KR20180031153A - Airport robot, and method for operating server connected thereto - Google Patents

Abstract

An airport robot disposed and moving in an airport according to an embodiment of the present invention comprises: a travel driving portion for moving the airport robot; a position recognition portion for recognizing the position of the airport robot; and a control portion for receiving position information of other airport robot from the other airport robot moving in the airport, recognizing the position of the other airport robot based on the received position information, detecting presence or absence of sensor interference along the vicinity of the airport robot and the other airport robot based on a recognition result, and controlling the travel driving portion to change a moving direction of the airport robot based on the detection result.

Description

TECHNICAL FIELD [0001] The present invention relates to an airport robot and an operation method of a server connected to the airport robot.

The present invention relates to an airport robot and an operation method of a server connected to the airport robot, which can minimize a malfunction due to sensor interference with another airport robot.

Recently, the introduction of robots and the like has been discussed in order to provide users with various services more effectively in a public place such as an airport. Users can use various services such as airport guidance service, boarding information guidance service, and other multimedia contents provision service through the robot arranged at the airport.

The airport robots disposed in the airport can freely move and provide various services as described above. The airport robots may be equipped with various sensors necessary for sensing the surrounding environment or providing the service, and may perform the sensing operation using the moving sensors.

When the airport robots move freely, the airport robots may be adjacent to each other. There is a possibility that a signal or light emitted from a sensor provided in each of the airport robots may interfere with each other when the airport robots are adjacent to each other. Such an interference phenomenon may cause malfunction of the airport robot. When the malfunction of the airport robot occurs, the reliability of the airport robot is lowered, and furthermore, the image of the airport company or the airport robot manufacturer may be lost.

A first object of the present invention is to provide an airport robot capable of detecting proximity to other airport robots in order to prevent malfunction due to sensor interference between a plurality of airport robots disposed in an airport.

A second object of the present invention is to provide an airport robot capable of detecting the proximity of other airport robots in various ways.

A third object of the present invention is to provide an airport robot capable of detecting whether or not a communication with a different airport robot is connected or disconnected from another airport robot even when the connection is disconnected.

According to one aspect of the present invention, an airport robot according to an embodiment of the present invention includes: a travel driving unit for moving the airport robot; And a position recognition unit. The airport robot may include a control unit for receiving position information of another airport robot moving in the airport and recognizing the position of another airport robot. The control unit may detect whether the airport robot is adjacent to the other airport robot based on the recognition result, and may control the travel driving unit to change the moving direction of the airport robot based on the detection result.

The controller calculates the distance between the airport robot and the other airport robot on the basis of the result of the position recognition and can detect that the airport robot and the other airport robot are adjacent when the calculated distance is shorter than the reference distance.

According to an aspect of the present invention, the reference distance is set based on a sensing distance of a sensor included in the airport robot, and in particular, the reference distance is determined based on a sensing distance of a sensor included in the airport robot, May be set to have a value larger than a sum of sensing distances of the sensors included in the other airport robots.

According to an aspect of the present invention, an airport robot includes a local area wireless communication module supporting a local area wireless communication system. The airport robot can detect whether or not the other airport robots are adjacent based on whether a response signal to the advertisement signal outputted through the near field wireless communication module is received.

The airport robot may sense that the other airport robot is adjacent when the response signal is received.

According to one embodiment of the present invention, the airport robot can calculate the distance to the other airport robots based on the position information of the other airport robots disposed at the airport. When the proximity of another airport robot is detected based on the calculation result, the airport robot can change the direction of travel. Accordingly, it is possible to prevent the possibility of malfunction due to sensor interference that may occur along with the proximity of another airport robot, thereby improving the reliability of the airport robot.

Also, the airport robot according to the embodiment of the present invention can detect the proximity of another airport robot using the advertisement signal outputted from the near field wireless communication module. That is, the airport robot according to the embodiment of the present invention can detect the proximity of other airports and change the direction of movement even when communication connection with other airport robots is not performed or communication connection is unexpectedly disconnected.

1 is a view for explaining a structure of an airport robot system according to an embodiment of the present invention.
2 is a block diagram illustrating a hardware configuration of an airport robot according to an embodiment of the present invention.
FIG. 3 is a detailed view showing a configuration of a micom and AP of an airport robot according to another embodiment of the present invention.
4 is a view showing an example in which a plurality of airport robots according to an embodiment of the present invention are moved within an airport to provide services.
5 is a flowchart for explaining a method of operating an airport robot of any one of a plurality of airport robots disposed in an airport according to an embodiment of the present invention.
6A to 6C are views illustrating an operation of the airport robot shown in Fig.
7 is a ladder diagram for explaining an operation of the server included in the airport robot system according to the embodiment of the present invention to control the movement of the airport robot.
8A to 8C are diagrams illustrating operations of a server and an airport robot according to the embodiment shown in FIG.
9 is a flowchart illustrating an operation method of an airport robot of one of a plurality of airport robots according to another embodiment of the present invention.
Figs. 10A to 10C are diagrams illustrating an operation of the airport robot shown in Fig. 9. Fig.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, wherein like reference numerals are used to designate identical or similar elements, and redundant description thereof will be omitted. The suffix "module" and " part "for the components used in the following description are given or mixed in consideration of ease of specification, and do not have their own meaning or role.

1 is a view for explaining a structure of an airport robot system according to an embodiment of the present invention.

An airport robot system according to an embodiment of the present invention may include an airport robot 100, a server 300, a camera 400, and a mobile terminal 500.

The airport robot 100 can perform patrol, guidance, cleaning, disinfection and transportation within the airport.

The airport robot 100 can transmit and receive signals to / from the server 300 or the mobile terminal 500. For example, the airport robot 100 can transmit and receive signals including the server 300 and the information on the situation in the airport. In addition, the airport robot 100 can receive image information of each area of the airport from the camera 400 in the airport. Therefore, the airport robot 100 can monitor the situation of the airport by synthesizing the image information photographed by the airport robot 100 and the image information received from the camera 400.

The airport robot 100 can receive commands directly from the user. For example, it is possible to directly receive a command from a user through input or voice input touching a display unit provided in the airport robot 100. The airport robot 100 may perform operations such as patrol, guidance, and cleaning according to a command received from the user, the server 300, or the mobile terminal 500 and the like.

Next, the server 300 may receive information from the airport robot 100, the camera 400, and / or the mobile terminal 500. The server 300 may collectively store and manage information received from each of the devices. The server 300 may transmit the stored information to the airport robot 100 or the mobile terminal 500. In addition, the server 300 may transmit a command signal to each of a plurality of airport robots 100 disposed at an airport.

The camera 400 may include a camera installed in the airport. For example, the camera 400 may include a plurality of closed circuit television (CCTV) cameras installed in an airport, an infrared heat sensing camera, and the like. The camera 400 may transmit the photographed image to the server 300 or the airport robot 100.

The mobile terminal 500 can exchange data with the server 300 in the airport. For example, the mobile terminal 500 may receive airport-related data such as flight time schedules, airport maps, etc. from the server 300. The user can obtain necessary information from the server 300 through the mobile terminal 500 by receiving the information. In addition, the mobile terminal 500 can transmit data such as a photograph, a moving picture, a message, and the like to the server 300. For example, the user can request the cleaning of the corresponding area by transmitting the lost photograph to the server 300 and receiving the missing photograph, or photographing the photograph of the area requiring cleaning in the airport to the server 300.

In addition, the mobile terminal 500 can transmit and receive data to and from the airport robot 100.

For example, the mobile terminal 500 may transmit a signal for calling the airport robot 100, a signal for requesting a specific operation, or an information request signal to the airport robot 100. The airport robot 100 may move to the position of the mobile terminal 500 or perform an operation corresponding to the command signal in response to the paging signal received from the mobile terminal 500. [ Or the airport robot 100 may transmit data corresponding to the information request signal to the mobile terminal 500 of each user.

2 is a block diagram illustrating a hardware configuration of an airport robot according to an embodiment of the present invention.

As shown in FIG. 2, the hardware of the airport robot 100 according to an embodiment of the present invention may be composed of a Micom group and an AP group. The microcomputer 110 may include a microcomputer 110, a power source 120, an obstacle recognition unit 130, and a driving unit 140. The AP group may include an AP 150, a user interface unit 160, an object recognition unit 170, a location recognition unit 180, and a LAN 190.

The microcomputer 110 may manage a driving unit 120 including a battery or the like among the hardware of the airport robot, an obstacle recognizing unit 130 including various sensors, and a driving driving unit 140 including a plurality of motors and wheels .

The power supply unit 120 may include a battery driver 121 and a lithium-ion battery 122. The battery driver 121 can manage the charging and discharging of the lithium-ion battery 122. The lithium-ion battery 122 can supply power for driving the airport robot. The lithium-ion battery 122 can be constructed by connecting two 24V / 102A lithium-ion batteries in parallel.

The obstacle recognizing unit 130 may include an IR remote control receiver 131, a USS 132, a Cliff PSD 133, an ARS 134, a Bumper 135, and an OFS 136. The IR remote control receiving unit 131 may include a sensor for receiving a signal of an IR (infrared) remote control for remotely controlling the airport robot. USS (Ultrasonic sensor) 132 may include a sensor for determining the distance between the obstacle and the airport robot using ultrasonic signals. The Cliff PSD 133 may include sensors for detecting cliffs or cliffs in an airport robot traveling range 360 degrees in all directions. The ARS (Attitude Reference System) 134 may include a sensor capable of detecting the attitude of the airport robot. The ARS 134 may include a sensor consisting of three axes of acceleration and three axes of acceleration for detecting the amount of rotation of the airport robot. The bumper 135 may include a sensor that detects a collision between the airport robot and the obstacle. The sensor included in the bumper 135 can detect a collision between the airport robot and the obstacle in the range of 360 degrees. The OFS (Optical Flow Sensor) 136 may include a sensor for measuring the traveling state of an airport robot and a sensor for measuring the distance traveled by the airport robot on various floor surfaces.

The travel driving unit 140 includes a motor driver 141, a wheel motor 142, a rotation motor 143, a main brush motor 144, a side brush motor 145 and a suction motor 146 . The motor driver 141 may serve to drive a wheel motor, a brush motor, and a suction motor for traveling and cleaning the airport robot. The wheel motor 142 may drive a plurality of wheels for driving the airport robot. The rotation motor 143 may be driven for left-right rotation, up-down rotation of the main body of the airport robot or the head portion of the airport robot, or for turning or rotating the wheels of the airport robot. The main brush motor 144 can drive a brush that scavenges dirt from the airport floor. The side brush motor 145 can drive a brush for sweeping dirt in the area around the outer surface of the airport robot. The suction motor 146 can be driven to suck the dirt on the airport floor.

The AP (Application Processor) 150 can function as a central processing unit, i.e., a control unit, for managing the entire system of hardware modules of the airport robot. The AP 150 can drive an application program for traveling and user input / output information to the microcomputer 110 by using position information received through various sensors, thereby driving a motor or the like.

The user interface unit 160 includes a user interface processor 161, an LTE router 162, a WIFI SSID 163, a microphone board 164, a barcode reader 165, a touch monitor 166, And a speaker 167. The user interface processor 161 can control the operation of the user interface unit responsible for user input and output. The LTE router 162 can receive the necessary information from the outside and can perform LTE communication for transmitting information to the user. The WIFI SSID 163 can perform position recognition of a specific object or an airport robot by analyzing the signal strength of WiFi. The microphone board 164 receives a plurality of microphone signals, processes the voice signal into voice data, which is a digital signal, and analyzes the direction of the voice signal and the voice signal. The barcode reader 165 can read the barcode information written in the plurality of tickets used in the airport. The touch monitor 166 may include a touch panel configured to receive user input and a monitor for displaying output information. The speaker 167 can play a role of notifying the user of specific information by voice.

The object recognition unit 170 may include a 2D camera 171, an RGBD camera 172, and a recognition data processing module 173. The 2D camera 171 may be a sensor for recognizing a person or an object based on a two-dimensional image. For detecting a person or object using captured images having depth data obtained from a camera having RGBD sensors or other similar 3D imaging devices as RGBD cameras (Red, Green, Blue, Distance, 172) Sensor. The recognition data processing module 173 can process a signal such as a 2D image / image or 3D image / image obtained from the 2D camera 171 and the RGBD camera 172 to recognize a person or an object.

The position recognition unit 180 may include a stereo board 181, a lidar 182, and a SLAM camera 183. A SLAM camera (Simultaneous Localization And Mapping camera, 183) can implement simultaneous location tracking and mapping techniques. The airport robot can detect the surrounding information by using the SLAM camera 183 and process the obtained information to create a map corresponding to the task execution space and estimate its own absolute position. Light Detection and Ranging (Lidar) 182 is a laser radar, which can be a sensor that irradiates a laser beam and collects and analyzes backscattered light among light absorbed or scattered by an aerosol to perform position recognition. The stereo board 181 processes and processes sensing data collected from the rider 182 and the SLAM camera 183 to manage the data for recognition of the position of an airport robot and recognition of obstacles.

The LAN 190 may communicate with the user input / output related user interface processor 161, the recognition data processing module 173, the stereo board 181 and the AP 150.

FIG. 3 is a detailed view showing a configuration of a micom and AP of an airport robot according to another embodiment of the present invention.

As shown in FIG. 3, the microcomputer 210 and the AP 220 may be implemented in various embodiments to control recognition and behavior of the airport robot.

As one example, the microcomputer 210 may include a data access service module 215. The data access service module 215 includes a data acquisition module 211, an emergency module 212, a motor driver module 213 and a battery manager module 214, . ≪ / RTI > The data acquisition module 211 can acquire sensed data from a plurality of sensors included in the airport robot and transmit the sensed data to the data access service module 215. The emergency module 212 is a module capable of detecting an abnormal state of the airport robot. When the airport robot performs a predetermined type of action, the emergency module 212 detects that the airport robot has entered an abnormal state . The motor driver module 213 can manage driving control of a wheel, a brush, and a suction motor for driving and cleaning the airport robot. The battery manager module 214 may charge and discharge the lithium-ion battery 122 of FIG. 1 and may transmit the battery state of the airport robot to the data access service module 215.

The AP 220 can act as a control unit for receiving various types of cameras and sensors, user inputs, etc., recognizing and processing the received signals, and controlling the operation of the airport robot. The interaction module 221 synthesizes the recognition data received from the recognition data processing module 173 and the user input received from the user interface module 222 to collectively manage software that allows the user and the airport robot to interact with each other Lt; / RTI > The user interface module 222 receives a user's close command such as a display unit 223, a key, a touch screen, a reader, or the like, which is a monitor for present state of the airport robot and operation / Such as a remote control signal for remote control, or a user input received from a user input 224 that receives a user's input signal from a microphone or bar code reader. When at least one user input is received, the user interface module 222 may pass user input information to a state machine module 225. The state management module 225 receiving the user input information can manage the entire state of the airport robot and issue an appropriate command corresponding to the user input. The planning module 226 can determine the start and end points / actions for the specific operation of the airport robot in accordance with the command received from the state management module 225, and calculate the route to which the airport robot should move. The navigation module 227 is responsible for the overall running of the airport robot, and may cause the airport robot to travel according to the travel route calculated by the planning module 226. [ The motion module 228 can perform the operation of the basic airport robot in addition to the traveling.

In addition, the airport robot according to another embodiment of the present invention may include a position recognition unit 230. [ The position recognition unit 230 may include a relative position recognition unit 231 and an absolute position recognition unit 234. [ The relative position recognition unit 231 can calculate the amount of movement of the airport robot for a predetermined period of time by correcting the amount of movement of the airport robot through the RGM mono sensor 232 and recognize the current environment of the airport robot through the LiDAR 233 can do. The absolute position recognition unit 234 may include a Wifi SSID 235 and a UWB 236. [ The Wifi SSID 235 is a UWB sensor module for recognizing the absolute position of the airport robot, and is a WIFI module for estimating the current position by detecting the Wifi SSID. The Wifi SSID 235 can recognize the position of the airport robot by analyzing the signal strength of the Wifi. The UWB 236 can calculate the distance between the transmitter and the receiver and sense the absolute position of the airport robot.

In addition, the airport robot according to another embodiment of the present invention may include a map management module 240. The map management module 240 may include a grid module 241, a path planning module 242, and a map partitioning module 243. The grid module 241 can manage a grid-shaped map generated by the airport robot through the SLAM camera, or map data of the surrounding environment for the position recognition input to the airport robot in advance. The path planning module 242 can take charge of the travel path calculation of the airport robots in the map division for cooperation among the plurality of airport robots. In addition, the path planning module 242 can calculate a traveling route through which the airport robot should move in an environment where one airport robot operates. The map division module 243 can calculate the area to be managed by the plurality of airport robots in real time.

The data sensed and calculated from the position recognition unit 230 and the map management module 240 may be transmitted to the state management module 225 again. The state management module 225 can command the planning module 226 to control the operation of the airport robot based on the data sensed and calculated from the position recognition module 230 and the map management module 240. [

Hereinafter, various embodiments of the route guidance service provided in the airport and provided to the user by the airport robot will be described.

4 is a view showing an example in which a plurality of airport robots according to an embodiment of the present invention are moved within an airport to provide services.

Referring to FIG. 4, a plurality of airport robots 100_1 to 100_9 may be disposed in the airport 600. FIG. Each of the plurality of airport robots 100_1 to 100_9 can provide various services such as guidance, patrol, cleaning, or anti-virus.

Each of the plurality of airport robots 100_1 to 100_9 can freely move within the airport and provide the various services. The plurality of airport robots 100_1 to 100_9 can smoothly move within the airport based on the information of the surrounding environment within a predetermined distance sensed through the plurality of sensors included in each of the plurality of airport robots 100_1 to 100_9, .

As each of the plurality of airport robots 100_1 to 100_9 moves freely, some of the airport robots may be adjacent to each other. As shown in FIG. 4, the third airport robot 100_3 and the fourth airport robot 100_4 may be adjacent to each other when they are moving.

When airport robots are adjacent to each other, light generated from sensors included in each airport robot and ultrasonic waves may interfere with each other. When such an interference occurs, an error may occur in the sensing result sensed by the sensor. If an error occurs in the sensing result, the airport robot may malfunction and fail to provide smooth service in the airport.

According to the embodiment of the present invention, it is possible to continuously provide smooth service of the airport robot by minimizing the sensor interference between the airport robots. Various embodiments related to this will be described with reference to Figs. 5 to 10C.

5 is a flowchart for explaining a method of operating an airport robot of any one of a plurality of airport robots disposed in an airport according to an embodiment of the present invention.

5, an embodiment of the present invention will be described focusing on the operation of the first airport robot 100_1 among a plurality of airport robots 100_1 to 100_9 disposed at the airport 600 as shown in FIG. 4 .

Referring to FIG. 5, the first airport robot 100_1 can provide a service while moving in the airport (S100).

For example, when the first airport robot 100_1 is a robot that provides a route guidance service, the first airport robot 100_1, when receiving a route guidance request from the user, moves to the destination according to the received route guidance request, Guidance service can be provided. When the first airport robot 100_1 is a robot responsible for patrol in the airport, the first airport robot 100_1 can perform a patrol operation while moving along a preset route or freely moving within the airport. When the first airport robot 100_1 is a robot for cleaning or preventing the first airport robot 100_1, the first airport robot 100_1 may perform a cleaning or anti-virus operation while moving through the airports.

The first airport robot 100_1 can receive position information of another airport robot (assumed to be the second airport robot 100_2) disposed in the airport (S110).

A plurality of airport robots disposed at the airport 600 can be connected to each other and exchange information or data through a wireless communication method. For example, each of the airport robots may be directly connected through the wireless communication method, or may be connected through the server 300. [

Each of the airport robots can share location information of each other. That is, although the first airport robot 100_1 is shown only to receive the position information of the second airport robot 100_2 from the second airport robot 100_2 in step S110, the second airport robot 100_2 And may receive location information of the first airport robot 100_1. 5, it is assumed that the first airport robot 100_1 receives the position information of the second airport robot 100_2 from the second airport robot 100_2.

The first airport robot 100_1 can determine the position of the second airport robot 100_2 based on the received position information (S120).

The AP 150 of the first airport robot 100_1 may determine the current position of the second airport robot 100_2 from the position information of the second airport robot 100_2. The controller 150 may also determine the location of the first airport robot 100_1 using the location recognition unit 230. [

The first airport robot 100_1 determines whether the first airport robot 100_1 and the second airport robot 100_2 are adjacent to each other based on the positions of the first airport robot 100_1 and the second airport robot 100_2 Whether or not it is a sensor interfering between the airport robots 100_1 and 100_2. To this end, the controller 150 may calculate the distance between the first airport robot 100_1 and the second airport robot 100_2 based on the determined position.

The first airport robot 100_1 is connected to the first airport robot 100_1 and the second airport robot 100_2 based on whether the distance between the first airport robot 100_1 and the second airport robot 100_2 is within a reference distance ) Are adjacent to each other.

If the distance between the first airport robot 100_1 and the second airport robot 100_2 is within the reference distance (YES in S130), the first airport robot 100_1 calculates, based on the position of the second airport robot 100_2 The moving direction can be changed (S140).

The controller 150 of the first airport robot 100_1 determines that the airport robots 100_1 and 100_2 are adjacent to each other when the distance between the first airport robot 100_1 and the second airport robot 100_2 is within the reference distance Can be detected. In this case, the control unit 150 can control the travel driving unit 140 to change the moving direction based on the position of the second airport robot 100_2.

For example, the controller 150 can change the moving direction of the first airport robot 100_1 in a direction away from the position of the second airport robot 100_2. Specifically, when the first airport robot 100_1 is adjacent to the second airport robot 100_2 while the first airport robot 100_1 is moving in the first direction, the controller 150 moves the second airport robot 100_2 in the second direction corresponding to the direction opposite to the first direction The moving direction of the first airport robot 100_1 can be changed.

On the other hand, when the distance between the first airport robot 100_1 and the second airport robot 100_2 is longer than the reference distance (NO in S130), the first airport robot 100_1 continuously performs the service without changing the moving direction . Also, the first airport robot 100_1 can periodically receive location information of the second airport robot 100_2.

Each step shown in FIG. 5 will be described in more detail with reference to FIGS. 6A to 6C.

6A to 6C are views illustrating an operation of the airport robot shown in Fig.

Referring to FIGS. 6A and 6B, the first and second airport robots 100_1 and 100_2 may be disposed in an airport to provide various services while moving. For smooth movement and service provision, each of the airport robots 100_1 and 100_2 can perform an operation such as avoiding an obstacle or detecting a foreign object to be removed by using a sensor.

At this time, the detection distance of the sensors included in the first airport robot 100_1 (or the maximum detection distance among the detection distances of the sensors) is the first detection distance D1, and the sensors included in the second airport robot 100_1 (Or the maximum sensing distance) may be the second sensing distance D2. The first sensing distance D1 and the second sensing distance D2 may be the same or different from each other.

When the area included in the first sensing distance D1 on the basis of the first airport robot 100_1 overlaps the area included in the second sensing distance D2 on the basis of the second airport robot 100_2, Interference between the sensors included in each of the first airport robot 100_1 and the second airport robot 100_2 may occur.

In order to prevent the interference between the sensors, the reference distance for determining whether the airport robots 100_1 and 100_2 are adjacent to each other may be set to be larger than the sum of the first sensing distance D1 and the second sensing distance D2 have.

6A and 6B, as the first airport robot 100_1 moves toward the direction in which the second airport robot 100_2 is located, the distance between the first airport robot 100_1 and the second airport robot 100_2 Can be approximated.

Referring to FIG. 6B, the first airport robot 100_1 can periodically receive position information POS2 of the second airport robot 100_2 from the second airport robot 100_2. The position information POS2 may be directly transmitted from the second airport robot 100_2 to the first airport robot 100_1 or transmitted from the second airport robot 100_2 to the first airport robot 100_1 via the server 300 .

The control unit 150 of the first airport robot 100_1 determines the position of the second airport robot 100_2 based on the received position information POS2 and determines the position of the first airport robot 100_2 based on the determination result And the distance D between the second airport robot 100_2. If the calculated distance D is shorter than the reference distance, the controller 150 can determine that the first airport robot 100_1 and the second airport robot 100_2 are adjacent to each other.

6C, when it is determined that the first airport robot 100_1 and the second airport robot 100_2 are adjacent to each other, the control unit 150 controls the travel direction of the first airport robot 100_1 to change the moving direction of the first airport robot 100_1, (140). The distance D 'between the first airport robot 100_1 and the second airport robot 100_2 may increase as compared with the distance D of FIG. 6B as the direction of movement of the first airport robot 100_1 is changed . 6A and 6B, when the first airport robot 100_1 is moving in the first direction, the controller 150 moves the moving direction of the first airport robot 100_1 to the opposite direction of the first direction Direction to the second direction.

According to the embodiment, the control unit 150 may transmit a control signal for changing the moving direction of the second airport robot 100_2 to the second airport robot 100_2. The second airport robot 100_2 can move away from the first airport robot 100_1 by changing the moving direction in response to the received control signal.

In other words, according to the embodiment shown in FIGS. 5 to 6C, the airport robot 100 according to the embodiment of the present invention senses the proximity of another airport robot using the location information of other airport robots, It is possible to prevent a malfunction due to interference with sensors of other airport robots.

7 is a ladder diagram for explaining an operation of the server included in the airport robot system according to the embodiment of the present invention to control the movement of the airport robot.

Referring to FIG. 7, each of the first airport robot 100_1 and the second airport robot 100_2 disposed at the airport can transmit the location information to the server 300 (S200, S210). The airport robots 100_1 and 100_2 may periodically transmit the respective location information to the server 300. [

The server 300 can determine the positions of the first and second airport robots 100_1 and 100_2 based on the received position information at step S220.

The server 300 receives an image including the first airport robot 100_1 and the second airport robot 100_2 from a plurality of cameras 400 installed at an airport according to the embodiment of steps S200 to S220 You may. Based on the received image, the server 300 may determine the position of the first airport robot 100_1 and the second airport robot 100_2, respectively. In this case, the airport robots 100_1 and 100_2 may not transmit the location information to the server 300. [

The server 300 can calculate the distance between the first airport robot 100_1 and the second airport robot 100_2 based on the determination result at step S230.

If the calculated distance is within the reference distance (YES in S240), the server 300 may transmit a control signal for changing the moving direction to the first airport robot 100_1 (S250). The control signal may include information on a moving direction to be changed with respect to the first airport robot 100_1.

The first airport robot 100_1 can change the moving direction based on the received control signal (S260).

According to the embodiment, the server 300 may transmit a control signal for changing the moving direction to the second airport robot 100_2 (S270). That is, the server 300 may transmit the control signal to at least one airport robot of the first airport robot 100_1 and the second airport robot 100_2.

The second airport robot 100_2 can change the moving direction based on the received control signal (S270).

Each step shown in Fig. 7 will be described in more detail with reference to Figs. 8A to 8C.

8A to 8C are diagrams illustrating operations of a server and an airport robot according to the embodiment shown in FIG.

Referring to FIG. 8A, each of the first airport robot 100_1 and the second airport robot 100_2 may periodically transmit location information POS1 and POS2 to the server 300. For example, the airport robot 100 and the server 300 are connected through a mobile communication method such as long term evolution (LTE) or wideband code division multiple access (W-CDMA) or a wireless communication method such as Wi-Fi .

The server 300 can determine the position of the first airport robot 100_1 and the position of the second airport robot 100_2 based on the received position information POS1 and POS2. Based on the determination result, the server 300 can calculate the distance D between the first airport robot 100_1 and the second airport robot 100_2.

As shown in FIG. 8A, when the first airport robot 100_1 moves toward the second airport robot 100_2, the calculated distance D may gradually decrease. The server 300 can detect the proximity between the airport robots 100_1 and 100_2 by determining whether the calculated distance D is shorter than the reference distance.

Referring to FIG. 8B, when the calculated distance D is shorter than the reference distance, the server 300 can detect the proximity between the airport robots 100_1 and 100_2. Based on the detection result, the server 300 may transmit a control signal for changing the moving direction of at least one of the first airport robot 100_1 and the second airport robot 100_2. In FIG. 8B, it is assumed that the server 300 transmits a control signal CTRL for changing the moving direction of the first airport robot 100_1 to the first airport robot 100_1.

Referring to FIG. 8C, the first airport robot 100_1 can change the moving direction based on the received control signal CTRL. The distance D 'between the first airport robot 100_1 and the second airport robot 100_2 may be longer than the reference distance as the first airport robot 100_1 moves in the changed moving direction.

That is, according to the embodiment shown in FIGS. 7 to 8C, the server 300 can detect the proximity of the airport robots using the location information of each of the airport robots. Based on the detection result, the server 300 can remotely control the moving direction of the airport robots to prevent malfunction due to sensor interference between the airport robots.

9 is a flowchart illustrating an operation method of an airport robot of one of a plurality of airport robots according to another embodiment of the present invention.

Referring to FIG. 9, any one of the airport robots (first airport robot 100_1) of the plurality of airport robots can output the advertisement signal according to the short-range wireless communication method (S300).

The short-range wireless communication scheme may be any one of various short-range wireless communication schemes such as Bluetooth and BLE (Bluetooth low energy). For this, the airport robot 100 may include a short-range wireless communication module (not shown). The control unit 150 of the airport robot 100 may control the short-range wireless communication module to output the advertisement signal.

9 to 10C, it is assumed that the short-range wireless communication method is BLE.

Generally, when the first device and the second device are connected through the BLE communication method, the first device can broadcast an advertising signal for informing existence of the first device. The transmission distance of the broadcasting signal to be broadcast can be changed according to the intensity of the outputted signal. When the second device receives the advertisement signal output from the first device, the second device may output a response signal to the received advertisement signal. The first device can detect the presence of the second device and perform the connection operation with the second device by receiving the response signal output from the second device.

Referring to FIG. 9, the controller 150 of the first airport robot 100_1 may output an advertisement signal for detecting the presence of another airport robot.

The first airport robot 100_1 can receive a response signal according to the advertisement signal from another airport robot (S310).

For example, when another airport robot disposed in the airport receives the advertisement signal, the other airport robot can output a response signal corresponding to the received advertisement signal.

The first airport robot 100_1 can sense that the other airport robot is located within the transmission distance of the advertisement signal from the first airport robot 100_1 by receiving the response signal.

The first airport robot 100_1 can change the moving direction based on the received response signal (S320).

By receiving the response signal according to the advertisement signal as described above in step S310, the first airport robot 100_1 can detect that the other airport robots are adjacent. Accordingly, the first airport robot 100_1 can move away from the other airport robot by controlling the travel driving unit 140 to change the moving direction.

In other words, in the embodiment shown in FIG. 9, the transmission distance of the advertisement signal outputted by the first airport robot 100_1 may correspond to a reference distance for determining whether or not it is adjacent to another airport robot.

For example, when the other airport robot exists at a distance greater than the transmission distance, the other airport robot can not receive the response signal because it can not receive the advertisement signal. Therefore, the first airport robot 100_1 may not receive a response signal according to the advertisement signal. In this case, the first airport robot 100_1 can sense that the other airport robots are not adjacent.

Each step shown in Fig. 9 will be described in more detail with reference to Figs. 10A to 10C.

Figs. 10A to 10C are diagrams illustrating an operation of the airport robot shown in Fig. 9. Fig.

10A to 10C, only the first airport robot 100_1 among the first airport robot 100_1 and the second airport robot 100_2 outputs the advertisement signal BLE_ADV for convenience of explanation. However, Depending on the embodiment, the second airport robot 100_2 may also output an advertising signal.

Referring to FIG. 10A, the first airport robot 100_1 can periodically output (broadcast) the advertisement signal BLE_ADV by the short-range wireless communication method while moving within the airports.

Generally, the advertisement signal can be used for detecting the presence of another device and connecting with other devices detected through a short-range wireless communication method. However, in the present invention, the advertisement signal BLE_ADV output by the first airport robot 100_1 may be used for detecting whether or not another airport robot adjacent to the first airport robot 100_1 exists .

The controller 150 of the first airport robot 100_1 can adjust the transmission distance D_BLE of the advertisement signal BLE_ADV by adjusting the output intensity of the advertisement signal BLE_ADV. For example, the transmission distance D_BLE is a distance between a first sensing distance D1, which is a sensing distance (or maximum sensing distance) of sensors included in the first airport robot 100_1, (I.e., the sensing distance of the sensors included in the first sensing range 100_2). In particular, the area included in the first sensing distance D1 on the basis of the first airport robot 100_1 and the area included in the second sensing distance D2 on the basis of the second airport robot 100_2 are overlapped with each other The interference between the sensors included in the airport robots 100_1 and 100_2 may occur. Therefore, the transmission distance D_BLE can be adjusted to have a value larger than the sum of the first sensing distance D1 and the second sensing distance D2.

10A, when there is no other airport robot in the transmission distance D_BLE of the advertisement signal BLE_ADV output from the first airport robot 100_1, the first airport robot 100_1 It may not receive a response signal. In this case, the controller 150 may detect that there is no other airport robot adjacent to the first airport robot 100_1.

Referring to FIG. 10B, as the first airport robot 100_1 moves, the distance between the first airport robot 100_1 and the second airport robot 100_2 can be shortened. When the distance between the first airport robot 100_1 and the second airport robot 100_2 becomes smaller than the transmission distance D_BLE, the second airport robot 100_2 transmits the advertisement tie (BLE_ADV).

Based on the received advertisement signal BLE_ADV, the second airport robot 100_2 can output the response signal BLE_RESP. The first airport robot 100_1 detects the presence of another airport robot within the transmission distance D_BLE from the first airport robot 100_1 by receiving the response signal BLE_RESP output from the second airport robot 100_2 . That is, the first airport robot 100_1 can detect proximity to another airport robot.

Referring to FIGS. 10B and 10C, when the proximity of another airport robot is detected, the controller 150 of the first airport robot 100_1 may control the travel driver 140 to change the travel direction. For example, the control unit 150 may control the travel driving unit 140 to move the first airport robot 100_1 in the direction opposite to the current direction of travel.

The distance between the first airport robot 100_1 and the second airport robot 100_2 may be longer than the transmission distance D_BLE as the moving direction of the first airport robot 100_1 is changed. Accordingly, it is possible to prevent sensor interference due to the proximity of the first airport robot 100_1 and the second airport robot 100_2.

According to the embodiment, when the first airport robot 100_1 and the second airport robot 100_2 are adjacent to each other as shown in FIG. 10B, the moving direction of the second airport robot 100_2 may be changed. For example, when the second airport robot 100_2 receives the advertisement signal BLE_ADV output from the first airport robot 100_1, the control unit 150 of the second airport robot 100_2 transmits the advertisement signal BLE_ADV to the first airport robot 100_2, (100_1) are adjacent to each other. The control unit 150 of the second airport robot 100_2 can output the response signal BLE_RESP while changing the moving direction of the second airport robot 100_2 based on the detection result.

According to the embodiment shown in FIGS. 9 to 10C, the airport robot 100 detects the proximity of the robot to other airports using the advertisement signal used in the connection using the short-range wireless communication system, It is possible to prevent malfunction due to sensor interference with other airport robots. In particular, according to the present embodiment, even when the connection between the airport robots is not established or the connection is disconnected, the proximity between the airport robots can be detected.

The present invention described above can be embodied as computer-readable codes on a medium on which a program is recorded. The computer readable medium includes all kinds of recording devices in which data that can be read by a computer system is stored. Examples of the computer readable medium include a hard disk drive (HDD), a solid state disk (SSD), a silicon disk drive (SDD), a ROM, a RAM, a CD-ROM, a magnetic tape, a floppy disk, , And may also be implemented in the form of a carrier wave (e.g., transmission over the Internet). Further, the computer may include a control unit of the airport robot. Accordingly, the above description should not be construed in a limiting sense in all respects and should be considered illustrative. The scope of the present invention should be determined by rational interpretation of the appended claims, and all changes within the scope of equivalents of the present invention are included in the scope of the present invention.

Claims (15)

BACKGROUND ART [0002] In an airport robot that is deployed at an airport and moves,
A traveling driving unit for moving the airport robot;
At least one sensor for detecting various information within a sensing distance centering on the airport robot;
A position recognition unit 180 for recognizing the position of the airport robot; And
Receiving position information of the other airport robot from another airport robot moving within the airport,
Recognizes the position of the other airport robot based on the received position information,
Detecting whether or not the sensor of the airport robot and the other airport robot are adjacent to each other based on the recognition result,
And a control unit (150) for controlling the travel driving unit to change the moving direction of the airport robot based on the detection result. The method according to claim 1,
Wherein,
Calculates a distance between the airport robot and the other airport robot based on the recognition result,
When the calculated distance is shorter than the reference distance, the airport robot detects that the airport robot is adjacent to the other airport robot,
And controls the travel driving unit to change the moving direction of the airport robot. 3. The method of claim 2,
Wherein,
And controls the traveling drive unit to change to a second direction corresponding to a direction opposite to the first direction when the moving direction of the airport robot is the first direction. 3. The method of claim 2,
The reference distance,
And the detection distance of the at least one sensor. 5. The method of claim 4,
The reference distance,
Wherein the sensor is set to have a value larger than a sum of a sensing distance of the at least one sensor and a sensing distance of at least one sensor included in the other airport robot. 3. The method of claim 2,
Wherein,
And transmits a control signal for changing the direction of movement of the other airport robot to the other airport robot when it is detected that the airport robot and the other airport robot are adjacent to each other. BACKGROUND ART [0002] In an airport robot that is deployed at an airport and moves,
A traveling driving unit for moving the airport robot;
At least one sensor for detecting various information within a sensing distance centering on the airport robot;
A short range wireless communication module supporting a short range wireless communication method; And
Controls the short-range wireless communication module to broadcast an advertising signal,
Detecting whether or not the sensor interference is caused by the proximity of another airport robot based on whether or not a response signal to the broadcast advertising signal is received,
And a controller for controlling the travel driving unit to change the moving direction of the airport robot based on the detection result. 8. The method of claim 7,
Wherein,
When receiving the response signal, detects that the airport robot and the other airport robot are adjacent to each other,
And controls the travel driving unit to change the moving direction of the airport robot. 9. The method of claim 8,
Wherein,
And controls the traveling driving unit to change the traveling direction of the airport robot to a second direction opposite to the first direction when the moving direction of the airport robot is the first direction. 8. The method of claim 7,
Wherein,
Setting a transmission distance of the advertisement signal by adjusting an output intensity of the advertisement signal,
Wherein the transmission distance is set based on a sensing distance of the at least one sensor. 11. The method of claim 10,
The transmission distance,
Wherein the sensor is set to have a value larger than a sum of a sensing distance of the at least one sensor and a sensing distance of at least one sensor included in the other airport robot. A method of operating a server connected to a first airport robot and a second airport robot, respectively,
Receiving location information of the first airport robot and location information of the second airport robot;
Determining positions of the first airport robot and the second airport robot based on the received location information;
Detecting the proximity of the first airport robot and the second airport robot based on the determined position to detect whether sensor interference occurs between the first airport robot and the second airport robot; And
And controlling the moving direction of at least one airport robot among the first airport robot and the second airport robot based on the detection result. 13. The method of claim 12,
The method of claim 1,
Calculating a distance between the first airport robot and the second airport robot based on the determined position;
Detecting that the first airport robot and the second airport robot are adjacent if the calculated distance is shorter than the reference distance; And
And detecting that the first airport robot and the second airport robot are not adjacent if the calculated distance is longer than the reference distance. 14. The method of claim 13,
The reference distance,
Wherein the first airport robot is set to have a value larger than a sum of a detection distance of a sensor included in the first airport robot and a detection distance of a sensor included in the second airport robot. 13. The method of claim 12,
Wherein the controlling comprises:
And transmitting a control signal for changing the direction of movement to each of the at least one airport robot.

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