JP6677513B2 - Autonomous traveling device - Google Patents

Description

  The present invention relates to an autonomous traveling device, and more particularly, to an autonomous traveling device having a function of measuring a distance to an obstacle.

2. Description of the Related Art Today, autonomous traveling devices that move autonomously, such as a transport robot that transports luggage and a monitoring robot that monitors conditions in and around a building or a predetermined site, are used.
Such a conventional autonomous traveling device stores map information and travel route information of an area to be traveled in advance, and uses an information acquired from a camera, a range image sensor, and a GPS (Global Positioning System) to detect an obstacle. Drive on a predetermined route while avoiding the road.

In a conventional autonomous traveling device, when an obstacle is found on an autonomously traveling route, the vehicle travels while decelerating, changes the route, or stops before colliding with the obstacle (for example, see Patent Document 1, 2).
In order to drive safely, for example, when the distance to the obstacle is 10 m or more, the vehicle travels at a relatively high normal speed, and when it is within 3 m, deceleration is started, and when it is within 1 m, Performs a speed control process such as stopping.

International Publication WO2012 / 164691 JP-A-9-161196

However, when traveling in a narrow passage, or when a plurality of obstacles are separated by a predetermined distance or more, even if there is a traffic width capable of traveling safely in the traveling direction, the vehicle may decelerate, In some cases, the vehicle stopped just before an obstacle.
In particular, in the case of a monitoring robot that monitors a predetermined site, monitoring is required within a predetermined time according to a predetermined route, but it is necessary to avoid obstacles and continue traveling without deceleration. However, the deceleration process may be frequently performed because an obstacle is found, and the monitoring process may not be completed within a predetermined time.

  Therefore, the present invention has been made in view of the above circumstances, and in order to ensure the safety of autonomous driving, when it is necessary to decelerate or stop in principle, decelerate or stop. However, if there is no need to decelerate in response to the detection of obstacles in the direction of the traveling route, an autonomous traveling device that travels without deceleration as much as possible and avoids obstacles and continues traveling The task is to provide.

The present invention relates to a vehicle, a traveling control unit that controls a driving member that causes the vehicle to travel, and a predetermined light that is emitted to a predetermined first obstacle determination area that includes a space ahead in the traveling direction, and A distance detector that receives light reflected by an object present in the determination area and detects a distance to the object; and a position of the object whose distance is detected in the first obstacle determination area. An obstacle detection unit that detects the direction of the position where the object is present with respect to the traveling direction; A storage unit that stores therein, a control unit, wherein the distance detection unit is included in the first obstacle determination area, a first detection mode for detecting a distance to an object in the first obstacle determination area, The width in the direction perpendicular to the traveling direction is the determination width W. A second detection mode for detecting a distance to an object in a second obstacle determination area having a first obstacle detection area, wherein the obstacle detection unit detects the first obstacle determination area while the vehicle body is traveling in the first detection mode. When the control unit switches the detection mode from the first detection mode to the second detection mode when the object OB1 is detected within the range, it is determined whether an obstacle is present in the second obstacle determination area. While the vehicle is traveling in the second detection mode while the vehicle is traveling in the second detection mode, if no obstacle is detected in the second obstacle determination area, the vehicle travels without deceleration. The present invention provides an autonomous traveling device , wherein the traveling control unit performs a deceleration process when traveling in a direction and detecting an obstacle in the second obstacle determination area .

According to this, even if an object is detected in the first obstacle determination area, the vehicle travels in the traveling direction unless an obstacle exists in the second obstacle determination area having the determination width W1, so that the vehicle travels in the traveling direction. The traveling can be continued by reducing the required deceleration processing.
When an object is present in the second obstacle determination area having the determination width W1, if the vehicle continues to travel as it is, there is a high possibility of collision with the object. Easier to take.

The present invention also provides a vehicle, a traveling control unit that controls a driving member that causes the vehicle to travel, and a predetermined light that is emitted to a predetermined first obstacle determination area including a space ahead in the traveling direction. A distance detector that receives light reflected by an object present in the obstacle determination area and detects a distance to the object; and a distance detector that detects the distance to the object in the first obstacle determination area of the object whose distance is detected. And an obstacle detection unit for detecting the direction of the position where the object is present with respect to the traveling direction, and a determination width set as a width that allows the vehicle body to travel safely and longer than the width of the vehicle body A storage unit storing W1; and a control unit, wherein the distance detection unit includes a first detection mode for detecting a distance to an object in the first obstacle determination area, and a first detection mode included in the first obstacle determination area. And the width in the direction perpendicular to the traveling direction is set. A second detection mode for detecting the distance to an object in the second obstacle determination area having a width, during running the vehicle body in the first detection mode, the obstacle detection unit, the first failure When a plurality of objects are detected in the object determination area, the plurality of objects are respectively present in different directions with respect to the traveling direction, and when the distance Ws between the plurality of objects is larger than the determination width W1, Is a second obstacle determination area having the determination width W1 included in the first obstacle determination area between the plurality of objects, or a width larger than the determination width W1 and smaller than the distance Ws between the objects. After setting the second obstacle determination area having the following, and switching the detection mode from the first detection mode to the second detection mode, it is determined whether an obstacle is present in the second obstacle determination area. While traveling in the direction of travel Is, during running the vehicle body in the second detection mode, the case is not an obstacle is detected in the second obstacle determination area, travels toward the traveling direction without decelerating, the second obstacle determining The present invention provides an autonomous traveling apparatus characterized in that the traveling control unit performs a deceleration process when an obstacle is detected in an area .
According to this, the vehicle body is caused to travel in the traveling direction while confirming whether or not an obstacle exists in the second obstacle determination area. Therefore, the second obstacle determination area set between a plurality of objects is provided. If there are no obstacles, the vehicle can pass between a plurality of objects without deceleration.

Further, when two objects whose distance Ws between the objects is larger than the determination width W1 are detected in the first obstacle determination area, the control unit determines that the traveling direction of the vehicle body is the distance between the two objects. It is characterized in that the traveling direction and the position of the vehicle body are adjusted so as to be perpendicular to the direction of Ws and to pass substantially the center between the two objects.
According to this, the traveling direction and the position of the vehicle body are adjusted so that the vehicle body passes through substantially the center between the two objects, so that the vehicle can pass between the two objects more reliably without deceleration. Become.

Further, when the vehicle body passes by the side of the object OB1 which caused the switching from the first detection mode to the second detection mode, and the object OB1 is no longer detected in the first obstacle determination area, The detection mode is switched from the second detection mode to the first detection mode.
In addition, a warning sound or a warning light is activated while traveling in the second detection mode, and the warning sound or the warning light is not activated while traveling in the first detection mode.

In addition, the distance detection unit includes a light emitting unit that emits light to the first obstacle determination area in a traveling direction, a light receiving unit that receives light, and a plurality of measurement points of the first obstacle determination area. A scanning control unit that scans the emission direction of the light so that the light is emitted toward the light source. The distance between the light emitting unit and the plurality of measurement points is calculated using the time difference between the time when the light receiving unit has received the light and the distance from the calculated distance to the object. Is detected.
Further, the distance detection unit emits a laser to a two-dimensional space or a three-dimensional space in a predetermined first obstacle determination area, and measures a distance at a plurality of measurement points in the first obstacle determination area. Is used.

According to the present invention, when an object is detected in the first obstacle determination area including the forward space in the traveling direction, the vehicle is driven while confirming whether or not an obstacle exists in the second obstacle determination area. Therefore, even if an object is detected in the first obstacle determination area, if there is no obstacle in the second obstacle determination area, the vehicle can travel without deceleration.
Therefore, for example, when the vehicle autonomously travels in a predetermined monitoring area according to predetermined route information, when there is an obstacle near the route, or when the vehicle passes through a narrow passage, it is possible to reduce unnecessary deceleration processing and stopping. The monitoring process can be completed within the expected time.

BRIEF DESCRIPTION OF THE DRAWINGS It is an external view of one Example of the autonomous traveling apparatus of this invention. FIG. 2 is an explanatory diagram of a configuration related to traveling of the autonomous traveling device of the present invention. 1 is a configuration block diagram of an embodiment of the autonomous traveling device of the present invention. FIG. 4 is a schematic explanatory diagram of one embodiment of a distance detection unit of the present invention. FIG. 3 is a schematic explanatory diagram of a scanning direction of a laser emitted from a distance detection unit according to the present invention. It is the schematic explanatory drawing which looked at the irradiation field of the laser of this invention from the upper direction and the back. FIG. 4 is an explanatory diagram of one embodiment of information stored in a storage unit of the present invention. FIG. 3 is an explanatory diagram of one embodiment of a traveling state when the autonomous traveling device of the present invention travels in a normal traveling mode. FIG. 3 is an explanatory diagram of one embodiment of a traveling state when the autonomous traveling device of the present invention travels in a normal traveling mode. FIG. 3 is an explanatory diagram of one embodiment of a traveling state when the autonomous traveling device of the present invention travels in a vehicle width traveling mode. FIG. 3 is an explanatory diagram of one embodiment of a traveling state when the autonomous traveling device of the present invention travels in a vehicle width traveling mode. It is an explanatory view of one example of a running state when the autonomous running device of the present invention runs between two obstacles. It is an explanatory view of one example of a running state when the autonomous running device of the present invention runs between two obstacles. FIG. 4 is an explanatory diagram of an embodiment of a traveling state in which the autonomous traveling device of the present invention travels between two obstacles after changing a course. FIG. 4 is an explanatory diagram of an embodiment of a traveling state in which the autonomous traveling device of the present invention travels between two obstacles after changing a course. FIG. 4 is an explanatory diagram of an embodiment of a traveling state in which the autonomous traveling device of the present invention travels between two obstacles after changing a course. FIG. 4 is an explanatory diagram of an embodiment of a traveling state in which the autonomous traveling device of the present invention travels between two obstacles after changing a course. 4 is a flowchart of an embodiment of obstacle detection and traveling control of the autonomous traveling device of the present invention. 4 is a flowchart of an embodiment of obstacle detection and traveling control of the autonomous traveling device of the present invention. 4 is a flowchart of an embodiment of obstacle detection and traveling control of the autonomous traveling device of the present invention. 4 is a flowchart of an embodiment of obstacle detection and traveling control of the autonomous traveling device of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. The present invention is not limited by the description of the following embodiments.
<Configuration of autonomous traveling device>
FIG. 1 shows an external view of an embodiment of the autonomous traveling apparatus according to the present invention.
In FIG. 1, an autonomous traveling device 1 of the present invention is a vehicle having a function of autonomously moving while avoiding an obstacle based on predetermined route information.
In addition, the autonomous traveling device 1 may include various functions such as a transport function, a monitoring function, a cleaning function, a guidance function, and a notification function in addition to the movement function.
In the following embodiments, an autonomous traveling apparatus that can autonomously travel in a predetermined outdoor monitoring area or passage and monitor and transport the monitoring area and the like will be mainly described.

In the external view of FIG. 1, the autonomous traveling device 1 (hereinafter, also referred to as a vehicle) mainly includes a vehicle body 10, four wheels (21, 22), a monitoring unit 2, and a control unit 3.
The monitoring unit 2 is a part having a function of checking a state of a moving area or a road surface and a function of monitoring a monitoring target. For example, a distance detecting unit 51 for checking a state of a moving front space, a camera (imaging unit) 55, a position information acquisition unit 58 for acquiring information on the current position where the vehicle is traveling.
The control unit 3 is a part that executes a traveling function and a monitoring function of the autonomous traveling apparatus of the present invention, and includes, for example, a control unit 50, an image recognition unit 56, an obstacle detection unit 57, a communication unit 54, It comprises a storage unit 70 and the like.

The autonomous traveling device 1 of the present invention uses the camera 55, the distance detection unit 51, the obstacle detection unit 57, and the like to travel while checking the state of the vehicle body 10 in the forward direction in the traveling direction. For example, when it is detected that an obstacle or a step is present ahead, the course is changed by performing operations such as stopping, rotating, retreating, and moving forward in order to prevent collision with the obstacle. Then, when an obstacle is recognized by image recognition or when a contact is detected, a predetermined function such as a stopping operation of the vehicle body is executed.
However, when traveling on a narrow passage, or when an obstacle is detected but traveling is possible without colliding with the obstacle, autonomous traveling is continued without deceleration.

FIG. 2 is an explanatory diagram of a configuration related to traveling of the autonomous traveling device of the present invention.
FIG. 2A is a right side view of the vehicle 1, and the right front wheel 21 and the rear wheel 22 are indicated by phantom lines. FIG. 2B is a cross-sectional view taken along line BB of FIG. 2A, and sprockets 21b, 22b, 31b, and 32b described later are indicated by phantom lines. Front wheels (21, 31) are arranged on the front surface 13 of the vehicle body 10, and rear wheels (22, 32) are arranged on the rear surface 14.
A band-shaped cover 18 is provided on each of the side surfaces 12R and 12L of the vehicle body 10, and extends along the front-back direction of the vehicle body 10. Axles 21a, 31a and axles 22a, 32a for rotatably supporting the front wheels 21, 31 and the rear wheels 22, 32 are provided below the cover 18. Each axle 21a, 31a, 22a, 32a is independently rotatable when not coupled by a power transmission member.

  Belts 23 and 33, which are power transmission members, are provided on the pair of left and right front wheels (21, 31) and rear wheels (22, 32). Specifically, a sprocket 21b is provided on the axle 21a of the right front wheel 21, and a sprocket 22b is provided on the axle 22a of the rear wheel 22. Further, between the front wheel sprocket 21b and the rear wheel sprocket 22b, for example, a belt 23 provided on the inner surface side with a projection meshing with the sprocket is wound. Similarly, a sprocket 31b is provided on the axle 31a of the left front wheel 31, and a sprocket 32b is provided on the axle 32a of the rear wheel 32. A sprocket 32b is provided between the front wheel sprocket 31b and the rear wheel sprocket 32b. , A belt 33 having the same structure as the belt 23 is wound.

Therefore, the pair of left and right front wheels and rear wheels (21 and 22, 31 and 32) are connected and driven by the belts (23 and 33), so that only one of the wheels needs to be driven. For example, the front wheels (21, 31) may be driven. When one of the wheels is a driving wheel, the other wheel functions as a driven wheel driven without slipping by a belt as a power transmission member.
As a power transmission member for connecting and driving the pair of left and right front wheels and the rear wheel, a sprocket and a belt provided with a projection meshing with the sprocket are used.For example, a sprocket and a chain meshing with the sprocket are used. Is also good. Further, when slippage is allowable, a pulley and a belt having large friction may be used as the power transmission member. However, the power transmission member is configured such that the rotation speeds of the drive wheel and the driven wheel are the same.
In FIG. 2, the front wheels (21, 31) correspond to driving wheels, and the rear wheels (22, 32) correspond to driven wheels.

  Two motors, an electric motor 41R for driving the right and left front wheels 21 and 22 and an electric motor 41L for driving the left and right front wheels 31 and 32, are provided on the front wheel side of the bottom surface 15 of the vehicle body 10. ing. A gearbox 43R is provided as a power transmission mechanism between the motor shaft 42R of the right electric motor 41R and the axle 21a of the right front wheel 21. Similarly, a gear box 43L is provided as a power transmission mechanism between the motor shaft 42L of the left electric motor 41L and the axle 31a of the left front wheel 31. Here, the two electric motors 41R and 41L are arranged in parallel so as to be symmetrical with respect to the center line in the traveling direction of the vehicle body. Has been established.

  The gear boxes 43R and 43L are composed of a plurality of gears and shafts, and are assembly parts that change the torque, the number of revolutions, and the direction of rotation to transmit the power from the electric motor to the axle that is the output shaft. A clutch for switching the cutoff may be included. The left and right rear wheels 22 and 32 are supported by bearings 44R and 44L, respectively, and the bearings 44R and 44L are disposed close to the right side surface 12R and the left side surface 12L of the bottom surface 15 of the vehicle body 10, respectively. .

With the above configuration, the pair of front and rear wheels 21 and 22 on the right side in the traveling direction and the pair of front and rear wheels 31 and 32 on the left side can be driven independently. That is, the power of the right electric motor 41R is transmitted to the gearbox 43R via the motor shaft 42R, and the rotation speed, torque or rotation direction is changed by the gearbox 43R and transmitted to the axle 21a. The rotation of the axle 21a causes the wheels 21 to rotate, and the rotation of the axle 21a is transmitted to the axle 22a via the sprocket 21b, the belt 23, and the sprocket 22b, thereby rotating the rear wheel 22. The transmission of power from the left electric motor 41L to the front wheel 31 and the rear wheel 32 is the same as the above-described right operation.

When the rotational speeds of the two electric motors 41R and 41L are the same, the autonomous traveling device 1 will move forward or backward if the gear ratios (reduction ratios) of the gearboxes 43R and 43L are the same. When changing the speed of the autonomous traveling device 1, the gear ratio of each of the gear boxes 43R and 43L may be changed while maintaining the same value.
When the traveling direction is changed, the gear ratio of each gear box 43R, 43L is changed to change the rotation speed of the right front wheel 21 and the rear wheel 22 and the rotation speed of the left front wheel 31 and the rear wheel 32. What is necessary is just to make a difference. Further, by changing the rotation direction of the output from each of the gear boxes 43R and 43L, the rotation directions of the left and right wheels are reversed, so that the stationary turning around the center of the vehicle body becomes possible.

  In the case where the autonomous traveling device 1 is turned at a fixed position, since a steering mechanism for changing the angle of the front and rear wheels is not provided, the larger the distance between the front and rear wheels (wheel base), the greater the resistance applied to the wheels. A large driving torque is required for turning. However, since the gear ratios in the gear boxes 43R and 43L are variable, a large torque can be applied to the wheels only by lowering the rotation speed of the wheels during turning.

  For example, as the gear ratio in the gearbox 43R, when the number of teeth of the gear on the motor shaft 42R side is 10, the number of teeth of the intermediate gear is 20, and the number of teeth of the gear on the axle 21b is 40, the rotation speed of the axle 21b Is 1/4 the number of rotations of the motor shaft 42R, but a torque four times as large is obtained. Further, by selecting a gear ratio that further reduces the number of revolutions, a larger torque can be obtained, so that it is possible to turn even on a road surface with a large resistance to wheels such as uneven terrain and sandy ground. .

  Further, since the gearboxes 43R and 43L are provided between the motor shafts 42R and 42L and the axles 21a and 31a, vibrations from the wheels 21 and 31 are not directly transmitted to the motor shafts. Further, a clutch for transmitting and disconnecting (disconnecting) power is provided in the gear boxes 43R and 43L, and when the electric motors 41R and 41L are not energized, the electric motors 41R and 41L and the axles 21a and 31a serving as drive shafts are provided. It is desirable to shut off the power transmission during. Thus, even if a force is applied to the vehicle body 10 at the time of stop and the wheels rotate, the rotation is not transmitted to the electric motors 41R and 41L, so that no back electromotive force is generated in the electric motors 41R and 41L, and the electric motor There is no risk of damaging the circuits 41R and 41L.

As described above, since the left and right pair of front and rear front wheels and the rear wheel are connected by the power transmission member and the four wheels are driven by the two electric motors arranged on the front wheel side, the rear wheels are exclusively used. It is not necessary to provide a gearbox dedicated to the rear wheel required between the electric motor and the electric motor and the rear wheel, and the installation space for the electric motor dedicated to the rear wheel and the gearbox can be reduced. .
As described above, the two electric motors 41R, 41L are disposed on the left and right sides in the traveling direction on the front wheels 21, 31 on the bottom surface 15 of the vehicle body 10, and the gearbox 43R is provided on the left and right sides of each of the electric motors 41R, 41L. , 43L, but only the bearings 44R, 44L are disposed on the rear wheels 22, 32 side of the bottom surface 15, so that the bottom surface 15 of the vehicle body 10 A wide accommodation space 16 can be secured up to the end.

  Each of the electric motors 41R and 41L uses a battery (rechargeable battery) 40 such as a lithium ion battery as a power source, and installs the battery 40 in the housing space 16. Specifically, the battery 40 has a rectangular parallelepiped outer shape, for example, and can be placed at a substantially central position on the bottom surface 15 as shown in FIG. Further, it is desirable that the rear surface 14 of the vehicle body 10 be configured to be openable and closable with respect to, for example, the top surface or the bottom surface 15 so that the battery 40 can be easily inserted into and removed from the storage space 16. As a result, a large-capacity battery 40 for realizing long-time running can be mounted in the housing space 16 of the vehicle body 10, and operations such as replacement, charging, and inspection of the battery 40 can be easily performed from the rear surface 14. Will be possible. Furthermore, since the battery 40 can be disposed on the bottom surface 15, an electric vehicle that has a low center of gravity of the vehicle body 10 and can run stably can be obtained.

FIG. 3 is a block diagram showing the configuration of an embodiment of the autonomous traveling apparatus according to the present invention.
3, the autonomous traveling apparatus 1 of the present invention mainly includes a control unit 50, a distance detection unit 51, a traveling control unit 52, wheels 53, a communication unit 54, a camera 55, an image recognition unit 56, an obstacle detection unit 57, A position information acquisition unit 58, a rechargeable battery 59, a speed detection unit 60, a monitoring information acquisition unit 61, and a storage unit 70 are provided.
In addition, the autonomous traveling device 1 is connected to the management server 5 via the network 6, autonomously travels based on instruction information and the like sent from the management server 5, and transmits acquired monitoring information and the like to the management server 5.
As the network 6, any network currently used can be used, but since the autonomous mobile device 1 is a mobile device, a network capable of wireless communication (for example, a wireless LAN) can be used. preferable.

  As a network for wireless communication, the Internet or the like open to the public may be used, or a wireless network of a dedicated line in which connectable devices are limited may be used. As a wireless transmission method in a wireless communication path, various wireless LAN (Local Area Network) (whether or not WiFi (registered trademark) authentication is performed), ZigBee (registered trademark), Bluetooth (registered trademark) LE (Low Energy ) May be used in consideration of the wireless reach distance and the transmission band. For example, a mobile phone network may be used.

The management server 5 mainly includes a communication unit 91, a monitoring control unit 92, and a storage unit 93.
The communication unit 91 is a part that communicates with the autonomous traveling device 1 via the network 6, and preferably has a wireless communication function.
The monitoring control unit 92 is a part that executes a movement control for the autonomous traveling device 1, an information collection function and a monitoring function of the autonomous traveling device 1, and the like.
The storage unit 93 stores information for instructing the autonomous traveling device 1 to move, monitoring information (reception monitoring information 93a) sent from the autonomous traveling device 1, a program for monitoring control, and the like. It is.

The control unit 50 of the autonomous traveling device 1 is a part that controls the operation of each component such as the traveling control unit 52, and is realized mainly by a microcomputer including a CPU, a ROM, a RAM, an I / O controller, a timer, and the like. You.
The CPU performs the running function, the image recognition function, the obstacle detection function, and the like of the present invention by organically operating various hardware based on a control program stored in the ROM or the like in advance.

The distance detection unit 51 is a unit that detects a distance from a current position of the vehicle to an object existing in a predetermined space (for example, an obstacle determination area) including a space ahead in the traveling direction and a road surface. The distance detection unit 51 is arranged near the center of the front surface of the vehicle body. Here, when the vehicle travels outdoors, the object means, for example, a building, a pillar, a wall, a protrusion, or the like.
The distance detection unit 51 emits predetermined light to an obstacle determination area in the forward space in the traveling direction, and then receives reflected light reflected by an object and a road surface existing in the forward space to determine a distance to the object and the road surface. Is detected. Specifically, the distance detecting unit 51 mainly includes a light emitting unit 51a that emits light to an obstacle determination area in a predetermined forward space in a traveling direction, a light receiving unit 51b that receives light reflected by an object, And a scanning control unit 51c that changes the emission direction of the image two-dimensionally or three-dimensionally.

FIG. 4 is an explanatory diagram of one embodiment of the distance detecting section 51 of the present invention.
Here, it is shown that the laser 51d emitted from the light emitting unit 51a is reflected by the object 100, and a part of the laser that has reciprocated by the light receiving distance L0 and returned is received by the light receiving unit 51b.

As the emitted light, laser, infrared light, visible light, ultrasonic wave, electromagnetic wave, or the like can be used, but a laser is preferably used because distance measurement must be sufficiently possible even at night.
Further, LIDAR (Light Detection and Ranging or Laser Imaging Detection and Ranging: lidar) is used as a distance detection sensor today, but this may be used as the distance detection unit 51.
LIDAR is a device that emits a laser to a two-dimensional space or a three-dimensional space in a predetermined obstacle determination area and measures distances at a plurality of measurement points in the obstacle determination area.
In addition, the LIDAR detects the reflected light reflected by the object with the light receiving unit 51b after emitting the laser from the light emitting unit 51a, and calculates the light receiving distance L0 from, for example, the time difference between the emission time and the light receiving time. This light receiving distance L0 corresponds to measured distance information 72 described later.

Assuming that the laser emitted from the light emitting unit 51a hits an immovable object separated by a distance L0, the laser travels a distance (2L0) corresponding to twice the distance L0 from the tip of the light emitting unit 51a to the object surface, The light is received by the light receiving unit 51b.
The time when the laser is emitted and the time when the laser is received are shifted by the time T0 required for the laser to travel the distance (2L0). That is, a time difference occurs. The light receiving distance L0 can be calculated by using the time difference T0 and the speed of light.
Further, the distance to the object (obstacle) is detected from the calculated light receiving distance L0.

FIG. 4 shows a case where the distance detection unit 51 is not moved, and shows a case where the laser emitted from the light emitting unit 51a travels on the same optical path.
Therefore, when the light reflected on one point of the object 100 is received, only the distance between the tip of the light emitting unit 51a and one point of the object is calculated.

The scanning control unit 51c is a unit that scans the light emission direction so that the light is emitted toward a plurality of predetermined measurement points in the obstacle determination area in the space ahead of the traveling direction. Is gradually changed at regular intervals, thereby gradually moving the optical path along which the emitted laser travels.
The LIDAR 51 calculates the distance to the object (horizontal two-dimensional scanning) by changing the laser emission direction by a predetermined scanning pitch within a predetermined horizontal two-dimensional space. When the distance is calculated three-dimensionally, the emission direction of the laser is changed by a predetermined scanning pitch in the vertical direction, and the above-described two-dimensional scanning in the horizontal direction is performed to calculate the distance.

FIG. 5 is a schematic explanatory diagram of the scanning direction of the laser beam emitted from the distance detection unit (LIDAR) 51.
FIG. 6 shows a view of the irradiation area of the laser emitted from the distance detection unit (LIDAR) 51 when viewed from above (FIG. 6A) and a view when viewed from behind (FIG. 6B). Show.
In FIG. 5, one point indicates a position (hereinafter, referred to as a measuring point) where the laser hits on a two-dimensional plane (vertical plane) in the vertical direction at a position separated by a predetermined distance.

For example, if the direction of the distance detection unit 51 is changed so that the emission direction of the laser beam emitted from the light emitting unit 51a of the distance detection unit 51 moves to the right by a predetermined scanning pitch in the horizontal direction, the laser moves in the horizontal direction. Of the next position (measurement point) shifted to the right by the scanning pitch.
If an object exists at the position of this vertical plane, a part of the reflected light of the laser reflected at each measurement point is received by the light receiving unit 51b.
As described above, when the irradiation direction of the laser is sequentially shifted by a predetermined scanning pitch in the horizontal direction, the laser is irradiated to a predetermined number of measurement points. For each of the plurality of measurement points irradiated with the laser, the presence or absence of reception of the reflected light is checked to calculate the distance.

FIG. 6A is an explanatory diagram illustrating an example in which the laser irradiation direction is shifted in the horizontal direction by a scanning pitch and the laser is scanned in the left-right direction (that is, the horizontal direction).
For example, as shown in FIG. 6A, when a laser beam is irradiated in the rightmost direction, if an object exists in that direction, the light receiving distance L0 is calculated by receiving the reflected light from the object. You.

As shown in FIG. 5, when the laser scanning direction is the vertical direction, for example, when the laser emitting direction is shifted upward by a predetermined scanning pitch in the vertical direction, the laser The vertical plane of the next position (measurement point) shifted by the scanning pitch in the upward direction in the direction.
After shifting the emission direction of the laser upward by one scanning pitch in the vertical direction, as shown in FIG. The measurement point at a position shifted by the scanning pitch is irradiated with a laser.
As described above, by sequentially performing the horizontal laser scanning and the vertical laser scanning, a predetermined three-dimensional space is irradiated with the laser, and if an object exists in the three-dimensional measurement space, the laser is irradiated. The distance to the object is calculated.

In addition, when light (laser) emitted toward a plurality of measurement points is reflected by an object, if it is confirmed that the light reflected by the object is received by the light receiving unit, the distance is calculated. It is determined that a part of the object exists at the position of the measured point.
Furthermore, the object is present in an area including a plurality of measurement points determined to include a part of the object, and the information of the area including the plurality of measurement points is used to characterize the shape of the object or the posture of the human body. Get detection information.
The detection information is information characterizing some object, but may be obtained by the distance detection unit 51 or may be obtained from image data of the object taken by the camera 55.

In the two-dimensional scanning, the direction in which the laser is scanned is described as the horizontal direction. However, the direction is not limited to this, and the direction in which the laser is emitted may be changed in the vertical direction.
When irradiating a laser to a three-dimensional measurement space, the same two-dimensional scanning in the vertical direction may be performed sequentially after shifting two-dimensionally in the vertical direction by a predetermined scanning pitch in the horizontal direction.

FIG. 6B is a schematic explanatory diagram of the measurement points of the laser irradiated on the three-dimensional space when the laser is scanned in the horizontal direction and the vertical direction.
If there is no object in the direction of one measuring point from which the laser is emitted, the laser proceeds on the optical path as it is, no reflected light is received, and the distance cannot be measured.
Conversely, when reflected light is received with respect to the laser emitted to a certain measurement point, the distance is calculated, and it is recognized that an object exists at a position separated by the calculated distance.
FIG. 6B shows that reflected light has been detected at the six measurement points in the lower right part, and an object (for example, a human body or an obstacle) is included in an area including the six measurement points. Is recognized to exist.

When the laser 51d is incident on the light receiving section 51b of the distance detecting section 51, an electric signal corresponding to the received light intensity of the laser is output.
The control unit 50 checks the electric signal output from the light receiving unit 51b, and determines that the laser has been received, for example, when an electric signal having an intensity equal to or higher than a predetermined threshold is detected.
A conventionally used laser light emitting element is used for the light emitting section 51a, and a laser light receiving element for detecting a laser is used for the light receiving section 51b.

Further, the control unit 50 uses the time difference T0 between the emission time of the laser emitted from the light emitting unit 51a and the light receiving time at which it has been confirmed that the reflected light has been received by the light receiving unit 51b. A light receiving distance L0 that is a distance between a plurality of measurement points is calculated.
The control unit 50 obtains the current time using, for example, a timer, calculates the time difference T0 between the laser emission time and the light reception time at which the laser light reception is confirmed, and calculates the time difference T0 between the two times and the laser time. Is used to calculate the light receiving distance L0.

The traveling control unit 52 is a part that controls a driving member that causes the vehicle body to travel. The traveling control unit 52 mainly controls the rotation of the wheels 53 corresponding to the driving member to perform a straight traveling, a rotating operation, and the like. To run. The driving member includes a wheel, a caterpillar (registered trademark), and the like.
The wheels 53 correspond to four wheels (21, 22, 31, 32) as shown in FIGS.
Further, as described above, of the wheels, the left and right front wheels (21, 31) may be used as drive wheels, and the left and right rear wheels (22, 32) may be driven wheels that do not perform rotation control.
Further, encoders (not shown) are provided for the left and right wheels of the drive wheels (21, 31), respectively, and the traveling distance and the like of the vehicle are measured based on the number of rotations, the rotation direction, the rotation position, and the rotation speed of the wheels, and the traveling is controlled. You may. The encoder corresponds to a speed detection unit 60 described later.

The communication unit 54 is a part that transmits and receives data to and from the management server 5 via the network 6. As described above, it is preferable to have a function of connecting to the network 6 by wireless communication and communicating with the management server 5.
For example, when the abnormal state occurs and the notification process is executed, the communication unit 54 places the notification information including the occurrence of the abnormal state, the date and time of occurrence of the abnormal state, and the occurrence position in a position different from the autonomous traveling device. To the management server 5.
Further, the notification information may be transmitted to a terminal owned by a person in charge at a position different from the autonomous traveling device, or may be transmitted to at least one or both of the management server and the terminal.
Although it is necessary to set in advance where the transmission destination is, it may be possible to change or add the transmission destination based on the content of the abnormal state or the like in accordance with the operation mode of the vehicle. .

The camera 55 mainly captures an image of a predetermined space including a space in front of the vehicle in the traveling direction, and the captured image may be a still image or a moving image. The captured image is stored in the storage unit 70 as input image data 71, and is transferred to the management server 5 in response to a request from the management server 5.
Further, not only one camera 55 but also a plurality of cameras 55 may be provided. For example, four cameras may be fixedly installed so as to shoot the front, left, right, and rear of the vehicle body, respectively, and the shooting direction of each camera may be changed. May be provided.
When the vehicle travels outdoors and the weather is good and the shooting area is sufficiently bright, an image taken by the camera is analyzed to detect a human body, an obstacle, a state of a road surface, and the like.

The image recognition unit 56 is a unit that recognizes an object included in image data (input image data 71) captured by the camera 55. For example, an object included in image data is extracted, and when the extracted object is an object having predetermined characteristics of a human body, the object is recognized as a human body. Further, the image data (human body image) of the recognized human body part is compared with the person registration information stored in advance in the storage unit 70 to determine whether or not the human body image can match a previously registered person. . The image recognition processing may use an existing image recognition technology.
The object to be recognized is not limited to the human body, and may recognize an obstacle such as a wall, a pillar, a step, an animal, or a narrow passage.

The obstacle detection unit 57 is a unit that mainly detects an object (obstacle) using information acquired from the distance detection unit 51. In particular, the position of the object whose distance has been detected by the distance detection unit 51 in the obstacle determination region and the direction of the position where the object exists with respect to the traveling direction are detected.
For example, the distance detection unit 51 detects that an obstacle exists at the position of the measurement point where the reflected light is received and the distance is calculated.
Further, as described above, since the distances to the plurality of measurement points are calculated, the size, position, shape, and distance to the obstacle are obtained from the position information of the calculated measurement points. You.
Further, assuming that the scanning direction of the laser at the center of the laser scanning direction shown in FIG. 6A is the traveling direction of the vehicle, the position of the measuring point where the obstacle is detected and the scanning direction of the laser are determined. From the relationship, it can be determined whether the detected obstacle is on the right side, the left side, or just on the traveling direction with respect to the traveling direction.
Further, the angle of the position where the obstacle is present can be calculated by using the traveling direction as the reference zero degree for determining the direction. That is, the direction in which the obstacle exists with respect to the traveling direction can be detected.

When a plurality of obstacles are detected at different positions in the scanning area of the laser, the obstacle, in addition to the size, position, shape, distance, direction in the traveling direction, and the plurality of obstacles are determined for each obstacle. The distance between objects (distance between obstacles) is also calculated.
Information about these detected obstacles (for example, distance, position, direction, size, distance between obstacles) is stored in the storage unit 70 as obstacle information 77 as described later.
However, since the obstacle information 77 is always obtained even while the vehicle is running, it is updated every predetermined time.

  By using the distance to the obstacle detected as described above, the direction of the obstacle with respect to the traveling direction, and the distance between a plurality of obstacles, a change in the traveling direction of the vehicle and speed control are performed, In particular, if it is determined that there is no need to decelerate even if an obstacle is found in the traveling direction, the vehicle continues traveling without decelerating.

The position information acquisition unit 58 is a part that acquires information (latitude, longitude, and the like) indicating the current position of the vehicle. For example, the position information acquisition unit 58 may acquire the current position information 73 using a GPS (Global Position System). .
While comparing the acquired current position information 73 with the route information 74 stored in the storage unit 70 in advance, a direction in which the vehicle should travel is determined, and the vehicle is made to travel autonomously.
In order for the vehicle to travel autonomously, it is preferable to use information obtained from all of the above-described distance detection unit 51, camera 55, obstacle detection unit 57, and position information acquisition unit 58, or from at least one of them. Autonomous driving may be performed using the obtained information.

  Further, as the position information acquisition unit 58, similarly to the GPS, another satellite positioning system currently used may be used. For example, using the Quasi-Zenith Satellite System (QZSS) in Japan, GLONASS (Global Navigation Satellite System) in Russia, Galileo in EU, Hokuto in China, IRNSS (Indian Regional Navigational Satellite System) in India, etc. Is also good.

The rechargeable battery 59 is a part that supplies electric power to each functional element of the vehicle 1, and mainly supplies electric power for performing a traveling function, a distance detection function, an image recognition function, a collision detection function, and a communication function. It is.
For example, rechargeable batteries such as lithium ion batteries, nickel hydride batteries, Ni-Cd batteries, lead batteries, and various fuel cells are used.
In addition, a battery remaining amount detection unit (not shown) is provided to detect the remaining capacity (battery remaining amount) of the rechargeable battery and determine whether to return to a predetermined charging facility based on the detected remaining battery amount. Is determined, and when the remaining battery level becomes lower than the predetermined remaining level, the control unit may automatically return to the charging facility.

  The speed detector 60 is a part that detects the speed of the vehicle 1 during traveling, and mainly corresponds to an encoder attached to the wheels 53. The CPU acquires speed information from the speed detection unit 60 in real time, and controls the travel control unit 52 to accelerate or decelerate according to the situation.

In addition to the above components, the vehicle 1 may include a collision detection unit that detects that the vehicle 1 has collided with, contacted, or approached an obstacle while traveling. For example, a contact sensor or a non-contact sensor including a pressure-sensitive switch, a micro switch, an ultrasonic sensor, and an infrared distance measuring sensor is used, and is disposed, for example, on a bumper of a vehicle body.
Although one collision detection unit may be provided, it is preferable to provide a plurality of collision detection units at predetermined positions in front, side, and rear of the vehicle body in order to detect a collision from the front, side, and rear of the vehicle body.
For example, it is preferable that a plurality of collision detection units be mounted between the elastic member constituting the bumper and the vehicle body at a predetermined distance from each other.
If the collision detection unit detects a collision with an obstacle after the traveling control unit 52 executes the vehicle deceleration process, the traveling control unit 52 stops the vehicle in order to prevent the vehicle body from being damaged. Execute the processing to be performed. Further, the CPU may recognize the position where the obstacle exists based on the signal output from the collision detection unit. Further, based on the recognized position information of the obstacle, the CPU stops the vehicle body or determines a direction in which the vehicle should travel next while avoiding the obstacle.

  The storage unit 70 is a unit that stores information and programs necessary for executing each function of the autonomous traveling device 1, and includes semiconductor storage elements such as ROM, RAM, and flash memory, storage devices such as HDD and SSD, and others. Is used. In the storage unit 70, for example, input image data 71, measured distance information 72, current position information 73, route information 74, transmission monitoring information 75, set speed information 76, obstacle information 77, operation mode 78, deceleration area information 79 , The vehicle width determination area 80 and the like are stored.

  The input image data 71 is image data captured by the camera 55. When there are a plurality of cameras, the information is stored for each camera. The image data may be either a still image or a moving image. The image data is used for detection of a suspicious person, detection of an abnormal state, determination of a course of a vehicle, and the like, and is transmitted to the management server 5 as one piece of transmission monitoring information 75.

The measurement distance information 72 is the light receiving distance L0 calculated based on the information acquired from the distance detection unit 51 as described above. One light receiving distance L0 means a distance measured at one measurement point in a predetermined distance measurement area.
Further, this information 7 2 is stored for each measurement point belongs to a predetermined distance measurement area, is in association with each position information for each measurement point. For example, when there are m measurement points in the horizontal direction and n measurement points in the vertical direction, the light receiving distances L0 respectively corresponding to a total of m × n measurement points are stored.

  If there is an object (obstacle, road surface, pillar, etc.) that reflects the laser in the direction of each measurement point and the reflected light from the object can be received, the light receiving distance L0 to the object is stored. You. However, when no object is present in the measurement point direction, the reflected light is not received. Therefore, instead of the light reception distance L0, for example, information indicating that measurement could not be performed may be stored as the measurement point distance information 72. .

  The current position information 73 is information indicating the current position of the vehicle acquired by the position information acquisition unit 58. For example, the information is information including latitude and longitude acquired using GPS. This information is used, for example, to determine the course of the vehicle.

  The route information 74 previously stores a map of a route on which the vehicle should travel. For example, when a route or area to be moved is fixedly determined in advance, the route information 74 is stored as fixed information from the beginning. However, when it is necessary to change the route, information transmitted from the management server 5 via the network 6 may be stored as new route information 74.

The transmission monitoring information 75 is information of various monitoring targets acquired during traveling and while stopping, and is information transmitted to the management server 5 via the network 6. This information includes, for example, input image data 71 captured by the camera 55, travel distance, travel route, environmental data (temperature, humidity, radiation, gas, rainfall, voice, ultraviolet rays, etc.), terrain data, obstacle data, It includes road surface information, warning information, and the like.
In order to obtain such monitoring information, it is preferable to provide, for example, a thermometer, a hygrometer, a microphone, a gas detection device, and the like.

The set speed information 76 corresponds to the running speed of the vehicle, and the current running speed is set based on this information.
For example, when traveling on a route without obstacles, a relatively high speed is set in the set speed information 76, and the traveling control unit 52 sets the wheels so that the vehicle travels at the speed set in the set speed information 76. 53 is controlled.
If it is determined that the vehicle needs to be decelerated by detecting an obstacle or a step, a relatively slow speed is set in the set speed information 76.

  The obstacle information 77 is information relating to the detected obstacle, and includes a distance from the current position to the obstacle, a shape, a position, a direction, a size, a color, a distance between obstacles, a height difference, and a tilt angle of the obstacle. The information consists of: For example, the shape and size of the obstacle and the distance to the obstacle are acquired by the distance detection unit 51 and stored as a part of the obstacle information 77. Information for identifying an obstacle is also obtained by the camera 55, the image recognition unit 56, and the obstacle detection unit 57.

The operation mode 78 (MD) refers to the type of the traveling state of the vehicle, and mainly includes a mode when an obstacle or the like is not detected (referred to as a normal traveling mode M1) and a mode when an obstacle or the like is detected. (Referred to as a vehicle width running mode M2).
The normal traveling mode M1 corresponds to the first detection mode described above, and is a mode in which the vehicle travels while detecting an obstacle or the like over the entire range in which laser scanning is possible.
The vehicle width traveling mode M2 corresponds to the above-described second detection mode, and is a mode in which the vehicle travels while limiting the range in which an obstacle or the like is detected out of the entire range in which laser scanning is possible. In particular, as described later, in a mode in which, when two objects are detected, a range in which another obstacle is detected is limited to a range between the two objects. In this case, of the space in the traveling direction, a rectangular space having a width slightly larger than the width of the vehicle itself (vehicle width W0) is set as a range for detecting another obstacle.
When the vehicle is traveling in the vehicle width traveling mode (second detection mode), a warning sound or a warning light (not shown) is activated, and when traveling in the normal traveling mode (first detection mode), the warning sound or the warning light is not activated. You may do so.

The deceleration area information 79 is information in which an area for detecting the presence of an obstacle is set. In principle, when it is detected that an obstacle exists in the set area, deceleration processing is performed.
However, as will be described later, two obstacles are detected in the traveling direction, and the distance Ws between these obstacles is larger than a predetermined determination width W1. If the vehicle can pass between obstacles without hitting the obstacle, the deceleration process is not performed.
As the deceleration area information 79, for example, one of an obstacle determination area A1 and a vehicle width determination area A2 is set in accordance with the traveling state, as described later.

The vehicle width determination area 80 (A2) is one of the area information set in the deceleration area information 79, and the size of the area is set in advance in accordance with the vehicle width W0 of the autonomous traveling device. .
The vehicle width determination area 80 (A2) is an area in a rectangular space defined by the determination width W1 and the determination depth L1, as shown in FIG.
The determination width W1 is a width in a direction perpendicular to the traveling direction, is set as a width that allows the vehicle to safely travel, and is set and stored in advance as a width longer than the width of the vehicle (vehicle width W0). Is done.
When the vehicle width determination area 80 (A2) is set in the deceleration area information 79, it is determined whether an obstacle or the like exists inside the vehicle width determination area 80.
However, in the following embodiments, the vehicle width determination area A2 is described as a rectangular space area, but is not limited to this shape.
For example, a fan-shaped shape that opens farther in the traveling direction or a shape such as an inverted triangle may be set as the vehicle width determination area A2.

<Description of Information Stored in Storage Unit>
FIG. 7 is an explanatory diagram of main information among the information stored in the storage unit 70.
FIG. 7A shows an example of four pieces of information stored in the storage unit 70, and FIGS. 7B to 7D show explanatory diagrams of these pieces of information.
The deceleration area information 79 (GA) sets an area for detecting an obstacle as described above. In the following embodiment, one of the two areas (A1, A2) is set. Shall be.
The two regions are an obstacle determination region A1 corresponding to the above-described first obstacle determination region and a vehicle width determination region A2 corresponding to the above-described second obstacle determination region.

FIG. 7B shows an example of the obstacle determination area A1.
FIG. 7B is a plan view of the autonomous traveling device 1 as viewed from above, and shows a state in which the autonomous traveling device 1 is traveling upward in the drawing.
In FIG. 7B, a fan-shaped area in front of the autonomous traveling device 1 in the traveling direction is an obstacle determination area A1.
The fan-shaped area is an area determined by the detection angle α and the detection distance L. If an obstacle exists in an area that is opened by an angle of α / 2 in the left-right direction with respect to the traveling direction, Obstacles shall be detected.
Here, the detection angle α is set to an angle within 180 degrees for the sake of explanation, but may be set to an angle of 180 degrees or more, for example, an angle of about 270 degrees. The detection distance L is, for example, about 25 m.
When the later-described operation mode 78 (MD) is the normal traveling mode M1, it is checked whether an obstacle exists inside the obstacle determination area A1.

FIG. 7C shows an embodiment of the vehicle width determination area A2.
In FIG. 7 (c), the vehicle width determination area A2 is an area indicated by oblique lines and is inside the above-described obstacle determination area A1 and has a rectangular shape having a length L1 and a width W1 as illustrated. Area. However, as described above, the shape of the vehicle width determination area A2 is not limited to a rectangle.
The length L1 in the vertical direction (also called the determination depth) is the length in the direction parallel to the traveling direction, and the length in the horizontal direction (also called the vehicle width determination width or the determination width) W1 is perpendicular to the traveling direction. The length in the direction.

The vehicle width determination area A2 is set when an object is detected in the obstacle determination area A1.
The area A2 is a rectangular space in a direction perpendicular to the traveling direction and having a determination width W1 about the center of the vehicle body as a middle point and in the traveling direction.
However, when the mounting position of the LIDAR, which is the distance detecting unit 51, is deviated from the center of the vehicle body, the front rectangular space having the determination width W1 and having the mounting position of the light emitting unit 51a constituting the LIDAR as a middle point, The vehicle width determination area A2 may be used.
When the vehicle goes straight, the front rectangular area shown in FIG. 7C may be used as the vehicle width determination area A2. However, when the vehicle turns right or left, the turning direction corresponds to the turning angle. A rectangular area having a determination width W1 inclined by a predetermined angle may be set as the vehicle width determination area A2.
When the vehicle width determination area A2 is set, that is, when the operation mode MD is the vehicle width traveling mode M2, an obstacle is detected in the rectangular space of the area A2 using the information detected by the obstacle detection unit 57. The vehicle is driven in the traveling direction while confirming whether or not the vehicle is present.

Assuming that the lateral length (vehicle width) of the vehicle 1 is W0, in consideration of the vehicle width W0, the lateral length (determination width) W1 of the vehicle width determination area A2 is such that W1> W0. Is set in advance.
The determination width W1 corresponds to the length of the passage width that allows the vehicle 1 with a vehicle width W0 to travel safely when traveling straight in the traveling direction.
Ideally, if W1 is set slightly larger than W0, the vehicle 1 can run on the road having the passage width W1. Considering that the vehicle 1 shakes left and right due to an error or the like, the determination width W1 is preferably set to be, for example, about 1 m larger than the vehicle width W0.

The determination width W1 and the determination depth L1 of the vehicle width determination area A2 may be stored in the storage unit 70 in advance as the vehicle width determination area information 80.
Further, the vehicle width determination area A2 detects two obstacles located at positions separated by a predetermined distance, and if the distance Ws between the two obstacles is larger than the determination width W1 (Ws> W1), decelerates. This is set in the area information GA.

FIG. 7D shows a state where two obstacles (OB1 and OB2) are detected inside the obstacle determination area A1.
When LIDAR is used as the distance detection unit 51, if it is detected that an obstacle is present inside the area A1, the distance from the vehicle 1 to each obstacle is measured, and two obstacles (OB1, OB2) are detected. The existing position and direction are also obtained.
Therefore, the distance Ws between the two obstacles can be calculated by a predetermined formula by using the acquired information such as the distance and the direction.
If the calculated distance Ws between obstacles is larger than the previously stored determination width W1 (Ws> W1), the vehicle width determination area A2 having the determination width W1 is set in the obstacle determination area A1, and thereafter The vehicle 1 travels without deceleration in the vehicle width traveling mode M2.
The determination width W1, which is the horizontal length of the rectangular space of the area A2, is set so as to be between two obstacles.

In the vehicle width traveling mode M2, the vehicle travels in the traveling direction while checking whether or not an obstacle exists inside the vehicle width determination area A2 in the obstacle determination area A1.
That is, the vehicle travels while checking whether another obstacle exists between the two detected obstacles OB1 and OB2.
If there is no other obstacle in the vehicle width determination area A2 which is a rectangular space ahead in the traveling direction, the vehicle may travel in the traveling direction without decelerating.
On the other hand, when another obstacle is detected in the area A2, the vehicle may decelerate or stop.

As described above, the obstacle information 77 includes the distance to the obstacle, the position, the direction, the size, the distance between obstacles, and the like. Since these pieces of information are acquired while traveling autonomously, they change every moment. I do.
The position of the obstacle is stored, for example, in two-dimensional or three-dimensional spatial coordinates, and the direction may be stored as an angle with respect to the traveling direction, or as information such as left or right with respect to the traveling direction. Is also good.
As the operation mode 78 (MD), a plurality of modes may be set in advance based on the driving conditions, the driving speed, the GPS reception accuracy, and the like. Here, the normal driving mode M1 and the vehicle width driving mode M2 are set. Assume that two modes are set in advance.
The normal traveling mode M1 is a mode in which the vehicle travels at a relatively high speed in a state where no obstacle is detected inside the obstacle determination area A1, and is, for example, a mode in which the vehicle travels at a constant speed of 5 km / h (speed V1 = 5).

The vehicle width travel mode M2 is a mode set when the vehicle width determination area A2 is set as described above, and in principle, the size of the area for detecting an obstacle differs from the normal travel mode M1. A mode in which the vehicle runs at the same speed V1 alone.
That is, when the vehicle width traveling mode M2 is set, two obstacles are detected in the obstacle determination area, but since the distance Ws between the two obstacles is larger than the determination width W1, the vehicle 1 The vehicle travels in the vehicle width determination area A2 between the two obstacles at the same speed V1 as the normal travel mode M1 without decelerating.
However, when a new obstacle is detected in the vehicle width determination area A2, the vehicle is decelerated or stopped.

  The determination width W1 and the determination depth L1 of the information 80 for determining the size of the vehicle width determination area A2 may be fixedly set in advance. Further, the determination width W1 is set in advance as a width that allows the vehicle body to travel safely, but may be set to a value at least larger than the vehicle width W0. However, the set value of the determination width W1 may be changed in consideration of the relationship with the vehicle width W0 and the width of the passage in which the vehicle travels.

<Example of Obstacle Detection>
Several examples of changes in the running state when an obstacle is detected during autonomous running will be described below.
(Example 1)
FIG. 8 shows a first embodiment of the traveling state when traveling in the normal traveling mode.
FIG. 8A shows a case where no obstacle is detected inside the obstacle determination area A1 in the traveling direction when traveling in the normal traveling mode M1.
In this case, the vehicle 1 runs at a constant speed V1 without decelerating.
FIG. 8B shows a case where one obstacle OB1 is detected inside the obstacle determination area A1 in the traveling direction while traveling in the normal traveling mode M1.
It is assumed that the object (obstacle OB1) detected in the obstacle determination area A1 exists in the forward space having the determination width W1 in the traveling direction.
At this time, based on the measured distance Lm to the obstacle OB1 and the position information of the obstacle, if the obstacle OB1 is on the path slightly to the left in the traveling direction but substantially in the traveling direction, the distance Lm to the obstacle is If it is shorter than the distance set in advance as the deceleration start distance, deceleration processing is performed.
That is, when the object OB1 detected in the area A1 exists in the traveling direction space having the determination width W1 including the position where the vehicle is located, if the distance Lm to the object is shorter than the predetermined distance, Perform deceleration processing.

FIG. 8C shows a case where one obstacle OB1 is detected inside the obstacle determination area A1 while traveling in the normal traveling mode M1, and the measured distance Lm to the obstacle OB1 is very small. This shows a case where the length is shortened.
For example, a distance Lx for stopping the vehicle 1 when the vehicle is approached any longer is stored in advance, and the vehicle 1 is stopped when the measured distance Lm to the obstacle OB1 is shorter than Lx.

(Example 2)
FIG. 9 shows a second embodiment of the traveling state when traveling in the normal traveling mode.
FIG. 9A shows that when the vehicle is traveling in the normal traveling mode M1, an obstacle OB1 exists in the left front, but the obstacle OB1 still enters the obstacle determination area A1 in the traveling direction. Not shown.
In this case, since no obstacle is detected in the obstacle determination area A1, the vehicle 1 travels at a constant speed V1 without deceleration.

FIG. 9B shows a state after a predetermined time has elapsed from the traveling state of FIG. 9A.
Here, it is assumed that the presence of the obstacle OB1 is detected because a part of the obstacle OB1 enters the inside of the obstacle determination area A1.
In addition, by acquiring the measurement distance Lm to the obstacle OB1 and the information on the position and direction of the obstacle, the obstacle OB1 is located on the left side of the area A1 and is not on the path in the traveling direction. Suppose that it is confirmed that it exists outside the determination width W1.
Based on the above confirmation contents, even if the vehicle 1 goes straight in the traveling direction, the vehicle 1 does not collide with the obstacle OB1, so that the vehicle 1 continues traveling without deceleration at the constant speed V1.

FIG. 9C shows a state after a predetermined time has elapsed from the traveling state of FIG. 9B.
Here, a case is shown in which the obstacle OB1 is no longer detected inside the obstacle determination area A1.
In other words, even if the vehicle 1 goes straight without deceleration, the obstacle OB1 passes on the left side of the vehicle 1, so that the vehicle 1 does not collide with the obstacle OB1.
Therefore, the vehicle 1 does not decelerate, but continues running at the constant speed V1.

(Example 3)
FIG. 10 shows a third embodiment of the traveling state when traveling in the vehicle width traveling mode.
FIG. 10A illustrates a case where the vehicle 1 is slightly wider than the determination width W1 of the vehicle width determination area A2 and is about to enter a passage having walls on both sides.
Here, for ease of explanation, a case is shown in which the vehicle 1 is about to enter substantially the center of the passage. Further, it is assumed that the width of the passage is substantially constant Ws and Ws> W1.
Assuming that the vehicle 1 is traveling in the normal traveling mode M1 immediately before entering this passage, an obstacle determination area A1 is set as the deceleration area information 79, and there is an obstacle inside the obstacle determination area A1. Run while checking whether or not.

In FIG. 10A, a part of the walls A and B on both sides of the passage enters the obstacle determination area A1, and thus a part of the walls A and B is detected as an obstacle. At this time, the obstacle information 77 as shown in FIG.
For example, the distance between the wall A and the wall B detected as two obstacles (distance Ws between obstacles) is calculated as the width of the passage.
Further, since the positions and directions of the walls A and B are also acquired, it is detected that the walls A and B exist in the left and right directions with respect to the traveling direction, respectively.

Two obstacles (wall A and wall B) are detected, but the distance Ws between the obstacles is larger than the determination width W1, so that the vehicle width determination area A2 is set as the deceleration area information 79, and will be described in the future. It is checked whether or not an obstacle exists inside the vehicle width determination area A2.
That is, the vehicle width determination area A2 determined by the determination width W1 in the direction perpendicular to the traveling direction and the determination depth L1 in the direction parallel to the traveling direction is set in the obstacle determination area A1. You. Further, the operation mode MD is referred to as a vehicle width traveling mode M2.
Here, assuming that the light emitting unit 51a of the distance measuring unit 51 is provided at the center position in front of the vehicle body, the determination width W1 is set to have a length of W1 / 2 in the left-right direction from the center of the vehicle body. You.
However, in the traveling state of FIG. 10A, the vehicle 1 is within the range of the distance Ws between the two walls A and B, and no other obstacle has been detected in the traveling direction yet. Travels in the traveling direction without deceleration.

FIG. 10B illustrates a case where the vehicle 1 is traveling in a passage after a predetermined time has elapsed from the traveling state of FIG. 10A.
Here, it is assumed that the obstacle OB1 exists in the back of the passage, but the obstacle OB1 has not yet been detected in the vehicle width determination area A2.
Therefore, in the traveling state of FIG. 10B, the vehicle 1 continues traveling in the traveling direction without decelerating.

FIG. 10C illustrates a case where an obstacle OB1 is detected inside the vehicle width determination area A2 during traveling in the passage after a predetermined time has elapsed from the traveling state of FIG. 10B. .
In this case, by acquiring the obstacle information 77 of the obstacle OB1, the obstacle OB1 exists on the left side with respect to the traveling direction, the distance to the obstacle OB1 is Lm, and the position is determined by the determination width W1. Is also detected to be inside.
Assuming that distance Lm to obstacle OB1 is smaller than a preset distance to be decelerated, vehicle 1 decelerates and travels in the same traveling direction.
As described above, even if the vehicle enters the narrow passage, if the passage width is wider than the determination width W1 set in consideration of the vehicle width W0, the vehicle may be able to travel without deceleration.

(Example 4)
FIG. 11 shows a fourth embodiment of the traveling state when traveling in the vehicle width traveling mode.
FIG. 11 illustrates a case in which the vehicle does not travel on a path having walls on both sides but passes between two obstacles at positions separated by a predetermined distance or more.
It is assumed that there are two obstacles (OB1, OB2) at positions separated by a distance Ws in the traveling direction of the vehicle. Here, it is assumed that the distance between obstacles Ws> the determination width W1.
In FIG. 11A, it is assumed that two obstacles (OB1, OB2) are detected inside the obstacle determination area A1 while the vehicle 1 is traveling in the normal traveling mode M1.
At this time, the obstacle information 77 of the two obstacles is acquired, and the positions of the two obstacles are on the left and right sides in the traveling direction, and it is detected that the distance Ws between the obstacles is larger than the determination width W1. Then, the operation mode MD is switched to the vehicle width traveling mode M2.

Further, a rectangular vehicle width determination area A2 including the determination depth L1 and the determination width W1 is set in the deceleration area information 79, and thereafter, it is checked whether there is an obstacle inside the area A2.
If the distance Ws between the two obstacles is larger than the determination width W1 (Ws> W1), and the vehicle 1 is traveling near the center of the distance Ws, it does not collide with the obstacles (OB1, OB2). Therefore, the vehicle travels in the traveling direction without deceleration.

In FIG. 11A, the distance between obstacles Ws is shown to be slightly larger than the determination width W1, but Ws may be considerably larger than W1. As described above, when the distance Ws between the obstacles is considerably larger than the determination width W1, the determination width W1 is not used as the lateral length of the vehicle width determination area A2, but the obstacle width is larger than the determination width W1. A width smaller than the inter-object distance Ws may be set.
That is, instead of using the vehicle width determination area A2 in a rectangular space having a fixed vertical and horizontal length as an area for checking for the presence or absence of an obstacle, the area is automatically determined in accordance with the distance Ws between two obstacles. The setting of the lateral length of the vehicle width determination area A2 may be changed.

FIG. 11B illustrates a case where the vehicle 1 further travels in the traveling direction after FIG. Here, it is assumed that the two obstacles (OB1, OB2) have come out of the obstacle determination area A1.
Assuming that the vehicle 1 is traveling at the constant speed V1, the distance to the obstacle (OB1, OB2) has already been measured in the state of FIG. From the and the position information of the obstacle, it is possible to calculate an approximate time when the two obstacles are out of the obstacle determination area A1.
Thereafter, since the two obstacles (OB1, OB2) are no longer detected, the area for detecting the obstacle is returned from the vehicle width determination area A2 to the obstacle determination area A1. That is, the obstacle determination area A1 is set in the deceleration area information 79, and the process returns to the normal traveling mode M1.
Also, in the case of FIG. 11B, the vehicle 1 does not collide with two obstacles, and thus travels in the traveling direction without deceleration.

FIG. 11C shows a case in which the vehicle 1 has traveled in the traveling direction after FIG. 11A and has detected a new obstacle OB3 inside the vehicle width determination area A2. .
At this time, since the obstacle OB3 exists in the vehicle width determination area A2, the vehicle may collide with the obstacle OB3 if the vehicle proceeds as it is.
Therefore, when the obstacle OB3 is detected in the vehicle width determination area A2, the vehicle decelerates.
As described above, even if two obstacles are detected, if the distance Ws between the two obstacles is larger than the predetermined determination width W1 set in consideration of the vehicle width W0, the vehicle does not decelerate. In some cases, the vehicle can run, and when a new obstacle is detected within the range of the determination width W1, the vehicle may be decelerated.

FIG. 11A shows a case where two obstacles are detected in the obstacle determination area A1 during traveling in the normal traveling mode M1. If an obstacle is detected only in the one-sided area on the left or right side of the center of the vehicle in the traveling direction within the area, only the one-sided area on the left or right side where the obstacle is detected has a rectangular shape. The vehicle width determination area A2 may be set.
For example, when one obstacle OB1 is detected only in the left half of the one-way area in the area of the determination width W1 in FIG. 11A, the vehicle width determination area is provided only in the left half of the one-way area. A2 may be set.
Further, at this time, the traveling mode on only the side where the vehicle width determination area A2 is set may be switched to the vehicle width traveling mode M2, and the part that remains in the obstacle determination area A1 may be kept in the normal traveling mode M1.

(Example 5)
FIGS. 12 and 13 show a detailed example in which a vehicle passes between two obstacles.
Here, when the obstacle detection unit 57 detects a plurality of objects (two obstacles in FIG. 12) in the obstacle determination area A1, the plurality of objects are respectively moved in different directions with respect to the traveling direction. A case where there is a distance Ws between a plurality of objects that is larger than the determination width W1 will be described.
In this case, a rectangular space having a determination width W1 or a rectangular space having a width larger than the determination width W1 and smaller than the inter-object distance Ws is set between a plurality of objects, and an obstacle exists in the rectangular space. The vehicle is driven in the traveling direction while confirming whether or not to perform the operation.

FIG. 12A shows a case where the vehicle 1 is traveling at a constant speed in the normal traveling mode M1. In this state, it is checked whether or not an obstacle exists in the obstacle determination area A1.
In FIG. 12A, it is assumed that two obstacles (OB1 and OB2) are present at a distance Ws forward in the traveling direction. Here, it is assumed that the distance Ws between obstacles is larger than the determination width W1 (Ws> W1).
It is also assumed that the traveling direction of the vehicle 1 is near the center of the distance Ws between the two obstacles.
Assuming that these two obstacles (OB1, OB2) have not yet been detected inside the obstacle determination area A1, the vehicle 1 continues running at a constant speed without decelerating.

FIG. 12B shows a state after a predetermined time has elapsed from the traveling state of FIG.
Here, it is assumed that a part of the two obstacles (OB1, OB2) enters the obstacle determination area A1, and the presence of the two obstacles is detected. In this case, the distance, position, and direction to the two obstacles, the distance Ws between the two obstacles, and the like are acquired and stored as the obstacle information 77.
From these acquired information, the two obstacles (OB1 and OB2) are on the left and right sides with respect to the traveling direction, respectively, and the distance Ws between the obstacles is larger than the determination width W1. It can be seen that the vehicle is traveling near the center between two obstacles.

In FIG. 12B, although two obstacles are detected, the distance Ws between the obstacles is larger than the determination width W1, and the vehicle 1 travels near the center between the two obstacles. Since the vehicle has not yet collided with an obstacle, the vehicle travels in the traveling direction without deceleration.
Therefore, since two obstacles separated by the predetermined determination width W1 or more are detected, the operation mode MD is switched to the vehicle width traveling mode M2 as shown in FIG.
Further, a vehicle width determination area A2 having a determination width W1 and a determination depth L1 is set in the deceleration area information 79, and it is determined whether or not an obstacle exists in a rectangular area A2 between the two obstacles. While moving the vehicle body in the traveling direction.

  FIG. 12C shows the same state as the traveling state in FIG. 11A, but in the traveling state in FIG. 12C, no obstacle is detected inside the vehicle width determination area A2. Therefore, the vehicle continues traveling in the traveling direction without deceleration.

Next, FIG. 13A shows the same state as that shown in FIG. 11B.
That is, when a predetermined time has elapsed from the state of FIG. 12C, the state of FIG. It is no longer detected in A1.
In this case, since the two obstacles are no longer detected, the area for detecting the obstacle is returned from the vehicle width determination area A2 to the obstacle determination area A1, as shown in FIG. The mode MD is switched to the normal traveling mode M1.
That is, the obstacle determination area A1 is set in the deceleration area information 79.
Also in the case of FIG. 13A and FIG. 13B, since the vehicle does not collide with the two obstacles (OB1, OB2), the vehicle 1 continues traveling in the traveling direction without decelerating. .

FIG. 13C shows a running state after a predetermined time has elapsed from the running state of FIG. 13B.
The two obstacles (OB1, OB2) are almost right beside the vehicle 1, and the vehicle 1 passes between the two obstacles.
Also in this case, if no new obstacle is detected in the obstacle determination area A1, the vehicle continues running without decelerating.
As described above, in a case where two obstacles exist at an interval larger than the determination width W1 ahead of the traveling direction and the vehicle 1 travels substantially in the center between the obstacles, the vehicle 1 Can pass between two obstacles without slowing down.

FIG. 18 is a flowchart illustrating an example of the obstacle detection and the travel control illustrated in FIGS. 12 and 13.
In this flowchart, as shown in FIGS. 12 and 13, when the distance Ws between two obstacles found inside the obstacle determination area A1 is wider than a predetermined vehicle width determination width W1, the principle is as follows. Then, the vehicle continues traveling without decelerating, sets the vehicle width determination area A2 in the obstacle determination area A1, and checks whether an obstacle exists in this area A2.

In steps S1 to S4 in FIG. 18, initialization is performed.
First, in step S1, the control unit 50 reads the route information 74 from the storage unit 70, and recognizes the route to be traveled.
In step S2, an obstacle determination area A1 is set in the deceleration area information GA79 of the storage unit 70 (GA = A1).
As a result, as shown in FIGS. 5 and 7B, the fan-shaped area is set as an area for checking for the presence or absence of an obstacle.

In step S3, the normal traveling mode M1 is set as the operation mode MD of the storage unit 70 (MD = M1). As a result, the vehicle travels at a constant speed in principle along the route indicated by the route information while detecting the presence or absence of an obstacle in the deceleration region GA set in the deceleration region information 79.
In step S4, the fixed speed information V stored in the storage unit 70 is set to a fixed normal speed V1 (V = V1). For example, V1 = 5 km / hour is set.

After the initial setting, the travel control unit 52 controls the wheels 53 to autonomously travel on the route at the speed of the set speed information V in step S5.
When the vehicle is traveling autonomously, it also performs distance detection processing by the distance detection unit 51, image shooting by the camera 55, image recognition processing of input image data, speed detection processing, monitoring information acquisition processing, and the like.
In step S6, the obstacle detection unit 57 checks whether or not an obstacle exists inside the deceleration area GA.
Here, when the presence of an obstacle is detected, obstacle information 77 such as the position, direction, and distance of the detected obstacle is acquired and stored as described above.

In step S7, if there is an obstacle in the deceleration area GA, the process proceeds to step S14, and if not, the process proceeds to step S8.
In step S8, since the obstacle has not been detected yet, the set speed information V is kept at the normal speed V1.
In step S9, the current operation mode MD stored in the storage unit 70 is checked.
When the operation mode MD is the normal traveling mode M1, the process returns to step S5.
When the operation mode MD is the vehicle width traveling mode M2, the process proceeds to step S10.
In step S10, it is checked whether an obstacle exists inside the obstacle determination area A1.
In step S11, if there is an obstacle in the obstacle determination area A1, the process returns to step S5; otherwise, the process proceeds to step S12.

In step S12, since no obstacle has been detected, an obstacle determination area A1 is set in the deceleration area GA as in step S2 (GA = A1).
In step S13, as in step S3, the normal traveling mode M1 is set as the operation mode MD (MD = M1).
Then, the process returns to step S5.

In step S14, since an obstacle is detected, it is checked whether there is an obstacle within the vehicle width determination width W1 in a direction perpendicular to the traveling direction. This vehicle width determination width W1 corresponds to the lateral length of the vehicle width determination area A2 shown in FIG.
For example, using the obstacle information 77 as shown in FIG. 7A acquired for the detected obstacle, it is checked whether the obstacle exists in W1.
When two or more obstacles are detected, the distance Ws between the obstacles is calculated, and it is checked whether Ws is greater than W1.
If there is no obstacle within the vehicle width determination width W1, the process proceeds to step S15, and if there is an obstacle, the process proceeds to step S18.

In step S15, since there is no obstacle in the determination width W1 of the traveling direction, it is determined that there is no problem if the vehicle travels without deceleration. (V = V1).
In step S16, an obstacle has been detected, but there is no obstacle in the determination width W1. Therefore, in order to limit the area in which the obstacle is detected within the determination width W1, the vehicle is included in the deceleration area information GA. The width determination area A2 is set (GA = A2).
In step S17, the vehicle width traveling mode M2 is set as the operation mode MD (MD = M2). Then, the process returns to step S5.
When the setting in steps S15 to S17 is performed, an obstacle is detected, but as shown in FIGS. 12B and 12C, the obstacle is not included in the determination width W1 of the traveling direction. Is not detected yet, so that the vehicle continues traveling forward without deceleration.

In step S18, since there is an obstacle in the determination width W1 of the traveling direction of the vehicle, for example, as shown in FIG. First, it is checked whether or not the distance Lm to the obstacle in the acquired obstacle information 77 is smaller than a preset stop determination distance Lp.
If Lm <Lp, the process proceeds to step S20; otherwise, the process proceeds to step S19.
In step S19, since the distance Lm to the obstacle is still longer than the stop determination distance Lp, the slow speed V2 (<V1) lower than the normal speed V1 is set in the set speed information V, and the speed is reduced (V = V2). Then, the process returns to step S5.
On the other hand, in step S20, since Lm <Lp, it is determined that the distance Lm to the obstacle is quite short, and the traveling is stopped. Thereafter, the process may return to step S5, or wait for an instruction from a person in charge of controlling the vehicle or a user.

In this flowchart, as shown in FIG. 12 and FIG. 13, the vehicle travels mainly between two obstacles located at a position separated by a distance wider than the vehicle width determination width W1 and substantially near the center therebetween. If so, continue running without decelerating.
If the vehicle does not travel near the center between the two obstacles, traveling control as in the sixth embodiment described below may be performed.

(Example 6)
FIGS. 14 and 15 show a case where the vehicle passes between two obstacles, travels on a route close to one of the obstacles, and approaches the obstacle.
Here, a case where two objects are detected in the obstacle determination area A1, the distance Ws between the two objects is larger than the determination width W1, and the traveling direction and the position of the vehicle body are adjusted. ,explain.
For example, the stationary rotation of the vehicle body and the movement in a predetermined direction are performed so that the traveling direction of the vehicle body is perpendicular to the direction of the distance Ws between the two objects, and the vehicle body passes through substantially the center between the two objects. By doing so, the traveling direction and the position are adjusted.

FIG. 14A illustrates a case where the vehicle 1 is traveling at a constant speed in the normal traveling mode M1.
In the running state of FIG. 14A, it is checked whether or not an obstacle exists in the obstacle determination area A1 set in the deceleration area GA, but an obstacle is still detected in this area A1. I do not decelerate and drive without deceleration.
Further, two obstacles (OB1, OB2) separated by a distance Ws (> W1) are present ahead of the traveling direction of the vehicle 1, and the vehicle 1 travels on a path closer to the left obstacle OB1. Shall be
Here, if the vehicle 1 keeps traveling in such a traveling direction, it is assumed that there is a possibility that one obstacle OB1 is detected and the vehicle collides with the obstacle OB1.

FIG. 14B shows a case where a predetermined time has elapsed from the traveling state of FIG. 14A.
Here, it is assumed that one obstacle OB1 is detected inside the obstacle determination area A1 in a slightly leftward direction in the traveling direction of the vehicle.
When the obstacle OB1 is detected, the obstacle information 77 corresponding to the obstacle OB1 is obtained.
For example, the distance Lm to the obstacle OB1, the position, the direction, the size, and the like of the obstacle OB1 are acquired.
Based on the obstacle information 77, the obstacle OB1 is located slightly to the left in the traveling direction of the vehicle 1, and the determination width W1 in the vertical direction (the horizontal direction on the paper) of the traveling direction with the center of the vehicle 1 as the center. Suppose that it is confirmed that it is inside.
In this case, if the vehicle 1 continues to travel as it is, it is determined that there is a possibility of collision with the obstacle OB1, and the vehicle 1 is moved as shown in FIG.

FIG. 14C shows a case where after the vehicle shown in FIG. 14B, the vehicle 1 stops at the current position and then changes its stationary direction rightward (rotates rightward). For example, rotate right by 90 degrees.
Thereafter, the vehicle 1 moves a predetermined distance to the right without the detected obstacle OB1.
In this state, since the existence of another obstacle OB2 has not been detected yet, it is not possible to move in consideration of the distance Ws between the two obstacles OB1 and OB2 as the predetermined distance. Therefore, the predetermined distance may be, for example, a distance of W0 / 2.
After moving to the right by a predetermined distance, the vehicle 1 stops, rotates 90 degrees to the left, and turns so as to face the same direction as the initial traveling direction. After turning, the vehicle moves forward in the traveling direction.
If the predetermined distance moved rightward is short, and only the obstacle OB1 is detected by moving forward and the distance to the obstacle OB1 is shortened, deceleration or stopping may be performed.
Further, even when only a different obstacle OB2 is detected by moving forward because the predetermined distance moved rightward is long, deceleration or stop may be performed.

FIG. 15A illustrates an example of a traveling state in which the vehicle has moved forward after rotating to the left at a fixed position after FIG. 14C.
Here, the vehicle 1 is traveling in the normal traveling mode, and shows a case where two obstacles (OB1, OB2) are detected in the obstacle determination area A1.
Further, it is assumed that the vehicle 1 starts traveling near the center of the distance Ws between the two obstacles (OB1, OB2).
Further, it is assumed that it is detected that the distance Ws between the obstacles is larger than the determination width W1 by acquiring the obstacle information 77 of the two obstacles.
In this case, Ws> W1, and the vehicle 1 travels substantially at the center between the two obstacles. Therefore, it is determined that the vehicle 1 does not collide with either of the two obstacles even if it travels as it is. As shown in FIG. 15 (b), the mode is switched to the vehicle width traveling mode M2, and traveling is continued without deceleration.

  Further, a vehicle width determination area A2 included in the obstacle determination area A1 is set in the deceleration area information GA, and the vehicle travels while checking whether or not a new obstacle exists in the area A2. If there is no obstacle in this area A2, the vehicle continues traveling without decelerating.

FIG. 15C shows a case where the vehicle is traveling in the vehicle width traveling mode M2 after FIG. 15B.
Here, a case is shown in which the vehicle 1 further advances from the traveling state of FIG. 15B, and there is no obstacle in the vehicle width determination area A2, and no obstacle is detected in the obstacle determination area A1. I have.
Since no obstacle is detected in any of the two areas A1 and A2, thereafter, the mode is switched to the normal traveling mode M1, the setting of the vehicle width determination area A2 is released, and the obstacle determination area is included in the deceleration area information GA. A1 is set to continue traveling in the traveling direction without deceleration.

  As described above, after one obstacle has been detected and moved to change the traveling direction, when two obstacles having an interval larger than the determination width W1 are detected ahead of the traveling direction, the two obstacles are detected. When the vehicle 1 can travel between the obstacles, the vehicle 1 passes between the two obstacles without decelerating. This reduces unnecessary deceleration processing and travels to avoid stopping, so that it is possible to avoid obstacles and continue traveling.

FIG. 19 is a flowchart illustrating an example of the obstacle detection and the travel control illustrated in FIGS. 14 and 15.
In FIG. 19, as compared with FIG. 18, when an obstacle is detected in one direction, processing for moving the traveling direction by stationary rotation or the like is added.
The same steps as those in FIG. 18 are denoted by the same step numbers, and description thereof is omitted.
The initial settings in steps S1 to S4 and the series of processes in steps S5 to S17 are the same as those in FIG.
If it is determined in step S14 that there is an obstacle within the determination width W1 in the traveling direction, the process proceeds to step S31. This state is, for example, a running state as shown in FIG.

In step S31, the direction of the detected obstacle is checked.
Here, the direction of the obstacle is confirmed based on the distance to the obstacle acquired by the LIDAR, which is the distance detection unit 51, and the obstacle information 77 including position information and the like.
For example, in the case of FIG. 14B, only one obstacle is detected, and it is determined that the obstacle is on the left side of the traveling direction.

In step S32, it is determined whether the detected obstacle exists only in one direction or in both directions with respect to the traveling direction.
Here, one direction means only the left direction of the traveling direction or only the right direction of the traveling direction. If an obstacle exists only in one direction, the obstacle is located on either the left side or the right side. It means that an object exists.
In addition, the case where obstacles exist in both directions means a state in which an obstacle exists in the left direction in the traveling direction and an obstacle also exists in the right direction in the traveling direction. Are present in the left and right directions of the traveling direction separated by a distance of. However, even when one large obstacle having a width equal to or larger than the determination width W1 exists in the entire front including the left and right sides in the traveling direction (for example, when there is a wall in front), it is determined that the obstacle exists in both directions. Judge.

If it is determined in step S32 that an obstacle exists only in one direction, the process proceeds to step S33. If an obstacle exists in both directions, the process proceeds to step S18.
In step S33, the vehicle 1 is moved by a predetermined distance in a direction without the detected obstacle in order to avoid colliding with the obstacle.
For example, as shown in FIG. 14B, when the obstacle OB1 exists only in the left direction in the traveling direction, as shown in FIG. 14C, the vehicle 1 is moved in the right direction without the obstacle. Move.
Here, when the vehicle 1 is moved, first, the vehicle 1 is temporarily stopped, fixedly rotated at the stopped position (in the case of FIG. 14C, rotated rightward by 90 degrees), and then travels a predetermined distance in the forward direction. Then, the rotation may be reverse to the above-mentioned stationary rotation so as to face the same direction as the original traveling direction.
The predetermined distance traveled in the forward direction may be determined, for example, by a random value up to W1, or may be set to W0 / 2 in advance and stored in the storage unit 70 in advance.
By such a movement, for example, after traveling a predetermined distance to the right from the traveling state of FIG. 14 (c), turning 90 degrees to the left and returning to the original traveling direction, Resume normal driving.
After step S33, the process returns to step S5, and the autonomous traveling is continued at a position where the traveling direction is the same as the original traveling direction and is shifted by a predetermined distance in a direction without any obstacle.
Steps other than the above-described steps S31 to S33 are the same as those in FIG.

  By performing the above-described processing, even when the vehicle is initially traveling toward one obstacle as shown in FIG. At this time, it is necessary to decelerate and stop, but in other traveling states, it is possible to travel without decelerating. In particular, as shown in FIG. Between the vehicles without deceleration.

(Example 7)
FIGS. 16 and 17 show a case where there are two obstacles separated by a predetermined distance, and a case where the two obstacles are approached from a direction closer to one of the obstacles.
FIG. 16A shows a case in which the vehicle 1 travels at a constant speed in the normal traveling mode M1, and approaches two obstacles from a direction close to the obstacle OB1.
Here, it is assumed that the traveling direction of the vehicle 1 is not perpendicular to the line connecting the two obstacles (OB1 and OB2) but is slightly inclined to the right.
Further, the distance Ws between the two obstacles is assumed to be larger than the determination width W1. The vehicle 1 travels without deceleration until an obstacle is detected in the obstacle determination area A1.

FIG. 16B shows a case where a predetermined time has elapsed from the traveling state of FIG. 16A.
In FIG. 16B, it is assumed that one obstacle OB1 is detected in the obstacle determination area A1.
At this time, the distance Lm1 to the obstacle OB1 and the position, direction, size, and the like of the obstacle OB1 are acquired and stored in the storage unit 70.
In the case of FIG. 16B, it is recognized that one obstacle OB1 exists in a position on the left side of the traveling direction and at a distance Lm1.
Here, as shown in FIGS. 20 and 21 described later, the direction of the detected obstacle OB1 is set and stored in the obstacle direction information SD that stores the direction in which the obstacle exists.
In the case of FIG. 16B, for example, information “left” is stored in the obstacle direction information SD.
In the initial stage in which it is detected that the obstacle OB1 has entered the area A1, the distance Lm1 to the obstacle OB1 is sufficiently long. Continue running without deceleration. Thereafter, the vehicle 1 further approaches the obstacle OB1.

FIG. 16C shows a state in which the vehicle travels further in the traveling direction in the normal traveling mode M1 after the operation shown in FIG. This shows a case where OB2 is detected.
In FIG. 16C, when two obstacles (OB1, OB2) are detected, obstacle information 77 is obtained, and based on the information 77, the obstacle OB1 exists in the left direction in the traveling direction. The obstacle OB2 is determined to be present on the right side in the traveling direction. That is, it can be seen that obstacles exist in both directions with respect to the traveling direction of the vehicle.

Although not shown in FIG. 16 (c), if the vehicle 1 travels a little further in the traveling direction, a new obstacle is set in the area of the determination width W1 in the direction perpendicular to the traveling direction of the vehicle. OB2 may be detected in some cases. Also in this case, it is determined that the obstacle exists in both directions with respect to the traveling direction of the vehicle.
Further, the distance Ws between the two obstacles is calculated from the position information of the two obstacles, and the angle between the traveling direction of the vehicle 1 and the direction of the distance Ws between the two obstacles is also calculated.
In the case of FIG. 16C, the angle between the traveling direction and the direction of the distance Ws is not vertical, and the vehicle 1 is slightly oblique to the direction of the distance Ws from the two obstacles (OB1, OB2). ).

In this case, it is recognized that the two obstacles (OB1, OB2) are present at an interval Ws larger than the determination width W1 in both the left and right directions with respect to the traveling direction of the vehicle 1.
Therefore, as shown in FIG. 17A, the vehicle is temporarily stopped, fixedly rotated in a direction in which an obstacle having a longer distance to the obstacle exists, and moves by a predetermined distance.
In the case of FIG. 16C, since the distance Lm2 to the obstacle OB2 is longer than the distance Lm1 to the obstacle OB1 (Lm2> Lm1), as shown in FIG. And rotate forward to the right.

On the other hand, if the distance Lm1 to the obstacle OB1 is longer than the distance Lm2 to the obstacle OB2 (Lm1> Lm2) at the current position of the vehicle, the vehicle is stationaryly rotated leftward and leftward. You only have to go forward.
Here, the angle of the stationary rotation may be an angle such that the traveling direction after the rotation is parallel to the direction of the distance Ws between the two obstacles.
The distance moved after the stationary rotation may be determined by the distance of W0 / 2, as in the sixth embodiment.

As shown in FIG. 17 (a), after stationary rotation to the right and moving to the right by a predetermined distance, stationary rotation to the left (90 ° left rotation) in the opposite direction, the traveling direction of the vehicle 1 is changed by two obstacles. The direction is perpendicular to the distance Ws between objects.
By performing such stationary rotation and movement, the vehicle 1 can pass between the two obstacles at a substantially central position of the distance Ws between the two obstacles.

FIG. 17B shows a case in which, after FIG. 17A, the stationary left rotation is performed, and the vehicle travels in the new traveling direction (upward on the paper) in the normal traveling mode M1.
In this running state, a case where two obstacles (OB1, OB2) are detected in the obstacle determination area A1 is shown.
This corresponds to the traveling state shown in FIG.
Therefore, thereafter, the operation mode MD may be switched to the vehicle width traveling mode M2, the vehicle width determination area A2 may be set to the deceleration area GA, and traveling control may be performed as described with reference to FIG.

In FIG. 17C, the mode is switched to the vehicle width traveling mode M2, and a vehicle width determination area A2 having a determination width W1 shorter than the obstacle distance Ws is set as in FIG. The vehicle travels in the traveling direction without decelerating while checking whether a new obstacle exists.
After FIG. 17C, the traveling control may be performed in the same manner as shown in FIGS. 13A to 13B.
As described above, when there are two obstacles that are separated from each other by the predetermined determination width W1 or more, the vehicle approaches the obstacle from a slightly slanted direction with respect to the direction of the distance Ws between the two obstacles. If two obstacles are detected, after the two obstacles are detected, the position and the traveling direction of the vehicle are changed by rotating and moving the vehicle at a fixed position. Can be passed without deceleration.

20 and 21 show flowcharts of an example of the obstacle detection and traveling control shown in FIGS. 16 and 17.
In FIGS. 20 and 21, compared to FIG. 18, a process for performing new driving control is added when an obstacle is detected in one direction and when an obstacle is detected in both directions.
The same steps as those in FIG. 18 are denoted by the same step numbers, and description thereof is omitted.

In this flowchart, the obstacle direction information SD is newly defined and stored in the storage unit 70.
The obstacle direction information SD stores, when an obstacle is detected, the direction in which the obstacle exists with respect to the traveling direction of the vehicle. Using this information SD or the like, the direction to change direction is determined.
For example, when an obstacle exists in the right direction with respect to the traveling direction, information “right” is stored in the SD, and when an obstacle exists in the left direction, information “left” is stored in the SD. If there is no obstacle, information indicating no obstacle may be stored in the SD.

20, steps S1 to S8 are the same as those in FIG.
If no obstacle is detected, the process proceeds to step S41 after step S8.
In step S41, information indicating "no obstacle" is set and stored in the obstacle direction information SD. Thereafter, the process proceeds to step S9, and the same processing as in FIG. 18 is performed from step S9 to S14.
In step S14 of FIG. 21, it is checked whether or not an obstacle exists within the vehicle width determination width W1 in the direction perpendicular to the traveling direction. If an obstacle exists, the process proceeds to step S45, where the obstacle is detected. If not, the process proceeds to step S42.

In step S42, the direction in which the detected obstacle exists is checked.
Here, using the obstacle information 77 of the detected obstacle, it is checked whether the position of the obstacle exists on the left side, the right side, or both directions with respect to the traveling direction. You. If there is only the left side or only the right side, it is determined that it exists only in one direction.
In step S43, if the checked direction of the obstacle is only one direction, the process proceeds to step S44, and if it is both directions, the process proceeds to step S15.
In step S44, the direction in which the checked obstacle exists is set and stored in the obstacle direction information SD. For example, “left” or “right” is set in SD. Then, the process returns to step S5.

In step S45, since it is detected that an obstacle exists within the determination width W1, the direction in which the obstacle exists is checked.
That is, similarly to step S42, it is checked whether an obstacle exists in only one direction or an obstacle exists in both directions with respect to the traveling direction.
In step S46, when there is an obstacle in only one direction set in the obstacle direction information SD, the process proceeds to step S18. On the other hand, if there are obstacles in both directions, the process proceeds to step S47.

In step S47, the traveling direction of the vehicle is changed.
Here, for example, as shown in FIG. 17A, the vehicle is fixedly rotated and moved, and the vehicle is rotated by a predetermined angle in the direction indicated by the obstacle direction information SD or in the opposite direction. Change the direction of travel of the vehicle.
For example, as described above, the distance to the two obstacles is compared, and the stationary rotation and the movement are performed in the direction approaching the obstacle with the longer distance. Thus, as shown in FIG. 17B, the traveling direction and the traveling position of the vehicle are changed. Then, the process returns to step S5.

Steps other than the above-described steps S41 to S47 are the same as those in FIG.
By performing the above processing, as shown in FIG. 16, even when the traveling direction of the vehicle is not perpendicular to the direction of the distance Ws between the two obstacles, the distance to the two obstacles and the obstacle By checking the position, direction, etc. of the vehicle, it is possible to pass between two obstacles located at positions separated by the determination width W1 or more without decelerating except for the deceleration processing at the time of turning. become.

Reference Signs List 1 autonomous traveling device, 2 monitoring unit, 3 control unit, 5 management server, 6 network, 10 body, 12R right side, 12L left side, 13 front, 14 rear, 15 bottom, 16 housing space, 18 cover, 21 front wheel, 21a axle, 21b sprocket, 22 rear wheel, 22a axle, 22b sprocket, 23 belt, 31 front wheel, 31a wheel, 31b sprocket, 32 rear wheel, 32a wheel, 32b sprocket, 33 belt, 40 battery, 41R electric motor, 41L electric motor Motor, 42R motor shaft, 42L motor shaft, 43R gearbox, 43L gearbox, 44R bearing, 44L bearing, 47 front bumper, 47a outer surface base material, 47b elastic member, 47c, 47d, 47e mounting base material, 48 rear bumper, 49 pressure-sensitive switch, 50 control unit, 51 distance detecting unit (LIDAR), 51a light emitting unit, 51b light receiving unit, 51c scanning control unit, 51d laser, 52 running control unit , 53 wheels, 54 communication section, 55 camera, 56 image recognition section, 57 obstacle detection section, 58 position information acquisition section, 59 rechargeable battery, 60 speed detection section, 61 monitoring information acquisition section, 70 storage section, 71 input image Data, 72 measured distance information, 73 current position information, 74 route information, 75 transmission monitoring information, 76 set speed information, 77 obstacle information, 78 operation mode, 79 deceleration area information, 80 vehicle width judgment area, 91 communication section, 92 monitoring control unit, 93 storage unit, 93a reception monitoring information, 10 Object

Claims (5)

The body and
A travel control unit that controls a drive member that drives the vehicle body,
A predetermined light is emitted to a predetermined first obstacle determination area including a forward space in the traveling direction, and a light reflected by an object present in the first obstacle determination area is received, and the light is reflected to the object. A distance detector for detecting the distance of
An obstacle detection unit that detects a position of the object whose distance has been detected in the first obstacle determination area, and a direction with respect to a traveling direction of a position where the object is present,
A storage unit configured to store a determination width W1 that is set as a width that allows the vehicle body to travel safely and that is longer than the width of the vehicle body, and a control unit;
A first detection mode in which the distance detection unit detects a distance to an object in the first obstacle determination area;
A second detection mode included in the first obstacle determination area and detecting a distance to an object in a second obstacle determination area having a width in a direction perpendicular to a traveling direction and having the determination width W1;
When the obstacle detection unit detects the object OB1 in the first obstacle determination area while the vehicle body is traveling in the first detection mode, the control unit may change the second detection mode from the first detection mode to the second detection mode. After switching the detection mode to the detection mode, while confirming whether or not an obstacle is present in the second obstacle determination area, the vehicle is driven in the traveling direction ,
If the vehicle body does not detect an obstacle in the second obstacle determination area while traveling in the second detection mode, the vehicle travels in the traveling direction without decelerating, and moves in the second obstacle determination area. The autonomous traveling device , wherein the traveling control unit performs a deceleration process when an object is detected . The body and
A travel control unit that controls a drive member that drives the vehicle body,
A predetermined light is emitted to a predetermined first obstacle determination area including a forward space in the traveling direction, and a light reflected by an object present in the first obstacle determination area is received, and the light is reflected to the object. A distance detector for detecting the distance of
An obstacle detection unit that detects a position of the object whose distance has been detected in the first obstacle determination area, and a direction with respect to a traveling direction of a position where the object is present,
A storage unit configured to store a determination width W1 that is set as a width that allows the vehicle body to travel safely and that is longer than the width of the vehicle body, and a control unit;
A first detection mode in which the distance detection unit detects a distance to an object in the first obstacle determination area;
A second detection mode that is included in the first obstacle determination area and detects a distance to an object in a second obstacle determination area having a width set in a direction perpendicular to the traveling direction;
When the obstacle detection unit detects a plurality of objects in the first obstacle determination area while the vehicle body is traveling in the first detection mode,
When a plurality of objects are present in different directions with respect to the traveling direction, and the distance Ws between the plurality of objects is larger than the determination width W1,
The control unit may include, between the plurality of objects, a second obstacle determination area having the determination width W1 included in the first obstacle determination area, or a distance Ws between the objects greater than the determination width W1. Also sets a second obstacle determination area having a small width,
After switching the detection mode from the first detection mode to the second detection mode,
Moving the vehicle body in the traveling direction while checking whether an obstacle exists in the second obstacle determination area,
If the vehicle does not detect an obstacle in the second obstacle determination area while traveling in the second detection mode, the vehicle travels in the traveling direction without decelerating, and moves in the second obstacle determination area. If it detects an object, the cruise control unit is autonomous traveling unit you and performs deceleration processing. In a case where two objects in which the distance Ws between the objects is larger than the determination width W1 are detected in the first obstacle determination area, the control unit determines whether the traveling direction of the vehicle body is equal to the distance Ws between the two objects. 3. The autonomous traveling apparatus according to claim 2 , wherein the traveling direction and the position of the vehicle body are adjusted so that the vehicle body is perpendicular to the direction and the vehicle body passes substantially in the center between the two objects. When the vehicle body passes by the side of the object OB1 that has caused the switch from the first detection mode to the second detection mode and the object OB1 is no longer detected in the first obstacle determination area, The autonomous traveling device according to claim 1, wherein the detection mode is switched from the two detection modes to the first detection mode. While traveling in the second detection mode, activate a warning sound or a warning light,
The autonomous traveling device according to any one of claims 1 to 4 , wherein the warning sound or the warning light is not activated while traveling in the first detection mode.

Images