plurality of base points on the control route detected based on the pressure value measured by each pressure sensor 7. Get as.

  The display control unit 34 receives the position information of the mobile robot 1 received via the communication unit 32 and the position information of the mobile robot 1 obtained by the position management unit 35 via the control unit 31, and based on these. In addition, the display unit 6 is controlled to display the current position and current state of the mobile robot 1 on the display unit 6 of each base device on the control route.

  The charging control unit 36 is connected to the charging unit 8 of the base point device, and when the mobile robot 1 is present on the base point device (base point device 9d in FIG. 1) including the charging unit 8 (for example, the position management unit 35 From the position information of the mobile robot 1 obtained based on the pressure value measured by the pressure sensor 7 of the base point device 9d and the position information of the mobile robot 1 notified from the mobile robot 1, the mobile robot 1 is placed on the base point device 9d. When it is determined that the mobile robot 1 exists, the charging unit 8 is driven to charge the mobile robot 1 and the operation status of the charging unit 8 is managed.

  FIG. 2 shows an example of the control route 5 provided on the floor in the house. In FIG. 2, the control route is provided in a loop shape on the floor of the ocean. As shown in FIG. 2, at the six locations BP1 to BP6 of the control route 5, the base point device of FIG. Here, the base point devices at the respective locations BP1 to BP6 are referred to as base point devices BP1 to BP6. For example, the base point device BP4 has the configuration shown in the base point device 9d in FIG. 1, and the other base point devices have the configuration shown in the base point devices 9a to 9c in FIG.

  The mobile robot 1 travels on the control route, deviates from the control route, and travels in the bathroom / bathroom / toilet direction A1, Japanese-style room A2, entrance / hall direction A3, and western back A4. I do.

  As shown in FIG. 4, when the mobile robot 1 goes to the bathroom / bathroom / toilet direction A1, it moves from the base point BP1 of the control route 5 to the bathroom / bathroom / toilet area A1, and goes to the bathroom / bathroom / toilet area A1. When returning from the toilet direction A1 to the control route, the vehicle goes on the control route from the base point BP1. While the mobile robot 1 is in the bathroom / bathroom / toilet direction A1, the display unit 6 of the base point device BP1 in FIG. 2 corresponding to the bathroom / bathroom / toilet direction A1 causes the mobile robot 1 to move to the bathroom / bathroom / toilet. It displays that it is in the direction A1.

  When the mobile robot 1 goes to the Japanese-style room direction A2, it goes from the base point BP2 of the control route 5 to the Japanese-style room direction A2, and when returning from the Japanese-style room direction A2 to the control route 5, it goes on the control route from the basic point BP2. While the mobile robot 1 is in the Japanese-style room direction A2, the display unit 6 of the base point device BP3 in FIG. 2 corresponding to the Japanese-style room direction A2 displays that the control robot 1 is in the Japanese-style room direction A2.

  When the mobile robot 1 goes to the entrance / hall direction A3, it goes from the control route base point BP5 to the entrance / hall direction A3, and when returning from the entrance / hall direction A3 to the control route 5, the base point BP5 goes to the control route 5. Noru. While the mobile robot 1 is in the entrance / hall direction A3, the display unit 6 of the base point device BP5 in FIG. 2 corresponding to the entrance / hall direction A3 displays that the control robot 1 is in the entrance / hall direction A3.

  When the control robot 1 goes to the western backplane A4, it goes from the control route BP6 to the western backplane A4, and when returning from the western backplane A4 to the control route 5, it goes from the base point BP6 to the control route 5. While the mobile robot 1 is in the western back surface A4, the display unit 6 of the base point device BP6 in FIG. 2 corresponding to the western back surface A4 displays that the control robot 1 is in the western back surface A4.

  Here, a display method for displaying the position and state of the mobile robot 1 by the display unit 6 of each base device on the control route will be described. The display control unit 34 of the robot management device 3 controls how the display unit 6 of which base point device is displayed in accordance with the position and state of the mobile robot 1.

(Mobile robot status display method)
(1) Characters, character strings, symbols, and the like indicating the current state of the mobile robot 1 are displayed on the display unit 6 of each base device on the control route. For example, if the mobile robot 1 is in a work execution state, the display unit 6 of each base device displays a character string “work in progress” or a character or symbol corresponding thereto.

  (2) Among the states that the mobile robot 1 has, when the work is currently being executed, such as the work being executed state, the moving state for the work, or the traveling work state, etc. Each display unit 6 is lit to display. When the mobile robot 1 is in an abnormal state, each display unit 6 displays the blinking. In other cases, that is, in the states where the mobile robot 1 has no particular work at present, such as a moving state for return and a standby state, each display unit 6 is neither blinking nor lit.

  (3) When the display unit 6 of each base device on the control route displays a plurality of colors, the work execution state, the movement state for work, the movement state for return, and the traveling work state The state of the mobile robot 1 is displayed on each display unit 6 by assigning a light emission color to each state such as a standby state and an abnormal state and displaying the light emission color corresponding to each state.

  (4) When the above-mentioned (2) and (3) are combined and the display unit 6 of each base point device on the control route displays a plurality of colors, the work executing state, the moving state for the work, the feedback For each state, such as the moving state, patrol work state, standby state, and abnormal state, for each of the robots, a light emission color and blinking / lighting are assigned, and each state of the mobile robot 1 is blinking / lighting. Is displayed. For example, yellow is lit when the work is in progress, blue is blinking when moving for work, blue is light when moving for return, yellow is blinking when traveling, and black is waiting. The abnormal state is red lighting or blinking, and the state of the mobile robot 1 is displayed on each display unit 6.

  (5) The above (1) and (4) are combined and displayed. For example, if the mobile robot 1 is in a work execution state, the display unit 6 of each base device displays a character string “work in progress”, or a character or symbol corresponding to the character string in blinking yellow.

  (6) In the case of the display unit 6 that can use two colors, for example, blue and red, among the states of the mobile robot 1, for example, blue in the normal operation state and red in the abnormal state indicate. In the normal operation state, in the state where the work is currently being executed or the work is about to be started soon, such as the work being executed state, the moving state for the work, the traveling work state, etc., each display unit 6 This state is displayed by blinking blue. In the normal operation state, such as a moving state for return and a standby state, where no work is currently performed, each display unit 6 displays this state in blue. To do. When the mobile robot 1 is in an abnormal state, each display unit 6 displays a red light or blinks.

  (7) The above (1) and (6) are combined and displayed. For example, if the mobile robot 1 is in a work execution state, the display unit 6 of each base device displays a character string “work in progress” or a character, symbol, or the like corresponding to the character string blinking in blue. If the mobile robot 1 is in a moving state for return, the character string “moving for return” or the corresponding character, symbol, etc. is displayed on the display unit 6 of each base point device in blue. Display with lighting.

(Mobile robot position display method)
(8) The display unit 6 of the base point device nearest to the position where the mobile robot 1 is present or the base point device corresponding to the position is lit or blinks.

  (9) The base unit closest to the location of the mobile robot 1 or the display unit 6 of the base unit corresponding to the location flashes, and each base unit or mobile robot nearest to the path traveled by the mobile robot 1 The display unit 6 of each base device corresponding to the place where the vehicle 1 has traveled or each base device on the travel route of the mobile robot 1 is lit.

  (10) The base unit nearest to the position where the mobile robot 1 is present or the display unit 6 of the base point device corresponding to the present position blinks or lights up, and each base point device nearest to the route traveled by the mobile robot 1 or The display unit 6 of each base point device corresponding to the place where the mobile robot 1 has traveled or the base point device on the travel route of the mobile robot 1 blinks or lights up an arrow indicating the moving direction of the mobile robot 1.

  (11) The base unit nearest to the position where the mobile robot 1 is present or the display unit 6 of the base unit corresponding to the present position lights up or blinks, and each base unit nearest to the route traveled by the mobile robot 1 or The display unit 6 of each base point device corresponding to the place where the mobile robot 1 has traveled or the base point device on the travel route of the mobile robot 1 blinks in order to indicate the moving direction of the mobile robot 1.

  (12) If the mobile robot 1 is in a traveling work state where the mobile robot 1 is performing a work while moving such as cleaning or patrol within the movement range, it corresponds to the place where the mobile robot 1 cleaned or looked around. The display unit 6 of the base point device lights up or blinks. For example, when the cleaning or patrol of the Japanese-style room area A2 is completed, the display unit 6 of the base point device BP3 is turned on or blinks.

  (13) If the mobile robot 1 is in a traveling work state where the mobile robot 1 is performing a work while moving within the moving range, such as cleaning and patrol, the destination of the mobile robot 1, that is, the mobile robot 1 The display unit 6 of the base device corresponding to the place to be cleaned or the place to look around lights up or blinks. For example, when the mobile robot 1 cleans and looks around the toilet room / bathroom / toilet area A1 after cleaning / tour around the Japanese-style room A2, the base device BP1 corresponding to the bathroom / bathroom / toilet area A1 The display unit 6 is turned on or blinks.

  (14) When displaying the combination of the above (12) and (13), in (12), when the display unit 6 of the base device corresponding to the place where the mobile robot 1 has cleaned or looked around is turned on ( 13), the display unit 6 of the base device corresponding to the destination of the mobile robot 1 blinks. Further, when the display unit 6 blinks at (12), the display unit 6 is lit at (13).

  (15) In the above (12) and (13), the display unit 6 of the base point device closest to the current position of the mobile robot 1 or the base point device corresponding to the current location of the mobile robot 1 is the other display unit 6 The current position of the mobile robot 1 is displayed by lighting or blinking of a color different from the display color at.

  (16) The display unit 6 of each base unit displays the arrow in a lighting or blinking direction in the direction in which the mobile robot 1 currently exists.

  (17) The above (8) to (16) are appropriately combined.

(Displaying a combination of mobile robot status and position)
(A) By combining the above (1) and (8), the base unit nearest to the position where the mobile robot 1 is present or the display unit 6 of the base unit corresponding to the position is a character indicating the state of the mobile robot 1 A character string, symbol, etc. is lit or blinked.

  (B) By combining the above (1) and (9), the display unit 6 of each base point device displays characters, character strings, symbols, and the like indicating the state of the mobile robot 1, and at the position where the mobile robot 1 is present. The display unit 6 of the nearest base point device or the base point device corresponding to the existing position blinks, and each base point nearest to the route traveled by the mobile robot 1 or each base point corresponding to the place where the mobile robot 1 traveled The display unit 6 of each base device on the travel route of the device or the mobile robot 1 is lit.

  (C) The above (3) is combined with at least one of the above (8) to (16).

  (D) When the mobile robot 1 is in an abnormal state, the display unit 6 of the base device closest to the current position of the mobile robot 1 or the base device corresponding to the current position of the mobile robot 1 is lit in red. The display unit 6 of each other base point device on the route blinks red.

  In addition to the above (A) to (C), on the display unit 6 of each base unit on the control route, one of color, lighting / flashing, display contents, etc., or some of them may be combined. The state and position of the mobile robot 1 can be displayed on the display unit 6 of each base device on the control route. It is possible to display the position and state of the mobile robot 1 on each display unit 6 so that the position and state of the mobile robot 1 can be understood only by looking at the display on the display unit 6 of any one base point device on the control route. desirable.

  Next, a configuration example of the display unit 6 of each base point device will be described with reference to FIG. The display unit 6 shown in FIGS. 3A and 3B shows an example of a display panel in which the arrangement of at least one light emitting component whose light emission is controlled by the display control unit 34 is different. In the display panel shown in FIG. 3A, the light-emitting component 101 is disposed on the belt. In FIG. 3B, one light emitting component is arranged in the center, and four light emitting components are arranged at equal intervals so as to surround the periphery. In the display panel shown in FIG. 3C, light emitting components are arranged in a grid pattern. In particular, in the case of a display panel as shown in FIGS. 3B and 3C, an arrow shape can be displayed by selecting a light emitting component that emits light from among a plurality of arranged light emitting components. Therefore, the moving direction (traveling direction) of the mobile robot 1 and the direction in which the mobile robot exists can be easily displayed.

  Further, in the case of the display panel as shown in FIG. 3C, if the mobile robot 1 is configured so as to obtain a resolution capable of displaying characters by arranging many light emitting components like a grid, The status can be displayed with characters, character strings, symbols, and the like. At the same time, an arrow or the like can be displayed to indicate the moving direction or existing position of the mobile robot 1.

  Only by looking at the display on the display unit 6 of any one base device on the control route, the position and state of the mobile robot 1 can be seen and displayed in a plurality of colors using illumination components that emit different colors. A display panel that can be used is desirable.

  FIG. 5 shows another example of the control route 5 provided on the floor surface in the house. In FIG. 5, the control route is provided in a straight line on the floor at the center of the ocean. As shown in FIG. 5, the base point device of FIG. 1 is embedded in the floor surface at the eight locations BP <b> 1 to BP <b> 8 of the control route 5. Here, the base point devices at the respective locations BP1 to BP8 are referred to as base point devices BP1 to BP8. For example, the base point device BP1 has the configuration shown in the base point device 9d in FIG. 1, and the other base point devices have the configurations shown in the base point devices 9a to 9c in FIG.

  In FIG. 5, while the mobile robot 1 is in the toilet / bathroom / toilet direction A1, the display unit 6 of the base point device BP7 in FIG. 5 corresponding to the toilet / bathroom / toilet direction A1 causes the mobile robot 1 to・ Display that you are in the bathroom / toilet direction A1.

  While the mobile robot 1 is in the Japanese-style room direction A2, the display unit 6 of the base point device BP2 in FIG. 5 corresponding to the Japanese-style room direction A2 displays that the control robot 1 is in the Japanese-style room direction A2.

  While the mobile robot 1 is in the entrance / hall direction A3, the display unit 6 of the base point device BP3 in FIG. 5 corresponding to the entrance / hall direction A3 displays that the control robot 1 is in the entrance / hall direction A3.

  While the mobile robot 1 is in the western back plane A4, the display unit 6 of the base point device BP6 in FIG. 5 corresponding to the western back plane A4 displays that the control robot 1 is in the western back plane A4.

  FIG. 6 shows still another example of the control route 5 provided on the floor surface in the house. In FIG. 6, the control route is provided with the floor between the oceans obliquely. As shown in FIG. 6, at 11 locations BP1 to BP11 of the control route 5, the base point device of FIG. 1 is embedded in the floor surface. Here, the base point devices at the respective locations BP1 to BP11 are referred to as base point devices BP1 to BP11. For example, the base point device BP1 has the configuration shown in the base point device 9d in FIG. 1, and the other base point devices have the configurations shown in the base point devices 9a to 9c in FIG.

  In FIG. 6, while the mobile robot 1 is in the toilet / bathroom / toilet direction A1, the display unit 6 of the base point device BP8 in FIG. 6 corresponding to the toilet / bathroom / toilet direction A1 causes the mobile robot 1 to・ Display that you are in the bathroom / toilet direction A1.

  While the mobile robot 1 is in the Japanese-style room area A2, the display unit 6 of the base point device BP2 in FIG. 6 corresponding to the Japanese-style room area A2 displays that the control robot 1 is in the Japanese-style room area A2.

  While the mobile robot 1 is in the entrance / hall direction A3, the display unit 6 of the base point device BP4 in FIG. 6 corresponding to the entrance / hall direction A3 displays that the control robot 1 is in the entrance / hall direction A3.

  While the mobile robot 1 is in the western back plane A4, the display unit 6 of the base point device BP10 in FIG. 6 corresponding to the western back plane A4 displays that the control robot 1 is in the western back plane A4.

  As shown in FIGS. 2, 5, and 6, when the mobile robot 1 is located at a location A 1 to A 4 that is a blind spot deviating from the control route 5, it is easy to see and understand the nearest to that location. With the base point base point device, the control robot 1 displays that it is at that location.

  Further, as shown in FIG. 2, the control route 5 does not have to be in a loop shape, and may be a straight line, may have branches in some places, or may be short. Any route may be used as long as a predetermined length in which at least two base point devices are embedded can be secured. It is desirable that the route be sure to pass when the mobile robot 1 or a person moves from room to room within the moving range.

  The length of the control route only needs to be long enough to correct the movement position of the mobile robot 1 during calibration, as will be described later.

  Next, the position management unit 35 of the robot management apparatus 3 will be described. Each position sensor 35 is connected to each pressure sensor 7 provided in each control route-shaped base point device.

  When a person or the mobile robot 1 is placed on the pressure sensor 7, the pressure sensor 7 measures the pressure at that time and notifies the position management unit 35 of the robot management device 3 of the measured pressure value. ing. Each pressure sensor 7 has identification information, for example, when there is a change in the measured pressure value, notifies the position management unit 35 together with the identification information of the pressure sensor 7.

  For example, the weight of the mobile robot 1 is sufficiently light compared to the weight of an adult or a child. The position management unit 35 determines that there is a person at the base point where the pressure sensor is disposed when the pressure value of the pressure sensor is equal to or greater than a predetermined first threshold value. Further, when the pressure value of the pressure sensor is equal to or smaller than the second threshold value smaller than the first threshold value and equal to or larger than the third threshold value smaller than the second threshold value, the reference point where the pressure sensor is disposed is used. It is determined that the mobile robot 1 exists. When the pressure value of the pressure sensor is equal to or smaller than the fourth threshold value which is smaller than the third threshold value, it is determined that neither the person nor the mobile robot 1 exists at the base point where the pressure sensor is arranged.

  For example, when the position management unit 35 determines that there is a person in the base point device BP4 in FIG. 2, the position management unit 35 notifies the control unit 31 accordingly. The control unit 31 instructs the mobile robot 1 to move to the base point BP4 via the communication unit 32. This is effective in the case of the mobile robot 1 that travels in a wide space such as a museum as a movement range.

  In FIG. 2, when the mobile robot 1 passes through the base point BP3 on the control route, travels to the base point BP2, passes further through the base point BP2, and reaches the base point BP1, the position management unit 35 determines the base points BP3, BP2, BP1. From the pressure values obtained from the respective pressure sensors, it is determined that the current position of the mobile robot 1 is the base point BP1. Thereafter, the mobile robot 1 moves away from the control route 5 at the base point BP1 toward the toilet / bathroom / toilet direction A1 in order to move to the toilet / bathroom / toilet direction A1 in FIG. Therefore, after the position management unit 35 determines the position of the mobile robot 1 as the base point BP1, for example, when the presence of the mobile robot 1 cannot be detected from the pressure value of each pressure sensor 7 even after a predetermined time has elapsed, The presence position of the mobile robot 1 is determined to be the bathroom / bathroom / toilet direction A1. That is, it is determined that the current position of the mobile robot 1 is the base point BP1.

  Thereafter, the position management unit 35 determines the position of the mobile robot 1 until the weight of the mobile robot 1 is measured by the pressure sensor 7 at the base point BP1, that is, until the mobile robot 1 returns to the control route again. The toilet / bathroom / toilet direction A1, that is, the base point BP1 is determined.

  Next, self-position detection and calibration of the mobile robot 1 will be described. When the mobile robot 1 is inspected, the mobile robot 1 is caused to travel on the control route in the calibration mode.

  For example, even if the same mobile robot 1 travels between the floor surface on which the carpet is packed and the floor surface of the flooring, even if the same mobile robot 1 travels, it is calculated by the position detection unit 15 of the mobile robot 1. A difference occurs in the amount of movement. In order to correct the difference between the distance actually moved by the mobile robot 1 and the distance calculated by the mobile robot 1, it is preferable to perform calibration periodically.

  In the calibration mode, the mobile robot 1 travels between arbitrary base points along the control route. The distance between any two base points is known. The calibration processing unit 14 of the mobile robot 1 calculates the distance calculated by the position detection unit 15 of the mobile robot 1 when traveling between the two arbitrary base points (for example, the control unit 31 of the robot management device 3 Compared with the correct distance between the two base points (transmitted via the communication unit 32 or stored in a predetermined memory of the calibration processing unit 14 of the mobile robot 1) In addition, a correction amount for the rotational speed of the wheel during traveling is calculated.

  Moreover, since the position management unit 35 can determine which base point the mobile robot 1 has passed by using the pressure sensor provided at each base point, each time the mobile robot 1 passes through each base point on the control route. In addition, the position (base point position) of the mobile robot 1 determined by the position management unit 35 is notified to the mobile robot 1 via the communication unit 32. Then, the calibration processing unit 14 of the mobile robot 1 compares the position calculated by the position detection unit 15 with the position of the base point notified from the robot management device 3, and based on the error between the two, A correction amount for the wheel direction, the wheel rotation direction, and the like is calculated.

  For example, as shown in FIG. 7, between any two base points (for example, base points BP6 and BP1) on the control route 5 in FIG. The mobile robot 1 can be calibrated at high speed by causing the mobile robot 1 to travel on a straight line and performing the calibration by itself. That is, by carrying the mobile robot 1 to one of the two base points BP6 and BP1 and traveling to the other base point, the actual position of the other base point and the position detection unit 15 of the mobile robot 1 Mapping is performed between the calculated position of the mobile robot 1 itself, and a correction amount for the travel distance and direction of the mobile robot 1 is obtained.

  During normal operation of the mobile robot 1, the position detection unit 15 of the mobile robot 1 calculates the position of the mobile robot 1 itself using the correction amount obtained in this way.

  As described above, according to the above-described embodiment, a plurality of display panels 6 having at least one light-emitting component whose light emission is controlled are arranged on the floor surface of the passage of the mobile robot 1 and each display panel on the passage is provided. At each point (base point) where is arranged, a plurality of pressure sensors 7 are arranged so as to measure the pressure due to the weight of the mobile robot. The position management unit 35 of the robot management device 3 moves based on the pressure values measured by the plurality of pressure sensors 7 among a plurality of points (base points) where the plurality of display panels 6 are arranged. The point (base point) where the robot exists is detected. Further, the display control unit 34 controls the light emission of the plurality of display panels 6 based on the state of the mobile robot transmitted from the mobile robot and the base point detected by the position management unit 35.

  Preferably, the light emission color of the light emitting component is predetermined for each state of the mobile robot, and the display control unit 34 controls the light emission of the light emission component of the light emission color corresponding to the current state of the mobile robot. Displays the robot status.

  With such a configuration, even when the mobile robot is not found, the user of the mobile robot can provide the mobile robot's current state (work in progress / moving / standby / abnormal state, etc.) in the path of the mobile robot 1. It can be easily confirmed by looking at each display panel.

  Since a display panel using light emitting elements (light emitting components) such as LEDs may be disposed only on the moving path of a mobile robot such as a floor, the structure is simple and the reliability is improved.

  In addition, in the said embodiment, although each base point apparatus became a structure containing the display part 6 and a pressure sensor, not only in this case, a base point apparatus may be the structure containing only the display part 6. In this case, the position management unit 35 of the robot management device 3 detects the base point where the mobile robot exists from the position information transmitted from the mobile robot 1.

  That is, a plurality of display panels 6 having at least one light emitting component that is controlled to emit light are arranged on the floor surface of the path of the mobile robot 1. When the robot management apparatus 3 receives the state of the mobile robot transmitted from the mobile robot, the robot management apparatus 3 controls the display panels 6 to emit light based on the received state of the mobile robot.

  Moreover, the pressure sensor 7 may be included only in the base point device having the charging unit 8 among the plurality of base point devices on the control route.

  Further, a charging device that charges the mobile robot 1 by non-contact electromagnetic induction may be provided in all of the control route or a part of the control route. In the case of the configuration shown in FIG. 1, the mobile robot 1 needs to return to the point where the base point BP4 (base point device having the charging unit 8) in FIG. If charging can be performed within a range (for example, the entire control route 5), the mobile robot 1 can be charged while working.

  Further, in the case where communication means for communicating by connecting the robot management device 3 to an external network such as a public network is provided, only display information displayed on the display unit 6 of each base device on the control route is transferred to the network. By transmitting to the user's portable terminal or the like, the user can grasp the situation of the house with peace of mind without knowing the internal information of the house even when the house is away.

  During patrol and cleaning work in the house when the house is away, it is easy to confirm the actual work by reciprocating the control route to the mobile robot 1 several times.

  Note that the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the components without departing from the scope of the invention in the implementation stage. In addition, various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the embodiment. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, constituent elements over different embodiments may be appropriately combined.

The figure which showed the schematic structural example of the robot system which concerns on embodiment of this invention. The figure which showed an example of the control route provided on the floor surface in a house. The figure which showed the structural example of the display part of a base point apparatus. The figure for demonstrating the movement path | route when a mobile robot moves in the house of FIG. The figure which showed the other example of the control route provided on the floor surface in a house. The figure which showed the further another example of the control route provided on the floor surface in a house. The figure for demonstrating a calibration.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Mobile robot, 3 ... Robot management apparatus, 5 ... Control route, 6 ... Display part, 7 ... Pressure sensor, 8 ... Charging part, 9a-9d ... Base point apparatus, 11 ... Control part, 12 ... Communication part, 13 ... State management unit 14 ... Calibration processing unit 15 ... Position detection unit 16 ... Self-running unit 31 ... Control unit 32 ... Communication unit 34 ... Display control unit 35 ... Position management unit 36 ... Charge control unit .

Claims (12)

A mobile robot,
A plurality of display panels disposed in a path of the mobile robot and having at least one light emitting component that is controlled to emit light;
A robot management device;
With
The mobile robot includes transmission means for transmitting at least the state of the mobile robot to the robot management device,
The robot management device includes:
Receiving means for receiving at least the state of the mobile robot from the mobile robot;
Display control means for controlling light emission of the plurality of display panels based on at least the state of the mobile robot received by the receiving means;
A robot system comprising: A mobile robot,
A plurality of display panels disposed in a path of the mobile robot and having at least one light emitting component that is controlled to emit light;
A plurality of pressure sensors respectively arranged to measure the pressure due to the weight of the mobile robot at each point where each display panel on the passage is arranged;
A robot management device;
With
The mobile robot includes transmission means for transmitting at least the state of the mobile robot to the robot management device,
The robot management device includes:
Receiving means for receiving at least the state of the mobile robot from the mobile robot;
Position detecting means for detecting a point where the mobile robot exists among a plurality of points where each of the plurality of display panels is arranged based on pressure values measured by at least each of the plurality of pressure sensors; ,
Display control for displaying the state and position of the mobile robot by controlling the light emission of the plurality of display panels based on the state of the mobile robot received by the receiving means and the point detected by the position detecting means. Means,
A robot system comprising:   The robot system according to claim 1, wherein the mobile robot has a plurality of states including a work execution state, a moving state, a standby state, and an abnormal state. In each state of the mobile robot, the light emission color of the light emitting component is predetermined,
3. The robot system according to claim 1, wherein the display control unit displays the state of the mobile robot by performing light emission control on a light emitting component having a light emission color corresponding to the current state of the mobile robot. . The transmission means of the mobile robot further transmits position information of the mobile robot,
The receiving means of the robot management device further receives position information from the mobile robot;
The display control means includes
Based on the position information of the mobile robot and the state of the mobile robot received by the receiving means, the current state of the mobile robot is displayed on the display panel closest to the position of the mobile robot among the plurality of display panels. The robot system according to claim 1, wherein a light emitting component having a light emission color corresponding to is turned on or blinked. In each state of the mobile robot, the light emission color of the light emitting component is predetermined,
The display control means includes
3. The robot system according to claim 2, wherein a light emitting component of a light emitting color corresponding to the current state of the mobile robot is turned on or blinked on a display panel at a point detected by the position detecting means.   The robot system according to claim 1, wherein the mobile robot further comprises calculation means for calculating a position of the mobile robot from a moving direction and a moving distance of the mobile robot. The mobile robot is
Calculating means for calculating the position of the mobile robot from the moving direction and moving distance of the mobile robot;
Means for determining a correction amount of the position of the mobile robot calculated by the calculation means by running between any two pressure sensors of the plurality of pressure sensors;
The robot system according to claim 2, further comprising:   3. The charging device according to claim 1, further comprising charging means for charging the mobile robot by electromagnetic induction at at least one of the points where the display panels are arranged on the passage. Robot system.   Charging for charging the mobile robot by bringing a charging terminal of the robot into contact with an electric supply terminal provided on the display panel surface at at least one of the points where the display panels are arranged on the passage 3. The robot system according to claim 1, further comprising means. A plurality of display panels having at least one light-emitting component disposed in a passage of a mobile robot having a plurality of states including a work execution state, a moving state, a standby state, and an abnormal state;
Receiving means for receiving the state of the mobile robot from the mobile robot;
Display control means for controlling the light emission of the plurality of display panels based on the state of the mobile robot received by the receiving means, and displaying the state of the mobile robot;
A robot management apparatus comprising: A plurality of display panels having at least one light-emitting component disposed in a passage of a mobile robot having a plurality of states including a work execution state, a moving state, a standby state, and an abnormal state;
A plurality of pressure sensors respectively arranged to measure the pressure due to the weight of the mobile robot at each point where each display panel on the passage is arranged;
With
Receiving means for receiving the state of the mobile robot transmitted from the mobile robot;
Based on the pressure value measured by each of the plurality of pressure sensors, position detection means for detecting a point where the mobile robot exists among a plurality of points where each of the plurality of display panels is disposed;
Based on the state of the mobile robot received by the receiving means and the point detected by the position detecting means, the plurality of display panels are controlled to emit light control display,
A robot management apparatus comprising:

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