WO2018086612A1 - 自动工作系统及其控制方法 - Google Patents

自动工作系统及其控制方法 Download PDF

Info

Publication number
WO2018086612A1
WO2018086612A1 PCT/CN2017/110743 CN2017110743W WO2018086612A1 WO 2018086612 A1 WO2018086612 A1 WO 2018086612A1 CN 2017110743 W CN2017110743 W CN 2017110743W WO 2018086612 A1 WO2018086612 A1 WO 2018086612A1
Authority
WO
WIPO (PCT)
Prior art keywords
map
automatic
module
work
work area
Prior art date
Application number
PCT/CN2017/110743
Other languages
English (en)
French (fr)
Inventor
邵勇
周昶
刘芳世
Original Assignee
苏州宝时得电动工具有限公司
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Family has litigation
First worldwide family litigation filed litigation Critical https://patents.darts-ip.com/?family=62110419&utm_source=google_patent&utm_medium=platform_link&utm_campaign=public_patent_search&patent=WO2018086612(A1) "Global patent litigation dataset” by Darts-ip is licensed under a Creative Commons Attribution 4.0 International License.
Priority claimed from CN201610997071.2A external-priority patent/CN108073164B/zh
Application filed by 苏州宝时得电动工具有限公司 filed Critical 苏州宝时得电动工具有限公司
Priority to CN201911165788.0A priority Critical patent/CN110888437B/zh
Priority to CN201780007838.5A priority patent/CN108604098B/zh
Priority to EP17869757.9A priority patent/EP3540552B1/en
Priority to CN201911165755.6A priority patent/CN110941270B/zh
Publication of WO2018086612A1 publication Critical patent/WO2018086612A1/zh
Priority to US16/409,267 priority patent/US11269349B2/en
Priority to US17/589,624 priority patent/US20220300008A1/en

Links

Images

Classifications

    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05DSYSTEMS FOR CONTROLLING OR REGULATING NON-ELECTRIC VARIABLES
    • G05D1/00Control of position, course, altitude or attitude of land, water, air or space vehicles, e.g. using automatic pilots
    • G05D1/02Control of position or course in two dimensions
    • G05D1/021Control of position or course in two dimensions specially adapted to land vehicles
    • G05D1/0268Control of position or course in two dimensions specially adapted to land vehicles using internal positioning means
    • G05D1/0274Control of position or course in two dimensions specially adapted to land vehicles using internal positioning means using mapping information stored in a memory device
    • AHUMAN NECESSITIES
    • A01AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
    • A01DHARVESTING; MOWING
    • A01D34/00Mowers; Mowing apparatus of harvesters
    • A01D34/006Control or measuring arrangements
    • A01D34/008Control or measuring arrangements for automated or remotely controlled operation
    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05DSYSTEMS FOR CONTROLLING OR REGULATING NON-ELECTRIC VARIABLES
    • G05D1/00Control of position, course, altitude or attitude of land, water, air or space vehicles, e.g. using automatic pilots
    • G05D1/0088Control of position, course, altitude or attitude of land, water, air or space vehicles, e.g. using automatic pilots characterized by the autonomous decision making process, e.g. artificial intelligence, predefined behaviours
    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05DSYSTEMS FOR CONTROLLING OR REGULATING NON-ELECTRIC VARIABLES
    • G05D1/00Control of position, course, altitude or attitude of land, water, air or space vehicles, e.g. using automatic pilots
    • G05D1/02Control of position or course in two dimensions
    • G05D1/021Control of position or course in two dimensions specially adapted to land vehicles
    • G05D1/0212Control of position or course in two dimensions specially adapted to land vehicles with means for defining a desired trajectory
    • G05D1/0219Control of position or course in two dimensions specially adapted to land vehicles with means for defining a desired trajectory ensuring the processing of the whole working surface
    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05DSYSTEMS FOR CONTROLLING OR REGULATING NON-ELECTRIC VARIABLES
    • G05D1/00Control of position, course, altitude or attitude of land, water, air or space vehicles, e.g. using automatic pilots
    • G05D1/02Control of position or course in two dimensions
    • G05D1/021Control of position or course in two dimensions specially adapted to land vehicles
    • G05D1/0276Control of position or course in two dimensions specially adapted to land vehicles using signals provided by a source external to the vehicle
    • G05D1/0278Control of position or course in two dimensions specially adapted to land vehicles using signals provided by a source external to the vehicle using satellite positioning signals, e.g. GPS

Definitions

  • the invention relates to an automatic working system and a control method thereof. More particularly, it relates to an automatic lawn mower system that does not have a boundary line, and a control method of the automatic lawn mower system.
  • the self-mobile device can automatically travel and work in a certain area to complete a specific task. Since the automated working system operates without human intervention, there may be some security issues with the operation of the mobile device, for example, the mobile device may travel to an area where the user does not wish to appear. In the case of an automatic lawn mower, the automatic mower may travel to an area outside the lawn or to a pit area.
  • one method for solving the above problem is to install a sensor on the automatic lawn mower to detect a boundary or an obstacle.
  • the user is required to lay a boundary line on the lawn, and an electrical signal is transmitted in the boundary line to generate an electromagnetic field.
  • the boundary sensor on the automatic lawn mower detects the electromagnetic field, and the controller of the automatic lawn mower judges according to the electromagnetic field detected by the boundary sensor. Whether the automatic mower works in the working area defined by the boundary line. With this method, laying the boundary line is troublesome and affects the appearance of the lawn.
  • Another method is to create a map of the work area and control the automatic mower to operate within the work area defined by the map.
  • One of the methods for establishing a map is to establish a coordinate system, record the position coordinates of the work area, and use the position coordinates of the recorded work area to define the range in which the automatic mower can work safely.
  • the controller of the automatic mower determines the relationship between the current position of the automatic mower and the position coordinates of the working area stored in the controller, and if the automatic mower is found to be driving outside the safe working range The position controls the automatic mower to deflect into the working area, thus ensuring the safe operation of the automatic mower.
  • the method of establishing a map may also be to create an image library by collecting an image of the work area, and define an image with different features as a work area, a work area, or a boundary.
  • the camera mounted on the automatic mower captures the image of the ground in front of the automatic mower, and the controller analyzes the image features to determine whether the automatic mower is in a safe working area.
  • the method of establishing a map does not have to arrange a boundary line on the lawn, thereby saving the user the trouble of laying the boundary line.
  • this method which is to establish the accuracy of the map.
  • the position coordinates of the work area of the map record deviate from the position coordinates of the actual work area, and the map indicates that the area that can work safely exceeds the range in which the automatic mower can actually work safely, and the automatic work system automatically cuts the grass when working.
  • the machine will travel to an unsafe area, causing safety problems.
  • the map indicates that the safe working area is smaller than the area where the automatic mower can work safely, the automatic mower will not reach the area not included in the map-defined safe working area when the automatic working system is working. The lawn cutting is incomplete.
  • This method of establishing a map even if a high-precision positioning device is used, can still avoid the inaccuracy of establishing a map, and the positioning device with higher positioning accuracy, the higher the cost of the corresponding automatic working system is impossible. Unlimited increase in the accuracy of the positioning device. Therefore, there is an urgent need to find a way to solve the inaccurate problem of establishing a map.
  • An automatic working system comprising a self-mobile device and a positioning device; the self-mobile device comprising a mobile module and a task execution module, and a driving circuit connected to the mobile module and the task execution module, the driving circuit driving the mobile
  • the module drives the mobile device to move and drives the task execution module to perform a work task;
  • the positioning device is configured to detect a current location of the self-mobile device;
  • the automatic working system includes: a storage unit configured to store a work area map And a map confirmation program, the map confirmation program comprising: providing drive circuit instructions to move along a boundary of the work area, receiving an acknowledgement signal from the user to complete the map confirmation program; working the program, providing drive circuit instructions to the map Moving and executing a work task within the defined work area; the control module being configured to execute the map confirmation program by monitoring an output of the positioning device, and executing the work program after the map confirmation program is completed.
  • the positioning device comprises a satellite positioning device.
  • the satellite positioning device comprises a differential satellite positioning device.
  • the differential satellite positioning device comprises an RTK-GPS positioning device.
  • the positioning device is fixedly connected to the self-mobile device, or the positioning device is detachably connected to the self-mobile device.
  • the map confirmation program further comprises: providing a driving circuit instruction to keep the task execution module from performing a work task.
  • the task execution module includes a cutting assembly, the map validation program including providing drive circuit instructions to maintain the cutting assembly from performing a cutting operation.
  • the map validation program further comprises, after providing the drive circuit instructions to move along a boundary of the work area, providing drive circuit instructions to move within the boundary defined work area.
  • the automatic working system includes an alarm unit configured to output an alarm signal indicating an abnormal condition of the work area.
  • the automatic working system includes an environmental sensor, at least partially installed on the self-mobile device, for detecting an abnormal situation of the working area when the mobile device moves within the working area; and the control module monitors the environmental sensor by Outputting, controlling the alarm unit to output an alarm signal.
  • the map confirmation program further comprises receiving a control signal from the user, and providing a driving circuit instruction according to the control signal to control the movement mode.
  • control signal includes a stop movement signal
  • map confirmation program includes receiving a stop movement signal from the user, and providing a drive circuit instruction to control the stop movement according to the stop movement signal.
  • the map confirmation program further comprises receiving a map modification signal from the user to modify the work area map.
  • the communication module is configured to communicate with the user's smart terminal for receiving an acknowledgment signal from the user.
  • a control method of an automatic working system comprising a self-mobile device and a positioning device; the self-mobile device comprising a mobile module and a task execution module; the positioning device configured to detect a current current of the self-mobile device Position: the control method includes the steps of: storing a work area map; controlling access to the map confirmation mode, and in the map confirmation mode, by monitoring the current position of the mobile device, controlling the mobile module to drive the self-mobile device along the work area based on the work area map The boundary moves; receives the acknowledgment signal from the user; the control enters the working mode only after receiving the acknowledgment signal from the user; in the working mode, by monitoring the current position of the mobile device, the mobile module is controlled to drive the mobile device in the map. Move within the work area and control the task execution module to perform work tasks.
  • the positioning device comprises a satellite positioning device.
  • the satellite positioning device comprises a differential satellite positioning device.
  • the differential satellite positioning device comprises an RTK-GPS positioning device.
  • the positioning device is fixedly connected to the self-mobile device, or the positioning device is detachably connected to the self-mobile device.
  • the task execution module is controlled not to perform a work task.
  • the task execution module includes a cutting component, and in the map confirmation mode, the cutting component is controlled not to perform a cutting operation.
  • the method further includes the step of controlling the mobile module to move from the mobile device in the working area defined by the boundary.
  • an alarm unit is provided, and an alarm signal indicating an abnormal condition of the working area is output.
  • an environmental sensor is provided, at least partially installed on the self-mobile device, detecting an abnormal condition of the working area when the mobile device moves within the working area; controlling the alarm unit to output an alarm by monitoring an output of the environmental sensor signal.
  • a control signal from the user is received, and the mobile module is controlled to change the mobile mode from the mobile device according to the control signal.
  • control signal includes a stop movement signal
  • the mobile module is controlled to stop moving from the mobile device according to the stop movement signal.
  • a map modification signal from the user is received, and the work area map is modified according to the map modification signal.
  • a communication module is provided to communicate with the user's smart terminal for receiving an acknowledgment signal from the user.
  • An automatic working system comprising: a self-moving device, the self-mobile device comprising a mobile module, a task execution module and a control module; the mobile module drives movement from the mobile device; the task execution module performs a work task; the control The module is electrically connected to the mobile module and the task execution module; the control module includes a storage unit that stores a work area map; the control module controls movement from the mobile device within the work area defined by the map; the automatic work system includes an artificial The observation mode, in the human observation mode, the automatic working system works under the observation of the user; after the storage unit stores the map, the control module controls the control module to control the task execution module to perform the work task, the control module controls the The mobile module drives the mobile device to move to check the map; when the control module controls the mobile module to move from the mobile device to check the map, the automatic working system operates in an artificial observation mode.
  • the control module controls the mobile module to move from the mobile device to check the map
  • the mobile module is controlled to move from the mobile device along the boundary of the map record.
  • the control module controls the mobile module to move from the mobile device to check the map
  • the mobile module is controlled to move from the mobile device to cover the map-defined working area.
  • control module controls the mobile module to move from the mobile device to check the map
  • the control module controls the task execution module to remain in an inoperative state.
  • control module modifies the map stored by the storage unit based on the result observed by the user.
  • the automatic working system includes an interaction module, and when the control module controls the mobile module to move from the mobile device to check the map, the interaction module is electrically connected to the control module, and is used for the self-mobile device.
  • the control module modifies the map stored by the storage unit based on the output of the interaction module.
  • the interaction module comprises a communication module for communication between the mobile device and the user's smart terminal.
  • the interaction module includes an input/output device for the user to observe or operate.
  • the self-moving device includes an obstacle detecting sensor electrically connected to the control module, and the control module controls the moving module to move from the mobile device to check the map, and the obstacle detecting sensor is configured to detect The barrier within the work area defined by the map, the control module modifying the map stored by the storage unit based on the detection result of the obstacle detection sensor.
  • the self-moving device includes a slope detecting sensor electrically connected to the control module, and the slope detecting sensor is configured to detect when the controlling module controls the moving module to move from the mobile device to check the map.
  • the slope information of the work area defined by the map, the control module modifies the map stored by the storage unit based on the detection result of the slope detecting sensor.
  • the automatic working system comprises a positioning device, and the control module controls the positioning device to output the current position of the mobile device when the mobile module controls the movement from the mobile device to check the map.
  • control module is configured according to a current location of the self-mobile device output by the positioning device, And the reliability of the signal output by the positioning device, modifying the map stored by the storage unit.
  • control module controls the mobile module to move from the mobile device to check the modified map.
  • the present invention also provides a self-mobile device control method
  • the self-mobile device includes a mobile module to drive movement from the mobile device; a task execution module to perform a work task; and the self-mobile device control method includes the steps of: recording and storing a work area map; after storing the map, controlling the task execution module to perform a work task, controlling the mobile module to move from the mobile device to move within the work area defined by the map to check the map; When the map is made, the mobile device is moved under the user's observation.
  • the process of checking the map includes the step of controlling the mobile module to move from a mobile device along a boundary of the map record.
  • the process of checking the map includes the step of controlling the mobile module to move from the mobile device to cover the work area defined by the map.
  • the process of checking the map includes the steps of locating the current location of the mobile device, comparing the current location of the mobile device with the stored location of the map record, and determining whether the mobile device is located in the work area defined by the map. Inside.
  • the task execution module is controlled to remain in an inoperative state.
  • the map is modified based on the results observed by the user.
  • the process of checking the map includes the steps of controlling interaction with the user from the mobile device and modifying the map based on the result of the interaction.
  • the mobile module is controlled to move from the mobile device to check the modified map.
  • the present invention also provides a self-moving device that automatically moves in a work area based on a work area map, including a housing, a moving module, a task execution module, and a control module, wherein the control module controls the mobile module to drive the self-mobile device Moving, and controlling a work task execution of the task execution module; the control module acquires a current location of the mobile device from the positioning device; the work area map includes location information of one or more locations of the work area;
  • the mobile device includes a map confirmation mode. In the map confirmation mode, the control module controls the self-mobile device to automatically move based on the work area map, and controls the task execution module not to perform a work task.
  • the beneficial effects of the present invention are: after the storage unit stores the map, the control mode Before the block control task execution module performs the work task, the control module controls the mobile module to move from the mobile device to check the map, thereby avoiding a security problem when the work task is performed from the mobile device due to the inaccurate map.
  • the process of inspecting the map is carried out under human observation, which ensures the reliability of the inspection of the map.
  • the process of checking the map keeps the task execution module inoperative, ensuring the security of the inspection process.
  • the present invention also provides an automatic lawn mower capable of simplifying the use preparation of the lawn mower and achieving rapid regression.
  • An automatic lawn mower comprising:
  • a work area identification module configured to determine whether an area to be passed by the automatic lawn mower is a work area
  • a driving module for driving the automatic lawn mower to walk in the working area
  • a positioning module configured to receive a positioning signal to obtain a coordinate of a current position of the automatic mower or a coordinate area composed of a plurality of coordinates
  • a map construction and storage module configured to determine whether the coordinates are stored in the work map, and if the determination is no, add the coordinates to the work map to obtain an updated work map;
  • the regression path planning module is configured to receive the regression instruction and generate a regression path according to the updated work map, and control the automatic lawn mower to return to the predetermined position along the position of the regression path before the regression.
  • the above automatic mower can start working quickly, and use the work process to perfect the work map. After the work is finished, it can be navigated according to the existing work map, thus achieving rapid regression without requiring the user to train the automatic mower to learn all the work in advance. region.
  • the predetermined location is a charging station.
  • the work area identification module includes a grassland detection module for identifying whether an area to be passed by the automatic lawn mower is grass.
  • the positioning module has a communication module for receiving a positioning signal
  • the communication module includes a GPS module, a D-GPS module, a UWB module, a Zigbee module, a wifi module, an ultrasonic receiving module, an inertial navigation module, an odometer, One or more of an electronic map and an acceleration sensor.
  • the regression path is a path defined by known coordinates in the work map, and the distance from the position before the return to the predetermined position is the shortest.
  • the regression path planning module is further configured to record the number of times each known coordinate in the work map is passed by the automatic mower, and the return path is determined by the coordinates of the position before the return, the predetermined position
  • the coordinates, the position before the return, and the predetermined position are defined by the known coordinates with the least number of passes by the automatic mower.
  • a walking method of an automatic lawn mower comprising the steps of:
  • Receiving a regression instruction Receiving a regression instruction, generating a regression path according to the updated work map, and controlling the automatic lawn mower to return to the predetermined position along the position of the regression path before the regression.
  • the regression path is a path defined by known coordinates in the work map, the shortest distance from the position before the return to the predetermined position.
  • the receiving the regression instruction, generating a regression path according to the updated work map, and controlling the automatic lawn mower to return to the predetermined position before the return to the predetermined position along the regression path comprises:
  • the regression path is generated based on the coordinates of the position where the regression occurred, the coordinates of the predetermined position, the known position between the position before the return and the predetermined position, and the number of times the automatic mower passes the least.
  • the coordinate origin of the coordinates is the predetermined position.
  • FIG. 1 is a schematic view of an automatic working system according to a first embodiment of the present invention.
  • FIG. 2 is a schematic structural view of an automatic lawn mower according to a first embodiment of the present invention.
  • Fig. 3 is a schematic view showing the map of the work area of the first embodiment of the present invention.
  • FIG. 4 is a flow chart of an automatic work system inspection map of the first embodiment of the present invention.
  • Fig. 5 is a block diagram showing the structure of an automatic lawn mower according to a sixth embodiment of the present invention.
  • Figure 6 is a schematic diagram of the construction of a work map during the first work of the automatic mower.
  • Figure 7 is a schematic diagram of the automatic map mower based on the work map regression constructed in Figure 6.
  • Figure 8 is a schematic diagram of the construction of a work map during the second work of the automatic mower.
  • Figure 9 is a schematic diagram of the automatic lawn mower based on the updated work map of Figure 7.
  • Figure 10 is a schematic diagram of the construction of a work map during the Nth work of the automatic mower.
  • Figure 11 is a schematic diagram of the automatic lawn mower based on the work map regression updated in Figure 10.
  • Figure 12 is a flow chart of an automatic lawn mower walking method of one embodiment.
  • Figure 13 is a block diagram showing the structure of an automatic working system according to a fifth embodiment of the present invention.
  • Figure 14 is a flow chart showing a method of controlling an automatic working system according to a fifth embodiment of the present invention.
  • the automated working system 100 includes self-mobile devices.
  • the self-moving device is an automatic lawn mower 1.
  • the self-mobile device may also be an unattended device such as an automatic cleaning device, an automatic watering device, an automatic snow sweeper, and the like.
  • the automated working system 100 also includes a charging station 2 for refueling the automatic mower 1.
  • the automatic lawn mower 1 includes a housing 3; the moving module is mounted on the housing 3, and the moving module includes a crawler belt 5. Driven by the drive motor to drive the automatic mower 1 to move; the task execution module is mounted on the bottom of the housing 3, including the cutting assembly 7, to perform mowing work.
  • the automatic mower 1 also includes an energy module that includes a battery pack that provides energy for the movement and operation of the automatic mower 1.
  • the automatic mower 1 further includes a control module electrically connected with the mobile module, the task execution module and the energy module, and the control mobile module drives the automatic mower 1 to move, and controls the task execution module to perform the work task.
  • the control module includes a storage unit that stores a map of the work area.
  • a method for establishing a map is to establish a spatial coordinate system with the charging station 2 as an origin, and use a positioning device to record the position coordinates of the working area, and the working area.
  • the position coordinates are processed to generate a map of the work area.
  • the work area map contains location information for one or more locations of the work area.
  • the work area map may also be obtained by manually delineating the work area on the electronic map by the user.
  • the automatic working system includes a positioning device, and the positioning device includes a satellite positioning device, which belongs to a satellite navigation system, and the satellite navigation system uses a Global Positioning System (GPS) for navigation.
  • GPS Global Positioning System
  • the satellite navigation system can also be navigated using a Galileo satellite navigation system, or a Beidou satellite navigation system.
  • the satellite positioning device includes a mobile station 15, The mobile station 15 can move with the automatic mower 1 to output the current position of the automatic mower.
  • the satellite navigation system further includes a base station 17, and the base station 17 is fixedly disposed.
  • the base station 17 is disposed on the charging station 2, the base station 17 wirelessly communicates with the mobile station 15, and the base station 17 transmits a positioning correction signal to the mobile station 15.
  • DGPS differential GPS
  • the mobile station 15 is detachably mounted to the casing 3 of the automatic lawn mower 1. When the mobile station 15 is detached from the automatic mower 1, it can work independently and record the position coordinates of the movement itself.
  • the mobile station 15 is mounted on the casing 3 of the automatic mower 1, it is electrically connected to the control module of the automatic mower 1, and outputs the current position coordinates of the automatic mower 1.
  • the positioning device further includes an inertial navigation device, and the inertial navigation device includes a gyroscope, an accelerometer, etc., and the inertial navigation device can output the current position coordinate of the automatic mower 1 according to the initial position of the automatic mower 1
  • the navigation device can cooperate with the satellite positioning device to play the role of assisting navigation when the satellite signal is poor.
  • the map of the work area includes boundary information of the work area, obstacle information in the work area, slope information of the work area, strength information of the satellite signal received by the work area, and the like.
  • a natural boundary is formed between the turf and the non-turf area, that is, the boundary 200 of the actual working area, the obstacle 9 in the working area, the slope 11, and the area 13 where the satellite signal is weak.
  • the obstacle 9 can be a tree, a pit, or the like.
  • the slope 11 is a working area where the slope exceeds the threshold, and the automatic lawn mower can improve the stability and work efficiency by changing the movement mode when working on the slope.
  • the area 13 where the satellite signal is weak may be an area blocked by the house, an area under the shadow of the vegetation, etc.
  • the automatic mower 1 cannot receive a good satellite signal in these areas, and the satellite positioning apparatus cannot output an accurate position signal.
  • the inertial navigation device is used for navigation at the same time, when the automatic mower 1 stays in a region where the satellite signal is weak for a long time, the inertial navigation device will not be able to output an accurate position signal due to error accumulation. Therefore, when the automatic lawn mower 1 moves in a region where the satellite signal is weak, it is preferably moved in a different manner from the movement in a region where the satellite signal is good.
  • Figure 3 is a schematic diagram of a map of a work area with a display device as a carrier.
  • the work area of the map record may be biased relative to the actual work area.
  • the right side boundary of the actual work area includes a portion that is recessed toward the center of the work area, and the position of the boundary 300 of the map record does not accurately reflect the portion of the recess, that is, the position of the boundary 300 of the map record is not accurate.
  • the location of the boundary 300 of the map record is inaccurate and will cause the automatic mower 1 to move when the area near the boundary moves.
  • Moving to an area outside the boundary 200 of the actual work area leads to security issues.
  • the actual work area includes the obstacle 11.
  • the obstacle 11 may be a pit, and the map does not record the pit position, which will cause the automatic mower 1 to fall when moving to the pit position, resulting in a safety problem. .
  • the control module controls the automatic mower to perform the mowing work, and the control module controls the mobile module to drive the automatic mower 1 to move within the work area defined by the map to check whether the map is accurate.
  • the automatic working system includes a human observation mode, and in the human observation mode, the automatic working system works under the observation of the user.
  • the control module controls the mobile module to drive the automatic mower 1 to move to check the map
  • the automatic working system works in the human observation mode to ensure the reliability of the inspection of the map.
  • the automatic working system includes an interaction module. In the human observation mode, the interaction module provides the automatic mower 1 to interact with the user.
  • the interaction module includes a communication module for communication between the automatic lawn mower 1 and the user's intelligent terminal.
  • the control module controls the cutting unit 7 of the automatic lawn mower 1 to remain in an inoperative state, and therefore, even if the recorded map is inaccurate, the automatic lawn mower moves 1 to Unsafe areas outside the boundaries of the actual work area or pits will not cause the cutting assembly 7 to injure or injure other objects, thus ensuring the safety of the inspection process.
  • the above process is referred to as the map confirmation mode of the automatic mower, that is, in the map confirmation mode, the control module controls the automatic mower to move based on the work area map, and controls the task execution module not to perform the work task.
  • the mobile station 15 in the process of the automatic lawn mower 1 inspecting the map, is installed in the casing 3 of the automatic lawn mower 1 and electrically connected with the control module of the automatic lawn mower 1 to output the automatic lawn mower 1 current position.
  • the control module compares the current position of the automatic mower 1 with the position recorded in the stored map, and determines whether the automatic mower 1 moves within the work area defined by the map, and if the control module determines that the automatic mower 1 moves to the map-defined
  • the position outside the work area controls the automatic mower 1 to change the movement mode and move to the work area.
  • the process of the automatic lawn mower checking the map includes the following steps: the control module controls the movement module to drive the automatic lawn mower to move along the boundary of the map record to check whether the boundary of the map record is accurate.
  • the control module controls the mobile module to drive the automatic mower to move along the boundary of the map record
  • the user observes the movement of the automatic mower, and the user determines whether the automatic mower moves along the boundary of the actual working area.
  • the automatic lawn mower is controlled to move from the charging station in a counterclockwise direction along the boundary of the map record.
  • the boundary of the graph record is offset to the right with respect to the boundary of the actual work area, and the movement of the automatic mower along the boundary of the map record will gradually deviate from the boundary of the actual work area.
  • the right side of the boundary of the actual work area may be a non-turf area such as a road, and moving the automatic mower to the area while performing mowing work may cause safety problems.
  • the user discovers that the automatic mower has deviated from the boundary of the actual work area by observing the movement of the automatic mower.
  • the user can stop the automatic mower from moving.
  • the user observes the process of checking the map by the automatic lawn mower, and ensures the reliability of the inspection result of the map.
  • the automatic working system includes a communication module, and the communication module can be integrated into the mobile station, or can be independently set on the automatic lawn mower and electrically connected to the control module.
  • the communication module is used for wireless communication between the automatic mower and the user's smart terminal.
  • the communication module sends the current position information of the automatic mower to the user's smart terminal, and the user's smart terminal stores and displays the work area map, and simultaneously displays the current position of the automatic mower.
  • the automatic lawn mower checks the map the user observes the movement of the automatic lawn mower.
  • the user When the automatic lawn mower moves away from the boundary of the actual working area, the user records the position A of the automatic lawn mower moving away from the boundary of the actual working area. Since the cutting assembly of the automatic mower does not work, the automatic mower can be allowed to continue moving until it returns to the boundary of the actual working area. The user records the automatic mower returning to position B of the boundary of the actual work area. After the user obtains the starting point position A point and the ending point position B of the portion of the boundary of the map record that deviates from the boundary of the actual working area, the automatic mower is controlled to stop moving, and then the positioning device is used to re-record the actual work including the points A to B. The position coordinates of the boundary of the region, using the re-recorded boundary position coordinates to correct the map.
  • the control module will modify the map stored by the storage unit, and control the mobile module to drive the automatic mower to check whether the modified map is correct.
  • the automatic mower is returned to the starting position of the map correction, or the position on the boundary of the map before the starting point of the map correction, so that the automatic mower moves along the boundary of the modified map.
  • the cutting assembly is still controlled to remain inoperative to ensure the safety of the inspection process.
  • the user observes the movement of the automatic mower and determines whether the automatic mower moves along the boundary of the actual working area. If the automatic mower moves to the end position of the map correction, it always moves along the boundary of the actual working area. , indicating that the correction of the map is correct.
  • the control mobile module drives the automatic mower to move to check the corrected map, further ensuring the reliability of the inspection of the map.
  • the method of checking the map by the automatic lawn mower is basically the same as that in the first embodiment, with the difference that the measure for correcting the map is different from that in the first embodiment.
  • the user's smart terminal marks the start point position A point and the end point position B point on the displayed map.
  • the user modifies the map by manually connecting the start point position A point and the end point position B point on the display screen of the smart terminal.
  • the user may determine the shape of the boundary between the starting point A point and the end point B point according to the shape feature of the actual boundary, or may be based on the offset of the boundary of the map record before the correction with respect to the boundary of the actual working area.
  • the degree of deviation of the boundary between the start point position A point and the end point position B point with respect to the boundary of the map record before correction is determined.
  • the control module will modify the map stored in the storage unit, and control the mobile module to drive the automatic mower to check whether the modified map is correct.
  • the method of checking the map by the automatic lawn mower is basically the same as that in the first embodiment, with the difference that the measure for correcting the map is different from that in the first embodiment.
  • the automatic lawn mower is controlled to stop moving, and the automatic lawn mower returns to the point A, which starts to deviate from the boundary of the actual working area, or point A.
  • the user remotely controls the automatic mower movement through the intelligent terminal, so that the automatic mower moves along the boundary of the actual working area, and the automatic mower moves the coordinates of the position through which the movement moves according to the boundary of the actual working area.
  • the user observes the current position of the automatic mower on the map displayed by the smart terminal, and determines whether the current position of the automatic mower has returned to the boundary of the map record before the correction, if the current position of the automatic mower has returned to the correction
  • the remote control of the automatic mower is stopped and the end position is recorded.
  • the map is corrected using the position coordinates recorded by the automatic mower in the remote mode.
  • the control module will modify the map stored in the storage unit, and control the mobile module to drive the automatic mower to check whether the modified map is correct.
  • the automatic lawn mower is controlled to continue to move along the boundary of the map record until the movement along the boundary of the map is completed. If the correction to the map is incorrect, take measures to correct the map again. Take correction again In the case of the map measure, the method of correcting the map in the second embodiment or the third embodiment may also be selected.
  • the boundary of the map record is outwardly deviated with respect to the boundary of the actual work area.
  • the boundary of the map record may also deviate inward relative to the boundary of the actual work area.
  • the boundary of the map record can also be corrected by the above method, so that the boundary of the map record is consistent with the boundary of the actual work area, and the problem that the area near the boundary of the actual work area cannot be cut is avoided, so that the lawn can reach the ideal. Cutting effect.
  • the automatic lawn mower inspection map further includes the following steps: the control module controls the movement module to drive the automatic mower movement to cover the work area defined by the map, and checks the obstacle information in the work area of the map record. Whether the slope information of the work area or the strength of the satellite signal received by the work area is accurate, in particular, whether there is an unsafe area in the actual work area where the map is not recorded. Check the automatic mower for any abnormalities such as trapping, falling, colliding, stagnation, slipping, and leaving the work area.
  • the work area defined by the map including the work area within the boundary position of the map record. If an area in the map is marked as an unsafe area, for example, marked as a pit, the automatic mower is not allowed to enter the area, the map is limited The unsafe area has been excluded from the work area.
  • the automatic mower When the automatic mower covers the work area defined by the map, it can be moved by a random path or by a preset path, wherein the preset path is automatically generated by the program according to the boundary shape of the map. In this embodiment, the automatic mower is caused to cover the work area defined by the map with a preset path.
  • the automatic lawn mower includes an environmental sensor.
  • the automatic lawn mower includes an obstacle detection sensor to detect an obstacle in the moving direction of the automatic lawn mower.
  • the obstacle detecting sensor includes a collision detecting sensor.
  • the control module determines that there is an obstacle in the moving direction of the automatic lawn mower.
  • the obstacle detecting sensor may further include a non-contact sensor such as an ultrasonic sensor instead of the collision detecting sensor to detect an obstacle in the moving direction of the automatic mower.
  • the obstacle detecting sensor may further include a cliff detecting sensor for detecting whether there is a pit or the like in the moving direction of the automatic mower.
  • the control module acquires the position of the detected obstacle, and compares the position of the detected obstacle with the position marked as an obstacle in the stored map, if the detected If the location of the obstacle does not meet the location marked as an obstacle in the stored map, then the detected obstacle is an unknown obstacle, and the control module controls the intelligence of the communication module to the user.
  • the terminal sends a message prompting the user to correct the map.
  • the automatic mower can also determine whether it is trapped or tipped by an obstacle detection sensor such as an accelerometer or a lift sensor. If it is determined that it is trapped or overturned, the user is notified to prompt the user to correct the map. Mark these unsafe areas on the map to prevent the automatic mower from entering these unsafe areas when performing mowing work.
  • the automatic lawn mower further includes a slope detecting sensor for detecting the slope of the working area.
  • the slope detecting sensor detects the inclination of the automatic lawn mower, thereby indirectly obtaining the slope of the working area where the automatic lawn mower is located, and the control module determines whether the slope of the working area exceeds a threshold, and if the threshold is exceeded, determining the current position.
  • the area is a slope.
  • the control module compares the detected position of the slope with the position marked as a slope in the stored map. If the detected position of the slope does not match the position marked as a slope in the stored map, the control communication module sends the position to the user's smart terminal. Information, prompting the user to correct the map.
  • the control module determines the strength of the satellite signal in the working area according to the reliability of the positioning signal output by the satellite positioning device. For example, when the satellite positioning device can only receive signals from three or fewer satellites, the control module determines that the satellite signal at the current location is weak. The control module compares the detected weak position of the satellite signal with the position of the stored map marked as a weak satellite signal, and if the detected position of the weak satellite signal does not match the position of the stored map marked as a weak satellite signal, then the control communication The module sends a message to the user's smart terminal, prompting the user to correct the map.
  • the automatic lawn mower can be controlled to stop moving, and the user observes the position of the automatic lawn mower to determine whether the automatic lawn mower is correctly detected.
  • the measures for correcting the map are taken, and the measures for correcting the map are similar to those for correcting the boundary of the map record.
  • the control module modifies the map stored by the storage unit and controls the automatic mower movement to check the corrected map. Specifically, in the present embodiment, the automatic mower is returned to the position where the obstacle is detected, or the slope, or the satellite signal is weak, or the position before the position, continues to cover the work area defined by the map.
  • the automatic mower covers the work area defined by the map, if an unknown obstacle, or a slope, or a weak satellite signal is found again, the user is notified again to prompt the user to take measures to correct the map until the automatic mower is completed. Covers the work area defined by the map.
  • the automatic mower covers the work area defined by the map to check the map, and the control cutting component remains inactive. Therefore, even if the recorded map is inaccurate, it can be avoided.
  • the cutting-free components injure or injure other objects, thus ensuring the safety of the automatic working system. For example, when the automatic mower enters the unsafe area and is overturned, it avoids the safety problem when the person approaches the automatic mower. For example, when the automatic mower enters the non-turf area, the work of the cutting unit is avoided. Damage to objects in the area.
  • the user when the automatic mower detects an unknown obstacle, or a slope, or a weak satellite signal in the covering process, the user is notified to determine whether the automatic mower is correctly detected by the user, thereby ensuring the correct The reliability of the inspection of the map.
  • the method for checking the map by the automatic lawn mower is basically the same as that in the first embodiment, and the difference is that the automatic lawn mower covers the work area defined by the map, and the user automatically cuts the grass by observing The movement and status of the machine directly determine whether the map is accurate. Specifically, in the process of the automatic lawn mower covering the work area defined by the map, the user can observe whether the automatic lawn mower encounters an unknown obstacle, or a slope, or a region with weak satellite signals; and can also determine the automatic lawn mower. Whether the movement mode is reasonable; also can determine whether the automatic mower moves along the preset path generated by the program.
  • the measure for correcting the map is similar to the method in the first embodiment. If the user judges that the automatic lawn mower moves in an unreasonable manner, or determines that the automatic lawn mower moves away from the preset path, the automatic lawn mower can be controlled to stop moving, and the mobile mode is manually set on the smart terminal, or based on the smart terminal display.
  • the preset path manually modifies the path, or remotely controls the automatic mower to modify the path, and so on. The user's observations ensure the reliability of the inspection of the map.
  • the control module controls the mobile module to drive the automatic mower to move within the work area defined by the map.
  • the control module controls the automatic mower to move within the work area defined by the map and perform the mowing work.
  • the automatic working system in this embodiment is a safe automatic working system.
  • the step of inspecting the map is performed while controlling the cutting assembly to remain closed, ensuring the security of the step of inspecting the map.
  • the inspection of the map is performed under the observation of the user, and the inspection of the map is guaranteed. Check the reliability. Therefore, the method of inspecting the map in this embodiment is a safe and reliable method, which further ensures the security of the automatic working system in the embodiment.
  • the flow of checking the map by the automatic working system of the first embodiment of the present invention is as shown in FIG. 4, and includes the steps of:
  • S102 Control the automatic lawn mower to move along the boundary of the map record, and the smart terminal displays the position of the automatic lawn mower on the map.
  • step S103 The user observes the movement of the automatic mower to determine whether the automatic mower moves along the boundary of the actual working area; if the automatic mower moves along the boundary of the actual working area, the process proceeds to step S200; if the automatic mower does not follow the actual The boundary of the work area moves, and the flow proceeds to step S104.
  • S104 The user takes measures to correct the map.
  • S200 Control the automatic mower to move along the boundary of the map record for one week, confirm the map, and generate a preset path.
  • step S202 determining whether the automatic lawn mower encounters an unknown obstacle, or a slope, or an area where the satellite signal is weak, and if yes, proceeds to step S203; if not, proceeds to step S204.
  • S203 The user takes measures to correct the map.
  • the position coordinates recorded by the positioning device can be transmitted to the control module of the automatic lawn mower through the electrical connection between the mobile station and the automatic lawn mower, and can also be wirelessly transmitted to the intelligent terminal of the user.
  • the map stored by the storage unit may be generated by the control module, generated by the positioning device, or generated by the intelligent terminal.
  • the preset path may be generated by a program in the control module, or generated by a program in the positioning device, or generated by a program in the intelligent terminal. In this embodiment, the preset path is updated according to the correction of the map.
  • the automatic mower realizes communication with the intelligent terminal of the user through the communication module, including sending the current location information to the intelligent terminal, and receiving the wisdom.
  • the automated working system may further include an input/output device that may be integrated into the mobile station of the positioning device or may be independently mounted to the automatic lawn mower to be electrically connected to the control module.
  • the input/output device can include a touch screen.
  • the touch screen is used to display the map and the current position of the automatic mower.
  • the touch screen can also be operated by the user to correct the map. Therefore, the touch screen can replace the communication module as an interactive module for realizing automatic mower interaction with the user.
  • the user can also control the automatic mower to stop moving by pressing the stop button on the automatic mower.
  • the automatic lawn mower may further include a warning unit.
  • the warning unit sends a warning signal when an unknown obstacle, or a slope, or a weak satellite signal is found. .
  • the boundary of the actual working area may refer to a natural boundary formed between the lawn and the non-turf, or may be defined by the user according to needs.
  • the control module determines that the unknown obstacle is an obstacle that the automatic mower can easily avoid, such as trees, and may not record the obstacle position and correct the position without notifying the user. map.
  • control module in the process of the automatic mower covering the work area defined by the map, can also determine and record the positioning accuracy variance and the solution state of the current position, including differential fixed solution, floating point solution, pseudorange solution, Single point solution is still no satellite, inertial mode.
  • the work area may include more than two separate areas and a channel connecting the separated areas, and the map of the work area will include channel information for the work area.
  • the automated working system includes an automatic lawn mower and a positioning device.
  • the automatic mower includes a mobile module and a task execution module, and a driving circuit connected to the mobile module and the task execution module.
  • the driving circuit drives the mobile module to drive the automatic mower to move, and drives the task execution module to perform the work task.
  • the task execution module includes a cutting component, and the driving circuit drives the cutting component to perform a cutting operation.
  • the positioning device is configured to detect the current position of the automatic mower. Ben
  • the structure of the automatic lawn mower and the positioning device in the embodiment is basically the same as that of the first embodiment. The difference is that in the embodiment, the automatic working system includes: a storage unit, a storage work area map, a map confirmation program, and a map confirmation program.
  • the automatic working system further includes a control module that performs the above-mentioned map confirmation program by monitoring the output of the positioning device, and executes the above-mentioned working program after the above-mentioned map confirmation program is completed.
  • the automatic working system enters the map confirmation program in response to the user's instruction, and the control module receives the driving circuit instruction, and controls the mobile module to drive the automatic lawn mower to move along the boundary of the working area, specifically, based on the working area map stored by the storage unit (
  • the work area boundary position information is included, and the current position of the automatic mower output by the positioning device controls the automatic mower to move along the boundary of the work area, and the control method is similar to that in the first embodiment.
  • the automatic working system receives the confirmation signal from the user, the current work area map is marked as the official version and stored, and the map confirmation program is completed.
  • the control module executes the process of the map confirmation program, that is, the user confirms whether the boundary of the current work area map matches the boundary of the actual work area by observing the automatic lawn mower moving along the boundary based on the work area map.
  • the automatic working system must be able to execute the working program after the map confirmation program is completed, that is, the control module receives the driving circuit command, controls the moving module to drive the automatic mower to move, and controls the cutting module to perform the cutting work.
  • the control module controls the automatic mower to automatically move and perform cutting in the work area based on the confirmed work area map (marked as official version and stored) and the current position of the automatic mower output by the positioning device. jobs.
  • the automatic working system must execute the map confirmation program before executing the working program, thereby ensuring the accuracy of the stored work area map, thereby ensuring the safety of the automatic working system based on the working area map working process.
  • the above map confirmation procedure must be completed by receiving a confirmation signal from the user, which ensures the reliability of the map confirmation.
  • the boundary of the working area includes the outer boundary and the inner boundary of the working area
  • the inner boundary includes a boundary formed by the periphery of the obstacle, the flower bed, the pool, etc., and the automatic mower is prohibited from entering the area enclosed by the inner boundary.
  • the map confirmation program further includes providing a drive circuit instruction to keep the cutting assembly from performing the cutting operation.
  • the control module receives the drive The motor circuit command controls the cutting assembly to not work. That is to say, the control module controls the moving module to drive the automatic mower to move along the boundary of the working area to confirm whether the boundary is accurate, and the cutting component is in a non-working state. This ensures the security of the map confirmation process, and the effect is similar to that in the first embodiment, and will not be described again.
  • the map confirmation program further includes: after providing the driving circuit instruction to move along the boundary of the working area, providing the driving circuit instruction to move in the boundary defined working area, including the working area defined by the outer boundary and the inner boundary,
  • the working area defined by the inner boundary refers to a working area other than the area enclosed by the inner boundary.
  • the control module receives the driving circuit instruction, and controls the mobile module to drive the automatic mower to move in the working area defined by the boundary.
  • the control module is based on the working area map of the confirmed boundary and the automatic mower output by the positioning device. The current position of the control mobile module drives the automatic mower to move within the defined working area of the boundary.
  • the map confirmation program can be divided into two stages.
  • the second stage is based on the confirmed work area map boundary. Confirm whether the map of the work area defined by the boundary is accurate and whether the safety of the system can be guaranteed.
  • the two phases respectively receive an acknowledgment signal from the user, that is, first receive an accurate boundary acknowledgment signal from the user's confirmed work area map, and after receiving the boundary confirmation signal from the user, enter the second stage to confirm the boundary defined work area. Whether the map is accurate or not, the map confirmation procedure is completed after receiving an accurate map confirmation signal from the work area map defined by the user's confirmation boundary.
  • the work area defined by the boundary must be confirmed to ensure that the movement of the automatic mower does not cross the boundary of the actual work area, thereby ensuring safety and ensuring automatic cutting.
  • the grass machine covers the entire work area and avoids missing uncut areas.
  • the process of confirming the boundary defined work area is similar to that of the first embodiment.
  • the user can follow the automatic lawn mower to confirm whether the map is accurate, or can prompt the user to confirm the map by causing the automatic lawn mower to alarm when encountering an abnormal situation. Whether it is accurate or not, especially for the process of confirming whether the boundary defined work area is accurate. Abnormal conditions in the work area include situations in which the automatic mower collides, is trapped, slips, and falls.
  • the automatic working system includes an alarm unit that outputs an alarm signal indicating an abnormal condition of the working area.
  • the alarm unit may be a speaker, a display, or the like mounted on the automatic lawn mower casing, or may be a communication module, and send a remote alarm signal to the user terminal.
  • the automatic mower also includes an environmental sensor, at least partially mounted to the automatic mower, for detecting an abnormal condition of the work area when the automatic mower moves within the work area, including moving along the boundary.
  • the control module controls the alarm unit to output an alarm signal by monitoring the output of the environmental sensor.
  • Environmental sensors include cameras, capacitive grass recognition sensors, ultrasonic sensors, photoelectric distance sensors, accelerometers, and positioning devices themselves, among others. The application of the environmental sensor is similar to that in the first embodiment.
  • the map confirmation program further includes receiving a control signal from the user, and providing a driving circuit command according to the control signal to control the movement mode.
  • the automatic mower moves away from the boundary of the actual working area along the boundary, and the map confirmation program receives the stop movement signal sent by the user, and provides a drive circuit command according to the stop movement signal to control the stop. mobile.
  • the control module receives the drive circuit command and controls the automatic mower to stop moving.
  • the map confirmation process is carried out under the control of the user, ensuring the security of the map confirmation process.
  • the map confirmation program further includes receiving a map modification signal from the user to modify the work area map.
  • the map correction measures will be taken.
  • the map correction measures are similar to those in the previous embodiment, and will not be described again.
  • the map confirmation program receives the map modification signal from the user, corrects the stored work area map using the map correction information, or replaces the stored work area map with the corrected work area map.
  • the map confirmation program receives the confirmation signal from the user, the current work area map is marked as the official version (relative to the modified version) and stored.
  • the automated work system automatically moves and performs the cutting work based on the work area map marked as the official version in the work program.
  • the automatic working system may receive an acknowledgment signal from the user through the communication module, the communication module is used to communicate with the user's smart terminal or the remote controller, or receive an acknowledgment signal from the user through local input, and the like.
  • the user can observe or control the movement of the automatic mower by the APP loaded on the smart terminal, and the APP receives the confirmation signal of the user and transmits the confirmation signal to the automatic working system.
  • the positioning device includes a satellite positioning device, and receives the satellite positioning data, or the beacon positioning device, and communicates with the beacon disposed inside or outside the working area to obtain positioning data
  • the beacon positioning device includes a UWB positioning device or an ultrasonic positioning device.
  • the positioning device can be fixedly attached to the automatic mower or the detachable connection of the positioning device to the automatic mower.
  • the satellite positioning device includes a differential satellite positioning device, and the differential satellite positioning device includes an RTK-GPS positioning device.
  • RTK-GPS positioning The carrier phase difference technology is used, which is similar to the positioning device in the first embodiment.
  • the navigation principle can refer to the satellite navigation system in the first embodiment.
  • the positioning device is detachably connected to the automatic lawn mower, and during the process of executing the map confirmation program and the working program by the automatic working system, the positioning device is installed on the automatic lawn mower to output the current position of the automatic lawn mower.
  • the positioning device includes a housing; a satellite signal receiver installed in the housing for providing positioning data, and the first control module and the first storage unit.
  • the automatic lawn mower includes a second control module and a second storage unit mounted to the housing of the automatic lawn mower.
  • the control module of the automatic working system includes a first control module and a second control module
  • the storage unit includes a first storage unit and a second storage unit.
  • the work area map, the map confirmation program, and the work program may be stored in the first storage unit, or may be stored in the second storage unit, or partially stored in the first storage unit, and partially stored in the second storage unit.
  • the map confirmation program and the work program may be executed by the first control module, or by the second control module, or partially by the first control module, and partially by the second control module.
  • the satellite signal receiver provides positioning data
  • the first storage unit stores the work area map
  • the first control module compares the current position of the automatic lawn mower with the work area map, and outputs control commands to the automatic lawn mower.
  • the second control module receives the control command output by the first control module, generates a driving signal, and controls the driving circuit to drive the moving module to drive the automatic mower to move.
  • the first control module receives an acknowledgment signal from the user, specifically, a user acknowledgment signal transmitted by the APP.
  • the second control module is further configured to control the driving circuit to drive the cutting component to perform the cutting work, collect the detection data of the environmental sensor, control the alarm unit to output the alarm signal, and the like.
  • the storage unit may be included in the control module or may be independent of the control module.
  • the driving circuit includes a first driving circuit that drives the moving module to drive the automatic mower to move.
  • the moving module includes a driving motor, and the first driving circuit drives the driving motor to cause the driving motor to drive the automatic mower to move.
  • the drive circuit includes a second drive circuit that drives the cutting assembly to perform a cutting operation.
  • the cutting assembly includes a cutting motor, and the second drive circuit drives the cutting motor such that the cutting motor drives the cutter head and the blade to move.
  • FIG. 14 is a flow chart showing a control method corresponding to the automatic working system of the embodiment. As shown in FIG. 14, the control method includes the following steps:
  • S305 Control the moving module to drive the automatic mower to move along the boundary of the working area by monitoring the current position of the automatic mower;
  • step S307 determining whether the work area map is accurate, if it is accurate, proceeds to step S313; if not, proceeds to step S309;
  • S311 Receive a map modification signal from the user, and modify the work area map according to the map modification signal;
  • S313 Receive a boundary confirmation signal from a user
  • S315 by monitoring the current position of the automatic mower, controlling the mobile module to drive the automatic mower to move within the working area defined by the boundary;
  • step S317 determining whether the work area map is accurate, if it is accurate, proceeds to step S323; if not, proceeds to step S319;
  • S319 receiving a stop movement signal from the user, and controlling the mobile module to drive the automatic mower to stop moving according to the stop movement signal;
  • S321 receiving a map modification signal from a user, and modifying a work area map according to the map modification signal;
  • S327 Control the moving module to drive the automatic mower to move, and control the cutting component to perform the cutting work.
  • control enters the working mode only after receiving the confirmation signal from the user, which ensures the security of the automatic working system based on the map work.
  • the map confirmation mode it is also possible to complete the map confirmation as a necessary condition for entering the work mode, rather than a sufficient condition.
  • the automatic lawn mower 1 of the sixth embodiment of the present invention includes a work area identification module 101, a drive module 102, a positioning module 103, a map construction and storage module. 104 and regression path planning module 105. It can be understood that the functions of the map construction and storage module 104 can also be completed by the storage unit and the control module in the above embodiment.
  • the work area identification module 101 is configured to determine whether the area to be passed by the automatic lawn mower 1 is a work area.
  • the work area identification module 101 includes a grass detection module for identifying whether the area to be passed by the automatic lawn mower is grass. For example, an image can be captured by a camera to identify whether it is a grass by recognizing the texture of the captured image.
  • an obstacle 9 such as a bush
  • the automatic mower 1 avoids the obstacle 9 by turning, retreating, or the like.
  • the drive module 102 is used to drive the automatic mower 1 to walk in the work area.
  • the drive module 102 includes a power mechanism, a transmission mechanism, a traveling mechanism, and the like.
  • the power mechanism generally includes a motor and a battery pack that supplies energy to the motor.
  • the battery pack is mounted with the motor on the frame of the automatic mower. In this way, the automatic mower does not rely on an external power source and is better able to adapt to the need to cruise in the work area.
  • the transmission mechanism is generally a gear transmission mechanism for transmitting the rotational power outputted by the motor through the speed ratio conversion and/or commutation to the traveling mechanism, thereby driving the automatic lawn mower 1 to walk.
  • the walking element of the running mechanism may be a walking wheel or a walking track.
  • the walking elements are typically made of a flexible material or at least partially flexible to relieve stress on the grass.
  • the positioning module 103 is configured to receive a positioning signal to obtain a coordinate of a current position of the automatic mower or a coordinate area composed of a plurality of coordinates.
  • the map construction and storage module 104 is configured to determine whether the acquired coordinates are stored in the work map. When the determination is no, the coordinates are added to the work map to obtain the updated work map.
  • the map construction and storage module 104 determines whether the determinations have been stored in the working map, and if the determination result is yes , indicating that the current position of the automatic mower 1 is a proven work area. If the judgment result is no, the current position of the automatic mower 1 is an unexplained work area, and the area needs to join the work. In the map, to improve the work map, it is conducive to the subsequent mowing work and return.
  • the positioning module 103 has a communication module for receiving a positioning signal, and the communication module includes a GPS module, a D-GPS module, a UWB module, a Zigbee module, a wifi module, an ultrasonic receiving module, an inertial navigation module, an odometer, an electronic map, and an acceleration.
  • the communication module includes a GPS module, a D-GPS module, a UWB module, a Zigbee module, a wifi module, an ultrasonic receiving module, an inertial navigation module, an odometer, an electronic map, and an acceleration.
  • the communication module includes a GPS module, a D-GPS module, a UWB module, a Zigbee module, a wifi module, an ultrasonic receiving module, an inertial navigation module, an odometer, an electronic map, and an acceleration.
  • the sensors there are various ways of positioning, as long as the coordinates of the various places that the automatic mower 1 passes during the walking can be obtained.
  • the coordinates may be coordinate values assigned by the satellite positioning system that reflect the position of the object on the earth. It can also be a coordinate value in a self-constructed coordinate system. At this time, the origin of the coordinate system of the coordinate can be set as needed. For example, since the automatic mower 1 usually starts from the charging station 2, performs mowing work, and now needs to be charged, returns to the charging station. Therefore, the origin of the coordinate system can be the charging station 2.
  • the automatic lawn mower 1 uses the work area identification module 101 to identify the unexplained work area, so that the automatic lawn mower 1 does not need to be fully verified when working, in other words, the work map is not required to be perfect, but it is completely absent. A proven work area.
  • the automatic mower 1 can be put into operation quickly without having to learn all the work areas first, especially when moving to work in a new work area.
  • the work map can be updated every time the automatic lawn mower 1 works (ie, mowing work), so that the work map is continuously improved.
  • the automatic mower 1 can design a regression path based on the updated known work map when regression is required after each mowing operation.
  • the regression path planning module 105 is configured to receive the regression instruction and generate a regression path according to the updated work map, and control the automatic lawn mower 1 to return to the predetermined position along the return path from the position before the regression.
  • the automatic mower 1 is usually returned to the charging station 2 for charging, and therefore, the predetermined position is generally a charging station.
  • the predetermined position may also be other required positions, for example, it may be an area where it is important to mowing, or, for example, it may be a position convenient for the user to inspect and overhaul the automatic mower 1.
  • each walk of the automatic mower 1 is capable of updating a known work map.
  • the regression path can be planned based on the updated known map.
  • the automatic mower 1 quickly returns based on the known map planning path, and does not require the user to train the mower to learn all the work areas.
  • the regression path planning module 105 generates an optimal regression path based on the known map.
  • the optimal regression path is the path that meets the needs of different purposes.
  • the regression path is a path defined by known coordinates in the work map, the shortest distance from the position before the return to the predetermined position.
  • the shortest path may be a straight line or a broken line or arc after avoiding obstacles.
  • the regression path planning module 105 is further configured to record the number of times each known coordinate in the work map is passed by the automatic mower 1.
  • the regression path is the coordinates of the position where the regression occurred, the coordinates of the predetermined position, the known coordinates between the position before the return and the predetermined position, and the number of passes by the automatic mower 1 is the least. limited. In this way, the automatic mower 1 can avoid excessive crushing of certain areas when returning.
  • the automatic mower 1 is set to the charging station 2 to start its first work, and the arrow indicates the walking path of the automatic mower 1. In this process, no coordinates have been recorded in the work map, and the coordinates of the positions passed by the automatic mower 1 are recorded and constructed into an initial work map.
  • the automatic mower 1 ends the first work, and returns to the charging station 2 from the position in Fig. 7.
  • the regression path planning module 105 generates a polygonal line path as indicated by the arrow in the figure. It can be seen that the automatic lawn mower 1 does not need to return according to the original path, and the fast return can be realized according to the polygonal line path in FIG.
  • the automatic mower 1 starts at the charging station 2 and begins its second work.
  • the hatching indicates the area that passes through the first work, and the area defined by the solid line boundary is the area that passes through the second work.
  • the area passing through the automatic mower 1 is partially coincident with the area where the first work passes, and the coordinates corresponding to the areas do not need to be repeatedly recorded, and the map construction and storage module 104 only records the newly added coordinates to make the update.
  • the post map contains the new area that was taken during the second job.
  • the automatic mower 1 starts to return from the position shown in Fig. 9.
  • the regression path generated by the regression path planning module 105 is as indicated by the arrow in FIG. It can be seen that the regression path planning module 105 does not return according to the forward path of the second work or the first work, but at the same time, the area determined by the first work and the second work are detected. The area to generate a faster regression path.
  • Figures 10 and 11 with the increase in the number of times the automatic mower 1 is operated, new coordinates are continuously added to the work map, and the work map is more and more perfect.
  • Figures 10 and 11 show the entire work area. Detected situation.
  • the regression path planning module 105 can generate a better regression path each time in accordance with the new work map.
  • the above automatic lawn mower 1 can start working quickly, and use the working process to perfect the work map. After the work is finished, the work map can be navigated according to the existing work map, thereby realizing rapid regression without requiring the user to train the automatic lawn mower in advance. Work area.
  • an embodiment of the present invention further provides a walking method of the above automatic lawn mower 1, comprising the steps of:
  • S110 Determine whether an area to be passed by the automatic lawn mower is a work area.
  • the work area identification module 101 is used to identify the area to be walked, and the user does not need to train the lawn mower in advance, which improves the convenience of use.
  • S120 Drive an automatic lawn mower to walk in the working area.
  • the power mechanism drives the running mechanism to advance the automatic mower.
  • the automatic mower can automatically avoid obstacles and walk only in the work area.
  • S130 Receive a positioning signal to obtain a coordinate of a current position of the automatic mower or a coordinate area composed of a plurality of coordinates.
  • the positioning is realized by various methods such as GPS and D-GPS, and the coordinates of the positions in the walking path are obtained.
  • S140 Determine whether the coordinates are stored in the work map. If the determination is no, add the coordinates to the work map to obtain an updated work map.
  • the map construction and storage module 104 utilizes the automatic mower 1 to continuously improve the work map every time the work is performed.
  • the regression path is a path defined by known coordinates in the work map, the shortest distance from the position before the return to the predetermined position.
  • the shortest path may be a straight line or a broken line or arc after avoiding obstacles.
  • the regression path planning module 105 is further configured to record the number of times each known coordinate in the work map is passed by the automatic mower 1.
  • the regression path is defined by the coordinates of the position where the regression occurred, the coordinates of the predetermined position, the known coordinates between the position before the return and the predetermined position, and the number of passes by the automatic mower 1 is the least. In this way, the automatic mower 1 can avoid excessive crushing of certain areas when returning.
  • the automatic mower 1 can start working quickly, and use the working process to perfect the work map. After the work is finished, the work map can be navigated according to the existing work map, thereby realizing rapid regression without requiring the user to train the automatic mower in advance. Learn all the work areas.
  • the present invention is not limited to the specific embodiment structures, and the structures and methods based on the inventive concept are all within the scope of the present invention.

Landscapes

  • Engineering & Computer Science (AREA)
  • Radar, Positioning & Navigation (AREA)
  • Remote Sensing (AREA)
  • Automation & Control Theory (AREA)
  • General Physics & Mathematics (AREA)
  • Aviation & Aerospace Engineering (AREA)
  • Physics & Mathematics (AREA)
  • Health & Medical Sciences (AREA)
  • Business, Economics & Management (AREA)
  • Artificial Intelligence (AREA)
  • Evolutionary Computation (AREA)
  • Game Theory and Decision Science (AREA)
  • Medical Informatics (AREA)
  • Life Sciences & Earth Sciences (AREA)
  • Environmental Sciences (AREA)
  • Control Of Position, Course, Altitude, Or Attitude Of Moving Bodies (AREA)
  • Guiding Agricultural Machines (AREA)
  • Harvester Elements (AREA)

Abstract

一种自动工作系统(100),包括自移动设备(1)和定位设备(15)。该自移动设备(1)包括移动模块(5)和任务执行模块(7),以及连接至移动模块(5)和任务执行模块(7)的驱动电路,该驱动电路驱动移动模块(5)带动自移动设备(1)移动,并驱动任务执行模块(7)执行工作任务;该定位设备(15)被配置为检测自移动设备(1)的当前位置;该自动工作系统(100)包括存储单元,被配置为存储工作区域地图,以及:地图确认程序,该地图确认程序包括,提供驱动电路指令以沿工作区域的边界(200)移动,接收来自用户的确认信号以完成地图确认程序;工作程序,提供驱动电路指令以在地图限定的工作区域内移动并执行工作任务;控制模块,被配置为通过监测定位设备(15)的输出,执行地图确认程序,并在地图确认程序完成后执行工作程序。

Description

自动工作系统及其控制方法 技术领域
本发明涉及一种自动工作系统及其控制方法。尤其涉及一种不布边界线的自动割草机系统,以及自动割草机系统的控制方法。
背景技术
自动工作系统中,自移动设备能够在一定区域内自动行驶并工作,来完成特定的任务。由于自动工作系统是在没有人为操作的情况下工作的,自移动设备的运行可能出现一些安全性问题,例如,自移动设备可能行驶到用户不希望其出现的区域。以自动割草机为例,自动割草机可能行驶到草坪以外的区域,或行驶到凹坑区域。
以自动割草机所在的自动工作系统为例,解决上述问题的一种方法为,在自动割草机上安装传感器,检测边界或障碍物。采用这种方法,需要用户在草坪上铺设边界线,边界线中传输电信号,从而产生电磁场,自动割草机上的边界传感器检测电磁场,自动割草机的控制器根据边界传感器检测到的电磁场判断自动割草机是否在边界线限定的工作区域内工作。采用这种方法,铺设边界线麻烦,而且影响草坪美观。
另一种方法为,建立工作区域的地图,控制自动割草机在地图限定的工作区域内活动。建立地图的方法有多种,其中一种建立地图的方法为,建立坐标系,记录工作区域的位置坐标,用所记录的工作区域的位置坐标限定自动割草机可以安全工作的范围。自动工作系统工作时,自动割草机的控制器判断自动割草机的当前位置与存储在控制器中的工作区域的位置坐标的关系,若发现自动割草机将行驶到安全工作的范围以外的位置,则控制自动割草机向工作区域内偏转,从而保证自动割草机的安全工作。
当然,建立地图的方法也可以是通过采集工作区域的图像,建立图像库,为含有不同特征的图像定义为工作区域内、或工作区域外、或边界等。自动工作系统工作时,安装在自动割草机上的摄像头捕获自动割草机前方地面的图像,控制器分析图像特征,判断自动割草机是否位于安全的工作区域。
建立地图的方法不必在草坪上布置边界线,为用户省去布边界线的麻烦。 但是,这种方法存在一个问题,就是建立地图的准确性。
例如,地图记录的工作区域的位置坐标与实际工作区域的位置坐标有偏差,地图指示可以安全工作的区域超出了自动割草机实际可以安全工作的范围,则自动工作系统工作时,自动割草机将行驶到不安全的区域工作,导致安全性问题。又如,地图指示可以安全工作的区域小于自动割草机实际可以安全工作的区域,则自动工作系统工作时,自动割草机将不能达到未包含在地图限定的安全工作区域内的区域,使得草坪切割不完整。
这种建立地图的方法,即使使用高精度的定位设备,也仍然无法避免建立地图的不准确的问题,而且采用定位精度越高的定位设备,相应的自动工作系统的成本也越高,不可能无限制的提高定位设备的精度。因此,亟需找到一种能够解决建立地图的不准确的问题的方法。
发明内容
为了解决自动工作系统的工作区域的地图建立的不准确的问题,本发明所采用的技术方案是:
一种自动工作系统,包括自移动设备和定位设备;所述自移动设备包括移动模块和任务执行模块,以及连接至所述移动模块和任务执行模块的驱动电路,所述驱动电路驱动所述移动模块带动自移动设备移动,并驱动任务执行模块执行工作任务;所述定位设备被配置为检测所述自移动设备的当前位置;所述自动工作系统包括:存储单元,被配置为存储工作区域地图,以及:地图确认程序,所述地图确认程序包括,提供驱动电路指令以沿工作区域的边界移动,接收来自用户的确认信号以完成所述地图确认程序;工作程序,提供驱动电路指令以在地图限定的工作区域内移动并执行工作任务;控制模块,被配置为通过监测定位设备的输出,执行所述地图确认程序,并在所述地图确认程序完成后执行所述工作程序。
优选的,所述定位设备包括卫星定位设备。
优选的,所述卫星定位设备包括差分卫星定位设备。
优选的,所述差分卫星定位设备包括RTK-GPS定位设备。
优选的,所述定位设备固定连接于所述自移动设备,或者所述定位设备与所述自移动设备可拆卸的连接。
优选的,所述地图确认程序还包括,提供驱动电路指令以保持任务执行模块不执行工作任务。
优选的,所述任务执行模块包括切割组件,所述地图确认程序包括提供驱动电路指令以保持所述切割组件不执行切割工作。
优选的,所述地图确认程序还包括,在提供驱动电路指令以沿工作区域的边界移动之后,提供驱动电路指令以在边界限定的工作区域内移动。
优选的,所述自动工作系统包括报警单元,被配置为输出指示工作区域异常状况的报警信号。
优选的,所述自动工作系统包括环境传感器,至少部分安装于所述自移动设备,用于当自移动设备在工作区域内移动时,检测工作区域异常状况;所述控制模块通过监测环境传感器的输出,控制所述报警单元输出报警信号。
优选的,所述地图确认程序还包括,接收来自用户的控制信号,根据所述控制信号提供驱动电路指令以控制移动方式。
优选的,所述控制信号包括停止移动信号,所述地图确认程序包括接收来自用户的停止移动信号,根据所述停止移动信号提供驱动电路指令以控制停止移动。
优选的,所述地图确认程序还包括,接收来自用户的地图修改信号,以修改所述工作区域地图。
优选的,包括通信模块,与用户的智能终端通信,用于接收来自用户的确认信号。
一种自动工作系统的控制方法,所述自动工作系统包括自移动设备和定位设备;所述自移动设备包括移动模块和任务执行模块;所述定位设备被配置为检测所述自移动设备的当前位置;所述控制方法包括步骤:存储工作区域地图;控制进入地图确认模式,地图确认模式下,通过监测自移动设备的当前位置,基于所述工作区域地图控制移动模块带动自移动设备沿工作区域的边界移动;接收来自用户的确认信号;仅在接收到来自用户的确认信号后,控制进入工作模式;工作模式下,通过监测自移动设备的当前位置,控制移动模块带动自移动设备在地图限定的工作区域内移动,并控制任务执行模块执行工作任务。
优选的,所述定位设备包括卫星定位设备。
优选的,所述卫星定位设备包括差分卫星定位设备。
优选的,所述差分卫星定位设备包括RTK-GPS定位设备。
优选的,所述定位设备固定连接于所述自移动设备,或者所述定位设备可拆卸的连接于所述自移动设备。
优选的,地图确认模式下,控制所述任务执行模块不执行工作任务。
优选的,所述任务执行模块包括切割组件,地图确认模式下,控制所述切割组件不执行切割工作。
优选的,地图确认模式下,基于所述工作区域地图控制移动模块带动自移动设备沿工作区域的边界移动之后,还包括步骤,控制移动模块带动自移动设备在边界限定的工作区域内移动。
优选的,提供报警单元,输出指示工作区域异常状况的报警信号。
优选的,提供环境传感器,至少部分安装于所述自移动设备,当自移动设备在工作区域内移动时,检测工作区域异常状况;通过监测所述环境传感器的输出,控制所述报警单元输出报警信号。
优选的,地图确认模式下,接收来自用户的控制信号,根据所述控制信号控制所述移动模块带动自移动设备改变移动方式。
优选的,所述控制信号包括停止移动信号,根据所述停止移动信号控制所述移动模块带动自移动设备停止移动。
优选的,地图确认模式下,接收来自用户的地图修改信号,根据所述地图修改信号修改所述工作区域地图。
优选的,提供通信模块,与用户的智能终端通信,用于接收来自用户的确认信号。
一种自动工作系统,包括:自移动设备,所述自移动设备包括移动模块、任务执行模块和控制模块;所述移动模块带动自移动设备移动;所述任务执行模块执行工作任务;所述控制模块与移动模块和任务执行模块电连接;所述控制模块包括存储单元,存储工作区域地图;所述控制模块控制自移动设备在所述地图限定的工作区域内移动;所述自动工作系统包括人为观察模式,人为观察模式下,所述自动工作系统在用户观察下工作;所述存储单元存储地图后,所述控制模块控制所述任务执行模块执行工作任务之前,所述控制模块控制所 述移动模块带动自移动设备移动以检查所述地图;所述控制模块控制所述移动模块带动自移动设备移动以检查所述地图时,述自动工作系统工作在人为观察模式。
优选的,所述控制模块控制所述移动模块带动自移动设备移动以检查所述地图时,控制所述移动模块带动自移动设备沿所述地图记录的边界移动。
优选的,所述控制模块控制所述移动模块带动自移动设备移动以检查所述地图时,控制所述移动模块带动自移动设备移动以覆盖地图限定的工作区域。
优选的,所述控制模块控制所述移动模块带动自移动设备移动以检查所述地图时,所述控制模块控制所述任务执行模块保持不工作状态。
优选的,所述控制模块基于用户观察的结果修改存储单元存储的地图。
优选的,所述自动工作系统包括交互模块,所述控制模块控制所述移动模块带动自移动设备移动以检查所述地图时,所述交互模块与所述控制模块电连接,用于自移动设备与用户之间的交互,所述控制模块基于所述交互模块的输出修改存储单元存储的地图。
优选的,所述交互模块包括通讯模块,用于自移动设备与用户的智能终端之间的通讯。
优选的,所述交互模块包括输入/输出设备,供用户观察或操作。
优选的,所述自移动设备包括障碍检测传感器,与所述控制模块电连接,所述控制模块控制所述移动模块带动自移动设备移动以检查所述地图时,所述障碍检测传感器用于检测所述地图限定的工作区域内的障碍,所述控制模块基于所述障碍检测传感器的检测结果修改存储单元存储的地图。
优选的,所述自移动设备包括坡度检测传感器,与所述控制模块电连接,所述控制模块控制所述移动模块带动自移动设备移动以检查所述地图时,所述坡度检测传感器用于检测所述地图限定的工作区域的坡度信息,所述控制模块基于所述坡度检测传感器的检测结果修改存储单元存储的地图。
优选的,所述自动工作系统包括定位设备,所述控制模块控制所述移动模块带动自移动设备移动以检查所述地图时,所述定位设备用于输出自移动设备的当前位置。
优选的,所述控制模块根据所述定位设备输出的自移动设备的当前位置, 以及定位设备输出的信号的可靠度,修改存储单元存储的地图。
优选的,所述控制模块控制所述移动模块带动自移动设备移动以检查修改的所述地图。
本发明还提供一种自移动设备的控制方法,所述自移动设备包括移动模块,带动自移动设备移动;任务执行模块,执行工作任务;所述自移动设备的控制方法包括步骤:记录并存储工作区域地图;存储所述地图后,控制所述任务执行模块执行工作任务之前,控制所述移动模块带动自移动设备在所述地图限定的工作区域内移动,以检查所述地图;检查所述地图时,使自移动设备在用户观察下移动。
优选的,检查所述地图的过程包括步骤,控制所述移动模块带动自移动设备沿所述地图记录的边界移动。
优选的,检查所述地图的过程包括步骤,控制所述移动模块带动自移动设备移动以覆盖所述地图限定的工作区域。
优选的,检查所述地图的过程包括步骤,定位自移动设备的当前位置,比较自移动设备的当前位置与存储的所述地图记录的位置,判断自移动设备是否位于所述地图限定的工作区域内。
优选的,检查地图时,控制所述任务执行模块保持不工作状态。
优选的,基于用户观察的结果修改所述地图。
优选的,检查所述地图的过程包括步骤,控制自移动设备与用户进行交互,基于交互的结果修改所述地图。
优选的,控制所述移动模块带动自移动设备移动以检查修改的所述地图。
本发明还提供一种自移动设备,基于工作区域地图在工作区域内自动移动,包括壳体,移动模块,任务执行模块和控制模块,所述控制模块控制所述移动模块带动所述自移动设备移动,并控制任务执行模块的工作任务执行;所述控制模块从定位设备获取自移动设备的当前位置;所述工作区域地图包含所述工作区域的一个或多个位置的位置信息;所述自移动设备包括地图确认模式,地图确认模式下,所述控制模块控制所述自移动设备基于所述工作区域地图自动移动,并控制所述任务执行模块不执行工作任务。
与现有技术相比,本发明的有益效果是:存储单元存储地图之后,控制模 块控制任务执行模块执行工作任务之前,控制模块控制移动模块带动自移动设备移动以检查地图,避免由于地图不准确导致自移动设备执行工作任务时出现安全问题。检查地图的过程在人为观察下进行,保证了对地图的检查的可靠性。检查地图的过程保持任务执行模块不工作,保证了检查过程的安全性。
本发明还提供一种能够简化割草机的使用准备,并实现快速回归的自动割草机。
一种自动割草机,包括:
工作区域识别模块,用于判断自动割草机要经过的区域是否为工作区域;
驱动模块,用于驱动自动割草机在所述工作区域内行走;
定位模块,用于接受定位信号,以取得自动割草机当前的位置的坐标或多个坐标组成的坐标区域;
地图构建与存储模块,用于判断所述坐标是否存储于工作地图中,判断为否时,将所述坐标加入所述工作地图获得更新的工作地图;
回归路径规划模块,用于接收回归指令并根据所述更新的工作地图生成回归路径,并控制自动割草机沿所述回归路径自回归前所处的位置回归至预定位置。
上述自动割草机,可开始快速工作,且利用工作过程完善工作地图,在工作结束后可以根据已经有的工作地图导航,从而实现快速回归,不需要用户提前训练自动割草机学习全部的工作区域。
优选的,所述预定位置为充电站。
优选的,所述工作区域识别模块包括草地检测模块,用以识别自动割草机要经过的区域是否为草地。
优选的,所述定位模块具有用以接收定位信号的通信模块,所述通信模块包括GPS模块、D-GPS模块、UWB模块、Zigbee模块、wifi模块、超声波接收模块、惯性导航模块、里程计、电子地图和加速度传感器中的一种或多种。
优选的,所述回归路径为:由所述工作地图中的已知坐标限定的、自回归前所处的位置至预定位置的距离最短的路径。
优选的,所述回归路径规划模块还用于记录所述工作地图中各已知坐标被自动割草机经过的次数,所述回归路径由回归前所处的位置的坐标、预定位置 的坐标、回归前所处的位置与预定位置之间被自动割草机经过的次数最少的已知坐标限定。
还提出一种自动割草机的行走方法,包括步骤:
判断自动割草机要经过的区域是否为工作区域;
驱动自动割草机在所述工作区域内行走;
接受定位信号,以取得自动割草机当前的位置的坐标或多个坐标组成的坐标区域;
判断所述坐标是否存储于工作地图中,判断为否时,将所述坐标加入所述工作地图获得更新的工作地图;
接收回归指令,根据所述更新的工作地图生成回归路径,并控制自动割草机沿所述回归路径自回归前所处的位置回归至预定位置。
在其中一个实施例中,所述回归路径为:由所述工作地图中的已知坐标限定的、自回归前所处的位置至预定位置的距离最短的路径。
优选的,所述接收回归指令,根据所述更新的工作地图生成回归路径,并控制自动割草机沿所述回归路径自回归前所处的位置回归至预定位置的步骤包括:
记录所述工作地图中各已知坐标被自动割草机经过的次数;
根据回归前所处的位置的坐标、预定位置的坐标、回归前所处的位置与预定位置之间被自动割草机经过的次数最少的已知坐标生成所述回归路径。
优选的,所述坐标的坐标原点为所述预定位置。
附图说明
以上所述的本发明的目的、技术方案以及有益效果可以通过下面附图实现:
图1为本发明的第一实施例的自动工作系统示意图。
图2为本发明的第一实施例的自动割草机的结构示意图。
图3为本发明的第一实施例的工作区域的地图示意图。
图4为本发明的第一实施例的自动工作系统检查地图的流程图。
图5为本发明的第六实施例的自动割草机的结构框图。
图6为自动割草机第1次工作时构建工作地图的示意图。
图7为自动割草机基于图6所构建的工作地图回归的示意图。
图8为自动割草机第2次工作时构建工作地图的示意图。
图9为自动割草机基于图7所更新的工作地图回归的示意图。
图10为自动割草机第N次工作时构建工作地图的示意图。
图11为自动割草机基于图10所更新的工作地图回归的示意图。
图12为一个实施例的自动割草机行走方法的流程图。
图13为本发明的第五实施例的自动工作系统结构示意图。
图14为本发明的第五实施例的自动工作系统控制方法流程图。
具体实施方式
图1为本发明的第一实施例的自动工作系统100示意图。自动工作系统包括自移动设备。本实施例中,自移动设备为自动割草机1,在其他实施例中,自移动设备也可以为自动清洁设备、自动浇灌设备、自动扫雪机等适合无人值守的设备。自动工作系统100还包括充电站2,用于为自动割草机1补给电能。
图2为本发明的第一实施例的自动割草机1的结构示意图,本实施例中,自动割草机1包括壳体3;移动模块,安装于壳体3,移动模块包括履带5,由驱动马达驱动以带动自动割草机1移动;任务执行模块,安装于壳体3底部,包括切割组件7,执行割草工作。自动割草机1还包括能源模块,能源模块包括电池包,为自动割草机1的移动和工作提供能量。自动割草机1还包括控制模块,与移动模块、任务执行模块以及能源模块电连接,控制移动模块带动自动割草机1移动,并控制任务执行模块执行工作任务。本实施例中,控制模块包括存储单元,存储工作区域的地图。
如背景技术中所述,建立地图的方法有多种,本实施例中,建立地图的方法为,以充电站2为原点建立空间坐标系,利用定位设备记录工作区域的位置坐标,对工作区域的位置坐标进行处理,生成工作区域的地图。工作区域地图包含工作区域的一个或多个位置的位置信息。在其他实施例中,也可以通过用户在电子地图上手动划定工作区域来获取工作区域地图。
参考图1,本实施例中,自动工作系统包括定位设备,定位设备包括卫星定位设备,属于卫星导航系统,卫星导航系统利用全球定位系统(GPS)进行导航。当然,在其他实施例中,卫星导航系统也可以利用伽利略卫星导航系统、或北斗卫星导航系统等进行导航。本实施例中,卫星定位设备包括移动站15, 移动站15可随自动割草机1移动,输出自动割草机的当前位置。本实施例中,卫星导航系统还包括基站17,基站17固定设置,优选的,基站17设置在充电站2上,基站17与移动站15无线通讯,基站17向移动站15发送定位修正信号,实现差分GPS(DGPS)定位。本实施例中,移动站15可拆卸的安装于自动割草机1的壳体3。移动站15从自动割草机1上拆下时,可以独立工作,记录自身移动所经过的位置坐标。移动站15安装在自动割草机1的壳体3上时,与自动割草机1的控制模块电连接,输出自动割草机1的当前位置坐标。本实施例中,记录地图时,将移动站15从自动割草机1上拆下,由用户手持移动来记录工作区域的边界、障碍等位置坐标。本实施例中,定位设备还包括惯性导航设备,惯性导航设备包括陀螺仪、加速计等,惯性导航设备可根据自动割草机1的初始位置,输出自动割草机1的当前位置坐标,惯性导航设备能够与卫星定位设备配合,在卫星信号差时,起到辅助导航的作用。
本实施例中,工作区域的地图包括工作区域的边界信息、工作区域内的障碍信息、工作区域的坡度信息、工作区域接收到的卫星信号的强弱信息等。如图1所示的工作区域,草坪与非草坪区域之间形成自然边界,即实际工作区域的边界200,工作区域中存在障碍9,斜坡11,还存在卫星信号弱的区域13。障碍9可以是树木、凹坑等。斜坡11为坡度超过阈值的工作区域,自动割草机在斜坡上工作时可以通过改变移动方式来提高稳定性和工作效率。卫星信号弱的区域13可能是被房屋遮挡的区域、植被阴影下的区域等,自动割草机1在这些区域不能接收到良好的卫星信号,卫星定位设备不能输出准确的位置信号。本实施例中,虽然同时采用了惯性导航设备进行导航,但是自动割草机1长时间逗留在卫星信号弱的区域时,惯性导航设备将由于误差累积也不能输出准确的位置信号。因此,自动割草机1在卫星信号弱的区域内移动时,优选的采用与在卫星信号良好的区域内不同的移动方式移动。
图3为以显示设备作为载体的工作区域的地图示意图。对比图1和图3,地图记录的工作区域相对于实际工作区域可能存在偏差。例如,实际工作区域的右侧边界包括向工作区域的中心凹陷的部分,而地图记录的边界300位置未准确反映该凹陷的部分,也就是说,地图记录的边界300位置不准确。地图记录的边界300位置不准确,将导致自动割草机1在边界附近的区域移动时,移 动至实际工作区域的边界200以外的区域,导致安全性问题。又例如,实际工作区域包括障碍11,具体的,障碍11可能为凹坑,而地图未记录该凹坑位置,这将导致自动割草机1移动至该凹坑位置时跌落,导致安全性问题。
本实施例中,存储单元存储地图后,控制模块控制自动割草机1执行割草工作之前,控制模块控制移动模块带动自动割草机1在地图限定的工作区域内移动,以检查地图是否准确。本实施例中,自动工作系统包括人为观察模式,人为观察模式下,自动工作系统在用户观察下工作。控制模块控制移动模块带动自动割草机1移动以检查地图时,自动工作系统工作在人为观察模式,以保证对地图的检查的可靠性。自动工作系统包括交互模块,人为观察模式下,交互模块提供自动割草机1与用户的交互。本实施例中,交互模块包括通讯模块,用于自动割草机1与用户的智能终端之间的通讯。
本实施例中,自动割草机1检查地图的过程中,控制模块控制自动割草机1的切割组件7保持不工作状态,因此,即使由于记录的地图不准确,自动割草机移动1至实际工作区域的边界外或凹坑等不安全区域,也不会导致切割组件7伤人或伤其他物体,保证了检查过程的安全性。将上述过程称为自动割草机的地图确认模式,即地图确认模式下,控制模块控制自动割草机基于工作区域地图移动,并控制任务执行模块不执行工作任务。
本实施例中,自动割草机1检查地图的过程中,移动站15安装于自动割草机1的壳体3,与自动割草机1的控制模块电连接,输出自动割草机1的当前位置。控制模块比较自动割草机1的当前位置与存储的地图中记录的位置,判断自动割草机1是否在地图限定的工作区域内移动,若控制模块判断自动割草机1移动至地图限定的工作区域以外的位置,则控制自动割草机1改变移动方式,向工作区域内移动。
本实施例中,自动割草机检查地图的过程包括步骤:控制模块控制移动模块带动自动割草机沿地图记录的边界移动,以检查地图记录的边界是否准确。
本实施例中,控制模块控制移动模块带动自动割草机沿地图记录的边界移动时,用户观察自动割草机的移动,用户判断自动割草机是否沿实际工作区域的边界移动。本实施例中,控制自动割草机从充电站出发以逆时针方向沿地图记录的边界移动,当自动割草机移动至工作区域右侧边界上的A点时,由于地 图记录的边界相对于实际工作区域的边界向右侧偏移,自动割草机沿地图记录的边界移动将逐渐偏离实际工作区域的边界。实际工作区域的边界的右侧可能为马路等非草坪区域,自动割草机在执行割草工作时移动至该区域可能导致安全性问题。此时,用户通过观察自动割草机的移动发现自动割草机已偏离实际工作区域的边界。用户可使自动割草机停止移动。本实施例中,用户观察自动割草机检查地图的过程,保证了对地图的检查结果的可靠性。
在自动割草机检查地图的过程中,当用户发现地图不准确时,将采取修正地图的措施。本实施例中,自动工作系统包括通讯模块,通讯模块可集成于移动站,也可独立设置于自动割草机上,与控制模块电性连接。自动割草机检查地图时,通讯模块用于自动割草机与用户的智能终端进行无线通讯。具体的,自动割草机检查地图时,通讯模块将自动割草机的当前位置信息发送给用户的智能终端,用户的智能终端存储并能够显示工作区域地图,同时显示自动割草机的当前位置。自动割草机检查地图时,用户观察自动割草机的移动,当自动割草机偏离实际工作区域的边界移动时,用户记录自动割草机开始偏离实际工作区域的边界移动的位置A点。由于自动割草机的切割组件不工作,因此可以允许自动割草机继续移动,直至回到实际工作区域的边界上。用户记录自动割草机回到实际工作区域的边界移动的位置B点。用户获得地图记录的边界偏离实际工作区域的边界的部分的起点位置A点和终点位置B点后,控制自动割草机停止移动,然后使用定位设备重新记录包含A点至B点部分的实际工作区域的边界的位置坐标,使用重新记录的边界位置坐标来修正地图。
本实施例中,用户采取修正地图的措施后,控制模块将修改存储单元存储的地图,并再次控制移动模块带动自动割草机移动来检查修改后的地图是否正确。具体的,使自动割草机回到地图修正的起点位置,或地图的边界上位于地图修正的起点位置以前的位置,令自动割草机沿修正的地图的边界移动。此时,仍然控制切割组件保持不工作状态,以保证检查过程的安全性。同样的,用户观察自动割草机的移动,判断自动割草机是否沿实际工作区域的边界移动,若自动割草机移动至地图修正的终点位置的过程中,始终沿实际工作区域的边界移动,说明对地图的修正正确,若自动割草机再次偏离实际工作区域的边界移动,说明对地图的修正不正确,需要再次采取修正地图的措施。本实施例中, 控制移动模块带动自动割草机移动以检查修正的地图,进一步保证了对地图的检查的可靠性。
本发明的第二实施例中,自动割草机检查地图的方法与第一实施例中的基本相同,差异在于,修正地图的措施与第一实施例中的不同。具体的,用户获得地图的边界偏离实际工作区域的边界的部分的起点位置A点和终点位置B点后,用户的智能终端将在显示的地图上标记该起点位置A点和终点位置B点,用户通过在智能终端的显示屏上,手动连接起点位置A点与终点位置B点,来修改地图。具体的,用户可以根据实际边界的形状特征决定起点位置A点与终点位置B点之间的边界的形状,也可以根据修正前的地图记录的边界相对于实际工作区域的边界的偏移情况,决定起点位置A点与终点位置B点之间的边界相对于修正前的地图记录的边界的偏移程度。同样的,用户采取修正地图的措施后,控制模块将修改存储单元存储的地图,并再次控制移动模块带动自动割草机移动来检查修改后的地图是否正确。
本发明的第三实施例中,自动割草机检查地图的方法与第一实施例中的基本相同,差异在于,修正地图的措施与第一实施例中的不同。具体的,当用户判断自动割草机偏离实际工作区域的边界移动时,控制自动割草机停止移动,使自动割草机回到开始偏离实际工作区域的边界移动的位置A点,或A点以前的位置,并记录该起点位置。用户通过智能终端遥控自动割草机移动,使自动割草机沿实际工作区域的边界移动,自动割草机沿实际工作区域的边界移动的过程中,记录自身移动所经过的位置的坐标。用户观察智能终端显示的地图上的自动割草机的当前位置,判断自动割草机的当前位置是否已回到修正前的地图记录的边界上,若自动割草机的当前位置已回到修正前的地图记录的边界上,则停止对自动割草机的遥控,并记录该终点位置。使用自动割草机在遥控模式下记录的位置坐标来修正地图。同样的,用户采取修正地图的措施后,控制模块将修改存储单元存储的地图,并再次控制移动模块带动自动割草机移动来检查修改后的地图是否正确。
本发明的第一实施例中,用户采取修正地图的措施后,若对地图的修正正确,则控制自动割草机继续沿地图记录的边界移动,直至完成沿地图的边界移动一周。若对地图的修正不正确,则再次采取修正地图的措施。再次采取修正 地图的措施时,也可选择使用第二实施例或第三实施例中修正地图的方法。
本发明的第一实施例中,地图记录的边界相对于实际工作区域的边界向外偏离,在其他实施例中,地图记录的边界也可能相对于实际工作区域的边界向内偏离,在这种情况下,同样可以采用上述方法对地图记录的边界进行修正,使得地图记录的边界与实际工作区域的边界一致,避免靠近实际工作区域的边界的区域不能被切割到的问题,使草坪能够达到理想的切割效果。
本发明的第一实施例中,自动割草机检查地图的过程还包括步骤:控制模块控制移动模块带动自动割草机移动以覆盖地图限定的工作区域,检查地图记录的工作区域内的障碍信息、或工作区域的坡度信息、或工作区域接收到的卫星信号的强弱信息是否准确,尤其的,检查实际工作区域中是否存在地图未记录的不安全区域。检查自动割草机是否发生受困、跌落、碰撞、停滞、打滑、离开工作区域等异常情况。
地图限定的工作区域,包括地图记录的边界位置以内的工作区域,若地图中的某区域被标记为不安全区域,例如标记为凹坑,则自动割草机不被允许进入该区域,地图限定的工作区域已排除了该不安全区域。
自动割草机覆盖地图限定的工作区域时,可以随机路径移动,也可以预设路径移动,其中,预设路径根据地图的边界形状,由程序自动生成。本实施例中,令自动割草机以预设路径覆盖地图限定的工作区域。
本实施例中,自动割草机包括环境传感器,具体的,自动割草机包括障碍检测传感器,检测自动割草机移动方向上的障碍。具体的,障碍检测传感器包括碰撞检测传感器,当碰撞检测传感器检测到自动割草机发生碰撞时,控制模块判断自动割草机移动方向上存在障碍。障碍检测传感器还可以包括超声波传感器等非接触式传感器,代替碰撞检测传感器检测自动割草机移动方向上的障碍。障碍检测传感器还可以包括悬崖检测传感器,检测自动割草机移动方向上是否存在凹坑等。当然,也可以使用摄像头来检测自动割草机移动方向上的障碍。当障碍检测传感器检测到自动割草机移动方向上存在障碍,控制模块获取检测到的障碍所在的位置,比较检测到的障碍所在的位置与存储的地图中标记为障碍的位置,若检测到的障碍所在的位置不符合存储的地图中标记为障碍的位置,则判断检测到的障碍为未知障碍,控制模块控制通讯模块向用户的智能 终端发送信息,提示用户修正地图。当然,自动割草机也可以通过加速计、抬起传感器等障碍检测传感器判断自身是否发生受困、倾覆等事故,若判断自身发生受困、倾覆等事故则通知用户,促使用户修正地图,在地图上标记这些不安全区域,以防止自动割草机执行割草工作时进入这些不安全区域。
本实施例中,自动割草机还包括坡度检测传感器,检测工作区域的坡度。具体的,坡度检测传感器检测自动割草机的倾角,从而间接获得自动割草机所在位置的工作区域的坡度,控制模块判断工作区域的坡度是否超过阈值,若超过阈值,则判断当前位置的工作区域为斜坡。控制模块比较检测到的斜坡的位置与存储的地图中标记为斜坡的位置,若检测到的斜坡所在的位置不符合存储的地图中标记为斜坡的位置,则控制通讯模块向用户的智能终端发送信息,提示用户修正地图。
本实施例中,控制模块根据卫星定位设备输出的定位信号的可靠度,判断工作区域的卫星信号的强弱。例如,当卫星定位设备只能接收到三颗以下卫星的信号时,控制模块判断当前位置的卫星信号弱。控制模块比较检测到的卫星信号弱的位置与存储的地图中标记为卫星信号弱的位置,若检测到的卫星信号弱的位置不符合存储的地图中标记为卫星信号弱的位置,则控制通讯模块向用户的智能终端发送信息,提示用户修正地图。
用户通过智能终端接收到自动割草机发送的修正地图的提示信息后,可控制自动割草机停止移动,用户观察自动割草机所在位置,判断自动割草机的检测是否正确。用户确认自动割草机的检测正确后,采取修正地图的措施,修正地图的措施与修正地图记录的边界时采取的措施相似。用户采取修正地图的措施后,控制模块修改存储单元存储的地图,并控制自动割草机移动以检查修正的地图。具体的,本实施例中,使自动割草机回到检测到障碍、或斜坡、或卫星信号弱的位置,或该位置以前的位置,继续覆盖地图限定的工作区域。自动割草机覆盖地图限定的工作区域的过程中,若再次发现未知的障碍、或斜坡、或卫星信号弱的位置,则再次通知用户,促使用户采取修正地图的措施,直至自动割草机完成覆盖地图限定的工作区域。
本实施例中,自动割草机覆盖地图限定的工作区域以检查地图的过程中,控制切割组件保持不工作状态,因此,即使由于记录的地图不准确,也可以避 免切割组件伤人或伤其他物体,从而保证了自动工作系统的安全性。例如,自动割草机进入不安全区域而倾覆时,避免了人靠近自动割草机时的安全问题,又如,自动割草机进入非草坪区域时,避免了割切组件的工作对非草坪区域中的物体的伤害。
本实施例中,自动割草机在覆盖过程中检测到未知的障碍、或斜坡、或卫星信号弱的区域时,通知用户,通过用户来判断自动割草机的检测是否正确,从而保证了对地图的检查的可靠性。
本发明的第四实施例中,自动割草机检查地图的方法与第一实施例中的基本相同,差异在于,自动割草机覆盖地图限定的工作区域的过程中,用户通过观察自动割草机的移动和状态直接判断地图是否准确。具体的,自动割草机覆盖地图限定的工作区域的过程中,用户通过观察,判断自动割草机是否遇到未知的障碍、或斜坡、或卫星信号弱的区域;还可以判断自动割草机的移动方式是否合理;还可以判断自动割草机是否沿程序生成的预设路径移动。若用户判断自动割草机遇到未知的障碍、或斜坡、或卫星信号弱的区域,采取修正地图的措施,与第一实施例中的方法类似。若用户判断自动割草机的移动方式不合理,或者判断自动割草机偏离预设路径移动,则可以控制自动割草机停止移动,在智能终端上手动设置移动方式,或者基于智能终端显示的预设路径手动修改路径,或者遥控自动割草机移动来修改路径,等等。用户的观察保证了对地图的检查的可靠性。
本发明的第一实施例的自动工作系统,在存储单元存储地图之后,在控制模块控制切割组件执行割草工作之前,控制模块控制移动模块带动自动割草机在地图限定的工作区域内移动,以检查地图。在完成了对地图的检查之后,自动割草机进入工作模式,控制模块再控制自动割草机在地图限定的工作区域内移动并执行割草工作。本实施例中,由于在控制自动割草机执行割草工作之前,实施了检查地图的步骤,因此保证了存储单元存储的地图的准确性,防止了由于地图不准确导致的自动割草机在工作过程中引起的安全事故,因而,本实施例中的自动工作系统是一种安全的自动工作系统。本实施例中,检查地图的步骤是在控制切割组件保持关闭的情况下进行的,保证了检查地图的步骤的安全性。本实施例中,对地图的检查是在用户的观察下实施的,保证了对地图的检 查的可靠性。因此,本实施例中的检查地图的方法是一种安全、可靠的方法,这也进一步保证了本实施例中的自动工作系统的安全性。
本发明的第一实施例的自动工作系统检查地图的流程如图4所示,包括步骤:
S100:记录并存储地图。
S101:启动自动割草机,关闭切割组件。
S102:控制自动割草机沿地图记录的边界移动,智能终端显示自动割草机在地图上的位置。
S103:用户观察自动割草机的移动,判断自动割草机是否沿实际工作区域的边界移动;若自动割草机沿实际工作区域的边界移动,进入步骤S200;若自动割草机未沿实际工作区域的边界移动,进入步骤S104。
S104:用户采取修正地图的措施。
S105:使自动割草机回到修正的起点以前的位置,沿修正的地图记录的边界移动;回到步骤S103。
S200:控制自动割草机沿地图记录的边界移动一周,确认地图,生成预设路径。
S201:控制自动割草机沿预设路径移动,保持切割组件关闭。
S202:判断自动割草机是否遇未知的障碍、或斜坡、或卫星信号弱的区域,若是,进入步骤S203;若否,进入步骤S204。
S203:用户采取修正地图的措施。
S204:控制自动割草机覆盖工作区域,确认地图。
本发明的第一实施例中,定位设备记录的位置坐标,可以通过移动站与自动割草机的电性连接,传输给自动割草机的控制模块,还可以无线传输给用户的智能终端。存储单元存储的地图可以由控制模块生成,也可以由定位设备生成,也可以由智能终端生成。预设路径可以由控制模块中的程序生成,或定位设备中的程序生成,或智能终端中的程序生成。本实施例中,预设路径根据地图的修正而更新。
本实施例中,自动割草机检查地图的过程中,自动割草机通过通讯模块实现与用户的智能终端之间的通信,包括向智能终端发送当前位置信息,接收智 能终端发送的停止移动的指令,接收智能终端发送的修正地图的信息等等。
在其他实施例中,自动工作系统还可以包括输入/输出设备,输入/输出设备可以集成于定位设备的移动站,也可以独立安装于自动割草机,与控制模块电连接。输入/输出设备可以包括触摸屏。自动割草机检查地图时,触摸屏用于显示地图、以及自动割草机的当前位置。用户观察自动割草机的移动时,可以同时观察触摸屏上自动割草机的当前位置。触摸屏还可以供用户操作,来修正地图。因此,触摸屏可以替代通讯模块作为实现自动割草机与用户交互的交互模块。
本发明的第一实施例中,用户也可以通过按压自动割草机上的停止按钮来控制自动割草机停止移动。
本实施例中,自动割草机还可以包括警示单元,自动割草机覆盖地图限定的工作区域的过程中,发现未知的障碍、或斜坡、或卫星信号弱的区域时,警示单元发出警示信号。
本实施例中,实际工作区域的边界既可以指草坪与非草坪之间形成的自然边界,也可以由用户根据需要来界定。
本实施例中,自动割草机覆盖地图限定的工作区域的过程中,控制模块判断未知障碍为树木等自动割草机容易避开的障碍时,也可以不通知用户,自行记录障碍位置并修正地图。
本实施例中,自动割草机覆盖地图限定的工作区域的过程中,控制模块还可以判断并记录当前位置的定位精度方差、解算状态,包括差分固定解、浮点解、伪距解、单点解还是无卫星,惯导模式等。
本发明的其他实施例中,工作区域可能包括两个以上的分隔区域以及连接分隔区域的通道,则工作区域的地图将包括工作区域的通道信息。自动割草机检查工作区域的地图的步骤,包括沿工作区域的通道移动的步骤。
本发明的第五实施例中,自动工作系统包括自动割草机和定位设备。其中,自动割草机包括移动模块和任务执行模块,以及连接至移动模块和任务执行模块的驱动电路,驱动电路驱动移动模块带动自动割草机移动,并驱动任务执行模块执行工作任务。具体的,任务执行模块包括切割组件,驱动电路驱动切割组件执行切割工作。其中,定位设备被配置为检测自动割草机的当前位置。本 实施例中自动割草机与定位设备的结构与第一实施例基本相同,差异在于,本实施例中,自动工作系统包括:存储单元,存储工作区域地图,还存储地图确认程序,地图确认程序包括,提供驱动电路指令以沿工作区域的边界移动,接收来自用户的确认信号以完成地图确认程序;存储单元还存储工作程序,提供驱动电路指令以在地图限定的工作区域内移动并执行切割工作。自动工作系统还包括控制模块,控制模块通过监测定位设备的输出,执行上述地图确认程序,并在上述地图确认程序完成后执行上述工作程序。具体的,自动工作系统响应于用户的指令进入地图确认程序,控制模块接收驱动电路指令,控制移动模块带动自动割草机沿工作区域的边界移动,具体的,基于存储单元存储的工作区域地图(包含工作区域边界位置信息)、以及定位设备输出的自动割草机的当前位置,控制自动割草机沿工作区域的边界移动,控制方法与第一实施例中类似。当自动工作系统接收到来自用户的确认信号时,将当前工作区域地图标记为正式版并存储,完成地图确认程序。具体的,控制模块执行地图确认程序的过程,即用户通过观察自动割草机基于工作区域地图沿边界移动,确认当前工作区域地图的边界是否与实际工作区域的边界相符的过程。必须在地图确认程序完成后,自动工作系统才能够执行工作程序,即控制模块接收驱动电路指令,控制移动模块带动自动割草机移动,并控制切割模块执行切割工作。具体的,控制模块基于经确认的(被标记为正式版并存储的)工作区域地图、以及定位设备输出的自动割草机的当前位置,控制自动割草机在工作区域内自动移动并执行切割工作。
本实施例中,自动工作系统在执行工作程序之前必须先执行地图确认程序,保证了所存储的工作区域地图的准确性,从而保证了自动工作系统基于工作区域地图工作过程的安全性。上述地图确认程序须通过接收来自用户的确认信号来完成,保证了地图确认的可靠性。
本实施例中,工作区域的边界包括工作区域的外边界和内边界,内边界包括障碍物、花坛、水池等的外围形成的边界,自动割草机被禁止进入内边界围成的区域以内工作。
本实施例中,地图确认程序还包括,提供驱动电路指令以保持切割组件不执行切割工作。具体的,自动工作系统进入地图确认程序后,控制模块接收驱 动电路指令,控制切割组件不工作。也就是说,控制模块控制移动模块带动自动割草机沿工作区域边界移动以确认边界是否准确的过程中,切割组件处于非工作状态。这样保证了地图确认过程的安全性,效果与第一实施例中类似,不再赘述。
本实施例中,地图确认程序还包括,在提供驱动电路指令以沿工作区域的边界移动之后,提供驱动电路指令以在边界限定的工作区域内移动,包括外边界和内边界限定的工作区域,内边界限定的工作区域指内边界围成的区域以外的工作区域。具体的,控制模块接收驱动电路指令,控制移动模块带动自动割草机在边界限定的工作区域内移动,具体的,控制模块基于已确认边界的工作区域地图、及定位设备输出的自动割草机的当前位置,控制移动模块带动自动割草机在边界限定的工作区域内移动。本实施例中,地图确认程序可以分为两个阶段,第一阶段,确认工作区域地图的边界是否准确、是否能保证系统工作的安全性,第二阶段,基于经确认的工作区域地图边界,确认边界限定的工作区域地图是否准确、是否能保证系统工作的安全性。两个阶段分别接收来自用户的确认信号,即先接收来自用户的确认工作区域地图的边界准确的边界确认信号,在接收到来自用户的边界确认信号之后,进入第二阶段确认边界限定的工作区域地图是否准确,在接收到来自用户的确认边界限定的工作区域地图准确的地图确认信号后,才是完成了地图确认程序。本实施例中,必须在先确认了工作区域地图的边界之后,再确认边界限定的工作区域,以保证自动割草机的移动不会越过实际工作区域的边界,保证安全性,同时保证自动割草机能够覆盖整个工作区域,避免遗漏未切割区域。本实施例中,确认边界限定的工作区域的过程与第一实施例类似。
本实施例中,自动工作系统执行地图确认程序过程中,可以通过用户跟随自动割草机以确认地图是否准确,也可以通过使自动割草机在遇到异常状况时报警,以提示用户确认地图是否准确,尤其适用于确认边界限定的工作区域是否准确的过程。工作区域异常状况包括令自动割草机碰撞、受困、打滑、跌落等状况。本实施例中,自动工作系统包括报警单元,输出指示工作区域异常状况的报警信号。具体的,报警单元可以是安装在自动割草机壳体上的扬声器、显示器等,也可以是通信模块,向用户终端发送远程报警信号。本实施例中, 自动割草机还包括环境传感器,至少部分安装于自动割草机,用于当自动割草机在工作区域内移动(包括沿边界移动)时,检测工作区域异常状况。控制模块通过监测环境传感器的输出,控制报警单元输出报警信号。环境传感器包括摄像头、电容草地识别传感器、超声波传感器、光电测距传感器、加速计以及定位设备本身,等等。环境传感器的应用与第一实施例中类似。
本实施例中,地图确认程序还包括,接收来自用户的控制信号,根据控制信号提供驱动电路指令以控制移动方式。例如,自动工作系统执行地图确认程序过程中,自动割草机沿边界移动偏离了实际工作区域的边界,地图确认程序接收到用户发出的停止移动信号,根据停止移动信号提供驱动电路指令以控制停止移动。控制模块接收到驱动电路指令,控制自动割草机停止移动。地图确认程序在用户的控制下进行,保证了地图确认过程的安全性。
本实施例中,地图确认程序还包括,接收来自用户的地图修改信号,以修改工作区域地图。当用户判断当前工作区域地图可能不准确,需要修改工作区域地图时,将采取地图修正措施,地图修正措施与前述实施例中类似,不再赘述。地图确认程序接收来自用户的地图修改信号,使用地图修正信息修正已存储的工作区域地图,或者使用修正后的工作区域地图代替已存储的工作区域地图。当地图确认程序接收到来自用户的确认信号后,将当前工作区域地图标记为正式版(相对于修改版)并存储。自动工作系统在工作程序中将基于被标记为正式版的工作区域地图自动移动并执行切割工作。
本实施例中,自动工作系统可以通过通信模块接收来自用户的确认信号,通信模块用于与用户的智能终端或远程控制器通信,或者通过本地输入接收来自用户的确认信号,等等。其中,用户可以通过加载于智能终端的APP来观察或控制自动割草机的移动,APP接收用户的确认信号,将确认信号传输给自动工作系统。
本实施例中,定位设备包括卫星定位设备,接收卫星定位数据,或者beacon定位设备,与布置在工作区域内/外的beacon通信以获取定位数据,beacon定位设备包括UWB定位设备或超声波定位设备。定位设备可以固定连接于自动割草机,或者定位设备与自动割草机可拆卸的连接。其中,卫星定位设备包括差分卫星定位设备,差分卫星定位设备包括RTK-GPS定位设备。RTK-GPS定位设 备利用载波相位差分技术,其构成与第一实施例中的定位设备类似,其导航原理可参考第一实施例中卫星导航系统。
本实施例中,定位设备与自动割草机可拆卸的连接,自动工作系统执行地图确认程序和工作程序的过程中,定位设备安装于自动割草机,输出自动割草机的当前位置。参考图13,本实施例中,定位设备包括壳体;安装于壳体的卫星信号接收器,用于提供定位数据,以及第一控制模块和第一存储单元。自动割草机包括第二控制模块和第二存储单元,安装于自动割草机的壳体。本实施例中,自动工作系统的控制模块包括第一控制模块和第二控制模块,存储单元包括第一存储单元和第二存储单元。本实施例中,工作区域地图、地图确认程序以及工作程序可以存储在第一存储单元中,也可以存储在第二存储单元中,或者部分存储在第一存储单元中,部分存储在第二存储单元中。地图确认程序和工作程序可以由第一控制模块执行,也可以由第二控制模块执行,或者部分由第一控制模块执行,部分由第二控制模块执行。优选的,本实施例中,卫星信号接收器提供定位数据,第一存储单元存储工作区域地图,第一控制模块比较自动割草机的当前位置和工作区域地图,输出控制指令给自动割草机的第二控制模块,第二控制模块接收第一控制模块输出的控制指令,生成驱动信号,控制驱动电路驱动移动模块带动自动割草机移动。第一控制模块接收来自用户的确认信号,具体的,接收APP传输的用户确认信号。第二控制模块还用于控制驱动电路驱动切割组件执行切割工作,采集环境传感器的检测数据、控制报警单元输出报警信号等。
本实施例中,存储单元可以包括在控制模块中,也可以独立于控制模块。
本实施例中,驱动电路包括第一驱动电路,驱动移动模块带动自动割草机移动,具体的,移动模块包括驱动马达,第一驱动电路驱动该驱动马达使得驱动马达带动自动割草机移动。驱动电路包括第二驱动电路,驱动切割组件执行切割工作,具体的,切割组件包括切割马达,第二驱动电路驱动该切割马达使得切割马达带动刀盘和刀片运动。
图14所示为对应于本实施例的自动工作系统的控制方法流程图,如图14所示,该控制方法包括步骤:
S300:存储工作区域地图;
S301:控制进入地图确认模式;
S303:控制切割组件不执行切割工作;
S305:通过监测自动割草机的当前位置,基于工作区域地图控制移动模块带动自动割草机沿工作区域的边界移动;
S307:判断工作区域地图是否准确,若准确,进入步骤S313;若不准确,进入步骤S309;
S309:接收来自用户的停止移动信号,根据停止移动信号控制移动模块带动自动割草机停止移动;
S311:接收来自用户的地图修改信号,根据地图修改信号修改工作区域地图;
S313:接收来自用户的边界确认信号;
S315:通过监测自动割草机的当前位置,控制移动模块带动自动割草机在边界限定的工作区域内移动;
S317:判断工作区域地图是否准确,若准确,进入步骤S323;若不准确,进入步骤S319;
S319:接收来自用户的停止移动信号,根据停止移动信号控制移动模块带动自动割草机停止移动;
S321:接收来自用户的地图修改信号,根据地图修改信号修改工作区域地图;
S323:接收来自用户的地图确认信号,将当前工作区域地图标记为正式版;
S325:控制进入工作模式;
S327:控制移动模块带动自动割草机移动,并控制切割组件执行切割工作。
本实施例中,仅在接收到来自用户的确认信号后,控制进入工作模式,保证了自动工作系统基于地图工作的安全性。当然,在地图确认模式后,也可以不进入工作模式,完成地图确认为进入工作模式的必要条件,而非充分条件。
本发明还提出了另外一种实施例,请参考图5,本发明的第六实施例的自动割草机1,包括工作区域识别模块101、驱动模块102、定位模块103、地图构建与存储模块104及回归路径规划模块105。可以理解的是,地图构建与存储模块104的功能也可以由上面实施例中的存储单元和控制模块完成。
工作区域识别模块101,用于判断自动割草机1要经过的区域是否为工作区域。就割草机而言,工作区域识别模块101包括草地检测模块,用以识别自动割草机要经过的区域是否为草地。例如,可以通过摄像头拍摄图像,通过识别拍摄到的图像的纹理来识别是否为草地。当工作区域识别模块101识别前方为障碍物9(如灌木丛)时,自动割草机1通过转向、后退等方式避开该障碍物9。
驱动模块102用以驱动自动割草机1在工作区域内行走。驱动模块102包括动力机构、传动机构、行走机构等。其中,对于自动割草机而言,动力机构一般包括电机和给电机提供能源的电池包。电池包与电机一同安装在自动割草机的机架上。这样,自动割草机不依赖于外部电源,能够更好地适应在工作区域内巡航的需要。传动机构一般为齿轮传动机构,用以将电机输出的旋转动力经过速比转换及/或换向后传递给行走机构,从而驱动自动割草机1行走。行走机构的行走元件可以是行走轮,也可以是行走履带。行走元件通常采用柔性材料制造或至少包含部分柔性材料,以减轻对草地的压力。
定位模块103用以接受定位信号,以取得自动割草机当前的位置的坐标或多个坐标组成的坐标区域。
地图构建与存储模块104,用于判断获取到的坐标是否存储于工作地图中,判断为否时,将坐标加入工作地图获得更新的工作地图。
自动割草机1行走过程中,定位模块103获取到行走路径中各处的坐标或多个坐标后,地图构建与存储模块104就判断这些判断是否已经存储于工作地图中,若判断结果为是,则说明自动割草机1当前所处位置是已经探明的工作区域,若判断结果为否,则说明自动割草机1当前所处位置是未探明的工作区域,此区域需要加入工作地图中,以完善工作地图,利于后续割草工作及回归。
定位模块103具有用以接收定位信号的通信模块,所述通信模块包括GPS模块、D-GPS模块、UWB模块、Zigbee模块、wifi模块、超声波接收模块、惯性导航模块、里程计、电子地图和加速度传感器中的一种或多种。换言之,定位的方式可以有多种,只要能够取得自动割草机1行走过程中所经过的各处的坐标即可。
坐标可以是卫星定位系统分配的反映物体在地球上位置的坐标值。还可以是自行构建的坐标系中的坐标值。此时,该坐标的坐标系的原点可以根据需要设置。例如,由于自动割草机1通常是从充电站2处出发、执行割草工作及现在需要充电时返回充电站。因此,该坐标系的原点可以是充电站2。
自动割草机1利用工作区域识别模块101识别未探明的工作区域,这样,自动割草机1在工作时不需要工作区域已经全部探明,换言之不需要工作地图全部完善,可以是完全没有经过探明的工作区域。自动割草机1可以快速地投入工作,不需要先学习全部的工作区域,特别是转移到在新的工作区域工作时。
另外,由于设置了定位模块103和地图构建与存储模块104,自动割草机1每一次的工作(即割草作业)过程中,均能更新工作地图,使工作地图不断地完善。这样,每一次割草作业结束后需要回归时,自动割草机1可以基于更新后的已知的工作地图设计回归路径。
回归路径规划模块105用于接收回归指令并根据更新的工作地图生成回归路径,并控制自动割草机1沿回归路径自回归前所处的位置回归至预定位置。
自动割草机1通常是返回充电站2进行充电,因此,预定位置一般为充电站。然而,预定位置也可以是其他需要位置,例如可以是需要重点割草的区域,又如,可以是方便使用者检查、检修自动割草机1的位置。
前文已叙,自动割草机1的每一次行走都能够更新已知的工作地图。回归时,可以基于该更新后的已知地图来规划回归路径。自动割草机1基于已知地图规划路径,快速回归,无需用户训练割草机学习全部工作区域。回归路径规划模块105基于已知地图来生成最优的回归路径。最优的回归路径是满足不同目的需求的路径。
例如,回归路径为:由所述工作地图中的已知坐标限定的、自回归前所处的位置至预定位置的距离最短的路径。距离最短的路径可能是直线,也可能是避开障碍物后的折线或弧线。
又例如,回归路径规划模块105还用于记录工作地图中各已知坐标被自动割草机1经过的次数。回归路径由回归前所处的位置的坐标、预定位置的坐标、回归前所处的位置与预定位置之间被自动割草机1经过的次数最少的已知坐标 限定。这样,自动割草机1回归时可以避免过度碾压某些区域。
下面结合附图6至10,简要说明上述自动割草机1的工作过程。
参图6,自动割草机1至充电站2出发,开始其第一次工作,箭头示意了自动割草机1的行走路径。在此过程中,工作地图中还没记录任何坐标,自动割草机1所经过的各处位置的坐标均被记录,构建成初始的工作地图。
参图7,自动割草机1结束第一次工作,自图7中所处的位置开始向充电站2回归。此时回归路径规划模块105生成如图中的箭头所示的折线路径,可以看到,自动割草机1不需要依原路返回,依照图7中折线路径即可实现快速回归。
参图8,自动割草机1至充电站2出发,开始其第二次工作。其中剖面线示意了第一次工作时经过的区域,实线边界界定的区域则为第二次工作时经过的区域。此过程中,自动割草机1经过的区域有部分是与第一次工作经过的区域重合,这些区域对应的坐标不需要重复记录,地图构建与存储模块104仅记录新增的坐标,使更新后的地图包含第二次工作时所走过的新的区域。
参图9,第二次工作结束后,自动割草机1自图9中所处的位置开始回归。回归路径规划模块105生成的回归路径如图9中箭头所示。可以看到,回归路径规划模块105不是按照第二次工作或第一次工作时的前进路径原路返回,而是同时有利用第一次工作时探明的区域和第二次工作时探明的区域,以生成较为快捷的回归路径。
参图10和图11,随着自动割草机1工作次数的增多,不断有新的坐标被加入到工作地图中,工作地图也越来越完善,图10和图11示意了全部工作区域全部探明的情况。回归路径规划模块105每次都可以依照新的工作地图来生成较佳的回归路径。
上述自动割草机1,可开始快速工作,且利用工作过程完善工作地图,在工作结束后可以根据已经有的工作地图导航,从而实现快速回归,不需要用户提前训练自动割草机1学习全部的工作区域。
参图12,本发明的一个实施例还提供了一种上述自动割草机1的行走方法,包括步骤:
S110、判断自动割草机要经过的区域是否为工作区域。自动割草机1工作时,依靠工作区域识别模块101探明待行走的区域,不依赖于工作地图的完善与否,用户不需要提前训练割草机,提高了使用的便捷性。
S120、驱动自动割草机在所述工作区域内行走。动力机构驱动行走机构,使自动割草机前进。并且自动割草机能够自动地避开障碍物,只在工作区域内行走。
S130、接受定位信号,以取得自动割草机当前的位置的坐标或多个坐标组成的坐标区域。利用GPS、D-GPS等多种方式实现定位,取得行走路径中的各处位置的坐标。
S140、判断所述坐标是否存储于工作地图中,判断为否时,将所述坐标加入所述工作地图获得更新的工作地图。地图构建与存储模块104利用自动割草机1每一次的工作时的行走不断的完善工作地图。
S150、接收回归指令,根据所述更新的工作地图生成回归路径,并控制自动割草机沿所述回归路径自回归前所处的位置回归至预定位置。每一次工作结束时,自动割草机1要从回归前所处的位置回归至预定位置,此时回归路径规划模块105利用已知的工作地图进行导航,生产较佳的回归路径。
例如,回归路径为:由所述工作地图中的已知坐标限定的、自回归前所处的位置至预定位置的距离最短的路径。距离最短的路径可能是直线,也可能是避开障碍物后的折线或弧线。
又例如,回归路径规划模块105还用于记录工作地图中各已知坐标被自动割草机1经过的次数。回归路径由回归前所处的位置的坐标、预定位置的坐标、回归前所处的位置与预定位置之间被自动割草机1经过的次数最少的已知坐标限定。这样,自动割草机1回归时可以避免过度碾压某些区域。
利用上述方法,自动割草机1可开始快速工作,且利用工作过程完善工作地图,在工作结束后可以根据已经有的工作地图导航,从而实现快速回归,不需要用户提前训练自动割草机1学习全部的工作区域。
本发明不局限于所举的具体实施例结构,基于本发明构思的结构和方法均属于本发明保护范围。

Claims (28)

  1. 一种自动工作系统,包括自移动设备和定位设备;
    所述自移动设备包括移动模块和任务执行模块,以及连接至所述移动模块和任务执行模块的驱动电路,所述驱动电路驱动所述移动模块带动自移动设备移动,并驱动任务执行模块执行工作任务;
    所述定位设备被配置为检测所述自移动设备的当前位置;其特征在于,
    所述自动工作系统包括:
    存储单元,被配置为存储工作区域地图,以及:
    地图确认程序,所述地图确认程序包括,
    提供驱动电路指令以沿工作区域的边界移动,
    接收来自用户的确认信号以完成所述地图确认程序;
    工作程序,提供驱动电路指令以在地图限定的工作区域内移动并执行工作任务;
    控制模块,被配置为通过监测定位设备的输出,执行所述地图确认程序,并在所述地图确认程序完成后执行所述工作程序。
  2. 根据权利要求1所述的自动工作系统,其特征在于,所述定位设备包括卫星定位设备。
  3. 根据权利要求2所述的自动工作系统,其特征在于,所述卫星定位设备包括差分卫星定位设备。
  4. 根据权利要求3所述的自动工作系统,其特征在于,所述差分卫星定位设备包括RTK-GPS定位设备。
  5. 根据权利要求1所述的自动工作系统,其特征在于,所述定位设备固定连接于所述自移动设备,或者所述定位设备与所述自移动设备可拆卸的连接。
  6. 根据权利要求1所述的自动工作系统,其特征在于,所述地图确认程序还包括,提供驱动电路指令以保持任务执行模块不执行工作任务。
  7. 根据权利要求6所述的自动工作系统,其特征在于,所述任务执行模块包括切割组件,所述地图确认程序包括提供驱动电路指令以保持所述切割组件不执行切割工作。
  8. 根据权利要求1所述的自自动工作系统,其特征在于,所述地图确认程序还 包括,在提供驱动电路指令以沿工作区域的边界移动之后,提供驱动电路指令以在边界限定的工作区域内移动。
  9. 根据权利要求1所述的自动工作系统,其特征在于,所述自动工作系统包括报警单元,被配置为输出指示工作区域异常状况的报警信号。
  10. 根据权利要求9所述的自动工作系统,其特征在于,所述自动工作系统包括环境传感器,至少部分安装于所述自移动设备,用于当自移动设备在工作区域内移动时,检测工作区域异常状况;所述控制模块通过监测环境传感器的输出,控制所述报警单元输出报警信号。
  11. 根据权利要求1所述的自动工作系统,其特征在于,所述地图确认程序还包括,接收来自用户的控制信号,根据所述控制信号提供驱动电路指令以控制移动方式。
  12. 根据权利要求11所述的自动工作系统,其特征在于,所述控制信号包括停止移动信号,所述地图确认程序包括接收来自用户的停止移动信号,根据所述停止移动信号提供驱动电路指令以控制停止移动。
  13. 根据权利要求1所述的自动工作系统,其特征在于,所述地图确认程序还包括,接收来自用户的地图修改信号,以修改所述工作区域地图。
  14. 根据权利要求1所述的自动工作系统,其特征在于,包括通信模块,与用户的智能终端通信,用于接收来自用户的确认信号。
  15. 一种自动工作系统的控制方法,所述自动工作系统包括自移动设备和定位设备;
    所述自移动设备包括移动模块和任务执行模块;
    所述定位设备被配置为检测所述自移动设备的当前位置;其特征在于,
    所述控制方法包括步骤:
    存储工作区域地图;
    控制进入地图确认模式,地图确认模式下,
    通过监测自移动设备的当前位置,基于所述工作区域地图控制移动模块带动自移动设备沿工作区域的边界移动;
    接收来自用户的确认信号;
    仅在接收到来自用户的确认信号后,控制进入工作模式;工作模式下,通过监 测自移动设备的当前位置,控制移动模块带动自移动设备在地图限定的工作区域内移动,并控制任务执行模块执行工作任务。
  16. 根据权利要求15所述的控制方法,其特征在于,所述定位设备包括卫星定位设备。
  17. 根据权利要求16所述的控制方法,其特征在于,所述卫星定位设备包括差分卫星定位设备。
  18. 根据权利要求17所述的控制方法,其特征在于,所述差分卫星定位设备包括RTK-GPS定位设备。
  19. 根据权利要求15所述的控制方法,其特征在于,所述定位设备固定连接于所述自移动设备,或者所述定位设备可拆卸的连接于所述自移动设备。
  20. 根据权利要求15所述的控制方法,其特征在于,地图确认模式下,控制所述任务执行模块不执行工作任务。
  21. 根据权利要求20所述的控制方法,其特征在于,所述任务执行模块包括切割组件,地图确认模式下,控制所述切割组件不执行切割工作。
  22. 根据权利要求15所述的控制方法,其特征在于,地图确认模式下,基于所述工作区域地图控制移动模块带动自移动设备沿工作区域的边界移动之后,还包括步骤,控制移动模块带动自移动设备在边界限定的工作区域内移动。
  23. 根据权利要求15所述的控制方法,其特征在于,提供报警单元,输出指示工作区域异常状况的报警信号。
  24. 根据权利要求23所述的控制方法,其特征在于,提供环境传感器,至少部分安装于所述自移动设备,当自移动设备在工作区域内移动时,检测工作区域异常状况;通过监测所述环境传感器的输出,控制所述报警单元输出报警信号。
  25. 根据权利要求15所述的控制方法,其特征在于,地图确认模式下,接收来自用户的控制信号,根据所述控制信号控制所述移动模块带动自移动设备改变移动方式。
  26. 根据权利要求25所述的控制方法,其特征在于,所述控制信号包括停止移动信号,根据所述停止移动信号控制所述移动模块带动自移动设备停止移动。
  27. 根据权利要求15所述的控制方法,其特征在于,地图确认模式下,接收来自用户的地图修改信号,根据所述地图修改信号修改所述工作区域地图。
  28. 根据权利要求15所述的控制方法,其特征在于,提供通信模块,与用户的智能终端通信,用于接收来自用户的确认信号。
PCT/CN2017/110743 2016-11-11 2017-11-13 自动工作系统及其控制方法 WO2018086612A1 (zh)

Priority Applications (6)

Application Number Priority Date Filing Date Title
CN201911165788.0A CN110888437B (zh) 2016-11-11 2017-11-13 自动工作系统及其控制方法
CN201780007838.5A CN108604098B (zh) 2016-11-11 2017-11-13 自动工作系统及其控制方法
EP17869757.9A EP3540552B1 (en) 2016-11-11 2017-11-13 Automatic work system and control method therefor
CN201911165755.6A CN110941270B (zh) 2016-11-11 2017-11-13 自动工作系统及其控制方法
US16/409,267 US11269349B2 (en) 2016-11-11 2019-05-10 Automatic working system and control method thereof
US17/589,624 US20220300008A1 (en) 2016-11-11 2022-01-31 Automatic working system and control method thereof

Applications Claiming Priority (4)

Application Number Priority Date Filing Date Title
CN201611040581 2016-11-11
CN201610997071.2 2016-11-11
CN201610997071.2A CN108073164B (zh) 2016-11-11 2016-11-11 自动割草机及其行走方法
CN201611040581.7 2016-11-11

Related Child Applications (1)

Application Number Title Priority Date Filing Date
US16/409,267 Continuation US11269349B2 (en) 2016-11-11 2019-05-10 Automatic working system and control method thereof

Publications (1)

Publication Number Publication Date
WO2018086612A1 true WO2018086612A1 (zh) 2018-05-17

Family

ID=62110419

Family Applications (1)

Application Number Title Priority Date Filing Date
PCT/CN2017/110743 WO2018086612A1 (zh) 2016-11-11 2017-11-13 自动工作系统及其控制方法

Country Status (4)

Country Link
US (2) US11269349B2 (zh)
EP (1) EP3540552B1 (zh)
CN (3) CN110888437B (zh)
WO (1) WO2018086612A1 (zh)

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP3588229A3 (en) * 2018-06-21 2020-03-04 Kubota Corporation Work vehicle and base station
US20210116581A1 (en) * 2019-10-22 2021-04-22 Neutron Holdings, Inc. Dba Lime Leveraging operations depots for antenna placement to gather phase and position data
CN113805575A (zh) * 2020-06-12 2021-12-17 颜炳郎 载具系统
SE544259C2 (en) * 2018-06-07 2022-03-15 Husqvarna Ab Robotic work tool system and method for defining a working area
EP3506039B1 (en) 2017-12-27 2022-05-25 Kubota Corporation Work area determination system for autonomous traveling work machine, autonomous traveling work machine and work area determination program
EP4218390A1 (en) * 2018-05-25 2023-08-02 The Toro Company Autonomous grounds maintenance machines with path planning for trap and obstacle avoidance

Families Citing this family (37)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN108267752B (zh) * 2016-12-15 2022-01-18 苏州宝时得电动工具有限公司 自移动设备的工作区域的分区方法、装置和电子设备
CN110831428A (zh) * 2017-06-09 2020-02-21 安德烈·斯蒂尔股份两合公司 绿地处理系统、用于检测待处理的地面的边界的至少一个部分的方法和用于运行自主移动绿地处理机器人的方法
WO2019167199A1 (ja) * 2018-02-28 2019-09-06 本田技研工業株式会社 制御装置、移動体及びプログラム
WO2019185930A1 (en) * 2018-03-30 2019-10-03 Positec Power Tools (Suzhou) Co., Ltd Self-moving device, working system, automatic scheduling method and method for calculating area
US10835096B2 (en) * 2018-08-30 2020-11-17 Irobot Corporation Map based training and interface for mobile robots
WO2020085240A1 (ja) * 2018-10-22 2020-04-30 株式会社ナイルワークス 運転経路生成システム、運転経路生成方法、運転経路生成プログラム、座標測量システム、およびドローン
US11084427B2 (en) * 2018-11-05 2021-08-10 Ford Global Technologies, Llc Running board assembly and method permitting overcurrent
CN110058590A (zh) * 2019-04-08 2019-07-26 浙江亚特电器有限公司 用于智能割草机的碰撞处理方法
CN114207542A (zh) * 2019-08-05 2022-03-18 苏州宝时得电动工具有限公司 一种自动工作系统
CN112540600A (zh) * 2019-09-19 2021-03-23 苏州宝时得电动工具有限公司 自移动设备工作区域的边界修正方法及自移动设备
CN112631267B (zh) * 2019-10-09 2023-01-24 苏州宝时得电动工具有限公司 自动行走设备控制方法及自动行走设备
CN112857368B (zh) * 2019-11-12 2024-04-09 苏州宝时得电动工具有限公司 一种割草机导航方法、装置和割草机
CN113064417B (zh) * 2019-12-13 2022-11-15 苏州宝时得电动工具有限公司 自移动设备及其工作方法
US20230115421A1 (en) * 2019-12-13 2023-04-13 Postiec Power Tools (Suzhou) Co.,Ltd. Self-moving device and working method therefor
CN111174758B (zh) * 2020-01-18 2021-07-16 湖南工学院 一种机器人无信号地形探测的方法
SE543954C2 (en) * 2020-03-18 2021-10-05 Husqvarna Ab Robotic work tool system and method comprising a base rtk unit, a mobile rtk unit and an auxiliary rtk unit
JP7469931B2 (ja) 2020-03-27 2024-04-17 本田技研工業株式会社 移動式充電装置、充電システム、移動式充電装置における制御方法とプログラム及び媒体
CN113849393A (zh) * 2020-06-28 2021-12-28 苏州宝时得电动工具有限公司 自移动设备及其工作方法
CN116400694A (zh) * 2020-06-28 2023-07-07 苏州宝时得电动工具有限公司 自移动设备
CN112015179A (zh) * 2020-08-21 2020-12-01 苏州三六零机器人科技有限公司 清扫设备的运行轨迹规划方法、装置、系统及存储介质
CN112137528B (zh) * 2020-09-25 2021-12-10 小狗电器互联网科技(北京)股份有限公司 扫地机器人清扫区域检测方法、装置、设备、系统和介质
CN112137512B (zh) * 2020-09-25 2021-12-10 小狗电器互联网科技(北京)股份有限公司 扫地机器人清扫区域检测方法、装置、设备、系统和介质
CN112022011B (zh) * 2020-09-25 2021-09-17 小狗电器互联网科技(北京)股份有限公司 扫地机器人的控制方法、设备、系统和存储介质
CN112605987B (zh) * 2020-11-25 2022-06-03 深圳拓邦股份有限公司 机器人导航工作方法、装置及机器人
CN112462770B (zh) * 2020-11-25 2022-10-28 常熟向洋电气科技有限公司 边界测定和确定的方法
CN114661036A (zh) * 2020-12-03 2022-06-24 苏州宝时得电动工具有限公司 自移动设备和自移动设备的控制方法
US20220197295A1 (en) * 2020-12-22 2022-06-23 Globe (jiangsu) Co., Ltd. Robotic mower, and control method thereof
US20220305658A1 (en) * 2021-03-29 2022-09-29 Husqvarna Ab Operation for a Robotic Work Tool
CN114137988A (zh) * 2021-12-01 2022-03-04 山东新坐标智能装备有限公司 机器人路径导航纠偏方法、系统、及存储介质
CN114793599A (zh) * 2022-04-14 2022-07-29 宁波市华代科技有限公司 一种智能割草机用智能作业系统
US20230389458A1 (en) * 2022-06-01 2023-12-07 Deere & Company System and method for field object detection, mapping, and avoidance
CN115202344A (zh) * 2022-06-30 2022-10-18 未岚大陆(北京)科技有限公司 割草机工作边界的割草方法、装置、存储介质及割草机
US20240069561A1 (en) * 2022-08-31 2024-02-29 Techtronic Cordless Gp Mapping objects encountered by a robotic garden tool
EP4372512A1 (en) * 2022-11-21 2024-05-22 SMAUT Technology s.r.o. Robotic mower, system and method for navigating a robotic mower
SE2251396A1 (en) * 2022-11-30 2024-05-31 Husqvarna Ab Improved definition of boundary for a robotic work tool
WO2024179428A1 (zh) * 2023-02-28 2024-09-06 苏州宝时得电动工具有限公司 一种设备控制方法及相关设备
CN116149337B (zh) * 2023-04-14 2023-07-07 未岚大陆(北京)科技有限公司 割草控制方法、设置方法、割草机、设置装置和电子设备

Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20050007057A1 (en) * 1995-05-30 2005-01-13 Friendly Robotics, Ltd. Navigation method and system for autonomous machines with markers defining the working area
CN101091428A (zh) * 2006-10-20 2007-12-26 大连理工大学 一种自动割草机器人
CN104252176A (zh) * 2013-06-28 2014-12-31 罗伯特·博世有限公司 用于对自主式服务机器人的至少一个工作区域进行工作区域检测的方法
CN106054898A (zh) * 2016-07-26 2016-10-26 天津鲁赫环保科技有限公司 智能除草机及除草方法

Family Cites Families (24)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US6338013B1 (en) 1999-03-19 2002-01-08 Bryan John Ruffner Multifunctional mobile appliance
US6611738B2 (en) 1999-07-12 2003-08-26 Bryan J. Ruffner Multifunctional mobile appliance
US8195342B2 (en) 2008-09-11 2012-06-05 Deere & Company Distributed knowledge base for vehicular localization and work-site management
US8706297B2 (en) 2009-06-18 2014-04-22 Michael Todd Letsky Method for establishing a desired area of confinement for an autonomous robot and autonomous robot implementing a control system for executing the same
RU2012122469A (ru) * 2009-11-06 2013-12-20 Эволюшн Роботикс, Инк. Способы и системы для полного охвата поверхности автономным роботом
DE102012200445A1 (de) 2012-01-13 2013-07-18 Robert Bosch Gmbh Autonomes Arbeitsgerät
DE102012201870A1 (de) * 2012-02-08 2013-08-08 RobArt GmbH Verfahren zum automatischen Auslösen einer Selbstlokalisierung
WO2014027945A1 (en) 2012-08-14 2014-02-20 Husqvarna Ab Mower with object detection system
CN106102446A (zh) * 2014-01-21 2016-11-09 苏州宝时得电动工具有限公司 自动割草机
US9516806B2 (en) 2014-10-10 2016-12-13 Irobot Corporation Robotic lawn mowing boundary determination
US10188029B1 (en) * 2014-10-20 2019-01-29 Hydro-Gear Limited Partnership Method of generating a three-dimensional map of a lawn and its use to improve mowing efficiency
KR102332752B1 (ko) * 2014-11-24 2021-11-30 삼성전자주식회사 지도 서비스를 제공하는 전자 장치 및 방법
US9420741B2 (en) * 2014-12-15 2016-08-23 Irobot Corporation Robot lawnmower mapping
DE102014226084A1 (de) 2014-12-16 2016-06-16 Robert Bosch Gmbh Verfahren zur Kartierung einer Bearbeitungsfläche für autonome Roboterfahrzeuge
WO2016097900A1 (en) * 2014-12-17 2016-06-23 Husqvarna Ab Robotic vehicle learning site boundary
US10643377B2 (en) 2014-12-22 2020-05-05 Husqvarna Ab Garden mapping and planning via robotic vehicle
US9538702B2 (en) 2014-12-22 2017-01-10 Irobot Corporation Robotic mowing of separated lawn areas
US10869432B2 (en) 2014-12-23 2020-12-22 Husqvarna Ab Lawn monitoring and maintenance via a robotic vehicle
EP3316443B1 (en) * 2015-06-26 2020-05-06 Positec Power Tools (Suzhou) Co., Ltd Autonomous mobile device and wireless charging system thereof
DE102015222414A1 (de) 2015-11-13 2017-05-18 Robert Bosch Gmbh Autonomes Arbeitsgerät
JP6212590B2 (ja) * 2016-03-31 2017-10-11 本田技研工業株式会社 自律走行作業車の制御装置
WO2017192981A1 (en) * 2016-05-06 2017-11-09 Mtd Products Inc Autonomous mower navigation system and method
EP3298874B1 (en) * 2016-09-22 2020-07-01 Honda Research Institute Europe GmbH Robotic gardening device and method for controlling the same
WO2018142482A1 (ja) * 2017-01-31 2018-08-09 本田技研工業株式会社 無人作業システム、管理サーバー、及び無人作業機

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20050007057A1 (en) * 1995-05-30 2005-01-13 Friendly Robotics, Ltd. Navigation method and system for autonomous machines with markers defining the working area
CN101091428A (zh) * 2006-10-20 2007-12-26 大连理工大学 一种自动割草机器人
CN104252176A (zh) * 2013-06-28 2014-12-31 罗伯特·博世有限公司 用于对自主式服务机器人的至少一个工作区域进行工作区域检测的方法
CN106054898A (zh) * 2016-07-26 2016-10-26 天津鲁赫环保科技有限公司 智能除草机及除草方法

Cited By (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP3506039B1 (en) 2017-12-27 2022-05-25 Kubota Corporation Work area determination system for autonomous traveling work machine, autonomous traveling work machine and work area determination program
EP4218390A1 (en) * 2018-05-25 2023-08-02 The Toro Company Autonomous grounds maintenance machines with path planning for trap and obstacle avoidance
US11832553B2 (en) 2018-05-25 2023-12-05 The Toro Company Autonomous grounds maintenance machines with path planning for trap and obstacle avoidance
SE544259C2 (en) * 2018-06-07 2022-03-15 Husqvarna Ab Robotic work tool system and method for defining a working area
EP3588229A3 (en) * 2018-06-21 2020-03-04 Kubota Corporation Work vehicle and base station
EP3764188A1 (en) * 2018-06-21 2021-01-13 Kubota Corporation Work vehicle and base station
US11543829B2 (en) 2018-06-21 2023-01-03 Kubota Corporation Work vehicle and base station
US20210116581A1 (en) * 2019-10-22 2021-04-22 Neutron Holdings, Inc. Dba Lime Leveraging operations depots for antenna placement to gather phase and position data
US11693123B2 (en) * 2019-10-22 2023-07-04 Neutron Holdings, Inc. Leveraging operations depots for antenna placement to gather phase and position data
CN113805575A (zh) * 2020-06-12 2021-12-17 颜炳郎 载具系统

Also Published As

Publication number Publication date
CN110888437A (zh) 2020-03-17
CN110941270B (zh) 2023-02-17
CN108604098B (zh) 2019-12-13
US11269349B2 (en) 2022-03-08
CN108604098A (zh) 2018-09-28
EP3540552B1 (en) 2022-06-01
US20220300008A1 (en) 2022-09-22
US20190265725A1 (en) 2019-08-29
EP3540552A1 (en) 2019-09-18
CN110888437B (zh) 2023-02-21
EP3540552A4 (en) 2020-04-22
CN110941270A (zh) 2020-03-31

Similar Documents

Publication Publication Date Title
WO2018086612A1 (zh) 自动工作系统及其控制方法
CN108226965B (zh) 自移动设备的定位故障处理方法、装置和电子设备
US11841710B2 (en) Automatic working system, self-moving device, and methods for controlling same
US10646997B2 (en) Navigation for a robotic working tool
CN106462161B (zh) 自主型移动机器人
CN115826585A (zh) 使用视觉系统的自主机器导航和训练
WO2017167207A1 (zh) 自动工作系统及其工作区域的地图建立方法
CN112578779A (zh) 地图建立方法、自移动设备、自动工作系统
WO2016097891A1 (en) Robotic vehicle for detecting gps shadow zones
IT201900010668A1 (it) Metodo di installazione di un dispositivo mobile per la manutenzione di terreni
WO2023274339A1 (zh) 自动工作系统
US20230008134A1 (en) Robotic work tool system and method for defining a working area perimeter
CN114322980A (zh) 获取位置坐标及绘制电子地图的方法、计算机可读存储介质和自主作业设备
WO2021023227A1 (zh) 一种自动工作系统
WO2024159849A1 (zh) 一种自主作业设备的作业方法及自主作业设备
CN113064417B (zh) 自移动设备及其工作方法
CN118426453A (zh) 一种自主作业设备的作业方法及自主作业设备
CN118426454A (zh) 自主作业设备的遗漏事件检测方法及自主作业设备

Legal Events

Date Code Title Description
121 Ep: the epo has been informed by wipo that ep was designated in this application

Ref document number: 17869757

Country of ref document: EP

Kind code of ref document: A1

NENP Non-entry into the national phase

Ref country code: DE

ENP Entry into the national phase

Ref document number: 2017869757

Country of ref document: EP

Effective date: 20190611