JP2012105557A - Automatic lawn mower - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an automatic lawn mower capable of cutting a slope landform flexibly corresponding to a traveling road surface.SOLUTION: The autonomous traveling type automatic lawn mower has various sensors including at least a position detector and drive wheels controlled by motors, and includes a control unit having a learning function. The control unit has: a drum control part for controlling the drive wheels based on information of the sensors and moving the drive wheels to a target point; a vehicle body balance part for keeping the balance of a vehicle body by moving an axle according to the slope of the traveling road surface; a cutting part for allowing the cutting unit to follow along the traveling road surface to perform lawn mowing; and a processing part for performing various operations and processing corresponding to the operations to control each unit based on the information of the sensors.

Description

  The present invention relates to an automatic lawn mower, and more particularly, to an autonomous traveling type automatic lawn mower capable of performing unmanned work corresponding to obstacles and sloping ground by accurately grasping position information.

  In order to maintain the lawn condition in golf courses, parks, soccer fields, etc., regular mowing is necessary. Especially in a large place such as a golf course, it takes a lot of labor and cost. Therefore, for example, a lawn mower capable of selecting manual operation and automatic operation as in Patent Document 1 and an unmanned lawn mower having an autonomous navigation device as in Patent Document 2 are disclosed.

  However, there are some problems with conventional unmanned lawn mowers that perform automatic operation. For example, when there are steps such as holes and depressions on the road surface, or when there is sloping terrain, it can be assumed in advance. Has dealt with by avoiding the point or making a program corresponding to the slope, but it is not possible to deal with the hole made immediately before, etc., and when judging the slope based on the map data There is a problem such as a problem that occurs when a position shift occurs.

Japanese Patent Laid-Open No. 9-128044 JP 9-37610 A

  Accordingly, the present invention has been made in view of the above-described conventional problems, and an object of the present invention is to provide an automatic lawn mower capable of cutting inclined terrain in a flexible manner corresponding to a traveling road surface. There is.

  An automatic lawn mower of the present invention made to achieve the above object has an autonomous traveling type having at least various sensors including position detecting means and motor-controlled drive wheels, and having a control unit for performing a learning function. An automatic lawn mower, wherein the control unit controls a driving wheel based on information from the sensor and moves the driving wheel to a target point, and moves the axle according to the inclination of the traveling road surface. A vehicle body balancing section that keeps the balance in place, a cutting section that cuts the lawn by following the cutting unit along the road surface, and various calculations for controlling each unit based on the information of the sensor and corresponding to the calculations And an arithmetic processing unit for performing the processing.

In the automatic lawn mower according to the present invention, the arithmetic processing unit includes a horizontal component in the advancing direction and a vertical component in the acceleration of the horizontal (X, Y direction) axis and the vertical (Z direction) axis detected by the acceleration sensor. Is decomposed by an angular component orthogonal to the traveling direction among the angles obtained from the angular velocities of the horizontal (X, Y direction) axis and the vertical (Z direction) axis detected by the gyro sensor, and each of the decomposed components is integrated. Thus, the speed and distance compensated for the influence of the height difference of the moving path are obtained.
The vehicle body balance unit moves the axle according to the inclination of the vehicle body calculated by the arithmetic processing unit from the angular velocity detected by the gyro sensor, and maintains the vehicle body balance.
The cutting unit is a road surface following mechanism that operates a movable mechanism provided on each axis of the cutting unit according to the inclination calculated by the arithmetic processing unit from the angular velocity detected by the gyro sensor to follow the inclined surface of the traveling route. Is provided.

  According to the automatic lawn mower of the present invention, unattended automatic driving is enabled by learning a driving pattern, and autonomous driving corresponding to a driving road surface and a moving path on the spot is enabled, thereby mowing the lawn. The labor and cost required can be reduced.

1 is an external view of an automatic lawn mower according to an embodiment of the present invention. It is explanatory drawing of the cutting unit of the automatic lawn mower shown in FIG. It is a schematic block diagram of the automatic lawn mower by one Embodiment of this invention. 3 is a view for explaining operations of an acceleration sensor and a gyro sensor of an automatic lawn mower according to an embodiment of the present invention. It is operation | movement explanatory drawing which balances the vehicle body inclination of the automatic lawn mower by one Embodiment of this invention. It is operation | movement explanatory drawing of the obstacle sensor of the automatic mower by one Embodiment of this invention. It is drawing for demonstrating the movement pattern of the automatic lawn mower by one Embodiment of this invention. It is operation | movement explanatory drawing of the movement pattern shown in FIG. It is explanatory drawing for processing the movement pattern of the automatic lawn mower by one Embodiment of this invention. It is a schematic block diagram of the arithmetic processing part which processes the movement pattern shown in FIG. FIG. 11 is a diagram for explaining the movement of the vehicle body by the movement command shown in FIG. 10. It is a block diagram of the arithmetic processing part shown in FIG. It is a flowchart which shows the operation | movement outline | summary of the automatic lawn mower by one Embodiment of this invention. FIG. 14 is a process flow diagram of the self-check shown in FIG. 13. FIG. 14 is a process flow diagram of the state monitoring shown in FIG. 13. FIG. 16 is a flowchart of interrupt processing for state monitoring shown in FIG. 15. It is a schematic flowchart of the teaching process shown in FIG. FIG. 18 is an interrupt process flowchart of the teaching process shown in FIG. 17. It is drawing which shows the teaching processing sequence of the automatic mower by one Embodiment of this invention. FIG. 14 is a schematic flowchart of the automatic lawn mowing mode shown in FIG. 13. FIG. 21 is an interrupt process flow diagram for the automatic mowing mode shown in FIG. 20. It is a processing flow figure of GPS data shown in FIG. It is a processing flow figure of the gyro data shown in FIG. It is drawing which shows the automatic lawn mower processing sequence of the automatic lawn mower by one Embodiment of this invention. FIG. 14 is a schematic flowchart of manual / movement processing shown in FIG. 13. FIG. 26 is an interrupt process flowchart of the manual / movement process shown in FIG. 25.

  Next, the specific example of the form for implementing the automatic lawn mower of this invention is demonstrated in detail, referring drawings.

  FIG. 1 is an external view of an automatic mower according to an embodiment of the present invention, and FIG. 2 is an explanatory diagram of a cutting unit of the automatic mower shown in FIG.

  Referring to FIG. 1, an automatic lawn mower 1 according to the present embodiment includes a GPS receiver for acquiring position information, a 3D gyro sensor that senses the direction and inclination of a vehicle body, and an operation / setting device that includes a display screen. A touch panel, a control unit including a calculation unit, an obstacle sensor using an infrared laser, an RFID reader for obtaining restricted areas and position correction values, exchanging information with a base station, and obtaining data from an RTK-GPS reference station Radio for driving, monitor lamp for driving and warning, cutting unit for mowing lawn with tracking mechanism of traveling road surface, motor-controlled driving wheel (drum) and rudder, detection of wheel rotation and running condition In addition to an encoder and a battery for monitoring the environment, although not shown in the figure, the surrounding situation is imaged, and the operation status is confirmed and monitored at the base station, and all of them are used for obstacle recognition, etc. Have a place camera or the like. By processing the captured image of the camera, it can be determined as an obstacle from the terrain, and the recognition rate can be improved by combining with recognition by the obstacle sensor.

  In this embodiment, a wide area of about 1 km is covered using a small area radio as a communication method between a base station (or a GPS reference station) and a mobile station (automatic mower 1). In the case of RTK-GPS, correction data of 160 bytes / second is normally sent from the GPS reference station. However, when the correction data is sent as it is, there is a case where the data cannot be sent if the transmission speed is low. For this, it is conceivable to separate a communication line dedicated for RTK-GPS communication and a communication line for other data, but problems such as the number of radios, complication, radio wave interference, cost, etc. occur. . Therefore, in this embodiment, the WGS-84 world geodetic system coordinates are divided into 2 km x 2 km areas, converted to offset coordinates with the lower left as the origin, the number of bytes is reduced from 4 bytes to 2 bytes, and data compression is performed. By doing so, the correction data of 160 bytes is reduced to about 50 bytes. By this processing, the communication time can be shortened, and operation status data can be transmitted and received between the automatic mower 1 and the base station.

  Referring to FIG. 2, an automatic lawn mower 1 has a cutting unit 2 that has eight blades and has a cutting width of 350 m and a cutting speed of 1.3 m / sec to 1.5 m / sec, and a cutting unit. And a control unit including a calculation unit for causing 2 to follow the traveling road surface.

  FIG. 3 is a schematic configuration diagram of an automatic mower according to an embodiment of the present invention, and is a configuration diagram mainly focusing on a control unit.

  The automatic lawn mower 1 includes a control unit 21 including an arithmetic processing unit, and a position detection unit 22 is connected to the control unit 21. The position detection unit 22 calculates and moves an error at the reference station from the number and phase of carrier waves. RTK (realtime kinetic) -GPS receiver 11 and MEMS (Micro Electro Mechanical Systems) 12 capable of precise positioning at a cm level by notifying the station, a small vibration type 3D gyro sensor (3-axis angular velocity sensor) 12 A multi-axis geomagnetic sensor (electronic compass) 13 using a Hall element or the like, and a semiconductor multi-axis acceleration sensor 14 using MEMS or the like are connected.

  Although not shown, the control unit 21 includes a CPU (central control unit) that controls the entire process, a DSP (Digital Signal Processor) for digital signal processing, various input / output (I / O) interfaces, and the like. Includes digital and analog ASIC (Application Specific Integrated Circuit) with integrated peripheral circuits including functions, ROM including non-volatile flash memory for storing control programs and various data, RAM used as temporary storage for work area during operation, etc. However, although a touch panel type input / output device having a monitor screen, a communication device with a base station, and the like are connected, their descriptions and configuration drawings that are not the gist of the present invention are omitted.

  The control unit 21 also includes an obstacle sensor 17 that detects a person, an object, a tree, a step, or the like by using a monitor lamp 15 and an alarm 16 used for response, warning, alerting, etc. for various settings, an infrared laser, or the like. CCD or CMOS type omnidirectional camera 18 used to image surrounding conditions and monitor at base stations, recognize obstacles, etc. IC tags installed at fixed points for detection of restricted areas and latitude / longitude correction An RFID reader 19 for reading the information is connected.

  Information from the lift sensor 23 that detects that the vehicle body is lifted and the tilt sensor 24 that detects the inclination of the vehicle body when traveling is connected to the control unit 21 and is transmitted to the interlock unit 25. When the motor driver 31 is directly controlled without using the control unit 21 and a foreign object is caught in the cutting unit 2, when the device is lifted, when a tilt exceeding a specified level is detected, or when an abnormality such as a fall or a collision occurs, Stop the drive wheel (drum) immediately. The operation status of the automatic lawn mower may be constantly transmitted to the monitoring center where the base station is located, and when an abnormality is detected, the travel of the automatic lawn mower 1 may be stopped remotely from the base station. Further, when an abnormality is detected, the abnormality information may be transmitted to a pre-registered mail address. The lift sensor 23 and the tilt sensor 24 can be shared by the gyro sensor 12 and the acceleration sensor 14. The acceleration sensor 14 can also be used as a collision sensor that is regarded as a collision when an acceleration greater than or equal to a predetermined value is detected.

  The motor driver 31 communicates with the control unit 21 and is controlled based on the result calculated by the arithmetic processing unit of the control unit 21 to drive the motors 32, 34 and 36 of the drive wheels and the cutting unit 2. The rotation state of the drive wheels driven by the motors 32, 34, 36 and the cutting unit 2 is obtained by inputting the rotation information generated by the pulse encoders 33, 35, 37 provided in conjunction with the rotation shaft to the control unit 21. The rotation state is monitored and fed back to the arithmetic processing in the control unit 21. Such information is exchanged through control commands.

  In addition to this, the automatic mower 1 also includes a power source battery 27 for operating the automatic mower 1, a charging connector 26 for charging the battery 27, a stabilized power source for supplying power to each unit, and its A voltage detector 28 for monitoring the voltage, a thermal protector 29 for detecting an abnormal temperature of each unit and stopping the power supply are provided. Although not shown, the control process of the control unit 21 is mainly performed by the CPU 1 and includes a CPU 2 that performs other comprehensive control. The CPU 2 is connected to various input / output interfaces such as a memory card, USB, and RS232C, in addition to an omnidirectional camera, a display screen for operation / setting, a touch panel, and a communication circuit with a base station.

  FIG. 4 is a view for explaining operations of an acceleration sensor and a gyro sensor of an automatic lawn mower according to an embodiment of the present invention, and FIG. 5 is a vehicle body tilt of the automatic lawn mower according to an embodiment of the present invention. It is operation | movement explanatory drawing which balances.

  Referring to FIG. 4, the triaxial acceleration sensor 14 detects an X (horizontal horizontal), Y (horizontal vertical), and Z (vertical) axis acceleration by using a semiconductor type acceleration sensor using MEMS or the like, and an angular velocity. The gyro sensor 12 for detecting X, Y, and Z-axis angular velocities (roll) using a mechanical (rate) gyro or a vibratory gyro using a MEMS silicon vibrator ring, which can detect angular velocities with high accuracy. , Pitch, yaw), and the angular velocity is integrated to calculate the angle.

  Referring to FIG. 5, when there is an up-down movement (a difference in height) in the movement path, the distance and speed (assuming the traveling direction is the X direction) are the X-axis acceleration, the Z-axis acceleration, and the Y-axis pitch angle. The horizontal component (X-axis direction) and the vertical component (Z-axis direction) can be obtained by decomposing (sampling) by the pitch angle and integrating the respective components. The gyro sensor 12 detects the inclination (pitching, rolling, yawing) of the vehicle body from the angular velocities of the X (horizontal horizontal), Y (horizontal vertical), and Z (vertical) axes, so that the automatic mower 1 is always kept in equilibrium. Used for. At this time, the road surface following mechanism (not shown) of the cutting unit 2 absorbs the yaw direction corresponding to the rotation difference of the driving wheel (drum), the pitch due to the terrain, the roll, and the vertical direction. The movable mechanism is provided in the turf so that mowing can be performed following the road surface.

  FIG. 6 is an operation explanatory diagram of the obstacle sensor of the automatic lawn mower according to the embodiment of the present invention.

  Referring to FIG. 6, the automatic lawn mower 1 detects obstacles such as people, objects, and trees present on the movement target route by the obstacle sensor 17 and waits for a predetermined time until the obstacle is removed. When it is stored as data or after a predetermined time has elapsed, a detour is performed to avoid a collision. As the obstacle sensor 17, an ultrasonic sensor or an infrared sensor using a laser LED is used, and the obstacle is detected by measuring the reflected wave or reflected light, and the distance to the obstacle is measured. The level difference of the road surface of the travel route is determined by measuring the distance from the reflection of ultrasonic waves or laser light irradiated at a predetermined angle (θ1, θ2) and measuring the difference in reflection distance from the flat surface.

  When recognizing the difference from an obstacle or when acquiring IC tag information of a weak wireless signal at a fixed point provided in a key point, it is determined that the area is a restricted entry area, and the latitude and longitude data is passed when the point passes. Acquire and correct your position. A special rope or the like is used in the restricted entry area, and IC tags are embedded in the rope at intervals of 50 cm, for example, and information on the IC tag is read with an RFID antenna attached to the tip of the automatic lawn mower.

  FIG. 7 is a view for explaining a movement pattern of the automatic mower according to the embodiment of the present invention, and FIG. 8 is an operation explanatory view of the movement pattern shown in FIG.

  Referring to FIG. 7, the movement pattern of the automatic mower 1 is based on the movement path (teaching data) stored in the next autonomous running by first tracing the movement path and storing the route by the teaching function described later. The lawn mower 1 is automatically activated. The travel route is stored based on the map coordinates acquired by the GPS receiver 11 or the like, or the outer periphery is designated from the map to automatically calculate the optimal route inside.

  Referring to FIG. 8, the current location is acquired from the RTK-GPS reception data from the GPS receiver 11 when the automatic mower 1 is activated. When GPS reception is impossible, information such as position and traveling direction is preliminarily edited by a PC (personal computer) or the like and recorded on a memory card or the like, and this is recorded on the map data stored in the automatic mower 1. The movement route is traced using the movement pattern in which the coordinate data of the passing point (target point) is stored.

  In the case of RTK-GPS, it takes about 5 to 10 minutes to start positioning, so if the GPS data is interrupted for some reason, the automatic mower 1 will stop operating. The azimuth angle is acquired by the gyro sensor 12 so that the latitude and longitude data can be acquired even when the GPS signal is interrupted, and the azimuth and movement distance data are obtained using the rotation speed and the rotation difference acquired from the encoders 33, 35, and 37. create. As a result, unmanned work is possible, and rainy weather can be used when a waterproof structure is adopted.

  At the time of movement, the automatic mower 1 is integrated so that the data from the acceleration sensor 14 and the gyro sensor 12 are integrated and continuously stored, and the current position of the automatic mower 1 is obtained and the deviation from the stored coordinates is corrected. Move. At this time, the movement distance is obtained by counting the pulses from the encoders 33, 35, and 37, and the accuracy of the movement data is increased. The deviation is also corrected by the geomagnetic sensor 13. On the map screen displayed on the monitor screen of the automatic mower 1, the travel locus corrected with the map data is displayed.

  FIG. 9 is an explanatory diagram for processing the movement pattern of the automatic lawn mower according to one embodiment of the present invention, and FIG. 10 is a schematic configuration diagram of an arithmetic processing unit that processes the movement pattern shown in FIG. . 11 is a drawing for explaining the movement of the vehicle body by the movement command shown in FIG. 10, and FIG. 12 is a block diagram of the arithmetic processing unit shown in FIG.

  Referring to FIG. 9, first, a movement pattern storing coordinates data of passing points is created by editing information such as a position and a traveling direction on the basis of map data using a PC (personal computer) or the like in advance, and a plurality of movement targets. Set the point. At that time, it is also possible to automatically calculate the optimum route inside by specifying the outer periphery from the map. When creating an automatic route, the position coordinates and range of an obstacle are set in advance, and a movement route is set to avoid the obstacle. A description of the optimization model is omitted. The created movement pattern is transferred to and stored in the automatic mower 1 using a memory card or the like. The automatic lawn mower 1 traces the movement path by repeating the operation of moving between the current movement target point and the next movement target point.

  Referring to FIG. 10, the arithmetic processing unit of the automatic mower 1 sets the next movement target point, and controls the drive wheels toward the target point based on information from various sensors and encoders 33, 35, and 37. A drive shaft movement command for transmission is transmitted to the motor control unit.

  Referring to FIG. 11, the motor driver 31 receives the movement command and drives the driving wheel or rudder to determine the traveling direction. In this embodiment, as shown in FIG. 11, the rudder is not controlled, and the direction is determined by changing the direction of the rear wheel tire only with the drive wheels.

  Referring to FIG. 12, the arithmetic processing unit moves latitude / longitude data 111 from the RTK-GPS receiver 11, X, Y, Z acceleration data 131 from the acceleration sensor 14, and azimuth data 121 from the gyro sensor 12 and the geomagnetic sensor 13, respectively. It inputs into the direction acquisition part 215, correct | amends based on the driving | running | working information from encoder 33,35,37, and acquires the present position and moving direction of the automatic lawn mower 1. FIG. The arithmetic processing unit generates a control command by comparing the teaching data 211 of the set movement target point with the current data value acquired by the moving direction acquisition unit 215 by the destination calculation unit 212, and proceeds by the sampling unit 213. The horizontal component of the direction (X-axis direction) and the vertical component (Z-axis direction) are decomposed by the pitch angle of the Y-axis orthogonal to the traveling direction to correct the distance error due to the tilt component, and the integrator 214 temporarily uses the distance or velocity component. And is corrected based on the traveling information from the encoders 33, 35, and 37, sampled again by the sampling unit 311, and transmitted to the steering angle / motor output unit 321. If an error occurs in the movement position, the movement direction is corrected by giving a rotation difference to the left and right drive shaft motors so as to approach the movement target value. The relative azimuth is obtained by obtaining the rotational speeds of the left and right drive shafts from the encoders 33, 35, and 37, and the data obtained from the encoders 33, 35, and 37 is used as a correction value.

  FIG. 13 is a flowchart showing an outline of the operation of the automatic lawn mower according to one embodiment of the present invention, and is a process flow diagram of the CPU 2 that controls the entire process of the automatic lawn mower 1.

  Referring to FIG. 13, first, the CPU 2 performs an “initial setting process” (step S101). As initialization processing in the initial setting processing, port setting, interlock-related setting, RS232C transmission / reception interrupt setting, and interval timer setting (10 ms) are performed as CPU settings. The variables to be initialized in each process include, as flags, a mode start flag, a teaching completion flag, a communication time-out flag between the CPUs 1 and 2, a gyro sensor, an M (motor) controller, and a GPS status flag. CPU 1 as a counter, such as a gyro status flag, a U-turn stop flag by an RFID or the like indicating a prohibited area, for example, an operation state flag with initial value = 1 (standby), operating = 0, sensor abnormality = 1 (standby) And 2, a communication timeout determination counter between a gyro sensor, an M (motor) controller, a GPS abnormality counter, a gyro status abnormality counter, and the like, such as self status, teaching data number, teaching data, latitude / longitude, left / right turn ( Turn: The top position of the automatic mower is the target position Operation oriented in direction), mowing, cutting angle, there is a GPS target azimuth angle and the like. In this embodiment, the RS232C is used for communication between the CPU 1, 2, GPS, gyro sensor, M (motor) controller, etc., but serial communication such as USB or other communication protocols may be used. Good. Further, in the present embodiment, the processing of the control unit is shared by the CPUs 1 and 2, but these may be configured by a single CPU, combined with a DSP or ASIC, or further combined into a single CPU. It can be configured by using various calculation / control units such as those built in the chip.

  After the initial setting process, “self-check” is performed (step S102), and it is determined whether or not the self-check is normally performed (step S103). If normal, the self-state flag is normally set (step S105). If an abnormality is detected, the CPU 1 is notified of the state (alarm notification) determined by the self-check (S104), monitoring is performed until the abnormality is removed, and the self-check is continued without performing other operations. When the self-check is normally completed, an initial completion notification is sent to the CPU 1 (step S106), and the process shifts to “status monitoring” in which monitoring of items substantially similar to the self-check is continued (step S107). Transition. It is determined whether or not the state is normal while waiting for the start of the operation mode (step S108). If it is normal, “automatic mowing mode” (step S111) and “teaching mode” are selected according to the operation mode (step S109). ”(Step S110),“ manual / movement mode ”(step S112), and the state monitoring is continued. When the operation mode is changed, variables are initialized. If a state abnormality is detected, the state monitoring is continued without shifting to the operation mode.

  As interrupt processing, reception of gyro sensor information (for example, every 10 ms), GPS data (for example, every 50 ms) via the CPU 1, mode state, other sensor states, teaching-related reception, driving M (motor) and lawn mowing M There is reception of command data obtained from the encoder information of the (motor) state.

  FIG. 14 is a process flow diagram of the self-check shown in FIG.

  Referring to FIG. 14, the “self-check” monitors the interlock function and each sensor port (I / O port: IN) to confirm that it is normal. Monitoring items include an emergency stop SW (switch), a lift sensor, a tilt sensor, and a collision sensor (acceleration sensor). It is determined whether or not the interlock function and the sensor port are normal (step S132). If normal, the motor servo function is turned on via the I / O (step S133). An abnormality flag is set, the motor servo function is turned off (step S135), and the process proceeds to the next check process (step S136). If the motor servo function is normal, the RS232C communication check is performed after a wait of 500 ms (step S134), the gyro function is started to check whether the status of the received data is normal, and the drive motor and lawn It is confirmed that there is a response to the motor rotational speed control parameter request for the mowing motor and that the motor servo function is ON (step S136), the RAM check of the work area is performed (step S137), and the main routine of FIG. Return to (Step S103).

  FIG. 15 is a flowchart of the status monitoring process shown in FIG. 13, and FIG. 16 is a flowchart of the status monitoring interrupt process shown in FIG.

  Referring to FIG. 15, “status monitoring” monitors the interlock function and each sensor port to confirm that they are normal, as in the self-check. The monitoring items are emergency stop SW, lift sensor, tilt sensor, and collision sensor. It is determined whether there is no change in the interlock function and the sensor port state and the state is normal (step S202). If there is no change in the state and the state is normal, the flag obtained by the self-check, etc. Is set (step S203), and it is determined whether teaching has been started (step S206) or automatic lawn mowing has been started (step S207). If there is a change in the state or an abnormality is detected in the state, the corresponding abnormality flag is set, then the drive motor and lawn mowing motor are stopped and the motor servo function is turned off (step S204). The state data is set (step S205), the process proceeds to a step of determining whether teaching has been started (step S206) or whether automatic lawn mowing has been started (step S207).

  When teaching or automatic lawn mowing is started, the pitch and roll are monitored by comparing the data received from the gyro sensor with the specified value, and the rotation status including rotation stop and reverse rotation of the drive motor and lawn mowing motor is monitored from the encoder. Monitoring is performed based on the information (step S208). It is determined whether the state of the gyro function and the motor rotation is not changed and the state is normal (step S209). If the state is not changed and the state is normal, the state obtained by the self-check is set. In step S203, it is determined whether there has been a change in the state data in the self-check (step S213). If there is a change in the state of the gyro function and motor rotation or if an abnormality is detected, the corresponding abnormality flag is set, and then the drive motor and lawn mowing motor are stopped to turn off the motor servo function (step S211). Then, the state data obtained by the self-check is set (step S212), and the process proceeds to step S213 for determining whether or not the state in the self-check has changed.

  Referring to FIG. 16, step S208 for monitoring the rotation state of the drive motor and the lawn mowing motor determines whether the motor is rotating based on the information of the encoder based on the 100 ms interval interrupt by RS232C (step S231). If the motor is rotating, the encoder value is acquired and transmitted to the CPU 1, the operation state flag is set during operation, and the process returns to the original process. If it is determined that the motor is stopped, the end flag is set and the process returns to the original process. Here, the RS232C reception interrupt will be described. The encoder value linked to the motor-controlled drive wheel is acquired (step S251), the motor rotation state obtained from the encoder is set (step S252), and whether or not there is an abnormality is determined. Judgment is made (step S253). If the motor rotation state is normal, the process returns to the original process. If it is determined that there is an abnormality, the corresponding abnormality flag is set, and then the drive motor and lawn mowing motor are stopped to turn off the motor servo function (step S254). Return to the original process.

  Referring to FIG. 15 again, if there is no change compared with the state in the self-check and the self-check is normal (S214), it is determined whether or not the operation state is waiting (step S215). If the operating state is standby, it is determined whether or not the manual / moving mode is selected (step S217). If the operating state is in progress or the manual / moving mode is selected, the motor servo function is turned on and the CPU 1 is reached. The self-check state is notified (S218), and the process returns to the original process. If there is no change in the self-check state, the process directly returns to the original process. If the self-check state is abnormal, the corresponding abnormality flag is set and the CPU 1 is notified of the self-check state (S218). Return. Note that the operation state flag is not used in the manual / movement mode.

  FIG. 17 is a schematic flowchart of the teaching process shown in FIG. 13, and FIG. 18 is an interrupt process flowchart of the teaching process shown in FIG.

  Referring to FIG. 17, when the “teaching process” is started (step S301), it is determined whether the sensor data is normal (step S302), and then it is determined whether the teaching instruction has changed (step S303). ). When the “teaching process” is to be ended (step S304), data reception from the gyro sensor is stopped (step S305), and the process returns to the original process. When the “teaching process” is not performed, the process returns to the original process. If an abnormality is detected in the sensor data, the type of sensor is identified and the corresponding abnormality flag is set (step S306), then the drive motor and lawn mowing motor are stopped (step S307), and the operation state flag is set to the standby state. (Step S308), the motor servo function is turned off (step S309), and the process returns to the original process. If an abnormality occurs, stop the operation and wait until the abnormality is removed. If there is no change in the teaching instruction, the process returns to the original process. Examples of sensors to be monitored include obstacle sensors, distance sensors, rain sensors, and the like using infrared lasers. The operation state flag set in the standby state due to the sensor abnormality is canceled when data is received from the CPU 1.

  If there is a change in the teaching instruction, it is determined whether or not the operation state is a standby normal state (step S311). In the standby state, the motor servo function is turned on to start the drive motor and lawn mowing motor, and then the stop / The operation proceeds to forward / turning operation (step S313). If it is in the operating state, the process proceeds to stop / advance / turning operation step S313.

  In the case of the turning operation, a turning command is transmitted to the drive motor. At this time, the turning level is set to 0, and at the time of stopping, the difference in the current azimuth angle from the turning start to the turning stop is transmitted to the CPU 1 (step S316). The turning command may change the turning angular velocity value transmitted on the left and right. In the case of forward movement, a forward command is transmitted to the drive motor. At this time, the turning level is set to 0, and when stopped, the difference between the azimuth angle before the advance and the current azimuth angle is transmitted to the CPU 1 (step S315). In the case of a stop operation, a stop command is transmitted to the drive motor, and the azimuth angle acquired by the gyro sensor is stored. Each command is transmitted once when the condition changes.

  Thereafter, in response to the lawn mowing operation ON / OFF corresponding to the stop / advance / turning operation (step S317), if the lawn mowing operation corresponding to the advance / turning operation is ON, an ON command is transmitted to the lawn mowing motor (step S317). S318) Returning to the original processing, if the mowing operation corresponding to the stop operation is OFF, an OFF command is transmitted to the mowing motor (step S319), the operation state flag is set during operation (step S320), and the original operation is performed. Return to processing. During the teaching process, GPS data reception from the CPU 1 and other RS232C data are accepted by interruption.

  Referring to FIG. 18, the change of the operation mode shown in FIG. 13 is accepted by receiving an interrupt. When the teaching mode is started, the corresponding mode start flag is set to ON and data reception from the gyro sensor is started. (Step S331). When the teaching mode is interrupted, the corresponding mode start flag is set to OFF (step S332), and the mode start flag is set to ON again by resuming the teaching mode (step S333). At the end of the teaching mode, a motor stop command is sent, the motor start flag is set to OFF (step S334), and the process returns to the original process. The change of each operation mode shifts to the corresponding operation mode by generating an event interrupt by an operation from the touch panel or an instruction from the base station.

  FIG. 19 is a drawing showing a teaching processing sequence of an automatic lawn mower according to an embodiment of the present invention.

  Referring to FIG. 19, CPU 2 receives a teaching mode instruction command of start, end, stop, or interruption from CPU 1 and returns an ACK response if it can be accepted, and a NACK response otherwise. When starting the teaching mode, the CPU 2 makes a data transmission start request to the gyro sensor and starts receiving gyro data. In response to this, the gyro sensor transmits data to the CPU 2 at specified intervals. If the teaching mode is stopped, make a data stop request to the gyro sensor. Stop receiving gyro data.

  When the teaching mode is started, the CPU 1 requests the CPU 2 to start moving forward and waits for an ACK or NACK response. The CPU 2 that has received the forward start request from the CPU 1 sends a PWM (Pulse Width Modulation) signal output command at a predetermined ratio corresponding to the forward speed to the drive motor controller to advance the automatic lawn mower 1 and send an ACK response to the CPU 1. return. At the same time, the CPU 2 notifies the CPU 1 of the movement angle that is the difference from the stop azimuth and confirms it by an ACK or NACK response. When the CPU 2 receives a stop command from the CPU 1, it sends a command to stop the PWM signal output to the drive motor controller to stop the automatic mower 1 and returns an ACK response to the CPU 1, and the gyro direction obtained by the gyro reception Save the corner. It should be noted that the movement angle transmission is not performed during the rounding described below.

  The CPU 2 that has received the right turn (turn by right rotation) instruction command X (1, 2, 3) from the CPU 1 outputs a turning angular velocity command corresponding to the right turn instruction command X (1, 2, 3) to the drive motor controller. Then, the automatic mower 1 is turned and an ACK response is returned to the CPU 1. When the CPU 2 receives the right turning stop command from the CPU 1, the CPU 2 outputs a command of the turning angular velocity 0 to the drive motor controller to stop the turning of the automatic lawn mower 1, and returns an ACK response to the CPU 1, and also includes the stop azimuth angle. The movement angle from the turn start to the turn stop, which is the difference between the two, is notified and an ACK or NACK response is waited. In the case of the left turn, the same process as the right turn is performed.

  When receiving the lawn mowing ON command from the CPU 1, the CPU 2 transmits a PWM signal output command at a predetermined ratio corresponding to the rotation speed of the cutter to the lawn mowing motor controller to cause the automatic mower 1 to start the lawn mowing operation and to mow the lawn. The output control timer of the motor controller is started and an ACK response is returned to the CPU 1. The output control amount is changed after a predetermined time so that the rotation speed of the cutter is set to a predetermined rotation speed. Upon receiving the lawn mowing OFF command from the CPU 1, the CPU 2 transmits a command to stop the PWM signal output to the lawn mowing motor controller to stop the rotation of the cutter to stop the lawn mowing operation of the automatic lawn mower 1 and the lawn mowing. The output control timer of the motor controller is stopped and an ACK response is returned to the CPU 1.

  20 is a schematic flowchart of the automatic lawn mowing mode shown in FIG. 13, and FIG. 21 is an interrupt process flow chart of the automatic lawn mowing mode shown in FIG.

  Referring to FIG. 20, in the automatic lawn mowing mode, first, the mode start flag is confirmed (step S401). If the automatic lawn mowing mode has not been started, the process returns to the original process and the automatic lawn mowing mode is started. Teaching data is acquired from the CPU 1 and expanded to the RAM in units of target points. It is determined whether or not the data reception by the teaching process is completed (step S402). The process proceeds to “Process” and “Gyro Data Reception Process” (step S403). If the teaching data has not been received yet, the CPU 1 first requests the reference point data from the CPU 1 (step S404), performs the “reference point reception process” (step S405), and then requests the CPU 1 for the teaching data (step S404). S406) "Teaching data processing" (step S407) is performed. It is determined whether or not the teaching data is normal (step S408). If the teaching data cannot be acquired normally, the CPU 1 is notified of the abnormal end (step S414) and the mode start flag of the automatic lawn mowing mode is turned OFF. Then, the target counter is reset (step S413) and the process returns to the original process. If the teaching data is normal, the teaching data reception completion flag is turned ON (step S409), and reception of gyro data is started (step S410), and the process proceeds to "GPS data reception processing" and "gyro data reception processing" step S403. To do. When the “GPS data reception process” and the “gyro data reception process” are completed (step S411), the CPU 1 is notified of normal or abnormal termination (step S412), the mode start flag is turned OFF, and the target counter is reset. (Step S413) Return to the original process. If the “GPS data reception process” and the “gyro data reception process” have not ended, the process returns to the original process.

  Referring to FIG. 21, as described with reference to FIG. 18, the change of the operation mode shown in FIG. 13 is accepted by receiving an interrupt, and when the automatic mowing mode is started, the mode start flag is set to ON. Then, the target counter is reset (step S431). When the automatic mowing mode is interrupted, the mode start flag is set to OFF (step S432), and the mode start flag is set to ON again by resuming the automatic mowing mode (step S433). When the automatic mowing mode ends, a motor stop command is sent, the motor start flag is set to OFF, the target counter is reset, and the process returns to the original process (step S434).

  FIG. 22 is a processing flowchart of the GPS data shown in FIG.

  Referring to FIG. 22, “GPS data reception processing” determines whether or not the sensor data is normal (step S501), and then determines whether or not the GPS data is normally received (step S508). If an abnormality is detected in the sensor data, the type of sensor is identified and the corresponding abnormality flag is set (step S502), the drive motor and lawn mowing motor are stopped and the motor servo function is turned off (step S509). The operation state flag is set to the standby state (step S510), and the process returns to the original process. If an abnormality occurs, stop the operation and wait until the abnormality is removed. Even if GPS data cannot be received normally, the drive motor and lawn mowing motor are stopped, the motor servo function is turned off (step S509), the operation state flag is set to the standby state (step S510), and the original processing is performed. Return to. If the RFID reader detects the information of the IC tag in step S502 for identifying the type of sensor, the U-turn stop flag is checked (step S503). If the U-turn is not made, the process returns to the original process and the U-turn stop is stopped. In this case, the U-turn stop flag is set and the target direction is set to +180 degrees (step S504), the turning angular velocity transmitted to the drive motor is calculated (step S505), and the calculated turning angular velocity is transmitted to the drive motor ( Step S506) The operation state flag is set during operation, and the process returns to the original process.

  When the data is normally received from the GPS, it is determined whether or not the operation state is waiting (step S511). If the data is waiting, the motor servo function is turned on to start the drive motor and the lawn mowing motor (step S511). S512) If it is in operation, the distance and direction to the moving target point are calculated as they are (step S513), the turning angular velocity is calculated and transmitted to the drive motor, and the head of the automatic mower 1 is set to the next target point. (Step S514), it is determined whether the target point has been reached while checking the current position (step S515). It is determined whether or not the target point has been reached (step S516). If the target point has not been reached, the turning angular velocity to the drive motor is calculated (step S522), and the calculated turning angular velocity is transmitted to the drive motor ( In step S523), the operation state flag is set during operation, and the process returns to the original process. Until the final target point is reached, the index indicating the next movement target point is updated (step S520), the distance and direction to the movement target point are calculated (step S521), and the turning angular velocity to the drive motor is calculated. (Step S522) The calculated turning angular velocity is transmitted to the drive motor, the direction is changed to the next target point (step S523), the operation state flag is set during operation, and the process returns to the original process. When the final target point is reached (step S517), the drive motor is stopped, the motor servo function is turned off (step S518), the end flag is set to a normal state (step S519), and the process returns to the original processing. During the GPS data reception process, the RS232C data is received by interruption and the sensor state is received from the CPU 1.

  FIG. 23 is a processing flowchart of the gyro data shown in FIG.

  Referring to FIG. 23, in the “gyro data reception process”, it is determined whether or not the gyro data is normally received (step S601), and the gyro data is normally received when abnormal data of a predetermined number of times or more is continuously received. Is not received (step S602), if abnormal (step S603), the drive motor is stopped and the motor servo function is turned off (step S604), and the end flag is set to an abnormal state. Then (step S605) returns to the original process. When the gyro data is normally received, the calculation for correcting the azimuth is performed and the abnormality counter is set to 0 (step S606). Even when the correction is not performed, the U-turn stop flag is checked (step S608). If the U-turn is not made, the process returns to the original process. If the U-turn is stopped, the drive motor is stopped and the motor servo function is turned off. (Step S609), the end flag is set to an abnormal state (Step S610), and the process returns to the original process. When the azimuth correction is performed, the operation state is confirmed (step S611). If the operation is not performed, the process returns to the original process, and if the operation is performed, the turning angular velocity to be transmitted to the drive motor is calculated (step S612). The calculated turning angular velocity is transmitted to the motor (step S613), and the process returns to the original process. During the gyro data reception process, the RS232C data is received by interruption and the sensor state is received from the CPU 1.

  FIG. 24 is a diagram showing an automatic lawn mowing processing sequence of the automatic lawn mower according to the embodiment of the present invention.

  Referring to FIG. 24, CPU 2 receives an instruction of automatic mowing mode from start, end, stop, or interruption from CPU 1 and returns an ACK response if it is acceptable, and a NACK response otherwise. return. When the automatic lawn mowing mode is started, the CPU 2 makes a data transmission start request to the gyro sensor and starts receiving gyro data. When the automatic mowing mode is stopped, a data stop request is sent to the gyro sensor. Stop receiving gyro data.

  When the mowing is ready, the CPU 2 requests the CPU 1 to transmit a reference point and waits for an ACK or NACK response. Upon receiving the reference point notification from CPU 1, CPU 2 converts the received reference point into coordinates ("DDmm.Mmmmm" is converted to "DD.dddddddddd") and returns the offset coordinates to the original WGS-84 world geodetic system coordinates. , An ACK response is returned to CPU1. When the teaching data is requested from the CPU 2, the CPU 1 returns an ACK response and transmits the teaching data to the CPU 2. CPU1 receives the ACK response from CPU2, and repeats the transmission of the teaching data of the next target point. Transmission of teaching data is repeated, for example, every 90 ms. The CPU 2 stores the acquired teaching data in the RAM in the order of sequence numbers (numbers). When CPU 2 completes the reception of teaching data, CPU 2 transmits a completion notification to CPU 1 and waits for an ACK response. In response to the ACK response, CPU 2 sets the teaching flag to OK.

  When the lawn mowing operation is started, the CPU 2 receives the state of each sensor from the CPU 1 and, if the data is normal, sends a motor rotation start command to the driving motor coat roller and the lawn mowing motor controller to automatically The mower 1 is activated and an ACK response is returned to the CPU 1. If the data is abnormal, a 180 degree direction change command is sent, then a motor stop command is sent to the drive motor coat roller and the lawn mower motor controller to stop the automatic lawn mower 1 and a NACK response is returned to the CPU 1. . It also receives GPS data from the CPU 1 and gyro data from the gyro sensor, calculates the distance and azimuth to the target point from the GPS data, notifies the drive motor controller, and adjusts the moving direction according to the azimuth angle of the gyro reception data Then, the difference between the gyro azimuth angle and the GPS azimuth is calculated, the turning angle is transmitted to the drive motor controller to adjust the direction, and the head of the automatic lawn mower 1 moves toward the target point. The above operation is repeated until the final target point is reached. When the final target point is reached, the CPU 2 transmits a motor rotation stop command to the drive motor controller and the lawn mowing motor controller, respectively, and notifies the CPU 1 of the end, and ACK or Wait for NACK response. The CPU 2 receives an ACK response from the CPU 1 and transmits a transmission stop request to the gyro sensor.

  25 is a schematic flowchart of the manual / move process shown in FIG. 13, and FIG. 26 is an interrupt process flowchart of the manual / move process shown in FIG.

  Referring to FIG. 25, when a manual moving operation, that is, “manual / moving process” is started by an operation of the touch panel or the instruction from the base station (step S701), it is determined whether or not the teaching instruction has changed. (Step S702) If the “teaching process” is not performed, the process returns to the original process. If there is a change in the teaching instruction, the operation proceeds to stop / advance / turning operation (step S703). If it is in the operating state, the process proceeds to stop / advance / turning operation step S313.

  In the case of the turning operation, a turning command is transmitted to the drive motor (step S706). The turning command may change the turning angular velocity value transmitted on the left and right. In the case of the forward movement, the forward command is transmitted to the drive motor, the turning angular velocity is set to 0, and the turning stop command is transmitted to the drive motor (step S705). In the case of a stop operation, a stop command is transmitted to the drive motor.

  Thereafter, in response to the manual mowing operation ON / OFF corresponding to the stop / advance / turning operation (step S707), in the case of the manual mowing operation ON corresponding to the forward / turning operation, an ON command is transmitted to the mowing motor. (Step S708) Returning to the original process, if the manual mowing operation corresponding to the stop operation is OFF, a stop command is transmitted to the mowing motor (step S709), and the process returns to the original process. During the manual / movement process, GPS data reception from the CPU 1 and other RS232C data are received by interruption.

  Referring to FIG. 26, the change of the operation mode shown in FIG. 13 is accepted by receiving an interrupt. When the manual / movement mode is started, the mode start flag is set to ON and the teaching instruction data is cleared (step S731). ). When the manual / movement mode is interrupted, the mode start flag is set to OFF (step S732), and the mode start flag is set to ON again by resuming the manual / movement mode (step S733). At the end of the manual / movement mode, a motor stop command is sent, the motor start flag is set to OFF (step S734), and the process returns to the original process.

  As described above, the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the technical scope of the present invention.

DESCRIPTION OF SYMBOLS 1 Automatic lawn mower 2 Cutting unit 11 GPS receiver 12 Gyro sensor 13 Geomagnetic sensor 14 Acceleration sensor 15 Monitor lamp 16 Alarm 17 Obstacle sensor 18 Omnidirectional camera 19 RFID reader 21 Control unit (arithmetic processing part)
22 Position detection unit 23 Lift sensor 24 Tilt sensor 25 Interlock part 26 Charging connector 27 Battery 28 Stabilized power supply (voltage detection part)
29 Thermal Protector 31 Motor Driver 32, 34, 36 Motor 33, 35, 37 Encoder 111 Latitude / Longitude Data 121 Direction Data 131 X, Y, Z Acceleration Data 201 Arithmetic Processing Unit 211 Teaching Data 212 Destination Calculation Unit 214 Integrator 213, 311 Sampling unit 215 Movement direction acquisition unit 216 Displacement detection unit 321 Steering angle / motor output unit

Claims (4)

Autonomous lawn mower of autonomous traveling type having at least various sensors including position detection means and motor-controlled drive wheels, and equipped with a control unit that bears a learning function,
The control unit is
A drum controller for controlling the drive wheel based on the information of the sensor to move it to a target point; and
A vehicle body balancing section that moves the axle according to the inclination of the road surface to keep the vehicle body balanced,
A cutting unit for cutting the lawn by following the cutting unit along the road surface;
An automatic lawnmower comprising: various arithmetic operations for controlling each unit based on information from the sensor, and an arithmetic processing unit that performs processing corresponding to the arithmetic operations.   The arithmetic processing unit detects a horizontal component in a traveling direction and a vertical component in a horizontal (X, Y direction) axis and a vertical (Z direction) axis detected by an acceleration sensor by a horizontal ( It is decomposed by the angle component orthogonal to the traveling direction among the angles obtained from the angular velocities of the (X, Y direction) axis and the vertical (Z direction) axis, and by integrating each of the decomposed components, 2. The automatic lawn mower according to claim 1, wherein a speed and a distance compensated for the influence are obtained.   3. The automatic lawn mower according to claim 2, wherein the vehicle body balance unit moves the axle according to the inclination of the vehicle body calculated by the arithmetic processing unit from the angular velocity detected by the gyro sensor to maintain the vehicle body balance. .   The cutting unit is a road surface following mechanism that operates a movable mechanism provided on each axis of the cutting unit according to the inclination calculated by the arithmetic processing unit from the angular velocity detected by the gyro sensor to follow the inclined surface of the traveling route. The automatic lawn mower according to claim 2, further comprising:

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