阅读说明：本技术 行驶控制装置、车辆和行驶控制方法 (Travel control device, vehicle, and travel control method ) 是由 长岛正明 松永英树 后藤建 町田巧 鹰野聪明 于 2017-12-01 设计创作，主要内容包括：本发明提供一种能够考虑用户目的地的适宜性的行驶控制装置、车辆和行驶控制方法。行驶控制装置(12)从周围环境检测部获取周围环境信息。而且,行驶控制装置(12)根据与用户目的地(Putar)有关的周围环境信息来判定用户目的地(Putar)是否适合停车。并且,行驶控制装置(12)在判定为用户目的地(Putar)不适合停车的情况下使车辆(10)在错开用户目的地(Putar)的修正目的地(Pcor)停车。(The invention provides a travel control device, a vehicle and a travel control method capable of considering the suitability of a user destination. A travel control device (12) acquires ambient environment information from an ambient environment detection unit. The travel control device (12) determines whether or not the user destination (Putar) is suitable for parking based on the surrounding environment information relating to the user destination (Putar). When it is determined that the user destination (Putar) is not appropriate for parking, the travel control device (12) causes the vehicle (10) to park at a correction destination (Pcor) that is offset from the user destination (Putar).)

1.A travel control device (12) that automatically travels a vehicle (10) on at least a portion of a road up to a user destination entered by a user through a destination entry portion,

it is characterized in that the preparation method is characterized in that,

the travel control device (12) also performs the following control:

ambient environment information is acquired from an ambient environment detection unit, whether the user destination is suitable for parking is determined on the basis of the ambient environment information on the user destination, and the vehicle (10) is parked at a correction destination shifted from the user destination when it is determined that the user destination is not suitable for parking.

2. The running control apparatus (12) according to claim 1,

when it is determined that the user destination is not suitable for parking, the travel control device (12) causes the vehicle (10) to park by using, as the correction destination, a point on the same lane (304a) as the user destination that is farther from or closer to the user destination.

3. The running control apparatus (12) according to claim 1,

when it is determined that the user destination is not suitable for parking, the travel control device (12) causes the vehicle (10) to park by using, as the correction destination, a point on a lane (312a) facing the same section (320) as the user destination, the point being on the far side or the front side of the user destination.

4. The running control apparatus (12) according to claim 3,

when it is determined that the user destination is not suitable for parking, the travel control device (12) causes the vehicle to make a left turn or a right turn after passing through the user destination, and causes the vehicle (10) to park by using, as the correction destination, a point on a lane (312a) facing the same section (320) as the user destination and on the farther side than the user destination.

5. The running control apparatus (12) according to any one of claims 1 to 4,

when it is determined that the user destination is not suitable for parking, the travel control device (12) notifies the vehicle (10) of the travel to the corrected destination shifted from the user destination by a notification section.

6. The running control apparatus (12) according to any one of claims 1 to 5,

when it is determined that the user destination is located within an intersection (306), a railroad crossing, or a construction area, or around any of these points, the travel control device (12) stops the vehicle (10) by using, as the correction destination, a point that is offset from any of the intersection (306), the railroad crossing, and the construction area, or around any of these points.

7. The running control apparatus (12) according to any one of claims 1 to 6,

when it is determined that another vehicle (300) is in a stopped state at or around the user destination, the travel control device (12) stops the vehicle (10) in front of or behind the other vehicle (300).

8. A vehicle (10) characterized in that,

the vehicle (10) comprising the running control apparatus (12) according to any one of claims 1 to 7 and an automatic door (110l),

when it is determined that the user destination is not suitable for parking, the travel control device (12) causes the vehicle (10) to park at the corrected destination shifted from the user destination, and automatically opens the automatic door (110 l).

9. A running control method characterized in that,

comprises a destination reception step, an information acquisition step, and an automatic travel step, wherein,

the user destination receiving step is a step of receiving a user destination from a user at a destination input unit;

the information acquisition step is a step of acquiring ambient environment information from an ambient environment detection unit;

the automatic travel step is a step in which the travel control device (12) automatically travels the vehicle (10) on at least a part of the road to the user destination,

in the automatic traveling step, it is determined whether the user destination is suitable for parking based on the surrounding environment information on the user destination, and the vehicle (10) is parked at a corrected destination shifted from the user destination when it is determined that the user destination is not suitable for parking.

Technical Field

The present invention relates to a travel control device, a vehicle, and a travel control method for automatically traveling a vehicle on at least a part of a road to a destination.

Background

International publication No. 2011/158347 (hereinafter referred to as "WO 2011/158347 a 1") aims to provide a driving assistance device (0008, abstract) that is easy to operate by feel without giving a driver a sense of discomfort. In order to achieve this object, in WO 2011/158347 a1, when execution of automated driving is instructed by an automated driving switch, an automated driving mode is switched according to a setting situation of a destination and whether or not there is a continuous travel intention.

That is, when the destination is set by the destination setting unit 3, a travel route for reaching the destination by the automated driving is generated and the automated driving is started (summary, S12 of fig. 2). When the destination is not set in the destination setting unit 3 and the travel intention detecting unit 4 detects that the driver has an intention to continue traveling, a travel route for the off-road automatic driving is generated and the automatic driving is started (summary, S16 in fig. 2). When the destination setting unit 3 does not set a destination and the travel intention detecting unit 4 detects that the driver does not intend to continue traveling, a travel route for automatic parking is generated and automatic driving is started (summary, S18 of fig. 2).

The destination setting unit 3 is used for setting a destination for automated driving by a driver, and for example, uses a touch panel ([0027]) of a navigation system.

Disclosure of Invention

As described above, in WO 2011/158347 a1, when the destination is set by the destination setting unit 3, a travel route for reaching the destination by the automated driving is generated and the automated driving is started (summary, S12 of fig. 2). It can be explained that the destination autopilot continues until the vehicle reaches the destination (fig. 2). However, it is only disclosed in WO 2011/158347 a1 that the vehicle is automatically driven to the destination set by the driver. In other words, whether the destination set by the driver (user) is appropriate as the parking position (or the risk of the user's destination) is not studied in depth.

The present invention has been made in view of the above-described problems, and an object thereof is to provide a travel control device, a vehicle, and a travel control method that can consider the suitability of a user destination.

The travel control device according to the present invention automatically travels a vehicle on at least a part of a road up to a user destination input by a user through a destination input unit,

it is characterized in that the preparation method is characterized in that,

the travel control device further performs the following control:

the vehicle is stopped at a corrected destination shifted from the user destination when it is determined that the user destination is not suitable for stopping.

According to the present invention, when it is determined that the user destination set by the user is not suitable for parking, the vehicle is parked at the corrected destination shifted from the user destination. Accordingly, the vehicle can be parked at a place (place) suitable for parking. Therefore, the convenience of the user accompanying the alighting can be improved.

The following steps can be also included: when it is determined that the user destination is not suitable for parking, the travel control device causes the vehicle to park by using, as the corrected destination, a point located farther from or closer to the user destination on the same lane as the user destination. Accordingly, the user destination and the correction destination (actual get-off position) are located on the same lane. Therefore, the user can easily grasp the positional relationship between the user destination and the get-off position.

The following steps can be also included: when it is determined that the user destination is not suitable for parking, the travel control device causes the vehicle to park by using, as the corrected destination, a point located farther from or closer to the user destination on a lane in the same section as the user destination. Accordingly, the user destination and the correction destination (actual getting-off position) are located in the same section (division). Therefore, the user can easily grasp the positional relationship between the user destination and the get-off position.

The following steps can be also included: when it is determined that the user destination is not suitable for parking, the travel control device causes the vehicle to make a left turn or a right turn after passing through the user destination, and causes a point on a lane facing the same section as the user destination and farther from the user destination to be the correction destination, thereby parking the vehicle. Accordingly, the vehicle is parked in the same section (section) as the user destination after passing through the user destination. Therefore, the user can more easily grasp the positional relationship between the user destination and the get-off position.

The following steps can be also included: when it is determined that the user destination is not suitable for parking, the travel control device notifies the vehicle of the corrected destination deviated from the user destination through a notification portion. Accordingly, the user can know that the vehicle is in a normal operating state.

The following steps can be also included: when it is determined that the user destination is located in an intersection, a railroad crossing, or a construction area, or around any one of these points, the travel control device stops the vehicle by using, as the correction destination, a point that is shifted from any one of the intersection, the railroad crossing, and the construction area, and around the point. Accordingly, even when the user destination is located in the intersection, the railroad crossing, or the construction area, or around any one of these points, the user can get off the vehicle at an appropriate point.

The following steps can be also included: when it is determined that another vehicle is in a stopped state at or around the user destination, the travel control device stops the vehicle in front of or behind the another vehicle. Accordingly, even when another vehicle is parked at the user destination, the user can get off the vehicle at an appropriate place.

The vehicle according to the present invention is characterized by comprising the travel control device and an automatic door,

when it is determined that the user destination is not appropriate for parking, the travel control device causes the vehicle to park at the corrected destination shifted from the user destination, and automatically opens the automatic door.

Accordingly, the user can recognize that the present automated driving is finished.

The running control method according to the present invention is characterized in that,

comprises a destination reception step, an information acquisition step, and an automatic travel step, wherein,

the user destination receiving step is a step of receiving a user destination from a user at a destination input unit;

the information acquisition step is a step of acquiring ambient environment information from an ambient environment detection unit;

the automatic travel step is a step in which the travel control device automatically travels the vehicle on at least a part of the road up to the user destination,

in the automatic traveling step, it is determined whether or not the user destination is suitable for parking based on the surrounding environment information on the user destination, and the vehicle is parked at a corrected destination shifted from the user destination when it is determined that the user destination is not suitable for parking.

Drawings

Fig. 1 is a block diagram schematically showing a configuration of a vehicle according to an embodiment of the present invention.

Fig. 2 is a diagram showing the computing device of the AD unit according to the above-described embodiment and its surrounding parts.

Fig. 3 is a flowchart of the automatic driving control of the embodiment.

Fig. 4 is a flowchart of the arrival-time processing of the embodiment (details of S16 of fig. 3).

Fig. 5 is a diagram showing an example of a case where a plurality of other vehicles are parked at the vehicle destination and the surroundings thereof in the above embodiment.

Fig. 6 is a flowchart of the alternative location search processing of the embodiment (details of S25 of fig. 4).

Detailed Description

A. One embodiment of the invention

< A-1. Structure >

[ A-1-1. outline ]

Fig. 1 is a block diagram schematically showing a configuration of a vehicle 10 according to an embodiment of the present invention. The vehicle 10 (hereinafter also referred to as "own vehicle 10") has an external sensor 20, a navigation device 22, a map positioning unit 24 (hereinafter referred to as "MPU 24"), a vehicle body behavior sensor 26, a driving operation sensor 28, an occupant sensor 30, a communication device 32, a human-machine interface 34 (hereinafter referred to as "HMI 34"), a driving force output device 36, a brake device 38, a steering device 40, door actuators 42l, 42r, and an AD unit 44. "AD" in the AD unit 44 is an abbreviation of automatic Driving (Autonomous Driving). The navigation device 22, the MPU24, and the AD unit 44 constitute the travel control device 12.

[ A-1-2. external sensor 20]

The outside world sensor 20 (surroundings monitoring sensor) detects information relating to the outside world of the vehicle 10 (hereinafter also referred to as "outside world information Ie.). the outside world sensor 20 includes a plurality of outside-vehicle cameras 60, a plurality of radars 62, And L IDAR64 (L ightDetection And Ranging).

The plurality of external cameras 60 output image information Iimage related to a surrounding image Fs obtained by imaging the surroundings (front, side, and rear) of the vehicle 10, the plurality of radars 62 output radar information Iradar indicating reflected waves of electromagnetic waves transmitted to the surroundings (front, side, and rear) of the vehicle 10, L IDAR64 continuously emits laser light in all directions of the vehicle 10, measures the three-dimensional position of the reflection point from the reflected waves, and outputs the three-dimensional position as three-dimensional information Ilidar.

[ A-1-3. navigation device 22]

The navigation device 22 calculates a target route Rtar from the current position Pcur to the destination Ptar, guides the occupant, and outputs it to the MPU 24. As shown in fig. 1, the navigation device 22 has a global positioning system sensor 70 (hereinafter referred to as "GPS sensor 70") and a1 st map database 72 (hereinafter referred to as "map DB 72" or "1 st map DB 72"). The GPS sensor 70 detects the current position Pcur of the vehicle 10. The 1 st map DB72 stores map information Imap.

The navigation device 22 receives an input of a destination Ptar (hereinafter also referred to as "user destination push") from the user through the HMI34 (particularly, the touch panel 104 or the microphone 106). The navigation device 22 calculates a target route Rtar from the current position Pcur to the user destination Putar using the map information Imap of the 1 st map DB 72. In the case where the automatic driving control is being executed, the navigation device 22 transmits the target route Rtar to the MPU 24. The target route Rtar is used for automatic driving control.

[A-1-4.MPU24]

The MPU24 manages the 2 nd map database 80 (hereinafter referred to as "2 nd map DB 80"), the accuracy of the map information Imap stored in the 2 nd map DB80 is higher than the accuracy of the map information Imap contained in the 1 st map DB72, and the positional accuracy is equal to or less than centimeter units, the 1 st map DB72 does not have detailed information of lanes of roads, but the 2 nd map DB80 has detailed information of lanes of roads, the MPU24 reads out the map information Imap (high accuracy map) corresponding to the target route Rtar received from the navigation device 22 from the 2 nd map DB80 and transmits the map information Imap (high accuracy map) corresponding to the target route Rtar received from the navigation device 22 to the AD unit 44, and the map information Imap (high accuracy map) corresponding to the target route L tar is used for automatic driving control.

[ A-1-5. vehicle body behavior sensor 26]

The vehicle body behavior sensor 26 detects information (hereinafter also referred to as "vehicle body behavior information Ib") related to the behavior of the vehicle 10 (particularly, the vehicle body), the vehicle body behavior sensor 26 includes a vehicle speed sensor, an acceleration sensor, and a yaw rate sensor (all not shown), the vehicle speed sensor detects the vehicle speed V [ km/h ] and the traveling direction of the vehicle 10, the acceleration sensor detects the acceleration G [ m/s/s ] of the vehicle 10, the acceleration G includes a front-rear acceleration α, a lateral acceleration Glat, and a top-bottom acceleration Gv (acceleration G ] may be in only a part of directions), and the yaw rate sensor detects the yaw rate Y [ rad/s ] of the vehicle 10.

[ A-1-6. Driving operation sensor 28]

The driving operation sensor 28 detects information (hereinafter also referred to as "driving operation information Ido") relating to the driving operation of the driver. The driving operation sensor 28 includes an accelerator pedal sensor and a brake pedal sensor (both not shown). The accelerator pedal sensor detects an operation amount [% ] of an unillustrated accelerator pedal. The brake pedal sensor detects an operation amount [% ] of a brake pedal, not shown. The driving operation sensor 28 may include a steering angle sensor, a steering torque sensor (both not shown), and the like.

[ A-1-7. occupant sensor 30]

The occupant sensor 30 detects information (hereinafter also referred to as "occupant information Io") relating to the state of the occupant (not directly related to driving operation). The occupant sensor 30 has an in-vehicle camera 90 and a seat sensor 92. The in-vehicle camera 90 is a driver monitor camera that photographs the face of the driver and its surroundings. The seat sensor 92 is a pressure sensor provided on a seat cushion, not shown. The occupant sensor 30 may include a seat belt sensor that detects a worn/unworn state of a seat belt, not shown.

[ A-1-8. communication device 32]

The communication device 32 performs wireless communication with an external apparatus. The external device referred to herein includes, for example, the route guidance server 50. It is assumed that the communication device 32 of the present embodiment is mounted (fixed) on the vehicle 10, but may be a device that can be brought to the outside of the vehicle 10, such as a mobile phone or a smartphone.

[A-1-9.HMI34]

The HMI34 (destination input unit, notification unit) receives an operation input from the occupant and presents various information to the occupant visually, aurally, and tactually. The HMI34 includes an autopilot switch 100 (hereinafter also referred to as "autopilot SW 100"), a speaker 102, a touch panel 104, and a microphone 106.

The autopilot SW100 is a switch for instructing the start and end of autopilot control by an operation of an occupant the start or end of autopilot control can be instructed by other methods (voice input via the microphone 106, etc.) in addition to or instead of the autopilot SW 100. the touch panel 104 includes, for example, a liquid crystal panel or an organic E L panel.

[ A-1-10. Driving force output device 36]

The driving force output device 36 includes a running drive source (an engine, a traction motor, and the like) and a drive electronic control device (hereinafter referred to as a "drive ECU"), which are not shown. The drive ECU controls the travel drive source in accordance with the operation amount of the accelerator pedal or a command from the AD unit 44 to adjust the travel drive force of the vehicle 10.

[ A-1-11. brake 38]

The brake device 38 includes a brake motor (or a hydraulic mechanism), a brake member, and a brake electronic control device (hereinafter referred to as a "brake ECU"), which are not shown. The braking device 38 may also be a device that controls engine-based braking and/or traction motor-based regenerative braking. The brake ECU operates a brake motor and the like in accordance with the operation amount of a brake pedal or a command from the AD unit 44 to control the braking force of the vehicle 10.

[ A-1-12. steering device 40]

The steering device 40 includes an Electric Power Steering (EPS) motor and an EPS electronic control device (hereinafter referred to as an "EPSECU"), which are not shown. The EPS ECU controls the EPS motor in accordance with the operation of the steering wheel by the driver or an instruction from the AD unit 44, thereby controlling the steering angle of the vehicle 10.

[ A-1-13. door actuators 42l, 42r ]

The door actuator 42l automatically opens and closes the left slide door 110l in accordance with an instruction from the AD unit 44. The door actuator 42r automatically opens and closes the right slide door 110r in accordance with an instruction from the AD unit 44.

[ A-1-14.AD unit 44]

(A-1-14-1. outline of AD unit 44)

The AD unit 44 executes automatic driving control in which the vehicle 10 is driven to the destination Ptar without a driving operation (acceleration, deceleration, and steering) performed by the driver, and the AD unit 44 includes, for example, a Central Processing Unit (CPU). AD unit 44 has input/output device 120, arithmetic device 122, and storage device 124.

The input/output device 120 performs input/output with devices (sensors 20, 26, 28, 30, and the like) other than the AD unit 44. The arithmetic unit 122 performs arithmetic operations based on signals from the sensors 20, 26, 28, and 30, the navigation device 22, the MPU24, the communication device 32, the HMI34, and the like. Then, the arithmetic device 122 generates signals for the communication device 32, the HMI34, the driving force output device 36, the brake device 38, and the steering device 40 based on the arithmetic result. The details of the arithmetic device 122 will be described later with reference to fig. 2.

The storage device 124 stores programs and data used by the arithmetic device 122. The storage device 124 has, for example, a random access memory (hereinafter referred to as "RAM"). As the RAM, a volatile memory such as a register and a nonvolatile memory such as a flash memory can be used. In addition, the storage device 124 may have a Read Only Memory (ROM) and/or a Solid State Disk (SSD) in addition to the RAM.

(A-1-14-2. arithmetic unit 122)

Fig. 2 is a diagram showing arithmetic device 122 of AD section 44 according to the present embodiment and its surrounding parts. As shown in fig. 2, the arithmetic device 122 of the AD unit 44 includes an external world recognition unit 200, a vehicle position recognition unit 202, a communication control unit 204, an action planning unit 206, and a travel control unit 208. These respective units are realized by, for example, the arithmetic device 122(CPU or the like) executing a program stored in the storage device 124 of the AD unit 44. The program may be supplied from an external management server (not shown) via the communication device 32. It is also possible to constitute a part of the program by software (circuit parts).

The environment recognition unit 200 recognizes the situation and the object around the host vehicle 10 from the environment information Ie from the environment sensor 20 (fig. 1). The environment recognition unit 200 recognizes the overall road environment, for example, the road shape, the road width, the position of a lane marker, the number of lanes, the lane width, the lighting state of a traffic light, the open/close state of a railroad crossing breaker, and the like, from the image information Iimage of the external camera 60.

The environment recognition unit 200 includes another vehicle detection unit 210, an intersection detection unit 212, a railroad crossing detection unit 214, and a construction site detection unit 216. The other-vehicle detection unit 210 detects another vehicle 300 (fig. 5) located around the host vehicle 10. The detection of the other vehicle 300 uses image information Iimage of the external camera 60 or the like. Alternatively, another vehicle may be detected by communicating with another vehicle 300 via the communication device 32.

The intersection detection unit 212 detects an intersection 306 (fig. 5) located around the host vehicle 10. The detection of the intersection 306 uses the image information Iimage of the vehicle exterior camera 60. Alternatively, the intersection 306 may be detected using the current position Pcur of the host vehicle 10 and the map information Imap. Alternatively, the intersection 306 may be detected by communicating with a roadside beacon (not shown) via the communication device 32.

The railroad crossing detection unit 214 detects a railroad crossing (not shown) located around the host vehicle 10. The detection of the railroad crossing uses the image information iirange of the external camera 60. Alternatively, the current position Pcur of the host vehicle 10 and the map information Imap may be used to detect a railroad crossing. Alternatively, the railroad crossing may be detected by communicating with a roadside beacon (not shown) via the communication device 32.

The construction site detection unit 216 detects a construction site (not shown) located around the host vehicle 10. The detection at the construction site uses image information Iimage of the external camera 60. Alternatively, the construction site may be detected using the current position Pcur of the host vehicle 10 and construction information from the route guidance server 50. Alternatively, the construction site may be detected by communicating with a roadside beacon (not shown) via the communication device 32.

The vehicle position recognition unit 202 recognizes the current position Pcur of the vehicle 10 with high accuracy based on the recognition result of the external world recognition unit 200, the map information Imap from the MPU24, and the current position Pcur from the navigation device 22. The communication control unit 204 controls communication between the AD unit 44 and the vehicle-external device (for example, the route guidance server 50).

The action planning unit 206 determines the traveling state of the host vehicle 10 based on the map information Imap (high-precision map) from the MPU24, the recognition results of the external recognition unit 200 and the host vehicle position recognition unit 202, and the detection result of the vehicle body behavior sensor 26, and plans various actions of the host vehicle 10. specifically, the action planning unit 206 calculates a target trajectory L tar, a target vehicle speed Vtar, and the like.

As shown in fig. 2, the action planning unit 206 includes a risk determination unit 220, a vehicle destination calculation unit 222, and a trajectory generation unit 224, the risk determination unit 220 determines a risk R (described later in detail) of a destination Ptar (user destination Putar) input by a user through an HMI34, the vehicle destination calculation unit 222 calculates a destination Ptar (hereinafter also referred to as "vehicle destination Pvtar") at which the vehicle 10 is actually stopped from the user destination Putar, map information Imap from an MPU24, and the risk R, and the trajectory generation unit 224 generates a target trajectory L tar to the vehicle destination Pvtar, and causes the vehicle 10 to automatically travel to the vehicle destination Pvtar.

The target route Rtar calculated by the navigation device 22 is a route for informing the driver of the road on which the vehicle should travel, and is only a relatively rough route, whereas the target route L tar calculated by the action planning unit 206 includes relatively detailed contents for controlling acceleration, deceleration, and steering of the vehicle 10 in addition to the rough route calculated by the navigation device 22.

The travel control unit 208 calculates and transmits control commands for the driving force output device 36, the brake device 38, and the steering device 40 based on the determination result (the target trajectory L tar, the target vehicle speed Vtar, and the like) of the action planning unit 206, in other words, the travel control unit 208 controls the output of each actuator, which controls the behavior of the vehicle body, and the like, the actuators herein include an engine, a brake motor, an EPS motor, and the like, the travel control unit 208 controls the behavior amount (hereinafter referred to as "vehicle body behavior amount Qb") of the vehicle 10 (particularly, the vehicle body) by controlling the output of the actuator, and the vehicle body behavior amount Qb herein includes, for example, the vehicle speed V, the front-rear acceleration α, the steering angle θ st, the lateral acceleration Glat, and the yaw rate Y.

[ A-1-15. route guidance server 50]

The route guidance server 50 generates or calculates a target route Rtar to the destination Ptar in place of the vehicle 10, based on the current position Pcur of the vehicle 10 and the destination Ptar received from the communication device 32. The route guidance server 50 includes an input/output device, a communication device, an arithmetic device, and a storage device, which are not shown. The storage device stores programs and data used by the arithmetic device.

< A-2 > control of the present embodiment

[ A-2-1. outline ]

The vehicle 10 of the present embodiment is capable of executing automatic driving control for automatically driving the vehicle 10 to the destination Ptar. The automatic driving control is performed by the navigation device 22, the MPU24, and the AD unit 44 (i.e., the travel control device 12).

In the present embodiment, when the destination Ptar (user destination Putar) (located on the road) specified by the user is a point unsuitable for parking (a point unsuitable for parking), a point deviated from the position of the user destination Putar is set as the actual destination Ptar (vehicle destination Pvtar). When the user destination Putar is a place suitable for parking (a place suitable for parking), the user destination Putar is directly set as the vehicle destination Pvtar.

[ A-2-2. automatic Driving control ]

(A-2-2-1. summary)

Fig. 3 is a flowchart of the automatic driving control according to the present embodiment. In step S11, the navigation device 22 receives an input of a destination Ptar (user destination Putar) from the user through the HMI34 (touch panel 104, microphone 106, etc.). The input user destination Putar can be a portion (e.g., facility name, residence) having an area in the 1 st map DB 72. The user destination Putar, which is a section having an area, has reference coordinates defined as points. The reference coordinates are determined as XY coordinates.

Alternatively, the user destination Putar can be a portion defined as a point in the 1 st map DB 72. The user destination Putar defined as a point is set to, for example, a point touched by the user or a point designated by a cursor on a map screen (not shown) displayed on the touch panel 104.

The AD unit 44 sets the user destination puttar (or the reference coordinates thereof) as the vehicle destination Pvtar (Pvtar ← Putar). The vehicle destination Pvtar is defined as a point in the 1 st map DB72, and the XY coordinates thereof are determined. However, the vehicle destination Pvtar may also be defined as a portion having an area (for example, a region having a length and a width of several meters). In this case, a reference point for generating the target route Rtar needs to be set in advance.

When the user designates a point (place) that is not located on a road, such as a lake, the navigation device 22 sets a point on the road (for example, a point on the road closest to the point designated by the user) based on the point designated by the user as the user destination Putar. The term "on-road" as used herein includes not only a point located within a lane of a road but also an area indicating facilities facing the road.

In step S12, the navigation apparatus 22 generates a target route Rtar from the current position Pcur to the vehicle destination Pvtar. In addition, the navigation device 22 notifies the MPU24 of the generated target route Rtar.

In step S13, the MPU24 reads map information Imap (high-precision map) corresponding to the target route Rtar received from the navigation device 22 from the 2 nd map DB80 and transmits the map information Imap to the AD unit 44. the AD unit 44 generates a target trajectory L tar from the map information Imap (high-precision map) from the MPU24 and the recognition results of the external world recognition unit 200 and the vehicle position recognition unit 202. then, the AD unit 44 controls the driving force output device 36, the brake device 38, the steering device 40, and the like in accordance with the target trajectory L tar.

In the present embodiment, the target route Rtar indicates a relatively long trajectory from the current position Pcur to the vehicle destination Pvtar, whereas the target trajectory L tar indicates a relatively short trajectory necessary for automatically driving the vehicle 10.

In step S14, the AD unit 44 determines whether the host vehicle 10 is located near the vehicle destination Pvtar, for example, based on whether the distance L from the current position Pcur of the host vehicle 10 to the vehicle destination Pvtar is equal to or less than the distance threshold THl, or based on whether the predicted time Te until the host vehicle 10 reaches the vehicle destination Pvtar is equal to or less than the time threshold THte.

In a case where the vehicle 10 is not located near the vehicle destination Pvtar (S14: false), in step S15, the AD unit 44 updates the target trajectory L tar with respect to the distance the vehicle 10 has traveled while maintaining the vehicle destination Pvtar, returns to step S14, in a case where the vehicle 10 is located near the vehicle destination Pvtar (S14: true), in step S16, the AD unit 44 executes the arrival-time processing (details described later with reference to fig. 4).

(A-2-2-2. arrival time processing (S16 of FIG. 3))

(A-2-2-2-1. Abstract)

Fig. 4 is a flowchart of the arrival time processing of the present embodiment (details of S16 in fig. 3). In step S21, the AD unit 44 acquires the surrounding environment information Ise for determining whether the vehicle destination Pvtar is a parking-suitable place Pad (hereinafter also referred to as a "parking-suitable place Pad"). The ambient information Ise is, for example, external information Ie from the external sensor 20 (image information iirange of the external camera 60). Alternatively, the ambient environment information Ise may include the map information Imap from the MPU24, the current position Pcur from the navigation apparatus 22, and the like. Alternatively, the ambient environment information Ise may include the recognition results of the external world recognition unit 200 and the host vehicle position recognition unit 202.

In step S22, the AD unit 44 determines the risk R of the vehicle destination Pvtar set in step S11 of fig. 3. The risk R is information indicating whether it is the parking place Pad suitable or the parking place Pia unsuitable. The parking unsuitable place Pia refers to a place unsuitable for parking although located on the road.

For example, the AD unit 44 determines whether or not another vehicle 300 (fig. 5) is present at or around the vehicle destination Pvtar based on the external world information Ie (or the recognition result of the external world recognition unit 200 based on the external world information Ie). In addition, the AD unit 44 determines whether the vehicle destination Pvtar is located within the intersection 306 (fig. 5), within a railroad crossing, within a construction site, or around these sites. The determination of whether or not the vehicle is located "around" is determined, for example, based on whether or not the distance Du between the reference point Preff and the vehicle destination Pvtar at each of the intersection 306, the railroad crossing, and the construction site is within the distance threshold THdu.

When it is determined that there is no other vehicle 300 at the vehicle destination Pvtar and its surroundings, and the vehicle destination Pvtar is not located at any of the points within the railroad crossing, within the intersection 306, within the construction site, and around these points, the AD unit 44 determines that the vehicle destination Pvtar is the parking suitable point Pad (sets the risk R indicating that the vehicle destination Pvtar is the parking suitable point Pad). Further, when it is determined that another vehicle 300 is present at or around the vehicle destination Pvtar, or that the vehicle destination Pvtar is located at any one of the points within the intersection 306, within the railroad crossing, within the construction site, and around these points, the AD unit 44 determines that the vehicle destination Pvtar is an unsuitable parking spot Pia (sets a risk R indicating that the vehicle destination Pvtar is an unsuitable parking spot Pia).

Further, even in a case where the vehicle destination Pvtar is located around the intersection 306, the railroad crossing, or the construction site, if there is a parking lot, it can be determined that the parking lot is the parking suitable spot Pad.

If the vehicle destination Pvtar is not suitable for the parking spot Pia (S23: true in fig. 4), in step S24, the AD unit 44 notifies the occupant (user) of the intention to change the vehicle destination Pvtar (═ user destination Putar) through the HMI34 (touch panel 104 and/or speaker 102) (notification processing). In the next step S25, AD unit 44 executes an alternative point search process of searching for an alternative point Pal to set a new vehicle destination Pvtar. The alternative location search processing will be described later with reference to fig. 6. In the case where the vehicle destination Pvtar is not unsuitable for the parking place Pia (S23: false in fig. 4) or after the alternative place search process (S25), the flow proceeds to step S26.

In step S26, the AD unit 44 determines whether the vehicle 10 has reached the vehicle destination Pvtar, returns to step S26 in a state after updating the target trajectory L tar in the case where the vehicle destination Pvtar has not been reached (S26: false), or returns to step S23 instead of returning to step S26, and in the case where the vehicle destination Pvtar has been reached (S26: true), in step S27, the AD unit 44 executes the reach-time door control.

(A-2-2-2-2. alternative location search processing (S25 of FIG. 4))

As described above, when the vehicle destination Pvtar is the unsuitable parking spot Pid (S23: true in fig. 4), the alternative spot search process of selecting the alternative spot Pal and setting a new vehicle destination Pvtar is executed.

Fig. 5 is a diagram showing an example of a case where a plurality of other vehicles 300 are in a stopped state at the vehicle destination Pvtar and the surroundings thereof. In fig. 5, a road 302 on which the host vehicle 10 is traveling is a one-sided 1-lane, and includes a traveling lane 304a and a reverse lane 304b of the host vehicle 10. In fig. 5, an intersection 306 exists on the near side and the far side of the vehicle destination Pvtar. Hereinafter, for ease of understanding, reference signs 300a, 300b, 300c are given to 3 other vehicles 300, and reference signs 306a, 306b are given to the intersection 306 at 2.

Since the distances D1, D2 of the vehicle destination Pvtar from the intersections 306a, 306b are equal to or greater than the distance threshold THd, the vehicle can be stopped at the vehicle destination Pvtar in accordance with the relationship with the intersections 306a, 306 b. However, since there are a plurality of other vehicles 300a, 300b, 300c, it is not possible to stop at the vehicle destination Pvtar and its near side and far side.

That is, the other vehicle 300a is in the stopped state at the vehicle destination Pvtar. Further, other vehicles 300b and 300c are present at positions closer to the intersection 306a than the other vehicle 300 a. The distance D3 between the intersection 306a and the other vehicle 300c closest to the intersection 306a is smaller than the distance threshold THd, and there is no space for the host vehicle 10 to stop.

Further, another vehicle is not present at the intersection 306b side of the another vehicle 300 a. However, the difference D4-THd between the distance D4 between the other vehicle 300a and the intersection 306b and the distance threshold THd is shorter than the sum of the front-rear direction length of the host vehicle 10 and the margin. Therefore, the host vehicle 10 cannot be stopped (or a new vehicle destination Pvtar cannot be set) between the other vehicle 300a and the intersection 306 b.

Therefore, as will be described later, a new vehicle destination Pvtar (hereinafter also referred to as "corrected destination Pcor") is set on the road 310 (driving lane 312a, reversing lane 312b) that has left-turned at the intersection 306b on the far side. The corrected destination Pcor is set at a point where the distance from the intersection 306 is equal to or greater than the distance threshold THd.

In addition, the user destination puttar of fig. 5 is defined as a portion having an area, but the reference point thereof is located at the same position as the vehicle destination Pvtar of fig. 5.

Fig. 6 is a flowchart of the alternative point search processing of the present embodiment (details of S25 in fig. 4). In step S31 of fig. 6, the AD unit 44 determines whether the vehicle 10 is in a state before passing through the vehicle destination Pvtar (═ user destination Putar). If the vehicle is in a state before passing through the vehicle destination Pvtar (S31: true), the AD unit 44 searches the front of the vehicle 10 for an alternative point Pal that can be the new vehicle destination Pvtar (corrected destination Pcor) in step S32. At this time, if the alternate point Pal is not a parking lot, the alternate point Pal is set on the lane side facing the current vehicle destination Pvtar.

In the case of left-hand traffic as shown in fig. 5, when the vehicle 10 is parked in a state where the user destination Putar is located on the left side with respect to the traveling direction of the vehicle 10, the user can travel to the user destination Putar without crossing the road after getting off the vehicle 10. Therefore, the substitute point Pal is set on the lane side (in fig. 5, the lane 304a or 312a) facing (closer to) the user destination Putar.

In addition, if the alternative point Pal is not a parking lot, the position closest to the current vehicle destination Pvtar (user destination Putar) is set as the alternative point Pal. Accordingly, the distance from the user walking after the vehicle 10 is unloaded to the user destination Putar becomes shorter.

If the vehicle is not in the state before passing the vehicle destination Pvtar (S31: false), in other words, if the vehicle is in the state after passing the vehicle destination Pvtar, the routine proceeds to step S33.

In step S33, the vehicle 10 determines whether there is an intersection in front of itself (e.g., the intersection 306b of fig. 5) — when there is an intersection in front of the vehicle 10 (S33: true), in step S34, the AD unit 44 sets the intersection to make a left turn (the target trajectory L tar for a left turn is generated in S15 of fig. 3).

Accordingly, the corrected destination Pcor is located in the same section 320 (fig. 5) as the initial vehicle destination Pvtar (user destination Putar). In other words, the vehicle 10 is stopped at a point farther from the user destination Putar as the corrected destination Pcor on the lane to the same section 320 as the user destination Putar. When there is no intersection ahead of the vehicle 10 (S33: false), the AD unit 44 keeps the straight traveling setting (setting of traveling along the road) in step S35.

After step S34 or S35, in step S36, the AD unit 44 searches the front of the vehicle 10 for an alternative point Pal that can become a new vehicle destination Pvtar. Step S36 is performed in the same manner as step S32. However, as a result of step S34, when the vehicle 10 makes a left turn at the intersection 306b next or when making a left turn, the vehicle 10 searches for the alternative point Pal with a new driving lane after the left turn as the target. For example, in fig. 5, when the vehicle 10 is traveling on the traveling lane 304a and has passed the vehicle destination Pvtar, the substitute point Pal is searched for with the new traveling lane 312a as the target.

After steps S32, S36, in step S37, the AD unit 44 determines whether or not the substitute point Pal is found, in the case where the substitute point Pal is not found (S37: false), the AD unit 44 returns to step S31 in a state where the target trajectory L tar is updated in correspondence with the distance that the vehicle 10 has traveled.

In the case where the substitute spot Pal is found (S37: true), the AD unit 44 sets the substitute spot Pal to a new vehicle destination Pvtar in step S38. The new vehicle destination Pvtar is also referred to as a corrected destination Pcor in order to be distinguished from the original vehicle destination Pvtar (i.e., the user destination Putar). In the next step S39, the AD unit 44 notifies the occupant (user) of the setting of the correction destination Pcor through the HMI34 (the touch panel 104 and/or the speaker 102) (notification processing).

(A-2-2-2-3. door control at arrival (S27 of FIG. 4))

In the case where the vehicle 10 reaches the vehicle destination Pvtar (S26: true in fig. 4), the AD unit 44 executes the arrival-time door control (S27) — as described above, the target trajectory L tar causes the vehicle 10 to stop such that the vehicle destination Pvtar is located on the left side (in the case of left-side traffic).

In addition, the vehicle 10 may have a front seat (driver seat and passenger seat) and a rear seat, and the AD unit 44 may keep the sliding door 110l closed when the sliding door 110l is disposed corresponding to the rear seat and the presence of the occupant is detected only in the driver seat as a result of detection by the occupant sensor 30.

< A-3 > Effect of the present embodiment

As described above, according to the present embodiment, when it is determined that the user destination puttar set by the user (the first vehicle destination Pvtar) is not suitable for parking (S23: true in fig. 4), the vehicle 10 is parked at the corrected destination Pcor shifted from the user destination Putar (S25, fig. 5, and fig. 6 in fig. 4). Accordingly, the vehicle 10 can be parked at a place suitable for parking. Therefore, the convenience of the user accompanying the alighting can be improved.

In the present embodiment, when it is determined that the user destination Putar is not suitable for parking (S23: true in fig. 4), the AD unit 44 (the travel control apparatus 12) stops the vehicle 10 by using, as the corrected destination Pcor, a point on the same lane 304a as the user destination Putar, a point on the farther side or the closer side than the user destination Putar (S32 and the like in fig. 6). Accordingly, the user destination Putar and the correction destination Pcor (actual getting-off position) exist on the same lane. Therefore, the user can easily grasp the positional relationship between the user destination Putar and the get-off position.

In the present embodiment, when it is determined that the user destination Putar is not suitable for parking (S23: true in fig. 4), the AD unit 44 (the travel control apparatus 12) stops the vehicle 10 using a point on the far side or the front side of the user destination Putar as the corrected destination Pcor on the lane 312a facing the same section 320 as the user destination Putar (S33 to S36 in fig. 6). Accordingly, the user destination Putar and the correction destination Pcor (actual getting-off position) are located in the same section 320 (section). Therefore, the user can easily grasp the positional relationship between the user destination Putar and the get-off position.

In the present embodiment, when it is determined that the user destination Putar is not suitable for parking (S23: true in fig. 4), the AD unit 44 (the travel control apparatus 12) makes the vehicle 10 turn left after passing through the user destination Putar, and stops the vehicle 10 using a point farther from the user destination Putar as the corrected destination Pcor on the lane 312a facing the same section 320 as the user destination Putar (S33: true → S34 → S36 in fig. 5 and 6).

Accordingly, after passing through the user destination Putar, the vehicle 10 is parked facing the same section 320 (section) as the user destination Putar (fig. 5). Therefore, the user can easily grasp the positional relationship between the user destination Putar and the get-off position.

In the present embodiment, when it is determined that the user destination Putar is not suitable for parking (S23: true in fig. 4), the AD unit 44 (the travel control apparatus 12) notifies the HMI34 (a notification unit) that the vehicle 10 is traveling to the corrected destination Pcor shifted from the user destination Putar (S24). Accordingly, the user can know that the vehicle 10 is in the normal operation state.

In the present embodiment, when the AD unit 44 (the travel control device 12) determines that the user destination Putar is located within the intersection 306, the railroad crossing, or the construction area, or around any of these points (S23: true in fig. 4), the AD unit 44 stops the vehicle 10 by shifting any of the intersection 306, the railroad crossing, and the construction area, and around the point as the correction destination Pcor (fig. 6). Accordingly, even when the user destination Putar is located within the intersection 306, the railroad crossing, or the construction area, or around any one of these points, the user can get off the vehicle at a suitable point.

In the present embodiment, when the AD unit 44 (travel control device 12) determines that the other vehicle 300 is in the stopped state at or around the user destination Putar (S23 of fig. 4: true), the vehicle 10 is stopped in front of or behind the other vehicle 300 (fig. 6). Accordingly, even when the other vehicle 300 is in a stopped state at or around the user destination Putar, the user can get off at an appropriate place.

In the present embodiment, the vehicle 10 includes an AD unit 44 (running control device 12) and a slide door 110l (automatic door) (fig. 1). If it is determined that the user destination Putar is not suitable for parking (S23: true in fig. 4), the AD unit 44 stops the vehicle 10 at the corrected destination Pcor shifted from the user destination Putar (fig. 5 and 6), and automatically opens the sliding door 110l (S27 in fig. 4). Accordingly, the user can recognize that the present automated driving is finished.

B. Modification example

The present invention is not limited to the above embodiments, and it is needless to say that various configurations can be adopted according to the contents described in the present specification. For example, the following structure can be adopted.

< B-1. applicable object >

In the present embodiment, the travel control device 12 is applied to a vehicle 10 (fig. 5) which is a passenger vehicle. However, for example, if the appropriate parking spot Pad shifted from the user destination Putar is set as the vehicle destination Pvtar when the user destination Putar is the inappropriate parking spot Pia, the present invention is not limited to this. For example, the travel control device 12 can be applied to a vehicle (or a mobile body) such as an electric train, a ship, or an airplane.

< B-2. vehicle 10 >

[ B-2-1. automatic door ]

In the above embodiment, the slide doors 110l and 110r (fig. 1) are used on the left and right sides of the vehicle 10. However, for example, if the right-side slide door 110r is omitted and only the left-side slide door 110l is provided (in the case of left-side traffic), from the viewpoint of automatically opening the doors on the opposite sides of the reversing lanes 304b, 312b when the vehicle 10 is parked.

In the above embodiment, the automatic vehicle door uses the sliding doors 110l, 110r (fig. 1). However, for example, from the viewpoint of an automatically openable and closable vehicle door, the present invention is not limited to this. For example, a folding door (a door used in a bus), a gull-wing door, or the like can be used instead of the sliding doors 110l and 110 r.

In the above embodiment, the vehicle 10 is provided with the slide doors 110l and 110r as the automatic doors (fig. 1). However, for example, if the appropriate parking spot Pad shifted from the user destination Putar is set as the vehicle destination Pvtar when the user destination Putar is the inappropriate parking spot Pia, the present invention is not limited to this. For example, the vehicle 10 may be configured without an automatic door.

[ B-2-2. automatic Driving control ]

In the above embodiment, the case where the vehicle 10 passes on the left side is shown (fig. 5). However, for example, if the appropriate parking point Pad shifted from the user destination Putar is set as the vehicle destination Pvtar when the user destination Putar is the inappropriate parking point Pia, the right-hand traffic of the vehicle 10 can be applied.

In the above embodiment, it is determined which of the parking place Pad and the parking place Pia is the vehicle destination Pvtar (i.e., the user destination Putar) is suitable from the external information Ie such as the image information Iimage of the external camera 60 (or the recognition result of the external recognition unit 200 based on the external information Ie) (S22 in fig. 4). However, for example, from the viewpoint of acquiring road information for determining which of the parking suitable spot Pad and the parking unsuitable spot Pia the user destination Putar is, it is not limited to this.

For example, when an external monitoring camera exists near the user destination Putar, the presence or absence of another vehicle 300 or the like may be determined by receiving an image of the external monitoring camera, so that it may be determined which of the parking spot Pad suitable for the user destination Putar and the parking spot Pia unsuitable for the user destination Putar. Alternatively, the determination may be made by performing inter-vehicle communication with another vehicle 300 via the communication device 32 to determine the position of the other vehicle 300. In this case, the determination can also be made by acquiring the predetermined parking position of the other vehicle 300 before the other vehicle 300 actually parks.

In the above embodiment, the target route Rtar is generated by the vehicle 10 (S12 of fig. 3). However, for example, if the appropriate parking spot Pad shifted from the user destination Putar is set as the vehicle destination Pvtar when the user destination Putar is the inappropriate parking spot Pia, the present invention is not limited to this. The target route Rtar may be generated by the route guidance server 50, for example.

In the above embodiment, in the case where the vehicle 10 has reached the vehicle destination Pvtar (S26: true in fig. 4), the slide door 110l is opened (S27). However, for example, if the appropriate parking spot Pad shifted from the user destination Putar is set as the vehicle destination Pvtar when the user destination Putar is the inappropriate parking spot Pia, the present invention is not limited to this. For example, it is also possible to configure not to automatically open the slide door 110l even when the vehicle 10 has reached the vehicle destination Pvtar (S26: true in fig. 4).

[ B-2-3. alternative site search processing ]

In the above embodiment, the alternative point Pal is searched for a range on the front side of the vehicle destination Pvtar (user destination Putar), and thereafter, the alternative point Pal is searched for a range on the far side of the vehicle destination Pvtar (S31 to S36 in fig. 6). However, for example, from the viewpoint of setting the correction destination Pcor to the near side or the far side of the vehicle destination Pvtar (user destination Putar), the present invention is not limited to this. For example, when the AD unit 44 can search for the alternative point Pal on both the near side and the far side of the vehicle destination Pvtar (user destination Putar), the correction destination Pcor may be set preferentially on the far side of the vehicle destination Pvtar.

In the above embodiment, the alternative location search processing is performed according to the flow shown in fig. 6. However, for example, from the viewpoint of searching for the alternative location Pal, the present invention is not limited to this. For example, the alternative location search process may be changed according to the reason why the parking location Pia is not suitable.

Specifically, when the user destination Putar is located inside or near a railroad crossing, the alternative point Pal may be searched as follows. That is, the AD unit 44 determines whether or not the user destination Putar is located at a position farther from the railroad crossing. When the user destination post is located at a position farther from the railroad crossing, the AD unit 44 sets the substitute point Pal at a position farther from the railroad crossing. When the user destination post is not located farther from the railroad crossing, the AD unit 44 sets the substitute point Pal to a position closer to the front side than the railroad crossing.

At this time, if the substitute spot Pal is not a parking lot, the substitute spot Pal is set on the lane side facing the user destination Putar. In the case of left-hand traffic, when the vehicle 10 is parked in a state where the user destination Putar is located on the left side toward the traveling direction of the vehicle 10, the user can go to the user destination Putar without crossing the road after getting off the vehicle 10. Therefore, the substitute point Pal is set on the lane side facing (closer to) the user destination Putar.

In addition, if the alternative point Pal is not a parking lot, a position that is a distance from the railroad crossing equal to or greater than the distance threshold and closest to the user destination Putar is taken as the alternative point Pal. Accordingly, the distance from the user walking after the vehicle 10 is unloaded to the user destination Putar becomes shorter.

The alternative point Pal (or the corrected destination Pcor) may be set similarly for the intersection 306 and the construction site.

[ B-2-4. unsuitable parking spot Pia ]

In the above embodiment, the point where another vehicle 300 (another vehicle 300a, 300b, 300c, etc. of fig. 5) parks, the intersection 306 (intersection 306a, 306b, etc. of fig. 5), the railroad crossing, the construction site, and the surroundings of these points are set as the unsuitable parking point Pia (S23 of fig. 4). However, for example, if the appropriate parking spot Pad shifted from the user destination Putar is set as the vehicle destination Pvtar when the user destination Putar is the inappropriate parking spot Pia, the present invention is not limited to this. For example, the unsuitable parking spot Pia may be a spot where the other vehicle 300 is parked, 1 spot or 2 spots or 3 spots in the intersection 306, railroad crossing, and construction site, or around these spots. Alternatively, the unsuitable parking spot Pia can also include a streetcar running area.

< B-3. other >)

In the above embodiment, the flow shown in fig. 3, 4, and 6 is used. However, for example, when the effects of the present invention can be obtained, the contents of the flow (the order of the steps) are not limited thereto. For example, the order of step S38 and step S39 of fig. 6 can be switched.

C. Description of the reference numerals

10: a vehicle; 12: a travel control device; 20: an external sensor (surrounding environment detection unit); 34: HMI (destination input unit, notification unit); 70: a GPS sensor (surrounding environment detection unit); 102: a speaker (notification unit); 104: a touch panel (destination input unit, notification unit); 106: a microphone (destination input unit); 110 l: sliding doors (automatic vehicle doors); 300. 300a, 300b, 300 c: other vehicles; 304 a: a traveling lane of the host vehicle (the same lane as the user destination); 306. 306a, 306 b: an intersection; 312 a: the driving lane of the host vehicle (the lane facing the same section); 320: a field; ise: ambient environment information; pcor: correcting the destination; putar: the user destination.