Robots and robot management systems

The robot management system efficiently sets movement paths for robots by acquiring state information on other robots and constraint areas, addressing deadlock issues and optimizing navigation.

JP2026115942APending Publication Date: 2026-07-09SECOM CO LTD

Patent Information

Authority / Receiving Office
JP · JP
Patent Type
Applications
Current Assignee / Owner
SECOM CO LTD
Filing Date
2024-12-27
Publication Date
2026-07-09

AI Technical Summary

Technical Problem

When multiple autonomous robots operate in a facility, deadlocks can occur at narrow passages where two robots cannot pass through at the same time, necessitating efficient management of constraint areas to prevent such situations.

Method used

The robot and robot management system utilize state acquisition means to gather information on other robots and constraint areas, and path setting means to set optimal movement paths based on this information, considering the positions, directions, and states of other robots and constraint areas.

Benefits of technology

This approach allows for efficient path setting even when constraint areas are present, preventing deadlocks and optimizing robot movement within the facility.

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Abstract

The objective is to efficiently set a movement path even when constraint areas are set on the robot's movement path. [Solution] The robot 10 includes a state acquisition means 171 that acquires robot state information indicating the state of other robots 10a and 10b present in the robot 10's movement area, arrangement information of one or more areas arranged in the movement area which are areas on which the robot 10's actions are restricted, and a path setting means 172 that sets a movement path from the robot 10's starting point to a destination point based on the state of other robots indicated in the robot state information acquired by the state acquisition means.
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Description

Technical Field

[0001] The present invention relates to a robot and a robot management system.

Background Art

[0002] There is known a robot management system that manages autonomous mobile robots that autonomously travel within a facility to perform patrol security, inspection work, etc., in place of resident security guards (see, for example, Patent Document 1). When a person passing through a security gate is detected during an open period in which the security gate is open by a robot transmitting an open request signal, the robot management system described in Patent Document 1 detects the person as an unauthorized intruder without passing permission. Thereby, the robot management system described in Patent Document 1 can prevent unauthorized entry or passing-by entry by an unauthorized intruder when a robot passes through a security gate.

Prior Art Documents

Patent Documents

[0003]

Patent Document 1

Summary of the Invention

Problems to be Solved by the Invention

[0004] However, when a plurality of robots capable of autonomous movement are operated in a facility, when two robots pass through a passage where it is difficult for two robots to pass through at the same time, such as a narrow passage, a deadlock may occur where the robots are in a waiting state. In order to prevent the occurrence of a deadlock, it is desirable that a passage where it is difficult for two robots to pass through at the same time be appropriately managed as a restricted area that restricts the actions of a plurality of robots, such as an area where only one robot can pass through.

[0005] The present invention aims to efficiently set a robot's movement path, even when a constraint area is set on the robot's movement path. [Means for solving the problem]

[0006] The robot according to the present invention comprises: a state acquisition means for acquiring robot state information indicating the state of other robots present in the robot's movement area; arrangement information of constraint areas, which are one or more areas arranged in the movement area and which are areas on which the robot's actions are restricted; and a path setting means for setting a movement path from the robot's starting point to a destination point based on the state of other robots indicated in the robot state information acquired by the state acquisition means.

[0007] Furthermore, in the robot according to the present invention, it is preferable that the state acquisition means acquires information indicating the position of other robots within the movement area as robot state information, and the path setting means sets a movement path by searching for a path based on the position information indicating the position of the constraint area in the movement area and the position of other robots acquired by the state acquisition means.

[0008] Furthermore, in the robot according to the present invention, it is preferable that the path setting means sets the movement path based on the relationship between the positions of other robots present around the constraint area and the position of the constraint area.

[0009] Furthermore, in the robot according to the present invention, the path setting means searches for a plurality of paths from the robot's starting point to the destination point, the state acquisition means acquires information indicating the state of other robots present in at least the plurality of explored paths as robot state information, and the path setting means preferably sets one of the plurality of explored paths as the movement path based on the presence or absence of constraint areas in the plurality of explored paths and the state of other robots.

[0010] Furthermore, in the robot according to the present invention, the state acquisition means acquires information indicating the presence or number of other robots as robot state information, and the path setting means preferably sets a path from the starting point to the destination point that has a small number of constraint areas and a small number of other robots as the travel path.

[0011] Furthermore, in the robot according to the present invention, it is preferable that the state acquisition means acquires information indicating the position of another robot and information indicating the direction or path of movement of the other robot as robot state information, and the path setting means sets a movement path based on the position of the other robot, the direction or path of movement of the other robot and the position of the constraint area.

[0012] Furthermore, in the robot according to the present invention, it is preferable that the state acquisition means acquires information indicating the position of other robots and information indicating the size of other robots as robot state information, and the path setting means sets a movement path based on the position and size of other robots and the position of the constraint area.

[0013] Furthermore, in the robot according to the present invention, it is preferable that the state acquisition means acquires information indicating the position of other robots and information indicating the movement speed of other robots as robot state information, and the path setting means sets a movement path based on the position of other robots, the movement speed of other robots and the position of the constraint area.

[0014] Furthermore, in the robot according to the present invention, it is preferable that the state acquisition means acquires information indicating the position of other robots and information indicating the movement priority of other robots as robot state information, and the path setting means sets the movement path based on the position of other robots, the movement priority and the position of the constraint area.

[0015] Furthermore, the robot management system according to the present invention is a robot management system composed of a plurality of robots and a management server, and includes a state acquisition means for acquiring robot state information indicating the state of a plurality of robots present in a movement area, and a path setting means for setting a movement path from the starting point to the destination point of a first robot among the plurality of robots, and the path setting means sets the movement path of the first robot based on the arrangement information of constraint areas, which are one or more areas arranged in the movement area and are areas on which constraints are imposed on the actions of the robots, and the state of other robots other than the first robot indicated in the robot state information acquired by the state acquisition means.

[0016] Furthermore, the robot management system according to the present invention is a management server for managing multiple robots, comprising: state acquisition means for acquiring robot state information indicating the state of multiple robots present in a movement area; path setting means for setting a movement path from the starting point to the destination point of a first robot among the multiple robots; and transmission means for transmitting the movement path set by the path setting means to the first robot, wherein the path setting means sets the movement path of the first robot based on arrangement information of constraint areas, which are one or more areas arranged in the movement area and which are areas where robot actions are restricted, and the state of other robots other than the first robot indicated in the robot state information acquired by the state acquisition means. [Effects of the Invention]

[0017] The robot according to the present invention can efficiently set a movement path even when a constraint area is set in the movement path. [Brief explanation of the drawing]

[0018] [Figure 1] This figure shows the overall system configuration of the robot management system according to the embodiment. [Figure 2](A) is a diagram showing an example of the node information shown in FIG. 1, (B) is a diagram showing an example of the edge information shown in FIG. 1, and (C) is a diagram showing the graph structure of the path within the facility indicated by the node information and edge information shown in FIG. 1. [Figure 3] (A) is a diagram showing an example of the data structure of the robot table shown in FIG. 1, and (B) is a diagram showing an example of the data structure of the edge table shown in FIG. 1. [Figure 4] It is a flowchart showing an example of the operation of the detection process executed by the management server shown in FIG. 1. [Figure 5] It is a sequence diagram showing an example of the operation of the movement path setting process executed by the robot shown in FIG. 1. [Figure 6] (A) is a diagram showing the graph structure corresponding to the process indicated by S204 in FIG. 5, (B) is a diagram showing the graph structure corresponding to the process indicated by S207 in FIG. 5, (C) is a diagram showing the graph structure corresponding to the process indicated by S210 in FIG. 5, and (D) is a diagram showing the graph structure in the state where the process indicated by S210 in the movement path setting process according to the first modification example is executed. [Figure 7] (A) is the graph structure in the state where the process indicated by S210 in the movement path setting process according to the second modification example is executed, (B) is a diagram showing the graph structure in the state where the process indicated by S210 in the movement path setting process according to the third modification example is executed, (C) is the graph structure in the state where the process indicated by S210 in the movement path setting process according to the fourth modification example is executed, and (D) is a diagram showing the graph structure in the state where the process indicated by S210 in the movement path setting process according to the fifth modification example is executed. [Figure 8] It is a sequence diagram showing an example of the operation of the movement path setting process according to the sixth modification example. [Figure 9](A) is a diagram showing a graph structure corresponding to the process shown by S312 in FIG. 8, (B) is a diagram (Part 1) showing a graph structure corresponding to the process shown by S313 in FIG. 8, (C) is a diagram (Part 2) showing a graph structure corresponding to the process shown by S313 in FIG. 9, and (D) is a diagram (Part 3) showing a graph structure corresponding to the process shown by S313 in FIG. 9.

Mode for Carrying Out the Invention

[0019] The robot and robot management system according to the present invention will be described below with reference to the drawings. However, note that the technical scope of the present invention is not limited to those embodiments, and extends to the invention described in the claims and its equivalents.

[0020] (Configuration and Functions of the Robot According to the Embodiment) FIG. 1 is a diagram showing the overall system configuration of a robot management system according to an embodiment composed of a plurality of robots and a management server.

[0021] The robot management system 1 includes a plurality of robots 10 and a management server 20 that manages the plurality of robots 10. The robot management system 1 is a system that performs security, cleaning, or management of facilities such as companies, condominiums, and commercial facilities by controlling a plurality of robots 10. The robot management system 1 sets the movement routes of each of the plurality of robots 10 based on the arrangement information of the restricted areas included in the movement routes from the starting points to the destination points of each of the plurality of robots 10 and the robot state indicating the states of other robots existing in the movement areas of the robots. The restricted area is one or more areas set in the movement area of the robot 10, and is an area where restrictions on the actions of the plurality of robots 10 are imposed. The restricted area is, for example, an exclusive area where only one robot can enter, an area where passing driving is prohibited, an area where overtaking driving is prohibited, and an area where U-turns are prohibited, etc., which are areas where restrictions on the actions of the robot 10 are imposed. The restricted area may be changed according to the situation inside the facility such as the arrangement of articles and the congestion situation.

[0022] Each of the multiple robots 10 moves autonomously within its designated area of ​​operation within the facility and performs predetermined tasks. The robots 10 include security robots that perform security within the facility, cleaning robots that perform cleaning within the facility, guidance robots that provide information to facility users, transport robots that transport items such as AEDs within the facility, and rescue robots that transport sick and injured people. Each of the robots 10 moves along a predetermined route according to a predetermined schedule to a predetermined point (location) and performs predetermined tasks.

[0023] The management server 20 is located in a control console or similar device inside or outside the facility and controls or manages multiple robots 10. Each robot 10 and the management server 20 are interconnected via a communication network N such as an intranet or the Internet. The robots 10 are connected to the communication network N via a wireless communication network such as a wireless LAN or a mobile phone network.

[0024] The robot 10 includes a position sensor 11, a drive unit 12, an input unit 13, an output unit 14, a first communication unit 15, a first storage unit 16, and a first processing unit 17, etc. The position sensor 11 is a sensor used to acquire the current position of the robot 10. The position sensor 11 includes one or more laser sensors (LiDAR). Each laser sensor is mounted on the front, side, back, and / or top surface of the robot 10. Each laser sensor includes an irradiator that emits light such as near-infrared light, visible light, or ultraviolet light in a predetermined direction, and a receiver that receives the reflected light. The direction in which each irradiator emits light is set to have various azimuth and elevation angles with respect to the direction of movement of the robot 10. Each laser sensor measures the distance to objects present around the robot 10 based on the time from when the irradiator emits light until the receiver receives the reflected light. The position sensor 11 outputs a position detection signal to the first processing unit 17 at a predetermined period, which includes multiple combinations of each direction in which the laser sensor emitted light and the measured distance. The position sensor 11 may include a receiver that receives radio waves (navigation signals) transmitted from navigation satellites (artificial satellites) such as GNSS (Global Navigation Satellite System). The receiver receives navigation signals transmitted from multiple navigation satellites and outputs them to the first processing unit 17.

[0025] The drive unit 12 includes a motor for rotating the tires of the robot 10, a motor for changing the direction of the tires, and / or a motor for changing the angle of the arm of the robot 10. The drive unit 12 receives a drive signal from the first processing unit 17, rotates according to the received drive signal, and drives the tires and / or the arm.

[0026] The input unit 13 includes one or more sensors for detecting the surrounding conditions of the robot 10. The input unit 13 includes one or more laser sensors, similar to the laser sensor in the position sensor 11, for example. Each laser sensor outputs a detection signal to the first processing unit 17 at a predetermined interval, which includes multiple combinations of the direction in which light was irradiated and the measured distance. The input unit 13 may include one or more visible light cameras provided on the front, side, back, and / or top surface of the robot 10. The imaging direction of each visible light camera is set to have various azimuth and elevation angles with respect to the direction of movement of the robot 10. Each visible light camera includes, for example, a photoelectric conversion element sensitive to visible light, such as a CCD element or CMOS element, an imaging optical system that forms an image on the photoelectric conversion element, and an A / D converter. Each visible light camera sequentially generates a visible light image based on visible light at a predetermined frame period and outputs it to the first processing unit 17. In addition, the input unit 13 may include a thermal imaging camera that acquires thermal images, either in place of or in addition to the visible light cameras. The thermal imaging camera includes, for example, two-dimensionally arranged sensors that detect the radiant energy of two wavelengths of electromagnetic radiation from an object, and an A / D converter that amplifies the electrical signal output from the sensors and performs analog-to-digital (A / D) conversion. The thermal imaging camera generates a thermal image based on temperature values ​​determined by the ratio of two types of radiant energies, and outputs it to the first processing unit 17 at a predetermined frame period. The input unit 13 may include a microphone. The microphone has an A / D converter, generates an audio signal based on the detected sound, and outputs it to the first processing unit 17 at a predetermined interval. The input unit 13 may include a temperature sensor. The temperature sensor detects the temperature around the robot 10 and outputs a temperature signal indicating the detected temperature to the first processing unit 17 at a predetermined interval.

[0027] The output unit 14 includes an LED that lights up or turns off according to instructions from the first processing unit 17. The output unit 14 also includes a display including a liquid crystal, organic EL, etc., and an interface circuit that outputs image data to the display, and may display various information such as images and text according to instructions from the first processing unit 17. The output unit 14 also includes a speaker and an interface circuit that outputs audio data to the speaker, and may output audio according to instructions from the first processing unit 17. If the robot 10 is a cleaning robot or a transport robot, the robot 10 does not need to have the output unit 14.

[0028] The first communication unit 15 has, for example, an antenna for transmitting and receiving wireless signals and a wireless communication interface circuit for transmitting and receiving signals through a wireless communication line in accordance with a wireless communication protocol such as a wireless LAN, and is connected to the communication network N via an access point. Alternatively, the first communication unit 15 has, for example, a communication interface circuit compliant with the W-CDMA or LTE method, and is connected to the communication network N via a communication network such as a base station and a mobile communication network. The first communication unit 15 outputs data received from the communication network N to the first processing unit 17 and transmits data input from the first processing unit 17 to the communication network N.

[0029] The first storage unit 16 includes semiconductor memory such as ROM and RAM, a magnetic disk or optical disk drive such as CD-ROM or DVD-ROM, and its recording medium. The first storage unit 16 stores a computer program and various data for controlling the robot 10, and inputs and outputs this information to and from the first processing unit 17. The computer program may be installed in the first storage unit 16 from a computer-readable portable recording medium such as a CD-ROM or DVD-ROM using a known setup program or the like. The computer program may also be stored on a recording medium owned by a predetermined server and installed via a network. The first storage unit 16 also stores data such as node information 161, edge information 162, current status information 163, reserved status information 164, and schedule information 165.

[0030] Figure 2(A) shows an example of node information 161, Figure 2(B) shows an example of edge information 162, and Figure 2(C) shows the graph structure of the paths within the facility indicated by node information 161 and edge information 162. Node information 161 is a table having a "Node ID" column and a "Location" column. The "Node ID" column stores the identification numbers "N001" to "N009" for each of the multiple nodes. The "Location" column stores the three-dimensional coordinates for each of the identification numbers "N001" to "N009" and associates them with each identification number "N001" to "N009". Edge information 162 is a table having an "Edge ID" column and a "Location" column. The "Edge ID" column stores the identification numbers "E001" to "E010" for each of the multiple edges. The "Location" column stores the locations of each identification number "E001" to "E010" as defined by the nodes indicated by the identification numbers "N001" to "N009" included in node information 161, and is stored in association with each of the identification numbers "N001" to "N010". The edge indicated by identification number "E001" is defined as the edge between the node indicated by identification number "N001" and the node indicated by identification number "N002". The edge indicated by identification number "E002" is defined as the edge between the node indicated by identification number "N001" and the node indicated by identification number "N003". The same applies to the following, where the edge indicated by identification number "E010" is defined as the edge between the node indicated by identification number "N006" and the node indicated by identification number "N007". In addition to node information 161 and edge information 162, the first storage unit 16 may further store map information indicating the shape of corridors or rooms within the facility, the location of fixed obstacles such as equipment or partitions, etc. The current state information 163 indicates the current state of the robot 10, such as "Preparing," indicating that it is waiting in a predetermined home position without performing any work; "Working," indicating that it is performing work; "Moving," indicating that it is moving to a desired position; or "Waiting," indicating that it is waiting to enter an edge which is a constraint area. The reservation status information 164 indicates the edges that are currently reserved for use as constraint regions on the movement path of the robot 10, which is in motion, and which are scheduled to pass through. For example, when the robot 10 moves from a node indicated by identification number "N001" to a node indicated by identification number "N006" via the edges indicated by identification numbers "E001", "E003", and "E005", the reservation status information 164 indicates that the edges indicated by identification numbers "E001", "E003", and "E005" are reserved. Schedule information 165 indicates the schedule for robot 10. The schedule includes, for each task, the departure time, departure point, work start time, work location, work content, work end time, return time, return point, and travel route. Schedule information 165 is set by the management server 20. The departure point and return point are set to predetermined home positions, for example, nodes indicated by identification number "N001". The departure point may also be the robot's current location.

[0031] The first processing unit 17 includes a processor such as a CPU or MPU, memory such as ROM or RAM, and peripheral circuits, and performs various signal processing for the robot 10. The first processing unit 17 includes state acquisition means 171 and path setting means 172, etc., which are implemented as functional modules of a program that runs on the processor. A DSP, LSI, ASIC, FPGA, etc. may be used as the first processing unit 17.

[0032] The first processing unit 17 receives schedule information for the robot 10 from the management server 20 via the first communication unit 15, and drives the drive unit 12 according to the received schedule information to move the robot 10. The first processing unit 17 moves along the paths defined by the node information 161 and edge information 162. Periodically, the first processing unit 17 acquires position detection signals or navigation signals from the position sensors 11 to detect the current position and direction of the robot 10. The first processing unit 17 identifies the current position and direction from the combination of the direction in which each laser sensor irradiated light and the distance to the object, as well as the positions of paths, rooms, obstacles, etc., shown in the map information. Alternatively, the first processing unit 17 determines the current position and direction by obtaining the latitude, longitude, and altitude from the acquired navigation signals. When the robot 10 arrives at the work position shown in the schedule information, the first processing unit 17 executes the work related to the work content shown in the schedule information.

[0033] The management server 20 includes an operation unit 21, a display unit 22, a second communication unit 23, a second storage unit 24, and a second processing unit 25, among others.

[0034] The operation unit 21 includes an input device such as a touch panel or keyboard, and an interface circuit that acquires signals from the input device. It accepts user operations and outputs a signal corresponding to the accepted operation to the second processing unit 25. The display unit 22 includes a display including a liquid crystal or organic EL display, and an interface circuit that outputs image data to the display. It displays various information such as images and text according to instructions from the second processing unit 25.

[0035] The second communication unit 23 has a communication interface circuit compliant with, for example, TCP / IP, and is connected to the communication network N. Alternatively, the second communication unit 23 has, for example, an antenna for transmitting and receiving wireless signals and a wireless communication interface circuit for transmitting and receiving signals via a wireless communication line in accordance with a wireless communication protocol such as a wireless LAN, and is connected to the communication network N via an access point. The second communication unit 23 outputs data received from the communication network N to the second processing unit 25 and transmits data input from the second processing unit 25 to the communication network N.

[0036] The second storage unit 24 includes semiconductor memory such as ROM and RAM, a magnetic disk or optical disk drive such as a CD-ROM or DVD-ROM, and its recording medium. The second storage unit 24 stores computer programs and various data for controlling the management server 20, and inputs and outputs this information to and from the second processing unit 25. The computer program may be installed in the second storage unit 24 from a computer-readable portable recording medium such as a CD-ROM or DVD-ROM using a known setup program or the like. The computer program may also be stored on a recording medium owned by a predetermined server and installed via a network. Furthermore, the second storage unit 24 stores data such as node information 241, edge information 242, robot table 243, edge table 244, etc. Node information 241 and edge information 242 are the same information as node information 161 and edge information 162 stored by the robot 10, respectively.

[0037] Figure 3(A) shows an example of the data structure of the robot table 243. As shown in Figure 3(A), the robot table 243 contains, for each of the multiple robots 10 owned by the robot management system 1, the identification number (robot ID), function, movement priority, housing size, movement speed, current position, movement direction, current status, reservation status, battery level, schedule information, etc., which are all linked and set together. The "Function" column indicates the functions that each robot can perform, including security within the facility, cleaning the facility, guiding facility users, transporting luggage within the facility, transporting first-aid supplies, and transporting sick and injured people. The "Movement Priority" column indicates whether a robot should be given priority for movement within the facility, and includes two classifications: "High" indicating high movement priority and "Low" indicating low movement priority. Security robots that guard the facility, first-aid supply transport robots that transport first-aid supplies such as AEDs, and rescue robots that transport sick and injured people are set to have a high movement priority. The "Current Position" column shows the current position of each robot 10 in the movement area it can move in, in three-dimensional coordinates. The "Movement Direction" column shows the direction in which each robot 10 is moving, for example, in terms of azimuth. The information shown in the "Current Status" column and the "Reservation Status" column is the same as the information shown in the current status information 163 and the reservation status information 164. The "Battery Level" column shows the remaining charge stored in the secondary battery installed in each robot 10. The "Schedule Information" shows the departure time, departure point, work start time, work location, work details, work end time, return time, return point, and travel route for multiple tasks. The identification number, function, movement priority, housing size, and movement speed of each robot 10 are set in the robot management system 1 when each robot 10 is put into use. The current position, direction of movement, current status, and battery level of each robot 10 are periodically transmitted from each robot 10 to the management server 20 and updated. The schedule information for each robot 10 is set by the controller at predetermined intervals such as daily, weekly, or monthly.

[0038] Figure 3(B) shows an example of the data structure of edge table 244. As shown in Figure 3(B), the edge table 244 contains, in relation to each edge, the identification number, constraint area, number of units using, first usage time, number of reserved units, second usage time, number of standby units, third usage time, cost value, etc., for each edge as it is stored in the edge information 242. In the edge table 244, the "Constraint Area" column indicates whether or not an edge is a constraint area. When the "Constraint Area" column is "YES", the corresponding edge has a constraint area, and when the "Constraint Area" column is "NO", the corresponding edge does not have a constraint area. The "Number of Units Using" column indicates the number of robots 10 using the constraint area, and the "First Usage Time" column indicates the time that robots 10 use the constraint area. The first usage time may be a predetermined usage time required for robots 10 to pass through the entire constraint area, or it may be the remaining time required for robots 10 to pass through the rest of the constraint area when robots 10 are passing through the constraint area. The "Number of Reserved Units" column indicates the number of robots 10 that have reserved the constraint area, and the "Second Usage Time" column indicates the time that the reserved robots 10 will use the constraint area. The "Number of Standby Units" column indicates the number of robots 10 waiting to enter the constraint area, and the "Third Usage Time" column indicates the time that the robots 10 will wait to enter the constraint area. The "Cost Value" column indicates the cost value, which is a weighted value based on the length of each edge, i.e., the distance value. The cost value is set to be larger as the edge length increases. For example, the cost value may be set proportionally to the edge length. The identification number, constraint area, and cost value of each edge are set in the robot management system 1 when the movement area of ​​the robot 10 is defined. The constraint area may be changed according to the arrangement of items and the conditions within the facility, such as congestion. The number of units in use, the number of units reserved, the number of units on standby, and the usage time for each edge are periodically transmitted from each robot 10 to the management server 20 and updated.

[0039] The second processing unit 25 includes a processor such as a CPU or MPU, memory such as ROM or RAM, and peripheral circuits, and executes various processes of the management server 20. The second processing unit 25 includes detection means 251, aggregation means 252, and transmission means 253, etc., which are implemented as functional modules of a program that runs on the processor. A DSP, LSI, ASIC, FPGA, etc. may be used as the second processing unit 25.

[0040] The second processing unit 25 receives the schedule setting for the robot 10 from the controller using the operation unit 21, and transmits the schedule information indicating the received schedule to the robot 10 via the second communication unit 23 to set the schedule for the robot 10. The second processing unit 25 also detects the status of multiple robots 10 and stores the status of each of the detected robots 10 in the robot table 243.

[0041] Figure 4 is a flowchart showing an example of the operation of the detection process performed by the management server 20. The detection process shown in Figure 4 is mainly performed by the second processing unit 25 in cooperation with each element of the management server 20, based on a program that is stored in the second storage unit 24 in advance. The detection process shown in Figure 4 is performed at predetermined detection cycles, such as every 10 seconds.

[0042] First, the detection means 251 acquires detection information from the robot 10 assigned the identification number "R001" (S101). The detection information includes current position information and current direction information indicating the current position and direction of movement, current state information indicating the current state, reservation information indicating the current reservation state, and battery level information. The detection means 251 transmits a detection information request signal to the robot 10 assigned the identification number "R001" indicating the transmission of a detection signal indicating detection information. In response to receiving the detection information request signal, the robot 10 assigned the identification number "R001" acquires a position detection signal from the position sensor 11 and detects its current position and direction. The robot 10 assigned the identification number "R001" also acquires current state information 163 and reservation state information 164 stored in the first storage unit. The robot 10 assigned the identification number "R001" also acquires battery level information indicating the remaining battery level. Robot 10, assigned identification number "R001", transmits a detection signal to the management server 20 indicating detection information including current location information and current direction information showing the detected current position and direction, acquired current status information 163 and reserved status information 164, and battery level information. Detection means 251 acquires detection information corresponding to the received detection signal and stores the current location information, current direction information, current status information, reserved status information and battery level information included in the acquired detection information in the robot table 243, associating them with identification number "R001".

[0043] Next, the detection means 251 determines whether or not it has acquired detection information from all robots 10 (S102). The processes shown in S101 and S102 are repeated until the detection means 251 determines that it has acquired detection information from all robots 10 (S102-YES). As the processes shown in S101 and S102 are repeated, detection information is sequentially acquired from multiple robots 10 corresponding to identification numbers "R002", "R003", and "R004", respectively.

[0044] When the detection means 251 determines that detection information has been obtained from all robots 10 (S102-YES), the aggregation means 252 aggregates the state of the robots 10 at each edge (S103). First, the aggregation means 252 refers to the node information 241 and the robot table 243 to estimate whether the current position of the robot 10 with identification number "R001" is one of the edges associated with identification numbers "E001" to "E010". Next, the aggregation means 252 refers to the robot table 243 to determine whether the current state of the robot 10 with identification number "R001" is either "in use" or "on standby" in the constraint area. Next, the aggregation means 252 counts up the number of current states of the constraint area included in the estimated edge (number of units in use, number of units on standby) by one and stores the counted number in the second storage unit 24. Next, the aggregation means 252 refers to the reservation status information stored in the robot table 243 and extracts the edges that are the constraint regions reserved by the robot 10 with identification number "R001". Then, the aggregation means 252 increments the number of "reserved" (reserved number) of the extracted edges by one and stores the incremented number in the second storage unit 24.

[0045] Next, the aggregation means 252 determines whether or not the states of all robots 10 have been aggregated (S104). The processes shown in S103 and S104 are repeated until the aggregation means 252 determines that the states of all robots 10 have been aggregated (S104-YES). As the processes shown in S103 and S104 are repeated, the current states of the robots 10 located at each edge associated with identification numbers "E001" to "E010" are aggregated. When the aggregation means 252 determines that the states of all robots 10 have been aggregated (S104-YES), the detection process ends.

[0046] Figure 5 is a sequence diagram showing an example of the operation of the movement path setting process performed by the robot 10. The movement path setting process shown in Figure 5 is mainly performed by the first processing unit 17 in cooperation with each element of the robot 10, based on a program stored in the first storage unit 16 in advance. The movement path setting process shown in Figure 5 is performed when the robot 10, also called the self-robot, starts work according to the schedule information and moves from the home position to the work start point.

[0047] First, the status acquisition means 171 sends a schedule request signal to the management server 20 requesting the robot 10 to send a schedule signal indicating the schedule of the next task to be performed (S201). The status acquisition means 171 sends a schedule request signal to the management server 20, for example, when the previous task is completed and the robot returns to a predetermined standby position. The schedule request signal includes information indicating the transmission of a schedule signal, the time the schedule signal was transmitted, and an identification number indicating the robot 10 that transmitted the schedule signal.

[0048] Next, the transmitting means 253 transmits a schedule signal to the robot 10 indicating the schedule of the next task to be performed by the robot 10 (S202). The transmitting means 253 obtains schedule information indicating the schedule of the next task to be performed by the robot 10 that transmitted the schedule signal in the process shown in S201, by referring to the "Schedule Information" column of the robot table 243. Next, the transmitting means 253 generates a schedule signal corresponding to the acquired schedule information and transmits the generated schedule signal to the robot 10 that transmitted the schedule request signal.

[0049] Next, the state acquisition means 171 acquires schedule information indicating the schedule of the next task to be performed by the robot 10 (S203). The state acquisition means 171 acquires schedule information corresponding to the schedule signal transmitted in the process shown in S202 and stores the acquired schedule information as schedule information 165 in the first storage unit 16. The robot 10 acquires schedule information 165 indicating that the node indicated by identification number "N001" is the starting point and the node indicated by identification number "N006" is the destination point.

[0050] Next, the route setting means 172 searches for multiple routes from the robot 10's starting point to the destination point (S204). The route setting means 172 refers to the schedule information 165 and executes a process to search for multiple routes at a predetermined set time earlier than the departure time set in the schedule information 165. The route setting means 172 uses the graph structure shown in Figure 2(C) to identify all routes from the node indicated by identification number "N001", which is the home position of each robot 10, to the node indicated by identification number "N006", which is the work position. The route setting means 172 searches for multiple routes using known graph search techniques, such as Dijkstra's algorithm or A* (A-star) search algorithm. The route setting means 172 extracts the first route R1 and the second route R2 as search results and stores the first route information and the second route information, which represent the extracted first route R1 and second route R2, respectively, in the first storage unit 16. As shown in Figure 6(A), the route setting means 172 searches for a route that passes through the edges indicated by identification numbers "E001", "E003", and "E005" in order as the first route R1. The route setting means 172 also searches for a route that passes through the edges indicated by identification numbers "E002", "E004", "E007", and "E010" in order as the second route R2.

[0051] Next, the state acquisition means 171 sends a constraint area request signal to the management server 20 requesting the transmission of constraint area signals indicating the constraint areas included in the first path R1 and the second path R2, respectively, which were searched in the process shown in S204 (S205). At this time, the management server 20 may also be sent a constraint area request signal requesting the transmission of constraint area signals indicating the constraint areas included in all paths (edges).

[0052] Next, the transmitting means 253 transmits constraint area signals to the robot 10 indicating the constraint areas included in the first path R1 and the second path R2, respectively (S206). The transmitting means 253 extracts constraint area information indicating the constraint areas included in the first path R1 and the second path R2, respectively, by referring to the edge information 242 and the "Constraint Area" column of the edge table 244. The transmitting means 253 transmits constraint area signals corresponding to the extracted constraint area information to the robot 10. The transmitting means 253 extracts information indicating identification numbers "E001" and "E004" as constraint area information. The transmitting means 253 transmits constraint area signals indicating constraint area information to the robot 10.

[0053] Next, the state acquisition means 171 acquires constraint area information corresponding to the constraint area signal transmitted in the process shown in S206 (S207). The state acquisition means 171 stores the constraint area information corresponding to the constraint area signal transmitted in the process shown in S206, that is, information indicating identification numbers "E001" and "E004", in the first storage unit 16. As shown in Figure 6(B), the state acquisition means 171 acquires constraint region information indicating that the edges indicated by identification numbers "E001" and "E004" are constraint regions C1 to C2.

[0054] Next, the state acquisition means 171 sends a robot state request signal to the management server 20 requesting the transmission of robot state signals indicating the status of other robots other than its own robot that are located in the first path R1 and the second path R2, which are multiple paths explored in the process shown in S204 (S208). At this time, a robot state request signal requesting the transmission of robot state signals indicating the status of all other robots may also be sent to the management server 20. Alternatively, a robot state request signal requesting the transmission of robot state signals indicating the status of other robots located around the first path R1 and the second path R2, which are multiple paths explored in the process shown in S204 may also be sent to the management server 20.

[0055] Next, the transmitting means 253 transmits robot status signals to the robot 10 indicating the status of other robots located on the first path R1 and the second path R2 (S209). The transmitting means 253 extracts robot status information indicating the robot status of other robots 10 located on the first path R1 and the second path R2, using the "current position" column of the robot table 243 as a reference. The transmitting means 253 transmits robot status signals corresponding to the extracted robot status information to the robot 10.

[0056] Next, the state acquisition means 171 acquires robot state information corresponding to the robot state signal transmitted in the process shown in S209 (S210). The state acquisition means 171 stores the robot state information corresponding to the robot state signal transmitted in the process shown in S209 in the first storage unit 16. As shown in Figure 6(C), the state acquisition means 171 acquires robot state information indicating that the first robot 10a and the second robot 10b are present at the edge indicated by identification number "E003".

[0057] Then, the path setting means 172 prioritizes one of the multiple paths explored in the process shown in S204 and sets it as the movement path based on the presence or absence of constraint areas in the multiple paths and the state of other robots present in the multiple paths (S211). The path setting means 172 refers to the node information 161 and the edge information 162 and estimates the positions of the first robot 10a and the second robot 10b, which are other robots 10 corresponding to the robot state information. The path setting means 172 estimates that the first robot 10a and the second robot 10b are located at the edge indicated by the identification number "E003". The path setting means 172 determines that the first path R1 includes the constraint area C1 and that the first robot 10a and the second robot 10b are present. The path setting means 172 determines that the second path R2 includes the constraint area C2, but that no other robots 10 are present. The route setting means 172 determines that the number of constraint regions included in the first route R1 and the second route R2 are the same, and that the number of robots 10 in the first route R1 is greater than the number of robots 10 in the second route R2. The route setting means 172 determines that since the number of robots 10 in the first route R1 is greater than the number of robots 10 in the second route R2, selecting the second route R2 is less likely to result in waiting for other robots 10 to pass. The route setting means 172 sets the second route R2 as the travel route because selecting the second route R2 is less likely to result in waiting for other robots 10 to pass and is expected to allow the robots to reach the destination node indicated by identification number "N006" earlier. Note that if the number of robots 10 in the first route R1 and the number of robots 10 in the second route R2 are equal, the route with fewer constraint regions included in each route may be set as the travel route.

[0058] The robot management system 1 can efficiently set a movement path even when constraint areas are set in the movement path by setting the movement path based on the presence or absence of constraint areas in the multiple paths explored and the status of other robots present in the multiple paths explored. The robot management system 1 can also efficiently set a movement path even when constraint areas are set in the movement path by setting the movement path based on robot status information indicating the number of other robots present in each of the multiple paths.

[0059] The robot management system 1 sets a movement path based on robot status information indicating the number of other robots present in each of the multiple paths. However, the robot management system according to the embodiment may set a movement path based on robot status information indicating the presence or absence of other robots in each of the multiple paths.

[0060] Furthermore, the robot management system according to this embodiment may set a movement path based on the relationship between the positions of other robots and the positions of the constraint area. Figure 6(D) shows the graph structure of the state after the process shown in S210 in the travel path setting process according to the first modified example has been executed. In the movement path setting process according to the first modified example, in the process shown in S209, the transmitting means 253 refers to the "current position" column of the robot table 243 and extracts robot state information indicating the robot state of other robots 10 located on the first path R1 and the second path R2. The transmitting means 253 transmits a robot state signal corresponding to the extracted robot state information to the robot 10. In the state shown in Figure 6(D), in the process shown in S210, the first robot 10a is located at the edge indicated by identification number "E003", and the second robot 10b is located at the edge indicated by identification number "E010". The path setting means 172 refers to the node information 161 and the edge information 162 and calculates the distance between each of the first robot 10a and the second robot 10b, which are other robots 10 corresponding to the robot state information, and the constraint regions C1 and C2. The path setting means 172 calculates the distance between the node indicated by identification number "N002", which is the end of the edge indicated by identification number "E001", which is included in the first path R1 and is the closest constraint region C1 to the first robot 10a, and the current position of the first robot 10a. The route setting means 172 calculates the distance between the node indicated by identification number "N005", which is the end of the constraint region C2 indicated by identification number "E004" that is included in the second route R2 and is closest to the second robot 10b, and the current position of the second robot 10b. The route setting means 172 determines that if the second route R2 is selected, the waiting time will be longer than if the first route R1 is selected, because the distance between the end of the constraint region C2 closest to the second robot 10b and the current position of the second robot 10b is longer than the distance between the end of the constraint region C1 closest to the first robot 10a and the current position of the first robot 10a. The route setting means 172 determines that if the second route R2 is selected, the waiting time will be longer than if the first route R1 is selected, so the route setting means 172 determines that if the first route R1 is selected, the possibility of waiting for other robots 10 to pass is lower. The route setting means 172 sets the first route R1 as the travel route because it is expected that selecting the first route R1 will reduce the likelihood of having to wait for other robots 10 to pass, and will allow the robot to reach the destination node indicated by identification number "N006" earlier. In the movement path setting process according to the first modified example, the robot management system according to the embodiment can efficiently set a movement path even when a constraint area is set in the movement path, by setting a movement path based on the relationship between the position of other robots and the position of the constraint area.

[0061] Furthermore, the robot management system according to the embodiment may set a movement path based on the positions of other robots present in each of the multiple paths, the direction of movement of other robots, and the position of the constraint area. Figure 7(A) shows the graph structure of the state after the process shown in S210 has been executed in the travel path setting process according to the second modified example. In the movement path setting process according to the second modified example, in the process shown in S209, the transmitting means 253 extracts robot state information indicating the position and movement direction of other robots 10 located on the first path R1 and the second path R2, by referring to the "current position" column and the "movement direction" column of the robot table 243. The transmitting means 253 transmits a robot state signal corresponding to the extracted robot state information to the robot 10. In the state shown in Figure 7(A), in the process shown in S210, the first robot 10a is located at the edge indicated by identification number "E003" and moves toward the edge indicated by identification number "E001", which is the constraint region C1. On the other hand, the second robot 10b is located at the edge indicated by identification number "E002" and moves toward the edge indicated by identification number "E004", which is the constraint region C2. The path setting means 172 determines that since the first robot 10a moves toward the edge that is the constraint region C1, selecting the first path R1 will result in a longer waiting time than selecting the second path R2. Since selecting the first path R1 will result in a longer waiting time than selecting the second path R2, the path setting means 172 determines that selecting the second path R2 is less likely to result in waiting for other robots 10 to pass. The route setting means 172 sets the second route R2 as the travel route because it is expected that selecting the second route R2 will reduce the likelihood of having to wait for other robots 10 to pass, and will allow the robot to reach the destination node indicated by identification number "N006" earlier. In the second modified example of the movement path setting process, the robot management system according to the embodiment can efficiently set a movement path even when a constraint area is set on the movement path, by setting the movement path based on the movement direction of other robots present in each of the multiple paths.

[0062] In the movement path setting process according to the second modification, the robot management system sets the movement path based on the positions of other robots present in each of the multiple paths, the movement direction of those robots, and the position of the constraint area. However, the robot management system according to the embodiment may set the movement path based on the positions of other robots present in each of the multiple paths, the movement path of those robots, and the position of the constraint area. Furthermore, the robot management system may determine that there is a long waiting time not only when the robot 10 moves toward the edge which is the constraint area, but also when the robot 10 moves toward the destination point.

[0063] Furthermore, the robot management system according to this embodiment may set a movement path based on the positions of other robots present in each of the multiple paths, the size of the housings of the other robots, and the location of the constraint area. Figure 7(B) shows the graph structure of the state after the process shown in S210 has been executed in the travel path setting process according to the third modified example. In the movement path setting process according to the third modified example, in the process shown in S209, the transmitting means 253 extracts robot state information indicating the positions and housing sizes of other robots 10 located on the first path R1 and the second path R2, by referring to the "current position" column and the "size" column of the robot table 243. The transmitting means 253 transmits a robot state signal corresponding to the extracted robot state information to the robot 10. In the state shown in Figure 7(B), in the process shown in S210, the first robot 10a is located at the edge indicated by identification number "E003" in the first path R1, and the second robot 10b is located at the edge indicated by identification number "E010" in the second path R2. Also, the size of the housing of the second robot 10b is larger than the size of the housing of the first robot 10a. The path setting means 172 determines that since the size of the housing of the second robot 10b located in the second path R2 is larger than the size of the housing of the first robot 10a located in the first path R1, selecting the second path R2 is likely to result in a longer waiting time than selecting the first path R1. The path setting means 172 determines that since selecting the second path R2 is likely to result in a longer waiting time than selecting the first path R1, selecting the first path R1 is less likely to result in waiting for other robots 10 to pass. The route setting means 172 sets the first route R1 as the travel route because it is expected that selecting the first route R1 will reduce the likelihood of having to wait for other robots 10 to pass, and will allow the robot to reach the destination node indicated by identification number "N006" earlier. In the movement path setting process according to the third modified example, the robot management system according to the embodiment can efficiently set movement paths even when constraint areas are set in the movement paths, by setting movement paths based on the size of the housings of other robots present in each of the multiple paths.

[0064] In the movement path setting process according to the third modified example, the robot management system determines the size of robot 10 by referring to the "size" column of the robot table 243, which shows the size of the housing of other robots 10. However, the robot management system according to the embodiment may determine the size of robot 10 by referring to information regarding the presence or absence of arm protrusion and the size of the load to be carried.

[0065] Furthermore, the robot management system according to this embodiment may set a movement path based on the positions of other robots present in each of the multiple paths, their movement speeds, and the positions of the constraint areas. Figure 7(C) shows the graph structure of the state after the process shown in S210 has been executed in the movement path setting process according to the fourth modified example. In the movement path setting process according to the fourth modified example, in the process shown in S209, the transmitting means 253 extracts robot state information indicating the position and movement speed of other robots 10 located on the first path R1 and the second path R2, by referring to the "current position" column and the "movement speed" column of the robot table 243. The transmitting means 253 transmits a robot state signal corresponding to the extracted robot state information to the robot 10. In the state shown in Figure 7(C), in the process shown in S210, the first robot 10a is located at the edge indicated by identification number "E003" in the first path R1, and the second robot 10b is located at the edge indicated by identification number "E010" in the second path R2. Also, the movement speed of the second robot 10b is slower than that of the first robot 10a. The path setting means 172 determines that since the movement speed of the second robot 10b, which is located on the second path R2, is slower than that of the first robot 10a, which is located on the first path R1, selecting the second path R2 is likely to result in a longer waiting time than selecting the first path R1. The path setting means 172 determines that if the second path R2 is selected, the passing time with the second robot 10b will be longer, and the waiting time is likely to be longer than if the first path R1 were selected, therefore, selecting the first path R1 is less likely to result in waiting for other robots 10 to pass. The route setting means 172 sets the first route R1 as the travel route because selecting the first route R1 is expected to reduce the likelihood of waiting for other robots 10 to pass and allow the robot to reach the destination node indicated by identification number "N006" earlier. In the travel route setting process according to the fourth modified example, the robot management system sets the travel route based on the travel speed of other robots present in each of the multiple routes, regardless of whether the direction of movement of other robots is the same as or opposite to the direction of movement of robot 10. When the direction of movement of other robots is the same as the direction of movement of robot 10, robot 10 may waste time when overtaking other robots with slower travel speeds. Also, when the direction of movement of other robots is opposite to the direction of movement of robot 10, robot 10 may waste time when passing other robots with slower travel speeds. In the movement path setting process according to the fourth modified example, the robot management system according to the embodiment can efficiently set a movement path even when a constraint area is set on the movement path, by setting the movement path based on the movement speed of other robots present in each of the multiple paths.

[0066] Furthermore, the robot management system according to the embodiment may set movement paths based on the positions of other robots present in each of the multiple paths, the movement priority of those robots, and the positions of the constraint areas. Figure 7(D) shows the graph structure of the state after the process shown in S210 in the travel path setting process according to the fifth modified example has been executed. In the movement path setting process according to the fifth modified example, in the process shown in S209, the transmitting means 253 extracts robot state information indicating the position and movement priority of other robots 10 located on the first path R1 and the second path R2, by referring to the "current position" column and the "movement priority" column of the robot table 243. The transmitting means 253 transmits a robot state signal corresponding to the extracted robot state information to the robot 10. In the state shown in Figure 7(D), in the process shown in S210, the first robot 10a is located at the edge indicated by identification number "E003" included in the first path R1, and the second robot 10b is located at the edge indicated by identification number "E010" included in the second path R2. Also, the movement priority of the first robot 10a is "high (H)", and the movement priority of the second robot 10b is "low (L)". Since the movement priority of the first robot 10a located on the first path R1 is "high", it is determined that if the first path R1 is selected, there is a risk of interference such as passing or overtaking with the first robot 10a, which has a "high" movement priority. The path setting means 172 determines that if the first path R1 is selected, there is a risk of interference with the first robot 10a, which has a "high" movement priority, and therefore sets the second path R2, which does not have a robot 10 with a "high" movement priority, as the movement path. In the fifth modified example of the movement path setting process, the robot management system according to the embodiment can efficiently set a movement path even when a constraint area is set on the movement path, by setting the movement path based on the movement priority of other robots present in each of the multiple paths. In this embodiment, the robot management system sets the second path R2, which does not contain any robots 10 with high movement priority, as the movement path, and does not set the first path R1, which contains robots 10 with high movement priority, as the movement path. However, in cases where there are no other movement paths except for paths where other robots with high movement priority exist, the robot management system according to this embodiment may set the path where other robots with high movement priority exist as the movement path. The robot management system according to this embodiment can be made less likely to set paths where other robots with high movement priority exist as movement paths.

[0067] Furthermore, the robot management system according to this embodiment may set the movement path based on the path length of the route from the starting point to the destination point, and the robot state acquired by the state acquisition means. Figure 8 is a sequence diagram showing an example of the operation of the movement path setting process according to the sixth modified example. The movement path setting process shown in Figure 8 is executed mainly by the first processing unit 17 in cooperation with each element of the robot 10, based on a program stored in the first storage unit 16 in advance. The processes shown in S301 to S309 are the same as the processes shown in S201 to S203 and S205 to S210, except that constraint area information showing all constraint areas is extracted in the process shown in S305 and constraint area information showing all constraint areas is acquired in the process shown in S306. Therefore, a detailed explanation of the processes shown in S301 to S309 is omitted here.

[0068] Following the process shown in S309, the status acquisition means 171 sends a cost value request signal to the management server 20 requesting the transmission of a cost value signal indicating the cost value of an edge included in the route within the facility (S310).

[0069] Next, the transmitting means 253 transmits a cost value signal to the robot 10 indicating the cost value of the edge included in the route within the facility (S311). The transmitting means 253 extracts cost value information indicating the cost value of the edge included in the route within the facility by referring to the edge information 242 and the "cost value" column of the edge table 244. The transmitting means 253 transmits a constraint area signal corresponding to the extracted cost value information to the robot 10. Note that the transmitting means 253 may extract cost value information indicating only the cost value of the edge existing between the starting point and the destination point, rather than extracting cost value information indicating the cost value of all edges included in the route within the facility.

[0070] Next, the state acquisition means 171 acquires cost value information corresponding to the cost value signal transmitted in the process shown in S312 (S312). The state acquisition means 171 stores the cost value information corresponding to the cost value signal transmitted in the process shown in S311 in the first storage unit 16. As shown in Figure 9(A), the status acquisition means 171 acquires cost value information indicating the respective cost values ​​"C001" to "C010" for each of the identification numbers "E001" to "E010" included in the route within the facility.

[0071] Then, the route setting means 172 sets a movement path based on the path length from the starting point to the destination point and the robot state acquired by the state acquisition means (S313). The route setting means 172 determines that all of the constraint areas C1 and C2 are in use and that constraint area C1 is in standby. The route setting means 172 determines that the edges indicated by identification numbers "E001" and "E004" are constraint areas C1 and C2, so it corrects the cost values ​​of the edges indicated by identification numbers "E001" and "E004" to increase. Also, the route setting means 172 determines that the first robot 10a and the second robot 10b are located at the edge indicated by identification number "E003", so it corrects the cost values ​​of the edge indicated by identification number "E003" to increase. As shown in Figure 9(B), the route setting means 172 increases the cost value of the edge indicated by identification number "E001", which is a constraint region C1 that is in use and in standby state, from "C001" to "C001+A1". The route setting means 172 also increases the cost value of the edge indicated by identification number "E004", which is a constraint region C2 that is in use, from "C004" to "C004+A1". Furthermore, as shown in Figure 9(C), the route setting means 172 increases the cost value of the edge indicated by identification number "E003", which is a constraint region C2 that is in use, from "C003" to "C003+A2". Next, the route setting means 172 identifies the entire route from the node indicated by identification number "N001", which is the home position of each robot 10, to the node indicated by identification number "N006", which is the work position. The route setting means 172 uses known graph search techniques, such as Dijkstra's algorithm or A* (A-star) search algorithm, to search for the route that minimizes the sum of the corrected cost values. As shown in Figure 9(D), the route setting means 172 sets a travel route that sequentially passes through the edges indicated by identification numbers "E002", "E004", "E007", and "E010". In the movement path setting process according to the sixth modified example, the robot management system according to the embodiment sets the movement path based on the path length of the path from the starting point to the destination point and the robot state information acquired by the state acquisition means, thereby enabling efficient movement path setting even when a constraint area is set in the movement path.

[0072] In the movement path setting process according to the sixth modified example, the robot management system sets the movement path based on robot state information indicating the number of other robots present in each of the multiple paths. However, the robot management system according to the embodiment may set the movement path based on robot state information indicating the presence or absence of other robots present in each of the multiple paths. The robot management system according to the embodiment may also set the movement path based on robot state information indicating the relationship between the position of other robots and the position of the constraint area. The robot management system according to the embodiment may also set the movement path based on robot state information indicating the direction of movement of other robots present in each of the multiple paths. The robot management system according to the embodiment may also set the movement path based on robot state information indicating the movement path of other robots present in each of the multiple paths. The robot management system according to the embodiment may also set the movement path based on robot state information indicating the size of the housing of other robots present in each of the multiple paths. The robot management system according to the embodiment may also set the movement path based on robot state information indicating the movement speed of other robots present in each of the multiple paths. The robot management system according to the embodiment may also set the movement path based on robot state information indicating the movement priority of other robots present in each of the multiple paths.

[0073] Furthermore, in the robot management system 1, the robot 10 performs a process to set a movement path. However, in the robot management system according to this embodiment, the management server may perform a process to set a movement path from the starting point to the destination point of the first robot among the multiple robots. When the management server 20 performs a process to set a movement path, the management server has a state acquisition means, a path setting means, and a transmission means. In this case, the state acquisition means of the management server acquires robot state information indicating the state of the multiple robots present in the movement area. The path setting means of the management server sets the movement path of the first robot based on the presence or absence of a constraint area, which is one or more areas arranged in the movement area where constraints on the robot's actions are imposed, and the state of other robots other than the first robot indicated in the robot state information acquired by the state acquisition means. The transmission means of the management server transmits the movement path of a predetermined robot, also referred to as the first robot, set by the path setting means, to the predetermined robot. The robot can efficiently set a movement path by controlling its movement based on the received movement path.

[0074] Furthermore, one of the multiple robots 10, designated as the master robot, may perform the process of setting the movement paths of the other robots 10. When the master robot performs the process of setting the movement paths of the other robots, the master robot stores a robot table 244 and an edge table 245, and has state acquisition means and path setting means to acquire robot state information of the other robots and set the movement path of each of the other robots. In this case, the master robot transmits the movement paths of the other robots set by the path setting means to each of the other robots. Alternatively, a robot control server different from the management server 20 may have at least one of the state acquisition means and path setting means, and the management server 20 and the robot control server may cooperate to set the movement paths of each robot. Also, all of the multiple robots 10 may store a robot table 244 and an edge table 245, and have state acquisition means and path setting means to acquire robot state information of the other robots and set the movement paths of each of the other robots.

[0075] Furthermore, the robot management system described sets the movement path based on the presence or absence of constraint areas along the path and the status of other robots. However, the robot management system according to the embodiment may set the movement path based on the arrangement information of constraint areas and the status of other robots. The arrangement information of constraint areas may be information indicating the presence or absence of constraint areas along the path, information indicating the number of constraint areas along the path, or information indicating the position of constraint areas in the movement area, including the coordinates of each constraint area in a map showing the movement area.

[0076] A robot management system according to one embodiment of the present invention can contribute to solving social issues such as the declining workforce and long working hours. Furthermore, a robot management system according to one embodiment of the present invention can contribute to achieving Goal 9 of the Sustainable Development Goals (SDGs) adopted by the United Nations, "Build resilient infrastructure, promote inclusive and sustainable industrialization and foster innovation." [Explanation of symbols]

[0077] 1. Robot Management System 10 Robots 20 Management Server 171 State acquisition means 172 Route setting means

Claims

1. A state acquisition means for acquiring robot state information that indicates the state of other robots in the robot's movement area, Information on the arrangement of constraint regions, which are one or more regions arranged in the movement region and which are regions on which the robot's actions are restricted; and a path setting means that sets a movement path from the robot's starting point to the destination point based on the state of the other robots shown in the robot state information acquired by the state acquisition means. A robot equipped with [the following features].

2. The state acquisition means acquires information indicating the position of the other robot within the movement area as robot state information, The robot according to claim 1, wherein the path setting means sets the movement path by searching for a path based on the arrangement information indicating the position of the constraint area in the movement area and the position of the other robot acquired by the state acquisition means.

3. The robot according to claim 2, wherein the path setting means sets the movement path based on the relationship between the positions of other robots present around the constraint area and the position of the constraint area.

4. The route setting means searches for multiple routes from the robot's starting point to the destination point, The state acquisition means acquires information indicating the state of other robots present in at least the multiple paths that have been explored as robot state information, The robot according to claim 1, wherein the path setting means sets one of the explored paths as the movement path based on the presence or absence of the constraint area in the explored plurality of paths and the state of the other robots.

5. The status acquisition means acquires information indicating the presence or number of other robots as robot status information, The robot according to claim 4, wherein the route setting means sets as the travel route a route from the starting point to the destination point in which the number of constraint areas is small and the number of other robots is small.

6. The state acquisition means acquires information indicating the position of the other robot and information indicating the direction or path of movement of the other robot as robot state information. The robot according to any one of claims 1 to 3, wherein the path setting means sets the movement path based on the position of the other robot, the direction of movement or movement path of the other robot, and the position of the constraint area.

7. The state acquisition means acquires information indicating the position of the other robot and information indicating the size of the other robot as robot state information. The robot according to any one of claims 1 to 3, wherein the path setting means sets the movement path based on the position of the other robot, the size, and the position of the constraint area.

8. The state acquisition means acquires information indicating the position of the other robot and information indicating the movement speed of the other robot as the robot state information. The robot according to any one of claims 1 to 3, wherein the path setting means sets the movement path based on the position of the other robot, the movement speed of the other robot, and the position of the constraint area.

9. The state acquisition means acquires information indicating the position of the other robot and information indicating the movement priority of the other robot as robot state information. The robot according to any one of claims 1 to 3, wherein the path setting means sets the movement path based on the position of the other robot, the movement priority, and the position of the constraint area.

10. A robot management system comprising multiple robots and a management server, A state acquisition means for acquiring robot state information indicating the state of the multiple robots present in the moving area, The system includes a path setting means for setting a travel path from the starting point to the destination point of a first robot among the plurality of robots, The path setting means sets the movement path of the first robot based on the arrangement information of constraint areas, which are one or more areas arranged in the movement area and which are areas on which the robot's actions are restricted, and the state of other robots other than the first robot as shown in the robot state information acquired by the state acquisition means. Robot management system.

11. A management server that manages multiple robots, A state acquisition means for acquiring robot state information indicating the state of the multiple robots present in the moving area, A path setting means for setting a movement path from the starting point to the destination point of the first robot among the plurality of robots, The system includes a transmission means for transmitting the movement path set by the route setting means to the first robot, The path setting means sets the movement path of the first robot based on the arrangement information of constraint areas, which are one or more areas arranged in the movement area and which are areas on which the robot's actions are restricted, and the state of other robots other than the first robot as shown in the robot state information acquired by the state acquisition means. Management server.