JP4631519B2 - Parking assistance device and parking assistance method - Google Patents

Description

  The present invention relates to a parking assistance apparatus and method for assisting a parking operation by displaying an image around a vehicle.

Conventionally, from the viewpoint of grasping the distance between an obstacle and the host vehicle or facilitating the recognition of the obstacle, a device that supports a driver's parking operation by displaying an image around the vehicle during parking is known. It has been. In this type of apparatus, it is necessary to appropriately switch and display a necessary image in accordance with a series of parking states from the start to the end of parking, so it is necessary to determine the current parking state effectively. For example, in Patent Document 1, if a GPS satellite cannot be received for a certain period of time, it is considered that the host vehicle may be traveling in an indoor parking area, and the vehicle travels within the indoor parking area based on the turning state of the vehicle. It is determined whether it is in the middle.
JP 2000-310542 A

  However, in the method disclosed in Patent Document 1, when the vehicle is present in the indoor parking area, the parking start can be determined. However, when parking in the outdoor parking area, parking is performed. There is an inconvenience that the state cannot be determined.

  In order to solve such a problem, the present invention provides a parking assistance device that displays an image around a vehicle and assists a parking operation. In this parking assist apparatus, each of the plurality of imaging units is attached to the periphery of the vehicle, images a landscape around the vehicle, and the display unit displays an image output from the imaging unit. Further, the switching means switches the imaging means for displaying the video on the display means from among the plurality of imaging means according to a predetermined display pattern. The navigation means acquires road information on which the host vehicle travels as navigation information, and the vehicle information acquisition means acquires vehicle information including a driving operation amount and a vehicle state amount. The parking state determination unit determines the parking state of the host vehicle based on the navigation information acquired by the navigation unit and the vehicle information acquired by the vehicle information acquisition unit. The pattern setting unit sets a display pattern based on the parking state of the host vehicle determined by the parking state determination unit, and outputs the set display pattern to the switching unit.

  According to the present invention, since the scenery around the vehicle necessary for parking can be automatically displayed according to the parking state of the vehicle, the parking operation of the driver can be effectively supported.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(First embodiment)
FIG. 1 is a block diagram showing the overall configuration of the parking support apparatus 10 according to the first embodiment, and FIG. 2 is an explanatory view schematically showing the parking support apparatus 10 shown in FIG. The parking assistance device 10 is a device that presents information around the vehicle and assists the parking operation. The vehicle information acquisition unit (vehicle information acquisition unit) 11, the navigation device (navigation unit) 11, the parking state determination unit 13, The camera unit 14, the camera image switching device (switching device) 15, the camera image display device (display device) 16, the sheet position control device (sheet position control device) 17, and the sheet position actuator (sheet position driving device) 18 are mainly configured. Is done.

  The vehicle information acquisition unit 11 includes various sensors and acquires a driving operation amount and a vehicle state amount as vehicle information. The driving operation amount is various operation amounts related to the operation of the driver. For example, the steering angle, the presence / absence of depression of the brake, the gear position, the operation of the blinker, the operation of the hazard, and the like correspond to this. The vehicle state quantity is various state quantities relating to the state of the vehicle. For example, the vehicle speed, the lateral acceleration, the yaw rate, and the like correspond to this. For example, the vehicle information acquisition unit 11 receives vehicle state quantities such as vehicle speed, lateral acceleration, and yaw rate, steering angle, accelerator opening, brake switch (brake SW) signal, gear position, winker switch (winker switch) SW) signal, hazard switch (hazard SW) signal and other information related to the driving operation amount are acquired.

  The navigation device 12 is a device that acquires road information on which the host vehicle is traveling as navigation information. Specifically, the navigation device 12 includes a vehicle position detection unit 12a, a road information acquisition unit 12b, and a map database (map DB) 12c. The own vehicle position detection unit 12a uses autonomous navigation based on information output from various sensors (not shown) such as a wheel speed sensor, a geomagnetic sensor, and a gyro and a GPS receiver (not shown). Detect position. The road information acquisition unit 12b matches the detected position of the host vehicle with map information stored in the map DB 12c, and acquires road information around the host vehicle. The map database 12c is a database in which navigation map information is associated with position information, and is readable and stored in a hard disk device integrated with the navigation device 12 or a recording medium such as a DVD or CD-ROM. Yes. The map information includes a node representing a specific point on the road and a link representing a connection between the specific points. The vehicle position detection unit 12a further includes an antenna for receiving information from an information providing infrastructure for a narrow range such as a beacon installed on a road, or an information providing infrastructure for a wide range such as FM multiplex broadcasting. And a converter. In addition, as the own vehicle position detection unit 12a, a mobile phone including a GPS antenna and a receiver may be used.

  The parking state determination unit 13 is a unit that determines the parking state of the vehicle. For example, a microcomputer mainly composed of a CPU, a ROM, a RAM, and an I / O interface can be used. When the parking state determination unit 13 grasps this functionally, the vehicle information reading unit 13a, the navigation information reading unit 13b, the parking state determination unit (parking state determination unit) 13c, and the camera image switching command unit (pattern) Setting means) 13d and a sheet position command section (sheet position setting means) 13d.

  The vehicle information reading unit 13a reads the vehicle information acquired by the vehicle information acquisition unit 11, and outputs the vehicle information to the parking state determination unit 13c. The navigation information reading unit 13b reads navigation information from the navigation device 12, that is, road information around the host vehicle, and outputs the navigation information to the parking state determination unit 13c. Based on the vehicle information and the navigation information, the parking state determination unit 13c determines the parking state of the host vehicle that assumes parking. Here, the parking state is a series of vehicle states from the start of parking (intention to start parking by the driver) to the end of parking (completed parking in the parking space). The camera image switching command unit 13d switches a display pattern (image switching signal) for designating an image around the vehicle to be displayed on the camera image display device 16 based on the parking state determined by the parking state determination unit 13c. Output to the unit 15. The seat position command unit 13e outputs to the seat position control device 17 a seat position (seat position switching signal) for designating the position of the seat on which the driver is seated based on the parking state determined by the parking state determination unit 13c. To do.

  As shown in the present embodiment, the parking state determination unit 13 may be configured with these functional elements 13a to 13d as a single independent arithmetic unit, but each function is distributed to different devices. May be configured. For example, each function of the vehicle information reading unit 13a, the navigation information reading unit 13b, and the parking state determination unit 13c is incorporated in the navigation device 12, and the function of the camera image switching command unit 13d is incorporated in the camera image switching device 15, and the seat position command The function of the unit 13e is incorporated in the seat position control device 17.

  The camera unit 14 is attached to the periphery of the vehicle, and includes a plurality of cameras (imaging means) that capture a well-known scene of the vehicle. In the present embodiment, the cameras 14a are arranged in a total of eight locations, starting from the front center of the vehicle, in the clockwise direction: front center, right front corner, right side, right rear corner, rear center, left rear corner, left side, and left front corner. ~ 14h are attached. As each camera 14a-14h, the CCD camera etc. for imaging visible light can be used. The cameras 14a to 14h are simply referred to as “camera 14” when collectively referred to.

  The camera video switching device 15 selects a camera 14 that displays video on the camera video display device 16 from the camera units 14 (plural cameras 14a to 14h) according to the display pattern output from the camera video switching command unit 13d. Then, the images output from the cameras 14a to 14h are selectively switched. For example, when the right front corner, the left front corner, and the rear scenery are designated as the display pattern, the camera image switching device 15 selects the cameras 14b, 14h, and 14e as display target cameras, and these cameras The images output from 14b, 14h, and 14e are displayed on the camera image display device 16. In addition, the camera video switching device 15 can selectively display only a specific area from the video output from the camera 14. For example, when the camera image switching device 15 displays the image of the camera 14c provided on the right side of the vehicle on the camera image display device 16, the left side lower side, the left side front, the left side rear, etc. In this way, only the video in a specific angle range is displayed according to the designated display pattern.

  The camera video display device 16 is a device that displays video output from the camera 14 selected by the camera video switching device 15. As this camera image display device 16, a wide display composed of a plurality of liquid crystal displays can be used so as to cover a range from the meter hood to the center console and the cluster panel. In addition, a large display of 15 inches or more may be provided in the center console section, or a horizontal monitor having one display from the instrument panel to the left end of the passenger seat may be provided.

  The seat position control device 17 drives a seat position actuator (for example, an electric motor) 18 provided in each part of the seat such as a seat seat surface and a seat back based on the seat position output from the seat position command unit 13e. Control is performed so that each part of the sheet moves to a desired position.

  FIG. 3 is a conceptual explanatory diagram of parking support processing of the parking support device 10 according to the first embodiment. For example, when parking in a parking area such as a store along the road, the driver decelerates to the low speed range just before the stop, and then to the shoulder side where the parking area is located (left side for left-hand traffic) Steer. At this time, when steering is performed on the premise that the driver enters the parking area, the direction of the host vehicle and the direction of the road are greatly deviated. Therefore, in consideration of such a series of operations, the parking assist device 10 has been steered until the vehicle speed is reduced to a predetermined value or less and then the steering angle is set to a left or right steering angle of a predetermined value or more. Determine whether or not. Then, the parking state determination unit 13 calculates the difference between the direction of the host vehicle and the direction of the road. If the value is equal to or greater than a predetermined value, the parking state determination unit 13 is off the road and enters a certain site such as a parking area. The parking start of the own vehicle is determined. When it is determined that parking is started, the parking assist device 10 can confirm the object such as parking at the entrance to the parking area or a step, for example, when turning left, the left and right front corners of the vehicle Is displayed on the camera image display device 16.

  4 and 5 are flowcharts showing the procedure of the parking support process according to the first embodiment. The process shown in this flowchart is called at predetermined intervals (for example, 100 ms) and executed by the parking state determination unit 13.

  First, in step 10, the parking state determination unit 13c refers to the vehicle speed in the vehicle information read by the vehicle information reading unit 13a, and determines whether or not the current vehicle speed is smaller than the first vehicle speed threshold value Vs. Determine. The first vehicle speed threshold value Vs is a value for determining whether or not the vehicle speed has been decelerated to a low speed range based on parking, and is set in advance through experiments and simulations. In the present embodiment, the vehicle speed threshold value Vs is set to a minimum value (for example, 15 km / h) of the vehicle speed that cannot be regarded as parking when traveling at a higher speed.

  If an affirmative determination is made in step 10, that is, if the vehicle speed has fallen to such an extent that parking can be considered (vehicle speed <Vs), the routine proceeds to step 11. On the other hand, if a negative determination is made in step 10, that is, if the vehicle speed cannot be considered to be parked (vehicle speed ≧ Vs), the processing after step 11 is skipped and the process proceeds to step 25. In step 25, the parking state determination unit 13c sets a brake operation flag that is set to “ON” to “OFF” when a brake operation is performed by the driver. In step 26, the parking state determination unit 13c resets a parking determination flag, which will be described later, to “0”, and exits this routine. In the determination of step 10, in the case where the vehicle is traveling near the first vehicle speed threshold value Vs, the vehicle speed threshold value Vs may be provided with hysteresis from the viewpoint of preventing control hunting. (The same applies to other threshold values used in the following description).

  In step 11, the parking state determination unit 13c refers to the state of the brake SW in the vehicle information read by the vehicle information reading unit 13a, and determines whether or not the brake SW is “ON”. When the driver is stepping on the brake pedal, the brake SW is “ON”, so an affirmative determination is made in step 11 and the routine proceeds to step 12. In step 12, the parking state determination unit 13c sets the brake operation flag to “ON”. On the other hand, if the driver has not depressed the brake pedal, the brake SW is “OFF”, so a negative determination is made in step 11, step 12 is skipped, and the routine proceeds to step 13.

  In step 13, the parking state determination unit 13c determines whether or not the brake operation flag is “ON”. If the brake operation flag is set to “OFF”, the routine exits according to the negative determination in step 13. On the other hand, when the brake operation flag is switched from “OFF” to “ON”, the process proceeds to step 14 according to an affirmative determination in step 13.

  In step 14, the parking state determination unit 13c refers to the steering angle in the vehicle information read by the vehicle information reading unit 13a, and this steering angle (absolute value) is larger than the first steering threshold STs. It is determined whether or not. The first steering threshold value STs is a value for determining whether or not the steering angle has been steered to such an extent that it can be regarded as entering the parking area, and an optimal value is set in advance through experiments and simulations. ing. In the present embodiment, the first steering threshold value STs is set to a maximum steering angle value (for example, 20 deg) that cannot be regarded as entering the shoulder side (parking area) from the travel lane if the value is less than that. ing. Here, the steering angle acquired by the vehicle information acquisition unit 11 is “0” in the straight traveling state corresponding to the neutral position of the steering wheel, the steering angle at the right steering is positive, and the steering angle at the left steering is negative. .

  If an affirmative determination is made in step 14, that is, if a steering operation that can be regarded as entering the parking area is performed (steering angle (absolute value)> STs), the process proceeds to step 15. On the other hand, if a negative determination is made in step 14, that is, if a steering operation that can be regarded as entering the parking area is not performed (steering angle (absolute value) ≦ STs), the processing of steps 15 to 18 is performed. Skip to step 19 to be described later.

  FIG. 6 is an explanatory diagram for explaining the own vehicle direction VDR and the road direction LDR. In step 15, the parking state determination unit 13c measures the host vehicle direction, that is, the direction VDR in which the host vehicle is facing. The vehicle direction can be measured by, for example, referring to the navigation information read by the navigation information reading unit 13b and specifying the detected value of the gyro. For example, as shown in FIG. 6, the angle is defined counterclockwise so that true north is “0 °” and west is “90 °” as shown in FIG.

  In step 16, the parking state determination unit 13c calculates a road direction, that is, a direction LDR in which the road on which the host vehicle is traveling extends. In calculating the road direction LDR, the navigation information read by the navigation information reading unit 13b is referred to. Specifically, the parking state determination unit 13c refers to the map information around the host vehicle, and as shown in FIG. 6, the coordinates (Xz1, Yz1) of the node behind the traveling direction of the host vehicle and the node ahead Based on the coordinates (X1, Y1), for example, the road direction LDR is calculated from the following calculation formula for calculating the inner product of the vectors.

(Formula 1)
(1) X1-Xz1 <LDR = COS -1 when 0 {(Y1-Yz1) / ((Y1-Yz1) 2 + (X1-Xz1) 2) -1/2}
(2) When X1−Xz1 ≧ 0 LDR = 2π−COS ⁻¹ {(Y1−Yz1) / ((Y1−Yz1) ²
+ (X1-Xz1) ² ) ^-1/2 }
Since the road direction LDR calculated based on Equation 1 is in radians, when this is converted from a radians system to an arc degree system, the road direction LDR is uniquely defined as a value in the range of 0 ° to 360 °. Is calculated automatically.

  In step 17, the parking state determination unit 13c determines whether or not the difference DD between the host vehicle direction VDR and the road direction LDR is greater than the route threshold value DRs. The reason for making such a determination is to effectively determine whether or not the driver's steering operation is an operation for entering the parking area, not an operation following the progress of the road. Therefore, in this step 17, it is determined whether or not the steering operation deviates from the course direction of the road, that is, the steering operation enters the parking area, by comparing the own vehicle direction VDR and the road direction LDR. judge. In this route threshold value DRs, a maximum value (for example, 25 °) of the difference DD that cannot be regarded as entering the parking area is set in advance.

  In step 17, the parking state determination unit 13c calculates a difference DD between the host vehicle direction VDR and the road direction LDR based on the following equation.

(Formula 2)
DD = | VDR-LDR |
When the calculated value DD is in the range of 181 ° to 360 °, the calculated value is corrected as follows (see Equation 3).

(Formula 3)
DD = 360 ° -DD
If the determination in step 17 is affirmative, that is, if it can be considered that there is an entry into the parking area (DD> DRs), the process proceeds to step 18. On the other hand, if a negative determination is made in step 17, that is, if it cannot be considered that there is an entry into the parking area (DD ≦ DRs), step 18 is skipped and the process proceeds to step 19.

  In step 18, when the determination condition for determining entry into the parking area is satisfied based on the series of determination results described above, the parking state determination unit 13c determines the parking start of the host vehicle and sets the parking determination flag. Set to “1”. The parking determination flag indicates the current parking state according to the value. Specifically, “0” means outside the parking action, “1” means entering the parking area, “2” means traveling in the parking area, and “3” means starting parking in the parking space. In response to the parking determination flag being set to “1”, the camera video switching command unit 13d sets a display pattern so that the scene corresponding to the current parking state is displayed on the camera video display device 16.

  FIG. 7 is an explanatory diagram of a parking state and a display pattern. When the parking determination flag is set to “1” (when there is a vehicle in the state shown in (1) in the figure), the camera image switching command unit 13d is, for example, a vehicle in the right front corner, the left front corner, and the steering direction. The landscape on the lower side is set as a display pattern, and this display pattern is output to the camera video switching device 15. This is from the viewpoint of facilitating confirmation of contact with the front end corner of the gate pillar or the like to the parking area, and curbing of curbs. The camera image switching device 15 selects the images from the camera 14b, the camera 14h, and the camera 14g when turning left, or selects the images from the camera 14b, the camera 14h, and the camera 14c when turning right, Images output from 14h and 14g (or 14c) are displayed on the camera image display device 16.

  In steps 19 to 24, the parking state determination unit 13 c starts parking in the parking area where the host vehicle travels while searching for the parking space and parking in the parking space, as shown in FIG. 7. The parking start is determined, and the information displayed on the camera video display device 16 is switched.

  Specifically, in step 19, the parking state determination unit 13 c determines whether or not the parking determination flag is set to “1”. If an affirmative determination is made in step 19, that is, if the vehicle has entered the parking area, the process proceeds to step 20. On the other hand, if a negative determination is made in step 19, that is, if the vehicle has not entered the parking area, the routine is exited.

  Then, the parking state determination unit 13c determines whether or not the current parking state of the vehicle is a state where the steering wheel is returned and the vehicle is traveling at a low speed while searching for the parking space (the state shown in FIG. 7 (2)). Specifically, in step 20, the parking state determination unit 13c determines whether the vehicle speed is a value within a predetermined range where it is recognized that the vehicle is looking for a parking space, that is, the second vehicle speed threshold value Vf1. It is determined whether or not it is larger than (Vf1 <Vs: 5 km / h, for example) and smaller than the first vehicle speed threshold value Vs. In step 21, the parking state determination unit 13c determines whether or not the steering angle (absolute value) is equal to or smaller than the first steering threshold value STs. If an affirmative determination is made in both steps 20 and 21 (Vf1 <vehicle speed <Vs, steering angle (absolute value) ≦ STs), the routine proceeds to step 22. On the other hand, if a negative determination is made in step 20, or if an affirmative determination is made in step 20, but a negative determination is made in step 21, the process proceeds to step 23.

  In step 22, when the determination condition for determining traveling in the parking area is provided according to the determination result, the parking state determining unit 13c determines traveling of the vehicle in the parking area and sets the parking determination flag. Set to “2”. Then, the camera image switching command unit 13d causes the camera image display device 16 to display a landscape corresponding to the current parking state in response to the parking determination flag being set to “2”. When the parking determination flag is set to “2”, the camera image switching command unit 13d sets, for example, a landscape in front of the left and right from the side of the vehicle (beside the vehicle) as a display pattern, and this is switched to the camera image. Output to the device 15. This is from the viewpoint of facilitating discovery of pedestrians and the like that exist behind other parked vehicles. The camera image switching device 15 selects images from the camera 14g and the camera 14c, and causes the camera image display device 16 to display images output from these cameras 14g and 14g.

  In step 23, the parking state determination unit 13c compares the vehicle speed with the second vehicle speed threshold value Vf1, and determines whether or not the vehicle speed state is such that it is permitted to start parking in the parking space (see FIG. 7 (3) state). If the determination in step 23 is affirmative, that is, if the vehicle speed is equal to or lower than the second vehicle speed threshold value Vf1, the process proceeds to step 24. On the other hand, if a negative determination is made in step 23, that is, if the vehicle speed is greater than the second threshold value Vf1, this routine is exited.

  In step 24, the parking state determination unit 13c determines the parking start of the host vehicle in the parking space when the determination condition for determining the parking start to the parking space is provided according to the above determination result, and the parking determination flag. Is set to “3”. Then, the camera video switching command unit 13d causes the camera video display device 16 to display a landscape corresponding to the current parking state in response to the parking determination flag being set to “3”. For example, as shown in (3) of FIG. 7, when the vehicle turns backward while turning right, the camera image switching command unit 13d sets the left rear corner, the left front corner, and the rear scenery as display patterns. This is output to the camera image switching device 15. As a result, the camera video switching device 15 selects videos from the cameras 14f, 14h, and 14e, and causes the camera video display device 16 to display videos output from these cameras 14f to 14e.

  FIG. 8 is an explanatory diagram for explaining the relationship between the traveling direction and the steering direction during parking and the display patterns corresponding thereto. From the viewpoint of parking assistance to the driver, the camera image switching command unit 13d displays the scenery of the location where the driver should be alerted based on the traveling direction of the vehicle (for example, the gear position) and the steering direction (steering angle). Set as display pattern. Specifically, when performing forward parking while steering to the left, the scenery on the left side down, forward, and right front corner is set to the display pattern, and when parking forward while keeping steering almost neutral, the left front corner, The scenery at the front and right front corners is set as the display pattern. In addition, when performing forward parking while steering to the right, the left front corner, the front and the lower right side scenery are set in the display pattern, and when performing reverse parking while steering to the left, the rear, right rear corner, and right front corner are displayed. Scenery is set as the display pattern. Further, when the vehicle is parked backward while maintaining the steering substantially neutral, the scenery of the left rear corner, the rear, and the right rear corner is set as the display pattern.

  In addition, the seat position command unit 13e switches the seat position to a position suitable for parking in response to the parking determination flag being set to “3”. For example, the optimum seat position is defined as the seat position corresponding to the above-described six parking patterns, and the seat position command unit 13e selects the seat position corresponding to the parking pattern and uses this as the seat position control device. 17 to output. As a result, the seat position control device 17 drives the seat position actuator so as to achieve the set seat position, and controls the position of each part of the seat on which the driver gets (for example, raises the seat). The seat position control method is disclosed in, for example, Japanese Patent Application Laid-Open No. 2004-182150, and should be referred to if necessary.

  As described above, according to the present embodiment, the parking state determination unit 13 c is based on the navigation information acquired by the navigation device 12 and the vehicle information acquired by the vehicle information acquisition unit 11. The parking state of the own vehicle is determined. Then, the camera video switching command unit 13d sets a display pattern based on the parking state determined by the parking state determination unit 13c, and outputs the set display pattern to the camera video switching device 15. Accordingly, the camera video switching device 15 switches the camera 14 that causes the display device 16 to display video according to the set display pattern. As a result, since the camera image necessary for parking is automatically displayed according to the parking state of the vehicle, the driver's parking operation can be effectively supported.

  Further, the parking state determination unit 13c calculates a direction difference between the direction of the road around the host vehicle and the traveling direction of the host vehicle based on the navigation information, and the calculated direction difference, the vehicle speed, the steering angle, However, when the determination condition (vehicle speed <Vs, | steering angle | STs, direction crossing (DD)> DRs) for determining entry into the parking area is satisfied, the start of parking of the host vehicle is determined. When the start of parking of the host vehicle is determined, the camera image switching command unit 13d sets the left and right front corners of the vehicle and the scenery below the side of the vehicle in the steering direction as a display pattern. This makes it possible to automatically display a camera image around the vehicle that is necessary when turning right and left from the road and entering the parking area.

  In addition, after determining the start of parking of the host vehicle, the vehicle state determination unit 13c determines that the steering angle and the vehicle speed determine travel in the parking area (parking determination flag “1”, Vf1 <vehicle speed If <Vs, | steering angle | ≦ STs), the vehicle travels within the parking area. And when the driving | running | working in the parking area of the own vehicle is determined, the camera image | video switching instruction | indication part 13d sets the scenery of the right-and-left front from the vehicle side as a display pattern. As a result, the vehicle state determination unit 13c can determine a traveling state for finding a parking space, and in this case, finds a pedestrian or the like existing behind another parked vehicle. It is possible to display an easy camera image (scenery around the vehicle).

  Further, after determining the parking start of the host vehicle, the parking state determination unit 13c determines that the steering angle and the vehicle speed determine the parking start in the parking space (parking determination flag “1”, Vf1 ≧ vehicle speed). , | Steering angle |> STs), it is determined that parking is started in the parking space in the parking area of the host vehicle. Then, when it is determined that parking of the host vehicle in the parking space is determined, the camera video switching command unit 13d sets a display pattern based on the traveling direction of the vehicle and the steering angle. Thereby, it can switch automatically to the camera image of the vehicle periphery required when parking in a parking space.

  In addition, the parking state determination unit 13c determines the parking state by further using the brake operation signal and the accelerator opening. Thereby, parking start determination can be performed effectively.

  Furthermore, in the present embodiment, the parking assist device 10 includes a seat position actuator 18 that sets the position of each part of the seat on which the driver is seated, a seat position control device 17 that controls the seat position actuator 18 according to a predetermined seat position, It further has a seat position command unit 13e that sets the seat position based on the parking state and outputs the set seat position to the seat position control device 17. Thereby, since it can switch to the seat position suitable for parking at the time of parking, a driver's parking operation can be assisted more effectively.

  In addition, this embodiment is not limited only to the method mentioned above, In the determination of step 11-step 13, you may use the conditions that the accelerator opening is 0 (fully closed). Further, it may be detected that the processing from step 15 to step 17 is off the road on condition that the map matching processing in the navigation device 12 is off.

  Further, as shown in FIG. 9 between step 17 and step 18, the vehicle travels using the content recorded in the map data of the navigation device, for example, POI data (position information of convenience stores, restaurants, etc.). Processing for requesting a condition that the distance to the nearest POI facing the link that has been (map-matched) is within a predetermined value (for example, 50 m) may be provided. Thus, by adding the distance between the latest content included in the navigation information and the host vehicle to the determination condition, it is possible to determine the start of parking with higher accuracy.

  Further, when the processing from step 20 to step 22 is performed for a predetermined distance (for example, 20 m) from the time when the parking determination flag is set to “1”, the parking determination flag is set to “2”. Also good.

(Second Embodiment)
FIG. 10 is a conceptual explanatory diagram of parking support processing of the parking support device 10 according to the second embodiment. The parking assistance device 10 of the second embodiment is different from that of the first embodiment in that it switches the necessary video around the vehicle according to the parking state in the service area. Specifically, for example, in the state shown in (1) of FIG. 10 (service area entry), it is considered that there are few cases where an image around the vehicle is required at the time of traveling on the taxiway to the service area. Therefore, no video is displayed. Next, as shown in (2) of FIG. 10, when the vehicle enters the service area and travels while looking for a parking space while decelerating, a landscape in front of the left and right sides is displayed from the side of the vehicle (straight side). Make it easy to find pedestrians coming out of the shadows of other parked vehicles. Further, as shown in (3) of FIG. 10, after the parking space is found and parking is started, the necessary scenery around the vehicle is displayed according to the forward / backward and steering directions. In addition, description is abbreviate | omitted about the structure same as 1st Embodiment, and difference is demonstrated hereafter.

  FIG. 11 is a flowchart illustrating a procedure of parking support processing according to the second embodiment. The process shown in this flowchart is called at predetermined intervals (for example, 100 ms) and executed by the parking state determination unit 13.

  First, in step 30, the parking state determination unit 13c refers to the navigation information read by the navigation information reading unit 13b and determines whether or not the vehicle has entered the service area. Typical attributes recorded in the map data of the navigation device include, for example, the following road type and link type.

Road type: Expressway national highway, urban highway, general national road, main local road, general prefectural road, main general road, general road, narrow street Link type: main line (up / down line non-separation), main line (up / down line separation), Junction, intersection, ramp, side road on the same route as the main line, side line of service area (SA), rotary Therefore, the parking state determination unit 13c refers to the link type of the link to which the navigation device 12 is map-matched, It is determined whether or not the type is “SA side line”. If an affirmative determination is made in step 30, that is, if the host vehicle has entered the service area, the process proceeds to step 31. In step 31, the parking state determination unit 13c determines that the current parking state is entering the service area, and sets the parking determination flag to “4” indicating that the host vehicle has entered the service area. When the parking determination flag is set to “4”, the camera video switching command unit 13d does not set the display pattern and does not display the video on the camera video display device 16. On the other hand, if an affirmative determination is made in step 30, that is, if the service area has not been entered, the process proceeds to step 32.

  In step 32, the parking state determination unit 13c determines whether or not the vehicle has entered the main line. Specifically, the parking state determination unit 13 c refers to the link type of the navigation device 12 and determines whether or not the type is “main line”. If an affirmative determination is made in step 32, that is, if the vehicle has entered the main line, the routine proceeds to step 41. In step 41, the parking state determination unit 13c sets the brake operation flag to “OFF”. In step 42, the parking state determination unit 13c resets the parking determination flag to “0” and exits this routine. . On the other hand, if a negative determination is made in step 32, that is, if the vehicle is still in the service area, the process proceeds to step 33.

  In step 33, the parking state determination unit 13c determines whether or not the brake SW is “ON” in order to determine whether or not a brake operation has been performed after entering the service area. When the driver performs a brake operation, this brake SW is “ON”, so an affirmative determination is made in step 33 and the routine proceeds to step 34. In step 34, the parking state determination unit 13c sets the brake operation flag to “ON”. On the other hand, when the driver does not perform the brake operation, the brake SW is “OFF”. Therefore, a negative determination is made in step 33, step 34 is skipped, and the process proceeds to step 35.

  In step 35, the parking state determination unit 13c determines whether the vehicle is decelerating to a predetermined vehicle speed or less after entering the service area and searching for a parking space, as in the state of (2) in FIG. Specifically, the parking state determination unit 13c determines whether or not the parking determination flag is set to a value of “1” or more. When the parking determination flag is set to “0”, the routine exits according to the negative determination in step 35. On the other hand, when the parking determination flag is set to a value of “1” or more, the process proceeds to step 36 according to the affirmative determination of step 35.

  In step 36, the parking state determination unit 13c determines whether or not the brake operation flag is set to “ON”. If an affirmative determination is made in step 36, that is, if the brake operation flag is set to “ON”, the routine proceeds to step 37. On the other hand, if a negative determination is made in step 36, that is, if the brake operation flag is set to “OFF”, the routine is exited.

  And in steps 37-40, the parking state determination part 13c is the parking state of the own vehicle in the parking area driving | running | working while the own vehicle searches for a parking space, and the parking start which starts parking to a parking space. Judgment is made and the scenery displayed on the camera image display device 16 is switched.

  Specifically, in step 37, the parking state determination unit 13c determines whether the vehicle speed exists within a predetermined range such that it is recognized that a parking space is being searched, that is, the first threshold value Vf1 ( It is determined whether Vf1 <Vs is greater than 5 km / h, for example, and smaller than the first vehicle speed threshold value Vs. If an affirmative determination is made in step 37, the process proceeds to step 38. On the other hand, if a negative determination is made in step 37, the process proceeds to step 39. The first and second threshold values Vs and Vf1 are set according to the conditions for entering the service area, for example, the setting value of Vs is set to 25 km / h. You may make it a higher value than the case of a parking area.

  In step 38, the parking state determination unit 13c determines that the current parking state is traveling in the parking area when the determination condition for determining traveling in the parking area is satisfied according to the above determination result, and parking determination is performed. Set the flag to “2”. Then, the camera image switching command unit 13d causes the camera image display device 16 to display a landscape corresponding to the current parking state in response to the parking determination flag being set to “2”. When the parking determination flag is set to “2”, the camera image switching command unit 13d sets, for example, the scenery of the front left side and the front right side as the display pattern, and this is set to the camera video switching device 15. Output. This is from the viewpoint of facilitating discovery of pedestrians and the like that exist in the shadow of other parked vehicles such as large buses. The camera image switching device 15 selects images from the camera 14g and the camera 14c, and causes the camera image display device 16 to display images output from these cameras 14g and 14g.

  On the other hand, in step 39, the parking state determination unit 13c compares the vehicle speed with the second vehicle speed threshold value Vf1, and determines whether or not the vehicle speed state is such that it is recognized that parking is started in the parking space. (State shown in FIG. 10 (3)). If an affirmative determination is made in step 39, that is, if the vehicle speed is equal to or less than the second vehicle speed threshold value Vf1, the routine proceeds to step 40. On the other hand, if a negative determination is made in step 39, the routine is exited.

  In Step 40, the parking state determination unit 13c determines that the current parking state is the start of parking in the parking space when the determination condition for determining the parking start in the parking space in the parking area is provided according to the above determination result. Judgment is made and the parking discrimination flag is set to “3”. Then, in response to the parking determination flag being set to “3”, the camera video switching command unit 13d displays a scene corresponding to the current parking state based on the traveling direction and the steering direction during parking. It is displayed on the device 16. For example, as shown in FIG. 10 (3), when the vehicle turns backward while turning left, the camera image switching command unit 13d sets the right rear corner, the right front corner, and the rear scene as display patterns. This is output to the camera image switching device 15. The camera image switching device 15 selects images from the cameras 14d, 14b, and 14e, and causes the camera image display device 16 to display images output from these cameras 14d, 14b, and 14e.

  In addition, the seat position command unit 13e switches the seat position to a position suitable for parking in response to the parking determination flag being set to “3”. For example, the optimum seat position is defined as the seat position corresponding to the above-described six parking patterns, and the seat position command unit 13e selects the seat position corresponding to the parking pattern and uses this as the seat position control device. 17 to output. As a result, the seat position control device 17 drives the seat position actuator so as to achieve the set seat position, and controls the seat position on which the driver gets.

  Thus, in the present embodiment, the parking state determination unit 13c determines whether or not the host vehicle has entered the service area based on the navigation information. And the camera image | video switching instruction | indication part 13d sets a display pattern based on a vehicle speed and a steering angle, when approaching into the service area of the own vehicle is determined. Thereby, according to the parking state in a service area, it can switch automatically to the camera image of a required vehicle periphery. As a result, similar to the first embodiment, since the camera image necessary for parking is automatically displayed according to the parking state of the vehicle, the driver's parking operation can be supported.

  In addition, after the vehicle state determination unit 13c determines that the host vehicle has entered the service area, the vehicle speed includes a determination condition (Vf1 <vehicle speed <Vs) for determining traveling in the parking area. The vehicle travels in the parking area. And when the driving | running | working within the parking area of the own vehicle is determined, the camera image | video switching instruction | indication part 13d sets the scenery of the right-and-left front from the right side of a vehicle as a display pattern. As a result, the vehicle state determination unit 13c can determine a traveling state for finding a parking space, and in this case, finds a pedestrian or the like existing behind another parked vehicle. It is possible to display an easy camera image (scenery around the vehicle).

  In addition, after the parking state determination unit 13c determines that the host vehicle has entered the service area, the parking state determination unit 13c performs parking if the vehicle speed satisfies a determination condition (Vf1 ≧ vehicle speed) for determining parking start in the parking space. The parking start of the own vehicle to the parking space in the area is determined. Then, when it is determined that parking of the host vehicle in the parking space is determined, the camera video switching command unit 13d sets a display pattern based on the traveling direction of the vehicle and the steering angle. Thereby, it can switch automatically to the camera image of the vehicle periphery required when parking in a parking space.

(Third embodiment)
FIG. 12 is a conceptual explanatory diagram of parking support processing of the parking support device 10 according to the third embodiment. The parking support device 10 of the third embodiment is different from that of the first or second embodiment in that parking start to the parking space on the shoulder is determined from driving operations such as steering and vehicle speed, and parking start is determined. If it is, the camera image around the vehicle necessary for parking on the shoulder is switched.

  FIG. 13 is a timing chart showing time-series changes in the steering angle, the vehicle speed, and the brake operation when parking in the parking space on the shoulder. Specifically, the driving operation and the vehicle state when starting parking on the shoulder are as follows when parking at the left end of the road as shown in FIG. 12, for example. (1) While decelerating from running on the main line, (2) steer to the left, and (3) move the vehicle to the left. (4) Steer from the left side to the right side, and (5) Return the steering to neutral (decelerate to (3) to (5) to a low speed). Therefore, in this embodiment, such a feature is extracted and the start of parking on the shoulder is determined.

  FIG. 14 and FIG. 15 are flowcharts showing a procedure of parking support processing according to the third embodiment. The process shown in this flowchart is called at predetermined intervals (for example, 100 ms) and executed by the parking state determination unit 13.

  First, in step 50, the parking state determination unit 13c refers to the vehicle speed in the vehicle information read by the vehicle information reading unit 13a, and the current vehicle speed is smaller than the first vehicle speed threshold value Vs described above. It is determined whether or not. This step 50 is a process for determining whether or not it has been canceled after it is determined that the shoulder parking has started (timing T33 in FIG. 13). If an affirmative determination is made in step 50 (vehicle speed <Vs), the process proceeds to step 52. On the other hand, if a negative determination is made in step 50 (vehicle speed ≧ Vs), the routine proceeds to step 51. In step 51, the parking state determination unit 13c resets the roadside parking determination flag set to “ON” to “OFF” when parking on the roadside is started.

  In step 52, the parking state determination unit 13c determines whether or not the current vehicle speed is smaller than the third vehicle speed threshold value Vt (Vt> Vs). The third vehicle speed threshold value Vt is a value for determining that the vehicle has been decelerated from a predetermined value on the premise of parking on the shoulder of the road, or that the vehicle has started after parking and has accelerated to a predetermined value or more. Yes, it is preset through experiments and simulations. In the present embodiment, the third vehicle speed threshold value Vt is generally set to 40 km / h. If a negative determination is made in step 52, that is, if the vehicle speed is equal to or higher than the third vehicle speed threshold value Vt (vehicle speed ≧ Vt), deceleration based on parking has not been performed, or the vehicle has started after parking. It is determined that the vehicle is accelerating, and the process proceeds to step 53. On the other hand, if an affirmative determination is made in step 52, that is, if the vehicle speed is smaller than the third vehicle speed threshold value Vt (vehicle speed <Vt), it is determined that deceleration has been performed on the premise of parking on the shoulder. (Detection of timing T12 shown in FIG. 13), the process proceeds to step 58.

  In steps 53 to 57, the parking state determination unit 13c resets various flags and parameters, and exits this routine. Specifically, the parking state determination unit 13c sets the steering flag that is set to “ON” to “OFF” when the steering for changing the course in the shoulder direction is performed, and the brake described above. Set the operation flag to “OFF”. In addition, the parking state determination unit 13c sets the reverse steering flag set to “ON” to “OFF” when steering in the reverse direction (reverse steering) is performed as a correction rudder from steering in the shoulder direction. When the steering is returned from the reverse steering to the neutral direction, the steering return flag set to “ON” is set to “OFF”. Furthermore, the parking state determination unit 13c resets the value of the movement amount of the vehicle in the road width direction to “0”.

  In step 58, the parking state determination unit 13c refers to the steering angle in the vehicle information read by the vehicle information reading unit 13a, and this steering angle (absolute value) is larger than the second steering threshold value St. It is determined whether or not. The second steering threshold value St is a value for determining whether or not steering is performed to bring the vehicle toward the parking space in the shoulder direction, and an optimum value is set in advance through experiments and simulations. Has been. In the present embodiment, the second steering threshold value St is set to a maximum value (for example, 10 deg) of the steering angle in a case where it is not recognized that the course is changed from the traveling lane to the shoulder side. The reason why comparison processing is performed using the absolute value of the steering angle here is to deal with left-handed shoulder parking in the case of left-hand traffic, or in the case of right-hand traffic, This is to accommodate parking.

  If an affirmative determination is made in step 58, that is, if steering is being performed toward the parking space on the shoulder (steering angle (absolute value)> steering threshold value St), the process proceeds to step 59. In step 59, the parking state determination unit 13c sets the steering flag to “ON” on the premise that there is steering that can be regarded as a course change in the shoulder direction (detection of timing T11 shown in FIG. 13). On the other hand, if a negative determination is made in step 58, that is, if the course is not changed in the shoulder direction (steering angle (absolute value) ≦ steering threshold value St), the processing in step 59 is skipped. Then, the process proceeds to Step 60.

  In step 60, the parking state determination unit 13c determines whether or not the steering flag is “ON”. If the determination in step 60 is affirmative, that is, if the steering flag is “ON”, the process proceeds to step 61. On the other hand, if a negative determination is made in step 60, that is, if the steering flag is “OFF”, the routine is exited.

  In step 61, the parking state determination unit 13c determines whether or not the steering flag is set from “OFF” to “ON”. If an affirmative determination is made in step 61, the process proceeds to step 62. On the other hand, if a negative determination is made in step 61, step 62 is skipped and the process proceeds to step 63.

  In step 62, the parking state determination unit 13c starts to accumulate the movement amount of the vehicle in the road width direction. As a method for calculating the amount of movement, it can be calculated based on the steering angle and the lateral acceleration based on the neutral position of the steering, or based on the steering angle and the vehicle speed. In addition, the start timing of the integrated value of the moving amount is not only based on the time when the steering flag is switched from “OFF” to “ON”. For example, in step 52, the vehicle speed becomes smaller than the predetermined value Vt. Time may be used as a reference.

  In step 63, the parking state determination unit 13c refers to the state of the brake SW in the vehicle information read by the vehicle information reading unit 13a, and determines whether or not the brake SW is “ON”. If the driver is stepping on the brake pedal, the brake SW is “ON”, so an affirmative determination is made in step 63 and the routine proceeds to step 64. In step 64, the parking state determination unit 13c sets the brake operation flag to “ON”, assuming that the brake operation is started on the premise of parking on the shoulder of the road (detection at timing T13 shown in FIG. 13). On the other hand, when the driver has not depressed the brake pedal, the brake SW is “OFF”, so a negative determination is made in step 63, step 64 is skipped, and the routine proceeds to step 65.

  In step 65, the parking state determination unit 13c determines whether or not the brake operation flag is “ON” in order to determine whether or not the brake operation on the premise of parking on the shoulder is already performed. When the brake operation flag is set to “OFF”, the routine is exited according to a negative determination in step 65. On the other hand, once the brake operation flag is switched from “OFF” to “ON”, the process proceeds to step 66 according to an affirmative determination in step 65.

  In Step 66, the parking state determination unit 13c determines whether or not there has been steering in the reverse direction (reverse steering) as the correction rudder after steering in the shoulder direction. Specifically, if an affirmative determination is made in step 58 under the condition of steering angle> St, an affirmative determination is made in this step under the condition of steering angle <−St. On the other hand, if an affirmative determination is made in step 58 under the condition that the steering angle <-ST, an affirmative determination is made in this step under the condition that the steering angle> St.

  If an affirmative determination is made in step 66, the process proceeds to step 67. In step 67, the parking state determination unit 13c sets the reverse steering flag to “ON”, assuming that reverse steering is performed (detection of timing T2 in FIG. 13). On the other hand, if a negative determination is made in step 66, step 67 is skipped and the process proceeds to step 68. Note that, at the processing timing of step 66, the vehicle speed is smaller than the processing timing of step 58, so the steering angle tends to be larger. Therefore, in the process of step 66, a value (absolute value base) larger than the second steering threshold value St used in the previous step 58 may be used.

  In step 68, the parking state determination unit 13c determines whether or not the reverse steering flag is “ON”. If an affirmative determination is made in step 68, the process proceeds to step 69. On the other hand, if a negative determination is made in step 68, the routine is exited.

  In step 69, the parking state determination unit 13c determines whether or not the steering is returned from the reverse steering to the neutral direction (detection of T13 shown in FIG. 13). Specifically, the parking state determination unit 13c takes the difference between the absolute value of the steering angle in the previous cycle and the absolute value of the steering angle in the current cycle, and if this is negative, the steering angle is the neutral position of the steering It is determined that it has been returned to. Here, the reason for determining the steering in the neutral direction by using the difference between the absolute values of the steering angles is to cope with the return of the left and right steering. If an affirmative determination is made in step 69, the process proceeds to step 70. In step 70, the parking state determination unit 13c sets the steering return flag to “ON”, assuming that the steering is returned from the reverse steering to the neutral direction (detection at timing T31 in FIG. 13). On the other hand, if a negative determination is made in step 69, step 70 is skipped and the process proceeds to step 71.

  In step 71, the parking state determination unit 13c determines whether or not the steering return flag is set to “ON”. If an affirmative determination is made in step 71, the process proceeds to step 72. On the other hand, if a negative determination is made in step 71, this routine is exited.

  In step 72, the parking state determination unit 13c determines whether or not the movement amount in the road width direction that has been calculated in step 62 is greater than the movement amount threshold value Ws. When parking in the parking space on the shoulder side, the vehicle moves more than a predetermined value in the direction of the shoulder (detection of timing T32 shown in FIG. 13). Therefore, a maximum value (for example, 3.0 m) of a movement amount that is not recognized as roadside parking is preset in the movement amount threshold value Ws. The movement amount threshold value Ws may be set as follows using the number of lanes recorded in the map information of the navigation device 12 and the number of lanes N of the link with which the host vehicle is map-matched. .

(Formula 4)
Ws = N × Wt Wt is a constant (for example, 3.0 m)
FIG. 16 is an explanatory diagram for explaining another setting example of the movement amount threshold value Ws. The movement amount threshold value Ws may be set in proportion to the road width Wd using the road width Wd recorded in the map information of the navigation device 12 (see Formula 5).

(Formula 5)
Ws = k × Wd k is a constant (for example, 0.5)
If an affirmative determination is made in step 72, that is, if the vehicle has moved more than the movement amount threshold value Ws in the road shoulder direction (movement amount> Ws), the process proceeds to step 73. On the other hand, if a negative determination is made in step 72, that is, if the amount of movement of the vehicle in the road shoulder direction is equal to or less than the movement amount threshold (movement amount ≦ Ws), the routine is exited.

  In step 73, the parking state determination unit 13c determines whether or not the current vehicle speed is smaller than the first vehicle speed threshold value Vs, and approaches the parking space when parking on the road shoulder and decelerates the vehicle speed to an extremely low speed. Is detected (detection of timing T33 shown in FIG. 13). If an affirmative determination is made in step 73, that is, if the vehicle speed has decreased to such an extent that it can be considered that parking has started (vehicle speed <Vs), the routine proceeds to step 74. On the other hand, if a negative determination is made in step 73, that is, if the vehicle speed is such that parking cannot be considered (vehicle speed ≧ Vs), the routine is exited.

  In step 74, the parking state determination unit 13c, based on the series of determination results described above, parks the host vehicle in the roadside parking space when a determination condition for determining parking start in the roadside parking space is provided. The start is determined, and the shoulder parking determination flag is set to “ON”. If this roadside parking determination flag is “ON”, it means that the following determination condition is satisfied, and this indicates the flow of each timing T11 to T13, T2, T31 to T33 shown in FIG. Means that

(Judgment condition)
1. Steering flag = ON
2. Reverse steering flag = ON
3. Steering return flag = ON
4). Brake operation flag = ON
5. Travel distance in the width direction> Ws
6). Vehicle speed <Vs
In step 74, the camera video switching command unit 13 d causes the camera video display device 16 to display a landscape corresponding to the current parking state in response to the roadside parking determination flag being set to “ON”. Specifically, the camera image switching command unit 13d displays the image around the vehicle that is necessary when the width is brought close to the road shoulder, that is, the front angle of the vehicle corresponding to the road shoulder (movement direction of the own vehicle) side, and the road shoulder side Is set as a display pattern, and is output to the camera image switching device 15. For example, when parking on the left shoulder of a one-way street, even if it is a left-hand traffic or a right-hand traffic, the left front corner, the left front side, and the left rear side are displayed patterns. This is from the viewpoint of facilitating the confirmation of the distance from the vehicle to the curb or guardrail. The camera image switching device 15 selects images from the cameras 14h and 14g, and is output from these cameras 14h and 14g. Video to be displayed on the camera video display device 16.

  In addition, the seat position command unit 13e switches the seat position to a position suitable for parking in response to the parking determination flag being set to “3”. For example, the optimum seat position is defined as the seat position corresponding to the above-described six parking patterns, and the seat position command unit 13e selects the seat position corresponding to the parking pattern and uses this as the seat position control device. 17 to output. As a result, the seat position control device 17 drives the seat position actuator so as to achieve the set seat position, and controls the seat position on which the driver gets.

  Thus, in the present embodiment, the parking state determination unit 13c calculates the amount of movement of the host vehicle in the road shoulder direction based on the vehicle information, and calculates the calculated amount of movement, the vehicle speed, and the steering angle. If the vehicle has the following criteria for determining the start of parking in the parking space on the shoulder (| steering angle |> St, reverse steering, return to neutral direction, travel> Ws, vehicle speed <Vs) Judge the start of parking in the parking space on the shoulder. When the start of parking in the parking space on the shoulder of the own vehicle is determined, the camera image switching command unit 13d displays the front angle of the vehicle corresponding to the moving direction of the own vehicle and the scenery on the lower side of the vehicle. Set as. Accordingly, it is possible to determine the parking start of the road shoulder parking space using the vehicle speed, the steering angle, and the movement amount, and it is possible to automatically switch to the scenery around the vehicle necessary when parking on the road shoulder. As a result, since a camera image necessary for parking is automatically displayed according to the parking state of the vehicle, the driver's parking operation can be supported.

  Further, the parking state determination unit 13c may set a determination condition corresponding to the amount of movement of the host vehicle in the road shoulder direction according to the number of lanes or the road width included in the navigation information. Thereby, the parking start to the parking space of the shoulder can be determined effectively without being influenced by the number of road lanes or the road width.

  In addition, this embodiment is only shown as an example, and for example, in addition to the above-described conditions 1 to 6, it may be added that the vehicle position is a predetermined value (for example, 10 m) or more away from the intersection. . As a method for detecting the distance from the own vehicle position to the nearest intersection, for example, as shown in FIG. 5, nodes before and after the link with which the own vehicle is map-matched (nodes having branches with other roads, ie, 3 It can be uniquely specified as a distance to a node connected to two or more links. Thus, by further providing the distance from the vehicle position included in the navigation information to the nearest intersection as the determination condition, when stopping at the intersection (especially when turning right or left), it is determined that parking has started. Can be prevented.

(Fourth embodiment)
The parking assistance device 10 of the fourth embodiment is different from that of the first embodiment in that the switching threshold to the camera image is changed using the route guidance information of the navigation device, so that it is erroneously performed during route guidance. It is to switch the necessary video around the vehicle when it is off the route.

  FIG. 17 is a flowchart illustrating a parking determination procedure according to the fourth embodiment. The process shown in this flowchart is called at predetermined intervals (for example, 100 ms) and executed by the parking state determination unit 13. This process is performed in parallel with the parking assistance process described in the first to third embodiments. In addition, the parking state determination unit 13 can specify what function the navigation device 12 is currently executing based on the navigation information acquired from the navigation device 12.

  First, in step 80, the parking state determination unit 13c determines whether or not the navigation device 12 is guiding a route. If a negative determination is made in step 80, that is, if the navigation device 12 is not guiding a route, the routine is exited. On the other hand, if an affirmative determination is made in step 80, that is, if the navigation device 12 is guiding a route, the process proceeds to step 81.

  In step 81, the parking state determination unit 13c determines whether or not the navigation device 12 is currently rerouted. The reroute is to reset the route information according to the current vehicle position when the vehicle deviates from the route set by the navigation device 12. If an affirmative determination is made in step 81, that is, if re-routing is currently in progress, the routine proceeds to step 82 described later. On the other hand, if a negative determination is made in step 81, that is, if the current reroute is not in progress, the process proceeds to step 83.

  In step 83, the parking state determination unit 13c determines whether reroute has been completed, that is, whether reroute has already been completed. If the determination in step 83 is affirmative, that is, if reroute has been completed, the process proceeds to step 84. On the other hand, if a negative determination is made in step 83, that is, if re-routing is being performed, this routine is exited.

  In step 84, the parking state determination unit 13c determines whether or not the vehicle deviates from the route information set for the destination, and whether the host vehicle is moving away from the destination. Specifically, the parking state determination unit 13c acquires the distance or time from the current position to the destination from the navigation device 12, and compares it with the value acquired in the previous cycle. If the distance (time) of the current cycle is longer than the distance (time) of the previous cycle, an affirmative determination is made in step 84 and the process proceeds to step 82. On the other hand, if the distance (time) of the current cycle is shorter than the distance (time) of the previous cycle, a negative determination is made in step 84 and the routine is exited.

  In step 82, the parking state determination unit 13c changes various threshold values related to switching of camera image display around the vehicle. For example, by changing the vehicle speed threshold value Vs to a higher value (for example, 25 km / h) or the steering angle STs to a smaller value (for example, 15 deg), the level of the determination condition shown in the above-described embodiment is reduced. It seems that the camera image is set so that it can be easily displayed.

  As described above, according to the present embodiment, the parking state determination unit 13c increases the arrival distance or arrival time to the destination while the vehicle is in the course of guidance and re-routing by the navigation device 12 based on the navigation information. If so, the level of the determination condition described above is reduced. As a result, if the vehicle is mistakenly removed from the route during route guidance, the vehicle enters the parking area to return to the original route, or temporarily parks on the shoulder and makes a U-turn. In that case, compared to a normal case, there is an effect that the scenery around the vehicle is easily displayed.

  In the first to third embodiments described above, these are described in the individual embodiments according to the characteristics. However, the parking state is determined by combining any of these methods, and the display pattern is set. May be. For example, the approach to the service area and the start determination of shoulder parking are combined.

1 is a block diagram illustrating an overall configuration of a parking assistance device 10 according to a first embodiment. It is explanatory drawing which shows typically the parking assistance apparatus 10 shown in FIG. It is a conceptual explanatory drawing of the parking assistance process of the parking assistance apparatus 10 which concerns on 1st Embodiment. It is a flowchart which shows the procedure of the parking assistance process which concerns on 1st Embodiment. It is a flowchart which shows the procedure of the parking assistance process which concerns on 1st Embodiment. It is explanatory drawing explaining the own vehicle direction VDR and road direction LDR. It is explanatory drawing of a parking state and a display pattern. It is explanatory drawing explaining the relationship between the advancing direction and parking direction at the time of parking, and the display pattern corresponding to this. It is explanatory drawing of determination conditions. It is a conceptual explanatory drawing of the parking assistance process of the parking assistance apparatus 10 which concerns on 2nd Embodiment. It is a flowchart which shows the procedure of the parking assistance process which concerns on 2nd Embodiment. It is a conceptual explanatory drawing of the parking assistance process of the parking assistance apparatus 10 which concerns on 3rd Embodiment. It is a timing chart which shows the time-sequential change of a steering angle, a vehicle speed, and brake operation. It is a flowchart which shows the procedure of the parking assistance process which concerns on 3rd Embodiment. It is a flowchart which shows the procedure of the parking assistance process which concerns on 3rd Embodiment. It is explanatory drawing explaining another example of a setting of the movement amount threshold value Ws. It is a flowchart which shows the procedure of the parking assistance process which concerns on 4th Embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Parking assistance apparatus 11 Vehicle information acquisition part 12 Navigation apparatus 12a Own vehicle position detection part 12b Road information acquisition part 12c Map database 13 Parking state determination unit 13a Parking information reading part 13b Navigation information acquisition part 13c Parking state determination part 13d Camera image switching Command unit 13e Sheet position command unit 14 Camera units 14a to 14h Camera 15 Camera image switching device 16 Camera image display device 17 Sheet position control device 18 Sheet position actuator

Claims (15)

In the parking assistance device that displays the video around the vehicle and assists the parking operation,
A plurality of imaging means each for imaging the scenery around the vehicle;
Display means for displaying video output from the imaging means;
Switching means for switching the imaging means for displaying video on the display means from among the plurality of imaging means according to a predetermined display pattern;
Navigation means for acquiring road information on which the vehicle is traveling as navigation information;
Vehicle information acquisition means for acquiring vehicle information including a driving operation amount and a vehicle state amount;
Based on the navigation information acquired by the navigation means and the vehicle information acquired by the vehicle information acquisition means, a parking state determination means for determining the parking state of the host vehicle assuming parking,
The parking state based on the parking state of the vehicle determined by the determination means sets the display pattern, the set display pattern possess a pattern setting means for outputting to said switching means,
The parking state determination means calculates a direction difference between the direction of the road around the host vehicle and the traveling direction of the host vehicle based on the navigation information, and the calculated direction difference and the vehicle speed as the vehicle information When the steering angle, which is the vehicle information, includes a determination condition for determining entry into a parking area, it is determined that parking of the host vehicle is started , and the host vehicle performs the navigation based on the navigation information. If the route is being guided by the means and is being rerouted, or if the arrival distance or arrival time to the destination has increased, the level of the determination condition is reduced,
The pattern setting means, when the parking state determination means determines that parking of the host vehicle is started, sets the left and right front corners of the vehicle and the scenery below the side of the vehicle in the steering direction as the display pattern. A parking assist device. The parking state determination means calculates a movement amount of the host vehicle in a road shoulder direction based on the vehicle information, the calculated movement amount, a vehicle speed that is the vehicle information, and a steering angle that is the vehicle information. Determine the start of parking of the vehicle in the roadside parking space, when the determination condition for determining the parking start to the roadside parking space is provided,
The pattern setting means , when the parking state determination means determines that parking of the own vehicle in the parking space on the shoulder is determined, the front angle of the vehicle corresponding to the moving direction of the own vehicle and the scenery in the front-rear direction on the side of the vehicle The parking assist device according to claim 1, wherein the display pattern is set. In the parking assistance device that displays the video around the vehicle and assists the parking operation,
A plurality of imaging means each for imaging the scenery around the vehicle;
Display means for displaying video output from the imaging means;
Switching means for switching the imaging means for displaying video on the display means from among the plurality of imaging means according to a predetermined display pattern;
Navigation means for acquiring road information on which the vehicle is traveling as navigation information;
Vehicle information acquisition means for acquiring vehicle information including a driving operation amount and a vehicle state amount;
Based on the navigation information acquired by the navigation means and the vehicle information acquired by the vehicle information acquisition means, a parking state determination means for determining the parking state of the host vehicle assuming parking,
Pattern setting means for setting the display pattern based on the parking state of the host vehicle determined by the parking state determination means, and outputting the set display pattern to the switching means;
The parking state determination means calculates a movement amount of the host vehicle in a road shoulder direction based on the vehicle information, the calculated movement amount, a vehicle speed that is the vehicle information, and a steering angle that is the vehicle information. Are determined to determine the start of parking in the roadside parking space, the parking start determination unit determines the parking start of the vehicle in the roadside parking space, On the basis, if the vehicle is in the course of guidance and re-route by the navigation means, or if the arrival distance or arrival time to the destination is increased, the level of the determination condition is reduced,
The pattern setting means , when the parking state determination means determines that parking of the own vehicle in the parking space on the shoulder is determined, the front angle of the vehicle corresponding to the moving direction of the own vehicle and the scenery in the front-rear direction on the side of the vehicle Is set as the display pattern. When the parking state determination means determines the start of parking of the host vehicle, the steering angle that is the vehicle information and the vehicle speed that is the vehicle information satisfy a determination condition for determining traveling in the parking area. , Determine the driving in the parking area of the vehicle,
The said pattern setting means sets the scenery ahead from the vehicle right-and-left side as the said display pattern, when driving | running | working in the parking area of the own vehicle is determined by the said parking state determination means. The parking assistance apparatus described in 1. After the parking state determination means determines the parking start of the host vehicle, the steering condition that is the vehicle information and the vehicle speed that is the vehicle information determine the parking start in the parking space in the parking area. If it is equipped with, determine the parking start of the parking space of the vehicle,
The pattern setting means , based on the vehicle traveling direction as the vehicle information and the steering angle as the vehicle information, when the parking state determination means determines that parking of the host vehicle in the parking space is determined. The parking assist device according to claim 1, wherein the display pattern is set. The parking state determination means according to claim 1, characterized in that it further comprises a most recent content on the road included in the navigation information, the distance between the host vehicle as the determination condition Parking assistance device. The parking state determination means determines whether the host vehicle has entered the service area based on the navigation information,
The said pattern setting means sets the said display pattern based on the vehicle speed which is the said vehicle information, when the approach to the service area of the own vehicle is determined by the said parking state determination means. Or the parking assistance apparatus described in Claim 3. The parking state determination means determines whether the vehicle information is within the parking area of the host vehicle when the vehicle speed as the vehicle information has a determination condition for determining traveling in the parking area after determining the entry of the host vehicle into the service area. Judgment of driving,
The said pattern setting means sets the scenery ahead from the vehicle right-and-left side as the said display pattern, when driving | running | working in the parking area of the own vehicle is determined by the said parking state determination means. 7. The parking assistance device described in 7. The parking state determination means, after determining the entry to the service area of the host vehicle, when the vehicle speed as the vehicle information has a determination condition for determining the start of parking in the parking space in the parking area, Determine the parking start of your vehicle in the parking space,
The pattern setting means , based on the vehicle traveling direction as the vehicle information and the steering angle as the vehicle information, when the parking state determination means determines that parking of the host vehicle in the parking space is determined. The parking assist device according to claim 7, wherein the display pattern is set. The parking state determination means, the determination condition corresponding to the amount of movement of the shoulder direction of the vehicle, according to claim 2, characterized in that variably set according to the number of lanes or roads included in the navigation information or The parking assistance device according to claim 3 . The said parking state determination means has further the distance from the own vehicle position contained in the said navigation information to the nearest intersection as the said determination conditions, It was described in Claim 2 or Claim 3 characterized by the above-mentioned. Parking assistance device. The said parking state determination means further has the brake operation signal which is the said vehicle information, or the accelerator opening which is the said vehicle information as the said determination conditions, The Claim 1 or Claim 3 characterized by the above-mentioned. Parking assistance device. Seat position driving means for setting the position of each part of the seat on which the driver is seated;
Sheet position control means for controlling the sheet position driving means according to a predetermined sheet position;
A seat position setting unit configured to set the seat position based on the parking state of the host vehicle determined by the parking state determination unit and to output the set seat position to the seat position control unit; The parking assistance device according to claim 1 or 3 , characterized in that In the parking support method for supporting the parking operation by displaying the video around the vehicle,
Navigation information including road information on which the host vehicle travels is acquired, vehicle information including a driving operation amount and a vehicle state amount is acquired, and the host vehicle is premised on parking based on the navigation information and the vehicle information. Determining the parking state of the vehicle, setting a display pattern based on the parking state of the host vehicle, and displaying the scenery around the vehicle corresponding to the display pattern ,
Based on the navigation information, a direction difference between the direction of the road around the host vehicle and the traveling direction of the host vehicle is calculated, the calculated direction difference, the vehicle speed as the vehicle information, and the steering as the vehicle information. When the corner has a determination condition for determining entry into the parking area, the parking start of the host vehicle is determined and , based on the navigation information, the host vehicle is in the course of guidance and reroute, Alternatively, if the arrival distance or arrival time to the destination has increased, the level of the determination condition is reduced,
When it is determined that parking of the host vehicle is determined , a parking assist method , wherein the left and right front corners of the vehicle and the scenery on the lower side of the vehicle in the steering direction are set as the display pattern . In the parking support method for supporting the parking operation by displaying the video around the vehicle,
Navigation information including road information on which the host vehicle travels is acquired, vehicle information including a driving operation amount and a vehicle state amount is acquired, and the host vehicle is premised on parking based on the navigation information and the vehicle information. Determining the parking state of the vehicle, setting a display pattern based on the parking state of the host vehicle, and displaying the scenery around the vehicle corresponding to the display pattern ,
Based on the vehicle information, the amount of movement of the host vehicle in the shoulder direction is calculated, and the calculated amount of movement, the vehicle speed that is the vehicle information, and the steering angle that is the vehicle information are the parking space on the shoulder. When the determination condition for determining the start of parking is satisfied, the start of parking of the host vehicle in the parking space on the shoulder is determined, and the host vehicle is in the course of guidance and reroute based on the navigation information Or, if the arrival distance or arrival time to the destination has increased, reduce the level of the determination condition,
When it is determined that parking of the own vehicle in the parking space on the shoulder is determined, the front angle of the vehicle corresponding to the moving direction of the own vehicle and the landscape in the front-rear direction of the vehicle are set as the display pattern. Parking assistance method.

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